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40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.1.2 Minimum requirements	The accuracy requirement in table 8.7.11.1.1 is valid under the following conditions: P-CCPCH_RSCP1,2  -102 dBm.. where the received P-CCPCH Ec/Io is defined as, and the received SCH Ec/Io is defined as, and SCH_Ec/Ior is equally divided between primary synchronisation code and the sum of all secondary synchronisation codes, where the secondary synchronisation codes are also equally divided. Table 8.7.11.1.1: SFN-CFN observed time difference accuracy for an intra frequency UTRA TDD neighbour cell Parameter Unit Accuracy [chip] Conditions Io [dBm/3,84 MHz] SFN-CFN observed time difference chip +/-0,5 -94...-50 The normative reference for this requirement is TS 25.123 [2] clause 9.1.1.11 and A.9.1.10.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.1.3 Test Purpose	The purpose of this test is to verify that the measurement accuracy of SFN-CFN observed time difference is within the limit specified in clause 8.7.11.1.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.1.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.1.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. In this case all cells are on the same frequency. Cell 1 and cell 2 shall be synchronised, i.e. share the same frame and timeslot timing. The DL DPCH shall be transmitted in timeslot 4 and the UL DPCH shall be transmitted in timeslot 12. The second Beacon timeslot shall be provided in timeslot 8 for cell 1 and in timeslot 10 for cell 2. During the test, the timing difference between cell 1 and cell 2 can be set to any value from 0…255 frames. The SFN-CFN observed time difference accuracy requirements in the intra-frequency case are tested by using test parameters in Table 8.7.11.1.2. Table 8.7.11.1.2: SFN-CFN observed time difference intra frequency test parameters Parameter Unit Test 1 Test 2 Test 3 Cell 1 Cell 2 Cell 1 Cell 2 Cell 1 Cell 2 DL timeslot number 0 2 0 2 0 2 UTRA RF Channel number Channel 1 Channel 1 Channel 1 PCCPCH_Ec/Ior dB -3 -3 -3 SCH_Ec/Ior dB -9 -9 -9 SCH_toffset 0 5 0 5 0 5 OCNS_Ec/Ior dB -3,12 -3,12 -3,12 Ioc dBm / 3,84 MHz -75.2 -75.2 -57.8 -54.7 -98.7 -98.7 Îor/Ioc dB 5 5 7 3 3 3 Io, Note 1 dBm / 3,84 MHz -69 -50 -94 Propagation condition AWGN AWGN AWGN NOTE 1: Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. 1) A call is set up according to the test procedure specified in TS 34.108 [3] subclause 7.3.2.3. The RF parameters for Test 1 are set up according to table 8.7.11.1.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.1.4.2 Procedure	1) SS shall transmit the MEASUREMENT CONTROL message. 2) UE shall transmit periodically MEASUREMENT REPORT messages. 3) SS shall check "OFF" and "Tm" values in MEASUREMENT REPORT message and calculate SFN-CFN observed time difference value according to the definition in clause 5.1.11 of TS 25.225 [22]. This value shall be compared to the actually set SFN-CFN observed time difference value for each MEASUREMENT REPORT message. 4) SS shall count the number of MEASUREMENT REPORT messages transmitted by UE. After 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.1.2 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. After further 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.1.2 for Test 3. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. 5) After further 1000 MEASUREMENT REPORT messages have been received from UE, the SS shall transmit RRC CONNECTION RELEASE message. 6) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in the default message content in clause 9 of 34.108 [3] and in Annex I, with the following exceptions: MEASUREMENT CONTROL message (Step 1): Information Element/Group name Value/Remark Message Type (10.2.17) UE information elements -RRC transaction identifier 0 -Integrity check info Not Present Measurement Information elements -Measurement Identity 1 -Measurement Command (10.3.7.46) Modify -Measurement Reporting Mode (10.3.7.49) -Measurement Report Transfer Mode AM RLC -Periodical Reporting / Event Trigger Reporting Mode Periodical reporting -Additional measurements list (10.3.7.1) Not Present -CHOICE Measurement type Intra-frequency measurement -Intra-frequency measurement (10.3.7.36) -Intra-frequency measurement objects list (10.3.7.33) Not Present -Intra-frequency measurement quantity (10.3.7.38) -Filter coefficient (10.3.7.9) 0 -CHOICE mode TDD -Measurement quantity list 1 -Measurement quantity Primary CCPCH RSCP -Intra-frequency reporting quantity (10.3.7.41) -Reporting quantities for active set cells (10.3.7.5) -SFN-SFN observed time difference reporting indicator No report -Cell synchronisation information reporting indicator TRUE -Cell Identity reporting indicator TRUE -CHOICE mode TDD -Timeslot ISCP reporting indicator FALSE -Primary CCPCH RSCP reporting indicator TRUE -Pathloss reporting indicator TRUE -Reporting quantities for monitored set cells (10.3.7.5) -SFN-SFN observed time difference reporting indicator No report -Cell synchronisation information reporting indicator TRUE -Cell Identity reporting indicator TRUE -CHOICE mode TDD -Timeslot ISCP reporting indicator FALSE -Proposed TGSN reporting required FALSE -Primary CCPCH RSCP reporting indicator TRUE -Pathloss reporting indicator TRUE -Reporting quantities for detected set cells (10.3.7.5) Not Present -Reporting cell status (10.3.7.61) -CHOICE reported cell Report all active set cells + cells within monitored set on used frequency -Maximum number of reported cells Virtual/active set cells + 2 -Measurement validity (10.3.7.51) Not Present -CHOICE report criteria (10.3.7. -Periodical reporting criteria (10.3.7.53) -Amount of reporting Infinity -Reporting interval 250 ms Physical channel information elements -DPCH compressed mode status info (10.3.6.34) Not Present
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.1.5 Test requirements	The SFN-CFN observed time difference accuracy shall meet the requirements in clause 8.7.11.1.2. NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4. 8.7.11.1A Intra frequency measurement requirement for 1,28 Mcps option Void 8.7.11.1B Intra frequency measurement requirement for 7,68 Mcps option 8.7.11.1B.1 Definition and applicability The intra frequency SFN-CFN observed time difference is defined as the SFN-CFN observed time difference from the active cell to a neighbour cell that is in the same frequency. This measurement is specified in clause 5.1.11 of TS 25.225 [22]. The reference point for the SFN-CFN observed time difference shall be the antenna connector of the UE. The requirements and this test apply to all types of UTRA TDD UE. 8.7.11.1B.2 Minimum requirements The accuracy requirement in table 8.7.11.1B.2.1 is valid under the following conditions: P-CCPCH_RSCP1,2  -102 dBm.. where the received P-CCPCH Ec/Io is defined as, and the received SCH Ec/Io is defined as, and SCH_Ec/Ior is equally divided between primary synchronisation code and the sum of all secondary synchronisation codes, where the secondary synchronisation codes are also equally divided. Table 8.7.11.1B.2.1: SFN-CFN observed time difference accuracy for an intra frequency UTRA TDD neighbour cell Parameter Unit Accuracy [chip] Conditions Io [dBm/7.68 MHz] SFN-CFN observed time difference chip +/-1 -94...-50 The normative reference for this requirement is TS 25.123 [2] clause 9.1.1.11.1 and A.9.3.10. 8.7.11.1B.3 Test Purpose The purpose of this test is to verify that the measurement accuracy of SFN-CFN observed time difference is within the limit specified in clause 8.7.11.1B.2. 8.7.11.1B.4 Method of test 8.7.11.1B.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. In this case all cells are on the same frequency. Cell 1 and cell 2 shall be synchronised, i.e. share the same frame and timeslot timing. The DL DPCH shall be transmitted in timeslot 4 and the UL DPCH shall be transmitted in timeslot 12. The second Beacon timeslot shall be provided in timeslot 8 for cell 1 and in timeslot 10 for cell 2. During the test, the timing difference between cell 1 and cell 2 can be set to any value from 0…255 frames. The SFN-CFN observed time difference accuracy requirements in the intra-frequency case are tested by using test parameters in Table 8.7.11.1B.4.1.1. Table 8.7.11.1B.4.1.1: SFN-CFN observed time difference intra frequency test parameters Parameter Unit Test 1 Test 2 Test 3 Cell 1 Cell 2 Cell 1 Cell 2 Cell 1 Cell 2 DL timeslot number 0 2 0 2 0 2 UTRA RF Channel number Channel 1 Channel 1 Channel 1 PCCPCH_Ec/Ior dB -3 -3 -3 SCH_Ec/Ior dB -9 -9 -9 SCH_toffset 0 5 0 5 0 5 OCNS_Ec/Ior dB -3,12 -3,12 -3,12 Ioc dBm / 7.68 MHz -75.2 -75.2 -57.8 -54.7 -98.7 -98.7 Îor/Ioc dB 5 5 7 3 3 3 Io, Note 1 dBm / 7.68 MHz -69 -50 -94 Propagation condition AWGN AWGN AWGN NOTE 1: Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. 1) A call is set up according to the test procedure specified in TS 34.108 [3] subclause 7.3.2.3. The RF parameters for Test 1 are set up according to table 8.7.11.1B.4.1.1. 8.7.11.1B.4.2 Procedure 1) SS shall transmit the MEASUREMENT CONTROL message. 2) UE shall transmit periodically MEASUREMENT REPORT messages. 3) SS shall check "OFF" and "Tm" values in MEASUREMENT REPORT message and calculate SFN-CFN observed time difference value according to the definition in clause 5.1.11 of TS 25.225 [22]. This value shall be compared to the actually set SFN-CFN observed time difference value for each MEASUREMENT REPORT message. 4) SS shall count the number of MEASUREMENT REPORT messages transmitted by UE. After 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.1B.4.1.1 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. After further 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.1B.4.1.1 for Test 3. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. 5) After further 1000 MEASUREMENT REPORT messages have been received from UE, the SS shall transmit RRC CONNECTION RELEASE message. 6) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in the default message content in clause 9 of 34.108 [3] and in Annex I, with the following exceptions: MEASUREMENT CONTROL message (Step 1): Information Element/Group name Value/Remark Message Type (10.2.17) UE information elements -RRC transaction identifier 0 -Integrity check info Not Present Measurement Information elements -Measurement Identity 1 -Measurement Command (10.3.7.46) Modify -Measurement Reporting Mode (10.3.7.49) -Measurement Report Transfer Mode AM RLC -Periodical Reporting / Event Trigger Reporting Mode Periodical reporting -Additional measurements list (10.3.7.1) Not Present -CHOICE Measurement type Intra-frequency measurement -Intra-frequency measurement (10.3.7.36) -Intra-frequency measurement objects list (10.3.7.33) Not Present -Intra-frequency measurement quantity (10.3.7.38) -Filter coefficient (10.3.7.9) 0 -CHOICE mode TDD -Measurement quantity list 1 -Measurement quantity Primary CCPCH RSCP -Intra-frequency reporting quantity (10.3.7.41) -Reporting quantities for active set cells (10.3.7.5) -SFN-SFN observed time difference reporting indicator No report -Cell synchronisation information reporting indicator TRUE -Cell Identity reporting indicator TRUE -CHOICE mode TDD -Timeslot ISCP reporting indicator FALSE -Primary CCPCH RSCP reporting indicator TRUE -Pathloss reporting indicator TRUE -Reporting quantities for monitored set cells (10.3.7.5) -SFN-SFN observed time difference reporting indicator No report -Cell synchronisation information reporting indicator TRUE -Cell Identity reporting indicator TRUE -CHOICE mode TDD -Timeslot ISCP reporting indicator FALSE -Proposed TGSN reporting required FALSE -Primary CCPCH RSCP reporting indicator TRUE -Pathloss reporting indicator TRUE -Reporting quantities for detected set cells (10.3.7.5) Not Present -Reporting cell status (10.3.7.61) -CHOICE reported cell Report all active set cells + cells within monitored set on used frequency -Maximum number of reported cells Virtual/active set cells + 2 -Measurement validity (10.3.7.51) Not Present -CHOICE report criteria (10.3.7. -Periodical reporting criteria (10.3.7.53) -Amount of reporting Infinity -Reporting interval 250 ms Physical channel information elements -DPCH compressed mode status info (10.3.6.34) Not Present 8.7.11.1B.5 Test requirements The SFN-CFN observed time difference accuracy shall meet the requirements in clause 8.7.11.1B.2. NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2 Inter frequency measurement requirement for 3,84 Mcps option
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.1 Definition and applicability	The inter frequency SFN-CFN observed time difference is defined as the SFN-CFN time difference from the active cell to a UTRA TDD neighbour cell that is in a different frequency. This measurement is specified in clause 5.1.11 of TS 25.225 [22]. The reference point for the SFN-CFN observed time difference shall be the antenna connector of the UE. The requirements and this test apply to all types of UTRA TDD UE.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.2 Minimum requirements	The accuracy requirement in table 8.7.11.2.1 is valid under the following conditions: P-CCPCH_RSCP1,2  -102 dBm.. where the received P-CCPCH Ec/Io is defined as, and the received SCH Ec/Io is defined as, and SCH_Ec/Ior is equally divided between primary synchronisation code and the sum of all secondary synchronisation codes, where the secondary synchronisation codes are also equally divided. Table 8.7.11.2.1: SFN-CFN observed time difference accuracy for an inter frequency UTRA TDD neighbour cell Parameter Unit Accuracy [chip] Conditions Io [dBm/3,84 MHz] SFN-CFN observed time difference chip +/-0,5 -94...-50 The normative reference for this requirement is TS 25.123 [2] clause 9.1.1.11 and A.9.1.10.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.3 Test purpose	The purpose of this test is to verify that the measurement accuracy of SFN-CFN observed time difference is within the limit specified in clause 8.7.11.2.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. In this case, UTRA TDD cell 1 and UTRA TDD cell 2 are on different frequencies. Cell 1 and cell 2 shall be synchronised, i.e. share the same frame and timeslot timing. The DL DPCH shall be transmitted in timeslot 4 and the UL DPCH shall be transmitted in timeslot 12. The second Beacon timeslot shall be provided in timeslot 8 for cell 1 and in timeslot 10 for cell 2. During the test, the timing difference between cell 1 and cell 2 can be set to any value from 0…256 frames. The SFN-CFN observed time difference accuracy requirements in the intra-frequency case are tested by using test parameters in Table 8.7.11.2.2. Table 8.7.11.2.2: SFN-CFN observed time difference inter frequency test parameters Parameter Unit Test 1 Test 2 Test 3 Cell 1 Cell 2 Cell 1 Cell 2 Cell 1 Cell 2 DL timeslot number 0 2 0 2 0 2 UTRA RF Channel number Channel 1 Channel 2 Channel 1 Channel 2 Channel 1 Channel 2 PCCPCH_Ec/Ior dB -3 -3 -3 SCH_Ec/Ior dB -9 -9 -9 SCH_toffset 0 5 0 5 0 5 OCNS_Ec/Ior dB -3,12 -3,12 -3,12 Ioc dBm / 3,84 MHz -75.2 -75.2 -57.8 -54.7 -98.7 -98.7 Îor/Ioc dB 5 5 7 3 3 3 Io, Note 1 dBm / 3,84 MHz -69 -50 -94 Propagation condition AWGN AWGN AWGN NOTE 1: Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. 1) A call is set up according to the test procedure specified in TS 34.108 [3] subclause 7.3.2.3. The RF parameters for Test 1 are set up according to table 8.7.11.2.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.4.2 Procedure	1) SS shall transmit the MEASUREMENT CONTROL message. 2) UE shall transmit periodically MEASUREMENT REPORT messages. 3) SS shall check "OFF" and "Tm" values in MEASUREMENT REPORT message and calculate SFN-CFN observed time difference value according to the definition in clause 5.1.11 of TS 25.225 [22]. This value shall be compared to the actually set SFN-CFN observed time difference value for each MEASUREMENT REPORT message. 4) SS shall count the number of MEASUREMENT REPORT messages transmitted by UE. After 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.2.2 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. After further 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.2.2 for Test 3. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. 5) After further 1000 MEASUREMENT REPORT messages have been received from UE, the SS shall transmit RRC CONNECTION RELEASE message. 6) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in the default message content in clause 9 of 34.108 [3] and in Annex I, with the following exceptions: MEASUREMENT CONTROL message for inter frequency measurements (Step 1): Information Element/Group name Value/Remark Message Type (10.2.17) UE information elements -RRC transaction identifier 0 -Integrity check info Not Present Measurement Information elements -Measurement Identity 2 -Measurement Command (10.3.7.46) Setup -Measurement Reporting Mode (10.3.7.49) -Measurement Report Transfer Mode AM RLC -Periodical Reporting / Event Trigger Reporting Mode Periodical reporting -Additional measurements list (10.3.7.1) Not Present -CHOICE Measurement type Inter-frequency measurement -Inter-frequency measurement (10.3.7.16) -Inter-frequency measurement objects list (10.3.7.13) -CHOICE inter-frequency cell removal Not present -New inter-frequency cells Cell 2 information is included -Cell for measurement Not Present -Inter-frequency measurement quantity (10.3.7.18) -CHOICE reporting critera Inter-frequency reporting criteria -Filter coefficient (10.3.7.9) 0 -CHOICE mode TDD -Measurement quantity for frequency quality estimate Primary CCPCH RSCP -Inter-frequency reporting quantity (10.3.7.21) -UTRA carrier RSSI FALSE -Frequency quality estimate TRUE -Non frequency related cell reporting quantities (10.3.7.5) -SFN-SFN observed time difference reporting indicator No report -Cell synchronisation information reporting indicator TRUE -Cell identity reporting indicator TRUE -CHOICE mode TDD -Timeslot ISCP reporting indicator FALSE -Proposed TGSN Reporting required FALSE -Primary CCPCH RSCP reporting indicator TRUE -Pathloss reporting indicator FALSE -Reporting cell status (10.3.7.61) -CHOICE reported cell Report all active set cells + cells within monitored set on used frequency -Maximum number of reported cells Virtual/active set cells + 2 -Measurement validity (10.3.7.51) Not present -Inter-frequency set update Not present -CHOICE report criteria (10.3.7. -Periodical reporting criteria (10.3.7.53) -Amount of reporting Infinity -Reporting interval 500 ms Physical channel information elements -DPCH compressed mode status info (10.3.6.34) Not Present
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.11.2.5 Test requirements	The SFN-CFN observed time difference accuracy shall meet the requirements in clause 8.7.11.2.2. NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4. 8.7.11.2A Inter frequency measurement requirement for 1,28 Mcps option Void 8.7.11.2B Inter frequency measurement requirement for 7,68 Mcps option 8.7.11.2B.1 Definition and applicability The inter frequency SFN-CFN observed time difference is defined as the SFN-CFN time difference from the active cell to a UTRA TDD neighbour cell that is in a different frequency. This measurement is specified in clause 5.1.11 of TS 25.225 [22]. The reference point for the SFN-CFN observed time difference shall be the antenna connector of the UE. The requirements and this test apply to 7.68Mcps TDD UE. 8.7.11.2B.2 Minimum requirements The accuracy requirement in table 8.7.11.2B.2.1 is valid under the following conditions: P-CCPCH_RSCP1,2  -102 dBm.. where the received P-CCPCH Ec/Io is defined as, and the received SCH Ec/Io is defined as, and SCH_Ec/Ior is equally divided between primary synchronisation code and the sum of all secondary synchronisation codes, where the secondary synchronisation codes are also equally divided. Table 8.7.11.2B.2.1: SFN-CFN observed time difference accuracy for an inter frequency UTRA TDD neighbour cell Parameter Unit Accuracy [chip] Conditions Io [dBm/7.68 MHz] SFN-CFN observed time difference chip +/-1 -94...-50 The normative reference for this requirement is TS 25.123 [2] clause 9.1.1.11.1 and A.9.3.10. 8.7.11.2B.3 Test purpose The purpose of this test is to verify that the measurement accuracy of SFN-CFN observed time difference is within the limit specified in clause 8.7.11.2B.2. 8.7.11.2B.4 Method of test 8.7.11.2B.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. In this case, UTRA TDD cell 1 and UTRA TDD cell 2 are on different frequencies. Cell 1 and cell 2 shall be synchronised, i.e. share the same frame and timeslot timing. The DL DPCH shall be transmitted in timeslot 4 and the UL DPCH shall be transmitted in timeslot 12. The second Beacon timeslot shall be provided in timeslot 8 for cell 1 and in timeslot 10 for cell 2. During the test, the timing difference between cell 1 and cell 2 can be set to any value from 0…256 frames. The SFN-CFN observed time difference accuracy requirements in the intra-frequency case are tested by using test parameters in Table 8.7.11.2B.4.1.1. Table 8.7.11.2B.4.1.1: SFN-CFN observed time difference inter frequency test parameters Parameter Unit Test 1 Test 2 Test 3 Cell 1 Cell 2 Cell 1 Cell 2 Cell 1 Cell 2 DL timeslot number 0 2 0 2 0 2 UTRA RF Channel number Channel 1 Channel 2 Channel 1 Channel 2 Channel 1 Channel 2 PCCPCH_Ec/Ior dB -3 -3 -3 SCH_Ec/Ior dB -9 -9 -9 SCH_toffset 0 5 0 5 0 5 OCNS_Ec/Ior dB -3,12 -3,12 -3,12 Ioc dBm / 7.68 MHz -75.2 -75.2 -57.8 -54.7 -98.7 -98.7 Îor/Ioc dB 5 5 7 3 3 3 Io, Note 1 dBm / 7.68 MHz -69 -50 -94 Propagation condition AWGN AWGN AWGN NOTE 1: Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. 1) A call is set up according to the test procedure specified in TS 34.108 [3] subclause 7.3.2.3. The RF parameters for Test 1 are set up according to table 8.7.11.2B.4.1.1. 8.7.11.2.4B.2 Procedure 1) SS shall transmit the MEASUREMENT CONTROL message. 2) UE shall transmit periodically MEASUREMENT REPORT messages. 3) SS shall check "OFF" and "Tm" values in MEASUREMENT REPORT message and calculate SFN-CFN observed time difference value according to the definition in clause 5.1.11 of TS 25.225 [22]. This value shall be compared to the actually set SFN-CFN observed time difference value for each MEASUREMENT REPORT message. 4) SS shall count the number of MEASUREMENT REPORT messages transmitted by UE. After 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.2B.4.1.1 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. After further 1000 MEASUREMENT REPORT messages have been received from UE, the RF parameters are set up according to table 8.7.11.2B.4.1.1 for Test 3. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 1s and ignore the MEASUREMENT REPORT messages during this period. Then, steps 2) and 3) above are repeated. 5) After further 1000 MEASUREMENT REPORT messages have been received from UE, the SS shall transmit RRC CONNECTION RELEASE message. 6) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in the default message content in clause 9 of 34.108 [3] and in Annex I, with the following exceptions: MEASUREMENT CONTROL message for inter frequency measurements (Step 1): Information Element/Group name Value/Remark Message Type (10.2.17) UE information elements -RRC transaction identifier 0 -Integrity check info Not Present Measurement Information elements -Measurement Identity 2 -Measurement Command (10.3.7.46) Setup -Measurement Reporting Mode (10.3.7.49) -Measurement Report Transfer Mode AM RLC -Periodical Reporting / Event Trigger Reporting Mode Periodical reporting -Additional measurements list (10.3.7.1) Not Present -CHOICE Measurement type Inter-frequency measurement -Inter-frequency measurement (10.3.7.16) -Inter-frequency measurement objects list (10.3.7.13) -CHOICE inter-frequency cell removal Not present -New inter-frequency cells Cell 2 information is included -Cell for measurement Not Present -Inter-frequency measurement quantity (10.3.7.18) -CHOICE reporting critera Inter-frequency reporting criteria -Filter coefficient (10.3.7.9) 0 -CHOICE mode TDD -Measurement quantity for frequency quality estimate Primary CCPCH RSCP -Inter-frequency reporting quantity (10.3.7.21) -UTRA carrier RSSI FALSE -Frequency quality estimate TRUE -Non frequency related cell reporting quantities (10.3.7.5) -SFN-SFN observed time difference reporting indicator No report -Cell synchronisation information reporting indicator TRUE -Cell identity reporting indicator TRUE -CHOICE mode TDD -Timeslot ISCP reporting indicator FALSE -Proposed TGSN Reporting required FALSE -Primary CCPCH RSCP reporting indicator TRUE -Pathloss reporting indicator FALSE -Reporting cell status (10.3.7.61) -CHOICE reported cell Report all active set cells + cells within monitored set on used frequency -Maximum number of reported cells Virtual/active set cells + 2 -Measurement validity (10.3.7.51) Not present -Inter-frequency set update Not present -CHOICE report criteria (10.3.7. -Periodical reporting criteria (10.3.7.53) -Amount of reporting Infinity -Reporting interval 500 ms Physical channel information elements -DPCH compressed mode status info (10.3.6.34) Not Present 8.7.11.2B.5 Test requirements The SFN-CFN observed time difference accuracy shall meet the requirements in clause 8.7.11.2B.2. NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.12 UE transmitted power
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.12.1 UE transmitted power for 3.84 Mcps TDD Option	Void 8.7.12.1A UE transmitted power for 1.28 Mcps TDD Option 8.7.12.1A.1 Definition and applicability The UE transmitted power absolute accuracy is defined as difference between the UE reported value and the UE transmitted power measured by test system. The reference point for the UE transmitted power shall be the antenna connector of the UE. The requirements and this test apply to all types of 1.28 Mcps TDD UE. 8.7.12.1A.2 Minimum requirements The measurement period in CELL_DCH state and CELL_FACH state is 1 slot. Table 8.7.12.1A.2.1 UE transmitted power absolute accuracy Parameter Unit Accuracy [dB] PUEMAX 24dBm PUEMAX 21dBm UE transmitted power  PUEMAX dBm +1/-3 2 PUEMAX > UE transmitted power  PUEMAX-1 dBm +1,5/-3,5 2,5 PUEMAX-1 > UE transmitted power  PUEMAX-2 dBm +2/-4 3 PUEMAX-2 > UE transmitted power  PUEMAX-3 dBm +2,5/-4,5 3,5 PUEMAX-3 > UE transmitted power  PUEMAX-10 dBm +3/-5 4 NOTE 1: User equipment maximum output power, PUEMAX, is the maximum output power level without tolerance defined for the power class of the UE in 3GPP TS 25.102 "UTRA (UE) TDD; Radio Transmission and Reception". NOTE 2: UE transmitted power is the reported value. The normative reference for this requirement is TS 25.123 clause 9.1.2.1. 8.7.12.1A.3 Test purpose The purpose of this test is to verify that for any reported value of UE Transmitted Power in the range PUEMAX to PUEMAX-10 that the actual UE mean power lies within the range specified in clause 8.7.12.1A.2. 8.7.12.1A.4 Method of test 8.7.12.1A.4.1 Initial conditions Test environment: normal, TL/VL, TL/VH, TH/VL, TH/VH; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS to the UE antenna connector as shown in figure A.1. The test parameters are given in Table 8.7.12.1A.4.1 and 8.7.12.1A.4.2 below. In the measurement control information it shall be indicated to the UE that periodic reporting of the UE transmitted power measurement shall be used. Table 8.7.12.1A.4.1: General test parameters for UE transmitted power Parameter Unit Value Comment DCH parameters DL Reference Measurement Channel 12.2 kbps As specified in clause C.3.1.2 DL-Power Control Off Table 8.7.12.1A.4.2: Cell Specific parameters for UE transmitted power Parameter Unit Cell 1 Timeslot Number 0 DwPTS UTRA RF Channel Number (NOTE 2) Channel 1 PCCPCH_Ec/Ior dB -3 D wPCH _Ec/Ior dB 0 OCNS_Ec/Ior dB - 3 dB 3 dBm/1.28 MHz -70 PCCPCH_RSCP (NOTE 1) dBm -70 Propagation Condition AWGN NOTE 1: PCCPCH RSCP level has been calculated from other parameters for information purposes. They are not settable parameters themselves. NOTE2: In the case of multi-frequency network, the UTRA RF Channel Number can be set for the primary frequency in this test. 8.7.12.1A.4.2 Procedure 1) A call is set up according to the test procedure specified in TS 34.108 [3] subclause 7.3.2. The RF parameters are set up according to table 8.7.12.1A.4.1 and 8.7.12.1A.4.2. Set the UE power and Maximum allowed UL TX power to the maximum power for the UE power class. 2) SS shall send continuously during the entire test Up power control commands to the UE. 3) SS shall transmit the MEASUREMENT CONTROL message as defined in the specific message contents below. 4) Decode the UE Transmitted power reported by the UE in the next available MEASUREMENT REPORT message. 5) Measure the mean power of the UE over a period of one timeslot. 6) Steps 4 and 5 shall be repeated until statistical significance according to Annex F.6.2.8 is achieved. 7) Decrease the Maximum allowed UL TX power by 1 dB. The SS shall transmit the PHYSICAL CHANNEL RECONFIGURATION message, as defined in the specific message contents below. 8) SS shall wait for the PHYSICAL CHANNEL RECONFIGURATION COMPLETE message from the UE. 9) Repeat from step 4) until the Maximum allowed UL TX Power reaches PUEMAX-10. Specific Message Contents All messages indicated above shall use the same content as described in default message content in clause 9 of 34.108 [3], with the following exceptions: MEASUREMENT CONTROL message: Information Element Value/Remark Message Type UE information elements -RRC transaction identifier -Integrity check info -message authentication code -RRC message sequence number 0 SS calculates the value of MAC-I for this message and writes to this IE. The first/ leftmost bit of the bit string contains the most significant bit of the MAC-I. SS provides the value of this IE, from its internal counter. Measurement Information elements -Measurement Identity -Measurement Command -CHOICE Measurement type -UE Internal measurement quantity -Measurement quantity -Filter coefficient -UE Internal reporting quantity -UE Transmitted power -CHOICE mode -CHOICE TDD option -1.28Mcps TDD -Tadv info -CHOICE report criteria -Amount of reporting -Reporting interval -Measurement Reporting Mode -Measurement Report Transfer Mode -Periodical Reporting / Event Trigger Reporting Mode -AdditionalMeasurementList 5 SETUP UE Internal measurement UE Transmitted power 0 TRUE TDD False Periodical reporting criteria Infinity 250 AM RLC Periodical reporting Not Present MEASUREMENT REPORT message: Information Element Value/remark Message Type Integrity check info The presence of this IE is dependent on PIXIT statements in TS 34.123-2. If integrity protection is indicated to be active, this IE shall be present with the values of the sub IEs as stated below. Else, this IE and the sub-IEs shall be absent. - Message authentication code This IE is checked to see if it is present. The value is compared against the XMAC-I value computed by SS. - RRC Message sequence number This IE is checked to see if it is present. The value is used by SS to compute the XMAC-I value. Measurement identity 5 Measured Results - CHOICE Measurement UE Internal measured results - Choice mode TDD - UE Transmitted power list Checked that this IE is present -UE Transmitted power Checked that this IE is present - CHOICE TDD option -1.28Mcps TDD -Tadv Checked that this IE is absent Measured results on RACH Checked that this IE is absent Additional measured results Checked that this IE is absent Event results Checked that this IE is absent PHYSICAL CHANNEL RECONFIGURATION message: Information Element Value/Remark Version Message Type UE Information Elements -RRC transaction identifier -Integrity check info -message authentication code -RRC message sequence number -Integrity protection mode info -Ciphering mode info -Activation time -New U-RNTI -New C-RNTI -RRC State Indicator -UTRAN DRX cycle length coefficient 0 SS calculates the value of MAC-I for this message and writes to this IE. The first/ leftmost bit of the bit string contains the most significant bit of the MAC-I. SS provides the value of this IE, from its internal counter. Not Present Not Present Not Present Not Present Not Present CELL_DCH Not Present CN Information Elements -CN Information info Not Present UTRAN mobility information elements -URA identity Not Present RB information elements -Downlink counter synchronisation info Not Present PhyCH information elements -Frequency info Not Present Uplink radio resources -Maximum allowed UL TX power At the first time this value is set to PUEMAX-1. After the second time this value is decreased　with 1 dB from previous value. 8.7.12.1A.5 Test requirements Compare each of the UE transmitted power reports against the following mean power measurement. At least 90% of the mean power measurements for any one value of reported UE transmitted power shall be within the range specified in table 8.7.12.1A.5. Table 8.7.12.1A.5 UE transmitted power test requirements UE reported value SS measured mean power (X) range [dBm] PUEMAX 24dBm PUEMAX 21dBm UE_TX_POWER_104 33-3.7  X < 34+1.7 33-2.7  X < 34+2.7 UE_TX_POWER_103 32-3.7  X < 33+1.7 32-2.7  X < 33+2.7          UE_TX_POWER_097 26-3.7  X < 27+1.7  UE_TX_POWER_096 25-3.7  X < 26+1.7  UE_TX_POWER_095 24-3.7  X < 25+1.7  UE_TX_POWER_094 23-4.2  X < 24+2.2 23-2.7  X < 24+2.7 UE_TX_POWER_093 22-4.7  X < 23+2.7 22-2.7  X < 23+2.7 UE_TX_POWER_092 21-5.2  X < 22+3.2 21-2.7  X < 22+2.7 UE_TX_POWER_091 20-5.7  X < 21+3.7 20-3.2  X < 21+3.2 UE_TX_POWER_090 19-5.7  X < 20+3.7 19-3.7  X < 20+3.7 UE_TX_POWER_089 18-5.7  X < 19+3.7 18-4.2  X < 19+4.2 UE_TX_POWER_088  17-4.7  X < 18+4.7 UE_TX_POWER_087  16-4.7  X < 17+4.7 UE_TX_POWER_086  15-4.7  X < 15+4.7          UE_TX_POWER_022 -49-5.7  X < -48+3.7 -49-4.7  X < -48+4.7 UE_TX_POWER_021 -50-5.7  X < -49+3.7 -50-4.7  X < -49+4.7 NOTE 1: Although test requirements are given for all UE reported values, a good UE will likely report values between PUEMAX and PUEMAX - 10 dB. However, even a good UE may report also wider range of values due to errors in TPC command reception and allowed range specified for UE transmit power setting accuracy when Maximum Allowed UL TX Power has been signaled. On the other hand, a faulty UE may report any power value but then it does not fulfill the Table 8.7.12.1A.5 requirements for mean power or then it will not pass some other tests e.g. TC 5.2 of this specification. NOTE 2: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.13 UE Transmission Power Headroom
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.13.1 UPH for 3.84Mcps TDD Option	Void 8.7.13.1A UPH for 1.28Mcps TDD Option 8.7.13.1A.1 Definition and applicability The accuracy requirements for the UE transmission power headroom depends on the total power transmitted by the UE as defined in the functionality in section 9.2.6.3 of TS 25.321[14], section 9.1.2.3.2 of TS 25.123 [2] and section 5.1.16 of TS 25.225 [22]. The requirements and this test apply to Release 7 and later releases for all types of UTRA for the 1.28Mcps TDD UE that supports E-DCH and HSDPA. 8.7.13.1A.2 Minimum Requirements The UE transmission power headroom (UPH) is defined in section 5.1.16 of TS 25.225 [22] as the ratio of the maximum UE transmission power and the product of P e-base power and serving cell path loss, and shall be calculated as following: Where: P max, tx = min {Maximum allowed UL TX Power, P max} is the UE maximum transmission power; Maximum allowed UL TX Power is set by UTRAN and defined in [9]; P max is the UE nominal maximum output power according to the UE power class and specified in [1] table 6.1; P e-base is a closed-loop quantity defined in [9] and L Path_loss is the serving cell path loss. The reference point for the UE transmission power headroom shall be the antenna connector of the UE. The accuracy requirements for UE transmission power headroom depends on the total power transmitted by the UE. Table 8.7.13.1A defines the accuracy of the measured quantity as defined in section 9.1.2.3.2 of TS 25.123 [2]. Table 8.7.13.1A.1: UPH reporting accuracy Total UE output power value (dBm) UPH reporting Accuracy [dB]* PUEMAX 24dBm PUEMAX 21dBm Total output power  PUEMAX +1/-3 2 PUEMAX-1 Total output power <PUEMAX +1,5/-3,5 2,5 PUEMAX-2 Total output power <PUEMAX-1 +2/-4 3 PUEMAX-3 Total output power <PUEMAX-2 +2,5/-4,5 3,5 PUEMAX-10 Total output power <PUEMAX-3 +3/-5 4 Note: UPH reporting accuracy is the difference between the UPH reported by the UE and the actual uplink power headroom Note: PUEMAX, is the maximum output power level without tolerance defined for the power class of the UE in 3GPP TS 25.102 8.7.13.1A.3 Test purpose The purpose of this test case is to verify that the UE transmission power headroom measurement report accuracy is within the specified limits defined in section 9.1.2.3.2 of 25.123 [2] shown in table 8.7.13.1A.1. 8.7.13.1A.4 Method of test 8.7.13.1A.4.1 Initial conditions Test environment: normal, TL/VL, TL/VH, TH/VL, TH/VH; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect the SS (node B emulator) to the UE antenna connector as shown in figure A.1. 2) HSDPA and E-DCH configurations are set as in table 8.7.13.1A.2. Table 8.7.13.1A.2: General test parameters for UE transmission power headroom Parameter Unit Value Comment DL DCH configuration DL Reference Measurement Channel 12.2 kbps As specified in Annex C.3.1.2 of the present document DL configuration DL Fixed Reference Channel (FRC 1) As specified in Annex C.4.2.1 of the present document E-DCH configuration 5 ms TTI E-DCH Transport Block Size Table 0 according to TS 25.321 [13] annex BC.1 DL Power Control Off Active cell Cell 1 Reference E-TFCI index 0 as per Table 0 according to TS 25.321 [13] annex BC.1. 3) The power levels and cell specific parameters are set as in table 8.7.13.1A.3. Table 8.7.13.1A.3: Cell Specific parameters for UE transmission power headroom Parameter Unit Cell 1 Timeslot Number 0 DwPTS UTRA RF Channel Number (NOTE 2) Channel 1 PCCPCH_Ec/Ior dB - 3 D wPCH _Ec/Ior dB 0 OCNS_Ec/Ior dB - 3 dB 3 dBm/ 1.28 MHz -70 PCCPCH RSCP, Note 1 dB m -70 Propagation Condition AWGN NOTE 1: PCCPCH RSCP level has been calculated from other parameters for information purposes. They are not settable parameters themselves. NOTE2: In the case of multi-frequency network, the UTRA RF Channel Number can be set for the primary frequency in this test. 4) The UE is switched on. 5) An E-DCH call is set up according to TS 34.108 [3] 7.3.9 with the following exceptions in the RADIO BEARER SETUP message. These e exceptions are derived from Table 8.7.13.2, and in addition allow the beta values to be set and each UL physical channel to be at constant power during the measurement. Table 8.7.13.1A.4: Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) Information Element/Group name Value/Remark E-PUCH Info(TDD only) >E-TFCS information >>Reference Beta Information QPSK list >>>Reference Code Rate 0.2 >>>Reference Beta -14 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.3 >>>Reference Beta -13 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.4 >>>Reference Beta -12 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.5 >>>Reference Beta -10 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.6 >>>Reference Beta -9 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.7 >>>Reference Beta -8 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.8 >>>Reference Beta -7 >>Reference Beta Information QPSK list >>>Reference Code Rate 0.9 >>>Reference Beta -6 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.2 >>>Reference Beta -9 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.3 >>>Reference Beta -8 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.4 >>>Reference Beta -6 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.5 >>>Reference Beta -5 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.6 >>>Reference Beta -4 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.7 >>>Reference Beta -2 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.8 >>>Reference Beta -1 >>Reference Beta Information 16QAM list >>>Reference Code Rate 0.9 >>>Reference Beta 0 >CHOICE TDD mode >>1.28 Mcps TDD >>>PRXdes_base -85 >>>Beacon PL Est. >>>TPC step size 1 >>>E-PUCH TS configuration list >>>>TS number 1 >>>E-PUCH TS configuration list >>>>TS number 2 >>>Minimum allowed code rate 3(0.1) >>>Maximum allowed code rate 50(0.8) 8.7.13.1A.4.2 Test procedure 1) The Scheduling Information configuration for the E-DCH indicates to the UE that it shall periodically report Scheduling Information, which contains UPH measurement every E-DCH TTI. During the test the system simulator shall not send any scheduling grant to the UE, and therefore the UE will not send any payload data on the E-DCH. 2) The SS shall set the CPRI value in E-AGCH to be 3 dB for a power class 3 UE, or 0 dB for a power class 4 UE by using uplink power control. CRRI and TRRI value in E-AGCH respectively is “00100”and “11000”. 3) The SS measures both the power transmitted by the UE on E-PUCH and the total output power of the UE in time slot which assigned E-PUCH transmitted by SS. The SS shall analyse the E-TFCI transmitted on the E-UCCH for each E-DCH TTI and estimates the e. The SS averages both the E-PUCH output power，e and total output power of the UE over 100 times. Then, the SS calculates the difference between average E-PUCH power measured and e. 4) The SS estimates the UE transmission power headroom as the difference between the maximum allowed uplink transmits power (P max) and the difference calculated in step 3. 5) The SS notes the UE transmission power headroom value reported in the Scheduling Information. 6) The SS calculates the difference between the UE transmission power headroom value estimated in step 4 and the reported UE transmission power headroom noted in step 5. The SS notes this as the UE transmission power headroom accuracy, and compares it to the applicable limit according to the total output power measured in step 3. 7) If the UE transmission power headroom accuracy exceeds the value in Table 8.7.13.1A.5 count a bad result, otherwise a good result with respect to the actually set TX power. 8) Repeat steps 3 to 7 in order to collect more good or bad results for the currently set power level. Continue the repetition, until statistical significance according to Annex F.6.2.8 is achieved. 9) The SS sends 5 up TPC commands at the nesting E-AGCH to bring the TX power of the UE up by a nominal 1 dB step, and then alternate UP/DOWN to maintain constant TX power. 10) Repeat steps 3 through 9 and note the UE transmission power headroom accuracy for each UE total power value until the UE stops reporting UPH or does not give lower UPH values for 8 consecutive repetitions of steps 3 through 9. 8.7.13.1A.5 Test requirements The UE transmission power headroom measurement report accuracy recorded in steps 6, 9 and 10 above shall meet the requirements in table 8.7.13.1A.5. The rate of correct measurements observed during repeated tests shall be at least 90%. To pass the test, the UE transmission power headroom accuracy for each power level in the reporting range must pass. Once a power level is passed, no more results need be collected on this power level. Table 8.7.13.1A.5: Test requirement for UPH reporting accuracy Total UE output power value (dBm) UPH reporting Accuracy [dB] PUEMAX 24dBm PUEMAX 21dBm Total output power  PUEMAX +1.7/-3.7 2.7 PUEMAX-1 Total output power <PUEMAX +2.2/-4.2 3.2 PUEMAX-2 Total output power <PUEMAX-1 +2.7/-4.7 3.7 PUEMAX-3 Total output power <PUEMAX-2 +3.2/-5.2 4.2 PUEMAX-10 Total output power <PUEMAX-3 +3.7/-5.7 4.7 Note: UPH reporting accuracy is the difference between the UPH reported by the UE and the actual uplink power headroom *Note: PUEMAX, is the maximum output power level without tolerance defined for the power class of the UE in 3GPP TS 25.102 NOTE1: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4. 8.7.13.1B UPH for 7.68Mcps TDD Option Void
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14 E-UTRAN FDD RSRP	Editor’s note: This Test case is incomplete for frequencies above 3GHz • The Test system uncertainties applicable above 3GHz are undefined • The Test Tolerances and Test Requirements applicable above 3GHz are undefined
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.1 Definition and applicability	The absolute accuracy of RSRP is defined as the RSRP measured from a cell that has different carrier frequency from the serving cell. The E-UTRAN FDD RSRP absolute accuracy measurement is used for handover between UTRAN TDD and E-UTRAN FDD for Rel.9 and later. The requirements and this test apply to the combined UTRAN TDD and E-UTRAN FDD UE.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.2 Minimum Requirements	In Cell DCH state, whether or not UE requires idle intervals to perform E-UTRAN measurements, the requirements for accuracy of E-UTRA RSRP measurements in CELL_DCH state shall be the same as the inter-frequency RSRP Accuracy Requirements in 3GPP TS 36.133, as follows: Cell specific reference signals are transmitted either from one, two or four antenna ports. Conditions defined in 36.101 Section 7.3 for reference sensitivity are fulfilled. RSRP\|dBm according to 36.133 Annex B.3.3 for a corresponding Band Table 8.7.14.2-1: RSRP Inter frequency absolute accuracy Parameter Unit Accuracy [dB] Conditions1 Normal condition Extreme condition Bands 1, 4, 6, 10, 11, 18, 19, 21, 23, 24, 33, 34, 35, 36, 37, 38, 39, 40 Bands 2, 5, 7, 41 Band 25 Bands 3, 8, 12, 13, 14, 17, 20, 22 Bands 9, 42, 43 Io Io Io Io Io RSRP for Ês/Iot  -6 dB dBm 6 9 -121dBm/15kHz … -70dBm/ BWChannel -119dBm/15kHz … -70dBm/ BWChannel -117.5dBm/15kHz … -70dBm/ BWChannel -118dBm/15kHz … -70dBm/ BWChannel -120dBm/15kHz … -70dBm/ BWChannel RSRP for Ês/Iot  -6 dB dBm 8 11 -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel Note 1: Io is assumed to have constant EPRE across the bandwidth. The normative reference for this requirement is TS 25.123 [2] clauses 9.1.1.5a and A.9.2.5a.1.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.3 Test purpose	The purpose of this test is to verify that the E-UTRA FDD RSRP measurement absolute accuracy is within the specified limits. This test will verify the requirements in 8.7.14.2 and applies to UE supporting this capability.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.4.1 Initial conditions	Test environment: normal, TL/VL, TL/VH, TH/VL, TH/VH; see clauses G.2.1 and G.2.2. Frequencies to be tested: see table J.2 in Annex J. In the test in Cell_DCH state, “E-UTRAN FDD RSRP Measurement” is applied to measure on E-UTRAN FDD. Tables 8.7.14.4.1-1 and 8.7.14.4.1-2 define the limits of signal strengths and code powers on the UTRA TDD cell. In the measurement control information periodic reporting of E-UTRAN FDD RSRP is indicated to the UE. The E-UTRAN FDD test parameters are given in Table 8.7.14.4.1-3. Table 8.7.14.4.1-1: General parameters of E-UTRA FDD RSRP measurement tests Parameter Unit Value Comment DCH parameters DL Reference Measurement Channel 12.2 kbps As specified in TS 25.102 section A.2.2 Power Control On Target quality value on DTCH BLER 0.01 Active cell Cell 1 1.28Mcps TDD cell Neighbour cell Cell 2 E-UTRA FDD cell CP length of cell 2 normal Idle intervals period ms 80 As specified in TS 25.331 Filter coefficient 0 L3 filtering is not used Inter-RAT(E-UTRA FDD) measurement quantity E-UTRA FDD RSRP Table 8.7.14.4.1-2: E-UTRA FDD RSRP measurement tests parameters (cell 1) Parameter Unit Test 1, Test 2 DL timeslot number 0 DwPTS UTRA RF Channel number (NOTE) Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Îor/Ioc dB 3 Ioc dBm / 1.28MHz -75 Propagation condition AWGN NOTE: In the case of multi-frequency, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.14.4.1-3: E-UTRA FDD RSRP measurement tests parameters (cell 2) Parameter Unit Test 1 Test 2 E-UTRA RF Channel Number 1 1 BWchannel MHz 10 10 Measurement bandwidth 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.1 in TS 36.521-3 [33] R.6 FDD R.6 FDD OCNG Patterns defined in D.1.2 (OP.2 FDD) in TS 36.521-3 [33] OP.2 FDD OP.2 FDD PBCH_RA dB 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 1, 4, 6,10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -88.65 -117 Bands 2, 5 and 7 -115 Band 25 -113.5 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -114 Band 9 -116 dB 10 -4 RSRPNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -78.65 -121 Bands 2, 5 and 7 -119 Band 25 -117.5 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -118 Band 9 -120 IoNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/9 MHz -50.45 -87.76 Bands 2, 5 and 7 -85.76 Band 25 -84.26 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -84.76 Band 9 -86.76 dB 10 -4 Propagation condition - AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRP and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP minimum requirements are specified assuming independent interference and noise at each receiver antenna port.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.4.2 Test Procedure	1) A call is set up according to the test procedure specified in TS 34.108 [3] clause 7.3.2. The RF parameters for Test 1 are set up according to table 8.7.14.5-2. 2) SS shall transmit the MEASUREMENT CONTROL message for inter RAT measurement. In the measurement control information periodic reporting of the EUTRAN FDD RSRP is requested to the UE. 3) UE shall transmit periodically MEASUREMENT REPORT messages. 4) SS shall check RSRP value of Cell 2 in the MEASUREMENT REPORT messages. Levels of Cell 2 reported by the UE are compared to the actual level of Cell 2 for each MEASUREMENT REPORT message. 5) SS shall check MEASUREMENT REPORT messages transmitted by UE until statistical significance according to Annex Tables G.2.3-1 in TS 36.521-3 [33] is achieved. 6) The RF parameters are set up according to tables 8.7.14.5-3 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 5s and ignore the MEASUREMENT REPORT messages during this period. Then, step 4) and 5) above are repeated. 7) The SS shall transmit RRC CONNECTION RELEASE message. 8) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in the default message content in clause 9 of 34.108 [3], with the following exceptions: NOTE: Numbers in brackets after an item e.g “Message Type (10.2.17)” in the IE description are references to clause numbers in TS 25.331 [9] describing that item in more detail. MEASUREMENT CONTROL message for EUTRAN FDD measurement (Step 1): Information Element Value/Remark Message Type (10.2.17) UE information elements -RRC transaction identifier -Integrity check info 0 Not Present Measurement Information elements -Measurement Identity -Measurement Command -Measurement Reporting Mode - Measurement Report Transfer Mode - Periodical Reporting / Event Trigger Reporting Mode -Additional measurement list -CHOICE Measurement Type -Inter-frequency measurement object list -CHOICE Inter-frequency cell removal -New inter-frequency cells -Cell for measurement -Inter-frequency measurement quantity -CHOICE reporting criteria -Filter coefficient -CHOICE mode -Measurement quantity -Inter-frequency reporting quantity -UTRA Carrier RSSI -Frequency quality estimate -Non frequency related cell reporting quantities -SFN-SFN observed time difference reporting indicator -Cell synchronisation information reporting indicator -Maximum number of reported cells -Measurement validity -Inter-frequency set update -CHOICE report criteria -Amount of reporting -Reporting interval 2 Setup Acknowledged mode RLC Periodical reporting Not Present Inter-RAT measurement Not Present Cell 2 information is included Not Present Inter-frequency reporting criteria 0 EUTRAN FDD RSRP FALSE FALSE No report Report all active set cells + cells within monitored set on used frequency Virtual/active set cells + 1 Not Present Not Present Periodical reporting criteria Infinity 500 ms Physical channel information elements -DPCH compressed mode status info Not Present
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.14.5 Test requirements	Table 8.7.14.5-2 and table 8.7.14.5-3 defines the primary level settings including test tolerances for all tests. For the test to pass, the ratio of successful reported values according to table 8.7.14.5-4 in each test shall be more than 90%, with a confidence level of 95%. Table 8.7.14.5-1: Void Table 8.7.14.5-2: UTRAN TDD cell specific test parameters for E-UTRAN FDD RSRP absolute accuracy tests Parameter Unit Test 1, Test 2 DL timeslot number 0 DwPTS UTRA RF Channel number (NOTE) Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Îor/Ioc dB 3 Ioc dBm / 1.28MHz -75 Propagation condition AWGN NOTE: In the case of multi-frequency, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.14.5-3: E-UTRAN FDD cell specific test parameters for E-UTRAN FDD RSRP absolute accuracy tests Parameter Unit Test 1 Test 2 E-UTRA RF Channel Number 1 1 BWchannel MHz 10 10 Measurement bandwidth 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.1 in TS 36.521-3 [33] R.6 FDD R.6 FDD OCNG Patterns defined in D.1.2 (OP.2 FDD) in TS 36.521-3 [33] OP.2 FDD OP.2 FDD PBCH_RA dB 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 1, 4, 6,10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -88.95 -117.00 Bands 2, 5 and 7 -115.00 Band 25 -113.50 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -114.00 Band 9 -116.00 dB 10.00 -3.20 RSRPNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -78.95 -120.20 Bands 2, 5 and 7 -118.20 Band 25 -116.70 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -117.20 Band 9 -119.20 IoNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/9 MHz -50.75 -87.52 Bands 2, 5 and 7 -85. 52 Band 25 -84.02 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -84.52 Band 9 -86.52 dB 10.00 -3.20 Propagation condition - AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRP and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP minimum requirements are specified assuming independent interference and noise at each receiver antenna port. Table 8.7.14.5-4: E-UTRAN FDD RSRP absolute accuracy requirements for the reported values Test 1 Test 2 All bands Bands 1, 4, 6, 10, 11 18, 19, 21, 23, 24 Bands 2, 5, 7 Band 25 Bands 3, 8, 12, 13, 14, 17, 20, 22 Band 9 Normal Conditions Lowest reported value (Cell 2) RSRP_52 RSRP_13 RSRP_15 RSRP_17 RSRP_16 RSRP_14 Highest reported value (Cell 2) RSRP_71 RSRP_28 RSRP_30 RSRP_31 RSRP_31 RSRP_29 Extreme Conditions Lowest reported value (Cell 2) RSRP_49 RSRP_10 RSRP_12 RSRP_14 RSRP_13 RSRP_11 Highest reported value (Cell 2) RSRP_74 RSRP_31 RSRP_33 RSRP_34 RSRP_34 RSRP_32 NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15 E-UTRAN TDD RSRP	Editor’s note: This Test case is incomplete for frequencies above 3GHz • The Test system uncertainties applicable above 3GHz are undefined • The Test Tolerances and Test Requirements applicable above 3GHz are undefined
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.1 Definition and applicability	The absolute accuracy of RSRP is defined as the RSRP measured from a cell that has different carrier frequency from the serving cell. The E-UTRAN TDD RSRP absolute accuracy measurement is used for handover between UTRAN TDD and E-UTRAN TDD. The requirements and this test apply to release 9 and later releases UTRA 1.28Mcps TDD UEs that support release 8 and later releases E-UTRA TDD.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.2 Minimum Requirements	In Cell DCH state, whether or not UE requires idle intervals to perform E-UTRAN measurements, the requirements for accuracy of E-UTRA RSRP measurements in CELL_DCH state shall be the same as the inter-frequency RSRP Accuracy Requirements in 3GPP TS 36.133 [26], as follows: Cell specific reference signals are transmitted either from one, two or four antenna ports. Conditions defined in TS 36.101 [27] Section 7.3 for reference sensitivity are fulfilled. RSRP\|dBm according to TS 36.133 [26] Annex B.3.3 for a corresponding Band Table 8.7.15.2-1: RSRP Inter frequency absolute accuracy Parameter Unit Accuracy [dB] Conditions1 Normal condition Extreme condition Bands 1, 4, 6, 10, 11, 18, 19, 21, 23, 24, 33, 34, 35, 36, 37, 38, 39, 40 Bands 2, 5, 7, 41 Band 25 Bands 3, 8, 12, 13, 14, 17, 20, 22 Bands 9, 42, 43 Io Io Io Io Io RSRP for Ês/Iot  -6 dB dBm 6 9 -121dBm/15kHz … -70dBm/ BWChannel -119dBm/15kHz … -70dBm/ BWChannel -117.5dBm/15kHz … -70dBm/ BWChannel -118dBm/15kHz … -70dBm/ BWChannel -120dBm/15kHz … -70dBm/ BWChannel RSRP for Ês/Iot  -6 dB dBm 8 11 -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel -70dBm/ BWChannel … -50dBm/ BWChannel Note 1: Io is assumed to have constant EPRE across the bandwidth. The normative reference for this requirement is TS 25.123 [2] clauses 9.1.1.5a and A.9.2.5a.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.3 Test purpose	The purpose of this test is to verify that the E-UTRA TDD RSRP measurement absolute accuracy is within the specified limits. This test will verify the requirements in 8.7.15.2 and applies to UE supporting this capability.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.4.1 Initial conditions	Test environment: normal, TL/VL, TL/VH, TH/VL, TH/VH; see clauses G.2.1 and G.2.2. Frequencies to be tested: see table J.2 in Annex J. In the test in Cell_DCH state, “E-UTRAN TDD RSRP Measurement” is applied to measure on E-UTRAN TDD. Tables 8.7.15.4.1-1 and 8.7.15.4.1-2 define the limits of signal strengths and code powers on the UTRA TDD cell. In the measurement control information periodic reporting of E-UTRAN TDD RSRP is indicated to the UE. The E-UTRAN TDD test parameters are given in Table 8.7.15.4.1-3. Table 8.7.15.4.1-1: General parameters of E-UTRA TDD RSRP measurement tests Parameter Unit Value Comment DCH parameters DL Reference Measurement Channel 12.2 kbps As specified in section C.3.1 Power Control On Target quality value on DTCH BLER 0.01 Active cell Cell 1 1.28Mcps UTRA TDD cell Neighbour cell Cell 2 E-UTRA TDD cell CP length of cell 2 Normal Uplink-downlink configuration of cell 2 1 As specified in table 4.2.2 in TS 36.211 [30] Special subframe configuration of cell 2 6 As specified in table 4.2.1 in TS 36.211 [30] Idle intervals period ms 80 As specified in TS 25.331 [9] Filter coefficient 0 L3 filtering is not used Inter-RAT(E-UTRA TDD) measurement quantity E-UTRA TDD RSRP Table 8.7.15.4.1-2: E-UTRA TDD RSRP measurement tests parameters (cell 1) Parameter Unit Test 1, Test 2 DL timeslot number 0 DwPTS UTRA RF Channel number Note2 Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Ioc dBm/1.28MHz -75 Îor/Ioc dB 3 PCCPCH RSCP Note1 dBm -75 Io Note 1 dBm/1.28MHz -70.24 Propagation condition AWGN NOTE 1: PCCPCH RSCP and Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. NOTE 2: In the case of multi-frequency network of 1.28 Mcps TDD, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.15.4.1-3: E-UTRA TDD RSRP measurement tests parameters (cell 2) Parameter Unit Test 1 Test 2 E-UTRA RF Channel Number 2 2 BWchannel MHz 10 10 Measurement bandwidth 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.2 in TS 36.521-3 [33] R.6 TDD R.6 TDD OCNG Patterns defined in D2.2 (OP.2 TDD) in TS 36.521-3 [33] OP.2 TDD OP.2 TDD PBCH_RA dB 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 33 ~ 40 dBm/15 kHz -88.65 -117 Bands 42 and 43 -116 Band 41 -115 dB 10 -4 RSRPNote3 Bands 33 ~ 40 dBm/15 kHz -78.65 -121 Bands 42 and 43 -120 Band 41 -119 IoNote3 Bands 33 ~ 40 dBm/9 MHz -50.45 -87.76 Bands 42 and 43 -86.76 Band 41 -85.76 dB 10 -4 Propagation condition - AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRP and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP minimum requirements are specified assuming independent interference and noise at each receiver antenna port.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.4.2 Test Procedure	1) A call is set up according to the test procedure specified in TS 34.108 [3] clause 7.3.2. The RF parameters for Test 1 are set up according to tables 8.7.15.5-2 and 8.7.15.5-3. 2) SS shall transmit the MEASUREMENT CONTROL message for inter RAT measurement. In the measurement control information periodic reporting of the EUTRAN TDD RSRP is requested to the UE. 3) After sending the measurement control message, wait for 10s, then the UE shall transmit periodically MEASUREMENT REPORT messages. 4) After the 10s wait in step 3), SS shall check E-UTRAN TDD RSRP value of Cell 2 in periodical MEASUREMENT REPORT messages. E-UTRAN TDD RSRP power of Cell 2 reported by UE is compared to actual E-UTRAN TDD RSRP value of Cell 2 for each MEASUREMENT REPORT message. If the UE fails to report the measurement values including neighbour cell RSRP, the number of failures is increased by one. 5) SS shall check MEASUREMENT REPORT messages transmitted by UE until statistical significance according to Annex Tables G.2.3-1 in TS 36.521-3 [33] is achieved. 6) The RF parameters are set up according to table s 8.7.15.5-2 and 8.7.15. 5-3 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 5s and ignore the MEASUREMENT REPORT messages during this period. Then, step 3) to 5) above are repeated. 7) The SS shall transmit RRC CONNECTION RELEASE message. 8) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in default message content in clause 9 of TS 34.108 [3], and clause 4.4 and 4.7B.1 of TS 36.508 [28] with the following exceptions: MEASUREMENT CONTROL message for EUTRAN TDD measurement (Step 2): Derivation Path: TS 36.508 [28], clause 4.7B.1 Table 4.7B.1-3: MEASUREMENT CONTROL Information Element Value/remark Comment Condition Message Type RRC transaction identifier 0 Measurement Identity 2 Measurement Reporting Mode - Measurement Report Transfer Mode Acknowledged mode RLC - CHOICE Inter-RAT measurement objects E-UTRA frequency list - New frequencies - E-UTRA carrier frequency Downlink EARFCN of E-UTRA Cell - Measurement bandwidth mbw6 - Periodical Reporting/Event Trigger Reporting Mode Periodical reporting CHOICE Measurement type Inter-RAT measurement - Inter-RAT measurement quantity - Measurement quantity for UTRAN quality estimate - Filter coefficient 0 - CHOICE mode TDD TDD_UTRA - Measurement quantity Primary CCPCH RSCP - CHOICE system E-UTRA - Measurement quantity RSRP - Filter coefficient 0 - CHOICE report criteria Periodical reporting criteria - Periodical reporting criteria - Amount of reporting Infinity - Reporting interval 500 ms - Reporting cell status - CHOICE reported cell Report cells within active set or within virtual active set or of the other RAT - Maximum number of reported cells 1 - Idle Interval Information - k 3 (80 ms) The actual idle interval period equal to 2^k radio frames. - offset Not present Default value is 0
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.15.5 Test requirements	Table 8.7.15.5-2 and table 8.7.15.5-3 defines the primary level settings including test tolerances for all tests. For the test to pass, the ratio of successful reported values according to table 8.7.15.5-4 in each test shall be more than 90%, with a confidence level of 95%. Table 8.7.15.5-1: Void Table 8.7.15.5-2: UTRAN TDD cell specific test parameters for E-UTRAN TDD RSRP absolute accuracy tests Parameter Unit Test 1, Test 2 DL timeslot number 0 DwPTS UTRA RF Channel number Note2 Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Ioc dBm/1.28MHz -75 Îor/Ioc dB 3 PCCPCH RSCP Note1 dBm -75 Io Note 1 dBm/1.28MHz -70.24 Propagation condition AWGN Note 1: PCCPCH RSCP and Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. Note 2: In the case of multi-frequency network of 1.28 Mcps TDD, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.15.5-3: E-UTRAN TDD cell specific test parameters for E-UTRAN TDD RSRP absolute accuracy tests Parameter Unit Test 1 Test 2 E-UTRA RF Channel Number 2 2 BWchannel MHz 10 10 Measurement bandwidth 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.2 in TS 36.521-3 [33] R.6 TDD R.6 TDD OCNG Patterns defined in D.2.2 (OP.2 TDD) in TS 36.521-3 [33] OP.2 TDD OP.2 TDD PBCH_RA dB 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 33 ~ 40 dBm/15 kHz -88. 95 -117.00 Bands 42 and 43 -116.00 Band 41 -115.00 dB 10.00 -3.20 RSRPNote3 Bands 33 ~ 40 dBm/15 kHz -78. 95 -120.20 Bands 42 and 43 -119.20 Band 41 -118.20 IoNote3 Bands 33 ~ 40 dBm/9 MHz -50.75 -87.52 Bands 42 and 43 -86.52 Band 41 -85.52 dB 10.00 -3.20 Propagation condition - AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRP and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP minimum requirements are specified assuming independent interference and noise at each receiver antenna port. Table 8.7.15.5-4: E-UTRAN TDD RSRP absolute accuracy requirements for the reported values Test 1 Test 2 All bands Bands 33 ~ 40 Bands 42 and 43 Band 41 Normal Conditions Lowest reported value (Cell 2) RSRP_52 RSRP_13 RSRP_14 RSRP_15 Highest reported value (Cell 2) RSRP_71 RSRP_28 RSRP_29 RSRP_30 Extreme Conditions Lowest reported value (Cell 2) RSRP_49 RSRP_10 RSRP_11 RSRP_12 Highest reported value (Cell 2) RSRP_74 RSRP_31 RSRP_32 RSRP_33 NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16 E-UTRAN FDD RSRQ	Editor’s note: This Test case is incomplete for frequencies above 3GHz • The Test system uncertainties applicable above 3GHz are undefined • The Test Tolerances and Test Requirements applicable above 3GHz are undefined
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.1 Definition and applicability	The absolute accuracy of RSRQ is defined as the RSRQ measured from a cell that has different carrier frequency from the serving cell. The E-UTRAN FDD RSRQ absolute accuracy measurement is used for handover between UTRAN TDD and E-UTRAN FDD for Rel.9 and later. The requirements and this test apply to the combined UTRAN TDD and E-UTRAN FDD UE.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.2 Minimum Requirements	In Cell DCH state, whether or not UE requires idle intervals to perform E-UTRAN measurements, the requirements for accuracy of E-UTRA RSRQ measurements in CELL_DCH state shall be the same as the inter-frequency RSRQ Accuracy Requirements in 3GPP TS 36.133, as follows: Cell specific reference signals are transmitted either from one, two or four antenna ports. Conditions defined in 36.101 Section 7.3 for reference sensitivity are fulfilled. RSRP\|dBm according to 36.133 Annex B.3.3 for a corresponding Band Table 8.7.16.2-1: RSRQ Inter frequency absolute accuracy Parameter Unit Accuracy [dB] Conditions1 Normal condition Extreme condition Bands 1, 4, 6, 10, 11, 18, 19, 21, 23, 24, 33, 34, 35, 36, 37, 38, 39, 40 Bands 2, 5, 7, 41 Band 25 Bands 3, 8, 12, 13, 14, 17, 20, 22 Bands 9, 42, 43 Io Io Io Io Io RSRQ when RSRP Ês/Iot > -3 dB dBm  2.5  4 -121dBm/ 15kHz … -50dBm/ BWChannel -119dBm/ 15kHz … -50dBm/ BWChannel -117.5dBm/ 15kHz … -50dBm/ BWChannel -118dBm/ 15kHz … -50dBm/ BWChannel -120dBm/ 15kHz … -50dBm/ BWChannel RSRQ when RSRP Ês/Iot ≥ -6 dB dBm  3.5  4 -121dBm/ 15kHz … -50dBm/ BWChannel -119dBm/ 15kHz … -50dBm/ BWChannel -117.5dBm/ 15kHz … -50dBm/ BWChannel -118dBm/ 15kHz … -50dBm/ BWChannel -120dBm/ 15kHz … -50dBm/ BWChannel Note 1: Io is assumed to have constant EPRE across the bandwidth. The normative reference for this requirement is TS 25.123 [2] clauses 9.1.1.5b and A.9.2.5b.1.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.3 Test purpose	The purpose of this test is to verify that the E-UTRA FDD RSRQ measurement absolute accuracy is within the specified limits. This test will verify the requirements in 8.7.16.2 and applies to UE supporting this capability.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.4.1 Initial conditions	Test environment: normal, TL/VL, TL/VH, TH/VL, TH/VH; see clauses G.2.1 and G.2.2. Frequencies to be tested: see table J.2 in Annex J. In the test in Cell_DCH state, “E-UTRAN FDD RSRQ Measurement” is applied to measure on E-UTRAN FDD. Tables 8.7.16.4.1-1 and 8.7.16.4.1-2 define the limits of signal strengths and code powers on the UTRA TDD cell. In the measurement control information periodic reporting of E-UTRAN FDD RSRQ is indicated to the UE. The E-UTRAN FDD test parameters are given in Table 8.7.16.4.1-3. Table 8.7.16.4.1-1: General parameters of E-UTRA FDD RSRQ measurement tests Parameter Unit Value Comment DCH parameters DL Reference Measurement Channel 12.2 kbps As specified in TS 25.102 section A.2.2 Power Control On Target quality value on DTCH BLER 0.01 Active cell Cell 1 1.28Mcps TDD cell Neighbour cell Cell 2 E-UTRA FDD cell CP length of cell 2 normal Idle intervals period ms 80 As specified in TS 25.331 Filter coefficient 0 L3 filtering is not used Inter-RAT(E-UTRA FDD) measurement quantity E-UTRA FDD RSRQ Table 8.7.16.4.1-2: E-UTRA FDD RSRQ measurement tests parameters (cell 1) Parameter Unit Cell 1 DL timeslot number 0 DwPTS UTRA RF Channel number (NOTE) Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Îor/Ioc dB 3 Ioc dBm / 1.28MHz -75 Propagation condition AWGN Note: In the case of multi-frequency, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.16.4.1-3: E-UTRA FDD RSRQ measurement tests parameters (cell 2) Parameter Unit Test 1 Test 2 Test 3 E-UTRA RF Channel Number 1 1 1 Bwchannel MHz 10 10 10 Measurement bandwidth 22—27 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.1 in TS 36.521-3 [33] R.6 FDD R.6 FDD R.6 FDD OCNG Patterns defined in D.1.1 (OP.1 FDD) and D.1.2 (OP.2 FDD) in TS 36.521-3 [33] OP.2 FDD OP.2 FDD OP.2 FDD PBCH_RA dB 0 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -80 -104.70 -119.50 Bands 2, 5 and 7 -117.50 Band 25 -116.00 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -116.50 Band 9 -118.50 dB -1.75 -4.0 -4.0 RSRPNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -81.75 -108.70 -123.50 Bands 2, 5 and 7 -121.50 Band 25 -120.00 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -120.50 Band 9 -122.50 RSRQNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dB -14.76 -16.25 -16.25 Bands 2, 5 and 7 Band 25 Bands 3, 8, 12, 13, 14, 17, 20 and 22 Band 9 IoNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/9 MHz -50 -75.46 -90.26 Bands 2, 5 and 7 -88.26 Band 25 -86.76 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -87.26 Band 9 -89.26 dB -1.75 -4.0 -4.0 Propagation condition - AWGN AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRQ, RSRP and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP and RSRQ minimum requirements are specified assuming independent interference and noise at each receiver antenna port.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.4.2 Test Procedure	1) A call is set up according to the test procedure specified in TS 34.108 [3] clause 7.3.2. The RF parameters for Test 1 are set up according to table 8.7.16.5-2 and 8.7.16.5-3. 2) SS shall transmit the MEASUREMENT CONTROL message for inter RAT measurement. In the measurement control information periodic reporting of the EUTRAN FDD RSRQ is requested to the UE. 3) UE shall transmit periodically MEASUREMENT REPORT messages. 4) SS shall check RSRQ value of Cell 2 in the MEASUREMENT REPORT messages. The RSRQ values of Cell 2 reported by the UE are compared to the actual RSRQ value of Cell 2 for each MEASUREMENT REPORT message. 5) SS shall check MEASUREMENT REPORT messages transmitted by UE until statistical significance according to Annex Tables G.2.3-1 in TS 36.521-3 [33] is achieved. 6) The RF parameters are set up according to tables 8.7.16.5-2 and 8.7.16.5-3 for Test 2 and 3. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 5s and ignore the MEASUREMENT REPORT messages during this period. Then, step 4) and 5) above are repeated. 7) After further 1000 MEASUREMENT REPORT messages have been received from UE, the SS shall transmit RRC CONNECTION RELEASE message. 8) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in the default message content in clause 9 of 34.108 [3], with the following exceptions: Note: Numbers in brackets after an item e.g “Message Type (10.2.17)” in the IE description are references to clause numbers in TS 25.331 [9] describing that item in more detail. MEASUREMENT CONTROL message for EUTRAN FDD measurement (Step 1): Information Element Value/Remark Message Type (10.2.17) UE information elements -RRC transaction identifier -Integrity check info 0 Not Present Measurement Information elements -Measurement Identity -Measurement Command -Measurement Reporting Mode - Measurement Report Transfer Mode - Periodical Reporting / Event Trigger Reporting Mode -Additional measurement list -CHOICE Measurement Type -Inter-frequency measurement object list -CHOICE Inter-frequency cell removal -New inter-frequency cells -Cell for measurement -Inter-frequency measurement quantity -CHOICE reporting criteria -Filter coefficient -CHOICE mode -Measurement quantity -Inter-frequency reporting quantity -UTRA Carrier RSSI -Frequency quality estimate -Non frequency related cell reporting quantities -SFN-SFN observed time difference reporting indicator -Cell synchronisation information reporting indicator -Maximum number of reported cells -Measurement validity -Inter-frequency set update -CHOICE report criteria -Amount of reporting -Reporting interval 2 Setup Acknowledged mode RLC Periodical reporting Not Present Inter-RAT measurement Not Present Cell 2 information is included Not Present Inter-frequency reporting criteria 0 EUTRAN FDD RSRQ FALSE FALSE No report Report all active set cells + cells within monitored set on used frequency Virtual/active set cells + 1 Not Present Not Present Periodical reporting criteria Infinity 500 ms Physical channel information elements -DPCH compressed mode status info Not Present
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.16.5 Test requirements	Table 8.7.16.5-2 and table 8.7.16.5-3 defines the primary level settings including test tolerances for all tests. For the test to pass, the ratio of successful reported values according to table 8.7.16.5-4 in each test shall be more than 90% with a confidence level of 95%. Table 8.7.16.5-1: Void Table 8.7.16.5-2: UTRAN TDD cell specific test parameters for E-UTRAN FDD RSRQ absolute accuracy tests Parameter Unit Cell 1 DL timeslot number 0 DwPTS UTRA RF Channel number (NOTE) Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Îor/Ioc dB 3 Ioc dBm / 1.28MHz -75 Propagation condition AWGN NOTE: In the case of multi-frequency, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.16.5-3: E-UTRAN FDD cell specific test parameters for E-UTRAN FDD RSRQ absolute accuracy tests Parameter Unit Test 1 Test 2 Test 3 E-UTRA RF Channel Number 1 1 1 Bwchannel MHz 10 10 10 Measurement bandwidth 22—27 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.1 in TS 36.521-3 [33] R.6 FDD R.6 FDD R.6 FDD OCNG Patterns defined in D.1.1 (OP.1 FDD) and D.1.2 (OP.2 FDD) in TS 36.521-3 [33] OP.2 FDD OP.2 FDD OP.2 FDD PBCH_RA dB 0 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -80.80 -104.70 -119.50 Bands 2, 5 and 7 -117.50 Band 25 -116.00 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -116.50 Band 9 -118.50 dB -1.75 -3.20 -3.20 RSRPNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/15 kHz -82.55 -107.90 -122.70 Bands 2, 5 and 7 -120.70 Band 25 -119.20 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -119.70 Band 9 -121.70 RSRQNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dB -14.76 -15.69 -15.69 Bands 2, 5 and 7 Bands 3, 8, 12, 13, 14, 17, 20 and 22 Band 9 IoNote3 Bands 1, 4, 6, 10, 11, 18, 19, 21, 23 and 24 dBm/9 MHz -50.80 -75.22 -90.02 Bands 2, 5 and 7 -88.02 Band 25 -86.52 Bands 3, 8, 12, 13, 14, 17, 20 and 22 -87.02 Band 9 -89.02 dB -1.75 -3.20 -3.20 Propagation condition - AWGN AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRQ, RSRP and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP and RSRQ minimum requirements are specified assuming independent interference and noise at each receiver antenna port. Table 8.7.16.5-4: E-UTRAN FDD RSRQ absolute accuracy requirements for the reported values Test 1 Test 2 Test 3 All bands All bands Bands 1, 4, 6, 10, 11 18, 19, 21, 23, 24 Bands 2, 5, 7 Band 25 Bands 3, 8, 12, 13, 14, 17, 20, 22 Band 9 Normal Conditions Lowest reported value (Cell 2) RSRQ_04 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 Highest reported value (Cell 2) RSRQ_16 RSRQ_16 RSRQ_16 RSRQ_16 RSRQ_16 RSRQ_16 RSRQ_16 Extreme Conditions Lowest reported value (Cell 2) RSRQ_01 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 Highest reported value (Cell 2) RSRQ_19 RSRQ_17 RSRQ_17 RSRQ_17 RSRQ_17 RSRQ_17 RSRQ_17 NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17 E-UTRAN TDD RSRQ	Editor’s note: This Test case is incomplete for frequencies above 3GHz • The Test system uncertainties applicable above 3GHz are undefined • The Test Tolerances and Test Requirements applicable above 3GHz are undefined
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.1 Definition and applicability	The absolute accuracy of RSRQ is defined as the RSRQ measured from a cell that has different carrier frequency from the serving cell. The E-UTRAN TDD RSRQ absolute accuracy measurement is used for handover between UTRAN TDD and E-UTRAN TDD. The requirements and this test apply to release 9 and later releases UTRA 1.28Mcps TDD UEs that support release 8 and later releases E-UTRA TDD.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.2 Minimum Requirements	In CELL DCH state, whether or not UE requires idle intervals to perform E-UTRAN measurements, the requirements for accuracy of E-UTRA RSRQ measurements in CELL_DCH state shall be the same as the inter-frequency RSRQ Accuracy Requirements in 3GPP TS 36.133 [26], as follows: Cell specific reference signals are transmitted either from one, two or four antenna ports. Conditions defined in TS 36.101 [27] Section 7.3 for reference sensitivity are fulfilled. RSRP\|dBm according to 36.133 Annex B.3.3 for a corresponding Band Table 8.7.17.2-1: RSRQ Inter frequency absolute accuracy Parameter Unit Accuracy [dB] Conditions1 Normal condition Extreme condition Bands 1, 4, 6, 10, 11, 18, 19, 21, 23, 24, 33, 34, 35, 36, 37, 38, 39, 40 Bands 2, 5, 7, 41 Band 25 Bands 3, 8, 12, 13, 14, 17, 20, 22 Bands 9, 42, 43 Io Io Io Io Io RSRQ when RSRP Ês/Iot > -3 dB dBm  2.5  4 -121dBm/ 15kHz … -50dBm/ BWChannel -119dBm/ 15kHz … -50dBm/ BWChannel -117.5dBm/ 15kHz … -50dBm/ BWChannel -118dBm/ 15kHz … -50dBm/ BWChannel -120dBm/ 15kHz … -50dBm/ BWChannel RSRQ when RSRP Ês/Iot ≥ -6 dB dBm  3.5  4 -121dBm/ 15kHz … -50dBm/ BWChannel -119dBm/ 15kHz … -50dBm/ BWChannel -117.5dBm/ 15kHz … -50dBm/ BWChannel -118dBm/ 15kHz … -50dBm/ BWChannel -120dBm/ 15kHz … -50dBm/ BWChannel Note 1: Io is assumed to have constant EPRE across the bandwidth. The normative reference for this requirement is TS 25.123 [2] clauses 9.1.1.5b and A.9.2.5b.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.3 Test purpose	The purpose of this test is to verify that the E-UTRA TDD RSRQ absolute measurement accuracy is within the specified limits. This test will verify the requirements in section 8.7.17.2 and applies to UE supporting this capability.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.4.1 Initial conditions	Test environment: normal, TL/VL, TL/VH, TH/VL, TH/VH; see clauses G.2.1 and G.2.2. Frequencies to be tested: see table J.2 in Annex J. In the test in Cell_DCH state, “E-UTRAN TDD RSRQ Measurement” is applied to measure on E-UTRAN TDD. Tables 8.7.17.4.1-1 and 8.7.17.4.1-2 define the limits of signal strengths and code powers on the UTRA TDD cell. In the measurement control information periodic reporting of E-UTRAN TDD RSRQ is indicated to the UE. The E-UTRAN TDD test parameters are given in Table 8.7.17.4.1-3. Table 8.7.17.4.1-1: General parameters of E-UTRA TDD RSRQ measurement tests Parameter Unit Value Comment DCH parameters DL Reference Measurement Channel 12.2 kbps As specified in section C.3.1 Power Control On Target quality value on DTCH BLER 0.01 Active cell Cell 1 1.28Mcps UTRA TDD cell Neighbour cell Cell 2 E-UTRA TDD cell CP length of cell 2 Normal Uplink-downlink configuration of cell 2 1 As specified in table 4.2.2 in TS 36.211 [30] Special subframe configuration of cell 2 6 As specified in table 4.2.1 in TS 36.211 [30] Idle intervals period ms 80 As specified in TS 25.331 [9] Filter coefficient 0 L3 filtering is not used Inter-RAT(E-UTRA TDD) measurement quantity E-UTRA TDD RSRQ Table 8.7.17.4.1-2: E-UTRA TDD RSRQ measurement tests parameters (cell 1) Parameter Unit Test 1, Test 2, and Test 3 DL timeslot number 0 DwPTS UTRA RF Channel number Note2 Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Ioc dBm/1.28MHz -75 Îor/Ioc dB 3 PCCPCH RSCP Note1 dBm -75 Io Note 1 dBm/1.28MHz -70.24 Propagation condition AWGN Note 1: PCCPCH RSCP and Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. Note 2: In the case of multi-frequency network of 1.28 Mcps TDD, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.17.4.1-3: E-UTRA TDD RSRQ measurement tests parameters (cell 2) Parameter Unit Test 1 Test 2 Test 3 E-UTRA RF Channel Number 2 2 2 BWchannel MHz 10 10 10 Measurement bandwidth 22—27 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.2 in TS 36.521-3 [33] R.6 TDD R.6 TDD R.6 TDD OCNG Patterns defined in D.2.2 (OP.2 TDD) in TS 36.521-3 [33] OP.2 TDD OP.2 TDD OP.2 TDD PBCH_RA dB 0 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 33 – 40 dBm/15 kHz -80 -104.70 -119.50 Band 42 and 43 -118.50 Band 41 -117.50 dB -1.75 -4.0 -4.0 RSRPNote3 Bands 33 – 40 dBm/15 kHz -81.75 -108.70 -123.50 Band 42 and 43 -122.50 Band 41 -121.50 RSRQNote3 Bands 33 – 43 dB -14.76 -16.25 -16.25 IoNote3 Bands 33 – 40 dBm/9 MHz -50 -75.46 -90.26 Bands 42 and 43 -89.26 Bands 41 -88.26 dB -1.75 -4.0 -4.0 Propagation condition - AWGN AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRP, RSRQ and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP and RSRQ minimum requirements are specified assuming independent interference and noise at each receiver antenna port.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.4.2 Test Procedure	1) A call is set up according to the test procedure specified in TS 34.108 [3] clause 7.3.2. The RF parameters for Test 1 are set up according to tables 8.7.17.5-2 and 8.7.17.5-3. 2) SS shall transmit the MEASUREMENT CONTROL message for inter RAT measurement. In the measurement control information periodic reporting of the EUTRAN TDD RSRQ is requested to the UE. 3) After sending the measurement control message, wait for 10s, then the UE shall transmit periodically MEASUREMENT REPORT messages. 4) After the 10s wait in step 3), SS shall check E-UTRAN TDD RSRQ value of Cell 2 in periodical MEASUREMENT REPORT messages. E-UTRAN TDD RSRQ values of Cell 2 reported by UE is compared to actual E-UTRAN TDD RSRQ value of Cell 2 for each MEASUREMENT REPORT message. If the UE fails to report the measurement values including neighbour cell RSRQ, the number of failures is increased by one. 5) SS shall check MEASUREMENT REPORT messages transmitted by UE until statistical significance according to Tables G.2.3-1 in TS 36.521-3 [33] is achieved. 6) The RF parameters are set up according to tables 8.7.17.5-2 and 8.7.17. 5-3 for Test 2. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 5s and ignore the MEASUREMENT REPORT messages during this period. Then, step 3) to 5) above are repeated. 7) The RF parameters are set up according to tables 8.7.17.5-2 and 8.7.17. 5-3 for Test 3. While RF parameters are being set up, MEASUREMENT REPORT messages from UE are ignored. SS shall wait for additional 5s and ignore the MEASUREMENT REPORT messages during this period. Then, step 3) to 5) above are repeated. 8) The SS shall transmit RRC CONNECTION RELEASE message. 9) UE shall transmit RRC CONNECTION RELEASE COMPLETE message. Specific Message Contents All messages indicated above shall use the same content as described in default message content in clause 9 of TS 34.108 [3] and clause 4.4 and 4.7B.1 of TS 36.508 [28], with the following exceptions: MEASUREMENT CONTROL message for EUTRAN TDD measurement (Step 1): Derivation Path: TS 36.508 [28], clause 4.7B.1 Table 4.7B.1-3: MEASUREMENT CONTROL Information Element Value/remark Comment Condition Message Type RRC transaction identifier 0 Measurement Identity 2 Measurement Reporting Mode - Measurement Report Transfer Mode Acknowledged mode RLC - Periodical Reporting/Event Trigger Reporting Mode Periodical reporting CHOICE Measurement type Inter-RAT measurement - CHOICE Inter-RAT measurement objects E-UTRA frequency list - New frequencies - E-UTRA carrier frequency Downlink EARFCN of E-UTRA Cell - Measurement bandwidth mbw6 - Inter-RAT measurement quantity - Measurement quantity for UTRAN quality estimate - Filter coefficient 0 - CHOICE mode TDD TDD_UTRA - Measurement quantity Primary CCPCH RSCP - CHOICE system E-UTRA - Measurement quantity RSRQ - Filter coefficient 0 - CHOICE report criteria Periodical reporting criteria - Periodical reporting criteria - Amount of reporting Infinity - Reporting interval 500 ms - Reporting cell status - CHOICE reported cell Report cells within active set or within virtual active set or of the other RAT - Maximum number of reported cells 1 - Idle Interval Information - k 3 (80 ms) The actual idle interval period equal to 2^k radio frames. - offset Not present Default value is 0.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	8.7.17.5 Test requirements	Table 8.7.17.5-2 and table 8.7.17.5-3 defines the primary level settings including test tolerances for all tests. For the test to pass, the ratio of successful reported values according to table 8.7.17.5-4 in each test shall be more than 90% with a confidence of 95%. Table 8.7.17.5-1: Void Table 8.7.17.5-2: UTRAN TDD cell specific test parameters for E-UTRAN TDD RSRQ absolute accuracy tests Parameter Unit Test 1, Test 2, and Test 3 DL timeslot number 0 DwPTS UTRA RF Channel number Note2 Channel 1 PCCPCH_Ec/Ior dB -3 DwPCH_Ec/Ior dB 0 OCNS_Ec/Ior dB -3 Ioc dBm/1.28MHz -75 Îor/Ioc dB 3 PCCPCH RSCP Note1 dBm -75 Io Note 1 dBm/1.28MHz -70.24 Propagation condition AWGN Note 1: PCCPCH RSCP and Io levels have been calculated from other parameters for information purposes. They are not settable parameters themselves. Note 2: In the case of multi-frequency network of 1.28 Mcps TDD, the UTRA RF Channel Number can be set for the primary frequency in this test. Table 8.7.17.5-3: E-UTRAN TDD cell specific test parameters for E-UTRAN TDD RSRQ absolute accuracy tests Parameter Unit Test 1 Test 2 Test 3 E-UTRA RF Channel Number 2 2 2 BWchannel MHz 10 10 10 Measurement bandwidth 22—27 22—27 22—27 PDCCH/PCFICH/PHICH Reference measurement channel defined in A.2.2 in TS 36.521-3 [33] R.6 TDD R.6 TDD R.6 TDD OCNG Patterns defined in D.2.2 (OP.2 TDD) in TS 36.521-3 [33] OP.2 TDD OP.2 TDD OP.2 TDD PBCH_RA dB 0 0 0 PBCH_RB PSS_RA SSS_RA PCFICH_RB PHICH_RA PHICH_RB PDCCH_RA PDCCH_RB PDSCH_RA PDSCH_RB OCNG_RANote1 OCNG_RBNote1 Note2 Bands 33 – 40 dBm/15 kHz -80.80 -104.70 -119.50 Band 42 and 43 -118.50 Band 41 -117.50 dB -1.75 -3.20 -3.20 RSRPNote3 Bands 33 – 40 dBm/15 kHz -82.55 -107.90 -122.70 Band 42 and 43 -121.70 Band 41 -120.70 RSRQNote3 Bands 33 – 40 dB -14.76 -15.69 -15.69 IoNote3 Bands 33 – 40 dBm/9 MHz -50.80 -75.22 -90.02 Band 42 and 43 -89.02 Band 41 -88.02 dB -1.75 -3.20 -3.20 Propagation condition - AWGN AWGN AWGN Note 1: OCNG shall be used such that both cells are fully allocated and a constant total transmitted power spectral density is achieved for all OFDM symbols. Note 2: Interference from other cells and noise sources not specified in the test is assumed to be constant over subcarriers and time and shall be modelled as AWGN of appropriate power for to be fulfilled. Note 3: RSRP, RSRQ and Io levels have been derived from other parameters for information purposes. They are not settable parameters themselves. Note 4: RSRP and RSRQ minimum requirements are specified assuming independent interference and noise at each receiver antenna port. Table 8.7.17.5-4: E-UTRAN TDD RSRQ absolute accuracy requirements for the reported values Test 1 Test 2 Test 3 All bands All bands Bands 33 ~ 40 Bands 42, 43 Bands 41 Normal Conditions Lowest reported value (Cell 2) RSRQ_04 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 Highest reported value (Cell 2) RSRQ_16 RSRQ_16 RSRQ_16 RSRQ_16 RSRQ_16 Extreme Conditions Lowest reported value (Cell 2) RSRQ_01 RSRQ_00 RSRQ_00 RSRQ_00 RSRQ_00 Highest reported value (Cell 2) RSRQ_19 RSRQ_17 RSRQ_17 RSRQ_17 RSRQ_17 NOTE: If the above Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. The Test Tolerance for this test is defined in clause F.2 and the explanation of how the Minimum Requirement has been relaxed by the Test Tolerance is given in clause F.4. 9 Performance requirements for HSDPA
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.1 General	Receiving performance test of the UE is implemented during communicating with the SS via air interface. The procedure uses normal call protocol until the UE is communicating on traffic channel basically. (Refer to TS 34.108 [3] Common Test Environments for User Equipment (UE) Conformance Testing.) On the traffic channel, the UE provides special function for testing that is described in Logical Test Interface and the UE is tested using this function. (Refer to TS 34.109 [4] Logical Test Interface (FDD/TDD) Special conformance testing functions). Unless otherwise stated the receiver characteristics are specified at the antenna connector of the UE. For UE(s) with an integral antenna only, a reference antenna with a gain of 0 dBi is assumed. UE with an integral antenna may be taken into account by converting these power levels into field strength requirements, assuming a 0 dBi gain antenna. Receiver characteristics for UE(s) with multiple antennas/antenna connectors are for further study. The UE antenna performance has a significant impact on system performance, and minimum requirements on the antenna efficiency are therefore intended to be included in future versions of the present document. It is recognized that different requirements and test methods are likely to be required for the different types of UE. All Bit Error ratio (BER) measurements shall be performed according to the general rules for statistical testing in Annex F.6.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2 Performance requirement for 3.84 Mcps TDD option	During the Fixed Reference Channel tests the behaviour of the Node-B emulator in response to the ACK/NACK signalling field of the HS-DPCCH is specified in Table 9.2.1: Table 9.2.1: Node-B Emulator Behaviour in response to ACK/NACK/DTX 0 HS-DPCCH ACK/NACK Field State 0 Node-B Emulator Behaviour 1 ACK 1 ACK: new transmission using 1st redundancy and constellation version (RV) 2 NACK 2 NACK: retransmission using the next RV (up to the maximum permitted number or RV’s) 3 DTX 3 DTX: retransmission using the RV previously transmitted to the same H-ARQ process
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1 HS-DSCH throughput for Fixed Reference Channels
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.1 Definition and applicability	The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 3.84 Mcps TDD UE from release 5 and later that support HSDPA.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.2 Minimum requirements	The requirements are specified in terms of minimum information bit throughput R for the DL reference channels specified in Annex C.4.1 with the addition of the relevant parameters in Tables 9.2.1.1 and 9.2.1.3. Using this configuration the throughput shall meet or exceed the minimum requirements specified in tables 9.2.1.2 and 9.2.1.4. Table 9.2.1.1: Test parameters for fixed reference measurement channel requirements for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) QPSK Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - QPSK Scrambling code and basic midamble code number* - 0, 1 Number of TS - 8 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 C(i,16) i=1..14 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 Redundancy and constellation version coding sequence** - {0,0,0,0} s=1, R=0, b=0 dB -12,04 -11.46 dB 0 Ioc dBm/3,84MHz -60 Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note : This sequence implies Chase combining Table 9.2.1.2: Performance requirements for fixed reference measurement channel requirement in multipath channels for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) QPSK Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 8,5 1300 2 PB3 9,0 1300 3 VA30 9,75 1300 4 VA120 11,5 1400 Table 9.2.1.3: Test parameters for fixed reference measurement channel requirements for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) 16QAM Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - 16QAM Scrambling code and basic midamble code number - 0, 1 Number of TS - 8 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 C(i,16) i=1..14 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 Redundancy and constellation version coding sequence** - {0,0,0,0} s=1, r=0 dB -12,04 -11,46 dB 0 Ioc dBm/3,84MHz -60 Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note *: This sequence implies Chase combining Table 9.2.1.4: Performance requirements for fixed reference measurement channel requirement in multipath channels for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) 16QAM Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 16,0 2600 2 PB3 17,5 2600 3 VA30 18,5 2600 4 VA120 14,5 1600 The reference for this requirement is TS 25.102 [1] clauses 9.1.1.1 and 9.1.1.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.3 Test purpose	To verify the ability of the receiver to receive a predefined test signal, representing a multi-path fading channel with information bit throughput R not falling below a specified value.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect the SS (node B emulator) and fader and AWGN noise source to the UE antenna connector as shown in figure A.10. 2) Set up an HSDPA call according to TS 34.108 [3] clause 7.3.6.3 with levels according to Annex E.3. 3) Set the node B emulator ACK/NACK/DTX behaviour according to table 9.2.1. Set the test parameters and levels for tests 1-4 according to tables 9.2.1.1. The reference channel configuration is defined in section C.4.1. The configuration of the TX power for downlink physical channels is annex in E.3. 4) The information bit data shall be pseudo random and not repeated before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM, test 1,2,3): The information bit payload block is 52996 bits long. Hence the PRBSequence must be at least 52996 * 10 bits long. ) Use a PRBS from ITU-T O.153 Ref [25]. 5) Setup the fading simulator with fading conditions as described in table D.2.2.1A.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.4.2 Procedure	a. Once the HSDPA connection is setup, start transmitting HSDPA data. b. For all relevant propagation conditions, for all relevant Ioc levels, for all relevant Ec/Ior, for all relevant Îor/Ioc defined in Tables 9.2 and 9.4 count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.3 and F.6.3.5.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.1.5 Test Requirements	Tables 9.2.1.1 to 9.2.1.4 define the primary level settings including test tolerance for all relevant throughput tests. The pass / fail decision for throughput is done according to Annex F.6.3.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2 HS-DSCH throughput for Variable Reference Channels
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.1 Definition and applicability	The HS-DSCH data throughput for variable reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 3.84 Mcps TDD UE from release 5 and later that support HSDPA.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.2 Minimum requirements	For the parameters specified in Table 9.2.2.1 the measured throughput R shall exceed the throughput specified in Table 9.2.2.2 for each radio condition. The variable Reference Channel is specified in Annex C.4.3. Table 9.2.2.1: Test parameters for variable reference measurement channel requirements for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) Parameters Unit Test 1 Test 2 Test 3 Test 4 Scrambling code and basic midamble code number* - 0, 1 Number of TS - 8 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 Number of Hybrid ARQ processes** - 4 Maximum number of Hybrid ARQ transmissions - 1 Redundancy and constellation version coding sequence (Xrv, s, r, b) (0, 1, 0, 0) HS-PDSCHi_Ec/Ior dB –12,04 dB 0 Ioc dBm/3,84MHz -60 Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note *: For timing requirements, HARQ is not active Table 9.2.2.2: Performance requirements for variable reference measurement channel requirement in multipath channels for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 8,8 1240 14,8 2500 18,8 3600 24,8 5000 2 PB3 8,8 1220 14,8 2430 20,8 4030 24,8 5080 3 VA30 10,1 1190 16,1 2290 20,1 3220 24,1 4260 4 VA120 7,1 590 11,1 1180 15,1 1840 19,1 2390
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.3 Test purpose	To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, with the selection of QPSK and 16QAM modulation, and appropriate blocksize being determined by the SS based on the CQI reported by the UE..
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect the SS (node B emulator) and fader and AWGN noise source to the UE antenna connector as shown in figure A.10. 2) Set up an HSDPA call according to TS 34.108 [3] clause 7.3.6.3 with levels according to Annex E.3. 3) Set the node B emulator ACK/NACK/DTX behaviour according to table 9.2.1. Set the test parameters and levels for tests 1-4 according to tables 9.2.2.1. The reference channel configuration is defined in section C.4.3. The configuration of the TX power for downlink physical channels is annex in E.3. 4) The information bit data shall be pseudo random and not repeated before 10 different information bit payload blocks are processed. Use a PRBS from ITU-T O.153 Ref [25] 5) Setup the fading simulator with fading conditions as described in table D.2.2.1A.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.4.2 Procedure	1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value,then SS will decode the CQI report and transmit a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE. 3) For any HSDPA block transmitted by the SS, record transmitted block size and relevant received ACK, NACK and statDTX reported by UE. If UE reports ACK,the transmitted block is correctly received by UE.Continue transmission of the HS-PDSCH data and record transmitted block size until [2000] records have been reached. 4) For all relevant propagation conditions ,calculate the throughput, which is the ratio of the sum of correctly received transport bits over the testing time. [2000] multiplied by transmission time interval is the testing time.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.2.5 Test Requirements	Table 9.2.2.1 define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.2.2.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3 Reporting of HS-DSCH Channel Quality Indicator
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.1 Definition and applicability	The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 3.84 Mcps TDD UE from release 5 and later that support HSDPA.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.2 Minimum requirements	For the parameters specified in Table 9.2.3.1, the reported CQI value shall be in the range of +/-10 of the reported median more than 90% of the time. The BLER for the reported median CQI shall be less than 10%. Table 9.2.3.1: Test parameters for variable reference measurement channel requirements for 7,3 Mbps – Category 8 - UE (3,84 Mcps TDD Option) Parameters Unit Test 1 Test 2 Scrambling code and basic midamble code number* - 0, 1 Number of TS - 8 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 Number of Hybrid ARQ processes** - 4 Maximum number of Hybrid ARQ transmissions - 1 Redundancy and constellation version coding sequence (Xrv, s, r, b) (0, 1, 0, 0) HS-PDSCHi_Ec/Ior dB –12,04 dB 0 dB 5 10 Ioc dBm/3,84MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note*: For timing requirements, HARQ is not active Table 9.3.3.2 Performance requirements for CQI reporting measurement channel requirements for 7.3 Mbps – Category 9- UE (3.84 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 10 90 10% Test 2
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.3 Test purpose	To verify that the variance of the CQI reports in an AWGN channel is within the limits defined and that a BLER of better than 10% is obtained for the median reported CQI.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set up an HSDPA call according to TS 34.108 [3] clause 7.3.6.3 with levels according to Annex E.3. 3) Set the node B emulator ACK/NACK/DTX behaviour according to table 9.2.1. Set the test parameters and levels for tests 1-2 according to tables 9.2.3.1. The reference channel configuration is defined in section C.4.1. The configuration of the TX power for downlink physical channels is annex in E.3. 4) The information bit data shall be pseudo random and not repeated before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM, test 1,2,3): The information bit payload block is 52996 bits long. Hence the PRBSequence must be at least 52996 * 10 bits long. ) Use a PRBS from ITU-T O.153 Ref [25].
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.4.2 Procedure	Note: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 1) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 2) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 3) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - 10) ≤ Median CQI ≤ ( Median CQI + 10) then continue with next step , otherwise fail the UE. 4) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 5) Repeat the same procedure (steps 2 to 5 ) with test conditions according to the table 9.3.3.1 for Test 2, Test 3 and Test 4
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.3.5 Test Requirements	The pass fail decision as specified in the test procedure in 9.3.1.4.2. No test tolerance is applied to the test parameters.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4 HS-SCCH Detection Performance	void 9.2.4A HS-SCCH Detection Performance
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.1 Definition and applicability	The detection performance of the HS-SCCH is determined by the probability of event Em, which is declared when the UE is signaled on HS-SCCH, but DTX is observed in the corresponding HS-SICH ACK/NACK field. The probability of event Em is denoted P(Em). The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 3.84 Mcps TDD UE from release 5 and later that support HSDPA.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.2 Minimum requirements	For the test parameters in Table 9.2.4.1, for each value of HS-SCCH-1 Ec/Ior specified in Table 9.2.4.2, the measured P(Em) shall be less than or equal to the corresponding specified value of P(Em). Table 9.2.4.1: Test parameters for HS-SCCH detection (3.84 Mcps TDD option) Parameter Unit Test 1 Test 2 Test 3 Number of TS under test - 1 Number of HS-SCCH codes per timeslot - 4 HS-SCCH UE Identity (,, …, ) - UE1 = 0000000000000000 (UE1 under test) UE2 = 0101010101010101 UE3 = 1010101010101010 UE4 = 1111111111111111 HS-SCCH Channelization Codes* C(k,Q) HS-SCCH-1 = C(1, 16), for UE1 (UE under test) HS-SCCH-2 = C(2, 16) for UE2 HS-SCCH-3 = C(3, 16) for UE3 HS-SCCH-4 = C(4, 16) for UE4 HS-SCCH Ec/Ior dB HS-SCCH-2_Ec/Ior = HS-SCCH-3_Ec/Ior = HS-SCCH-4_Ec/Ior, Where,  HS-SCCH-X_Ec/Ior = 1, where X = 1, 2, 3, 4 Table 9.2.4.2: Minimum requirement for HS-SCCH detection (3.84 Mcps TDD option) Test Number Propagation Conditions Reference value HS-SCCH-1 (dB) (dB) 1 PA3 -1.6 0 0.05 2 PA3 -3.0 5 0.01 3 VA30 -2.5 0 0.01 The reference for this requirement is TS 25.102 [2] clause 9.1.4.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.3 Test purpose	To verify that P(Em) does not exceed the limit in table 9.2.4.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1. Connect SS, multipath fading simulator and an AWGN noise source to the UE antenna connector as shown in figure A.10. 2. Setup fading simulators as fading condition, which are described in table D.2.2.1A. 3. Set the node B emulator ACK/NACK/DTX behaviour according to table 9.2.1. Set the test parameters and levels for tests 1-3 according to tables 9.2.4.1 and 9.2.4.2. The reference channel configuration is defined in section C.4.1. The configuration of the TX power for downlink physical channels is annex in E.3.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.4.2 Procedure	1. The UE is switched on. 2. Set up an HSDPA call according to TS 34.108 [3] clause 7.3.6.3. 3. Count the number of NACK, ACK and statDTX on the UL HS-DPCCH during the test interval and decide pass or fail according to Annex F.6.1 and table F.6.1.8. NACK and ACK are counted as a pass and statDTX is counted as a failure.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.2.4.5 Test Requirements	The probability of event Em denoted as P(Em) (test procedure step 3) shall not exceed the specified value in table 9.2.4.2. No test tolerance is applied to the test parameters.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3 Performance requirements for 1.28 Mcps TDD option
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.1 HS-DSCH throughput for Fixed Reference Channels	The overall performance metric for HS-DSCH requirements is the throughput “R” measured on HS-DSCH. During the Fixed Reference Channel tests the behaviour of the Node-B emulator in response to the ACK/NACK signalling field of the HS-SICH is specified in Table 9.3.1.1: Table 9.3.1.1: Node-B Emulator Behaviour in response to ACK/NACK/DTX (Fixed reference channel) HS-DPCCH ACK/NACK Field State Node-B Emulator Behaviour ACK ACK: new transmission using 1st redundancy version (RV) NACK NACK: retransmission using the next RV (up to the maximum permitted number or RV’s) DTX DTX: retransmission using the RV previously transmitted to the same H-ARQ process 9.3.1A HS-DSCH throughput for Fixed Reference Channels 0.5 Mbps UE class QPSK 9.3.1A.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 0.5 Mbps UE class. 9.3.1A.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1A.1: Test parameters for fixed reference measurement channel requirements for 0.5 Mbps UE class QPSK Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - QPSK Scrambling code and basic midamble code number* - 1 Midamble Common midamble Number of TS** 2 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..10 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 Redundancy and constellation version coding sequence - {0,0,0,0} dB -10 Ioc dBm/1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note: The timeslot just after the second switch point should be included. Table 9.3.1A.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for 0.5Mbps UE class QPSK Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 160 2 PB3 10 170 3 VA30 10 161 4 VA120 10 153 9.3.1A.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for QPSK modulation. 9.3.1A.4 Method of test 9.3.1A.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1A.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM): The information bit payload block is 3650 bits long. Hence the PRBSequence must be at least 3650 10 bits long. ) Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3, table F.6.3.5.1.. 9.3.1A.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1A.3 of test requirement. Table 9.3.1A.3: Test requirements for fixed reference measurement channel requirement in multipath channels for 0.5Mbps UE class QPSK Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 160 2 PB3 10.6 170 3 VA30 10.6 161 4 VA120 10.6 153 The pass / fail decision for throughput is done according to Annex F.6.3.9.3.1B HS-DSCH throughput for Fixed Reference Channels 1.1 Mbps UE class 16QAM 9.3.1B.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 1.1 Mbps UE class.. 9.3.1B.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1B.1: Test parameters for fixed reference measurement channel requirements for 1.1 Mbps UE class, 16QAM Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - 16QAM Scrambling code and basic midamble code number* - 1 Midamble Common midamble Number of TS** - 2 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..12 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 Redundancy and constellation version coding sequence - {6,2,1,5} dB -10.8 Ioc dBm/1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note: The timeslot just after the second switch point should be included. Table 9.3.1B.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for 1.1Mbps UE class, 16QAM Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15 388 2 PB3 15 347 3 VA30 15 316 4 VA120 15 274 9.3.1B.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for 16QAM modulation. 9.3.1B.4 Method of test 9.3.1B.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1B.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM): The information bit payload block is 3650 bits long. Hence the PRBSequence must be at least 3650 10 bits long. ) Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3, table F.6.3.5.2. 9.3.1B.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1B.3 of test requirement. Table 9.3.1B.3: Test requirements for fixed reference measurement channel requirement in multipath channels for 1.1Mbps UE class, 16QAM Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15.6 388 2 PB3 15.6 347 3 VA30 15.6 316 4 VA120 15.6 274 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1C HS-DSCH throughput for Fixed Reference Channels 1.6 Mbps UE class QPSK/16QAM 9.3.1C.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 1.6 Mbps UE class.. 9.3.1C.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1C.1: Test parameters for fixed reference measurement channel requirements for 1.6 Mbps UE class Parameters Unit Test 1 Test 2 Test 3 Test 4 Test 5 Test 6 Test 7 Test 8 HS-PDSCH Modulation - QPSK 16QAM Scrambling code and basic midamble code number* - 1 Midamble Common midamble Number of TS** - 3 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..10 C(i,16) i=1..12 Redundancy and constellation version coding sequence - {0,0,0,0} {6,2,1,5} dB -10 -10.8 Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note: The timeslot just after the second switch point should be included. Table 9.3.1C.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for 1.6Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 270 2 PB3 10 278 3 VA30 10 259 4 VA120 10 242 5 PA3 15 488 6 PB3 15 471 7 VA30 15 431 8 VA120 15 377 9.3.1C.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for QPSK and 16QAM modulation. 9.3.1C.4 Method of test 9.3.1C.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1C.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM): The information bit payload block is 3650 bits long. Hence the PRBSequence must be at least 3650 10 bits long. ) Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3, tables F.6.3.5.3 and F.6.3.5.4. 9.3.1C.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1C.3 of test requirement. Table 9.3.1C.3: Test requirements for fixed reference measurement channel requirement in multipath channels for 1.6Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 270 2 PB3 10.6 278 3 VA30 10.6 259 4 VA120 10.6 242 5 PA3 15.6 488 6 PB3 15.6 471 7 VA30 15.6 431 8 VA120 15.6 377 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1D HS-DSCH throughput for Fixed Reference Channels 2.2 Mbps UE class QPSK/16QAM 9.3.1D.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 2.2 Mbps UE class.. 9.3.1D.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1D.1: Test parameters for fixed reference measurement channel requirements for 2.2 Mbps UE class Parameters Unit Test 1 Test 2 Test 3 Test 4 Test 5 Test 6 Test 7 Test 8 HS-PDSCH Modulation - QPSK 16QAM Scrambling code and basic midamble code number* - 1 Minimum Common midamble Number of TS** - 4 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..10 C(i,16) i=1..12 Redundancy and constellation version coding sequence - {0,0,0,0} {6,2,1,5} dB -10 -10.8 Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note: The timeslot just after the second switch point should be included. Table 9.3.1D.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for 2.2Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 360 2 PB3 10 343 3 VA30 10 320 4 VA120 10 275 5 PA3 15 615 6 PB3 15 606 7 VA30 15 554 8 VA120 15 493 9.3.1D.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for QPSK and 16QAM modulation. 9.3.1D.4 Method of test 9.3.1D.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1D.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM): The information bit payload block is 3650 bits long. Hence the PRBSequence must be at least 3650 10 bits long. ) Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3, tables F.6.3.5.5 and F.6.3.5.6. 9.3.1D.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1D.3 of test requirement. Table 9.3.1D.3: Test requirements for fixed reference measurement channel requirement in multipath channels for 2.2Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 360 2 PB3 10.6 343 3 VA30 10.6 320 4 VA120 10.6 275 5 PA3 15.6 615 6 PB3 15.6 606 7 VA30 15.6 554 8 VA120 15.6 493 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1E HS-DSCH throughput for Fixed Reference Channels 2.8 Mbps UE class QPSK/16QAM 9.3.1E.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 2.8 Mbps UE class.. 9.3.1E.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1E.1: Test parameters for fixed reference measurement channel requirements for 2.8 Mbps UE class Parameters Unit Test 1 Test 2 Test 3 Test 4 Test 5 Test 6 Test 7 Test 8 HS-PDSCH Modulation - QPSK 16QAM Scrambling code and basic midamble code number* - 1 Midamble Common midamble Number of TS - 5 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..10 C(i,16) i=1..12 Redundancy and constellation version coding sequence - {0,0,0,0} {6,2,1,5} dB -10 -10.8 Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1E.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for 2.8Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 461 2 PB3 10 470 3 VA30 10 438 4 VA120 10 409 5 PA3 15 890 6 PB3 15 810 7 VA30 15 730 8 VA120 15 630 9.3.1E.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for QPSK and 16QAM modulation. 9.3.1E.4 Method of test 9.3.1E.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1E.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM): The information bit payload block is 3650 bits long. Hence the PRBSequence must be at least 3650 10 bits long. ) Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3, tables F.6.3.5.7and F.6.3.5.8. 9.3.1E.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1E.3 of test requirement. Table 9.3.1E.3: Test requirements for fixed reference measurement channel requirement in multipath channels for 2.8Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 461 2 PB3 10.6 470 3 VA30 10.6 438 4 VA120 10.6 409 5 PA3 15.6 890 6 PB3 15.6 810 7 VA30 15.6 730 8 VA120 15.6 630 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1F HS-DSCH throughput for Fixed Reference Channels Categories 16-18- 64QAM The overall performance metric for HS-DSCH requirements is the throughput “R” measured on HS-DSCH. 9.3.1F.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 8 and later that support HSDPA UE capability categories 16 - 24. 9.3.1F.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1F.1: Test parameters for fixed reference measurement channel requirements for category 16-18 UE Parameters Unit Test 1 (Category 16-18) HS-PDSCH Modulation - 64QAM Scrambling code and basic midamble code number* - 1 Number of TS - 3 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..14 Redundancy and constellation version coding sequence - {6,5,4,0} dB -11.46 Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1F.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for category 16-18 UE Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 18 660 9.3.1F.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for 64QAM modulation. 9.3.1F.4 Method of test 9.3.1F.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2.6. 9.3.1F.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [25]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1F.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1F.3 of test requirement. Table 9.3.1F.3: Test requirements for fixed reference measurement channel requirement in multipath channels for category 16-18 UE Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 18.6 660 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1G HS-DSCH throughput for Fixed Reference Channels – Categories 19-21 64QAM 9.3.1G.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24], and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 8 and later that support HSDPA UE capability categories 19 - 21. 9.3.1G.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1G.1: Test parameters for fixed reference measurement channel requirements for category 19-21 UE Parameters Unit Test 1 (Category 19-21) HS-PDSCH Modulation - 64QAM Scrambling code and basic midamble code number - 1 Number of TS - 4 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..14 Redundancy and constellation version coding sequence - {6,5,4,0} dB -11.46 Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1G.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for category 19-21 UE Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 18 875 9.3.1G.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for 64QAM modulation. 9.3.1G.4 Method of test 9.3.1G.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2.6. 9.3.1G.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [25]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1G.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1G.3 of test requirement. Table 9.3.1G.3: Test requirements for fixed reference measurement channel requirement in multipath channels for category 19-21 UE Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 18.6 875 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1H HS-DSCH throughput for Fixed Reference Channels – Categories 22-24 64QAM 9.3.1H.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24], and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 8 and later that support HSDPA UE capability categories 16 - 18. 9.3.1H.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows table specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1H.1: Test parameters for fixed reference measurement channel requirements for category 22-24 UE Parameters Unit Test 1 (Category 22-24) HS-PDSCH Modulation - 64QAM Scrambling code and basic midamble code number - 1 Number of TS - 5 Number of Hybrid ARQ processes - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..14 Redundancy and constellation version coding sequence - {6,5,4,0} dB -11.46 Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1H.2: Minimum performance requirements for fixed reference measurement channel requirement in multipath channels for category 22-24 UE Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 18 1090 9.3.1H.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above for 64QAM modulation. 9.3.1H.4 Method of test 9.3.1H.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1A.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2.6. 9.3.1H.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [25]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1H.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.1H.3 of test requirement. The pass / fail decision for throughput is done according to Annex F.6.3. Table 9.3.1H.3: Test requirements for fixed reference measurement channel requirement in multipath channels for category 22-24 UE Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 18.6 1090 9.3.1I HS-DSCH throughput for Fixed Reference Channels –MIMO UE Category 25 9.3.1I.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and tests for category25 apply to 1,28 Mcps TDD UEs from release 8 and later that MIMO is configured. If MIMO is not configured, a category 25 UE should have the capability of category 18. 9.3.1I.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows tables specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1I.1: Test parameters for fixed reference measurement channels for Category 25 UE class Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - QPSK 16QAM Scrambling code and basic midamble code number - 0 Number of TS - 3 Number of Hybrid ARQ processes per stream - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 C(i,16) i=1..16 Redundancy and constellation version coding sequence - {0,0,0,0} {6,2,1,5} dB -12.04 -12.04 Stream Number Configuration - Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1I.2: Performance requirements for fixed reference channels for Category 25 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 390 2 PA3 6 160 3 PA3 16 860 4 PA3 12 370 9.3.1I.3 Test purpose To verify that the MIMO configured UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, for QPSK and 16QAM modulation. 9.3.1I.4 Method of test 9.3.1I.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A..11010a8 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1I.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. (e.g. Fixed reference Channel Definition (16 QAM): The information bit payload block is 3650 bits long. Hence the PRBSequence must be at least 3650 10 bits long. ) Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1I.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in tables above of test requirement. Table 9.3.1I.3: Test requirements for fixed reference channels for Category 25 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 390 2 PA3 6.6 160 3 PA3 16.6 860 4 PA3 12.6 370 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1J HS-DSCH throughput for Fixed Reference Channels –MIMO UE Category 26 9.3.1J.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and tests for category 26 apply to 1,28 Mcps TDD UEs from release 8 and later that MIMO is configured. If MIMO is not configured, a category 26 UE should have the capability of category 21 9.3.1J.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows tables specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1J.1: Test parameters for fixed reference measurement channels for Category 26 UE class Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - QPSK 16QAM Scrambling code and basic midamble code number* - 0 Number of TS - 4 Number of Hybrid ARQ processes per stream - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 C(i,16) i=1..16 Redundancy and constellation version coding sequence - {0,0,0,0} {6,2,1,5} dB -12.04 -12.04 Stream Number Configuration - Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1J.2: Performance requirements for fixed reference channels for Category 26 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 650 2 PA3 6 220 3 PA3 16 950 4 PA3 12 380 9.3.1J.3 Test purpose To verify that the MIMO configured UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, for QPSK and 16QAM modulation. 9.3.1J.4 Method of test 9.3.1J.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10aA.18 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1J.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1J.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in tables above of test requirement. Table 9.3.1J.3: Test requirements for fixed reference channels for Category 26 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 650 2 PA3 6.6 220 3 PA3 16.6 950 4 PA3 12.6 380 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1K HS-DSCH throughput for Fixed Reference Channels –MIMO UE Category 27 9.3.1K.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and tests for category 27 apply to 1,28 Mcps TDD UEs from release 8 and later that MIMO is configured. If MIMO is not configured, a category 27 UE should have the capability of category 24 9.3.1K.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows tables specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1K.1: Test parameters for fixed reference measurement channels for Category 27 UE class Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - QPSK 16QAM Scrambling code and basic midamble code number - 0 Number of TS - 5 Number of Hybrid ARQ processes per stream - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 C(i,16) i=1..16 Redundancy and constellation version coding sequence - {0,0,0,0} {6,2,1,5} dB -12.04 -12.04 Stream Number Configuration - Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1K.2: Performance requirements for fixed reference channels for Category 27 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10 850 2 PA3 6 280 3 PA3 16 1200 4 PA3 12 500 9.3.1K.3 Test purpose To verify that the MIMO configured UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, for QPSK and 16QAM modulation. 9.3.1K.4 Method of test 9.3.1K.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10aA.18 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1K.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1K.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in tables above of test requirement. Table 9.3.1K.3: Test requirements for fixed reference channels for Category 27 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 10.6 850 2 PA3 6.6 280 3 PA3 16.6 1200 4 PA3 12.6 500 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1L HS-DSCH throughput for Fixed Reference Channels –MIMO UE Category 28 9.3.1L.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and tests for category 28 apply to 1,28 Mcps TDD UEs from release 8 and later that MIMO is configured. 9.3.1L.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows tables specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1L.1: Test parameters for fixed reference measurement channels for Category 28 UE class Parameters Unit Test 1 Test 2 HS-PDSCH Modulation - 64QAM Scrambling code and basic midamble code number - 0 Number of TS - 3 Number of Hybrid ARQ processes per stream - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 Redundancy and constellation version coding sequence - {6,5,4,0} dB -12.04 Stream Number Configuration - Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1L.2: Performance requirements for fixed reference channels for Category 28 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 20 800 2 PA3 18 540 9.3.1L.3 Test purpose To verify that the MIMO configured UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, for 64QAM modulation. 9.3.1L.4 Method of test 9.3.1L.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10aA.18 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1L.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1L.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in tables above of test requirement. Table 9.3.1L.3: Performance requirements for fixed reference channels for Category 28 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 20.6 800 2 PA3 18.6 540 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1M HS-DSCH throughput for Fixed Reference Channels –MIMO UE CategoriesCategory 29 9.3.1M.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and tests for category 29 apply to 1,28 Mcps TDD UEs from release 8 and later that MIMO is configured. 9.3.1M.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows tables specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1M.1: Test parameters for fixed reference measurement channels for Category 29 UE class Parameters Unit Test 1 Test 2 HS-PDSCH Modulation - 64QAM Scrambling code and basic midamble code number - 0 Number of TS - 4 Number of Hybrid ARQ processes per stream - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 Redundancy and constellation version coding sequence - {6,5,4,0} dB -12.04 Stream Number Configuration - Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Ioc dBm/ 1.28MHz -60 Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1M.2: Performance requirements for fixed reference channels for Category 29 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 20 1200 2 PA3 18 780 9.3.1M.3 Test purpose To verify that the MIMO configured UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, for 64QAM modulation. 9.3.1M.4 Method of test 9.3.1M.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.18 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1M.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1M.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in tables above of test requirement. Table 9.3.1M.3: Performance requirements for fixed reference channels for Category 28 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 20.6 1200 2 PA3 18.6 780 The pass / fail decision for throughput is done according to Annex F.6.3. 9.3.1N HS-DSCH throughput for Fixed Reference Channels –MIMO UE CategoriesCategory 30 9.3.1N.1 Definition and applicability The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and tests for category 30 apply to 1,28 Mcps TDD UEs from release 8 and later that MIMO is configured. 9.3.1N.2 Minimum requirements For the parameters specified in below tables the measured throughput shall be equal to or better than the the specified value in belows tables specified the performance requirement. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.1N.1: Test parameters for fixed reference measurement channels for Category 30 UE class Parameters Unit Test 1 Test 2 HS-PDSCH Modulation - 64QAM Scrambling code and basic midamble code number - 0 Number of TS - 5 Number of Hybrid ARQ processes per stream - 4 Maximum number of Hybrid ARQ transmissions - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) i=1..16 Redundancy and constellation version coding sequence - {6,5,4,0} dB -12.04 Stream Number Configuration - Fixed Dual Stream Fixed Single Stream (2nd Stream is not used) Ioc dBm/ 1.28MHz -60 *Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.1N.2: Performance requirements for fixed reference channels for Category 30 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 20 1570 2 PA3 18 1000 9.3.1N.3 Test purpose To verify that the MIMO configured UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, for 64QAM modulation. 9.3.1N.4 Method of test 9.3.1N.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.18 2) Set Ack/Nack/ DTX handling at the SS as table 9.3.1.1,Setup fading simulators as fading conditions, which are described in table D.2.2.1.A. 3) Set up a HSDPA connection according to the Generic HSDPA setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 4) Set the test parameters according to above tables of test parameters. The configuration of the downlink channels is defined in table C.4.2. 9.3.1N.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. 2) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 3) For all relevant propagation conditions,count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.3 tables F.6.3.5.1 and F.6.3.5.2. 9.3.1N.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in tables above of test requirement. Table 9.3.1N.3: Performance requirements for fixed reference channels for Category 28 UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 20.6 1570 2 PA3 18.6 1000 The pass / fail decision for throughput is done according to Annex F.6.3.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.2 HS-DSCH throughput for Variable Reference Channels	The overall performance metric for HS-DSCH requirements is the throughput “R” measured on HS-DSCH. 9.3.2A HS-DSCH throughput for Variable Reference Channels 0.5 Mbps UE class 9.3.2A.1 Definition and applicability The HS-DSCH data throughput for variable reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 0.5Mbps UE class. 9.3.2A.2 Minimum requirements For the parameters specified in tables 9.3.2A.1 the measured throughput shall be equal to or better than the the specified value in table 9.3.2A.2. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.2A.1: Test parameters for variable reference measurement channel requirements for 0.5 Mbps UE class Parameter Unit Test 1 Test 2 Test 3 HS-PDSCH Modulation and TBS - * Scrambling code and basic midamble code Number - 1 Midamble Common midamble Number of TS - 2 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Redundancy and constellation version coding sequence Xrv 0 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i10 HS-PDSCHi_Ec/Ior dB -10 Ioc dBm -60 * Note 1 As requested by the last received CQI report Note 2 Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note 3 If the indicated CQI is 0, the Node-B emulator shall format the next HS-PDSCH transmission with the transport block size and the modulation scheme that were previously used. **Note: The timeslot just after the second switch point should be included. Table 9.3.2A.2: Minimum performance requirements for variable reference measurement channel requirement in multipath channels for 0.5 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15 242 2 PB3 15 244 3 VA30 15 211 9.3.2A.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined in table 9.3.2A.1, with the selection of QPSK and 16QAM modulation, and appropriate blocksize being determined by the SS based on the CQI reported by the UE. 9.3.2A.4 Method of test 9.3.2A.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Setup fading simulators as fading conditions , which are described in table D.2.2.1.A. 4) Set up a HSDPA connection according to the Generic HSDPA setup procedure,See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 5) Set the test parameters for tests according to above tables of test paramters 6) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 9.3.2A.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63(the first HSDPA block size isn’t recorded),then SS will decode the CQI report and transmit a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE. 2) For any HSDPA block transmitted by the SS, record transmitted block size and relevant received ACK, NACK and statDTX reported by UE. If UE reports ACK,the transmitted block is correctly received by UE.Continue transmission of the HS-PDSCH data and record transmitted block size until [2000] records have been reached. 3) For all relevant propagation conditions ,calculate the throughput, which is the ratio of the sum of correctly received transport bits over the testing time. [2000] multiplied by transmission time interval is the testing time. 9.3.2A.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.2A.3 of test requirement. Table 9.3.2A.3: Test requirements for variable reference measurement channel requirement in multipath channels for 0.5 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15.6 242 2 PB3 15.6 244 3 VA30 15.6 211 9.3.2B HS-DSCH throughput for Variable Reference Channels 1.1 Mbps UE class 9.3.2B.1 Definition and applicability The HS-DSCH data throughput for variable reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 1.1Mbps UE class. 9.3.2B.2 Minimum requirements For the parameters specified in tables 9.3.2B.1 the measured throughput shall be equal to or better than the the specified value in table 9.3.2B.2. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.2B.1: Test parameters for variable reference measurement channel requirements for 1.1 Mbps UE class Parameter Unit Test 1 Test 2 Test 3 HS-PDSCH Modulation and TBS - Scrambling code and basic midamble code Number - 1 Midamble Common midamble Number of TS - 2 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Redundancy and constellation version coding sequence Xrv 0 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i10 HS-PDSCHi_Ec/Ior dB -10 Ioc dBm -60 * Note 1 As requested by the last received CQI report Note 2 Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note 3 If the indicated CQI is 0, the Node-B emulator shall format the next HS-PDSCH transmission with the transport block size and the modulation scheme that were previously used. **Note: The timeslot just after the second switch point should be included. Table 9.3.2B.2: Minimum performance requirements for variable reference measurement channel requirement in multipath channels for 1.1 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15 318 2 PB3 15 323 3 VA30 15 213 9.3.2B.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined in table 9.3.2B.1, with the selection of QPSK and 16QAM modulation, and appropriate blocksize being determined by the SS based on the CQI reported by the UE. 9.3.2B.4 Method of test 9.3.2B.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Setup fading simulators as fading conditions , which are described in table D.2.2.1.A. 4) Set up a HSDPA connection according to the Generic HSDPA setup procedure,See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 5) Set the test parameters for tests according to above tables of test paramters 6) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 9.3.2B.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63(the first HSDPA block size isn’t recorded),then SS will decode the CQI report and transmit a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE. 2) For any HSDPA block transmitted by the SS, record transmitted block size and relevant received ACK, NACK and statDTX reported by UE. If UE reports ACK,the transmitted block is correctly received by UE.Continue transmission of the HS-PDSCH data and record transmitted block size until [2000] records have been reached. 3) For all relevant propagation conditions ,calculate the throughput, which is the ratio of the sum of correctly received transport bits over the testing time. [2000] multiplied by transmission time interval is the testing time. 9.3.2B.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.2B.3 of testrequirement. Table 9.3.2B.3: Test requirements for variable reference measurement channel requirement in multipath channels for 1.1 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15.6 318 2 PB3 15.6 323 3 VA30 15.6 213 9.3.2C HS-DSCH throughput for Variable Reference Channels 1.6 Mbps UE class 9.3.2C.1 Definition and applicability The HS-DSCH data throughput for variable reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 1.6Mbps UE class. 9.3.2C.2 Minimum requirements For the parameters specified in tables 9.3.2C.1 the measured throughput shall be equal to or better than the the specified value in table 9.3.2C.2. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.2C.1: Test parameters for variable reference measurement channel requirements for 1.6 Mbps UE class Parameter Unit Test 1 Test 2 Test 3 HS-PDSCH Modulation and TBS - Scrambling code and basic midamble code Number - 1 Midamble Common midamble Number of TS - 3 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Redundancy and constellation version coding sequence Xrv 0 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i10 HS-PDSCHi_Ec/Ior dB -10 Ioc dBm -60 * Note 1 As requested by the last received CQI report Note 2 Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note 3 If the indicated CQI is 0, the Node-B emulator shall format the next HS-PDSCH transmission with the transport block size and the modulation scheme that were previously used. **Note: The timeslot just after the second switch point should be included. Table 9.3.2C.2: Minimum performance requirements for variable reference measurement channel requirement in multipath channels for 1.6 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15 480 2 PB3 15 483 3 VA30 15 323 9.3.2C.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined in table 9.3.2C.1, with the selection of QPSK and 16QAM modulation, and appropriate blocksize being determined by the SS based on the CQI reported by the UE. 9.3.2C.4 Method of test 9.3.2C.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Setup fading simulators as fading conditions , which are described in table D.2.2.1.A. 4) Set up a HSDPA connection according to the Generic HSDPA setup procedure,See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 5) Set the test parameters for tests according to above tables of test paramters 6) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 9.3.2C.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63(the first HSDPA block size isn’t recorded),then SS will decode the CQI report and transmit a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE. 2) For any HSDPA block transmitted by the SS, record transmitted block size and relevant received ACK, NACK and statDTX reported by UE. If UE reports ACK,the transmitted block is correctly received by UE.Continue transmission of the HS-PDSCH data and record transmitted block size until [2000] records have been reached. 3) For all relevant propagation conditions ,calculate the throughput, which is the ratio of the sum of correctly received transport bits over the testing time. [2000] multiplied by transmission time interval is the testing time. 9.3.2C.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.2C.3 of testrequirement. Table 9.3.2C.3: Test requirements for variable reference measurement channel requirement in multipath channels for 1.6 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15.6 480 2 PB3 15.6 483 3 VA30 15.6 323 9.3.2D HS-DSCH throughput for Variable Reference Channels 2.2 Mbps UE class 9.3.2D.1 Definition and applicability The HS-DSCH data throughput for variable reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 2.2Mbps UE class. 9.3.2D.2 Minimum requirements For the parameters specified in tables 9.3.2D.1 the measured throughput shall be equal to or better than the the specified value in table 9.3.2D.2. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.2D.1: Test parameters for variable reference measurement channel requirements for 2.2 Mbps UE class Parameter Unit Test 1 Test 2 Test 3 HS-PDSCH Modulation and TBS - Scrambling code and basic midamble code Number - 1 Midamble Common midamble Number of TS - 4 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Redundancy and constellation version coding sequence Xrv 0 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i10 HS-PDSCHi_Ec/Ior dB -10 Ioc dBm -60 * Note 1 As requested by the last received CQI report Note 2 Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note 3 If the indicated CQI is 0, the Node-B emulator shall format the next HS-PDSCH transmission with the transport block size and the modulation scheme that were previously used. **Note: The timeslot just after the second switch point should be included. Table 9.3.2D.2: Minimum performance requirements for variable reference measurement channel requirement in multipath channels for 2.2 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15 625 2 PB3 15 631 3 VA30 15 418 9.3.2D.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined in table 9.3.2D.1, with the selection of QPSK and 16QAM modulation, and appropriate blocksize being determined by the SS based on the CQI reported by the UE. 9.3.2D.4 Method of test 9.3.2D.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Setup fading simulators as fading conditions , which are described in table D.2.2.1.A. 4) Set up a HSDPA connection according to the Generic HSDPA setup procedure,See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 5) Set the test parameters for tests according to above tables of test paramters 6) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 9.3.2D.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63(the first HSDPA block size isn’t recorded),then SS will decode the CQI report and transmit a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE. 2) For any HSDPA block transmitted by the SS, record transmitted block size and relevant received ACK, NACK and statDTX reported by UE. If UE reports ACK,the transmitted block is correctly received by UE.Continue transmission of the HS-PDSCH data and record transmitted block size until [2000] records have been reached. 3) For all relevant propagation conditions ,calculate the throughput, which is the ratio of the sum of correctly received transport bits over the testing time. [2000] multiplied by transmission time interval is the testing time. 9.3.2D.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.2D.3 of testrequirement. Table 9.3.2D.3: Test requirements for variable reference measurement channel requirement in multipath channels for 2.2 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15.6 625 2 PB3 15.6 631 3 VA30 15.6 418 9.3.2E HS-DSCH throughput for Variable Reference Channels 2.8 Mbps UE class 9.3.2E.1 Definition and applicability The HS-DSCH data throughput for variable reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 2.2Mbps UE class. 9.3.2E.2 Minimum requirements For the parameters specified in tables 9.3.2E.1 the measured throughput shall be equal to or better than the the specified value in table 9.3.2E.2. The reference for this requirement is TS 25.102 [1] section 9. Table 9.3.2E.1: Test parameters for variable reference measurement channel requirements for 2.8 Mbps UE class Parameter Unit Test 1 Test 2 Test 3 HS-PDSCH Modulation and TBS - Scrambling code and basic midamble code Number - 1 Midamble Common midamble Number of TS - 5 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Redundancy and constellation version coding sequence Xrv 0 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i10 HS-PDSCHi_Ec/Ior dB -10 Ioc dBm -60 * Note 1 As requested by the last received CQI report Note 2 Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. *Note 3 If the indicated CQI is 0, the Node-B emulator shall format the next HS-PDSCH transmission with the transport block size and the modulation scheme that were previously used. Table 9.3.2E.2: Minimum performance requirements for variable reference measurement channel requirement in multipath channels for 2.8 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15 783 2 PB3 15 792 3 VA30 15 544 9.3.2E.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined in table 9.3.2E.2, with the selection of QPSK and 16QAM modulation, and appropriate blocksize being determined by the SS based on the CQI reported by the UE. 9.3.2E.4 Method of test 9.3.2E.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Setup fading simulators as fading conditions , which are described in table D.2.2.1.A. 4) Set up a HSDPA connection according to the Generic HSDPA setup procedure,See TS 34.108 [3] and TS 34.109 [4] for details regarding generic HSDPA setup procedure. 5) Set the test parameters for tests according to above tables of test paramters 6) The information bit data shall be pseudo random and not repeated not before 10 different information bit payload blocks are processed. Use a PRBS from ITU-R O.153 Ref [26]. 9.3.2E.4.2 Procedure 1) Once the HSDPA connection is setup, start transmitting HSDPA Data. The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63(the first HSDPA block size isn’t recorded),then SS will decode the CQI report and transmit a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE. 2) For any HSDPA block transmitted by the SS, record transmitted block size and relevant received ACK, NACK and statDTX reported by UE. If UE reports ACK,the transmitted block is correctly received by UE.Continue transmission of the HS-PDSCH data and record transmitted block size until [2000] records have been reached. 3) For all relevant propagation conditions ,calculate the throughput, which is the ratio of the sum of correctly received transport bits over the testing time. [2000] multiplied by transmission time interval is the testing time. 9.3.2E.5 Test Requirements Tables of test parameters define the primary level settings including test tolerance for all relevant throughput tests. the measured throughput shall be equal to or better than the the specified value in table 9.3.2E.3 of testrequirement. Table 9.3.2E.3: Test requirements for variable reference measurement channel requirement in multipath channels for 2.8 Mbps UE class Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 15.6 783 2 PB3 15.6 792 3 VA30 15.6 544
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.3 Reporting of HS-DSCH Channel Quality Indicator	9.3.3A Reporting of HS-DSCH Channel Quality Indicator-0.5Mbps UE class 9.3.3A.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 0.5 Mbps UE class. 9.3.3A.2 Minimum requirements For the parameters specified in tables 9.3.3.1 the UE shall report a CQI value within the limits of table 9.3.3A.2. Table 9.3.3A.1: Test parameters for CQI reporting measurement channel requirements for 0.5Mbps UE class 0.5Mbps UE Parameter Unit Test 1 Number of TS - 2 Number of HS-PDSCH codes per TS - 10 HS-PDSCHi_Ec/Ior dB -10 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) 1i10 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 dB 1 Table 9.3.3A.2 Performance requirements for CQI reporting measurement channel requirements for 0.5Mbps UE class Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 3 90 10% 9.3.3A.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3A.4 Method of test 9.3.3A.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. Note: The following value of x is derived from Table 9.3.3A.2 9.3.3A.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3A.1. Note: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 9.3.3A.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3A.4.2. No test tolerance is applied to the test parameters. 9.3.3B Reporting of HS-DSCH Channel Quality Indicator-1.1Mbps UE class 9.3.3B.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 1.1 Mbps UE class.. 9.3.3B.2 Minimum requirements For the parameters specified in tables 9.3.3B.1 the UE shall report a CQI value within the limits of table 9.3.3B.2. Table 9.3.3B.1: Test parameters for CQI reporting measurement channel requirements for 1.1Mbps UE class 1.1Mbps UE Parameter Unit Test 1 Test 2 Number of TS - 2 Number of HS-PDSCH codes per TS - 10 HS-PDSCHi_Ec/Ior dB -10 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) 1i10 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 dB 1 8 Table 9.3.3B.2 Performance requirements for CQI reporting measurement channel requirements for 1.1Mbps U E class Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 3 90 10% Test 2 +/- 2 90 9.3.3B.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3B.4 Method of test 9.3.3B.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. Note: The following value of x is derived from Table 9.3.3B.2 9.3.3B.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3B.1. Note: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 6) Repeat the same procedure (steps 2 to 5) with test conditions according to the table 9.3.3B.1. 9.3.3B.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3B.4.2. No test tolerance is applied to the test parameters. 9.3.3C Reporting of HS-DSCH Channel Quality Indicator-1.6Mbps UE class 9.3.3C.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 1.6 Mbps UE class.. 9.3.3C.2 Minimum requirements For the parameters specified in tables 9.3.3C.1 the UE shall report a CQI value within the limits of table 9.3.3C.2. Table 9.3.3C.1: Test parameters for CQI reporting measurement channel requirements for 1.6Mbps UE class 1.6Mbps UE Parameter Unit Test 1 Test 2 Number of TS - 3 Number of HS-PDSCH codes per TS - 10 HS-PDSCHi_Ec/Ior dB -10 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) 1i10 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 dB 1 8 Table 9.3.3C.2 Performance requirements for CQI reporting measurement channel requirements for 1.6Mbps U E class Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3C.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3C.4 Method of test 9.3.3C.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. Note: The following value of x is derived from Table 9.3.3C.2 9.3.3C.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3C.1. Note: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 6) Repeat the same procedure (steps 2 to 5) with test conditions according to the table 9.3.3C.1. 9.3.3C.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3C.4.2. No test tolerance is applied to the test parameters. 9.3.3D Reporting of HS-DSCH Channel Quality Indicator-2.2Mbps UE class 9.3.3D.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 2.2 Mbps UE class.. 9.3.3D.2 Minimum requirements For the parameters specified in tables 9.3.3D.1 the UE shall report a CQI value within the limits of table 9.3.3D.2. Table 9.3.3D.1: Test parameters for CQI reporting measurement channel requirements for 2.2Mbps UE class 1.6Mbps UE Parameter Unit Test 1 Test 2 Number of TS - 4 Number of HS-PDSCH codes per TS - 10 HS-PDSCHi_Ec/Ior dB -10 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) 1i10 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 dB 1 8 Table 9.3.3D.2 Performance requirements for CQI reporting measurement channel requirements for 2.2Mbps U E class Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3D.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3D.4 Method of test 9.3.3D.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. Note: The following value of x is derived from Table 9.3.3D.2 9.3.3D.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3D.1. Note: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 6) Repeat the same procedure (steps 2 to 5) with test conditions according to the table 9.3.3D.1. 9.3.3D.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3D.4.2. No test tolerance is applied to the test parameters. 9.3.3E Reporting of HS-DSCH Channel Quality Indicator-2.8Mbps UE class 9.3.3E.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA which is 2.8 Mbps UE class.. 9.3.3E.2 Minimum requirements For the parameters specified in tables 9.3.3E.1 the UE shall report a CQI value within the limits of table 9.3.3E.2. Table 9.3.3E.1: Test parameters for CQI reporting measurement channel requirements for 2.8Mbps UE class 2.2Mbps UE Parameter Unit Test 1 Test 2 Number of TS - 5 Number of HS-PDSCH codes per TS - 10 HS-PDSCHi_Ec/Ior dB -10 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) 1i10 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 dB 1 8 Table 9.3.3E.2 Performance requirements for CQI reporting measurement channel requirements for 2.8Mbps U E class Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3E.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3E.4 Method of test 9.3.3E.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. Note: The following value of x is derived from Table 9.3.3E.2 9.3.3E.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3E.1. Note: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 6) Repeat the same procedure (steps 2 to 5) with test conditions according to the table 9.3.3E.1. 9.3.3E.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3E.4.2. No test tolerance is applied to the test parameters. 9.3.3F Reporting of HS-DSCH Channel Quality Indicator – 64QAM UE capability categories 16 - 18 9.3.3F.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 8 and later that support HSDPA UE capability categories 16 - 18. 9.3.3F.2 Minimum requirements For the parameters specified in tables 9.3.3A.1 the UE shall report a CQI value within the limits of table 9.3.3F.2. Table 9.3.3F.1: Test parameters for CQI reporting measurement channel requirements for UE capability categories 16 - 18 Category 16-18 Parameter Unit Test 1 Number of TS - 3 Number of HS-PDSCH codes per TS - 14 HS-PDSCHi_Ec/Ior dB -11.46 HS-PDSCH Channelization Codes* C(k,Q) C(i,16) 1i14 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Ioc** dBm/1.28MHz -60 dB 18 Propagation Channel - AWGN Note 1: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note 2: For multi-carrier reception, it refers to on each carrier. Table 9.3.3F.2: Performance requirements for CQI reporting measurement channel requirements for UE capability categories 16 - 18 Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% 9.3.3F.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3F.4 Method of test 9.3.3F.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. NOTE: The following value of x is derived from Table 9.3.3F.2 9.3.3F.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3F.1. NOTE: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 9.3.3F.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3F.4.2. No test tolerance is applied to the test parameters. 9.3.3G Reporting of HS-DSCH Channel Quality Indicator – 64QAM UE capability categories 19 - 21 9.3.3G.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 8 and later that support HSDPA UE capability categories 19 - 21. 9.3.3G.2 Minimum requirements For the parameters specified in tables 9.3.3G.1 the UE shall report a CQI value within the limits of table 9.3.3G.2. Table 9.3.3G.1: Test parameters for CQI reporting measurement channel requirements for UE capability categories 19 - 21 Category 19-21 Parameter Unit Test 1 Number of TS - 4 Number of HS-PDSCH codes per TS - 14 HS-PDSCHi_Ec/Ior dB -11.46 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i14 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Ioc** dBm/1.28MHz -60 dB 18 Propagation Channel - AWGN Note 1: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note 2: For multi-carrier reception, it refers to on each carrier. Table 9.3.3G.2: Performance requirements for CQI reporting measurement channel requirements for UE capability categories 19 - 21 Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% 9.3.3G.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3G.4 Method of test 9.3.3G.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. NOTE: The following value of x is derived from Table 9.3.3G.2 9.3.3G.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3G.1. NOTE: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 9.3.3G.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3G.4.2. No test tolerance is applied to the test parameters. 9.3.3H Reporting of HS-DSCH Channel Quality Indicator – 64QAM UE capability categories 22 - 24 9.3.3H.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [1], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 8 and later that support HSDPA UE capability categories 22 - 24. 9.3.3H.2 Minimum requirements For the parameters specified in tables 9.3.3H.1 the UE shall report a CQI value within the limits of table 9.3.3H.2. Table 9.3.3H.1: Test parameters for CQI reporting measurement channel requirements for UE capability categories 22 - 24 Category 22-24 Parameter Unit Test 1 Number of TS - 5 Number of HS-PDSCH codes per TS - 14 HS-PDSCHi_Ec/Ior dB -11.46 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i14 Number of DPCHo - 0 Number of HARQ Process - 4 Number of transmission - 1 Ioc** dBm/1.28MHz -60 dB 18 Propagation Channel - AWGN Note 1: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. *Note 2: For multi-carrier reception, it refers to on each carrier. Table 9.3.3H.2: Performance requirements for CQI reporting measurement channel requirements for UE capability categories 22 - 24 Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% 9.3.3H.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, such that CQI reported by the UE falls within the acceptable range. 9.3.3H.4 Method of test 9.3.3H.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, and an AWGN source to the UE antenna connector as shown in figure A.9. 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. NOTE: The following value of x is derived from Table 9.3.3H.2 9.3.3H.4.2 Procedure 1) Set test conditions according to test 1 according table 9.3.3H.1. NOTE: the following part of the procedure will test, if the UE reports a limited range of CQI indicator under the predefined channel conditions. 2) The SS shall transmit a HSDPA block to UE selecting any TBS value excluding 0 or 63,then SS will decodes the CQI report and transmits a new block on the HS-DSCH with the transport block size and modulation scheme recommended by the UE.For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side). This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 9.3.3H.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3H.4.2. No test tolerance is applied to the test parameters. 9.3.3I Reporting of HS-DSCH Channel Quality Indicator – category 25 MIMO 9.3.3I.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN and static orthogonal environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [21], section 9. The requirements and this test apply to 1,28 Mcps TDD MIMO capable UEs category 25 from release 8 and later. 9.3.3I.2 Minimum requirements For the parameters specified in tables 9.3.3I.1 the UE categories 25 shall report a CQI value within the limits of table 9.3.3I.2. The MIMO dual stream static orthogonal propagation conditions are defined in Annex D.2.5.1. For UE supporting Spreading Factor 1 only in dual stream transmission, the number of HS-PDSCH codes per TS should be configured to 1 in dual stream transmission, and the HS-PDSCHi_Ec/Ior should be 0dB. Table 9.3.3I.1: Test parameters for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Category 25 Parameter Unit Test 1 Test 2 Number of TS - 3 Number of HS-PDSCH codes per TS - 16 Number of HS-PDSCH codes per TS - 16 HS-PDSCHi_Ec/Ior dB -12.04 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i16 Number of DPCHo - 0 Number of HARQ Process per stream - 4 Number of transmission - 1 Ioc dBm -60 dB 8 10 Stream Number configuration - Single Stream Dual Stream Propagation Channel - AWGN Static Orthogonal Table 9.3.3I.2: Performance requirements for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3I.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above, such that CQI reported by the UE falls within the acceptable range. 9.3.3I.4 Method of test 9.3.3I.4.1 Initial conditions Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.18 2) Set Ack/Nack/DTX handling at the SS such that regardless of the response from the UE (Ack, Nack or DTX) new data is sent each time, this is because HARQ transmissions are set to one, i.e. no re-transmission of failed blocks. 3) Set up a call according to the Generic call setup procedure. See TS 34.108 [3] and TS 34.109 [4] for details regarding generic call setup procedure. 9.3.3I.4.2 Procedure For test 1, the test procedure is as followed: 1) Set test conditions according to test 1 according table 9.3.3I.1. 2) The SS shall transmit a HSDPA block on one antenna to UE, selecting any TBS value excluding 0 or 63, then SS will decodes CQI report and transmits a new block on HS-DSCH with the transport block size and modulation scheme recommended by the UE on the other antenna. For any HSDPA block transmitted by the SS, record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of the HS-PDSCH data and collect RTBS value of CQI until [2000] reports have been gathered. 3) Set up a relative frequency distribution for the RTBS value of CQI indicator reported. Calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side) . This RTBS value of CQI indicator is declared as Median CQI value, 4) If [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI - x) ≤ Median CQI ≤ ( Median CQI + x) then continue with next step , otherwise fail the UE. 5) Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. For test 2, the test procedure is as followed: 1) Set test conditions according to test 1 according table 9.3.3I.1. 2) The SS shall transmit two streams on each antenna to UE, each with a sequence of HSDPA blocks. For each stream, SS firstly transmit a HSDPA block, selecting any TBS value excluding 0 or 63, then SS will decodes CQI report and transmits a new block on HS-DSCH with the transport block size and modulation scheme recommended by the UE. For any HSDPA block transmition, the SS shall record the received RTBS value of CQI indicator and the ACK, NACK and statDTX . Continue transmission of each streams of HS-PDSCH data and collect RTBS value of CQI until [2000] reports for this stream have been gathered. 3) For each stream, the SS set up a relative frequency distribution for the RTBS value of CQI indicator reported, then calculate the median value (Median RTBS is the RTBS that is at or crosses 50% distribution from the lower RTBS side) for this stream. This RTBS value of CQI indicator is declared as Median CQI-stream value, 4) For each stream, if [1800] or more of the RTBS value of CQI indicator are in the range (Median CQI-stream - x) ≤ Median CQI-stream ≤ ( Median CQI-stream + x) then continue with next step , otherwise fail the UE. 5) For each stream, Calculate the the ratio ( NACK + statDTX / ACK + NACK + statDTX) when the SS transmit the TBS according to the median-CQI-stream value.If the ratio< 0.1 ,then pass the UE,otherwise fail the UE. 9.3.3I.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3I.4.2. No test tolerance is applied to the test parameters. 9.3.3J Reporting of HS-DSCH Channel Quality Indicator – category 26 MIMO 9.3.3J.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN and static orthogonal environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [21], section 9. The requirements and this test apply to 1,28 Mcps TDD MIMO capable UEs category 26 from release 8 and later. 9.3.3J.2 Minimum requirements For the parameters specified in tables 9.3.3J.1 the UE categories 26 shall report a CQI value within the limits of table 9.3.3J.2. The MIMO dual stream static orthogonal propagation conditions are defined in Annex D.2.5.1. For UE supporting Spreading Factor 1 only in dual stream transmission, the number of HS-PDSCH codes per TS should be configured to 1 in dual stream transmission, and the HS-PDSCHi_Ec/Ior should be 0dB. Table 9.3.3J.1: Test parameters for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Category 26 Parameter Unit Test 1 Test 2 Number of TS - 4 Number of HS-PDSCH codes per TS - 16 Number of HS-PDSCH codes per TS - 16 HS-PDSCHi_Ec/Ior dB -12.04 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i16 Number of DPCHo - 0 Number of HARQ Process per stream - 4 Number of transmission - 1 Ioc dBm -60 dB 8 10 Stream Number configuration - Single Stream Dual Stream Propagation Channel - AWGN Static Orthogonal Table 9.3.3J.2: Performance requirements for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3J.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above, such that CQI reported by the UE falls within the acceptable range. 9.3.3J.4 Method of test 9.3.3J.4.1 Initial conditions <FFS> According to 9.3.3I 9.3.3J.4.2 Procedure <FFS> According to 9.3.3I 9.3.3J.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3J.4.2. No test tolerance is applied to the test parameters. 9.3.3K Reporting of HS-DSCH Channel Quality Indicator – category 27 MIMO 9.3.3K.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN and static orthogonal environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [21], section 9. The requirements and this test apply to 1,28 Mcps TDD MIMO capable UEs category 27 from release 8 and later. 9.3.3K.2 Minimum requirements For the parameters specified in tables 9.3.3K.1 the UE categories 27 shall report a CQI value within the limits of table 9.3.3K.2. The MIMO dual stream static orthogonal propagation conditions are defined in Annex D.2.5.1. For UE supporting Spreading Factor 1 only in dual stream transmission, the number of HS-PDSCH codes per TS should be configured to 1 in dual stream transmission, and the HS-PDSCHi_Ec/Ior should be 0dB. Table 9.3.3K.1: Test parameters for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Category 27 Parameter Unit Test 1 Test 2 Number of TS - 5 Number of HS-PDSCH codes per TS - 16 Number of HS-PDSCH codes per TS - 16 HS-PDSCHi_Ec/Ior dB -12.04 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i16 Number of DPCHo - 0 Number of HARQ Process per stream - 4 Number of transmission - 1 Ioc dBm -60 dB 8 10 Stream Number configuration - Single Stream Dual Stream Propagation Channel - AWGN Static Orthogonal Table 9.3.3K.2: Performance requirements for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/-2 90 10% Test 2 +/-2 90 9.3.3K.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above, such that CQI reported by the UE falls within the acceptable range. 9.3.3K.4 Method of test 9.3.3K.4.1 Initial conditions <FFS> According to 9.3.3I 9.3.3K.4.2 Procedure <FFS> According to 9.3.3I 9.3.3K.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3K.4.2. No test tolerance is applied to the test parameters. 9.3.3L Reporting of HS-DSCH Channel Quality Indicator – category 28 MIMO 9.3.3L.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN and static orthogonal environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [21], section 9. The requirements and this test apply to 1,28 Mcps TDD MIMO capable UEs category 28 from release 8 and later. 9.3.3L.2 Minimum requirements For the parameters specified in tables 9.3.3L.1 the UE categories 28 shall report a CQI value within the limits of table 9.3.3L.2. The MIMO dual stream static orthogonal propagation conditions are defined in Annex D.2.5.1. For UE supporting Spreading Factor 1 only in dual stream transmission, the number of HS-PDSCH codes per TS should be configured to 1 in dual stream transmission, and the HS-PDSCHi_Ec/Ior should be 0dB. Table 9.3.3L.1: Test parameters for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Category 28 Parameter Unit Test 1 Test 2 Number of TS - 3 Number of HS-PDSCH codes per TS - 16 Number of HS-PDSCH codes per TS - 16 HS-PDSCHi_Ec/Ior dB -12.04 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i16 Number of DPCHo - 0 Number of HARQ Process per stream - 4 Number of transmission - 1 Ioc dBm -60 dB 16 18 Stream Number - Single Stream Dual Stream Propagation Channel - AWGN Static Orthogonal Table 9.3.3L.2: Performance requirements for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3L.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above, such that CQI reported by the UE falls within the acceptable range. 9.3.3L.4 Method of test 9.3.3L.4.1 Initial conditions <FFS> According to 9.3.3I 9.3.3L.4.2 Procedure <FFS> According to 9.3.3I 9.3.3L.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3L.4.2. No test tolerance is applied to the test parameters. 9.3.3M Reporting of HS-DSCH Channel Quality Indicator – category 29 MIMO 9.3.3M.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN and static orthogonal environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [21], section 9. The requirements and this test apply to 1,28 Mcps TDD MIMO capable UEs category 29 from release 8 and later. 9.3.3M.2 Minimum requirements For the parameters specified in tables 9.3.3M.1 the UE categories 29 shall report a CQI value within the limits of table 9.3.3M.2. The MIMO dual stream static orthogonal propagation conditions are defined in Annex D.2.5.1. For UE supporting Spreading Factor 1 only in dual stream transmission, the number of HS-PDSCH codes per TS should be configured to 1 in dual stream transmission, and the HS-PDSCHi_Ec/Ior should be 0dB. Table 9.3.3M.1: Test parameters for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Category 29 Parameter Unit Test 1 Test 2 Number of TS - 4 Number of HS-PDSCH codes per TS - 16 Number of HS-PDSCH codes per TS - 16 HS-PDSCHi_Ec/Ior dB -12.04 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i16 Number of DPCHo - 0 Number of HARQ Process per stream - 4 Number of transmission - 1 Ioc dBm -60 dB 16 18 Stream Number - Single Stream Dual Stream Propagation Channel - AWGN Static Orthogonal Table 9.3.3M.2: Performance requirements for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3M.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above, such that CQI reported by the UE falls within the acceptable range. 9.3.3M.4 Method of test 9.3.3M.4.1 Initial conditions <FFS> According to 9.3.3I 9.3.3M.4.2 Procedure <FFS> According to 9.3.3I 9.3.3M.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3M.4.2. No test tolerance is applied to the test parameters. 9.3.3N Reporting of HS-DSCH Channel Quality Indicator – category 30 MIMO 9.3.3N.1 Definition and applicability The reporting accuracy of channel quality indicator (CQI) under AWGN and static orthogonal environments is determined by the reporting variance and the BLER performance using the transport format indicated by the reported CQI median. The CQI is measured while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [21], section 9. The requirements and this test apply to 1,28 Mcps TDD MIMO capable UEs category 30 from release 8 and later. 9.3.3N.2 Minimum requirements For the parameters specified in tables 9.3.3L.1 the UE categories 30 shall report a CQI value within the limits of table 9.3.3L.2. The MIMO dual stream static orthogonal propagation conditions are defined in Annex D.2.5.1. For UE supporting Spreading Factor 1 only in dual stream transmission, the number of HS-PDSCH codes per TS should be configured to 1 in dual stream transmission, and the HS-PDSCHi_Ec/Ior should be 0dB. Table 9.3.3N.1: Test parameters for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Category 30 Parameter Unit Test 1 Test 2 Number of TS - 5 Number of HS-PDSCH codes per TS - 16 Number of HS-PDSCH codes per TS - 16 HS-PDSCHi_Ec/Ior dB -12.04 HS-PDSCH Channelization Codes C(k,Q) C(i,16) 1i16 Number of DPCHo - 0 Number of HARQ Process per stream - 4 Number of transmission - 1 Ioc dBm -60 dB 16 18 Stream Number - Single Stream Dual Stream Propagation Channel - AWGN Static Orthogonal Table 9.3.3N.2: Performance requirements for CQI reporting measurement channel requirements (1.28 Mcps TDD Option) Test Permitted CQI range from median (x) % of time that CQI must be within +/- x of median (Y) Maximum BLER for median reported CQI Test 1 +/- 2 90 10% Test 2 +/- 2 90 9.3.3N.3 Test purpose To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined above, such that CQI reported by the UE falls within the acceptable range. 9.3.3N.4 Method of test 9.3.3N.4.1 Initial conditions <FFS> According to 9.3.3I 9.3.3N.4.2 Procedure <FFS> According to 9.3.3I 9.3.3N.5 Test Requirements The pass fail decision as specified in the test procedure in 9.3.3N.4.2. No test tolerance is applied to the test parameters.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4 HS-SCCH Detection Performance
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.1 Definition and applicability	The detection performance of the HS-SCCH is determined by the probability of event Em, which is declared when the UE is signaled on HS-SCCH, but DTX is observed in the corresponding HS-SICH ACK/NACK field. The probability of event Em is denoted P(Em). This corresponds to case when the SS indicates to the UE via the HS-SCCH that HSDPA data is to be sent, but the UE fails to decode this correctly. The normative reference for this test is 25.102 [2], section 9. The requirements and this test apply to 1,28 Mcps TDD UE from release 5 and later that support HSDPA.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.2 Minimum requirements	For the parameters specified in tables 9.3.4.1, for each value of HS-SCCH specified in Table 9.3.4.3 the measured P(Em) shall be less than or equal to the corresponding specified value of P(Em). The reference for this requirement is TS 25.102 [1] section 9.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.3 Test purpose	To verify that the UE receiver is capable meeting the minimum requirements for support of HSDPA in the conditions defined below, and does not report a DTX when valid data was sent, more often than the performance limits allow. Table 9.3.4.1: Test parameters for HS-SCCH detection (1.28Mcps TDD option) Parameter Unit Test 1 Test2 Number of TS under test - 1 Number of HS-SCCH codes per timeslot - 8 (4 x2) Scrambling code and basic midamble code number* - 0 Midamble Common midamble Number of DPCHo - 2 Number of H-ARQ process - 4 HS-SCCH UE Identity (,, …, ) - UE1 = 0000000000000000 (UE1 under test) UE2 = 0101010101010101 UE3 = 1010101010101010 UE4 = 1111111111111111 HS-SCCH Channelization Codes* C(k,Q) C(i,16) 1i8 HS-SCCH Channelization Codes for UE under test C(k,Q) C(i,16) 1i2 DPCHo Channelization Codes C(k,Q) C(i,16) 9i10 dB -10 Ioc dBm/1.28MHz -60 Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Table 9.3.4.2: Test parameters for HS-PDSCH (1.28Mcps TDD option) Parameter Unit Test 1 Test2 Number of TS under test - 2 Number of HS-PDSCH codes per timeslot - 10 Scrambling code and basic midamble code number - 0 HS-PDSCH Channelization Codes for UE under test C(k,Q) C(i,16) 1i10 dB -10 Ioc dBm/1.28MHz -60 dB ** Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note *: Allocate a sufficient power to so that probability of missing HS-DPSCH is very low. Table 9.3.4.3: Minimum requirement for HS-SCCH detection (1.28Mcps TDD option) Test Number Propagation Conditions (dB) 1 PA3 16 0.01 2 VA30 12 0.01 The propagation conditions are described in Annex D.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.4 Method of test
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.4.1 Initial conditions	Test environment: normal; see clauses G.2.1 and G.2.2. Frequencies to be tested: mid range; see clause G.2.4. 1) Connect SS, multipath fading simulator and an AWGN source to the UE antenna connector as shown in figure A.10. 2) Set Ack/Nack handling at the SS as table 9.3.1.1 (Fixed channel test) 3) Set up test parameter according to table 9.3.4.1 and able 9.3.4.2.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.4.2 Procedure	1. The UE is switched on. 2. An RRC connection is set-up according to the generic HSDPA set-up procedure specified in TS 34.108 [3]. 3. Count the number of NACK, ACK and statDTX on the UL HS-SICH during the test interval and decide pass or fail according to Annex F.6.1 and table F.6.1.8. NACK and ACK are counted as a pass and statDTX is counted as a failure.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.3.4.5 Test Requirements	The probability of event Em denoted as P(Em) (test procedure step 3) shall not exceed the specified value in table 9.3.4.4. Table 9.3.4.4: Test requirement for HS-SCCH detection (1.28Mcps TDD option) Test Number Propagation Conditions (dB) 1 PA3 16.6 0.01 2 VA30 12.6 0.01
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.4 Performance requirement for 7.68 Mcps TDD option	During the Fixed Reference Channel tests the behaviour of the Node-B emulator in response to the ACK/NACK signalling field of the HS-DPCCH is specified in Table 9.4.1: Table 9.4.1: Node-B Emulator Behaviour in response to ACK/NACK/DTX HS-DPCCH ACK/NACK Field State Node-B Emulator Behaviour ACK ACK: new transmission using 1st redundancy and constellation version (RV) NACK NACK: retransmission using the next RV (up to the maximum permitted number or RV’s) DTX DTX: retransmission using the RV previously transmitted to the same H-ARQ process
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.4.1 HS-DSCH throughput for Fixed Reference Channels
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.4.1.1 Definition and applicability	The HS-DSCH data throughput for fixed reference channels is defined by the capabilities of the UE as defined in [24] , and the throughput is measured by counting the amount of data succeesfully received at the UE by monitoring the ACK/NACK signalling field of the HS-SICH received at the SS, while random data is streamed from the SS to the UE. The normative reference for this test is 25.102 [2], section 9.3. The requirements and this test apply to 7.68 Mcps TDD UE from release 7 and later that support HSDPA.
40bd05ebf1e9d686c3dc55dd3e817398	34.122	9.4.1.2 Minimum requirements	The requirements are specified in terms of minimum information bit throughput R for the DL reference channels specified in Annex C.4.2A with the addition of the relevant parameters in Tables 9.4.1.1 and 9.4.1.3. Using this configuration the throughput shall meet or exceed the minimum requirements specified in tables 9.4.1.2 and 9.4.1.4. Table 9.4.1.1: Test parameters for fixed reference measurement channel requirements for 5,3 Mbps – Category 8 - UE (7,68 Mcps TDD Option) QPSK Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - QPSK Scrambling code and basic midamble code number* - 0, 1 Number of TS - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,32) i=1..32 Number of Hybrid ARQ processes - 3 Maximum number of Hybrid ARQ transmissions - 4 Redundancy and constellation version coding sequence** - {0,0,0,0} s=1, R=0, b=0 dB -15,05 dB 0 Ioc dBm/7,68MHz -60 Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note : This sequence implies Chase combining Table 9.4.1.2: Performance requirements for fixed reference measurement channel requirement in multipath channels for 5,3 Mbps – Category 8 - UE (7,68 Mcps TDD Option) QPSK Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 5,2 880 2 PB3 5,5 880 3 VA30 6,2 880 4 VA120 6,2 880 Table 9.4.1.3: Test parameters for fixed reference measurement channel requirements for 5,3 Mbps – Category 8 - UE (7,68 Mcps TDD Option) 16QAM Parameters Unit Test 1 Test 2 Test 3 Test 4 HS-PDSCH Modulation - 16QAM Scrambling code and basic midamble code number - 0, 1 Number of TS - 4 HS-PDSCH Channelization Codes* C(k,Q) C(i,32) i=1..32 Number of Hybrid ARQ processes - 3 Maximum number of Hybrid ARQ transmissions - 4 Redundancy and constellation version coding sequence** - {0,0,0,0} s=1, R=0, b=0 dB -15,05 dB 0 Ioc dBm/7,68MHz -60 Note : Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code. Note *: This sequence implies Chase combining Table 9.4.1.4: Performance requirements for fixed reference measurement channel requirement in multipath channels for 5,3 Mbps – Category 8 - UE (7,68 Mcps TDD Option) 16QAM Test Number Propagation conditions [dB] R (Throughput) [kbps] 1 PA3 11,1 1765 2 PB3 13,2 1765 3 VA30 13,7 1765 4 VA120 13,6 1765 The reference for this requirement is TS 25.102 [1] clauses 9.3.1.1 and 9.3.1.2.

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