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9.4.1.3 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.
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9.4.1.4 Method of test
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9.4.1.4.1 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 9.4.1. Set the test parameters and levels for tests 1-4 according to tables 9.4.1.1. The reference channel configuration is defined in section C.4.2A. 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.2.2.3.2 or D.2.2.3.4 depending on the frequency band.
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9.4.1.4.2 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 9.4.1.2 and 9.4.1.4 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.6.3.5.5 and F.6.3.5.6.
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9.4.1.5 Test Requirements
Tables 9.4.1.1 to 9.4.1.4 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.
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9.4.2 HS-DSCH throughput for Variable Reference Channels
FFS
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9.4.3 Reporting of HS-DSCH Channel Quality Indicator
FFS
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9.4.4 HS-SCCH Detection Performance
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9.4.4.1 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 9.3.4. The requirements and this test apply to 7.68 Mcps TDD UE from release 7 and later that support HSDPA.
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9.4.4.2 Minimum requirements
For the test parameters in Table 9.4.4.1, for each value of HS-SCCH-1 Ec/Ior specified in Table 9.4.4.2, the measured P(Em) shall be less than or equal to the corresponding specified value of P(Em). Table 9.4.4.1: Test parameters for HS-SCCH detection (7.68 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, 32), for UE1 (UE under test) HS-SCCH-2 = C(2, 32) for UE2 HS-SCCH-3 = C(3, 32) for UE3 HS-SCCH-4 = C(4, 32) 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 9.4.4.2: Minimum requirement for HS-SCCH detection (7.68 Mcps TDD option) Test Number Propagation Conditions Reference value HS-SCCH-1 (dB) (dB) 1 PA3 -6.0 0 0.05 2 PA3 -7.5 5 0.01 3 VA30 -6.0 0 0.01 The reference for this requirement is TS 25.102 [2] clause 9.3.4.
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9.4.4.3 Test purpose
To verify that P(Em) does not exceed the limit in table 9.4.4.2.
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9.4.4.4 Method of test
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9.4.4.4.1 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.2.2.3.1. 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 9.4.4.1 and 9.4.4.2. The reference channel configuration is defined in section C.4.2A. The configuration of the TX power for downlink physical channels is annex in E.3.
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9.4.4.4.2 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.
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9.4.4.5 Test Requirements
The probability of event Em denoted as P(Em) (test procedure step 3) shall not exceed the specified value in table 9.4.4.2. No test tolerance is applied to the test parameters.
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10 Performance requirements (MBMS)
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10.1 Demodulation of MCCH
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10.1.1 Definition and applicability
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10.1.1.1 3.84 Mcps TDD Option
The receive characteristic of the MCCH is determined by the RLC SDU error rate (RLC_SDU_ER). The requirement is valid for all RRC states for which the UE has capabilities. The requirements and this test apply to the 3,84 Mcps TDD UE.
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10.1.1.2 7.68 Mcps TDD Option
The receive characteristic of the MCCH is determined by the RLC SDU error rate (RLC_SDU_ER). The requirement is valid for all RRC states for which the UE has capabilities. The requirements and this test apply to the 7,68 Mcps TDD UE.
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10.1.2 Minimum requirement
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10.1.2.1 3.84 Mcps TDD Option
For the parameters specified in Table 10.1.1, the measured average downlink S-CCPCH_Ec/Ior power ratio shall be below the specified value for the RLC_SDU_ER shown in Table 10.1.2. Table 10.1.1: Test parameters for MCCH detection Parameters Unit Test 1 Ioc dBm/3.84 MHz -60 dB -3 Number of Interfering codes/timeslot - 7 × SF16 MCCH Data Rate kbps 7.2 Propagation condition - VA3 Table 10.1.2: Test requirements for MCCH detection Test Number S-CCPCH_Ec/Ior (dB) RLC_SDU_ER 1 -1.25 0.01
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10.1.2.2 7.68 Mcps TDD Option
For the parameters specified in Table 10.1.3, the measured average downlink S-CCPCH_Ec/Ior power ratio shall be below the specified value for the RLC_SDU_ER shown in Table 10.1.4. Table 10.1.3: Test parameters for MCCH detection Parameters Unit Test 1 Ioc dBm/7.68 MHz -60 dB -3 Number of Interfering codes/timeslot - 15 × SF32 MCCH Data Rate kbps 7.2 Propagation condition - VA3 Table 10.1.4: Test requirements for MCCH detection Test Number S-CCPCH_Ec/Ior (dB) RLC_SDU_ER 1 -4.7 0.01
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10.1.3 Test Purpose
The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for the MCCH channel does not exceed 0.01.
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10.1.4 Method of test
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10.1.4.1 Initial conditions
1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.10. 2) The MCCH Reference Measurement Channel parameters are defined in Annex C.5.1. 3) The configuration for the downlink channel for each radio link is defined in Annex.E. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10. 6) Setup the test parameter for MCCH detection test as specified in Table 10.1.1 and 10.1.2 for 3.84 Mcps TDD and Table 10.1.3. and 10.1.4 for 7.68 Mcps TDD. Set up fading simulator as per the fading conditionVA3, which is described in table D.2.2. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Switch on the fading simulator.
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10.1.4.2 Procedure
1) SS shall start the test by sending data on the MCCH radio bearer and maintain the count of transmitted RLC SDU blocks on the MCCH. 2) SS shall send a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message and wait for the UE to response with a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” reporting the received RLC SDU counter value. 3) SS shall compute the RLC SDU error rate based on the transmitted RLC SDUs count and received RLC SDU count reported by the UE. 4) The test shall be run until the statistical significance according to Annex to F.6.1.8 is achieved.
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10.1.5 Test Requirements
The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests shall not exceed 0.1 for the specified . The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1
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10.2 Demodulation of MTCH
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10.2.1 Definition and applicability
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10.2.1.1 3.84 Mcps TDD Option
The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to the 3,84 Mcps TDD UE.
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10.2.1.2 1.28 Mcps TDD Option
The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to Release 6 and later releases for all types of UTRA for the 1.28Mcps TDD UE that support MBMS.
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10.2.1.3 7.68 Mcps TDD Option
The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to the 7,68 Mcps TDD UE.
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10.2.2 Minimum requirement
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10.2.2.1 3.84 Mcps TDD Option
For the parameters specified in Table 10.2.1 the average downlink power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.2.2. Table 10.2.1: Parameters for MTCH detection for 3.84Mcps TDD Parameters Unit Test 1 Test 2 Test 3 Test 4 Ioc dBm/3.84 MHz -60 (S-CCPCH_Ec)/Ior per active timeslot dB 0 0 0 0 MTCH Data Rate Kbps 128 256 256 256 Propagation condition - VA3 Extended Delay Spread (see Table B.1D) Number of Radio Links - 2 3 1 1 S-CCPCH Modulation - QPSK QPKS 16QAM 16QAM Number of UE Rx Branches - 1 1 1 2 Table 10.2.2: Test requirements for MTCH detection for 3.84Mcps TDD Test Number (dB) RLC SDU ER 1 5.7 0.1 2 5.5 0.1 3 14.5 0.1 4 8.3 0.1
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10.2.2.2 1.28 Mcps TDD Option
For the parameters specified in Table 10.2.3 the average downlink power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.2.4. Table 10.2.3: Parameters for MTCH detection Parameters Unit Test 1 Test 2 Ioc dBm/1.28 MHz -60 (S-CCPCH_Ec)/Ior per active timeslot dB 0 MTCH Data Rate kbps 64 128 Number of codes per timeslot - 8xSF16 14xSF16 Number of interfering codes per timeslot - 0 0 Propagation condition - VA3 Number of Radio Links - 3 3 Table 10.2.4: Test requirements for MTCH detection Test Number (dB) RLC SDU ER 1 4.8 0.1 2 6.0 0.1
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10.2.2.3 7.68 Mcps TDD Option
For the parameters specified in Table 10.2.5 the average downlink power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.2.6. Table 10.2.5.: Parameters for MTCH detection for 7.68 Mcps TDD Parameters Unit Test 1 Test 2 Test 3 Test 4 Ioc dBm/7.68 MHz -60 (S-CCPCH_Ec)/Ior per active timeslot dB -3 -3 -3 -3 MTCH Data Rate Kbps 128 256 256 256 Number of interfering codes/timeslot - 16 × SF32 16 × SF32 16 × SF32 16 × SF32 Propagation condition - VA3 Extended Delay Spread (see Table B.8) Number of Radio Links - 2 3 1 1 S-CCPCH Modulation - QPSK QPSK 16QAM 16QAM Number of UE Rx Branches - 1 1 1 2 Table 10.2.6: Test requirements for MTCH detection for 7.68 Mcps TDD Test Number (dB) RLC SDU ER 1 6.1 0.1 2 5.0 0.1 ­3 14.7 0.1 4 8.2 0.1
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10.2.3 Test Purpose
The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for each individual data rate of the MTCH channel does not exceed 0.1. The test shall be performed in CELL_PCH state only.
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10.2.4 Method of test
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10.2.4.1 Initial conditions
1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.16. 2) The DL Reference Measurement Channel parameters are defined in Annex C.5.2. 3) The same MTCH data shall be sent in all radio links during the test. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10 with transition to the CELL_PCH state. 6) Setup the test parameter for MTCH detection test as specified in Table 10.2.1 and 10.2.2 for 3.84 Mcps TDD , Table 10.2.3 and 10.2.4 for 1.28Mcps TDD and Table 10.2.5. and 10.2.6 for 7.68 Mcps TDD. Set up fading simulator as per the fading conditionVA3, which is described in table D.2.2. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Switch on the fading simulator.
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10.2.4.2 Procedure
1) SS shall start the test by sending data on the MTCH radio bearer and maintain the count of transmitted RLC SDU blocks on the MTCH. 2) SS shall send a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message and wait for the UE to response with a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” reporting the received RLC SDU counter value. 3) SS shall compute the RLC SDU error rate based on the transmitted RLC SDUs count and received RLC SDU count reported by the UE. 4) The test shall be run until the statistical significance according to Annex to F.6.1.8 is achieved.
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10.2.5 Test Requirements
The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests does not exceed 0.1. The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1 10.2A Demodulation of MTCH-for MBSFN capable UE 10.2A.1 Definition and applicability 10.2A.1.1 Void 10.2A.1.2 1.28 Mcps TDD Option The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to Release 7 and later releases for all types of UTRA for the 1.28Mcps TDD UE that support MBSFN. 10.2A.1.3 Void 10.2A.2 Minimum requirement 10.2A.2.1 Void 10.2A.2.2 1.28 Mcps TDD Option For the parameters specified in Table 10.2A.3A the average downlink power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.2A.4A. Table 10.2A.3A: Parameters for MTCH detection Parameters Unit Test 11 Test 21 Test 32 Test 42 MTCH Data rate Kbps 192 384 192 384 Rx antenna - 1 2 1 2 Modulation - QPSK 16QAM QPSK 16QAM Ioc dBm/1.28 MHz -60 -60 -60 -60 (S-CCPCH_Ec)/Ior dB 0 0 0 0 Propagation condition - MBSFN channel model 1 (Annex D) MBSFN channel model 1 (Annex D) MBSFN channel model 2 (Annex D) MBSFN channel model 2 (Annex D) Slot Format # - 04 24 44 74 NOTE1: Test 1 and Test 2 are specified for the UE supporting normal delay spread. NOTE2: Test 3 and Test 4 are specified for the UE supporting extended delay spread. NOTE3: In the case of Rx diversity, the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. NOTE4: See Table 8Ha in TS25.221. Table 10.2A.4A: Test requirements for MTCH detection Test Number (dB) RLC SDU ER 1 13.3 0.1 2 14.7 0.1 3 13.3 0.1 4 15.1 0.1 10.2A.2.3 Void 10.2A.3 Test Purpose The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for each individual data rate of the MTCH channel does not exceed 0.1. The test shall be performed in CELL_PCH state only. 10.2A.4 Method of test 10.2A.4.1 Initial conditions 1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.16. 2) The DL Reference Measurement Channel parameters are defined in Annex C.5.2. 3) The same MTCH data shall be sent in all radio links during the test. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10 with transition to the CELL_PCH state. 6) Setup the test parameter for MTCH detection test as specified in Table 10.2A.3A and 10.2A.4A for 1.28Mcps TDD. Set up fading simulator as per the fading condition, which is described in table D.2.2.2.3. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Switch on the fading simulator. 10.2A.4.2 Procedure 1) SS shall start the test by sending data on the MTCH radio bearer and maintain the count of transmitted RLC SDU blocks on the MTCH. 2) SS shall send a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message and wait for the UE to response with a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” reporting the received RLC SDU counter value. 3) SS shall compute the RLC SDU error rate based on the transmitted RLC SDUs count and received RLC SDU count reported by the UE. 4) The test shall be run until the statistical significance according to Annex to F.6.1.8 is achieved. 10.2A.5 Test Requirements The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests does not exceed 0.1. The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1
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10.3 Demodulation of MTCH and cell identification
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10.3.1 1.28Mcps TDD option
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10.3.1.1 Definition and applicability
MBMS combining is not controlled by a network but instead it is autonomously handled by a terminal. UE has to be able to receive MTCH and identify intra-frequency neighbour cells according to the requirements. The receive characteristic of the MTCH combined with cell identification is determined by RLC SDU error rate (RLC SDU ER). The requirements and this test apply to Release 6 and later releases for1.28Mcps TDD UE that supports MBMS.
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10.3.1.2 Minimum requirements
For the parameters specified in Table 10.3.1.1 the average downlink S-CCPCH power ratio shall be below the specified value for the RLC SDU error rate shown in Table 10.3.1.2. The cell reselection parameters are given in clause in Table 10.3.1.3. The different cells are assumed to be time aligned. Table 10.3.1.1: Parameters for MTCH demodulation requirements with cell identification Parameter Unit Test 1 Stage 1 Stage 2 Stage 3 Time in each stage s 2s 800ms 2s dBm/1.28MHz -60 Propagation condition VA 3 MTCH Data Rate kbps 64kbps Number of Radio Links Cell 1, Cell 2 Cell 1, Cell2, Cell3 Cell 1, Cell 3 Table 10.3.1.2: Requirements for MTCH detection Test Number RLC SDU ER 1 6.1 0.05 Parameters for combined MTCH demodulation and cell identification requirements are defined in Table 10.3.1.3. Table 10.3.1.3: Cell reselection parameters Parameter Unit Value Serving cell in the initial condition Cell1 Neighbour cells 32 intra-frequency neighbour cells are indicated including Cell2 and Cell3 Cell_selection_and_reselection_quality_measure PCCPCH RSCP Qrxlevmin dBm -103 UE_TXPWR_MAX_ RACH dB 21 Treselection Seconds 4 Sintrasearch dB not sent IE “FACH Measurement occasion info” not sent The reference for this requirement is TS 25.102 [1] clause 10.3.1 and TS 25.102 [1] annex A.4.2.2.
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10.3.1.3 Test purpose
To verify that the RLC SDU error rate does not exceed the value at the S-CCPCH r specified in table 10.3.1.2.
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10.3.1.4 Method of test
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10.3.1.4.1 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 and AWGN noise source and fading simulators to the UE antenna connector as shown in Figure A.16. 2) The DL Reference Measurement Channel parameters are defined in Annex C.5.1.2 3) The same MTCH data shall be sent in all active cells during the test. 4) The UE is switched on. 5) The UE selects the broadcast service provided by the SS (included in the MBMS_ACTIVATED_SERVICES variable). 6) Set up a call according to the generic call setup procedure specified in TS 34.108 [3] clause 7.3.10 to configure and activate an MBMS session with transition to CELL_PCH state. The SS broadcast the cell reselection parameters according to table 10.3.1.3.
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10.3.1.4.2 Procedures
1) The SS configures and activates cell 1 to 3 with RF parameters according to Stage 1 conditions in Table 10.3.1.1. 2) The SS transmits valid MAC headers and RLC SDUs on the MTCH radio bearer for 2 seconds. The SS counts the number of transmitted RLC SDUs on the MTCH with valid MAC headers (NSS_Stage1). 3) The SS transmits invalid MAC headers sets the test parameters for Cell 1, Cell 2 and Cell 3 as specified in table 10.3.1.1 and Stage 2. 4) The SS transmits valid MAC headers and RLC SDUs on the MTCH radio bearer for 0.8 seconds. The SS counts the number of transmitted RLC SDUs on the MTCH with valid MAC headers (NSS_Stage2). 5) The SS transmits invalid MAC headers sets the test parameters for Cell 1, Cell 2 and Cell 3 as specified in table 10.3.1.1 and Stage 3. 6) The SS transmits valid MAC headers and RLC SDUs on the MTCH radio bearer for 2 seconds. The SS counts the number of transmitted RLC SDUs on the MTCH with valid MAC headers (NSS_Stage3). 7) Repeat step 9) to 14) until the confidence level for RLC SDU’s according to annex F.6.1.8. 8) The SS transmits a PAGING TYPE 1 message to the UE on the PCH and the UE moves to CELL_FACH state, sending a CELL UPDATE message. The SS replies with a CELL UPDATE CONFIRM message. 9) The UE confirms the received C-RNTI to be used in CELL FACH state by transmitting a UTRAN MOBILITY INFORMATION CONFIRM message on the uplink DCCH. 10) The SS sends a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message. 11) The SS waits for the UE to respond by a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” message reporting the number of received RLC SDUs on MTCH (NUEOK). 12) The SS in Cell 1 calculates the SDU error rate as: (Number of SS transmitted RLC SDUs – UE received RLC SDUs) / Number of SS transmitted RLC SDUs; where Number of SS transmitted RLC SDUs = NSS_Stage1 + NSS_Stage2 + NSS_Stage3; and UE received RLC SDUs = NUEOK. 13) End the RRC connection according to the generic call setup procedure specified in TS 34.108 [3] clause 7.3.10. 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].
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10.3.1.5 Test requirements
The test parameters are specified in table 10.3.1.4. Table 10.3.1.4: Parameters for MTCH demodulation requirements with cell identification Parameter Unit Test 1 Stage 1 Stage 2 Stage 3 Time in each stage s 2s 800ms 2s dBm/1.28MHz -60 Propagation condition VA 3 MTCH Data Rate kbps 64kbps Number of Radio Links Cell 1, Cell 2 Cell 1, Cell2, Cell3 Cell 1, Cell 3 The RLC SDU ER shall not exceed the value specified in table 10.3.1.5 for the specified Table 10.3.1.5: Requirements for MTCH detection Test Number RLC SDU ER 1 6.1 0.05 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.
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10.4 Demodulation of MCCH for a MBSFN capable UE
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10.4.1 Definition and applicability
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10.4.1.1 3.84 Mcps TDD Option
The test is only applicable for UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MCCH is determined by the RLC SDU error rate (RLC_SDU_ER). The requirement is valid for all RRC states for which the UE has capabilities. The requirements and this test apply to the 3,84 Mcps TDD UE.
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10.4.1.2 7.68 Mcps TDD Option
The test is only applicable for UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MCCH is determined by the RLC SDU error rate (RLC_SDU_ER). The requirement is valid for all RRC states for which the UE has capabilities. The requirements and this test apply to the 7,68 Mcps TDD UE.
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10.1.4.1 3.84 Mcps TDD Option
For the parameters specified in table 10.4.1, the measured average downlink S-CCPCH_Ec/Ior power ratio shall be below the specified value for the RLC_SDU_ER shown in table 10.4.2. Table 10.4.1: Test parameters for MCCH detection for MBSFN enabled UE Parameters Unit Test 1 Ioc dBm/3.84 MHz -60 dB 12 Number of Interfering codes/timeslot - 7 × SF16 MCCH Data Rate kbps 7.2 Propagation condition - Extended delay spread (see Appendix B) Slot Format #i - 20 Table 10.4.2: Test requirements for MCCH detection (at least two receiver antennas) for MBSFN enabled UE Test Number S-CCPCH_Ec/Ior (dB) RLC_SDU_ER 1 -19.29 0.01
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10.4.2.2 7.68 Mcps TDD Option
For the parameters specified in table 10.4.3, the measured average downlink S-CCPCH_Ec/Ior power ratio shall be below the specified value for the RLC_SDU_ER shown in table 10.4.4. Table 10.4.3: Test parameters for MCCH detection for MBSFN enabled UE Parameters Unit Test 1 Ioc dBm/7.68 MHz -60 dB 12 Number of Interfering codes/timeslot - 15 × SF32 MCCH Data Rate kbps 7.2 Propagation condition - Extended delay spread (see Appendix B) Slot Format #i - 20 Table 10.4.4: Test requirements for MCCH detection (at least two receiver antennas) for MBSFN enabled UE Test Number S-CCPCH_Ec/Ior (dB) RLC_SDU_ER 1 -22.71 0.01
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10.4.3 Test Purpose
The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for the MCCH channel does not exceed 0.01.
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10.4.4 Method of test
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10.4.4.1 Initial conditions
1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.17. 2) The MCCH Reference Measurement Channel parameters are defined in Annex C.5.1. 3) The configuration for the downlink channel for each radio link is defined in Annex.E. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10. 6) Setup the test parameter for MCCH detection test as specified in Table 10.4.1 and 10.4.2 for 3.84 Mcps TDD and Table 10.4.3. and 10.4.4 for 7.68 Mcps TDD. Set up fading simulator as per the fading condition EDS, which is described in table D.2.2.1B for 3.84Mcps and table D.2.2.3.5 for 3.84Mcps. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Switch on the fading simulator.
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10.4.4.2 Procedure
1) SS shall start the test by sending data on the MCCH radio bearer and maintain the count of transmitted RLC SDU blocks on the MCCH. 2) SS shall send a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message and wait for the UE to response with a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” reporting the received RLC SDU counter value. 3) SS shall compute the RLC SDU error rate based on the transmitted RLC SDUs count and received RLC SDU count reported by the UE. 4) The test shall be run until the statistical significance according to Annex to F.6.1.8 is achieved.
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10.4.5 Test Requirements
The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests shall not exceed 0.1 for the specified S-CCPCH_Ec/Ior power ratio. The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1
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10.5 Demodulation of MTCH for a MBSFN capable UE
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10.5.1 Definition and applicability
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10.5.1.1 3.84 Mcps TDD Option
The test is only applicable for UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to the 3,84 Mcps TDD UE.
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10.2.1.2 7.68 Mcps TDD Option
The test is only applicable for UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to the 7,68 Mcps TDD UE.
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10.5.2 Minimum requirement
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10.5.2.1 3.84 Mcps TDD Option
For the parameters specified in Table 10.5.1 the average downlink power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.5.2. Table 10.5.1: Parameters for MTCH detection for 3.84Mcps TDD for MBSFN capable UE Parameters Unit Test 1 Ioc dBm/3.84 MHz -60 (S-CCPCH_Ec)/Ior per active timeslot dB 0 MTCH Data Rate kbps 512 Propagation condition - Extended delay spread (see Appendix B) Number of Radio Links - 1 S-CCPCH Modulation - 16QAM Table 10.5.2: Test requirements for MTCH detection for 3.84Mcps TDD for MBSFN capable UE (at least two receiver antennas) Test Number (dB) RLC SDU ER 1 14.58 0.1
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10.5.2.2 7.68 Mcps TDD Option
For the parameters specified in Table 10.5.3 the average downlink power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.5.4. Table 10.5.3.: Parameters for MTCH detection for 7.68 Mcps TDD Parameters Unit Test 1 Ioc dBm/7.68 MHz -60 (S-CCPCH_Ec)/Ior per active timeslot dB -3 MTCH Data Rate kbps 512 Number of interfering codes/timeslot - 16 × SF32 Propagation condition - Extended delay spread (see Appendix B) Number of Radio Links - 1 S-CCPCH Modulation - 16QAM Table 10.5.4: Test requirements for MTCH detection for 7.68 Mcps TDD Test Number (dB) RLC SDU ER 1 14.21 0.1
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10.5.3 Test Purpose
The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for each individual data rate of the MTCH channel does not exceed 0.1. The test shall be performed in CELL_PCH state only.
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10.5.4 Method of test
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10.5.4.1 Initial conditions
1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.17. 2) The DL Reference Measurement Channel parameters are defined in Annex C.5.2. 3) The configuration for the downlink channel for each radio link is defined in Annex.E.. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10 with transition to the CELL_PCH state. 6) Setup the test parameter for MTCH detection test as specified in Table 10.5.1 and 10.5.2 for 3.84 Mcps TDD , and Table 10.5.5. and 10.5.6 for 7.68 Mcps TDD. Set up fading simulator as per the fading condition EDS, which is described in table D.2.2.1B for 3.84Mcps and table D.2.2.3.5 for 3.84Mcps. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Switch on the fading simulator.
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10.5.5 Test Requirements
The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests does not exceed 0.1. The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1 10.5A Demodulation of MTCH for a IMB capable UE 10.5A.1 Definition and applicability The test is only applicable for UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. 10.5A.2 Minimum requirement For the parameters specified in Table 10.5A.1a the measured average downlink S-CCPCH_Ec/Ior power ratio shall be below the specified value for the RLC SDU ER shown in Table 10.5A.2a. Table 10.5A.1a: Parameters for MTCH detection Parameters Unit Test 1 Ioc dBm/3.84MHz -60 dB 12 MTCH Data Rate kbps 512 (see Annex C) Propagation condition - Extended Delay Spread (see Annex D) Table 10.5A.2a: Test requirements for MTCH detection (at least two receiver antennas) Test Number S-CCPCH_Ec/Ior (dB) RLC SDU ER 1 -3.5 0.1 10.5A.3 Test Purpose The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for each individual data rate of the MTCH channel does not exceed 0.1. 10.5A.4 Method of test 10.5A.4.1 Initial conditions 1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.17. 2) The DL Reference Measurement Channel parameters are defined in Annex C.5.2. 3) The configuration for the downlink channel for each radio link is defined in Annex.E.. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10 with transition to the CELL_PCH state. 6) Setup the test parameter for MTCH detection test as specified in Table 10.5A.1a and 10.5A.2a for 3.84 Mcps TDD IMB. Set up fading simulator as per the fading condition EDS, which is described in table D.2.2.1B for 3.84Mcps. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Switch on the fading simulator. 10.5A.4.2 Procedure 1) SS shall start the test by sending data on the MTCH radio bearer and maintain the count of transmitted RLC SDU blocks on the MTCH. 2) SS shall send a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message and wait for the UE to response with a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” reporting the received RLC SDU counter value. 3) SS shall compute the RLC SDU error rate based on the transmitted RLC SDUs count and received RLC SDU count reported by the UE. 4) The test shall be run until the statistical significance according to Annex to F.6.1.8 is achieved. 10.5A.5 Test Requirements The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests does not exceed 0.1. The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1
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10.6 MBSFN TDD and FDD same platform sharing
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10.6.1 Definition and applicability
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10.6.1.1 3.84 Mcps TDD Option
This test case is to ensure that a simultaneous demodulation of MTCH and FDD transmission is possible for a MBSFN TDD UE sharing the same platform with a FDD UE. The test is only applicable for TDD UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to the 3,84 Mcps TDD (non-IMB) UE.
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10.6.1.2 7.68 Mcps TDD Option
This test case is to ensure that a simultaneous demodulation of MTCH and FDD transmission is possible for a MBSFN TDD UE sharing the same platform with a FDD UE. The test is only applicable for TDD UEs with at least two receiver antenna connectors where the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The receive characteristic of the MTCH is determined by RLC SDU error rate (RLC SDU ER). RLC SDU ER is specified for each individual data rate of the MTCH. The requirement is valid for all RRC states for which the UE has capabilities for MBMS. The requirements and this test apply to the 7,68 Mcps TDD UE.
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10.6.2 Minimum requirement
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10.6.2.1 3.84 Mcps TDD Option
For the parameters specified in Table 10.6.1 the average downlink Îor power shall be below the specified value for the RLC SDU ER shown in Table 10.6.2. Table 10.6.1: Parameters for MTCH detection sharing same platform with FDD for 3.84Mcps TDD Parameters Unit Test 1 Test 2 FDD UE Tx Pwr dBm/ 3.84 MHz Nominal Maximum Output Power Nominal Maximum Output Power Ioc dBm/ 3.84 MHz -infinity -infinity (S-CCPCH_Ec)/Ior per active timeslot dB 0 0 MTCH Data Rate kbps 512 512 Number of interfering codes/timeslot - 0 0 Propagation condition - Extended Delay Spread (see Appendix B) Extended Delay Spread (see Appendix B) Number of Radio Links - 1 1 S-CCPCH Modulation - 16QAM 16QAM TDD operating frequencies MHz 1900-1920 2570-2620 FDD operating band - Band I Band VII TDD/FDD carrier frequencies - Applicable for all combinations of TDD and FDD carrier frequencies except for combinations where the carrier frequency separation is less than 15 MHz Applicable for all combinations of TDD and FDD carrier frequencies except for combinations where the carrier frequency separation is less than 15 MHz Table 10.6.2: Test requirements for MTCH detection sharing same platform with FDD for 3.84Mcps TDD UE (at least two receiver antennas) Test Number Îor (dBm) RLC SDU ER 1 -83.42 0.1 2 -83.42 0.1
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10.6.2.3 7.68 Mcps TDD Option
For the parameters specified in Table 10.6.3 the average downlink Îor power shall be below the specified value for the RLC SDU ER shown in Table 10.6.4. Table 10.6.3: Parameters for MTCH detection sharing same platform with FDD for 7.68Mcps TDD Parameters Unit Test 1 Test 2 FDD UE Tx Pwr dBm/ 3.84 MHz Nominal Maximum Output Power Nominal Maximum Output Power Ioc dBm/ 7.68 MHz -infinity -infinity (S-CCPCH_Ec)/Ior per active timeslot dB -3 -3 MTCH Data Rate kbps 512 512 Number of interfering codes/timeslot - 16 × SF32 16 × SF32 Propagation condition - Extended Delay Spread (see Appendix B) Extended Delay Spread (see Appendix B) Number of Radio Links - 1 1 S-CCPCH Modulation - 16QAM 16QAM TDD operating frequencies MHz 1900-1920 2570-2620 FDD operating band - Band I Band VII TDD/FDD carrier frequencies - Applicable for all combinations of TDD and FDD carrier frequencies except for combinations where the carrier frequency separation is less than 17.5 MHz Applicable for all combinations of TDD and FDD carrier frequencies except for combinations where the carrier frequency separation is less than 17.5 MHz Table 10.6.4: Test requirements for MTCH detection sharing same platform with FDD for 3.84Mcps TDD UE (at least two receiver antennas) Test Number Îor (dBm) RLC SDU ER 1 -80.79 0.1 2 -80.79 0.1
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10.6.3 Test Purpose
The aim of the test is to verify that the RLC SDU error rate (RLC SDU ER) for each individual data rate of the MTCH channel does not exceed 0.1. The test shall be performed in CELL_PCH state only.
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10.6.4 Method of test
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10.6.4.1 Initial conditions
1) Connect the SS and AWGN noise source and fading simulator to the UE antenna connector as shown in Figure A.17. 2) The DL Reference Measurement Channel parameters are defined in Annex C.5.2. 3) The configuration for the downlink channel for each radio link is defined in Annex.E.. 4) The UE is switched on. 5) Set up a call according to the generic call setup procedure in TS34.108 [3] clause 7.3.10 with transition to the CELL_PCH state. 6) Setup the test parameter for MTCH detection test as specified in Table 10.5.1 and 10.5.2 for 3.84 Mcps TDD , and Table 10.5.5. and 10.5.6 for 7.68 Mcps TDD. Set up fading simulator as per the fading condition EDS, which is described in table D.2.2.1B for 3.84Mcps and table D.2.2.3.5 for 3.84Mcps. 7) Enter the UE into loopback test mode 3. See TS 34.108 and TS 34.109 for details regarding loopback test mode 3 for MBMS. 8) Use the SS to ensure that the UE is transmitting an FDD signal as defined in table 10.6.1 for 3.84Mcps TDD and table 10.6.3 for 7.68Mcps TDD. 9) Switch on the fading simulator.
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10.6.4.2 Procedure
1) SS shall start the test by sending data on the MTCH radio bearer and maintain the count of transmitted RLC SDU blocks on the MTCH. 2) SS shall send a “UE TEST LOOP MODE 3 RLC SDU COUNTER REQUEST” message and wait for the UE to response with a “UE TEST LOOP MODE 3 RLC SDU COUNTER RESPONSE” reporting the received RLC SDU counter value. 3) SS shall compute the RLC SDU error rate based on the transmitted RLC SDUs count and received RLC SDU count reported by the UE. 4) The test shall be run until the statistical significance according to Annex to F.6.1.8 is achieved.
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10.6.5 Test Requirements
The RLC SDU error rate (RLC SDU ER) for all the MTCH demodulation tests does not exceed 0.1. The RLC SDU error rate = the ratio of (transmitted RLC SDU count – received RLC SDU count) / (transmitted RLC SDU count) < 0.1
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11 Performance requirement (E-DCH)
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11.1 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH)
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11.1.1 Definition and applicability
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11.1.1.1 3.84 Mcps TDD Option
The performance of the E-HICH detection is determined by the false ACK probability (probability of detecting an ACK given that a NACK was sent) and the false NACK probability (probability of detecting a NACK given that an ACK was sent). The requirements and this test apply to Release 7 and later releases for all types of UTRA for the 3.84 Mcps TDD UE that support HSDPA and E-DCH.
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11.1.1.2 1.28 Mcps TDD Option
The performance of the E-HICH detection is determined by the false ACK probability (probability of detecting an ACK given that a NACK was sent) and the false NACK probability (probability of detecting a NACK given that an ACK was sent). The requirements and this test apply to Release 7 and later releases for all types of UTRA for the 1.28 Mcps TDD UE that support HSDPA and E-DCH.
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11.1.1.3 7.68 Mcps TDD Option
The performance of the E-HICH detection is determined by the false ACK probability (probability of detecting an ACK given that a NACK was sent) and the false NACK probability (probability of detecting a NACK given that an ACK was sent). The requirements and this test apply to Release 7 and later releases for all types of UTRA for the 7.68 Mcps TDD UE that support HSDPA and E-DCH.
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11.1.2 Minimum requirement
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11.1.2.1 3.84 Mcps TDD Option
For the parameters specified in Table 11.1.1 the average downlink E-HICH Ec/Ior power ratio shall be below the specified value for the false ACK and false NACK probabilities shown in Table 11.1.2. Table 11.1.1: Test parameters for E-HICH detection (3.84 Mcps TDD option) Parameters Unit Test 1 Test 2 Ioc dBm/3.84 MHz -60 dB 0 Number of Interfering codes/timeslot - 7 × SF16 (all codes have equal powers) E-HICH signalling pattern - 100% NACK 100% ACK Propagation condition - VA30 Table 11.1.2: Test requirements for E-HICH detection (3.84 Mcps TDD option) Test Number E-HICH Ec/Ior (dB) Parameter Probability 1 -18.5 False ACK 2E-3 2 -18.5 False NACK 2E-2
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11.1.2.2 1.28 Mcps TDD Option
For the parameters specified in Table 11.1.3 the average downlink E-HICH Ec/Ior power ratio shall be below the specified value for the false ACK and false NACK probabilities shown in Table 11.1.4. Table 11.1.3: Test parameters for E-HICH detection (1.28 Mcps TDD option) Parameters Unit Test 1 Test 2 Ioc dBm/1.28 MHz -60 dB 0 Number of Interfering codes/timeslot - 7 × SF16 (all codes have equal powers) E-HICH signalling pattern - 100% NACK 100% ACK Propagation condition - VA30 Table 11.1.4: Test requirements for E-HICH detection (1.28 Mcps TDD option) Test Number E-HICH Ec/Ior (dB) Parameter Probability 1 -7.5 False ACK 2E-3 2 -7.5 False NACK 2E-2
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11.1.2.3 7.68 Mcps TDD Option
For the parameters specified in Table 11.3 the average downlink E-HICH Ec/Ior power ratio shall be below the specified value for the false ACK and false NACK probabilities shown in Table 11.4. Table 11.1.5: Test parameters for E-HICH detection (7.68 Mcps TDD option) Parameters Unit Test 1 Test 2 Ioc dBm/7.68 MHz -60 dB 0 Number of Interfering codes/timeslot - 15 × SF32 (all codes have equal powers) E-HICH signalling pattern - 100% NACK 100% ACK Propagation condition - VA30 Table 11.1.6: Test requirements for E-HICH detection (7.68 Mcps TDD option) Test Number E-HICH Ec/Ior (dB) Parameter Probability 1 -21.7 False ACK 2E-3 2 -21.7 False NACK 2E-2
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11.1.3 Test Purpose
The test verifies that the false ACK probability and false NACK probability of E-HICH meet the requirement.
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11.1.4 Method of test
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11.1.4.1 Initial conditions
40bd05ebf1e9d686c3dc55dd3e817398
34.122
11.1.4.1.1 3.84Mcps TDD Option
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 and AWGN noise source and fading simulator to the UE antenna connector as shown in figure Figure A.10. 2) Set the test parameters for the false ACK test and the false NACK test as specified in table 11.1.1. 3) The UL Reference Measurement Channel parameters are defined in Annex C.6.1.1 and DL Reference Measurement Channel parameters are defined in Annex C4.1.1.1 4) The value of TRRI shall be set to ‘111111’ and CRRI on E-AGCH shall be set to 15. Note that the radio bearer reconfiguration message used to conifigure the UE will define 6 E-PUCH TS and therefore the length of the TRRI will be 6 bits. 5) The value of PRRI is set to 31. This ensures that the UL datarate remains constant. 6) The UE is switched on. 7) Enter the UE into loopback mode 1, looping back both the 12.2kbps RMC and HSDPA to E-DCH, and start the loopback test. See TS 34.108 [3] clause 7.3.9 and TS 34.109 [4] clauses 5.3.2.3 and 5.3.2.6. To fill the RLC transmit buffer, run the loopback for [3]s before starting the procedure. 8) Switch on the fading simulator.
40bd05ebf1e9d686c3dc55dd3e817398
34.122
11.1.4.1.2 1.28Mcps TDD Option
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 and AWGN noise source and fading simulator to the UE antenna connector as shown in figure Figure A.10. 2) Set the test parameters for the false ACK test and the false NACK test as specified in 11.1.3 for 1.28Mcps TDD option. 3) The UL Reference Measurement Channel parameters are defined in Annex C.6.1.2 and DL Reference Measurement Channel parameters are defined in Annex C4.2.1.1 4) The value of TRRI shall be set to ‘11000’ and CRRI on E-AGCH shall be set to 3. 5) The value of PRRI is same. This ensures that the UL datarate remains constant. 6) The UE is switched on. 7) Enter the UE into loopback mode 1, looping back both the 12.2kbps RMC and HSDPA to E-DCH, and start the loopback test. See TS 34.108 [3] clause 7.3.9 and TS 34.109 [4] clauses 5.3.2.3 and 5.3.2.6. To fill the RLC transmit buffer, run the loopback for [3]s before starting the procedure. 8) Switch on the fading simulator.