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40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.4.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.5 Demodulation of MTCH for a MBSFN capable UE | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.5.1 Definition and applicability | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.5.2 Minimum requirement | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.5.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.6 MBSFN TDD and FDD same platform sharing | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.6.1 Definition and applicability | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.6.2 Minimum requirement | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 10.6.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11 Performance requirement (E-DCH) | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH) | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.1 Definition and applicability | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.2 Minimum requirement | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.3 Test Purpose | The test verifies that the false ACK probability and false NACK probability of E-HICH meet the requirement. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.4.1.3 7.68Mcps 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.6.1.3 and DL Reference Measurement Channel parameters are defined in Annex C4.2A.1.1
4) The value of TRRI shall be set to ‘111111’ and CRRI on E-AGCH shall be set to 31. 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 | 11.1.4.2 3.84Mcps TDD Option | The measurement principle for the false ACK test (step 2 to 5) and for the false NACK test (step 6 to 9) is as follows. Upon the UE transmission on E-UCCH and E-PUCH, the SS reacts with E-HICH = ACK or NACK. The UE transmits new data or retransmissions on the corresponding E-UCCH and E-PUCH. The SS shall discriminate between:
(1) new data is a sign for ACK, received by the UE
(2) retransmission is a sign for NACK, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission.
1. The Nominal Avg. Information Bit Rate in the DL is set to 2649.6kbps according to Annex C4.1.1.1. The expected througput under this level and fading conditions is 1300 kbps. The UL datarate was configured by signalling TRRI=111111 and CRRI=15 on the E-AGCH. The expected UL datarate is 34.7 kbps corresponding to E-TFC Index 46.
2. In the test false ACK the SS responds with 100% ACK.
3. If the UE indicates on the E-UCCH a retransmission, the ACK from the SS was received as NACK by the UE. This is counted as false(ACK).
If the UE indicates on the E-UCCH new data, the ACK from the SS was received as ACK by the UE. This is counted as correct ACK.
4. Continue until statistical significance according to Annex F.6.4 is achieved.
5. If the number of retransmissions reaches the maximum number of retransmissions due to several false ACK detections in series, the first new data on the E-PUCH with E-UCCH are not the consequence of ACK. This case is not counted as sample.
6. In the test false NACK the SS responds with 100% NACK.
7. If the UE indicates on the E-UCCH new data, the NACK from the SS was received as ACK by the UE. This is counted as false(NACK ). If the UE indicates on E-UCCH retransmission, the NACK from the SS was received as NACK by the UE. This is counted as correct reception.
8. Continue until statistical significance according to Annex F.6.4 is achieved.
9. The number of retransmissions will reach the maximum number of transmissions due to several retransmissions in series. The first new data on the E-PUCH with E-UCCH are not the consequence of ACK received by the UE. This case is not counted as sample. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.4.2.2 1.28Mcps TDD Option | The measurement principle for the false ACK test (step 2 to 5) and for the false NACK test (step 6 to 9) is as follows. Upon the UE transmission on E-UCCH and E-PUCH, the SS reacts with E-HICH = ACK or NACK. The UE transmits new data or retransmissions on the corresponding E-UCCH and E-PUCH. The SS shall discriminate between:
(1) new data is a sign for ACK, received by the UE
(2) retransmission is a sign for NACK, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission.
. 1. The Nominal Avg. Information Bit Rate in the DL is set to 199.2 kbps according to FRC1in Annex C4.2.1.1. The expected througput under this level and fading conditions is 161 kbps. The UL datarate was configured by signalling TRRI=11000 and CRRI=3 on the E-AGCH. The expected UL datarate is 57.4 kbps corresponding to E-TFC Index 56.
2. In the test false ACK the SS responds with 100% ACK.
3. If the UE indicates on the E-UCCH a retransmission, the ACK from the SS was received as NACK by the UE. This is counted as false(ACK).
If the UE indicates on the E-UCCH new data, the ACK from the SS was received as ACK by the UE. This is counted as correct ACK.
4. Continue until statistical significance according to Annex F.6.4 is achieved.
5. If the number of retransmissions reaches the maximum number of retransmissions due to several false ACK detections in series, the first new data on the E-PUCH with E-UCCH are not the consequence of ACK. This case is not counted as sample.
6. In the test false NACK the SS responds with 100% NACK.
7. If the UE indicates on the E-UCCH new data, the NACK from the SS was received as ACK by the UE. This is counted as false(NACK ). If the UE indicates on E-UCCH retransmission, the NACK from the SS was received as NACK by the UE. This is counted as correct reception.
8. Continue until statistical significance according to Annex F.6.4 is achieved.
9. The number of retransmissions will reach the maximum number of transmissions due to several retransmissions in series. The first new data on the E-PUCH with E-UCCH are not the consequence of ACK received by the UE. This case is not counted as sample. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.4.2.3 7.68Mcps TDD Option | The measurement principle for the false ACK test (step 2 to 5) and for the false NACK test (step 6 to 9) is as follows. Upon the UE transmission on E-UCCH and E-PUCH, the SS reacts with E-HICH = ACK or NACK. The UE transmits new data or retransmissions on the corresponding E-UCCH and E-PUCH. The SS shall discriminate between:
(1) new data is a sign for ACK, received by the UE
(2) retransmission is a sign for NACK, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission.
. 1. The Nominal Avg. Information Bit Rate in the DL is set to 1761.2kbps according to Annex C4.2A.1.1. The expected througput under this level and fading conditions is 880 kbps. The UL datarate was configured by signalling TRRI=111111 and CRRI=15 on the E-AGCH. The expected UL datarate is 35.9 kbps corresponding to E-TFC Index 41.
2. In the test false ACK the SS responds with 100% ACK.
3. If the UE indicates on the E-UCCH a retransmission, the ACK from the SS was received as NACK by the UE. This is counted as false(ACK).
If the UE indicates on the E-UCCH new data, the ACK from the SS was received as ACK by the UE. This is counted as correct ACK.
4. Continue until statistical significance according to Annex F.6.4 is achieved.
5. If the number of retransmissions reaches the maximum number of retransmissions due to several false ACK detections in series, the first new data on the E-PUCH with E-UCCH are not the consequence of ACK. This case is not counted as sample.
6. In the test false NACK the SS responds with 100% NACK.
7. If the UE indicates on the E-UCCH new data, the NACK from the SS was received as ACK by the UE. This is counted as false(NACK ). If the UE indicates on E-UCCH retransmission, the NACK from the SS was received as NACK by the UE. This is counted as correct reception.
8. Continue until statistical significance according to Annex F.6.4 is achieved.
9. The number of retransmissions will reach the maximum number of transmissions due to several retransmissions in series. The first new data on the E-PUCH with E-UCCH are not the consequence of ACK received by the UE. This case is not counted as sample. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.1.5 Test Requirements | The false ACK and false NACK detection probability shall not exceed to the values specified in Table 11.1.2 for 3.84 Mcps TDD option, 11.1.4 for 1.28Mcps TDD option and Table 11.1.6 for 7.68 Mcps TDD option. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2 Demodulation of E-DCH Absolute Grant Channel (E-AGCH) | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.1 Definition and applicability | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.2.1 3.84 Mcps TDD Option | For the parameters specified in Table 11.2.1 the average downlink E-AGCH Îor/Ioc power ratio shall be below the specified value for the missed detection probability shown in Table 11.2.2.
Table 11.2.1: Test parameters for E-AGCH detection (3.84 Mcps TDD option)
Parameters
Unit
Test 1
Ioc
dBm/3.84 MHz
-60
dB
-6.02
Number of Interfering codes/timeslot
-
3 × SF16
Total bits in Timeslot Resource Related Information (TRRI)
bits
6
Total bits in Resource Duration Indicator (RDI)
bits
3
Total bits in E-AGCH
bits
38
Propagation condition
-
VA30
Table 11.2.2: Test requirements for E-AGCH detection (3.84 Mcps TDD option)
Test Number
E-AGCH Îor/Ioc (dB)
Missed Detection Probability
1
1.6
0.01 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.2.2 1.28 Mcps TDD Option | The performance of the E-AGCH detection is determined by the missed detection probability.
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. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.2.3 7.68 Mcps TDD Option | For the parameters specified in Table 11.2.5 the average downlink E-AGCH Îor/Ioc power ratio shall be below the specified value for the missed detection probability shown in Table 11.2.6.
Table 11.2.5: Test parameters for E-AGCH detection (7.68 Mcps TDD option)
Parameters
Unit
Test 1
Ioc
dBm/7.68 MHz
-60
dB
-9.03
Number of Interfering codes/timeslot
-
7 × SF32
Total bits in Timeslot Resource Related Information (TRRI)
bits
6
Total bits in Resource Duration Indicator (RDI)
bits
3
Total bits in E-AGCH
bits
39
Propagation condition
-
VA30
Table 11.2.6: Test requirements for E-AGCH detection (7.68 Mcps TDD option)
Test Number
E-AGCH Îor/Ioc (dB)
Missed Detection Probability
1
1.2
0.01 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.2 Minimum requirement | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.2.2 1.28Mcps TDD Option | For the parameters specified in Table 11.2.3 the average downlink Îor/Ioc power ratio shall be below the specified value for the missed detection probability shown in Table 11.2.4.
Table 11.2.3: Test parameters for E-AGCH detection (1.28 Mcps TDD option)
Parameters
Unit
Test 1
Ioc
dBm/1.28 MHz
-60
dB
-3
Number of Interfering codes/timeslot
-
2 × SF16
Total bits in Timeslot Resource Related Information (TRRI)
bits
5
Total bits in Resource Duration Indicator (RDI)
bits
3
Total bits in E-AGCH
bits
26
Propagation condition
-
VA30
Table 11.2.4: Test requirements for E-AGCH detection (1.28 Mcps TDD option)
Test Number
Îor/Ioc (dB)
Missed Detection Probability
1
8
0.01 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.3 Test Purpose | The aim of the test is to verify that the missed detection probability of the E-AGCH channel does not exceed 0.01. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.1 Initial conditions | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.1.1 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 miss detection E-AGCH test as specified in table 11.2.1.
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.
5) The UE is switched on.
6) 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.
7) Switch on the fading simulator. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.1.2 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 miss detection E-AGCH test as specified in 11.2.3 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 UE is switched on.
6) 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.
7) Switch on the fading simulator. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.1.3 7.68Mcps 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 miss detection E-AGCH test as specified in table 11.2.1.
3) The UL Reference Measurement Channel parameters are defined in Annex C.6.1.3 and DL Reference Measurement Channel parameters are defined in Annex C4.2A.1.1
4) The value of TRRI shall be set to ‘111111’ and CRRI on E-AGCH shall be set to 31.
5) The UE is switched on.
6) 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.
7) Switch on the fading simulator. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.2 Procedure | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.2.1 3.84Mcps TDD Option | 1) The SS shall signal 100% ACK on the E-HICH for all processes.
2) The SS shall signal the PRRI according to the E-AGCH information sequence as defined in Table 11.2.4.6A.
3) The SS shall analyse the E-TFCI transmitted on the E-UCCH for each E-DCH TTI to determine if a missed detection event has occurred by correlating the detected E-TFCIs with the expected E-TFCIs corresponding to the PRRI sent on E-AGCH when the TRRI and CRRI is constant. If the expected E-TFC is not detected by the SS, record a missed detection event.
4) The test shall be run such that statistical significance according to Annex F.6.4 is achieved. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.2.2 1.28Mcps TDD Option | 1) The SS shall signal 100% ACK on the E-HICH for all processes.
2) The SS shall signal the PRRI according to the E-AGCH information sequence as defined in Table 11.2.4.7.
3) The SS shall analyse the E-TFCI transmitted on the E-UCCH for each E-DCH TTI to determine if a missed detection event has occurred by correlating the detected E-TFCIs with the expected E-TFCIs corresponding to the PRRI sent on E-AGCH when the TRRI and CRRI is constant. If the expected E-TFC is not detected by the SS, record a missed detection event.
4) The test shall be run such that statistical significance according to Annex F.6.4 is achieved |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.4.2.3 7.68Mcps TDD Option | 1) The SS shall signal 100% ACK on the E-HICH for all processes.
2) The SS shall signal the PRRI according to the E-AGCH information sequence as defined in Table 11.2.4.9.
3) The SS shall analyse the E-TFCI transmitted on the E-UCCH for each E-DCH TTI to determine if a missed detection event has occurred by correlating the detected E-TFCIs with the expected E-TFCIs corresponding to the PRRI sent on E-AGCH when the TRRI and CRRI is constant. If the expected E-TFC is not detected by the SS, record a missed detection event.
4) The test shall be run such that statistical significance according to Annex F.6.4 is achieved |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.5 Test Requirements | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.5.1 3.84Mcps TDD Option | The missed detection probability shall not exceed to the values specified in Table 11. 2.4.6B for 3.84 Mcps TDD.
The missed detection probability = the ratio of (missed detection event)/ (all detected E-TFCI event) ≤ 0.01.
Tables 11.2.4.6A and 11.2.4.6B define the primary level settings including test tolerance and test parameters for the test.
Table 11.2.4.6A: Test parameters for E-AGCH detection
Parameter
Unit
Missed detection
PRRI
TBD
Table 11.2.4.6B: Test requirements for E-AGCH detection (3.84 Mcps TDD option)
Test Number
E-AGCH Î or /I oc (dB)
Missed Detection Probability
1
2.2
0.01 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.5.2 1.28Mcps TDD Option | The missed detection probability shall not exceed to the values specified in Table 11.2.4.8.
The missed detection probability = the ratio of (missed detection event)/ (all detected E-TFCI event) ≤ 0.01.
Tables 11.2.4.7 and 11.2.4.8 define the primary level settings including test tolerance and test parameters for the test.
Table 11.2.4.7: Test parameters for E-AGCH detection
Parameter
Unit
Missed detection
PRRI
TBD
Table 11.2.4.8 : Test requirements for E-AGCH detection ( 1.28 Mcps TDD option)
Test Number
E-AGCH Î or /I oc (dB)
Missed Detection Probability
1
8.6
0.01 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 11.2.5.3 7.68Mcps TDD Option | The missed detection probability shall not exceed to the values specified in Table 11. 2.4.9 for 7.68 Mcps TDD option.
The missed detection probability = the ratio of (missed detection event)/ (all detected E-TFCI event) ≤ 0.01.
Tables 11.2.4.9 and 11.2.4.10 define the primary level settings including test tolerance and test parameters for the test.
Table 11.2.4.9: Test parameters for E-AGCH detection
Parameter
Unit
Missed detection
PRRI
TBD
Table 11.2.4.10: Test requirements for E-AGCH detection ( 7.68 Mcps TDD option)
Test Number
E-AGCH Î or /I oc (dB)
Missed Detection Probability
1
1.8
0.01 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12 Performance requirement under multiple-cell scenario | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.1 General | The performance requirements for the UE in this clause is specified for the measurement channels specified in annex C and the propagation conditions specified in annex D. 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. For UEs with more than one receiver antenna connector the fading of the signals and the AWGN signals applied to each receiver antenna connector shall be uncorrelated. The levels of the test signal applied to each of the antenna connectors shall be as defined in the respective sections below.
Table 12.1: Summary of UE performance targets
Test Chs.
Information Data Rate
Performance metric
Static
Multi-path
Case 1
Multi-path Case 3
DCH
12.2 kbps
BLER<10-2
BLER<10-2
BLER<10-2
64 kbps
BLER<10-1
BLER<10-1
BLER<10-1
All Block Error ratio (BLER) measurements in clause 12 shall be performed according to the general rules for statistical testing in Annex F.6. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.1.2 Definition of Additive White Gaussian Noise (AWGN) Interferer | The minimum bandwidth of the AWGN interferer shall be 1.5 times chip rate of the radio access mode. (e.g. 5.76 MHz for a chip rate of 3,84 Mcps). The flatness across this minimum bandwidth shall be less than 0.5 dB and the peak to average ratio at a probability of 0.001% shall exceed 10 dB. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2 Demodulation of DCH in static propagation conditions | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.1 Definition and applicability | The performance requirement of DCH in static propagation conditions is determined by the maximum Block Error Ratio (BLER ). The BLER is specified for each individual data rate of the DCH. DCH is mapped into the Dedicated Physical Channel (DPCH).
The requirements and this test apply to all types of 1.28 Mcps TDD UE of Release 11 and later. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.2 Minimum requirements | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.2.1 3.84 Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.2.2 1.28 Mcps TDD Option | For the parameters specified in Table 12.2.2.2a and and Table 12.2.2.2b the BLER should not exceed the piece-wise linear BLER curve specified in Table 12.2.2.2c. The reference for this requirement is TS 25.102 [1] clause 12.2.1.2.
Table 12.2.2.2a: DCH parameters in static propagation conditions (12.2 kbps)
Parameters
Unit
Test 1
Test 2
Test 3
Number of DPCHo
4
12
28
Scrambling code and basic midamble code number of SS#1*
19
19
19
Scrambling code and basic midamble code number of SS#2*
58
58
58
Scrambling code and basic midamble code number of SS#3*
85
85
85
DPCH Channelization Codes of SS#1*
C(k,Q)
C(i,16)
i=1,2
C(i,16)
i=1,2
C(i,16)
i=1,2
DPCHo Channelization Codes of SS#2*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
DPCHo Channelization Codes of SS#3*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
of SS#2
dB
10
5
0
of SS#3
dB
4
-1
-6
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#2
chip
0
0
0
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#3
chip
0
0
0
Power of SS#2**
dBm
-67
-67.22
-68.54
Power of SS#3**
dBm
-73
-73.22
-74.54
Ioc
dBm/1,28MHz
-80
Midamble
Default midamble (Kcell = 8)
*Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code.
**Note: Power of SS can be calculated from and Ioc.
Table 12.2.2.2b: DCH parameters in static propagation conditions (64 kbps)
Parameters
Unit
Test 4
Test 5
Test 6
Number of DPCHo
4
12
28
Scrambling code and basic midamble code number of SS#1*
19
19
19
Scrambling code and basic midamble code number of SS#2*
58
58
58
Scrambling code and basic midamble code number of SS#3*
85
85
85
DPCH Channelization Codes of SS#1*
C(k,Q)
C(i,16)
1≤ i ≤8
C(i,16)
1≤ i ≤8
C(i,16)
1≤ i ≤8
DPCHo Channelization Codes of SS#2*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
DPCHo Channelization Codes of SS#3*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
of SS#2
dB
10
5
0
of SS#3
dB
4
-1
-6
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#2
chip
0
0
0
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#3
chip
0
0
0
Power of SS#2**
dBm
-67
-67.22
-68.54
Power of SS#3**
dBm
-73
-73.22
-74.54
Ioc
dBm/1,28MHz
-80
Midamble
Default midamble (Kcell = 8)
*Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code.
**Note: Power of SS can be calculated from and Ioc.
Table 12.2.2.2c: Minimum requirements in static propagation conditions
Test Number
[dB]
BLER
1
-0.3
10-2
2
2.8
10-2
3
8.7
10-2
4
4.1
10-1
5
10.7
10-1
6
12.9
10-1 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.2.3 7.68 Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.3 Test purpose | The test purpose is to verify the ability of the receiver to receive a predefined test signal ,representing a static propagation channel for the wanted and for the co-channel signals from serving and adjacent cells, with a block error ratio (BLER) not exceeding a specified value. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.4.1 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, AWGN Generator and additional components to the UE antenna connector as shown in figure A.19.
2) A call is set up according to the Generic call setup procedure. The characteristic of the call shall be according to the DL reference measurement channels (12,2 kbit/s) or (64 kbit/s) specified in annex C for 1.28Mcps TDD option.
3) Enter the UE into loopback test mode and start the loopback test. (test 1) and/or activate the Ack/Nack test mode.
4) The levels of the wanted signal and the co-channel signals are set according to Table 12.2.2.2a, Table 12.2.2.2b and Table 12.2.2.2c for the 1,28 Mcps TDD Option. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.4.2 Procedure | Measure the BLER of DCH received from the UE at the SS for all tests specified in Table 12.2.2.2a and Table 12.2.2.2b for 1,28 Mcps TDD Option. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.5 Test requirements | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.5.1 3.84Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.5.2 1.28Mcps TDD Option | The measured BLER shall not exceed the values indicated in table 12.2.5.2 for 1.28 Mcps TDD Option.
Table 12.2.5.2: Performance requirements in static propagation conditions
Test Number
[dB]
BLER
1
0.3
10-2
2
3.4
10-2
3
9.3
10-2
4
4.7
10-1
5
11.3
10-1
6
13.5
10-1
NOTE: If the Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.2.5.3 7.68Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3 Demodulation of DCH in Multipath fading Case 1 conditions | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.1 Definition and applicability | The performance requirement of DCH in Multipath fading Case 1 conditions is determined by the maximum Block Error Ratio (BLER). The BLER is specified for each individual data rate of the DCH. DCH is mapped into the Dedicated Physical Channel (DPCH).
The requirements and this test apply to all types of 1.28 Mcps TDD UE of Release 11 and later. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.2 Minimum requirements | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.2.1 3.84 Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.2.2 1.28 Mcps TDD Option | For the parameters specified in Table 12.3.2.2a and and Table 12.3.2.2b the BLER should not exceed the piece-wise linear BLER curve specified in Table 12.3.2.2c. The reference for this requirement is TS 25.102 [1] clause 12.3.1.2.
Table 12.3.2.2a: DCH parameters in Multipath fading Case 1 conditions (12.2 kbps)
Parameters
Unit
Test 1
Test 2
Test 3
Number of DPCHo
4
12
28
Scrambling code and basic midamble code number of SS#1*
19
19
19
Scrambling code and basic midamble code number of SS#2*
58
58
58
Scrambling code and basic midamble code number of SS#3*
85
85
85
DPCH Channelization Codes of SS#1*
C(k,Q)
C(i,16)
i=1,2
C(i,16)
i=1,2
C(i,16)
i=1,2
DPCHo Channelization Codes of SS#2*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
DPCHo Channelization Codes of SS#3*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
of SS#2
dB
10
5
0
of SS#3
dB
4
-1
-6
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#2
chip
0
0
0
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#3
chip
0
0
0
Power of SS#2**
dBm
-67
-67.22
-68.54
Power of SS#3**
dBm
-73
-73.22
-74.54
Ioc
dBm/1,28MHz
-80
Midamble
Default midamble (Kcell = 8)
*Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code.
**Note: Power of SS can be calculated from and Ioc.
Table 12.3.2.2b: DCH parameters in Multipath fading Case 1 conditions (64 kbps)
Parameters
Unit
Test 4
Test 5
Test 6
Number of DPCHo
4
12
28
Scrambling code and basic midamble code number of SS#1*
19
19
19
Scrambling code and basic midamble code number of SS#2*
58
58
58
Scrambling code and basic midamble code number of SS#3*
85
85
85
DPCH Channelization Codes of SS#1*
C(k,Q)
C(i,16)
1≤ i ≤8
C(i,16)
1≤ i ≤8
C(i,16)
1≤ i ≤8
DPCHo Channelization Codes of SS#2*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
DPCHo Channelization Codes of SS#3*
C(k,Q)
C(i,16)
1≤ i ≤2
C(i,16)
1≤ i ≤6
C(i,16)
1≤ i ≤14
of SS#2
dB
10
5
0
of SS#3
dB
4
-1
-6
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#2
chip
0
0
0
SFN-SFN Observed Timing Difference Type 2 between SS#1 and SS#3
chip
0
0
0
Power of SS#2**
dBm
-67
-67.22
-68.54
Power of SS#3**
dBm
-73
-73.22
-74.54
Ioc
dBm/1,28MHz
-80
Midamble
Default midamble (Kcell = 8)
*Note: Refer to TS 25.223 for definition of channelization codes, scrambling code and basic midamble code.
**Note: Power of SS can be calculated from and Ioc.
Table 12.3.2.2c: Performance requirements in Multipath fading Case 1 conditions
Test Number
[dB]
BLER
1
11.8
10-2
2
15.2
10-2
3
19.5
10-2
4
13.3
10-1
5
18.4
10-1
6
21.1
10-1 |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.2.3 7.68 Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.3 Test purpose | The test purpose is to verify the ability of the receiver to receive a predefined test signal ,representing a static propagation channel for the wanted and for the co-channel signals from serving and adjacent cells, with a block error ratio (BLER) not exceeding a specified value. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.4 Method of test | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.4.1 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 the SS, the fading simulator, AWGN Generator and additional components to the UE antenna connector as shown in figure A.20.
2) A call is set up according to the Generic call setup procedure. The characteristic of the call shall be according to the DL reference measurement channels (12,2 kbit/s) or (64 kbit/s) specified in annex C for 1.28Mcps TDD option.
3) Enter the UE into loopback test mode and start the loopback test. (test 1) and/or activate the Ack/Nack test mode.
4) The levels of the wanted signal and the co-channel signals are set according to Table 12.3.2.2a, Table 12.3.2.2b and Table 12.3.2.2c for the 1,28 Mcps TDD Option. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.4.2 Procedure | Measure the BLER of DCH received from the UE at the SS for all tests specified in Table 12.3.2.2a and Table 12.3.2.2b for 1,28 Mcps TDD Option. |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.5 Test requirements | |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.5.1 3.84Mcps TDD Option | [FFS] |
40bd05ebf1e9d686c3dc55dd3e817398 | 34.122 | 12.3.5.2 1.28Mcps TDD Option | The measured BLER shall not exceed the values indicated in table 12.3.5.2 for 1.28 Mcps TDD Option.
Table 12.3.5.2: Performance requirements in static propagation conditions
Test Number
[dB]
BLER
1
13.0
10-2
2
16.4
10-2
3
20.7
10-2
4
14.5
10-1
5
19.6
10-1
6
22.3
10-1
NOTE: If the Test Requirement differs from the Minimum Requirement then the Test Tolerance applied for this test is non-zero. |
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