G.3A Statistical testing of Performance Requirements with throughput for CA/DC/LAA
36.521-13GPPEvolved Universal Terrestrial Radio Access (E-UTRA)Part 1: Conformance testingRadio transmission and receptionRelease 17TSUser Equipment (UE) conformance specification
G.3A.1 General
The minimum requirements for performance tests in fading conditions in clause 8 with respect to CA/DC are 70% of the maximum throughput. The minimum requirements in static conditions in clause 8 with respect to CA/DC are [TBD]. Statistical tests in static propagation conditions lead to a statistically justified number of samples (testtime) and a test limit. The fading conditions require a minimum test time, overriding the statistically justified test time. It can be found in Tables G.3A.5. The statistically justified test limit is also used for the tests under fading conditions. The throughput is measured on both carriers in parallel (unless otherwise stated). The test for both carriers need the same time. The sum of the CC’s throughput is compared against the limit, where the limit is the sum of the individual carrier’s limit.
G.3A.2 Mapping throughput to error ratio
G.2.2 applies separate for each CC
G.3A.3 Design of the test
The test is defined by the following design principles (see clause G.x, Theory….):
1. The standard concept is applied (not the early decision concept).
2. A second limit is introduced, defining the Bad DUT.
3. To decide the test pass:
– Supplier risk is applied based on the Bad DUT quality.
– To decide the test fails.
– Customer Risk is applied based on the specified DUT quality.
The test is defined by the following parameters:
1) Limit Error Ratio = 0.3.
(in case 70% throughput is tested , otherwise [TBD]).
2) Bad DUT factor M = 1.378 (selectivity) justification see: TS 34.121 Clause F.6.3.3.
(M = 1.378 is tied to 70% throughput, otherwise M is [TBD].)
3) Confidence level CL = 95% (for specified DUT and Bad DUT-quality).
G.3A.4 Pass Fail limit
Testing with the parameters from G.3A.3 (70% throughput, M = 1.378, CL95%): Apply 184 samples to the DUT per CC and count the errors for each CC. The test limit to pass for one CC is ≤ 66 errors, however this is not individually applicable for CA/DC.
Pass fail decision for one test point in CA/DC: The sum of the CC’s errors is compared against the test limit, where the test limit is the sum of the individual carrier’s test limit.
It is allowed to apply more samples, in parallel for all CCs, to the DUT (e.g. up to an integer number of frames).
In fading conditions it is necessary to apply more samples, in parallel for all CCs, to the DUT, as in fading conditions the minimum test time overrides the statistically justified test time.
When more samples are applied, decide against the ratio 66/184 = 0.3587.
Testing with parameters from G.3A.3 ([TBD]% throughput, M = [TBD], CL = 95%) is [TBD].
G.3A.5 Minimum test time
In contrast to G.3.5, where the minimum test time is derived from simulations, the test time here is selected without simulation utilising test time information from similar demodulation scenarios in non-CA test cases and while maintaining the reasonable testing time.
Note MNAS values in this clause may need to be changed in future if current MNAS values turn out to be too short for giving stable CA/DC throughput results.
Table G.3A.5-1: Minimum Test time FDD PDSCH Single Antenna Port Performance for CA (2DL CA)
|
Clause 8.2.1.1.1_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.2FDD (2×10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.42FDD (2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
3 |
R.42-3 FDD + R.42-2 FDD (15MHz+5MHz,full,QPSK,1/3) (1×2 Low) EVA5) |
50 000 |
55 556 |
Table G.3A.5-1A: Minimum Test time FDD PDSCH Single Antenna Port Performance for CA (3DL CA)
|
Clause 8.2.1.1.1_A.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42FDD (3×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.42FDD + R.42-3FDD (20+20+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
3 |
R.42FDD + R.2FDD (20+20+10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
4 |
R.42FDD + R.42-3FDD (20+15+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
5 |
R.42FDD + R.42-3FDD + R.2FDD (20+15+10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
6 |
R.42FDD + R.2FDD (20+10+10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
7 |
R.42-3FDD + R.2FDD (15+15+10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
8 |
R.42FDD + R.2FDD + R.42-2FDD (20+10+5 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
9 |
R.42FDD + R.42-3FDD + R.42-2FDD (20+15+5 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-1B: Minimum Test time FDD PDSCH Single Antenna Port Performance for CA (4DL CA)
|
Clause 8.2.1.1.1_A.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42FDD (4×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.2FDD + R.42FDD (10+20+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
3 |
R.2FDD + R.42FDD (10+10+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
4 |
R.42-2FDD + R.2FDD + R.42FDD (5+10+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
5 |
R.42-2FDD + R.2FDD + R.42FDD (5+10+10+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-1C: Minimum Test time FDD PDSCH Single Antenna Port Performance for CA (5DL CA)
|
Clause 8.2.1.1.1_A.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42FDD (5×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.42-3FDD + R.42FDD (15+4×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
3 |
R.2FDD + R.42FDD (10+4×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
4 |
R.2FDD + R.42FDD (2×10+3×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
5 |
R.42-2FDD + R.2FDD + R.42FDD (5+10+3×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
6 |
R.2FDD + R.42FDD (3×10+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
|
7 |
R.2FDD + R.42FDD (4×10+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-1D: Minimum Test time FDD PDSCH Single Antenna Port Performance for CA (6DL CA)
|
Clause 8.2.1.1.1_A.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42FDD (6×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-1E: Minimum Test time FDD PDSCH Single Antenna Port Performance for CA (7DL CA)
|
Clause 8.2.1.1.1_A.7 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42FDD (7×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-2: Minimum Test time FDD PDSCH Open Loop Spatial Multiplexing 2×2 (2DL CA)
|
Clause 8.2.1.3.1_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.11 FDD (2×10 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
2 |
R.30 FDD (2×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
3 |
R.11-2 FDD (2×5 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
4 |
FFS |
FFS |
FFS |
|
5 |
R.11-7 FDD + R.11-2 FDD (15MHz+5MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
Table G.3A.5-2A: Minimum Test time FDD PDSCH Open Loop Spatial Multiplexing 2×2 (3DL CA)
|
Clause 8.2.1.3.1_A.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30 FDD (3×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
2 |
R.30 FDD + R.11-7 FDD (20+20+15 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
3 |
R.30 FDD + R.11 FDD (20+20+10 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
4 |
R.30 FDD + R.11-7 FDD (20+15+15 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
5 |
R.30 FDD + R.11-7 FDD + R.11 FDD (20+15+10 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
6 |
R.30 FDD + R.11 FDD (20+10+10 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
7 |
R.11-7 FDD + R.11 FDD (15+15+10 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
8 |
R.30 FDD + R.11 FDD + R.11-2 FDD (20+10+5 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
9 |
R.30 FDD + R.11-7 FDD + R.11-2 FDD (20+15+5 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
Table G.3A.5-2B: Minimum Test time FDD PDSCH Open Loop Spatial Multiplexing 2×2 (4DL CA)
|
Clause 8.2.1.3.1_A.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30 FDD (4×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
2 |
R.11 FDD + R.30 FDD (10+20+20+20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
3 |
R.11 FDD + R.30 FDD (10+10+20+20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
4 |
R.11-2 FDD + R.11 FDD + R.30 FDD (5+10+20+20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
|
5 |
R.11-2 FDD + R.11 FDD + R.30 FDD (5+10+10+20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 |
10 000 |
11 112 |
Table G.3A.5-2C: Minimum Test time FDD PDSCH Open Loop Spatial Multiplexing 2×2 (5DL CA)
|
Clause 8.2.1.3.1_A.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30FDD (5×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
2 |
R.11-7FDD + R.30FDD (15+4×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
3 |
R.11FDD + R.30FDD (10+4×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
4 |
R.11FDD + R.30FDD (2×10+3×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
5 |
R.11-2FDD + R.11FDD + R.30FDD (5+10+3×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
6 |
R.11FDD + R.30FDD (3×10+2×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
7 |
R.11FDD + R.30FDD (4×10+20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
Table G.3A.5-2D: Minimum Test time FDD PDSCH Open Loop Spatial Multiplexing 2×2 (6DL CA)
|
Clause 8.2.1.3.1_A.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30FDD (6×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
Table G.3A.5-2E: Minimum Test time FDD PDSCH Open Loop Spatial Multiplexing 2×2 (7DL CA)
|
Clause 8.2.1.3.1_A.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30FDD (7×20 MHz,full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
Table G.3A.5-3: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (2DL CA)
|
Clause 8.2.1.4.2_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3 FDD (2×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.14FDD (2×10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
3 |
R.14-7 FDD + R.14-6 FDD (15MHz+5MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-3A: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (3DL CA)
|
Clause 8.2.1.4.2_A.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3 FDD (3×20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.14-3 FDD + R.14-7 FDD (20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
3 |
R.14-3 FDD + R.14 FDD (20+20+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
4 |
R.14-3 FDD + R.14-7 FDD (20+15+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
5 |
R.14-3 FDD + R.14-7 FDD + R.14 FDD (20+15+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
6 |
R.14-3 FDD + R.14 FDD (20+10+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
7 |
R.14-7 FDD + R.14 FDD (15+15+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
8 |
R.14-3 FDD + R.14 FDD + R.14-6 FDD (20+10+5 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
9 |
R.14-3 FDD + R.14-7 FDD + R.14-6 FDD (20+15+5 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
Table G.3A.5-3B: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (4DL CA)
|
Clause 8.2.1.4.2_A.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3 FDD (4×20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.14-3 FDD + R.14-7 FDD (20+20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
3 |
R.14-3 FDD + R.14 FDD (20+20+20+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
4 |
R.14-3 FDD + R.14-7 FDD (20+20+15+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
5 |
R.14-3 FDD + R.14-7 FDD + R.14 FDD (20+20+15+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
6 |
R.14-3 FDD + R.14 FDD (20+20+10+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
7 |
R.14-3 FDD + R.14-7 FDD + R.14 FDD (20+15+15+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
8 |
R.14-3 FDD + R.14-7 FDD + R.14 FDD (20+15+10+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
9 |
R.14-3 FDD + R.14 FDD (20+10+10+10MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
10 |
R.14-7 FDD + R.14 FDD (15+15+15+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
11 |
R.14-3 FDD + R.14 FDD + R.14-6 FDD (20+20+10+5 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
12 |
R.14-6FDD + R.14 FDD + R.14-3 FDD (5+10+10+10+20MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
Table G.3A.5-3C: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (5DL CA)
|
Clause 8.2.1.4.2_A.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3 FDD (5×20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.14-7 FDD + R.14-3 FDD (15 + 4x20MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
3 |
R.14 FDD + R.14-3 FDD (10 + 4×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
4 |
R.14 FDD + R.14-3 FDD (2×10 + 3×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
5 |
R.14-6 FDD + R.14 FDD + R.14-3 FDD (5 + 10 + 3×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
6 |
R.14 FDD + R.14-3 FDD (3×10 + 2×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
|
7 |
R.14 FDD + R.14-3 FDD (4×10 + 20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
55 556 |
Table G.3A.5-3D: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (6DL CA)
|
Clause 8.2.1.4.2_A.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3 FDD (6×20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-3E: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (7DL CA)
|
Clause 8.2.1.4.2_A.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3 FDD (7×20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-4: Minimum Test time FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for Dual Connectivity
|
Clause 8.2.1.4.3A Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.14-3FDD (2×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
2 |
R.14-7FDD + R.14-3FDD (15+20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
3 |
R.14FDD + R.14-3FDD (10+20 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
4 |
R.14-7FDD (2×15 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
|
5 |
R.14FDD (2×10 MHz,full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
55 556 |
Table G.3A.5-4A: Void
Table G.3A.5-5: Void
Table G.3A.5-6: Minimum Test time TDD PDSCH Single Antenna Port Performance for CA (2DL CA)
|
Clause 8.2.2.1.1_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.42TDD (2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42TDD (20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
R.42-3 TDD (1×2 Low) EVA5 |
Table G.3A.5-6A: Minimum Test time TDD PDSCH Single Antenna Port Performance for CA (3DL CA)
|
Clause 8.2.2.1.1_A.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42TDD (3×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42TDD + R.42-3TDD (20+20+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-6B: Minimum Test time TDD PDSCH Single Antenna Port Performance for CA (4DL CA)
|
Clause 8.2.2.1.1_A.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42TDD (4×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42TDD + R.42-3TDD (20+20+20+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-6C: Minimum Test time TDD PDSCH Single Antenna Port Performance for CA (5DL CA)
|
Clause 8.2.2.1.1_A.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.42TDD (5×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42TDD + R.42-3TDD (20+20+20+20+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-7: Minimum Test time TDD PDSCH Open Loop Spatial Multiplexing 2×2 2DL CA
|
Clause 8.2.2.3.1_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.30-1 TDD (2×20 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
|
2 |
R.30-1 TDD (20 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
|
[TBD] (2×2 Low) EVA70 |
Table G.3A.5-7A: Minimum Test time TDD PDSCH Open Loop Spatial Multiplexing 2×2 3DL CA
|
Clause 8.2.2.3.1_A.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.30-1 TDD (3×20 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
|
2 |
R.30-1 TDD + R.11-9 TDD (20+20+15 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
Table G.3A.5-7B: Minimum Test time TDD PDSCH Open Loop Spatial Multiplexing 2×2 4DL CA
|
Clause 8.2.2.3.1_A.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.30-1 TDD (4×20 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
|
2 |
R.30-1 TDD + R.11-9 TDD (20+20+20+15 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
Table G.3A.5-7C: Minimum Test time TDD PDSCH Open Loop Spatial Multiplexing 2×2 5DL CA
|
Clause 8.2.2.3.1_A.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.30-1 TDD (5×20 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
|
2 |
R.30-1 TDD + R.11-9 TDD (20+20+20+20+15 MHz, full,16QAM,1/2) (2×2 Low) EVA70 |
10 000 |
20 000 |
Table G.3A.5-8: Minimum Test time TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 2DL CA
|
Clause 8.2.2.4.2_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.43TDD (2×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
|
2 |
R.43TDD (20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
|
R.43-5 TDD (15 MHz, full, 16QAM,1/2) (4×2 Low) EVA 5 |
Table G.3A.5-8A: Minimum Test time TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 3DL CA
|
Clause 8.2.2.4.2_A.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.43 TDD (3×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
|
2 |
R.43 TDD + R.43-5 TDD (20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
Table G.3A.5-8B: Minimum Test time TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 4DL CA
|
Clause 8.2.2.4.2_A.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.43 TDD (4×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
|
2 |
R.43 TDD + R.43-5 TDD (20+20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
Table G.3A.5-8C: Minimum Test time TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 5DL CA
|
Clause 8.2.2.4.2_A.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.43 TDD (5×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
|
2 |
R.43 TDD + R.43-5 TDD (20+20+20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
Table G.3A.5-9: Minimum Test time TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for Dual Connectivity
|
Clause 8.2.2.4.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.43 TDD (2×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
Table G.3A.5-10Void
Table G.3A.5-11: Minimum Test time TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 (intra band non-contiguous DL CA)
|
Clause 8.2.2.4.2_A.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.43TDD (2×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
100 000 |
Table G.3A.5-12: Minimum Test time FDD PDSCH Soft buffer management test (2 DL CA)
|
Clause 8.2.1.3.1A_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30 FDD (2×20 MHz, full 16QAM, 1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
2 |
R.35-2 FDD (15MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
10 000 |
12 500 |
|
R.35-3 FDD (10MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
|||
|
3 |
R.30 FDD (20 MHz, full 16QAM, 1/2) (2×2 Low) EVA70 |
10 000 |
11 112 |
|
R.11 FDD (10 MHz, full 16QAM, 1/2) (2×2 Low) EVA70 |
|||
|
4 |
R.30 FDD (20 MHz, full 16QAM, 1/2) (2×2 Low) EVA70 |
10 000 |
12 500 |
|
R.30-1 FDD (15 MHz, full 16QAM, 1/2) (2×2 Low) EVA70 |
|||
|
5 |
R.35-1 FDD (2×20 MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
10 000 |
12 500 |
|
6 |
R.35-1 FDD (20 MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
10 000 |
12 500 |
|
R.35-3 FDD (10MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
|||
|
7 |
R.35-1 FDD (20 MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
10 000 |
12 500 |
|
R.35-2 FDD (15MHz, full 64QAM, 0.39) (2×2 Low) EVA5 |
Table G.3A.5-14: Minimum Test time TDD PDSCH Soft buffer management test (2 DL CA)
|
Clause 8.2.2.3.1A_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.30-2 TDD (2×20 MHz,full,16QAM,1/3) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
2 |
R.35-1 TDD (2×20 MHz,full,64QAM,1/3) (2×2 Low) EVA5 |
10 000 |
50 000 |
Table G.3A.5-15: Minimum Test time TDD power imbalance test (2 DL CA)
|
Clause 8.2.2.7_A.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.49 TDD for PCC (20 MHz,full, 64QAM, 0.81-087) (1×2) OCNG for SCC |
10 000 in PCC |
20 000 |
|
2 |
OCNG for PCC R.49-1 TDD for SCC (15 MHz,full, 64QAM, 0.80-0.86) (1×2) |
10 000 in SCC |
20 000 |
Table G.3A.5-15A: Minimum Test time TDD Intra-band contiguous carrier aggregation with minimum channel spacing (2DL CA)
|
Clause 8.2.2.8.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.9 TDD for PCC and SCC (20 MHz,full, 64QAM, 3/4) (1×2 Low) EVA, 5 |
100 000 in PCC and SCC |
200 000 |
Table G.3A.5-15B: Minimum Test time TDD Intra-band contiguous carrier aggregation with minimum channel spacing (3DL CA)
|
Clause 8.2.2.8.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.9 TDD for PCC and SCC (20 MHz,full, 64QAM, 3/4) (1×2 Low) EVA, 5 |
100 000 in PCC and SCC |
200 000 |
Table G.3A.5-16: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for FDD Pcell (2DL CA)
|
Clause 8.2.3.1.1.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.2 FDD+R.42 TDD (20+10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
3 |
R.42-3 FDD+R.42 TDD (20+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-17: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for FDD PCell (3DL CA)
|
Clause 8.2.3.1.1.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42-3 FDD+R.42 TDD (15+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
3 |
R.2 FDD+R.42 TDD (10+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
4 |
R.42 FDD+R.42 TDD (2×20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
5 |
R.42-3 FDD+R.42 FDD+R.42 TDD (15+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
6 |
R.2 FDD+R.42 FDD +R.42 TDD (10+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-17a: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for FDD PCell (4DL CA)
|
Clause 8.2.3.1.1.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+3×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42 FDD+R.42 TDD (2×20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
3 |
R.42 FDD+R.42-3 FDD+ R.42 TDD (20+15+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
4 |
R.42-3 FDD+R.42 TDD (2×15+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
5 |
R.42 FDD +R.42-3 FDD+R.42 FDD+R.42 TDD (2×20+15+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
6 |
R.42 FDD+ R.42-3 FDD +R.42 TDD (2×15+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
7 |
R.42 FDD+ R.2 FDD +R.42 TDD (2×20+10+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-17b: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for FDD PCell (5DL CA)
|
Clause 8.2.3.1.1.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42-3 FDD+R.42 FDD+R.42 TDD (15+2×20+2x20MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42-3 FDD+R.42 FDD+R.42 TDD (2×15+20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-17c: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for FDD PCell (6DL CA)
|
Clause 8.2.3.1.1.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+5x20MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42 FDD+R.42 TDD (2×20+4×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-17d: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for FDD PCell (7DL CA)
|
Clause 8.2.3.1.1.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+6x20MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42 FDD+R.42 TDD (2×20+5×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-18: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for TDD Pcell (2DL CA)
|
Clause 8.2.3.1.2.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.2 FDD+R.42 TDD (20+10 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
3 |
R.42-3 FDD+R.42 TDD (20+15 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-19: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell(3DL CA)
|
Clause 8.2.3.1.2.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42-3 FDD+R.42 TDD (15+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
3 |
R.2 FDD+R.42 TDD (10+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
4 |
R.42 FDD+R.42 TDD (2×20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
5 |
R.42-3 FDD+R.42 FDD+R.42 TDD (15+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
6 |
R.2 FDD+R.42 FDD +R.42 TDD (10+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-19a: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell(4DL CA)
|
Clause 8.2.3.1.2.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+3×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42 FDD+R.42 TDD (2×20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
3 |
R.42 FDD+ R.42-3 FDD+ R.42 TDD (20+15+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
4 |
R.42-3 FDD+R.42 TDD (2×15+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
5 |
R.42 FDD + R.42-3 FDD+R.42 TDD (2×20+15+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
6 |
R.42-3 FDD+R.42 FDD +R.42 TDD (2×15+20+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
7 |
R.42 FDD+R.2 FDD +R.42 TDD (2×20+10+20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-19b: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell(5DL CA)
|
Clause 8.2.3.1.2.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42-3 FDD+ R.42 FDD+R.42 TDD (15+2×20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42-3 FDD+ R.42 FDD + R.42 TDD (2×15+20+2×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-19c: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell (6DL CA)
|
Clause 8.2.3.1.2.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+5×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42 FDD + R.42 TDD (2×20+4×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-19d: Minimum Test time TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell (7DL CA)
|
Clause 8.2.3.1.2.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.42 FDD+R.42 TDD (20+6×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
|
2 |
R.42 FDD + R.42 TDD (2×20+5×20 MHz,full,QPSK,1/3) (1×2 Low) EVA5 |
50 000 |
100 000 |
Table G.3A.5-20: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (2DL CA)
|
Clause 8.2.3.2.1.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.11 FDD + R.30-1 TDD (20+10 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
3 |
R.11-7 FDD + R.30-1 TDD (20+15 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-21: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (3DL CA)
|
Clause 8.2.3.2.1.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.11-7 FDD + R.30-1 TDD (15+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
3 |
R.11 FDD + R.30-1 TDD (10+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-21a: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (4DL CA)
|
Clause 8.2.3.2.1.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+3×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.30FDD + R.30-1 TDD (2×20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
3 |
R.30FDD +R.11-7 FDD + R.30-1 TDD (20+15+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
4 |
R.11-7 FDD + R.30FDD + R.30-1 TDD (2×15+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
5 |
R.30FDD +R.11-7 FDD + R.30-1 TDD (2×20+15+20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
6 |
R.11-7 FDD + R.30FDD +R.30-1 TDD (2×15+20+20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
7 |
R.30FDD +R.11 FDD + R.30-1 TDD (2×20+10+20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-21b: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (5DL CA)
|
Clause 8.2.3.2.1.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.11-7 FDD+R.30 FDD + R.30-1 TDD (15+2×20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.11-7 FDD+R.30FDD + R.30-1 TDD (2×15+20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-21c: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (6DL CA)
|
Clause 8.2.3.2.1.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (1×20+5×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.30FDD + R.30-1 TDD (2×20+4×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-21d: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (7DL CA)
|
Clause 8.2.3.2.1.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (1×20+6×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.30FDD + R.30-1 TDD (2×20+5×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-22: Minimum Test time TDD FDD CA Soft buffer management test for FDD PCell (2DL CA)
|
Clause 8.2.3.2.1A Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.35-1 FDD+ R.35-1 TDD (20+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
2 |
R.35-1 FDD+ R.35-1 TDD (20+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
3 |
R.35-3 FDD+ R.35-1 TDD (10+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
4 |
R.35-3 FDD+ R.35-1 TDD (10+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
5 |
R.35-2 FDD+ R.35-1 TDD (15+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
6 |
R.35-2 FDD+ R.35-1 TDD (15+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
Table G.3A.5-23: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (2DL CA)
|
Clause 8.2.3.2.2.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.11 FDD + R.30-1 TDD (20+10 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
3 |
R.11-7 FDD + R.30-1 TDD (20+15 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-24: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (3DL CA)
|
Clause 8.2.3.2.2.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.11-7 FDD + R.30-1 TDD (15+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
3 |
R.11 FDD + R.30-1 TDD (10+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-24a: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (4DL CA)
|
Clause 8.2.3.2.2.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+3×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.30 FDD + R.30-1 TDD (2×20+2x20MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
3 |
R.30FDD +R.11-7 FDD + R.30-1 TDD (20+15+2x20MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
4 |
R.11-7 FDD+ R.30FDD + R.30-1 TDD (2×15+2x20MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
5 |
R.30FDD +R.11-7 FDD + R.30-1 TDD (2×20+15+20MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
6 |
R.11-7 FDD+ R.30FDD+ R.30-1 TDD (2×15+20+20MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
7 |
R.30FDD +R.11 FDD + R.30-1 TDD (2×20+10+20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-24b: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (5DL CA)
|
Clause 8.2.3.2.2.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.11-7 FDD+R.30 FDD + R.30-1 TDD (15+2×20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.11-7 FDD+R.30FDD + R.30-1 TDD (2×15+20+2×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-24c: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (6DL CA)
|
Clause 8.2.3.2.2.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+5×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.30FDD + R.30-1 TDD (2×20+4×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-24d: Minimum Test time TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (7DL CA)
|
Clause 8.2.3.2.2.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.30 FDD + R.30-1 TDD (20+6×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
|
2 |
R.30FDD + R.30-1 TDD (2×20+5×20 MHz,full,QPSK,1/3) (2×2 Low) EVA70 |
10 000 |
25 000 |
Table G.3A.5-25: Minimum Test time TDD FDD CA PDSCH Soft buffer management test for TDD PCell (2DL CA)
|
Clause 8.2.3.2.2A Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in the measured CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.35-1 FDD+ R.35-1 TDD (20+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
2 |
R.35-1 FDD+ R.35-1 TDD (20+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
3 |
R.35-3 FDD+ R.35-1 TDD (10+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
4 |
R.35-3 FDD+ R.35-1 TDD (10+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
5 |
R.35-2 FDD+ R.35-1 TDD (15+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
|
6 |
R.35-2 FDD + R.35-1 TDD (15+20 MHz,full,64QAM,0.39) (2×2 Low) EVA70 |
10 000 |
50 000 |
Table G.3A.5-26: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for FDD PCell (2DL CA)
|
Clause 8.2.3.3.1.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.14-3 FDD + R.43TDD (2×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
2 |
R.14 FDD + R.43TDD (20+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
3 |
R.14-7 FDD + R.43 TDD (20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
Table G.3A.5-27: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for FDD PCell (3DL CA)
|
Clause 8.2.3.3.1.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.14-3 FDD + R.43TDD (3×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
2 |
R.14-7 FDD +R.43 TDD (20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
3 |
R.14 FDD +R.43 TDD (20+20+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
Table G.3A.5-27a: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for FDD PCell (4DL CA)
|
Clause 8.2.3.3.1.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-3 FDD+R.43 TDD (20+3×20 MHz, full,16QAM, 1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-3 FDD+R.43 TDD (2×20+2×20 MHz, full,16QAM, 1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
3 |
R.14-3FDD+ R.14-7FDD+R.43TDD (20+15+2×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
4 |
R.14-7 FDD+R.43 TDD (2×15+2×20 MHz, full,16QAM, 1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
5 |
R.14-3FDD +R.14-7FDD+R.43TDD (2×20+15+20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
6 |
R.14-7FDD+ R.14-3FDD+R.43TDD (2×15+20+20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
7 |
R.14-3 FDD+ R.14 FDD +R.43TDD (2×20+10+20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-27b: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for FDD PCell (5DL CA)
|
Clause 8.2.3.3.1.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-7 FDD+R.14-3FDD+R.43TDD (15+2×20+2x20MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-7 FDD+R.14-3FDD+R.43TDD (2×15+20+2×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-27c: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for FDD PCell (6DL CA)
|
Clause 8.2.3.3.1.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-3FDD+R.43TDD (20+5x20MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-3FDD+R.43TDD (2×20+4×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-27d: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for FDD PCell (7DL CA)
|
Clause 8.2.3.3.1.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-3FDD+R.43TDD (20+6x20MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-3FDD+R.43TDD (2×20+5×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-28: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for TDD PCell (2DL CA)
|
Clause 8.2.3.3.2.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.14-3 FDD + R.43TDD (2×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
2 |
R.14 FDD + R.43TDD (20+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
3 |
R.14-7 FDD + R.43TDD (15+20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
Table G.3A.5-29: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for TDD PCell (3DL CA)
|
Clause 8.2.3.3.2.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.14-3 FDD + R.43TDD (3×20 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
2 |
R.14 FDD + R.43TDD (20+20+15 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
|
3 |
R.14-7 FDD + R.43TDD (20+20+10 MHz,full,16QAM, 1/2) (4×2 Low) EVA 5 |
50 000 |
125 000 |
Table G.3A.5-29a: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for TDD PCell (4DL CA)
|
Clause 8.2.3.3.2.3 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.14-3 FDD+R.43 TDD (20+3×20 MHz, full,16QAM, 1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-3 FDD+R.43 TDD (2×20+2×20 MHz, full,16QAM, 1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
3 |
R.14-3FDD+ R.14-7FDD+R.43TDD (20+15+2×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
4 |
R.14-7 FDD+R.43 TDD (2×15+2×20 MHz, full,16QAM, 1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
5 |
R.14-3FDD +R.14-7FDD+R.43TDD (2×20+15+20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
6 |
R.14-7FDD+ R.14-3FDD+R.43TDD (2×15+20+20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
7 |
R.14-3 FDD+ R.14 FDD +R.43TDD (2×20+10+20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-29b: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for TDD PCell (5DL CA)
|
Clause 8.2.3.3.2.4 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-7 FDD+R.14-3FDD+R.43TDD (15+2×20+2x20MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-7 FDD+R.14-3FDD+R.43TDD (2×15+20+2×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-29c: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for TDD PCell (6DL CA)
|
Clause 8.2.3.3.2.5 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-3FDD+R.43TDD (20+5x20MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-3FDD+R.43TDD (2×20+4×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-29d: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for TDD PCell (7DL CA)
|
Clause 8.2.3.3.2.6 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
1 |
R.14-3FDD+R.43TDD (20+6x20MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
|
2 |
R.14-3FDD+R.43TDD (2×20+5×20 MHz, full,16QAM,1/2) (4×2 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-30: LAA Dual-Layer Spatial Multiplexing with DM-RS with FDD as Pcell
|
Clause 8.3.3.1.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD |
|||
|
1 |
R.30 FDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2-FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
2 |
R.30 FDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2-FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
3 |
R.30 FDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2-FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
4 |
R.30 FDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2-FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
NOTE 1: MNAS is not simulated, but estimated based on similar scenario in Table G.3A.5-16 Test1. NOTE 2: MNS for SCC is not deterministic due to the statistical burst transmission model in clause B.3.8. The average MNS is presented in this table. This is calculated based on an average burst length of 5.25 ms which in average takes 6.25 ms assuming UE not capable of partial subframes, and a simulated probability of LBT success (p) equal to 0.5 (ratio 6.25/5.25/0.5). |
|||
Table G.3A.5-30A: LAA Dual-Layer Spatial Multiplexing with DM-RS with TDD as Pcell
|
Clause 8.3.3.1.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD |
|||
|
1 |
R.30-1 TDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2 FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
2 |
R.30-1 TDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2 FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
3 |
R.30-1 TDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2 FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
4 |
R.30-1 TDD (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA70 + R.2 FS3 (1×20 MHz, full 16QAM, 1/2), (2×2 Low) EVA5 |
50,000 |
121,000 |
|
NOTE 1: MNAS is not simulated, but estimated based on similar scenario in Table G.3A.5-16 Test1. NOTE 2: MNS for SCC is not deterministic due to the statistical burst transmission model in clause B.3.8. The average MNS is presented in this table. This is calculated based on an average burst length of 5.25 ms which in average takes 6.25 ms assuming UE not capable of partial subframes, and a simulated probability of LBT success (p) equal to 0.5 (ratio 6.25/5.25/0.5). |
|||
Table G.3A.5-31: Minimum Test time LAA PDSCH CA Closed Loop Spatial Multiplexing Performance with 4Tx Antenna ports and with FDD as PCell (FDD Single Carrier)
|
Clause 8.2.4.1.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/FS3 |
|||
|
1 |
R.14-3 FDD + R.1 FS3 (20 MHz, full,16QAM, 1/2) + (20 MHz, full, 64QAM, 0.6) (4×2 Low) + (4×2 Low) EVA 5 + EVA5 |
50 000 |
300,000 |
|
NOTE 1: MNAS is not simulated, but estimated based on similar scenario in Table G.3A.5-xx Test1. NOTE 2: MNS for SCC is not deterministic due to the statistical burst transmission model in clause B.3.8. The average MNS is presented in this table. This is calculated based on an average burst length of 5.25 ms which in average takes 6.25 ms assuming UE not capable of partial subframes, and a simulated probability of LBT success (p) equal to 0.5 (ratio 6.25/5.25/0.5). |
|||
Table G.3A.5-32: Minimum Test time LAA PDSCH CA Closed Loop Spatial Multiplexing Performance with 4Tx Antenna ports and with TDD as PCell (TDD Single Carrier)
|
Clause 8.2.4.1.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
TDD/FS3 |
|||
|
1 |
R.43 TDD + R.1 FS3 (20 MHz, full,16QAM, 1/2) + (20 MHz, full, 64QAM, 0.6) (4×2 Low) + (4×2 Low) EVA 5 + EVA5 |
50 000 |
300 000 |
|
NOTE 1: MNAS is not simulated, but estimated based on similar scenario in Table G.3A.5-yy Test1. NOTE 2: MNS for SCC is not deterministic due to the statistical burst transmission model in clause B.3.8. The average MNS is presented in this table. This is calculated based on an average burst length of 5.25 ms which in average takes 6.25 ms assuming UE not capable of partial subframes, and a simulated probability of LBT success (p) equal to 0.5 (ratio 6.25/5.25/0.5). |
|||
Table G.3A.5-33: Minimum Test time for PDSCH Dual-layer Spatial Multiplexing for 4Rx (2DL CA – 5DL CA)
|
Clause 8.13.1.2.2-8.13.1.2.5/8.13.2.2.2-8.13.2.2.5/8.13.3.2.3-8.13.3.2.10 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
|
FDD |
TDD |
|||
|
All |
R.51 (5-20MHz, full, 16QAM,) (2×4 Low) ETU5 |
50000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
56 000 |
100 000 |
Table G.3.5A-34: Minimum Test time for PDSCH Closed Loop Multi Layer Spatial Multiplexing for 4Rx (2DL CA – 5DL CA)
|
Clause 8.13.1.1.1.2-8.13.1.1.1.5/8.13.2.1.1.2-8.13.2.1.1.5 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
|
FDD |
TDD |
|||
|
All |
R.43 (1.4-20MHz, full, 16QAM,) (4×4 Low) EVA5 |
50000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
Table G.3A.5-35: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×4 (2DL CA – 5DL CA)
|
Clause 8.13.3.1.1.2-8.13.3.1.1.5/ 8.13.3.1.2.2-8.13.3.1.2.5 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
All |
R.14 FDD + R.43 TDD (1.4-20MHz, full, 16QAM,) (4×4 Low) EVA5 |
50 000 |
125 000 |
Table G.3A.5-36: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×4 with 256QAM for FDD PCell (2DL CA)
|
Clause 8.13.3.6.1 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.72-3 FDD + R.72-3 TDD (2×20 MHz,full,256QAM, 0.62) (4×4 Low) EPA 5 |
50 000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
126 000 |
|
2 |
R.72 FDD + R.72-3 TDD (10 + 20MHz,full,256QAM, 0.62) (4×4 Low) EPA 5 |
50 000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
126 000 |
|
3 |
R.72-2 FDD + R.72-3 TDD (15 MHz,full,256QAM, 0.61) + (20 MHz,full,256QAM, 0.62) (4×4 Low) EPA 5 |
50 000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
126 000 |
Table G.3A.5-37: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×4 with 256QAM for TDD PCell (2DL CA)
|
Clause 8.13.3.6.2 Test No |
Demodulation scenario plain text: RMC (Bandwidth, allocated RBs, modulation, coding) Antenna (configuration, correlation) Propagation condition, Doppler [additional parameters, if applicable] (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
1 |
R.72-3 FDD + R.72-3 TDD (2×20 MHz,full,256QAM, 0.62) (4×4 Low) EPA 5 |
50 000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
126 000 |
|
2 |
R.72 FDD + R.72-3 TDD (10 + 20MHz,full,256QAM, 0.62) (4×4 Low) EPA 5 |
50 000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
126 000 |
|
3 |
R.72-2 FDD + R.72-3 TDD (15 MHz,full,256QAM, 0.61) + (20 MHz,full,256QAM, 0.62) (4×4 Low) EPA 5 |
50 000 Note: MNAS is not simulated. It is estimated based on other similar test cases using EPA5 propagation conditions |
126 000 |
Table G.3A.5-38: Minimum Test time for PDSCH Closed Loop Multi Layer Spatial Multiplexing with 256QAM (2DL CA)
|
Clause 8.13.1.1.3/ 8.13.2.1.3 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
|
FDD |
TDD |
|||
|
All |
R.72 (1.4-20MHz, full, 256QAM,) (4×4 Low) EPA5 |
50000 |
56 000 |
100 000 |
Table G.3A.5-39: Minimum Test time for PDSCH Closed Loop Four-Layer Spatial Multiplexing (2DL CA)
|
Clause 8.13.1.1.4/ 8.13.2.1.4 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
|
FDD |
TDD |
|||
|
All |
R.74 (1.4-20MHz, full, 16QAM,) (4×4 Low) EPA5 |
50000 |
56 000 |
100 000 |
Table G.3.5A-40: Minimum Test time for TDD-FDD CA PDSCH Closed Loop Single Layer Spatial Multiplexing 2×4 with TM4 Interference Model-Enhanced Performance Requirement Type A (2DL CA)
|
Clause 8.13.3.3.1/ 8.13.3.3.2 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
All |
R.47 FDD + R.47 TDD (5-20MHz, full, 16QAM) (2×4 Low) EVA5 |
50 000 |
125 000 |
Table G.3.5A-41: Minimum Test time for TDD-FDD CA PDSCH Single-layer Spatial Multiplexing 2×4 on antenna ports 7 or 8 with TM9 Interference Model-Enhanced Performance Requirement Type A (2DL CA)
|
Clause 8.13.3.4.1/ 8.13.3.4.2 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
All |
R.76 FDD + R.76 TDD (5-20MHz, full, QPSK) (2×4 Low) EVA5 |
50 000 |
125 000 |
Table G.3.5A-42: Minimum Test time for 4-Rx PDSCH Closed Loop Single Layer Spatial Multiplexing 2×4 with TM4 Interference Model – Enhanced Performance Type A(2DL CA)
|
Clause 8.13.1.3.1 8.13.2.3.1 Test No |
Demodulation scenario (info only) |
MNAS (Simulation) |
MNSF (Min No Sub Frames, mandatory) |
|
|
FDD |
TDD |
|||
|
1 |
R.47 (2×10 MHz, full, 16QAM, 1/3) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
2 |
R.47-3 (2×20 MHz, full, 16QAM, 1/3) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
3 |
R.47-1 (2×5 MHz, full, 16QAM, 1/3) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
4 |
R.47-2 + R.47-1 (15+5 MHz, full, 16QAM, 1/3) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
5 |
R.47 + R.47-1 (10+5 MHz, full, 16QAM, 1/3) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
Table G.3.5A-43: Minimum Test time for 4-Rx PDSCH Single-layer Spatial Multiplexing on antenna ports 7 or 8 with TM9 Interference Model – Enhanced Performance Type A(2DL CA)
|
Clause 8.13.1.4.1 8.13.2.4.1 Test No |
Demodulation scenario (info only) |
MNAS (Simulation) |
MNSF (Min No Sub Frames, mandatory) |
|
|
FDD |
TDD |
|||
|
1 |
R.76 + R76-5 (2×10 MHz, full, QPSK, 1/2) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
2 |
R.76-3+ R.76-7 (2×20 MHz, full, QPSK, 1/2) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
3 |
R.76-1+ R.76-4 (2×5 MHz, full, QPSK, 1/2) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
4 |
R.76-2+R.76-6+ R.76-1+R.76-4 (15+5 MHz, full, QPSK, 1/2) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
|
5 |
R.76+R.76-5+ R.76-1+R.76-4 (10+5 MHz, full, QPSK, 1/2) (2×2+ 2×4 Low) EVA5 |
Note: MNAS is not simulated. It is estimated based on other similar test cases using EVA5 propagation conditions |
56 000 |
100 000 |
Table G.3A.5-44: Minimum Test time TDD FDD CA PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×4 (2DL CA)
|
Clause 8.13.7.1/ 8.13.7.2 Test No |
Demodulation scenario (info only) |
Minimum Number of Active Subframes in each CC |
Minimum Number of Subframes (MNS) in each CC (MNS = active and inactive subframes) |
|
FDD/TDD |
|||
|
All |
R.74 (1.4-20MHz, full, 16QAM,) (4×4 Low) EPA5 |
50 000 |
125 000 |
G.3A.6 Test conditions
Table G.3A.6-1: Test conditions for CA/DC performance tests
|
Test |
Statistical independence |
Number of components in the test vector, as specified in the test requirements and initial conditions of the applicable test |
Over all Pass/Fail condition |
|
8.2.1.1.1_A.1 FDD PDSCH Single Antenna Port Performance for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.1.1_A.2 FDD PDSCH Single Antenna Port Performance for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.1.1_A.4 FDD PDSCH Single Antenna Port Performance for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.1.1_A.5 FDD PDSCH Single Antenna Port Performance for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.1.1_A.6 FDD PDSCH Single Antenna Port Performance for CA (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.1.1_A.7 FDD PDSCH Single Antenna Port Performance for CA (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1_A.1 FDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1_A.2 FDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1_A.3 FDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1_A.4 FDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1_A.5 FDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1_A.6 FDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.3.1A_A.1 FDD PDSCH Soft buffer management test for CA (2 DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.2_A.1 FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4 x 2 for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.2_A.2 FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4 x 2 for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.2_A.3 FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4 x 2 for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.2_A.4 FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4 x 2 for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.2_A.5 FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for CA (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.2_A.6 FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for CA (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.1.4.3A FDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for Dual Connectivity |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.1.1_A.1 TDD PDSCH Single Antenna Port Performance for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.1.1_A.2 TDD PDSCH Single Antenna Port Performance for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.1.1_A.3 TDD PDSCH Single Antenna Port Performance for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.1.1_A.4 TDD PDSCH Single Antenna Port Performance for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.3.1_A.1 TDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.3.1_A.2 TDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.3.1_A.3 TDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.3.1_A.4 TDD PDSCH Open Loop Spatial Multiplexing 2×2 for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.3.1A_A.1 TDD PDSCH Soft buffer management test (2 DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.4.2_A.1 TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.4.2_A.2 TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.4.2_A.3 TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.4.2_A.4 TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.2.4.4 TDD PDSCH Closed Loop Multi Layer Spatial Multiplexing 4×2 for Dual Connectivity |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.1.1.5 TDD FDD CA PDSCH Single Antenna Port Performance for FDD PCell (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.1.2.5 TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.1.2.6 TDD FDD CA PDSCH Single Antenna Port Performance for TDD PCell (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.2.1.5 TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.2.1.6 TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for FDD PCell (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.2.2.1 TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.2.2.2 TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.2.2.5 TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.2.2.6 TDD FDD CA PDSCH Open Loop Spatial Multiplexing 2×2 for TDD PCell (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.3.1.5 TDD FDD CA PDSCH Closed Loop Multi Lyaer Spatial Multiplexing 4×2 for FDD PCell (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.3.1.6 TDD FDD CA PDSCH Closed Loop Multi Lyaer Spatial Multiplexing 4×2 for FDD PCell (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.3.2.5 TDD FDD CA PDSCH Closed Loop Multi Lyaer Spatial Multiplexing 4×2 for TDD PCell (6DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.2.3.3.2.6 TDD FDD CA PDSCH Closed Loop Multi Lyaer Spatial Multiplexing 4×2 for TDD PCell (7DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.3.3.1.1 LAA Dual-Layer Spatial Multiplexing with DM-RS with FDD as Pcell |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.3.3.1.2 LAA Dual-Layer Spatial Multiplexing with DM-RS with TDD as Pcell |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.1.1_A.1 FDD Sustained data rate performance for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.1.1_A.2 FDD Sustained data rate performance for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.1.1_A.4 FDD Sustained data rate performance for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.2.1_A.1 TDD Sustained data rate performance for CA (2DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.2.1_A.2 TDD Sustained data rate performance for CA (3DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.2.1_A.4 TDD Sustained data rate performance for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
8.7.2.1_A.5 TDD Sustained data rate performance for CA (5DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |
|
9.6.1.1_A.3 FDD CQI Reporting under AWGN conditions – PUCCH 1-0 for CA (4DL CA) |
subframes are independent |
1 |
To pass the test case all applicable components in the test vector must pass |