F.1 Measurement uncertainties and test tolerances for FR1
38.521-43GPPNRPart 4: PerformanceRadio transmission and receptionRelease 17TSUser Equipment (UE) conformance specification
F.1.1 Acceptable uncertainty of test system (normative)
The maximum acceptable uncertainty of the Test System is specified below for each test, where appropriate. The Test System shall enable the stimulus signals in the test case to be adjusted to within the specified range, and the equipment under test to be measured with an uncertainty not exceeding the specified values. All ranges and uncertainties are absolute values, and are valid for a confidence level of 95 %, unless otherwise stated.
A confidence level of 95 % is the measurement uncertainty tolerance interval for a specific measurement that contains 95 % of the performance of a population of test equipment.
For RF tests it should be noted that the uncertainties in clause F.1 apply to the Test System operating into a nominal 50 ohm load and do not include system effects due to mismatch between the DUT and the Test System.
The downlink signal uncertainties apply at each receiver antenna connector.
F.1.1.1 Measurement of test environments
The measurement accuracy of the UE test environments defined in TS 38.508-1 [5] subclause 4.1, Test environments shall be
– Pressure 5 kPa.
– Temperature 2 degrees.
– Relative Humidity 5 %.
– DC Voltage 1,0 %.
– AC Voltage 1,5 %.
– Vibration 10 %.
– Vibration frequency 0,1 Hz.
The above values shall apply unless the test environment is otherwise controlled and the specification for the control of the test environment specifies the uncertainty for the parameter.
F.1.1.2 Measurement of Demod Performance requirements
This clause defines the maximum test system uncertainty for Demod Performance requirements. The maximum test system uncertainty allowed for the measurement uncertainty contributors are defined in Table F.1.1.2-1.
Table F.1.1.2-1: Maximum measurement uncertainty values for the test system for FR1 (up to 6 GHz) and Channel BW ≤ 40 MHz
|
MU contributor |
Unit |
Value |
Comment |
|---|---|---|---|
|
AWGN flatness and signal flatness, max deviation for any Resource Block, relative to average over BWconfig |
dB |
±2.0 |
Same as in LTE |
|
Signal to noise ratio uncertainty |
dB |
±0.3 |
Same as in LTE |
|
Signal to noise ratio variation |
dB |
±0.5 |
Same as in LTE |
|
Fading profile power uncertainty for 1Tx |
dB |
±0.5 |
Same as in LTE |
|
Fading profile power uncertainty for 2Tx |
dB |
±0.7 |
Same as in LTE |
|
Fading profile power uncertainty for 4Tx |
dB |
±0.7 |
Same as in LTE |
The maximum test system uncertainty for test cases defined in section 5 is defined in Table F.1.1.2-2.
Table F.1.1.2-2: Maximum test system uncertainty for FR1 demodulation performance test cases
|
Subclause |
Maximum Test System Uncertainty |
Derivation of Test System Uncertainty |
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|
5.2.2.1.1_1 2Rx FDD FR1 PDSCH mapping Type A performance – 2×2 MIMO with baseline receiver for both SA and NSA |
± 0.9 dB for > 10Hz doppler ± 1 dB for 10Hz doppler ± 0.6 dB for test 1-6 ± 0.9 dB for test 1-7 |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty 2. Fading profile power uncertainty 3. Effect of AWGN flatness and signal flatness 4. SNR uncertainty due to finite test time Items 1, 2, 3 and 4 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2) + SNR uncertainty due to finite test time2 Signal-to-noise ratio uncertainty ±0.3 dB Fading profile power uncertainty ±0.7 dB for 2Tx AWGN flatness and signal flatness ±2.0 dB SNR uncertainty due to finite test time ±0.3 dB for 10Hz Doppler, otherwise ±0.0 dB For test point 1-6, Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time2) = 0.6 dB For test point 1-7, Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time2) = 0.9 dB |
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|
5.2.2.1.1_2 2Rx FDD FR1 PDSCH Mapping Type A performance – 2×2 MIMO with enhanced receiver type X for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.2_1 2Rx FDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.3_1 2Rx FDD FR1 PDSCH mapping Type B performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.4_1 2Rx FDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.5_1 2Rx FDD FR1 PDSCH 0.001% BLER performance – 1×2 MIMO with baseline receiver for both SA and NSA |
[± 0.6 dB] |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty 2. Effect of AWGN flatness and signal flatness Items 1 and 2 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2) Signal-to-noise ratio uncertainty ±0.3 dB AWGN flatness and signal flatness ±2.0 dB |
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|
5.2.2.1.6_1 2Rx FDD FR1 PDSCH repetitions over multiple slots performance – 2×2 MIMO with baseline receiver for both SA and NSA |
[0.7dB] |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty 2. Effect of AWGN flatness and signal flatness 3. SNR uncertainty due to finite test time Items 1, 2 and 3 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2+ SNR uncertainty due to finite test time2) Signal-to-noise ratio uncertainty ±0.3 dB AWGN flatness and signal flatness ±2.0 dB SNR uncertainty due to finite test time ±[0.4] dB for 1% residual BLER |
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|
5.2.2.1.7_1 2Rx FDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.8_1 2Rx FDD FR1 PDSCH pre-emption performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.9_1 2Rx FDD FR1 HST-SFN performance – 2×2 MIMO with baseline receiver for both SA and NSA |
± 0.6 dB |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty, ±0.3 dB 2. Effect of AWGN flatness and signal flatness, ±2.0 dB 3. SNR uncertainty due to finite test time, ±0.0 dB for >10Hz Doppler. Items 1, 2, 3 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time2) = 0.6 dB |
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|
5.2.2.1.10_1 2Rx FDD FR1 HST-DPS performance – 2×2 MIMO with baseline receiver for both SA and NSA |
± 0.6 dB |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty, ±0.3 dB 2. Effect of AWGN flatness and signal flatness, ±2.0 dB 3. SNR uncertainty due to finite test time, ±0.0 dB for >10Hz Doppler. Items 1, 2, 3 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time2) = 0.6 dB |
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|
5.2.2.1.11_1 2Rx FDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.12_1 2Rx FDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.13_1 2Rx FDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.1.14_1 2Rx FDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.6_1 |
Same as 5.2.2.1.6_1 |
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|
5.2.2.2.1_1 2Rx TDD FR1 PDSCH mapping Type A performance – 2×2 MIMO with baseline receiver for both SA and NSA |
± 0.9 dB for test 1-10 ± 0.6 dB for test 1-11 For other TPs, same as 5.2.2.1.1_1 |
For test point 1-10, Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time2) = 0.9 dB For test point 1-11, Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time2) = 0.6 dB For other TPs, same as 5.2.2.1.1_1 |
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|
5.2.2.2.1_2 2Rx TDD FR1 PDSCH Mapping Type A performance – 2×2 MIMO with enhanced receiver type X for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.2_1 2Rx TDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.3_1 2Rx TDD FR1 PDSCH mapping Type B performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.4_1 2Rx TDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.5_1 2Rx TDD FR1 PDSCH 0.001% BLER performance – 1×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.5_1 |
Same as 5.2.2.1.5_1 |
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|
5.2.2.2.6_1 2Rx TDD FR1 PDSCH repetitions over multiple slots performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.6_1 |
Same as 5.2.2.1.6_1 |
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|
5.2.2.2.7_1 2Rx TDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.8_1 2Rx TDD FR1 PDSCH pre-emption performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.9_1 2Rx TDD FR1 HST-SFN performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.9_1 |
Same as 5.2.2.1.9_1 |
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|
5.2.2.2.10_1 2Rx TDD FR1 HST-DPS performance – 2×2 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.10_1 |
Same as 5.2.2.1.10_1 |
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|
5.2.2.2.11_1 2Rx TDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.12_1 2Rx TDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
|||||||||
|
5.2.2.2.13_1 2Rx TDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2.2.2.14_1 2Rx TDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.2.1.6_1 |
Same as 5.2.2.1.6_1 |
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|
5.2.3.1.1_1 4Rx FDD FR1 PDSCH mapping Type A performance – 2×4 MIMO with baseline receiver for both SA and NSA |
± 0.9 dB for > 10Hz doppler ± 1.0 dB for 10Hz doppler |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty 2. Fading profile power uncertainty 3. Effect of AWGN flatness and signal flatness 4. SNR uncertainty due to finite test time Items 1, 2, 3 and 4 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2 + SNR uncertainty due to finite test time 2) Signal-to-noise ratio uncertainty ±0.3 dB Fading profile power uncertainty ±0.7 dB for 2Tx AWGN flatness and signal flatness ±2.0 dB SNR uncertainty due to finite test time ±0.3 dB for 10Hz Doppler, otherwise ±0.0 dB |
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|
5.2.3.1.1_2 4Rx FDD FR1 PDSCH mapping Type A performance – 4×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.1_4 4Rx FDD FR1 PDSCH mapping Type A performance – 4×4 MIMO with enhanced receiver type 1 for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.2_1 4Rx FDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 4×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.3_1 4Rx FDD FR1 PDSCH mapping Type B performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.4_1 4Rx FDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.5_1 4Rx FDD FR1 PDSCH 0.001% BLER performance – 1×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.5_1 |
Same as 5.2.2.1.5_1 |
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|
5.2.3.1.6_1 4Rx FDD FR1 PDSCH repetitions over multiple slots performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.6_1 |
Same as 5.2.2.1.6_1 |
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|
5.2.3.1.7_1 4Rx FDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.8_1 4Rx FDD FR1 PDSCH pre-emption performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.9_1 4Rx FDD FR1 HST-SFN performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.9_1 |
Same as 5.2.2.1.9_1 |
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|
5.2.3.1.10_1 4Rx FDD FR1 HST-DPS performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.10_1 |
Same as 5.2.2.1.10_1 |
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|
5.2.3.1.11_1 4Rx FDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×4 MIMO for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.12_1 4Rx FDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×4 MIMO for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.13_1 4Rx FDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×4 MIMO for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.1.14_1 4Rx FDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×4 MIMO for both SA and NSA |
Same as 5.2.3.1.6_1 |
Same as 5.2.3.1.6_1 |
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|
5.2.3.2.1_1 4Rx TDD FR1 PDSCH mapping Type A performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.1_2 4Rx TDD FR1 PDSCH mapping Type A performance – 4×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.1_4 4Rx TDD FR1 PDSCH mapping Type A performance – 4×4 MIMO with enhanced receiver type 1 for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.2_1 4Rx TDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.3_1 4Rx TDD FR1 PDSCH mapping Type B performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.4_1 4Rx TDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.5_1 4Rx TDD FR1 PDSCH 0.001% BLER performance – 1×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.5_1 |
Same as 5.2.2.1.5_1 |
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|
5.2.3.2.6_1 4Rx TDD FR1 PDSCH repetitions over multiple slots performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.2.1.6_1 |
Same as 5.2.2.1.6_1 |
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|
5.2.3.2.7_1 4Rx TDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.9_1 4Rx TDD FR1 HST-SFN performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.9_1 |
Same as 5.2.3.1.9_1 |
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|
5.2.3.2.10_1 4Rx TDD FR1 HST DPS performance – 2×4 MIMO with baseline receiver for both SA and NSA |
Same as 5.2.3.1.10_1 |
5.2.3.1.10_1 |
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|
5.2.3.2.11_1 4Rx TDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.12_1 4Rx TDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.13_1 4Rx TDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2.3.2.14_1 4Rx TDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×2 MIMO for both SA and NSA |
Same as 5.2.3.1.6_1 |
Same as 5.2.3.1.6_1 |
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|
5.2A.2.1.1 2Rx Normal PDSCH Demodulation Performance for CA (2DL CA) |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2A.2.1.2 2Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2A.2.1.3 2Rx Normal PDSCH Demodulation Performance for CA (4DL CA) |
Same as 5.2.2.1.1_1 |
Same as 5.2.2.1.1_1 |
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|
5.2A.2.2.1 2Rx PDSCH Demodulation Performance for CA with power imbalance (2DL CA) |
±0.7 dB, f ≤ 3.0GHz ±1.0 dB, 3.0GHz < f ≤ 4.2GHz ±1.5 dB, 4.2GHz < f ≤ 6GHz Downlink EVM ≤ 6% |
6% EVM is equivalent to a Test system downlink SNR of 24.4dB. The noise from the Test system is then sufficiently below that required for the UE to demodulate the signal with the required % success rate. Under these conditions the UE throughput is limited by the Reference measurement channel and the UE capability, and not by the Test system EVM. |
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|
5.2A.2.5.1 2RX PDSCH Demodulation Performance for HST-DPS CA |
Same as 5.2.2.1.10_1 |
Same as 5.2.2.1.10_1 |
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|
5.2A.3.1.1 4Rx Normal PDSCH Demodulation Performance for CA (2DL CA) |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2A.3.1.2 4Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2A.3.1.3 4Rx Normal PDSCH Demodulation Performance for CA (4DL CA) |
Same as 5.2.3.1.1_1 |
Same as 5.2.3.1.1_1 |
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|
5.2A.3A.1.1 2Rx-4Rx Normal PDSCH Demodulation Performance for CA (2DL CA) |
Same as 5.2.2.1.1_1 for 2Rx CC and 5.2.3.1.1_1 for 4Rx CC |
Same as 5.2.2.1.1_1 for 2Rx CC and 5.2.3.1.1_1 for 4Rx CC |
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|
5.2A.3A.1.2 2Rx-4Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
Same as 5.2.2.1.1_1 for 2Rx CC and 5.2.3.1.1_1 for 4Rx CC |
Same as 5.2.2.1.1_1 for 2Rx CC and 5.2.3.1.1_1 for 4Rx CC |
|||||||||
|
5.2A.3A.1.3 2Rx-4Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
Same as 5.2.2.1.1_1 for 2Rx CC and 5.2.3.1.1_1 for 4Rx CC |
Same as 5.2.2.1.1_1 for 2Rx CC and 5.2.3.1.1_1 for 4Rx CC |
|||||||||
|
5.3.2.1.1 2Rx FDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
± 0.9 dB |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty 2. Fading profile power uncertainty 3. Effect of AWGN flatness and signal flatness 4. SNR uncertainty due to finite test time Items 1, 2, 3 and 4 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2+ SNR uncertainty due to finite test time2) Signal-to-noise ratio uncertainty ±0.3 dB Fading profile power uncertainty ±0.5 dB for 1Tx AWGN flatness and signal flatness ±2.0 dB SNR uncertainty due to finite test time ±0.4 dB |
|||||||||
|
5.3.2.1.2 2Rx FDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
± 1.0 dB |
Overall system uncertainty for fading conditions comprises four quantities: 1. Signal-to-noise ratio uncertainty 2. Fading profile power uncertainty 3. Effect of AWGN flatness and signal flatness 4. SNR uncertainty due to finite test time Items 1, 2, 3 and 4 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2+ SNR uncertainty due to finite test time2) Signal-to-noise ratio uncertainty ±0.3 dB Fading profile power uncertainty ±0.7 dB for 2 Tx AWGN flatness and signal flatness ±2.0 dB SNR uncertainty due to finite test time ±0.4 dB |
|||||||||
|
5.3.2.1.3 2Rx FDD FR1 PDCCH 1 Tx antenna performance for power saving |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.3.2.2.1 2Rx TDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.3.2.2.2 2Rx TDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
Same as 5.3.2.1.2 |
Same as 5.3.2.1.2 |
|||||||||
|
5.3.2.2.3 2Rx TDD FR1 PDCCH 1 Tx antenna performance for power saving |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.3.3.1.1 4Rx FDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.3.3.1.2 4Rx FDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
Same as 5.3.2.1.2 |
Same as 5.3.2.1.2 |
|||||||||
|
5.3.3.1.3 4Rx FDD FR1 PDCCH 1 Tx antenna performance for power saving |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.3.3.2.1 4Rx TDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.3.3.2.2 4Rx TDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
Same as 5.3.2.1.2 |
Same as 5.3.2.1.2 |
|||||||||
|
5.3.3.2.3 4Rx TDD FR1 PDCCH 1 Tx antenna performance for power saving |
Same as 5.3.2.1.1 |
Same as 5.3.2.1.1 |
|||||||||
|
5.5.1 FR1 Sustained downlink data rate performance for single carrier |
±0.7 dB, f ≤ 3.0GHz ±1.0 dB, 3.0GHz < f ≤ 4.2GHz ±1.5 dB, 4.2GHz < f ≤ 6GHz Downlink EVM ≤ 3% |
3% EVM is equivalent to a Test system downlink SNR of 30.5dB. The noise from the Test system is then sufficiently below that required for the UE to demodulate the signal with the required % success rate. Under these conditions the UE throughput is limited by the Reference measurement channel and the UE capability, and not by the Test system EVM. |
|||||||||
|
9.4B.1.1 Sustained downlink data rate performance for EN-DC within FR1 |
E-UTRA CC: ±0.7 dB, f ≤ 3.0GHz ±1.0 dB, 3.0GHz < f ≤ 4.2GHz NR CC: Same as 5.5.1 |
Same as 5.5.1 |
|||||||||
|
11.1.2.1.1_1 2Rx FR1 PSSCH performance – single active PSSCH link |
± 0.8 dB |
Overall system uncertainty for fading conditions comprises three quantities: 1. Signal-to-noise ratio uncertainty 2. Fading profile power uncertainty 3. Effect of AWGN flatness and signal flatness Items 1, 2 and 3 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2) Signal-to-noise ratio uncertainty ±0.3 dB Fading profile power uncertainty ±0.5 dB for single Tx AWGN flatness and signal flatness ±2.0 dB |
|||||||||
|
11.1.3.1.1_1 2Rx FR1 PSCCH performance – single active PSSCH link |
Same as 11.1.2.1.1_1 |
Same as 11.1.2.1.1_1 |
|||||||||
|
11.1.5.1.1_1 2Rx FR1 PSCCH performance – single active PSSCH link |
Same as 11.1.2.1.1_1 |
Same as 11.1.2.1.1_1 |
|||||||||
|
11.1.6.1.1_1 2Rx FR1 Power imbalance performance – two active PSSCH link |
± 0.6 dB |
Overall system uncertainty for fading conditions comprises two quantities: 1. Signal-to-noise ratio uncertainty 2. Effect of AWGN flatness and signal flatness Items 1, and 2 are assumed to be uncorrelated so can be root sum squared: AWGN flatness and signal flatness has x 0.25 effect on the required SNR, so use sensitivity factor of x 0.25 for the uncertainty contribution. Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + (0.25 x AWGN flatness and signal flatness) 2) Signal-to-noise ratio uncertainty ±0.3 dB AWGN flatness and signal flatness ±2.0 dB |
|||||||||
|
11.1.7.1.1_1 2Rx FR1 HARQ buffer soft combining performance – maximum number of HARQ processes |
Same as 11.1.2.1.1_1 |
Same as 11.1.2.1.1_1 |
|||||||||
|
11.1.8.1.1_1 2Rx FR1 PSCCH decoding capability – maximum number of received PSCCHs |
Downlink absolute power uncertainty, averaged over BWConfig ±1.0 dB Downlink EVM ≤ 3% |
3% EVM is equivalent to a Test system downlink SNR of 30.5dB. The noise from the Test system is then sufficiently below that required for the UE to demodulate the signal with the required % success rate. Under these conditions the UE throughput is limited by the Reference measurement channel and the UE capability, and not by the Test system EVM. |
|||||||||
|
11.1.9.1.1_1 2Rx FR1 PSFCH decoding capability – maximum number of received PSFCHs |
Same as 11.1.8.1.1_1 |
Same as 11.1.8.1.1_1 |
F.1.1.3 Measurement of Channel State Information reporting
This clause defines the maximum test system uncertainty for channel state information reporting requirements. The maximum test system uncertainty allowed for the measurement uncertainty contributors are defined in Table F.1.1.3-1.
Table F.1.1.3-1: Maximum measurement uncertainty values for the test system for FR1 (up to 6 GHz) and Channel BW ≤ 40 MHz
|
MU contributor |
Unit |
Value |
Comment |
|---|---|---|---|
|
AWGN flatness and signal flatness, max deviation for any Resource Block, relative to average over BWconfig |
dB |
Same as in table F.1.1.2-1 |
|
|
Signal to noise ratio uncertainty |
dB |
Same as in table F.1.1.2-1 |
|
|
Signal to noise ratio variation |
dB |
Same as in table F.1.1.2-1 |
|
|
Fading profile power uncertainty for 1Tx |
dB |
Same as in table F.1.1.2-1 |
|
|
Fading profile power uncertainty for 2Tx |
dB |
Same as in table F.1.1.2-1 |
The maximum test system uncertainty for test cases defined in section 6 is defined in Table F.1.1.3-2.
Table F.1.1.3-2: Maximum test system uncertainty for FR1 channel state information reporting test cases
|
Subclause |
Maximum Test System Uncertainty |
Derivation of Test System Uncertainty |
||||||
|
6.2.2.1.1.1 2Rx FDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
+/- 0.3 dB |
Overall system uncertainty for AWGN conditions comprises: Signal-to-noise ratio uncertainty ±0.3 dB AWGN flatness and signal flatness ±2.0 dB not expected to have any significant effect |
||||||
|
6.2.2.1.1.2 2Rx FDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.2.2.1.2.1 2Rx FDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
+/- 0.8 dB |
Overall system uncertainty for fading conditions comprises two quantities: 1. Signal-to-noise ratio uncertainty ±0.3 dB 2. Fading profile power uncertainty for 2Tx ±0.7 dB Items 1 and 2 are assumed to be uncorrelated so can be root sum squared: Test System uncertainty = SQRT (Signal-to-noise ratio uncertainty 2 + Fading profile power uncertainty 2) AWGN flatness and signal flatness ±2.0 dB not expected to have any significant effect |
||||||
|
6.2.2.1.2.2 2Rx FDD FR1 aperiodic subband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.2.2.1.1 2Rx TDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.2.2.2.1.2 2Rx TDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.2.2.2.2.1 2Rx TDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.2.2.2.2 2Rx TDD FR1 aperiodic subband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.3.1.1.1 4Rx FDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.2.3.1.1.2 4Rx FDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.2.3.1.2.1 4Rx FDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.3.1.2.2 4Rx FDD FR1 aperiodic subband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.3.2.1.1 4Rx TDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.2.3.2.2.1 4Rx TDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.3.2.2.2 4Rx TDD FR1 aperiodic subband CQI reporting under fading conditions for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2A.3.1.1 2Rx CQI reporting accuracy under AWGN conditions for CA (2DL CA) |
Same as 6.2.2.1.1.1 for each CC |
Same as 6.2.2.1.1.1 |
||||||
|
6.2A.3.1.2 2Rx CQI reporting accuracy under AWGN conditions for CA (3DL CA) |
Same as 6.2.2.1.1.1 for each CC |
Same as 6.2.2.1.1.1 |
||||||
|
6.2A.3.1.3 2Rx CQI reporting accuracy under AWGN conditions for CA (4DL CA) |
Same as 6.2.2.1.1.1 for each CC |
Same as 6.2.2.1.1.1 |
||||||
|
6.3.2.1.1 2Rx FDD FR1 Single PMI with 4Tx Type I- SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.1.2 2Rx FDD FR1 Single PMI with 8Tx Type I – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.1.3 2Rx FDD FR1 Multiple PMI with 16Tx Type I – SinglePanel Codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.1.4 2Rx FDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.1.5 2Rx FDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.1.6 2Rx FDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.2.3.2.1.2 4Rx TDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
Same as 6.2.2.1.1.1 |
Same as 6.2.2.1.1.1 |
||||||
|
6.3.2.2.1 2Rx TDD FR1 Single PMI with 4Tx TypeI – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.2.2 2Rx TDD FR1 Single PMI with 8Tx TypeI – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.2.3 2Rx TDD FR1 Single PMI with 16Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.2.4 2Rx TDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.2.6 2Rx TDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.1.1 Single PMI with 4TX TypeI-SinglePanel Codebook– SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.1.2 Single PMI with 8TX TypeI-SinglePanel Codebook– SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.1.3 4Rx FDD FR1 Multiple PMI with 16Tx Type I – SinglePanel Codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.1.4 4Rx FDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.1.5 4Rx FDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.1.6 4Rx FDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.2.1 4Rx TDD FR1 Single PMI with 4Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.2.2.5 2Rx TDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.2.2 4Rx TDD FR1 Single PMI with 8Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.2.3 4Rx TDD FR1 Single PMI with 16Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.2.4 4Rx TDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.2.5 4Rx TDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.3.3.2.6 4Rx TDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.4.2.1_1 2Rx FDD FR1 RI reporting for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.4.2.2_1 2Rx TDD FR1 RI reporting for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.4.3.1_1 4Rx FDD FR1 RI reporting for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
||||||
|
6.4.3.2_1 4Rx TDD FR1 RI reporting for both SA and NSA |
Same as 6.2.2.1.2.1 |
Same as 6.2.2.1.2.1 |
F.1.2 Interpretation of measurement results (normative)
The measurement results returned by the Test System are compared – without any modification – against the Test Requirements as defined by the shared risk principle.
The Shared Risk principle is defined in ETR 273-1-2 clause 6.5.
The actual measurement uncertainty of the Test System for the measurement of each parameter shall be included in the test report.
The recorded value for the Test System uncertainty shall be, for each measurement, equal to or lower than the appropriate figure in clause F.1 of the present document.
If the Test System for a test is known to have a measurement uncertainty greater than that specified in clause F.1, it is still permitted to use this apparatus provided that an adjustment is made value as follows:
Any additional uncertainty in the Test System over and above that specified in clause F.1 shall be used to tighten the Test Requirement, making the test harder to pass. For some tests, for example receiver tests, this may require modification of stimulus signals. This procedure will ensure that a Test System not compliant with clause F.1does not increase the chance of passing a device under test where that device would otherwise have failed the test if a Test System compliant with clause F.1 had been used.
F.1.3 Test Tolerance and Derivation of Test Requirements (informative)
The Test Requirements in the present document have been calculated by relaxing the Minimum Requirements of the core specification using the Test Tolerances defined in this clause. When the Test Tolerance is zero, the Test Requirement will be the same as the Minimum Requirement. When the Test Tolerance is non-zero, the Test Requirements will differ from the Minimum Requirements, and the formula used for the relaxation is given in this clause.
The Test Tolerances are derived from Test System uncertainties, regulatory requirements and criticality to system performance. As a result, the Test Tolerances may sometimes be set to zero.
The test tolerances should not be modified for any reason e.g. to take account of commonly known test system errors (such as mismatch, cable loss, etc.).
The downlink Test Tolerances apply at each receiver antenna connector.
F.1.3.1 Measurement of test environments
The UE test environments are set to the values defined in TS 36.508 subclause 4.1, without any relaxation. The applied Test Tolerance is therefore zero.
F.1.3.2 Measurement of Demod Performance requirements
The derivation of the test requirements for the test cases in section 5 is defined in Table F.1.3.2-1.
Table F.1.3.2-1: Derivation of Test Requirements (FR1 demodulation performance tests)
|
Test |
Minimum Requirement in TS 38.101-4 |
Test Tolerance |
Test Requirement in TS 38.521-4 |
|||||
|
5.2.2.1.1_1 2Rx FDD FR1 PDSCH mapping Type A performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler 0.6 dB for test 1-6 0.9 dB for test 1-7 |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.1_2 2Rx FDD FR1 PDSCH Mapping Type A performance – 2×2 MIMO with enhanced receiver type X for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.2_1 2Rx FDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.3_1 2Rx FDD FR1 PDSCH mapping Type B performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.4_1 2Rx FDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.5_1 2Rx FDD FR1 PDSCH 0.001% BLER performance – 1×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.6_1 2Rx FDD FR1 PDSCH repetitions over multiple slots performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.7] |
Formula: SNR + TT |
|||||
|
5.2.2.1.7 2Rx FDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.8_1 2Rx FDD FR1 PDSCH pre-emption performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.9_1 2Rx FDD FR1 HST-SFN performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.10_1 2Rx FDD FR1 HST-DPS performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.11_1 2Rx FDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.12_1 2Rx FDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.13_1 2Rx FDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.1.14_1 2Rx FDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
[0.7] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.1_1 2Rx TDD FR1 PDSCH mapping Type A performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler 0.9 dB for test 1-10 0.6 dB for test 1-11 |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.1_2 2Rx TDD FR1 PDSCH Mapping Type A performance – 2×2 MIMO with enhanced receiver type X for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.2_1 2Rx TDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.3_1 2Rx TDD FR1 PDSCH mapping Type B performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.4_1 2Rx TDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.5_1 2Rx FDD FR1 PDSCH 0.001% BLER performance – 1×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.6 dB] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.6_1 2Rx TDD FR1 PDSCH repetitions over multiple slots performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.6 dB] |
Formula: SNR + TT |
|||||
|
5.2.2.2.7_1 2Rx TDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.8_1 2Rx TDD FR1 PDSCH pre-emption performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.9_1 2Rx TDD FR1 HST-SFN performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.10_1 2Rx TDD FR1 HST-DPS performance – 2×2 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.11_1 2Rx TDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.12_1 2Rx TDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.13_1 2Rx TDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.2.2.14_1 2Rx TDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
[0.7dB] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.1_1 4Rx FDD FR1 PDSCH mapping Type A performance – 2×4 MIMO baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.1_2 4Rx FDD FR1 PDSCH mapping Type A performance – 4×4 MIMO baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.1_4 4Rx FDD FR1 PDSCH mapping Type A performance – 4×4 MIMO with enhanced receiver type 1 for both SA and NSA |
SNRs as specified |
0.9 dB for > 10Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.2_1 4Rx FDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 4×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.3_1 4Rx FDD FR1 PDSCH mapping Type B performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.4_1 4Rx FDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB for > 10 Hz doppler 1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.5_1 4Rx FDD FR1 PDSCH 0.001% BLER performance – 1×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.6 dB] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.6_1 4Rx FDD FR1 PDSCH repetitions over multiple slots performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.7dB] |
Formula: SNR + TT |
|||||
|
5.2.3.1.7_1 4Rx FDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.8_1 4Rx FDD FR1 PDSCH pre-emption performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.9_1 4Rx FDD FR1 HST-SFN performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.10_1 4Rx FDD FR1 HST-DPS performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.11_1 4Rx FDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×4 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.12_1 4Rx FDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×4 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.13_1 4Rx FDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×4 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.1.14_1 4Rx FDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×4 MIMO for both SA and NSA |
SNRs as specified |
[0.7dB] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.2_1 4Rx TDD FR1 PDSCH mapping Type A and CSI-RS overlapped with PDSCH performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.3_1 4Rx TDD FR1 PDSCH mapping Type B performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.4_1 4Rx TDD FR1 PDSCH Mapping Type A and LTE-NR coexistence performance – 4×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.5_1 4Rx TDD FR1 PDSCH 0.001% BLER performance – 1×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.6 dB] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.6_1 4Rx TDD FR1 PDSCH repetitions over multiple slots performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
[0.7dB] |
Formula: SNR + TT |
|||||
|
5.2.3.2.7_1 4Rx TDD FR1 PDSCH Mapping Type B and UE processing capability 2 performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.8_1 4Rx TDD FR1 PDSCH pre-emption performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.9_1 4Rx TDD FR1 HST-SFN performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.10_1, 4Rx TDD FR1 HST DPS performance – 2×4 MIMO with baseline receiver for both SA and NSA |
SNRs as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.11_1 4Rx TDD FR1 PDSCH Single-DCI based SDM scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.12_1 4Rx TDD FR1 PDSCH Multiple-DCI based transmission scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.13_1 4Rx TDD FR1 PDSCH Single-DCI based FDM scheme A performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2.3.2.14_1 4Rx TDD FR1 PDSCH Single-DCI based Inter-slot TDM scheme performance – 2×2 MIMO for both SA and NSA |
SNRs as specified |
[0.7dB] |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.2.1.1 2Rx Normal PDSCH Demodulation Performance for CA (2DL CA) |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.2.1.2 2Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.2.1.3 2Rx Normal PDSCH Demodulation Performance for CA (4DL CA) |
SNRs as specified |
1.0 dB for 10Hz doppler |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.2.2.1 2Rx PDSCH Demodulation Performance for CA with power imbalance (2DL CA) |
Power level as specified |
No TT added |
T-put limit unchanged |
|||||
|
5.2A.2.5.1 2RX PDSCH Demodulation Performance for HST-DPS CA |
SNR as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.3.1.1 4Rx Normal PDSCH Demodulation Performance for CA (2DL CA) |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.3.1.2 4Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.3.1.3 4Rx Normal PDSCH Demodulation Performance for CA (4DL CA) |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.3A.1.1 2Rx-4Rx Normal PDSCH Demodulation Performance for CA (2DL CA) |
SNRs as specified |
2Rx CC: 1.0 dB for 10Hz doppler 4Rx CC: 0.9dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.3A.1.2 2Rx-4Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
SNRs as specified |
2Rx CC: 1.0 dB for 10Hz doppler 4Rx CC: 0.9dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.2A.3A.1.3 2Rx-4Rx Normal PDSCH Demodulation Performance for CA (3DL CA) |
SNRs as specified |
2Rx CC: 1.0 dB for 10Hz doppler 4Rx CC: 0.9dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
11.1.2.1.1_1 2Rx FR1 PSSCH performance – single active PSSCH link |
SNR as specified |
0.8 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
11.1.3.1.1_1 2Rx FR1 PSCCH performance – single active PSSCH link |
SNR as specified |
0.8 dB |
Formula: SNR + TT missing detection probability limit unchanged |
|||||
|
11.1.5.1.1_1 2Rx FR1 PSCCH performance – single active PSSCH link |
SNR as specified |
0.8 dB |
Formula: SNR + TT missing detection probability limit unchanged |
|||||
|
11.1.6.1.1_1 2Rx FR1 Power imbalance performance – two active PSSCH link |
SNR as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
11.1.7.1.1_1 2Rx FR1 HARQ buffer soft combining performance – maximum number of HARQ processes |
SNR as specified |
0.6 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
11.1.8.1.1_1 2Rx FR1 PSCCH decoding capability – maximum number of received PSCCHs |
sidelink power |
0 dB |
sidelink power unchanged missing detection probability limit unchanged |
|||||
|
11.1.9.1.1_1 2Rx FR1 PSFCH decoding capability – maximum number of received PSFCHs |
sidelink power |
0 dB |
sidelink power unchanged missing detection probability limit unchanged |
|||||
|
5.3.2.1.1 2Rx FDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.2.1.2 2Rx FDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.2.1.3 2Rx FDD FR1 PDCCH 1 Tx antenna performance for power saving |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.2.2.1 2Rx TDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.2.2.2 2Rx TDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.2.2.3 2Rx TDD FR1 PDCCH 1 Tx antenna performance for power saving |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.3.1.1 4Rx FDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.3.1.2 4Rx FDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.3.1.3 4Rx FDD FR1 PDCCH 1 Tx antenna performance power saving |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.3.2.1 4Rx TDD FR1 PDCCH 1 Tx antenna performance for both SA and NSA |
SNRs as specified |
0.9 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
|
5.3.3.2.2 4Rx TDD FR1 PDCCH 2 Tx antenna performance for both SA and NSA |
SNRs as specified |
1.0 dB |
Formula: SNR + TT T-put limit unchanged |
|||||
F.1.3.3 Measurement of Channel State Information reporting
The derivation of the test requirements for the test cases in section 6 is defined in Table F.1.3.3-1.
Table F.1.3.3-1: Derivation of Test Requirements (FR1 channel state information reporting tests)
|
Test |
Minimum Requirement in TS 38.101-4 |
Test Tolerance |
Test Requirement in TS 38.521-4 |
|
6.2.2.1.1.1 2Rx FDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.2.1.1.2 2Rx FDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.2.1.2.1 2Rx FDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 20% 1.05 BLER 0.02 |
SNR 0 dB 0% 0.01 BLER 0 |
SNR unchanged unchanged 1.04 BLER limit unchanged |
|
6.2.2.1.2.2 2Rx FDD FR1 periodic subband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 2% 55% 1.05 BLER 0.02 |
SNR 0 dB 0% 0% 0.01 BLER 0 |
SNR unchanged limit unchanged limit unchanged 1.04 BLER limit unchanged |
|
6.2.2.2.1.1 2Rx TDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.2.2.1.2 2Rx TDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.2.2.2.1 2Rx TDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 20% 1.05 BLER 0.02 |
SNR 0 dB 0% 0.01 BLER 0 |
SNR unchanged unchanged 1.04 BLER limit unchanged |
|
6.2.2.2.2.2 2Rx TDD FR1 periodic subband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 2% 55% 1.05 BLER 0.02 |
SNR 0 dB 0% 0% 0.01 BLER 0 |
SNR unchanged limit unchanged limit unchanged 1.04 BLER limit unchanged |
|
6.2.3.1.1.1 4Rx FDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.3.1.1.2 4Rx FDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.3.1.2.1 4Rx FDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 5% 1.05 BLER 0.02 |
SNR 0 dB 0% 0.01 BLER 0 |
SNR unchanged unchanged 1.04 BLER limit unchanged |
|
6.2.3.1.2.2 4Rx FDD FR1 aperiodic subband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 2% 55% 1.05 BLER 0.02 |
SNR 0 dB 0% 0% 0.01 BLER 0 |
SNR unchanged limit unchanged limit unchanged 1.04 BLER limit unchanged |
|
6.2.3.2.1.1 4Rx TDD FR1 periodic CQI reporting under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.3.2.1.2 4Rx TDD FR1 periodic CQI reporting with Table 3 under AWGN conditions for both SA and NSA |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
SNR unchanged |
|
6.2.3.2.2.1 4Rx TDD FR1 periodic wideband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 5% 1.05 BLER 0.02 |
SNR 0 dB 0% 0.01 BLER 0 |
SNR unchanged unchanged 1.04 BLER limit unchanged |
|
6.2.3.2.2.2 4Rx TDD FR1 aperiodic subband CQI reporting under fading conditions for both SA and NSA |
SNRs as specified 2% 55% 1.05 BLER 0.02 |
SNR 0 dB 0% 0% 0.01 BLER 0 |
SNR unchanged limit unchanged limit unchanged 1.04 BLER limit unchanged |
|
6.2A.3.1.1 2Rx CQI reporting accuracy under AWGN conditions for CA (2DL CA) |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
Test requirement unchanged |
|
6.2A.3.1.2 2Rx CQI reporting accuracy under AWGN conditions for CA (3DL CA) |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
Test requirement unchanged |
|
6.2A.3.1.3 2Rx CQI reporting accuracy under AWGN conditions for CA (4DL CA) |
SNRs as specified Limits as in the Test Procedure |
No test tolerances applied |
Test requirement unchanged |
|
6.3.2.1.1 2Rx FDD FR1 Single PMI with 4Tx Type I- SinglePanel codebook for both SA and NSA |
SNRs as specified 1.30 |
SNR 0 dB 0.01 |
SNR unchanged 1.29 |
|
6.3.2.1.2 2Rx FDD FR1 Single PMI with 8Tx Type I – SinglePanel codebook for both SA and NSA |
SNRs as specified 1.50 |
SNR 0 dB 0.01 |
SNR unchanged 1.49 |
|
6.3.2.1.3 2Rx FDD FR1 Multiple PMI with 16Tx Type I – SinglePanel Codebook for both SA and NSA |
SNRs as specified 2.50 |
SNR 0 dB 0.01 |
SNR unchanged 2.49 |
|
6.3.2.1.4 2Rx FDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified g 5.0 |
SNR 0 dB g 0.01 |
SNR unchanged g 4.99 |
|
6.3.2.1.5 2Rx FDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
SNRs as specified g 1.9 |
SNR 0 dB g 0.01 |
SNR unchanged g 1.89 |
|
6.3.2.1.6 2Rx FDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
SNRs as specified 2.2 |
SNR 0 dB 0.01 |
SNR unchanged 2.19 |
|
6.3.2.2.1 2Rx TDD FR1 Single PMI with 4Tx TypeI – SinglePanel codebook for both SA and NSA |
SNRs as specified 1.30 |
SNR 0 dB 0.01 |
SNR unchanged 1.29 |
|
6.3.2.2.2 2Rx TDD FR1 Single PMI with 8Tx TypeI – SinglePanel codebook for both SA and NSA |
SNRs as specified 1.50 |
SNR 0 dB 0.01 |
SNR unchanged 1.49 |
|
6.3.2.2.3 2Rx TDD FR1 Single PMI with 16Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified 2.50 |
SNR 0 dB 0.01 |
SNR unchanged 2.49 |
|
6.3.2.2.4 2Rx TDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified 5.0 |
SNR 0 dB 0.01 |
SNR unchanged 4.99 |
|
6.3.2.2.5 2Rx TDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
SNRs as specified g 1.9 |
SNR 0 dB g 0.01 |
SNR unchanged g 1.89 |
|
6.3.2.2.6 2Rx TDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
SNRs as specified 2.2 |
SNR 0 dB 0.01 |
SNR unchanged 2.19 |
|
6.3.3.1.1 Single PMI with 4TX TypeI-SinglePanel Codebook– SinglePanel codebook for both SA and NSA |
SNRs as specified 1.30 |
SNR 0 dB 0.01 |
SNR unchanged 1.29 |
|
6.3.3.1.2 Single PMI with 8TX TypeI-SinglePanel Codebook– SinglePanel codebook for both SA and NSA |
SNRs as specified 1.50 |
SNR 0 dB 0.01 |
SNR unchanged 1.49 |
|
6.3.3.1.3 4Rx FDD FR1 Multiple PMI with 16Tx Type I – SinglePanel Codebook for both SA and NSA |
SNRs as specified 3.00 |
SNR 0 dB 0.01 |
SNR unchanged 2.99 |
|
6.3.3.1.4 4Rx FDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified g 7.0 |
SNR 0 dB g 0.01 |
SNR unchanged g 6.99 |
|
6.3.3.1.5 4Rx FDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
SNRs as specified g 1.9 |
SNR 0 dB g 0.01 |
SNR unchanged g 1.89 |
|
6.3.3.1.6 4Rx FDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
SNRs as specified 2.2 |
SNR 0 dB 0.01 |
SNR unchanged 2.19 |
|
6.3.3.2.1 4Rx TDD FR1 Single PMI with 4Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified 1.30 |
SNR 0 dB 0.01 |
SNR unchanged 1.29 |
|
6.3.3.2.2 4Rx TDD FR1 Single PMI with 8Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified 1.50 |
SNR 0 dB 0.01 |
SNR unchanged 1.49 |
|
6.3.3.2.3 4Rx TDD FR1 Single PMI with 16Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified 3.0 |
SNR 0 dB 0.01 |
SNR unchanged 2.99 |
|
6.3.3.2.4 4Rx TDD FR1 Single PMI with 32Tx Type1 – SinglePanel codebook for both SA and NSA |
SNRs as specified g 7.0 |
SNR 0 dB g 0.01 |
SNR unchanged g 6.99 |
|
6.3.3.2.5 4Rx TDD FR1 Multiple PMI with 16Tx TypeII codebook for both SA and NSA |
SNRs as specified g 1.8 |
SNR 0 dB g 0.01 |
SNR unchanged g 1.79 |
|
6.3.3.2.6 4Rx TDD FR1 Multiple PMI with 16Tx Enhanced TypeII codebook for both SA and NSA |
SNRs as specified 2.2 |
SNR 0 dB 0.01 |
SNR unchanged 2.19 |
|
6.4.2.1_1 2Rx FDD FR1 RI reporting for both SA and NSA |
SNRs as specified 1.00 for Test 1 1.05 for Test 2 0.90 for Test 3 |
SNR 0 dB 0.01 for Test 1 0.01 for Test 2 0.01 for Test 3 |
SNR unchanged 0.99 for Test 1 1.04 for Test 2 0.89 for Test 3 |
|
6.4.2.2_1 2Rx TDD FR1 RI reporting for both SA and NSA |
SNRs as specified 1.00 for Test 1 1.05 for Test 2 0.90 for Test 3 |
SNR 0 dB 0.01 for Test 1 0.01 for Test 2 0.01 for Test 3 |
SNR unchanged 0.99 for Test 1 1.04 for Test 2 0.89 for Test 3 |
|
6.4.3.1_1 4Rx FDD FR1 RI reporting for both SA and NSA |
SNRs as specified 0.90 for Test 1 1.05 for Test 2 0.90 for Test 3 0.90 for Test 4 |
SNR 0 dB 0.01 for Test 1 0.01 for Test 2 0.01 for Test 3 0.01 for Test 4 |
SNR unchanged 0.89 for Test 1 1.04 for Test 2 0.89 for Test 3 0.89 for Test 4 |
|
6.4.3.2_1 4Rx TDD FR1 RI reporting for both SA and NSA |
SNRs as specified 0.90 for Test 1 1.05 for Test 2 0.90 for Test 3 0.90 for Test 4 |
SNR 0 dB 0.01 for Test 1 0.01 for Test 2 0.01 for Test 3 0.01 for Test 4 |
SNR unchanged 0.89 for Test 1 as per Table G.3.4 1.04 for Test 2 as per Table G.3.4 0.89 for Test 3 as per Table G.3.4 0.89 for Test 4 as per Table G.3.4 |