E.6 EVM for PRACH
38.521-23GPPNRPart 2: Range 2 StandaloneRadio transmission and receptionRelease 17TSUser Equipment (UE) conformance specification
The description below is generic in the sense that all PRACH formats are covered. The numbers, used in the text below are taken from PRACH format B4 without excluding the other formats. The sampling rate for the PUSCH, 122.88 Mbps in the time domain, is re-used for the PRACH. The carrier spacing of the PUSCH is up to 48 times higher than that of PRACH depending on the PRACH format and SCS. This results in an oversampling factor ovf of up to 48, when acquiring the time samples for the PRACH. The pre-FFT algorithms (clauses E.6.6 and E.6.7) use all time samples, although oversampled. For the FFT the time samples are decimated by the ovf, resulting in the same FFT size as for the other transmit modulation tests. Decimation requires a decision, which samples are used and which ones are rejected. The algorithm in E.6.6, Timing of the FFT window, can also be used to decide about the used samples.
E.6.1 Basic principle
The basic principle is the same as described in E.2.1
E.6.2 Output signal of the TX under test
The output signal of the TX under test is processed same as described in E.2.2
The measurement period is different since 2 PRACH preambles are recorded for long preamble formats as defined in Table 6.3.3.1-1 in [9] and 10 preambles are recorded for short preamble formats as defined in Table 6.3.3.1-2 in [9].
E.6.3 Reference signal
The test description in 6.4.2.1.4.1 is based on non-contention based access:
– PRACH configuration index (responsible for Preamble format, System frame number and subframe number)
– Preamble ID
– Preamble power
signalled to the UE, defines the reference signal unambiguously, such that no demodulation process is necessary to gain the reference signal.
The reference signal i(ν) is constructed by the measuring equipment according to the relevant TX specifications, using the following parameters: the applicable Zadoff Chu sequence, nominal carrier frequency, nominal amplitude and phase for each subcarrier, nominal timing, no carrier leakage. It is represented as a sequence of samples at a sampling rate of 122.88 Mbps in the time domain.
E.6.4 Measurement results
The measurement result is:
– EVMPRACH
E.6.5 Measurement points
The measurement points are illustrated in the figure below:
Figure E.6.5-1: Measurement points
E.6.6 Pre FFT minimization process
The pre-FFT minimization process is applied to each PRACH preamble separately. The time period for the pre- FFT minimisation process includes the complete CP and Zadoff-Chu sequence (in other words, the power transition period is per definition outside of this time period) Sample timing, Carrier frequency and carrier leakage in z(ν) are jointly varied in order to minimise the difference between z(ν) and i(ν). Best fit (minimum difference) is achieved when the RMS difference value between z(ν) and i(ν) is an absolute minimum.
After this process the samples z(ν) are called z0(ν).
RF error, and carrier leakage are necessary for best fit of the measured signal towards the ideal signal in the pre FFT domain. However they are not used to compare them against the limits.
E.6.7 Timing of the FFT window
The FFT window length is 81922– samples for preamble format B4, however in the measurement period at least 119362–samples are taken where . The position in time for FFT must be determined.
In an ideal signal, the FFT may start at any instant within the cyclic prefix without causing an error. The TX filter, however, reduces the window. The EVM requirements shall be met within a window W<CP.
The reference instant for the FFT start is the centre of the reduced window, called 
,
EVM is measured at the following two instants: 
–W/2 and 
+W/2.
The timing of the measured signal z0(ν) with respect to the ideal signal i(ν) is determined in the pre FFT domain as follows:
Correlation between z0(ν) and i(ν) will result in a correlation peak. The meaning of the correlation peak is approx. the “impulse response” of the TX filter. The correlation peak, (the highest, or in case of more than one, the earliest) indicates the timing in the measured signal with respect to the ideal signal.
W is different for different preamble formats and shown in Table E.6.7-1 for and where .
Table E.6.7-1 EVM window length for PRACH formats for
|
Preamble format |
Cyclic prefix length
|
Nominal FFT size1 |
EVM window length W in FFT samples |
Ratio of W to CP* |
|
A1 |
11522– |
81922– |
5762– |
50.0% |
|
A2 |
23042– |
81922– |
17282– |
75.0% |
|
A3 |
34562– |
81922– |
28802– |
83.3% |
|
B1 |
8642– |
81922– |
2882– |
33.3% |
|
B2 |
14402– |
81922– |
8642– |
60.0% |
|
B3 |
20162– |
81922– |
14402– |
71.4% |
|
B4 |
37442– |
81922– |
31682– |
84.6% |
|
C0 |
49602– |
81922– |
43842– |
88.4% |
|
C2 |
81922– |
81922– |
76162– |
93.0% |
|
Note 1: The use of other FFT sizes is possible as long as appropriate scaling of the window length is applied. Note 2: These percentages are informative. |
||||
The number of samples, used for FFT is reduced compared to z0(ν). This subset of samples is called z’’(ν).
The sample frequency 122.88 MHz is oversampled with respect to the PRACH-subcarrier spacing of . EVM is based on 81922– samples per PRACH preamble and requires decimation of the time samples by the factor of . The final number of samples per PRACH preamble, used for FFT is reduced compared to z’’(ν) by the same factor. This subset of samples is called z’(ν).
E.6.8 Post FFT equalisation
Equalisation is not applicable for the PRACH.
E.6.9 Derivation of the results
E.6.9.1 EVMPRACH
Perform FFT on z’(ν) and i(ν) using the FFT timing 
–W/2 and 
+W/2.
For format B4 the first and the repeated preamble sequence are FFT-converted separately using the standard FFT length of 8192.
The EVMPRACH is the difference between the ideal waveform and the measured and equalized waveform for the allocated RB(s).
where
t covers the count of demodulated symbols in the slot.
f covers the count of demodulated symbols within the allocated bandwidth.
are the samples of the signal evaluated for the EVMPRACH
is the ideal signal reconstructed by the measurement equipment, and
is the average power of the ideal signal. For normalized modulation symbols 
is equal to 1.
From the acquired samples 2m EVMPRACH values can be derived, m values for the timing 
–W/2 and m values for the timing 
+W/2.
E.6.9.2 Averaged EVMPRACH
The PRACH EVM, 
, is averaged over m preamble sequence measurements.
where m is the number of recorded preambles as defined in Annex E.6.2.
The averaging is done separately for timing¦ 
–W/2 and +W/2 leading to
and 
is compared against the test requirements.
Annex F (normative):
Measurement uncertainties and Test Tolerances