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srsRAN_4G/matlab/tests/prach_detect_test.m

200 lines
7.0 KiB
Matlab

%% PRACH Detection Conformance Test
%clear
d=50;%linspace(4,14,6);
pDetection2 = zeros(2,length(d));
for dd=1:length(d)
detect_factor=d(dd);
numSubframes = 1; % Number of subframes frames to simulate at each SNR
SNRdB = 10;%linspace(-14,10,8); % SNR points to simulate
foffset = 0.0; % Frequency offset in Hertz
delay=0;
add_fading=false;
addpath('../../build/srslte/lib/phch/test')
%% UE Configuration
% User Equipment (UE) settings are specified in the structure |ue|.
ue.NULRB = 15; % 6 Resource Blocks
ue.DuplexMode = 'FDD'; % Frequency Division Duplexing (FDD)
ue.CyclicPrefixUL = 'Normal'; % Normal cyclic prefix length
ue.NTxAnts = 1; % Number of transmission antennas
%% PRACH Configuration
prach.Format = 0; % PRACH format: TS36.104, Table 8.4.2.1-1
prach.HighSpeed = 0; % Normal mode: TS36.104, Table 8.4.2.1-1
prach.FreqOffset = 4; % Default frequency location
info = ltePRACHInfo(ue, prach); % PRACH information
%% Propagation Channel Configuration
% Configure the propagation channel model using a structure |chcfg| as per
% TS36.104, Table 8.4.2.1-1 [ <#9 1> ].
chcfg.NRxAnts = 1; % Number of receive antenna
chcfg.DelayProfile = 'ETU'; % Delay profile
chcfg.DopplerFreq = 70.0; % Doppler frequency
chcfg.MIMOCorrelation = 'Low'; % MIMO correlation
chcfg.Seed = 1; % Channel seed
chcfg.NTerms = 16; % Oscillators used in fading model
chcfg.ModelType = 'GMEDS'; % Rayleigh fading model type
chcfg.InitPhase = 'Random'; % Random initial phases
chcfg.NormalizePathGains = 'On'; % Normalize delay profile power
chcfg.NormalizeTxAnts = 'On'; % Normalize for transmit antennas
chcfg.SamplingRate = info.SamplingRate; % Sampling rate
%% Loop for SNR Values
% Initialize the random number generator stream
rng('default');
% Initialize variables storing probability of detection at each SNR
pDetection = zeros(2,length(SNRdB));
for nSNR = 1:length(SNRdB)
% Scale noise to ensure the desired SNR after SC-FDMA demodulation
ulinfo = lteSCFDMAInfo(ue);
SNR = 10^(SNRdB(nSNR)/20);
N = 1/(SNR*sqrt(double(ulinfo.Nfft)))/sqrt(2.0);
% Detected preamble count
detectedCount = 0;
detectedCount_srs = 0;
% Loop for each subframe
for nsf = 1:numSubframes
prach.SeqIdx = 0;%randi(838,1,1)-1; % Logical sequence index: TS36.141, Table A.6-1
prach.CyclicShiftIdx = 11;%randi(16,1,1)-1; % Cyclic shift index: TS36.141, Table A.6-1
prach.PreambleIdx = 1;%randi(64,1,1)-1; % Preamble index: TS36.141, Table A.6-1
info = ltePRACHInfo(ue, prach); % PRACH information
% PRACH transmission
ue.NSubframe = mod(nsf-1, 10);
ue.NFrame = fix((nsf-1)/10);
% Set PRACH timing offset in us as per TS36.141, Figure 8.4.1.4.2-2
%prach.TimingOffset = info.BaseOffset + ue.NSubframe/10.0;
prach.TimingOffset = 0;
% Generate transmit wave
[txwave,prachinfo] = ltePRACH(ue, prach);
% Channel modeling
if (add_fading)
chcfg.InitTime = (nsf-1)/1000;
[rxwave, fadinginfo] = lteFadingChannel(chcfg, ...
[txwave; zeros(25, 1)]);
else
rxwave = txwave;
end
% Add noise
%noise = N*complex(randn(size(rxwave)), randn(size(rxwave)));
%rxwave = rxwave + noise;
% Remove the implementation delay of the channel modeling
if (add_fading)
rxwave = rxwave((fadinginfo.ChannelFilterDelay + 1):end, :);
end
rxwave=x;
% rxwave=[zeros(delay,1); txwave(1:end-delay)];
% Apply frequency offset
t = ((0:size(rxwave, 1)-1)/chcfg.SamplingRate).';
rxwave = rxwave .* repmat(exp(1i*2*pi*foffset*t), ...
1, size(rxwave, 2));
% PRACH detection for all cell preamble indices
[detected, offsets] = ltePRACHDetect(ue, prach, rxwave, (0:63).');
[detected_srs, offsets_srs, corrout] = srslte_prach_detect(ue, prach, rxwave, detect_factor);
disp(detected)
disp(detected_srs)
disp(offsets_srs*1e6)
% Test for preamble detection
if (length(detected)==1)
% Test for correct preamble detection
if (detected==prach.PreambleIdx)
% Calculate timing estimation error. The true offset is
% PRACH offset plus channel delay
trueOffset = prach.TimingOffset/1e6 + 310e-9;
measuredOffset = offsets(1)/chcfg.SamplingRate;
timingerror = abs(measuredOffset-trueOffset);
% Test for acceptable timing error
if (timingerror<=2.08e-6)
detectedCount = detectedCount + 1; % Detected preamble
else
disp('Timing error');
end
else
disp('Detected incorrect preamble');
end
else
disp('Detected multiple or zero preambles');
end
% Test for preamble detection
if (length(detected_srs)==1)
% Test for correct preamble detection
if (detected_srs==prach.PreambleIdx)
% Calculate timing estimation error. The true offset is
% PRACH offset plus channel delay
trueOffset = prach.TimingOffset/1e6 + 310e-9;
measuredOffset = offsets_srs(1);
timingerror = abs(measuredOffset-trueOffset);
% Test for acceptable timing error
if (timingerror<=2.08e-6)
detectedCount_srs = detectedCount_srs + 1; % Detected preamble
else
disp('SRS: Timing error');
end
else
disp('SRS: Detected incorrect preamble');
end
else
fprintf('SRS: Detected %d preambles. D=%.1f, Seq=%3d, NCS=%2d, Idx=%2d\n', ...
length(detected_srs),detect_factor, prach.SeqIdx, prach.CyclicShiftIdx, prach.PreambleIdx);
end
end % of subframe loop
% Compute final detection probability for this SNR
pDetection(1,nSNR) = detectedCount/numSubframes;
pDetection(2,nSNR) = detectedCount_srs/numSubframes;
end % of SNR loop
pDetection2(1,dd)=pDetection(1,1);
pDetection2(2,dd)=pDetection(2,1);
end
%% Analysis
if (length(SNRdB)>1)
plot(SNRdB, pDetection)
legend('Matlab','srsLTE')
grid on
xlabel('SNR (dB)')
ylabel('Pdet')
else
plot(d,pDetection2)
legend('Matlab','srsLTE')
grid on
xlabel('d')
ylabel('Pdet')
fprintf('Pdet=%.4f%%, Pdet_srs=%.4f%%\n',pDetection(1,nSNR),pDetection(2,nSNR))
end
plot(corrout)