sof/tools/test/audio/test_utils/find_test_signal.m

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function [d, nt, nt_use, nt_skip] = find_test_signal(x0, test)
%% [d, nt, nt_use, nt_skip] = find_test_signal(x, test)
%
% Inputs
% x - input signal
% test - test definitions
%
% Outputs
% d - delay to fist test tone start
% nt - number of samples in test tone
% nt_use - number of samples to use
% nt_skip - number of samples to skip
%
% SPDX-License-Identifier: BSD-3-Clause
% Copyright(c) 2017 Intel Corporation. All rights reserved.
% Author: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com>
d = [];
nt = [];
nt_use = [];
nt_skip = [];
%% Use channel with strongest signal
ch = select_channel(x0);
x = x0(:, ch);
%% Find start marker
fprintf('Finding test start marker...\n');
s = sync_chirp(test.fs, 'up');
nx = length(x);
n_seek = round(test.fs*(test.idle_t + test.mark_t));
n = min(max(round(test.fs*test.sm), n_seek), nx);
y = x(1:n);
[r, lags] = xcorr(y, s);
[r_max, idx] = max(r);
d_start = lags(idx);
%% Find end marker
fprintf('Finding test end marker...\n');
s = sync_chirp(test.fs, 'down');
n_seek = round(test.fs*(test.idle_t + test.mark_t));
n = min(max(round(test.fs*test.em),n_seek), nx);
y = x(end-n+1:end);
[r, lags] = xcorr(y, s);
[r_max, idx] = max(r);
d_end = nx-n+lags(idx);
%% Check correct length of signal
len = d_end-d_start;
len_s = len/test.fs;
ref_s = test.mark_t+test.nf*test.na*test.tl;
if abs(len_s-ref_s) > test.mt
fprintf(1, 'Start and end markers were not found. Signal quality may be poor.\n');
return
end
%% Delay to first tone, length of tone in samples
d = d_start + round(test.mark_t*test.fs);
if (d < 0)
fprintf(1, 'Invalid delay value. Signal quality may be poor.\n');
return
d = [];
end
nt = round(test.tl*test.fs);
nt_use = nt -round(test.is*test.fs) -round(test.ie*test.fs);
if nt_use < 0
fprintf(1, 'Test signal ignore start/end mismatch.\n');
d = [];
nt = [];
nt_use = [];
return
end
nt_skip = round(test.is*test.fs);
end
%% Select channel function
function ch = select_channel(x)
rms = get_rms(x);
[~, ch] = max(rms);
end
%% RMS level in decibels
function rms_db = get_rms(x)
s = size(x);
nch = s(2);
rms_db = zeros(1, nch);
for i = 1:nch
rms_db(i) = 20*log10(sqrt(mean(x(:,i).^2)));
end
end