sof/tools/test/audio/std_utils/fr_test_measure.m

217 lines
5.7 KiB
Matlab

function test = fr_test_measure(test)
%% t = fr_test_measure(t)
%
% Measure frequency response from captured frequency sweep created by
% fr_test_input() that sets most of the input struct fiels. The output
% is read from file t.fn_out.
%
% The test criteria is defined with first three or four latter input
% parameters. The latter has precedence if defined.
%
% Input parameters
% t.fr_lo - Measure ripple start frequency
% t.fr_hi - Measure ripple end frequency
% t.fr_rp_max_db - Max. ripple +/- dB
% t.fr_mask_flo - Frequencies for lower mask
% t.fr_mask_fhi - Frequencies for higher mask
% t.fr_mask_mlo - Upper limits of mask
% t.fr_mask_mhi - Lower limits of mask
%
% Output parameters
% t.f - Frequency grid (Hz)
% t.m - Measured frequency response (dB)
% t.rp - Measured ripple +/- dB
% t.fr3db_hz - Bandwidth in Hz for -3 dB attenuated response
% t.fail - Returns zero for passed
% t.fh - Figure handle
% t.ph - Plot handle
%
% SPDX-License-Identifier: BSD-3-Clause
% Copyright(c) 2017 Intel Corporation. All rights reserved.
% Author: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com>
%% Check if upper and lower mask is defined
if length(test.fr_mask_flo) || length(test.fr_mask_fhi)
test.fr_lo = 0;
test.fr_hi = 0;
end
if test.fr_lo > 0 || test.fr_hi > 0
test.fr_mask_flo = [];
test.fr_mask_fhi = [];
test.fr_mask_mlo = [];
test.fr_mask_mhi = [];
end
test.ph = [];
test.fh = [];
%% Reference: AES17 6.2.3 Frequency response
% http://www.aes.org/publications/standards/
[x, nx] = load_test_output(test);
default_result = NaN * ones(1,length(test.ch));
test.rp = default_result;
test.fr3db_hz = default_result;
test.fail = 0;
j = 1;
for channel = test.ch
if nx == 0
test.fail = 1;
return
end
%% Find sync
[d, nt, nt_use, nt_skip] = find_test_signal(x(:,j), test);
if isempty(d)
test.fail = 1;
return
end
win = hamming(nt_use);
m0 = zeros(test.nf,1);
for n=1:test.nf
fprintf('Measuring %.0f Hz ...\n', test.f(n));
i1 = d+(n-1)*nt+nt_skip;
i2 = i1+nt_use-1;
m0(n) = level_dbfs(x(i1:i2,j).*win) -test.a_db;
end
%% Scale 997 Hz point as 0 dB
df = test.f - test.f_ref;
[~,i997] = min(abs(df));
m_offs = m0(i997);
test.m(:,j) = m0 - m_offs;
%% Check pass/fail
if test.fr_lo > 0 && test.fr_hi > 0 && ~isempty(test.fr_rp_max_db)
idx0 = find(test.f < test.fr_hi);
idx1 = find(test.f(idx0) > test.fr_lo);
range_db = max(test.m(idx1,j))-min(test.m(idx1,j));
test.rp(j) = range_db/2;
if test.rp(j) > test.fr_rp_max_db
fprintf('Failed response ch%d +/- %f dBpp (max +/- %f dB)\n', ...
test.ch(j), test.rp(j), test.fr_rp_max_db);
test.fail = 1;
end
end
%% Find frequency response 3 dB 0-X Hz
idx3 = find(test.m(:,j) > -3);
test.fr3db_hz(j) = test.f(idx3(end));
%% Interpolate mask in logaritmic frequencies, check
if ~isempty(test.fr_mask_fhi)
f_log = log(test.f);
mask_hi = interp1(log(test.fr_mask_fhi), ...
test.fr_mask_mhi(:,j), f_log, 'linear');
over_mask = test.m(:,j)-mask_hi';
idx = find(isnan(over_mask) == 0);
[m_over_mask, io] = max(over_mask(idx));
if m_over_mask > 0
fprintf('Failed upper response mask around %.0f Hz\n', ...
test.f(io(1)));
test.fail = 1;
end
end
if ~isempty(test.fr_mask_flo)
f_log = log(test.f);
mask_lo = interp1(log(test.fr_mask_flo), ...
test.fr_mask_mlo(:,j), f_log, 'linear');
under_mask = mask_lo'-test.m(:,j);
idx = find(isnan(under_mask) == 0);
[m_under_mask, iu] = max(under_mask(idx));
if m_under_mask > 0
fprintf('Failed lower response mask around %.0f Hz\n', ...
test.f(iu(1)));
test.fail = 1;
end
end
%% Next channel to measure
j=j+1;
end
%% Do plots
nr = j-1;
for i = 1:nr
test.fh(i) = figure('visible', test.plot_visible);
test.ph(i) = subplot(1,1,1);
if test.plot_channels_combine
semilogx(test.f, test.m);
else
semilogx(test.f, test.m(:,i));
end
grid on;
xlabel('Frequency (Hz)');
ylabel('Magnitude (dB)');
if ~isempty(test.fr_mask_fhi)
hold on;
plot(test.f, mask_hi, 'k--');
hold off;
end
if ~isempty(test.fr_mask_flo)
hold on;
plot(test.f, mask_lo, 'k--');
hold off;
end
if ~isempty(test.plot_fr_axis)
axis(test.plot_fr_axis);
end
if test.plot_channels_combine && (test.nch > 1)
switch test.nch
case 2
lstr1 = sprintf("ch%d", test.ch(1));
lstr2 = sprintf("ch%d", test.ch(2));
legend(lstr1, lstr2, ...
'Location', 'NorthEast');
end
else
lstr = sprintf("ch%d", test.ch(i));
legend(lstr, 'Location', 'NorthEast');
end
if test.plot_passband_zoom
axes('Position', [ 0.2 0.2 0.4 0.2]);
box on;
i1 = find(test.f < test.fr_lo, 1, 'last');
i2 = find(test.f > test.fr_hi, 1, 'first');
if isempty(i1)
i1 = 1;
end
if isempty(i2)
i2 = length(test.f);
end
if test.plot_channels_combine
plot(test.f(i1:i2), test.m(i1:i2,:));
else
plot(test.f(i1:i2), test.m(i1:i2,i));
end
rp = 1.0;
if ~isempty(test.fr_rp_max_db)
rp = test.fr_rp_max_db;
hold on;
plot([test.fr_lo test.fr_hi], [-rp/2 -rp/2], 'r--');
plot([test.fr_lo test.fr_hi], [ rp/2 rp/2], 'r--');
hold off
end
axis([0 test.f_max -rp rp]);
grid on;
end
if test.plot_channels_combine
break
end
end
end