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

103 lines
3.3 KiB
Matlab

function test = fr_test_input(test)
%% t = fr_test_input(t)
%
% Create frequency sweep data file for playback & record on real device or
% for algorithm simulation.
%
% Input parameters
% t.f_max - maximum frequency of sweep, set e.g. to 0.99*fs/2
% t.fs - sample rate
% t.bits_in - number of bits in signal
% t.ch - mix test signal to channel ch, e.g. set to [1 2] to measure
% two channels
% t.nch - total number of channels in data
%
% Output parameters
% t.fn_in - Created input file name
% t.fn_out - Proposed output file name for captured output
% t.f_ref - Reference frequency used to report deviation (997 Hz)
% t.f_min - Sweep start frequency
% t.f - Frequencies in sweep
% t.is - Ignore signal from tone start
% t.ie - Ignore signal from tone end
% t.tr - tone gain ramp length in seconds
% t.sm - Seek start marker this time length from start
% t.em - Seek end marker this time length from end
% t.mt - Error if marker positions delta is greater than this
% t.tc - Min cycles of sine wave per frequency
% t.tl - Tone length in seconds
% t.a_db - Tone amplitude (dB)
% t.a - Tone amplitude (lin)
% t.nt - Number of samples per tone
% t.nf - Number of frequencies
% t.na - Number of amplitudes
% t.mark_t - Length of marker tone in seconds
% t.mark_a - Amplitude max of marker tone (lin)
% t.mark_a_db - Amplitude max of marker tone (dB)
% t.ts - Tone start times
%
% E.g.
% t.fs=48e3; t.f_max=20e3; t.bits_in=16; t.ch=1; t.nch=2; t = fr_test_input(t);
%
% SPDX-License-Identifier: BSD-3-Clause
% Copyright(c) 2016 Intel Corporation. All rights reserved.
% Author: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com>
%% Reference: AES17 6.2.3 Frequency response
% http://www.aes.org/publications/standards/
if nargin < 1
fprintf('Warning, using default parameters!\n');
test.fs = 48e3; test.f_max = 0.99*test.fs/2; test.ch=1; test.nch=1;
test.bits_in=32;
end
if test.ch == 0
test.ch = 1+round(rand(1,1)*(test.nch-1)); % Test random channel 1..Nch
end
fprintf('Using parameters Fmax=%.1f kHz, Fs=%.1f, ch=%d, Nch=%d, bits_in=%d\n', ...
test.f_max/1e3, test.fs/1e3, test.ch, test.nch, test.bits_in);
pid = getpid();
test.fn_in = sprintf('fr_test_in_%d.%s', pid, test.fmt);
test.fn_out = sprintf('fr_test_out_%d.%s', pid, test.fmt);
test.f_ref = 997;
test.f_min = 20;
%% Use a dense frequency grid to see -3 dB point well
if test.quick
n_oct = ceil(log(test.f_max/test.f_ref)/log(2)*6);
else
n_oct = ceil(log(test.f_max/test.f_ref)/log(2)*35);
end
f = logspace(log10(test.f_ref), log10(test.f_max), n_oct);
c = f(1)/f(2);
f_next = test.f_ref*c;
while (f_next > test.f_min)
f = [f_next f];
f_next = f_next*c;
end
test.f = f;
%% Tone sweep parameters
test.is = 20e-3; % Ignore signal from tone start
test.ie = 20e-3; % Ignore signal from tone end
test.tr = 10e-3; % Gain ramp time for tones
test.sm = 3; % Seek start marker from 3s from start
test.em = 3; % Seek end marker from 3s from end
test.mt = 0.1; % Error if marker positions delta is greater than 0.1s
test.tc = 10; % Min. 10 cycles of sine wave for a frequency
t_min = 0.1;
% Use t_min or min cycles count as tone length
test.tl = max(test.tc*1/min(f),t_min);
test.a_db = -20;
test.a = 10.^(test.a_db/20);
%% Mix the input file for test and write output
test = mix_sweep(test);
end