tom@455: % Copyright 2012, Google, Inc.
tom@455: % Author: Richard F. Lyon
tom@455: %
tom@455: % This Matlab file is part of an implementation of Lyon's cochlear model:
tom@455: % "Cascade of Asymmetric Resonators with Fast-Acting Compression"
tom@455: % to supplement Lyon's upcoming book "Human and Machine Hearing"
tom@455: %
tom@455: % Licensed under the Apache License, Version 2.0 (the "License");
tom@455: % you may not use this file except in compliance with the License.
tom@455: % You may obtain a copy of the License at
tom@455: %
tom@455: %     http://www.apache.org/licenses/LICENSE-2.0
tom@455: %
tom@455: % Unless required by applicable law or agreed to in writing, software
tom@455: % distributed under the License is distributed on an "AS IS" BASIS,
tom@455: % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
tom@455: % See the License for the specific language governing permissions and
tom@455: % limitations under the License.
tom@455: 
tom@455: %% Test/demo hacking for CARFAC Matlab stuff:
tom@455: 
tom@455: clear variables
tom@455: 
tom@455: %%
tom@455: file_signal = wavread('plan.wav');
tom@455: 
tom@455: % file_signal = file_signal(9000+(1:10000));  % trim for a faster test
tom@455: file_signal = file_signal(9300+(1:5000));  % trim for a faster test
tom@455: 
tom@455: % repeat with negated signal to compare responses:
dicklyon@456: % file_signal = [file_signal; -file_signal];
tom@455: 
tom@455: % make a long test signal by repeating at different levels:
tom@455: test_signal = [];
dicklyon@456: for dB = -40:20:0  % -60:20:40  % -80:20:60
tom@455:   test_signal = [test_signal; file_signal * 10^(dB/20)];
tom@455: end
tom@455: 
tom@455: %%
tom@455: CF_struct = CARFAC_Design;  % default design
tom@455: 
tom@455: %% Run mono, then stereo test:
tom@455: 
tom@455: agc_plot_fig_num = 6;
tom@455: 
dicklyon@473: for n_ears = 1:2
dicklyon@473:   CF_struct = CARFAC_Init(CF_struct, n_ears);
tom@455: 
dicklyon@473:   [CF_struct, nap_decim, nap] = CARFAC_Run(CF_struct, test_signal, ...
dicklyon@473:     agc_plot_fig_num);
tom@455: 
tom@455: %   nap = deskew(nap);  % deskew doesn't make much difference
tom@455: 
dicklyon@473:   if n_ears == 1  % because this hack doesn't work for binarual yet
dicklyon@467:     MultiScaleSmooth(nap_decim, 4);
dicklyon@456:   end
tom@455: 
dicklyon@473:   % Display results for 1 or 2 ears:
dicklyon@473:   for ear = 1:n_ears
dicklyon@473:     smooth_nap = nap_decim(:, :, ear);
dicklyon@473:     if n_ears == 1
tom@455:       mono_max = max(smooth_nap(:));
tom@455:     end
dicklyon@473:     figure(3 + ear + n_ears)  % Makes figures 5, ...
tom@455:     image(63 * ((max(0, smooth_nap)/mono_max)' .^ 0.5))
tom@455:     title('smooth nap from nap decim')
tom@455:     colormap(1 - gray);
tom@455:   end
tom@455: 
tom@455:   % Show resulting data, even though M-Lint complains:
tom@455:   CF_struct
dicklyon@473:   CF_struct.CAR_state
tom@455:   CF_struct.AGC_state
tom@455:   min_max_decim = [min(nap_decim(:)), max(nap_decim(:))]
tom@455: 
tom@455:   % For the 2-channel pass, add a silent second channel:
tom@455:   test_signal = [test_signal, zeros(size(test_signal))];
tom@455: end
tom@455: 
tom@455: % Expected result:  Figure 3 looks like figure 2, a tiny bit darker.
tom@455: % and figure 4 is empty (all zero)