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: function CF_struct = CARFAC_Init(CF_struct, n_mics) tom@455: % function CF_struct = CARFAC_Init(CF_struct, n_mics) tom@455: % tom@455: % Initialize state for n_mics channels (default 1). tom@455: % This allocates and zeros all the state vector storage in the CF_struct. tom@455: tom@455: % TODO (dicklyon): Review whether storing state in the same struct as tom@455: % the design is a good thing, or whether we want another tom@455: % level of object. I like fewer structs and class types. tom@455: tom@455: if nargin < 2 tom@455: n_mics = 1; % monaural tom@455: end tom@455: tom@455: % % this is probably what I'd do in the C++ version: tom@455: % if CF_struct.n_mics ~= n_mics; tom@455: % % free the state and make new number of channels tom@455: % % make a struct arrray, one element per mic channel, numbered: tom@455: % for k = 1:n_mics tom@455: % CF_struct.state(k) = struct('mic_number', k); tom@455: % end tom@455: % end tom@455: % But this code doesn't work because I don't understand struct arrays. tom@455: tom@455: % For now I don't ever free anything if n_mics is reduced; tom@455: % so be sure to respect n_mics, not the size of the state struct array. tom@455: tom@455: AGC_time_constants = CF_struct.AGC_params.time_constants; tom@455: n_AGC_stages = length(AGC_time_constants); tom@455: tom@455: CF_struct.n_mics = n_mics; tom@455: CF_struct.k_mod_decim = 0; % time index phase, cumulative over segments tom@455: tom@455: % This zeroing grows the struct array as needed: tom@455: for mic = 1:n_mics tom@455: CF_struct.filter_state(mic).z1_memory = zeros(CF_struct.n_ch, 1); tom@455: CF_struct.filter_state(mic).z2_memory = zeros(CF_struct.n_ch, 1); tom@455: % cubic loop tom@455: CF_struct.filter_state(mic).zA_memory = zeros(CF_struct.n_ch, 1); tom@455: % AGC interp tom@455: CF_struct.filter_state(mic).zB_memory = zeros(CF_struct.n_ch, 1); tom@455: % AGC incr tom@455: CF_struct.filter_state(mic).dzB_memory = zeros(CF_struct.n_ch, 1); tom@455: CF_struct.filter_state(mic).zY_memory = zeros(CF_struct.n_ch, 1); tom@455: CF_struct.filter_state(mic).detect_accum = zeros(CF_struct.n_ch, 1); tom@455: % AGC loop filters' state: tom@455: % HACK init tom@455: CF_struct.AGC_state(mic).AGC_memory = zeros(CF_struct.n_ch, n_AGC_stages); tom@455: CF_struct.AGC_state(mic).AGC_sum = zeros(CF_struct.n_ch, 1); tom@455: % IHC state: tom@455: if CF_struct.IHC_coeffs.just_hwr tom@455: CF_struct.IHC_state(mic).ihc_accum = zeros(CF_struct.n_ch, 1); tom@455: else tom@455: CF_struct.IHC_state(mic).cap_voltage = ... tom@455: CF_struct.IHC_coeffs(mic).rest_cap * ones(CF_struct.n_ch, 1); tom@455: CF_struct.IHC_state(mic).cap1_voltage = ... tom@455: CF_struct.IHC_coeffs(mic).rest_cap1 * ones(CF_struct.n_ch, 1); tom@455: CF_struct.IHC_state(mic).cap2_voltage = ... tom@455: CF_struct.IHC_coeffs(mic).rest_cap2 * ones(CF_struct.n_ch, 1); tom@455: CF_struct.IHC_state(mic).lpf1_state = ... tom@455: CF_struct.IHC_coeffs(mic).rest_output * zeros(CF_struct.n_ch, 1); tom@455: CF_struct.IHC_state(mic).lpf2_state = ... tom@455: CF_struct.IHC_coeffs(mic).rest_output * zeros(CF_struct.n_ch, 1); tom@455: CF_struct.IHC_state(mic).ihc_accum = zeros(CF_struct.n_ch, 1); tom@455: end tom@455: end tom@455: tom@455: