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annotate trunk/matlab/bmm/carfac/CARFAC_Run_Segment.m @ 536:2964a3b4a00a

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New design params, including narrower AGC, Greenwood map for more channels, default 71, some renaming, open loop feature, ...
author dicklyon@google.com
date Thu, 22 Mar 2012 22:37:56 +0000
parents 95a11cca4619
children 89b1fe5de60f
rev   line source
dicklyon@534 1 % Copyright 2012, Google, Inc.
dicklyon@534 2 % Author Richard F. Lyon
dicklyon@534 3 %
dicklyon@534 4 % This Matlab file is part of an implementation of Lyon's cochlear model:
dicklyon@534 5 % "Cascade of Asymmetric Resonators with Fast-Acting Compression"
dicklyon@534 6 % to supplement Lyon's upcoming book "Human and Machine Hearing"
dicklyon@534 7 %
dicklyon@534 8 % Licensed under the Apache License, Version 2.0 (the "License");
dicklyon@534 9 % you may not use this file except in compliance with the License.
dicklyon@534 10 % You may obtain a copy of the License at
dicklyon@534 11 %
dicklyon@534 12 % http://www.apache.org/licenses/LICENSE-2.0
dicklyon@534 13 %
dicklyon@534 14 % Unless required by applicable law or agreed to in writing, software
dicklyon@534 15 % distributed under the License is distributed on an "AS IS" BASIS,
dicklyon@534 16 % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
dicklyon@534 17 % See the License for the specific language governing permissions and
dicklyon@534 18 % limitations under the License.
dicklyon@534 19
dicklyon@536 20 function [naps, CF, BM] = CARFAC_Run_Segment(CF, input_waves, open_loop)
dicklyon@536 21 % function [naps, CF, BM] = CARFAC_Run_Segment(CF, input_waves, open_loop)
dicklyon@534 22 %
dicklyon@534 23 % This function runs the CARFAC; that is, filters a 1 or more channel
dicklyon@534 24 % sound input segment to make one or more neural activity patterns (naps);
dicklyon@534 25 % it can be called multiple times for successive segments of any length,
dicklyon@534 26 % as long as the returned CF with modified state is passed back in each
dicklyon@534 27 % time.
dicklyon@534 28 %
dicklyon@534 29 % input_waves is a column vector if there's just one audio channel;
dicklyon@534 30 % more generally, it has a row per time sample, a column per audio channel.
dicklyon@534 31 %
dicklyon@534 32 % naps has a row per time sample, a column per filterbank channel, and
dicklyon@534 33 % a layer per audio channel if more than 1.
dicklyon@536 34 % BM is basilar membrane motion (filter outputs before detection).
dicklyon@534 35 %
dicklyon@534 36 % the input_waves are assumed to be sampled at the same rate as the
dicklyon@534 37 % CARFAC is designed for; a resampling may be needed before calling this.
dicklyon@534 38 %
dicklyon@534 39 % The function works as an outer iteration on time, updating all the
dicklyon@534 40 % filters and AGC states concurrently, so that the different channels can
dicklyon@534 41 % interact easily. The inner loops are over filterbank channels, and
dicklyon@534 42 % this level should be kept efficient.
dicklyon@534 43 %
dicklyon@534 44 % See other functions for designing and characterizing the CARFAC:
dicklyon@534 45 % CF = CARFAC_Design(fs, CF_CAR_params, CF_AGC_params, n_ears)
dicklyon@534 46 % transfns = CARFAC_Transfer_Functions(CF, to_chans, from_chans)
dicklyon@534 47
dicklyon@536 48 if nargin < 3
dicklyon@536 49 open_loop = 0;
dicklyon@536 50 end
dicklyon@536 51
dicklyon@536 52 if nargout > 2
dicklyon@536 53 do_BM = 1;
dicklyon@536 54 else
dicklyon@536 55 do_BM = 0;
dicklyon@536 56 end
dicklyon@536 57
dicklyon@534 58 [n_samp, n_ears] = size(input_waves);
dicklyon@534 59
dicklyon@534 60 if n_ears ~= CF.n_ears
dicklyon@534 61 error('bad number of input_waves channels passed to CARFAC_Run')
dicklyon@534 62 end
dicklyon@534 63
dicklyon@534 64 n_ch = CF.n_ch;
dicklyon@534 65 naps = zeros(n_samp, n_ch, n_ears); % allocate space for result
dicklyon@536 66 if do_BM
dicklyon@536 67 BM = zeros(n_samp, n_ch, n_ears);
dicklyon@536 68 end
dicklyon@534 69
dicklyon@534 70 detects = zeros(n_ch, n_ears);
dicklyon@534 71 for k = 1:n_samp
dicklyon@534 72 % at each time step, possibly handle multiple channels
dicklyon@534 73 for ear = 1:n_ears
dicklyon@534 74 [car_out, CF.CAR_state(ear)] = CARFAC_CAR_Step( ...
dicklyon@534 75 input_waves(k, ear), CF.CAR_coeffs, CF.CAR_state(ear));
dicklyon@534 76
dicklyon@534 77 % update IHC state & output on every time step, too
dicklyon@534 78 [ihc_out, CF.IHC_state(ear)] = CARFAC_IHC_Step( ...
dicklyon@534 79 car_out, CF.IHC_coeffs, CF.IHC_state(ear));
dicklyon@534 80
dicklyon@534 81 detects(:, ear) = ihc_out; % for input to AGC, and out to SAI
dicklyon@534 82 naps(k, :, ear) = ihc_out; % output to neural activity pattern
dicklyon@536 83 if do_BM
dicklyon@536 84 BM(k, :, ear) = car_out;
dicklyon@536 85 end
dicklyon@534 86 end
dicklyon@534 87 % run the AGC update step, taking input from IHC_state,
dicklyon@534 88 % decimating internally, all ears at once due to mixing across them:
dicklyon@534 89 [CF.AGC_state, updated] = CARFAC_AGC_Step( ...
dicklyon@534 90 CF.AGC_coeffs, detects, CF.AGC_state);
dicklyon@534 91
dicklyon@534 92 % connect the feedback from AGC_state to CAR_state when it updates
dicklyon@536 93 if updated & ~open_loop
dicklyon@534 94 CF = CARFAC_Close_AGC_Loop(CF);
dicklyon@534 95 end
dicklyon@534 96 end
dicklyon@534 97