Mercurial > hg > aimc
view trunk/matlab/bmm/carfac/CARFAC_IHC_Step.m @ 617:2767ce76a1b0
Minor tweaks to AGC params, state update, and hacking script.
| author | dicklyon@google.com |
|---|---|
| date | Thu, 09 May 2013 18:24:51 +0000 |
| parents | 3e2e0ab4f708 |
| children |
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% Copyright 2012, Google, Inc. % Author: Richard F. Lyon % % This Matlab file is part of an implementation of Lyon's cochlear model: % "Cascade of Asymmetric Resonators with Fast-Acting Compression" % to supplement Lyon's upcoming book "Human and Machine Hearing" % % Licensed under the Apache License, Version 2.0 (the "License"); % you may not use this file except in compliance with the License. % You may obtain a copy of the License at % % http://www.apache.org/licenses/LICENSE-2.0 % % Unless required by applicable law or agreed to in writing, software % distributed under the License is distributed on an "AS IS" BASIS, % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % See the License for the specific language governing permissions and % limitations under the License. function [ihc_out, state] = CARFAC_IHC_Step(filters_out, coeffs, state); % function [ihc_out, state] = CARFAC_IHC_Step(filters_out, coeffs, state); % % One sample-time update of inner-hair-cell (IHC) model, including the % detection nonlinearity and one or two capacitor state variables. % AC couple the filters_out, with 20 Hz corner ac_diff = filters_out - state.ac_coupler; state.ac_coupler = state.ac_coupler + coeffs.ac_coeff * ac_diff; if coeffs.just_hwr ihc_out = min(2, max(0, ac_diff)); % limit it for stability else conductance = CARFAC_Detect(ac_diff); % rectifying nonlinearity if coeffs.one_cap; ihc_out = conductance .* state.cap_voltage; state.cap_voltage = state.cap_voltage - ihc_out .* coeffs.out_rate + ... (1 - state.cap_voltage) .* coeffs.in_rate; else % change to 2-cap version more like Meddis's: ihc_out = conductance .* state.cap2_voltage; state.cap1_voltage = state.cap1_voltage - ... (state.cap1_voltage - state.cap2_voltage) .* coeffs.out1_rate + ... (1 - state.cap1_voltage) .* coeffs.in1_rate; state.cap2_voltage = state.cap2_voltage - ihc_out .* coeffs.out2_rate + ... (state.cap1_voltage - state.cap2_voltage) .* coeffs.in2_rate; end % smooth it twice with LPF: ihc_out = ihc_out * coeffs.output_gain; state.lpf1_state = state.lpf1_state + coeffs.lpf_coeff * ... (ihc_out - state.lpf1_state); state.lpf2_state = state.lpf2_state + coeffs.lpf_coeff * ... (state.lpf1_state - state.lpf2_state); ihc_out = state.lpf2_state - coeffs.rest_output; end state.ihc_accum = state.ihc_accum + ihc_out; % for where decimated output is useful