Mercurial > hg > ltpda
view m-toolbox/classes/@pzmodel/pzm2ab.m @ 1:2014ba5b353a database-connection-manager
Remove old code
author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Sat, 03 Dec 2011 18:13:55 +0100 |
parents | f0afece42f48 |
children |
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% PZM2AB convert pzmodel to IIR filter coefficients using bilinear transform. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DESCRIPTION: PZM2AB convert pzmodel to IIR filter coefficients using bilinear % transform. % % CALL: [a,b] = pzm2ab(pzm, fs) % % VERSION: $Id: pzm2ab.m,v 1.10 2009/08/31 17:11:41 ingo Exp $ % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function varargout = pzm2ab(varargin) import utils.const.* %%% Collect input variable names in_names = cell(size(varargin)); for ii = 1:nargin,in_names{ii} = inputname(ii);end %%% Collect all AOs and plists [pzm, pzm_invars, fs] = utils.helper.collect_objects(varargin(:), 'pzmodel', in_names); %%% Check inputs if numel(pzm) ~= 1 error('### Please use only one PZ-Model.'); end if numel(fs) ~= 1 && ~isnumeric(fs) error('### Please define ''fs''.'); else fs = fs{1}; end gain = pzm.gain; poles = pzm.poles; zeros = pzm.zeros; np = numel(poles); nz = numel(zeros); ao = []; bo = []; utils.helper.msg(utils.const.msg.OPROC1, 'converting %s', pzm.name) % First we should do complex pole/zero pairs cpoles = []; for j=1:np if poles(j).q > 0.5 cpoles = [cpoles poles(j)]; end end czeros = []; for j=1:nz if zeros(j).q > 0.5 czeros = [czeros zeros(j)]; end end czi = 1; for j=1:length(cpoles) if czi <= length(czeros) % we have a pair p = cpoles(j); z = czeros(czi); [ai,bi] = cpolezero(p.f, p.q, z.f, z.q, fs); if ~isempty(ao) [ao,bo] = pzmodel.abcascade(ao,bo,ai,bi); else ao = ai; bo = bi; end % increment zero counter czi = czi + 1; end end if length(cpoles) > length(czeros) % do remaining cpoles for j=length(czeros)+1:length(cpoles) utils.helper.msg(msg.OPROC2, 'computing complex pole'); [ai,bi] = cp2iir(cpoles(j), fs); if ~isempty(ao) [ao,bo] = pzmodel.abcascade(ao,bo,ai,bi); else ao = ai; bo = bi; end end else % do remaining czeros for j=length(cpoles)+1:length(czeros) utils.helper.msg(msg.OPROC2, 'computing complex zero'); [ai,bi] = cz2iir(czeros(j), fs); if ~isempty(ao) [ao,bo] = pzmodel.abcascade(ao,bo,ai,bi); else ao = ai; bo = bi; end end end % Now do the real poles and zeros for j=1:np pole = poles(j); if isnan(pole.q) || pole.q < 0.5 utils.helper.msg(msg.OPROC2, 'computing real pole'); [ai,bi] = rp2iir(pole, fs); if ~isempty(ao) [ao,bo] = pzmodel.abcascade(ao,bo,ai,bi); else ao = ai; bo = bi; end end end for j=1:nz zero = zeros(j); if isnan(zero.q) || zero.q < 0.5 utils.helper.msg(msg.OPROC2, 'computing real zero'); [ai,bi] = rz2iir(zero, fs); if ~isempty(ao) [ao,bo] = pzmodel.abcascade(ao,bo,ai,bi); else ao = ai; bo = bi; end end end ao = ao.*gain; varargout{1} = ao; varargout{2} = bo; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Local Functions % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FUNCTION: cpolezero % % DESCRIPTION: Return IIR filter coefficients for a complex pole and % complex zero designed using the bilinear transform. % % CALL: [a,b] = cpolezero(pf, pq, zf, zq, fs) % % HISTORY: 18-02-2007 M Hewitson % Creation. % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function [a,b] = cpolezero(pf, pq, zf, zq, fs) import utils.const.* utils.helper.msg(msg.OPROC1, 'computing complex pole/zero pair'); wp = pf*2*pi; wp2 = wp^2; wz = zf*2*pi; wz2 = wz^2; k = 4*fs*fs + 2*wp*fs/pq + wp2; a(1) = (4*fs*fs + 2*wz*fs/zq + wz2)/k; a(2) = (2*wz2 - 8*fs*fs)/k; a(3) = (4*fs*fs - 2*wz*fs/zq + wz2)/k; b(1) = 1; b(2) = (2*wp2 - 8*fs*fs)/k; b(3) = (wp2 + 4*fs*fs - 2*wp*fs/pq)/k; % normalise dc gain to 1 g = iirdcgain(a,b); a = a / g; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FUNCTION: iirdcgain % % DESCRIPTION: Work out the DC gain of an IIR filter given the coefficients. % % CALL: g = iirdcgain(a,b) % % INPUTS: a - numerator coefficients % b - denominator coefficients % % OUTPUTS g - gain % % HISTORY: 03-07-2002 M Hewitson % Creation. % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function g = iirdcgain(a,b) suma = sum(a); if(length(b)>1) sumb = sum(b); g = suma / sumb; else g = suma; end end