Mercurial > hg > ltpda
view m-toolbox/classes/+utils/@math/lp2z.m @ 51:9d5c88356247 database-connection-manager
Make unit tests database connection parameters configurable
author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Wed, 07 Dec 2011 17:24:37 +0100 |
parents | f0afece42f48 |
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% LP2Z converts a continous TF in to a discrete TF. % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DESCRIPTION: LP2Z converts a continous (lapalce notation) transfer % function in a discrete (z transfor formalism) partial fractioned transfer % function. % % Input function can be in rational, poles and zeros or partial fractions % form: % The rational case assumes an input function of the type: % % a(1)s^m + a(2)s^{m-1} + ... + a(m+1) % H(s) = -------------------------------------- % b(1)s^n + b(2)s^{n-1} + ... + b(n+1) % % The poles and zeros case assumes an impution function of the type: % % (s-Z(1))(s-Z(2))...(s-Z(n)) % H(s) = K --------------------------- % (s-P(1))(s-P(2))...(s-P(n)) % % The partail fraction case assumes an input function of the type: % % R(1) R(2) R(n) % H(s) = -------- + -------- + ... + -------- + K(s) % s - P(1) s - P(2) s - P(n) % % LP2Z function is also capable to handling input transfer functions with % multiple poles. % % % % CALL: % pfstruct = lp2z(varargin) % [res,poles,dterm] = lp2z(varargin) % [pfstruct,res,poles,dterm] = lp2z(varargin) % % % % INPUTS: % Input parameters are: % 'FS' sampling frequency % 'RRTOL' the repeated-root tolerance, default value is % 1e-15. If two roots differs less than rrtolerance value, they % are reported as multiple roots. % 'INOPT' define the input function type % 'PF' use this option if you want to input a function % expanded in partial fractions. Then you have to input the % vectors containing: % 'RES' the vector containig the residues % 'POLES' The vector containing the poles % 'DTERMS' The vector containing the direct terms % 'RAT' input the continous function in rational form. % then you have to input the vector of coefficients: % 'NUM' is the vector with numerator coefficients. % 'DEN' is the vector of denominator coefficienets. % 'PZ' input the continuous function in poles and % zeros form. Then you have to input the vectors with poles % and zeros: % 'POLES' the vector with poles % 'ZEROS' the vector with zeros % 'GAIN' the value of the gain % 'MODE' Is the mode used for the calculation of the roots of a % polynomial. Admitted values are: % 'SYM' uses symbolic roots calculation (you need Symbolic % Math Toolbox to use this option) % 'DBL' uses the standard numerical matlab style roots % claculation (double precision) % % % OUTPUTS: % Function output is a structure array with two fields: 'num' and % 'den' respectively. Each term of the partial fraction expansion % can be seen as rational transfer function in z domain. These % reduced transfer functions can be used to filter in parallel a % series of data. This representation is particularly useful when % poles with multiplicity higher than one are present. In this % case the corresponding terms of the partial fraction expansion % are really rational transfer functions whose order depends from % the pole multiplicity [1]. % As a sencond option residues, poles and direct term are output % as standard vectors (this possibility works only with simple % poles). % The third possibility is to call the function with four output, % 1st is a struct, 2nd are residues, 3rd are ples and 4th is the % direct term. % % NOTE1: The function is capable to convert in partial fractions % only rational functions with numerator of order lower or equal % to the order of the denominator. When the order of the % numerator is higher than the order of the denominator (improper % rational functions) the expansion in partial fractions is not % useful and other methods are preferable. % % NOTE2: 'SYM' calculation mode requires Symbolic Math Toolbox % to work % % % % REFERENCES: % [1] Alan V. Oppenheim, Allan S. Willsky and Ian T. Young, Signals % and Systems, Prentice-Hall Signal Processing Series, Prentice % Hall (June 1982), ISBN-10: 0138097313. Pages 767 - 776. % % % VERSION $Id: lp2z.m,v 1.11 2009/02/10 12:14:29 luigi Exp $ % % HISTORY: 16-04-2008 L Ferraioli % Creation % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function varargout = lp2z(varargin) %% Finding input parameters % Default values for the parameters fs = 10; inopt = 'RAT'; tol = 1e-15; mode = 'DBL'; % Finding input parameters if ~isempty(varargin) for j=1:length(varargin) if strcmp(varargin{j},'INOPT') inopt = varargin{j+1}; end if strcmp(varargin{j},'FS') fs = varargin{j+1}; end if strcmp(varargin{j},'MODE') mode = varargin{j+1}; end if strcmp(varargin{j},'RRTOL') tol = varargin{j+1}; end end end %% Conversion to partial fractions and discretization % swithing between input options switch inopt case 'RAT' % Finding proper parameters for jj=1:length(varargin) if strcmp(varargin{jj},'NUM') num = varargin{jj+1}; end if strcmp(varargin{jj},'DEN') den = varargin{jj+1}; end end % conversion in partail fractions cP is the vector of residues, cP is the % vector of poles and cK is the vector of direct terms [cR, cP, cK, mul] = utils.math.cpf('INOPT', 'RAT', 'NUM', num,... 'DEN', den, 'MODE', mode, 'RRTOL', tol); case 'PZ' % Finding proper parameters for jj=1:length(varargin) if strcmp(varargin{jj},'ZEROS') zer = varargin{jj+1}; end if strcmp(varargin{jj},'POLES') pol = varargin{jj+1}; end if strcmp(varargin{jj},'GAIN') gain = varargin{jj+1}; end end % conversion in partail fractions cP is the vector of residues, cP is the % vector of poles and cK is the vector of direct terms [cR, cP, cK, mul] = utils.math.cpf('INOPT', 'PZ', 'ZEROS', zer,... 'POLES', pol, 'GAIN', gain, 'RRTOL', tol); case 'PF' % Finding proper parameters for jj=1:length(varargin) if strcmp(varargin{jj},'RES') cR = varargin{jj+1}; end if strcmp(varargin{jj},'POLES') cP = varargin{jj+1}; end if strcmp(varargin{jj},'DTERMS') cK = varargin{jj+1}; end end % finding poles multiplicity mul = mpoles(cP,tol,0); end % Checking for not proper functions if length(cK)>1 error('Unable to directly discretize not proper continuous functions ') end % disctretization T = 1/fs; dpls = exp(cP.*T); % poles discretization % Construct a struct array in which the elements of the partial % fractions expansion are stored. Each partial fraction can be % considered as rational function with proper numerator and denominator % coefficients pfstruct = struct(); indxmul = 0; for kk=1:length(mul) if mul(kk)==1 pfstruct(kk).num = cR(kk).*T; pfstruct(kk).den = [1 -1*dpls(kk)]; else coeffs = PolyLogCoeffs(1-mul(kk),exp(cP(kk)*T)); coeffs = flipdim(coeffs,2); pfstruct(kk).num = (cR(kk)*T^mul(kk)/prod(1:mul(kk)-1)).*coeffs; pfstruct(kk).den = BinomialExpansion(mul(kk),exp(cP(kk)*T)); indxmul = 1; end end % Inserting the coefficients relative to the presence of a direct term if ((length(cK)==1)&&(not(cK(1)==0))) pfstruct(length(mul)+1).num = cK.*T; pfstruct(length(mul)+1).den = [1 0]; end % Output also the vector of residues, poles and direct term if non multiple % poles are found if indxmul == 0 res = cR.*T; poles = dpls; dterm = cK.*T; else res = []; poles = []; dterm = []; end % Output empty fields struct in case of no input if isempty(cR)||isempty(cP) pfstruct.num = []; pfstruct.den = []; end %% Output data if indxmul == 1 disp( ' Found poles with multiplicity higher than one. Results are output in struct form only. ') end if nargout == 1 varargout{1} = pfstruct; elseif nargout == 3 varargout{1} = res; varargout{2} = poles; varargout{3} = dterm; elseif nargout == 4 varargout{1} = pfstruct; varargout{2} = res; varargout{3} = poles; varargout{4} = dterm; else error('Unespected number of outputs! Output must be 1, 3 or 4') end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FUNCTION: Eulerian Number % % DESCRIPTION: Calculates the Eulerian Number % % HISTORY: 12-05-2008 L Ferraioli % Creation % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function enum = eulerian(n,k) enum = 0; for jj = 0:k+1; enum = enum + ((-1)^jj)*(prod(1:n+1)/(prod(1:n+1-jj)*prod(1:jj)))*(k-jj+1)^n; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FUNCTION: PloyLogCoeffs % % DESCRIPTION: Computes the coefficients of a poly-logarithm expansion for % negative n values % % HISTORY: 12-05-2008 L Ferraioli % Creation %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function coeffs = PolyLogCoeffs(n,x) if n>=0 error('n must be a negative integer!') else % Now we keep the absolute value of n n = -1*n; end coeffs = []; for ii=0:n; coeffs = [coeffs eulerian(n,ii)*(x^(n-ii))]; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FUNCTION: BinomialExpansion % % DESCRIPTION: Performs the binomial expamsion of the expression (1-x)^n % % HISTORY: 12-05-2008 L Ferraioli % Creation %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function binexp = BinomialExpansion(n,x) binexp = []; for jj=0:n binexp = [binexp ((-1)^jj)*(prod(1:n)/(prod(1:n-jj)*prod(1:jj))*(x^jj))]; end