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function [y, h] = resample( x, p, q, h )
//This function resamples in the input sequence x supplied by a factor of p/q.
//Calling Sequence
//y = resample(x, p, q)
//y = resample(x, p, q, h)
//[y, h] = resample(...)
//Parameters
//x: scalar, vector or matrix of real or complex numbers
//p: positive integer value
//q: positive integer value
//h: scalar, vector or matrix of real or complex numbers
//Description
//This is an Octave function.
//This function resamples in the input sequence x supplied by a factor of p/q. If x is a matrix, then every column is resampled.hange the sample rate of x by a factor of p/q.
//This is performed using a polyphase algorithm. The impulse response h, given as parameter 4, of the antialiasing filter is either specified or designed with a Kaiser-windowed sinecard.
//Examples
//resample(1,2,3)
//ans = 0.66667
funcprot(0);
rhs = argn(2)
lhs = argn(1)
if(rhs<3 | rhs>4)
error("Wrong number of input arguments.")
end
select(rhs)
case 3 then
if(lhs==1)
y = callOctave("resample",x,p,q)
elseif(lhs==2)
[y,h] = callOctave("resample",x,p,q)
end
case 4 then
if(lhs==1)
y = callOctave("resample",x,p,q,h)
elseif(lhs==2)
[y,h] = callOctave("resample",x,p,q,h)
end
end
endfunction
//**************************************************************************************************
//Tried to impement without callOctave but fot this it requires ufirdn function which implemented in .cc file in octave, simple implementation of upfirdn doesn't work for resample function
//**************************************************************************************************
//function [y, h] = resample( x, p, q, h )
// nargin = argn(2);
//
// [rows, columns] = size(x) ;
//
// if nargin < 3 | nargin > 4
// error("resample.sci : invalid number of inputs");
// elseif or([p q]<=0) | or([p q]~=floor([p q])),
// error("resample.sci: p and q must be positive integers");
// end
//
//// ## simplify decimation and interpolation factors
//
// great_common_divisor=gcd([p,q]);
// if (great_common_divisor>1)
// p = double(p) / double (great_common_divisor);
// q = double(q) / double (great_common_divisor);
// else
// p = double(p);
// q = double(q);
// end
//
//// ## filter design if required
//
// if (nargin < 4)
//
//// ## properties of the antialiasing filter
//
// log10_rejection = -3.0;
// stopband_cutoff_f = 1 / (2 * max (p, q));
// roll_off_width = stopband_cutoff_f / 10.0;
//
//// ## determine filter length
//// ## use empirical formula from [2] Chap 7, Eq. (7.63) p 476
//
// rejection_dB = -20.0*log10_rejection;
// L = ceil((rejection_dB-8.0) / (28.714 * roll_off_width));
//
//// ## ideal sinc filter
//
// t=(-L:L)';
// ideal_filter=2*p*stopband_cutoff_f*sinc(2*stopband_cutoff_f*t);
//
//// ## determine parameter of Kaiser window
//// ## use empirical formula from [2] Chap 7, Eq. (7.62) p 474
//
// if ((rejection_dB>=21) & (rejection_dB<=50))
// beta = 0.5842 * (rejection_dB-21.0)^0.4 + 0.07886 * (rejection_dB-21.0);
// elseif (rejection_dB>50)
// beta = 0.1102 * (rejection_dB-8.7);
// else
// beta = 0.0;
// end
//
//// ## apodize ideal filter response
//
// h=kaiser(2*L+1,beta).*ideal_filter;
//
// end
//
//// ## check if input is a row vector
// isrowvector=%F;
// if ((rows==1) & (columns>1))
// x=x(:);
// isrowvector=%T;
// end
//
//// ## check if filter is a vector
// if ~isvector(h)
// error("resample.sci: the filter h should be a vector");
// end
//
// Lx = rows;
// Lh = length(h);
// L = ( Lh - 1 )/2.0;
// Ly = ceil(Lx*p/q);
//
//// ## pre and postpad filter response
//
// nz_pre = floor(q-pmodulo(L,q));
//// hpad = prepad(h,Lh+nz_pre);
// hpad = h ;
// for i = 1:Lh+nz_pre-length(h)
// hpad = [0;hpad];
// end
//
// offset = floor((L+nz_pre)/q);
// nz_post = 0;
// while ceil( ( (Lx-1)*p + nz_pre + Lh + nz_post )/q ) - offset < Ly
// nz_post = nz_post + 1;
// end
//
// //hpad = postpad(hpad,Lh + nz_pre + nz_post);
// for i = 1:Lh + nz_pre + nz_post-length(hpad)
// hpad = [hpad;0];
// end
//
//// ## filtering
// xfilt = upfirdn(x,hpad,p,q);
// y = xfilt(offset+1:offset+Ly,:);
//
// if isrowvector,
// y=y.';
// end
//
//endfunctio
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