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function d = finddelay(x,y,varargin)
// This function returns the estimated delay between two input signals using crosscorrelation.
// If signals are periodic, delay with least absolute value is returned.
// Calling Sequence
// D = FINDDELAY(X,Y)
// D = FINDDELAY(...,MAXLAG)
// Description
// D = FINDDELAY(X,Y), returns estimated Delay D between X
// and Y. D is positive implies Y is delayed with respect to X and vice versa.
// If X, Y are matrices, then D is a row vector corresponding to delay between columns of X and Y
// D = FINDDELAY(...,MAXLAG), uses MAXLAG as the maximum correlation
// window size used to find the estimated delay(s) between X and Y:
//
// > If MAXLAG is an integer-valued scalar, and X and Y are row or column
// vectors or matrices, the vector D of estimated delays is found by
// cross-correlating (the columns of) X and Y over a range of lags
// -MAXLAG:MAXLAG.
// > If MAXLAG is an integer-valued row or column vector, and one input is vector
// and another be matirx (let X is a row or column vector ,
// and Y is a matrix) then the vector D of estimated delays is found by
// cross-correlating X and column J of Y over a range of lags
// -MAXLAG(J):MAXLAG(J), for J=1:Number of columns of Y.
// > If MAXLAG is an integer-valued row or column vector, and X and Y are
// both matrices. then vector D of estimated delays is found by
// cross-correlating corresponding columns of X and Y over a range of lags
// -MAXLAG(J):MAXLAG(J).
//
// By default, MAXLAG is equal to MAX(LX,LY)-1 for vectors,
// Examples
// X = [ 0 0 1 2 3 ];
// Y = [ 0 0 0 1 2 3];
// D = finddelay(X,Y,2)
// disp(D)
// X = [ 0 1 0 0 ; 1 0 2 1 ;0 0 0 2 ];
// Y = [ 0 0 1 0 ;1 0 0 2 ; 0 0 0 0 ];
// D = finddelay(X,Y)
// disp(D)
// See also
// alignsignals
// Authors
// Pola Lakshmi Priyanka, IIT Bombay//
//*************************************************************************************************************************************//
// Check number of input arguments
[out_a,inp_a]=argn(0)
if inp_a<=1 | inp_a>3 then
error('comm:finddelay: Invalid number of input arguments')
end
if out_a>1 then
error('comm:finddelay: Invalid number of output arguments')
end
//Error Checking of input arguments
if (~or(type(x)==[1 5 8]) | (isempty(x) ) | (ndims(x)>2) | ~or(type(y)==[1 5 8]) | (isempty(y) ) | (ndims(y)>2))
error('comm:finddelay:Input arguments must be numeric');
end
if isvector(x)
x = x';
end
if isvector(y)
y = y';
end
[row_x,col_x] = size(x);
[row_y,col_y] = size(y);
x = double(x);
y = double(y);
// Check if matrices are of compatible
if ~isvector(x) & ~isvector(y)
if col_x~=col_y
error('comm:finddelay:When both inputs are matrices, they must have the same number of columns.')
end
end
// Check for maxlag
if inp_a==3
if ( ndims(varargin(1))>2 | ~isreal(varargin(1)) | isempty(varargin(1)) | or(isnan(varargin(1))) | or(isinf(varargin(1))) | varargin(1) ~= ceil(varargin(1))),
error('comm:finddelay:Input argument 3 should be a finite integer vector')
end
if ( (isvector(x)) & (isvector(y)) & (length(varargin(1))>1) )
error('comm:finddelay: If x and y are both vectors, maxlag should be a scalar')
elseif ( (isvector(y)) & (length(varargin(1))>1) & (length(varargin(1))~=col_x) ),
error('comm:finddelay: If maxlag is a row/column vector, it should be of same length as the number of columns of X or Y');
elseif ( (isvector(x)) & (length(varargin(1))>1) & (length(varargin(1))~=col_y) ),
error('comm:finddelay: If maxlag is a row/column vector, it should be of same length as the number of columns of X or Y');
elseif ( (length(varargin(1))>1) & (length(varargin(1))~=col_x) & (length(varargin(1))~=col_y) ),
error('comm:finddelay: If X and Y are matrices, MAXLAG should be the same length as the number of columns of X and Y.');
else
if isempty(varargin(1))
maxlag = max(row_x,row_y)-1; //default value
else
maxlag = double(abs(varargin(1)));
end
end
else
maxlag = max(row_x,row_y)-1;
end
max_col=max(col_x,col_y);
if (length(maxlag)==1)
maxlag = repmat(maxlag,1,max_col);
end
if col_x<max_col
x = repmat(x,1,max_col);
elseif col_y<max_col
y = repmat(y,1,max_col);
end
// Initialise cross-correlation matrix .
maxlag_max = max(maxlag);
c_normalized = zeros(2*maxlag_max+1,max_col);
index_max = zeros(1,max_col);
max_c = zeros(1,max_col);
// Compute cross-correlation matrix:
sq_x = abs(x).^2
sq_y = abs(y).^2
cxx0 = sum(sq_x,"r");
cyy0 = sum(sq_y,"r");
for i = 1:max_col
if ( (cxx0(i)==0) | (cyy0(i)==0) )
c_normalized(:,i) = zeros(2*maxlag_max+1,1);
else
c_normalized(maxlag_max-maxlag(i)+1:maxlag_max-maxlag(i)+2*maxlag(i)+1,i) ...
= abs(xcorr(x(:,i),y(:,i),maxlag(i)))/sqrt(cxx0(i)*cyy0(i));
end
end
// Find lowest positive or zero indices of lags (negative delays) giving the
// largest absolute values of normalized cross-correlations.
[max_pos,index_max_pos] = max(c_normalized(maxlag_max+1:$,:),"r");
// Find lowest negative indices of lags (positive delays) giving the largest
// absolute values of normalized cross-correlations.
A=c_normalized(1:maxlag_max,:)
[max_neg,index_max_neg] = max(A($:-1:1,:),"r");
if isempty(max_neg)
index_max = maxlag_max + index_max_pos;
else
for i=1:max_col
if max_pos(i)>max_neg(i)
index_max(i) = maxlag_max + index_max_pos(i);
max_c(i) = max_pos(i);
elseif max_pos(i)<max_neg(i)
index_max(i) = maxlag_max + 1 - index_max_neg(i);
max_c(i) = max_neg(i);
elseif max_pos(i)==max_neg(i)
if index_max_pos(i)<=index_max_neg(i)
index_max(i) = maxlag_max + index_max_pos(i);
max_c(i) = max_pos(i);
else
index_max(i) = maxlag_max + 1 - index_max_neg(i);
max_c(i) = max_neg(i);
end
end
end
end
// Subtract delays.
d = (maxlag_max + 1) - index_max;
endfunction
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