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// Date of creation: 20 Jan, 2016
function [w,pow] = rootmusic(x,p,varargin)
// Frequencies and power of sinusoids using the root MUSIC algorithm
//
// Calling Sequence
// w = rootmusic(x,p)
// [w,pow] = rootmusic(x,p)
// [f,pow] = rootmusc(...,fs)
// [w,pow] = rootmusic(...,'corr')
//
// Parameters
// x - int|double - vector|matrix
// Input signal.
// If x is a vector, then it reprsenets one realization of the signal.
// If x is a matrix, then each row represents a separate observation of
// the signal.
// p - int|double - scalar|2 element vector
// p(1) is the signal subspace dimension and hence the number of
// complex exponentials in x.
// p(2), if specified, represents a threshold that is multiplied by
// the smallest estimated eigenvalue of the signal's correlation
// matrix.
// fs - int|double - scalar
// Sampling frequency (in Hz)
// If fs is specified by an empty vector or unspecified, it defaults
// to 1 Hz
// 'corr' flag
// If specified, x is interpreted as a correlation matrix rather than
// a matrix of the signal data. For x to be a correlation matrix,
// x must be a square matrix and all its eigenvalues must be
// nonnegative
//
// Examples:
// 1) 3 complex exponentials:
//
// n=0:99;
// s=exp(1*%i*%pi/2*n)+2*exp(1*%i*%pi/4*n)+exp(1*%i*%pi/3*n)+rand(1,100,"normal");
// [A,R]=corrmtx(s,12,'mod');
// [W,P] = rootmusic(R,3,'corr');
// //2)
// n=0:99;
// s=exp(1*%i*%pi/2*n)+2*exp(1*%i*%pi/4*n)+exp(1*%i*%pi/3*n);
// [A,R]=corrmtx(s,12,'mod');
// [W,P] = rootmusic(R,3,'corr');
//EXPECTED OUTPUT:
//W = 0.7738111 1.5690374 1.0426234
//P =377.4255 103.18124 123.86659
//
// Author
// Ayush
//
// See also
// corrmtx | peig | pmusic | rooteig
//
// References
// 1) Monson H. Hayes, Statistical Digital Signal Processing And Modeling,
// Wiley & Sons, Inc, [Section 8.6.3]
//
//
// Output arguments
// w - double - vector
// Estimated frequencies of the complex sinusoids
// pow - double - vector
// estimated absolute value squared amplitudes of the sinusoids at
// the frequencies w
//
funcprot(0);
//exec('/home/shashi/Desktop/FOSSEE-Signal-Processing-Toolbox-master/macros/musicBase.sci',-1);
//exec('/home/shashi/Desktop/FOSSEE-Signal-Processing-Toolbox-master/macros/nnls.sci',-1);
// **** checking the number of input and output arguments ****
[numOutArgs, numInArgs] = argn(0);
if numOutArgs~=1 & numOutArgs~=2 then
error(78,"rootmusic");
end
if numInArgs<1 | numInArgs>4 then
error(77,"rootmusic");
end
// **** parsing the input arguments ****
isFsSpecified = %F;
fs = [];
varargLength = length(varargin);
// searching for the 'corr' flag
isCorrFlag = %F;
if varargLength==0 then
stringIndices = [];
else
stringIndices = find(type(varargin(1:varargLength))==10);
end
if ~isempty(stringIndices) then
// ignoring all other strings except the corr flag
isCorrFlag = or(strcmpi(varargin(stringIndices),"corr")==0);
varargin(stringIndices) = [];
end
// varargin can have only an entry for fs
if length(varargin)==1 then
fs = varargin(1);
if length(fs)==1 then
if ~IsIntOrDouble(fs, %T) then
msg = "rootmusic: Wrong type for argument #4 (fs); Positive scalar expected";
error(msg,10084);
end
fs = double(fs);
isFsSpecified = %T;
elseif length(fs)>1 then
msg = "rootmusic: Wrong type for argument #4 (fs); Positive scalar expected";
error(msg,10084);
end
elseif length(varargin)>1 then
msg = "rootmusic: Wrong type for argument #4 (fs); Positive scalar expected";
error(msg,10084);
end
// extracting primary input x/R
primaryInput = x;
if ndims(primaryInput)<1 | ndims(primaryInput)>2 then
msg = "rootmusic: Wrong dimension for argument #1; Vector or a matrix expected";
error(msg,10053);
end
if ~IsIntOrDouble(primaryInput, %F) then
msg = "rootmusic: Wrong type for argument #1; Numeric vector or a matrix expected";
error(msg,10053);
end
// covert to a column vector
if ndims(primaryInput)==1 then
primaryInput = primaryInput(:);
end
// casting to double
primaryInput = double(primaryInput);
//****extracting p****
// p must be either scalar or a 2-element vector
if length(p)~=1 & length(p)~=2 then
msg = "rootmusic: Wrong type for argument #2 (p); " + ...
"A scalar or a 2-element vector expected";
error(msg,10053);
end
// first argument of p must be an integer
if ~IsIntOrDouble(p(1),%T) then
msg = "rootmusic: Wrong input argument #2 p(1); " + ...
"positive integer expected";
error(msg,10036);
return
end
p(1) = int(p(1));
// TODO: check if positive required
// 2nd argument, if exists, must be a positive integer'
if length(p)==2 then
if ~IsIntOrDouble(p(2),%F) then
msg = "rootmusic: Wrong type for argument #2 p(2); must be a scalar";
error(msg,10053);
end
end
isXReal = isreal(x)
if ~isCorrFlag then
// check that p(1) should be even if x is real
if isXReal & modulo(p(1),2)~=0 then
msg = "rootmusic: Wrong input argument #2 p(1); " + ...
" An even value expected for real input x";
error(msg,10036);
end
end
// **** calling pmusic ****
data= struct();
data.x = primaryInput;
data.p = p;
data.nfft = 256;
data.w = [];
data.fs = fs;
data.isWindowSpecified = %F;
data.windowLength = 2*p(1);
data.windowVector = [];
data.noverlap = [];
data.isCorrFlag = isCorrFlag;
data.isFsSpecified = isFsSpecified;
data.freqrange = "twosided";
[outData,msg] = musicBase(data);
if length(msg)~=0 then
// throw error
msg = "rootmusic: "+msg
error(msg);
end
pEffective = outData.pEffective;
eigenvals = outData.eigenvals;
w = computeFreqs(outData.noiseEigenvects,pEffective,%f,eigenvals);
if isempty(w) then
// assign all frequency and powers as -nan
w = %nan*(1:pEffective)';
pow = w;
return;
end
// **** Estimating the variance of the noise ****
// Estimate is the mean of the eigenvalues belonging to the noise subspace
sigma_noise = mean(eigenvals(pEffective+1:$));
pow = computePower(outData.signalEigenvects,eigenvals,w,pEffective,...
sigma_noise,isXReal);
// is fs is specified, convert normailized frequencies to actual frequencies
if isFsSpecified then
w = w*fs/(2*%pi);
end
endfunction
function w = computeFreqs(noiseEigenvects,pEffective,EVFlag,eigenvals)
// Computes the frequencies of the complex sinusoids using the roots of
// the polynomial formed with the noise eigenvectors
//
// Parameters
// noiseEigenvects -
// A matrix where noise eigenvectors are represented by each column
// pEffective -
// The effective dimension of the signal subspace
// EVFlag -
// Flag to indicate weighting to be used for rooteig
// eigenvals -
// Eigenvals of the correlation matrix
//
// Output arguments
// w -
// A vector with frequencies of the complex sinusoids
numOfNoiseEigenvects = size(noiseEigenvects,2);
if EVFlag then
// weights are the eigenvalues in the noise subspace
weights = eigenvals($-numOfNoiseEigenvects+1:$);
else
weights = ones(numOfNoiseEigenvects,1);
end
// Form a polynomial consisting of a sum of polynomials given by the
// product of the noise subspace eigenvectors and the reversed and
// conjugated version. (eq 8.163 from [1])
D = 0;
for i=1:numOfNoiseEigenvects
eigenvect = noiseEigenvects(:,i);
D = D + conv(eigenvect,conj(eigenvect($:-1:1)))./weights(i);
end
roots = roots(D);
// selecting the roots inside the unit circle
rootsSelected = roots(abs(roots)<1);
// sort the roots in order of increasing distance from the unit circle
[dist,indices] = gsort(abs(rootsSelected)-1);
sortedRoots = rootsSelected(indices);
if isempty(sortedRoots) then
w = [];
else
w = atan(imag(sortedRoots(1:pEffective)),real(sortedRoots(1:pEffective)));
end
endfunction
function power = computePower(signalEigenvects,eigenvals,w,pEffective,...
sigma_noise,isXReal)
if isXReal then
// removing the negative frequencies as sinusoids will be present in
// complex conjugate pairs
w = w(w>=0);
pEffective = length(w);
end
// Solving eq. 8.160 from [1] (Ap = b) where p is the power matrix
A = zeros(length(w),pEffective);
for i=1:pEffective
A(:,i) = computeFreqResponseByPolyEval(signalEigenvects(:,i), ...
w,1,%F);
end
A = (abs(A).^2)';
b = eigenvals(1:pEffective) - sigma_noise;
// Solving Ap=b with the constraint that all elements of p >=0
power = nnls(A,b+A*sqrt(%eps)*ones(pEffective,1));
endfunction
function h = computeFreqResponseByPolyEval(b,f,fs,isFsSpecified)
// returns the frequency response (h) for a digital filter with numerator b.
// The evaluation of the frequency response is done at frequency values f
f = f(:);
b = b(:);
if isFsSpecified then
// normalizing the f vector
w = f*2*%pi/fs;
else
w = f;
end
n = length(b);
powerMatrix = zeros(length(f),n);
powerMatrix(:,1) = 1;
for i=2:n
powerMatrix(:,i) = exp(w*(-i+1)*%i);
end
h = powerMatrix*b;
endfunction
function result = IsIntOrDouble(inputNum, isPositiveCheck)
// Checks if The Input Is Integer Or Double
// Also Checks if It Is Greater Than 0 For IsPositiveCheck = True
if ~(type(inputNum)==1 | type(inputNum)==8) then
result = %F;
return
end
if isPositiveCheck & or(inputNum<=0) then
result = %F;
return
end
result = %T;
return
endfunction
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