function [msoAngles,lsoAngles,wbMsoAngles] = takanen2013_directionmapping(mso,lso,contraMso,wbMmso)
%TAKANEN2013_DIRECTIONMAPPING Map the directional cues to directions
% Usage: [msoAngles,lsoAngles,wbMsoAngles] = takanen2013_directionmapping(mso,lso,contraMso,wbMmso)
%
% Input parameters:
% mso : output of the MSO model projecting to left or right
% hemisphere
% lso : output of the LSO model projecting to left or right
% hemisphere
% contraMso : output of the MSO model projecting to opposite
% hemisphere
% wbMso : output of the wideband MSO model projecting to left
% or right hemisphere
%
% Output parameters:
% msoAngles : direction estimates provided by the model of MSO
% lsoAngles : direction estimates provided by the model of MSO
% wbMsoAngles : direction estimates provided by the wideband MSO
% model
%
% This function maps the outputs of the models of MSO and LSO into
% azimuth angles ranging from -90 to 90 in 10 degree resolution using a
% a set of reference values computed using monophonic signals and
% measured HRTFs of the corresponding directions. More detailed
% description about the process can be found in Takanen, Santala, Pulkki
% 2013 (Sec. 3.2.5)
%
% See also: takanen2013, takanen2013_mso, takanen2013_lso,
% takanen2013_wbmso
%
% References:
% M. Takanen, O. Santala, and V. Pulkki. Visualization of functional
% count-comparison-based binaural auditory model output. Hearing
% research, 309:147--163, 2014. PMID: 24513586.
%
%
% Url: http://amtoolbox.org/amt-1.5.0/doc/modelstages/takanen2013_directionmapping.php
% #StatusDoc: Perfect
% #StatusCode: Perfect
% #Verification: Verified
% #Requirements: MATLAB M-Signal
% #Author: Marko Takanen (2013)
% #Author: Olli Santala
% #Author: Ville Pulkki
% This file is licensed unter the GNU General Public License (GPL) either
% version 3 of the license, or any later version as published by the Free Software
% Foundation. Details of the GPLv3 can be found in the AMT directory "licences" and
% at <https://www.gnu.org/licenses/gpl-3.0.html>.
% You can redistribute this file and/or modify it under the terms of the GPLv3.
% This file is distributed without any warranty; without even the implied warranty
% of merchantability or fitness for a particular purpose.
%% ------ Computation ----------------------------------------------------
%load the precomputed set of reference values
x=amt_load('takanen2013','lookuptable.mat');
referencevalues=x.referencevalues;
dims = size(mso);
%initialize the output values
msoAngles = zeros(dims(1),dims(2));
lsoAngles=msoAngles;
wbMsoAngles =msoAngles;
nAngles = length(referencevalues.angles);
for freqInd =1:dims(2)
%find the closest match to the cue value amongst the reference values
%in the lookup table
temp = abs((lso(:,freqInd)*ones(1,nAngles))-(ones(dims(1),1)*referencevalues.lso(:,freqInd)'));
%set the direction corresponding to the found reference value as the
%direction estimate
[~,ind] = min(temp,[],2);
lsoAngles(:,freqInd) = referencevalues.angles(ind);
%otherwise similar approach as above is used for MSO, except for the
%fact that contralateral MSO cues are used to solve some ambiguities in
%direction estimation
temp = abs((mso(:,freqInd)*ones(1,nAngles))-(ones(dims(1),1)*referencevalues.mso(:,freqInd)'))+...
abs((contraMso(:,freqInd)*ones(1,nAngles))-(ones(dims(1),1)*referencevalues.contramso(:,freqInd)'));
[~,ind] = min(temp,[],2);
msoAngles(:,freqInd) = referencevalues.angles(ind);
%direction mapping for wideband MSO
temp = abs((wbMmso(:,freqInd)*ones(1,nAngles))-(ones(dims(1),1)*referencevalues.wbmso(:,freqInd)'));
[~,ind] = min(temp,[],2);
wbMsoAngles(:,freqInd) = referencevalues.angles(ind);
end