function [out, cbar] = plot_reijniers2014(dirs, values, varargin)
%PLOT_REIJNIERS2014 - plot scatter plots out of data from reijniers2014
%
% Usage: colorbar = plot_reijniers2014(dirs, values);
% colorbar = plot_reijniers2014(dirs, values,'bias',bias);
% plot_reijniers2014(dirs, values);
% plot_reijniers2014(dirs, values,'bias',bias,'scatter');
%
% Input parameters:
% dirs : Normed source directions in cartesian coordinates
% values : Arbitrary values corresponding to direction in dirs (e.g.
% error or probability density)
% bias : optional, display arrows indicating the size and direction
% of local population response biases for different source
% positions
% target : optional, display the target given in Cartesian coordinates
% as a small cross
%
% Output parameters:
% c : Colorbar of the plot to modify outside of this function.
%
% Further, plot flags can be specified:
%
% 'interp' Plot scattered interoplated data (default).
%
% 'scatter' Plot only discrete scattered data instead of inter-
% polated scattered data.
%
% See also: exp_reijniers2014 reijniers2014
%
% References:
% R. Barumerli, P. Majdak, R. Baumgartner, J. Reijniers, M. Geronazzo,
% and F. Avanzini. Predicting directional sound-localization of human
% listeners in both horizontal and vertical dimensions. In Audio
% Engineering Society Convention 148. Audio Engineering Society, 2020.
%
% J. Reijniers, D. Vanderleist, C. Jin, C. S., and H. Peremans. An
% ideal-observer model of human sound localization. Biological
% Cybernetics, 108:169--181, 2014.
%
%
% Url: http://amtoolbox.org/amt-1.1.0/doc/plot/plot_reijniers2014.php
% Copyright (C) 2009-2021 Piotr Majdak, Clara Hollomey, and the AMT team.
% This file is part of Auditory Modeling Toolbox (AMT) version 1.1.0
%
% This program is free software: you can redistribute it and/or modify
% it under the terms of the GNU General Public License as published by
% the Free Software Foundation, either version 3 of the License, or
% (at your option) any later version.
%
% This program is distributed in the hope that it will be useful,
% but WITHOUT ANY WARRANTY; without even the implied warranty of
% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
% GNU General Public License for more details.
%
% You should have received a copy of the GNU General Public License
% along with this program. If not, see <http://www.gnu.org/licenses/>.
% AUTHOR: Jonas Reijniers
% Modified and adapted for amtoolbox
% by Roberto Barumerli and Michael Sattler,
% Acoustics Research Institute, Vienna, Austria, 2019
%% ------ Check input options ---------------------------------------------
definput.flags.plot_type = {'interp','scatter'};
definput.flags.type = {'missingflag', 'fig2a','fig2b', ...
'fig3','fig4','fig5','fig6', 'fig7', 'fig3_barumerli2020aes'};
definput.keyvals.bias = [];
definput.keyvals.target = [];
[flags,kv] = ltfatarghelper({'bias','target'},definput,varargin);
% sphere radius [m]
rad = 1;
%% computing lambert projection considering front and back
[AZ,EL]=cart2sph(dirs(:,1),dirs(:,2),dirs(:,3));
% front
idxf=find(abs(AZ)<=pi/2);
[xf,yf] = polar_to_lambert(AZ(idxf), EL(idxf), rad);
% back indices
idxb=find(abs(AZ)>=pi/2);
AZpar=AZ-pi; % reverse on the frontal plane for plotting
[xb,yb] = polar_to_lambert(AZpar(idxb), EL(idxb), rad);
xb = -xb;
%% make gridlines
daz=30;
AZgrid=repmat((-90:90),length(-90:daz:90),1)'*pi/180;
ELgrid=repmat((-90:daz:90)',1,length(-90:90))'*pi/180;
[xgrid1,ygrid1,zgrid1]=sph2cart(AZgrid,ELgrid,1);
[xgrid2,ygrid2,zgrid2]=sph2cart(ELgrid,AZgrid,1);
[AZgrid1, ELgrid1] = cart2sph(xgrid1,zgrid1,ygrid1);
[AZgrid2, ELgrid2] = cart2sph(xgrid2,zgrid2,ygrid2);
[xvergrid,yvergrid] = polar_to_lambert(AZgrid1, ELgrid1, rad);
[xhorgrid,yhorgrid] = polar_to_lambert(AZgrid2, ELgrid2, rad);
% plotting
if flags.do_fig2a
fig = figure('NumberTitle', 'off', 'Name', 'Fig. 2 (a)');
elseif flags.do_fig2b
fig = figure('NumberTitle', 'off', 'Name', 'Fig. 2 (b)');
elseif flags.do_fig3
fig = figure('NumberTitle', 'off', 'Name', 'Fig. 3');
elseif flags.do_fig4
fig = figure('NumberTitle', 'off', 'Name', 'Fig. 4 (a)');
elseif flags.do_fig5
fig = figure('NumberTitle', 'off', 'Name', 'Fig. 5');
elseif flags.do_fig6
fig = figure('NumberTitle', 'off', 'Name', 'Fig. 6');
else
fig = figure;
end
hold on
% add data valuess
if flags.do_interp
[xg,yg] = meshgrid(-1:5e-3:1);
Vfq = griddata(xf,yf,values(idxf),xg,yg);
Vbq = griddata(xb,yb,values(idxb),xg,yg);
contourf(xg,yg,Vfq, 30, 'LineColor','none');
contourf(xg+2,yg,Vbq, 30, 'LineColor','none');
end
if flags.do_scatter
scatter(xf,yf,30,values(idxf),'filled','r');
scatter(xb+2,yb,30,values(idxb),'filled');
end
% plot grid
grid_color = 100 * [1 1 1] ./ 255;
plot(xvergrid,yvergrid, 'Color', grid_color);
plot(xhorgrid,yhorgrid, 'Color', grid_color);
plot(xvergrid+2,yvergrid, 'Color', grid_color);
plot(xhorgrid+2,yhorgrid, 'Color', grid_color);
text(-0.3, -1.35, 'FRONT', 'FontSize',13);
text(1.75, -1.35, 'BACK', 'FontSize',13);
set(gca,'XColor', 'none','YColor','none');
%%
if ~isempty(kv.bias)
% front indices
bias = kv.bias;
bias = bias + dirs;
[AZ,EL]=cart2sph(bias(:,1),bias(:,2),bias(:,3));
[xfb,yfb] = polar_to_lambert(AZ(idxf), EL(idxf), rad);
% back indices
AZpar=AZ-pi; % of pi/2)
[xbb,ybb] = polar_to_lambert(AZpar(idxb), EL(idxb), rad);
xbb = -xbb;
q1 = quiver(xf,yf,xfb-xf,yfb-yf);
q1.Color = 'black';
q1.MaxHeadSize = 0.05;
q2 = quiver(xb+2,yb,xbb-xb,ybb-yb);
q2.Color = 'black';
q2.MaxHeadSize = 0.05;
% q2.AutoScaleFactor = 1.5;
end
if ~isempty(kv.target)
% front indices
[AZ,EL]=cart2sph(kv.target(:,1),kv.target(:,2),kv.target(:,3));
idxf=find(abs(AZ)<=pi/2);
if ~isempty(idxf)
[xfb,yfb] = polar_to_lambert(AZ(idxf), EL(idxf), rad);
q1 = plot(xfb,yfb,'x');
q1.Color = 'blue';
end
% back indices
idxb=find(abs(AZ)>=pi/2);
if ~isempty(idxb)
AZpar=AZ-pi; % of pi/2)
[xbb,ybb] = polar_to_lambert(AZpar(idxb), EL(idxb), rad);
xbb = -xbb;
q2 = plot(xbb+2,ybb,'x');
q2.Color = 'blue';
end
end
axis([-1 3 -1 1])
pbaspect([2 1 1]);
colormap(flipud(hot));
c = colorbar;
box on;
if nargout == 1
out = fig;
elseif nargout == 2
out = fig;
cbar = c;
end
function [x,y] = polar_to_lambert(az, el, rad)
% convert polar coordinates to Lambert equal area projection
% equal area transformation
% for a reference see
% http://mathworld.wolfram.com/StereographicProjection.html
% and
% Formulas 22-4 (p173), 24-13 and 24-14 (p. 185-186) in
% Snyder, J. P. Map Projections - A Working Manual.
% U. S. Geological Survey Professional Paper 1395.
% Washington, DC: U. S. Government Printing Office, pp. 154-163, 1987.
az_0 = 0;
k = sqrt(2 ./ (eps + 1 + (cos(el) .* cos(az - az_0))));
x = k * rad .* cos(el) .* sin(az - az_0) ./ sqrt(2); % ./sqrt(2) normalizing
y = k * rad .* sin(el) ./ sqrt(2);