THE AUDITORY MODELING TOOLBOX
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plot_roenne2012_chirp - Plot Fig. 6 or 7 of Rønne et al. (2012)
Program code:
function plot_roenne2012_chirp(waveVamp, waveVlat, varargin)
%plot_roenne2012_chirp Plot Fig. 6 or 7 of Rønne et al. (2012)
% Usage: plot_roenne2012_chirp(flag)
%
% PLOT_ROENNE2012_CHIRP(waveVamp, waveVlat) plots the output of
% ROENNE2012_CHIRP in the style of Fig. 6 or 7 of Rønne et al. (2012).
% Simulations are compared to data from Elberling et al. (2010).
%
% The flag may be one of:
%
% 'twofig' Plot the amplitude and latency in two different plot
% windows. This is the default.
%
% 'subplot Use subplot to position the window side-by-side
%
% 'amponly' Plot amplitude only.
%
% 'latonly' Plot latency only.
%
% ---------
%
% Please cite Rønne et al. (2012) and Zilany and Bruce (2007) if you use
% this model.
%
% See also: roenne2012_chirp, roenne2012, exp_roenne2012
%
% References:
% C. Elberling, J. Calloe, and M. Don. Evaluating auditory brainstem
% responses to different chirp stimuli at three levels of stimulation. J.
% Acoust. Soc. Am., 128(1):215-223, 2010.
%
% F. M. Rønne, T. Dau, J. Harte, and C. Elberling. Modeling auditory
% evoked brainstem responses to transient stimuli. The Journal of the
% Acoustical Society of America, 131(5):3903-3913, 2012. [1]http ]
%
% M. S. A. Zilany and I. C. Bruce. Representation of the vowel (epsilon)
% in normal and impaired auditory nerve fibers: Model predictions of
% responses in cats. J. Acoust. Soc. Am., 122(1):402-417, jul 2007.
%
% References
%
% 1. http://scitation.aip.org/content/asa/journal/jasa/131/5/10.1121/1.3699171
%
%
% Url: http://amtoolbox.sourceforge.net/amt-0.9.9/doc/plot/plot_roenne2012_chirp.php
% Copyright (C) 2009-2015 Piotr Majdak and the AMT team.
% This file is part of Auditory Modeling Toolbox (AMT) version 0.9.9
%
% 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/>.
% Define input flags
definput.flags.type = {'twofig','subplot','amponly','latonly'};
if 0
definput.keyvals.waveVlat = [6.40000000000000,6.06666666666667, ...
5.86666666666667;6.16666666666667,5.80000000000000, ...
5.50000000000000;6.10000000000000,5.73333333333333, ...
5.36666666666667;6.03333333333334,5.66666666666667, ...
5.23333333333333;5.96666666666667,5.60000000000000, ...
5.10000000000000;5.93333333333333,5.53333333333334, ...
4.56666666666667];
definput.keyvals.waveVamp = [0.222761519867971,0.368049605362604, ...
0.426295534454623;0.304245724239426, ...
0.613841499609571,0.662285715806521; ...
0.313992730990412,0.635926344773530, ...
0.588473779376608;0.314083457955007, ...
0.609949392701705,0.523100938263095; ...
0.308279424002208,0.569882100923284, ...
0.411055469911713;0.299982088057727, ...
0.524606196043760,0.356573917626301];
end;
[flags,kv] = ltfatarghelper({}, definput,varargin);
fntz = 12; % fontsize
coldata = [0.7,0.7,0.7];
col = [0,0,0];
[Delay,CElatmean,CElatstd] = data_elberling2010('fig5');
[Delay,CEmean,CEstd] = data_elberling2010('fig4');
Delay2 = [Delay;Delay;Delay];
if flags.do_subplot
subplot(1,2,1);
end;
if flags.do_twofig
figure;
end;
%% Plot figure 6 from Rønne et al. (2012)
if flags.do_amponly
% Plot Elberling et al. (2010) reference data
errorbar(Delay2',CEmean,CEstd/sqrt(20),'-', ...
'linewidth',1.5,'color',coldata);
hold all;
set(gca,'fontsize',fntz);
axis([-1.2 5.5 0 800]);
xlabel('Change of delay [ms]');
ylabel('ABR amplitude [nv]');
text(-.7,waveVamp(1,1)*1000, '20','fontsize',fntz);
text(-.7,waveVamp(1,2)*1000, '40','fontsize',fntz);
text(-.7,waveVamp(1,3)*1000, '60','fontsize',fntz);
text(-.9,waveVamp(1,3)*1000+70, 'dB nHL','fontsize',fntz);
text(-.2,50, 'Click','fontsize',fntz);
text(Delay(2),75, '1','fontsize',fntz);
text(Delay(3),75, '2','fontsize',fntz);
text(Delay(4),75, '3','fontsize',fntz);
text(Delay(5),75, '4','fontsize',fntz);
text(Delay(6),75, '5','fontsize',fntz);
text(3,40, 'Chirps','fontsize',fntz);
% Plot Simulated wave V latencies
plot(Delay,waveVamp*1000,'-*k','linewidth',1.5);
xlabel('Change of delay [ms]');
ylabel('ABR latency [ms]');
% axis([-1.2 6.5 0 10]);
end
if flags.do_subplot
subplot(1,2,2);
end;
if flags.do_twofig
figure;
end;
%% Plot figure 7 from Rønne et al. (2012)
if flags.do_latonly
% Amplitude in nV
waveVamp = waveVamp*1000;
set(gca,'fontsize',fntz);
hold all;
errorbar(Delay2',CElatmean,CElatstd/sqrt(20),'-','linewidth',1.5, ...
'color',coldata)
plot(Delay,waveVlat,'-*k','linewidth',1.5);
% Plot text strings
text(-.7,5.88, '60','fontsize',fntz,'color',coldata);
text(-.7,6.59, '40','fontsize',fntz,'color',coldata);
text(-.7,7.6, '20','fontsize',fntz,'color', coldata);
text(-.9,8.7, 'dB nHL','fontsize',fntz,'color',coldata);
text(5.5,waveVlat(6,1), '20','fontsize',fntz);
text(5.5,waveVlat(6,2), '40','fontsize',fntz);
text(5.5,waveVlat(6,3), '60','fontsize',fntz);
text(5.3,waveVlat(6,1)+.6, 'dB nHL','fontsize',fntz);
text(-.2,.5, 'Click','fontsize',fntz);
text(Delay(2),1, '1','fontsize',fntz);
text(Delay(3),1, '2','fontsize',fntz);
text(Delay(4),1, '3','fontsize',fntz);
text(Delay(5),1, '4','fontsize',fntz);
text(Delay(6),1, '5','fontsize',fntz);
text(3,.5, 'Chirps','fontsize',fntz);
box on;
axis([-2 7 0 10]);
end
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