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StochasticE.asv
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StochasticE.asv
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function [ s, inputs ] = StochasticE( N , N_mean, N_var, a )
%StochasticS Summary of this function goes here
% Detailed explanation goes here
% writing the inputs to an array
inputs = [N , N_mean, N_var, a];
% we need to multiply our input/observed probability densities
% by x in order to get to the radial dist we use for plotting
% declaring empty arrays
s = struct('x', [], 'y', [], 'a', [], 's', [], 'X', [], 'Y', []);
quadrant = 1;
count = 1;
while count < (N+1)
% LINEAR
rng_x = rand(1);
EXPONENTIAL
y = exp(-a*(1-rng_x)) * rng_x;
y_max = 1 * exp(0);
rng_y = rand(1);
rng_a = rand(1)*2*pi/4;
rng_s = N_mean + randn(1)*N_var;
% evaluating whether values fall within probability density
if (rng_y < y_eqn)
s(count).x = rng_x;
s(count).y = rng_y; % this line is irrelevant to 2D distribution
s(count).a = rng_a;
s(count).s = rng_s;
h = rng_x; % h is the hypoteneuse
dx = h - h*cos(rng_a);
dy = h*sin(rng_a);
% assigning points across each quadrant
if quadrant == 1
s(count).X = (h - dx);
s(count).Y = (+dy);
elseif quadrant == 2
s(count).X = (-h + dx);
s(count).Y = (+dy);
elseif quadrant == 3
s(count).X = (-h + dx);
s(count).Y = (-dy);
elseif quadrant == 4
s(count).X = (+h - dx);
s(count).Y = (-dy);
end
% increment counter
if quadrant == 4
quadrant = 1;
else
quadrant = quadrant + 1;
end
count = count + 1;
end
end
end