WUT_Computer_Science/ENUME/projectC/rk4.asv

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% solve ODE system using RK4 with constant step size
function [x, derivativesTable] = rk4(functions, initialValues, interval, stepSize, maxSteps)
x = initialValues;
derivativesTable = buildDerivatiesTable(x, functions);
% Calculate stepCount
stepCount = ceil((interval(2) - interval(1)) / stepSize);
if nargin == 5
stepCount = min(stepCount, maxSteps - 1);
end % IF we include max steps in our function input
% (nargin is number of arguments in input)
% then choose smaller number between maxSteps and stepCount and choose
% it for stepCount
[x, derivativesTable] = rk4Loop(x, stepCount, stepSize, functions, derivativesTable);
% append arguments to output
x = [interval(1):stepSize:(stepCount * stepSize); x];
end
function derivativesTable = buildDerivatiesTable(x, functions)
derivativesTable = zeros(size(x));
for eqnum = 1:size(functions, 1)
derivativesTable(eqnum, 1) = functions{eqnum}(x(:, 1));
end
end
function [x, derivativesTable] = rk4Loop(x, stepCount, stepSize, functions, derivativesTable)
for step = 1 : stepCount
[x, derivativesTable] = rk4stepLoop(x, step, functions, stepSize, derivativesTable);
end
end
function [x, derivativesTable] = rk4stepLoop(x, step, functions, stepSize, derivativesTable)
stepValue = x(:, step);
for equationNumber = 1 : 2
% generic single-step iteration
phi = RK4Phi(functions{equationNumber}, stepValue, stepSize);
x(equationNumber, step + 1) = x(equationNumber, step) + stepSize * phi;
% update derivatives table
derivativesTable(equationNumber, step + 1) = functions{equationNumber}(x(:, step + 1));
end
end