# Second Order Diff Eq with ode45 in Matlab

So I need to solve x''(t) = -x(t)^p with initial conditions x(0)= 0 and v(0) = x'(0) = v_o = 1. The value of the parameter p is 1.

This is what I have:

``````function [t, velocity, x] = ode_oscilation(p)

y=[0;0;0];
% transform system to the canonical form

function y = oscilation_equation(x,p)
y=zeros(2,1);
y(1)=y(2);
y(2)=-(x)^p;
%  to make matlab happy we need to return a column vector
% so we transpose (note the dot in .')
y=y.';
end

tspan=[0, 30]; % time interval of interest

[t,velocity,x] = ode45(@oscilation_equation, tspan, 1);

t = y(:,1);
xposition=y(:,3);
velocity=y(:,2);

end
``````

and this is the error message I receive:

ode_oscillation(1) Error using odearguments (line 91) ODE_OSCILLATION/OSCILATION_EQUATION must return a column vector.

Error in ode45 (line 114) [neq, tspan, ntspan, next, t0, tfinal, tdir, y0, f0, odeArgs, odeFcn, ...

Error in ode_oscillation (line 17) [t,velocity,x] = ode45(@oscilation_equation, tspan,1);

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There's a few things going wrong here. First, from `help ode45`:

ode45 Solve non-stiff differential equations, medium order method.

``````[TOUT,YOUT] = ode45(ODEFUN,TSPAN,Y0) with TSPAN = [T0 TFINAL] integrates
the system of differential equations y' = f(t,y) from time T0 to TFINAL
with initial conditions Y0.
``````

Note that `ode45` expects a function `f(t,y)`, where `size(t) == [1 1]` for time and `size(y) == [1 N]` or `[N 1]` for solution values. Your `oscilation_equation` has the order of input arguments inverted, and you input a constant parameter `p` instead of time `t`.

Also, the initial conditions `Y0` should have the same size as `y`; so `size(y0) == [N 1]` or `[1 N]`. You just have `1`, which is clearly causing errors.

Also, your output arguments `t`, `xposition` and `velocity` will be completely ignored and erroneous, since `y` is not set as output argument from `ode45`, and most of all, their names do not correspond to `ode_oscilation`'s output arguments. Also, their order of extracting from columns of `y` is incorrect.

So, in summary, change everything to this:

``````function [t, v, x] = ode_oscilation(p)

% initial values
y0 = [0 1];

% time interval of interest
tspan =[0 30];

% solve system
[t,y] = ode45(@(t,y) [y(2); -y(1)^p], tspan, y0);

% and return values of interest
x = y(:,1);
v = y(:,2);

end
``````
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