First off: why are the initial values to the differential equation the initial speed (`speedInitial`

) and the initial acceleration (`accelerationInitial`

)? That means that the differential equation `car`

will be computing the acceleration (`y(1)`

) and the jerk (`y(2)`

), the time-derivative of the acceleration, at each time `t`

. That seems incorrect...I would say the initial values should be the initial position (`positionInitial`

) and the initial speed (`speedInitial`

). But, I don't know your model, I could be wrong.

Now, getting the `gear`

in the solution directlty: you can't, not without hacking `ode45`

. This is also logical; you also cannot get `dy`

at all times directly, can you? That's just not how `ode45`

is set up.

There's two ways out I see here:

## Global variable

**DISCLAIMER**: **don't use this method. It's only here to show what most people would do as a first attempt.**

You can store `gear`

in a global variable. It's probably the least amount of coding, but also the least convenient outcome:

```
global ts gear ii
ii = 1;
tInit = 0;
tEnd = 5,
[t,y] = ode45(...
@(t,y) car(t,y,modelStructure), ...
[tInit tEnd], ...
[speedInitial, accelerationInitial], options);
...
function [dy] = car(t,y,modelStructure)
global ts gear ii
dy = zeros(2,1);
dy(1) = y(2);
[dy(2),gear(ii)] = getAcceleration(y(1),modelStructure);
ts(ii) = t;
ii = ii + 1;
```

But, due to the nature of `ode45`

, this will get you an array of times `ts`

and associated `gear`

which contains intermediate points and/or points that got rejected by `ode45`

. So, you'll have to filter for those afterwards:

```
ts( ~ismember(ts, t) ) = [];
```

I'll say it again: this is *NOT* the method I'd recommend. Only use global variables when testing or doing some quick-n-dirty stuff, but always very quickly shift towards other solutions. Also, the global variables grow at each (sub-)iteration of `ode45`

, which is an unacceptable performance penalty.

It's better to use the next method:

## Post-solve call

This is also not too hard for your case, and the way I'd recommend you to go. First, modify the differential equation as below, and solve as normal:

```
tInit = 0;
tEnd = 5,
[t,y] = ode45(...
@(t,y) car(t,y,modelStructure), ...
[tInit tEnd], ...
[speedInitial, accelerationInitial], options);
...
function [dy, gear] = car(t,y,modelStructure)
dy = [0;0];
dy(1) = y(2);
[dy(2),gear] = getAcceleration(y(1),modelStructure);
```

and then after `ode45`

completes, do this:

```
gear = zeros(size(t));
for ii = 1:numel(t)
[~, gear(ii)] = car(t(ii), y(ii,:).', modelStructure);
end
```

That will get you all the gears the car would have at times `t`

.

The only drawback that I can see here is that you'll have many more function evaluations of `car`

than `ode45`

would use by itself. But this is only a real problem if each evaluation of `car`

takes in the order of seconds or longer, which I suspect is not the case in your setup.