Whenever Matlab detects you're indecing to an element *outside* the current bounds of the matrix/array, it will automatically pad the missing elements with zeros:

```
>> clear b; b(10) = 5
b =
0 0 0 0 0 0 0 0 0 5
```

This feature is both **very useful**, and **very dangerous**. It is useful for the fact declarations can be made very easy, such as your own case. You can create a whole array of custom-made classes by issuing something like

```
myClassArray(500) = myClass(1, 2);
```

which is infinitely better than something like

```
% cannot pre-allocate (zeros() or ones() give double/uint8/..., not myClass)
for ii = 1:499
myClassArray(ii) = myClass; % so, growing array
end
myClassArray(500) = myClass(1,2);
```

But, growing arrays can be hard to spot:

```
a = zeros(10,1);
for ii = 1:10
a(ii+1) = rand;
end
```

which can make performance drop tremendously. Also, when you translate code prototyped in Matlab to a statically-typed language like C++, copying this code will result in buffer overflows and thus segfaults.

Now, going back to your case:

```
clear a; a(1:2:5) = 1:-4:-7
```

The `1:2:5`

will expand to the array `[1 3 5]`

, and the `1:-4:-7`

will give the values `[1 -3 -7]`

. Since the variable `a`

does not exist yet, Matlab will create a new one and fill the elements `[1 3 5]`

with the values `[1 -3 -7]`

. The indices that have been skipped in order to initialize variable `a`

(namely, `[2 4]`

) will then have been initialized automatically to zero.

If you're familiar with Python, it's a bit like the syntax to assign multiple values to multiple variables

```
x,y = 1,2
```

But in your Matlab case, these different variables are indices to a non-existent array, which requires "filling the holes with something" to make it a valid, consistent array.

Does this make things clear?