Refering to Jordi's Answer:

[Quoted] ... Note, however, that this does not hold for all structuring elements...

In fact, it holds, in the following way (not in Jordi's example):

First step, calculate the 5x5 kernel by dilation twice in 3x3 kernel on a single center point 5x5 source image:

```
00000 00000 00100
00000 010 00100 010 01110
00100 + 111 -> 01110 + 111 -> 11111 ===> this is the equivalent 5x5 kernel for 2x 3x3 dilation
00000 010 00100 010 01110
00000 00000 00100
```

Then applying twice of 3x3 original dilation kernel is equivalent to applying this 5x5 dilation kernel on a bigger image. For example:

```
0000000000 0000000000 00100
0000000000 010 010 0000000000 01110
0011100000 + 111 + 111 === 0011100000 + 11111
0000001000 010 010 0000001000 01110
0000000000 0000000000 00100
0000000000 0000000000
```

This does not directly answer your question though. However, I can not just use 'comment' as it is very hard (if not impossible) to format all these equations/explanations.

In fact, a proof for binary image (image with only value 0 or 1 in each pixel) for the larger combined kernel for dilation is easy:

Let's define the binary operator `+`

to be the dilation operator, where the 1st operand is the kernel, and the second operand is the image to be dilated.. So, if we want to do dilation on image `I`

with kernel `K`

, we write `dilated-image = K + I`

Let's define binary operator `U`

to be the union operator, or, in other word, the binary 'OR' operator for each pixel, where the two operand of `U`

must be binary images in the same dimension. For example: `A U B`

means doing -OR- on each corresponding pixel of A and B:

```
A= 0 0 1 B= 0 1 1
1 0 1 1 1 1
1 1 0 0 1 0
```

Then

```
A U B = 0 1 1
1 1 1
1 1 0
```

We also define `U A(i), i=1, ..., n to be A(1) U A(2) U ... U A(n)`

.

Let's define `K^n`

to be the dilation-styled larger kernel by applying n times of kernel `K`

on a single center point image.

Note that any image `I`

, we can decompose it into union of single point images. For example,

```
0 1 0 0 1 0 0 0 0 0 0 0
I = 0 0 0 === 0 0 0 U 0 0 0 U 0 0 0
1 0 1 0 0 0 1 0 0 0 0 1
```

Now it's time to prove it:

For any image `I`

, we define `D(i), i = 1, ..., n`

to be the single point decomposition of `I`

,
and thus `I = U D(i), i = 1, ..., n`

By definition of the binary dilation, `K + I == K + (U D(i)) == U (K+D(i))`

.
(Remember that dilation is to mask kernel `K`

on each pixel of `I`

, and mark all corresponding 1's).

Now, let's see what is `K + (K + I)`

:

```
K + (K + I) == K + U (K + D(i))
== U(K + (K + D(i))) (Note: this is tricky. see Theorem 1 below)
== U (K^2 + D(i)) (by definition of K^2)
== K^2 + U D(i) (by definition of the dilation)
== K^2 + I (since I = U D(i))
```

Now, we already know `K + (K + I) == K^2 + I`

, and it's easy to apply mathematical induction to prove that `K + K + K .. + K + I = K^n + I`

(Note: please apply right association, as I have drop the parenthesis).

Theorem 1: Proof of the deduction from `K + U (K + D(i))`

to `U(K + (K+D(i)))`

It's suffice to just prove that for any two binary images A and B in a same dimension,
`K + (A U B) = (K+A) U (K+B)`

It's quite easy to see that, if we decompose image `A`

and `B`

, and apply kernel `K`

on the decomposed images, those common points (i.e. the intersection points of `A`

and `B`

, or the common 1's point of `A`

and `B`

), will contribute the same resulting points after applying kernel `K`

. And by the definition of dilation, we need to union all points contributed by each decomposed image of A and B. Thus Theorem 1 holds.

=== UPDATE ===

Regarding to kid.abr's comment "27 operations compared to 7x7 kernel with 49 operations":
Generally speaking, it is not 27 operations. It depends. For example, a source image of 100x100 pixels,
with 20 singular point (1's) sparsely distributed. Applying a 3x3 solid kernel (i.e. All 1's) 3 times on it
requires the following steps for each of the 20 singular point:

Loop 1: 9 operations, and generate 9 points.

Loop 2: For each of the 9 points generated, it needs 9 operations => 9 x 9 = 81 steps. And it generates 25 points

Loop 3: For each of the 25 points generated, it needs 9 operations => 25 x 9 = 225 steps.

Total: 9 + 81 + 225 = 315 steps.

Please note that when we visit a pixel with 0 value in the source image, we don't need to apply the kernel
on that point, right?

So, the same case applying the larger kernel, it requires 7x7 = 49 steps.

Yet, if the source image has a large solid area of 1's, the 3-step method wins.