I have the following two 8-tap filters:

```
h0 ['-0.010597', '0.032883', '0.030841', '-0.187035', '-0.027984', '0.630881', '0.714847', '0.230378']
h1 ['-0.230378', '0.714847', '-0.630881', '-0.027984', '0.187035', '0.030841', '-0.032883', '-0.010597']
```

Here they are on a graph:

I'm using it to obtain the *approximation* (lower subband of an image). This is `a(m,n)`

in the following diagram:

I got the coefficients and diagram from the book Digital Image Processing, 3rd Edition, so I trust that they are correct. The *star* symbol denotes **one dimensional** convolution (either over rows or over columns). The down arrow denotes downsampling in **one dimension** (either over rows, or columns).

My problem is that the filter coefficients for `h0`

and `h1`

sum to greater than 1 (approximately 1.4 or sqrt(2) to be exact). Naturally, if I convolve any image with the filter, the image will get brighter. Indeed, here's what I get (expected result on right):

Can somebody suggest what the problem is here? **Why should it work** if the convolution filter coefficients sum to greater than 1?

I have the source code, but it's quite long so I'm hoping to avoid posting it here. If it's absolutely necessary, I'll put it up later.

**EDIT**

What I'm doing is:

- Decompose into subbands
- Filter one of the subbands
**Recompose**subbands into original image

Note that the point isn't just to have a displayable subband-decomposed image -- I have to be able to perfectly reconstruct the original image from the subbands as well. So if I scale the filtered image in order to compensate for my decomposition filter making the image brighter, this is what I will have to do:

- Decompose into subbands
**Apply intensity scaling to approximation subband**- Filter one of the subbands
**Apply inverse intensity scaling to approximation subband**- Recompose subbands into original image

Step 2 performs the scaling. This is what @Benjamin is suggesting. The problem is that then step 4 becomes necessary, or the original image will not be properly reconstructed. This longer method **will** work. However, the textbook explicitly says that **no scaling is performed on the approximation subband**. Of course, it's possible that the textbook is wrong. However, what's more possible is I'm misunderstanding something about the way this all works -- this is why I'm asking this question.

**EDIT (2010/7/8)**

I wrote to the author of the book for a confirmation. He said that you *do* have to perform the scaling, despite of what is being said in the book.