# Image comparison algorithm that ignores brightness

I am looking for an algorithm that I can use to compare two images and determine if there is something significantly different between the two. By "significant", I mean, if you took two photos of a room and a large spider was clearly on the wall in one of them, you'd be able to detect it. I am not really interested in WHAT is detected or even where - just that there is something different. The algorithm would need to ignore brightness. If the room gets brighter or darker during the day, the algorithm should ignore it.

Even if you don't know of an algorithm, any hints in the right direction would help.

Thanks!

-
are the photos taken from exactly the same viewpoint? Are you trying to make security camera software? –  Will Jan 21 at 8:00
How about shadows that change in shape over time? You cannot write them off to brightness. –  Alexey Frunze Jan 21 at 8:03
Yes, the photos are taken from the exact same location. The camera never moves. This is for a security app. If shadows are extreme that it changes the shape, then yes, that too should be detected. –  AndroidDev Jan 21 at 8:05
You need to be top notch on your uses cases. A spider can move really slowly, and if designed incorrectly, the spider can go from one side of the screen to another while appearing invisible to your camera. –  UmNyobe Jan 21 at 9:27
Slow spiders will get caught if they appear between image captures. If they can outrun the capture rate, that's no problem. I'm not out to get superman. –  AndroidDev Jan 21 at 9:33
show 1 more comment

I'd try to perform a high-pass filtering of your 2d-data.

According to Fourier, every signal can be transformed to "frequency space" by analyzing which frequencies are in the signal. This also applies to 2d-signals, like images.

By the means of a "high-pass-filter", you remove all low-frequency parts, like constant offsets and slow gradients. If applied to an image it can serve as a simple "edge detection" algorithm. Looking at a sample might make it easier to understand:

I took an image of a spider on a wall from somewhere on the web (top-left). I then decreased the brightness of this image (lower-left). For both versions, I applied a high-pass filter using GIMP (This plugin). For both input images, the output looks very similar.

My recommendation: First apply a high-pass filter, then look at differences.

Possible problems

As requested, here are some problems that I can imagine.

• No sharp edges: if the object you want to detect doesn'T have sharp edges you probably will filter it out using HF-pass filtering. But what objects could that be? They must be huge, flat (to not produce shadows) and unstructured.

• Only color differs, not brightness: If the object only differs in term of its color, but the brightness is the same as the background, the grayscale-conversion might be a problem. But if you run into this problem, just analyse the R, G, B-data separately, then at least one channel should help detecting the object - otherwise, you can't see it anyway.

Edit As reply to ???, if you also adjust the levels of the high-pass filtered image (which of course is all around 0.5*256) by just normalizing it to the range 0, 256 again you get

Which probably isn't worse than your result. But, HP-filters are simple and, when using FFT, very fast.

-
brilliant use of an FFT! a very nice approach! i would also bump up constrast for better seperation, and perhaps even take a photo in the middle of the day, which i then would use to normalize the brightness of future photos. calculating the cross-correlation could also aid in quantifying the amount of differences in two photos if comparing them visually is not desired. –  FredrikRedin Jan 21 at 9:18
I used FFT in audio processing, so I am familiar with it. Never thought of how it applies to images though. This is an interesting approach. If I understand your approach, what you're attempting to do is simply reduce all the colors down to either grey or white, where the white shows up as edges along those structures that have clearly defined edges. Do you forsee any potential problems using this solution under certain situations? –  AndroidDev Jan 21 at 10:22
Yes, you understood me correctly. The key point is information reduction, only keep the information that really is relevant. I'll edit my answer to reflect some possible problems you might encounter. –  Thorsten Kranz Jan 21 at 10:36
I'm a little confused on a few things. Does the high pass filter cause a color image to convert to grey scale or do I have to first create a grey scale image and then pass that through a high pass filter? I'm not sure of what to even Google for a high pass filter for images. I know what they are for audio. Can you suggest what I kinds of high pass imaging filter algorithms I should be looking for? I need to write code, so a plugin is useless. –  AndroidDev Jan 21 at 10:53
You said that objects to go undetected would have to be huge and flat and probably without edges. How about thieves carrying a large grey drywall positioned between them and the camera? Would that get detected? –  AndroidDev Jan 21 at 11:06

If the camera is completely static and all differences are due to ambient lighting and/or camera exposure settings, then ignoring brightness (and contrast) can be done by normalizing the 2 images.

Subtract the respective image mean (average pixel value) from all pixels of each image and the take the difference. That will take care of brightness.

If you want to handle contrast too, the calculate the variance of each each image (after bringing the mean to 0), and multiply the pixel values by the factor that will bring them both the the same variance. The difference will now be invariant to contrast as well (assuming no over/under exposure regions).

-
This is sort of the approach I already have attempted. However, I was taking the RGB as a single value (ex. 0xaabbcc) and normalizing the image based on subtracting these values. It turns out that the variance is very inconsistent when colors are further away from each other. I think I need to add the RGB values and use that instead. I didn't understand your last paragraph on how to take contrast into account. Can you provide a simple example of a 4x4 pixel image? Thanks! –  AndroidDev Jan 21 at 10:39

A common approach with such a problem is to average the images taken by your camera over time, and detect any difference above a given threshold.

You need to keep an image in memory that will be the averaged image. Let's call it "avg".

Each time your camera takes a picture (called "pic"), you gonna :

• Sum up absolute pixels value differences between "avg" and "pic".
• If above a threshold, something is moving in front of the camera.
• Else, modify "avg" so it will converge slightly to "pic". Up to you to find the proper formula, `avg = avg * 0.95 + pic * 0.05` for instance.