Algorithm to detect overlapping rows of two images

Let's say I have 2 images A and B as below.

Notice that the bottom of A overlaps with the top of B for `n` rows of pixels, denoted by the two red rectangles. A and B have the same number of columns but might have different number of rows.

Two questions:

• Given A and B, how to determine `n` efficiently?
• If B is somehow changed in a way that 30%-50% of its pixels are completely replaced (for example, imagine the top left area showing # of votes/answers/views is replaced with an ad banner). How to determine `n`?

If anyone can point to an algorithm or better yet, an implementation in any language (preferred C/C++, C#, Java and JavaScript), it is much appreciated.

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Do you have it predetermined that bottom of A equals to top of B? If not, then there's an O(W*H*H) complexity to find out matched regions. –  Vesper Apr 25 '13 at 16:30
I'm not sure if I understand your question. For the 1st question, the bottom of A exactly matches the top of B although the number of matched rows (or lines, of pixels) is unknown (and to be determined). The same thing for the 2nd question except that the supposedly matched top of B might have been altered 30%-50%. –  Buu Nguyen Apr 25 '13 at 18:00

The FFT solution might be more complex than you were hoping for. For a general problem, that might be the only robust way.

For a simple solution, you need to start making assumptions. For example, can you guarantee that the columns of the images line up (barring the noted changes)? This allows you to go down the path suggested by @n.m.

Can you cut the image into vertical strips, and consider a row matches if a sufficient proportion of the strips match?

[ This could be redone to use a few passes with difference column offsets if we need to be robust to that.]

This gives something like:

``````class Image
{
public:
virtual ~Image() {}
typedef int Pixel;
virtual Pixel* getRow(int rowId) const = 0;
virtual int getWidth() const = 0;
virtual int getHeight() const = 0;
};

class Analyser
{
Analyser(const Image& a, const Image& b)
: a_(a), b_(b) {}
typedef Image::Pixel* Section;
static const int numStrips = 16;
struct StripId
{
StripId(int r = 0, int c = 0)
: row_(r), strip_(c)
{}
int row_;
int strip_;
};
typedef std::unordered_map<unsigned, StripId> StripTable;
int numberOfOverlappingRows()
{
int commonWidth = std::min(a_.getWidth(), b_.getWidth());
int stripWidth = commonWidth/numStrips;
StripTable aHash;
createStripTable(aHash, a_, stripWidth);
StripTable bHash;
createStripTable(bHash, b_, stripWidth);
// This is the position that the bottom row of A appears in B.
int bottomOfA = 0;
bool canFindBottomOfAInB = canFindLine(a_.getRow(a_.getHeight() - 1), bHash, stripWidth,  bottomOfA);
int topOfB= 0;
bool canFindTopOfBInA =  canFindLine(b_.getRow(0), aHash, stripWidth, topOfB);
int topOFBfromBottomOfA = a_.getHeight() - topOfB;
// Expect topOFBfromBottomOfA == bottomOfA
return bottomOfA;
}
bool canFindLine(Image::Pixel* source, StripTable& target, int stripWidth, int& matchingRow)
{
Image::Pixel* strip = source;
std::map<int, int> matchedRows;
for(int index = 0; index < stripWidth; ++index)
{
Image::Pixel hashValue = getHashOfStrip(strip,stripWidth);
bool match =  target.count(hashValue) > 0;
if (match)
{
++matchedRows[target[hashValue].row_];
}
strip += stripWidth;
}
// Can set a threshold requiring more matches than 0
if (matchedRows.size() == 0)
return false;
// FIXME return the most matched row.
matchingRow = matchedRows.begin()->first;
return true;
}
Image::Pixel* getStrip(const Image& im, int row, int stripId, int stripWidth)
{
return im.getRow(row) + stripId * stripWidth;
}
static Image::Pixel getHashOfStrip(Image::Pixel* strip, unsigned width)
{
Image::Pixel hashValue = 0;
for(unsigned col = 0; col < width; ++col)
{
hashValue |= *(strip + col);
}
}
void createStripTable(StripTable& hash, const Image& image, int stripWidth)
{
for(int row = 0; row < image.getHeight(); ++row)
{
for(int index = 0; index < stripWidth; ++index)
{
// Warning: Not this simple!
// If images are sourced from lossy intermediate and hence pixels not _exactly_ the same, need some kind of fuzzy equality here.
// Details are going to depend on the image format etc, but this is the gist.
Image::Pixel* strip = getStrip(image, row, index, stripWidth);
Image::Pixel hashValue = getHashOfStrip(strip,stripWidth);
hash[hashValue] = StripId(row, index);
}
}
}

const Image& a_;
const Image& b_;

};
``````
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This is a good compromise, give the assumptions you describe - maybe it might be an idea to consider a line-based checksum for matching if you can assume column alignment? –  Roger Rowland Apr 26 '13 at 6:07
Hmm. Op specifically wanted to allow some changes across the row, so how does a full line based checksum cope? –  Keith Apr 26 '13 at 6:12
Good point - I guess it might be possible to flag rows that are exact matches, so maybe get some contiguous matching rows, with some non-matching, hence identifying a change. I'm just thinking out loud here ... –  Roger Rowland Apr 26 '13 at 6:20
I know where you're coming from. It's easy to construct data that gives false matches with any dumbed down algorithm. Whether that's an issue will depend on the actual data set. –  Keith Apr 26 '13 at 6:42
Keith, thanks for this. Questions: 1. Shouldn't the for loop index from 0 to stripWidth be from 0 to numStrips? 2. My images are always JPEG, how do you suggest the "fuzzy equality" to be? 3. Wouldn't this algorithm find a false positive if the last row of A contains only noise (simplest case: the yellow background, thus can match many lines in B; another case: also background, not necessarily same color across the whole line but still repetitive patterned background in both A and B) –  Buu Nguyen Apr 26 '13 at 16:31

If I understood correctly, you probably want to look at normalized cross correlation of greyscale versions of the two images. Where you have large images, or large overlapping regions, this is done most efficiently in the frequency domain using the FFTs of the images (or overlap areas) and is called phase correlation.

The basic steps I would take in your situation are as follows:

1. Extract the bottom half of the first image and the top half of the second image.
2. Convert both image patches to greyscale.
3. Perform FFT on each image patch (there are some details here relating to windowing and padding).
4. Calculate the complex conjugate of the two FFTs (same as correlation in spatial domain).
5. Do inverse FFT on the result.
6. Find the peak in the above to get the XY shift that best aligns the two images.

Having found the relative offset between the top and bottom image patches, you can easily calculate n as you required.

If you want to experiment without having to code the above from scratch, OpenCV has a number of functions for template matching, which you can easily try. See here for details.

If part of either image has been changed - e.g. by a banner ad - the above procedure still gives the best match, and the magnitude of the peak you find in step 6 gives an indication of the match "confidence" - so you can get a rough idea of how similar the two areas are.

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Something like this will probably help:

First, traverse the image A from bottom upwards, search for a row with significant information in it. An "information" can be calculated, for example, by counting the total color shift across the row. Say, two adjacent pixels have colors #ffffff and #ff0000 - add 2.0 to total count. Have a series of thresholds ready, and lock on the first row that's reaching that threshold. The series can be "10.0, 0.1*row length, 0.15*row length, ..." to a reasonable limit. Then, traverse this array from topmost discovered downwards, take the corresponding row and search for its match in B from upside down. If found, and the threshold is big enough, take the next one in the array and calculate the position of its match, and compare. If succeed, you have locked a correct offset of B over A, and it equals `height_of_A - first_row_index + first_row_match_index`. If failed continue searching for the next row. If all matches failed, search for very last row of A from the very first row of B, up to the offset of the first row found from the bottom of A. If again failed, then the answer is 0. Of course, if using JPEG images, use threshold-match, as pixels might not be exact in A and B, perhaps with a tolerance to unmatched pixels as well.

-

If rows match exactly, then sort rows in both images and merge. Your duplicates are right there. Then go to the original images and find the longest contiguous streak of duplicates in A, such that the corresponding rows in B are also contiguous. Or just look near the top and the bottom of corresponding images.

If there are banner ads, the first thing that comes to mind is breaking the images into several vertical strips and doing that with each pair of strips separately.

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Can you elaborate what you meant by "sort rows and merge"? –  Buu Nguyen Apr 25 '13 at 20:51
You have two arrays of rows. Sort each array, then merge two sorted arrays. Which phase presents a difficulty? –  n.m. Apr 25 '13 at 20:55
Well, if you told me to sort 2 arrays of say, numbers or strings, I would understand. But this is 2 arrays of rows of pixels, on what criteria should they be sorted? –  Buu Nguyen Apr 25 '13 at 21:44
Doesn't matter as long as it's consistent with the usual equality. Rows are arrays of pixels. Lexicographical order will do. –  n.m. Apr 25 '13 at 21:52
Sorting rows will provide a non-contiguous original match set, while he requires contiguous matching. -1 –  Vesper Apr 26 '13 at 3:36