# How does bicubic interpolation work?

After reading text about this said topic, i found out that it considers 16 of the original neighboring pixels. What i want to know is how does it compute the color value of the new pixel. If the color of pixels can be determined by 200,100,255, how could you compute the value of the new one?

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It looks like you are specifying an RGB triplet for a single pixel, and not the 16 neighboring pixels like you mentioned. –  Andy West Dec 30 '09 at 8:48
to make things clear, can you give me a concrete example on how would you compute the new color of the interpolated pixel.(pixel by pixel RGB computation) –  aidriiyan Jan 3 '10 at 13:39

I think it's pretty well explained in Wikipedia. You need the intensity values of 4*4=16 pixels, from which you can calculate the interpolated value at any point within that 4*4 grid.

If you mean how to do this for RGB triplets, you just do the process separately for each component.

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what i need is pixel level computation. can you give me a concrete example –  aidriiyan Jan 3 '10 at 13:50

You should spend some time learning how to do a bilinear interpolation, as a tensor product linear interpolation. Once you understand it and how/why it works, then the bicubic case is easier to follow.

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correct me if im wrong.(bilinear) Example(1 intensity only): p00=255, p01=0, p10=100, p11=255 new pixel= [((255+0)/2) + ((100+255)/2)]/2= 153.... am i right?...if yes, how could i implement it in bicubic? if no, give me a good example. –  aidriiyan Jan 3 '10 at 13:48
@aidriiyan actually, no. bilinear doesn't mean just blindly average the pixels. The idea of bilinear interpolation is to compute the value of a pixel that is at some fractional offset horizontally and some fractional offset vertically from a given pixel. It does a weighted average, where the weights are based on the distances of the sample point from those pixels. –  doug65536 Jul 6 '13 at 23:24