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I am programming automatic focusing on a microscope with programmable axis controller. For testing, I've implemented a simulation, which returns an image depending on exposure, axis position, etc. The simulation takes a good image, and distorts it - e.g. makes brighter, darker.

The primer indicator for good focus are sharp edges (works well for my type of images). Basically I sum the intensity differences between neighboirung pixels. The higher the sum, the better focus.

My question is, how to simulate unfocused image? Did anyone implemented it already? A sequence of filters would be great.

I've tried cvSmooth, but it didn't give realistic results.

PS: My current workaround is changing ROI-size inversily proportional to distance from focus-position. It works well for testig my algorithms, but not good for demonstrations - as the image doesn't change during simulation.

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An unfocused image is VERY similar to an image taken with a long duration exposure and a bit of skakeyness of hand. One could argue then, that a decent simulation to get a blurry image could be to assume the objects for which the image was taken stay static in scene, and simly move the image about it. What this means is to essentially take some average of actual pixel and some surrounding pixels and re-assign back to your actual pixel. This will take the memory space of ~ 2x your original image to accomplish. Essentially I am saying to implement a 2D convolution filter. – trumpetlicks Jan 31 '13 at 13:35
    
Here is a good link for you, called gaussian blur: en.wikipedia.org/wiki/Gaussian_blur. Also looks as if you are trying to implement this in opencv, try here docs.opencv.org/doc/tutorials/imgproc/… – trumpetlicks Jan 31 '13 at 13:36
    
@trumpetlicks: The 2D convolution is true, but obtaining the right convolution mask is hard. It is certainly not a Gaussian anywhere but close to the focus. – thiton Jan 31 '13 at 13:45
    
@trumpetlicks: Gaussian Blur alone didn't help. cvSmooth offers several methods for smoothing, also Gaussian among them. – Valentin Heinitz Jan 31 '13 at 14:31
    
@trumpetlicks: "An unfocused image is VERY similar to an image taken with a long duration exposure and a bit of skakeyness of hand" I think this was another kind of unsharpness. I've intended to implement it also. This would simulate mechanical vibration. But what I am looking for, is unsharpness due to wrong lense-object distance. I think PSF suggested by thiton is the right way to dig. Thank you anyway! – Valentin Heinitz Jan 31 '13 at 14:34
up vote 4 down vote accepted

(I'm not sure if stack overflow is the right site for your problem, since it is heavily domain-specific)

View your microscope within the terms of a Point Spread Function (PSF). The PSF is the function that describes the image of a point-like light source in the microscope. If you take a single plane from the 3D point spread function, you have the defocussing behaviour for this axial distance. Fold your image with the point spread function image, and you have the defocussed image. This operation is usually called "folding", "convolution" or "smooth with kernel".

Of course, you'll need a point spread function for your microscope, and there are plenty of details to consider - most importantly, the type of optics involved, the numerical aperture, etc. Ask the relevant optical literature. Sibaritas Deconvolution Microscopy seems like a good start.

Be aware that, in general, 3D defocussing involves integrating a Bessel function through the phases. You might be able to approximate the behaviour with a Gaussian mask if the axial defocus is within roughly 2 times the lateral resolution of your microscope. This is something like one or two microns on normal microscopes. For larger axial defocusings, you need to compute the integral. I doubt that this is within OpenCV's scope, so you'd need to pre-compute a defocus function.

My dissertation project rapidSTORM has an implementation for oil objectives, but the code (pixelatedBessel.cpp) is not in opencv.

Especially for high-aperture microscopes, the computations become pretty involved, however - at my lab, we usually preferred to just put a point-like light source (e.g. a quantum dot) on the microscope and let the Z stage do the job.

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Thanks! PSF seems to be a good starting point. Thank you for the other links also! – Valentin Heinitz Jan 31 '13 at 14:29

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