# Tag Info

18

I've done this exact thing myself, and I see several things that could be optimized here. First off, I'd remove the enableTexture conditional and instead split your shader into two programs, one for the true state of this and one for false. Conditionals are very expensive in iOS fragment shaders, particularly ones that have texture reads within them. ...

13

I finally found a suitable solution: RenderScript allows implementing heavy computations which are scaled transparently to all cores available on the executing device. I've come to the conclusion, that with respect to a reasonable balance of performance and implementation complexity, this is a better approach than JNI or shaders. Since API Level 17, there ...

11

The only sensible way to do this is with FFT convolution, as underpins the filter function and similar. It is very easy to do manually: % Simulate some data n = 10^6; x = randi(10,1,n); xpad = [zeros(1,n) x]; % Setup smoothing kernel k = 1 ./ [(n+1):-1:2 1:n]; % FFT convolution Fx = fft(xpad); Fk = fft(k); Fxk = Fx .* Fk; xk = ifft(Fxk); xk = xk(1:n); ...

11

The basic idea is that the new pixels of the image are created by an weighted average of the pixels close to it (imagine drawing a circle around the pixel). For each pixel in the image you are going to create a little square around the pixel. Lets say you take the 8 neighbors next to a pixel (including diagonals even though do not matter here), and we ...

10

If the 2D filter kernel has a rank of 1 then it is separable. You can test this in e.g. Matlab or Octave: octave-3.2.3:1> sobel = [-1 0 1 ; -2 0 2 ; -1 0 1]; octave-3.2.3:2> rank(sobel) ans = 1 octave-3.2.3:3> See also: http://blogs.mathworks.com/steve/2006/11/28/separable-convolution-part-2/ - this covers using SVD (Singular Value ...

10

Here's how: #include <stddef.h> #include <stdio.h> void convolve(const double Signal[/* SignalLen */], size_t SignalLen, const double Kernel[/* KernelLen */], size_t KernelLen, double Result[/* SignalLen + KernelLen - 1 */]) { size_t n; for (n = 0; n < SignalLen + KernelLen - 1; n++) { size_t kmin, ...

9

A convolution kernel is a matrix of values that specify how the neighborhood of a pixel contribute to that pixel's state in the final image. There's a fair description of the basics here. A gaussian blur is a convolution function that uses a really ugly (you've seen the wikipedia page) function to compute a convolution kernel to pass over the image. ...

8

So I tested this out and can now confirm a few things: 1) numpy.convolve is not circular, which is what the fft code is giving you: 2) FFT does not internally pad to a power of 2. Compare the vastly different speeds of the following operations: x1 = np.random.uniform(size=2**17-1) x2 = np.random.uniform(size=2**17) np.fft.fft(x1) np.fft.fft(x2) 3) ...

8

What are the dimensions of the image and the kernel ? If the kernel is large then you can use FFT-based convolution, otherwise for small kernels just use direct convolution. The DSP might not be the best way to do this though - just because it has a MAC instruction doesn't mean that it will be more efficient. Does the ARM CPU on the Beagle Board have NEON ...

8

Without padding the result will be equivalent to circular convolution as you point out. For linear convolution, in convolving 2 images (2D signals) A*B the full output will be of size Ma+Mb-1 x Na+Nb-1, where Ma x Na, Mb x Nb the sizes of images A and B resp. After padding to the expected size, multiplying and transforming back, via ifft2, you can keep the ...

8

Convolution is a mathematical operator primarily used in signal processing. Numpy simply uses this signal processing nomenclature to define it, hence the "signal" references. An array in numpy is a signal. The convolution of two signals is defined as the integral of the second signal reversed sweeping over the first signal. It can more clearly be understood ...

7

FFT convolutions are based on the convolution theorem, which states that givem two functions f and g, if Fd() and Fi() denote the direct and inverse Fourier transform, and * and . convolution and multiplication, then: f*g = Fi(Fd(d).Fd(g)) To apply this to a signal f and a kernel g, there are some things you need to take care of: f and g have to be of ...

7

There are a number of different ways to do it with scipy, but 2D convolution isn't directly included in numpy. (It's also easy to implement with an fft using only numpy, if you need to avoid a scipy dependency.) scipy.signal.convolve2d, scipy.signal.convolve, scipy.signal.fftconvolve, and scipy.ndimage.convolve will all handle a 2D convolution (the last ...

7

What exact operation are you doing? There are a number of optimizations that ndimage provides if you don't need general N-d convolution. For example, your current operation: img = np.ones((512,512,512)) kernel = np.ones((5,5,5))/125 result = ndimage.convolve(img, kernel) is equivalent to: img = np.ones((512,512,512)) result = ...

7

Filter applies the mask extending upward and to the left, following the mathematical convention that the convolution between two functions reverses the direction of the second function. The box filter mask extends downwards and to the right, which is probably more intuitive. In any case, the problem is caused by the fact that the input image in the changed ...

7

convolution is associative, which means (f*g)*h = f*(g*h). So instead of r = conv(conv(x, [1,1,1]), [1,1,1]) you can use the more efficient (since you convolve on the image only once) asd = conv([1,1,1], [1,1,1]); r = conv(x, asd) where the new function is [1 2 3 2 1], which however is not of the same size of the original filter.

7

The 2-D FFT is seperable and you are correct in how to perform it except that you must multiply by the 2-D FFT of the 2D kernel. If you are using kissfft, an easier way to perform the 2-D FFT is to just use kiss_fftnd in the tools directory of the kissfft package. This will do multi-dimensional FFTs. The kernel size does not have to be any particular ...

7

The code in scipy for doing 2d convolutions is a bit messy and unoptimized. See http://svn.scipy.org/svn/scipy/trunk/scipy/signal/firfilter.c if you want a glimpse into the low-level functioning of scipy. If all you want is to process with a small, constant kernel like the one you showed, a function like this might work: def specialconvolve(a): # ...

6

Both convolve and fft are circular. The first element of convolution must be the dot product of these two series. The results you obtain are correct in this sense. To perform a linear convolution use: convolve(h2\$xt,x2\$xt,type="open") Circular convolution is also applied in this case but a required amount of zeros are padded to inputs to achieve linear ...

6

I think this is your answer. It's using different algorithms http://forums.nvidia.com/index.php?showtopic=195094 "I have been working on a similar problem. In the cuFFT manual, it is explained that cuFFT uses two different algorithms for implementing the FFTs. One is the Cooley-Tuckey method and the other is the Bluestein algorithm. When the ...

6

Even with the use of NEON vector operations via something like the Accelerate framework (which OpenCV currently doesn't use, if I'm not missing something), it's going to be hard to beat the performance of shaders when running simple 3x3 convolution kernels. For example, I can run a Sobel edge detection kernel on a 640x480 frame of video in 2.5 ms on an ...

6

You can certainly improve the performance of this operation significantly. The good news is that you don't need to drop into Java for this: Clojure is extremely fast if you optimise it correctly and in most instances can produce the same speed as pure Java. For maximum performance of numerical code in Clojure you will want to use: arrays, because you want ...

6

During the rsForEach call (or other Renderscript function), you can access the neighbouring pixels of the original image (or whatever type of data you are using) by binding the original image allocation to a pointer within the Renderscript where it can then be accessed as an array. Here is an example based upon the HelloCompute example: #pragma version(1) ...

6

In principle, yes. Just convert both images to frequency space using an FFT and divide the FFT of the result image by that of the source image. Then apply the inverse FFT to get an approximation of the convolution kernel. To see why this works, note that convolution in the spatial domain corresponds to multiplication in the frequency domain, and so ...

6

Very good and interesting question! :) For certain special matrix structures, the Ax = b problem can be solved very quickly. Circulant matrices. Matrices corresponding to cyclic convolution Ax = h*x (* - is convolution symbol) are diagonalized in the Fourier domain, and can be solved by: x = ifft(fft(b)./fft(h)); Triangular and banded. Triangular ...

5

You can use interp2 to find intermediate values on the same grid size for visualization purposes step = 0.1; % granularity [xn,yn] = meshgrid(1:step:5); % define finer grid zn = interp2(x,y,z,xn,yn); % get new z values surf(xn,yn,zn); Note that you will obtain the closest approximation to your original kernel using the default linear interpolation ...

5

You can start with a convolution, choose the values that exceed 1, and finally use a "dilation": b = numpy.convolve(a, [1, 1, 1], mode="same") > 1 b = b | numpy.r_[0, b[:-1]] | numpy.r_[b[1:], 0] Since this avoids the Python loop, it should be faster than your approach, but I didn't do timings. An alternative is to use a second convolution to dilate: ...

5

filter can handle FIR and IIR systems, while conv takes two inputs and returns their convolution. So conv(h,x) and filter(h,1,x) would give the same result. The 1 in filter indicates that the recursive coefficients of the filter are just [1]. But if you have an IIR filter, you can't use conv. filter can also return the filter states, so that it can be used ...

5

Scipy and Numpy are pretty efficient for numerical calculations. Specifically, you can use convolve and deconvolve For an even faster implementation of convolve, also check out fftconvolve

5

An faster version: __global__ void convAgB(double *a, double *b, double *c, int sa, int sb) { int i = (threadIdx.x + blockIdx.x * blockDim.x); int idT = threadIdx.x; int out,j; __shared__ double c_local [512]; c_local[idT] = c[i]; out = (i > sa) ? sa : i + 1; j = (i > sb) ? i - sb + 1 : 1; for(; j < out; j++) ...

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