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3

You're conflating conversion between time-discrete and time-continuous forms of a signal with reversibility of a transform. The only guarantee is: For a given transform of some discrete signal, its inverse transform will yield the "same" discrete signal back. The discrete signal is abstract from any frequencies. All that the transform does is take some ...


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Since you already have a array with the FFT values, you can implement a low pass filter by setting those FFT coefficients that correspond to frequencies over your cut-off value to zero. EDIT: After computing the FFT you don't get an array of frequencies, you get an array of complex numbers representing the magnitude and phase of the data.You should be able ...


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It seems that your issue resides in the way you print out the result. You cannot use the same routine to print for the two cases of CUFFT_R2C and CUFFT_C2C. In the former case, you have a (NY/2+1)*NX sized output, while the the latter case you have a NY*NX sized output. The fixed code below should work. Also, it would be also good to add proper CUDA error ...


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You are seeing several things when you increase the sample rate: most (forward) FFT implementations have an implicit scaling factor of N (sometimes sqrt(N)) - if you're increasing your FFT size as you increase the sample rate (i.e. keeping the time window constant) then the apparent magnitude of the peaks in the FFT will increase. When calculating absolute ...


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By applying an fft to the whole signal, you lose temporal information. You may not be that familiar with audio processing, but it seems to that such exercise is fun to learn a bit the basics if you are curious about it. The common time-frequency representation of a signal is the STFT, check out the Matlab help on spectrogram. However, the STFT is not the ...


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1.5 semitones happens to be the same ratio as the ratio between sampling rates of 48 kHz and 44.1 kHz. My guess is that you have hard-coded 48 kHz as your sample rate but that some of your computers are actually using a sample rate of 44.1 kHz (or vice versa). You should use a suitable API to determine the sample rate in use, or explicitly set it yourself. ...


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To draw large complex 2D graphs rapidly (30 or 60 fps) on iOS devices, one likely has to use Open GL to keep the most of any graph rendering on the GPU. Any Core Graphics or raw bitmap drawing into UIViews or CALayers will require not only lots of CPU cycles, but uploading large textures to the GPU texture cache, which will hit a bandwidth limit.


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Here is one library: http://www.fftw.org/download.html You can also use R with Java. See this link: Java-R integration? If you are not familiar with R check their home page r-project dot org (I can't post more links) While I haven't checked the implementation you link to, you should be able to use that one by suppling 0s for the imaginary part. In that ...


1

The Goertzel algorithm (or filter) is similar to computing the magnitude for just 1 bin of an FFT. The Goertzel algorithm is identical to 1 bin of an FFT, except for numerical artifacts, if the period of the frequency is an exact submultiple of your Goertzel filter's length. Otherwise there are some added scalloping effects from a rectangular window of ...


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I look at spectra almost every day, but I never heard of 'coherent integration' as a method to calculate one. As also mentioned by Jason, coherent integration would only work when your signal has a fixed phase during every FFT you average over. It is more likely that you want to do what the article calls 'incoherent integration'. This is more commonly known ...


1

Integration or averaging of FFT frames just amounts to adding the frames up element-wise and dividing by the number of frames. Since MATLAB provides vector operations, you can just add the frames with the + operator. coh_avg = (frame1 + frame2 + ...) / Nframes Where frameX are the complex FFT output frames. If you want to do non-coherent averaging, you ...


1

You have two options, both involve copying the pixels. You can either use the methods provided by the Image interface, namely At(x,y) or you can assert the image to one of the image types provided by the image packet and access the Pix attribute directly. Since you will most likely be using a Gray image, you could easily assert your image to type ...


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Remember that all processus execute the code in mpi. So as you write src(2,1)=(1.D0,0.D0) you are setting size frequencies, one for each process. Therefore, your code seems to work if a single process is used mpiexec -np 1 c2rnot. But if you run many processus mpiexec -np 2 c2rnot, you get something else... Could you try if(id==0) src(2,1)=(1.D0,0.D0) ...


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The method described above is not different from a Fourier transform. Fourier transform of a signal computes the integral of the signal multiplied by e-i.omega.t. Remember that ei.x = cos(x) + i.sin(x) By multiplying by sine and cosines, taking the average, and combining the results into a complex number, you are doing mathematically a very similar ...


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You probably want to set the imaginary component of your complex input to zero, not to the next point. The functions you want are sinusoids. Each sinusoid will have a frequency of an FFT result bin index * Fs/N. The magnitude and phase of each sinusoid will be given by the complex value corresponding to its FFT result bin. You can sum an increasing ...


1

DoubleFFT_1D has methods realForward which take an array of real-valued samples (doubles), so you do not need to convert the input to Complex. The documentation you linked further describes the input requirements which are different depending on if you use realForward(double[]) or realForward(double[], int).


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If you are working with audio with a bit depth of 16 bits (each sample has 16 bits), then each byte will only have half of a sample.What you need to do is cast your bytes to 16 bit samples then divide the resulting number by 32768 (This is the magnitude of the smallest number a 2's complement 16 bit number can store i.e 2^15) to get the actual audio sample ...


1

Generalized FFT functions like working with arrays of complex inputs and outputs. So, for input, you might need to create an array of complex numbers which conform to the Complex data structure that the FFT library wants. This will probably consist of a real and an imaginary component for each. Just set the imaginary portion to 0. The real portion is ...


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Selena, you appear to have a namespace collision. If you need both the Apache Commons bundle and the org.apache.batik.ext.awt.g2d bundle, you may have to try qualifying the variable declaration like this: org.apache.commons.math3.transform.TransformType type; What are you importing in this code file?


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1.Validation look here: slow DFT,iDFT at the end is mine slow implementation of DFT and iDFT tested and correct I also use it for fast implementations validation in the past 2.Your code stop recursion is wrong (you forget to set the return element) mine looks like this: if (n<=1) { if (n==1) { dst[0]=src[0]*2.0; dst[1]=src[1]*2.0; } return; } so ...



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