Fix center value of kernel; refactor; add high-pass, band-reject, and band-pass filters.
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LowPass.hs
98
LowPass.hs
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@ -12,32 +12,44 @@ import Numeric.GSL.Fourier as LA
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import Control.Applicative
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import Data.Complex
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import System.IO
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import System.Random
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import System.Time
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import Text.Printf
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sample_rate, cutoff :: Double
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sample_rate = 10000 {-Hz-}
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cutoff = 1000 {-Hz-}
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kernel_size :: Int
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kernel_size = 101
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lowPassKernel :: Vector Double
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lowPassKernel = raw / V.singleton sum
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lowPassKernel :: Double -> Double -> Int -> Vector Double
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lowPassKernel sr fc ksize = raw / V.singleton sum
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where
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n = V.enumFromN 0 kernel_size
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t = (n - fromIntegral (kernel_size `div` 2)) / V.singleton sample_rate
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n = V.enumFromN 0 ksize
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t = (n - fromIntegral (ksize `div` 2)) / V.singleton sr
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-- sinc function; replace division by zero with limit when t=0
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sinc' = sin (V.singleton (2*pi*cutoff) * t) / (V.singleton pi * t)
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sinc = sinc' V.// [(kernel_size `div` 2, 2 * pi * cutoff / sample_rate)]
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sinc' = sin (V.singleton (2*pi*fc) * t) / (V.singleton pi * t)
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sinc = sinc' V.// [(ksize `div` 2, 2 * fc)]
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-- Hamming window function
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kmax = fromIntegral (kernel_size - 1)
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kmax = fromIntegral (ksize - 1)
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hamm = 0.54 - 0.46 * cos (V.singleton (2 * pi / kmax) * n)
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-- Normalize the result
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raw = sinc * hamm
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sum = sumElements raw
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invertSpectrum :: Vector Double -> Vector Double
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invertSpectrum kernel = midVal `seq` (negate kernel V.// [(mid, 1 - midVal)])
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where
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mid = (dim kernel) `div` 2
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midVal = kernel @> mid
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highPassKernel :: Double -> Double -> Int -> Vector Double
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highPassKernel sr fc ksize =
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invertSpectrum $ lowPassKernel sr fc ksize
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bandRejectKernel :: Double -> (Double, Double) -> Int -> Vector Double
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bandRejectKernel sr (lfc, hfc) ksize =
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lowPassKernel sr lfc ksize + highPassKernel sr hfc ksize
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bandPassKernel :: Double -> (Double, Double) -> Int -> Vector Double
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bandPassKernel sr (lfc, hfc) ksize =
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invertSpectrum $ bandRejectKernel sr (lfc, hfc) ksize
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-- convolution = integral(kernel(t-tau)*input(tau),tau)
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-- t is output vector index (j); products and summation are done with dot product (<.>)
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convolve :: Vector Double -> Vector Double -> Vector Double
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@ -48,18 +60,20 @@ convolve kernel input = V.generate osize $ \j -> rkernel <.> V.slice j ksize inp
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osize = isize - ksize
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rkernel = V.reverse kernel
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main :: IO ()
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main = do
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let isize = 2000000
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seed <- randomIO
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(input, inputTime) <- time $ return $ LA.randomVector seed Gaussian isize
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(_, kernelTime) <- time $ return lowPassKernel
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(result, resultTime) <- time $ return $ convolve lowPassKernel input
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V.mapM_ (printf "%10.6f\n") $ V.slice 0 50 result
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--V.mapM_ (printf "%10.6f\n") $ V.map magnitude $ LA.fft $ V.map (:+0) result
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printf "Input Time: %8.6f seconds\n" $ inputTime
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printf "Kernel Time: %8.6f seconds\n" $ kernelTime
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printf "Result Time: %8.6f seconds\n" $ resultTime
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decimate :: Int -> Vector Double -> Vector Double
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decimate osize vec =
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V.generate osize $ \j ->
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(sumElements $ V.slice (j * ssize) ssize vec) / fromIntegral ssize
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where
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vsize = dim vec
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ssize = vsize `div` osize
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diffClockTimesSec :: ClockTime -> ClockTime -> Double
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diffClockTimesSec a b = sec + picosec / 1.0e12
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where
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diff = diffClockTimes a b
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sec = fromIntegral $ tdSec diff
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picosec = fromIntegral $ tdPicosec diff
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time :: IO a -> IO (a, Double)
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time f = do
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@ -68,9 +82,29 @@ time f = do
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end <- x `seq` getClockTime
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return (x, diffClockTimesSec end start)
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diffClockTimesSec :: ClockTime -> ClockTime -> Double
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diffClockTimesSec a b = sec + picosec / 1.0e12
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where
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diff = diffClockTimes a b
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sec = fromIntegral $ tdSec diff
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picosec = fromIntegral $ tdPicosec diff
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main :: IO ()
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main = do
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let sample_rate = 10000 {-Hz-} :: Double
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let cutoff = 1000 {-Hz-} :: Double
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let input_size = 1000000 :: Int
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let kernel_size = 201 :: Int
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seed <- randomIO
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(input, inputTime) <- time $ return $ LA.randomVector seed Gaussian input_size
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(kernel, kernelTime) <- time $ return $ lowPassKernel sample_rate cutoff kernel_size
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(result, resultTime) <- time $ return $ convolve kernel input
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--V.mapM_ (printf "%10.6f\n") kernel
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--let fft_result = V.map magnitude $ LA.fft $ V.map (:+0) result
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--V.mapM_ (printf "%10.6f\n") . decimate 500 . V.take (dim fft_result `div` 2) $ fft_result
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V.mapM_ (printf "%10.6f\n") . V.slice 0 50 $ result
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hFlush stdout
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hPutStrLn stderr $ printf "Input Time: %8.6f seconds" inputTime
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hPutStrLn stderr $ printf "Kernel Time: %8.6f seconds" kernelTime
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hPutStrLn stderr $ printf "Result Time: %8.6f seconds" resultTime
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