def simple_image(verbose=False):
display_func = _util.display_func(verbose)
print_func = _util.print_func(verbose)
a = 10 * af.randu(6, 6)
a3 = 10 * af.randu(5, 5, 3)
dx, dy = af.gradient(a)
display_func(dx)
display_func(dy)
display_func(af.resize(a, scale=0.5))
display_func(af.resize(a, odim0=8, odim1=8))
t = af.randu(3, 2)
display_func(af.transform(a, t))
display_func(af.rotate(a, 3.14))
display_func(af.translate(a, 1, 1))
display_func(af.scale(a, 1.2, 1.2, 7, 7))
display_func(af.skew(a, 0.02, 0.02))
h = af.histogram(a, 3)
display_func(h)
display_func(af.hist_equal(a, h))
display_func(af.dilate(a))
display_func(af.erode(a))
display_func(af.dilate3(a3))
display_func(af.erode3(a3))
display_func(af.bilateral(a, 1, 2))
display_func(af.mean_shift(a, 1, 2, 3))
display_func(af.medfilt(a))
display_func(af.minfilt(a))
display_func(af.maxfilt(a))
display_func(af.regions(af.round(a) > 3))
dx, dy = af.sobel_derivatives(a)
display_func(dx)
display_func(dy)
display_func(af.sobel_filter(a))
ac = af.gray2rgb(a)
display_func(ac)
display_func(af.rgb2gray(ac))
ah = af.rgb2hsv(ac)
display_func(ah)
display_func(af.hsv2rgb(ah))
display_func(af.color_space(a, af.CSPACE.RGB, af.CSPACE.GRAY))
def simple_image(verbose = False):
display_func = _util.display_func(verbose)
print_func = _util.print_func(verbose)
a = 10 * af.randu(6, 6)
a3 = 10 * af.randu(5,5,3)
dx,dy = af.gradient(a)
display_func(dx)
display_func(dy)
display_func(af.resize(a, scale=0.5))
display_func(af.resize(a, odim0=8, odim1=8))
t = af.randu(3,2)
display_func(af.transform(a, t))
display_func(af.rotate(a, 3.14))
display_func(af.translate(a, 1, 1))
display_func(af.scale(a, 1.2, 1.2, 7, 7))
display_func(af.skew(a, 0.02, 0.02))
h = af.histogram(a, 3)
display_func(h)
display_func(af.hist_equal(a, h))
display_func(af.dilate(a))
display_func(af.erode(a))
display_func(af.dilate3(a3))
display_func(af.erode3(a3))
display_func(af.bilateral(a, 1, 2))
display_func(af.mean_shift(a, 1, 2, 3))
display_func(af.medfilt(a))
display_func(af.minfilt(a))
display_func(af.maxfilt(a))
display_func(af.regions(af.round(a) > 3))
dx,dy = af.sobel_derivatives(a)
display_func(dx)
display_func(dy)
display_func(af.sobel_filter(a))
ac = af.gray2rgb(a)
display_func(ac)
display_func(af.rgb2gray(ac))
ah = af.rgb2hsv(ac)
display_func(ah)
display_func(af.hsv2rgb(ah))
display_func(af.color_space(a, af.CSPACE.RGB, af.CSPACE.GRAY))
af.display(af.scale(a, 1.2, 1.2, 7, 7)) af.display(af.skew(a, 0.02, 0.02)) h = af.histogram(a, 3) af.display(h) af.display(af.hist_equal(a, h)) af.display(af.dilate(a)) af.display(af.erode(a)) af.display(af.dilate3(a3)) af.display(af.erode3(a3)) af.display(af.bilateral(a, 1, 2)) af.display(af.mean_shift(a, 1, 2, 3)) af.display(af.medfilt(a)) af.display(af.minfilt(a)) af.display(af.maxfilt(a)) af.display(af.regions(af.round(a) > 3)) dx,dy = af.sobel_derivatives(a) af.display(dx) af.display(dy) af.display(af.sobel_filter(a)) ac = af.gray2rgb(a) af.display(ac) af.display(af.rgb2gray(ac)) ah = af.rgb2hsv(ac) af.display(ah)
def simple_image(verbose = False):
display_func = _util.display_func(verbose)
print_func = _util.print_func(verbose)
a = 10 * af.randu(6, 6)
a3 = 10 * af.randu(5,5,3)
dx,dy = af.gradient(a)
display_func(dx)
display_func(dy)
display_func(af.resize(a, scale=0.5))
display_func(af.resize(a, odim0=8, odim1=8))
t = af.randu(3,2)
display_func(af.transform(a, t))
display_func(af.rotate(a, 3.14))
display_func(af.translate(a, 1, 1))
display_func(af.scale(a, 1.2, 1.2, 7, 7))
display_func(af.skew(a, 0.02, 0.02))
h = af.histogram(a, 3)
display_func(h)
display_func(af.hist_equal(a, h))
display_func(af.dilate(a))
display_func(af.erode(a))
display_func(af.dilate3(a3))
display_func(af.erode3(a3))
display_func(af.bilateral(a, 1, 2))
display_func(af.mean_shift(a, 1, 2, 3))
display_func(af.medfilt(a))
display_func(af.minfilt(a))
display_func(af.maxfilt(a))
display_func(af.regions(af.round(a) > 3))
dx,dy = af.sobel_derivatives(a)
display_func(dx)
display_func(dy)
display_func(af.sobel_filter(a))
display_func(af.gaussian_kernel(3, 3))
display_func(af.gaussian_kernel(3, 3, 1, 1))
ac = af.gray2rgb(a)
display_func(ac)
display_func(af.rgb2gray(ac))
ah = af.rgb2hsv(ac)
display_func(ah)
display_func(af.hsv2rgb(ah))
display_func(af.color_space(a, af.CSPACE.RGB, af.CSPACE.GRAY))
a = af.randu(6,6)
b = af.unwrap(a, 2, 2, 2, 2)
c = af.wrap(b, 6, 6, 2, 2, 2, 2)
display_func(a)
display_func(b)
display_func(c)
display_func(af.sat(a))
a = af.randu(10,10,3)
display_func(af.rgb2ycbcr(a))
display_func(af.ycbcr2rgb(a))
a = af.randu(10, 10)
b = af.canny(a, low_threshold = 0.2, high_threshold = 0.8)
display_func(af.anisotropic_diffusion(a, 0.125, 1.0, 64, af.FLUX.QUADRATIC, af.DIFFUSION.GRAD))
def simple_signal(verbose=False):
display_func = _util.display_func(verbose)
print_func = _util.print_func(verbose)
signal = af.randu(10)
x_new = af.randu(10)
x_orig = af.randu(10)
display_func(af.approx1(signal, x_new, xp = x_orig))
signal = af.randu(3, 3)
x_new = af.randu(3, 3)
x_orig = af.randu(3, 3)
y_new = af.randu(3, 3)
y_orig = af.randu(3, 3)
display_func(af.approx2(signal, x_new, y_new, xp = x_orig, yp = y_orig))
a = af.randu(8, 1)
display_func(a)
display_func(af.fft(a))
display_func(af.dft(a))
display_func(af.real(af.ifft(af.fft(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft(a)
af.ifft_inplace(b)
display_func(b)
af.fft_inplace(b)
display_func(b)
b = af.fft_r2c(a)
c = af.fft_c2r(b)
display_func(b)
display_func(c)
a = af.randu(4, 4)
display_func(a)
display_func(af.fft2(a))
display_func(af.dft(a))
display_func(af.real(af.ifft2(af.fft2(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft2(a)
af.ifft2_inplace(b)
display_func(b)
af.fft2_inplace(b)
display_func(b)
b = af.fft2_r2c(a)
c = af.fft2_c2r(b)
display_func(b)
display_func(c)
a = af.randu(4, 4, 2)
display_func(a)
display_func(af.fft3(a))
display_func(af.dft(a))
display_func(af.real(af.ifft3(af.fft3(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft3(a)
af.ifft3_inplace(b)
display_func(b)
af.fft3_inplace(b)
display_func(b)
b = af.fft3_r2c(a)
c = af.fft3_c2r(b)
display_func(b)
display_func(c)
a = af.randu(10, 1)
b = af.randu(3, 1)
display_func(af.convolve1(a, b))
display_func(af.fft_convolve1(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
a = af.randu(5, 5)
b = af.randu(3, 3)
display_func(af.convolve2(a, b))
display_func(af.fft_convolve2(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
a = af.randu(5, 5, 3)
b = af.randu(3, 3, 2)
display_func(af.convolve3(a, b))
display_func(af.fft_convolve3(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
b = af.randu(3, 1)
x = af.randu(10, 1)
a = af.randu(2, 1)
display_func(af.fir(b, x))
display_func(af.iir(b, a, x))
display_func(af.medfilt1(a))
display_func(af.medfilt2(a))
display_func(af.medfilt(a))
def simple_image(verbose=False):
display_func = _util.display_func(verbose)
print_func = _util.print_func(verbose)
a = 10 * af.randu(6, 6)
a3 = 10 * af.randu(5, 5, 3)
dx, dy = af.gradient(a)
display_func(dx)
display_func(dy)
display_func(af.resize(a, scale=0.5))
display_func(af.resize(a, odim0=8, odim1=8))
t = af.randu(3, 2)
display_func(af.transform(a, t))
display_func(af.rotate(a, 3.14))
display_func(af.translate(a, 1, 1))
display_func(af.scale(a, 1.2, 1.2, 7, 7))
display_func(af.skew(a, 0.02, 0.02))
h = af.histogram(a, 3)
display_func(h)
display_func(af.hist_equal(a, h))
display_func(af.dilate(a))
display_func(af.erode(a))
display_func(af.dilate3(a3))
display_func(af.erode3(a3))
display_func(af.bilateral(a, 1, 2))
display_func(af.mean_shift(a, 1, 2, 3))
display_func(af.medfilt(a))
display_func(af.minfilt(a))
display_func(af.maxfilt(a))
display_func(af.regions(af.round(a) > 3))
dx, dy = af.sobel_derivatives(a)
display_func(dx)
display_func(dy)
display_func(af.sobel_filter(a))
display_func(af.gaussian_kernel(3, 3))
display_func(af.gaussian_kernel(3, 3, 1, 1))
ac = af.gray2rgb(a)
display_func(ac)
display_func(af.rgb2gray(ac))
ah = af.rgb2hsv(ac)
display_func(ah)
display_func(af.hsv2rgb(ah))
display_func(af.color_space(a, af.CSPACE.RGB, af.CSPACE.GRAY))
a = af.randu(6, 6)
b = af.unwrap(a, 2, 2, 2, 2)
c = af.wrap(b, 6, 6, 2, 2, 2, 2)
display_func(a)
display_func(b)
display_func(c)
display_func(af.sat(a))
a = af.randu(10, 10, 3)
display_func(af.rgb2ycbcr(a))
display_func(af.ycbcr2rgb(a))
a = af.randu(10, 10)
b = af.canny(a, low_threshold=0.2, high_threshold=0.8)
display_func(
af.anisotropic_diffusion(a, 0.125, 1.0, 64, af.FLUX.QUADRATIC,
af.DIFFUSION.GRAD))
def simple_signal(verbose=False):
display_func = _util.display_func(verbose)
print_func = _util.print_func(verbose)
a = af.randu(10, 1)
pos0 = af.randu(10) * 10
display_func(af.approx1(a, pos0))
a = af.randu(3, 3)
pos0 = af.randu(3, 3) * 10
pos1 = af.randu(3, 3) * 10
display_func(af.approx2(a, pos0, pos1))
a = af.randu(8, 1)
display_func(a)
display_func(af.fft(a))
display_func(af.dft(a))
display_func(af.real(af.ifft(af.fft(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft(a)
af.ifft_inplace(b)
display_func(b)
af.fft_inplace(b)
display_func(b)
b = af.fft_r2c(a)
c = af.fft_c2r(b)
display_func(b)
display_func(c)
a = af.randu(4, 4)
display_func(a)
display_func(af.fft2(a))
display_func(af.dft(a))
display_func(af.real(af.ifft2(af.fft2(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft2(a)
af.ifft2_inplace(b)
display_func(b)
af.fft2_inplace(b)
display_func(b)
b = af.fft2_r2c(a)
c = af.fft2_c2r(b)
display_func(b)
display_func(c)
a = af.randu(4, 4, 2)
display_func(a)
display_func(af.fft3(a))
display_func(af.dft(a))
display_func(af.real(af.ifft3(af.fft3(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft3(a)
af.ifft3_inplace(b)
display_func(b)
af.fft3_inplace(b)
display_func(b)
b = af.fft3_r2c(a)
c = af.fft3_c2r(b)
display_func(b)
display_func(c)
a = af.randu(10, 1)
b = af.randu(3, 1)
display_func(af.convolve1(a, b))
display_func(af.fft_convolve1(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
a = af.randu(5, 5)
b = af.randu(3, 3)
display_func(af.convolve2(a, b))
display_func(af.fft_convolve2(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
a = af.randu(5, 5, 3)
b = af.randu(3, 3, 2)
display_func(af.convolve3(a, b))
display_func(af.fft_convolve3(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
b = af.randu(3, 1)
x = af.randu(10, 1)
a = af.randu(2, 1)
display_func(af.fir(b, x))
display_func(af.iir(b, a, x))
display_func(af.medfilt1(a))
display_func(af.medfilt2(a))
display_func(af.medfilt(a))
af.display(af.scale(a, 1.2, 1.2, 7, 7)) af.display(af.skew(a, 0.02, 0.02)) h = af.histogram(a, 3) af.display(h) af.display(af.hist_equal(a, h)) af.display(af.dilate(a)) af.display(af.erode(a)) af.display(af.dilate3(a3)) af.display(af.erode3(a3)) af.display(af.bilateral(a, 1, 2)) af.display(af.mean_shift(a, 1, 2, 3)) af.display(af.medfilt(a)) af.display(af.minfilt(a)) af.display(af.maxfilt(a)) af.display(af.regions(af.round(a) > 3)) dx, dy = af.sobel_derivatives(a) af.display(dx) af.display(dy) af.display(af.sobel_filter(a)) ac = af.gray2rgb(a) af.display(ac) af.display(af.rgb2gray(ac)) ah = af.rgb2hsv(ac) af.display(ah)
def simple_image(verbose=False):
display_func = _util.display_func(verbose)
a = 10 * af.randu(6, 6)
a3 = 10 * af.randu(5, 5, 3)
dx, dy = af.gradient(a)
display_func(dx)
display_func(dy)
display_func(af.resize(a, scale=0.5))
display_func(af.resize(a, odim0=8, odim1=8))
t = af.randu(3, 2)
display_func(af.transform(a, t))
display_func(af.rotate(a, 3.14))
display_func(af.translate(a, 1, 1))
display_func(af.scale(a, 1.2, 1.2, 7, 7))
display_func(af.skew(a, 0.02, 0.02))
h = af.histogram(a, 3)
display_func(h)
display_func(af.hist_equal(a, h))
display_func(af.dilate(a))
display_func(af.erode(a))
display_func(af.dilate3(a3))
display_func(af.erode3(a3))
display_func(af.bilateral(a, 1, 2))
display_func(af.mean_shift(a, 1, 2, 3))
display_func(af.medfilt(a))
display_func(af.minfilt(a))
display_func(af.maxfilt(a))
display_func(af.regions(af.round(a) > 3))
display_func(
af.confidenceCC(af.randu(10,
10), (af.randu(2) * 9).as_type(af.Dtype.u32),
(af.randu(2) * 9).as_type(af.Dtype.u32), 3, 3, 10,
0.1))
dx, dy = af.sobel_derivatives(a)
display_func(dx)
display_func(dy)
display_func(af.sobel_filter(a))
display_func(af.gaussian_kernel(3, 3))
display_func(af.gaussian_kernel(3, 3, 1, 1))
ac = af.gray2rgb(a)
display_func(ac)
display_func(af.rgb2gray(ac))
ah = af.rgb2hsv(ac)
display_func(ah)
display_func(af.hsv2rgb(ah))
display_func(af.color_space(a, af.CSPACE.RGB, af.CSPACE.GRAY))
a = af.randu(6, 6)
b = af.unwrap(a, 2, 2, 2, 2)
c = af.wrap(b, 6, 6, 2, 2, 2, 2)
display_func(a)
display_func(b)
display_func(c)
display_func(af.sat(a))
a = af.randu(10, 10, 3)
display_func(af.rgb2ycbcr(a))
display_func(af.ycbcr2rgb(a))
a = af.randu(10, 10)
b = af.canny(a, low_threshold=0.2, high_threshold=0.8)
display_func(
af.anisotropic_diffusion(a, 0.125, 1.0, 64, af.FLUX.QUADRATIC,
af.DIFFUSION.GRAD))
a = af.randu(10, 10)
psf = af.gaussian_kernel(3, 3)
cimg = af.convolve(a, psf)
display_func(
af.iterativeDeconv(cimg, psf, 100, 0.5, af.ITERATIVE_DECONV.LANDWEBER))
display_func(
af.iterativeDeconv(cimg, psf, 100, 0.5,
af.ITERATIVE_DECONV.RICHARDSONLUCY))
display_func(af.inverseDeconv(cimg, psf, 1.0, af.INVERSE_DECONV.TIKHONOV))
def simple_signal(verbose=False):
display_func = _util.display_func(verbose)
signal = af.randu(10)
x_new = af.randu(10)
x_orig = af.randu(10)
display_func(af.approx1(signal, x_new, xp=x_orig))
signal = af.randu(3, 3)
x_new = af.randu(3, 3)
x_orig = af.randu(3, 3)
y_new = af.randu(3, 3)
y_orig = af.randu(3, 3)
display_func(af.approx2(signal, x_new, y_new, xp=x_orig, yp=y_orig))
a = af.randu(8, 1)
display_func(a)
display_func(af.fft(a))
display_func(af.dft(a))
display_func(af.real(af.ifft(af.fft(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft(a)
af.ifft_inplace(b)
display_func(b)
af.fft_inplace(b)
display_func(b)
b = af.fft_r2c(a)
c = af.fft_c2r(b)
display_func(b)
display_func(c)
a = af.randu(4, 4)
display_func(a)
display_func(af.fft2(a))
display_func(af.dft(a))
display_func(af.real(af.ifft2(af.fft2(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft2(a)
af.ifft2_inplace(b)
display_func(b)
af.fft2_inplace(b)
display_func(b)
b = af.fft2_r2c(a)
c = af.fft2_c2r(b)
display_func(b)
display_func(c)
a = af.randu(4, 4, 2)
display_func(a)
display_func(af.fft3(a))
display_func(af.dft(a))
display_func(af.real(af.ifft3(af.fft3(a))))
display_func(af.real(af.idft(af.dft(a))))
b = af.fft3(a)
af.ifft3_inplace(b)
display_func(b)
af.fft3_inplace(b)
display_func(b)
b = af.fft3_r2c(a)
c = af.fft3_c2r(b)
display_func(b)
display_func(c)
a = af.randu(10, 1)
b = af.randu(3, 1)
display_func(af.convolve1(a, b))
display_func(af.fft_convolve1(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
a = af.randu(5, 5)
b = af.randu(3, 3)
display_func(af.convolve2(a, b))
display_func(af.fft_convolve2(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
c = af.convolve2NN(a, b)
display_func(c)
in_dims = c.dims()
incoming_grad = af.constant(1, in_dims[0], in_dims[1])
g = af.convolve2GradientNN(incoming_grad, a, b, c)
display_func(g)
a = af.randu(5, 5, 3)
b = af.randu(3, 3, 2)
display_func(af.convolve3(a, b))
display_func(af.fft_convolve3(a, b))
display_func(af.convolve(a, b))
display_func(af.fft_convolve(a, b))
b = af.randu(3, 1)
x = af.randu(10, 1)
a = af.randu(2, 1)
display_func(af.fir(b, x))
display_func(af.iir(b, a, x))
display_func(af.medfilt1(a))
display_func(af.medfilt2(a))
display_func(af.medfilt(a))
