def testLinear(self):
"""Test using a specified linear stretch"""
rgbImage = rgb.LinearMapping(-8.45, 13.44).makeRgbImage(self.images[R])
if display:
rgb.displayRGB(rgbImage)
def testStarsResizeSpecifications(self):
"""Test creating an RGB image changing the output """
rgbImages = [self.images[R], self.images[G], self.images[B]]
map = rgb.AsinhZScaleMapping(rgbImages[0])
for xSize, ySize, frac in [
(self.images[R].getWidth() // 2, self.images[R].getHeight() // 2,
None),
(2 * self.images[R].getWidth(), None, None),
(self.images[R].getWidth() // 2, None, None),
(None, self.images[R].getHeight() // 2, None),
(None, None, 0.5),
(None, None, 2),
]:
rgbImage = map.makeRgbImage(*rgbImages,
xSize=xSize,
ySize=ySize,
rescaleFactor=frac)
h, w = rgbImage.shape[0:2]
self.assertTrue(xSize is None or xSize == w)
self.assertTrue(ySize is None or ySize == h)
self.assertTrue(
frac is None or w == int(frac * self.images[R].getWidth()),
"%g == %g" %
(w, int((frac if frac else 1) * self.images[R].getWidth())))
if display:
rgb.displayRGB(rgbImage)
def testSaturated(self):
"""Test interpolating saturated pixels"""
satValue = 1000.0
for f in [R, G, B]:
self.images[f] = saturate(self.images[f], satValue)
rgb.replaceSaturatedPixels(self.images[R], self.images[G], self.images[B], 1, 2000)
#
# Check that we replaced those NaNs with some reasonable value
#
for f in [R, G, B]:
self.assertTrue(np.isfinite(self.images[f].getImage().getArray()).all())
if False:
ds9.mtv(self.images[B], frame=0, title="B")
ds9.mtv(self.images[G], frame=1, title="G")
ds9.mtv(self.images[R], frame=2, title="R")
#
# Prepare for generating an output file
#
for f in [R, G, B]:
self.images[f] = self.images[f].getImage()
asinhMap = rgb.AsinhMapping(self.min, self.range, self.Q)
rgbImage = asinhMap.makeRgbImage(self.images[R], self.images[G], self.images[B])
if display:
rgb.displayRGB(rgbImage)
def testLinear(self):
"""Test using a specified linear stretch"""
rgbImage = rgb.LinearMapping(-8.45, 13.44).makeRgbImage(self.images[R])
if display:
rgb.displayRGB(rgbImage)
def testStars(self):
"""Test creating an RGB image"""
asinhMap = rgb.AsinhMapping(self.min, self.range, self.Q)
rgbImage = asinhMap.makeRgbImage(self.images[R], self.images[G], self.images[B])
if display:
rgb.displayRGB(rgbImage)
def display_image(image, contrast=1, figsize=(8, 8)):
"""Use matplotlib to plot an afw.image.Image."""
plt.figure(figsize=figsize)
scaled_image = ZScaleMapping(image, contrast=contrast)\
.makeRgbImage(image, image, image)
displayRGB(scaled_image)
plt.axis('off')
def testStarsAsinhZscaleIntensityBW(self):
"""Test creating a black-and-white image using an asinh stretch estimated
using zscale on the intensity"""
rgbImage = rgb.AsinhZScaleMapping(self.images[R]).makeRgbImage()
if display:
rgb.displayRGB(rgbImage)
def testStarsAsinhZscaleIntensityBW(self):
"""Test creating a black-and-white image using an asinh stretch estimated
using zscale on the intensity"""
rgbImage = rgb.AsinhZScaleMapping(self.images[R]).makeRgbImage()
if display:
rgb.displayRGB(rgbImage)
def testStarsAsinhZscaleIntensity(self):
"""Test creating an RGB image using an asinh stretch estimated using zscale on the intensity"""
rgbImages = [self.images[R], self.images[G], self.images[B]]
map = rgb.AsinhZScaleMapping(rgbImages)
rgbImage = map.makeRgbImage(*rgbImages)
if display:
rgb.displayRGB(rgbImage)
def testLinearMinMax(self):
"""Test using a min/max linear stretch
N.b. also checks that an image passed to the ctor is used as the default in makeRgbImage()
"""
rgbImage = rgb.LinearMapping(image=self.images[R]).makeRgbImage()
if display:
rgb.displayRGB(rgbImage)
def testStarsAsinhZscaleIntensity(self):
"""Test creating an RGB image using an asinh stretch estimated using zscale on the intensity"""
rgbImages = [self.images[R], self.images[G], self.images[B]]
map = rgb.AsinhZScaleMapping(rgbImages)
rgbImage = map.makeRgbImage(*rgbImages)
if display:
rgb.displayRGB(rgbImage)
def testLinearMinMax(self):
"""Test using a min/max linear stretch
N.b. also checks that an image passed to the ctor is used as the default in makeRgbImage()
"""
rgbImage = rgb.LinearMapping(image=self.images[R]).makeRgbImage()
if display:
rgb.displayRGB(rgbImage)
def testStarsResizeToSize(self):
"""Test creating an RGB image of a specified size"""
xSize = self.images[R].getWidth()//2
ySize = self.images[R].getHeight()//2
for rgbImages in ([self.images[R], self.images[G], self.images[B]],
[afwImage.ImageU(_.getArray().astype('uint16')) for _ in [
self.images[R], self.images[G], self.images[B]]]):
rgbImage = rgb.AsinhZScaleMapping(rgbImages[0]).makeRgbImage(*rgbImages,
xSize=xSize, ySize=ySize)
if display:
rgb.displayRGB(rgbImage)
def testStarsResizeToSize(self):
"""Test creating an RGB image of a specified size"""
xSize = self.images[R].getWidth()//2
ySize = self.images[R].getHeight()//2
for rgbImages in ([self.images[R], self.images[G], self.images[B]],
[afwImage.ImageU(_.getArray().astype('uint16')) for _ in [
self.images[R], self.images[G], self.images[B]]]):
rgbImage = rgb.AsinhZScaleMapping(rgbImages[0]).makeRgbImage(*rgbImages,
xSize=xSize, ySize=ySize)
if display:
rgb.displayRGB(rgbImage)
def testStarsAsinhZscaleIntensityPedestal(self):
"""Test creating an RGB image using an asinh stretch estimated using zscale on the intensity
where the images each have a pedestal added"""
rgbImages = [self.images[R], self.images[G], self.images[B]]
pedestal = [100, 400, -400]
for i, ped in enumerate(pedestal):
rgbImages[i] += ped
map = rgb.AsinhZScaleMapping(rgbImages, pedestal=pedestal)
rgbImage = map.makeRgbImage(*rgbImages)
if display:
rgb.displayRGB(rgbImage)
def testStarsAsinhZscaleIntensityPedestal(self):
"""Test creating an RGB image using an asinh stretch estimated using zscale on the intensity
where the images each have a pedestal added"""
rgbImages = [self.images[R], self.images[G], self.images[B]]
pedestal = [100, 400, -400]
for i, ped in enumerate(pedestal):
rgbImages[i] += ped
map = rgb.AsinhZScaleMapping(rgbImages, pedestal=pedestal)
rgbImage = map.makeRgbImage(*rgbImages)
if display:
rgb.displayRGB(rgbImage)
def plotDeblendFamilyRGB(parent,
bands=['g', 'r', 'i'],
min=0.01,
max=0.5,
Q=8,
rgbFileFmt=None):
x, y = parent.getX(), parent.getY()
fams = {}
imBbox = afwGeom.BoxI()
for bandName in "GRI".upper():
filterName = "HSC-%s" % bandName
x0, y0 = coaddDict[filterName].getXY0()
x0, y0 = 0, 0
fams[filterName] = familiesDict[filterName].find((x + x0, y + y0),
matchRadius=20)
if not fams[filterName]:
return
parent, kids = fams[filterName]
bbox = parent.getFootprint().getBBox()
for kid in kids:
kim = footprintToImage(kid.getFootprint(),
coaddDict[filterName].getMaskedImage())
bbox.include(kim.getBBox(afwImage.PARENT))
imBbox.include(bbox)
images = {}
for bandName in bands:
filterName = "HSC-%s" % bandName.upper()
images[bandName] = makeDeblendFamilyMosaic(
coaddDict[filterName].getMaskedImage(),
*fams[filterName],
background=-0.1,
imBbox=imBbox).makeMosaic(display=None)
for bands in [bands]:
B, G, R = bands
rgb = afwRgb.makeRGB(images[R], images[G], images[B], min, max - min,
Q)
afwRgb.displayRGB(rgb, show=True)
if rgbFileFmt:
afwRgb.writeRGB(rgbFileFmt % "".join(bands), rgb)
def testZScale(self):
"""Test using a zscale stretch"""
rgbImage = rgb.ZScaleMapping(self.images[R]).makeRgbImage()
if display:
plt = rgb.displayRGB(rgbImage, False)
plt.title("zscale")
plt.show()
def testZScale(self):
"""Test using a zscale stretch"""
rgbImage = rgb.ZScaleMapping(self.images[R]).makeRgbImage()
if display:
plt = rgb.displayRGB(rgbImage, False)
plt.title("zscale")
plt.show()
def plotDeblendFamilyRGB(parent, bands=['g', 'r', 'i'],
min=0.01, max=0.5, Q=8, rgbFileFmt=None):
x, y = parent.getX(), parent.getY()
fams = {}
imBbox = afwGeom.BoxI()
for bandName in "GRI".upper():
filterName = "HSC-%s" % bandName
x0, y0 = coaddDict[filterName].getXY0()
x0, y0 = 0, 0
fams[filterName] = familiesDict[filterName].find((x + x0, y + y0), matchRadius=20)
if not fams[filterName]:
return
parent, kids = fams[filterName]
bbox = parent.getFootprint().getBBox()
for kid in kids:
kim = footprintToImage(kid.getFootprint(), coaddDict[filterName].getMaskedImage())
bbox.include(kim.getBBox(afwImage.PARENT))
imBbox.include(bbox)
images = {}
for bandName in bands:
filterName = "HSC-%s" % bandName.upper()
images[bandName] = makeDeblendFamilyMosaic(coaddDict[filterName].getMaskedImage(),
*fams[filterName],
background=-0.1, imBbox=imBbox).makeMosaic(display=None)
for bands in [bands]:
B, G, R = bands
rgb = afwRgb.makeRGB(images[R], images[G], images[B], min, max - min, Q)
afwRgb.displayRGB(rgb, show=True)
if rgbFileFmt:
afwRgb.writeRGB(rgbFileFmt % "".join(bands), rgb)
def testStarsResizeSpecifications(self):
"""Test creating an RGB image changing the output """
rgbImages = [self.images[R], self.images[G], self.images[B]]
map = rgb.AsinhZScaleMapping(rgbImages[0])
for xSize, ySize, frac in [(self.images[R].getWidth()/2, self.images[R].getHeight()/2, None),
(2*self.images[R].getWidth(), None, None),
(self.images[R].getWidth()/2, None, None),
(None, self.images[R].getHeight()/2, None),
(None, None, 0.5),
(None, None, 2),
]:
rgbImage = map.makeRgbImage(*rgbImages, xSize=xSize, ySize=ySize, rescaleFactor=frac)
h, w = rgbImage.shape[0:2]
self.assertTrue(xSize is None or xSize == w)
self.assertTrue(ySize is None or ySize == h)
self.assertTrue(frac is None or w == int(frac*self.images[R].getWidth()),
"%g == %g" % (w, int((frac if frac else 1)*self.images[R].getWidth())))
if display:
rgb.displayRGB(rgbImage)
def testStars2(self):
"""Test creating an RGB image using makeRGB"""
rgbImage = rgb.makeRGB(self.images[R], self.images[G], self.images[B])
if display:
rgb.displayRGB(rgbImage)
