I would like to improve the layer mask that I am creating in Python. Although my mask pretty much hits the targeted color, my main problem with it, is it is doing so in binary, the pixel is either pure white or pure black. I'm unable to extrapolate the intensity of the color. I want to achieve something like how Photoshop does it wherein there are mid-tones of grey on the mask.

enter image description here enter image description here

Here is the current attempt: import cv2

image = cv2.imread('grade_0.jpg')

lower = np.array([0,0,0])
upper = np.array([12,255,255])

mask = cv2.inRange(cv2.cvtColor(image, cv2.COLOR_BGR2HSV), lower, upper)  
mask = 255 - mask
# mask = cv2.bitwise_not(mask) #inverting black and white
output = cv2.bitwise_and(image, image, mask = mask)

cv2.imshow("output", output)
cv2.imshow("mask", mask)

enter image description here enter image description here

Here are the plain images.

enter image description here enter image description here

  • 1
    inRange() won't be enough then. you'll have to define which colors are fully "in" the mask, which are fully "out", and how intermediate colors are mapped to alpha values. all of that can be done with plain numpy operations, or OpenCV operations doing the same as the numpy operations, except with more optimization. Mar 20 at 9:02
  • @ChristophRackwitz im sorry im having trouble understanding the "in" and "out" analogy. Can you please show of an example how it is done? which specific functions are needed to achieve the result desired?
    – DrakeJest
    Mar 20 at 10:41
  • your inRange now filter all h > 12, so h>12 -> mask = 1, h<=12 -> mask = 0. What @ChristophRackwitz says is doing something like h>50 -> mask = 1, h<12 -> mask=0, and 12<=h<=50 scales linearly between 0,1, i.e. (h-12)/(50-12). Adjust the upper bound 50 accordingly. Remember hue is circular, so h=179 is very close to h=0. Mar 21 at 13:47
  • to segment hues near 0, there are two common approaches. (1) select two ranges, 0 and up, and 359 (or 179) and down. (2) shift/rotate hues (add, modulo) so the range you want is away from this wrap-around. Mar 21 at 13:59
  • 1
    @VC.One , yes i understand it cant be done in binary. When i first asked the question i did not even know that masks are binary in nature. I cannot remember the exact value used in that image, but if i do it again in photoshop , its : HEX 7d5c4d, here is the image
    – DrakeJest
    Mar 28 at 16:24

4 Answers 4


Biiiiiig picture first. It's clickable and should be clicked. Let your eyes wander.

enter image description here

Pick your parameters:

  • The stain color you're interested in. I assumed some type of dark red/brown.
  • The distance function. I picked a gaussian. It's nice.
  • The parameters of the distance function. I show a bunch of sigmas, and two particular ways to weigh the colors.

Common definitions and functions:

import numpy as np
import cv2 as cv

target = (75, 105, 150) # BGR

subject = cv.imread(...)

distvecs = subject - np.float32(target)[None, None, :]

One flavor of weighting the color differences:

distvecs *= (0.114, 0.587, 0.299) # blue weighted least, according to perception
distance = distvecs.sum(axis=2) # manhattan distance

Other flavor of weighting the color differences:

# equal weight, euclidean distance
distance = np.linalg.norm(distvecs, axis=2)

You can come up with whatever you like. You could even mess around with color spaces. There are no rules.

Applying the gaussian to the distances:

def gaussian(x, sigma):
    return np.exp(-np.power(x, 2) / (2 * np.power(sigma, 2)))

def max_normalize(x):
    return x / x.max()

scored = max_normalize(gaussian(distance, sigma))

And that's the "mask".

And here's another result with a different target color, BGR tuple (68, 60, 100)

enter image description here

And another, for (121, 45, 87):

enter image description here

I'm surprised that everyone seems to do some kind of threshold, i.e. visible discontinuities.

There is some of that in my solution too, but only where the pictures contain high frequency components (strong gradients).

  • Hello ! I have waited for your answer, and it was worth the wait. I think the np.linalg method seems to be more accurate, manhattan seems to hit the bluish pixels more. So far the best solution, I like how it doesnt hit the blue pixels as much as the other solutions
    – DrakeJest
    Mar 28 at 23:25
  • the stain might have a touch of blue (if it's turning violet = red+blue) but it looks more brownish (red+green) to me. you can penalize blue by giving it extra weight, rather than less weight. Mar 28 at 23:37
  • Indeed i can see the effect by increasing blue's weight. What would be the conditions for increasing/decreasing the colors weight? is it really just if i see certain color appearing in the mask, ill increase its weight until i dont see it anymore?
    – DrakeJest
    Mar 29 at 0:19
  • that would work. weight is linear, so are the euclidean and manhattan distances, but the gaussian is non-linear, i.e. if you vary both a linear and a non-linear parameter, you might see more effects than just by varying one. for experimenting, I'd recommend placing some OpenCV trackbars in the window for any parameters you want to explore. the tight feedback loop (try something, see the effect) will quickly give you an intuition for the parameters you choose to vary. when I whipped this up, I just edited the code and reran it, which makes changing of parameters very slow/coarse. Mar 29 at 7:19
  • as for the "range and fuzziness" of photoshop, that aspect would be a sibling to the gaussian. photoshop's approach sounds like it's "piecewise linear", so something like if dist <= range: return 1; if dist <= range + fuzziness: return 1 - (dist - range) / fuzziness; return 0 might do the trick Mar 29 at 7:49

I believe applying quantization to your image might achieve the desired effect similar to color range as seen in Adobe Photoshop. Below is the code snippet that I've used for posterization, inspired by a solution on Stack Overflow (Adobe Photoshop-style posterization and OpenCV). This approach utilizes quantization to reduce the number of colors, effectively targetting color on the image:

import numpy as np
import cv2

gray_scale = True
im = cv2.imread('6TODV.jpg')
# im = cv2.imread('2sb5L.jpg')
n = 4    # Number of levels of quantization

indices = np.arange(0,256)   # List of all colors 

divider = np.linspace(0,255,n+1)[1] # we get a divider

quantiz = np.int0(np.linspace(0,255,n)) # we get quantization colors

color_levels = np.clip(np.int0(indices/divider),0,n-1) # color levels 0,1,2..

palette = quantiz[color_levels] # Creating the palette

im2 = palette[im]  # Applying palette on image

im2 = cv2.convertScaleAbs(im2) # Converting image back to uint8
if gray_scale:
    im2 = cv2.cvtColor(im2, cv2.COLOR_BGR2GRAY)


# mouse callback function for picking color
def onClick(event,x,y,flags,param):
    """Called whenever user left clicks"""
    global pos_x, pos_y
    if event == cv2.EVENT_LBUTTONDOWN:
        print(f'click at {x},{y}')
        pos_x, pos_y = x, y

wname = "Original Image"
cv2.setMouseCallback(wname, onClick)

pos_x, pos_y = 0, 0
while True:
    draw_im = im.copy()
    draw_im = cv2.circle(draw_im, (pos_x, pos_y), 2, (0, 0, 255), -1)

    if gray_scale:
        distances = np.abs(im2[pos_y, pos_x]-im2)
        distances = np.linalg.norm(im2[pos_y, pos_x]-im2, axis=2)
    distances = cv2.convertScaleAbs(distances)
    cv2.imshow('distances', distances)

    mask_threshold = 200 # set this to a value that works for you
    mask = distances < mask_threshold
    masked_im = im.copy()
    masked_im[~mask] = 255
    cv2.imshow('masked', masked_im)
    if cv2.waitKey(1) & 0xFF == 27:


This method should provide the effect you're looking for. Here are the results of the image processing applied to the provided picture.

N = 7


Gray Scale = True, N = 4
n=4 n=4

  • Sorry took so long to reply , I kind of like the your results there. I am unfamiliar with the method you are using. But it seems to have great result, So a question: what are the tune-able value here? It would seem that clicking on the, light - brown pixels would cause the mask to include blues pixels (which should not be masked since we only target brown), is there a value i can change to reduce the inclusions of blue pixel?
    – DrakeJest
    Mar 28 at 16:10
  • Use color mode and adjust the threshold. Distance metric should be adjusted if your work mostly involves distinguishing between browns and blues.
    – HOBE
    Apr 1 at 4:56

So let me throw in an answer, it might not be a great answer but i did try to somehow go in that direction

My approach involves creating a mask for every hue value in a given hue range, after that the mask is then combined but with an assigned grey value depending on its position in the input range

image = cv2.imread('grade_0.jpg')

greyMask = np.zeros(image.shape, dtype=np.uint8) #create an empty numpy image with the same size as the input image, this will be our final mask

lowerHSV = -2
upperHSV = 20

HSVdifference = upperHSV - lowerHSV

if lowerHSV <= 0 : # account for 0
    HSVdifference = HSVdifference + 1

baseGreyValue = math.floor(255/HSVdifference)

#Create a mask for every hue value in our range and map it into a grey value

greyValue = baseGreyValue
for i in reversed(range(HSVdifference)): #loop through hue range in reverse order 

    if i > 0:
        Hvalue = i
    elif i <= 0:
        Hvalue = 180 - i

    mask = cv2.inRange(cv2.cvtColor(image, cv2.COLOR_BGR2HSV), np.array([Hvalue-1, 0, 0]), np.array([Hvalue, 255, 255])) # get all pixels at specific hue 
    indices = np.where(mask==255) #get all the index of pixels
    greyMask[indices[0], indices[1], :] = [greyValue, greyValue, greyValue] #assign grey tone to final mask
    greyValue = greyValue + baseGreyValue

cv2.imshow("grey mask", greyMask) 


enter image description here

enter image description here


I apologize - my OpenCV is broken at the moment. But here is another method that I will implement in Imagemagick.

  • Read the input

  • Apply a sigmoidal contrast to emphasize the mid range and darken the lows and brighten the highs. (See https://scikit-image.org/docs/stable/api/skimage.exposure.html#skimage.exposure.adjust_sigmoid or just skip this step to have a linear equivalent)

  • Apply a dark only threshold to contrast enhanced image (values below some threshold become black)

    Syntax: image[np.where((image<[T,T,T]).all(axis=2))] = [0,0,0] where T=some low threshold value

  • Then apply a bright only threshold (values above some threshold become white)

    Syntax: image[np.where((image>[T,T,T]).all(axis=2))] = [0,0,0] where T=some high threshold value

  • Then change all white values to black.

    Syntax: skip if using two np steps above

  • Then convert to grayscale

    Syntax: image = cv2.cvtColor(image,cv2.COLOR_BGR2GRAY)

  • Save the result


enter image description here

magick sample.jpg -sigmoidal-contrast 20,50% x.png

enter image description here

magick x.png -black-threshold 20% -white-threshold 80% -fill black -opaque white -colorspace gray result.png

enter image description here

The sigmoidal-contrast function is:

( 1/(1+exp(β*(α-u))) - 1/(1+exp(β*(α)) ) / ( 1/(1+exp(β*(α-1))) - 1/(1+exp(β*α)) )

and has a transfer curve (input to output) shape of:

enter image description here

Here is the linear equivalent process, which just skips the sigmoidal contrast. I change the threshold values to compensate some for the lack of the sigmoidal contrast. So it is just a low threshold followed by a high threshold followed by changing white to black, followed by convert to grayscale.

magick sample.jpg -black-threshold 30% -white-threshold 70% -fill black -opaque white -colorspace gray result2.png

enter image description here

  • It seems to hit the blue pixels also, i do not want to include the blue pixels
    – DrakeJest
    Mar 28 at 23:21
  • Use the two thresholds and use 3 different T values to threshold on the colors you want.
    – fmw42
    Mar 29 at 4:21

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