# How can I convert an RGB image into grayscale in Python?

I'm trying to use `matplotlib` to read in an RGB image and convert it to grayscale.

In matlab I use this:

``````img = rgb2gray(imread('image.png'));
``````

In the matplotlib tutorial they don't cover it. They just read in the image

``````import matplotlib.image as mpimg
``````

and then they slice the array, but that's not the same thing as converting RGB to grayscale from what I understand.

``````lum_img = img[:,:,0]
``````

I find it hard to believe that numpy or matplotlib doesn't have a built-in function to convert from rgb to gray. Isn't this a common operation in image processing?

I wrote a very simple function that works with the image imported using `imread` in 5 minutes. It's horribly inefficient, but that's why I was hoping for a professional implementation built-in.

Sebastian has improved my function, but I'm still hoping to find the built-in one.

matlab's (NTSC/PAL) implementation:

``````import numpy as np

def rgb2gray(rgb):

r, g, b = rgb[:,:,0], rgb[:,:,1], rgb[:,:,2]
gray = 0.2989 * r + 0.5870 * g + 0.1140 * b

return gray
``````
• Note that you can write the same thing as your rgb2gray function simply as: `gray = np.mean(rgb, -1)`. Maybe `rgb[...,:3]` there if it is actually rgba. Commented Aug 31, 2012 at 1:00
• hmm, `gray = np.mean(rgb, -1)` works fine. thanks. Is there any reason not to use this? Why would I use the solutions in the answers below instead? Commented Aug 31, 2012 at 1:22
• The grayscale wikipedia page says the method of converting RGB to grayscale is not unique, but gives a commonly used formulas based on luminance. It is quite different than `np.mean(rgb, -1)`. Commented Aug 31, 2012 at 1:32
• so I guess I want Matlab's version? `0.2989 * R + 0.5870 * G + 0.1140 * B ` I'm assuming that it's the standard way of doing it. Commented Aug 31, 2012 at 1:37
• Shouldn't be 0.2990 * R + 0.5870 * G + 0.1140 * B instead? The weight sum should equal to 1 and not 0.9999. Check here: en.wikipedia.org/wiki/Grayscale Commented Oct 17, 2020 at 16:23

How about doing it with Pillow:

``````from PIL import Image
img = Image.open('image.png').convert('L')
img.save('greyscale.png')
``````

If an alpha (transparency) channel is present in the input image and should be preserved, use mode `LA`:

``````img = Image.open('image.png').convert('LA')
``````

Using matplotlib and the formula

``````Y' = 0.2989 R + 0.5870 G + 0.1140 B
``````

you could do:

``````import numpy as np
import matplotlib.pyplot as plt
import matplotlib.image as mpimg

def rgb2gray(rgb):
return np.dot(rgb[...,:3], [0.2989, 0.5870, 0.1140])

gray = rgb2gray(img)
plt.imshow(gray, cmap=plt.get_cmap('gray'), vmin=0, vmax=1)
plt.show()
``````
• If he has to use `matplotlib` for some other reason, he should be able to use the builtin `colorsys.rgb_to_yiq()` to transform plus a slice to get just the luma channel. Commented Aug 30, 2012 at 16:53
• why `.convert('LA')`? why not `.convert('gray')`? Seems needlessly cryptic. The PIL documentation doesn't mention anything about 'LA' for the convert function. Commented Aug 31, 2012 at 1:32
• using PIL: `cannot write mode LA as JPEG`, I needed to use L mode not LA
– jsky
Commented May 26, 2015 at 6:50
• This `img = Image.open('image.png').convert('LA')` needs to be `img = Image.open('image.png').convert('L')` Commented Oct 23, 2017 at 22:05
• @BluePython: `LA` mode has luminosity (brightness) and alpha. If you use `LA` mode, then `greyscale.png` will be an RGBA image with the alpha channel of `image.png` preserved. If you use `L` mode, then `greyscale.png` will be an RGB image (with no alpha). Commented Nov 8, 2017 at 12:31

You can also use scikit-image, which provides some functions to convert an image in `ndarray`, like `rgb2gray`.

``````from skimage import color
from skimage import io

``````

Notes: The weights used in this conversion are calibrated for contemporary CRT phosphors: Y = 0.2125 R + 0.7154 G + 0.0721 B

Alternatively, you can read image in grayscale by:

``````from skimage import io
``````
• is it normal that I'm getting 0<values<1 ? Am I supposed to multiply them by 255 to get the real gray scale?
– Sam
Commented Dec 1, 2015 at 20:24
• knowing that my aim is to use GLCM features (greycoprops)
– Sam
Commented Dec 1, 2015 at 20:56
• Note for io.imread: "as_grey" has been deprecated in favor of "as_gray". Same usage, just Americanized spelling. :) Commented Mar 30, 2019 at 20:06
• I believe this is the most useful answer to question at hand, output of this is also compatible with matplotlib and numpy. Commented Nov 14, 2019 at 21:31
• I am using the color object but my image is sort of reddish now and not gray (black and white). I need to use `cmap` as `gray' then only the image is shown as gray in `pyplot.imshow()` ? Any thoughts ? Where am I wrong? Commented Jan 17, 2020 at 14:55

Three of the suggested methods were tested for speed with 1000 RGBA PNG images (224 x 256 pixels) running with Python 3.5 on Ubuntu 16.04 LTS (Xeon E5 2670 with SSD).

Average run times

`pil :` 1.037 seconds

`scipy:` 1.040 seconds

`sk :` 2.120 seconds

PIL and SciPy gave identical `numpy` arrays (ranging from 0 to 255). SkImage gives arrays from 0 to 1. In addition the colors are converted slightly different, see the example from the CUB-200 dataset.

`SkImage:`

`PIL :`

`SciPy :`

`Original:`

`Diff :`

Code

1. Performance

``````run_times = dict(sk=list(), pil=list(), scipy=list())
for t in range(100):
start_time = time.time()
for i in range(1000):
z = random.choice(filenames_png)
run_times['sk'].append(time.time() - start_time)

start_time = time.time()
for i in range(1000):
z = random.choice(filenames_png)
img = np.array(Image.open(z).convert('L'))
run_times['pil'].append(time.time() - start_time)

start_time = time.time()
for i in range(1000):
z = random.choice(filenames_png)
run_times['scipy'].append(time.time() - start_time)

for k, v in run_times.items():
print('{:5}: {:0.3f} seconds'.format(k, sum(v) / len(v)))
``````

2. Output
``````z = 'Cardinal_0007_3025810472.jpg'
IPython.display.display(PIL.Image.fromarray(img1).convert('RGB'))
img2 = np.array(Image.open(z).convert('L'))
IPython.display.display(PIL.Image.fromarray(img2))
IPython.display.display(PIL.Image.fromarray(img3))
``````
3. Comparison
``````img_diff = np.ndarray(shape=img1.shape, dtype='float32')
img_diff.fill(128)
img_diff += (img1 - img3)
img_diff -= img_diff.min()
img_diff *= (255/img_diff.max())
IPython.display.display(PIL.Image.fromarray(img_diff).convert('RGB'))
``````
4. Imports
``````import skimage.color
import skimage.io
import random
import time
from PIL import Image
import numpy as np
import scipy.ndimage
import IPython.display
``````
5. Versions
``````skimage.version
0.13.0
scipy.version
0.19.1
np.version
1.13.1
``````
• SciPy's image I/O is literally PIL/Pillow. Hence, testing SciPy is effectively retesting PIL/Pillow with negligible overhead introduced by SciPy's wrapper functions. It would have been much more useful to substitute OpenCV (which does not leverage PIL/Pillow) for SciPy (which does). Nonetheless, thanks for the dedicated benchmarking! The discernable slowdown imposed by SciKit is fascinating... and horrifying. Commented Nov 16, 2017 at 7:47

You can always read the image file as grayscale right from the beginning using `imread` from OpenCV:

``````img = cv2.imread('messi5.jpg', 0)
``````

Furthermore, in case you want to read the image as RGB, do some processing and then convert to Gray Scale you could use `cvtcolor` from OpenCV:

``````gray_image = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
``````

The fastest and current way is to use Pillow, installed via `pip install Pillow`.

The code is then:

``````from PIL import Image
img = Image.open('input_file.jpg').convert('L')
img.save('output_file.jpg')
``````
• note that, if you're not chaining your methods like in the example above, `convert` returns a converted copy of the image
– Matt
Commented Mar 12, 2016 at 3:24
• does not work for 32 bit PNG, values will be clamped to 255 Commented May 31, 2020 at 21:58

The tutorial is cheating because it is starting with a greyscale image encoded in RGB, so they are just slicing a single color channel and treating it as greyscale. The basic steps you need to do are to transform from the RGB colorspace to a colorspace that encodes with something approximating the luma/chroma model, such as YUV/YIQ or HSL/HSV, then slice off the luma-like channel and use that as your greyscale image. `matplotlib` does not appear to provide a mechanism to convert to YUV/YIQ, but it does let you convert to HSV.

Try using `matplotlib.colors.rgb_to_hsv(img)` then slicing the last value (V) from the array for your grayscale. It's not quite the same as a luma value, but it means you can do it all in `matplotlib`.

Background:

Alternatively, you could use PIL or the builtin `colorsys.rgb_to_yiq()` to convert to a colorspace with a true luma value. You could also go all in and roll your own luma-only converter, though that's probably overkill.

Using this formula

``````Y' = 0.299 R + 0.587 G + 0.114 B
``````

We can do

``````import imageio
import numpy as np
import matplotlib.pyplot as plt

gray = lambda rgb : np.dot(rgb[... , :3] , [0.299 , 0.587, 0.114])
gray = gray(pic)
plt.imshow(gray, cmap = plt.get_cmap(name = 'gray'))
``````

However, the GIMP converting color to grayscale image software has three algorithms to do the task.

you could do:

``````import numpy as np
import matplotlib.pyplot as plt
import matplotlib.image as mpimg

def rgb_to_gray(img):
grayImage = np.zeros(img.shape)
R = np.array(img[:, :, 0])
G = np.array(img[:, :, 1])
B = np.array(img[:, :, 2])

R = (R *.299)
G = (G *.587)
B = (B *.114)

Avg = (R+G+B)
grayImage = img.copy()

for i in range(3):
grayImage[:,:,i] = Avg

return grayImage

grayImage = rgb_to_gray(image)
plt.imshow(grayImage)
plt.show()
``````

If you're using NumPy/SciPy already you may as well use:

`scipy.ndimage.imread(file_name, mode='L')`

• Both `scipy.ndimage.imread()` and `scipy.misc.imread()` are formally deprecated in SciPy 1.0.0 and will be permanently removed in SciPy 1.2.0. While SciPy's documentation recommends `imageio.imread()` as a suitable replacement, this function's API is bare bones to the point of absurdity. It provides no support for grayscale conversion and thus remains unsuitable for many applications – including ours. `</sigh>` Commented Nov 16, 2017 at 7:39

With OpenCV its simple:

``````import cv2

# To Grayscale
im = cv2.cvtColor(im, cv2.COLOR_BGR2GRAY)
cv2.imwrite("grayscale.jpg", im)

# To Black & White
im = cv2.threshold(im, 127, 255, cv2.THRESH_BINARY)[1]
cv2.imwrite("black-white.jpg", im)
``````

Use img.Convert(), supports “L”, “RGB” and “CMYK.” mode

``````import numpy as np
from PIL import Image

img = Image.open("IMG/center_2018_02_03_00_34_32_784.jpg")
img.convert('L')

print np.array(img)
``````

Output:

``````[[135 123 134 ...,  30   3  14]
[137 130 137 ...,   9  20  13]
[170 177 183 ...,  14  10 250]
...,
[112  99  91 ...,  90  88  80]
[ 95 103 111 ..., 102  85 103]
[112  96  86 ..., 182 148 114]]
``````
• should the 5th line be `img = img.convert('L')` ? Commented Mar 4, 2019 at 5:28

I came to this question via Google, searching for a way to convert an already loaded image to grayscale.

Here is a way to do it with SciPy:

``````import scipy.misc
import scipy.ndimage

img = scipy.misc.face()

# Convert the image
R = img[:, :, 0]
G = img[:, :, 1]
B = img[:, :, 2]
img_gray = R * 299. / 1000 + G * 587. / 1000 + B * 114. / 1000

# Show the image
scipy.misc.imshow(img_gray)
``````
• Nice. I just want to note the a shorter solution would be `img_gray = numpy.average(img, weights=[0.299, 0.587, 0.114], axis=2)` Commented Aug 4, 2017 at 15:25
• Both `scipy.ndimage.imread()` and `scipy.misc.imread()` are formally deprecated in SciPy 1.0.0 and will be permanently removed in SciPy 1.2.0. You probably just want to use Pillow's builtin grayscale conversion support (ala unutbu's answer), instead. Commented Nov 16, 2017 at 7:51
• What are the magic numbers in your code? 299, 587, 114... Commented Sep 1, 2021 at 16:52

When the values in a pixel across all 3 color channels (RGB) are same then that pixel will always be in grayscale format.

One of a simple & intuitive method to convert a RGB image to Grayscale is by taking the mean of all color channels in each pixel and assigning the value back to that pixel.

``````import numpy as np
from PIL import Image

img=np.array(Image.open('sample.jpg')) #Input - Color image
gray_img=img.copy()

for clr in range(img.shape[2]):
gray_img[:,:,clr]=img.mean(axis=2) #Take mean of all 3 color channels of each pixel and assign it back to that pixel(in copied image)

#plt.imshow(gray_img) #Result - Grayscale image
``````

Input Image:

Output Image:

• You can use this: img = np.mean(color_img, axis=2) But it is not correct way to do it, read this: e2eml.school/convert_rgb_to_grayscale.html Commented Jul 27, 2021 at 10:38
• gray_img still got 3 channels. why it so?? Commented Aug 13, 2022 at 16:23

Assuming my image is 3 channel in its original form

``````my_image = cv2.imread("./5d10e5939c5101174c54bb98.png")
#greyscaling the image
image_sum = my_image.sum(axis=2)
new_image = image_sum/image_sum.max()
``````

`new_image` is my single channel greyscale image

``````plt.figure(figsize=[12,8])
plt.imshow(new_image, cmap=plt.cm.gray)
plt.show()
``````

[ This is without using cv2's `cv2.COLOR_BGR2GRAY` parameter or PIL's `.convert('L')` method ]

``````image=myCamera.getImage().crop(xx,xx,xx,xx).scale(xx,xx).greyscale()
``````

You can use `greyscale()` directly for the transformation.