I tried this code:

import cv2
image = cv2.imread("sample.jpg")
pixel = image[200, 550]
print pixel

But I am getting error as:

'Nonetype' no attributes error getitem

This error is getting displayed after executing the third line of code.


How to fix the error

There are two potential causes for this error to happen:

  1. The file name is misspelled.
  2. The image file is not in the current working directory.

To fix this issue you should make sure the filename is correctly spelled (do case sensitive check just in case) and the image file is in the current working directory (there are two options here: you could either change the current working directory in your IDE or specify the full path of the file).

Average colour vs. dominant colour

Then to calculate the "average colour" you have to decide what you mean by that. In a grayscale image it is simply the mean of gray levels across the image. Colours are usually represented through 3-dimensional vectors whilst gray levels are scalars.

The average colour is the sum of all pixels divided by the number of pixels. However, this approach may yield a colour different to the most prominent visual color. What you might really want is dominant color rather than average colour.


Let's go through the code slowly. We start by importing the necessary modules and reading the image:

import cv2
import numpy as np
from skimage import io

img = io.imread('https://i.stack.imgur.com/DNM65.png')[:, :, :-1]

Then we can calculate the mean of each chromatic channel following a method analog to the one proposed by @Ruan B.:

average = img.mean(axis=0).mean(axis=0)

Next we apply k-means clustering to create a palette with the most representative colours of the image (in this toy example n_colors was set to 5).

pixels = np.float32(img.reshape(-1, 3))

n_colors = 5
criteria = (cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, 200, .1)

_, labels, palette = cv2.kmeans(pixels, n_colors, None, criteria, 10, flags)
_, counts = np.unique(labels, return_counts=True)

And finally the dominant colour is the palette colour which occurs most frequently on the quantized image:

dominant = palette[np.argmax(counts)]

Comparison of results

To illustrate the differences between both approaches I've used the following sample image:


The obtained values for the average colour, i.e. a colour whose components are the means of the three chromatic channels, and the dominant colour calculated throug k-means clustering are rather different:

In [30]: average
Out[30]: array([91.63179156, 69.30190754, 58.11971896])

In [31]: dominant
Out[31]: array([179.3999  ,  27.341282,   2.294441], dtype=float32)

Let's see how those colours look to better understand the differences between both approaches. On the left part of the figure below it is displayed the average colour. It clearly emerges that the calculated average colour does not properly describe the colour content of the original image. In fact, there's no a single pixel with that colour in the original image. The right part of the figure shows the five most representative colours sorted from top to bottom in descending order of importance (occurrence frequency). This palette makes it evident that the dominant color is the red, which is consistent with the fact that the largest region of uniform colour in the original image corresponds to the red Lego piece.


This is the code used to generate the figure above:

import matplotlib.pyplot as plt

avg_patch = np.ones(shape=img.shape, dtype=np.uint8)*np.uint8(average)

indices = np.argsort(counts)[::-1]   
freqs = np.cumsum(np.hstack([[0], counts[indices]/counts.sum()]))
rows = np.int_(img.shape[0]*freqs)

dom_patch = np.zeros(shape=img.shape, dtype=np.uint8)
for i in range(len(rows) - 1):
    dom_patch[rows[i]:rows[i + 1], :, :] += np.uint8(palette[indices[i]])

fig, (ax0, ax1) = plt.subplots(1, 2, figsize=(12,6))
ax0.set_title('Average color')
ax1.set_title('Dominant colors')

TL;DR answer

In summary, despite the calculation of the average colour - as proposed in @Ruan B.'s answer - is correct, the yielded result may not adequately represent the colour content of the image. A more sensible approach is that of determining the dominant colour through vector quantization (clustering).

| improve this answer | |
  • 2
    Note: with cv2(2.4.8) , need change cv2.kmeans(pixels, n_colors, None, criteria, 10, flags) to cv2.kmeans(pixels, n_colors, criteria, 10, flags) . Doc: docs.opencv.org/2.4/modules/core/doc/clustering.html – Mithril Jul 10 '17 at 4:36
  • 1
    Why can't we just take the average R value, average G value and average B value (across all pixels) and check if the image is more Red, Green or Blue? – Vishal Sep 2 '17 at 17:37
  • @Tonechas In the calculation of the dominant_color, you said that you calculate it as the most frequent colour appearing in the quantized image, but you never use this variable. If we remove the quantized variable, the scripts works in the same way. Is that a mistake or I'm missing something? – nachmr Nov 12 '18 at 12:34
  • 1
    @nachmr: dominant_color was used in the interactive session and in the code that generates the last figure to show the differences between both approaches. I edited my answer to include that code and make this point clearer. – Tonechas Nov 12 '18 at 18:07
  • 5
    This answer is quite OK, except where it says "it makes no sense to average vectors." Of course it does. It is perfectly valid to compute the average of a set of vectors, and the result is meaningful as the average of the input vectors. For vectors in RGB space, the result is the average RGB value, the average color, and perfectly correct mathematically. "Separating the image into its chromatic components and taking the average of each component is a possible way to go." Yes, and mathematically equivalent to computing the average vector. – Cris Luengo Nov 12 '18 at 18:38

I was able to get the average color by using the following:

import cv2
import numpy
myimg = cv2.imread('image.jpg')
avg_color_per_row = numpy.average(myimg, axis=0)
avg_color = numpy.average(avg_color_per_row, axis=0)


[ 197.53434769  217.88439451  209.63799938]

Great Resource which I referenced

| improve this answer | |
  • 1
    Thank you for this short and very efficient code. It returns [blue, green, red] instead of [red, green, blue] order – Mohsen Haddadi Dec 1 '17 at 7:08
  • 2
    @MohsenHaddadi its apparent , because cv2 reads image in BGR format. – Nasir Shah Nov 16 '18 at 13:14
  • I am getting this error, do you know why? ImportError: numpy.core.multiarray failed to import Traceback (most recent call last): File "/Users/luca/Desktop/example.py", line 1, in <module> import cv2 ImportError: numpy.core.multiarray failed to import – Luca Perico Nov 16 '18 at 14:39
  • @LucaPerico reinistall opencv python wheel to fix this – iratzhash Nov 8 '19 at 14:35

Another approach using K-Means Clustering to determine the dominant colors in an image with sklearn.cluster.KMeans()

Input image


With n_clusters=5, here are the most dominant colors and percentage distribution

[76.35563647 75.38689122 34.00842057] 7.92%
[200.99049989  31.2085501   77.19445073] 7.94%
[215.62791291 113.68567694 141.34945328] 18.85%
[223.31013152 172.76629675 188.26878339] 29.26%
[234.03101989 217.20047979 229.2345317 ] 36.03%

Visualization of each color cluster

enter image description here

Similarity with n_clusters=10,

[161.94723762 137.44656853 116.16306634] 3.13%
[183.0756441    9.40398442  50.99925105] 4.01%
[193.50888866 168.40201684 160.42104169] 5.78%
[216.75372674  60.50807092 107.10928817] 6.82%
[73.18055782 75.55977818 32.16962975] 7.36%
[226.25900564 108.79652434 147.49787087] 10.44%
[207.83209569 199.96071651 199.48047163] 10.61%
[236.01218943 151.70521203 182.89174295] 12.86%
[240.20499237 189.87659523 213.13580544] 14.99%
[235.54419627 225.01404087 235.29930545] 24.01%

enter image description here

import cv2, numpy as np
from sklearn.cluster import KMeans

def visualize_colors(cluster, centroids):
    # Get the number of different clusters, create histogram, and normalize
    labels = np.arange(0, len(np.unique(cluster.labels_)) + 1)
    (hist, _) = np.histogram(cluster.labels_, bins = labels)
    hist = hist.astype("float")
    hist /= hist.sum()

    # Create frequency rect and iterate through each cluster's color and percentage
    rect = np.zeros((50, 300, 3), dtype=np.uint8)
    colors = sorted([(percent, color) for (percent, color) in zip(hist, centroids)])
    start = 0
    for (percent, color) in colors:
        print(color, "{:0.2f}%".format(percent * 100))
        end = start + (percent * 300)
        cv2.rectangle(rect, (int(start), 0), (int(end), 50), \
                      color.astype("uint8").tolist(), -1)
        start = end
    return rect

# Load image and convert to a list of pixels
image = cv2.imread('1.png')
image = cv2.cvtColor(image, cv2.COLOR_BGR2RGB)
reshape = image.reshape((image.shape[0] * image.shape[1], 3))

# Find and display most dominant colors
cluster = KMeans(n_clusters=5).fit(reshape)
visualize = visualize_colors(cluster, cluster.cluster_centers_)
visualize = cv2.cvtColor(visualize, cv2.COLOR_RGB2BGR)
cv2.imshow('visualize', visualize)
| improve this answer | |
  • very neat ! Thank you – M H May 6 at 12:31

If you put the image into OpenCV's BGR format, you can run this code that puts each pixel into one of four classifications:


In the code that follows we process the image used by Tonechas,

colored lego pieces


import cv2 as cv
import numpy as np
from imageio import imread

image = imread('https://i.stack.imgur.com/DNM65.png')
img  = cv.cvtColor(np.array(image), cv.COLOR_RGB2BGR)
rows, cols, _ = img.shape

color_B = 0
color_G = 0
color_R = 0
color_N = 0 # neutral/gray color

for i in range(rows):
    for j in range(cols):
        k = img[i,j]
        if k[0] > k[1] and k[0] > k[2]:
            color_B = color_B + 1
        if k[1] > k[0] and k[1] > k[2]:
            color_G = color_G + 1
        if k[2] > k[0] and k[2] > k[1]:
            color_R = color_R + 1
        color_N = color_N + 1

pix_total = rows * cols
print('Blue:', color_B/pix_total, 'Green:', color_G/pix_total, 'Red:',  color_R/pix_total, 'Gray:',  color_N/pix_total)


Blue: 0.2978447577378059 Green: 0.21166979188369564 Red: 0.48950158575827024 Gray: 0.0009838646202282567
| improve this answer | |

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