Please look at this github page. I want to generate heat maps in this way using Python PIL,open cv or matplotlib library. Can somebody help me figure it out? Superimposed heatmaps

I could create a heat map for my network at the same size as the input, but I am not able superimpose them. The heatmap shape is (800,800) and the base image shape is (800,800,3)

  • 1
    did you get any solution ? i do have same kind of requirements Sep 6, 2021 at 5:32

4 Answers 4


Updated Answer -- 29th April, 2022.

After the repeated comments I have decided to update this post with a better visualization.

Consider the following image:

img = cv2.imread('image_path')

enter image description here

I obtained a binary image after performing binary threshold on the a-channel of the LAB converted image:

lab = cv2.cvtColor(img, cv2.COLOR_BGR2LAB)
a_component = lab[:,:,1]
th = cv2.threshold(a_component,140,255,cv2.THRESH_BINARY)[1]

enter image description here

Applying Gaussian blur:

blur = cv2.GaussianBlur(th,(13,13), 11)

enter image description here

The resulting heatmap:

heatmap_img = cv2.applyColorMap(blur, cv2.COLORMAP_JET)

enter image description here

Finally, superimposing the heatmap over the original image:

super_imposed_img = cv2.addWeighted(heatmap_img, 0.5, img, 0.5, 0)

enter image description here

Note: You can vary the weight parameters in the function cv2.addWeighted and observe the differences.

  • 1
    I mean the second image. please correct it! heated_img and fin look same.
    – curio17
    Sep 3, 2017 at 12:33
  • 4
    Your overall method is correct. But second and third image look the same, that's it! Change the picture of second.
    – curio17
    Sep 3, 2017 at 12:35
  • Let us continue this discussion in chat.
    – curio17
    Sep 3, 2017 at 12:38
  • Answer works well. However it's odd to create a direct heatmap of an image and overlay this on the image. I think that's what confused @curio1729. Typically the heatmap overlaid is a result of estimation/prediction/other done on the image. Mar 16, 2019 at 1:52
  • I agree. This would've been more clear if you dramatically blurred the input. I understand your heatmap is just an example, but because it is exactly the same underlying data is the original image, it doesn't look like what folks are expecting.
    – Geoff
    Sep 24, 2019 at 15:32

My code starts from a heatmap matrix (224,224) called cam, which is applied to the original image called frame, via opencv;

and it seems to work pretty well:

import numpy as np
from cv2 import cv2
from skimage import exposure 

capture = cv2.VideoCapture(...)
while True:
    ret, frame = capture.read()

    if ret:
        #resize original frame
        frame = cv2.resize(frame, (224, 224)) 

        #get color map
        cam = getMap(frame)
        map_img = exposure.rescale_intensity(cam, out_range=(0, 255))
        map_img = np.uint8(map_img)
        heatmap_img = cv2.applyColorMap(map_img, cv2.COLORMAP_JET)

        #merge map and frame
        fin = cv2.addWeighted(heatmap_img, 0.5, frame, 0.5, 0)

        #show result
        cv2.imshow('frame', fin)

the getMap() function gets the headmap given the frame;

I found some interesting free videos about this topic:




I had some problems with grayscale images at this line

super_imposed_img = cv2.addWeighted(heatmap_img, 0.5, img, 0.5, 0)

but this one worked for me

plt.imshow(binary_classification_result * 0.99 + original_gray_image * 0.01)

On the page you shared, it is done through a pre-trained model. You can use backbones like ResNet:

Load the backbone:

resnet_50 = tf.keras.applications.ResNet50(input_shape=(224, 224, 3),

Preprocess the image so that it matches resnet's default

img = cv2.imread("/content/your_image.jpg")[:,:,::-1]
img = cv2.resize(image, (224, 224))
ax = plt.imshow(img)

def preprocess(img):
  # use the pre processing function of ResNet50 
  img = preprocess_input(img)
  #expand the dimension
  return np.expand_dims(img, 0)

input_image = preprocess(img)

Applying this paper's suggestions:

def postprocess_activations(activations):

  output = np.abs(activations)
  output = np.sum(output, axis = -1).squeeze()

  #resize and convert to image 
  output = cv2.resize(output, (224, 224))
  output /= output.max()
  output *= 255
  return 255 - output.astype('uint8')

Generate and plot heatmaps:

def apply_heatmap(weights, img):

   #generate heat maps 
   heatmap = cv2.applyColorMap(weights, cv2.COLORMAP_JET)
   heatmap = cv2.addWeighted(heatmap, 0.7, img, 0.3, 0)
return heatmap


 def plot_heatmaps(rng):
  level_maps = None
  #given a range of indices generate the heat maps 
  for i in rng:
    activations = get_activations_at(input_image, i)
    weights = postprocess_activations(activations)
    heatmap = apply_heatmap(weights, img)
    if level_maps is None:
      level_maps = heatmap
      level_maps = np.concatenate([level_maps, heatmap], axis = 1)
  plt.figure(figsize=(15, 15))
  ax = plt.imshow(level_maps)
plot_heatmaps(range(164, 169))

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