I would like to take an image and change the scale of the image, while it is a numpy array.

For example I have this image of a coca-cola bottle:

bottle-1

Which translates to a numpy array of shape `(528, 203, 3)`

and I want to resize that to say the size of this second image:

bottle-2

Which has a shape of `(140, 54, 3)`

.

How do I change the size of the image to a certain shape while still maintaining the original image? Other answers suggest stripping every other or third row out, but what I want to do is basically shrink the image how you would via an image editor but in python code. Are there any libraries to do this in numpy/SciPy?

## Here is Solutions:

We have many solutions to this problem, But we recommend you to use the first solution because it is tested & true solution that will 100% work for you.

### Solution 1

Yeah, you can install `opencv`

(this is a library used for image processing, and computer vision), and use the ** cv2.resize** function. And for instance use:

```
import cv2
import numpy as np
img = cv2.imread('your_image.jpg')
res =
```**cv2.resize(img, dsize=(54, 140), interpolation=cv2.INTER_CUBIC)**

Here `img`

is thus a numpy array containing the original image, whereas `res`

is a numpy array containing the *resized* image. An important aspect is the `interpolation`

parameter: there are several ways how to resize an image. Especially since you scale down the image, and the size of the original image is *not* a multiple of the size of the resized image. Possible interpolation schemas are:

`INTER_NEAREST`

– a nearest-neighbor interpolation`INTER_LINEAR`

– a bilinear interpolation (used by default)`INTER_AREA`

– resampling using pixel area relation. It may be a preferred method for image decimation, as it gives moire’-free

results. But when the image is zoomed, it is similar to the

`INTER_NEAREST`

method.`INTER_CUBIC`

– a bicubic interpolation over 4×4 pixel neighborhood`INTER_LANCZOS4`

– a Lanczos interpolation over 8×8 pixel neighborhood

Like with most options, there is no “best” option in the sense that for every resize schema, there are scenarios where one strategy can be preferred over another.

### Solution 2

While it might be possible to use numpy alone to do this, the operation is not built-in. That said, you can use `scikit-image`

(which is built on numpy) to do this kind of image manipulation.

Scikit-Image rescaling documentation is here.

For example, you could do the following with your image:

```
from skimage.transform import resize
bottle_resized = resize(bottle, (140, 54))
```

This will take care of things like interpolation, anti-aliasing, etc. for you.

### Solution 3

For people coming here from Google looking for a fast way to downsample images in `numpy`

arrays for use in Machine Learning applications, here’s a super fast method (adapted from here ). This method only works when the input dimensions are a multiple of the output dimensions.

The following examples downsample from 128×128 to 64×64 (this can be easily changed).

Channels last ordering

```
# large image is shape (128, 128, 3)
# small image is shape (64, 64, 3)
input_size = 128
output_size = 64
bin_size = input_size // output_size
small_image = large_image.reshape((output_size, bin_size,
output_size, bin_size, 3)).max(3).max(1)
```

Channels first ordering

```
# large image is shape (3, 128, 128)
# small image is shape (3, 64, 64)
input_size = 128
output_size = 64
bin_size = input_size // output_size
small_image = large_image.reshape((3, output_size, bin_size,
output_size, bin_size)).max(4).max(2)
```

For grayscale images just change the `3`

to a `1`

like this:

Channels first ordering

```
# large image is shape (1, 128, 128)
# small image is shape (1, 64, 64)
input_size = 128
output_size = 64
bin_size = input_size // output_size
small_image = large_image.reshape((1, output_size, bin_size,
output_size, bin_size)).max(4).max(2)
```

This method uses the equivalent of max pooling. It’s the fastest way to do this that I’ve found.

### Solution 4

One-line numpy solution for **downsampling** (by 2):

```
smaller_img = bigger_img[::2, ::2]
```

And **upsampling** (by 2):

```
bigger_img = smaller_img.repeat(2, axis=0).repeat(2, axis=1)
```

(this asssumes HxWxC shaped image. h/t to L. Kärkkäinen in the comments above. note this method only allows whole integer resizing (e.g., 2x but not 1.5x))

### Solution 5

If anyone came here looking for a simple method to scale/resize an image in Python, without using additional libraries, here’s a very simple image resize function:

```
#simple image scaling to (nR x nC) size
def scale(im, nR, nC):
nR0 = len(im) # source number of rows
nC0 = len(im[0]) # source number of columns
return [[ im[int(nR0 * r / nR)][int(nC0 * c / nC)]
for c in range(nC)] for r in range(nR)]
```

Example usage: resizing a (30 x 30) image to (100 x 200):

```
import matplotlib.pyplot as plt
def sqr(x):
return x*x
def f(r, c, nR, nC):
return 1.0 if sqr(c - nC/2) + sqr(r - nR/2) < sqr(nC/4) else 0.0
# a red circle on a canvas of size (nR x nC)
def circ(nR, nC):
return [[ [f(r, c, nR, nC), 0, 0]
for c in range(nC)] for r in range(nR)]
plt.imshow(scale(circ(30, 30), 100, 200))
```

This works to shrink/scale images, and works fine with numpy arrays.

### Solution 6

For people who wants to resize(interpolate) a batch of numpy array, pytorch provide a faster function names torch.nn.functional.interpolate, just remember to use np.transpose first to change the channel from batchxWxHx3 to batchx3xWxH.

### Solution 7

SciPy’s `imresize()`

method was another resize method, but it will be removed starting with SciPy v 1.3.0 . SciPy refers to **PIL** image resize method: `Image.resize(size, resample=0)`

**size** – The requested size in pixels, as a 2-tuple: (width, height).

**resample** – An optional resampling filter. This can be one of PIL.Image.NEAREST (use nearest neighbour), PIL.Image.BILINEAR (linear interpolation), PIL.Image.BICUBIC (cubic spline interpolation), or PIL.Image.LANCZOS (a high-quality downsampling filter). If omitted, or if the image has mode “1” or “P”, it is set PIL.Image.NEAREST.

Link here:

https://pillow.readthedocs.io/en/3.1.x/reference/Image.html#PIL.Image.Image.resize

### Solution 8

Stumbled back upon this after a few years. It looks like the answers so far fall into one of a few categories:

- Use an external library. (OpenCV, SciPy, etc)
- User Power-of-Two Scaling
- Use Nearest Neighbor

**These solutions are all respectable, so I offer this only for completeness.** It has three advantages over the above: (1) it will accept arbitrary resolutions, even non-power-of-two scaling factors; (2) it uses pure Python+Numpy with no external libraries; and (3) it interpolates all the pixels for an arguably ‘nicer-looking’ result.

It does not make good use of Numpy and, thus, is **not fast**, especially for large images. If you’re only rescaling smaller images, it should be fine. I offer this under Apache or MIT license at the discretion of the user.

```
import math
import numpy
def resize_linear(image_matrix, new_height:int, new_width:int):
"""Perform a pure-numpy linear-resampled resize of an image."""
output_image = numpy.zeros((new_height, new_width), dtype=image_matrix.dtype)
original_height, original_width = image_matrix.shape
inv_scale_factor_y = original_height/new_height
inv_scale_factor_x = original_width/new_width
# This is an ugly serial operation.
for new_y in range(new_height):
for new_x in range(new_width):
# If you had a color image, you could repeat this with all channels here.
# Find sub-pixels data:
old_x = new_x * inv_scale_factor_x
old_y = new_y * inv_scale_factor_y
x_fraction = old_x - math.floor(old_x)
y_fraction = old_y - math.floor(old_y)
# Sample four neighboring pixels:
left_upper = image_matrix[math.floor(old_y), math.floor(old_x)]
right_upper = image_matrix[math.floor(old_y), min(image_matrix.shape[1] - 1, math.ceil(old_x))]
left_lower = image_matrix[min(image_matrix.shape[0] - 1, math.ceil(old_y)), math.floor(old_x)]
right_lower = image_matrix[min(image_matrix.shape[0] - 1, math.ceil(old_y)), min(image_matrix.shape[1] - 1, math.ceil(old_x))]
# Interpolate horizontally:
blend_top = (right_upper * x_fraction) + (left_upper * (1.0 - x_fraction))
blend_bottom = (right_lower * x_fraction) + (left_lower * (1.0 - x_fraction))
# Interpolate vertically:
final_blend = (blend_top * y_fraction) + (blend_bottom * (1.0 - y_fraction))
output_image[new_y, new_x] = final_blend
return output_image
```

Sample rescaling:

Upscaled by one and one quarter:

### Solution 9

Are there any libraries to do this in numpy/SciPy

Sure. You can do this without OpenCV, scikit-image or PIL.

Image resizing is basically mapping the coordinates of each pixel from the original image to its resized position.

Since the coordinates of an image must be integers (think of it as a matrix), if the mapped coordinate has decimal values, you should interpolate the pixel value to approximate it to the integer position (e.g. getting the nearest pixel to that position is known as Nearest neighbor interpolation).

All you need is a function that does this interpolation for you. SciPy has `interpolate.interp2d`

.

You can use it to resize an image in numpy array, say `arr`

, as follows:

```
W, H = arr.shape[:2]
new_W, new_H = (600,300)
xrange = lambda x: np.linspace(0, 1, x)
f = interp2d(xrange(W), xrange(H), arr, kind="linear")
new_arr = f(xrange(new_W), xrange(new_H))
```

Of course, if your image is RGB, you have to perform the interpolation for each channel.

If you would like to understand more, I suggest watching Resizing Images – Computerphile.

### Solution 10

```
import cv2
import numpy as np
image_read = cv2.imread('filename.jpg',0)
original_image = np.asarray(image_read)
width , height = 452,452
resize_image = np.zeros(shape=(width,height))
for W in range(width):
for H in range(height):
new_width = int( W * original_image.shape[0] / width )
new_height = int( H * original_image.shape[1] / height )
resize_image[W][H] = original_image[new_width][new_height]
print("Resized image size : " , resize_image.shape)
cv2.imshow(resize_image)
cv2.waitKey(0)
```

**Note: Use and implement solution 1 because this method fully tested our system.Thank you 🙂**

All methods was sourced from stackoverflow.com or stackexchange.com, is licensed under cc by-sa 2.5, cc by-sa 3.0 and cc by-sa 4.0