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You're reading from OpenCV 3.x with Python By Example Make the most of OpenCV and Python to build applications for object recognition and augmented reality

Product type Paperback

Published in Jan 2018

Publisher Packt

ISBN-13 9781788396905

Length 268 pages

Edition 2nd Edition

Languages

Python

Tools

OpenCV

Concepts

Augmented Reality

Authors (2):

Gabriel Garrido Calvo

Prateek Joshi

View More author details

Table of Contents (17) Chapters

Title Page

Contributors

Packt Upsell

Preface

1. Applying Geometric Transformations to Images FREE CHAPTER

2. Detecting Edges and Applying Image Filters

3. Cartoonizing an Image

4. Detecting and Tracking Different Body Parts

5. Extracting Features from an Image

6. Seam Carving

7. Detecting Shapes and Segmenting an Image

8. Object Tracking

9. Object Recognition

10. Augmented Reality

11. Machine Learning by an Artificial Neural Network

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Image warping

Let's have some more fun with the images and see what else we can achieve. Projective transformations are pretty flexible, but they still impose some restrictions on how we can transform the points. What if we want to do something completely random? We need more control, right? It just so happens we can do that as well. We just need to create our own mapping, and it's not that difficult. Following are a few effects that you can achieve with image warping:

Here is the code to create these effects:

import cv2 
import numpy as np 
import math 
 
img = cv2.imread('images/input.jpg', cv2.IMREAD_GRAYSCALE) 
rows, cols = img.shape 
 
##################### 
# Vertical wave 
 
img_output = np.zeros(img.shape, dtype=img.dtype) 
 
for i in range(rows): 
    for j in range(cols): 
        offset_x = int(25.0 * math.sin(2 * 3.14 * i / 180)) 
        offset_y = 0 
        if j+offset_x < rows: 
            img_output[i,j] = img[i,(j+offset_x)%cols] 
        else: 
            img_output[i,j] = 0 
 
cv2.imshow('Input', img) 
cv2.imshow('Vertical wave', img_output) 
 
##################### 
# Horizontal wave 
 
img_output = np.zeros(img.shape, dtype=img.dtype) 
 
for i in range(rows): 
    for j in range(cols): 
        offset_x = 0 
        offset_y = int(16.0 * math.sin(2 * 3.14 * j / 150)) 
        if i+offset_y < rows: 
            img_output[i,j] = img[(i+offset_y)%rows,j] 
        else: 
            img_output[i,j] = 0 
 
cv2.imshow('Horizontal wave', img_output) 
 
##################### 
# Both horizontal and vertical  
 
img_output = np.zeros(img.shape, dtype=img.dtype) 
 
for i in range(rows): 
    for j in range(cols): 
        offset_x = int(20.0 * math.sin(2 * 3.14 * i / 150)) 
        offset_y = int(20.0 * math.cos(2 * 3.14 * j / 150)) 
        if i+offset_y < rows and j+offset_x < cols: 
            img_output[i,j] = img[(i+offset_y)%rows,(j+offset_x)%cols] 
        else: 
            img_output[i,j] = 0 
 
cv2.imshow('Multidirectional wave', img_output) 
 
##################### 
# Concave effect 
 
img_output = np.zeros(img.shape, dtype=img.dtype) 
 
for i in range(rows): 
    for j in range(cols): 
        offset_x = int(128.0 * math.sin(2 * 3.14 * i / (2*cols))) 
        offset_y = 0 
        if j+offset_x < cols: 
            img_output[i,j] = img[i,(j+offset_x)%cols] 
        else: 
            img_output[i,j] = 0 
 
cv2.imshow('Concave', img_output) 
 
cv2.waitKey()