Here's a potential solution to find the bounding box contour with the largest surface area. We have two requirements:

**Largest bounding box is not intersecting with any other box**
**Largest bounding box is not inside another box**

Essentially we can reword the two requirements to this:

- Given C1 and C2, determine if C1 and C2 intersect
- Given C1 and C2, check if there is a point from C1 in C2

To solve #1, we can create a `contour_intersect`

function that uses a bitwise `AND`

operation with `np.logical_and()`

to detect intersection. The idea is to create two separate masks for each contour and then use the logical `AND`

operation on them. Any points that have a positive value (`1`

or `True`

) will be points of intersection. Essentially, if the entire array is `False`

then there was no intersection between the contours. But if there is a single `True`

, then the contours touched at some point and thus intersect.

For #2, we can create a function `contour_inside`

and use `cv2.pointPolygonTest()`

to determine if a point is inside, outside, or on the edge of a contour. The function returns `+1`

, `-1`

, or `0`

to indicate if a point is inside, outside, or on the contour, respectively. We find the centroid of C1 and then check if that point is inside C2.

Here's an example to visualize the scenarios:

Input image with three contours. Nothing special here, the expected answer would be the contour with the largest area.

Answer:

```
Contour #0 is the largest
```

Next we add two additional contours. Contour #3 will represent the intersection scenario and contour #4 will represent the inside contour scenario.

Answer:

```
Contour #0 has failed test
Contour #1 has failed test
Contour #2 is the largest
```

To solve this problem, we find contours then sort using contour area from largest to smallest. Next, we compare this contour with all other contours and check the two cases. If either case fails, we dump the current contour and move onto the next largest contour. The first contour that passes both tests for all other contours is our largest bounding box contour. Normally, contour #0 would be our largest but it fails the intersection test. We then move onto contour #1 but this fails the inside test. Thus the last remaining contour that passes both tests is contour #2.

```
import cv2
import numpy as np
# Check if C1 and C2 intersect
def contour_intersect(original_image, contour1, contour2):
# Two separate contours trying to check intersection on
contours = [contour1, contour2]
# Create image filled with zeros the same size of original image
blank = np.zeros(original_image.shape[0:2])
# Copy each contour into its own image and fill it with '1'
image1 = cv2.drawContours(blank.copy(), contours, 0, 1)
image2 = cv2.drawContours(blank.copy(), contours, 1, 1)
# Use the logical AND operation on the two images
# Since the two images had bitwise and applied to it,
# there should be a '1' or 'True' where there was intersection
# and a '0' or 'False' where it didnt intersect
intersection = np.logical_and(image1, image2)
# Check if there was a '1' in the intersection
return intersection.any()
# Check if C1 is in C2
def contour_inside(contour1, contour2):
# Find centroid of C1
M = cv2.moments(contour1)
cx = int(M['m10']/M['m00'])
cy = int(M['m01']/M['m00'])
inside = cv2.pointPolygonTest(contour2, (cx, cy), False)
if inside == 0 or inside == -1:
return False
elif inside == 1:
return True
# Load image, convert to grayscale, Otsu's threshold
image = cv2.imread('1.png')
original = image.copy()
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
thresh = cv2.threshold(gray, 0, 255, cv2.THRESH_BINARY_INV + cv2.THRESH_OTSU)[1]
# Find contours, sort by contour area from largest to smallest
cnts = cv2.findContours(thresh, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)
cnts = cnts[0] if len(cnts) == 2 else cnts[1]
sorted_cnts = sorted(cnts, key=lambda x: cv2.contourArea(x), reverse=True)
# "Intersection" and "inside" contours
# Add both contours to test
# --------------------------------
intersect_contour = np.array([[[230, 93]], [[230, 187]], [[326, 187]], [[326, 93]]])
sorted_cnts.append(intersect_contour)
cv2.drawContours(original, [intersect_contour], -1, (36,255,12), 3)
inside_contour = np.array([[[380, 32]], [[380, 229]], [[740, 229]], [[740, 32]]])
sorted_cnts.append(inside_contour)
cv2.drawContours(original, [inside_contour], -1, (36,255,12), 3)
# --------------------------------
# Find centroid for each contour and label contour number
for count, c in enumerate(sorted_cnts):
M = cv2.moments(c)
cx = int(M['m10']/M['m00'])
cy = int(M['m01']/M['m00'])
cv2.putText(original, str(count), (cx-5, cy+5), cv2.FONT_HERSHEY_SIMPLEX, 0.7, (246,255,12), 3)
# Find largest bounding box contour
largest_contour_name = ""
largest_contour = ""
contours_length = len(sorted_cnts)
for i1 in range(contours_length):
found = True
for i2 in range(i1 + 1, contours_length):
c1 = sorted_cnts[i1]
c2 = sorted_cnts[i2]
# Test intersection and "inside" contour
if contour_intersect(original, c1, c2) or contour_inside(c1, c2):
print('Contour #{} has failed test'.format(i1))
found = False
continue
if found:
largest_contour_name = i1
largest_contour = sorted_cnts[i1]
break
print('Contour #{} is the largest'.format(largest_contour_name))
print(largest_contour)
# Display
cv2.imshow('thresh', thresh)
cv2.imshow('image', image)
cv2.imshow('original', original)
cv2.waitKey()
```

**Note:** The assumption is that you have an array of contours from `cv2.findContours()`

with the format like this example:

```
cnts = cv2.findContours(thresh, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)
cnts = cnts[0] if len(cnts) == 2 else cnts[1]
sorted_cnts = sorted(cnts, key=lambda x: cv2.contourArea(x), reverse=True)
for c in sorted_cnts:
print(c)
print(type(c))
x,y,w,h = cv2.boundingRect(c)
print((x,y,w,h))
```

Output

```
[[[230 93]]
[[230 187]]
[[326 187]]
[[326 93]]]
<class 'numpy.ndarray'>
(230, 93, 97, 95)
```

**Performance note:** The intersection check function suffers on the performance side since it creates three copies of the input image to draw the contours and may be slower when it comes to execution time with a greater number of contours or a larger input image size. I'll leave this optimization step to you!

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