In this project, you will use the tools you learned about in the lesson to identify lane lines on the road. You can develop your pipeline on a series of individual images, and later apply the result to a video stream (really just a series of images). Check out the video clip "raw-lines-example.mp4" (also contained in this repository) to see what the output should look like after using the helper functions below.
Once you have a result that looks roughly like "raw-lines-example.mp4", you'll need to get creative and try to average and/or extrapolate the line segments you've detected to map out the full extent of the lane lines. You can see an example of the result you're going for in the video "P1_example.mp4". Ultimately, you would like to draw just one line for the left side of the lane, and one for the right.
In addition to implementing code, there is a brief writeup to complete. The writeup should be completed in a separate file, which can be either a markdown file or a pdf document. There is a write up template that can be used to guide the writing process. Completing both the code in the Ipython notebook and the writeup template will cover all of the rubric points for this project.
Let's have a look at our first image called 'test_images/solidWhiteRight.jpg'. Run the 2 cells below (hit Shift-Enter or the "play" button above) to display the image.
Note: If, at any point, you encounter frozen display windows or other confounding issues, you can always start again with a clean slate by going to the "Kernel" menu above and selecting "Restart & Clear Output".
The tools you have are color selection, region of interest selection, grayscaling, Gaussian smoothing, Canny Edge Detection and Hough Tranform line detection. You are also free to explore and try other techniques that were not presented in the lesson. Your goal is piece together a pipeline to detect the line segments in the image, then average/extrapolate them and draw them onto the image for display (as below). Once you have a working pipeline, try it out on the video stream below.
Your output should look something like this (above) after detecting line segments using the helper functions below
Your goal is to connect/average/extrapolate line segments to get output like this
Run the cell below to import some packages. If you get an import error for a package you've already installed, try changing your kernel (select the Kernel menu above --> Change Kernel). Still have problems? Try relaunching Jupyter Notebook from the terminal prompt. Also, consult the forums for more troubleshooting tips.
In [126]:
#importing some useful packages
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
import numpy as np
import cv2
%matplotlib inline
In [127]:
#reading in an image
img_name= 'solidWhiteRight.jpg'
image = mpimg.imread('test_images/' + img_name)
#printing out some stats and plotting
print('This image is:', type(image), 'with dimensions:', image.shape)
plt.imshow(image) # if you wanted to show a single color channel image called 'gray', for example, call as plt.imshow(gray, cmap='gray')
#DEFINE LIMIT FOR LANE's Y coordinate height
lane_limit_height = 330
#Store dimensions of image
ysize = image.shape[0]
xsize = image.shape[1]
Some OpenCV functions (beyond those introduced in the lesson) that might be useful for this project are:
cv2.inRange() for color selection
cv2.fillPoly() for regions selection
cv2.line() to draw lines on an image given endpoints
cv2.addWeighted() to coadd / overlay two images
cv2.cvtColor() to grayscale or change color
cv2.imwrite() to output images to file
cv2.bitwise_and() to apply a mask to an image
Check out the OpenCV documentation to learn about these and discover even more awesome functionality!
Below are some helper functions to help get you started. They should look familiar from the lesson!
In [128]:
import math
# im,port sys for computing max, min int
import sys
def grayscale(img):
"""Applies the Grayscale transform
This will return an image with only one color channel
but NOTE: to see the returned image as grayscale
(assuming your grayscaled image is called 'gray')
you should call plt.imshow(gray, cmap='gray')"""
return cv2.cvtColor(img, cv2.COLOR_RGB2GRAY)
# Or use BGR2GRAY if you read an image with cv2.imread()
# return cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
def canny(img, low_threshold, high_threshold):
"""Applies the Canny transform"""
return cv2.Canny(img, low_threshold, high_threshold)
def gaussian_blur(img, kernel_size):
"""Applies a Gaussian Noise kernel"""
return cv2.GaussianBlur(img, (kernel_size, kernel_size), 0)
def region_of_interest(img, vertices):
"""
Applies an image mask.
Only keeps the region of the image defined by the polygon
formed from `vertices`. The rest of the image is set to black.
"""
#defining a blank mask to start with
mask = np.zeros_like(img)
#defining a 3 channel or 1 channel color to fill the mask with depending on the input image
if len(img.shape) > 2:
channel_count = img.shape[2] # i.e. 3 or 4 depending on your image
ignore_mask_color = (255,) * channel_count
else:
ignore_mask_color = 255
#filling pixels inside the polygon defined by "vertices" with the fill color
cv2.fillPoly(mask, vertices, ignore_mask_color)
#returning the image only where mask pixels are nonzero
masked_image = cv2.bitwise_and(img, mask)
return masked_image
def draw_lines(img, lines, color=[255, 0, 0], thickness=2):
"""
NOTE: this is the function you might want to use as a starting point once you want to
average/extrapolate the line segments you detect to map out the full
extent of the lane (going from the result shown in raw-lines-example.mp4
to that shown in P1_example.mp4).
Think about things like separating line segments by their
slope ((y2-y1)/(x2-x1)) to decide which segments are part of the left
line vs. the right line. Then, you can average the position of each of
the lines and extrapolate to the top and bottom of the lane.
This function draws `lines` with `color` and `thickness`.
Lines are drawn on the image inplace (mutates the image).
If you want to make the lines semi-transparent, think about combining
this function with the weighted_img() function below
"""
# ``````````````` BELOW WAS THE CODE TO PLOT SMALL LINES BEFORE AVERAGING AND EXTRAPOLATING`````````
for line in lines:
for x1,y1,x2,y2 in line:
cv2.line(img, (x1, y1), (x2, y2), color, thickness)
# #````````````````````` NEW CODE FOR AVERAGING AND EXTRA POLATING BELOW```````````````````````````
def draw_lines_improved(img, lines, color=[255, 0, 0], thickness=2):
"""
NOTE: this is the function you might want to use as a starting point once you want to
average/extrapolate the line segments you detect to map out the full
extent of the lane (going from the result shown in raw-lines-example.mp4
to that shown in P1_example.mp4).
Think about things like separating line segments by their
slope ((y2-y1)/(x2-x1)) to decide which segments are part of the left
line vs. the right line. Then, you can average the position of each of
the lines and extrapolate to the top and bottom of the lane.
This function draws `lines` with `color` and `thickness`.
Lines are drawn on the image inplace (mutates the image).
If you want to make the lines semi-transparent, think about combining
this function with the weighted_img() function below
"""
l_x = []
l_y = []
r_x = []
r_y = []
# The goal is to have one straight line from the top right corner to all the way down.
# First, separate x and y points.
for line in lines:
for x1,y1,x2,y2 in line:
slope = (y2-y1)/(x2-x1)
# `````````````````` In Image y is reversed. The higher y value is actually lower in the image.
# `````````````````` The slope is negative for the left line, and positive for the right line.
if slope<0:
l_x += [x1, x2]
l_y += [y1, y2]
elif slope>0:
r_x += [x1, x2]
r_y += [y1, y2]
# Then we can use np.polyfit to fit a line to these points.
# A straight line can be represented with y = mx + b which is a polynomial of degree 1.
l_slope_and_intercept = np.polyfit(l_x, l_y, 1)
r_slope_and_intercept = np.polyfit(r_x, r_y, 1)
# print will show value of m and c in 'y=mx +c' : [ 1.40241735 -21.23284749]
l_m = l_slope_and_intercept[0]
l_c = l_slope_and_intercept[1]
r_m = r_slope_and_intercept[0]
r_c = r_slope_and_intercept[1]
l_y1 = ysize # max size of image (bottom most point)
l_x1 = int((l_y1 - l_c) / l_m) # x = (y -c)/m
l_y2 = lane_limit_height # central point
l_x2 = int((l_y2 - l_c) / l_m)
r_y1 = ysize
r_x1 = int((r_y1 - r_c) / r_m)
r_y2 = lane_limit_height
r_x2 = int((r_y2 - r_c) / r_m)
# DRAW LINES
cv2.line(img, (l_x1, l_y1), (l_x2, l_y2), color, thickness*5)
cv2.line(img, (r_x1, r_y1), (r_x2, r_y2), color, thickness*5)
# ````````````````````` OLD CODE FOR AVERAGING AND EXTRA POLATING BELOW ``````````````````````````
# ````````````````````` TWO WORKING SOLUTIONS ```````````````````````````
# ``````````````````````````````````` NOW COMMENTED OUT ````````````````````````````````````````````
# # ```````````````````````````` SOLUTION 1 ````````````````````````````````````````````````
# # ``````````` TAKE OUT OUTLIERS USING MEAN AND STANDARD DEVIATION AND THEN TAKE MEAN SLOPE
# # ``````````` PROBLEM : HOW TO FIND AVG INTERCEPT , ONCE YOU HAVE FOUNF AVG SLOPE ?
# l_slope_arr = []
# l_intercept_arr = []
# r_slope_arr = []
# r_intercept_arr = []
# for line in lines:
# for x1,y1,x2,y2 in line:
# slope = ((y2-y1)/(x2-x1))
# # print(slope)
# # `````````````````` In Image y is reversed. The higher y value is actually lower in the image.
# # `````````````````` The slope is negative for the left line, and positive for the right line.
# if slope<0:
# l_slope_arr.append(slope)
# l_intercept_arr.append(y1-(slope*x1))
# elif slope>0:
# r_slope_arr.append(slope)
# r_intercept_arr.append(y1-(slope*x1))
# l_mean_slope = np.mean(l_slope_arr)
# l_std_slope = np.std(l_slope_arr)
# l_final_list = [x for x in l_slope_arr if (x > l_mean_slope - 2 * l_std_slope)]
# l_final_list = [x for x in l_final_list if (x < l_mean_slope + 2 * l_std_slope)]
# l_avg_slope = np.mean(l_final_list)
# print(l_avg_slope)
# l_avg_intercept = np.mean(l_intercept_arr)
# l_x1 = (ysize - l_avg_intercept)/l_avg_slope
# l_x2 = (lane_limit_height - l_avg_intercept)/l_avg_slope
# cv2.line(img, (int(l_x1), ysize), (int(l_x2), lane_limit_height), color, thickness*5)
# # ````````` ```````````````````SOLUTION 2 ````````````````````````````````
# # ````` ``````````````TO FIND THE BOTTOM MOST MIN POINT
# # `````` `````````````TO FIND UPMOST MAX POINT
# # ``` ````````````````THEN DRAW A LINE FROM THERE
# # ``` `````````````````````` (WORKING)
# x_left_bottom = sys.maxsize
# y_left_bottom = -sys.maxsize
# x_left_up = -sys.maxsize
# y_left_up = sys.maxsize
# x_right_bottom = -sys.maxsize
# y_right_bottom = -sys.maxsize
# x_right_up = sys.maxsize
# y_right_up = sys.maxsize
# for line in lines:
# for x1,y1,x2,y2 in line:
# slope = ((y2-y1)/(x2-x1))
# # print(slope)
# # `````````````````` In Image y is reversed. The higher y value is actually lower in the image.
# # `````````````````` The slope is negative for the left line, and positive for the right line.
# if slope<0:
# x_left_bottom = min(x_left_bottom, x1)
# y_left_bottom = max(y_left_bottom, y1)
# x_left_up = max(x_left_up, x2)
# y_left_up = min(y_left_up, y2)
# elif slope>0:
# x_right_bottom = max(x_right_bottom, x2)
# y_right_bottom = max(y_right_bottom, y2)
# x_right_up = min(x_right_up, x1)
# y_right_up = min(y_right_up, y1)
# # ```````````````````` PRINT ALL THE COORDINATES``````````````````````````
# # print('x_left_bottom: ' + str(x_left_bottom))
# # print('y_left_bottom: ' + str(y_left_bottom))
# # print('x_left_up: ' + str(x_left_up))
# # print('y_left_up: ' + str(y_left_up))
# # print()
# # print('x_right_bottom: ' + str(x_right_bottom))
# # print('y_right_bottom: ' + str(y_right_bottom))
# # print('x_right_up: ' + str(x_right_up))
# # print('y_right_up: ' + str(y_right_up))
# # # Draw left and right averaged lines (ACTUAL - TAKING MINIMUM VALUES OF ACTUAL LANE)
# # cv2.line(img, (x_left_bottom, y_left_bottom), (x_left_up, y_left_up), color, thickness*5)
# # cv2.line(img, (x_right_bottom, y_right_bottom), (x_right_up, y_right_up), color, thickness*5)
# # Draw left and right averaged lines (Y BOTTOM MAX FOR BOTH, Y UP 330 FOR BOTH)
# cv2.line(img, (x_left_bottom, ysize), (x_left_up, y_left_up), color, thickness*5)
# cv2.line(img, (x_right_bottom, ysize), (x_right_up, y_right_up), color, thickness*5)
def hough_lines(img, rho, theta, threshold, min_line_len, max_line_gap):
"""
`img` should be the output of a Canny transform.
Returns an image with hough lines drawn.
"""
lines = cv2.HoughLinesP(img, rho, theta, threshold, np.array([]), minLineLength=min_line_len, maxLineGap=max_line_gap)
line_img = np.zeros((img.shape[0], img.shape[1], 3), dtype=np.uint8)
# USE THE IMPROVED DRAW LINES
# draw_lines(line_img, lines)
draw_lines_improved(line_img, lines)
return line_img
# Python 3 has support for cool math symbols.
def weighted_img(img, initial_img, α=0.8, β=1., λ=0.):
"""
`img` is the output of the hough_lines(), An image with lines drawn on it.
Should be a blank image (all black) with lines drawn on it.
`initial_img` should be the image before any processing.
The result image is computed as follows:
initial_img * α + img * β + λ
NOTE: initial_img and img must be the same shape!
"""
return cv2.addWeighted(initial_img, α, img, β, λ)
In [129]:
import os
os.listdir("test_images/")
Out[129]:
Build the pipeline and run your solution on all test_images. Make copies into the test_images_output directory, and you can use the images in your writeup report.
Try tuning the various parameters, especially the low and high Canny thresholds as well as the Hough lines parameters.
In [130]:
# TODO: Build your pipeline that will draw lane lines on the test_images
# then save them to the test_images directory.
for im in os.listdir("test_images/"):
if im=='output':
continue
image = mpimg.imread('test_images/' + im)
#Copy the image to prevent unecessary changes
image_cp = np.copy(image)
# Convert image to grey scale
gray = grayscale(image_cp)
# Define a kernel size and apply Gaussian smoothing
kernel_size = 5
blur_gray = gaussian_blur(gray, kernel_size)
# Define our parameters for Canny and apply
low_threshold = 50
high_threshold = 150
edges = canny(blur_gray, low_threshold, high_threshold)
# Define a polygon region of interest
# Keep in mind the origin (x=0, y=0) is in the upper left in image processing
# Coordinates of vertices
left_upper = [int(xsize/2)-50, lane_limit_height]
right_upper = [int(xsize/2)+50, lane_limit_height]
right_bottom = [xsize-50, ysize]
left_bottom = [50, ysize]
vertices = np.array( [[ left_upper,right_upper,right_bottom,left_bottom]], dtype=np.int32 )
region_canny_image = region_of_interest(edges, vertices)
# ````````````````` Test region of interest```````````````````````````````
# mpimg.imsave('test_images/output/' + 'test_region_area.png', region_image)
# plt.imshow(region_image)
# Define the Hough transform parameters
# Make a blank the same size as our image to draw on
rho = 2
theta = np.pi/180
threshold = 32
min_line_len = 10
max_line_gap = 200
# As you increase above longer the line connecting the left lane lines
# Run Hough on edge detected image
line_image = hough_lines(region_canny_image, rho, theta, threshold, min_line_len, max_line_gap)
# plt.imshow(line_image)
# Combine the processed image after selecting the required region with the original img
comb_hough_orig = weighted_img(line_image, image)
# plt.imshow(comb_hough_orig)
#saving the resultant image
img_out_name = im.split('.')[0] + '_out.png'
mpimg.imsave('test_images_output/' + img_out_name, comb_hough_orig)
#reading the output image
image_out = mpimg.imread('test_images_output/' + img_out_name)
plt.imshow(image_out)
In [ ]:
You know what's cooler than drawing lanes over images? Drawing lanes over video!
We can test our solution on two provided videos:
solidWhiteRight.mp4
solidYellowLeft.mp4
Note: if you get an import error when you run the next cell, try changing your kernel (select the Kernel menu above --> Change Kernel). Still have problems? Try relaunching Jupyter Notebook from the terminal prompt. Also, consult the forums for more troubleshooting tips.
If you get an error that looks like this:
NeedDownloadError: Need ffmpeg exe.
You can download it by calling:
imageio.plugins.ffmpeg.download()Follow the instructions in the error message and check out this forum post for more troubleshooting tips across operating systems.
In [131]:
# Import everything needed to edit/save/watch video clips
from moviepy.editor import VideoFileClip
from IPython.display import HTML
In [132]:
def process_image(image):
# NOTE: The output you return should be a color image (3 channel) for processing video below
# TODO: put your pipeline here,
# you should return the final output (image where lines are drawn on lanes)
#Copy the image to prevent unecessary changes
image_cp = np.copy(image)
# Convert image to grey scale
gray = grayscale(image_cp)
# Define a kernel size and apply Gaussian smoothing
kernel_size = 5
blur_gray = gaussian_blur(gray, kernel_size)
# Define our parameters for Canny and apply
low_threshold = 50
high_threshold = 150
edges = canny(blur_gray, low_threshold, high_threshold)
# Define a polygon region of interest
# Keep in mind the origin (x=0, y=0) is in the upper left in image processing
# Coordinates of vertices
left_upper = [int(xsize/2)-50, lane_limit_height]
right_upper = [int(xsize/2)+50, lane_limit_height]
right_bottom = [xsize-50, ysize]
left_bottom = [50, ysize]
vertices = np.array( [[ left_upper,right_upper,right_bottom,left_bottom]], dtype=np.int32 )
region_canny_image = region_of_interest(edges, vertices)
# ````````````````` Test region of interest```````````````````````````````
# mpimg.imsave('test_images/output/' + 'test_region_area.png', region_image)
# plt.imshow(region_image)
# Define the Hough transform parameters
# Make a blank the same size as our image to draw on
rho = 2
theta = np.pi/180
threshold = 32
min_line_len = 10
max_line_gap = 200
# As you increase above longer the line connecting the left lane lines
# Run Hough on edge detected image
line_image = hough_lines(region_canny_image, rho, theta, threshold, min_line_len, max_line_gap)
# plt.imshow(line_image)
# Combine the processed image after selecting the required region with the original img
comb_hough_orig = weighted_img(line_image, image)
# plt.imshow(comb_hough_orig)
result = comb_hough_orig
return result
Let's try the one with the solid white lane on the right first ...
In [133]:
white_output = 'test_videos_output/solidWhiteRight.mp4'
## To speed up the testing process you may want to try your pipeline on a shorter subclip of the video
## To do so add .subclip(start_second,end_second) to the end of the line below
## Where start_second and end_second are integer values representing the start and end of the subclip
## You may also uncomment the following line for a subclip of the first 5 seconds
##clip1 = VideoFileClip("test_videos/solidWhiteRight.mp4").subclip(0,5)
clip1 = VideoFileClip("test_videos/solidWhiteRight.mp4")
white_clip = clip1.fl_image(process_image) #NOTE: this function expects color images!!
%time white_clip.write_videofile(white_output, audio=False)
Play the video inline, or if you prefer find the video in your filesystem (should be in the same directory) and play it in your video player of choice.
In [134]:
HTML("""
<video width="960" height="540" controls>
<source src="{0}">
</video>
""".format(white_output))
Out[134]:
At this point, if you were successful with making the pipeline and tuning parameters, you probably have the Hough line segments drawn onto the road, but what about identifying the full extent of the lane and marking it clearly as in the example video (P1_example.mp4)? Think about defining a line to run the full length of the visible lane based on the line segments you identified with the Hough Transform. As mentioned previously, try to average and/or extrapolate the line segments you've detected to map out the full extent of the lane lines. You can see an example of the result you're going for in the video "P1_example.mp4".
Go back and modify your draw_lines function accordingly and try re-running your pipeline. The new output should draw a single, solid line over the left lane line and a single, solid line over the right lane line. The lines should start from the bottom of the image and extend out to the top of the region of interest.
Now for the one with the solid yellow lane on the left. This one's more tricky!
In [135]:
yellow_output = 'test_videos_output/solidYellowLeft.mp4'
## To speed up the testing process you may want to try your pipeline on a shorter subclip of the video
## To do so add .subclip(start_second,end_second) to the end of the line below
## Where start_second and end_second are integer values representing the start and end of the subclip
## You may also uncomment the following line for a subclip of the first 5 seconds
##clip2 = VideoFileClip('test_videos/solidYellowLeft.mp4').subclip(0,5)
clip2 = VideoFileClip('test_videos/solidYellowLeft.mp4')
yellow_clip = clip2.fl_image(process_image)
%time yellow_clip.write_videofile(yellow_output, audio=False)
In [136]:
HTML("""
<video width="960" height="540" controls>
<source src="{0}">
</video>
""".format(yellow_output))
Out[136]:
If you're satisfied with your video outputs, it's time to make the report writeup in a pdf or markdown file. Once you have this Ipython notebook ready along with the writeup, it's time to submit for review! Here is a link to the writeup template file.
In [137]:
challenge_output = 'test_videos_output/challenge.mp4'
## To speed up the testing process you may want to try your pipeline on a shorter subclip of the video
## To do so add .subclip(start_second,end_second) to the end of the line below
## Where start_second and end_second are integer values representing the start and end of the subclip
## You may also uncomment the following line for a subclip of the first 5 seconds
##clip3 = VideoFileClip('test_videos/challenge.mp4').subclip(0,5)
clip3 = VideoFileClip('test_videos/challenge.mp4')
challenge_clip = clip3.fl_image(process_image)
%time challenge_clip.write_videofile(challenge_output, audio=False)
In [138]:
HTML("""
<video width="960" height="540" controls>
<source src="{0}">
</video>
""".format(challenge_output))
Out[138]:
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