-
Notifications
You must be signed in to change notification settings - Fork 0
/
finding_lines_w.py
545 lines (462 loc) · 23.5 KB
/
finding_lines_w.py
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
import numpy as np
import cv2
from PIL import Image
import matplotlib.image as mpimg
class Line:
def __init__(self):
# was the line detected in the last iteration?
self.detected = False
# Set the width of the windows +/- margin
self.window_margin = 60
# x values of the fitted line over the last n iterations
self.prevx = []
# polynomial coefficients for the most recent fit
self.current_fit = [np.array([False])]
#radius of curvature of the line in some units
self.radius_of_curvature = None
# starting x_value
self.startx = None
# ending x_value
self.endx = None
# x values for detected line pixels
self.allx = None
# y values for detected line pixels
self.ally = None
# road information
self.road_inf = None
self.curvature = None
self.deviation = None
def warp_image(img, src, dst, size):
""" Perspective Transform """
M = cv2.getPerspectiveTransform(src, dst)
Minv = cv2.getPerspectiveTransform(dst, src)
warp_img = cv2.warpPerspective(img, M, size, flags=cv2.INTER_LINEAR)
return warp_img, M, Minv
def rad_of_curvature(left_line, right_line):
""" measure radius of curvature """
ploty = left_line.ally
leftx, rightx = left_line.allx, right_line.allx
leftx = leftx[::-1] # Reverse to match top-to-bottom in y
rightx = rightx[::-1] # Reverse to match top-to-bottom in y
# Define conversions in x and y from pixels space to meters
width_lanes = abs(right_line.startx - left_line.startx)
ym_per_pix = 22 / 720 # meters per pixel in y dimension
xm_per_pix = 3.7*(720/1280) / width_lanes # meters per pixel in x dimension
# Define y-value where we want radius of curvature
# the maximum y-value, corresponding to the bottom of the image
y_eval = np.max(ploty)
# Fit new polynomials to x,y in world space
left_fit_cr = np.polyfit(ploty * ym_per_pix, leftx * xm_per_pix, 2)
right_fit_cr = np.polyfit(ploty * ym_per_pix, rightx * xm_per_pix, 2)
# Calculate the new radii of curvature
left_curverad = ((1 + (2 * left_fit_cr[0] * y_eval * ym_per_pix + left_fit_cr[1]) ** 2) ** 1.5) / np.absolute(
2 * left_fit_cr[0])
right_curverad = ((1 + (2 * right_fit_cr[0] * y_eval * ym_per_pix + right_fit_cr[1]) ** 2) ** 1.5) / np.absolute(
2 * right_fit_cr[0])
# radius of curvature result
left_line.radius_of_curvature = left_curverad
right_line.radius_of_curvature = right_curverad
def smoothing(lines, pre_lines=3):
# collect lines & print average line
lines = np.squeeze(lines)
avg_line = np.zeros((720))
for ii, line in enumerate(reversed(lines)):
if ii == pre_lines:
break
avg_line += line
avg_line = avg_line / pre_lines
return avg_line
def blind_search(b_img, left_line, right_line):
"""
blind search - first frame, lost lane lines
using histogram & sliding window
give different weight in color info(0.8) & gradient info(0.2) using weighted average
"""
# Create an output image to draw on and visualize the result
# output = np.dstack((b_img, b_img, b_img)) * 255
output = cv2.cvtColor(b_img, cv2.COLOR_GRAY2RGB)
# Choose the number of sliding windows
num_windows = 9
# Set height of windows
window_height = np.int(b_img.shape[0] / num_windows)
# Identify the x and y positions of all nonzero pixels in the image
nonzero = b_img.nonzero()
nonzeroy = np.array(nonzero[0])
nonzerox = np.array(nonzero[1])
if left_line.startx == None:
# Take a histogram of the bottom half of the image
histogram = np.sum(b_img[int(b_img.shape[0] * 2 / 3):, :], axis=0)
midpoint = np.int(histogram.shape[0] / 2)
start_leftX = np.argmax(histogram[:midpoint])
start_rightX = np.argmax(histogram[midpoint:]) + midpoint
# Current positions to be updated for each window
current_leftX = start_leftX
current_rightX = start_rightX
else:
current_leftX = left_line.startx
current_rightX = right_line.startx
# Set minimum number of pixels found to recenter window
min_num_pixel = 50
# Create empty lists to receive left and right lane pixel indices
win_left_lane = []
win_right_lane = []
left_weight_x, left_weight_y = [], []
right_weight_x, right_weight_y = [], []
window_margin = left_line.window_margin
# Step through the windows one by one
for window in range(num_windows):
# Identify window boundaries in x and y (and right and left)
win_y_low = b_img.shape[0] - (window + 1) * window_height
win_y_high = b_img.shape[0] - window * window_height
win_leftx_min = int(current_leftX - window_margin)
win_leftx_max = int(current_leftX + window_margin)
win_rightx_min = int(current_rightX - window_margin)
win_rightx_max = int(current_rightX + window_margin)
if win_rightx_max > 720:
win_rightx_min = b_img.shape[1] - 2 * window_margin
win_rightx_max = b_img.shape[1]
# Draw the windows on the visualization image
cv2.rectangle(output, (win_leftx_min, win_y_low), (win_leftx_max, win_y_high), (0, 255, 0), 2)
cv2.rectangle(output, (win_rightx_min, win_y_low), (win_rightx_max, win_y_high), (0, 255, 0), 2)
# Identify the nonzero pixels in x and y within the window
left_window_inds = ((nonzeroy >= win_y_low) & (nonzeroy <= win_y_high) & (nonzerox >= win_leftx_min) & (
nonzerox <= win_leftx_max)).nonzero()[0]
right_window_inds = ((nonzeroy >= win_y_low) & (nonzeroy <= win_y_high) & (nonzerox >= win_rightx_min) & (
nonzerox <= win_rightx_max)).nonzero()[0]
# Append these indices to the lists
win_left_lane.append(left_window_inds)
win_right_lane.append(right_window_inds)
# If you found > minpix pixels, recenter next window on their mean position
if len(left_window_inds) > min_num_pixel:
win = b_img[win_y_low:win_y_high, win_leftx_min:win_leftx_max]
temp, count_g, count_h = 0, 0, 0
for i in range(win.shape[1]):
for j in range(win.shape[0]):
if win[j, i] >= 70 and win[j, i] <= 130:
temp += 0.2 * (i + win_leftx_min)
count_g += 1
output[j + win_y_low, i + win_leftx_min] = (255, 0, 0)
elif win[j, i] > 220:
temp += 0.8 * (i + win_leftx_min)
count_h += 1
output[j + win_y_low, i + win_leftx_min] = (0, 0, 255)
# else:
# output[j + win_y_low, i + win_leftx_min] = (255, 255, 255)
if not (count_h == 0 and count_g == 0):
left_w_x = temp / (0.2 * count_g + 0.8 * count_h) # + win_leftx_min
#cv2.circle(output, (int(left_w_x), int((win_y_low + win_y_high) / 2)), 10, (255, 0, 0), -1)
#cv2.circle(output, (int(current_leftX), int((win_y_low + win_y_high) / 2)), 10, (255, 0, 0), -1)
left_weight_x.append(int(left_w_x))
left_weight_y.append(int((win_y_low + win_y_high) / 2))
current_leftX = int(left_w_x)
if len(right_window_inds) > min_num_pixel:
win = b_img[win_y_low:win_y_high, win_rightx_min:win_rightx_max]
temp, count_g, count_h = 0, 0, 0
for i in range(win.shape[1]):
for j in range(win.shape[0]):
if win[j, i] >= 70 and win[j, i] <= 130:
temp += 0.2 * (i + win_rightx_min)
count_g += 1
output[j + win_y_low, i + win_rightx_min] = (255, 0, 0)
elif win[j, i] > 200:
temp += 0.8 * (i + win_rightx_min)
count_h += 1
output[j + win_y_low, i + win_rightx_min] = (0, 0, 255)
# else:
# output[j + win_y_low, i + win_rightx_min] = (255, 255, 255)
if not (count_h == 0 and count_g == 0):
right_w_x = temp / (0.2 * count_g + 0.8 * count_h) # + win_leftx_min
#cv2.circle(output, (int(right_w_x), int((win_y_low + win_y_high) / 2)), 10, (255, 0, 0), -1)
#cv2.circle(output, (int(current_rightX), int((win_y_low + win_y_high) / 2)), 10, (255, 0, 0), -1)
right_weight_x.append(int(right_w_x))
right_weight_y.append(int((win_y_low + win_y_high) / 2))
current_rightX = int(right_w_x)
# Concatenate the arrays of indices
win_left_lane = np.concatenate(win_left_lane)
win_right_lane = np.concatenate(win_right_lane)
# Extract left and right line pixel positions
leftx, lefty = nonzerox[win_left_lane], nonzeroy[win_left_lane]
rightx, righty = nonzerox[win_right_lane], nonzeroy[win_right_lane]
#output[lefty, leftx] = [255, 0, 0]
#output[righty, rightx] = [0, 0, 255]
# Fit a second order polynomial to each
left_fit = np.polyfit(left_weight_y, left_weight_x, 2)
right_fit = np.polyfit(right_weight_y, right_weight_x, 2)
# Generate x and y values for plotting
ploty = np.linspace(0, b_img.shape[0] - 1, b_img.shape[0])
# ax^2 + bx + c
left_plotx = left_fit[0] * ploty ** 2 + left_fit[1] * ploty + left_fit[2]
right_plotx = right_fit[0] * ploty ** 2 + right_fit[1] * ploty + right_fit[2]
left_line.prevx.append(left_plotx)
right_line.prevx.append(right_plotx)
# frame to frame smoothing
if len(left_line.prevx) > 10:
left_avg_line = smoothing(left_line.prevx, 10)
left_avg_fit = np.polyfit(ploty, left_avg_line, 2)
left_fit_plotx = left_avg_fit[0] * ploty ** 2 + left_avg_fit[1] * ploty + left_avg_fit[2]
left_line.current_fit = left_avg_fit
left_line.allx, left_line.ally = left_fit_plotx, ploty
else:
left_line.current_fit = left_fit
left_line.allx, left_line.ally = left_plotx, ploty
if len(right_line.prevx) > 10:
right_avg_line = smoothing(right_line.prevx, 10)
right_avg_fit = np.polyfit(ploty, right_avg_line, 2)
right_fit_plotx = right_avg_fit[0] * ploty ** 2 + right_avg_fit[1] * ploty + right_avg_fit[2]
right_line.current_fit = right_avg_fit
right_line.allx, right_line.ally = right_fit_plotx, ploty
else:
right_line.current_fit = right_fit
right_line.allx, right_line.ally = right_plotx, ploty
left_line.startx, right_line.startx = left_line.allx[len(left_line.allx)-1], right_line.allx[len(right_line.allx)-1]
left_line.endx, right_line.endx = left_line.allx[0], right_line.allx[0]
left_line.detected, right_line.detected = True, True
# print radius of curvature
rad_of_curvature(left_line, right_line)
return output
def prev_window_refer(b_img, left_line, right_line):
"""
refer to previous window info - after detecting lane lines in previous frame
give different weight in color info(0.8) & gradient info(0.2) using weighted average
"""
# Create an output image to draw on and visualize the result
output = cv2.cvtColor(b_img, cv2.COLOR_GRAY2RGB)
# Set margin of windows
window_margin = left_line.window_margin
left_weight_x, left_weight_y = [], []
right_weight_x, right_weight_y = [], []
temp, count_g, count_h = 0, 0, 0
for i, j in enumerate(left_line.allx):
for m in range(window_margin):
j1, j2 = int(j) + m, int(j) - m
if b_img[i, j1] >= 70 and b_img[i, j1] <= 130:
temp += 0.2 * j1
count_g += 1
output[i, j1] = (255, 0, 0)
if b_img[i, j2] >= 70 and b_img[i, j2] <= 130:
temp += 0.2 * j2
count_g += 1
output[i, j2] = (255, 0, 0)
if b_img[i, j1] > 220:
temp += 0.8 * j1
count_h += 1
output[i, j1] = (0, 0, 255)
if b_img[i, j2] > 220:
temp += 0.8 * j2
count_h += 1
output[i, j2] = (0, 0, 255)
if (i+1) % 80 == 0:
if not (count_h == 0 and count_g == 0):
left_w_x = temp / (0.2 * count_g + 0.8 * count_h) # + win_leftx_min
#cv2.circle(output, (int(left_w_x), (i+1-40)), 10, (255, 0, 0), -1)
left_weight_x.append(int(left_w_x))
left_weight_y.append((i+1-40))
temp, count_g, count_h = 0, 0, 0
temp, count_g, count_h = 0, 0, 0
for i, j in enumerate(right_line.allx):
if j >= 720 - (window_margin):
for m in range(2*(window_margin)):
k = 720 - 2*(window_margin) + m
if b_img[i, k] >= 70 and b_img[i, k] <= 130:
temp += 0.2 * k
count_g += 1
output[i, k] = (255, 0, 0)
if b_img[i, k] > 220:
temp += 0.8 * k
count_h += 1
output[i, k] = (0, 0, 255)
else:
for m in range(window_margin):
j1, j2 = int(j) + m, int(j) - m
if b_img[i, j1] >= 70 and b_img[i, j1] <= 130:
temp += 0.2 * j1
count_g += 1
output[i, j1] = (255, 0, 0)
if b_img[i, j2] >= 70 and b_img[i, j2] <= 130:
temp += 0.2 * j2
count_g += 1
output[i, j2] = (255, 0, 0)
if b_img[i, j1] > 220:
temp += 0.8 * j1
count_h += 1
output[i, j1] = (0,0, 255)
if b_img[i, j2] > 220:
temp += 0.8 * j2
count_h += 1
output[i, j2] = (0, 0, 255)
if (i + 1) % 80 == 0:
if not (count_h == 0 and count_g == 0):
right_w_x = temp / (0.2 * count_g + 0.8 * count_h)
#cv2.circle(output, (int(right_w_x), (i+1-40)), 10, (255, 0, 0), -1)
right_weight_x.append(int(right_w_x))
right_weight_y.append((i+1-40))
temp, count_g, count_h = 0, 0, 0
#output[lefty, leftx] = [255, 0, 0]
#output[righty, rightx] = [0, 0, 255]
if len(left_weight_x) <= 5:
left_weight_x = left_line.allx
left_weight_y = left_line.ally
if len(right_weight_x) <= 5:
right_weight_x = right_line.allx
right_weight_y = right_line.ally
# Fit a second order polynomial to each
left_fit = np.polyfit(left_weight_y, left_weight_x, 2)
right_fit = np.polyfit(right_weight_y, right_weight_x, 2)
# Generate x and y values for plotting
ploty = np.linspace(0, b_img.shape[0] - 1, b_img.shape[0])
# ax^2 + bx + c
left_plotx = left_fit[0] * ploty ** 2 + left_fit[1] * ploty + left_fit[2]
right_plotx = right_fit[0] * ploty ** 2 + right_fit[1] * ploty + right_fit[2]
left_line.prevx.append(left_plotx)
right_line.prevx.append(right_plotx)
# frame to frame smoothing
if len(left_line.prevx) > 10:
left_avg_line = smoothing(left_line.prevx, 10)
left_avg_fit = np.polyfit(ploty, left_avg_line, 2)
left_fit_plotx = left_avg_fit[0] * ploty ** 2 + left_avg_fit[1] * ploty + left_avg_fit[2]
left_line.current_fit = left_avg_fit
left_line.allx, left_line.ally = left_fit_plotx, ploty
else:
left_line.current_fit = left_fit
left_line.allx, left_line.ally = left_plotx, ploty
if len(right_line.prevx) > 10:
right_avg_line = smoothing(right_line.prevx, 10)
right_avg_fit = np.polyfit(ploty, right_avg_line, 2)
right_fit_plotx = right_avg_fit[0] * ploty ** 2 + right_avg_fit[1] * ploty + right_avg_fit[2]
right_line.current_fit = right_avg_fit
right_line.allx, right_line.ally = right_fit_plotx, ploty
else:
right_line.current_fit = right_fit
right_line.allx, right_line.ally = right_plotx, ploty
# goto blind_search if the standard value of lane lines is high.
standard = np.std(right_line.allx - left_line.allx)
if (standard > 80):
left_line.detected = False
left_line.startx, right_line.startx = left_line.allx[len(left_line.allx) - 1], right_line.allx[len(right_line.allx) - 1]
left_line.endx, right_line.endx = left_line.allx[0], right_line.allx[0]
# print radius of curvature
rad_of_curvature(left_line, right_line)
return output
def find_LR_lines(binary_img, left_line, right_line):
"""
find left, right lines & isolate left, right lines
blind search - first frame, lost lane lines
previous window - after detecting lane lines in previous frame
"""
# if don't have lane lines info
if left_line.detected == False:
return blind_search(binary_img, left_line, right_line)
# if have lane lines info
else:
return prev_window_refer(binary_img, left_line, right_line)
def draw_lane(img, left_line, right_line, lane_color=(255, 0, 255), road_color=(0, 255, 0)):
""" draw lane lines & current driving space """
window_img = np.zeros_like(img)
window_margin = left_line.window_margin
left_plotx, right_plotx = left_line.allx, right_line.allx
ploty = left_line.ally
# Generate a polygon to illustrate the search window area
# And recast the x and y points into usable format for cv2.fillPoly()
left_pts_l = np.array([np.transpose(np.vstack([left_plotx - window_margin/5, ploty]))])
left_pts_r = np.array([np.flipud(np.transpose(np.vstack([left_plotx + window_margin/5, ploty])))])
left_pts = np.hstack((left_pts_l, left_pts_r))
right_pts_l = np.array([np.transpose(np.vstack([right_plotx - window_margin/5, ploty]))])
right_pts_r = np.array([np.flipud(np.transpose(np.vstack([right_plotx + window_margin/5, ploty])))])
right_pts = np.hstack((right_pts_l, right_pts_r))
# Draw the lane onto the warped blank image
cv2.fillPoly(window_img, np.int_([left_pts]), lane_color)
cv2.fillPoly(window_img, np.int_([right_pts]), lane_color)
# Recast the x and y points into usable format for cv2.fillPoly()
pts_left = np.array([np.transpose(np.vstack([left_plotx+window_margin/5, ploty]))])
pts_right = np.array([np.flipud(np.transpose(np.vstack([right_plotx-window_margin/5, ploty])))])
pts = np.hstack((pts_left, pts_right))
# Draw the lane onto the warped blank image
cv2.fillPoly(window_img, np.int_([pts]), road_color)
result = cv2.addWeighted(img, 1, window_img, 0.3, 0)
return result, window_img
def road_info(left_line, right_line):
""" print road information onto result image """
curvature = (left_line.radius_of_curvature + right_line.radius_of_curvature) / 2
direction = ((left_line.endx - left_line.startx) + (right_line.endx - right_line.startx)) / 2
#print('direction : ', direction, 'curvature : ',curvature)
if curvature > 2100:# and abs(direction) < 80:
road_inf = 'No Curve'
curvature = -1
elif curvature <= 2100 and direction < - 50:
road_inf = 'Left Curve'
elif curvature <= 2100 and direction > 50:
road_inf = 'Right Curve'
else:
if left_line.road_inf != None:
road_inf = left_line.road_inf
curvature = left_line.curvature
else:
road_inf = 'None'
curvature = curvature
center_lane = (right_line.startx + left_line.startx) / 2
lane_width = right_line.startx - left_line.startx
center_car = 720 / 2
if center_lane > center_car:
deviation = 'Left ' + str(round(abs(center_lane - center_car)/(lane_width / 2)*100, 3)) + '%'
elif center_lane < center_car:
deviation = 'Right ' + str(round(abs(center_lane - center_car)/(lane_width / 2)*100, 3)) + '%'
else:
deviation = 'Center'
left_line.road_inf = road_inf
left_line.curvature = curvature
left_line.deviation = deviation
return road_inf, curvature, deviation
def print_road_status(img, left_line, right_line):
""" print road status (curve direction, radius of curvature, deviation) """
road_inf, curvature, deviation = road_info(left_line, right_line)
cv2.putText(img, 'Road Status', (22, 30), cv2.FONT_HERSHEY_COMPLEX, 0.7, (80, 80, 80), 2)
lane_inf = 'Lane Info : ' + road_inf
if curvature == -1:
lane_curve = 'Curvature : Straight line'
else:
lane_curve = 'Curvature : {0:0.3f}m'.format(curvature)
deviate = 'Deviation : ' + deviation
cv2.putText(img, lane_inf, (10, 63), cv2.FONT_HERSHEY_SIMPLEX, 0.45, (100, 100, 100), 1)
cv2.putText(img, lane_curve, (10, 83), cv2.FONT_HERSHEY_SIMPLEX, 0.45, (100, 100, 100), 1)
cv2.putText(img, deviate, (10, 103), cv2.FONT_HERSHEY_SIMPLEX, 0.45, (100, 100, 100), 1)
return img
def print_road_map(image, left_line, right_line):
""" print simple road map """
img = cv2.imread('images/top_view_car.png', -1)
img = cv2.resize(img, (120, 246))
rows, cols = image.shape[:2]
window_img = np.zeros_like(image)
window_margin = left_line.window_margin
left_plotx, right_plotx = left_line.allx, right_line.allx
ploty = left_line.ally
lane_width = right_line.startx - left_line.startx
lane_center = (right_line.startx + left_line.startx) / 2
lane_offset = cols / 2 - (2*left_line.startx + lane_width) / 2
car_offset = int(lane_center - 360)
# Generate a polygon to illustrate the search window area
# And recast the x and y points into usable format for cv2.fillPoly()
left_pts_l = np.array([np.transpose(np.vstack([right_plotx - lane_width + lane_offset - window_margin / 4, ploty]))])
left_pts_r = np.array([np.flipud(np.transpose(np.vstack([right_plotx - lane_width + lane_offset + window_margin / 4, ploty])))])
left_pts = np.hstack((left_pts_l, left_pts_r))
right_pts_l = np.array([np.transpose(np.vstack([right_plotx + lane_offset - window_margin / 4, ploty]))])
right_pts_r = np.array([np.flipud(np.transpose(np.vstack([right_plotx + lane_offset + window_margin / 4, ploty])))])
right_pts = np.hstack((right_pts_l, right_pts_r))
# Draw the lane onto the warped blank image
cv2.fillPoly(window_img, np.int_([left_pts]), (140, 0, 170))
cv2.fillPoly(window_img, np.int_([right_pts]), (140, 0, 170))
# Recast the x and y points into usable format for cv2.fillPoly()
pts_left = np.array([np.transpose(np.vstack([right_plotx - lane_width + lane_offset + window_margin / 4, ploty]))])
pts_right = np.array([np.flipud(np.transpose(np.vstack([right_plotx + lane_offset - window_margin / 4, ploty])))])
pts = np.hstack((pts_left, pts_right))
# Draw the lane onto the warped blank image
cv2.fillPoly(window_img, np.int_([pts]), (0, 160, 0))
#window_img[10:133,300:360] = img
road_map = Image.new('RGBA', image.shape[:2], (0, 0, 0, 0))
window_img = Image.fromarray(window_img)
img = Image.fromarray(img)
road_map.paste(window_img, (0, 0))
road_map.paste(img, (300-car_offset, 590), mask=img)
road_map = np.array(road_map)
road_map = cv2.resize(road_map, (95, 95))
road_map = cv2.cvtColor(road_map, cv2.COLOR_BGRA2BGR)
return road_map