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improve detection, do more checking for the screws

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This commit is contained in:
Cole Deck 2019-12-06 11:50:38 -06:00
parent d41d79cdc5
commit 9b1c8e46cb
1 changed files with 25 additions and 33 deletions
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58
main.py
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@ -1,5 +1,5 @@
# import the necessary packages # import the necessary packages
from imutils import perspective #from imutils import perspective
from imutils import contours from imutils import contours
import numpy as np import numpy as np
import argparse import argparse
@ -17,7 +17,7 @@ def midpoint(ptA, ptB):
def sizeVexScrew(iteml): def sizeVexScrew(iteml):
# Screw Sizing code # Screw Sizing code
# subtract screw head size to find thread length # subtract screw head size to find thread length
shead = 0.09 shead = 0.1
iteml -= shead iteml -= shead
#print("Thread Length: " + str(iteml)) #print("Thread Length: " + str(iteml))
iteml *= 8 iteml *= 8
@ -27,11 +27,9 @@ def sizeVexScrew(iteml):
def sizeStandoff(iteml): def sizeStandoff(iteml):
# Standoff Sizing code # Standoff Sizing code
iteml *= 2
#print("Thread Length: " + str(iteml))
iteml *= 4
iteml = round(iteml) iteml = round(iteml)
iteml /= 4 iteml /= 2
return iteml return iteml
@ -64,7 +62,9 @@ if type(args["number"]) == type(selected):
# load the image, convert it to grayscale, and blur it slightly # load the image, convert it to grayscale, and blur it slightly
image = cv2.imread(args["image"]) image = cv2.imread(args["image"])
image = cv2.resize(image, (int(image.shape[1]*0.2), int(image.shape[0]*0.2)), interpolation = cv2.INTER_NEAREST) #image = cv2.resize(image, (int(image.shape[1]*0.2), int(image.shape[0]*0.2)), interpolation = cv2.INTER_NEAREST)
image = cv2.resize(image, (1000, int(image.shape[0]/image.shape[1] * 1000)), interpolation = cv2.INTER_NEAREST)
if args2.show: if args2.show:
cv2.imshow("Item Sorter", image) cv2.imshow("Item Sorter", image)
cv2.waitKey(0) cv2.waitKey(0)
@ -109,7 +109,7 @@ for c in cnts:
box = cv2.minAreaRect(c) box = cv2.minAreaRect(c)
box = cv2.cv.BoxPoints(box) if imutils.is_cv2() else cv2.boxPoints(box) box = cv2.cv.BoxPoints(box) if imutils.is_cv2() else cv2.boxPoints(box)
box = np.array(box, dtype="int") box = np.array(box, dtype="int")
box = perspective.order_points(box) #box = perspective.order_points(box)
(tl, tr, br, bl) = box (tl, tr, br, bl) = box
(tltrX, tltrY) = midpoint(tl, tr) (tltrX, tltrY) = midpoint(tl, tr)
(blbrX, blbrY) = midpoint(bl, br) (blbrX, blbrY) = midpoint(bl, br)
@ -134,27 +134,14 @@ for c in cnts:
if pixelsPerMetric is None and circular is True: if pixelsPerMetric is None and circular is True:
pixelsPerMetric = smaller(dA, dB) / args["width"] pixelsPerMetric = smaller(dA, dB) / args["width"]
#cv2.imshow("Screw Length Detection", orig)
#cv2.waitKey(0)
# order the points in the contour such that they appear
# in top-left, top-right, bottom-right, and bottom-left
# order, then draw the outline of the rotated bounding
# box
#cv2.drawContours(orig, [box.astype("int")], -1, (0, 255, 0), 2)
# if the pixels per metric has not been initialized, then
# compute it as the ratio of pixels to supplied metric
# (in this case, inches)
# compute the size of the object
orig = image.copy() orig = image.copy()
# loop over the contours individually # loop over the contours individually
for c in cnts: for c in cnts:
num += 1 num += 1
# if the contour is not sufficiently large, ignore it # if the contour is not sufficiently large, ignore it
if cv2.contourArea(c) < 100: if cv2.contourArea(c) < 100 or pixelsPerMetric is None:
continue continue
# compute the rotated bounding box of the contour # compute the rotated bounding box of the contour
@ -167,7 +154,7 @@ for c in cnts:
# in top-left, top-right, bottom-right, and bottom-left # in top-left, top-right, bottom-right, and bottom-left
# order, then draw the outline of the rotated bounding # order, then draw the outline of the rotated bounding
# box # box
box = perspective.order_points(box) #box = perspective.order_points(box)
# loop over the original points and draw them # loop over the original points and draw them
#for (x, y) in box: #for (x, y) in box:
@ -196,12 +183,7 @@ for c in cnts:
dA = np.linalg.norm(np.array((tltrX, tltrY, 0)) - np.array((blbrX, blbrY, 0))) dA = np.linalg.norm(np.array((tltrX, tltrY, 0)) - np.array((blbrX, blbrY, 0)))
dB = np.linalg.norm(np.array((tlblX, tlblY, 0)) - np.array((trbrX, trbrY, 0))) dB = np.linalg.norm(np.array((tlblX, tlblY, 0)) - np.array((trbrX, trbrY, 0)))
# if the pixels per metric has not been initialized, then
# compute it as the ratio of pixels to supplied metric
# (in this case, inches)
#if pixelsPerMetric is None:
# pixelsPerMetric = dB / args["width"]
# compute the size of the object
dimA = dA / pixelsPerMetric dimA = dA / pixelsPerMetric
dimB = dB / pixelsPerMetric dimB = dB / pixelsPerMetric
@ -238,11 +220,19 @@ for c in cnts:
objtype = "Penny" objtype = "Penny"
iteml = 0 iteml = 0
else: else:
epsilon = 4#0.05*cv2.arcLength(c,True) epsilon = 3#0.02*cv2.arcLength(c,True)
#print(str(epsilon)) #print(str(epsilon))
approx = cv2.approxPolyDP(c,epsilon,True) approx = cv2.approxPolyDP(c,epsilon,True)
hull = cv2.convexHull(approx, returnPoints=False)
hull2 = cv2.convexHull(c)
defects = cv2.convexityDefects(c,hull)
#print(str(defects.size) + " match")
cv2.drawContours(orig, (approx.astype("int")), -1, (255, 0, 0), 8) cv2.drawContours(orig, (approx.astype("int")), -1, (255, 0, 0), 8)
if not cv2.isContourConvex(approx): convexness = area_contour / cv2.contourArea(hull2)
#print(str(convexness) + " % fill")
#if not cv2.isContourConvex(approx):
#if cv2.matchShapes(hull, c, 1, 0.0) > 1:
if defects.size > 5 and (convexness < 0.9 or boxiness < 0.75):
objtype = "Screw" objtype = "Screw"
iteml = larger(dimA, dimB) iteml = larger(dimA, dimB)
#print("Screw Length (RAW): " + str(iteml)) #print("Screw Length (RAW): " + str(iteml))
@ -251,10 +241,12 @@ for c in cnts:
else: else:
if itemhr == 0.3125: if itemhr == 0.3125:
objtype = "Standoff" objtype = "Standoff"
iteml = sizeStandoff(radius * 2 / pixelsPerMetric) iteml = sizeStandoff(itemw)
if itemhr == 0.1875: if itemhr == 0.1875:
objtype = "Axle" objtype = "Axle"
iteml = radius * 2 / pixelsPerMetric iteml = (radius * 2 / pixelsPerMetric + itemw) / 2
print(str(iteml)) print(str(iteml))
# draw the object sizes on the image # draw the object sizes on the image