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high_pass_filter.py
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high_pass_filter.py
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#####################################################################
# Example : perform high pass filterings in fourier space of image frame
# from a video file specified on the command line (e.g. python FILE.py
# video_file) or from an attached web camera
# Author : Toby Breckon, [email protected]
# Copyright (c) 2015 School of Engineering & Computing Science,
# Copyright (c) 2019 Dept Computer Science,
# Durham University, UK
# License : LGPL - http://www.gnu.org/licenses/lgpl.html
#####################################################################
import cv2
import argparse
import sys
import numpy as np
import math
#####################################################################
# ignore divide by zero errors in np.log() operations
np.seterr(divide='ignore')
#####################################################################
keep_processing = True
# parse command line arguments for camera ID or video file
parser = argparse.ArgumentParser(
description='Perform ' +
sys.argv[0] +
' example operation on incoming camera/video image')
parser.add_argument(
"-c",
"--camera_to_use",
type=int,
help="specify camera to use",
default=0)
parser.add_argument(
"-r",
"--rescale",
type=float,
help="rescale image by this factor",
default=1.0)
parser.add_argument(
'video_file',
metavar='video_file',
type=str,
nargs='?',
help='specify optional video file')
args = parser.parse_args()
#####################################################################
# create a simple high pass filter
def create_high_pass_filter(width, height, radius):
hp_filter = np.ones((height, width, 2), np.float32)
cv2.circle(hp_filter, (int(width / 2), int(height / 2)),
radius, (0, 0, 0), thickness=-1)
return hp_filter
#####################################################################
# this function is called as a call-back everytime the trackbar is moved
# (here we just do nothing)
def nothing(x):
pass
#####################################################################
# define video capture object
try:
# to use a non-buffered camera stream (via a separate thread)
if not (args.video_file):
import camera_stream
cap = camera_stream.CameraVideoStream(use_tapi=False)
else:
cap = cv2.VideoCapture() # not needed for video files
except BaseException:
# if not then just use OpenCV default
print("INFO: camera_stream class not found - camera input may be buffered")
cap = cv2.VideoCapture()
# define display window name
window_name = "Live Camera Input" # window name
window_name2 = "Fourier Magnitude Spectrum" # window name
window_name3 = "Filtered Image" # window name
# if command line arguments are provided try to read video_file
# otherwise default to capture from attached H/W camera
if (((args.video_file) and (cap.open(str(args.video_file))))
or (cap.open(args.camera_to_use))):
# create windows by name (as resizable)
cv2.namedWindow(window_name, cv2.WINDOW_NORMAL)
cv2.namedWindow(window_name2, cv2.WINDOW_NORMAL)
cv2.namedWindow(window_name3, cv2.WINDOW_NORMAL)
# add some track bar controllers for settings
radius = 25
cv2.createTrackbar("radius", window_name2, radius, 200, nothing)
# if video file or camera successfully open then read frame from video
if (cap.isOpened):
ret, frame = cap.read()
# rescale if specified
if (args.rescale != 1.0):
frame = cv2.resize(frame, (0, 0), fx=args.rescale, fy=args.rescale)
# convert to grayscale
gray_frame = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
# use this single frame to set up optimized DFT settings
hieght, width = gray_frame.shape
nheight = cv2.getOptimalDFTSize(hieght)
nwidth = cv2.getOptimalDFTSize(width)
while (keep_processing):
# if video file or camera successfully open then read frame from video
if (cap.isOpened):
ret, frame = cap.read()
# when we reach the end of the video (file) exit cleanly
if (ret == 0):
keep_processing = False
continue
# rescale if specified
if (args.rescale != 1.0):
frame = cv2.resize(
frame, (0, 0), fx=args.rescale, fy=args.rescale)
# start a timer (to see how long processing and display takes)
start_t = cv2.getTickCount()
# convert to grayscale
gray_frame = cv2.cvtColor(frame, cv2.COLOR_BGR2GRAY)
# Performance of DFT calculation, via the FFT, is better for array
# sizes of power of two. Arrays whose size is a product of
# 2's, 3's, and 5's are also processed quite efficiently.
# Hence we modify the size of the array to the optimal size (by padding
# zeros) before finding DFT.
pad_right = nwidth - width
pad_bottom = nheight - hieght
nframe = cv2.copyMakeBorder(
gray_frame,
0,
pad_bottom,
0,
pad_right,
cv2.BORDER_CONSTANT,
value=0)
# perform the DFT and get complex output
dft = cv2.dft(np.float32(nframe), flags=cv2.DFT_COMPLEX_OUTPUT)
# shift it so that we the zero-frequency, F(0,0), DC component to the
# center of the spectrum.
dft_shifted = np.fft.fftshift(dft)
# perform high pass filtering
radius = cv2.getTrackbarPos("radius", window_name2)
hp_filter = create_high_pass_filter(nwidth, nheight, radius)
dft_filtered = cv2.mulSpectrums(dft_shifted, hp_filter, flags=0)
# shift it back to original quaderant ordering
dft = np.fft.fftshift(dft_filtered)
# recover the original image via the inverse DFT
filtered_img = cv2.dft(dft, flags=cv2.DFT_INVERSE)
# normalized the filtered image into 0 -> 255 (8-bit grayscale) so we
# can see the output
min_val, max_val, min_loc, max_loc = \
cv2.minMaxLoc(filtered_img[:, :, 0])
filtered_img_normalized = filtered_img[:, :, 0] * (
1.0 / (max_val - min_val)) + ((-min_val) / (max_val - min_val))
filtered_img_normalized = np.uint8(filtered_img_normalized * 255)
# calculate the magnitude spectrum and log transform + scale it for
# visualization
magnitude_spectrum = np.log(cv2.magnitude(
dft_filtered[:, :, 0], dft_filtered[:, :, 1]))
# create a 8-bit image to put the magnitude spectrum into
magnitude_spectrum_normalized = np.zeros(
(nheight, nwidth, 1), np.uint8)
# normalized the magnitude spectrum into 0 -> 255 (8-bit grayscale) so
# we can see the output
cv2.normalize(
np.uint8(magnitude_spectrum),
magnitude_spectrum_normalized,
alpha=0,
beta=255,
norm_type=cv2.NORM_MINMAX)
# display images
cv2.imshow(window_name, gray_frame)
cv2.imshow(window_name2, magnitude_spectrum_normalized)
cv2.imshow(window_name3, filtered_img_normalized)
# stop timer and convert to ms. (to see how long processing and display
# takes)
stop_t = ((cv2.getTickCount() - start_t) /
cv2.getTickFrequency()) * 1000
# start the event loop - essential
# cv2.waitKey() is a keyboard binding function (argument is the time in
# ms). It waits for specified milliseconds for any keyboard event.
# If you press any key in that time, the program continues.
# If 0 is passed, it waits indefinitely for a key stroke.
# (bitwise and with 0xFF to extract least significant byte of
# multi-byte response)
# here we use a wait time in ms. that takes account of processing time
# already used in the loop
# wait 40ms (i.e. 1000ms / 25 fps = 40 ms)
key = cv2.waitKey(max(2, 40 - int(math.ceil(stop_t)))) & 0xFF
# It can also be set to detect specific key strokes by recording which
# key is pressed
# e.g. if user presses "x" then exit
if (key == ord('x')):
keep_processing = False
# close all windows
cv2.destroyAllWindows()
else:
print("No video file specified or camera connected.")
#####################################################################