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answer_35.py
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answer_35.py
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import cv2
import numpy as np
import matplotlib.pyplot as plt
# DFT hyper-parameters
K, L = 128, 128
channel = 3
# bgr -> gray
def bgr2gray(img):
gray = 0.2126 * img[..., 2] + 0.7152 * img[..., 1] + 0.0722 * img[..., 0]
return gray
# DFT
def dft(img):
# Prepare DFT coefficient
G = np.zeros((L, K, channel), dtype=np.complex)
# prepare processed index corresponding to original image positions
x = np.tile(np.arange(W), (H, 1))
y = np.arange(H).repeat(W).reshape(H, -1)
# dft
for c in range(channel):
for l in range(L):
for k in range(K):
G[l, k, c] = np.sum(img[..., c] * np.exp(-2j * np.pi * (x * k / K + y * l / L))) / np.sqrt(K * L)
#for n in range(N):
# for m in range(M):
# v += gray[n, m] * np.exp(-2j * np.pi * (m * k / M + n * l / N))
#G[l, k] = v / np.sqrt(M * N)
return G
# IDFT
def idft(G):
# prepare out image
H, W, _ = G.shape
out = np.zeros((H, W, channel), dtype=np.float32)
# prepare processed index corresponding to original image positions
x = np.tile(np.arange(W), (H, 1))
y = np.arange(H).repeat(W).reshape(H, -1)
# idft
for c in range(channel):
for l in range(H):
for k in range(W):
out[l, k, c] = np.abs(np.sum(G[..., c] * np.exp(2j * np.pi * (x * k / W + y * l / H)))) / np.sqrt(W * H)
# clipping
out = np.clip(out, 0, 255)
out = out.astype(np.uint8)
return out
# BPF
def bpf(G, ratio1=0.1, ratio2=0.5):
H, W, _ = G.shape
# transfer positions
_G = np.zeros_like(G)
_G[:H//2, :W//2] = G[H//2:, W//2:]
_G[:H//2, W//2:] = G[H//2:, :W//2]
_G[H//2:, :W//2] = G[:H//2, W//2:]
_G[H//2:, W//2:] = G[:H//2, :W//2]
# get distance from center (H / 2, W / 2)
x = np.tile(np.arange(W), (H, 1))
y = np.arange(H).repeat(W).reshape(H, -1)
# make filter
_x = x - W // 2
_y = y - H // 2
r = np.sqrt(_x ** 2 + _y ** 2)
mask = np.ones((H, W), dtype=np.float32)
mask[(r < (W // 2 * ratio1)) | (r > (W // 2 * ratio2))] = 0
mask = np.repeat(mask, channel).reshape(H, W, channel)
# filtering
_G *= mask
# reverse original positions
G[:H//2, :W//2] = _G[H//2:, W//2:]
G[:H//2, W//2:] = _G[H//2:, :W//2]
G[H//2:, :W//2] = _G[:H//2, W//2:]
G[H//2:, W//2:] = _G[:H//2, :W//2]
return G
# Read image
img = cv2.imread("imori.jpg").astype(np.float32)
H, W, C = img.shape
# Gray scale
gray = bgr2gray(img)
# DFT
G = dft(img)
# BPF
G = bpf(G, ratio1=0.1, ratio2=0.5)
# IDFT
out = idft(G)
# Save result
cv2.imshow("result", out)
cv2.waitKey(0)
cv2.imwrite("out.jpg", out)