DaSE-Computer-Vision-2021
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150 řádky
5.1 KiB

from __future__ import print_function
from builtins import zip
from builtins import range
from past.builtins import xrange
import matplotlib
import numpy as np
from scipy.ndimage import uniform_filter
def extract_features(imgs, feature_fns, verbose=False):
"""
Given pixel data for images and several feature functions that can operate on
single images, apply all feature functions to all images, concatenating the
feature vectors for each image and storing the features for all images in
a single matrix.
Inputs:
- imgs: N x H X W X C array of pixel data for N images.
- feature_fns: List of k feature functions. The ith feature function should
take as input an H x W x D array and return a (one-dimensional) array of
length F_i.
- verbose: Boolean; if true, print progress.
Returns:
An array of shape (N, F_1 + ... + F_k) where each column is the concatenation
of all features for a single image.
"""
num_images = imgs.shape[0]
if num_images == 0:
return np.array([])
# Use the first image to determine feature dimensions
feature_dims = []
first_image_features = []
for feature_fn in feature_fns:
feats = feature_fn(imgs[0].squeeze())
assert len(feats.shape) == 1, 'Feature functions must be one-dimensional'
feature_dims.append(feats.size)
first_image_features.append(feats)
# Now that we know the dimensions of the features, we can allocate a single
# big array to store all features as columns.
total_feature_dim = sum(feature_dims)
imgs_features = np.zeros((num_images, total_feature_dim))
imgs_features[0] = np.hstack(first_image_features).T
# Extract features for the rest of the images.
for i in range(1, num_images):
idx = 0
for feature_fn, feature_dim in zip(feature_fns, feature_dims):
next_idx = idx + feature_dim
imgs_features[i, idx:next_idx] = feature_fn(imgs[i].squeeze())
idx = next_idx
if verbose and i % 1000 == 999:
print('Done extracting features for %d / %d images' % (i+1, num_images))
return imgs_features
def rgb2gray(rgb):
"""Convert RGB image to grayscale
Parameters:
rgb : RGB image
Returns:
gray : grayscale image
"""
return np.dot(rgb[...,:3], [0.299, 0.587, 0.144])
def hog_feature(im):
"""Compute Histogram of Gradient (HOG) feature for an image
Modified from skimage.feature.hog
http://pydoc.net/Python/scikits-image/0.4.2/skimage.feature.hog
Reference:
Histograms of Oriented Gradients for Human Detection
Navneet Dalal and Bill Triggs, CVPR 2005
Parameters:
im : an input grayscale or rgb image
Returns:
feat: Histogram of Gradient (HOG) feature
"""
# convert rgb to grayscale if needed
if im.ndim == 3:
image = rgb2gray(im)
else:
image = np.at_least_2d(im)
sx, sy = image.shape # image size
orientations = 9 # number of gradient bins
cx, cy = (8, 8) # pixels per cell
gx = np.zeros(image.shape)
gy = np.zeros(image.shape)
gx[:, :-1] = np.diff(image, n=1, axis=1) # compute gradient on x-direction
gy[:-1, :] = np.diff(image, n=1, axis=0) # compute gradient on y-direction
grad_mag = np.sqrt(gx ** 2 + gy ** 2) # gradient magnitude
grad_ori = np.arctan2(gy, (gx + 1e-15)) * (180 / np.pi) + 90 # gradient orientation
n_cellsx = int(np.floor(sx / cx)) # number of cells in x
n_cellsy = int(np.floor(sy / cy)) # number of cells in y
# compute orientations integral images
orientation_histogram = np.zeros((n_cellsx, n_cellsy, orientations))
for i in range(orientations):
# create new integral image for this orientation
# isolate orientations in this range
temp_ori = np.where(grad_ori < 180 / orientations * (i + 1),
grad_ori, 0)
temp_ori = np.where(grad_ori >= 180 / orientations * i,
temp_ori, 0)
# select magnitudes for those orientations
cond2 = temp_ori > 0
temp_mag = np.where(cond2, grad_mag, 0)
orientation_histogram[:,:,i] = uniform_filter(temp_mag, size=(cx, cy))[round(cx/2)::cx, round(cy/2)::cy].T
return orientation_histogram.ravel()
def color_histogram_hsv(im, nbin=10, xmin=0, xmax=255, normalized=True):
"""
Compute color histogram for an image using hue.
Inputs:
- im: H x W x C array of pixel data for an RGB image.
- nbin: Number of histogram bins. (default: 10)
- xmin: Minimum pixel value (default: 0)
- xmax: Maximum pixel value (default: 255)
- normalized: Whether to normalize the histogram (default: True)
Returns:
1D vector of length nbin giving the color histogram over the hue of the
input image.
"""
ndim = im.ndim
bins = np.linspace(xmin, xmax, nbin+1)
hsv = matplotlib.colors.rgb_to_hsv(im/xmax) * xmax
imhist, bin_edges = np.histogram(hsv[:,:,0], bins=bins, density=normalized)
imhist = imhist * np.diff(bin_edges)
# return histogram
return imhist