http://scikit-learn.org/stable/modules/feature_extraction.html
带病在网吧里。
。。。。。
写。求支持。
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1、首先澄清两个概念:特征提取和特征选择(
Feature extraction is very different from Feature
selection
)。
the former consists in transforming arbitrary data, such as text or images, into numerical
features usable for machine learning. The latter is a machine learning technique applied on these features(从已经提取的特征中选择更好的特征).
以下分为四大部分来讲。主要还是4、text feature extraction
2、loading features form dicts
class DictVectorizer。举个样例就好:
>>> measurements = [
... {'city': 'Dubai', 'temperature': 33.},
... {'city': 'London', 'temperature': 12.},
... {'city': 'San Fransisco', 'temperature': 18.},
... ]
>>> from sklearn.feature_extraction import DictVectorizer
>>> vec = DictVectorizer()
>>> vec.fit_transform(measurements).toarray()
array([[ 1., 0., 0., 33.],
[ 0., 1., 0., 12.],
[ 0., 0., 1., 18.]])
>>> vec.get_feature_names()
['city=Dubai', 'city=London', 'city=San Fransisco', 'temperature']
class DictVectorizer对于提取某个特定词汇附近的feature
windows很实用,比如增加我们通过一个已有的algorithm提取了word ‘sat’ 在句子‘The cat sat on the mat.’中的PoS(Part
of Speech)特征。例如以下:
>>> pos_window = [
... {
... 'word-2': 'the',
... 'pos-2': 'DT',
... 'word-1': 'cat',
... 'pos-1': 'NN',
... 'word+1': 'on',
... 'pos+1': 'PP',
... },
... # in a real application one would extract many such dictionaries
... ]
上面的PoS特征就能够vectorized into a sparse two-dimensional matrix suitable for feeding into a classifier (maybe after being piped into a text.TfidfTransformer for
normalization):
>>>
>>> vec = DictVectorizer()
>>> pos_vectorized = vec.fit_transform(pos_window)
>>> pos_vectorized
<1x6 sparse matrix of type '<... 'numpy.float64'>'
with 6 stored elements in Compressed Sparse ... format>
>>> pos_vectorized.toarray()
array([[ 1., 1., 1., 1., 1., 1.]])
>>> vec.get_feature_names()
['pos+1=PP', 'pos-1=NN', 'pos-2=DT', 'word+1=on', 'word-1=cat', 'word-2=the']
3、feature hashing
The class FeatureHasher is
a high-speed, low-memory vectorizer that uses a technique known as feature
hashing, or the “hashing trick”.
因为hash。所以仅仅保存feature的interger index。而不保存原来feature的string名字。所以没有inverse_transform方法。
FeatureHasher 接收dict对,即 (feature, value) 对,或者strings,由构造函数的參数input_type决定.结果是scipy.sparse matrix。假设是strings,则value默认取1,比如 ['feat1', 'feat2', 'feat2'] 被解释为[('feat1', 1), ('feat2', 2)].
4、text feature extraction
由于内容太多,分开写了。參考着篇博客:http://blog.csdn.net/mmc2015/article/details/46997379
5、image feature extraction
提取部分图片(Patch extraction):
The extract_patches_2d function从图片中提取小块,存储成two-dimensional
array, or three-dimensional with color information along the third axis. 使用reconstruct_from_patches_2d.
可以将全部的小块重构成原图:
>>> import numpy as np
>>> from sklearn.feature_extraction import image
>>> one_image = np.arange(4 * 4 * 3).reshape((4, 4, 3))
>>> one_image[:, :, 0] # R channel of a fake RGB picture
array([[ 0, 3, 6, 9],
[12, 15, 18, 21],
[24, 27, 30, 33],
[36, 39, 42, 45]])
>>> patches = image.extract_patches_2d(one_image, (2, 2), max_patches=2,
... random_state=0)
>>> patches.shape
(2, 2, 2, 3)
>>> patches[:, :, :, 0]
array([[[ 0, 3],
[12, 15]],
[[15, 18],
[27, 30]]])
>>> patches = image.extract_patches_2d(one_image, (2, 2))
>>> patches.shape
(9, 2, 2, 3)
>>> patches[4, :, :, 0]
array([[15, 18],
[27, 30]])
重构方式例如以下:
>>> reconstructed = image.reconstruct_from_patches_2d(patches, (4, 4, 3))
>>> np.testing.assert_array_equal(one_image, reconstructed)
The PatchExtractor class和 extract_patches_2d,一样,仅仅只是能够同一时候接受多个图片作为输入:
>>> five_images = np.arange(5 * 4 * 4 * 3).reshape(5, 4, 4, 3)
>>> patches = image.PatchExtractor((2, 2)).transform(five_images)
>>> patches.shape
(45, 2, 2, 3)
图片像素的连接(Connectivity graph of an image):
主要是依据像素的区别来推断图片的每两个像素点是否连接。
。。
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The function img_to_graph returns
such a matrix from a 2D or 3D image. Similarly, grid_to_graph build
a connectivity matrix for images given the shape of these image.
这有个直观的样例:http://scikit-learn.org/stable/auto_examples/cluster/plot_lena_ward_segmentation.html#example-cluster-plot-lena-ward-segmentation-py
头疼。。。。
碎觉。
。。