机器学习::文本特征提取(TF-IDF) - 第二部分

Read the first part of this tutorial:Text feature extraction (tf-idf) – Part I

这个职位是一个延续在哪里,我们开始学习有关文本特征提取和向量空间模型表示的理论和实践的第一部分。我真的建议你阅读第一部分of the post series in order to follow this second post.

由于很多人喜欢这个教程的第一部分,该第二部分是比第一个长一点。

Introduction

In the first post, we learned how to use theterm-frequency以表示在矢量空间的文本信息。然而,与术语频率方法的主要问题是,它大大加快了频繁的条款和规模下降,这比高频方面经验更丰富罕见的条款。基本的直觉是,在许多文件中经常出现的一个术语不太好鉴别,真正有意义的(至少在许多实验测试);这里最重要的问题是:你为什么会在例如分类问题,强调术语,是在你的文档的整个语料库几乎礼物?

在TF-IDF权重来解决这个问题。什么TF-IDF给出的是如何重要的是一个集合中的文档的话,这就是为什么TF-IDF结合本地和全球的参数,因为它考虑到不仅需要隔离的期限,但也文献集内的术语。什么TF-IDF然后做来解决这个问题,是缩小,同时扩大了难得的条件频繁的条款;出现比其他的10倍以上期限不为10倍比它更重要的是,为什么TF-IDF采用对数刻度的做到这一点。

但是,让我们回到我们的定义\mathrm{tf}(t,d)which is actually the term count of the termtin the documentd。使用这种简单的词频可能导致我们一样的问题keyword spamming,这是当我们有一个文档中的术语重复以改善上的IR其排名的目的(信息检索)系统,甚至对创建长文档偏见,使他们看起来比他们只是因为手册中出现的高频更重要。

To overcome this problem, the term frequency\mathrm{tf}(t,d)上的矢量空间中的文件的通常也归一化。让我们来看看我们是如何规范这一载体。

Vector normalization

Suppose we are going to normalize the term-frequency vector\ {VEC V_ {D_4}}that we have calculated in the first part of this tutorial. The documentd4from the first part of this tutorial had this textual representation:

D4:我们可以看到闪亮的阳光,明亮的阳光下。

和使用该文件的非归一化项频向量空间表示为:

\ {VEC V_ {D_4}} =(0,2,1,0)

规范化的向量,是一样的说话g the单位向量矢量,而他们使用的是“帽子”符号表示:\帽子{V}。The definition of the unit vector\帽子{V}一个向量的\vec{v}is:

\的DisplayStyle \帽子{V} = \压裂{\ vec的{V}} {\ | \ vec的{V} \ | _p}

Where the\帽子{V}is the unit vector, or the normalized vector, the\vec{v}在矢量将被归一化和\|\vec{v}\|_p是矢量的范数(大小,长度)\vec{v}in theL ^ p空间(别担心,我将所有的解释)。

The unit vector is actually nothing more than a normalized version of the vector, is a vector which the length is 1.

The normalization process (Source: http://processing.org/learning/pvector/)
The normalization process (Source: http://processing.org/learning/pvector/)

But the important question here is how the length of the vector is calculated and to understand this, you must understand the motivation of theL ^ p空间,也被称为勒贝格空间

勒贝格空间

多久这个载体?(来源:来源:http://processing.org/learning/pvector/)
多久这个载体?(来源:来源:http://processing.org/learning/pvector/)

通常,一个矢量的长度\vec{u} = (u_1, u_2, u_3, \ldots, u_n)使用计算Euclidean norma norm is a function that assigns a strictly positive length or size to all vectors in a vector space- ,其被定义为:

(Source: http://processing.org/learning/pvector/)
(Source: http://processing.org/learning/pvector/)

\|\vec{u}\| = \sqrt{u^2_1 + u^2_2 + u^2_3 + \ldots + u^2_n}

但是,这不是定义长度的唯一途径,这就是为什么你看到(有时)的数p符合规范的符号,就像在了一起\|\vec{u}\|_p。That’s because it could be generalized as:

\displaystyle \|\vec{u}\|_p = ( \left|u_1\right|^p + \left|u_2\right|^p + \left|u_3\right|^p + \ldots + \left|u_n\right|^p )^\frac{1}{p}

并简化为:

\displaystyle \|\vec{u}\|_p = (\sum\limits_{i=1}^{n}\left|\vec{u}_i\right|^p)^\frac{1}{p}

所以,当你阅读有关L2-norm,你正在阅读关于Euclidean norm,具有规范p = 2, the most common norm used to measure the length of a vector, typically called “magnitude”; actually, when you have an unqualified length measure (without thep号),你有L2-norm(Euclidean norm).

When you read about aL1范,你正在阅读关于norm withp=1, defined as:

\的DisplayStyle \ | \ VEC【U} \ | _1 =(\左| U_1 \右| + \左| U_2 \右| + \左| U_3 \右| + \ ldots + \左| u_n \右|)

Which is nothing more than a simple sum of the components of the vector, also known asTaxicab distance,也被称为曼哈顿距离。

Taxicab geometry versus Euclidean distance: In taxicab geometry all three pictured lines have the same length (12) for the same route. In Euclidean geometry, the green line has length6 \times \sqrt{2} \approx 8.48,并且是唯一的最短路径。
Source:Wikipedia :: Taxicab Geometry

请注意,您也可以使用任何规范正常化的载体,但我们将使用最常用的规范,L2范数,这也是在0.9版本的默认scikits.learn。You can also find papers comparing the performance of the two approaches among other methods to normalize the document vector, actually you can use any other method, but you have to be concise, once you’ve used a norm, you have to use it for the whole process directly involving the norm (a unit vector that used a L1-norm isn’t going to have the length 1 if you’re going to take its L2-norm later)。

返回矢量归

现在你知道了矢量正常化进程是什么,我们可以尝试一个具体的例子,使用L2范数的过程(我们现在使用正确的术语),以规范我们的矢量\ {VEC V_ {D_4}} =(0,2,1,0)in order to get its unit vector\ {帽子V_ {D_4}}。为了做到这一点,我们将简单的将其插入单位矢量的定义,对其进行评估:

\帽子{V}= \frac{\vec{v}}{\|\vec{v}\|_p} \\ \\  \hat{v_{d_4}} = \frac{\vec{v_{d_4}}}{||\vec{v_{d_4}}||_2} \\ \\ \\  \hat{v_{d_4}} = \frac{(0,2,1,0)}{\sqrt{0^2 + 2^2 + 1^2 + 0^2}} \\ \\  \hat{v_{d_4}} = \frac{(0,2,1,0)}{\sqrt{5}} \\ \\  \small \hat{v_{d_4}} = (0.0, 0.89442719, 0.4472136, 0.0)

And that is it ! Our normalized vector\ {帽子V_ {D_4}}has now a L2-norm\ | \帽子{V_ {D_4}} \ | _2 = 1.0

Note that here we have normalized our term frequency document vector, but later we’re going to do that after the calculation of the tf-idf.

The term frequency – inverse document frequency (tf-idf) weight

现在你已经了解了矢量归在理论和实践是如何工作的,让我们继续我们的教程。假设你有你的收藏(从教程的第一部分拍摄)在下列文件:

火车文档集:D1:天空是蓝色的。D2:阳光灿烂。测试文档集:D3:在天空,阳光灿烂。D4:我们可以看到闪亮的阳光,明亮的阳光下。

您的文档空间可以那么作为被定义D = \{ d_1, d_2, \ldots, d_n \}哪里n是在你的文集文档的数量,并在我们的情况下,D_ {火车} = \ {D_1,D_2 \}andD_ {测试} = \ {D_3,D_4 \}。The cardinality of our document space is defined by\左| {{D_火车}} \右|= 2and\左| {{D_测试}} \右|= 2,因为我们只有2两个用于训练和测试文档,但他们显然并不需要有相同的基数。

Let’s see now, how idf (inverse document frequency) is then defined:

\displaystyle \mathrm{idf}(t) = \log{\frac{\left|D\right|}{1+\left|\{d : t \in d\}\right|}}

哪里\left|\{d : t \in d\}\right|is thenumber of documents哪里the termt出现,术语频率函数满足当\mathrm{tf}(t,d) \neq 0, we’re only adding 1 into the formula to avoid zero-division.

为TF-IDF式则是:

\ mathrm {TF \ MBOX { - } IDF}(T)= \ mathrm {TF}(T,d)\倍\ mathrm {IDF}(t)的

and this formula has an important consequence: a high weight of the tf-idf calculation is reached when you have a high term frequency (tf) in the given document (local parameter) and a low document frequency of the term in the whole collection (global parameter)。

Now let’s calculate the idf for each feature present in the feature matrix with the term frequency we have calculated in the first tutorial:

M_{train} =  \begin{bmatrix}  0 & 1 & 1 & 1\\  0 & 2 & 1 & 0  \end{bmatrix}

Since we have 4 features, we have to calculate\ mathrm {IDF}(T_1),\ mathrm {IDF}(T_2),\ mathrm {IDF}(t_3处),\mathrm{idf}(t_4):

\ mathrm {IDF}(T_1)= \日志{\压裂{\左| d \右|} {1+ \左| \ {d:T_1 \在d \} \右|}} = \日志{\压裂{2} {1}} = 0.69314718

\ mathrm {IDF}(T_2)= \log{\frac{\left|D\right|}{1+\left|\{d : t_2 \in d\}\right|}} = \log{\frac{2}{3}} = -0.40546511

\ mathrm {IDF}(t_3处)= \日志{\压裂{\左| d \右|} {1+ \左| \ {d:t_3处\在d \} \右|}} = \日志{\压裂{2} {3}} = -0.40546511

\mathrm{idf}(t_4) = \log{\frac{\left|D\right|}{1+\left|\{d : t_4 \in d\}\right|}} = \log{\frac{2}{2}} = 0.0

These idf weights can be represented by a vector as:

\ {VEC {idf_列车}}= (0.69314718, -0.40546511, -0.40546511, 0.0)

现在,我们有我们的词频矩阵(M_{train})和表示我们的矩阵的每个特征的IDF(矢量\ {VEC {idf_列车}}), we can calculate our tf-idf weights. What we have to do is a simple multiplication of each column of the matrixM_{train}with the respective\ {VEC {idf_列车}}vector dimension. To do that, we can create a squarediagonal matrixM_{idf}with both the vertical and horizontal dimensions equal to the vector\ {VEC {idf_列车}}尺寸:

M_{idf} =   \begin{bmatrix}   0.69314718 & 0 & 0 & 0\\   0 & -0.40546511 & 0 & 0\\   0 & 0 & -0.40546511 & 0\\   0 & 0 & 0 & 0   \end{bmatrix}

然后将它乘到术语频率矩阵,因此最终结果然后可以定义为:

M_{tf\mbox{-}idf} = M_{train} \times M_{idf}

Please note that the matrix multiplication isn’t commutative, the result ofA \乘以Bwill be different than the result of the乙\一个时代, and this is why theM_{idf}是对乘法的右侧,以完成每个IDF值到其对应的特征相乘的期望的效果:

\begin{bmatrix}   \mathrm{tf}(t_1, d_1) & \mathrm{tf}(t_2, d_1) & \mathrm{tf}(t_3, d_1) & \mathrm{tf}(t_4, d_1)\\   \mathrm{tf}(t_1, d_2) & \mathrm{tf}(t_2, d_2) & \mathrm{tf}(t_3, d_2) & \mathrm{tf}(t_4, d_2)   \end{bmatrix}   \times   \begin{bmatrix}   \mathrm{idf}(t_1) & 0 & 0 & 0\\   0 & \mathrm{idf}(t_2) & 0 & 0\\   0 & 0 & \mathrm{idf}(t_3) & 0\\   0 & 0 & 0 & \mathrm{idf}(t_4)   \end{bmatrix}   \\ =   \begin{bmatrix}   \mathrm{tf}(t_1, d_1) \times \mathrm{idf}(t_1) & \mathrm{tf}(t_2, d_1) \times \mathrm{idf}(t_2) & \mathrm{tf}(t_3, d_1) \times \mathrm{idf}(t_3) & \mathrm{tf}(t_4, d_1) \times \mathrm{idf}(t_4)\\   \mathrm{tf}(t_1, d_2) \times \mathrm{idf}(t_1) & \mathrm{tf}(t_2, d_2) \times \mathrm{idf}(t_2) & \mathrm{tf}(t_3, d_2) \times \mathrm{idf}(t_3) & \mathrm{tf}(t_4, d_2) \times \mathrm{idf}(t_4)   \end{bmatrix}

现在让我们来看看这个乘法的一个具体的例子:

M_{tf\mbox{-}idf} = M_{train} \times M_{idf} = \\   \begin{bmatrix}   0 & 1 & 1 & 1\\   0 & 2 & 1 & 0   \end{bmatrix}   \times   \begin{bmatrix}   0.69314718 & 0 & 0 & 0\\   0 & -0.40546511 & 0 & 0\\   0 & 0 & -0.40546511 & 0\\   0 & 0 & 0 & 0   \end{bmatrix} \\   =   \begin{bmatrix}   0 & -0.40546511 & -0.40546511 & 0\\   0 & -0.81093022 & -0.40546511 & 0   \end{bmatrix}

And finally, we can apply our L2 normalization process to theM_{tf\mbox{-}idf}矩阵。Please note that this normalization is“row-wise”因为我们要处理矩阵的每一行作为一个分离向量进行归一化,而不是矩阵作为一个整体:

M_ {TF \ MBOX { - } IDF} = \压裂{M_ {TF \ MBOX { - } IDF}} {\ | M_ {TF \ MBOX { - } IDF} \ | _2} = \begin{bmatrix}   0 & -0.70710678 & -0.70710678 & 0\\   0 & -0.89442719 & -0.4472136 & 0   \end{bmatrix}

这就是我们的我们的测试文档集,这实际上是单位向量的集合的漂亮归TF-IDF权重。如果你把矩阵的每一行的L2范数,你会发现它们都具有1的L2范数。

Python的实践

Environment Used:Python的v.2.7.2,NumPy的1.6.1,SciPy的v.0.9.0,Sklearn (Scikits.learn) v.0.9

现在,你在等待的部分!在本节中,我将使用Python的使用,以显示TF-IDF计算的每一步Scikit.learn特征提取模块。

第一步是创建我们的训练和测试文档集和计算词频矩阵:

从sklearn.feature_extraction.text进口CountVectorizer train_set =(“天空是蓝色的。”,“阳光灿烂”。)TEST_SET =(“在天空中的太阳是光明的。”,“我们可以看到闪耀的太阳,。明亮的太阳“)count_vectorizer = CountVectorizer()count_vectorizer.fit_transform(train_set)打印 ”词汇“,count_vectorizer.vocabulary#词汇:{ '蓝':0, '太阳':1, '鲜艳':2 '天空':3} freq_term_matrix = count_vectorizer.transform(TEST_SET)打印freq_term_matrix.todense()#[[0 1 1 1]#[0 2 1 0]]

Now that we have the frequency term matrix (calledfreq_term_matrix),我们可以实例化TfidfTransformer,这将是负责来计算我们的词频矩阵TF-IDF权重:

从进口sklearn.feature_extraction.text TFIDF TfidfTransformer = TfidfTransformer(NORM = “L2”)tfidf.fit(freq_term_matrix)打印 “IDF:”,tfidf.idf_#IDF:[0.69314718 -0.40546511 -0.40546511 0]

请注意,我所指定的标准为L2,这是可选的(实际上默认为L2范数),但我已经添加了参数,使其明确向你表示,它会使用L2范数。还要注意的是,你可以通过访问称为内部属性看IDF计算权重idf_。Now that适合()方法计算矩阵中的IDF上,让我们改造freq_term_matrixto the tf-idf weight matrix:

tf_idf_matrix= tfidf.transform(freq_term_matrix) print tf_idf_matrix.todense() # [[ 0. -0.70710678 -0.70710678 0. ] # [ 0. -0.89442719 -0.4472136 0. ]]

And that is it, thetf_idf_matrix其实我们以前M_{tf\mbox{-}idf}矩阵。您可以通过使用达到相同的效果矢量器Scikit的类。学习是一个vectorizer that automatically combines theCountVectorizerTfidfTransformer给你。看到这个例子要知道如何使用它的文本分类过程。

I really hope you liked the post, I tried to make it simple as possible even for people without the required mathematical background of linear algebra, etc. In the next Machine Learning post I’m expecting to show how you can use the tf-idf to calculate the cosine similarity.

如果你喜欢,随时提出意见和建议,修改等。

Cite this article as: Christian S. Perone, "Machine Learning :: Text feature extraction (tf-idf) – Part II," inTerra Incognita,03/10/2011,//www.cpetem.com/2011/10/machine-learning-text-feature-extraction-tf-idf-part-ii/

References

理解逆文档频率:对IDF理论论证

维基百科:: TF-IDF

The classic Vector Space Model

Sklearn text feature extraction code

Updates

13 Mar 2015格式化,固定图像的问题。
03 Oct 2011添加了有关使用Python示例环境信息

103 thoughts to “Machine Learning :: Text feature extraction (tf-idf) – Part II”

  1. Wow!
    完美的前奏在TF-IDF,非常感谢你!亚洲金博宝亚洲金博宝很有意思,我想学这个领域很长一段时间,你的职位是一个真正的礼物。这将是非常有趣的阅读更多亚洲金博宝关于该技术的使用情况。而且可能是你有兴趣,请,摆脱对文本语料库表示的其他方法的一些光,如果他们存在?
    (对不起,糟糕的英语,我努力改善它,but there is still a lot of job to do)

  2. 出色的工作基督徒!我期待着阅读的文档分类你的下一个职位,聚类和主题提取朴素贝叶斯,随机梯度下降,Minibatch-K均值和非负矩阵分解

    而且,scikit学习的文档上的文本特征提取部分(我是罪魁祸首?)真的很差。如果你想给一个手并改善目前的状况,不要犹豫,加入邮件列表。

    1. 十分感谢奥利弗。我真的想帮助sklearn,我只是得到一些更多的时间来做到这一点,你们都做了伟大的工作,我真的在lib中已经实现的算法量折服,保持良好的工作!

  3. 我喜欢这个教程的新概念我在这里学习水平较好。
    That said, which version of scikits-learn are you using?.
    最新通过的easy_install安装似乎有不同的模块层次结构(即没有找到sklearn feature_extraction)。如果你能提到你使用的版本,我只是尝试用这些例子。

    1. 您好阿南德,我很高兴你喜欢它。我已经增加了大约只用一节“的Python惯例”之前,我使用的是scikits.learn 0.9(发布在几个星期前)环境的信息。

  4. 哪里是第3部分?我必须提交在4天内向量空间模型的分配。把它在周末的希望吗?

  5. 由于基督徒!与s亚洲金博宝klearn向量空间很不错的工作。我只有一个问题,假设我已经计算了“tf_idf_matrix”,我想计算成对余弦相似性(每行之间)。我是有问题的稀疏矩阵格式,你可以请给出这样的例子?也是我的基质是相当大的,由60K说25K。非常感谢!

  6. Great post… I understand what tf-idf and how to implement it with a concrete example. But I caught 2 things that I’m not sure about:
    1-你调用2维矩阵M_train,但它具有D3和D4文件的TF值,所以你应该已经给那矩阵M_test而不是M_train。由于D3和D4是我们的测试文档。
    2 - 当你计算IDF值的T2(这是“太阳”),它应该是日志(2/4)。因为文件的数目是2 D3有词“太阳” 1次,D4有它的2倍。这使得3,但是我们也加1到值摆脱0分的问题。这使得4 ...我说得对不对还是我失去了一些东西?
    Thank you.

    1. 你是正确的:这些都是优秀的博客文章,但作者真的有责任/责任回去和纠正错误,这样的(和其他人,例如,第1部分; ...):缺席训练下划线;设置STOP_WORDS参数;还我的电脑上,词汇索引是不同的。

      正如我们赞赏的努力(荣誉的作者!),它也是一个显著伤害那些谁斗争过去在原有材料的(未修正)的错误。

      1. 回复:我“你是正确的注释”(上),我应该补充:

        “......还注意到康斯登Passot的评论(下同)关于分母:

        ‘… what we are using is really the number of documents in which a term occurs, regardless of the number of times the term occurs in any given document. In this case, then, the denominator in the idf value for t2 (‘sun’) is indeed 2+1 (2 documents have the term ‘sun’, +1 to avoid a potential zero division error).’ “

    2. 哈立德,
      This is a response to a very old question. However, I still want to respond to communicate what I understand from the article.
      Your question 2: “When you calculate the idf value for the t2 (which is ‘sun’) it should be log(2/4)”
      我的理解:在数项的分母应该是(一些文件,其中术语出现+ 1),而不是长期的频率。术语“太阳”出现的文件的数目是2(1次在D3和D4中的2倍 - 完全出现3次在两个文件3是频率和2是文件号)。因此,分母为2 + 1 = 3。

  7. 优秀的帖子!
    I have some question. From the last tf-idf weight matrix, how can we get the importance of term respectively(e.g. which is the most important term?). How can we use this matrix to classify documents

  8. Thank You So Much. You explained it in such a simple way. It was really useful. Once again thanks a lot.

  9. I have same doubt as Jack(last comment). From the last tf-idf weight matrix, how can we get the importance of term respectively(e.g. which is the most important term?). How can we use this matrix to classify documents.

  10. I have a question..
    After the tf-idf operation, we get a numpy array with values. Suppose we need to get the highest 50 values from the array. How can we do that?

    1. F(IDF)的高值,表示特定载体(或文件)具有较高的局部强度和低全球实力,在这种情况下,你可以假设,在它的条款具有很高的重要性本地和不能忽视的。针对funtion(TF),其中只有长期重复大量的时间给予更多重视的那些,其中大部分时间是不正确的建模技术比较。

  11. Hey ,
    感谢名单FR d code..was的确非亚洲金博宝常有帮助!

    1.适用于文档聚类,计算反相的术语频率之后,shud我使用任何关联性系数等Jaccards系数,然后应用聚类算法中像k均值或shud我计算反转术语频率后直接适用d k均值到文档向量?

    2. How do u rate inverted term frequency for calcuating document vectors for document clustering ?

    由于一吨FR第四到来的答复!

  12. @Khalid:你在1-指出什么让我困惑过了一分钟(M_train VS M_test)。我想你误会了你的第二点,不过,因为我们用的是什么是真正发生的一个术语,无论任何给定的文档中出现的术语次数的文件数量。在这种情况下,那么,在为T2(“太阳”)的IDF值分母确实2 + 1(2个文件具有的术语“太阳”,1以避免潜在的零分割误差)。

    我喜欢阅读本系列的第三批呢!我特别想了解更多有关特征选择。是否有一个惯用的方式来获得最高的分数TF.IDF条款的排序列表?你将如何确定这些方面的整体?你将如何得到这是最负责高或低的余弦相似度(逐行)的条款?

    Thank you for the _great_ posts!

  13. Excellent article and a great introduction to td-idf normalization.

    You have a very clear and structured way of explaining these difficult concepts.

    谢谢!

      1. very good & infomative tutorial…. please upload more tutorials related to documents clustering process.

  14. 您可以为使用TFIDF所以我们有TFIDF的矩阵,我们怎么可以用它来计算余弦做余弦相似度任何引用。感谢神奇的物品。

  15. 请纠正我,如果我拨错
    从“频率后的公式calculated in the first tutorial:” should Mtest not Mtrain. also after starting ‘These idf weights can be represented by a vector as:” should be idf_test not idf_train.

    顺便说一句伟大的系列赛,你可以给如何实施分类的简单的方法?

  16. 亚洲金博宝很不错的职位。恭喜!!

    Showing your results, I have a question:

    I read in the wikipedia:
    The tf-idf value increases proportionally to the number of times a word appears in the document, but is offset by the frequency of the word in the corpus, which helps to control for the fact that some words are generally more common than others.

    当我看到它,我明白,如果一个字中的所有文档apperars就是一个字只出现在一个文档中不太重要的:

    However, in the results, the word “sun” or “bright” are most important than “sky”.

    I’m not sure of understand it completly.

  17. Terrific! I was familiar with tf-idf before but I found your scikits examples helpful as I’m trying to learn that package.

  18. 优秀的帖子!一次偶然的机会找上CountVectorizer更多信息,无意中发现了这一点,但我很高兴我通过两个您的文章(第1部分和第2部分)的读取。

    Bookmarking your blog now

  19. Does not seem to fit_transform() as you describe..
    Any idea why ?
    >>> ts
    (“天空是蓝色的”,“阳光灿烂”)
    >>> v7 = CountVectorizer()
    >>> v7.fit_transform(ts)
    <2×2 sparse matrix of type '’
    用4个存储元件在坐标格式>
    >>> print v7.vocabulary_
    {u’is’: 0, u’the’: 1}

    1. 其实,还有第一个Python样本中的两个小错误。
      1. CountVectorizer应该被实例化,如下所示:
      count_vectorizer = CountVectorizer(stop_words='english')
      这将确保“是”,“的”等被删除。

      2.要打印的词汇,你必须在末尾添加下划线。
      print "Vocabulary:", count_vectorizer.vocabulary_

      优秀的教程,只是小事情。hoep它可以帮助别人。

      1. 谢谢ash. although the article was rather self explanatory, your comment made the entire difference.

  20. 谢谢for the great explanation.

    我有一个关于IDF(T#)的计算问题。
    在第一种情况下,你写的IDF(T1)=日志(2/1),因为我们没有我们收集此类条款,因此,我们添加1分母。现在,在T2的情况下,你写的日志(2/3),所以分母等于3,而不是4(= 1 + 2 + 1)?万一t3时,你写:日志(2/3),从而分母等于3(= 1 + 1 + 1)。我在这里看到的那种不一致性。你能不能,请解释一下,你是怎么计算的分母值。

    谢谢。

    1. You got it wrong, in the denominator you don’t put the sum of the term in each document, you just sum all the documents that have at least one aparition of the term.

  21. 这是很好的,如果你能提供的方式来知道如何使用FT-IDF中的文档分类。我看到示例(Python代码),但如果有算法是最好的,因为没有所有的人都能理解这种语言。

    谢谢

  22. Nice. An explanation helps put things into perspective. Is tf-idf a good way to do clustering (e.g. use Jaccard analysis or variance against the average set from a known corpus)?

    继续写:)

  23. Hi Christian,

    这让我非常兴奋和幸运,读亚洲金博宝这篇文章。你理解的清晰反映了文件的清晰度。这让我重拾我的信心在机器学习领域。

    由于一吨为美丽的解释。

    想从你更多。

    谢谢,

  24. Thank you for the good wrap up. You mention a number of papers which compare L1 and L2 norm, I plan to study that a bit more in depth. You still know their names?

  25. how can i calculate tf idf for my own text file which is located some where in my pc?

  26. Brilliant article.

    By far the easiest and most sound explanation of tf-tdf I’ve read. I really liked how you explained the mathematics behind it.

  27. 嗨,伟大的职位!我使用的是TfidVectorizer模块scikit学习产生与规范= L2的TF-IDF矩阵。我把它叫做tfidf_matrix语料的fit_transform后,我一直在检查TfidfVectorizer的输出。我总结了行,但他们并不总和为1的代码是VECT = TfidfVectorizer(use_idf =真,sublunar_tf =真,规范=” L2)。tfidf_matrix = vect.fit_transform(数据)。当我运行tfidf_matrix.sum(轴= 1)的载体是大于1也许我看错矩阵或我误解如何正常化的作品。我希望有人能澄清这一点!谢谢

  28. Can I ask when you calculated the IDF, for example, log(2/1), did you use log to base 10 (e) or some other value? I’m getting different calculations!

  29. 伟大的教程,刚开始在ML一份新工作,这很清楚,因为它应该是解释的事情。亚洲金博宝

  30. Execellent帖子...。!非常感谢这篇文章。

    但是,我需要更多的信息,当你展示实际使用python,你可以为它提供JAVA语言..

  31. 我有点困惑,为什么TF-IDF在这种情况下,给出了负数?我们如何解读?纠正我,如果我错了,但是当载体为正值,这意味着该组件的大小确定字是该文件中有多么重要。如果是负数,我不知道如何解释它。如果我是采取向量的点积与所有积极的部件和一个负组件,这将意味着,一些部件可能负点积贡献,即使在载体有一个特定的词非常高的重视。亚洲金博宝

  32. 嗨,
    谢谢so much for this detailed explanation on this topic, really great. Anyway, could you give me a hint what could be the source of my error that I am keep on seeing:

    freq_term_matrix = count_vectorizer.transform(TEST_SET)
    AttributeError: ‘matrix’ object has no attribute ‘transform’

    我使用sklearn的版本错误?

  33. 真棒简单而有效的explaination.Please发布更多的话题与这样真棒explainations.Looking着为即将到来的文章。
    谢谢

  34. 谢谢克里斯,你是唯一一个谁是明确了对角矩阵在网络上。

  35. I understood the tf-idf calculation process. But what does that matrix mean and how can we use the tfidf matrix to calculate the similarity confuse me. can you explain that how can we use the tfidf matrix .thanks

  36. best explanation.. Very helpful. Can you please tell me how to plot vectors in text classification in svm.. I am working on tweets classification. I am confused please help me.

  37. 嗨,I’m sorry if i have mistaken but i could not understand how is ||Vd4||2 = 1.
    D4 =的值(0.0,0.89,0.44,0.0),因此归一化将是= SQRT(正方形(0.89)+平方(0.44))= SQRT(0.193)= 0.44
    所以我有没有遗漏了什么?请帮我明白了。

  38. 嗨,it is a great blog!
    如果我需要做双克的情况下,我该如何使用sklearn来完成呢?

  39. 这是非常大的亚洲金博宝。我喜欢你教。亚洲金博宝非常非常好

  40. I am not getting same result, when i am executing the same script.
    print (“IDF:”, tfidf.idf_) : IDF: [ 2.09861229 1. 1.40546511 1. ]

    我的Python版本:3.5
    Scikit了解的版本是:o.18.1

    什么我需要改变?可能是什么可能的错误?

    thanks,

    1. 它可以是很多东西,因为你使用的是不同的Python解释器的版本也不同Scikit-学习版,你应该会在结果的差异,因为他们可能已经改变了默认参数,算法,圆等

  41. 完美的介绍!
    No hocus pocus. Clear and simple, as technology should be.
    亚洲金博宝很有帮助
    非常感谢你。亚洲金博宝
    请发帖!
    Obrigado

  42. Why is |D| = 2, in the idf equation. Shouldn’t it be 4 since |D| denotes the number of documents considered, and we have 2 from test, 2 from train.

  43. hey , hii Christian
    your post is really helpful to me to understand tfd-idf from the basics. I’m working on a project of classification where I’m using vector space model which results in determining the categories where my test document should be present. its a part of machine learning . it would be great if you suggest me something related to that. I’m stuck at this point.
    谢谢

  44. 看到这个例子就知道如何使用它的文本分类过程。“这个”链接不起作用了。能否请您提供相关链接,例如。

    谢谢

  45. 当然有很大的了解这个问题。我真的很喜欢所有的点,你做。

  46. 1vbXlh You have brought up a very wonderful details , appreciate it for the post.

  47. 我知道这个网站提供基于高质量的文章或
    评论和其他数据,还有没有其他的网页呈现这类
    在质量信息?

  48. In the first example. idf(t1), the log (2/1) = 0.3010 by the calculator. Why they obtained 0.69.. Please What is wrong?

发表回复amandaCancel reply

您的电子邮件地址不会被公开。

This site uses Akismet to reduce spam.Learn how your comment data is processed