A Probabilistic Theory of Pattern RecognitionSpringer Science & Business Media, 27.11.2013 - 638 sivua Pattern recognition presents one of the most significant challenges for scientists and engineers, and many different approaches have been proposed. The aim of this book is to provide a self-contained account of probabilistic analysis of these approaches. The book includes a discussion of distance measures, nonparametric methods based on kernels or nearest neighbors, Vapnik-Chervonenkis theory, epsilon entropy, parametric classification, error estimation, free classifiers, and neural networks. Wherever possible, distribution-free properties and inequalities are derived. A substantial portion of the results or the analysis is new. Over 430 problems and exercises complement the material. |
Kirjan sisältä
Tulokset 1 - 5 kokonaismäärästä 79
Sivu xv
... Random Variables 584 A.7 Conditional Expectation 585 A.8 The Binomial Distribution 586 A.9 The Hypergeometric Distribution 589 A.10 The Multinomial Distribution 589 A.11 The Exponential and Gamma Distributions A.12 The Multivariate ...
... Random Variables 584 A.7 Conditional Expectation 585 A.8 The Binomial Distribution 586 A.9 The Hypergeometric Distribution 589 A.10 The Multinomial Distribution 589 A.11 The Exponential and Gamma Distributions A.12 The Multivariate ...
Sivu 7
... random variables are uppercase characters such as X , Y , and Z. Probability measures are denoted by greek letters such as μ and v . Numbers and vectors are denoted by lowercase letters such as a , b , c , x , and y . Sets are also ...
... random variables are uppercase characters such as X , Y , and Z. Probability measures are denoted by greek letters such as μ and v . Numbers and vectors are denoted by lowercase letters such as a , b , c , x , and y . Sets are also ...
Sivu 9
... random variables taking their respective values from Rd and { 0 , 1 } . The random pair ( X , Y ) may be described in a variety of ways : for example , it is defined by the pair ( μ , n ) , where μ is the probability measure for X and ...
... random variables taking their respective values from Rd and { 0 , 1 } . The random pair ( X , Y ) may be described in a variety of ways : for example , it is defined by the pair ( μ , n ) , where μ is the probability measure for X and ...
Sivu 12
... distribution of ( T , B , E ) , or , equivalently , the joint distribution of ( T , B , Y ) . So , let us assume that T , B , and E are i.i.d. exponential random variables ( thus , they have density e- " on [ 0 , ∞ ) ) . The Bayes rule ...
... distribution of ( T , B , E ) , or , equivalently , the joint distribution of ( T , B , Y ) . So , let us assume that T , B , and E are i.i.d. exponential random variables ( thus , they have density e- " on [ 0 , ∞ ) ) . The Bayes rule ...
Sivu 19
... variables T and B , where Y = I { T + B + E < 7 } and E is an inaccessible variable ( see Section 2.3 ) . ( 1 ) Let ... random variables with interpretations as in Section 2.3 . Let Y 1 ( 0 ) denote whether a student passes ( fails ) a ...
... variables T and B , where Y = I { T + B + E < 7 } and E is an inaccessible variable ( see Section 2.3 ) . ( 1 ) Let ... random variables with interpretations as in Section 2.3 . Let Y 1 ( 0 ) denote whether a student passes ( fails ) a ...
Sisältö
1 | |
4 | |
21 | |
27 | |
54 | |
Nearest Neighbor Rules | 60 |
4 | 67 |
6 | 74 |
Parametric Classification | 263 |
Generalized Linear Discrimination | 279 |
Complexity Regularization | 289 |
Condensed and Edited Nearest Neighbor Rules 303 | 302 |
Tree Classifiers | 315 |
DataDependent Partitioning | 363 |
Splitting the Data 387 | 386 |
The Resubstitution Estimate | 397 |
11 | 81 |
2 | 92 |
6 | 100 |
8 | 106 |
2 | 113 |
Error Estimation | 120 |
The Regular Histogram Rule | 133 |
Kernel Rules | 153 |
Consistency of the kNearest Neighbor Rule | 168 |
VapnikChervonenkis Theory | 187 |
Combinatorial Aspects of VapnikChervonenkis Theory | 214 |
4 | 224 |
1 | 234 |
The Maximum Likelihood Principle | 249 |
Deleted Estimates of the Error Probability | 407 |
Automatic Kernel Rules 423 | 422 |
Automatic Nearest Neighbor Rules | 451 |
Hypercubes and Discrete Spaces 461 | 460 |
Epsilon Entropy and Totally Bounded Sets | 479 |
Uniform Laws of Large Numbers 489 | 488 |
Neural Networks | 507 |
Other Error Estimates | 549 |
Feature Extraction 561 | 560 |
Appendix | 575 |
Notation | 591 |
Author Index | 619 |
Subject Index | 627 |
Muita painoksia - Näytä kaikki
A Probabilistic Theory of Pattern Recognition Luc Devroye,László Györfi,Gabor Lugosi Rajoitettu esikatselu - 1997 |
A Probabilistic Theory of Pattern Recognition Luc Devroye,Laszlo Gyorfi,Gábor Lugosi Esikatselu ei käytettävissä - 2014 |
A Probabilistic Theory of Pattern Recognition Luc Devroye,László Györfi,Gabor Lugosi Esikatselu ei käytettävissä - 2013 |
Yleiset termit ja lausekkeet
a₁ algorithm Assume asymptotic b₁ Bayes error binary Cauchy-Schwarz inequality cells Chapter class of classifiers classification rule condition converges to zero Corollary data points decision defined deleted estimate denotes density Devroye distribution empirical error error estimate error probability example finite fixed function HINT histogram rule Hoeffding's inequality hyperplane hyperrectangles inequality integer Jensen's inequality k-d tree k-nearest k-NN rule kernel rule L(gn Lemma linear classifier maximum likelihood minimizing the empirical nearest neighbor rule neural network node obtained otherwise pairs parameters partition pattern recognition probability of error proof of Theorem Prove random variables rate of convergence rectangles risk minimization rule gn sample selected shatter coefficients Show sigmoid split squared error structural risk minimization subsets tree classifiers universally consistent upper bound values vc dimension vector X₁ Y₁ фес