Borrow it

The Resource Genomic Signal Processing

Genomic Signal Processing

Resource Information

The item Genomic Signal Processing represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Missouri-St. Louis Libraries.
This item is available to borrow from 1 library branch.

Creator

Shmulevich, Ilya

Contributor

Dougherty, Edward R

Summary: Genomic signal processing (GSP) can be defined as the analysis, processing, and use of genomic signals to gain biological knowledge, and the translation of that knowledge into systems-based applications that can be used to diagnose and treat genetic diseases. Situated at the crossroads of engineering, biology, mathematics, statistics, and computer science, GSP requires the development of both nonlinear dynamical models that adequately represent genomic regulation, and diagnostic and therapeutic tools based on these models. This book facilitates these developments by providing rigorous mathema

Language: eng

Work

Publication

Princeton, Princeton University Press, 2014

Extent: 1 online resource (314 pages)

Note: 6.2 Cluster Operators

Contents

Cover; Title; Copyright; Contents; Preface; 1 Biological Foundations; 1.1 Genetics; 1.1.1 Nucleic Acid Structure; 1.1.2 Genes; 1.1.3 RNA; 1.1.4 Transcription; 1.1.5 Proteins; 1.1.6 Translation; 1.1.7 Transcriptional Regulation; 1.2 Genomics; 1.2.1 Microarray Technology; 1.3 Proteomics; Bibliography; 2 Deterministic Models of Gene Networks; 2.1 Graph Models; 2.2 Boolean Networks; 2.2.1 Cell Differentiation and Cellular Functional States; 2.2.2 Network Properties and Dynamics; 2.2.3 Network Inference; 2.3 Generalizations of Boolean Networks; 2.3.1 Asynchrony; 2.3.2 Multivalued Networks
2.4 Differential Equation Models2.4.1 A Differential Equation Model Incorporating Transcription and Translation; 2.4.2 Discretization of the Continuous Differential Equation Model; Bibliography; 3 Stochastic Models of Gene Networks; 3.1 Bayesian Networks; 3.2 Probabilistic Boolean Networks; 3.2.1 Definitions; 3.2.2 Inference; 3.2.3 Dynamics of PBNs; 3.2.4 Steady-State Analysis of Instantaneously Random PBNs ; 3.2.5 Relationships of PBNs to Bayesian Networks; 3.2.6 Growing Subnetworks from Seed Genes; 3.3 Intervention; 3.3.1 Gene Intervention; 3.3.2 Structural Intervention
3.3.3 External ControlBibliography; 4 Classification; 4.1 Bayes Classifier; 4.2 Classification Rules; 4.2.1 Consistent Classifier Design; 4.2.2 Examples of Classification Rules; 4.3 Constrained Classifiers; 4.3.1 Shatter Coefficient; 4.3.2 VC Dimension; 4.4 Linear Classification; 4.4.1 Rosenblatt Perceptron; 4.4.2 Linear and Quadratic Discriminant Analysis; 4.4.3 Linear Discriminants Based on Least-Squares Error; 4.4.4 Support Vector Machines; 4.4.5 Representation of Design Error for Linear Discriminant Analysis; 4.4.6 Distribution of the QDA Sample-Based Discriminant
4.5 Neural Networks Classifiers4.6 Classification Trees; 4.6.1 Classification and Regression Trees; 4.6.2 Strongly Consistent Rules for Data-Dependent Partitioning; 4.7 Error Estimation; 4.7.1 Resubstitution; 4.7.2 Cross-validation; 4.7.3 Bootstrap; 4.7.4 Bolstering; 4.7.5 Error Estimator Performance; 4.7.6 Feature Set Ranking; 4.8 Error Correction; 4.9 Robust Classifiers; 4.9.1 Optimal Robust Classifiers; 4.9.2 Performance Comparison for Robust Classifiers; Bibliography; 5 Regularization; 5.1 Data Regularization; 5.1.1 Regularized Discriminant Analysis; 5.1.2 Noise Injection
5.2 Complexity Regularization5.2.1 Regularization of the Error; 5.2.2 Structural Risk Minimization; 5.2.3 Empirical Complexity ; 5.3 Feature Selection; 5.3.1 Peaking Phenomenon; 5.3.2 Feature Selection Algorithms; 5.3.3 Impact of Error Estimation on Feature Selection; 5.3.4 Redundancy; 5.3.5 Parallel Incremental Feature Selection; 5.3.6 Bayesian Variable Selection; 5.4 Feature Extraction; Bibliography; 6 Clustering; 6.1 Examples of Clustering Algorithms; 6.1.1 Euclidean Distance Clustering; 6.1.2 Self-Organizing Maps; 6.1.3 Hierarchical Clustering; 6.1.4 Model-Based Cluster Operators

Isbn: 9781400865260

Instance

Label: Genomic Signal Processing

Title: Genomic Signal Processing

Creator

Shmulevich, Ilya

Contributor

Dougherty, Edward R

Subject

Language: eng

Summary: Genomic signal processing (GSP) can be defined as the analysis, processing, and use of genomic signals to gain biological knowledge, and the translation of that knowledge into systems-based applications that can be used to diagnose and treat genetic diseases. Situated at the crossroads of engineering, biology, mathematics, statistics, and computer science, GSP requires the development of both nonlinear dynamical models that adequately represent genomic regulation, and diagnostic and therapeutic tools based on these models. This book facilitates these developments by providing rigorous mathema

Member of

Cataloging source: EBLCP

http://library.link/vocab/creatorName: Shmulevich, Ilya

Dewey number: 572.865

Index: no index present

Language note: In English

LC call number: QP517.C45 S49 2014

Literary form: non fiction

Nature of contents: dictionaries

http://library.link/vocab/relatedWorkOrContributorName: Dougherty, Edward R

Series statement: Princeton Series in Applied Mathematics

http://library.link/vocab/subjectName

Cellular signal transduction
Genetic regulation
Genomics
SCIENCE
MATHEMATICS
Cellular signal transduction
Genetic regulation
Genomics

Label: Genomic Signal Processing

Instantiates

Genomic Signal Processing

Publication

Princeton, Princeton University Press, 2014

Note: 6.2 Cluster Operators

Antecedent source: unknown

Carrier category: online resource

Carrier category code

Carrier MARC source: rdacarrier

Color: multicolored

Content category: text

Content type code

Content type MARC source: rdacontent

Contents

Cover; Title; Copyright; Contents; Preface; 1 Biological Foundations; 1.1 Genetics; 1.1.1 Nucleic Acid Structure; 1.1.2 Genes; 1.1.3 RNA; 1.1.4 Transcription; 1.1.5 Proteins; 1.1.6 Translation; 1.1.7 Transcriptional Regulation; 1.2 Genomics; 1.2.1 Microarray Technology; 1.3 Proteomics; Bibliography; 2 Deterministic Models of Gene Networks; 2.1 Graph Models; 2.2 Boolean Networks; 2.2.1 Cell Differentiation and Cellular Functional States; 2.2.2 Network Properties and Dynamics; 2.2.3 Network Inference; 2.3 Generalizations of Boolean Networks; 2.3.1 Asynchrony; 2.3.2 Multivalued Networks
2.4 Differential Equation Models2.4.1 A Differential Equation Model Incorporating Transcription and Translation; 2.4.2 Discretization of the Continuous Differential Equation Model; Bibliography; 3 Stochastic Models of Gene Networks; 3.1 Bayesian Networks; 3.2 Probabilistic Boolean Networks; 3.2.1 Definitions; 3.2.2 Inference; 3.2.3 Dynamics of PBNs; 3.2.4 Steady-State Analysis of Instantaneously Random PBNs ; 3.2.5 Relationships of PBNs to Bayesian Networks; 3.2.6 Growing Subnetworks from Seed Genes; 3.3 Intervention; 3.3.1 Gene Intervention; 3.3.2 Structural Intervention
3.3.3 External ControlBibliography; 4 Classification; 4.1 Bayes Classifier; 4.2 Classification Rules; 4.2.1 Consistent Classifier Design; 4.2.2 Examples of Classification Rules; 4.3 Constrained Classifiers; 4.3.1 Shatter Coefficient; 4.3.2 VC Dimension; 4.4 Linear Classification; 4.4.1 Rosenblatt Perceptron; 4.4.2 Linear and Quadratic Discriminant Analysis; 4.4.3 Linear Discriminants Based on Least-Squares Error; 4.4.4 Support Vector Machines; 4.4.5 Representation of Design Error for Linear Discriminant Analysis; 4.4.6 Distribution of the QDA Sample-Based Discriminant
4.5 Neural Networks Classifiers4.6 Classification Trees; 4.6.1 Classification and Regression Trees; 4.6.2 Strongly Consistent Rules for Data-Dependent Partitioning; 4.7 Error Estimation; 4.7.1 Resubstitution; 4.7.2 Cross-validation; 4.7.3 Bootstrap; 4.7.4 Bolstering; 4.7.5 Error Estimator Performance; 4.7.6 Feature Set Ranking; 4.8 Error Correction; 4.9 Robust Classifiers; 4.9.1 Optimal Robust Classifiers; 4.9.2 Performance Comparison for Robust Classifiers; Bibliography; 5 Regularization; 5.1 Data Regularization; 5.1.1 Regularized Discriminant Analysis; 5.1.2 Noise Injection
5.2 Complexity Regularization5.2.1 Regularization of the Error; 5.2.2 Structural Risk Minimization; 5.2.3 Empirical Complexity ; 5.3 Feature Selection; 5.3.1 Peaking Phenomenon; 5.3.2 Feature Selection Algorithms; 5.3.3 Impact of Error Estimation on Feature Selection; 5.3.4 Redundancy; 5.3.5 Parallel Incremental Feature Selection; 5.3.6 Bayesian Variable Selection; 5.4 Feature Extraction; Bibliography; 6 Clustering; 6.1 Examples of Clustering Algorithms; 6.1.1 Euclidean Distance Clustering; 6.1.2 Self-Organizing Maps; 6.1.3 Hierarchical Clustering; 6.1.4 Model-Based Cluster Operators

Control code: 888743988

Dimensions: unknown

Extent: 1 online resource (314 pages)

File format: unknown

Form of item: online

Isbn: 9781400865260

Level of compression: unknown

Media category: computer

Media MARC source: rdamedia

Media type code

Other control number: 10.1515/9781400865260

http://library.link/vocab/ext/overdrive/overdriveId: 22573/ctt767z3h

Quality assurance targets: not applicable

Reformatting quality: unknown

Sound: unknown sound

Specific material designation: remote

System control number: (OCoLC)888743988

Label: Genomic Signal Processing

Publication

Princeton, Princeton University Press, 2014

Note: 6.2 Cluster Operators

Antecedent source: unknown

Carrier category: online resource

Carrier category code

Carrier MARC source: rdacarrier

Color: multicolored

Content category: text

Content type code

Content type MARC source: rdacontent

Contents

Cover; Title; Copyright; Contents; Preface; 1 Biological Foundations; 1.1 Genetics; 1.1.1 Nucleic Acid Structure; 1.1.2 Genes; 1.1.3 RNA; 1.1.4 Transcription; 1.1.5 Proteins; 1.1.6 Translation; 1.1.7 Transcriptional Regulation; 1.2 Genomics; 1.2.1 Microarray Technology; 1.3 Proteomics; Bibliography; 2 Deterministic Models of Gene Networks; 2.1 Graph Models; 2.2 Boolean Networks; 2.2.1 Cell Differentiation and Cellular Functional States; 2.2.2 Network Properties and Dynamics; 2.2.3 Network Inference; 2.3 Generalizations of Boolean Networks; 2.3.1 Asynchrony; 2.3.2 Multivalued Networks
2.4 Differential Equation Models2.4.1 A Differential Equation Model Incorporating Transcription and Translation; 2.4.2 Discretization of the Continuous Differential Equation Model; Bibliography; 3 Stochastic Models of Gene Networks; 3.1 Bayesian Networks; 3.2 Probabilistic Boolean Networks; 3.2.1 Definitions; 3.2.2 Inference; 3.2.3 Dynamics of PBNs; 3.2.4 Steady-State Analysis of Instantaneously Random PBNs ; 3.2.5 Relationships of PBNs to Bayesian Networks; 3.2.6 Growing Subnetworks from Seed Genes; 3.3 Intervention; 3.3.1 Gene Intervention; 3.3.2 Structural Intervention
3.3.3 External ControlBibliography; 4 Classification; 4.1 Bayes Classifier; 4.2 Classification Rules; 4.2.1 Consistent Classifier Design; 4.2.2 Examples of Classification Rules; 4.3 Constrained Classifiers; 4.3.1 Shatter Coefficient; 4.3.2 VC Dimension; 4.4 Linear Classification; 4.4.1 Rosenblatt Perceptron; 4.4.2 Linear and Quadratic Discriminant Analysis; 4.4.3 Linear Discriminants Based on Least-Squares Error; 4.4.4 Support Vector Machines; 4.4.5 Representation of Design Error for Linear Discriminant Analysis; 4.4.6 Distribution of the QDA Sample-Based Discriminant
4.5 Neural Networks Classifiers4.6 Classification Trees; 4.6.1 Classification and Regression Trees; 4.6.2 Strongly Consistent Rules for Data-Dependent Partitioning; 4.7 Error Estimation; 4.7.1 Resubstitution; 4.7.2 Cross-validation; 4.7.3 Bootstrap; 4.7.4 Bolstering; 4.7.5 Error Estimator Performance; 4.7.6 Feature Set Ranking; 4.8 Error Correction; 4.9 Robust Classifiers; 4.9.1 Optimal Robust Classifiers; 4.9.2 Performance Comparison for Robust Classifiers; Bibliography; 5 Regularization; 5.1 Data Regularization; 5.1.1 Regularized Discriminant Analysis; 5.1.2 Noise Injection
5.2 Complexity Regularization5.2.1 Regularization of the Error; 5.2.2 Structural Risk Minimization; 5.2.3 Empirical Complexity ; 5.3 Feature Selection; 5.3.1 Peaking Phenomenon; 5.3.2 Feature Selection Algorithms; 5.3.3 Impact of Error Estimation on Feature Selection; 5.3.4 Redundancy; 5.3.5 Parallel Incremental Feature Selection; 5.3.6 Bayesian Variable Selection; 5.4 Feature Extraction; Bibliography; 6 Clustering; 6.1 Examples of Clustering Algorithms; 6.1.1 Euclidean Distance Clustering; 6.1.2 Self-Organizing Maps; 6.1.3 Hierarchical Clustering; 6.1.4 Model-Based Cluster Operators

Control code: 888743988

Dimensions: unknown

Extent: 1 online resource (314 pages)

File format: unknown

Form of item: online

Isbn: 9781400865260

Level of compression: unknown

Media category: computer

Media MARC source: rdamedia

Media type code

Other control number: 10.1515/9781400865260

http://library.link/vocab/ext/overdrive/overdriveId: 22573/ctt767z3h

Quality assurance targets: not applicable

Reformatting quality: unknown

Sound: unknown sound

Specific material designation: remote

System control number: (OCoLC)888743988

Thomas Jefferson LibraryBorrow it

1 University Blvd, St. Louis, MO, 63121, US

38.710138 -90.311107

Genomic Signal Processing Resource Information The item Genomic Signal Processing represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Missouri-St. Louis Libraries.This item is available to borrow from 1 library branch.

Subject

Genre

Member of

Library Locations

Library Links

Genomic Signal Processing

Resource Information

The item Genomic Signal Processing represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of Missouri-St. Louis Libraries.
This item is available to borrow from 1 library branch.