Geschäftskunden Kundenprogramme
Vor Ort
Merkzettel Warenkorb
  • Produktbild: Feedback Control Theory for Dynamic Traffic Assignment
  • Produktbild: Feedback Control Theory for Dynamic Traffic Assignment
  • Produktbild: Feedback Control Theory for Dynamic Traffic Assignment

Feedback Control Theory for Dynamic Traffic Assignment

Aus der Reihe Advances in Industrial Control

Fr. 72.90

inkl. gesetzl. MwSt., Versandkostenfrei

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

16.09.2011

Verlag

Springer London

Seitenzahl

207

Maße (L/B/H)

23.5/15.5/1.3 cm

Gewicht

359 g

Auflage

Softcover reprint of the original 1st ed. 1999

Sprache

Englisch

ISBN

978-1-4471-1209-9

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

16.09.2011

Verlag

Springer London

Seitenzahl

207

Maße (L/B/H)

23.5/15.5/1.3 cm

Gewicht

359 g

Auflage

Softcover reprint of the original 1st ed. 1999

Sprache

Englisch

ISBN

978-1-4471-1209-9

Herstelleradresse

Springer Heidelberg
Tiergartenstr. 17
69121 Heidelberg
DE
buchhandel-buch@springer.com

Kundinnen und Kunden meinen

0 Bewertungen

Informationen zu Bewertungen

Zur Abgabe einer Bewertung ist eine Anmeldung im Konto notwendig. Die Authentizität der Bewertungen wird von uns nicht überprüft. Wir behalten uns vor, Bewertungstexte, die unseren Richtlinien widersprechen, entsprechend zu kürzen oder zu löschen.

Die Bewertungen sind nach Format, Anzahl Sterne und Datum sortiert.

Verfassen Sie die erste Bewertung zu diesem Artikel

Helfen Sie anderen Kund*innen durch Ihre Meinung

Kundinnen und Kunden meinen

0 Bewertungen filtern
  • Produktbild: Feedback Control Theory for Dynamic Traffic Assignment
  • Produktbild: Feedback Control Theory for Dynamic Traffic Assignment
  • Produktbild: Feedback Control Theory for Dynamic Traffic Assignment
  • 1 Introduction.- Objectives.- 1. Dynamic Traffic Routing.- Objectives.- Control Algorithm Design.- Sensing.- Actuation.- Automatic Control vs. Human-in-the-loop Control.- Overall System.- Traffic Analysis Notation.- 2. Motivation.- 3. Literature Review.- 4. FeedBack Control.- Control Design Steps.- Feedback Control Example.- Other Issues.- 5. Summary.- 6. Exercises.- Questions.- Problems.- 7. References.- 2 Traffic Flow Theory.- Objectives.- 1. Introduction.- 2. Conservation Law.- 3. Traffic Density-Flow Relationships.- Greenshield’s Model [1].- Greenberg Model [2]:.- Underwood Model [3]:.- Northwestern University Model [4]:.- Drew Model [5]:.- Pipes- Munjal Model [6]:.- Multiregime Models [7]:.- Diffusion Models:.- 4 Microscopic Traffic Characteristics [17,18,19].- 5 Traffic Model.- 6 Classification of PDEs[20,21,22].- Variables.- Order of the PDE.- Linearity.- Boundary Conditions.- 7 Existence of Solution [21].- Traffic Problem.- 8 Method of Characteristics to Solve First Order PDEs [20].- 9. Traffic Shock Wave Propagation.- 10. Traffic Measurements.- Time mean speed.- Space mean speed.- Time Headway.- Space Headway.- Flow measurements.- Traffic Density Measurements.- Occupancy.- Distributed Measurements.- Moving Observer Method.- 11. Summary.- 12. Exercises.- Questions.- Problems.- 13. References.- 3 Modeling and Problem Formulation.- Objectives.- 1. Introduction.- 2. System Dynamics.- 3. Feedback Control for the Traffic as a Distributed Parameter System.- DTR Formulation.- 4. Discretized System Dynamics.- 5. Feedback Control for the Traffic as a Lumped Parameter System.- DTR Formulation.- 6. Sample Problem for Space Discretized Dynamics.- 7. Sample Problem For Space and Time Discretized Dynamics: Three Alternate Routes Case Description.- System Dynamics.- System Analysis.- Simple Feedback Control Law.- Description of the Results for Different Scenarios.- 8. Summary.- 9. Exercises.- Questions.- Problems.- 10. References.- 4 Dynamic Traffic Routing Problem in Distributed Parameter Setting.- Objectives.- 1. Introduction.- 2. System Dynamics.- 3. Sliding Mode Control.- 4. Chattering Reduction.- 5. Numerical Examples.- 6. Generalization of Chattering Reduction Results.- 7. Control Design for DTR Problem.- 8. Numerical Solution of Traffic PDE.- Finite Difference Approximation.- 9. Error Analysis.- Boundary Conditions.- 10. Simulation Software.- 11. Simulation Results.- 12. Summary.- 13. Exercises.- Questions.- Problems.- 14. References.- 5 Dynamic Traffic Routing Problem in Distributed Parameter Setting Using Semigroup Theory.- Objectives.- 1. Introduction.- 2. Mathematical Preliminaries.- Basic Topology.- Vector Space.- Normed Linear Space.- Sequences.- Cauchy Sequence.- Banach Space.- Inner Product Space.- Hilbert Space.- Sobolev Space.- Semigroups.- 3. System Dynamics.- 4. Existing Work.- 5. Summary.- 6. Exercises.- Questions.- Problems.- 7. References.- 6 Fuzzy Feedback Control for Dynamic Traffic Routing.- Objectives.- 1. Introduction.- 2. Overview of Fuzzy Logic.- Crisp Sets.- Function Name.- Representation.- Function Name.- Representation.- Function Name.- Representation.- Fuzzy Sets.- 3. Sample Problem.- System Dynamics.- Simple Fuzzy Feedback Control Law.- Results & Description for different scenarios.- 4. Summary.- 5. Exercises.- Questions.- Problems.- 6. References.- 7 Feedback Control for Dynamic Traffic Routing in Lumped Parameter Setting.- Objectives.- 1. Introduction.- Notation.- 2. System Dynamics and DTR Problem.- DTR Formulation.- 3. Feedback Linearization Technique.- 4. Sample Problem (Two Alternate Routes with One Section Each).- 5. Sample Problem (Two Alternate Routes with Two Section Each).- 6. Solution for The One-Origin, One-Destination Case With Multiple Routes With Multiple Sections.- 7. Simulations.- Simulation environment.- 8. Sliding Mode Control for Point Diversion.- Sample Problem (Two alternate routes with one section).- Sample Problem (Two alternate routes with two section).- Solutions for the Generalized DTR Problem for Multiple Routes with Multiple Sections.- Simulation.- 9. Summary.- 10. Exercises.- Questions.- Problems.- 8 Feedback Control for Network Level Dynamic Traffic Routing.- Objectives.- 1. Introduction.- 2. System Description.- System Network.- System Dynamics.- 3. Dynamic Traffic Assignment Problem.- DTA Problem using Link Based Model.- DTA Problem using Route Based Model.- Feedback Control for the Traffic.- 4. Sample Problem.- System Network.- System Dynamics.- Feedback Control Design.- 5. Summary.- 6. Exercises.- Questions.- Problems.- 7. References.