On Activity-Based Network Design Problems JEE EUN (JAMIE) KANG, JOSEPH Y. J. CHOW, AND WILL W. RECKER 20 TH INTERNATIONAL SYMPOSIUM ON TRANSPORTATION AND.

Slides:

Advertisements

Similar presentations

B Multi-Layer Network Design II Dr. Greg Bernstein Grotto Networking

Advertisements

Regional Bicycle Demand Model: In Use Today in Portland Bill Stein, Metro TRB Transportation Applications Conference Reno, Nevada – May 9, 2011.

Dynamic Pickup and Delivery with Transfers* P. Bouros 1, D. Sacharidis 2, T. Dalamagas 2, T. Sellis 1,2 1 NTUA, 2 IMIS – RC “Athena” * To appear in SSTD’11.

Modeling Rich Vehicle Routing Problems TIEJ601 Postgraduate Seminar Tuukka Puranen October 19 th 2009.

Norman Washington Garrick CE 2710 Spring 2014 Lecture 07

Vehicle Routing & Scheduling: Part 1

Vehicle Routing & Scheduling Multiple Routes Construction Heuristics –Sweep –Nearest Neighbor, Nearest Insertion, Savings –Cluster Methods Improvement.

1 EL736 Communications Networks II: Design and Algorithms Class8: Networks with Shortest-Path Routing Yong Liu 10/31/2007.

Time of day choice models The “weakest link” in our current methods(?) Change the use of network models… Run static assignments for more periods of the.

What is the Model??? A Primer on Transportation Demand Forecasting Models Shawn Turner Theo Petritsch Keith Lovan Lisa Aultman-Hall.

SCAG Region Heavy Duty Truck Model Southern California Region Heavy Duty Truck Model.

GEOG 111 & 211A Transportation Planning Traffic Assignment.

Dynamic Origin-Destination Demand Flow Estimation under Congested Traffic Conditions Xuesong Zhou (Univ. of Utah) Chung-Cheng Lu (National Taipei University.

Urban Transport Modeling (based on these two sources) A Transportation Modeling Primer May, 1995 Edward A. Beimborn Center for Urban Transportation Studies.

Vehicle Routing & Scheduling

1 A Second Stage Network Recourse Problem in Stochastic Airline Crew Scheduling Joyce W. Yen University of Michigan John R. Birge Northwestern University.

11 Quantifying Benefits of Traffic Information Provision under Stochastic Demand and Capacity Conditions: A Multi-day Traffic Equilibrium Approach Mingxin.

Norman W. Garrick Transportation Forecasting What is it? Transportation Forecasting is used to estimate the number of travelers or vehicles that will use.

Airline Fleet Routing and Flight Scheduling under Market Competitions

Vehicle Routing & Scheduling: Part 2 Multiple Routes Construction Heuristics –Sweep –Nearest Neighbor, Nearest Insertion, Savings –Cluster Methods Improvement.

Airline Schedule Optimization (Fleet Assignment II) Saba Neyshabouri.

Transportation Planning and Modeling Transportation planning is a field involved with the evaluation, assessment, design and siting of transportation facilities.

1 EL736 Communications Networks II: Design and Algorithms Class11: Multi-Hour and Multi-Layer Network Design 12/05/2007.

Dynamic Freight Train Rerouting Alborz Parcham-Kashani Dr. Alan Erera Georgia Institute of Technology H. Milton Stewart School of Industrial & Systems.

Model Task Force Meeting November 29, 2007 Activity-based Modeling from an Academic Perspective Transportation Research Center (TRC) Dept. of Civil & Coastal.

Source: NHI course on Travel Demand Forecasting (152054A) Session 10 Traffic (Trip) Assignment Trip Generation Trip Distribution Transit Estimation & Mode.

SAN FRANCISCO COUNTY TRANSPORTATION AUTHORITY San Francisco DTA Project: Model Integration Options Greg Erhardt DTA Peer Review Panel Meeting July 25 th,

15.082J and 6.855J and ESD.78J November 30, 2010 The Multicommodity Flow Problem.

SHRP2 C10: Jacksonville Partnership to Develop an Integrated Advanced Travel Demand Model and a Fine-grained Time- sensitive Network Key Agency Partners:

Network Models Tran Van Hoai Faculty of Computer Science & Engineering HCMC University of Technology Tran Van Hoai.

A New Policy Sensitive Travel Demand Model for Tel Aviv Yoram Shiftan Transportation Research Institute Faculty of Civil and Environmental Engineering.

Florida Multimodal Statewide Freight Model

Kermit Wies, Craig Heither, CMAP Peter Vovsha, Jim Hicks, PB Hani Mahmassani, Ali Zockaie, NU TPAC, May 17-20, An Integrated ABM-DTA Model for the.

Some network flow problems in urban road networks Michael Zhang Civil and Environmental Engineering University of California Davis.

SAN FRANCISCO COUNTY TRANSPORTATION AUTHORITY San Francisco’s Dynamic Traffic Assignment Model Background SFCTA DTA Model Peer Review Panel Meeting July.

Comparing Dynamic Traffic Assignment Approaches for Planning

David B. Roden, Senior Consulting Manager Analysis of Transportation Projects in Northern Virginia TRB Transportation Planning Applications Conference.

Architecture David Levinson. East Asian Grids Kyoto Nara Chang-an Ideal Chinese Plan.

Hub Location Problems Chapter 12

Dynamic Origin-Destination Trip Table Estimation for Transportation Planning Ramachandran Balakrishna Caliper Corporation 11 th TRB National Transportation.

Dynamics of Traffic Flows in Combined Day-to-day and With- in Day Context Chandra Balijepalli ITS, Leeds September 2004.

Presented to Time of Day Subcommittee May 9, 2011 Time of Day Modeling in FSUTMS.

A Dynamic Traffic Simulation Model on Planning Networks Qi Yang Caliper Corporation TRB Planning Application Conference Houston, May 20, 2009.

Benjamin Heydecker JD (Puff) Addison Centre for Transport Studies UCL Dynamic Modelling of Road Transport Networks.

Household Activity Pattern Problem Paper by: W. W. Recker. Presented by: Jeremiah Jilk May 26, 2004 Jeremiah Jilk University of California, Irvine ICS.

Methodological Considerations for Integrating Dynamic Traffic Assignment with Activity-Based Models Ramachandran Balakrishna Daniel Morgan Srinivasan Sundaram.

Location Choice Modeling for Shopping and Leisure Activities with MATSim: Utility Function Extension and Validation Results A. Horni IVT ETH Zurich.

A Tour-Based Urban Freight Transportation Model Based on Entropy Maximization Qian Wang, Assistant Professor Department of Civil, Structural and Environmental.

Enlarging the Options in the Strategy-based Transit Assignment TRB Applications Conference Reno 2011 Isabelle Constantin and Michael Florian INRO.

Strategic Planning of National/Regional Freight Transportation Systems : An Analysis TG Crainic, J Damay, M Gendreau, R Namboothiri June 15, 2009.

1 An Arc-Path Model for OSPF Weight Setting Problem Dr.Jeffery Kennington Anusha Madhavan.

Lagrangean Relaxation

The Current State-of-the-Practice in Modeling Road Pricing Bruce D. Spear Federal Highway Administration.

Generated Trips and their Implications for Transport Modelling using EMME/2 Marwan AL-Azzawi Senior Transport Planner PDC Consultants, UK Also at Napier.

Assignment. Where are we? There are four scopes 1. Logit 2. Assignment Today! 3. LUTI 4. Other models and appraisal.

Spatial Networks Introduction to Spatial Computing CSE 5ISC Some slides adapted from Shashi Shekhar, University of Minnesota.

Urban Planning Group Implementation of a Model of Dynamic Activity- Travel Rescheduling Decisions: An Agent-Based Micro-Simulation Framework Theo Arentze,

Travel Demand Forecasting: Traffic Assignment CE331 Transportation Engineering.

Systems Analysis Group TPAC, 2015 Application Experience of Multiple Discrete Continuous Extreme Value (MDCEV) Model for Activity Duration and Trip Departure.

Network Analyst. Network A network is a system of linear features that has the appropriate attributes for the flow of objects. A network is typically.

Ken-ichi TANAKA Department of Management Science,

Aktivitetsbaseret modellering af transportefterspørgsel

Introduction to Spatial Computing CSE 5ISC

1st November, 2016 Transport Modelling – Developing a better understanding of Short Lived Events Marcel Pooke – Operational Modelling & Visualisation Manager.

Network Assignment and Equilibrium for Disaggregate Models

Fuzzy Dynamic Traffic Assignment Model

TransCAD Vehicle Routing 2018/11/29.

Chrissy Bernardo, Peter Vovsha, Gaurav Vyas (WSP),

Chapter 6 Network Flow Models.

Presentation transcript:

On Activity-Based Network Design Problems JEE EUN (JAMIE) KANG, JOSEPH Y. J. CHOW, AND WILL W. RECKER 20 TH INTERNATIONAL SYMPOSIUM ON TRANSPORTATION AND TRAFFIC THEORY 7/17/2013 1

Motivation Network Design Problem has been negligent of travel demand dynamics. Transportation Planning in general had been negligent of travel demand dynamics. Activity-Based Travel Demand Models are maturing 2

Motivation  “dinner” activity following “work”  Departure time adjustment  Mode choice  Destination choice  Activity participation  Sequence of activities  Aggregate time-dependent activity-based traffic assignment (Lam and Yin, 2001)  No NDP with individual traveler’s travel demand dynamics Work ends 6pm Dinner at 7 pm Free Flow Travel Time: 30 minutes 3

 Network LOS  Influences HHs on daily itinerary  Departure time adjustment  Activity sequence adjustment Motivating Examples H Work: Start at 9 For 8 hr Return before 22 Grocery Shopping: Start [5,20] For 1 hr Return before 22 19:00 8:00 Work 9:00 18:30 Grocery Shopping 17:30 17:00 19:00 8:18 Work 9:00 18:30 Grocery Shopping 17:30 17:00 17:42 7:00 Grocery Shopping 7:30 17:30 Work 9:00 8:30 4

 Network LOS  Paradoxical cases  link investment that generates traffic without any increase in activity participation  Improvement result in higher disutility H Work: Start at 9 For 8 hr Return before 22 Social Activity: Start at For 1 hr Return before 22 Motivating Examples 19:50 8:00 Work 9:00 19:25 Social 18:25 17:00 17:30 Waiting time 19:50 8:00 Work 9:00 19:25 Social 18:25 17:00 17:42 Home 17:45 5

Network Design Problem (NDP)  Strategic or tactical planning of resources to manage a network  Roadway Network Design Problems  “Optimal decision on expansion of a street and highway system in response to a growing demand for travel” (Yang and Bell, 1998)  Congestion effect  Route choice: “selfish traveler”  Bi-level structure  Upper Level: NDP  Lower Level: Traffic Assignment 6

Location Routing Problem (LRP)  Facility Location decisions are influenced by possible routing  Facility Location Strategy  Vehicle Routing Problem (VRP)  One central decision maker 7

Network Design Problem – Household Activity Pattern Problem  Inspired by Location Routing Problem  Activity-based Network Design Problem  Bi-level formulation  Upper Level: NDP  Lower Level: Household Activity Pattern Problem (HAPP) 8

Household Activity Pattern Problem (HAPP)  Full day activity-based travel demand model  Formulation of continuous path in time, space dimension restricted by temporal, spatial constraints (Hagerstrand, 1970)  Network-Based Mixed Integer Linear Programming  Base Case: Pickup and Delivery Problem with Time Windows (PDPTW)  Simultaneous Travel Decisions  Activity, vehicle allocation between HH members  Sequence of activities  Departure (activity) times  Some level of mode choice 9

Conservation of Flow Precedence Constraints Time windows Tour Length Constraints 10

Location Selection Problem for HAPP  Generalized VRP (Ghiani and Improta, 2000) Activities with Pre-Selected Locations 11

 Supernetwork approach  Infrastructure network  Activity network dHAPP dNDP Network design decisions Flow assignment Network Level of Service Individual HH travel decisions OD Flow NDP-HAPP Model 12

NDP-HAPP: dNDP Modified from Unconstrained Multicommodity Formulation (Magnanti and Wong, 1984) Aggregate individual HH itinerary into OD flow Each OD pair is treated as one commodity type 13

NDP-HAPP: dHAPP Update Network LOS 14

NDP-HAPP Solution Algorithm  Decomposition  Blocks of decision making rationale  Location Routing Problems (Perl and Daskin, 1985)  Iterative Optimization Assignment (Friesz and Harker, 1985) 15

Illustrative Example NDP-GHAPP H1 Work: Start [9, 9.5] For 8 hr Return before 22 Work: Start [8.5,9] For 8 hr Return before 22 Grocery Shopping Start [5,20] For 1 hr Return before 22 Node 1, Node 5 H2 General Shopping Start [5,21] For 1 hr Return before 22 Node 3, Node 8  Network  Objective:  2 HHs: 1 HH member with 1 vehicle  Objective:  A(HH1) = {work, grocery shopping}  A(HH2) = {work, general shopping} 16

Iteration 1Iteration 2Iteration 3Iteration 4 dHAPP1 Home (0) → grocery shopping (1) → work (2) → home (0) Objective Value: 2 Home (0) → work (2) → grocery shopping (1) → home (0) Objective Value: 2 Home (0) → grocery shopping (5) → work (2) → home (0) Objective Value: 4 Home (0) → grocery shopping (5) → work (2) → home (0) Objective Value: 3 dHAPP2 Home (5) → work (6) → general shopping (8) → home (5) Objective Value: 3 Home (5) → work (6) → general shopping (8) → home (5) Objective Value: 3 Home (5) → work (6) → general shopping (3) → home (5) Objective Value: 4 Home (5) → work (6) → general shopping (3) → home (5) Objective Value: 4 dNDP Network Design Decisions: Z01, Z10, Z12, Z21, Z58, Z67, Z76, Z78, Z85, Z87 dNDP objective value: 35 HH1 Paths link Flows: (0) → (1) → (2) → (1) → (0) HH2 Paths link Flows: (5) → (8) → (7) → (6) → (7) → (8) → (5) Update each dHAPP objective values: HH1: 2, HH2: 3 Network Design Decisions: Z03, Z10, Z21, Z36, Z52, Z67, Z78, Z85 dNDP objective value: 32 HH1 Paths link Flows: (0) → (3) → (6) → (7) → (8) → (5) → (2) → (1) → (0) HH2 Paths link Flows: (5) → (2) → (1) → (0) → (3) → (7) → (8) → (5) Update each dHAPP objective values: HH1: 4, HH2: 4 Network Design Decisions: Z03, Z10, Z21, Z34, Z36, Z45, Z52, Z63 dNDP objective value: 31 HH1 Paths link Flows: (0) → (3) → (4) → (5) → (2) → (1) → (0) HH2 Paths link Flows: (5) → (2) → (1) → (0) → (3) → (6) → (3) → (4) → (5) Update each dHAPP objective values: HH1: 3, HH2: 4 NA 3 Objective Changes in activity sequences, destination choice, departure times Changes in network investment decisions Shortest path, Link flow changes 17

Illustrative Example NDP-GHAPP  NDP-GHAPP  Optimal  NDP-HAPP  5% Optimality gap  Flexibility in dHAPP allows more options to be searched Grocery Node 5 H1 H2 General Node 3 17:00 6:00 9:00 8:30 7:30 18:00 Work 17:00 7:00 Work 8:30 16:30 18:00 19:00 18

Large scale case study  Link improvement decision  SR39, SR68, SR55, SR55, SR22, SR261, SR 241  dNDP: 19

 California Statewide Household Travel Survey  CalTrans, 2001  Departure and arrival times, trip/activity durations, geo-coded locations  60HHs  HAPP case1: no interaction between HH members  Time Windows generated similar to Recker and Parimi (1999)  Individually estimated objective weights (Chow and Recker, 2012)  dHAPP: Large scale case study 20

Budget NDP-HAPPConventional NDP # iter Link Construction Decision dNDP obj dHAPP obj # trips (# intra) # HHs affected Time (sec) Link Construction Decision NDP obj BeforeNA (76) NA , 7875, (76) 5/ , 7875, , 7875, 7578, 7937, 8660, 6786, (76) 13/ , 7875, 7578, 7937, 8660, 6786, , 7875, 7578, 7937, 8660, 6786, 8887, 6086, 8667, (76) 14/ , 7875, 7578, 7937, 8660, 6786, 8887, 6086, 8667, , 7875, 7578, 7937, 8660, 6786, 8887, 6086, 8667, 8889, 6162, 6589, 8765, (76) 17/ , 7875, 7578, 7937, 8660, 6786, 8887, 6086, 8667, 8889, 6162, 6589, 8765, , 7875, 7578, 7937, 8660, 6786, 8887, 6086, 8667, 8889, 6162, 6589, 8765, 8788, (76) 17/ , 7875, 7578, 7937, 8660, 6786, 8887, 6086, 8667, 8889, 6162, 6589, 8765, 8788, No limit1All (76) 17/60215All

NDP-HAPP Summary  OD is not a priori, subject of responses of individual HH decisions  Bi-level formulation  Upper level: NDP  Lower Level: HAPP  Decomposition algorithm  Reasonable in accuracy, running time  Incorporated OD changes, TOD changes  Future Research  More sophisticated network strategies  Integration of congestion effect: Infrastructure layer  Demand Capacity: Activity layer 22

Thank you Questions or comments? 23

Illustrative example NDP-HAPP Network ◦Objective: 2 HHs: 1 HH member with 1 vehicle ◦Objective: ◦A(HH1) = {work, grocery shopping} ◦A(HH2) = {work, general shopping} H1 Work: Start [9, 9.5] For 8 hr Return before 22 Work: Start [8.5,9] For 8 hr Return before 22 H2 Grocery Shopping Start [5,20] For 1 hr Return before 22 General Shopping Start [5,21] For 1 hr Return before 22 24

Illustrative example NDP-HAPP Iteration 1Iteration 2 dHAPP1 Home (0) → work (2) → grocery shopping (5) → home (0) Objective Value: 3 Home (0) → work (2) → grocery shopping (5) → home (0) Objective Value: 3 dHAPP2 Home (5) → work (6) → general shopping (8) → home (5) Objective Value: 3 Home (5) → work (6) → general shopping (8) → home (5) Objective Value: 3 dNDP Network Design Decisions: Z01, Z12, Z25, Z30, Z36, Z43, Z54, Z36, Z78, Z85 dNDP objective value: 36 HH1 Paths link Flows: Home (0) → (2) → (5) → (4) → (3) → (0) HH2 Paths link Flows: (5) → (4) → (3) → (6) → (7) → (8) → (5) Update each dHAPP objective values: HH1: 3, HH2: 3 NA Final Objective 42 25

Illustrative example NDP-HAPP  NDP-HAPP  5% Optimality gap 26