Design and Optimization of Shared Mobility on Demand
Design and Optimization of Shared Mobility on Demand

Author: Yue Guan (Ph. D.)

Publisher:

Published: 2021

Total Pages: 192

ISBN-13:

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Mobility of people and goods has been critical to urban life ever since cities emerged thousands of years ago. With the ushering in Cyber-Physical Systems enabled by the development of smart mobile devices, telecommunication technologies, as well as affordable, accessible and powerful computing resources, new paradigms are revolutionizing urban mobility. Among these, Shared Mobility on Demand Service (SMoDS) has changed the landscape of urban transportation, providing alternatives with a customized combination of affordability, flexibility, and carbon footprint. Dynamic routing and dynamic pricing are two central pillars of an SMoDS solution, where the former offers customized routes according to the specific passenger request and real time traffic conditions, and the latter provides incentive signals that appropriately influence the passengers’ subscription of the service. Although emerging SMoDS solutions have seen remarkable successes, further improvements are in need. In this thesis, we present an integrated SMoDS design with dynamic routing and dynamic pricing that introduces two major improvements over the state of the art: (i) enhanced optimality in travel times through dynamic routing with added spatial flexibility, and (ii) explicit accommodation of behavioral modelling of empowered passengers so as to lead to an accurate dynamic pricing strategy. The first part of this thesis focuses on the development of the dynamic routing framework with a new concept of space window. To accommodate the complexity introduced by space window in the optimization of dynamic routes, we propose an algorithm based upon the Alternating Minimization (AltMin) paradigm, and demonstrate an order of magnitude improvement in computational efficiency compared to benchmarks provided by standard solvers. The second part of this thesis, related to dynamic pricing, is broken down into two modules, with the first related to behavioral modelling of empowered passengers based on Cumulative Prospect Theory (CPT). The CPT based behavioral model is able to capture the subjective and potentially irrational behaviors of passengers when deciding upon the SMoDS ride offer amidst uncertainties and risks associated with framing effects, loss aversion, diminishing sensitivity, and probability distortion. Key properties and the implications of the CPT based passenger behavioral model on dynamic pricing are discussed in detail. The second module of dynamic pricing determines the desired probability of acceptance from each passenger so as to optimize key performance indicators of the SMoDS such as the estimated waiting time. A Reinforcement Learning (RL) based approach combined with the problem formulation in the form of a Markov Decision Process (MDP) is used to estimate this desired probability of acceptance. The proposed RL algorithm deploys an integrated planning and learning architecture where the planning phase is carried out by a lookahead tree search, and the learning phase is achieved via value iteration using a neural network as the value function approximator. Two major challenges that arise in this context is the varying dimension of the underlying state and the arrival of information in a sequential manner where long-term dependency needs to be preserved. These are addressed through the incorporation of Long Short-Term Memory (LSTM), convolutional and fully-connected layers. Their judicious incorporation in the underlying neural network architecture allows the extraction of this information and successful estimation of the desired probability of acceptance that leads to the optimization of the SMoDS. A number of computational experiments are carried out using various datasets of large-scale problems and are shown to result in a superior capability of the proposed RL algorithm.

Shared Mobility on Demand System Design
Shared Mobility on Demand System Design

Author: Mohammad Abdollahi (Industrial engineer)

Publisher:

Published: 2021

Total Pages: 0

ISBN-13:

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Tomorrows mobility will be radically different. Connected, Autonomous, Shared, and Electric Mobility are four main developments that are dramatically altering the automobile industry. We study the shared centralized class of mobility problems which considers a platform of self driving cars. There are new challenges with these systems such as how to balance the idle vehicle, how to price the shared autonomous system, and etc. We are attempting to address the question of how to share passengers ride to maximize satisfaction for riders, and the platform itself. Besides that, to have a good ETA estimate for trips, we develop a data-driven travel time prediction algorithm which can be used in our platform to get a good estimate for scheduling and routing the rides. Finally, we also study the pricing mechanism of these systems using a deep reinforcement learning agent that simulates the rides in New York. We start by studying both static and dynamic (real-time) ride pooling problem with time windows, multiple homogeneous/heterogeneous vehicles, passenger convenience and other business considerations. First, the problems under consideration is modeled as two different static MILP for homogeneous/heterogeneous fleet of vehicles, and also a constraint programming counterpart is provided for the heterogeneous vehicles case. Also to improve the linear relaxation of these models, several pre-processing steps and lifting inequalities are applied. While appealing, exact formulations have integer variables which render them as non-convex optimization problems. Thus, while this approach offers the benefit of system optimality, its formulation here is NP-hard, making it not viable for real world problems. To find a good quality solution, a heuristic decomposition algorithm based on constraint programming and branch and price is proposed to solve static model within a reasonable time for implementation in a real-world situation. Computational results show that the heuristic algorithms are superior compared to the exact algorithms in terms of the calculation time as the problem size (in terms of the number of requests) increases. In phase 2 of this dissertation, we propose a travel time predictive model by developing a integrated multi-step approach to learn the feature space. This multi stage algorithm is initiated by pre-processing task. Subsequently, the feature set is obtained by incorporating some publicly available information. Moreover, a feature engineer ing path is proposed to improve the feature space. This path includes Principal Component Analysis (PCA), geospatial features analysis, and unsupervised learning methods like K-Means and stacked autoencoders. Finally we apply a customized gradient boosting method to estimate travel times and comparing our results with LSTM network which shows superiority of our method in terms of capturing dynamics of traffic through time. Although more data with rare events need to be added in case of experiencing heavy snow or other events which magnifies travel times. Lastly, we developed a fleet management simulation platform where we model pricing problem as a partially observable Markov decision process (POMDP), and DQN agent is developed to estimate fares as a function of real-time interaction with the environment. Fare prices are considered to be continuous and stochastic variables, but for simplicity we have price adjustment in discrete units, and we determine them using a deep neural network (DNN). We compare our algorithm with the one for ride hailing system and see if our pricing mechanism can decrease rejections and cancellation and increase system objective as well as passengers0́9 utility. We illustrate the usefulness of our algorithm by applying it to real-world transportation problem and show that it learns fare estimates to minimize total travel time, maximize revenue, and other weighted objectives. Collectively, this work can be used for designing a ride sharing system of autonomous vehicles in which a controller module with many different predictive and prescriptive analytics engines dispatches vehicles and broadcasts ride fares to optimize system and riders utility.

Service Network Design of Bike Sharing Systems
Service Network Design of Bike Sharing Systems

Author: Patrick Vogel

Publisher: Springer

Published: 2016-04-13

Total Pages: 172

ISBN-13: 3319277359

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This monograph presents a tactical planning approach for service network design in metropolitan areas. Designing the service network requires the suitable aggregation of demand data as well as the anticipation of operational relocation decisions. To this end, an integrated approach of data analysis and mathematical optimization is introduced. The book also includes a case study based on real-world data to demonstrate the benefit of the proposed service network design approach. The target audience comprises primarily research experts in the field of traffic engineering, but the book may also be beneficial for graduate students.

Simulation-based Design of Integrated Public Transit and Shared Autonomous Mobility-on-demand Systems
Simulation-based Design of Integrated Public Transit and Shared Autonomous Mobility-on-demand Systems

Author: Yu Xin Leo Chen

Publisher:

Published: 2018

Total Pages: 97

ISBN-13:

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The autonomous vehicle (AV) is poised to be one of the most disruptive technologies in the transportation industry. The advent of three major trends in transportation: automation, on-demand mobility and ride-sharing, are set to revolutionize the way we travel. The forthcoming adoption and commercialization of AVs are expected to have extensive impacts on our road networks, congestion, safety, land use, public transportation (PT) and more. Rapid advances in AV technology are convincing many that AV services will play a significant role in future transportation systems. The advancement of AVs presents both opportunities and threats to transportation. It has the potential to significantly impact traffic congestion, traffic accidents, parking and VMT (vehicle miles traveled), especially for people that are not able to drive such as children and elderly people. Motivated by the potential of autonomous vehicles, authorities around the world are preparing for this revolution in transport and deems this an important research direction that requires significant investigation. This thesis tackled and contributed to three main research questions related to the impact of autonomous vehicles on transportation systems. First, this thesis proposes a simulation-based approach to the design and evaluation of integrated autonomous vehicle and public transportation systems. We highlight the transit-orientation by respecting the social-purpose considerations of transit agencies (such as maintaining service availability and ensuring equity) and identifying the synergistic opportunities between AV and PT. Specifically, we identified that AV has a strong potential to serve first-mile connections to the PT stations and provide efficient and affordable shared mobility in low-density suburban areas that are typically inefficient to serve by conventional fixed-route PT services. The design decisions reflect the interest of multiple stakeholders in the system. Second, the interaction between travelers (demand) and operators (supply) is modeled using a system of equations that is solved as a fixed-point problem through an iterative procedure. In this, we developed demand and supply as two sub-problems. The demand will be predicted using a nested logit model to estimate the volume for different modes based on modal attributes. The supply will use a simulation platform capable of incorporating critical operational decisions on factors including fleet sizes, vehicle capacities, sharing policies, fare schemes and hailing strategies such as in-advance and on-demand requests. Using feedback between demand and supply, we enable interactions between the decisions of the service operator and those of the travelers, in order to model the choices of both parties. Finally, this thesis systematically optimizes service design variables to determine the best outcome in accordance to AV+PT stakeholder goals. Optimization objective functions can be formulated to reflect the different objectives of different stakeholders. In this paper, we specifically propose and develop a simulation-based service design method where we quantify various benefits and costs to reflect the objectives of key AV+PT stakeholders. We simulate the service with different sets of system settings and identify the highest performing set. We employ a case study of regional service contracting to showcase the ability of this method to inform AV+PT service design. We tested our approach with a case study area in a major European city on an agent-based simulation platform, amod-abm. Agent-based simulation has the advantage of capturing individual (agent) behaviors and the interactions of the various individual agents in a realistic synthetic environment where the intent is to re-create a complex phenomenon of mobility on demand service delivered by AV. Although this thesis will focus on a major European city, the general framework and methodologies proposed here can be widely applicable. The thesis concludes that the demand-supply interaction can be effective for designing and assessing the role of AV technology in our mobility systems. Moreover, simulation-based optimization can be an effective method for transit agencies to make decisions that support their overall AV related transport strategy as well as operational planning.

Car-sharing Mobility-on-Demand Systems
Car-sharing Mobility-on-Demand Systems

Author: Ge Guo

Publisher: SAE International

Published: 2022-08-24

Total Pages: 18

ISBN-13: 1468604937

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One-way car-sharing services (CSSs) are believed to be a promising transportation mode for urban mobility. Due to the disparity of city functional areas and population, travel demand and vehicle supply in a CSS may inevitably tend to be imbalanced as well. Therefore, an essential requirement of one-way CSSs is the capability of providing fleet management solutions to improve quality of service and system performance. In other words, a CSS depends heavily on technologies that offer strategic decisions on topics like Fleet sizing Location and capacity of depots and charging stations Matching of travelers with vehicles Relocation of vehicles and dispatchers for fleet rebalancing Balancing and charging schedules of electric vehicles Car-sharing Mobility-on-Demand Systems addresses trending CSS technologies and outlines some insights into the existing unsettled issues and potential solutions. The discussions and outlook are presented as a collection of key points encountered in system planning, configuration, and especially fleet operation. In doing so, the focus is on innovation in technologies, policies, operations, and regulations that impact operators, users, and transport management authorities. Click here to access the full SAE EDGETM Research Report portfolio. https://doi.org/10.4271/EPR2022018

Network Design And Optimization For Smart Cities
Network Design And Optimization For Smart Cities

Author: Panos M Pardalos

Publisher: World Scientific

Published: 2017-05-03

Total Pages: 402

ISBN-13: 9813200022

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This comprehensive reference text is a collection of important research findings on the latest developments in network modeling for optimization of smart cities. Such models can be used from outlining the fundamental concepts of urban development to the description and optimization of physical networks, such as power, water or telecommunications. Networks help us understand city economics and various aspects of human interactions within cities with particular applications in quality of life and the flow of people and goods. Finally, the natural environment and even the climate of cities can be modeled and managed as networks.

Public Transportation Systems: Principles Of System Design, Operations Planning And Real-time Control
Public Transportation Systems: Principles Of System Design, Operations Planning And Real-time Control

Author: Carlos F Daganzo

Publisher: World Scientific

Published: 2019-03-20

Total Pages: 512

ISBN-13: 9813224118

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This unique book explains how to think systematically about public transportation through the lens of physics models. The book includes aspects of system design, resource management, operations and control. It presents both, basic theories that reveal fundamental issues, and practical recipes that can be readily used for real-world applications. The principles conveyed in this book cover not only traditional transit modes such as subways, buses and taxis but also the newer mobility services that are being enabled by advances in telematics and robotics.Although the book is rigorous, it includes numerous exercises and a presentation style suitable for senior undergraduate or entry-level graduate students in engineering. The book can also serve as a reference for transportation professionals and researchers keen in this field.

Leverage Data Streams for Better Operational Decision-Making
Leverage Data Streams for Better Operational Decision-Making

Author: Christoph Prinz

Publisher: Cuvillier Verlag

Published: 2023-05-31

Total Pages: 236

ISBN-13: 3736968027

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Smart sustainable mobility ecosystems promise to address society’s expectation of environmentally friendly on-demand mobility. While the technology stack to build such ecosystems is just around the corner in the form of connected, automated, and electric vehicles, strategies to deploy and operate such fleets in a coordinated manner must still be advanced. Most of such optimization challenges highly depend on the nature of customer demand, vehicle supply, and environmental influences. Hence, this dissertation investigates how available data streams from mobility ecosystems can be leveraged in Information Systems to solve related decision problems. The overarching goal of this work is to generate design knowledge to improve vehicle availability, provider profitability, and environmental sustainability for such ecosystems. Applying quantitative methods to real-world data from shared vehicle systems generates insights into the nature of demand and supply. Combining it with an analysis of empirical research on vehicle relocation algorithms builds the foundation for two artifact designs. The first artifact enables the development and simulation-based evaluation of operation modes for vehicle fleets. The second artifact enables artificial intelligence-based decision support for the vehicle rebalancing problem. The insights are finally incorporated and generalized to a nascent design theory on data-enabled operational decision-making in the context of smart sustainable mobility environments. The findings have multifaceted implications for researchers concerned with data-enabled value creation in Green IS, shared economy and smart mobility, and business analytics and data science. Furthermore, guidance for fleet providers to improve system attractiveness and for society to experience the potential amount of vehicle access without personal ownership is provided.

The Multi-Agent Transport Simulation MATSim
The Multi-Agent Transport Simulation MATSim

Author: Andreas Horni

Publisher: Ubiquity Press

Published: 2016-08-10

Total Pages: 620

ISBN-13: 190918876X

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The MATSim (Multi-Agent Transport Simulation) software project was started around 2006 with the goal of generating traffic and congestion patterns by following individual synthetic travelers through their daily or weekly activity programme. It has since then evolved from a collection of stand-alone C++ programs to an integrated Java-based framework which is publicly hosted, open-source available, automatically regression tested. It is currently used by about 40 groups throughout the world. This book takes stock of the current status. The first part of the book gives an introduction to the most important concepts, with the intention of enabling a potential user to set up and run basic simulations. The second part of the book describes how the basic functionality can be extended, for example by adding schedule-based public transit, electric or autonomous cars, paratransit, or within-day replanning. For each extension, the text provides pointers to the additional documentation and to the code base. It is also discussed how people with appropriate Java programming skills can write their own extensions, and plug them into the MATSim core. The project has started from the basic idea that traffic is a consequence of human behavior, and thus humans and their behavior should be the starting point of all modelling, and with the intuition that when simulations with 100 million particles are possible in computational physics, then behavior-oriented simulations with 10 million travelers should be possible in travel behavior research. The initial implementations thus combined concepts from computational physics and complex adaptive systems with concepts from travel behavior research. The third part of the book looks at theoretical concepts that are able to describe important aspects of the simulation system; for example, under certain conditions the code becomes a Monte Carlo engine sampling from a discrete choice model. Another important aspect is the interpretation of the MATSim score as utility in the microeconomic sense, opening up a connection to benefit cost analysis. Finally, the book collects use cases as they have been undertaken with MATSim. All current users of MATSim were invited to submit their work, and many followed with sometimes crisp and short and sometimes longer contributions, always with pointers to additional references. We hope that the book will become an invitation to explore, to build and to extend agent-based modeling of travel behavior from the stable and well tested core of MATSim documented here.

Shared Mobility and Automated Vehicles
Shared Mobility and Automated Vehicles

Author: Ata M. Khan

Publisher: IET

Published: 2021-12-21

Total Pages: 519

ISBN-13: 1785618628

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Shared mobility is gaining increasing attention in private and public sectors. Serving as a source of information on how best to shape shared vehicle systems of the future, this book contributes knowledge on key facets of shared mobility. It includes shared vehicle systems as well as shared automated vehicle systems.