Your search keyword '"Malikopoulos, Andreas A."' showing total 6 results

1. Optimal Control of Connected and Automated Vehicles at Multiple Adjacent Intersections.

Author

Chalaki, Behdad and Malikopoulos, Andreas A.

Subjects

AUTONOMOUS vehicles, SIGNALIZED intersections, ENERGY consumption, ROAD interchanges & intersections, TRAFFIC lanes, ACCELERATION (Mechanics)

Abstract

In this article, we establish a decentralized optimal control framework for connected and automated vehicles (CAVs) crossing multiple adjacent, multilane signal-free intersections to minimize energy consumption and improve traffic throughput. Our framework consists of two layers of planning. In the upper level planning, each CAV computes its optimal arrival time at each intersection recursively along with the optimal lane to improve the traffic throughput. In the low-level planning, we formulate an energy-optimal control problem with interior-point constraints, the solution of which yields the optimal control input (acceleration/deceleration) of each CAV to cross the intersections at the time specified by the upper level planning. Moreover, we extend the results of the proposed bi-level framework to include a bounded steady-state error in tracking the optimal position of the CAVs. Finally, we demonstrate the effectiveness of the proposed framework through simulation for symmetric and asymmetric intersections and comparison with traditional signalized intersections. [ABSTRACT FROM AUTHOR]

Published

2022

2. A decentralized energy-optimal control framework for connected automated vehicles at signal-free intersections.

Author

Malikopoulos, Andreas A., Cassandras, Christos G., and Zhang, Yue J.

Subjects

*TRAFFIC signs & signals, *ROAD interchanges & intersections, *ENERGY consumption, *OPTIMAL control theory, *CONSTRAINT satisfaction

Abstract

We address the problem of optimally controlling connected and automated vehicles (CAVs) crossing an urban intersection without any explicit traffic signaling, so as to minimize energy consumption subject to a throughput maximization requirement. We show that the solution of the throughput maximization problem depends only on the hard safety constraints imposed on CAVs and its structure enables a decentralized optimal control problem formulation for energy minimization. We present a complete analytical solution of these decentralized problems and derive conditions under which feasible solutions satisfying all safety constraints always exist. The effectiveness of the proposed solution is illustrated through simulation which shows substantial dual benefits of the proposed decentralized framework by allowing CAVs to conserve momentum and fuel while also improving travel time. [ABSTRACT FROM AUTHOR]

Published

2018

3. A Consumer-Oriented Control Framework for Performance Analysis in Hybrid Electric Vehicles.

Author

Shaltout, Mohamed L., Malikopoulos, Andreas A., Pannala, Sreekanth, and Chen, Dongmei

Subjects

HYBRID electric vehicles, ELECTRIC batteries, ENERGY management, ENERGY consumption, PERFORMANCE standards

Abstract

Hybrid electric vehicles (HEVs) have attracted considerable attention due to their potential to reduce fuel consumption and emissions. The objective of this paper is to enhance our understanding of the associated tradeoffs among the HEV subsystems, e.g., the engine, the motor, and the battery, and investigate the related implications for fuel consumption and battery capacity and lifetime. Addressing this problem can provide insights on how to prioritize these objectives based on consumers’ needs and preferences. The results of the proposed optimization approach can also be used to investigate the implications for HEV costs related to ownership and warranty. [ABSTRACT FROM PUBLISHER]

Published

2015

4. Conditions to provable system-wide optimal coordination of connected and automated vehicles.

Author

Mahbub, A.M. Ishtiaque and Malikopoulos, Andreas A.

Subjects

*AUTONOMOUS vehicles, *TRAFFIC flow, *ANALYTICAL solutions, *ENERGY consumption, *COMPUTER simulation

Abstract

Connected and automated vehicles (CAVs) provide the most intriguing opportunity to improve energy efficiency, traffic flow, and safety. In earlier work, we addressed the constrained optimal coordination problem of CAVs at different traffic scenarios using Hamiltonian analysis. In this paper, we investigate the properties of the unconstrained problem and provide conditions under which different combination of the state and control constraints become active. We present a condition-based computational framework that improves on the standard iterative solution procedure of the constrained Hamiltonian analysis. Finally, we derive a closed-form analytical solution of the constrained optimal control problem and validate the proposed framework using numerical simulation. The solution can be derived without any recursive steps, and thus it is appropriate for real-time implementation on-board the CAVs. [ABSTRACT FROM AUTHOR]

Published

2021

5. Decentralized optimal coordination of connected and automated vehicles for multiple traffic scenarios.

Author

Mahbub, A.M. Ishtiaque, Malikopoulos, Andreas A., and Zhao, Liuhui

Subjects

*SIGNALIZED intersections, *ENERGY consumption, *TRAFFIC flow, *ANALYTICAL solutions, *ROAD interchanges & intersections, *VEHICLES

Abstract

Connected and automated vehicles (CAVs) provide the most intriguing opportunity to optimize energy consumption and travel time. Several approaches have been proposed in the literature that allow CAVs to coordinate in situations where there is a potential conflict, for example, in signalized intersections, merging at roadways and roundabouts, to reduce energy consumption and optimize traffic flow. In this paper, we consider the problem of coordinating CAVs in a corridor consisting of multiple traffic scenarios. We formulate a two-level optimization problem in which we maximize traffic throughput in the upper-level problem, and derive a closed-form analytical solution that yields the optimal control input for each CAV, in terms of fuel consumption, in the low-level problem. We validate the effectiveness of the solution through simulation under 100% CAV penetration rate. Fuel consumption and travel time for the vehicles are significantly reduced compared to a baseline scenario consisting of human-driven vehicles. [ABSTRACT FROM AUTHOR]

Published

2020

6. A modeling framework for optimal energy management of a residential building.

Author

Sharma, Isha, Dong, Jin, Malikopoulos, Andreas A., Street, Michael, Ostrowski, Jim, Kuruganti, Teja, and Jackson, Roderick

Subjects

*ENERGY management, *DWELLINGS, *PREDICTIVE control systems, *ENERGY consumption, *MATHEMATICAL models, *MICROGRIDS

Abstract

Residential buildings are currently equipped with energy production facilities, e.g., solar rooftops and batteries, which in conjunction with smart meters, can function as smart energy hubs coordinating the loads and the resources in an optimal manner. This paper presents a mathematical model for the optimal energy management of a residential building and proposes a centralized energy management system (CEMS) framework for off-grid operation. The model of each component of the hub is integrated within the CEMS. The optimal decisions are determined in real-time by considering these models with realistic parameter settings and customer preferences. Model predictive control (MPC) is used to adapt the optimal decisions on a receding horizon to account for the deviations in the system inputs. Simulation results are presented to demonstrate the feasibility and effectiveness of the proposed CEMS framework. Results show that the proposed CEMS can reduce the energy cost and energy consumption of the customers by approximately 17% and 8%, respectively, over a day. Using the proposed CEMS, the total charging cycles of the ESS were reduced by more than 50% in a day. [ABSTRACT FROM AUTHOR]

Published

2016