Your search keyword '"Anthony H. DeCicco"' showing total 6 results

1. An agent-based approach to modeling airlines, customers, and policy in the U.S. Air Transportation System

Author

Brant M. Horio, Vivek Kumar, and Anthony H. DeCicco

Published

2015

2. An Integrated Framework for Modeling Air Carrier Behavior, Policy, and Impacts in the U.S. Air Transportation System

Author

Vivek Kumar, Virginia L. Stouffer, Jeremy C. Smith, Anthony H. DeCicco, Nelson M. Guerreiro, Brant M. Horio, and Shahab Hasan

Subjects

Computer science, Civil engineering, Air transportation system

Published

2015

3. Understanding Air Transportation Market Dynamics using a Search Algorithm for Calibrating Travel Demand and Price

Author

Anthony H. DeCicco, Vivek Kumar, Shahab Hasan, Nelson M. Guerreiro, Brant M. Horio, Virginia L. Stouffer, and Jeremy C. Smith

Subjects

Agent-based model, Microeconomics, Operations research, Cost estimate, Aviation, business.industry, Search algorithm, Market data, Ticket, Economics, Demand forecasting, Baseline (configuration management), business

Abstract

This paper presents a search algorithm based framework to calibrate origin-destination (O-D) market specific airline ticket demands and prices for the Air Transportation System (ATS). This framework is used for calibrating an agent based model of the air ticket buy-sell process - Airline Evolutionary Simulation (Airline EVOS) -that has fidelity of detail that accounts for airline and consumer behaviors and the interdependencies they share between themselves and the NAS. More specificially, this algorithm simultaneous calibrates demand and airfares for each O-D market, to within specified threshold of a pre-specified target value. The proposed algorithm is illustrated with market data targets provided by the Transportation System Analysis Model (TSAM) and Airline Origin and Destination Survey (DB1B). Although we specify these models and datasources for this calibration exercise, the methods described in this paper are applicable to calibrating any low-level model of the ATS to some other demand forecast model-based data. We argue that using a calibration algorithm such as the one we present here to synchronize ATS models with specialized forecast demand models, is a powerful tool for establishing credible baseline conditions in experiments analyzing the effects of proposed policy changes to the ATS.

Published

2015

4. Agent Based Modeling of Air Carrier Behavior for Evaluation of Technology Equipage and Adoption

Author

Brant M. Horio, Anthony H. DeCicco, Virginia L. Stouffer, Shahab Hasan, Rebecca L. Rosenbaum, and Jeremy C. Smith

Subjects

Transport engineering, Subject-matter expert, Schedule, National Airspace System, Engineering, Incentive, Conceptual framework, Aviation, business.industry, Next Generation Air Transportation System, Civil aviation, ComputerApplications_COMPUTERSINOTHERSYSTEMS, business

Abstract

As part of ongoing research, the National Aeronautics and Space Administration (NASA) and LMI developed a research framework to assist policymakers in identifying impacts on the U.S. air transportation system (ATS) of potential policies and technology related to the implementation of the Next Generation Air Transportation System (NextGen). This framework, called the Air Transportation System Evolutionary Simulation (ATS-EVOS), integrates multiple models into a single process flow to best simulate responses by U.S. commercial airlines and other ATS stakeholders to NextGen-related policies, and in turn, how those responses impact the ATS. Development of this framework required NASA and LMI to create an agent-based model of airline and passenger behavior. This Airline Evolutionary Simulation (AIRLINE-EVOS) models airline decisions about tactical airfare and schedule adjustments, and strategic decisions related to fleet assignments, market prices, and equipage. AIRLINE-EVOS models its own heterogeneous population of passenger agents that interact with airlines; this interaction allows the model to simulate the cycle of action-reaction as airlines compete with each other and engage passengers. We validated a baseline configuration of AIRLINE-EVOS against Airline Origin and Destination Survey (DB1B) data and subject matter expert opinion, and we verified the ATS-EVOS framework and agent behavior logic through scenario-based experiments. These experiments demonstrated AIRLINE-EVOS's capabilities in responding to an input price shock in fuel prices, and to equipage challenges in a series of analyses based on potential incentive policies for best equipped best served, optimal-wind routing, and traffic management initiative exemption concepts..

Published

2014

5. Assessment of System Safety Risks for NextGen Concepts and Technologies

Author

Robert Hemm, David A. Lee, Anthony H. DeCicco, and Brant M. Horio

Subjects

Risk analysis, Engineering, Operations research, business.industry, media_common.quotation_subject, System safety, Automation, Aviation safety, Traffic collision avoidance system, National Airspace System, Data link, Systems engineering, business, Function (engineering), media_common

Abstract

This paper reports on the research done under a National Aeronautics and Space Administration (NASA) Research Announcement task, “Assessment of System Safety Risks for NextGen Concepts and Technologies.” We describe the methods and tools used in the task and results from first-order analyses of two NextGen ground-based automation concepts. The first-order results demonstrate the ability of the assessment method developed in previous NASA research to address NextGen concepts and to link research results rigorously to systemwide risk. The method explicitly addresses response times and failures, and the results, while first-order, specifically identify the time criticality of tactical conflict detection and resolution. I. Introduction n this research, we extended and applied to automated NextGen concepts the separation assurance safety risk assessment method we developed for the NASA Research Announcement task, “Conduct Safety Analysis of the Separation Assurance Function in Today’s National Airspace System (NAS)” (Ref. 1). As in our previous work, we addressed the task objective in two ways. First, we established functional and quantitative frameworks to allow integration of the results of all forms of safety and risk research into a single risk assessment. Second, we identified sources of data and developed and tested modeling tools to demonstrate the feasibility of our analysis approach. We conducted first-order risk assessments of two NextGen concepts: a Ground-Automation Controlled (GAC) concept based on the Advanced Airspace Concept (AAC) proposed by Erzberger in Ref. 2, and a near-term GroundAutomation Assisted (GAA) concept based on the concept proposed by McNally et al. in Ref. 3. Both concepts are based on managing traffic with ground-based automation using data link communications to control aircraft on timebased four-dimensional trajectories (4DTs). This paper describes analysis of the fully operational concepts plus two abnormal conditions. The first abnormal condition is a loss of intent data condition, which could be caused by a weather or emergency disruption leading to open 4DTs or by a hardware failure leading to loss of transmitted intent data; the second is a single aircraft inoperative transponder condition, which could be caused by hardware failure or by being turned off. Both concepts include a ground-based strategic element, a ground-based tactical element, an airborne Traffic Alert and Collision Avoidance System (TCAS) element, and an airborne see-and-avoid element. The AAC concept includes a monitoring human controller element, while the human-based GAA concept includes an active human controller in the strategic and tactical elements. The paper is organized as follows: 1) Section II presents our aviation safety risk analysis method and introduces the two NextGen concepts assessed. 2) Section III discusses the conflict modeling tool and the conflict probability data used for the risk assessments.

Published

2012

6. Safety risk assessment case study using Airspace Conflict Analysis Simulation

Author

Robert Hemm, Brant M. Horio, and Anthony H. DeCicco

Subjects

Engineering, Safety risk, business.industry, Aerospace simulation, Next Generation Air Transportation System, Simulation modeling, Systems engineering, Solid modeling, business, Conflict analysis, Risk management, Visualization

Abstract

The concepts, operating paradigms, and required technologies of the Next Generation Air Transportation System (NextGen) are still evolving. These continuing changes highlight a need for a modeling platform that can effectively address the complexity of diverse future scenarios and help assess their impact on safety. We discuss this need in detail with respect to the requirements and benefits of such a flexible modeling platform. We describe the LMI ACAS (Airspace Conflict Analysis Simulation) tool, a simulation modeling framework with 3-dimensional visualization, and we show how such an application can meet these analytical requirements and discuss the benefits of implementing a multi-dimensional visualization.

Published

2012