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1. Transformer-based Model Predictive Control: Trajectory Optimization via Sequence Modeling

Author

Celestini, Davide, Gammelli, Daniele, Guffanti, Tommaso, D'Amico, Simone, Capello, Elisa, and Pavone, Marco

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Mathematics - Optimization and Control
Abstract

Model predictive control (MPC) has established itself as the primary methodology for constrained control, enabling general-purpose robot autonomy in diverse real-world scenarios. However, for most problems of interest, MPC relies on the recursive solution of highly non-convex trajectory optimization problems, leading to high computational complexity and strong dependency on initialization. In this work, we present a unified framework to combine the main strengths of optimization-based and learning-based methods for MPC. Our approach entails embedding high-capacity, transformer-based neural network models within the optimization process for trajectory generation, whereby the transformer provides a near-optimal initial guess, or target plan, to a non-convex optimization problem. Our experiments, performed in simulation and the real world onboard a free flyer platform, demonstrate the capabilities of our framework to improve MPC convergence and runtime. Compared to purely optimization-based approaches, results show that our approach can improve trajectory generation performance by up to 75%, reduce the number of solver iterations by up to 45%, and improve overall MPC runtime by 7x without loss in performance., Comment: 8 pages, 7 figures. Datasets, videos and code available at: https://transformermpc.github.io

Published
2024
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2. Generalizable Spacecraft Trajectory Generation via Multimodal Learning with Transformers

Author

Celestini, Davide, Afsharrad, Amirhossein, Gammelli, Daniele, Guffanti, Tommaso, Zardini, Gioele, Lall, Sanjay, Capello, Elisa, D'Amico, Simone, and Pavone, Marco

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Mathematics - Optimization and Control
Abstract

Effective trajectory generation is essential for reliable on-board spacecraft autonomy. Among other approaches, learning-based warm-starting represents an appealing paradigm for solving the trajectory generation problem, effectively combining the benefits of optimization- and data-driven methods. Current approaches for learning-based trajectory generation often focus on fixed, single-scenario environments, where key scene characteristics, such as obstacle positions or final-time requirements, remain constant across problem instances. However, practical trajectory generation requires the scenario to be frequently reconfigured, making the single-scenario approach a potentially impractical solution. To address this challenge, we present a novel trajectory generation framework that generalizes across diverse problem configurations, by leveraging high-capacity transformer neural networks capable of learning from multimodal data sources. Specifically, our approach integrates transformer-based neural network models into the trajectory optimization process, encoding both scene-level information (e.g., obstacle locations, initial and goal states) and trajectory-level constraints (e.g., time bounds, fuel consumption targets) via multimodal representations. The transformer network then generates near-optimal initial guesses for non-convex optimization problems, significantly enhancing convergence speed and performance. The framework is validated through extensive simulations and real-world experiments on a free-flyer platform, achieving up to 30% cost improvement and 80% reduction in infeasible cases with respect to traditional approaches, and demonstrating robust generalization across diverse scenario variations., Comment: 8 pages, 6 figures, submitted to 2025 American Control Conference (ACC)

Published
2024

3. Offline Hierarchical Reinforcement Learning via Inverse Optimization

Author

Schmidt, Carolin, Gammelli, Daniele, Harrison, James, Pavone, Marco, and Rodrigues, Filipe

Subjects
Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control, Mathematics - Optimization and Control
Abstract

Hierarchical policies enable strong performance in many sequential decision-making problems, such as those with high-dimensional action spaces, those requiring long-horizon planning, and settings with sparse rewards. However, learning hierarchical policies from static offline datasets presents a significant challenge. Crucially, actions taken by higher-level policies may not be directly observable within hierarchical controllers, and the offline dataset might have been generated using a different policy structure, hindering the use of standard offline learning algorithms. In this work, we propose OHIO: a framework for offline reinforcement learning (RL) of hierarchical policies. Our framework leverages knowledge of the policy structure to solve the inverse problem, recovering the unobservable high-level actions that likely generated the observed data under our hierarchical policy. This approach constructs a dataset suitable for off-the-shelf offline training. We demonstrate our framework on robotic and network optimization problems and show that it substantially outperforms end-to-end RL methods and improves robustness. We investigate a variety of instantiations of our framework, both in direct deployment of policies trained offline and when online fine-tuning is performed.

Published
2024

4. Towards Robust Spacecraft Trajectory Optimization via Transformers

Author

Takubo, Yuji, Guffanti, Tommaso, Gammelli, Daniele, Pavone, Marco, and D'Amico, Simone

Subjects
Mathematics - Optimization and Control, Computer Science - Artificial Intelligence, Computer Science - Robotics
Abstract

Future multi-spacecraft missions require robust autonomous trajectory optimization capabilities to ensure safe and efficient rendezvous operations. This capability hinges on solving non-convex optimal control problems in real time, although traditional iterative methods such as sequential convex programming impose significant computational challenges. To mitigate this burden, the Autonomous Rendezvous Transformer introduced a generative model trained to provide near-optimal initial guesses. This approach provides convergence to better local optima (e.g., fuel optimality), improves feasibility rates, and results in faster convergence speed of optimization algorithms through warm-starting. This work extends the capabilities of ART to address robust chance-constrained optimal control problems. Specifically, ART is applied to challenging rendezvous scenarios in Low Earth Orbit (LEO), ensuring fault-tolerant behavior under uncertainty. Through extensive experimentation, the proposed warm-starting strategy is shown to consistently produce high-quality reference trajectories, achieving up to 30% cost improvement and 50% reduction in infeasible cases compared to conventional methods, demonstrating robust performance across multiple state representations. Additionally, a post hoc evaluation framework is proposed to assess the quality of generated trajectories and mitigate runtime failures, marking an initial step toward the reliable deployment of AI-driven solutions in safety-critical autonomous systems such as spacecraft., Comment: Submitted to the IEEE Aerospace Conference 2025. 13 pages, 10 figures

Published
2024

5. Adapting a Foundation Model for Space-based Tasks

Author

Foutter, Matthew, Bhoj, Praneet, Sinha, Rohan, Elhafsi, Amine, Banerjee, Somrita, Agia, Christopher, Kruger, Justin, Guffanti, Tommaso, Gammelli, Daniele, D'Amico, Simone, and Pavone, Marco

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

Foundation models, e.g., large language models, possess attributes of intelligence which offer promise to endow a robot with the contextual understanding necessary to navigate complex, unstructured tasks in the wild. In the future of space robotics, we see three core challenges which motivate the use of a foundation model adapted to space-based applications: 1) Scalability of ground-in-the-loop operations; 2) Generalizing prior knowledge to novel environments; and 3) Multi-modality in tasks and sensor data. Therefore, as a first-step towards building a foundation model for space-based applications, we automatically label the AI4Mars dataset to curate a language annotated dataset of visual-question-answer tuples. We fine-tune a pretrained LLaVA checkpoint on this dataset to endow a vision-language model with the ability to perform spatial reasoning and navigation on Mars' surface. In this work, we demonstrate that 1) existing vision-language models are deficient visual reasoners in space-based applications, and 2) fine-tuning a vision-language model on extraterrestrial data significantly improves the quality of responses even with a limited training dataset of only a few thousand samples.

Published
2024

6. Real-time Control of Electric Autonomous Mobility-on-Demand Systems via Graph Reinforcement Learning

Author

Singhal, Aaryan, Gammelli, Daniele, Luke, Justin, Gopalakrishnan, Karthik, Helmreich, Dominik, and Pavone, Marco

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Machine Learning, Computer Science - Robotics
Abstract

Operators of Electric Autonomous Mobility-on-Demand (E-AMoD) fleets need to make several real-time decisions such as matching available vehicles to ride requests, rebalancing idle vehicles to areas of high demand, and charging vehicles to ensure sufficient range. While this problem can be posed as a linear program that optimizes flows over a space-charge-time graph, the size of the resulting optimization problem does not allow for real-time implementation in realistic settings. In this work, we present the E-AMoD control problem through the lens of reinforcement learning and propose a graph network-based framework to achieve drastically improved scalability and superior performance over heuristics. Specifically, we adopt a bi-level formulation where we (1) leverage a graph network-based RL agent to specify a desired next state in the space-charge graph, and (2) solve more tractable linear programs to best achieve the desired state while ensuring feasibility. Experiments using real-world data from San Francisco and New York City show that our approach achieves up to 89% of the profits of the theoretically-optimal solution while achieving more than a 100x speedup in computational time. We further highlight promising zero-shot transfer capabilities of our learned policy on tasks such as inter-city generalization and service area expansion, thus showing the utility, scalability, and flexibility of our framework. Finally, our approach outperforms the best domain-specific heuristics with comparable runtimes, with an increase in profits by up to 3.2x., Comment: 9 pages, revised SF travel data, includes additional experimental results, content and clarification revisions per reviewer feedback, and typo fixes

Published
2023
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7. Transformers for Trajectory Optimization with Application to Spacecraft Rendezvous

Author

Guffanti, Tommaso, Gammelli, Daniele, D'Amico, Simone, and Pavone, Marco

Subjects
Computer Science - Robotics
Abstract

Reliable and efficient trajectory optimization methods are a fundamental need for autonomous dynamical systems, effectively enabling applications including rocket landing, hypersonic reentry, spacecraft rendezvous, and docking. Within such safety-critical application areas, the complexity of the emerging trajectory optimization problems has motivated the application of AI-based techniques to enhance the performance of traditional approaches. However, current AI-based methods either attempt to fully replace traditional control algorithms, thus lacking constraint satisfaction guarantees and incurring in expensive simulation, or aim to solely imitate the behavior of traditional methods via supervised learning. To address these limitations, this paper proposes the Autonomous Rendezvous Transformer (ART) and assesses the capability of modern generative models to solve complex trajectory optimization problems, both from a forecasting and control standpoint. Specifically, this work assesses the capabilities of Transformers to (i) learn near-optimal policies from previously collected data, and (ii) warm-start a sequential optimizer for the solution of non-convex optimal control problems, thus guaranteeing hard constraint satisfaction. From a forecasting perspective, results highlight how ART outperforms other learning-based architectures at predicting known fuel-optimal trajectories. From a control perspective, empirical analyses show how policies learned through Transformers are able to generate near-optimal warm-starts, achieving trajectories that are (i) more fuel-efficient, (ii) obtained in fewer sequential optimizer iterations, and (iii) computed with an overall runtime comparable to benchmarks based on convex optimization., Comment: Presented in 2024 IEEE Aerospace Conference

Published
2023

8. Graph Reinforcement Learning for Network Control via Bi-Level Optimization

Author

Gammelli, Daniele, Harrison, James, Yang, Kaidi, Pavone, Marco, Rodrigues, Filipe, and Pereira, Francisco C.

Subjects
Computer Science - Machine Learning, Electrical Engineering and Systems Science - Systems and Control, Mathematics - Optimization and Control
Abstract

Optimization problems over dynamic networks have been extensively studied and widely used in the past decades to formulate numerous real-world problems. However, (1) traditional optimization-based approaches do not scale to large networks, and (2) the design of good heuristics or approximation algorithms often requires significant manual trial-and-error. In this work, we argue that data-driven strategies can automate this process and learn efficient algorithms without compromising optimality. To do so, we present network control problems through the lens of reinforcement learning and propose a graph network-based framework to handle a broad class of problems. Instead of naively computing actions over high-dimensional graph elements, e.g., edges, we propose a bi-level formulation where we (1) specify a desired next state via RL, and (2) solve a convex program to best achieve it, leading to drastically improved scalability and performance. We further highlight a collection of desirable features to system designers, investigate design decisions, and present experiments on real-world control problems showing the utility, scalability, and flexibility of our framework., Comment: 9 pages, 4 figures

Published
2023

9. Learning to Control Autonomous Fleets from Observation via Offline Reinforcement Learning

Author

Schmidt, Carolin, Gammelli, Daniele, Pereira, Francisco Camara, and Rodrigues, Filipe

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Machine Learning, Computer Science - Robotics
Abstract

Autonomous Mobility-on-Demand (AMoD) systems are an evolving mode of transportation in which a centrally coordinated fleet of self-driving vehicles dynamically serves travel requests. The control of these systems is typically formulated as a large network optimization problem, and reinforcement learning (RL) has recently emerged as a promising approach to solve the open challenges in this space. Recent centralized RL approaches focus on learning from online data, ignoring the per-sample-cost of interactions within real-world transportation systems. To address these limitations, we propose to formalize the control of AMoD systems through the lens of offline reinforcement learning and learn effective control strategies using solely offline data, which is readily available to current mobility operators. We further investigate design decisions and provide empirical evidence based on data from real-world mobility systems showing how offline learning allows to recover AMoD control policies that (i) exhibit performance on par with online methods, (ii) allow for sample-efficient online fine-tuning and (iii) eliminate the need for complex simulation environments. Crucially, this paper demonstrates that offline RL is a promising paradigm for the application of RL-based solutions within economically-critical systems, such as mobility systems.

Published
2023

10. Graph Meta-Reinforcement Learning for Transferable Autonomous Mobility-on-Demand

Author

Gammelli, Daniele, Yang, Kaidi, Harrison, James, Rodrigues, Filipe, Pereira, Francisco C., and Pavone, Marco

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Autonomous Mobility-on-Demand (AMoD) systems represent an attractive alternative to existing transportation paradigms, currently challenged by urbanization and increasing travel needs. By centrally controlling a fleet of self-driving vehicles, these systems provide mobility service to customers and are currently starting to be deployed in a number of cities around the world. Current learning-based approaches for controlling AMoD systems are limited to the single-city scenario, whereby the service operator is allowed to take an unlimited amount of operational decisions within the same transportation system. However, real-world system operators can hardly afford to fully re-train AMoD controllers for every city they operate in, as this could result in a high number of poor-quality decisions during training, making the single-city strategy a potentially impractical solution. To address these limitations, we propose to formalize the multi-city AMoD problem through the lens of meta-reinforcement learning (meta-RL) and devise an actor-critic algorithm based on recurrent graph neural networks. In our approach, AMoD controllers are explicitly trained such that a small amount of experience within a new city will produce good system performance. Empirically, we show how control policies learned through meta-RL are able to achieve near-optimal performance on unseen cities by learning rapidly adaptable policies, thus making them more robust not only to novel environments, but also to distribution shifts common in real-world operations, such as special events, unexpected congestion, and dynamic pricing schemes., Comment: 11 pages, 4 figures

Published
2022

11. Predictive and Prescriptive Performance of Bike-Sharing Demand Forecasts for Inventory Management

Author

Gammelli, Daniele, Wang, Yihua, Prak, Dennis, Rodrigues, Filipe, Minner, Stefan, and Pereira, Francisco Camara

Subjects
Mathematics - Optimization and Control, Computer Science - Machine Learning
Abstract

Bike-sharing systems are a rapidly developing mode of transportation and provide an efficient alternative to passive, motorized personal mobility. The asymmetric nature of bike demand causes the need for rebalancing bike stations, which is typically done during night time. To determine the optimal starting inventory level of a station for a given day, a User Dissatisfaction Function (UDF) models user pickups and returns as non-homogeneous Poisson processes with piece-wise linear rates. In this paper, we devise a deep generative model directly applicable in the UDF by introducing a variational Poisson recurrent neural network model (VP-RNN) to forecast future pickup and return rates. We empirically evaluate our approach against both traditional and learning-based forecasting methods on real trip travel data from the city of New York, USA, and show how our model outperforms benchmarks in terms of system efficiency and demand satisfaction. By explicitly focusing on the combination of decision-making algorithms with learning-based forecasting methods, we highlight a number of shortcomings in literature. Crucially, we show how more accurate predictions do not necessarily translate into better inventory decisions. By providing insights into the interplay between forecasts, model assumptions, and decisions, we point out that forecasts and decision models should be carefully evaluated and harmonized to optimally control shared mobility systems., Comment: 28 pages, 6 figures

Published
2021

12. Graph Neural Network Reinforcement Learning for Autonomous Mobility-on-Demand Systems

Author

Gammelli, Daniele, Yang, Kaidi, Harrison, James, Rodrigues, Filipe, Pereira, Francisco C., and Pavone, Marco

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Machine Learning, Computer Science - Robotics
Abstract

Autonomous mobility-on-demand (AMoD) systems represent a rapidly developing mode of transportation wherein travel requests are dynamically handled by a coordinated fleet of robotic, self-driving vehicles. Given a graph representation of the transportation network - one where, for example, nodes represent areas of the city, and edges the connectivity between them - we argue that the AMoD control problem is naturally cast as a node-wise decision-making problem. In this paper, we propose a deep reinforcement learning framework to control the rebalancing of AMoD systems through graph neural networks. Crucially, we demonstrate that graph neural networks enable reinforcement learning agents to recover behavior policies that are significantly more transferable, generalizable, and scalable than policies learned through other approaches. Empirically, we show how the learned policies exhibit promising zero-shot transfer capabilities when faced with critical portability tasks such as inter-city generalization, service area expansion, and adaptation to potentially complex urban topologies.

Published
2021

13. Generalized Multi-Output Gaussian Process Censored Regression

Author

Gammelli, Daniele, Rolsted, Kasper Pryds, Pacino, Dario, and Rodrigues, Filipe

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning
Abstract

When modelling censored observations, a typical approach in current regression methods is to use a censored-Gaussian (i.e. Tobit) model to describe the conditional output distribution. In this paper, as in the case of missing data, we argue that exploiting correlations between multiple outputs can enable models to better address the bias introduced by censored data. To do so, we introduce a heteroscedastic multi-output Gaussian process model which combines the non-parametric flexibility of GPs with the ability to leverage information from correlated outputs under input-dependent noise conditions. To address the resulting inference intractability, we further devise a variational bound to the marginal log-likelihood suitable for stochastic optimization. We empirically evaluate our model against other generative models for censored data on both synthetic and real world tasks and further show how it can be generalized to deal with arbitrary likelihood functions. Results show how the added flexibility allows our model to better estimate the underlying non-censored (i.e. true) process under potentially complex censoring dynamics., Comment: 17 pages, 6 figures, 3 tables

Published
2020

14. Recurrent Flow Networks: A Recurrent Latent Variable Model for Density Modelling of Urban Mobility

Author

Gammelli, Daniele and Rodrigues, Filipe

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning
Abstract

Mobility-on-demand (MoD) systems represent a rapidly developing mode of transportation wherein travel requests are dynamically handled by a coordinated fleet of vehicles. Crucially, the efficiency of an MoD system highly depends on how well supply and demand distributions are aligned in spatio-temporal space (i.e., to satisfy user demand, cars have to be available in the correct place and at the desired time). To do so, we argue that predictive models should aim to explicitly disentangle between temporal} and spatial variability in the evolution of urban mobility demand. However, current approaches typically ignore this distinction by either treating both sources of variability jointly, or completely ignoring their presence in the first place. In this paper, we propose recurrent flow networks (RFN), where we explore the inclusion of (i) latent random variables in the hidden state of recurrent neural networks to model temporal variability, and (ii) normalizing flows to model the spatial distribution of mobility demand. We demonstrate how predictive models explicitly disentangling between spatial and temporal variability exhibit several desirable properties, and empirically show how this enables the generation of distributions matching potentially complex urban topologies., Comment: 16 pages, 6 figures

Published
2020

15. Estimating Latent Demand of Shared Mobility through Censored Gaussian Processes

Author

Gammelli, Daniele, Peled, Inon, Rodrigues, Filipe, Pacino, Dario, Kurtaran, Haci A., and Pereira, Francisco C.

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning
Abstract

Transport demand is highly dependent on supply, especially for shared transport services where availability is often limited. As observed demand cannot be higher than available supply, historical transport data typically represents a biased, or censored, version of the true underlying demand pattern. Without explicitly accounting for this inherent distinction, predictive models of demand would necessarily represent a biased version of true demand, thus less effectively predicting the needs of service users. To counter this problem, we propose a general method for censorship-aware demand modeling, for which we devise a censored likelihood function. We apply this method to the task of shared mobility demand prediction by incorporating the censored likelihood within a Gaussian Process model, which can flexibly approximate arbitrary functional forms. Experiments on artificial and real-world datasets show how taking into account the limiting effect of supply on demand is essential in the process of obtaining an unbiased predictive model of user demand behavior., Comment: 21 pages, 10 figures

Published
2020

23. Learning and Control for Adaptive Transportation Systems

Author

Gammelli, Daniele and Gammelli, Daniele

Abstract

Transport er en gennemtrængende faktor af det moderne samfund, der gør det muligt at udføre hverdagsopgaver som at tage på arbejde, i skole eller andre simple personlige ærinder. Transport netværkets effektivitet har stor indflydelse på det enkelte individs livskvalitet og det er bredt anderkendt at inverstringer i transport infrastruktur kan generere store udviklingsmæssige gevinster i hele samfundet. I øjeblikket er transport i byer systemorienteret, hvorved brugere skal tilpasse sig et fast transportsystem (f.eks. faste busruter og køreplaner). I modsætning hertil, tror vi på visionen om et brugerorienteret system, hvorved udbud og efterspørgsel efter transport er sømløst tilpasset hinanden i et Adaptivt Transport System (ATS). For at forfølge denne vision er transportsystemer nødt til at erhverve sig to grundlæggende egenskaber: 1) at kunne forstå og forudsige de nuværende mobilitetsmønstre, og 2) at kunne konvertere denne viden til effektive beslutninger, der kan opfylde mobilitetsbehovet hos en bred og mangfoldig gruppe af borgere. Samtidig gør transportsystemets høje kompleksitet, sammen med den store mængde mobilitetsdata der er til rådighed (tænk f.eks. på den daglige strøm af data genereret af vores smartphones), dette til et perfekt scenarie for anvendelse af Machine Learning og datadrevne strategier i bred forstand. I denne forbindelse er det vores mål at udvikle læringsalgoritmer, der kan håndtere de udfordringer, der opstår inden for adaptive transportsystemer, med fokus på mobilitet-efter-behov-systemer. I den første del af afhandlingen (dvs. "Perception and Prediction") udvikler vi værktøjer til at forudsige udviklingen i efterspørgslen af mobilitet. Specifikt, fokuserer vi på at udvikle læringsalgoritmer, der er i stand til (i) at håndtere multimodaliteten i efterspørgslen af mobilitet gennem struktureret usikkerhedskvantificering og ii) at udnytte egenskaberne ved forudsigelsesproblemet ved at indføje fornuftige forudgående antagelser, Transportation is a permeating factor of modern society, effectively enabling the accomplishment of everyday tasks such as going to work, school, or simple personal errands. The efficiency of the transportation network highly influences the quality of life of individuals, and it is widely recognized that investments in transport infrastructure can generate large developmental payoffs throughout society. Currently, transportation within cities is intrinsically system-first, whereby users have to adapt to a fixed transportation system (e.g., fixed bus routes and schedules). In contrast, we believe in the vision of a user-first system, whereby supply and demand for transportation are seamlessly co-adapted into an Adaptive Transportation System (ATS). To pursue this vision, transportation systems need to acquire two fundamental capabilities: 1) being able to understand and predict current mobility patterns, and 2) converting this knowledge into effective decisions that can satisfy the need for mobility of a broad and diverse audience. At the same time, the high complexity of the transportation system, together with the vast availability of mobility data (e.g., consider the daily stream of data generated by our smartphones), make this a perfect scenario for applications of machine learning and data-driven strategies broadly. In this context, we aim to develop learning algorithms that are capable of addressing the challenges emerging within adaptive transportation systems, with a focus on mobility-on-demand systems. In the first part of the thesis (i.e., “Perception and Prediction'') we develop tools for predicting the evolution of mobility demand. Specifically, we focus on developing learning algorithms capable of (i) handling the multi-modality of mobility demand through structured uncertainty quantification, and (ii) exploiting properties of the prediction problem by injecting sensible prior assumptions, or inductive biases, w

Published
2022

24. Recurrent flow networks:A recurrent latent variable model for density estimation of urban mobility

Author

Gammelli, Daniele, Rodrigues, Filipe, Gammelli, Daniele, and Rodrigues, Filipe

Abstract

Mobility-on-demand (MoD) systems represent a rapidly developing mode of transportation wherein travel requests are dynamically handled by a coordinated fleet of vehicles. Crucially, the efficiency of an MoD system highly depends on how well supply and demand distributions are aligned in spatio-temporal space (i.e., to satisfy user demand, cars have to be available in the correct place and at the desired time). To do so, we argue that predictive models should aim to explicitly disentangle between temporal and spatial variability in the evolution of urban mobility demand. However, current approaches typically ignore this distinction by either treating both sources of variability jointly, or completely ignoring their presence in the first place. In this paper, we propose recurrent flow networks1 (RFN), where we explore the inclusion of (i) latent random variables in the hidden state of recurrent neural networks to model temporal variability, and (ii) normalizing flows to model the spatial distribution of mobility demand. We demonstrate how predictive models explicitly disentangling between spatial and temporal variability exhibit several desirable properties, and empirically show how this enables the generation of distributions matching potentially complex urban topologies.

Published
2022

26. Modeling Transport Data under Stochastic and Latent Censorship

Author

Peled, Inon, Gammelli, Daniele, Rodrigues, Filipe, Pacino, Dario, Pereira, Francisco Camara, Peled, Inon, Gammelli, Daniele, Rodrigues, Filipe, Pacino, Dario, and Pereira, Francisco Camara

Abstract

Data censorship involves two sets of corresponding values: known observations and latent (i.e., unknown) true values. Modeling of censored data has been researched in multiple works, including the famous Tobit model for known and deterministic censorship. However, when modeling demand for transport services, the censorship challenge becomes two-fold: not only is demand data inherently censored by limited supply, but it also typically lacks any account of the difference between observed and true demand. To address this problem, we devise and analyze two complementary methods for censored modeling, when no indication is given about the extent of censorship. The first modeling method is generic, while the other method is non-parametric and utilizes domain knowledge. Our experiments demonstrate both the importance of accounting for censorship and the capability of each method in reconstructing the underlying, latent patterns.

Published
2021

29. Considering patient clinical history impacts performance of machine learning models in predicting course of multiple sclerosis

Author

Seccia, Ruggiero, primary, Gammelli, Daniele, additional, Dominici, Fabio, additional, Romano, Silvia, additional, Landi, Anna Chiara, additional, Salvetti, Marco, additional, Tacchella, Andrea, additional, Zaccaria, Andrea, additional, Crisanti, Andrea, additional, Grassi, Francesca, additional, and Palagi, Laura, additional

Published
2020
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30. Gammelli, Daniele

Author

Gammelli, Daniele and Gammelli, Daniele

Published
2018

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