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1. stl2vec: Semantic and Interpretable Vector Representation of Temporal Logic

Author

Saveri, Gaia, Nenzi, Laura, Bortolussi, Luca, and Křetínský, Jan

Subjects
Computer Science - Artificial Intelligence
Abstract

Integrating symbolic knowledge and data-driven learning algorithms is a longstanding challenge in Artificial Intelligence. Despite the recognized importance of this task, a notable gap exists due to the discreteness of symbolic representations and the continuous nature of machine-learning computations. One of the desired bridges between these two worlds would be to define semantically grounded vector representation (feature embedding) of logic formulae, thus enabling to perform continuous learning and optimization in the semantic space of formulae. We tackle this goal for knowledge expressed in Signal Temporal Logic (STL) and devise a method to compute continuous embeddings of formulae with several desirable properties: the embedding (i) is finite-dimensional, (ii) faithfully reflects the semantics of the formulae, (iii) does not require any learning but instead is defined from basic principles, (iv) is interpretable. Another significant contribution lies in demonstrating the efficacy of the approach in two tasks: learning model checking, where we predict the probability of requirements being satisfied in stochastic processes; and integrating the embeddings into a neuro-symbolic framework, to constrain the output of a deep-learning generative model to comply to a given logical specification.

Published
2024

2. ECATS: Explainable-by-design concept-based anomaly detection for time series

Author

Ferfoglia, Irene, Saveri, Gaia, Nenzi, Laura, and Bortolussi, Luca

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Deep learning methods for time series have already reached excellent performances in both prediction and classification tasks, including anomaly detection. However, the complexity inherent in Cyber Physical Systems (CPS) creates a challenge when it comes to explainability methods. To overcome this inherent lack of interpretability, we propose ECATS, a concept-based neuro-symbolic architecture where concepts are represented as Signal Temporal Logic (STL) formulae. Leveraging kernel-based methods for STL, concept embeddings are learnt in an unsupervised manner through a cross-attention mechanism. The network makes class predictions through these concept embeddings, allowing for a meaningful explanation to be naturally extracted for each input. Our preliminary experiments with a simple CPS-based dataset show that our model is able to achieve great classification performance while ensuring local interpretability., Comment: 14 pages, 8 figures, accepted to 18th International Conference on Neural-Symbolic Learning and Reasoning (NeSy 2024)

Published
2024

3. Context, Composition, Automation, and Communication -- The C2AC Roadmap for Modeling and Simulation

Author

Uhrmacher, Adelinde, Frazier, Peter, Hähnle, Reiner, Klügl, Franziska, Lorig, Fabian, Ludäscher, Bertram, Nenzi, Laura, Ruiz-Martin, Cristina, Rumpe, Bernhard, Szabo, Claudia, Wainer, Gabriel A., and Wilsdorf, Pia

Subjects
Computer Science - Computational Engineering, Finance, and Science, I.6
Abstract

Simulation has become, in many application areas, a sine-qua-non. Most recently, COVID-19 has underlined the importance of simulation studies and limitations in current practices and methods. We identify four goals of methodological work for addressing these limitations. The first is to provide better support for capturing, representing, and evaluating the context of simulation studies, including research questions, assumptions, requirements, and activities contributing to a simulation study. In addition, the composition of simulation models and other simulation studies' products must be supported beyond syntactical coherence, including aspects of semantics and purpose, enabling their effective reuse. A higher degree of automating simulation studies will contribute to more systematic, standardized simulation studies and their efficiency. Finally, it is essential to invest increased effort into effectively communicating results and the processes involved in simulation studies to enable their use in research and decision-making. These goals are not pursued independently of each other, but they will benefit from and sometimes even rely on advances in other subfields. In the present paper, we explore the basis and interdependencies evident in current research and practice and delineate future research directions based on these considerations.

Published
2023

4. Learning Model Checking and the Kernel Trick for Signal Temporal Logic on Stochastic Processes

Author

Bortolussi, Luca, Gallo, Giuseppe Maria, Křetínský, Jan, and Nenzi, Laura

Subjects
Computer Science - Logic in Computer Science, Computer Science - Machine Learning
Abstract

We introduce a similarity function on formulae of signal temporal logic (STL). It comes in the form of a kernel function, well known in machine learning as a conceptually and computationally efficient tool. The corresponding kernel trick allows us to circumvent the complicated process of feature extraction, i.e. the (typically manual) effort to identify the decisive properties of formulae so that learning can be applied. We demonstrate this consequence and its advantages on the task of predicting (quantitative) satisfaction of STL formulae on stochastic processes: Using our kernel and the kernel trick, we learn (i) computationally efficiently (ii) a practically precise predictor of satisfaction, (iii) avoiding the difficult task of finding a way to explicitly turn formulae into vectors of numbers in a sensible way. We back the high precision we have achieved in the experiments by a theoretically sound PAC guarantee, ensuring our procedure efficiently delivers a close-to-optimal predictor.

Published
2022

5. Bayesian Machine Learning meets Formal Methods: An application to spatio-temporal data

Author

Vana, Laura, Visconti, Ennio, Nenzi, Laura, Cadonna, Annalisa, and Kastner, Gregor

Subjects
Statistics - Computation, Computer Science - Logic in Computer Science
Abstract

We propose an interdisciplinary framework that combines Bayesian predictive inference, a well-established tool in Machine Learning, with Formal Methods rooted in the computer science community. Bayesian predictive inference allows for coherently incorporating uncertainty about unknown quantities by making use of methods or models that produce predictive distributions, which in turn inform decision problems. By formalizing these decision problems into properties with the help of spatio-temporal logic, we can formulate and predict how likely such properties are to be satisfied in the future at a certain location. Moreover, we can leverage our methodology to evaluate and compare models directly on their ability to predict the satisfaction of application-driven properties. The approach is illustrated in an urban mobility application, where the crowdedness in the center of Milan is proxied by aggregated mobile phone traffic data. We specify several desirable spatio-temporal properties related to city crowdedness such as a fault-tolerant network or the reachability of hospitals. After verifying these properties on draws from the posterior predictive distributions, we compare several spatio-temporal Bayesian models based on their overall and property-based predictive performance.

Published
2021

6. Online Monitoring of Spatio-Temporal Properties for Imprecise Signals

Author

Visconti, Ennio, Bartocci, Ezio, Loreti, Michele, and Nenzi, Laura

Subjects
Computer Science - Logic in Computer Science
Abstract

From biological systems to cyber-physical systems, monitoring the behavior of such dynamical systems often requires to reason about complex spatio-temporal properties of physical and/or computational entities that are dynamically interconnected and arranged in a particular spatial configuration. Spatio-Temporal Reach and Escape Logic (STREL) is a recent logic-based formal language designed to specify and to reason about spatio-temporal properties. STREL considers each system's entity as a node of a dynamic weighted graph representing their spatial arrangement. Each node generates a set of mixed-analog signals describing the evolution over time of computational and physical quantities characterising the node's behavior. While there are offline algorithms available for monitoring STREL specifications over logged simulation traces, here we investigate for the first time an online algorithm enabling the runtime verification during the system's execution or simulation. Our approach extends the original framework by considering imprecise signals and by enhancing the logics' semantics with the possibility to express partial guarantees about the conformance of the system's behavior with its specification. Finally, we demonstrate our approach in a real-world environmental monitoring case study.

Published
2021

7. Mining Interpretable Spatio-temporal Logic Properties for Spatially Distributed Systems

Author

Mohammadinejad, Sara, Deshmukh, Jyotirmy V., and Nenzi, Laura

Subjects
Computer Science - Machine Learning
Abstract

The Internet-of-Things, complex sensor networks, multi-agent cyber-physical systems are all examples of spatially distributed systems that continuously evolve in time. Such systems generate huge amounts of spatio-temporal data, and system designers are often interested in analyzing and discovering structure within the data. There has been considerable interest in learning causal and logical properties of temporal data using logics such as Signal Temporal Logic (STL); however, there is limited work on discovering such relations on spatio-temporal data. We propose the first set of algorithms for unsupervised learning for spatio-temporal data. Our method does automatic feature extraction from the spatio-temporal data by projecting it onto the parameter space of a parametric spatio-temporal reach and escape logic (PSTREL). We propose an agglomerative hierarchical clustering technique that guarantees that each cluster satisfies a distinct STREL formula. We show that our method generates STREL formulas of bounded description complexity using a novel decision-tree approach which generalizes previous unsupervised learning techniques for Signal Temporal Logic. We demonstrate the effectiveness of our approach on case studies from diverse domains such as urban transportation, epidemiology, green infrastructure, and air quality monitoring.

Published
2021

9. A Logic for Monitoring Dynamic Networks of Spatially-distributed Cyber-Physical Systems

Author

Nenzi, L., Bartocci, E., Bortolussi, L., and Loreti, M.

Subjects
Computer Science - Logic in Computer Science
Abstract

Cyber-Physical Systems (CPS) consist of inter-wined computational (cyber) and physical components interacting through sensors and/or actuators. Computational elements are networked at every scale and can communicate with each other and with humans. Nodes can join and leave the network at any time or they can move to different spatial locations. In this scenario, monitoring spatial and temporal properties plays a key role in the understanding of how complex behaviors can emerge from local and dynamic interactions. We revisit here the Spatio-Temporal Reach and Escape Logic (STREL), a logic-based formal language designed to express and monitor spatio-temporal requirements over the execution of mobile and spatially distributed CPS. STREL considers the physical space in which CPS entities (nodes of the graph) are arranged as a weighted graph representing their dynamic topological configuration. Both nodes and edges include attributes modeling physical and logical quantities that can evolve over time. STREL combines the Signal Temporal Logic with two spatial modalities reach and escape that operate over the weighted graph. From these basic operators, we can derive other important spatial modalities such as everywhere, somewhere and surround. We propose both qualitative and quantitative semantics based on constraint semiring algebraic structure. We provide an offline monitoring algorithm for STREL and we show the feasibility of our approach with the application to two case studies: monitoring spatio-temporal requirements over a simulated mobile ad-hoc sensor network and a simulated epidemic spreading model for COVID19., Comment: arXiv admin note: substantial text overlap with arXiv:1904.08847

Published
2021
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10. MoonLight: A Lightweight Tool for Monitoring Spatio-Temporal Properties

Author

Bartocci, Ezio, Bortolussi, Luca, Loreti, Michele, Nenzi, Laura, and Silvetti, Simone

Subjects
Computer Science - Logic in Computer Science
Abstract

We present MoonLight, a tool for monitoring temporal and spatio-temporal properties of mobile and spatially distributed cyber-physical systems (CPS). In the proposed framework, space is represented as a weighted graph, describing the topological configurations in which the single CPS entities (nodes of the graph) are arranged. Both nodes and edges have attributes modelling physical and logical quantities that can change in time. MoonLight is implemented in Java and supports the monitoring of Spatio-Temporal Reach and Escape Logic (STREL). MoonLight can be used as a standalone command line tool, as a Java API, or via Matlab interface. We provide here some examples using the Matlab interface and we evaluate the tool performance also by comparing with other tools specialized in monitoring only temporal properties., Comment: 12 pages, 6 figures

Published
2021

11. Status and development of the TOP-IMPLART Project

Author

Picardi, L., Ampollini, A., Anello, P., Balduzzi, M., Bazzano, G., Borgognoni, F., Cisbani, E., DAndrea, M., De Angelis, C., De Angelis, G., Della Monaca, S., Esposito, G., Ghio, F., Giuliani, F., Lucentini, M., Marino, C., Montereali, R. M., Nenzi, P., Notaro, C., Patrono, C., Placido, C., Piccinini, M., Ronsivalle, C., Santavenere, F., Spurio, A., Strigari, L., Surrenti, V., Tabocchini, A., Trinca, E., and Vadrucci, M.

Subjects
Physics - Medical Physics, Physics - Applied Physics
Abstract

The TOP-IMPLART project consists of the design and implementation of a linear proton accelerator, its control and monitoring systems for the treatment of superficial and semi-deep tumors. The energy of 150 MeV (corresponding to a penetration in tissue of about 15 cm) is a milestone in design being useful for the proton therapy treatment of almost 50% of tumors based on their position and depth (including ocular melanoma, head-neck tumors, pediatric tumors, and more superficial tumors). The capability to vary the intensity on a pulse-to-pulse basis combined with an electronic feedback system allows to get the required dose uniformity (2.5%) reducing the number of re-paintings. In this paper the state of the art and the objectives of the TOP-IMPLART project are described within the framework of the progress of Protontherapy.

Published
2020

12. A kernel function for Signal Temporal Logic formulae

Author

Bortolussi, Luca, Gallo, Giuseppe Maria, and Nenzi, Laura

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

We discuss how to define a kernel for Signal Temporal Logic (STL) formulae. Such a kernel allows us to embed the space of formulae into a Hilbert space, and opens up the use of kernel-based machine learning algorithms in the context of STL. We show an application of this idea to a regression problem in formula space for probabilistic models., Comment: 12 pages, 3 figures

Published
2020

13. A Logic-Based Learning Approach to Explore Diabetes Patient Behaviors

Author

Lamp, Josephine, Silvetti, Simone, Breton, Marc, Nenzi, Laura, and Feng, Lu

Subjects
Computer Science - Logic in Computer Science, Statistics - Applications
Abstract

Type I Diabetes (T1D) is a chronic disease in which the body's ability to synthesize insulin is destroyed. It can be difficult for patients to manage their T1D, as they must control a variety of behavioral factors that affect glycemic control outcomes. In this paper, we explore T1D patient behaviors using a Signal Temporal Logic (STL) based learning approach. STL formulas learned from real patient data characterize behavior patterns that may result in varying glycemic control. Such logical characterizations can provide feedback to clinicians and their patients about behavioral changes that patients may implement to improve T1D control. We present both individual- and population-level behavior patterns learned from a clinical dataset of 21 T1D patients., Comment: 18 pages, 10 figures, submitted to 17th International Conference on Computational Methods in Systems Biology

Published
2019

14. Monitoring Mobile and Spatially Distributed Cyber-Physical Systems

Author

Bartocci, Ezio, Bortolussi, Luca, Loreti, Michele, and Nenzi, Laura

Subjects
Computer Science - Logic in Computer Science
Abstract

Cyber-Physical Systems~(CPS) consist of collaborative, networked and tightly intertwined computational (logical) and physical components, each operating at different spatial and temporal scales. Hence, the spatial and temporal requirements play an essential role for their correct and safe execution. Furthermore, the local interactions among the system components result in global spatio-temporal emergent behaviors often impossible to predict at the design time. In this work, we pursue a complementary approach by introducing STREL a novel spatio-temporal logic that enables the specification of spatio-temporal requirements and their monitoring over the execution of mobile and spatially distributed CPS. Our logic extends the Signal Temporal Logic with two novel spatial operators reach and escape from which is possible to derive other spatial modalities such as everywhere, somewhere and surround. These operators enable a monitoring procedure where the satisfaction of the property at each location depends only on the satisfaction of its neighbours, opening the way to future distributed online monitoring algorithms. We propose both a qualitative and quantitative semantics based on constraint semirings, an algebraic structure suitable for constraint satisfaction and optimisation. We prove that, for a subclass of models, all the spatial properties expressed with reach and escape, using euclidean distance, satisfy all the model transformations using rotation, reflection and translation. Finally, we provide an offline monitoring algorithm for STREL and, to demonstrate the feasibility of our approach, we show its application using the monitoring of a simulated mobile ad-hoc sensor network as running example.

Published
2019
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15. Signal Convolution Logic

Author

Silvetti, Simone, Nenzi, Laura, Bartocci, Ezio, and Bortolussi, Luca

Subjects
Computer Science - Logic in Computer Science
Abstract

We introduce a new logic called Signal Convolution Logic (SCL) that combines temporal logic with convolutional filters from digital signal processing. SCL enables to reason about the percentage of time a formula is satisfied in a bounded interval. We demonstrate that this new logic is a suitable formalism to effectively express non-functional requirements in Cyber-Physical Systems displaying noisy and irregular behaviours. We define both a qualitative and quantitative semantics for it, providing an efficient monitoring procedure. Finally, we prove SCL at work to monitor the artificial pancreas controllers that are employed to automate the delivery of insulin for patients with type-1 diabetes.

Published
2018

16. A Robust Genetic Algorithm for Learning Temporal Specifications from Data

Author

Nenzi, Laura, Silvetti, Simone, Bartocci, Ezio, and Bortolussi, Luca

Subjects
Computer Science - Artificial Intelligence, Computer Science - Logic in Computer Science
Abstract

We consider the problem of mining signal temporal logical requirements from a dataset of regular (good) and anomalous (bad) trajectories of a dynamical system. We assume the training set to be labeled by human experts and that we have access only to a limited amount of data, typically noisy. We provide a systematic approach to synthesize both the syntactical structure and the parameters of the temporal logic formula using a two-steps procedure: first, we leverage a novel evolutionary algorithm for learning the structure of the formula; second, we perform the parameter synthesis operating on the statistical emulation of the average robustness for a candidate formula w.r.t. its parameters. We compare our results with our previous work [{BufoBSBLB14] and with a recently proposed decision-tree [bombara_decision_2016] based method. We present experimental results on two case studies: an anomalous trajectory detection problem of a naval surveillance system and the characterization of an Ineffective Respiratory effort, showing the usefulness of our work., Comment: 16 pages, 3 figure

Published
2017

17. Model Checking Markov Population Models by Stochastic Approximations

Author

Bortolussi, Luca, Lanciani, Roberta, and Nenzi, Laura

Subjects
Computer Science - Logic in Computer Science
Abstract

Many complex systems can be described by population models, in which a pool of agents interacts and produces complex collective behaviours. We consider the problem of verifying formal properties of the underlying mathematical representation of these models, which is a Continuous Time Markov Chain, often with a huge state space. To circumvent the state space explosion, we rely on stochastic approximation techniques, which replace the large model by a simpler one, guaranteed to be probabilistically consistent. We show how to efficiently and accurately verify properties of random individual agents, specified by Continuous Stochastic Logic extended with Timed Automata (CSL-TA), and how to lift these specifications to the collective level, approximating the number of agents satisfying them using second or higher order stochastic approximation techniques.

Published
2017

18. Qualitative and Quantitative Monitoring of Spatio-Temporal Properties with SSTL

Author

Nenzi, L., Bortolussi, L., Ciancia, V., Loreti, M., and Massink, M.

Subjects
Computer Science - Logic in Computer Science, F.4.1
Abstract

In spatially located, large scale systems, time and space dynamics interact and drives the behaviour. Examples of such systems can be found in many smart city applications and Cyber-Physical Systems. In this paper we present the Signal Spatio-Temporal Logic (SSTL), a modal logic that can be used to specify spatio-temporal properties of linear time and discrete space models. The logic is equipped with a Boolean and a quantitative semantics for which efficient monitoring algorithms have been developed. As such, it is suitable for real-time verification of both white box and black box complex systems. These algorithms can also be combined with stochastic model checking routines. SSTL combines the until temporal modality with two spatial modalities, one expressing that something is true somewhere nearby and the other capturing the notion of being surrounded by a region that satisfies a given spatio-temporal property. The monitoring algorithms are implemented in an open source Java tool. We illustrate the use of SSTL analysing the formation of patterns in a Turing Reaction-Diffusion system and spatio-temporal aspects of a large bike-sharing system., Comment: 36 pages with 13 figures

Published
2017
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20. Bragg Curve Detection of Low-Energy Protons by Radiophotoluminescence Imaging in Lithium Fluoride Thin Films

Author

Rosa Maria Montereali, Valentina Nigro, Massimo Piccinini, Maria Aurora Vincenti, Alessandro Ampollini, Paolo Nenzi, Concetta Ronsivalle, and Enrico Nichelatti

Subjects
lithium fluoride, color centers, thin films, Bragg curve, Bragg peak, radiophotoluminescence, Chemical technology, TP1-1185
Abstract

Lithium fluoride (LiF) crystals and thin films are utilized as radiation detectors for energy diagnostics of proton beams. This is achieved by analyzing the Bragg curves in LiF obtained by imaging the radiophotoluminescence of color centers created by protons. In LiF crystals, the Bragg peak depth increases superlinearly with the particle energy. A previous study has shown that, when 35 MeV protons impinge at grazing incidence onto LiF films deposited on Si(100) substrates, the Bragg peak in the films is located at the depth where it would be found in Si rather than in LiF due to multiple Coulomb scattering. In this paper, Monte Carlo simulations of proton irradiations in the 1–8 MeV energy range are performed and compared to experimental Bragg curves in optically transparent LiF films on Si(100) substrates. Our study focuses on this energy range because, as energy increases, the Bragg peak gradually shifts from the depth in LiF to that in Si. The impact of grazing incidence angle, LiF packing density, and film thickness on shaping the Bragg curve in the film is examined. At energies higher than 8 MeV, all these quantities must be considered, although the effect of packing density plays a minor role.

Published
2023
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21. In Vivo Radiobiological Investigations with the TOP-IMPLART Proton Beam on a Medulloblastoma Mouse Model

Author

Daniela Giovannini, Cinzia De Angelis, Maria Denise Astorino, Emiliano Fratini, Evaristo Cisbani, Giulia Bazzano, Alessandro Ampollini, Massimo Piccinini, Enrico Nichelatti, Emiliano Trinca, Paolo Nenzi, Mariateresa Mancuso, Luigi Picardi, Carmela Marino, Concetta Ronsivalle, and Simonetta Pazzaglia

Subjects
proton therapy, linac, dosimetry, small-field irradiation, preclinical mouse models, medulloblastoma, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

Protons are now increasingly used to treat pediatric medulloblastoma (MB) patients. We designed and characterized a setup to deliver proton beams for in vivo radiobiology experiments at a TOP-IMPLART facility, a prototype of a proton-therapy linear accelerator developed at the ENEA Frascati Research Center, with the goal of assessing the feasibility of TOP-IMPLART for small animal proton therapy research. Mice bearing Sonic-Hedgehog (Shh)-dependent MB in the flank were irradiated with protons to test whether irradiation could be restricted to a specific depth in the tumor tissue and to compare apoptosis induced by the same dose of protons or photons. In addition, the brains of neonatal mice at postnatal day 5 (P5), representing a very small target, were irradiated with 6 Gy of protons with two different collimated Spread-Out Bragg Peaks (SOBPs). Apoptosis was visualized by immunohistochemistry for the apoptotic marker caspase-3-activated, and quantified by Western blot. Our findings proved that protons could be delivered to the upper part while sparing the deepest part of MB. In addition, a comparison of the effectiveness of protons and photons revealed a very similar increase in the expression of cleaved caspase-3. Finally, by using a very small target, the brain of P5-neonatal mice, we demonstrated that the proton irradiation field reached the desired depth in brain tissue. Using the TOP-IMPLART accelerator we established setup and procedures for proton irradiation, suitable for translational preclinical studies. This is the first example of in vivo experiments performed with a “full-linac” proton-therapy accelerator.

Published
2023
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22. A Logic for Monitoring Dynamic Networks of Spatially-distributed Cyber-Physical Systems

Author

L. Nenzi, E. Bartocci, L. Bortolussi, and M. Loreti

Subjects
computer science - logic in computer science, Logic, BC1-199, Electronic computers. Computer science, QA75.5-76.95
Abstract

Cyber-Physical Systems (CPS) consist of inter-wined computational (cyber) and physical components interacting through sensors and/or actuators. Computational elements are networked at every scale and can communicate with each other and with humans. Nodes can join and leave the network at any time or they can move to different spatial locations. In this scenario, monitoring spatial and temporal properties plays a key role in the understanding of how complex behaviors can emerge from local and dynamic interactions. We revisit here the Spatio-Temporal Reach and Escape Logic (STREL), a logic-based formal language designed to express and monitor spatio-temporal requirements over the execution of mobile and spatially distributed CPS. STREL considers the physical space in which CPS entities (nodes of the graph) are arranged as a weighted graph representing their dynamic topological configuration. Both nodes and edges include attributes modeling physical and logical quantities that can evolve over time. STREL combines the Signal Temporal Logic with two spatial modalities reach and escape that operate over the weighted graph. From these basic operators, we can derive other important spatial modalities such as everywhere, somewhere and surround. We propose both qualitative and quantitative semantics based on constraint semiring algebraic structure. We provide an offline monitoring algorithm for STREL and we show the feasibility of our approach with the application to two case studies: monitoring spatio-temporal requirements over a simulated mobile ad-hoc sensor network and a simulated epidemic spreading model for COVID19.

Published
2022
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23. Exploring the ENEA Casaccia and ENEA Frascati irradiation capabilities: Status and perspectives

Author

Croia Michele, Burgio Nunzio, Ampollini Alessandro, Astorino Maria Denise, Bazzano Giulia, Bianchi Barbara, Cesaroni Mateo, Falconi Luca, Fiore Salvatore, Lepore Luigi, Nascetti Augusto, Nenzi Paolo, Pietropaolo Antonino, Ronsivalle Concetta, Santagata Alfonso, Ratto Antonino, Ricci Pierpaolo, and Scaramuzzo Luigi

Subjects
nuclear research reactor, particle accelerator physics, neutron generator, irradiation facility, aerospace, science material, beam dynamics, monte carlo simulations, Physics, QC1-999
Abstract

A collaboration between different facilities in Casaccia and Frascati ENEA research centers has recently opened the possibility of performing irradiation experiments using different kinds of particles such as protons, neutrons, and electrons. The facilities involved in the project are the TAPIRO fast nuclear research reactor, the TOP-IMPLART proton accelerator (71 MeV), the REX electron accelerator (5 MeV) and the FNG neutron facility (2.5/14 MeV). This suite of plans represents a distributed irradiation facility using different particles and spectra, offering various irradiation capabilities for experiments in many fields, such as: nuclear physics, accelerator physics, aerospace, science material, medicine, detectors, radiation diagnostics, etc. Complete numerical models of all the facilities have been implemented to perform start-to-end simulations before experimental irradiation using beam dynamics and nuclear transport simulation codes. In addition, our distributed irradiation facility makes it possible to recreate an essential part of the Van Allen Belt radiation allowing us to check the FLUKA quantitative calibration regarding this specific simulation, facilitating the disentanglements of the uncertainties. Finally, a comparison of the estimated silicon 1 MeV neutron equivalent fluence (SI1MEVNE) of the radiation damage imparted by the different facilities is presented.

Published
2023
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25. On the Robustness of Temporal Properties for Stochastic Models

Author

Bartocci, Ezio, Bortolussi, Luca, Nenzi, Laura, and Sanguinetti, Guido

Subjects
Computer Science - Logic in Computer Science, Computer Science - Artificial Intelligence, Computer Science - Learning, Computer Science - Systems and Control
Abstract

Stochastic models such as Continuous-Time Markov Chains (CTMC) and Stochastic Hybrid Automata (SHA) are powerful formalisms to model and to reason about the dynamics of biological systems, due to their ability to capture the stochasticity inherent in biological processes. A classical question in formal modelling with clear relevance to biological modelling is the model checking problem. i.e. calculate the probability that a behaviour, expressed for instance in terms of a certain temporal logic formula, may occur in a given stochastic process. However, one may not only be interested in the notion of satisfiability, but also in the capacity of a system to mantain a particular emergent behaviour unaffected by the perturbations, caused e.g. from extrinsic noise, or by possible small changes in the model parameters. To address this issue, researchers from the verification community have recently proposed several notions of robustness for temporal logic providing suitable definitions of distance between a trajectory of a (deterministic) dynamical system and the boundaries of the set of trajectories satisfying the property of interest. The contributions of this paper are twofold. First, we extend the notion of robustness to stochastic systems, showing that this naturally leads to a distribution of robustness scores. By discussing two examples, we show how to approximate the distribution of the robustness score and its key indicators: the average robustness and the conditional average robustness. Secondly, we show how to combine these indicators with the satisfaction probability to address the system design problem, where the goal is to optimize some control parameters of a stochastic model in order to best maximize robustness of the desired specifications., Comment: In Proceedings HSB 2013, arXiv:1308.5724

Published
2013
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26. A temporal logic approach to modular design of synthetic biological circuits

Author

Bartocci, Ezio, Bortolussi, Luca, and Nenzi, Laura

Subjects
Computer Science - Logic in Computer Science, Computer Science - Emerging Technologies, Quantitative Biology - Quantitative Methods
Abstract

We present a new approach for the design of a synthetic biological circuit whose behaviour is specified in terms of signal temporal logic (STL) formulae. We first show how to characterise with STL formulae the input/output behaviour of biological modules miming the classical logical gates (AND, NOT, OR). Hence, we provide the regions of the parameter space for which these specifications are satisfied. Given a STL specification of the target circuit to be designed and the networks of its constituent components, we propose a methodology to constrain the behaviour of each module, then identifying the subset of the parameter space in which those constraints are satisfied, providing also a measure of the robustness for the target circuit design. This approach, which leverages recent results on the quantitative semantics of Signal Temporal Logic, is illustrated by synthesising a biological implementation of an half-adder.

Published
2013

27. The worldwide impact of Donati's comet on art and society in the mid-19th century

Author

Gasperini, Antonella, Galli, Daniele, and Nenzi, Laura

Subjects
Physics - History and Philosophy of Physics, Physics - Popular Physics
Abstract

Donati's comet was one of the most impressive astronomical events of the nineteenth century. Its extended sword-like tail was a spectacular sight that inspired several literary and artistic representations. Traces of Donati's comet are found in popular magazines, children's books, collection cards, and household objects through the beginning of the twentieth century.

Published
2012
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29. Concept and performance evaluation of two 3 GHz buncher units optimizing the dose rate of a novel preclinical proton minibeam irradiation facility.

Author

Michael Mayerhofer, Andreas Bergmaier, Gerd Datzmann, Hermann Hagn, Ricardo Helm, Johannes Mitteneder, Ralf Schubert, Luigi Picardi, Paolo Nenzi, Concetta Ronsivalle, Hans-Friedrich Wirth, and Günther Dollinger

Subjects
Medicine, Science
Abstract

To demonstrate the large potential of proton minibeam radiotherapy (pMBRT) as a new method to treat tumor diseases, a preclinical proton minibeam radiation facility was designed. It is based on a tandem Van-de-Graaff accelerator providing a 16 MeV proton beam and a 3 GHz linac post-accelerator (designs: AVO-ADAM S.A, Geneva, Switzerland and ENEA, Frascati, Italy). To enhance the transmission of the tandem beam through the post-accelerator by a factor of 3, two drift tube buncher units were designed and constructed: A brazed 5-gap structure (adapted SCDTL tank of the TOP-IMPLART project (ENEA)) and a non-brazed low budget 4-gap structure. Both are made of copper. The performance of the two differently manufactured units was evaluated using a 16 MeV tandem accelerator beam and a Q3D magnetic spectrograph. Both buncher units achieve the required summed voltage amplitude of 42 kV and amplitude stability at a power feed of less than 800 W.

Published
2021
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31. Mining Road Traffic Rules with Signal Temporal Logic and Grammar-Based Genetic Programming

Author

Federico Pigozzi, Eric Medvet, and Laura Nenzi

Subjects
context-free grammar genetic programming, grammatical evolution, traffic monitoring, formal methods, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

Traffic systems, where human and autonomous drivers interact, are a very relevant instance of complex systems and produce behaviors that can be regarded as trajectories over time. Their monitoring can be achieved by means of carefully stated properties describing the expected behavior. Such properties can be expressed using Signal Temporal Logic (STL), a specification language for expressing temporal properties in a formal and human-readable way. However, manually authoring these properties is a hard task, since it requires mastering the language and knowing the system to be monitored. Moreover, in practical cases, the expected behavior is not known, but it has instead to be inferred from a set of trajectories obtained by observing the system. Often, those trajectories come devoid of human-assigned labels that can be used as an indication of compliance with expected behavior. As an alternative to manual authoring, automatic mining of STL specifications from unlabeled trajectories would enable the monitoring of autonomous agents without sacrificing human-readability. In this work, we propose a grammar-based evolutionary computation approach for mining the structure and the parameters of an STL specification from a set of unlabeled trajectories. We experimentally assess our approach on a real-world road traffic dataset consisting of thousands of vehicle trajectories. We show that our approach is effective at mining STL specifications that model the system at hand and are interpretable for humans. To the best of our knowledge, this is the first such study on a set of unlabeled real-world road traffic data. Being able to mine interpretable specifications from this kind of data may improve traffic safety, because mined specifications may be helpful for monitoring traffic and planning safety promotion strategies.

Published
2021
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33. In Vivo Radiobiological Investigations with the TOP-IMPLART Proton Beam on a Medulloblastoma Mouse Model

Author

Giovannini, Daniela, primary, De Angelis, Cinzia, additional, Astorino, Maria Denise, additional, Fratini, Emiliano, additional, Cisbani, Evaristo, additional, Bazzano, Giulia, additional, Ampollini, Alessandro, additional, Piccinini, Massimo, additional, Nichelatti, Enrico, additional, Trinca, Emiliano, additional, Nenzi, Paolo, additional, Mancuso, Mariateresa, additional, Picardi, Luigi, additional, Marino, Carmela, additional, Ronsivalle, Concetta, additional, and Pazzaglia, Simonetta, additional

Published
2023
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34. WebMonitor: Verification of Web User Interfaces

Author

Ennio Visconti, Christos Tsigkanos, Laura Nenzi, Aehnelt M., Kirste T., Visconti, Ennio, Tsigkanos, Christo, and Nenzi, Laura

Subjects
Monitoring, Logic, Formal Verification, Web application
Abstract

Application development for the modern Web involves sophisticated engineering workflows which include user interface aspects. Those involve Web elements typically created with HTML/CSS markup and JavaScript-like languages, yielding Web documents. WebMonitor leverages requirements formally specified in a logic able to capture both the layout of visual components as well as how they change over time, as a user interacts with them. Then, requirements are verified upon arbitrary web pages, allowing for automated support for a wide set of use cases in interaction testing and simulation. We position WebMonitor within a developer workflow, where in case of a negative result, a visual counterexample is returned. The monitoring framework we present follows a black-box approach, and as such is independent of the underlying technologies a Web application may be developed with, as well as the browser and operating system used. WebMonitoris available as open source software: https://github.com/ennioVisco/webmonitor Video demonstration of WebMonitor: https://youtu.be/hqVw0JU3k9c

Published
2022

35. Dynamic range and dose linearity of the radiophotoluminescence intensity in lithium fluoride crystals irradiated with 2.3 and 26 MeV protons

Author

Massimo Piccinini, Enrico Nichelatti, Maria Aurora Vincenti, Valentina Nigro, Concetta Ronsivalle, Alessandro Ampollini, Paolo Nenzi, Giulia Bazzano, Emiliano Trinca, Rosa Maria Montereali, Piccinini, M., Nichelatti, E., Vincenti, M. A., Nigro, V., Ronsivalle, C., Ampollini, A., Nenzi, P., Bazzano, G., Trinca, E., and Montereali, R. M.

Subjects
Biophysics, General Chemistry, Condensed Matter Physics, Biochemistry, Atomic and Molecular Physics, and Optics
Abstract

Irradiation of lithium fluoride with protons causes the formation of electronic defects, known as colour centres, in the crystal lattice. Two stable defects among them, the F2 and F3+ aggregate ones, under blue light simultaneous excitation show broad photoluminescence in the red and green visible spectral ranges, respectively, their peculiar characteristics being well known for applications in optically-pumped tuneable lasers, broad-band miniaturized light-emitting photonic devices and passive radiation imaging detectors. Recently, exploitation of their radiophotoluminescence has been successfully proposed for proton-beam advanced diagnostics and dosimetry, even at low dose values typical of radiotherapy. In the present study, lithium fluoride crystals were irradiated with 2.3 MeV protons in the dose range from ∼104 to ∼107 Gy and their dynamic range, that is the capability of detecting the widest possible range of radiophotoluminescence intensity emitted by the colour centres, was found to be 114 dB at the F2 peak emission wavelength of 675 nm under continuous-wave laser excitation at 445 nm. Moreover, after including in the analysis a set of lithium fluoride crystals irradiated with 26.1 MeV protons in the dose range from 0.5 to 48 Gy at a much lower dose-rate, it was found that the radiophotoluminescence intensity of the F2 colour centres shows a linear dependence with dose from 0.5 to ∼2 × 105 Gy.

Published
2023

37. Beam commissioning of the 35 MeV section in an intensity modulated proton linear accelerator for proton therapy

Author

L. Picardi, A. Ampollini, G. Bazzano, E. Cisbani, F. Ghio, R. M. Montereali, P. Nenzi, M. Piccinini, C. Ronsivalle, F. Santavenere, V. Surrenti, E. Trinca, M. Vadrucci, and E. Wembe Tafo

Subjects
Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798
Abstract

This paper presents the experimental results on the Terapia Oncologica con Protoni-Intensity Modulated Proton Linear Accelerator (TOP-IMPLART) beam that is currently accelerated up to 35 MeV, with a final target of 150 MeV. The TOP-IMPLART project, funded by the Innovation Department of Regione Lazio (Italy), is led by Italian National Agency for New Technologies, Energy and Sustainable Economic Development (ENEA) in collaboration with the Italian Institute of Health and the Oncological Hospital Regina Elena-IFO. The accelerator, under construction and test at ENEA-Frascati laboratories, employs a commercial 425 MHz, 7 MeV injector followed by a sequence of 3 GHz accelerating modules consisting of side coupled drift tube linac (SCDTL) structures up to 71 MeV and coupled cavity linac structures for higher energies. The section from 7 to 35 MeV, consisting on four SCDTL modules, is powered by a single 10 MW klystron and has been successfully commissioned. This result demonstrates the feasibility of a “fully linear” proton therapy accelerator operating at a high frequency and paves the way to a new class of machines in the field of cancer treatment.

Published
2020
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38. Qualitative and Quantitative Monitoring of Spatio-Temporal Properties with SSTL

Author

L. Nenzi, L. Bortolussi, V. Ciancia, M. Loreti, and M. Massink

Subjects
computer science - logic in computer science, f.4.1, Logic, BC1-199, Electronic computers. Computer science, QA75.5-76.95
Abstract

In spatially located, large scale systems, time and space dynamics interact and drives the behaviour. Examples of such systems can be found in many smart city applications and Cyber-Physical Systems. In this paper we present the Signal Spatio-Temporal Logic (SSTL), a modal logic that can be used to specify spatio-temporal properties of linear time and discrete space models. The logic is equipped with a Boolean and a quantitative semantics for which efficient monitoring algorithms have been developed. As such, it is suitable for real-time verification of both white box and black box complex systems. These algorithms can also be combined with stochastic model checking routines. SSTL combines the until temporal modality with two spatial modalities, one expressing that something is true somewhere nearby and the other capturing the notion of being surrounded by a region that satisfies a given spatio-temporal property. The monitoring algorithms are implemented in an open source Java tool. We illustrate the use of SSTL analysing the formation of patterns in a Turing Reaction-Diffusion system and spatio-temporal aspects of a large bike-sharing system.

Published
2018
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39. Fluid-film lubrication computing with many-core processors and graphics processing units

Author

Nenzi Wang, Hsin-Yi Chen, and Yu-Wen Chen

Subjects
Mechanical engineering and machinery, TJ1-1570
Abstract

The advancement of modern processors with many-core and large-cache may have little computational advantages if only serial computing is employed. In this study, several parallel computing approaches, using devices with multiple or many processor cores, and graphics processing units are applied and compared to illustrate the potential applications in fluid-film lubrication study. Two Reynolds equations and an air bearing optimum design are solved using three parallel computing paradigms, OpenMP, Compute Unified Device Architecture, and OpenACC, on standalone shared-memory computers. The newly developed processors with many-integrated-core are also using OpenMP to release the computing potential. The results show that the OpenACC computing can have a better performance than the OpenMP computing for the discretized Reynolds equation with a large gridwork. This is mainly due to larger sizes of available cache in the tested graphics processing units. The bearing design can benefit most when the system with many-integrated-core processor is being used. This is due to the many-integrated-core system can perform computation in the optimization-algorithm-level and using the many processor cores effectively. A proper combination of parallel computing devices and programming models can complement efficient numerical methods or optimization algorithms to accelerate many tribological simulations or engineering designs.

Published
2018
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41. Learning Model Checking and the Kernel Trick for Signal Temporal Logic on Stochastic Processes

Author

Luca Bortolussi, Giuseppe Maria Gallo, Jan Křetínský, Laura Nenzi, Bortolussi, Luca, Maria Gallo, Giuseppe, Kretinski, Jan, and Nenzi, Laura

Subjects
FOS: Computer and information sciences, Machine Learning, Computer Science - Logic in Computer Science, Computer Science - Machine Learning, Kernel method, Kernel methods, Signal temporal logic, Formal Method, Model Checking, Formal Methods, Logic in Computer Science (cs.LO), Machine Learning (cs.LG)
Abstract

We introduce a similarity function on formulae of signal temporal logic (STL). It comes in the form of a kernel function, well known in machine learning as a conceptually and computationally efficient tool. The corresponding kernel trick allows us to circumvent the complicated process of feature extraction, i.e. the (typically manual) effort to identify the decisive properties of formulae so that learning can be applied. We demonstrate this consequence and its advantages on the task of predicting (quantitative) satisfaction of STL formulae on stochastic processes: Using our kernel and the kernel trick, we learn (i) computationally efficiently (ii) a practically precise predictor of satisfaction, (iii) avoiding the difficult task of finding a way to explicitly turn formulae into vectors of numbers in a sensible way. We back the high precision we have achieved in the experiments by a theoretically sound PAC guarantee, ensuring our procedure efficiently delivers a close-to-optimal predictor.

Published
2022

42. Status of the TOP-IMPLART Proton Linac

Author

Nenzi, Paolo, Ampollini, Alessandro, Astorino, Maria Denise, Bazzano, Giulia, Fortini, Fabio, Picardi, Luigi, Ronsivalle, Concetta, Surrenti, Vincenzo, Trinca, Emiliano, Snels, C., Vadrucci, M., Surrenti, V., Ronsivalle, C., Picardi, L., Marracino, F., Bazzano, G., Ampollini, A., and Nenzi, P.

Subjects
Proton and Ion Accelerators and Applications, Accelerator Physics
Abstract

The TOP-IMPLART (Intensity Modulated Proton Linear Accelerator for Radio Therapy) proton linac, is a RF pulsed linac, designed for protontherapy consisting of a low frequency (425 MHz) 7 MeV injector followed by a sequence of accelerating modules operating at 3 GHz under construction, assembly and test at the ENEA Frascati Research Center. The accelerator features also a vertical low energy (3-7 MeV) line for irradiation of samples in horizontal position. The segment currently completed includes 8 SCDTL modules up to 71 MeV grouped in two sections each one powered by a 10 MW klystron driven by a SCANDINOVA K100 modulator with a variable pulse length (1-5 us) at a repetition frequency of 25 Hz. The output current can be varied up to 30 uA. The beam is mainly used for radiobiology experiments and dosimetry systems tests, but the flexibility in beam characteristics makes it suitable also for applications different from protontherapy, as the irradiation of electronics components to verify their behavior in the space environment. In this work, the current status of the accelerator and beam characteristics measurements are presented with an overview of the experiments carried on it., Proceedings of the 31st International Linear Accelerator Conference, LINAC2022, Liverpool, UK

Published
2022
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43. One-Shot Learning of Ensembles of Temporal Logic Formulas for Anomaly Detection in Cyber-Physical Systems

Author

Patrick Indri, Alberto Bartoli, Eric Medvet, Laura Nenzi, Eric Medvet, Gisele Pappa, Bing Xue, Indri, Patrick, Bartoli, Alberto, Medvet, Eric, and Nenzi, Laura

Subjects
Specification mining, Ensemble learning, Grammar Guided Genetic Programming
Abstract

Cyber-Physical Systems (CPS) are prevalent in critical infrastructures and a prime target for cyber-attacks. Multivariate time series data generated by sensors and actuators of a CPS can be monitored for detecting cyber-attacks that introduce anomalies in those data. We use Signal Temporal Logic (STL) formulas to tightly describe the normal behavior of a CPS, identifying data instances that do not satisfy the formulas as anomalies. We learn an ensemble of STL formulas based on observed data, without any specific knowledge of the CPS being monitored. We propose an algorithm based on Grammar-Guided Genetic Programming (G3P) that learns the ensemble automatically in a single evolutionary run. We test the effectiveness of our data-driven proposal on two real-world datasets, finding that the proposed one-shot algorithm provides good detection performance.

Published
2022

44. Design and test of a compact beam current monitor based on a passive RF cavity for a proton therapy linear accelerator

Author

Giulia Bazzano, A. Ampollini, Luigi Picardi, L. Piersanti, F. Cardelli, Paolo Nenzi, Concetta Ronsivalle, Cardelli, F., Ampollini, A., Bazzano, G., Nenzi, P., Piersanti, L., Ronsivalle, C., and Picardi, L.

Subjects
Physics, Proton, business.industry, Detector, Linear particle accelerator, RF cavity, linac, proton, current detector, Optics, Proton Therapy, Physics::Accelerator Physics, Humans, Detection theory, Current (fluid), Particle Accelerators, Protons, business, Instrumentation, Realization (systems), Proton therapy, Beam (structure)
Abstract

In a medical accelerator, real-time monitoring systems of the beam and dose delivered to the patient are mandatory. In this work, we present a compact current profile detector that has been designed and tested in the framework of the TOP-IMPLART (Intensity Modulated Proton Linear Accelerator for RadioTerapy) project. This project foresees the realization of a proton linear accelerator, currently under construction at ENEA Frascati, for proton therapy applications. The linac produces a pulsed proton beam with 3 µs duration at 50 Hz repetition rate with a pulse current between 0.5 and 50 μA. A large dynamic range and spatial constraints make the use of usual noninterceptive beam diagnostics unfeasible. Therefore, the use of a beam current monitor based on a passive RF cavity working in the TM010 mode has been proposed. This paper reports the electromagnetic design of the device guided by a simplified analytical model. A prototype of such a device has been realized, characterized, and tested on the linac with a 35 MeV beam varying the beam current. The test results in air and in vacuum, together with the signal detection systems used, are presented.

Published
2021

45. Mining Road Traffic Rules with Signal Temporal Logic and Grammar-Based Genetic Programming

Author

Eric Medvet, Laura Nenzi, Federico Pigozzi, Pigozzi, Federico, Medvet, Eric, and Nenzi, Laura

Subjects
grammatical evolution, Technology, formal methods, context-free grammar genetic programming, traffic monitoring, Computer science, QH301-705.5, QC1-999, Autonomous agent, Genetic programming, Machine learning, computer.software_genre, Evolutionary computation, Set (abstract data type), Grammatical evolution, General Materials Science, Biology (General), Instrumentation, QD1-999, Fluid Flow and Transfer Processes, Structure (mathematical logic), business.industry, Process Chemistry and Technology, Physics, General Engineering, Specification language, Formal methods, Engineering (General). Civil engineering (General), Computer Science Applications, Chemistry, Artificial intelligence, TA1-2040, business, computer
Abstract

Traffic systems, where human and autonomous drivers interact, are a very relevant instance of complex systems and produce behaviors that can be regarded as trajectories over time. Their monitoring can be achieved by means of carefully stated properties describing the expected behavior. Such properties can be expressed using Signal Temporal Logic (STL), a specification language for expressing temporal properties in a formal and human-readable way. However, manually authoring these properties is a hard task, since it requires mastering the language and knowing the system to be monitored. Moreover, in practical cases, the expected behavior is not known, but it has instead to be inferred from a set of trajectories obtained by observing the system. Often, those trajectories come devoid of human-assigned labels that can be used as an indication of compliance with expected behavior. As an alternative to manual authoring, automatic mining of STL specifications from unlabeled trajectories would enable the monitoring of autonomous agents without sacrificing human-readability. In this work, we propose a grammar-based evolutionary computation approach for mining the structure and the parameters of an STL specification from a set of unlabeled trajectories. We experimentally assess our approach on a real-world road traffic dataset consisting of thousands of vehicle trajectories. We show that our approach is effective at mining STL specifications that model the system at hand and are interpretable for humans. To the best of our knowledge, this is the first such study on a set of unlabeled real-world road traffic data. Being able to mine interpretable specifications from this kind of data may improve traffic safety, because mined specifications may be helpful for monitoring traffic and planning safety promotion strategies.

Published
2021

46. Online Monitoring of Spatio-Temporal Properties for Imprecise Signals

Author

Ennio Visconti, Ezio Bartocci, Michele Loreti, Laura Nenzi, Visconti, E., Bartocci, E., Loreti, M., and Nenzi, L.

Subjects
FOS: Computer and information sciences, Computer Science - Logic in Computer Science, spatiooral logic, imprecise signal, online monitoring, runtime verification, signal temporal logic, Logic in Computer Science (cs.LO)
Abstract

From biological systems to cyber-physical systems, monitoring the behavior of such dynamical systems often requires to reason about complex spatio-temporal properties of physical and/or computational entities that are dynamically interconnected and arranged in a particular spatial configuration. Spatio-Temporal Reach and Escape Logic (STREL) is a recent logic-based formal language designed to specify and to reason about spatio-temporal properties. STREL considers each system's entity as a node of a dynamic weighted graph representing their spatial arrangement. Each node generates a set of mixed-analog signals describing the evolution over time of computational and physical quantities characterising the node's behavior. While there are offline algorithms available for monitoring STREL specifications over logged simulation traces, here we investigate for the first time an online algorithm enabling the runtime verification during the system's execution or simulation. Our approach extends the original framework by considering imprecise signals and by enhancing the logics' semantics with the possibility to express partial guarantees about the conformance of the system's behavior with its specification. Finally, we demonstrate our approach in a real-world environmental monitoring case study.

Published
2021

49. MoonLight: A Lightweight Tool for Monitoring Spatio-Temporal Properties

Author

Laura Nenzi, Simone Silvetti, Michele Loreti, Ezio Bartocci, Luca Bortolussi, Ezio Bartocci, Luca Bortolussi, Michele Loreti, Laura Nenzi, Simone Silvetti, Bartocci, E., Bortolussi, L., Loreti, M., Nenzi, L., and Silvetti, S.

Subjects
Moonlight, 050101 languages & linguistics, Java, Computer science, 05 social sciences, monitoring, spatio-temporal logic, tool, Matlab, tool, 02 engineering and technology, Computational science, 0202 electrical engineering, electronic engineering, information engineering, Graph (abstract data type), 020201 artificial intelligence & image processing, 0501 psychology and cognitive sciences, MATLAB, computer, Matlab, computer.programming_language
Abstract

We present MoonLight, a tool for monitoring temporal and spatio-temporal properties of mobile and spatially distributed cyber-physical systems (CPS). In the proposed framework, space is represented as a weighted graph, describing the topological configurations in which the single CPS entities (nodes of the graph) are arranged. Both nodes and edges have attributes modelling physical and logical quantities that can change in time. MoonLight is implemented in Java and supports the monitoring of Spatio-Temporal Reach and Escape Logic (STREL) introduced in [6]. MoonLight can be used as a standalone command line tool, as a Java API, or via Matlab ™interface. We provide here some examples using the Matlab ™interface and we evaluate the tool performance also by comparing with other tools specialized in monitoring only temporal properties.

Published
2020

50. On the Robustness of Temporal Properties for Stochastic Models

Author

Ezio Bartocci, Luca Bortolussi, Laura Nenzi, and Guido Sanguinetti

Subjects
Mathematics, QA1-939, Electronic computers. Computer science, QA75.5-76.95
Abstract

Stochastic models such as Continuous-Time Markov Chains (CTMC) and Stochastic Hybrid Automata (SHA) are powerful formalisms to model and to reason about the dynamics of biological systems, due to their ability to capture the stochasticity inherent in biological processes. A classical question in formal modelling with clear relevance to biological modelling is the model checking problem. i.e. calculate the probability that a behaviour, expressed for instance in terms of a certain temporal logic formula, may occur in a given stochastic process. However, one may not only be interested in the notion of satisfiability, but also in the capacity of a system to mantain a particular emergent behaviour unaffected by the perturbations, caused e.g. from extrinsic noise, or by possible small changes in the model parameters. To address this issue, researchers from the verification community have recently proposed several notions of robustness for temporal logic providing suitable definitions of distance between a trajectory of a (deterministic) dynamical system and the boundaries of the set of trajectories satisfying the property of interest. The contributions of this paper are twofold. First, we extend the notion of robustness to stochastic systems, showing that this naturally leads to a distribution of robustness scores. By discussing two examples, we show how to approximate the distribution of the robustness score and its key indicators: the average robustness and the conditional average robustness. Secondly, we show how to combine these indicators with the satisfaction probability to address the system design problem, where the goal is to optimize some control parameters of a stochastic model in order to best maximize robustness of the desired specifications.

Published
2013
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