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21 results on '"Alan, Anil"'

1. Parameterized Barrier Functions to Guarantee Safety under Uncertainty

Author

Alan, Anil, Molnar, Tamas G., Ames, Aaron D., and Orosz, Gábor

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

Deploying safety-critical controllers in practice necessitates the ability to modulate uncertainties in control systems. In this context, robust control barrier functions -- in a variety of forms -- have been used to obtain safety guarantees for uncertain systems. Yet the differing types of uncertainty experienced in practice have resulted in a fractured landscape of robustification -- with a variety of instantiations depending on the structure of the uncertainty. This paper proposes a framework for generalizing these variations into a single form: parameterized barrier functions (PBFs), which yield safety guarantees for a wide spectrum of uncertainty types. This leads to controllers that enforce robust safety guarantees while their conservativeness scales by the parameterization. To illustrate the generality of this approach, we show that input-to-state safety (ISSf) is a special case of the PBF framework, whereby improved safety guarantees can be given relative to ISSf., Comment: 6 pages, 4 figures

Published
2023

2. Experimental Validation of a Safe Controller Integration Scheme for Connected Automated Trucks

Author

Alan, Anil, He, Chaozhe R., Molnar, Tamas G., Mathew, Johaan C., Bell, A. Harvey, and Orosz, Gabor

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

Accomplishing safe and efficient driving is one of the predominant challenges in the controller design of connected automated vehicles (CAVs). It is often more convenient to address these goals separately and integrate the resulting controllers. In this study, we propose a controller integration scheme to fuse performance-based controllers and safety-oriented controllers safely for the longitudinal motion of a CAV. The resulting structure is compatible with a large class of controllers, and offers flexibility to design each controller individually without affecting the performance of the others. We implement the proposed safe integration scheme on a connected automated truck using an optimal-in-energy controller and a safety-oriented connected cruise controller. We validate the premise of the safe integration through experiments with a full-scale truck in two scenarios: a controlled experiment on a test track and a real-world experiment on a public highway. In both scenarios, we achieve energy efficient driving without violating safety., Comment: 14 pages, 11 figures

Published
2022

3. Disturbance Observers for Robust Safety-critical Control with Control Barrier Functions

Author

Alan, Anil, Molnar, Tamas G., Das, Ersin, Ames, Aaron D., and Orosz, Gabor

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

This work provides formal safety guarantees for control systems with disturbance. A disturbance observer-based robust safety-critical controller is proposed, that estimates the effect of the disturbance on safety and utilizes this estimate with control barrier functions to attain provably safe dynamic behavior. The observer error bound - which consists of transient and steady-state parts - is quantified, and the system is endowed with robustness against this error via the proposed controller. An adaptive cruise control problem is used as illustrative example through simulations including real disturbance data., Comment: 6 pages, 5 figures

Published
2022
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4. Control Barrier Functions and Input-to-State Safety with Application to Automated Vehicles

Author

Alan, Anil, Taylor, Andrew J., He, Chaozhe R., Ames, Aaron D., and Orosz, Gabor

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

Balancing safety and performance is one of the predominant challenges in modern control system design. Moreover, it is crucial to robustly ensure safety without inducing unnecessary conservativeness that degrades performance. In this work we present a constructive approach for safety-critical control synthesis via Control Barrier Functions (CBF). By filtering a hand-designed controller via a CBF, we are able to attain performant behavior while providing rigorous guarantees of safety. In the face of disturbances, robust safety and performance are simultaneously achieved through the notion of Input-to-State Safety (ISSf). We take a tutorial approach by developing the CBF-design methodology in parallel with an inverted pendulum example, making the challenges and sensitivities in the design process concrete. To establish the capability of the proposed approach, we consider the practical setting of safety-critical design via CBFs for a connected automated vehicle (CAV) in the form of a class-8 truck without a trailer. Through experimentation we see the impact of unmodeled disturbances in the truck's actuation system on the safety guarantees provided by CBFs. We characterize these disturbances and using ISSf, produce a robust controller that achieves safety without conceding performance. We evaluate our design both in simulation, and for the first time on an automotive system, experimentally., Comment: 16 pages, 16 figures

Published
2022

5. Input-to-State Safety with Input Delay in Longitudinal Vehicle Control

Author

Molnar, Tamas G., Alan, Anil, Kiss, Adam K., Ames, Aaron D., and Orosz, Gabor

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Robotics, Mathematics - Dynamical Systems
Abstract

Safe longitudinal control is discussed for a connected automated truck traveling behind a preceding connected vehicle. A controller is proposed based on control barrier function theory and predictor feedback for provably safe, collision-free behavior by taking into account the significant response time of the truck as input delay and the uncertainty of its dynamical model as input disturbance. The benefits of the proposed controller compared to control designs that neglect the delay or treat the delay as disturbance are shown by numerical simulations., Comment: Accepted to the 17th IFAC Workshop on Time Delay Systems. 6 pages, 3 figures

Published
2022

6. Safety-Aware Preference-Based Learning for Safety-Critical Control

Author

Cosner, Ryan K., Tucker, Maegan, Taylor, Andrew J., Li, Kejun, Molnár, Tamás G., Ubellacker, Wyatt, Alan, Anil, Orosz, Gábor, Yue, Yisong, and Ames, Aaron D.

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

Bringing dynamic robots into the wild requires a tenuous balance between performance and safety. Yet controllers designed to provide robust safety guarantees often result in conservative behavior, and tuning these controllers to find the ideal trade-off between performance and safety typically requires domain expertise or a carefully constructed reward function. This work presents a design paradigm for systematically achieving behaviors that balance performance and robust safety by integrating safety-aware Preference-Based Learning (PBL) with Control Barrier Functions (CBFs). Fusing these concepts -- safety-aware learning and safety-critical control -- gives a robust means to achieve safe behaviors on complex robotic systems in practice. We demonstrate the capability of this design paradigm to achieve safe and performant perception-based autonomous operation of a quadrupedal robot both in simulation and experimentally on hardware., Comment: 15 pages, 4 figures

Published
2021

7. Safe Controller Synthesis with Tunable Input-to-State Safe Control Barrier Functions

Author

Alan, Anil, Taylor, Andrew J., He, Chaozhe R., Orosz, Gábor, and Ames, Aaron D.

Subjects
Electrical Engineering and Systems Science - Systems and Control
Abstract

To bring complex systems into real world environments in a safe manner, they will have to be robust to uncertainties - both in the environment and the system. This paper investigates the safety of control systems under input disturbances, wherein the disturbances can capture uncertainties in the system. Safety, framed as forward invariance of sets in the state space, is ensured with the framework of control barrier functions (CBFs). Concretely, the definition of input to state safety (ISSf) is generalized to allow the synthesis of non-conservative, tunable controllers that are provably safe under varying disturbances. This is achieved by formulating the concept of tunable input to state safe control barrier functions (TISSf-CBFs) which guarantee safety for disturbances that vary with state and, therefore, provide less conservative means of accommodating uncertainty. The theoretical results are demonstrated with a simple control system with input disturbance and also applied to design a safe connected cruise controller for a heavy duty truck.

Published
2021

8. Adaptive Pressure Control for Use in Variable-Thrust Rocket Development

Author

Alan, Anil, Yildiz, Yildiray, and Poyraz, Umit

Subjects
Computer Science - Systems and Control
Abstract

The precise control of gas generator pressure is important to obtain variable thrust in ducted rockets. A delay resistant closed loop reference model adaptive control is proposed in this paper to address this problem. The proposed controller combines delay compensation and adaptation with improved transient response. The controller is successfully implemented using an industrial grade cold air test setup, which is a milestone towards obtaining a fully developed throttleable rocket gas generator controller. Simulation and experimental comparisons with alternative adaptive approaches and a fixed controller demonstrate improved performance and effective handling of time delays and uncertainties. A step by step design methodology, covering robustfying schemes, selection of adaptation rates and initial controller parameters, is also provided to facilitate implementations.

Published
2017

9. Integrating Safety With Performance in Connected Automated Truck Control: Experimental Validation

Author

Alan, Anil, He, Chaozhe R., Molnar, Tamas G., Mathew, Johaan Chacko, Bell, A. Harvey, and Orosz, Gabor

Abstract

Combining efficiency with safety is one of the most important design challenges for connected automated trucks. In order to address this challenge for longitudinal control problems, we propose a scheme that integrates a performance-based controller with a safety-oriented controller in a seamless manner. This safe integration scheme operates instantaneously, and it is compatible with a large class of controllers. We first link this practical integration method to the theoretical framework of control barrier functions that endows controllers with formal safety guarantees. Then, through this scheme we safely integrate a predictive-type controller minimizing energy consumption (predictive cruise control—PCC) with a safety-oriented cruise controller structure relying on connectivity (connected cruise control—CCC). Importantly, the efficacy of the safe and seamless integration between the PCC and the CCC is demonstrated using on-road experiments with a full-scale connected automated truck. Initial experimental campaign is held on a closed test track, and safe driving is achieved thanks to the CCC while up to 18% energy saving is obtained thanks to the PCC. Finally, experiments are extended to a public highway, and similar results are obtained with up to 4.3% energy saving.

Published
2024
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10. Control Barrier Functions and Input-to-State Safety With Application to Automated Vehicles

Author

Alan, Anil, Taylor, Andrew J., He, Chaozhe R., Ames, Aaron D., and Orosz, Gabor

Abstract

Balancing safety and performance is one of the predominant challenges in modern control system design. Moreover, it is crucial to robustly ensure safety without inducing unnecessary conservativeness that degrades performance. In this work, we present a constructive approach for safety-critical control synthesis via control barrier functions (CBFs). By filtering a hand-designed controller via a CBF, we are able to attain performant behavior while providing rigorous guarantees of safety. In the face of disturbances, robust safety and performance are simultaneously achieved through the notion of input-to-state safety (ISSf). We take a tutorial approach by developing the CBF-design methodology in parallel with an inverted pendulum example, making the challenges and sensitivities in the design process concrete. To establish the capability of the proposed approach, we consider the practical setting of safety-critical design via CBFs for a connected automated vehicle (CAV) in the form of a class-8 truck without a trailer. Through experimentation, we see the impact of unmodeled disturbances in the truck’s actuation system on the safety guarantees provided by CBFs. We characterize these disturbances and using ISSf, produce a robust controller that achieves safety without conceding performance. We evaluate our design both in simulation, and for the first time on an automotive system, experimentally.

Published
2023
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17. Pressure control of gas generator in throttleable ducted rockets: A time delay resistant adaptive control approach

Author

Alan, Anil, Yıldız, Yıldıray, and Makine Mühendisliği Anabilim Dalı

Subjects
Havacılık Mühendisliği, Mechanical Engineering, Aeronautical Engineering, Makine Mühendisliği, Pressure control, Adaptive control systems
Abstract

Operasyon sırasında itki değişimi yapabilen roketler, hareketli bir hedefi takip ederken büyük bir avantaja sahiptirler. Kanallı roketler için bu avantajı sağlamanın anahtarı, temel alt elemanlarından birisi olan gaz jeneratörü içerisinde yüksek hassasiyetle basınç kontrolü yapmaktır. Ancak, sistemin doğası bu kontrol problemini zorlaştırmaktadır, çünkü, sistemin modeli zaman değişimlidir ve doğrusal değildir. Dahası, zorlu çalışma koşullarından dolayı sistemde bilinmezlik ve dış bozucu etkenler gözlemlenmektedir. Açık literatürde bu kontrol problemine getirilen çözümler genel olarak doğrusal kontrolcü yaklaşımlarını içermektedir. Ancak problemin zorluğu, literatürde yer alan çalışmalardan farklı bir yaklaşıma ihtiyaç olduğunu göstermektedir. Bu nedenle, bu tezde, bir `zaman gecikmesine dirençli kapalı döngü referans modelli adaptif kontrolcü` geliştirilerek kontrol probleminin daha etkili bir şekilde çözümü sağlanmıştır. Önerilen kontrolcü, zaman gecikmesi direnci ve düzeltilmiş geçici tepki iyileştirmelerini bünyesinde barındırır. Kontrolcü, değişken itkili kanallı roket çalışmalarında bir kilometre taşı olarak kullanılan soğuk hava akış test sistemine başarılı bir şekilde gömülmüştür. Nümerik simülasyon ve testler sonucunda, önerilen kontrolcünün, farklı adaptif kontrolcülere ve sabit kazançlı bir kontrolcüye kıyasla daha yüksek bir zaman gecikmesi direnci ile iyileştirilmiş bir performans ortaya koyduğu gözlemlenmiştir. Adaptif kontrolcüler için adım adım tasarım prosedürü, gürbüzlüğü artırıcı metot, adaptasyon oranı ve başlangıç durumları belirleme konuları da kontrolcü tasarımını kolaylaştırmak adına tezde ele alınmıştır. Having variable thrust during the operation of a rocket provides tremendous advantages while chasing down a target. For ducted rockets, the key factor to obtain variable thrust is the precise pressure control inside the gas generator, which is one of the main elements of a throttleable ducted rocket and utilized to generate the fuel in gaseous form for combustion. However, the inherent nature ofthe system makes the control problem difficult due to time varying parameters, nonlinearities and time delays. Furthermore, disturbances and uncertainties exist due to challenging operation conditions. All these challenges make it necessary to design an advanced control approach. Therefore, a delay resistant closed loop reference model adaptive control is proposed in this thesis to address the control problem. The proposed controller combines delay compensation and adaptation with improved transient response. The controller is successfully implemented using an industrial grade cold air test setup, which is a milestone towards obtaining a fully developed throttleable rocket gas generator controller. Simulation and experimental comparisons with alternative adaptive approaches and a fixed controller demonstrate improved performance and effective handling of time delays and uncertainties. A step by step design methodology, covering robustfying schemes, selection of adaptation rates and initial controller parameters, is also provided to facilitate implementations. 88

Published
2017

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