Time-Varying Sensor and Actuator Selection for Uncertain Cyber-Physical Systems

Taha, Ahmad F.; Gatsis, Nikolaos; Summers, Tyler H.; Nugroho, Sebastian A.

doi:10.1109/tcns.2018.2873229

Cited by 34 publications

(21 citation statements)

References 41 publications

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“…and u based on f I i (·) 3 set:S as a subset in C with the greatest upper bound 4 Phase I: find the best upper bound 5 while u − l > h and S > x do 6 SplitS via BnB routines 7 Update C,S, l, and u based on f I i (·) 8 Phase II: find the best lower bound 9 while u − l > h and ∃S j ∈ C, |S j | > x do 10 Split S j via BnB routines 11 Update C,S, l, and u based on f I i (·) 12 Output: β i ← u not contain any maximizer is then discarded. These two routines are performed iteratively until the algorithm terminates.…”

Section: B Interval-based Optimization Approachmentioning

confidence: 99%

“…To solve P2, one reasonable approach is to transform P2 into MISDP. The reformulation of P2 from nonconvex MISDP to convex MISDP can be carried out by either using big-M method [7], [24] or McCormick's relaxation [6], [25]. With that in mind, here we present a way of reformulating P2 into MISDP via McCormick's relaxation.…”

Section: Convex Misdp Formulations Of Spp For Nds a The Case Formentioning

confidence: 99%

“…For instance, if the 0/1 integer constraint is relaxed such that γ j ∈ [0, 1], P2 can be solved through SDP routines-our earlier work [7] presents a thorough study on addressing actuator selection for linear dynamic systems through a robust control framework via SDP relaxations and approximations, as well as big-M method and heuristics. Recently, [9] revisits the problem described in [7] by proposing an approach that combines a new reformulation method to tackle the nonconvexity due to the multiplication between integer variables and matrix variable with BnB algorithm. By limiting the number of iterations on the BnB algorithm, the computational time can be shortened.…”

Section: Convex Misdp Formulations Of Spp For Nds a The Case Formentioning

confidence: 99%

See 2 more Smart Citations

Sensor Placement Strategies for Some Classes of Nonlinear Dynamic Systems via Lyapunov Theory

Nugroho

Taha

2019

2019 IEEE 58th Conference on Decision and Control (CDC)

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In this paper, the problem of placing sensors for some classes of nonlinear dynamic systems (NDS) is investigated. In conjunction with mixed-integer programming, classical Lyapunov-based arguments are used to find the minimal sensor configuration such that the NDS internal states can be observed while still optimizing some estimation metrics. The paper's approach is based on two phases. The first phase assumes that the encompassed nonlinearities belong to one of the following function set classifications: bounded Jacobian, Lipschitz continuous, one-sided Lipschitz, or quadratically inner-bounded. To parameterize these classifications, two approaches based on stochastic point-based and interval-based optimization methods are explored. Given the parameterization, the second phase formulates the sensor placement problem for various NDS classes through mixed-integer convex programming. The theoretical optimality of the sensor placement alongside a state estimator design are then given. Numerical tests on traffic network models showcase that the proposed approach yields sensor placements that are consistent with conventional wisdom in traffic theory.

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Section: B Interval-based Optimization Approachmentioning

confidence: 99%

Section: Convex Misdp Formulations Of Spp For Nds a The Case Formentioning

confidence: 99%

Section: Convex Misdp Formulations Of Spp For Nds a The Case Formentioning

confidence: 99%

See 1 more Smart Citation

Sensor Placement Strategies for Some Classes of Nonlinear Dynamic Systems via Lyapunov Theory

Nugroho

Taha

2019

2019 IEEE 58th Conference on Decision and Control (CDC)

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“…Control allocation is often necessary in redundantly actuated systems, such as parallel manipulators or fault‐tolerant systems, where the dimension of the control signal is less than or equal to the number of actuators available . Furthermore, a system's sensors and actuators can simultaneously be combined or selected in an optimal manner to minimize closed‐loop performance metrics or the number of sensors and actuators needed for closed‐loop stability …”

Section: Introductionmentioning

confidence: 99%

“…29 Control allocation is often necessary in redundantly actuated systems, such as parallel manipulators or fault-tolerant systems, where the dimension of the control signal is less than or equal to the number of actuators available. 30,31 Furthermore, a system's sensors and actuators can simultaneously be combined or selected in an optimal manner to minimize closed-loop performance metrics 32,33 or the number of sensors and actuators needed for closed-loop stability. 34 The novel contributions of this paper include techniques to linearly combine an LTI system's actuators and/or sensors in such a manner that the new system is interior conic with prescribed bounds and the difference between the new system and a specified desired system is minimized in a weighted  2 or  ∞ sense.…”

Section: Introductionmentioning

confidence: 99%

Optimal linear combination of sensors and actuators to enforce an interior conic open‐loop system

Caverly

2019

Intl J Robust & Nonlinear

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Summary This paper presents techniques to linearly combine the sensor measurements and/or actuator inputs of a linear time‐invariant system to obtain a new system that is interior conic with prescribed bounds. In the optimal sensor combination problem, a desired system output is defined, and in the optimal actuator combination problem, a desired system input is defined, along with a frequency bandwidth in which the desired system input or output should be matched. The simultaneous optimal sensor and actuator combination problem includes desired system outputs and inputs. In all cases, the weighted scriptH2 or scriptH∞ norm of the difference between the system with linearly combined sensors or actuators and the desired system is minimized while rendering the new system interior conic with prescribed bounds. The weighting transfer matrix used in the scriptH2‐ or scriptH∞‐optimization problem is determined by the frequency bandwidth of interest. The individual sensor and actuator combination methods involve linear matrix inequality constraints and are posed as convex optimization problems, whereas the combined sensor and actuator method is an iterative procedure composed of convex optimization steps. Numerical examples illustrate superior tracking performance with the proposed sensor and actuator combination techniques over comparable techniques in the literature when implemented with a simple feedback controller. Robust asymptotic stability of the closed‐loop system to plant uncertainty is demonstrated in the numerical examples.

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Event‐driven disturbance rejection control for discrete time‐varying systems

Zhang

Yin

et al. 2021

Intl J Robust & Nonlinear

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In this article, the problem of event-driven output feedback control is addressed for discrete time-varying systems with external disturbances. To estimate the unmeasured system states and external disturbances, a novel time-varying extended state functional observer is designed. Then, an event-driven control scheme is proposed to reduce the utilization of the communication resources, and the optimal feedback gain is designed by minimizing the upper bound of the cost function. Moreover, the disturbance rejection analyses are performed.Finally, the effectiveness of the proposed control approaches is illustrated through the numerical simulations. K E Y W O R D Sdiscrete time-varying systems, disturbance rejection control, event-driven strategy, extended state functional observer INTRODUCTIONIn the past decade, with the widespread use of Internet technology, the cyber-physical systems (CPSs), which combine the cyber and physical worlds by seamlessly integrating sensing, control, communication, and computation, have received many attentions. [1][2][3] The CPSs can offer a number of benefits such as increased mobility, lower economic and maintenance cost. However, there are some undesirable network-induced phenomena during the data transmission in the communication networks, such as network bandwidth constraints. 4 It should be pointed out that, in the traditional time-driven communication networks, the measurements and control inputs are transmitted periodically, which may waste the communication resources. To address this problem, an event-driven control scheme is proposed for saving the network bandwidth in the work of Zhang and Feng. 5 With this strategy, the bandwidth of communication network can be effectively reduced by sending necessary control signals under a predesigned event-triggering condition. 6 Benefiting from the event-driven control strategy, some improved methods have been applied in various types of systems. [7][8][9] For example, considering the consensus problem of linear multiagent systems on directed graph, a novel adaptive event-driven state feedback protocol is designed in the work of Li et al. 8 In the work of Xiong et al., 9 combined with the aperiodic sampled-data mechanism, a novel pull-based event-driven protocol is presented for systems. Note that most of the existing literatures focus on time-invariant systems, but the time-varying systems widely exist in practical applications. More recently, an adaptive event-driven control mechanism is studied for economizing the communication resources in the work of Chen et al. 10 In practical systems resulting from load variations, model uncertainties, or environmental noises, external disturbances always affect the control performances of the systems. Therefore, the disturbance attenuation and rejection

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Time-Varying Sensor and Actuator Selection for Uncertain Cyber-Physical Systems

Cited by 34 publications

References 41 publications

Sensor Placement Strategies for Some Classes of Nonlinear Dynamic Systems via Lyapunov Theory

Sensor Placement Strategies for Some Classes of Nonlinear Dynamic Systems via Lyapunov Theory

Optimal linear combination of sensors and actuators to enforce an interior conic open‐loop system

Event‐driven disturbance rejection control for discrete time‐varying systems

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