Approximation methods for optimal network coding in a multi-hop control network with packet losses

Smarra, Francesco; D’Innocenzo, Alessandro; Benedetto, Maria

doi:10.1109/ecc.2015.7330826

Cited by 9 publications

(9 citation statements)

References 22 publications

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“…We assumed that a time‐invariant controller gain

\overset{K}{true}

is designed via assigning the eigenvalues of the closed‐loop system in the nominal case (ie, neglecting the effect of packet losses) and that the actuator computes a linear combination

\sum_{i = 1}^{r} γ_{i} u_{i} false(k - n_{i} false)

of the data incoming from different routing paths and provided a suboptimal algorithm to compute the optimal weights γ i that maximize a metric induced by the notion of mean square stability. This paper extends and improves the results in the work of Smarra et al in several ways. First, we introduce the communication scheduling in our model and consider the effect of scheduling on the communication delay of each path.…”

Section: Introductionsupporting

confidence: 87%

“…In the work of Smarra et al, a state‐feedback control loop was considered as in Figure where multiple copies

u_{1} false(k false) = u_{2} false(k false) = … = u_{r} false(k false) = \overset{K}{true} x_{p} false(k false)

of the same actuation data are sent from the controller to the plant via r routing paths, each characterized by a delay equal to the number of hops n i (ie, scheduling was not considered, as instead we do in this paper) and a packet losses probability p i . We assumed that a time‐invariant controller gain

\overset{K}{true}

is designed via assigning the eigenvalues of the closed‐loop system in the nominal case (ie, neglecting the effect of packet losses) and that the actuator computes a linear combination

\sum_{i = 1}^{r} γ_{i} u_{i} false(k - n_{i} false)

of the data incoming from different routing paths and provided a suboptimal algorithm to compute the optimal weights γ i that maximize a metric induced by the notion of mean square stability.…”

Section: Introductionmentioning

confidence: 99%

“…Second, we assume that the actuation packets u 1 ( k ),…, u r ( k ) are not necessarily equal and we optimally design a time‐varying gain matrix for each path in the network, ie,

false[K_{1} false(k false) \in {double-struckR}^{m \times n}; …; K_{r} false(k false) \in {double-struckR}^{m \times n} false] = K false(k false) \in {double-struckR}^{r m \times n}

, taking into account the effect of packet losses and of the delays induced by the scheduling. Note that the problem formulation in the work of Smarra et al is a special case of the above definition where

K false(k false) = false[γ_{1} \overset{K}{true}; …; γ_{r} \overset{K}{true} false]

. Furthermore, while in the work of Smarra et al, the optimization is made on a metric based on the notion of mean square stability (ie, only taking into account the steady‐state behavior), here, we only focus on the transient behavior setting up a finite‐horizon LQR problem.…”

Section: Introductionmentioning

confidence: 99%

“…Note that the problem formulation in the work of Smarra et al is a special case of the above definition where

K false(k false) = false[γ_{1} \overset{K}{true}; …; γ_{r} \overset{K}{true} false]

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Codesign of controller, routing and scheduling in WirelessHART networked control systems

Girolamo

D’Innocenzo

2019

Intl J Robust & Nonlinear

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Summary In this paper, we provide a novel methodology to co‐design controller, scheduling and routing in a wireless control network compliant with the WirelessHART protocol. We both provide a modeling framework and derive a novel suboptimal solution to the linear‐quadratic regulator problem for a class of systems that extends Markov jump linear system considering both continuous and discrete inputs. To allow that, our results can be directly implemented in a real WirelessHART network, we setup a receding horizon optimization problem that takes into account the constraint for compliance with WirelessHART and validate our solution on a batch reactor control loop.

show abstract

“…We assumed that a time‐invariant controller gain

\overset{K}{true}

is designed via assigning the eigenvalues of the closed‐loop system in the nominal case (ie, neglecting the effect of packet losses) and that the actuator computes a linear combination

\sum_{i = 1}^{r} γ_{i} u_{i} false(k - n_{i} false)

Section: Introductionsupporting

confidence: 87%

“…In the work of Smarra et al, a state‐feedback control loop was considered as in Figure where multiple copies

u_{1} false(k false) = u_{2} false(k false) = … = u_{r} false(k false) = \overset{K}{true} x_{p} false(k false)

\overset{K}{true}

is designed via assigning the eigenvalues of the closed‐loop system in the nominal case (ie, neglecting the effect of packet losses) and that the actuator computes a linear combination

\sum_{i = 1}^{r} γ_{i} u_{i} false(k - n_{i} false)

of the data incoming from different routing paths and provided a suboptimal algorithm to compute the optimal weights γ i that maximize a metric induced by the notion of mean square stability.…”

Section: Introductionmentioning

confidence: 99%

“…Second, we assume that the actuation packets u 1 ( k ),…, u r ( k ) are not necessarily equal and we optimally design a time‐varying gain matrix for each path in the network, ie,

false[K_{1} false(k false) \in {double-struckR}^{m \times n}; …; K_{r} false(k false) \in {double-struckR}^{m \times n} false] = K false(k false) \in {double-struckR}^{r m \times n}

K false(k false) = false[γ_{1} \overset{K}{true}; …; γ_{r} \overset{K}{true} false]

Section: Introductionmentioning

confidence: 99%

“…Note that the problem formulation in the work of Smarra et al is a special case of the above definition where

K false(k false) = false[γ_{1} \overset{K}{true}; …; γ_{r} \overset{K}{true} false]

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Codesign of controller, routing and scheduling in WirelessHART networked control systems

Girolamo

D’Innocenzo

2019

Intl J Robust & Nonlinear

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show abstract

“…In these works, NCSs with missing packets are modeled as time‐homogeneous MJLSs, which are an important family of stochastic hybrid systems. In particular, it is shown (eg, in other works()) that discrete‐time MJLSs (MJLSs) represent a promising mathematical model to jointly take into account the dynamics of a physical plant and the nonidealities of wireless communication such as packet losses. This is the main reason for adopting such a model in this paper.…”

Section: Introductionmentioning

confidence: 99%

Efficient routing redundancy design over lossy networks

Smarra

Benedetto

D’Innocenzo

2018

Intl J Robust & Nonlinear

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Summary In this paper, a wireless networked control system is made robust with respect to packet losses by exploiting routing redundancy. Multiple copies of sensing and actuation data are sent via different routing paths, associated to possibly different delays. Similar to linear network coding, such data are recombined as a weighted linear combination. A MIMO output‐feedback architecture is considered. A methodology that takes into account both the network parameters and the plant dynamics is proposed to set up an optimization problem to design network weights to satisfy a robustness metric based on the notion of asymptotic mean‐square stability. Such metric induces either an objective or a constraint function that is nonlinear. For this reason, an efficient suboptimal design methodology is also proposed. Finally, the solutions are compared with the optimal choice from the communication designer point of view, which is based on the minimization of the quadratic error induced by the network on the actuation signal. The suboptimal methodology is shown, by means of a nontrivial example, to give results extremely close to the optimum with a strongly reduced computation time. It is also shown that the optimal choice from the communication design point of view, which neglects the plant dynamics, does not guarantee stochastic stability.

show abstract

Modeling and Co-Design of Control Tasks over Wireless Networking Protocols

D’Innocenzo

2018

Control Subject to Computational and Communication Constraints

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Approximation methods for optimal network coding in a multi-hop control network with packet losses

Cited by 9 publications

References 22 publications

Codesign of controller, routing and scheduling in WirelessHART networked control systems

Codesign of controller, routing and scheduling in WirelessHART networked control systems

Efficient routing redundancy design over lossy networks

Modeling and Co-Design of Control Tasks over Wireless Networking Protocols

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