Optimal control with unreliable communication: The TCP case

Bruno Sinopoli; Luca Schenato; Massimo Franceschetti; Kameshwar Poolla; Shankar S. Sastry

Optimal control with unreliable communication: The TCP case

Bruno Sinopoli
, Luca Schenato
, Massimo Franceschetti
, Kameshwar Poolla
, Shankar S. Sastry

Research output: Contribution to journal › Conference article › peer-review

Abstract

The paper considers the Linear Quadratic Gaussian (LQG) optimal control problem in the discrete time setting and when data loss may occur between the sensors and the estimation-control unit and between the latter and the actuation points. We consider the case where the arrival of the control packet is acknowledged at the receiving actuator, as it happens with the common Transfer Control Protocol (TCP). We start by showing that the separation principle holds. Additionally, we can prove that the optimal LQG control is a linear function of the state. Finally, building upon our previous results on estimation with unreliable communication, the paper shows the existence of critical arrival probabilities below which the optimal controller fails to stabilize the system. This is done by providing analytic upper and lower bounds on the cost functional.

Original language	English
Article number	ThC17.2
Pages (from-to)	3354-3359
Number of pages	6
Journal	Proceedings of the American Control Conference
Volume	5
State	Published - 2005
Event	2005 American Control Conference, ACC - Portland, OR, United States Duration: Jun 8 2005 → Jun 10 2005

Cite this

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title = "Optimal control with unreliable communication: The TCP case",

abstract = "The paper considers the Linear Quadratic Gaussian (LQG) optimal control problem in the discrete time setting and when data loss may occur between the sensors and the estimation-control unit and between the latter and the actuation points. We consider the case where the arrival of the control packet is acknowledged at the receiving actuator, as it happens with the common Transfer Control Protocol (TCP). We start by showing that the separation principle holds. Additionally, we can prove that the optimal LQG control is a linear function of the state. Finally, building upon our previous results on estimation with unreliable communication, the paper shows the existence of critical arrival probabilities below which the optimal controller fails to stabilize the system. This is done by providing analytic upper and lower bounds on the cost functional.",

author = "Bruno Sinopoli and Luca Schenato and Massimo Franceschetti and Kameshwar Poolla and Sastry, \{Shankar S.\}",

year = "2005",

language = "English",

volume = "5",

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journal = "Proceedings of the American Control Conference",

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TY - JOUR

T1 - Optimal control with unreliable communication

T2 - 2005 American Control Conference, ACC

AU - Sinopoli, Bruno

AU - Schenato, Luca

AU - Franceschetti, Massimo

AU - Poolla, Kameshwar

AU - Sastry, Shankar S.

PY - 2005

Y1 - 2005

N2 - The paper considers the Linear Quadratic Gaussian (LQG) optimal control problem in the discrete time setting and when data loss may occur between the sensors and the estimation-control unit and between the latter and the actuation points. We consider the case where the arrival of the control packet is acknowledged at the receiving actuator, as it happens with the common Transfer Control Protocol (TCP). We start by showing that the separation principle holds. Additionally, we can prove that the optimal LQG control is a linear function of the state. Finally, building upon our previous results on estimation with unreliable communication, the paper shows the existence of critical arrival probabilities below which the optimal controller fails to stabilize the system. This is done by providing analytic upper and lower bounds on the cost functional.

AB - The paper considers the Linear Quadratic Gaussian (LQG) optimal control problem in the discrete time setting and when data loss may occur between the sensors and the estimation-control unit and between the latter and the actuation points. We consider the case where the arrival of the control packet is acknowledged at the receiving actuator, as it happens with the common Transfer Control Protocol (TCP). We start by showing that the separation principle holds. Additionally, we can prove that the optimal LQG control is a linear function of the state. Finally, building upon our previous results on estimation with unreliable communication, the paper shows the existence of critical arrival probabilities below which the optimal controller fails to stabilize the system. This is done by providing analytic upper and lower bounds on the cost functional.

UR - https://www.scopus.com/pages/publications/23944449300

M3 - Conference article

AN - SCOPUS:23944449300

SN - 0743-1619

VL - 5

SP - 3354

EP - 3359

JO - Proceedings of the American Control Conference

JF - Proceedings of the American Control Conference

M1 - ThC17.2

Y2 - 8 June 2005 through 10 June 2005

ER -

Optimal control with unreliable communication: The TCP case

Abstract

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