A convex optimization approach to signal reconstruction over switching networks. (English) Zbl 1192.93017
Summary: We consider signal reconstruction over communication network channels that can be modeled as input switching systems. Such systems can be associated with a variety of applications including control and estimation over networks. In particular, we formulate the signal reconstruction problem as a prototypical model matching problem where the various mappings involved belong to a class of input switching systems. The design interest is placed on minimizing the worst case or stochastic average performance of this model matching system over all possible switchings with an \(\mathcal H_2\) norm as the performance criterion. This minimization is performed over all stable receivers \(R\) in the class of input switching systems. For the particular setup at hand, and in the case of matched switching, two convergent sequences to the optimal solution from above and below respectively are formulated in terms of quadratic programs. An approximate solution with any a priori given precision is possible by finite truncation. Also, it is shown that in the cases of arbitrary, partially matched or unmatched switching, the optimal receiver \(R\) need not depend on the switching sequence and that it can be obtained as a linear time-invariant solution to an associated \(\mathcal H_2\) norm optimization.
MSC:
| 93A30 | Mathematical modelling of systems (MSC2010) |
| 94A12 | Signal theory (characterization, reconstruction, filtering, etc.) |
| 90C25 | Convex programming |
| 93E03 | Stochastic systems in control theory (general) |
Keywords:
signal reconstruction; worst case switching; stochastic switching; model matching; convex programmingReferences:
| [1] | Ahmad, A., Wireless and mobile data networks (2005), John Wiley & Sons, Inc: John Wiley & Sons, Inc Hoboken, NJ |
| [2] | Alkar, A. Z.; Buhur, U., An internet based wireless home automation system for multifunctional devices, IEEE Transactions on Consumer Electronics, 51, 4, 1169-1174 (2005) |
| [3] | Arslan, H.; Bottomley, G. E., Channel estimation in narrowband wireless communication systems, Wireless Communications and Mobile Computing, 1, 2, 201-219 (2001) |
| [4] | Chapellat, H.; Dahleh, M., Analysis of time-varying control strategies for optimal disturbance rejection and robustness, IEEE Transactions on Automatic Control, 37, 11, 1734-1745 (1992) · Zbl 0778.93071 |
| [5] | Chizeck, H. J.; Ji, Y., Optimal quadratic control of jump linear systems with gaussian noise in discrete-time, (Proceedings of the 27th IEEE conference on decision and control (1988)), 1989-1992 |
| [6] | Conway, J. B., A course in functional analysis (1985), Springer-Verlag: Springer-Verlag New York · Zbl 0558.46001 |
| [7] | Costa, O. L.V.; Guerra, S., Stationary filter for linear minimum mean square error estimator of discrete-time Markovian jump systems, IEEE Transactions on Automatic Control, 47, 8, 1351-1356 (2002) · Zbl 1364.93795 |
| [8] | Culler, D.; Estrin, D.; Srivastava, M., Overview of sensor networks, IEEE Computer, 37, 8, 41-49 (2004) |
| [9] | Dahleh, M. A.; Diaz-Bobillo, I. J., Control of uncertain systems: A linear programming approach (1995), Prentice Hall: Prentice Hall Englewood Cliffs, NJ · Zbl 0838.93007 |
| [10] | de Souza, C. E.; Fragoso, M. D., \(H_\infty\) filtering for discrete-time systems with Markovian jump parameters, International Journal of Robust and Nonlinear Control, 13, 14, 1299-1316 (2003) · Zbl 1043.93016 |
| [11] | Liberzon, D., Switching in systems and control (2003), Birkhäuser: Birkhäuser Boston, MA · Zbl 1036.93001 |
| [12] | Qi, X.; Salapaka, M. V.; Voulgaris, P. G.; Khammash, M., Structured optimal and robust control with multiple criteria: A convex solution, IEEE Transactions on Automatic Control, 49, 10, 1623-1640 (2004) · Zbl 1365.93270 |
| [13] | Seiler, P.J. (2001). Coordinated control of unmanned aerial vehicles. Ph.D. thesis; Seiler, P.J. (2001). Coordinated control of unmanned aerial vehicles. Ph.D. thesis |
| [14] | Shorten, R.; Wirth, F.; Mason, O.; Wulff, K.; King, C., Stability criteria for switched and hybrid systems, SIAM Review, 49, 4, 545-592 (2007) · Zbl 1127.93005 |
| [15] | Simon, M. K.; Alouini, M., Digital communication over fading channels (2004), John Wiley & Sons, Inc: John Wiley & Sons, Inc Hoboken, NJ |
| [16] | Smith, S. C.; Seiler, P. J., Estimation with lossy measurements: Jump estimatiors for jump systems, IEEE Transactions on Automatic Control, 48, 12, 2163-2171 (2003) · Zbl 1364.93785 |
| [17] | Tse, D.; Viswanath, P., Fundamentals of wireless communication (2005), Cambridge University Press · Zbl 1099.94006 |
| [18] | US Department of Energy, Industrial wireless technology for the 21st century, (Proceedings of industrial wireless workshop (2002)) |
| [19] | Varaiya, P., Smart cars on smart roads: Problems of control, IEEE Transactions on Automatic Control, 38, 2, 195-207 (1993) |
| [20] | Voulgaris, P. G.; Hadjicostis, C. N.; Touri, R., A robust control approach to perfect reconstruction of digital signals, IEEE Transaction on Signal Processing, 55, 9, 4444-4457 (2007) · Zbl 1390.94460 |
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