Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 1 Chapter 11 Information.

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Presentation transcript:

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 1 Chapter 11 Information Theoretic Limits of Cognitive Radio Networks

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 2 Outline Introduction Rise+importance of cognitive networks Types of cognitive behavior Information theory basics Interference avoiding behavior Interference controlled behavior Interference mitigating behavior Summary

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 3 Introduction Primary users: primary spectrum license holders. Generally have priority access to spectrum. Secondary users: may access, under certain negotiated conditions, spectrum which is licensed out to primary users. Generally considered to use cognitive radio technology.

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 4 Introduction Primary users Secondary/cognitive users

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 5 Introduction In this chapter we focus on the information theoretic limits of communication in networks in which a subset of devices are cognitive radios. Cognitive radios have extra flexibility and capabilities: this must be modeled information theoretically! Different amounts of cognition are possible

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 6 Types of cognitive behavior How to manage interference is critical in wireless networks Cognitive behavior may be differentiated by how interference is handled: Interference avoiding Interference controlled Interference mitigating

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 7 Types of cognitive behavior: interference avoiding Secondary users communicate so as to completely avoid interfering with the primary users. ``white-space-filling ``spectral gap filling ``orthogonal

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 8 Types of cognitive behavior: interference controlled Secondary users communicate and control the amount of interference they cause the primary users. ``spectrum underlay ``interference- temperature

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 9 Types of cognitive behavior: interference mitigating Secondary users communicate and mitigate the interference seen from the primary to the secondary receiver through exploitation of side information. ``cognition

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 10 Information theory basics x: channel inputs in alphabet X y: channel outputs in alphabet Y In information theory, a channel is modeled as a set of conditional distributions p(y|x) for each x in X.

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 11 Information theory basics Two most common channels:

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 12 Information theory basics Measures of interest: 1) Capacity/capacity regions: largest rate / rate regions at which reliable communication may be ensured. 2) Throughput scaling laws: how the sum throughput in a network scales with the number of nodes in the network. 12

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 13 Entropy and mutual information Mutual information between random variables X and Y:

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 14 Channel capacity Information channel capacity: Highest rate (bits/channel use) that can communicate at reliably X Y Channel: p(y|x) Operational channel capacity: Channel coding theorem says: Information capacity = operational capacity

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 15 Gaussian channel capacity What about bits/second and bandwidth of the channel?

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 16 R1R1 R2R2 R1R1 R2R2 R2R2 R1R1 Point to point capacity R X Capacity regions Multi-user capacity region C 0 R C 0 R X

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) Scaling laws [Gupta+Kumar 2000]: Non-cooperative ad hoc networks per-node throughput ~ O(1/n) Degradation is due to multi-hop and interference between nodes What about cognitive networks? [Ozgur, Leveque, Tse 2007]: Cooperative ad hoc networks nodes may cooperate as in a MIMO system per-node throughput ~ O(1) (constant)

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 18 Classical multi-user channels

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 19 Relay channel A source and destination communicate through the help of a relay. Capacity is only known for certain classes of channels. Cognitive nodes may act as relays for primary nodes.

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 20 Multiple-access channel Two independent sources wish to communicate with the same destination. The capacity region is well understood. Superposition coding and successive decoding are key to achieving capacity.

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 21 Broadcast channel A single transmitter wishes to communicate with two independent receivers. The capacity region is unknown in general but is known for the Gaussian MIMO broadcast channel. Dirty paper coding has been shown to be capacity-achieving. 21

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 22 Interference channel Two independent transmitters wish to communicate wish two independent receivers. Capacity region is unknown in general, though is known to within a couple of bits in the Gaussian noise case. Rate-splitting achieves the largest known rate-region.

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 23 Cognitive channels? How can we model channels in which some of the nodes are cognitive radios? Can we draw inspiration/techniques from the ``classical relay, multiple- access, broadcast and interference channels? 23

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 24 Cognitive channels In the remainder, we will explain the following cognitive behaviors: 24

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 25 Cognitive channels For the purpose of illustration we assume an AWGN channel model described by the equations

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 26 Interference-avoiding behavior Secondary user knowledge: ideal knowledge of exactly when/where (time/freq/code) the primary user is transmitting. Secondary user behavior: fills in the gaps whenever the primary user is not transmitting.

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 27 Interference-controlled behavior Secondary user knowledge: the interference conditions at the primary Rx and the channel between secondary Tx and primary Rx Secondary user behavior: transmits with power such that the received interference at the primary Rx is within pre-defined threshold

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 28 Interference-mitigating behavior Type 1: Secondary user knowledge: the codebooks of the primary user Secondary user behavior: the secondary Rx may be able to decode the primary message and strip it off the received signal

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 29 Interference-mitigating behavior Type 2: Secondary Tx knowledge: the codebooks of the primary user and the message of the primary user Secondary user behavior: the secondary Tx codes so as to relay the primary message as well as mitigate its interference at the secondary Rx using dirty-paper coding

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 30 Aside: dirty-paper coding In the following channel model, if interference S is known non-causally at the Tx but not the Rx, the capacity region is that of an interference-free system!

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 31 Behaviors Interfere-mitigating cognitive behavior (type 2) fits well within the context of competitive, cooperative and cognitive behaviors:

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 32 Interference-mitigating behavior

Cognitive Radio Communications and Networks: Principles and Practice By A. M. Wyglinski, M. Nekovee, Y. T. Hou (Elsevier, December 2009) 33 Chapter 11 Summary The achievable rate regions depend on the amount of side-information the cognitive Tx/Rx has about the primary transmission. Studied 3 different types of behavior: interference avoiding, interference- controlled and interference-mitigating cognitive behavior from an information theoretic perspective.