To Relay or Not to Relay? Optimizing Multiple Relay Transmissions by Listening in Slow Fading Cooperative Diversity Communication

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To Relay or Not to Relay? Optimizing Multiple Relay Transmissions by Listening in Slow Fading Cooperative Diversity Communication Aggelos Bletsas, Moe Z. Win, Andrew Lippman Massachusetts Institute of Technology 77 Massachusetts Ave, Cambridge, MA 0239 aggelos@media.mit.edu Abstract The formation of virtual antenna arrays among cooperating nodes, distributed in space, has been shown to provide improved resistance to slow fading and has attracted considerable interest. Scaling cooperation in practice to a large number of participating relay nodes is an open area of research. It was recently shown that appropriate selection of a single, opportunistic available relay that maximizes a function of the end-to-end, instantaneous channel conditions, achieves the same diversity-multiplexing tradeoff with schemes that require multiple and simultaneous relay transmissions (possibly at the same frequency band) and employ distributed space-time coding. In this work we present analysis in slow fading environments that shows equivalence of opportunistic relaying to optimal decode-and-forward, based on distributed space-time coding, under an aggregate relay power constraint. Amplify-and-forward schemes under an aggregate relay power constraint are also examined, demonstrating improved performance when a single opportunistic relay is used. This result suggests that cooperative diversity benefits, under the assumptions followed in this work, are maximized when cooperative relays choose not to transmit, but rather choose to cooperatively listen, giving priority to the transmission of a single, opportunistic relay. In other words, cooperation benefits are maximized when relays act as sensors of the wireless channel and not necessarily as active retransmitters. Since no simultaneous transmissions are utilized, opportunistic relaying can be implemented in existing radio front ends and an actual implementation is briefly discussed. This work was supported by NSF under grant number CNS-043486, the MIT Media Laboratory Digital Life Program and a Nortel Networks graduate fellowship award. October 4, 2005 DRAFT

I. INTRODUCTION Utilization of terminals distributed in space can provide dramatic performance gains in wireless communication. For example, when Channel State Information (CSI) is available at a pair of neighboring nodes, then they could cooperatively beamform towards the final destination and increase total capacity [6]. When CSI is not available at a pair of cooperating nodes, or when radio hardware cannot support beamforming, then cooperation could provide for improved resistance to wireless fading [0]. There has been a tremendous interest in the research community around the theme of cooperation and basic results of single-relay cooperation analysis are presented in [9] and in references found there. Scaling cooperation to more than one relays and benefiting from their existence is still an open area of research. Distributed space-time coding could be used among the participating nodes, to achieve the optimal diversitymultiplexing tradeoff []. In practice, such code design becomes difficult given the distributed and ad-hoc nature of cooperative links, as opposed to Multiple Input Multiple Output (MIMO) links, where antennas belong to common terminals and for which, space-time coding was originally invented. For example, it is difficult in practice for each relay to acquire information about the channel state of other relays, as needed in the scheme proposed in [2]. It is also difficult for the receiver to acquire information about the channel state between source and all relays, because the receiver has no means to estimate such information and therefore, those channel states should be communicated to the receiver. Such space-time coding scheme that requires global CSI at the receiver, including information about the paths between source and relays, was proposed in [8], based on linear dispersion codes. An additional difficulty in applying MIMO space-time coding into the cooperative relay channel, is the fact that the number of useful antennas (relays) for cooperation is, in general, unknown and varying. Additional difficulties arise in the analysis and implementation of cooperative relay links. Baseband analysis, originating from the MIMO literature, implicitly assumes perfect carrier phase recovery at the receiver, even when multiple cooperative relays are simultaneously transmitting, allowing coherent reception at the receiver, with gains that scale with the number of transmitting elements [7]. Carrier phase recovery in MIMO links involves estimation and tracking of carrier phase differences among two participating oscillators, one at the transmitter and one at the receiver, in the presence of additive thermal noise (due to thermodynamics in the receiver) and multiplicative noise (due to multipath fading). However, carrier phase recovery in multiple cooperative relay links involves estimation and tracking of carrier phase differences among several transmit-receive pairs, proportionally to the number of participating relays, increasing the implementation complexity and therefore, the cost of the receiver. That is a fact that is usually hidden, when baseband performance analysis is conducted to evaluate cooperative reception schemes involving distributed transmitters. In an effort to simplify cooperative diversity to practice in slow fading environments, two modifications were recently proposed [4], [5]: Only a single relay is allowed to transmit (no same frequency band, simultaneous transmissions). The relay selection is proactive and is performed before the actual message is transmitted, in an effort to 2

Fig.. Scenario addressed in this work: source and destination are blocked or have poor connection. Relays forward information in the simplest two-stage scheme and different relay strategies are compared. save reception energy at the intermediate participating relays. In that way, relays which are not effective in retransmitting information, could enter sleep mode. The relay selection is distributed, requiring each relay to only know its own instantaneous channel conditions, towards source and destination (partial CSI at each relay). Each relay does not need to know the channel state (or functions of CSI) of other relays towards source and destination. It is even possible for the relays to be hidden from each other, meaning that they can not listen to each other transmissions, even though they are in communication range with source and destination. For example, consider the scenario when two relays are blocked by an intermediate wall, even though they both have line-of-sight with source and destination. Through a distributed contention resolution mechanism based on time, the best relay is elected and used for information forwarding, in a scheme called opportunistic relaying. The relay selection is completed within a small fraction of the channel coherence time, with a probability of success carefully analyzed and calculated. The analysis of the diversity-multiplexing gain tradeoff in opportunistic relaying (found in [5]) for both decode-and-forward and amplify-and-forward, revealed no performance loss compared to optimal distributed space-time coding, even though the latter scheme is based on simultaneous relay transmissions, possibly at the same frequency band. In this work, we investigate the optimality of opportunistic relaying under an aggregate relay power constraint and compare it with: a) space-time coding techniques where relays simultaneously transmit and b) other single relay selection techniques, found in the literature. The motivation behind imposing an aggregate relay power constraint is twofold: a) regulatory agencies always impose a total transmission power limit and b) we want to show off that benefits of cooperation can arise even when relays do not transmit (and therefore, do not add energy into the system). Analysis includes decode-and-forward (regenerative) processing or amplify-and-forward processing at each relay. The gains of opportunistic relaying suggest that relays are useful, even when they do not transmit, provided that they adhere to the opportunistic cooperation rule and give priority to the best available relay. II. ASSUMPTIONS AND PROBLEM FORMULATION We assume slow Rayleigh fading, where the source of information has a poor link towards the final destination. Or it might be the case that the source has no channel state information regarding the link towards destination 3

or other intermediate relays. Under those assumptions, there is no throughput rate that could guarantee reliable communication and therefore, the Shannon capacity between source and destination is zero. In Fig. (), we depict this highly inconvenient communication scenario: source and destination are blocked by an intermediate wall, while relays are located at the periphery of the obstacle, around-the-corner. The relays are able to communicate with both endpoints (source and destination). We further assume the simplest, two step, reactive transmission scheme for half-duplex radios: during the first phase, the source transmits a given number of symbols and the relays listen, while during the second step, the relays forward a version of the received signal, using the same number of symbols. Since we assume slow Rayleigh fading, the channel conditions remain constant during the two phases, following a Rayleigh distribution and corresponding to channel coherence time at least equal to the transmission symbols block. Notice that if the source was allowed to transmit a different symbol, while the relays were forwarding the previous, improved performance could be observed, compared to the above half-duplex scheme [2], [5], since one channel degree of freedom is not wasted. However, in this work we are interested in finding out the optimal strategy for relay transmissions and possibly, simplify their operation as opposed to finding the optimal transmission strategy for the source. Notice also that we have divided the communication into two equal phases: during the first stage the source sends a specific number of symbols and during the second step, the relay(s) send the same number of symbols. This scheme assumes that cooperation is coordinated at the transmission block of symbols level, minimizing overhead and simplifying protocol implementation. An alternative approach could have the duration of the two phases variable, requiring coordination at the symbol level among participating nodes. Even though such assumption might be theoretically appealing, it is hard to implement in practice, since coordination at the symbol level would require coordination overhead proportional to the number of transmitted symbols, increasing overall complexity. It is also possible that relays could not possibly coordinate, given that they might be hidden from each other: connection to a common source-destination pair by no means implies successful inter-relay communication. Therefore, the relays should be coordinated by a common node (e.g. the source or the destination) and as everything in life, such coordination requires overhead. Imposing cooperation at the symbol level would simply multiply that overhead by the amount of transmitted symbols. On the other hand, fixing the phase duration for source and relay(s) transmissions at the block level, simplifies network operation and fixes the coordination overhead. An alternative approach would have the relays coordinate before the actual message is transmitted, at the beginning of the transmission block. Pilot signals from source and destination could be used so that the relays could assess their channel states towards source or destination, which won t change for the block duration (slow fading). We refer to this scheme as proactive transmission scheme and more details will be given in the subsequent section. The relay strategies that we are going to explore include simultaneous transmissions at the same frequency band using distributed space-time coding [] and we refer to that scheme as All-relays scheme. We further include single relay schemes that select best relay according to average signal strength ( Single relay ) [3] or instantaneous signal strength ( Opportunistic ). The former advocate relay selection according to which relay has 4

the smallest distance [8] towards destination while the later advocate relay selection based on which relay has the strongest end-to-end signal towards destination [4]. Note that relay selection schemes ought to provide for intelligent distributed implementations: the relay selection process should be performed while each relay has limited knowledge about the existence of other relay nodes or their channel conditions towards source or destination, as in [5]. Also, each relay selection scheme should be completed within a limited period of time, requiring small overhead. That is especially important if relay selection was performed after every transmitted symbol. In this paper, we do not assume relay selection (coordination) at the symbol level, but rather at the block level, as explained before. Therefore, the channel states are instantaneous, meaning that they correspond to that particular block are remain constant for that particular block (slow fading). Therefore, their sampling needs to be performed just once, during that block 2 For the discussion in the following sections, we assume that each relay has partial knowledge of its own channel conditions towards source or destination, in the form of signal strength (but not phase). Therefore, beamforming is not an option. The ergodic capacity under the above assumptions is zero, and therefore we use outage probability to characterize end-to-end performance between source and destination, across different multiple relay schemes. We further fix the total relay transmissions power to P R for M relays, during the second stage: P D + P 2D +... + P MD = P R = const () For simplicity, we assume that the source transmission power P S is also constant and equal to P R. Note that the optimal power allocation across source and relays depends on the CSI conditions and might be different than (P S = P R ) []. However, optimal power allocation across source and relays is meaningful when a) there is CSI information at the source regarding the whole network (including channel conditions between relays and destination) and b) there is a good direct link between source and destination. None of the above apply in our study. The main focus is not optimal power allocation but the more general question about what the relays should optimally do: re-transmit or not? III. DECODE AND FORWARD ANALYSIS In this section we assume that received signal between any two points (s d) is y d = a sd x s + n d, where a sd is complex, circularly symmetric Gaussian random variable with E[ a 2 sd γ sd] = γ sd (corresponding to Rayleigh fading) and n d is complex, circularly symmetric Gaussian random variable with E[ n 2 d ] =. We denote as ρ the end-to-end (source-relay-destination), target spectral efficiency, in bps/hz and SNR = P s / = P R /, the signal-to-noise ratio. under an isotropic propagation model that does not include shadowing. 2 technically, it should be performed no later than every half the channel coherence time (Nyquist rate). 5

A. Proactive Decode and Forward In Opportunistic relaying [4], [5], the best relay b is chosen among a collection of M possible candidates, in a distributed fashion that requires each relay to know its own signal strength (but not phase), towards source and destination. The relay selection completes within a fraction of the channel coherence time and then, that single relay is used for information relaying. A method of distributed timers is used that allows the best relay to be selected, even though each relay has no CSI information regarding the links of other relays, towards source or destination. The best relay is the one that maximizes the following function of the channel conditions towards source and destination: b = arg i Other functions, such as the harmonic mean were considered. max{min{γ Si, γ id }}, i [..M] (2) Communication through the best opportunistic relay fails due to outage when the following event happens: where Θ 2 is given in the following equation: ( 2 log 2( + a Sb 2 P S ) < ρ) ( 2 log 2( + a bd 2 P R ) < ρ) (3) (γ Sb < Θ 2 ) (γ bd < Θ 2 ) (4) Θ 2 = (2 2ρ )/SNR (5) Since communication happens in two steps using half-duplex, same frequency radios, the required spectral efficiency per hop is now 2ρ, so that the communication application at the receiver, receives information with end-to-end spectral efficiency ρ. Equation (4) simply states that opportunistic relaying fails if either of the two hops (from source to best relay and from best relay to destination) fails. This probability can be analytically calculated for the case of Rayleigh fading: P r(outage) = P r (γ Sb < Θ 2 γbd < Θ 2 ) (6) P r (min{γ Sb, γ bd } < Θ 2 ) (7) (2) = P r (max { min{γ Si, γ id }} < Θ 2 ), i [..M] (8) i ( ) = P r (max {γ sid } < Θ 2 ), i [..M] (9) i M = P r (γ SiD < Θ 2 ) (0) = i= M ( exp( Θ 2 /γ SiD )) () i= = ( e Θ2( γ S + γ D ) )( e Θ2( γ S2 + γ 2D ) )... ( e Θ2( γ SM + γ MD ) ) (2) 6

where we have exploited in (*) the fact that the minimum of two independent exponentials is again an exponential random variable, with parameter the sum of the two parameters: = + (3) γ SiD γ Si γ id For example, for the case of M = 2 see-around-corner relays, the outage probability becomes: P r(outage) = ( e Θ2( γ S + γ D ) )( e Θ2( γ S2 + γ 2D ) ) (4) B. Reactive Decode and Forward An alternative approach would have the relays that successfully decode the message, to regenerate and transmit it, possibly through a distributed space-time code, as originally proposed in []. In other words, the multiple relay transmission during the second stage is performed by a subset D(k) of the relays, including k relays that successfully decoded the message, during the first stage: 2 log 2( + a S(i) 2 P S ) < ρ, (i) D(k) (5) γ S(i) < 22ρ SNR Θ 2 (6) Notice that a S(i) 2 γ S(i) denotes the path between source and relay (i) which might be different than relay i. i in (i) denotes index of index and in general, γ S(i) γ S(j) iff (i) = (j) 3. The importance of such notation, becomes clear below. Using appropriate distributed space-time coding that allows simultaneous transmissions (possibly at the same frequency bands), the outage event is given below: P r(outage) = P r(i < ρ) (7) where I = 2 log 2( a ()D 2 P ()D + a (2)D 2 P (2)D subject to P ()D + P (2)D +... + P (k)d = P R = fixed +... + a (k)d 2 P (k)d ) (8) Under the above aggregate power constraint, it is easy to see that the outage probability is minimized when a single relay is used from the decoding set D(k): the relay that belongs to D(k) and also has the maximum instantaneous channel γ bd towards destination. That is due to the following inequality: k i= a (i)d 2 P (i)d k i= γ (i)d P (i)d (9) k i= γ (b)d P (i)d = γ bd P R (20) 3 Similarly, we utilize notation for γ (i)d 7

Therefore, the relay b that belongs to D(k) with γ bd γ (i)d, (i) D(k) minimizes the outage probability and optimizes performance. For slow fading environments, a simple method can be devised, to select in a fast and distributed manner, the relay with the strongest channel conditions towards the destination, alongside the work in [4]. The outage probability for this scheme can be analytically computed. Notice that there are 2 M possible decoding sets for M relays, including D(0) i.e. the set that has no relays, at the event that no relay successfully decoded the message during the first stage of the protocol. Given a specific decoding set D(k), the outage probability under the optimal scheme described above becomes: P r(outage D(k)) = P r(γ ()D Θ 2 ) P r(γ (2)D Θ 2 )... P r(γ (k)d Θ 2 ) (2) The above equation simply states that if the best relay fails, then all relays should fail given that the best relay has the strongest path towards destination. The probability for a given decoding set, is given below: P r(d(k)) = P r(γ S() Θ 2 ) P r(γ S(2) Θ 2 )... P r(γ S(k) Θ 2 )P r(γ S(k+) Θ 2 ) P r(γ S(k+2) Θ 2 )... P r(γ S(M) Θ 2 ) Therefore, the outage probability of the optimal scheme i.e. the minimum outage probability for a given aggregate relay power, is given by: P r(outage) = 2 M D(k) P r(outage D(k)) P r(d(k)) (23) It was interesting to see that a careful selection of a single relay minimizes outage probability, under an aggregate power constraint, in the aforementioned reactive scheme. It was surprising to find out that the outage probability of the above reactive scheme (equation 23), was exactly the same with that, achieved by opportunistic relaying, described before (equation 2). For M = 2 for example, (23) can be analytically expressed below: P r(outage) = ( e Θ2/γ S )( e Θ 2/γ S2) + no relays in D(k) +( e Θ2/γ D ) e Θ 2/γ S( e Θ 2/γ S2) + only relay in D(k) +( e Θ2/γ 2D ) e Θ 2/γ S2( e Θ 2/γ S) + only relay 2 in D(k) +( e Θ2/γ D ) ( e Θ 2/γ 2D) e Θ 2/γ S e Θ 2/γ S2 = both relays in D(k) =... = = ( e Θ2 (/γ S +/γ D ) ) ( e Θ2 (/γ S2 +/γ 2D ) ) (24) (22) 8

This is exactly the same, as computed in the (reactive) opportunistic relaying analysis (equation 4). The same result holds for larger numbers of M. We show it below. P r(outage) = 2 M D(k) P r(outage D(k)) P r(d(k)) = ( M M ) ( M ) P r(outage D(k = 0)) P r(d(k = 0)) + P r(outage D(k = )) P r(d(k = )) + ( M k ) +... + P r(outage D(k)) P r(d(k)) + +... + P r(outage D(k = M )) P r(d(k = M )) + P r(outage D(k = M)) P r(d(k = M)) (25) For Rayleigh fading, P r(outage D(k)) P r(d(k) can be easily calculated using equations (2), (22): P r(outage D(k)) P r(d(k)) = ( e Θ2 (/γ ()D ) )( e Θ2 (/γ (2)D ) )... ( e Θ2 (/γ (k)d ) ) e Θ2 (/γ S() ) e Θ2 (/γ S(2) )... e Θ2 (/γ S(k) ) ( e Θ2 (/γ S(k+) ) )( e Θ2 (/γ S(k+2) ) )... ( e Θ2 (/γ S(M) ) ) (26) The following lemma completes the proof: Lemma : The outage probability of optimal reactive decode-and-forward as described above is: P r(outage) = P r(outage D(k)) P r(d(k)) 2 M D(k) = ( e Θ2( γ S + γ D ) )( e Θ2( γ S2 + γ 2D ) )... ( e Θ2( γ SM + γ MD ) ) (27) Proof: Proof: Setting e Θ2 (/γ (k)d ) = b (k) and e Θ2 (/γ S(k) ) = a (k) in equations (25) and (26), the multinomial theorem at the appendix produces the above result. This finding suggests that the choice of the min function as a quality measure for a 2-hop link (as proposed in [4], [5]) in a proactive relay selection scheme, is indeed optimal: as shown above, it minimizes the outage probability, under an aggregate relay power constraint in Rayleigh fading. Proactive relay selection requires smaller energy for information reception since relays that are not selected can avoid reception during the first stage of the protocol. In contrast, reactive schemes need all relays to receive information during the first stage and therefore scale the reception energy proportionally to the network size. That might be inappropriate when heavy Forward Error Correction (FEC) is used that requires energy expensive reception routines, especially in battery operated wireless networks. 9

0 0 Decode and Forward Strategies for 6 relays @ bps/hz 0 - Outage Probability 0-2 0-3 0-4 0-5 Selecting one Selecting all Selecting single Opportunistic -4-2 0 2 4 6 8 0 2 4 SNR Fig. 2. Outage event probability as a function of SNR. Opportunistic, single relay transmission outperforms simultaneous transmissions with distributed space-time coding ( All relays ) or single relay based on average channel conditions. C. Numerical Results We compute the outage probability as a function of SNR, for the symmetric case of M = 6 relays (γ Si = γ id =, i M). Proactive Decode-and-Forward ( Opportunistic ) is evaluated using (2), where the opportunistic relay transmits with full power P R. Reactive Space-time coding where all relays that have decoded the message, transmit during the second stage, is depicted as ( All relays ) and its performance can be easily evaluated: all successful relays have the same mean channel gains towards destination and total power P R is evenly distributed among them. Then P r(outage D(k)) amounts to estimating the probability distribution function of a chi-square random variable with 2k degrees of freedom and therefore, overall performance can be easily obtained by (23). Finally, selecting a single successful relay according to average channel conditions is depicted as ( Single ) and for the symmetric case, it amounts to selecting just one successful relay randomly (since all relays have the same mean channel gain to the destination) that transmits with full power P R. Fig. (2) shows that Opportunistic relaying in slow fading environments outperforms the two other schemes. This is because proactive relay selection based on instantaneous channel gains (via the min function) and decode-andforward is equivalent to optimal reactive decode-and-forward. The All relays and the Single relay are special cases of reactive decode-and-forward. This finding suggests that cooperative diversity gains do not necessarily arise from simultaneous transmissions but instead, resilience to fading arises from the availability of several potential paths towards the destination. It is therefore optimal, to select the best one. The main difficulty here is to have 0

the network as a whole entity cooperate in order to discover that path, with minimal overhead and fast, within a fraction of the channel coherence time. Such schemes were proposed in [4], [5] for slow fading environments and the main idea was to have all relays listen to pilot transmissions, before electing in a distributed manner the best relay. Notice that a single relay selection based on average channel gains ( Single ) is clearly suboptimal, with a substantial penalty loss. This is due to the fact, that selecting a relay based on average channel gains, removes potential selection diversity benefits as the above experiment clearly demonstrates. An alternative similar, suboptimal scheme would be to select a subset of the decoding set (instead of selecting just one), based on average channel gains and distribute the relay power P R appropriately. That is a scheme analyzed in [4] and can be viewed as a special case of reactive decode-and-forward, for which the optimal strategy is to select a single relay based one instantaneous channel conditions (and not average). IV. AMPLIFY AND FORWARD ANALYSIS In this section, we slightly change the notation: the received signal between any two points (s d) is y sd = Psd a sd x + n d where P sd is the average normalized received power between source s and destination d and depends on the transmitted power, as well as other propagation phenomena, like shadowing. a sd is a unit-power, complex, circularly symmetric, Gaussian random variable corresponding to Rayleigh fading and n d is the AWGN noise term, as defined before. We analyze the general case of amplify-and-forward when the source sends unit power message x during the first stage and unit power message x 2 during the second stage. Later at the analysis, we dismiss the terms due to x 2, according to the scenario of this paper. The system equations for the first stage follow: st Stage: y D, = P SD a SD x + n D, (28) y Ri, = P SRi a SRi x + n Ri,, i [, M] (29) Notice that the expected power of each symbol received at each relay Ri can be easily calculated, taking into account the assumptions above: E[ y Ri, 2 ] = P SRi +. Each relay normalizes its received signal with its average y power and transmits Ri,. This is a normalization followed in the three terminal analysis (one source, one E[ yri, 2 ] destination and one relay) presented in [5] 4. Here, we can easily generalize it to the case of multiple relays, during the second slot: 4 A similar normalization was followed in [9]

2nd Stage: y D,2 = P SD a SD x 2 + M + PSRi a SRi i= y Ri, E[ yri, 2 ] + n D,2 (30) y D,2 = P SD a SD x 2 + M PSRi PRiD + a SRi a RiD x + PSRi + i= + n D,2 + M i= PRiD PSRi + a RiD n Ri, } {{ } ñ D,2 y D,2 = P SD a SD x 2 + M PSRi PRiD + a SRi a RiD x + ñ D,2 PSRi + i= (3) From the last equation, we can see that the received signal at the destination, can be written as the sum of two terms, corresponding to the two transmitted information symbols plus one noise term. Assuming that the destination has knowledge of the wireless channel conditions between the relays and itself (for example, the receiver can estimate the channel using preamble information), the noise term in (32) becomes complex Gaussian with power easily calculated 5 : (32) E[ñ D,2 ñ D,2 H R D ] = M P RiD a Rid 2 ( + ) P i= SRi + ω 2 = ω 2 (33) Therefore, the system of the above equations can be easily written in matrix notation: y D, y D,2 ω = ω M i= PSD a SD 0 PSRi PRiD PSRi + a SRi a RiD ω PSD a SD x x 2 + n D, ñ D,2 ω 5 notice that we do not need knowledge of the wireless channels conditions at the receiver between source and relays, for the above assumption to hold. 2

The above notation can be summarized as: PSD a y = SD 0 PSD a SD H 2 ω x + n (34) y = H x + n (35) The noise term, under the above assumptions, has covariance matrix given below, 6 where I 2 is the 2x2 unity matrix: ω 2 = ( + M i= P RiD a Rid 2 P SRi + (36) E[n n T H R D ] = I 2 (37) According to the scenario described in the previous sections, we do not allow the source to transmit a new symbol x 2 during the second stage, when the half-duplex relays forward their information. In that way, the second column of matrix H is zero and H becomes a column vector (the first column of H above). The mutual information for the above assumptions can be easily calculated for the above linear system, using the result from Telatar s work [7]: I AF = 2 log 2( + P SD a SD 2 + H 2 2 ) (38) Alongside the assumption of having a very poor connection (or no connection) between initial source and final destination, the mutual information becomes: A. Numerical Results I AF = 2 log 2( + H 2 2 ) (39) We present results for the symmetric case of M relays (γ Si = γ id =, i M). Denoting P S the transmitted power from the source, (39) becomes: I AF = 2 log 2( + P S H 2 2 ) (40) where H 2 2 depends on the relaying strategy: a) all power P R is used at one random relay, b) power is distributed at all relays P RiD = P R /M and c) all power P R is used at the best, opportunistic relay. The exact representation of H 2 2 follows: H 2 2 one = H 2 2 all = H 2 2 opp = P S + P S + P R /M P R + a RiD a 2 SRi a RiD 2 (4) M + M i= a RiD a SRi a RiD 2 2 i= (42) P S + P R + a RbD a 2 SRb a RbD 2, with (43) 6 The symbols, T correspond to complex conjugate and conjugate-transpose respectively 3

0.9 Selection one random relay Selecting all relays Opportunistic Relaying 6 relays 0.8 CDF of Mutual Information 0.7 0.6 0.5 0.4 0.3 0.2 0. 0 0 0.5.5 2 2.5 3 3.5 4 bps/hz Fig. 3. Cumulative Distribution Function (CDF) of mutual information (eq. 39), for SNR=20 db. Notice that the CDF function provides the outage probability. Average values (in bps/hz) are also depicted min{ a SRb 2, a RbD 2 } min{ a SRi 2, a RiD 2 }, i [, M] The first term in (4), (43) is greater than the first term in (42). The second term in (42) corresponds to the magnitude of the sum of complex numbers with random phases. Therefore, the addition of an increasing number of those terms does not necessarily results in a proportional increase of the magnitude: that would be possible, only under equal phases (beamforming). The Cumulative Distribution Function (CDF (x) = P r(i AF x)) is depicted in Fig. 3 for the three cases above. Selecting the opportunistic relay outperforms the case of having all relays transmit. It is also shown, that choosing a random relay is a suboptimal technique, compared to the all relays case, since the probability of transmitting a low SN R signal increases. The above show again that the advantages of multiple nodes in a relay network, do not arise because of complex reception techniques, as the all relays transmit approach requires, but rather emerge because of the fact that multiple possible paths exist between source, the participating relays and the destination. Opportunistic relaying, simply exploits the best available path. V. COOPERATING RELAYS AS WIRELESS CHANNEL SENSORS: A DEMO In an effort to realize wireless networks that adapt to the wireless channel conditions and facilitate cooperation, we built a small-scale, cooperative diversity demonstration. The simplicity of opportunistic relaying allowed the use of simple, low-cost radios. We interfaced a low-cost micro-controller to the baseband output of a 96.5 MHz 4

Industrial Scientific Medical (ISM) transceiver module, in a custom Printed Circuit Board (PCB). Then we wrote all the necessary software functions for transmission, opportunistic relaying and reception. Fig. 4. Three colored relays ( red, yellow, blue ) are depicted. The relays are willing to assist a single source-destination pair (not depicted). The source is connected to a weather report service (through a PDA) and the destination is connected to a large store display. The goal of the demo setup was to demonstrate in human-perceived scales, the fact that the network as a whole, chose a different relay-path, depending on the wireless channel conditions, especially when people were moving inside the room. In Fig. 4, three colored relays are depicted ( red, yellow and green ) which are willing to cooperatively assist a source-destination pair (not depicted in fig. 4). The source is connected to a weather report service over the internet (through a Personal Digital Assistant) and the destination is connected to a large, store display, that displays the received information, without any type of error correction. As people moved inside the room (a.k.a. changing indoor wireless channel conditions), the best relay path changed and a different relay assisted the communication, as shown in fig. 5: blocking the red relay, resulted in information forwarding from the yellow relay, depicting the received message at the store display with yellow color. Blocking the yellow relay, resulted in selecting the red relay-path. More information regarding the demo implementation can be found in [3]. The relay selection requires only partial CSI at each relay (but no CSI regarding the other cooperating relays) and a detailed description and analysis can be found in [5]. The purpose of the above description is to emphasize that the simplicity of the scheme allowed implementation using existing radio hardware. Simultaneous transmission at the same frequency band are not needed, since a smart relay selection at the medium access layer (layer 2) eliminates the need for space-time coding (and simultaneous transmissions) at the physical layer. 5

Fig. 5. A single, best relay is chosen based on the end-to-end channel conditions, among all relays, in a distributed manner. The selection adapts to the wireless channel changes. For example, when red relay path is blocked, yellow path is chosen and vice versa. The text color at the store display shows the best path, currently used. VI. C ONCLUSION Under the assumptions followed in this work, we showed that the cooperative diversity benefits are increased when cooperative relays choose not to transmit, giving priority to the transmission of a single, opportunistic relay. We also demonstrated the equivalence of opportunistic relaying (under the min function rule) with the optimal, reactive and regenerative (decode-and-forward) multiple relays scheme, under the assumption of no CSI at the source. Therefore, cooperation should be viewed not only as a transmission problem (using distributed space-time codes) but also as a distributed relay selection task. For the cases studied in this work, there is no performance loss compared to distributed space-time coding, in fact there is improved performance, under an aggregate power constraint. Additionally, the proactive nature of the opportunistic scheme reduces the required energy, needed for reception at the relays, which is significant in modern error-correcting radios. Additionally, it was shown that benefits of cooperation arise and improve under opportunistic relaying, even when dumb processing is conducted at each relay (the case of amplify-and-forward). The scheme requires no same frequency, simultaneous transmissions and it simple enough to be implemented in existing RF front ends. An implementation example in low cost radio was briefly discussed. Future work could include analysis and implementation extensions in fast fading environments, where average channel conditions might be more appropriate, from an implementation perspective. Additionally, extensions can be explored in the interference limited regime. Hopefully, this work will spark interest in the exploration of schemes that view cooperative nodes not as active re-transmitters only, but also as distributed sensors of the wireless channel. This work demonstrated that cooperative relays can be useful even when they do not transmit, provided that they cooperatively listen. In that way, improved 6

performance is realized and implementation is feasible. REFERENCES [] J. Adeane, M. R. D. Rodrigues and I. J. Wassell, Optimum power allocation in cooperative networks, Proceedings of the Postgraduate Research Conference in Electronics, Photonics, Communications and Networks, and Computing Science, Lancaster, U.K., pp. 23-24, March- April 2005. [2] K. Azarian, H. E. Gamal, and P. Schniter, On the Achievable Diversity-vs-multiplexing Tradeoff in Cooperative Channels, IEEE Trans. Information Theory, submitted July 2004, available at http://www.ece.osu.edu/ schniter/postscript/tit05_coop.pdf [3] A. Bletsas, Intelligent Antenna Sharing in Cooperative Diversity Wireless Networks, Ph.D. Dissertation, Media Laboratory, Massachusetts Institute of Technology, September 2005. [4] A. Bletsas, A. Lippman, D.P. Reed, A Simple Distributed Method for Relay Selection in Cooperative Diversity Wireless Networks, based on Reciprocity and Channel Measurements, Proceedings of IEEE 6st VTC, May 30 - June 2005, Stockholm, Sweden. [5] A. Bletsas, A. Khisti, D.P. Reed, A. Lippman, A Simple Cooperative Diversity Method based on Network Path Selection, IEEE Journal on Selected Areas of Communication, Special Issue on 4G, submitted January 2005, accepted for publication, to appear. Available at http://web.media.mit.edu/ aggelos/papers/revised_4g0.pdf [6] A. Bletsas, M.Z. Win, A. Lippman, To Relay or Not to Relay? Optimizing Multiple Relay Transmissions by Listening in Cooperative Diversity Communication, August 2005, submitted to IEEE WCNC 2006. [7] M. Gastpar and M. Vetterli, On the capacity of large Gaussian relay networks. IEEE Transactions on Information Theory, 5(3):765-779, March 2005. [8] Y. Jing and B. Hassibi, Distributed space-time coding in wireless relay networks-part I: basic diversity results, Submitted to IEEE Trans. On Wireless Communications, July 2004. Available at http://www.cds.caltech.edu/ yindi/publications.html [9] G. Kramer, M. Gastpar and P. Gupta. Cooperative strategies and capacity theorems for relay networks. Submitted to IEEE Transactions on Information Theory, February 2004. Available at http://www.eecs.berkeley.edu/ gastpar/relaynetsit04.pdf [0] J. N. Laneman, D. N. C. Tse, and G. W. Wornell, Cooperative Diversity in Wireless Networks: Efficient Protocols and Outage Behavior, IEEE Trans. Inform. Theory, accepted for publication, June 2004. [] J. N. Laneman and G. W. Wornell, Distributed Space-Time Coded Protocols for Exploiting Cooperative Diversity in Wireless Networks, IEEE Trans. Inform. Theory, vol. 59, pp. 245 2525, October 2003. [2] P. Larsson, H. Rong, Large-Scale Cooperative Relay Network with Optimal Coherent Combining under Aggregate Relay Power Constraints, Proceedings of Working Group 4, World Wireless Research Forum WWRF8 meeting, Beijing, February 2004. [3] J. Luo, R. S. Blum, L. J. Cimini, L. J. Greenstein, and A. M. Haimovich, Link-Failure Probabilities for Practical Cooperative Relay Networks, IEEE VTC June 2005. [4] J. Luo, R. Blum, L. Cimini, L. Greenstein, and A. Haimovich, Power Allocation in a Transmit Diversity System with Mean Channel Gain Information, IEEE Communications Letters, vol. 9, no. 7, July 2005. [5] R. U. Nabar, H. Blcskei, and F. W. Kneubhler, Fading relay channels: Performance limits and space-time signal design, IEEE Journal on Selected Areas in Communications, June 2004, to appear, available from http://www.nari.ee.ethz.ch/commth/pubs/p/ jsac03 [6] A. Sendonaris, E. Erkip and B. Aazhang. User cooperation diversity-part I: System description. IEEE Transactions on Communications, vol. 5, no., pp. 927-938, November 2003. [7] E. Telatar, Capacity of Multi-Antenna Gaussian Channels, European Transac. on Telecom. (ETT), vol. 0, pp. 585 596, November/December 999. [8] B. Zhao and M.C. Valenti, Practical relay networks: A generalization of hybrid-arq, IEEE Journal on Selected Areas in Communications (Special Issue on Wireless Ad Hoc Networks), vol. 23, no., pp. 7-8, Jan. 2005. [9] A. Wittneben and B. Rankov, Impact of Cooperative Relays on the Capacity of Rank-Deficient MIMO Channels, Proceedings of the 2th IST Summit on Mobile and Wireless Communications, Aveiro, Portugal, pp. 42-425, June 2003. 7

APPENDIX Theorem : The following multinomial equality holds: ( a b ) ( a 2 b 2 )... ( a M b M ) =...... ( a ) ( a 2 )... ( a M ) + ( b () ) a () ( a (2) ) ( a (3) )... ( a (M) ) + ( M ) ( b () ) a () ( b (2) ) a (2) ( a (3) ) ( a (4) )... ( a (M) ) + ( M 2 ) ( b () ) a () ( b (2) ) a (2)... ( b (k) ) a (k) ( a (k+) ) ( a (k+2) )... ( a (M) ) + ( M k ) ( M M ) ( b () ) a () ( b (2) ) a (2)... ( b (M ) ) a (M ) ( a (M) ) + ( b () ) a () ( b (2) ) a (2)... ( b (M) ) a (M) The subscript notation (i) can be viewed as an index of index and denotes an integer number in [..M], with a (i) a (j), b (i) b (j) if and only if i = j. Example: ( a b )( a 2 b 2 )( a 3 b 3 ) = ( a )( a 2 )( a 3 ) + ( b ) a ( a 2 ) ( a 3 ) + ( b 2 ) a 2 ( a ) ( a 3 ) + ( b 3 ) a 3 ( a ) ( a 2 ) + ( b ) a ( b 2 ) a 2 ( a 3 ) + ( b 2 ) a 2 ( b ) a ( a 3 ) + ( b 3 ) a 3 ( b ) a ( a 2 ) + ( b ) a ( b 2 ) a 2 ( b 3 ) a 3 Proof: Proof: We prove it by rewriting the right-hand-side of the above equation. where ( a b ) ( a 2 b 2 )... ( a M b M ) = M k=0 A M k + BA M k, (44) A M k + BA M k = ( b () ) a () ( b (2) ) a (2)... ( b (k) ) a (k) ( a (k+) ) ( a (k+2) )... ( a (M) ) ( M k ) A M k contains only products of a (i) s, while BA M k contains mixed products of a (i) s with b (j) s. It is obvious that BA M k=0 = 0. Specifically, it can be shown that for integer k [, M] and integer λ [, k], BA M k = ( M ) b () f k () + ( M 2 ) b () b (2) f k ()(2) +...+ ( M λ ) b () b (2)... b (λ) f k ()(2)...(λ) +...+ ( M k ) b () b (2)... b (k) f k ()(2)...(k) (45) 8

with f k ()(2)...(λ) = ( ) k a () a (2)... a (λ) [ ( ) k λ ( ) k λ + +( ) k λ+ k λ ( k λ+) M λ +... + +( ) µ λ ( µ λ k λ +... + Similarly, for integer ν [k, M], ) ( M λ µ λ ) +( ) M λ ( M λ k λ ( ) M λ +( ) M λ k λ ( M λ k λ ) a (λ+) a (λ+2)... a (k) k λ terms a (λ+) a (λ+2)... a (k+) k λ+ terms a (λ+) a (λ+2)... a (µ) µ λ terms ) a (λ+) a (λ+2)... a (M ) + ( M λ ) M λ terms ] a (λ+) a (λ+2)... a (M) M λ terms + + + (46) A M k = ( M k ) = ( ) 0 ( k k a () a (2)... a (k) ( a (k+) ) ( a (k+2) )... ( a (M) ) ) +( ) ( k + k +... + +( ) ν k ( ν k +... + a () a (2)... a (k) + ( M k ) ) ) ( M k+) ( M ν ) +( ) M k ( M k a () a (2)... a (k+) + a () a (2)... a (k) a (k+)... a (ν) + ) ( M M ) a () a (2)... a (M ) + ( ) M +( ) M k a () a (2)... a (M) (47) k From equation (45), we see that the term b () b (2)... b (λ) in k BAM k, is multiplied by the following term: f k=λ ()(2)...(λ) + f k=λ+ ()(2)...(λ) + f k=λ+2 ()(2)...(λ) +... + f k=m ()(2)...(λ) = 9

( ( ) 2 0 ( ) 2 + ( ( ) ( ) ( ) µ λ µ λ µ λ ) +... + ( ) µ λ 0 µ λ =0 ( ( ) M λ 0 ( M λ since, n k=0 ( )k( n k) ( ) n = 0. Therefore: ( ) M ( M M ) k [ ( ) λ a () a (2)... a (λ) + ( + ) a (λ+) + ( ) 2 ) 2 ( M λ 2 ) ( M λ µ λ ) ) +... + ( ) M λ ( M λ M λ BA M k = ( M ) a () b () + ( M 2 ) ( M λ ) a (λ+) a (λ+2) + +... + a (λ+) a (λ+2)... a (µ) + +... + ) ) ] a(λ+) a (λ+2)... a (M) = ( ) λ a () a (2)... a (λ) (48) a () b () a (2) b (2) +... + a () b () a (2) b (2)... a (M ) b (M ) + ( ) M a b a 2 b 2... a M b M (49) = Similarly, from equation (48), we see that the term a () a (2)... a (k) a (k+)... a (ν), appears in each A M k k = 0..M) with a multiplying term ( ) ν k( ν k). Therefore, a() a (2)... a (k) a (k+)... a (ν) in k AM k by the following term: ν ( ) ν ( ) ν k ( ) ν = 0 k k=0 (for, is multiplied The only term that does not cancel out in k AM k, is the term that does not include any a is. That is the unit term, coming from A M 0. In short, A M k =. (50) Equations (50), (50) show that equation (44) is indeed true, concluding the proof. k 20