Low-complexity and power-efficient wireless cooperative relay networks with enhanced reliability

Choi, Gi Wan

09 January 2013

In recent years, global mobile data traffic has been increasing exponentially as mobile devices pervade our daily lives. To cope with the ever growing demands for higher data rates and seamless connectivity, one solution is to drastically increase the number of macro base stations in the conventional cellular architecture. However, this results in high deployment costs. Deploying low-power nodes such as relays that do not require a wired backhaul connection within a macrocell is one of cost-effective ways to extend high data rate coverage range. Relays are typically deployed to increase signal strength in poor coverage areas or to eliminate dead spots. But more importantly, relays provide a natural diversity, called cooperative diversity. In addition to a direct signal from a base station, extra copies of the same signal are forwarded from relays. Utilizing this diversity at the destination can yield significant performance enhancements. Thus, cooperative relay strategies need to be considered to enable high data rate coverage in a cost-effective manner. In this dissertation, we consider a simple single-relay network and present low-complexity and power-efficient cooperative relay designs that can achieve low error rate. We first study decode-and-forward (DF) relay networks with a single antenna at each node, where the relay decodes the received signal and forwards the re-encoded information to the destination. In DF relay scheme, decoding at the relay is not perfect and the error-propagation phenomenon is a detrimental problem, preventing the destination from collecting the cooperative diversity. To enable cooperative diversity in DF relay networks, we adopt link-adaptive power-scaling relay strategies where the relay scales the transmission power of the re-encoded signal based on the reliability of the source-relay link. We generalize power-profile designs and analyze the diversity order enabled by the general power-profile designs. We provide necessary and sufficient conditions for the designs to enable full cooperative diversity at the destination. In the second part of this dissertation, we extend the power-scaling relay strategy to DF multi-input multi-output (MIMO) relay networks, where multiple antennas are adopted at each node, and show that full cooperative diversity can also be achieved here. To collect spatial diversity provided by multiple antennas without using maximum-likelihood equalizers (MLEs) or near-ML detectors which exhibit high complexity, channel-controlled automatic repeat request (CC-ARQ) scheme is developed for DF MIMO relay networks to enable spatial diversity with linear equalizers (LEs) maintaining low-complexity. We also show that joint cooperative and spatial diversity can be achieved at the destination when the power-scaling strategy and the CC-ARQ with LEs are combined. Finally, amplify-and-forward (AF) MIMO relay designs, where the relay simply amplifies the received signal and forwards it to the destination, are studied with consideration of peak-power constraints at the relay. One practical concern for AF relaying is that the output signal at the relay may suffer from large peak-to-average power ratio (PAR), which may cause nonlinear distortion and/or saturation in the transmitted signal due to the limited linear range of power amplifiers. Thus, we first investigate peak-power constrained power-scaling strategies and find a sufficient condition to enable joint cooperative and spatial diversity at the destination. Based on this study, we propose simple and practical AF MIMO relay designs with peak-power constraint at the relay. CC-ARQ is also applied to AF MIMO relay networks to reduce the decoding complexity.

Receiver diversity

Cooperative diversity

CC-ARQ

Cooperative relay networks

MIMO

Peak-power constraint

AF

DF

Wireless communication systems

Mobile communication systems

Network performance (Telecommunication)

Performance evaluation and protocol design of fixed-rate and rateless coded relaying networks

Nikjah, Reza

06 1900

The importance of cooperative relaying communication in substituting for, or complementing, multiantenna systems is described, and a brief literature review is presented. Amplify-and-forward (AF) and decode-and-forward (DF) relaying are investigated and compared for a dual-hop relay channel. The optimal strategy, source and relay optimal power allocation, and maximum cooperative gain are determined for the relay channel. It is shown that while DF relaying is preferable to AF relaying for strong source-relay links, AF relaying leads to more gain for strong source-destination or relay-destination links. Superimposed and selection AF relaying are investigated for multirelay, dual-hop relaying. Selection AF relaying is shown to be globally strictly outage suboptimal. A necessary condition for the selection AF outage optimality, and an upper bound on the probability of this optimality are obtained. A near-optimal power allocation scheme is derived for superimposed AF relaying. The maximum instantaneous rates, outage probabilities, and average capacities of multirelay, dual-hop relaying schemes are obtained for superimposed, selection, and orthogonal DF relaying, each with parallel channel cooperation (PCC) or repetition-based cooperation (RC). It is observed that the PCC over RC gain can be as much as 4 dB for the outage probabilities and 8.5 dB for the average capacities. Increasing the number of relays deteriorates the capacity performance of orthogonal relaying, but improves the performances of the other schemes. The application of rateless codes to DF relaying networks is studied by investigating three single-relay protocols, one of which is new, and three novel, low complexity multirelay protocols for dual-hop networks. The maximum rate and minimum energy per bit and per symbol are derived for the single-relay protocols under a peak power and an average power constraint. The long-term average rate and energy per bit, and relay-to-source usage ratio (RSUR), a new performance measure, are evaluated for the single-relay and multirelay protocols. The new single-relay protocol is the most energy efficient single-relay scheme in most cases. All the multirelay protocols exhibit near-optimal rate performances, but are vastly different in the RSUR. Several future research directions for fixed-rate and rateless coded cooperative systems, and frameworks for comparing these systems, are suggested. / Communications

acknowledgment signals

amplify-and-forward relaying

average capacity

average power constraint

bit error rate

cooperative gain

cooperative communication

decode-and-forward relaying

degree of freedom

direct transmission

distributed space-time coding

dual-hop relaying

energy efficiency

energy per bit

energy per symbol

feedback communication

fixed-rate coded relaying

fixed-rate codes

fixed-rate coding

large SNR approximation

maximal ratio combining

maximum achievable rates

maximum likelihood

multiple access channels

mutual information

nonconcave fractional programming

numerical optimization

optimal power allocation

orthogonal relaying

outage optimality

outage probability

parallel channel coding

peak power constraint

power allocation schemes

power fairness

protocol design

rateless coded relaying

rateless codes

rate efficiency

rateless coding

Rayleigh fading

relay-to-source usage ratio

relaying networks

repetition coding

selection relaying

single-hop communication

superimposed relaying

symbol error rate

Performance evaluation and protocol design of fixed-rate and rateless coded relaying networks

Nikjah, Reza

Unknown Date

No description available.

acknowledgment signals

amplify-and-forward relaying

average capacity

average power constraint

bit error rate

cooperative gain

cooperative communication

decode-and-forward relaying

degree of freedom

direct transmission

distributed space-time coding

dual-hop relaying

energy efficiency

energy per bit

energy per symbol

feedback communication

fixed-rate coded relaying

fixed-rate codes

fixed-rate coding

large SNR approximation

maximal ratio combining

maximum achievable rates

maximum likelihood

multiple access channels

mutual information

nonconcave fractional programming

numerical optimization

optimal power allocation

orthogonal relaying

outage optimality

outage probability

parallel channel coding

peak power constraint

power allocation schemes

power fairness

protocol design

rateless coded relaying

rateless codes

rate efficiency

rateless coding

Rayleigh fading

relay-to-source usage ratio

relaying networks

repetition coding

selection relaying

single-hop communication

superimposed relaying

symbol error rate