4 research outputs found
Achievable Rate Region of the Bidirectional Buffer-Aided Relay Channel With Block Fading
The bidirectional relay channel, in which two users communicate with each
other through a relay node, is a simple but fundamental and practical network
architecture. In this paper, we consider the block fading bidirectional relay
channel and propose efficient transmission strategies that exploit the block
fading property of the channel. Thereby, we consider a decode-and-forward relay
and assume that a direct link between the two users is not present. Our aim is
to characterize the long-term achievable rate region and to develop protocols
which achieve all points of the obtained rate region. Specifically, in the
bidirectional relay channel, there exist six possible transmission modes: four
point-to-point modes (user 1-to-relay, user 2-to-relay, relay-to-user 1,
relay-to-user 2), a multiple-access mode (both users to the relay), and a
broadcast mode (the relay to both users). Most existing protocols assume a
fixed schedule for using a subset of the aforementioned transmission modes.
Motivated by this limitation, we develop protocols which are not restricted to
adhere to a predefined schedule for using the transmission modes. In fact,
based on the instantaneous channel state information (CSI) of the involved
links, the proposed protocol selects the optimal transmission mode in each time
slot to maximize the long-term achievable rate region. Thereby, we consider two
different types of transmit power constraints: 1) a joint long-term power
constraint for all nodes, and 2) a fixed transmit power for each node.
Furthermore, to enable the use of a non-predefined schedule for transmission
mode selection, the relay has to be equipped with two buffers for storage of
the information received from both users. As data buffering increases the
end-to-end delay, we consider both delay-unconstrained and delay-constrained
transmission in the paper.Comment: submitted to IEEE Transaction on Information Theor