2,915 research outputs found
Probabilistic Rateless Multiple Access for Machine-to-Machine Communication
Future machine to machine (M2M) communications need to support a massive
number of devices communicating with each other with little or no human
intervention. Random access techniques were originally proposed to enable M2M
multiple access, but suffer from severe congestion and access delay in an M2M
system with a large number of devices. In this paper, we propose a novel
multiple access scheme for M2M communications based on the capacity-approaching
analog fountain code to efficiently minimize the access delay and satisfy the
delay requirement for each device. This is achieved by allowing M2M devices to
transmit at the same time on the same channel in an optimal probabilistic
manner based on their individual delay requirements. Simulation results show
that the proposed scheme achieves a near optimal rate performance and at the
same time guarantees the delay requirements of the devices. We further propose
a simple random access strategy and characterized the required overhead.
Simulation results show the proposed approach significantly outperforms the
existing random access schemes currently used in long term evolution advanced
(LTE-A) standard in terms of the access delay.Comment: Accepted to Publish in IEEE Transactions on Wireless Communication
Opportunistic Error Correction for WLAN Applications
The current error correction layer of IEEE 802.11a WLAN is designed\ud
for worst case scenarios, which often do not apply. In this paper,\ud
we propose a new opportunistic error correction layer based on\ud
Fountain codes and a resolution adaptive ADC. The key part in the\ud
new proposed system is that only packets are processed by the\ud
receiver chain which have encountered ``good'' channel conditions.\ud
Others are discarded. With this new approach, around \ud
of the energy consumption can be saved compared with the\ud
conventional IEEE 802.11a WLAN system under the same channel\ud
conditions and throughput
An Opportunistic Error Correction Layer for OFDM Systems
In this paper, we propose a novel cross layer scheme to lower power\ud
consumption of ADCs in OFDM systems, which is based on resolution\ud
adaptive ADCs and Fountain codes. The key part in the new proposed\ud
system is that the dynamic range of ADCs can be reduced by\ud
discarding the packets which are transmitted over 'bad' sub\ud
carriers. Correspondingly, the power consumption in ADCs can be\ud
reduced. Also, the new system does not process all the packets but\ud
only processes surviving packets. This new error correction layer\ud
does not require perfect channel knowledge, so it can be used in a\ud
realistic system where the channel is estimated. With this new\ud
approach, more than 70% of the energy consumption in the ADC can be\ud
saved compared with the conventional IEEE 802.11a WLAN system under\ud
the same channel conditions and throughput. The ADC in a receiver\ud
can consume up to 50% of the total baseband energy. Moreover, to\ud
reduce the overhead of Fountain codes, we apply message passing and\ud
Gaussian elimination in the decoder. In this way, the overhead is\ud
3% for a small block size (i.e. 500 packets). Using both methods\ud
results in an efficient system with low delay
Short Block-length Codes for Ultra-Reliable Low-Latency Communications
This paper reviews the state of the art channel coding techniques for
ultra-reliable low latency communication (URLLC). The stringent requirements of
URLLC services, such as ultra-high reliability and low latency, have made it
the most challenging feature of the fifth generation (5G) mobile systems. The
problem is even more challenging for the services beyond the 5G promise, such
as tele-surgery and factory automation, which require latencies less than 1ms
and failure rate as low as . The very low latency requirements of
URLLC do not allow traditional approaches such as re-transmission to be used to
increase the reliability. On the other hand, to guarantee the delay
requirements, the block length needs to be small, so conventional channel
codes, originally designed and optimised for moderate-to-long block-lengths,
show notable deficiencies for short blocks. This paper provides an overview on
channel coding techniques for short block lengths and compares them in terms of
performance and complexity. Several important research directions are
identified and discussed in more detail with several possible solutions.Comment: Accepted for publication in IEEE Communications Magazin
Opportunistic error correction: when does it work best for OFDM systems?
The water-filling algorithm enables an energy-efficient OFDM-based transmitter by maximizing the capacity of a frequency selective fading channel. However, this optimal strategy requires the perfect channel state information at the transmitter that is not realistic in wireless applications. In this paper, we propose opportunistic error correction to maximize the data rate of OFDM systems without this limit. The key point of this approach is to reduce the dynamic range of the channel by discarding a part of the channel in deep fading. Instead of decoding all the information from all the sub-channels, we only recover the data via the strong sub-channels. Just like the water-filling principle, we increase the data rate over the stronger sub-channels by sacrificing the weaker sub-channels. In such a case, the total data rate over a frequency selective fading channel can be increased. Correspondingly, the noise floor can be increased to achieve a certain data rate compared to the traditional coding scheme. This leads to an energy-efficient receiver. However, it is not clear whether this method has advantages over the joint coding scheme in the narrow-band wireless system (e.g. the channel with a low dynamic range), which will be investigated in this paper
Reliable Physical Layer Network Coding
When two or more users in a wireless network transmit simultaneously, their
electromagnetic signals are linearly superimposed on the channel. As a result,
a receiver that is interested in one of these signals sees the others as
unwanted interference. This property of the wireless medium is typically viewed
as a hindrance to reliable communication over a network. However, using a
recently developed coding strategy, interference can in fact be harnessed for
network coding. In a wired network, (linear) network coding refers to each
intermediate node taking its received packets, computing a linear combination
over a finite field, and forwarding the outcome towards the destinations. Then,
given an appropriate set of linear combinations, a destination can solve for
its desired packets. For certain topologies, this strategy can attain
significantly higher throughputs over routing-based strategies. Reliable
physical layer network coding takes this idea one step further: using
judiciously chosen linear error-correcting codes, intermediate nodes in a
wireless network can directly recover linear combinations of the packets from
the observed noisy superpositions of transmitted signals. Starting with some
simple examples, this survey explores the core ideas behind this new technique
and the possibilities it offers for communication over interference-limited
wireless networks.Comment: 19 pages, 14 figures, survey paper to appear in Proceedings of the
IEE
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