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Vortragender: Herr Tim Schmitz, M. Sc.
Thema: Continuous-Amplitude Error Protection of
Discrete-Time Signals
Zeit: Freitag, 13. Dezember 2019, 14:00 Uhr
Ort: Institut für Kommunikationssysteme, Muffeter Weg 3a,
Hörsaal 4G
Transmitting analog audio, video, or sensor
data with a digital system requires sampling and quantization.
While a sampled signal can be reconstructed perfectly if the
Nyquist-Shannon sampling theorem is met, quantization
unavoidably abbs irreversible errors. Given a certain bitrate
for quantization (or source coding in general), the achievable
signal quality is therefore limited. Transmission of the signal
over a noisy channel causes additional errors. If some part of
the bitrate is used for protecting the signal with a channel
code, these additional errors can be reduced or even eliminated.
However, this reduces the achievable maximum quality if the
gross bitrate is fixed. Since this compromise between
quantization and channel coding is often designed for the
worst-case channel, the signal quality saturates early with
increasing channel quality, and transmission over a better
channel is far below optimum.
Instead of conventional digital systems, this
thesis covers a continuous-amplitude, discrete-time system. Such
a system does not exhibit this saturation of the signal quality,
as its performance further improves with increasing channel
quality. An example of such a system is a channel coding
strategy using analog modulo block codes (AMB codes) for error
protection. The encoder multiplies the unquantized symbol vector
with a code matrix and limits the transmission power with a
modulo operation. In practice, AMB coding is implemented by
digital signal processing. The digital representation of the
information symbols can be very precise and no coarse
quantization is required for bitrate reduction.
In this thesis, AMB codes are analyzed,
designed, and evaluated. The resulting code words, consisting of
a lattice and a continuous component, are presented and
analyzed. New decoding techniques are developed and evaluated.
Additionally, a novel method to analytically estimate the
quality of the decoded signal in terms of signal-to-distortion
ratio (SDR) can replace computationally much more demanding
simulations in many cases. This estimation strategy allows
evaluating the usefulness of codes with different
dimensionalities. A new, efficient design concept is developed
for codes with a single input symbol, which are most promising
in terms of complexity and performance. A system using AMB codes
outperforms traditional digital transmission systems with short
block lengths for medium to high signal-to-noise ratios on the
channel. Due to their typically very short block length and low
encoding complexity, AMB codes are especially well suited for
low-delay, low-power applications, such as hearing aids,
wireless mircophones, and wireless sensor networks.
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-- Irina Ronkartz Institute of Communication Systems (IKS) RWTH Aachen University Muffeter Weg 3a, 52074 Aachen, Germany +49 241 80 26958 (phone) ronkartz@iks.rwth-aachen.de http://www.iks.rwth-aachen.de/