Dear subscribers of the colloquium newsletter,
we are happy to inform you about the next date
of our Communication Technology Colloquium.
Thursday, September 16, 2021
Speaker: Vlerar Shala
Time: 11:00 a.m.
Location: https://rwth.zoom.us/j/97904157921?pwd=SWpsbDl0MWhrWjY1ZkZaeFRoYmErZz09
Meeting-ID: 979 0415 7921
Passwort: 481650
Master-Lecture:
AI-Based Optimization of Pulse Shaped OTFS for Vehicular
Communication
Future vehicular communication systems require
a reliable communication to enable connected and automated
driving. Vehicular channels are considered to be truly
doubly-dispersive channels, i.e., strongly varying in both time
and frequency. However, the performance of the traditional
wireless communication systems operating under doubly-dispersive
channels degrades significantly. Orthogonal time frequency and
space (OTFS) is a recently proposed modulation scheme designed
to be robust against doubly-dispersive channels. OTFS is a new
and novel two-dimensional (2D) pulse-shaped modulation scheme
designed in the delay-Doppler (DD) domain and promises
significant improvements on the physical layer. OTFS is a
combination of classical Gabor signaling with a unique
time-frequency (TF) spreading. Data symbols are located in the
DD domain and spread over the entire TF domain using the
symplectic finite Fourier transform (SFFT). The TF spreading
accounts in a linear fashion for the doubly dispersive nature of
time-variant multi-path channel. The TF spreading is also
referred to as OTFS transform and the Gabor transform as the
Heisenberg transform. However, OTFS requires proper channel
information and the use of appropriated equalizers to exploit
the full spreading gain.
Doubly-dispersive channels are characterized
by their spreading region spanned by two times �max, and �max,
corresponding to the maximum Doppler shift and delay spread. To
mitigate the strong interference between different TF slots, TF
grid and pulses should “match” the DD spreading region of the
doubly-dispersive channel, typically determined on a longer time
scale-like. This approach is known as pulse and grid matching
rule. In this thesis, we use the so-called mobility modes with
distinct grid and pulses to follow the pulse and grid matching
rule. However, mobility modes control the interference on a
coarse level because they cannot match the pulse and grid
matching rule completely. The remaining interference is
accounted by the implemented mean square error (MMSE) linear
equalizer, which is tuned for each frame. We implement the OTFS
transceiver based on a polyphase implementation for
orthogonalized Gaussian pulses and evaluate mobility modes with
doubly-dispersive vehicular channels generated by the QuaDRiGa
channel simulator.
For practical implementation, the performance
of mobility modes should be predicted and then the mobility mode
with the best performance is selected to send the next frame.
However, the prediction of mobility modes requires the
prediction of the channel itself. In this thesis, we propose a
novel method to predict the channel by predicting the spreading
function which represents the channel in the DD domain. We
propose to predict the spreading function using a new variant of
Long Short-Term Memory (LSTM) neural networks known as
Convolutional LSTM. The architecture of Convolutional LSTM is
both recurrent and convolutional which enables it to capture the
spatiotemporal correlation of the data and utilize it for the
prediction.
All interested parties are cordially invited,
registration is not required.
General information on the colloquium, as well
as a current list of dates of the Communication Technology
Colloquium can be found at:
http://www.iks.rwth-aachen.de/aktuelles/kolloquium
--
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/