207 research outputs found
Frequency-Selective PAPR Reduction for OFDM
We study the peak-to-average power ratio (PAPR) problem in orthogonal
frequency-division multiplexing (OFDM) systems. In conventional clipping and
filtering based PAPR reduction techniques, clipping noise is allowed to spread
over the whole active passband, thus degrading the transmit signal quality
similarly at all active subcarriers. However, since modern radio networks
support frequency-multiplexing of users and services with highly different
quality-of-service expectations, clipping noise from PAPR reduction should be
distributed unequally over the corresponding physical resource blocks (PRBs).
To facilitate this, we present an efficient PAPR reduction technique, where
clipping noise can be flexibly controlled and filtered inside the transmitter
passband, allowing to control the transmitted signal quality per PRB. Numerical
results are provided in 5G New Radio (NR) mobile network context, demonstrating
the flexibility and efficiency of the proposed method.Comment: Accepted for publication as a Correspondence in the IEEE Transactions
on Vehicular Technology in March 2019. This is the revised version of
original manuscript, and it is in press at the momen
Mobile Communications Beyond 52.6 GHz: Waveforms, Numerology, and Phase Noise Challenge
In this article, the first considerations for the 5G New Radio (NR) physical
layer evolution to support beyond 52.6GHz communications are provided. In
addition, the performance of both OFDM based and DFT-s-OFDM based networks are
evaluated with special emphasis on the phase noise (PN) induced distortion. It
is shown that DFT-s-OFDM is more robust against PN under 5G NR Release 15
assumptions, namely regarding the supported phase tracking reference signal
(PTRS) designs, since it enables more effective PN mitigation directly in the
time domain. To further improve the PN compensation capabilities, the PTRS
design for DFT-s-OFDM is revised, while for the OFDM waveform a novel block
PTRS structure is introduced, providing similar link performance as DFT-s-OFDM
with enhanced PTRS design. We demonstrate that the existing 5G NR Release 15
solutions can be extended to support efficient mobile communications at 60GHz
carrier frequency with the enhanced PTRS structures. In addition, DFT-s-OFDM
based downlink for user data could be considered for beyond 52.6GHz
communications to further improve system power efficiency and performance with
higher order modulation and coding schemes. Finally, network link budget and
cell size considerations are provided, showing that at certain bands with
specific transmit power regulation, the cell size can eventually be downlink
limited.Comment: This manuscript has been submitted to IEEE Wireless Communications
Magazine (WCM). 8 pages, 4 figures, and 2 table
Generalized Fast-Convolution-based Filtered-OFDM: Techniques and Application to 5G New Radio
This paper proposes a generalized model and methods for fast-convolution
(FC)-based waveform generation and processing with specific applications to
fifth generation new radio (5G-NR). Following the progress of 5G-NR
standardization in 3rd generation partnership project (3GPP), the main focus is
on subband-filtered cyclic prefix (CP) orthogonal frequency-division
multiplexing (OFDM) processing with specific emphasis on spectrally well
localized transmitter processing. Subband filtering is able to suppress the
interference leakage between adjacent subbands, thus supporting different
numerologies for so-called bandwidth parts as well as asynchronous multiple
access. The proposed generalized FC scheme effectively combines overlapped
block processing with time- and frequency-domain windowing to provide highly
selective subband filtering with very low intrinsic interference level. Jointly
optimized multi-window designs with different allocation sizes and design
parameters are compared in terms of interference levels and implementation
complexity. The proposed methods are shown to clearly outperform the existing
state-of-the-art windowing and filtering-based methods.Comment: To appear in IEEE Transactions on Signal Processin
Positioning of High-speed Trains using 5G New Radio Synchronization Signals
We study positioning of high-speed trains in 5G new radio (NR) networks by
utilizing specific NR synchronization signals. The studies are based on
simulations with 3GPP-specified radio channel models including path loss,
shadowing and fast fading effects. The considered positioning approach exploits
measurement of Time-Of-Arrival (TOA) and Angle-Of-Departure (AOD), which are
estimated from beamformed NR synchronization signals. Based on the given
measurements and the assumed train movement model, the train position is
tracked by using an Extended Kalman Filter (EKF), which is able to handle the
non-linear relationship between the TOA and AOD measurements, and the estimated
train position parameters. It is shown that in the considered scenario the TOA
measurements are able to achieve better accuracy compared to the AOD
measurements. However, as shown by the results, the best tracking performance
is achieved, when both of the measurements are considered. In this case, a very
high, sub-meter, tracking accuracy can be achieved for most (>75%) of the
tracking time, thus achieving the positioning accuracy requirements envisioned
for the 5G NR. The pursued high-accuracy and high-availability positioning
technology is considered to be in a key role in several envisioned HST use
cases, such as mission-critical autonomous train systems.Comment: 6 pages, 5 figures, IEEE WCNC 2018 (Wireless Communications and
Networking Conference
Efficient Fast-Convolution-Based Waveform Processing for 5G Physical Layer
This paper investigates the application of fast-convolution (FC) filtering
schemes for flexible and effective waveform generation and processing in the
fifth generation (5G) systems. FC-based filtering is presented as a generic
multimode waveform processing engine while, following the progress of 5G new
radio standardization in the Third-Generation Partnership Project, the main
focus is on efficient generation and processing of subband-filtered cyclic
prefix orthogonal frequency-division multiplexing (CP-OFDM) signals. First, a
matrix model for analyzing FC filter processing responses is presented and used
for designing optimized multiplexing of filtered groups of CP-OFDM physical
resource blocks (PRBs) in a spectrally well-localized manner, i.e., with narrow
guardbands. Subband filtering is able to suppress interference leakage between
adjacent subbands, thus supporting independent waveform parametrization and
different numerologies for different groups of PRBs, as well as asynchronous
multiuser operation in uplink. These are central ingredients in the 5G waveform
developments, particularly at sub-6-GHz bands. The FC filter optimization
criterion is passband error vector magnitude minimization subject to a given
subband band-limitation constraint. Optimized designs with different guardband
widths, PRB group sizes, and essential design parameters are compared in terms
of interference levels and implementation complexity. Finally, extensive coded
5G radio link simulation results are presented to compare the proposed approach
with other subband-filtered CP-OFDM schemes and time-domain windowing methods,
considering cases with different numerologies or asynchronous transmissions in
adjacent subbands. Also the feasibility of using independent transmitter and
receiver processing for CP-OFDM spectrum control is demonstrated
Superimposed training for single carrier transmission in future mobile communications
The amount of wireless devices and wireless traffic has been increasing exponentially for the last ten years. It is forecasted that the exponential growth will continue without saturation till 2020 and probably further. So far, network vendors and operators have tackled the problem by introducing new evolutions of cellular macro networks, where each evolution has increased the physical layer spectral efficiency. Unfortunately, the spectral efficiency of the physical layer is achieving the Shannon-Hartley limit and does not provide much room for improvement anymore.
However, considering the overhead due to synchronization and channel estimation reference symbols in the context of physical layer spectral efficiency, we believe that there is room for improvement. In this thesis, we will study the potentiality of superimposed training methods, especially data-dependent superimposed training, to boost the spectral efficiency of wideband single carrier communications even further.
The main idea is that with superimposed training we can transmit more data symbols in the same time duration as compared to traditional time domain multiplexed training. In theory, more data symbols means more data bits which indicates higher throughput for the end user. In practice, nothing is free. With superimposed training we encounter self-interference between the training signal and the data signal. Therefore, we have to look for iterative receiver structures to separate these two or to estimate both, the desired data signal and the interfering component.
In this thesis, we initiate the studies to find out if we truly can improve the existing systems by introducing the superimposed training scheme. We show that in certain scenarios we can achieve higher spectral efficiency, which maps directly to higher user throughput, but with the cost of higher signal processing burden in the receiver. In addition, we provide analytical tools for estimating the symbol or bit error ratio in the receiver with a given parametrization.
The discussion leads us to the conclusion that there still remains several open topics for further study when looking for new ways of optimizing the overhead of reference symbols in wireless communications. Superimposed training with data-dependent components may prove to provide extra throughput gain. Furthermore, the superimposed component may be used for, e.g., improved synchronization, low bit-rate signaling or continuous tracking of neighbor cells. We believe that the current systems could be improved by using the superimposed training collectively with time domain multiplexed training
5G New Radio Evolution Towards Sub-THz Communications
In this paper, the potential of extending 5G New Radio physical layer
solutions to support communications in sub-THz frequencies is studied. More
specifically, we introduce the status of third generation partnership project
studies related to operation on frequencies beyond 52.6 GHz and note also the
recent proposal on spectrum horizons provided by federal communications
commission (FCC) related to experimental licenses on 95 GHz - 3 THz frequency
band. Then, we review the power amplifier (PA) efficiency and output power
challenge together with the increased phase noise (PN) distortion effect in
terms of the supported waveforms. As a practical example on the waveform and
numerology design from the perspective of the PN robustness, link performance
results using 90 GHz carrier frequency are provided. The numerical results
demonstrate that new, higher subcarrier spacings are required to support high
throughput, which requires larger changes in the physical layer design. It is
also observed that new phase-tracking reference signal designs are required to
make the system robust against PN. The results illustrate that single-carrier
frequency division multiple access is significantly more robust against PN and
can provide clearly larger PA output power than cyclic-prefix orthogonal
frequency division multiplexing, and is therefore a highly potential waveform
for sub-THz communications.Comment: This manuscript has been accepted for publication to IEEE 6G Wireless
Summit 2020, 6 pages, 4 figure
Developing an Auditory and Visual Cross-Modal Continuous Performance Task for Evaluating Concussion
Neurocognitive tests like the SCAT3 and ImPACT have become standard concussion assessment tools. Although these tests have adequate sensitivity, specificity, and reliability, they are unimodal in nature. Consequently, the tests do not fully assess the range of processing that can be affected by concussion (Thompson, 2012). Therefore, we developed a cross-modal continuous performance task to examine cognitive processing post-concussion. Forty-three middle school school lacrosse players, college students, and physical therapy graduate students participated in the study. Twelve of these participants had been previously diagnosed with a concussion. Participants completed a symptom checklist from SCAT3 along with other demographic information (e.g., previously concussed, last concussion). They then completed the continuous performance task starting with visual detection followed by visual inhibition, auditory detection, and auditory inhibition. Older subjects were more accurate than younger subjects on the detection task (F(1, 84) = 20.61, p \u3c .001). Subjects were also more accurate on the visual task than the auditory task (F(1, 84) = 21.47, p \u3c .001). Both age (F(1, 84) = 5.65, p \u3c .02) and previous concussion (F(1, 84) = 4.49, p \u3c .04) interacted with test modality. College and graduate students who had previously been concussed performed the same as those who had not been concussed. However, middle schoolers who had been concussed did significantly worse on the auditory task than those who had not been concussed. Similarly, older subjects were more accurate than younger subjects on the inhibition task (F(1, 84) = 4.91, p \u3c .03). Older subjects were also significantly more accurate on the visual task than the middle schoolers (F(1, 84) = 5.33, p \u3c .03; Figure 2). However, no differences were found based on previous concussion
Frequency-Domain Signal Processing for Spectrally-Enhanced CP-OFDM Waveforms in 5G New Radio
Orthogonal frequency-division multiplexing (OFDM) has been selected as the
basis for the fifth-generation new radio (5G-NR) waveform developments.
However, effective signal processing tools are needed for enhancing the OFDM
spectrum in various advanced transmission scenarios. In earlier work, we have
shown that fast-convolution (FC) processing is a very flexible and efficient
tool for filtered-OFDM signal generation and receiver-side subband filtering,
e.g., for the mixed-numerology scenarios of the 5G-NR. FC filtering
approximates linear convolution through effective fast Fourier transform
(FFT)-based circular convolutions using partly overlapping processing blocks.
However, with the continuous overlap-and-save and overlap-and-add processing
models with fixed block-size and fixed overlap, the FC-processing blocks cannot
be aligned with all OFDM symbols of a transmission frame. Furthermore, 5G-NR
numerology does not allow to use transform lengths shorter than 128 because
this would lead to non-integer cyclic prefix (CP) lengths. In this article, we
present new FC-processing schemes which solve the mentioned limitations. These
schemes are based on dynamically adjusting the overlap periods and
extrapolating the CP samples, which make it possible to align the FC blocks
with each OFDM symbol, even in case of variable CP lengths. This reduces
complexity and latency, e.g., in mini-slot transmissions and, as an example,
allows to use 16-point transforms in case of a 12-subcarrier-wide subband
allocation, greatly reducing the implementation complexity. On the receiver
side, the proposed scheme makes it possible to effectively combine cascaded
inverse and forward FFT units in FC-filtered OFDM processing. Transform
decomposition is used to simplify these computations. Very extensive set of
numerical results is also provided, in terms of radio-link performance and
associated processing complexity.Comment: This work has been submitted to the IEEE Transactions on Wireless
Communications for possible publication. Copyright may be transferred without
notice, after which this version may no longer be accessibl
- …