5 research outputs found
Time Reversal with Post-Equalization for OFDM without CP in Massive MIMO
This paper studies the possibility of eliminating the redundant cyclic prefix
(CP) of orthogonal frequency division multiplexing (OFDM) in massive
multiple-input multiple-output systems. The absence of CP increases the
bandwidth efficiency in expense of intersymbol interference (ISI) and
intercarrier interference (ICI). It is known that in massive MIMO, different
types of interference fade away as the number of base station (BS) antennas
tends to infinity. In this paper, we investigate if the channel distortions in
the absence of CP are averaged out in the large antenna regime. To this end, we
analytically study the performance of the conventional maximum ratio combining
(MRC) and realize that there always remains some residual interference leading
to saturation of signal to interference (SIR). This saturation of SIR is
quantified through mathematical equations. Moreover, to resolve the saturation
problem, we propose a technique based on time-reversal MRC with zero forcing
multiuser detection (TR-ZF). Thus, the SIR of our proposed TR-ZF does not
saturate and is a linear function of the number of BS antennas. We also show
that TR-ZF only needs one OFDM demodulator per user irrespective of the number
of BS antennas; reducing the BS signal processing complexity significantly.
Finally, we corroborate our claims as well as analytical results through
simulations.Comment: 7 pages, 3 figure
Damped Zero-Pseudorandom Noise OFDM Systems
This paper proposed a new OFDM scheme called damped zero-pseudorandom noise orthogonal frequency division multiplexing (DZPN-OFDM) scheme. In the proposed scheme, ZPN-OFDM non-zero part damped to reduce the guard interval energy as well as the mutual interference power in-between the data and training blocks, and conservative the pseudo-noise conventional properties required for channel estimation or synchronization. The motivation of this paper is the OFDM long guard interval working in wide dispersion channels, where significant energy waste if conventional ZPN-OFDM is used as well as the BER performance degradation. Also, to solve the ZPN-OFDM spectrum efficiency loss problem, the proposed scheme doesn’t duplicate the guard interval. Both detailed performance analysis and simulation results show that the proposed DZPN-OFDM scheme can, indeed, offer significant bit error rate, spectrum efficiency as well as energy efficiency improvement
Delay Alignment Modulation: Manipulating Channel Delay Spread for Efficient Single- and Multi-Carrier Communication
The evolution of mobile communication networks has always been accompanied by
the advancement of ISI mitigation techniques, from equalization in 2G, spread
spectrum and RAKE receiver in 3G, to OFDM in 4G and 5G. Looking forward towards
6G, by exploiting the high spatial resolution brought by large antenna arrays
and the multi-path sparsity of mmWave and Terahertz channels, a novel ISI
mitigation technique termed delay alignment modulation (DAM) was recently
proposed. However, existing works only consider the single-carrier perfect DAM,
which is feasible only when the number of BS antennas is no smaller than that
of channel paths, so that all multi-path signal components arrive at the
receiver simultaneously and constructively. This imposes stringent requirements
on the number of BS antennas and multi-path sparsity. In this paper, we propose
a generic DAM technique to manipulate the channel delay spread via
spatial-delay processing, thus providing a flexible framework to combat channel
time dispersion for efficient single- or multi-carrier transmissions. We first
show that when the number of BS antennas is much larger than that of channel
paths, perfect delay alignment can be achieved to transform the time-dispersive
channel to time non-dispersive channel with the simple delay pre-compensation
and path-based MRT beamforming. When perfect DAM is infeasible or undesirable,
the proposed generic DAM technique can be applied to significantly reduce the
channel delay spread. We further propose the novel DAM-OFDM technique, which is
able to save the CP overhead or mitigate the PAPR issue suffered by
conventional OFDM. We show that the proposed DAM-OFDM involves joint frequency-
and time-domain beamforming optimization, for which a closed-form solution is
derived. Simulation results show that the proposed DAM-OFDM outperforms the
conventional OFDM in terms of spectral efficiency, BER and PAPR.Comment: 16 Pages, 15 figure