7,298 research outputs found
Capacity per Unit Energy of Fading Channels with a Peak Constraint
A discrete-time single-user scalar channel with temporally correlated
Rayleigh fading is analyzed. There is no side information at the transmitter or
the receiver. A simple expression is given for the capacity per unit energy, in
the presence of a peak constraint. The simple formula of Verdu for capacity per
unit cost is adapted to a channel with memory, and is used in the proof. In
addition to bounding the capacity of a channel with correlated fading, the
result gives some insight into the relationship between the correlation in the
fading process and the channel capacity. The results are extended to a channel
with side information, showing that the capacity per unit energy is one nat per
Joule, independently of the peak power constraint.
A continuous-time version of the model is also considered. The capacity per
unit energy subject to a peak constraint (but no bandwidth constraint) is given
by an expression similar to that for discrete time, and is evaluated for
Gauss-Markov and Clarke fading channels.Comment: Journal version of paper presented in ISIT 2003 - now accepted for
publication in IEEE Transactions on Information Theor
The Noncoherent Rician Fading Channel -- Part II : Spectral Efficiency in the Low-Power Regime
Transmission of information over a discrete-time memoryless Rician fading
channel is considered where neither the receiver nor the transmitter knows the
fading coefficients. The spectral-efficiency/bit-energy tradeoff in the
low-power regime is examined when the input has limited peakedness. It is shown
that if a fourth moment input constraint is imposed or the input
peak-to-average power ratio is limited, then in contrast to the behavior
observed in average power limited channels, the minimum bit energy is not
always achieved at zero spectral efficiency. The low-power performance is also
characterized when there is a fixed peak limit that does not vary with the
average power. A new signaling scheme that overlays phase-shift keying on
on-off keying is proposed and shown to be optimally efficient in the low-power
regime.Comment: To appear in the IEEE Transactions on Wireless Communication
Capacity Results for Block-Stationary Gaussian Fading Channels with a Peak Power Constraint
We consider a peak-power-limited single-antenna block-stationary Gaussian
fading channel where neither the transmitter nor the receiver knows the channel
state information, but both know the channel statistics. This model subsumes
most previously studied Gaussian fading models. We first compute the asymptotic
channel capacity in the high SNR regime and show that the behavior of channel
capacity depends critically on the channel model. For the special case where
the fading process is symbol-by-symbol stationary, we also reveal a fundamental
interplay between the codeword length, communication rate, and decoding error
probability. Specifically, we show that the codeword length must scale with SNR
in order to guarantee that the communication rate can grow logarithmically with
SNR with bounded decoding error probability, and we find a necessary condition
for the growth rate of the codeword length. We also derive an expression for
the capacity per unit energy. Furthermore, we show that the capacity per unit
energy is achievable using temporal ON-OFF signaling with optimally allocated
ON symbols, where the optimal ON-symbol allocation scheme may depend on the
peak power constraint.Comment: Submitted to the IEEE Transactions on Information Theor
Low SNR Capacity of Noncoherent Fading Channels
Discrete-time Rayleigh fading single-input single-output (SISO) and
multiple-input multiple-output (MIMO) channels are considered, with no channel
state information at the transmitter or the receiver. The fading is assumed to
be stationary and correlated in time, but independent from antenna to antenna.
Peak-power and average-power constraints are imposed on the transmit antennas.
For MIMO channels, these constraints are either imposed on the sum over
antennas, or on each individual antenna. For SISO channels and MIMO channels
with sum power constraints, the asymptotic capacity as the peak signal-to-noise
ratio tends to zero is identified; for MIMO channels with individual power
constraints, this asymptotic capacity is obtained for a class of channels
called transmit separable channels. The results for MIMO channels with
individual power constraints are carried over to SISO channels with delay
spread (i.e. frequency selective fading).Comment: submitted to IEEE I
Capacity of Underspread Noncoherent WSSUS Fading Channels under Peak Signal Constraints
We characterize the capacity of the general class of noncoherent underspread
wide-sense stationary uncorrelated scattering (WSSUS) time-frequency-selective
Rayleigh fading channels, under peak constraints in time and frequency and in
time only. Capacity upper and lower bounds are found which are explicit in the
channel's scattering function and allow to identify the capacity-maximizing
bandwidth for a given scattering function and a given peak-to-average power
ratio.Comment: To be presented at IEEE Int. Symp. Inf. Theory 2007, Nice, Franc
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