303 research outputs found
Discrete multitone modulation with principal component filter banks
Discrete multitone (DMT) modulation is an attractive method for communication over a nonflat channel with possibly colored noise. The uniform discrete Fourier transform (DFT) filter bank and cosine modulated filter bank have in the past been used in this system because of low complexity. We show in this paper that principal component filter banks (PCFB) which are known to be optimal for data compression and denoising applications, are also optimal for a number of criteria in DMT modulation communication. For example, the PCFB of the effective channel noise power spectrum (noise psd weighted by the inverse of the channel gain) is optimal for DMT modulation in the sense of maximizing bit rate for fixed power and error probabilities. We also establish an optimality property of the PCFB when scalar prefilters and postfilters are used around the channel. The difference between the PCFB and a traditional filter bank such as the brickwall filter bank or DFT filter bank is significant for effective power spectra which depart considerably from monotonicity. The twisted pair channel with its bridged taps, next and fext noises, and AM interference, therefore appears to be a good candidate for the application of a PCFB. This is demonstrated with the help of numerical results for the case of the ADSL channel
Distortion Exponent in MIMO Channels with Feedback
The transmission of a Gaussian source over a block-fading multiple antenna
channel in the presence of a feedback link is considered. The feedback link is
assumed to be an error and delay free link of capacity 1 bit per channel use.
Under the short-term power constraint, the optimal exponential behavior of the
end-to-end average distortion is characterized for all source-channel bandwidth
ratios. It is shown that the optimal transmission strategy is successive
refinement source coding followed by progressive transmission over the channel,
in which the channel block is allocated dynamically among the layers based on
the channel state using the feedback link as an instantaneous automatic repeat
request (ARQ) signal.Comment: Presented at the IEEE Information Theory Workshop (ITW), Taormina,
Italy, Oct. 200
A Review of Micro-Contact Physics for Microelectromechanical Systems (MEMS) Metal Contact Switches
Innovations in relevant micro-contact areas are highlighted, these include, design, contact resistance modeling, contact materials, performance and reliability. For each area the basic theory and relevant innovations are explored. A brief comparison of actuation methods is provided to show why electrostatic actuation is most commonly used by radio frequency microelectromechanical systems designers. An examination of the important characteristics of the contact interface such as modeling and material choice is discussed. Micro-contact resistance models based on plastic, elastic-plastic and elastic deformations are reviewed. Much of the modeling for metal contact micro-switches centers around contact area and surface roughness. Surface roughness and its effect on contact area is stressed when considering micro-contact resistance modeling. Finite element models and various approaches for describing surface roughness are compared. Different contact materials to include gold, gold alloys, carbon nanotubes, composite gold-carbon nanotubes, ruthenium, ruthenium oxide, as well as tungsten have been shown to enhance contact performance and reliability with distinct trade offs for each. Finally, a review of physical and electrical failure modes witnessed by researchers are detailed and examined
On the DMT of TDD-SIMO Systems with Channel-Dependent Reverse Channel Training
This paper investigates the Diversity-Multiplexing gain Trade-off (DMT) of a
training based reciprocal Single Input Multiple Output (SIMO) system, with (i)
perfect Channel State Information (CSI) at the Receiver (CSIR) and noisy CSI at
the Transmitter (CSIT), and (ii) noisy CSIR and noisy CSIT. In both the cases,
the CSIT is acquired through Reverse Channel Training (RCT), i.e., by sending a
training sequence from the receiver to the transmitter. A channel-dependent
fixed-power training scheme is proposed for acquiring CSIT, along with a
forward-link data transmit power control scheme. With perfect CSIR, the
proposed scheme is shown to achieve a diversity order that is quadratically
increasing with the number of receive antennas. This is in contrast with
conventional orthogonal RCT schemes, where the diversity order is known to
saturate as the number of receive antennas is increased, for a given channel
coherence time. Moreover, the proposed scheme can achieve a larger DMT compared
to the orthogonal training scheme. With noisy CSIR and noisy CSIT, a three-way
training scheme is proposed and its DMT performance is analyzed. It is shown
that nearly the same diversity order is achievable as in the perfect CSIR case.
The time-overhead in the training schemes is explicitly accounted for in this
work, and the results show that the proposed channel-dependent RCT and data
power control schemes offer a significant improvement in terms of the DMT,
compared to channel-agnostic orthogonal RCT schemes. The outage performance of
the proposed scheme is illustrated through Monte-Carlo simulations.Comment: Accepted for publication in IEEE Transactions on Communication
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