Elements of information theory
Elements of information theory
Information Theory and Reliable Communication
Information Theory and Reliable Communication
Operation and Modeling of the Mos Transistor (The Oxford Series in Electrical and Computer Engineering)
Molecular Electronics, Circuits, and Processing Platforms
Molecular Electronics, Circuits, and Processing Platforms
On multipath fading channels at high SNR
IEEE Transactions on Information Theory
Nearest neighbor decoding for additive non-Gaussian noise channels
IEEE Transactions on Information Theory
Fading channels: how perfect need "perfect side information" be?
IEEE Transactions on Information Theory
Spectral efficiency in the wideband regime
IEEE Transactions on Information Theory
Capacity bounds via duality with applications to multiple-antenna systems on flat-fading channels
IEEE Transactions on Information Theory
On the asymptotic capacity of stationary Gaussian fading channels
IEEE Transactions on Information Theory
Capacity Per Unit Energy of Fading Channels With a Peak Constraint
IEEE Transactions on Information Theory
Capacity Results for Block-Stationary Gaussian Fading Channels With a Peak Power Constraint
IEEE Transactions on Information Theory
Allerton'09 Proceedings of the 47th annual Allerton conference on Communication, control, and computing
On multipath fading channels at high SNR
IEEE Transactions on Information Theory
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This paper considers an additive noise channel where the time-k noise variance is a weighted sum of the squared magnitudes of the previous channel inputs plus a constant. This channel model accounts for the dependence of the intrinsic thermal noise on the data due to the heat dissipation associated with the transmission of data in electronic circuits: the data determine the transmitted signal, which in turn heats up the circuit and thus influences the power of the thermal noise. The capacity of this channel (both with and without feedback) is studied at low transmit powers and at high transmit powers. At low transmit powers, the slope of the capacity-versus-power curve at zero is computed and it is shown that the heating-up effect is beneficial. At high transmit powers, conditions are determined under which the capacity is bounded, i.e., under which the capacity does not grow to infinity as the allowed average power tends to infinity.