Saved in:
Bibliographic Details
Main Author: Lieu, Richard
Format: Preprint
Published: 2017
Subjects:
Online Access:https://arxiv.org/abs/1708.06847
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866908488192491520
author Lieu, Richard
author_facet Lieu, Richard
contents The impossibility of sending pulses of radio waves (Morse codes) through an ionized medium, despite the superluminal phase velocity of the constituent modes, has been demonstrated in many and various ways; essentially the reason is because each pulse, or wave packet, propagate through the plasma at the group velocity, which is subluminal. Nevertheless, messages can also be encoded as {\it phase} modulations of a monochromatic carrier wave, with more than one constituent modes (which may mathematically be extracted by Fourier transform). These modes propagate at their respective phase velocities and, upon reassembling them on the receiver's side, can become the original signal with the original message it bore having propagated at the phase velocity of the carrier wave, \ie~superluminally. We provide a concrete working scenario of transmitting a message for arrival with a time lead (compared to vacuum propagation) which is an order magnitude more than the duration of the message itself. It is also shown that the distortion of the signal due to the multiplicity of modes induced by the phase modulation is minimal if the bandwidth of the signal, including the duration of its onset and offset, is a small fraction of the carrier wave frequency. Thus phase and pulse modulations are fundamentally different phenomena in terms of their propagation speeds.
format Preprint
id arxiv_https___arxiv_org_abs_1708_06847
institution arXiv
publishDate 2017
record_format arxiv
spellingShingle The speed of transmission of phase modulated signals through a plasma medium
Lieu, Richard
General Physics
The impossibility of sending pulses of radio waves (Morse codes) through an ionized medium, despite the superluminal phase velocity of the constituent modes, has been demonstrated in many and various ways; essentially the reason is because each pulse, or wave packet, propagate through the plasma at the group velocity, which is subluminal. Nevertheless, messages can also be encoded as {\it phase} modulations of a monochromatic carrier wave, with more than one constituent modes (which may mathematically be extracted by Fourier transform). These modes propagate at their respective phase velocities and, upon reassembling them on the receiver's side, can become the original signal with the original message it bore having propagated at the phase velocity of the carrier wave, \ie~superluminally. We provide a concrete working scenario of transmitting a message for arrival with a time lead (compared to vacuum propagation) which is an order magnitude more than the duration of the message itself. It is also shown that the distortion of the signal due to the multiplicity of modes induced by the phase modulation is minimal if the bandwidth of the signal, including the duration of its onset and offset, is a small fraction of the carrier wave frequency. Thus phase and pulse modulations are fundamentally different phenomena in terms of their propagation speeds.
title The speed of transmission of phase modulated signals through a plasma medium
topic General Physics
url https://arxiv.org/abs/1708.06847