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Distance division multiplexing

a technology of distance division and multiplexing, applied in the field of communication of information, can solve the problems of general unobvious how any form of distance determination could help, and the current technology is especially worse off, and is useless for separation itsel

Active Publication Date: 2006-09-07
GURUPRASAD VENKATA
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

"The present invention provides a general mechanism for separating signals from multiple sources, even when they are located along the same direction from a receiver. This mechanism is largely independent of the signal forms and can make use of the entire bandwidth available for communication between the source and the receiver. It can also detect interference and determine the source of the interference. The invention uses a combination of subband filtering and time-varying sampling to extract the desired signal. The process flow involves several stages of signal processing in the receiver. The technical effect of the invention is to provide a more efficient and effective mechanism for separating signals from multiple sources."

Problems solved by technology

Such an ideal receiver is unachievable by Shannon's theory, but current technology is especially worse off with respect to the criterion of interference, because it splits the available physical bandwidth in some way to keep the signals from multiple sources separate all the way.
The main challenges are directivity and range selection.
It is in fact generally unobvious how any form of distance determination could help in signal selection or source isolation.
The encoded information would be generally available only after the signals are separated, and would be thus useless for the separation itself.

Method used

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Examples

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Embodiment Construction

[0068]FIG. 1 illustrates the inventive procedure for separating signals received from sources at different distances from the receiver, using a graph of the spectral shift as a function of distance. Incoming signals of spectra F(ω) and F′(ω), from sources [520] and [530] at distances r and r′=r+δr, respectively, from the receiver [600] located at the origin of the graph are assumed to ordinarily occupy the same frequency band W. The two signals would ordinarily be received together as the combined signal ΣjFj(ω)≡{Fj}[100] and interfere with each other's reception at the receiver.

[0069] By applying Step B of the inventive procedure as given in the Summary, the receiver causes the spectra of these component signals to be shifted in proportion to the source distances using the method described in the copending application, i.e. by frequency factors (1+αr) [220] and (1+αr′) ([230]. The component spectra then occupy the shifted bands F1(ω1)≡H(α)F1(ω)≡HF1 [320] and F2(ω1)≡H(α)F2(ω)≡HF2 [...

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Abstract

A general method for extracting an electromagnetic or other wave-propagated signal of a desired source from the overall received waveform containing the sum of signals from a multitude of such sources, independently of signal contents and modulation. The method comprises the steps of first expanding the spectrum of the received sum of signals in proportion to their source distances so as to spectrally isolate the signal from the desired source, selecting the isolated signal spectrum using a bandpass filter, and finally, spectrally compressing the selected signal back to its original band of frequencies. The distance dependent expansion is performed by scanning the phase gradient of the signal spectrum. Related method for computing the spread of source distances by measuring low and high frequency bounds of the expanded sum of signals or subbands, or by plotting the expanded sum of signals or subbands on a graph.

Description

BACKGROUND OF THE INVENTION [0001] 1. Technical Field [0002] This invention generally pertains to communication of information between a source and a receiver. More particularly, it concerns the use of source distance information at the receiver to ensure maximum bandwidth of communication and avoid noise and interference from other sources operating over the same frequencies. [0003] 2. Brief Description of the Prior Art [0004] In his classic paper titled “A mathematical theory of communication” (Bell System Technical Journal, vol. 27, pages 379-423,623-656, 1948), Claude E Shannon defined the object of communication technology as enabling the transfer of information from a source to a receiver. A perfect receiver should be accordingly defined as one that could receive an arbitrary signal f(r, t) from a transmitter at a relative distance r without noise, distortion or interference from any other source. Such an ideal receiver is unachievable by Shannon's theory, but current technolo...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): H04K1/10
CPCG01S11/02H04L27/00
Inventor GURUPRASAD, VENKATA
Owner GURUPRASAD VENKATA
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