Method of and means for spread-spectrum transmission

US 4,365,327 A
Filed: 12/12/1980
Issued: 12/21/1982
Est. Priority Date: 12/13/1979
Status: Expired due to Term

First Claim

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1. A method of sending signals from a plurality of transmitting stations to respective receiving stations over a common channel, comprising the steps of:

(a) periodically sampling an outgoing analog signal at a given transmitting station, at intervals not exceeding the reciprocal of twice the bandwidth of said outgoing signal, and storing the resulting samples for periods equaling said intervals to produce a stepped wave;

(b) multiplying said stepped wave at the given transmitting station with a sequence of bipolar binary pulses individual thereto and essentially uncorrelated with pulse sequences employed at other transmitting stations using said common channel, thereby producing a distorted wave;

(c) conveying said distorted wave via said signal link to the associated receiving station;

(d) multiplying the incoming distorted wave at the associated receiving station with a synchronized replica of said individual sequence to re-establish the wave of step (b) possibly encumbered by interfering signals from other users of said common channel;

(e) integrating the re-established stepped wave over intervals equaling the sampling intervals of step (a) to provide discrete signal with amplitudes proportional to those of the steps of the re-established wave;

(f) storing said discrete signals for periods equaling said sampling intervals to produce a delayed counterpart of the re-established stepped wave substantially purged of interfering signals and with a low-frequency component conforming to said outgoing analog signal; and

(g) isolating said low-frequency component.

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Abstract

An analog signal sent from one telephone subscriber to another is periodically sampled at a transmitting terminal and each sample is held for a storage period equal to a sampling interval as well as to a basic pulse period of a random or pseudorandom sequence of bipolar binary pulses. A stepped wave formed from these samples is mixed with that pulse sequence before being conveyed, e.g. by frequency modulation, to a receiving terminal where the wave so distorted is mixed with a like pulse sequence to re-establish the undistorted wave which may be contaminated by interferences from other users of the same signal link. The steps of the re-established wave are integrated over periods equal to the sampling interval and the integration products are stored for like periods to produce a purged stepped wave from which high-frequency components are subsequently filtered out to restore the original analog signal. The signal link utilized may be an emergency channel made available, e.g. for communication with a mobile station, when regular channels are busy.

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9 Claims

1. A method of sending signals from a plurality of transmitting stations to respective receiving stations over a common channel, comprising the steps of:
- (a) periodically sampling an outgoing analog signal at a given transmitting station, at intervals not exceeding the reciprocal of twice the bandwidth of said outgoing signal, and storing the resulting samples for periods equaling said intervals to produce a stepped wave;
  
  (b) multiplying said stepped wave at the given transmitting station with a sequence of bipolar binary pulses individual thereto and essentially uncorrelated with pulse sequences employed at other transmitting stations using said common channel, thereby producing a distorted wave;
  
  (c) conveying said distorted wave via said signal link to the associated receiving station;
  
  (d) multiplying the incoming distorted wave at the associated receiving station with a synchronized replica of said individual sequence to re-establish the wave of step (b) possibly encumbered by interfering signals from other users of said common channel;
  
  (e) integrating the re-established stepped wave over intervals equaling the sampling intervals of step (a) to provide discrete signal with amplitudes proportional to those of the steps of the re-established wave;
  
  (f) storing said discrete signals for periods equaling said sampling intervals to produce a delayed counterpart of the re-established stepped wave substantially purged of interfering signals and with a low-frequency component conforming to said outgoing analog signal; and
  
  (g) isolating said low-frequency component.
- View Dependent Claims (2, 3, 4)
- - 2. A method as defined in claim 1 wherein said individual sequence has a basic pulse period equaling said sampling intervals.
  - 3. A method as defined in claim 1 or 2, comprising the further step of subjecting said outgoing analog signal, before sampling, to a frequency-dependent amplitude modification substantially compensating for an attenuation proportional to (π
    - fT/sinπ
      
      fT)² undergone by said outgoing signal in step (a), f being any constituent frequency of said outgoing signal and T being the duration of a sampling interval.
  - 4. A method as defined in claim 1 or 2, comprising the further step of subjecting said low-frequency component to a frequency-dependent amplitude modification substantially compensating for an attenuation proportional to (π
    - fT/sinπ
      
      fT)² undergone by said outgoing signal in step (a), f being any constituent frequency of said outgoing signal and T being the duration of a sampling interval.

5. In a telecommunication system wherein a plurality of transmitting stations and a plurality of receiving stations are provided with a common channel for the conveyance of analog signals from a given transmitting station to an associated receiving station, each transmitting station comprising a first generator of an individual sequence of binary pulses essentially uncorrelated with pulse sequences emitted by corresponding generators of all other transmitting stations, each transmitting station further comprising first arithmetic means for multiplying an outgoing signal with said individual sequence, each receiving station comprising a second generator synchronized with said first generator of the associated transmitting station for emitting a replica of said individual sequence, each receiving station further comprising second arithmetic means for multiplying an incoming signal with said replica and circuitry including integrating means connected to said second arithmetic means for substantially reconstituting said outgoing signal,the improvement wherein at least one of said transmitting stations and an associated receiving station further comprise:
- sample-and-hold means upstream of said first arithmetic means for periodically taking samples of an outgoing analog signal and holding said samples for uniform storage periods equaling the sampling intervals, thereby giving rise to a stepped wave undergoing distortion in said first arithmetic means, the distorted wave being reconverted by said second arithmetic means into the original stepped wave possibly encumbered by interfering signals from other transmitting stations using said common channel, said interfering signals being substantially suppressed by said integrating means operating with integration periods equal to said sampling intervals;
  
  holding means in said circuitry connected to said integrating means for receiving therefrom a series of discrete signals with amplitudes proportional to those of respective steps of the reconstituted original stepped wave and preserving said discrete signals for periods equaling said sampling intervals, thereby producing a delayed counterpart of the reconstituted wave substantially purged of interfering signals; and
  
  filter means connected to said holding means for extracting from said delayed counterpart a low-frequency component conforming to said outgoing analog signal.
- View Dependent Claims (6, 7, 8, 9)
- - 6. A system as defined in claim 5 wherein said one of said transmitting stations further comprises frequency-selective amplitude-modifying means upstream of said sample-and-hold means having an amplitude/frequency characteristic substantially compensating for an attenuation proportional to (π
    - fT/sinπ
      
      fT)² undergone by said outgoing signal in said sample-and-hold means, f being any constituent frequency of said outgoing signal and T being the duration of a sampling interval.
  - 7. A system as defined in claim 5 wherein the receiving station associated with said one of said transmitting stations further comprises frequency-selective amplitude-modifying means in series with said filter means having an amplitude/frequency characteristic substantially compensating for an attenuation proportional to (π
    - fT/sinπ
      
      fT)² undergone by said outgoing signal in said sample-and-hold means, f being any constituent frequency of said outgoing signal and T being the duration of a sampling interval.
  - 8. A system as defined in claims 5, 6 or 7 wherein said one of said transmitting stations comprises a first terminal provided with frequency-modulating means for sending out signals over any one of several radio-frequency channels including a plurality of normal channels besides said common channel, the latter constituting said common signal link, first test means connected to said first terminal for ascertaining the availability of any normal channel, and first switchover means controlled by said first test means for connecting a source of outgoing analog signals to said first terminal directly in the presence of a free normal channel for signal transmission thereover and via said sample-and-hold means and said first arithmetic means in the absence of a free normal channel for signal transmission over said common channel;
    - the receiving station associated with said one of said transmitting stations comprising a second terminal provided with frequency-demodulating means for obtaining incoming signals from any of said radio-frequency channels, second test means connected to said second terminal for identifying a channel over which incoming signals are being received, and second switchover means controlled by said second test means for connecting said second terminal to a load directly upon arrival of incoming signals over any normal channel and via said second arithmetic means, said circuitry and said filter means upon arrival thereof over said common channel.
  - 9. A system as defined in claim 8 wherein said one of said transmitting stations is carried aboard a vehicle.

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Current Assignee
Cselt - Centro Studi E Laboratori Telecommunicazioni SPA
Original Assignee
Cselt - Centro Studi E Laboratori Telecommunicazioni SPA
Inventors
Pirani, Giancarlo
Primary Examiner(s)
Brigance, Gerald L.

Application Number

US06/215,793
Time in Patent Office

739 Days
Field of Search

370/18, 370/19, 370/119, 375/1
US Class Current

370/342
CPC Class Codes

H04B 1/69 Spread spectrum techniques

Method of and means for spread-spectrum transmission

First Claim

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Abstract

28 Citations

9 Claims

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Method of and means for spread-spectrum transmission

First Claim

1 Assignment

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Abstract

28 Citations

9 Claims

Specification

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