Method to gain access to a base station in a discrete multitone spread spectrum communications system

US 6,002,664 A
Filed: 02/24/1997
Issued: 12/14/1999
Est. Priority Date: 02/24/1997
Status: Expired due to Fees

First Claim

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1. A highly bandwidth-efficient communications method, comprising:

receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;

receiving at the base station during the first time period a second spread signal from the second remote unit comprising a second common access channel data signal spread over the first plurality of discrete tones in accordance with the first spreading code;

said discrete tones being sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a OAM modulation constellation which are related to an average amount of energy of the discrete tones;

adaptively despreading the first spread signal and the second spread signal received at the base station by using first despreading codes that are based on characteristics of the received first and second spread signals;

determining at the base station that a collision has occurred between the first and second spread signals;

transmitting from the base station a notice of the collision to the first and second remote unitssaid base station using said complex numbers to prepare said notice of the collision; and

said base station distinguishing the collision from a noise burst by using said complex numbers.

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Abstract

In a discrete multitone spread spectrum system, a base station distinguishes between normal collisions and noise bursts when receiving access request signals from remote units on a common access channel. The base station is then able to reply to the remote units with information about the quality of the common access channel and why their transmissions were not successful. The remote units then use this information to adapt their retry processes to the channel'"'"'s quality, depending on whether there was a noise burst, a normal collision, or a successful transmission on the channel.

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24 Claims

1. A highly bandwidth-efficient communications method, comprising:
- receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  receiving at the base station during the first time period a second spread signal from the second remote unit comprising a second common access channel data signal spread over the first plurality of discrete tones in accordance with the first spreading code;
  
  said discrete tones being sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a OAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  adaptively despreading the first spread signal and the second spread signal received at the base station by using first despreading codes that are based on characteristics of the received first and second spread signals;
  
  determining at the base station that a collision has occurred between the first and second spread signals;
  
  transmitting from the base station a notice of the collision to the first and second remote unitssaid base station using said complex numbers to prepare said notice of the collision; and
  
  said base station distinguishing the collision from a noise burst by using said complex numbers.
- View Dependent Claims (2, 3, 5, 6)
- - 2. The highly bandwidth-efficient communications method of claim 1, which further comprises:
    - said first and second spread signals are discrete tones received by the base station from the first and second remote units during a reverse interval of a time division duplex period.
  - 3. The highly bandwidth-efficient communications method of claim 2, which further comprises:
    - said discrete tones are modulated with an access request by the first and second remote units using a 16 QAM modulation scheme.
  - 5. The highly bandwidth-efficient communications method of claim 1, which further comprises:
    - said first remote unit and said second remote unit receiving said notice and in response thereto, beginning a first type back-off and retry process to avoid a second collision.
  - 6. The highly bandwidth-efficient communications method of claim 5, which further comprises:
    - said first remote unit and said second remote unit failing to receive said notice and in response thereto, beginning a second type back-off and retry process to minimize effects of noise bursts.

4. A highly bandwidth-efficient communications method, comprising:
- receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  receiving at the base station during the first time period a second spread signal from the second remote unit comprising a second common access channel data signal spread over the first plurality of discrete tones in accordance with the first spreading code;
  
  adaptively despreading the first spread signal and the second spread signal received at the base station by using first despreading codes that are based on characteristics of the received first and second spread signals;
  
  determining at the base station that a collision has occurred between the first and second spread signals;
  
  transmitting from the base station a notice of the collision to the first and second remote units;
  
  said first and second spread signals discrete tones received by the base station from the first and second remote units during a reverse interval of a time division duplex period;
  
  said discrete tones modulated by the first and second remote units using a QAM modulation scheme;
  
  said discrete tones sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a QAM modulation constellation which are related to an average amount of energy of the discrete tone;
  
  said base station using said complex numbers to prepare said notice of the collision; and
  
  said base station distinguishing the collision from a noise burst by using said complex numbers.

7. A highly bandwidth-efficient communications method, comprising:
- receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  receiving at the base station during the first time period a noise burst signal comprising that at least partially interferes with the first plurality of discrete tones;
  
  said discrete tones being sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a OAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  adaptively despreading the first spread signal and processing the noise burst signal received at the base station by using first despreading codes that are based on characteristics of the first spread signal;
  
  determining at the base station that a noise burst has occurred while receiving the first spread signal;
  
  transmitting from the base station a notice of the noise burst to the first remote unit;
  
  said base station using said complex numbers to prepare said notice of the noise burst; and
  
  said base station distinguishing the noise burst from collisions with spread signals from other remote units by using said complex numbers.
- View Dependent Claims (8, 9, 11, 12)
- - 8. The highly bandwidth-efficient communications method of claim 7, which further comprises:
    - said first spread signal is discrete tones received by the base station from the first remote unit during a reverse interval of a time division duplex period.
  - 9. The highly bandwidth-efficient communications method of claim 8, which further comprises:
    - said discrete tones are modulated with an access request by the first remote unit using a 16 QAM modulation scheme.
  - 11. The highly bandwidth-efficient communications method of claim 7, which further comprises:
    - said first remote unit receiving said notice and in response thereto, beginning a first type back-off and retry process to minimize effects of the noise burst.
  - 12. The highly bandwidth-efficient communications method of claim 11, which further comprises:
    - said first remote unit failing to receive said notice and in response thereto, beginning said first type back-off and retry process to minimize effects of noise bursts.

10. A highly bandwidth-efficient communications method, comprising:
- receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  receiving at the base station during the first time period a noise burst signal comprising that at least partially interferes with the first plurality of discrete tones;
  
  adaptively despreading the first spread signal and processing the noise burst signal received at the base station by using first despreading codes that are based on characteristics of the first spread signal;
  
  determining at the base station that a noise burst has occurred while receiving the first spread signal;
  
  transmitting from the base station a notice of the noise burst to the first remote unit;
  
  said first spread signal discrete tones received by the base station from the first remote unit during a reverse interval of a time division duplex period;
  
  said discrete tones modulated with an access request by the first remote unit using a QAM modulation scheme;
  
  said discrete tones sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a QAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  said base station using said complex numbers to prepare said notice of the noise burst; and
  
  said base station distinguishing the noise burst from collisions with spread signals from other remote units by using said complex numbers.

13. A highly bandwidth-efficient communications system, comprising:
- means for receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  means for receiving at the base station during the first time period a second spread signal from the second remote unit comprising a second common access channel data signal spread over the first plurality of discrete tones in accordance with the first spreading code;
  
  said discrete tones being sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a OAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  means for adaptively despreading the first spread signal and the second spread signal received at the base station by using first despreading codes that are based on characteristics of the received first and second spread signals;
  
  means for determining at the base station that a collision has occurred between the first and second spread signals;
  
  means for transmitting from the base station a notice of the collision to the first and second remote units;
  
  said base station using said complex numbers to prepare said notice of the collision; and
  
  said base station distinguishing the collision from a noise burst by using said complex numbers.
- View Dependent Claims (14, 15, 17, 18)
- - 14. The highly bandwidth-efficient communications system of claim 13, which further comprises:
    - said first and second spread signals are discrete tones received by the base station from the first and second remote units during a reverse interval of a time division duplex period.
  - 15. The highly bandwidth-efficient communications system of claim 14, which further comprises:
    - said discrete tones are modulated with an access request by the first and second remote units using a 16 QAM modulation scheme.
  - 17. The highly bandwidth-efficient communications system of claim 13, which further comprises:
    - said first remote unit and said second remote unit receiving said notice and in response thereto, beginning a first type back-off and retry process to avoid a second collision.
  - 18. The highly bandwidth-efficient communications system of claim 17, which further comprises:
    - said first remote unit and said second remote unit failing to receive said notice and in response thereto, beginning a second type back-off and retry process to minimize effects of noise bursts.

16. A highly bandwidth-efficient communications system, comprising:
- means for receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  means for receiving at the base station during the first time period a second spread signal from the second remote unit comprising a second common access channel data signal spread over the first plurality of discrete tones in accordance with the first spreading code;
  
  means for adaptively despreading the first spread signal and the second spread signal received at the base station by using first despreading codes that are based on characteristics of the received first and second spread signals;
  
  means for determining at the base station that a collision has occurred between the first and second spread signals;
  
  means for transmitting from the base station a notice of the collision to the first and second remote units;
  
  said first and second spread signals discrete tones received by the base station from the first and second remote units during a reverse interval of a time division duplex period;
  
  said discrete tones modulated with an access request by the first and second remote units using a QAM modulation scheme;
  
  said discrete tones sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a QAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  said base station using said complex numbers to prepare said notice of the collision; and
  
  said base station distinguishing the collision from a noise burst by using said complex numbers.

19. A highly bandwidth-efficient communications system, comprising:
- means for receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  means for receiving at the base station during the first time period a noise burst signal comprising that at least partially interferes with the first plurality of discrete tones;
  
  said discrete tones being sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a OAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  means for adaptively despreading the first spread signal and processing the noise burst signal received at the base station by using first despreading codes that are based on characteristics of the first spread signal;
  
  means for determining at the base station a notice of the noise burst to the first remote unit;
  
  said base station using said complex numbers to prepare said notice of the noise burst; and
  
  said base station distinguishing the noise burst from collisions with spread signals from other remote units by using said complex numbers.
- View Dependent Claims (20, 21, 23, 24)
- - 20. The highly bandwidth-efficient communications system of claim 19, which further comprises:
    - said first spread signal is discrete tones received by the base station from the first remote unit during a reverse interval of a time division duplex period.
  - 21. The highly bandwidth-efficient communications system of claim 20, which further comprises:
    - said discrete tones are modulated with an access request by the first remote unit using a 16 QAM modulation scheme.
  - 23. The highly bandwidth-efficient communications system of claim 19, which further comprises:
    - said first remote unit receiving said notice and in response thereto, beginning a first type back-off and retry process to minimize effects of the noise burst.
  - 24. The highly bandwidth-efficient communications system of claim 23, which further comprises:
    - said first remote unit failing to receive said notice and in response thereto, beginning said first type back-off and retry process to minimize effects of noise bursts.

22. A highly bandwidth-efficient communications system, comprising:
- means for receiving at a base station during a first time period a first spread signal from a first remote unit comprising a first common access channel data signal spread over a first plurality of discrete tones in accordance with a first spreading code assigned to at least the first and a second remote units;
  
  means for receiving at the base station during the first time period a noise burst signal comprising that at least partially interferes with the first plurality of discrete tones;
  
  means for adaptively despreading the first spread signal and processing the noise burst signal received at the base station by using first despreading codes that are based on characteristics of the first spread signal;
  
  means for determining at the base station a notice of the noise burst to the first remote unit;
  
  said first spread signal discrete tones received by the base station from the first remote unit during a reverse interval of a time division duplex period;
  
  said discrete tones modulated with an access request by the first remote unit using a QAM modulation scheme;
  
  said discrete tones sampled, digitized, passed through a fast Fourier transform (FFT) processor, and stored in FFT incremental frequency bins as complex numbers which represent points in a QAM modulation constellation which are related to an average amount of energy of the discrete tones;
  
  said base station using said complex numbers to prepare said notice of the noise burst;
  
  said base station distinguishing the noise burst from collisions with spread signals from other remote units by using said complex numbers.

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Current Assignee
AT&T Mobility II LLC (AT&T, Inc.)
Original Assignee
AT&T Wireless Services Incorporated (AT&T, Inc.)
Inventors
Schachter, Paul Joseph
Primary Examiner(s)
HSU, ALPUS

Application Number

US08/806,507
Time in Patent Office

1,023 Days
Field of Search

370/320, 370/335, 370/342, 370/206, 370/207, 370/280, 370/210, 370/445, 375/200, 375/202, 375/206, 375/298, 375/346, 375/348, 375/350, 455/507, 455/517, 455/59-61, 455/63, 455/67.1, 455/67.3
US Class Current

370/207
CPC Class Codes

H04L 1/0001   Systems modifying transmiss...

H04L 1/0026   Transmission of channel qua...

H04L 5/026   using code division

Method to gain access to a base station in a discrete multitone spread spectrum communications system

First Claim

6 Assignments

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Abstract

35 Citations

24 Claims

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Method to gain access to a base station in a discrete multitone spread spectrum communications system

First Claim

6 Assignments

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Accused Products

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Abstract

35 Citations

24 Claims

Specification

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