Frequency agile transceiver with multiple frequency synthesizers per transceiver

US 5,781,582 A
Filed: 05/04/1995
Issued: 07/14/1998
Est. Priority Date: 05/04/1995
Status: Expired due to Term

First Claim

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1. A base station for communicating over a cellular network with a mobile station, said base station comprising:

a receiver having a receiver synthesizer input and configured to receive inbound information from the mobile station on a predetermined receive frequency, said receiver further having two controllable receiver frequency sources that are configured to alternately supply a receiver synthesizer signal to said receiver synthesizer input;

a transmitter having a transmitter synthesizer input and configured to transmit outbound information to the mobile station on a predetermined transmit frequency, said transmitter further having two controllable transmitter frequency sources that are configured to alternately supply a transmitter synthesizer signal to said transmitter synthesizer input; and

a processor coupled to said receiver and said transmitter and configured to decode said inbound information and to encode said outbound information to communicate with the mobile station.

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Abstract

A base station communicates with a plurality of mobile stations over a cellular network. In one embodiment, the base station includes a receiver having a receiver synthesizer input, where the receiver is configured to receive inbound information from the mobile station on a first predetermined frequency. The receiver further has two programmable frequency sources that are configured to alternately supply a receiver synthesizer input signal to the receiver. The base station also includes a transmitter having a transmitter synthesizer input, where the transmitter is configured to transmit outbound information to the mobile station on a second predetermined frequency. The transmitter further has two programmable frequency sources that are configured to alternately supply a transmitter synthesizer input signal to the transmitter. A processor is connected to the receiver and the transmitter and is configured to decode the inbound information and to encode the outbound information to communicate with the mobile station. This two-way communication continues by programming and then alternately selecting the receive synthesizers to receive on the correct frequency, and by programming and then alternately selecting the transmit synthesizers to transmit on the correct frequency. A preferred protocol is Global Systems for Mobile Communication (GSM).

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26 Claims

1. A base station for communicating over a cellular network with a mobile station, said base station comprising:
- a receiver having a receiver synthesizer input and configured to receive inbound information from the mobile station on a predetermined receive frequency, said receiver further having two controllable receiver frequency sources that are configured to alternately supply a receiver synthesizer signal to said receiver synthesizer input;
  
  a transmitter having a transmitter synthesizer input and configured to transmit outbound information to the mobile station on a predetermined transmit frequency, said transmitter further having two controllable transmitter frequency sources that are configured to alternately supply a transmitter synthesizer signal to said transmitter synthesizer input; and
  
  a processor coupled to said receiver and said transmitter and configured to decode said inbound information and to encode said outbound information to communicate with the mobile station.
- View Dependent Claims (2, 3, 4, 5, 6, 7)
- - 2. The base station of claim 1, wherein:
    - said two receiver frequency sources each include a voltage controlled oscillator combined with a phase-locked feedback loop to maintain a respective first receiver synthesizer frequency and second receiver synthesizer frequency, and wherein said two receiver frequency sources are coupled to said processor;
      
      said receiver further includes a switch coupled to each of said receiver frequency sources, and selectable between a first position to deliver said first receiver synthesizer frequency to said receiver synthesizer input and a second position to deliver said second receiver synthesizer frequency to said receiver synthesizer input;
      
      said two transmitter frequency sources each include a voltage controlled oscillator combined with a phase-locked feedback loop to maintain a respective first transmitter synthesizer frequency and second transmitter synthesizer frequency, and wherein said two receiver frequency sources are coupled to said processor; and
      
      said transmitter further includes a switch coupled to each of said transmitter frequency sources, and selectable between a first position to deliver said first transmitter synthesizer frequency to said transmitter synthesizer input and a second position to deliver said second transmitter synthesizer frequency to said transmitter synthesizer input.
  - 3. The base station of claim 1 for further communicating with a second mobile station, said base station further comprising:
    - a second receiver having a second receiver synthesizer input and configured to receive second inbound information from the second mobile station on a second predetermined receive frequency, said second receiver further having two controllable receiver frequency sources that are configured to alternately supply a receiver synthesizer signal to said second receiver synthesizer input; and
      
      wherein said processor is further coupled to said second receiver and configured to decode said second inbound information to communicate with the second mobile station.
  - 4. The base station of claim 3, further comprising:
    - a second transmitter having a second transmitter synthesizer input and configured to transmit second outbound information to the second mobile station on a second predetermined transmit frequency, said second transmitter further having two controllable transmitter frequency sources that are configured to alternately supply a second transmitter synthesizer signal to said second transmitter synthesizer input; and
      
      wherein said processor is coupled to said second transmitter and configured to encode said second outbound information to communicate with the second mobile station.
  - 5. The base station of claim 1 for further communicating with a second mobile station, said base station further comprising:
    - a second transmitter having a second transmitter synthesizer input and configured to transmit second outbound information to the mobile station on a second predetermined transmit frequency, said second transmitter further having two controllable transmitter frequency sources that are configured to alternately supply a transmitter synthesizer signal to said second transmitter synthesizer input;
      
      wherein said processor is coupled to said second transmitter and configured to encode said second outbound information to communicate with the second mobile station.
  - 6. The base station of claim 3, wherein:
    - said processor is configured to reprogram said second receiver when said first transmitter is broken.
  - 7. The base station of claim 5, wherein:
    - said processor is configured to reprogram said second transmitter when said first transmitter is broken.

8. A method of communicating over a cellular network between a mobile station and a base station having a processor, and a transmitter containing a first controllable transmitter frequency source and a second controllable transmitter frequency source, said method comprising the steps of:
- (a) receiving, via the receiver, an initialization signal from the mobile station;
  
  (b) computing a first transmit frequency from a predetermined timing information;
  
  (c) tuning the first transmitter frequency source to generate the first transmit frequency;
  
  (d) supplying the first transmit frequency to the transmitter;
  
  (e) modulating the first transmit frequency with a first transmit signal representing information, said modulating step producing a second transmit signal;
  
  (f) transmitting the second transmit signal, via the transmitter, to the mobile station;
  
  (g) computing a second transmit frequency from the predetermined timing information plus one;
  
  (h) tuning the second transmitter frequency source to generate the second transmit frequency;
  
  (i) supplying the second transmit frequency to the transmitter;
  
  (j) modulating the second transmit frequency with a third transmit signal representing information, said modulating step producing a fourth transmit signal;
  
  (k) transmitting the fourth transmit signal, via the transmitter, to the mobile station;
  
  (l) repeating steps (b) trough (k) with newly computed frequencies from the predetermined timing information.
- View Dependent Claims (9, 10, 11)
- - 9. The method of claim 8, wherein said predetermined timing information is the hyperframe number.
  - 10. The method of claim 8, wherein said base station further has a receiver containing a first controllable receiver frequency source and a second controllable receiver frequency source, said method further comprising the steps of:
    - (m) computing a first receive frequency from a predetermined timing information;
      
      (n) tuning the first receiver frequency source to generate the first receive frequency;
      
      (o) supplying the first receive frequency to the receiver;
      
      (p) receiving a first receive signal, via the receiver, from the mobile station;
      
      (q) demodulating the first receive signal with the first receive frequency, said demodulating step producing a second receive signal representing information;
      
      (r) computing a second receive frequency from the predetermined timing information plus one;
      
      (s) tuning the second receiver frequency source to generate the second receive frequency;
      
      (t) supplying the second receive frequency to the receiver;
      
      (u) receiving a third receive signal, via the receiver, from the mobile station;
      
      (v) demodulating the third receive signal with the second receive frequency, said demodulating step producing a fourth receive signal representing information;
      
      (w) repeating steps (m) through (v) with a newly computed first receive frequency and second receive frequency from the predetermined timing information.
  - 11. The method of claim 10, wherein said predetermined timing information is the hyperframe number.

12. A method of communicating over a cellular network between a mobile station and a base station having a processor, and a receiver containing a first controllable receiver frequency source and a second controllable receiver frequency source, said method comprising the steps of:
- (a) computing a first receive frequency from a predetermined timing information;
  
  (b) tuning the first receiver frequency source to generate the first receive frequency;
  
  (c) supplying the first receive frequency to the receiver;
  
  (d) receiving a first receive signal, via the receiver, from the mobile station;
  
  (e) demodulating the first receive signal with the first receive frequency, said demodulating step producing a second receive signal representing information;
  
  (f) computing a second receive frequency from the predetermined timing information plus one;
  
  (g) tuning the second receiver frequency source to generate the second receive frequency;
  
  (h) supplying the second receive frequency to the receiver;
  
  (i) receiving a third receive signal, via the receiver, from the mobile station;
  
  (j) demodulating the third receive signal with the second receive frequency, said demodulating step producing a fourth receive signal representing information;
  
  (k) repeating steps (a) through (j) with a newly computed first receive frequency and second receive frequency from the predetermined timing information.
- View Dependent Claims (13)
- - 13. The method of claim 12, wherein said predetermined timing information is the hyperframe number.

14. A method of communicating over a cellular network between two mobile stations and a base station having a processor and two frequency agile transmitters, where each transmitter contains a first controllable transmitter frequency source and a second controllable transmitter frequency source, said method comprising the steps of:
- tuning the first transmitter to transmit outbound information to the first mobile station;
  
  tuning the second transmitter to transmit outbound information to the second mobile station; and
  
  when said second transmitter fails, tuning the first transmitter to transmit outbound information to the second mobile station.
- View Dependent Claims (15)
- - 15. The method of claim 14, wherein said base station further has two frequency agile receivers, where each receiver contains a first controllable receiver frequency source and a second controllable receiver frequency source, said method further comprising the steps of:
    - tuning the first receiver to receive inbound information from the first mobile station;
      
      tuning the second receiver to receive inbound information from the second mobile station; and
      
      when said second receiver fails, tuning the first receiver to receive inbound information from the second mobile station.

16. A method of communicating over a cellular network between two mobile stations and a base station having a processor and two frequency agile receivers, where each receiver contains a first controllable receiver frequency source and a second controllable receiver frequency source, said method comprising the steps of:
- tuning the first receiver to receive inbound information from the first mobile station;
  
  tuning the second receiver to receive inbound information from the second mobile station; and
  
  when said second receiver fails, tuning the first receiver to receive inbound information from the second mobile station.

17. A base station for communicating over a cellular network with a first mobile station and a second mobile station, comprising:
- a first receiver having a receiver synthesizer input and configured to receive inbound information from the first mobile station on a first predetermined frequency, said receiver further having two controllable receiver frequency sources that are configured to alternately supply a receiver synthesizer signal to said receiver synthesizer input;
  
  a second receiver having a second receiver synthesizer input and configured to receive second inbound information from the second mobile station on a second predetermined frequency, said second receiver further having two controllable receiver frequency sources that are configured to alternately supply a receiver synthesizer signal to said second receiver synthesizer input;
  
  a first transmitter having a transmitter synthesizer input and configured to transmit outbound information to the mobile station on a third predetermined frequency, said transmitter further having two controllable transmitter frequency sources that are configured to alternately supply a transmitter synthesizer signal to said transmitter synthesizer input;
  
  a second transmitter having a second transmitter synthesizer input and configured to transmit second outbound information to the second mobile station on a fourth predetermined frequency, said second transmitter further having two controllable transmitter frequency sources that are configured to alternately supply a second transmitter synthesizer signal to said second transmitter synthesizer input; and
  
  a processor coupled to said first receiver, said second receiver, said first transmitter and said second transmitter and configured to decode said inbound information, to encode said outbound information, to store statistics regarding an inbound information error rate over said first predetermined frequency, and when said statistics indicate a high error rate, to modify said first predetermined frequency.
- View Dependent Claims (18, 19, 20, 21, 22, 23)
- - 18. The base station of claim 17, wherein:
    - said processor is further configured to store a frequency table representing the available frequencies, and to modify said frequency table to modify said first predetermined frequency.
  - 19. The base station of claim 17, wherein:
    - said processor is further configured to store statistics regarding an inbound information error rate over said second predetermined frequency, and when said statistics indicate a high error rate, to modify said second predetermined frequency.
  - 20. The base station of claim 19, wherein:
    - said processor is further configured to store a frequency table representing the available frequencies, and to modify said frequency table to modify said first predetermined frequency and said second predetermined frequency.
  - 21. The base station of claim 17, wherein:
    - said first receiver is further configured to scan available frequencies; and
      
      said processor is further configured to modify said first predetermined frequency and said second predetermined frequency based on a scan of said available frequencies.
  - 22. The base station of claim 17, further comprising:
    - a second receiver coupled to said processor and configured to receiver said second predetermined frequency and to provide information regarding said second predetermined frequency to said processor.
  - 23. The base station of claim 22, wherein:
    - said second receiver is configured to scan available frequencies and to provide said processor with information regarding the presence of noise on any available frequency.

24. A method of communicating over a cellular network between a mobile station and a base station having a receiver containing a first controllable receiver frequency source and a second controllable receiver frequency source, and a processor, said method comprising the steps of:
- receiving inbound information from the mobile station at a first time on a first predetermined frequency associated with the first receiver frequency source and at a second time on a second predetermined frequency associated with the second receiver frequency source;
  
  decoding said inbound information;
  
  error-correcting the inbound information;
  
  storing error statistics regarding the errors detected in said error-correcting step; and
  
  when the error statistics exceed a predetermined threshold, modifying the first predetermined frequency.
- View Dependent Claims (25)
- - 25. The method of claim 24, said base station further comprising a transmitter containing a first controllable transmitter frequency source and a second controllable transmitter frequency source, said method comprising the steps of:
    - encoding outbound information;
      
      transmitting the outbound information to the mobile station at a third time on a third predetermined frequency associated with the first transmitter frequency source and at a fourth time on a fourth predetermined frequency associated with the second transmitter frequency source;
      
      receiving second error statistics regarding errors detected in said transmitting step;
      
      storing the second error statistics; and
      
      when the second error statistics exceed a predetermined threshold, modifying the third predetermined frequency.

26. A method of communicating over a cellular network between a mobile station and a base station having a transmitter containing a first controllable transmitter frequency source and a second controllable transmitter frequency source, and a processor, said method comprising the steps of:
- encoding outbound information;
  
  transmitting the outbound information to the mobile station on a first predetermine frequency associated with the first transmitter frequency source and a second predetermined frequency associated with the second transmitter frequency source;
  
  receiving error statistics regarding errors detected in said transmitting step;
  
  storing the error statistics; and
  
  when the error statistics exceed a predetermined threshold, modifying the first predetermined frequency.

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Current Assignee
Tyco Electronics Services GmbH (TE Connectivity Ltd. (United Kingdom))
Original Assignee
Interwave Communications International SA (Alvarion Limited)
Inventors
Msutta, Gurbux S., Sage, Gerald F.
Primary Examiner(s)
Chin, Wellington
Assistant Examiner(s)
LUTHER, WILLIAM A

Application Number

US08/434,597
Time in Patent Office

1,167 Days
Field of Search

375/202, 375/200, 375/344, 375/356, 375/375, 375/219, 375/376, 455/33.1, 455/49.1, 455/33.4, 455/50.1, 455/51.1, 455/53.1, 455/54.1, 455/57.1, 455/87, 455/422, 380/33, 380/21, 380/48, 380/49, 395/200.19, 364/232.2, 364/232.9, 379/58, 379/59, 379/62, 340/825.14, 340/825.2, 340/825.5, 340/825.73, 340/825.74, 370/297, 370/330
US Class Current

375/134
CPC Class Codes

H04B 1/7156   Arrangements for sequence s...

H04B 2001/7154   with means for preventing i...

H04B 2001/71566   Tracking

Frequency agile transceiver with multiple frequency synthesizers per transceiver

First Claim

9 Assignments

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Abstract

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26 Claims

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Frequency agile transceiver with multiple frequency synthesizers per transceiver

First Claim

9 Assignments

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Abstract

72 Citations

26 Claims

Specification

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