Uplink power control mechanism for maintaining constant output power from satellite transponder

US 4,941,199 A
Filed: 04/06/1989
Issued: 07/10/1990
Est. Priority Date: 04/06/1989
Status: Expired due to Term

First Claim

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1. For use in a satellite communications network wherein signals transmitted over an uplink communications channel from a transmitting terminal to a satellite amplifier device are amplified by said satellite amplifier device and conveyed therefrom over an outlink channel to a receiver terminal, a method of controlling the output of said transmitting terminal so as to maintain the strength of signals output by said satellite amplifier device effectively constant irrespective of variations in atmospheric conditions in the uplink signal transmission path between the transmitting terminal and the satellite comprising the steps of:

(a) transmitting first signals over said uplink communications channel to said satellite to be amplified by said satellite amplifier device and conveyed therefrom over said outlink channel to said receiver terminal and over a downlink channel to a receiver device located at said transmitter terminal, and generating second signals representative of the strength of the transmitted first signals;

(b) monitoring, at said transmitter terminal, first signals that have been amplified by said satellite amplifier device and conveyed therefrom over said downlink channel, and producing therefrom third signals representative of the signal-to-noise ratio in the monitored signals;

(c) in response to said second and third signals, generating fourth signals representative of the attenuation of said first signals resulting from variations in conditions in the uplink signal transmission path to said satellite; and

(d) adjusting the strength of said first signals as transmitted by said transmitter terminal in accordance with said fourth signals, so as to compensate for the attenuation thereof resulting from conditions in said uplink signal transmission path and thereby maintain the strength of signals output by said satellite amplifier device effectively constant.

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Abstract

Compensation for rain fades in a VSAT communications network is obtained by a uplink power control mechanism incorporated in a master station, which maintains the power output level of the satellite transponder constant without incorporating excessive static margins into the link power budget. A variable attenuator, which controls the output power of the master station'"'"'s high power amplifier is initially set at a prescribed level which will produce the intended satellite amplifier EIRP for a `clear sky` condition. The master station monitors the output of the satellite amplifier and derives a measure of the signal-to-noise ratio of downlinked signals. Knowing the variable attenuator setting and the signal-to-noise ratio of the downlinked signals, the magnitude of attenuation of outlink carrier frequency signals transmitted from the master station to the satellite is determined. In the event of a rain fade, the setting of the variable attenuator is adjusted by an amount that compensates for the fade and thereby causes outlink carrier frequency signals conveyed by the satellite amplifier device to remain effectively constant. An estimate of the error in the attenuator setting is preferably derived in accordance with the ratio of the difference between the squared (I) and (Q) channel values ((S+N)² -N²) to the square of the quadrature channel-derived noise value N² of a Costas loop in the master station'"'"'s receiver.

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20 Claims

1. For use in a satellite communications network wherein signals transmitted over an uplink communications channel from a transmitting terminal to a satellite amplifier device are amplified by said satellite amplifier device and conveyed therefrom over an outlink channel to a receiver terminal, a method of controlling the output of said transmitting terminal so as to maintain the strength of signals output by said satellite amplifier device effectively constant irrespective of variations in atmospheric conditions in the uplink signal transmission path between the transmitting terminal and the satellite comprising the steps of:
- (a) transmitting first signals over said uplink communications channel to said satellite to be amplified by said satellite amplifier device and conveyed therefrom over said outlink channel to said receiver terminal and over a downlink channel to a receiver device located at said transmitter terminal, and generating second signals representative of the strength of the transmitted first signals;
  
  (b) monitoring, at said transmitter terminal, first signals that have been amplified by said satellite amplifier device and conveyed therefrom over said downlink channel, and producing therefrom third signals representative of the signal-to-noise ratio in the monitored signals;
  
  (c) in response to said second and third signals, generating fourth signals representative of the attenuation of said first signals resulting from variations in conditions in the uplink signal transmission path to said satellite; and
  
  (d) adjusting the strength of said first signals as transmitted by said transmitter terminal in accordance with said fourth signals, so as to compensate for the attenuation thereof resulting from conditions in said uplink signal transmission path and thereby maintain the strength of signals output by said satellite amplifier device effectively constant.

2. For use in a satellite communications network wherein data to be transmitted from a first station to a second station is transmitted via an outlink carrier frequency from said first station to a satellite amplifier device, amplified and conveyed therefrom to a second station, a method of controlling the operation of a transmitter at said first station so as to maintain the strength of data-modulated outlink carrier frequency signals conveyed from the output of said satellite amplifier device effectively constant irrespective of a variation in atmospheric conditions between said first station and the satellite comprising the steps of:
- (a) setting the operation of said transmitter such that the strength of outlink carrier frequency signals conveyed from said satellite amplifier device is at a prescribed signal strength;
  
  (b) monitoring, at a receiver provided at said first station, outlink carrier frequency signals downlinked from said satellite amplifier device to said first station and deriving therefrom a measure of the signal-to-noise ratio of said downlinked signals;
  
  (c) determining a measure of attenuation of outlink carrier frequency signals transmitted from said first station to said satellite in accordance with the measure of the signal-to-noise ratio measure derived on step (b) and the transmitter operation setting of step (a); and
  
  (d) adjusting the strength of outlink carrier frequency signals transmitted by said transmitter by an amount that compensates for the measure of attenuation determined in step (c) and thereby causes outlink carrier frequency signals conveyed by said satellite amplifier device to remain effectively constant.
- View Dependent Claims (3, 4, 5, 6, 7, 8)
- - 3. A method according to claim 2, wherein said transmitter includes an adjustable attenuator through which the output signal strength of signals transmitted from said first station over said outlink carrier frequency to said satellite is controlled, and step (a) comprises, for a clear-sky condition, adjusting said attenuator to a first setting which causes outlink carrier frequency signals that are transmitted from said first station to said satellite to be conveyed from the output of said satellite amplifier device at a prescribed clear-sky signal strength.
  - 4. A method according to claim 2, wherein said variation in atmospheric conditions between said first station and said satellite corresponds to the presence of a rain fade, and wherein step (b) includes the step of deriving said measure of the signal-to-noise ratio of signals downlinked to the receiver at said first station and corrected in accordance with the influence upon the figure of merit of said receiver of a change in sky temperature, resulting from said rain fade.
  - 5. A method according to claim 4, wherein said transmitter includes an adjustable attenuator through which the output signal strength of signals transmitted from said first station over said outlink carrier frequency to said satellite is controlled, and step (a) comprises, for a clear-sky condition, adjusting said attenuator to a first setting which causes outlink carrier frequency signals that are transmitted from said first station to said satellite to be conveyed from the output of said satellite amplifier device at a prescribed clear-sky signal strength.
  - 6. A method according to claim 5, wherein step (c) comprises determining a measure of attenuation of outlink carrier frequency signals transmitted from said first station to said satellite in accordance with the current setting of said attenuator and said first setting of said attenuator.
  - 7. A method according to claim 4, wherein step (d) comprises adjusting said attenuator in accordance with the corrected measure of signal-to-noise ratio and said first setting of said attenuator.
  - 8. A method according to claim 4, wherein step (b) comprises deriving a measure of the signal.to.noise ratio of said downlinked signals in accordance with the ratio of the square of the sum of signal plus noise to the square of the noise in down linked signals.

9. A method of operating a satellite communications network having a first station from which outlink signals destined for a second station are transmitted over an uplink communications channel to a satellite amplifier device, amplified thereby and conveyed over a downlink channel to said second station, comprising the step of:
- (a) controlling the operation of the outlink carrier frequency signal transmitter at said first station so as to cause the strength of outlink carrier frequency signals conveyed from the output of said satellite amplifier device to be effectively constant irrespective of the presence of a rain fade between said first station and the satellite by;
  
  (a1) setting the operation of said transmitter such that the strength of outlink carrier frequency signals conveyed from said satellite amplifier device is at a prescribed signal strength;
  
  (a2) monitoring, at a receiver provided at said first station, outlink carrier frequency signals downlinked from said satellite amplifier device to said first station and deriving therefrom a measure of the signal-to-noise ratio of said downlinked signals;
  
  (a3) determining a measure of attenuation of outlink carrier frequency signals transmitted from said first station to said satellite in accordance with the measure of the signal-to-noise ratio derived in step (a2) and the transmitter operation setting of step (a1); and
  
  (a4) adjusting the strength of outlink carrier frequency signals transmitted by said transmitter by an amount that compensates for the measure of attenuation determined in step (a3) and thereby causes outlink carrier frequency signals conveyed by said satellite amplifier device to remain effectively constant.
- View Dependent Claims (10)
- - 10. A method according to claim 9, further including the step of (b) compensating for the presence of a rain fade on the return link channel between said satellite and said second station by:
    - (b1) measuring, at said second station, the strength of outlink signals conveyed from said satellite amplifier device to a receiver at said second station during a clear sky condition between said satellite and said second station; and
      
      (b2) monitoring the strength of outlink signals received at said second station and, in response to the strength of monitored signals undergoing a reduction from the clear sky condition measured in step (b1), increasing the strength of return link signals transmitted from said second station.

11. For use in a satellite communications network wherein signals transmitted over an uplink communications channel from a transmitting terminal to a satellite amplifier device are amplified by said satellite amplifier device and conveyed therefrom over an outlink channel to a receiver terminal, an uplink power control mechanism for controlling the output of said transmitting terminal so as to maintain the strength of signals output by said satellite amplifier device effectively constant irrespective of variations in atmospheric conditions between the transmitting terminal and the satellite comprising:
- first means, coupled to a transmitter through which first signals are transmitted over said uplink communications channel to said satellite to be amplified by said satellite amplifier device and conveyed therefrom over said outlink channel to said receiver terminal and over a downlink channel to a receiver device located at said transmitter terminal, for generating second signals representative of the strength of the transmitted first signals;
  
  second means, coupled to said receiver device, for monitoring first signals amplified by said satellite amplifier device and conveyed therefrom over said downlink channel and producing therefrom third signals, representative of the signal-to-noise ratio of the monitored signals;
  
  third means, coupled to said first and second means, and responsive to said second and third signals, for generating fourth signals representative of the attenuation of transmitted first signals resulting from atmospheric conditions in said uplink channel from said transmitter terminal to said satellite; and
  
  fourth means, coupled to said third means, for adjusting the strength of said first signals as transmitted by said transmitter terminal in accordance with said fourth signals, so as to compensate for the attenuation thereof resulting from atmospheric conditions in said uplink channel and thereby maintain the strength of signals output by said satellite amplifier device effectively constant.

12. For use in a satellite communications network wherein user data to be transmitted from a first station to a second station is transmitted via an outlink carrier frequency from said first station to a satellite amplifier device, amplified and conveyed therefrom to a second station, an arrangement for controlling the operation of a transmitter at said first station so as to maintain the strength of the user data-modulated outlink carrier frequency conveyed from the output of said satellite amplifier device effectively constant irrespective of a variation in atmospheric conditions between said first station and the satellite comprising:
- first means for setting the operation of said transmitter such that the strength of outlink carrier frequency signals conveyed from said satellite amplifier device is at a prescribed signal strength;
  
  second means, coupled to a receiver at said first station, for monitoring outlink carrier frequency signals downlinked from said satellite amplifier device to said first station and deriving therefrom a measure of the signal-to-noise ratio of said downlinked signals;
  
  third means, coupled to said first and second means, for deriving a measure of the attenuation of outlink carrier frequency signals transmitted from said first station to said satellite in accordance with the signal.to.noise ratio measure derived by said second means and the transmitter operation setting of said first means; and
  
  fourth means, coupled to said third means, for adjusting the strength of outlink carrier frequency signals transmitted by said transmitter by an amount that compensates for the measure of attenuation derived by said third means and thereby causes outlink carrier frequency signals conveyed by said satellite amplifier device to remain effectively constant.
- View Dependent Claims (13, 14, 15, 16, 17, 18)
- - 13. An arrangement according to claim 12, wherein said transmitter includes an adjustable attenuator through which the output signal strength of signals transmitted from said first station over said outlink carrier frequency to said satellite is controlled, and said first means includes means, for a clear-sky condition, for adjusting said attenuator to a first setting which causes outlink carrier frequency signals that are transmitted from said first station to said satellite to be conveyed from the output of said satellite amplifier device at a prescribed clear-sky signal strength.
  - 14. An arrangement according to claim 12, wherein said variation in atmospheric conditions between said first station and said satellite corresponds to the presence of a rain fade, and wherein said second means includes means for deriving said measure of the signal-to-noise ratio of signals downlinked to the receiver at said first station and corrected in accordance with the influence upon the figure of merit of said receiver of a change in sky temperature, resulting from said rain fade.
  - 15. An arrangement according to claim 14, wherein said transmitter includes an adjustable attenuator through which the output signal strength of signals transmitted from said first station over said outlink carrier frequency to said satellite is controlled, and said first means includes means, for a clear-sky condition, for adjusting said attenuator to a first setting which causes outlink carrier frequency signals that are transmitted from said first station to said satellite to be conveyed from the output of said satellite amplifier device at a prescribed clear-sky signal strength.
  - 16. An arrangement according to claim 15, wherein said third means includes means for deriving a measure of attenuation of outlink carrier frequency signals transmitted from said first station to said satellite in accordance with the current setting of said attenuator and said first setting of said attenuator.
  - 17. An arrangement according to claim 14, wherein said fourth means includes means for adjusting said attenuator in accordance with the corrected measure of signal-to-noise ratio and said first setting of said attenuator.
  - 18. An arrangement to claim 14, wherein said second means includes means for deriving a measure of the signal-to-noise ratio of said downlinked signals in accordance with the ratio of the square of the sum of signal plus noise to the square of the noise in down linked signals.

19. For use with a satellite communications network having a first station from which outlink signals destined for a second station are transmitted over an uplink communications channel to a satellite amplifier device, amplified thereby and conveyed over a downlink channel to said second station, a control system apparatus for controlling the operation said system to compensate for the presence of a rain fade comprising:
- first means, coupled with a transmitter by way of which said outlink signals are transmitted, for setting the operation of said transmitter such that the strength of outlink carrier frequency signals conveyed from said satellite amplifier device is at a prescribed signal strength;
  
  second means for monitoring, at a receiver provided at said first station, outlink carrier frequency signals downlinked from said satellite amplifier device to said first station and deriving therefrom a measure of the signal-to-noise ratio of said downlinked signals;
  
  third means, coupled to said first and second means, for deriving a measure of attenuation of outlink carrier frequency signals transmitted from said first station to said satellite in accordance with the measure of the signal-to-noise ratio derived by said second means and the transmitter operation setting of said first means; and
  
  fourth means, coupled to said third means, for adjusting the strength of outlink carrier frequency signals transmitted by said transmitter by an amount that compensates for the measure of attenuation derived by said third means and thereby causes outlink carrier frequency signals conveyed by said satellite amplifier device to remain effectively constant.
- View Dependent Claims (20)
- - 20. A control system according to claim 19, further including fifth means, at said second station, for compensating for the presence of a rain fade in the return link channel between said second station and said satellite, said fifth means including means for measuring the strength of outlink signals conveyed from said satellite amplifier device to a receiver at said second station during a clear sky condition between said satellite and said second station and means for monitoring the strength of outlink signals received at said second station and, in response to the strength of monitored signals undergoing a reduction from the clear sky condition measured by said measuring means, for increasing the strength of return link signals transmitted from said second station.

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Current Assignee
ViaSat Incorporated
Original Assignee
Scientific-Atlanta (Cisco Systems, Inc.)
Inventors
Saam, Thomas J.
Primary Examiner(s)
Griffin, Robert L.
Assistant Examiner(s)
KUNTZ, CURTIS A

Application Number

US07/334,146
Time in Patent Office

460 Days
Field of Search

455/69, 455/9, 455/10, 455/12, 455/52, 455/70, 455/63, 370/104, 370/69.1, 370/75
US Class Current

455/10
CPC Class Codes

H04B 7/18543   for adaptation of transmiss...

H04L 1/206   for modulated signals

H04L 27/227   using coherent demodulation

Uplink power control mechanism for maintaining constant output power from satellite transponder

First Claim

2 Assignments

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Abstract

77 Citations

20 Claims

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Uplink power control mechanism for maintaining constant output power from satellite transponder

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

77 Citations

20 Claims

Specification

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Solutions

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