Spread spectrum multiple access communication system using satellite or terrestrial repeaters

Claims

What we claim is:

1. A multiple access, spread spectrum communication system, comprising:

means for communicating information signals between at least two of a plurality of system users using code-division-spread-spectrum communication signals;

isolation means, coupled to said means for communicating, for unequally weighting signal power of said code-division-spread-spectrum communication signals, wherein said isolation means comprises:

activity detection means for measuring signal activity levels for said information signals relative to a no activity level over a predetermined sampling time and for providing an activity signal corresponding to measured activity; and

power control means coupled to said means for communicating for adjusting a transmission power duty cycle for said code-division-spread-spectrum communication signals in response to changes in said activity signal.

2. A multiple access, spread spectrum communication system, comprising:

means for communicating information signals between at least two of a plurality of system users using code-division-spread-spectrum communication signals;

isolation means, coupled to said means for communication, for unequally weighting signal power of said code-division-spread-spectrum communication signals; and

wherein said means for communicating further comprises:

chip generation means for generating a plurality of quasi-orthogonal spreading functions;

code selection means for assigning one of said spreading functions to a user;

a plurality of mobile user terminals capable of transmitting and receiving said code-division-spread-spectrum communication signals, each of said user terminals comprising:

transmission means for generating a code-division-spread-spectrum communication signal in response to an input information signal according to an assigned spreading function;

receiver means for generating an output information signal by processing a received code-division-spread-spectrum communication signal according to said assigned spreading function; and

at least one omni-directional antenna coupled to said transmission means and said receiver means; and

at least one repeater means for receiving code-division-spread-spectrum communication signals from said plurality of user terminals and for translating said code-division-spread-spectrum communication signals to form suitable for transfer to an intended recipient user.

3. The communication system of claim 2 wherein said repeater means further comprises means for transmitting a predetermined pilot chip sequence to said users.

4. The communication system of claim 2, wherein said at least one repeater means further comprises a phased array antenna structure capable of generating simultaneous multiple steerable beams.

5. The communication system of claim 2, wherein said at least one repeater means comprises at least one terrestrially based repeater means centrally located within a geographical region.

6. The communication system of claim 2, wherein said at least one repeater means comprises at least one satellite based repeater means.

7. The communication system of claim 2 further comprising at least one transceiver hub for receiving communication signals from said repeater means and transmitting communication signals to said repeater means.

8. The communication system of claim 2, wherein said at least one repeater means comprises:

at least one terrestrially based repeater for receiving, translating and re-transmitting said code-division-spread-spectrum communication signals;

at least one satellite based repeater for receiving, translating, and retransmitting said code-division-spread-spectrum communication signals; and

said user terminals are configured to transmit and receive code-division-spread-spectrum communication signals through at least one repeater means and each repeater means configured to receive and transmit code-division-spread-spectrum communication signals between to said user terminals.

9. The communication system of claim 8 further comprising polarization control means coupled to said omni-directional antenna for adjusting said antenna so as to select a predetermined polarization mode from a plurality of modes.

10. The communication system of claim 2 wherein said receiver further comprises a demodulator, comprising:

input means for sampling substantially the entire bandwidth of said code-division-spread-spectrum signals;

phase division means connected in series with said input means for dividing said spread spectrum signal into an analog in-phase signal and an analog quadrature signal;

converter means connected to said phase division means for converting said analog in-phase and analog quadrature signals to digital in-phase and quadrature signals at a variable rate.

11. A multiple access, spread spectrum communication system, comprising:

means for communicating information signals between at least two system users using code-division-spread-spectrum communication signals, said means for communicating comprising:

chip generation means for generating a plurality of quasi-orthogonal spreading functions;

code selection means for assigning at least one of said spreading functions to a system user;

a plurality of mobile user terminals capable of transmitting and receiving said code-division-spread-spectrum communication signals, each of said user terminals comprising:

transmission means for generating a code-division-spread-spectrum communication in response to an input information signal according to said assigned spreading function; and

receiver means for generating an output information signal by processing a code-division-spread-spectrum communication signal according to said assigned spreading function; said receiver having a demodular, comprising:

input means for receiving code-division-spread-spectrum communication signals;

a variable frequency source generating a local reference signal of predetermined frequency;

a radio frequency mixer connected to said input means and said variable frequency source for the code-division-spread-spectrum communication signals with the local reference signal to provide an intermediate spread spectrum signal;

filter means connected in series with said radio frequency mixer for filtering undesirable frequency components from said intermediate spread spectrum signal;

phase division means connected in series with said filter means for dividing said spread spectrum signal into an analog in-phase signal and an analog quadrature signal;

converter means connected to said phase division means for converting said analog incident and quadrature signals to digital incident and quadrature signals at a variable rate;

combiner means connected to an output of said converter means for juxtaposing said digital in-phase and quadrature signals onto a single data line for transfer to other components within said demodulator in serial fashion;

pilot chip reference means for generating a local bit sequence corresponding to a predetermined pilot chip sequence transmitted contiguous with communication signals received by said demodulator, said local bit sequence being generated with a predetermined period;

carrier tracking means connected to said combiner means and said pilot reference means for comparing said local pilot chip sequence to received signals in a timed relationship to determine the timing of said code-division-spread-spectrum communication signals with respect to said local pilot chip sequence and for adjusting the frequency of said variable frequency source;

chip synchronization means connected to said combiner means and said pilot reference means for comparing said local pilot chip sequency to received signals in a plurality of timed relationships to determine the timing of said code-division-spread-spectrum communication signals with respect to said local pilot chip sequence and for adjusting the rate for said converter means;

unit chip means for generating a bit sequence corresponding to said assigned spreading function;

despreading means connected to said combiner and said unit chip means for generating despread-spectrum in-phase and quadrature information signals;

output means connected to said despreading means for combining said despread-spectrum quadrature and in-phase signals into an output information signal;

at least one omni-directional antenna; and

at least one repeater means for receiving code-division-spread-spectrum communication signals from said plurality of user terminals and translating said code-division-spread-spectrum communication signals to a form for transfer to an intended recipient user.

12. The demodulator of claim 11 wherein said carrier tracking means and said chip-time tracking means further comprise:

first correlation means connected to said combiner means and said pilot reference means for comparing said in-phase and quadrature signals with said pilot chip sequence and providing an output representative of a first correlation pattern;

second correlation means connected to said combiner means and said pilot reference means for delaying said in-phase and quadrature signals an amount of time on the order of said pilot chip period and comparing said signals with said pilot chip sequence and providing an output representative of a second correlation pattern;

third correlation means connected to said combiner means and said pilot reference means for delaying said in-phase and quadrature signals an amount of time on the order of half said pilot chip period and comparing said signals with said pilot chip sequence and providing an output representative of a third correlation pattern;

chip synchronization means connected to said first and third correlation means for adjusting the rate of said converter means in response to the output provided by said first correlation and third correlation means; and

a carrier tracking loop connected to said second correlation means for adjusting said variable frequency source in response to the output provided by said second correlation means.

13. The demodulator of claim 11 further comprising a variable gain control disposed between and connected in series with said input means and said radio frequency mixer; and automatic gain control means connected to said combiner means for altering the gain said variable gain control in response to an absolute magnitude of said in-phase and quadrature signals.

14. The demodulator of claim 11 wherein said converter means comprises first analog conversion means for converting said in-phase signal to a digital in-phase signal and second analog conversion means for converting said quadrature signal to a digital quadrature signal.

15. The demodulator of claim 11 wherein said first correlation means comprises:

first means for multi-phase mixing said digital in-phase and quadrature signals with said pilot chip sequence;

first coherent summation means coupled to said means for multi-phase mixing, for generating the sum of said in-phase and said quadrature signals coherently over a predetermined period of time; and

squared summation means for generating the sum of the square of said in-phase and said quadrature signals over a predetermined period of time.

16. The demodulator of claim 11 wherein said second correlation means comprises:

second means for multi-phase mixing said incidence and quadrature signals with said pilot chip sequence;

first delay means positioned between said combiner means and said second means for multi-phase mixing; and

second coherent summation means coupled to said second means for multi-phase mixing, for generating the sum of said in-phase and said quadrature signals coherently over a predetermined period of time.

17. The demodulator of claim 11 wherein said third correlation means comprises:

third means for multi-phase mixing said incidence and quadrature signals with said pilot chip sequence;

second delay means positioned between said first delay means and said third means for multi-phase mixing;

third coherent summation means coupled to said third means for multi-phase mixing, for generating the sum of said in-phase and said quadrature signals coherently over a predetermined period of time; and

second squared summation means for generating the sum of the square of said in-phase and said quadrature signals over a predetermined period of time.

18. A multiple access spread spectrum communication system, comprising:

means for communicating information signals between at least two system users using code-division-spread-spectrum communication signals, said means for communicating comprising:

chip generation means for generating a plurality of quasi-orthogonal spreading functions;

code selection means for assigning at least one of said spreading function to a system user;

a plurality of mobile user terminals capable of transmitting and receiving said code-division-spread-spectrum communication signals, each of said user terminals comprising:

transmission means for generating a code-division-spread-spectrum communication in response to an input information signal according to said assigned spreading function;

activity detection means couple to said transmission means for sensing signal activity levels in said input information signal and decreasing a user terminal transmission power duty cycle in response to a decrease in sensed activity below a predetermined threshold level for a predetermined sampling period; and

receiver means for generating an output information signal by processing a code-division-spread-spectrum communication signal according to said assigned spreading function;

at least one omni-directional antenna; and

at least one repeater means for receiving code-division-spread-spectrum communication signals from said plurality of user terminals and translating said code-division-spread-spectrum communication signals to a form for transfer to an intended recipient user.

19. A multiple access, spread spectrum communication system, comprising:

means for communicating information signals between at least two system user's using code-division-spread-spectrum communication signals, said means for communicating comprising:

chip generation means for generating a plurality of quasi-orthogonal spreading functions;

code selection means for assigning at least one of said spreading functions to a system user;

a plurality of mobile user terminals capable of transmitting and receiving said code-division-spread-spectrum communication signals, each of said user terminals comprising:

transmission means for generating a code-division-spread-spectrum communication in response to an input information signal according to said assigned spreading function;

receiver means for generating an output information signal by processing a code-division-spread-spectrum communication signal according to said assigned spreading function;

at least one omni-directional antenna;

at least one repeater means for receiving code-division-spread-spectrum communication signals from said plurality of user terminals and translating said code-division-spread-spectrum communication signals to a form for transfer to an intended recipient user; and

activity detection means coupled to said repeater means for sensing signal activity levels in said code-division-spread-spectrum communication signals and decreasing repeater transmission power duty cycle in response to a decrease in sensed activity below a predetermined threshold level for a predetermined sampling period.

20. A multiple access, spread spectrum communication system, comprising:

means for communicating information signals between at least two system users, using code-division-spread-spectrum communication signals, said means for communicating comprising:

chip generation means for generating a plurality of quasi-orthogonal spreading functions;

code selection means for assigning at least one of said spreading functions to a system user;

a plurality of mobile user terminals capable of transmitting and receiving said code-division-spread-spectrum communication signals, each of said user terminals comprising:

transmission means for generating a code-division-spread-spectrum communication in response to an input information signal according to said assigned spreading function;

receiver means for generating an output information signal by processing a code-division-spread-spectrum communication signal according to said assigned spreading function; and

link power control means connected to said receiver means for sensing a received power level present in a received first code-division-spread-spectrum communication signals and for adjusting power applied to an antenna for transmitting a second code-division-spread-spectrum communication signals in response to the sensed power level;

at least one omni-directional antenna; and

at least one repeater means for receiving code-division-spread-spectrum communication signals from said plurality of user terminals and translating said code-division-spread-spectrum communication signals to a form for transfer to an intended recipient user.

21. A spread spectrum multiple access communication system having high system user capacity, comprising:

means for communicating system user addressable information signals between at least two of a plurality of system users using address corresponding code-division-spread-spectrum communication signals, said means for communicating generating mutual interference in communications between said at least two system users by contemporaneously communicating code-division-spread-spectrum communication signals between other system users, and said means for communicating having a processing gain for reducing said mutual interference; and

isolation means, coupled to said means for communicating, for providing an increase in system user realized average signal power for said system user address corresponding code-division-spread-spectrum communication signals in communications between said at least two system users relative to mutual interference signal power of said contemporaneous communications between said other system users.

22. The communication system of claim 21 wherein said isolation means comprises an antenna system having an antenna beam pattern forming multiple directive beams.

23. The communication system of claim 21 wherein said isolation means comprises an antenna system configured to obtain polarization mode selection between a plurality of polarization modes.

24. The communication system of claim 21 wherein said isolation means comprises:

activity detection means for measuring signal activity levels for said information signals relative to a no activity level over a predetermined sampling time and for providing an activity signal corresponding to measured activity; and

power control means coupled to said means for communicating for adjusting a transmission power duty cycle for said code-division-spread-spectrum communication signals in response to changes in said activity signal.

25. The communication system of claim 21 wherein said isolation means comprises interference pattern means for generating interference patterns of maximum signal to noise ratio at a receive location in communicated code-division-spread-spectrum communication signals, said interference pattern means having transmission means for transmitting a same communication signal via at least two different communication paths to said receive location and control means coupled to said transmission means for adjusting at least one of signal phase and transmission start times in said transmissions of said same communication signal transmitted via said different communication paths.

26. The communication system of claim 21 wherein said means for communicating further communicates a same communication signal via at least two different communication paths and said isolation means comprises signal combination means for coherently combining said same communication signal as received at a receive location from said different communication paths, said signal combination means having reception means for receiving each of said same communication signals as transmitted via each of said different communication paths and control means coupled to said reception means for adjusting at least one of signal phase and timing in receptions of said same communication signal via said different communication paths.

27. The communication system of claim 21 wherein said means for communicating comprises:

a plurality of terrestrially based repeater means for transmitting said code-division-spread spectrum communication signals;

a plurality of transceiver means each coupled to a respective one of certain system users for receiving said code-division-spread-spectrum communication signals and for transmitting system user addressed code-division-spread-spectrum communication signals;

said plurality of repeater means further for receiving transceiver means transmitted code-division-spread-spectrum communication signals; and

wherein said isolation means comprises the placement of each repeater means at a predetermined position with respect to each other repeater means, each repeater means in communicating with at least one of said certain system users within a predetermined respective geographic region using said code-division-spread-spectrum communication signals with mutual interference signal power from communications in adjacent geographic regions attenuated as a function of distance therefrom.

28. The communication system of claim 21 wherein said means for communicating further comprises:

link control means for detecting a minimum power level required to maintain code-division-spread-spectrum communication signals in a user communication link above a predetermined incident power level and for providing a link control signal corresponding to said minimum power level;

power control means connected to said communication means and said link control means for adjusting a transmission power level for said code-division-spread-spectrum communication signals in response to said link control signal.

29. The communication system of claim 21 wherein said means for communicating further comprises:

chip generation means for generating a plurality of quasi-orthogonal spreading functions;

code selection means for assigning one of said spreading functions to a user;

a plurality of mobile user terminals capable of transmitting and receiving said code-division-spread-spectrum communication signals, each of said user terminals comprising:

transmission means for generating, according to an assigned spreading function, a code-division-spread-spectrum communication signal in response to an input information signal;

receiver means for generating an output information signal by processing a received code-division-spread-spectrum communication signal according to said assigned spreading function; and

at least one omni-directional antenna for coupling to said transmission means and said receiver means; and

at least one repeater means for receiving code-division-spread-spectrum communication signals from said plurality of user terminals and for translating said received code-division-spread-spectrum communication signals to a form suitable for transfer to an intended recipient user.

30. The communication system of claim 21 wherein said code-division-spread-spectrum signals are transferred over one or more communication channels and said isolation means provides isolation between system user addressed signals in communications between said at least two system users and mutual interference signals in communications between said other system users in the range of about 1 dB to 15 dB.

31. The communication system of claim 21 wherein said means for communicating is configured for transmitting information signals from at least one central communication stations to at least one remote system users.

32. The communication system of claim 21 wherein said means for communicating is configured for transmitting information signals from at least one remote system users to at least one central communication stations.

33. In a spread spectrum multiple access communication system in which system users communicate user addressable information signals using address corresponding code-division-spread-spectrum communication signals wherein with respect to communications between at least two system users other system users generate mutual interference by contemporaneously communicating code-division-spread-spectrum communication signals with said system having a processing gain for reducing mutual interference, in said communication system a method for providing high system user capacity by further reducing mutual interference in communications between said at least two system users comprising the steps of:

providing a plurality of system user addressable narrow band information signals;

converting said plurality of system user addressable narrow band information signals into a corresponding plurality of system user address corresponding wide band code-division-spread-spectrum communication signals;

transmitting said plurality of code-division-spread-spectrum communication signals between system users;

receiving, at each respective system user, system user address corresponding code-division-spread-spectrum communication signals and other respective system user addressed code-division-spread-spectrum communication signals as mutual interference;

providing for each respective system user an increase in system user realized average signal power for said system user address corresponding code-division-spread-spectrum communication signals with respect to mutual interference signal power of said other system user address corresponding code-division-spread-spectrum communication signals; and

converting, at each respective system user, received address corresponding code-division-spread-spectrum communication signals into corresponding user addressable information signals.

34. The method of claim 33 wherein said step of providing an increase in system user realized average signal power comprises the steps of:

providing an antenna system having an antenna beam pattern forming multiple directive beams with each beam corresponding to certain system users; and

radiating each system user address corresponding code-division-spread-spectrum communication signals on each of said beams corresponding to each system user to which said radiated system user address corresponding communication signal corresponds.

35. The method of claim 33 wherein said step of providing an increase in system user realized average signal power comprises the steps of:

providing an antenna system having an antenna beam pattern forming multiple directive beams with each beam corresponding to certain system users; and

collecting upon each beam code-division-spread-spectrum communication signals from said corresponding system users which correspond to each respective beam.

36. The method of claim 33 wherein said step of providing an increase in system user realized average signal power comprises the step of providing each system user with a polarization mode selectable antenna set to receive transmitted code-division-spread-spectrum communication signals according to a predetermined one of a plurality of polarization modes where address corresponding code-division-spread-spectrum communication signals are transmitted according to a polarization mode to which said antenna system of each address corresponding system user is set to receive.

37. The method of claim 33 wherein said step of providing an increase in system user realized average signal power comprises the steps of:

measuring signal activity levels for said information signals relative to a no activity level over a predetermined sampling time;

providing an activity signal corresponding to said measured activity levels; and

adjusting a transmission power duty cycle for said code-division-spread-spectrum communication signals in response to changes in said activity signal.

38. The method of claim 33 wherein said step of providing an increase in system user realized average signal power comprises the steps of:

transmitting, in said step of transmitting, a same system user address corresponding code-division-spread-spectrum communication signal via at least two different communication paths to an address corresponding system user located at a receive location; and

adjusting in said transmission of said same communication signal one of signal phase and signal transmission delay time as transmitted upon said different communication paths, wherein an interference pattern occurs having a maximum signal to noise ratio in said transmitted same communication signals at said receive location.

39. The method of claim 33 wherein said step of providing an increase in system user realized average signal power comprises the steps of:

receiving at a system user located at a receive location a same system user address corresponding code-division-spread-spectrum communication signal as transmitted upon at least two different communication paths in said step of transmitting; and

coherently combining said same communication signal as received upon said different communication paths by adjusting at least one of signal phase and signal reception delay time of said same communication signal as received upon said different communication paths.

40. The method of claim 33 wherein said step of transmitting comprises the steps of:

providing a plurality of terrestrially based repeaters each capable of transmitting said code-division-spread-spectrum communication signals;

providing for certain system users a transceiver capable of transmitting and receiving said code-division-spread-spectrum communication signals; and

wherein said step of providing an increase in system user realized average signal power comprises the step of placing each repeater at a predetermined position with respect to other repeater wherein each repeater communicates with at least one of said certain system users within a predetermined respective geographic region using said code-division-spread-spectrum communication signals with mutual interference signal power from communications in adjacent geographic regions attenuated as a function of distance therefrom.

41. The method of claim 33 further comprising the steps of:

detecting a minimum power level required to maintain system user address corresponding code-division-spread-spectrum communication signals in a system user communication link above a predetermined incident power level;

providing a link control signal corresponding to said detected minimum power level; and

adjusting a transmission power level for said system user address corresponding code-division-spread-spectrum communication signals in response to said link control signal.

42. The method of claim 33 further comprising the step of transmitting a pilot chip sequence comprising a predetermined sequence of data bits.

43. The method of claim 33 wherein said step of transmitting comprises the steps of transmitting to and from a plurality of users through a repeater.

44. The method of claim 43 wherein said steps of transmitting to and from comprises the steps of transmitting to and from a terrestrial repeater

45. The method of claim 43 wherein said steps of transmitting to and from comprises the steps of transmitting to and from at least one satellite repeater.

46. The method of claim 43 wherein said steps of transmitting to and from comprises the steps of transmitting to and from at least one satellite repeater and at least one terrestrially based repeater.