Frequency management system

US 4,780,885 A
Filed: 07/15/1985
Issued: 10/25/1988
Est. Priority Date: 12/01/1982
Status: Expired due to Fees

First Claim

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1. A high frequency (HF) frequency-management system that performs automatic selection of the optimum HF frequency for reliable communications between two or more stations of an HF net and dissemination of the optimum frequency, for the automatic establishment of HF communications path between two or more radio stations of the said net, comprising of a frequency management means that controls the operation of a regular HF radio communications transmitter and receiver at each stations;

the said frequency-management means comprising means for transmitting sounding signals synchronously and repeatedly over a finite group of HF frequencies, from a first radio communications station to a second radio communications station;

means for link quality evaluation (LQE) at the second station;

means for transmitting back sounding signals, synchronously and repeatedly over said finite group of HF frequencies, from said second station back to said first station;

means for selecting optimum HF frequencies at the said first station, based on said sounding signals and LQE;

means for dissemination of said optimum HF frequencies information, by the said first station to the said second station (and all other stations in the net), for the automatic establishment of an HF communications path between said stations, wherein said first and second stations utlize said regular HF radio communications transmitter and receiver for both the frequency management functions as well as for the usual communication function, in time interleaved mode controlled by the said frequency management means; and

means for monitoring the noise and interferences on said finite group of HF frequencies, means for searching for incoming communication or sounding calls;

means for performing the timing and control of the HF radios;

means for acquiring and maintaining synchronization of the frequency management system and communication net; and

each said means performing the scanning of the HF frequencies, the detection and measurement of signals, noise and interferences on each frequency and the timing synchronization as required for the frequency management operation.

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Abstract

A high frequency (HF) frequency-management system for automatically selecting optimum HF frequency. A frequency management means controls the operation of a regular HF radio communications transmitter and receiver at each station. The frequency-management means transmits sounding signals synchronously and repeatedly over a finite group of HF frequencies, from a first radio communications station to a second radio communications station. Link quality evaluation (LQE) is carried out at the second station. Sounding signals are transmitted synchronously and repeatedly back to the first station. Optimum HF frequencies are selected based on the sounding signals and LQE. An HF communications path is automatically established between stations. The system performs the scanning of the HF frequencies, the detection and measurement of signals, noise and interferences on each frequency and the timing synchronization as required for the frequency management operation.

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18 Claims

1. A high frequency (HF) frequency-management system that performs automatic selection of the optimum HF frequency for reliable communications between two or more stations of an HF net and dissemination of the optimum frequency, for the automatic establishment of HF communications path between two or more radio stations of the said net, comprising of a frequency management means that controls the operation of a regular HF radio communications transmitter and receiver at each stations;
- the said frequency-management means comprising means for transmitting sounding signals synchronously and repeatedly over a finite group of HF frequencies, from a first radio communications station to a second radio communications station;
  
  means for link quality evaluation (LQE) at the second station;
  
  means for transmitting back sounding signals, synchronously and repeatedly over said finite group of HF frequencies, from said second station back to said first station;
  
  means for selecting optimum HF frequencies at the said first station, based on said sounding signals and LQE;
  
  means for dissemination of said optimum HF frequencies information, by the said first station to the said second station (and all other stations in the net), for the automatic establishment of an HF communications path between said stations, wherein said first and second stations utlize said regular HF radio communications transmitter and receiver for both the frequency management functions as well as for the usual communication function, in time interleaved mode controlled by the said frequency management means; and
  
  means for monitoring the noise and interferences on said finite group of HF frequencies, means for searching for incoming communication or sounding calls;
  
  means for performing the timing and control of the HF radios;
  
  means for acquiring and maintaining synchronization of the frequency management system and communication net; and
  
  each said means performing the scanning of the HF frequencies, the detection and measurement of signals, noise and interferences on each frequency and the timing synchronization as required for the frequency management operation.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
- - 2. A frequency management system according to claim 1, wherein at each station the frequency management means includes means for utilizing the radio receiver to search for incoming calls and to measure the noise and interference by sequentially monitoring the interference and occupancy of a finite group of HF channels, each channel tuned to a different frequency;
    - means for measuring the radio receiver AGC level and radio receiver noise output and distribution;
      
      means for measuring in-channel interference characteristics;
      
      means for classifying noise and interference present on each of the finite set of HF frequences into a predetermined number of categories, according to a predetermined set of criteria;
      
      means for hard-labeling of each one of the said HF frequencies as either a binary "1" for a `quiet` HF frequency or a binary "0" for a `noisy` HF frequency based on a predetermined set of criteria;
      
      means for storing and updating the resulting set of binary labels (IMP-Interference Measurement Pattern), wherein each bit represents a channel occupancy evaluation of one of the HF frequencies visited;
      
      means for using this binary word at the said first station as the sounding signal from the said first station to the said second station; and
      
      each said means performs the necessary gathering and storing of information concerning the noise, interference and channel occupancy conditions at said first station as well as at said second station.
  - 3. A system according to claim 2, wherein the number of channels is from 25 to 130 with 4 KHZ spacing, the number of selected optimal communication frequencies is from 2 to 20, and the number of categories used is from 2 to 8.
  - 4. A frequency management system according to claim 1 wherein said first station originates a sounding transmission repeatedly, once over each of the said finite group of HF frequencies by having its HF transmitter scan said HF frequencies;
    - said sounding transmission being an FSK or DPSK transmission containing the IMP and also synchronization information for synchronizing said second station receiver so that it is sequenced through same said group of HF frequencies at an equal rate, being at each one of the HF frequencies at the same period of time as the transmitter, to allow the sounding message to be received.
  - 5. A frequency management system according to claim 1 comprising timing and control means, wherein the timing and control means comprise means for randomly selecting N HF frequencies from within a specified HF sub-band given its limits f_low to f_high ;
    - means for storing said N HF frequencies as alternate channels with each channel having a predetermined frequency;
      
      means for placing said first and second stations in a transmit or receive mode;
      
      means for sequencing and tuning the HF receiver and transmitter through the group of N HF frequencies;
      
      means for providing timing for the frequency management system operation, such as bit synchronization, frame sync acquisition, sync cycle operation, and sounding cycle operation;
      
      means for generating a predetermined sequence based on the input of a key variable and real time of day; and
      
      each said means cooperates with each other such as to enable full timing synchronization between said first and second station.
  - 6. A frequency management system according to claim 1 wherein the link quality evaluation (LQE) means comprises of means for detecting the noise present on each of the (investigated) channels;
    - FSK and DPSK data detectors for providing a signal representative of the data levels that are present on the communication channels that the receiver is tuned;
      
      means for determining the signal-to-noise ratio;
      
      means for measuring the fading rate and its spread;
      
      means for measuring the rms multipath delay spread;
      
      means to arrive at the actual bit-error-rate;
      
      means for quantizing the parameters, signal-to-noise ratio and bit-error-rate, in combination with one or more of the parameters, fading rate, delay spread, channel noise, data levels, measured on the communication channel, to define the desired predetermined number of link quality categories according to a predetermined set of criteria;
      
      means for generating a corresponding number of binary words, each N-bit long, one for each category, wherein each bit represents a hard-decision qualifying respectively one of the N channels sounded (LQP-Link Quality Pattern); and
      
      each said means for measuring and storing the various channel parameters cooperates with the LQE and LQP means of the frequency management system in order to accurately characterize each of the said set of N HF frequencies as to its quality as a two-way communication channel for voice or data transmission.
  - 7. A frequency management system according to claim 1 comprising an optimal channel selection means, wherein the optimal channel selection means comprises of means for evaluating and comparing the receive Interference Measurement Patterns (IMP), which is the signals from said first station to said second station information contained in the sounding, the IMP locally measured and the Link Quality Pattern (LQP), which is the information contained in sounding signals from said second station to said first station, measured at said second station;
    - means for evaluationg and comparing the LQPs received and the LQEs measured at the first station, to allow the first station to derive, based on a two-way exhange of signals sounding, optimal operating frequencies.
  - 8. A frequency management system according to claim 1 containing frequency dissemination means, which comprises of means for selecting and storing optimal communication frequencies;
    - means for said first (or second) station to transmit on the selected frequencies information preceded by a unique sender'"'"'s identity and address, regarding the selected frequencies;
      
      means for utilizing the synchronization achieved between the stations, to disseminate frequency information by transmitting over the selected optimal frequencies; and
      
      each said means for storing and disseminating sender'"'"'s identity, sender'"'"'s address and selected communication frequencies, enable the frequency management system to perform the frequency management functions as well as the communication functions by addressing the desired station at will.
  - 9. A frequency management system according to claim 1 wherein the receiver synchronization means comprises of means for transmitting a N-frame sync cycle, pseudorandomly hopping over the group of N HF frequencies, where each frame includes a unique sync format;
    - means adapted to step the HF receivers at an irregular rate but in a unique search pattern of "skipping x channels and the waiting Y time-slots, etc", designed to keep the receiver always ahead of the transmitters;
      
      means for maintaining this search pattern until a predetermined number of syncs is detected, indicating synch acquisition;
      
      means for maintaining a continuous process of tracking frame syncs during the sounding signals transmissions;
      
      means for pseudo-randomly sequencing and tuning the HF receiver and transmitter through the group of N HF frequencies;
      
      means for generating a pseudorandom sequence based on the input of a key variable and real time of the day.

10. A method of selecting an optimum HF frequency for reliable communication between two or more stations of an HF net and for disseminating the optimum frequency, establishing automatically an HF communication path between two or more stations of said net, which comprises the steps of controlling the operation of a regular HF communications transmitter and receiver at each station, transmitting sounding signals synchronously and repeatedly over a finite group of HF frequencies, from a first radio communications station to a second radio communications station, continuously monitoring the interference and occupancy of a finite group of HF channels, each channel a different frequency;
- hard-labeling each one of the said channels as either a binary "1" for a `quiet` channel or a binary "0" for a `noisy` channel, based on a predetermined set of criteria;
  
  storing and updating the resulting set of binary labels wherein each bit represents an evaluation of one of the HF frequencies visited;
  
  using this binary word as a sounding signal and transmitting this signal repeatedly, once over each of the said finite group of frequencies by having the transmitter scan said channels;
  
  synchronizing said second station receiver so that it is sequenced through same said group of channels at an equal rate, being at each one of the channels at the same period of the time as the transmitter, to allow the sounding message to be received;
  
  majority-detecting said redundant sounding message by the receiver;
  
  performing link quality measurements on each of the scanned group of frequencies;
  
  hard-labeling each one of the said channels as either binary "1" for a "good" or "acceptable", and a binary "0" for a "bad" or "not-acceptable" communication quality, based on another set of criteria;
  
  storing the resulting set of binary labels to be used by it in forming the answer-back sounding signal from said second station to said first station;
  
  transmitting the answer-back sounding message repeatedly, once over each of the said group of channels by having said second station transmitter scan said channels;
  
  majority-detecting said answer-back sounding message by the first station receiver, performing link quality measurements by the first station receiver, on each one of the said scanned group of frequencies;
  
  selecting optimal frequencies by the first station, for reliable communications in both directions, based on the analysis of the received and locally evaluated link quality patterns;
  
  utilizing the synchronization maintained between the stations, to disseminate the selected frequencies information to said second station;
  
  automatically tuning the communications transmitters and receivers to the selected preferred frequencies, thus establishing reliable communication paths between the stations.
- View Dependent Claims (11, 12, 13, 14, 15, 16, 17, 18)
- - 11. A method according to claim 10 wherein at each station the HF communication radio receiver is utilized to search for incoming calls and to measure the noise and interference by sequentially monitoring the interference and occupancy of a finite group of HF channels, tuning each channel to a different frequency;
    - measuring the radio receiver AGC level and radio receiver noise output and distribution;
      
      measuring in-channel interference characteristics;
      
      classifying noise and interference present on each of the finite set of HF frequencies into a predetermined number of categories according to a predetermined set of criteria;
      
      hard-labeling each one of said HF frequencies as either binary "1" for a `quiet` HF frequency or a binary "0" for a `noisy` HF frequency based on a predetermined set of criteria;
      
      storing and updating the resulting set of binary labels (IMP-Interference Measurement Pattern), wherein each bit represents a channel occupancy evaluation of one of the HF frequencies visited;
      
      using this binary word at said first station as the sounding signal from said first station to said second station; and
      
      further performing the necessary gathering and storing of information concerning the noise, interference and channel occupancy conditions at said first station as well as at said second station.
  - 12. A method according to claim 10 which further comprises the steps of originating at said first station a sounding transmission repeatedly, once over each of the said finite group of HF frequencies by having its HF transmitter scan said HF frequencies;
    - said sounding transmission being an FSK or DPSK transmission containing the IMP and also synchronization information for synchronizing said second station receiver so that it is sequenced through same said group of HF frequencies at an equal rate, being at each one of said HF frequencies at the same period of time as the transmitter, to allow the sounding message to be received.
  - 13. A method according to claim 12 further comprises the steps of performing by the first station upon receiving the said back sounding message and performing an LQE over each one of the back sounded channels to arrive at the optimum frequencies, including the steps of majority-detecting said answer-back sounding message at the first station receiver;
    - performing link quality measurements at the said group of frequencies;
      
      selecting optimal frequencies at the first station for reliable communications in both directions, based on the analysis of the received link quality patterns (LQP) and on the derived LQE.
  - 14. A method according to claim 10 which further comprises the steps of randomly selecting N HF frequencies from within a specified HF sub-band given its limits f_low to f_high ;
    - storing said N HF frequencies as alternate channels with each channel having a predetermined frequency;
      
      placing the first and second station in a transmit or receive mode;
      
      sequencing and tuning the HF receiver and transmitter through the group of N HF frequencies;
      
      providing timing for the frequency management system operation, such as bit synchronization, frame sync acquisition, sync cycle operation, and sounding cycle operation;
      
      generating a predetermined sequence based on the input of a key variable and real time of day; and
      
      cooperating with each other such as to enable full timing synchronization between said first and said second station.
  - 15. A method according to claim 10 wherein at the second station, upon receiving said sounding signal from the first station, repeated over all the said group of HF frequencies in time sequence, link quality evaluation is performed.
  - 16. A method according to claim 10 wherein the link quality evaluation (LQE) comprises the steps of detecting the noise present on each of the (investigated) channels;
    - FSK and DPSK data detecting for providing the data levels that are present on the communication channels that the receiver is tuned;
      
      determining the signal-to-noise ratio;
      
      measuring the fading rate and its spread;
      
      measuring the rms multipath delay spread;
      
      using the demodulated message to arrive at the actual bit-error-rate;
      
      quantizing the parameters, signal-to-noise ratio and bit-error-rate, in combination with one or more of the parameters, fading rate, delay spread, channel noise, data levels, measured on the communication channel, to define the desired predetermind set of criteria;
      
      generating a corresponding number of binary words, each N-bit long, one for each category, wherein each bit represents a hard-decision qualifying respectively one of the N channels sounded (LQP-Link Quality Pattern); and
      
      said steps for measuring and storing the various channel parameters cooperate with the LQE and LQP means of the frequency management system in order to accurately characterize each of said set of N HF frequencies as to its quality as a two-way communication channel for voice or data transmission.
  - 17. A method according to claim 10 which further comprises the steps of responding by the said second station by transmitting the back sounding signal comprising of transmitting the answer-back sounding message repeatedly, once over each of the said group of HF frequencies by having the second station transmitter scan said HF frequencies;
    - the answer back sounding being the LQP message generated by said LQE means at the said second station.
  - 18. A method according to claim 10, wherein the number of channels is from 25 to 130 with 4 KHz spacing, the number of selected optimal communication frequencies is from 2 to 20, and the number of categories used is from 2 to 8.

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Current Assignee
Haim D. Paul, Joseph M. Perl
Original Assignee
Haim D. Paul, Joseph M. Perl
Inventors
Paul, Haim D., Perl, Joseph M.
Primary Examiner(s)
Griffin, Robert L.
Assistant Examiner(s)
Von Beek, Leslie

Application Number

US06/754,726
Time in Patent Office

1,198 Days
Field of Search

455/62, 455/67, 375/40
US Class Current

375/267
CPC Class Codes

H04B 1/74 for increasing reliability,...

H04B 7/005 Control of transmission; Eq...

Frequency management system

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Frequency management system

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