Time delay passive ranging technique

US 5,327,145 A
Filed: 05/22/1990
Issued: 07/05/1994
Est. Priority Date: 05/22/1990
Status: Expired due to Term

First Claim

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1. A method of passive ranging and geolocation based on signal emanations from an emitter and from an object, said method comprising the steps of:

measuring a first time of arrival difference (τ

₁) of an active ranging and interrogation signal from an emitter and the passive return of a reflected signal from an object illuminated and interrogated by the emitter;

measuring a second time of arrival difference (τ

₂) of an active answering signal from the object that is responsive to the emitter interrogation and a passive return of the answering signal that is reflected from the emitter;

measuring the respective bearings (θ

₁, θ

₂) of the arriving signals;

computing a platform angle (α

) between the emitter and the object in accordance with a first predefined relationship;

computing a relative range (R_T) between the emitter and the object in accordance with a second predefined relationship;

computing a first range (R) from the platform to the emitter in accordance with a third predefined relationship; and

computing a second range (D) from the platform to the object in accordance with a fourth predefined relationship.

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Abstract

A method of passive ranging and geolocation of multiple emitters by a single detection platform. Two independent emission sequences support formulation of two independent algebraic equations involving a triangular arrangement of platform and emitters. One sequence constitutes an interrogation signal by one emitter and a transponded or reflected signal from another. A second emission sequence constitutes the reversed order of emitters from those of the first emission sequence. The method utilizes the steps of measuring the time difference of arrival at the platform of signals having travelled the direct path and the transponded or reflected paths, and measuring the angles of arrival of received signals for each independent emission sequence. A series of steps computing ranges and angles based on prior measurements provide a set of desired ranges and angles identifying the relative positions of the emitters relative to the platform. The invention may be employed in bistatic or transponded mode depending on the kind of signal emissions that are to be exploited. In the bistatic mode, the energy from an emitter is reflected from the other emitter. In the transponder mode the emitters communicate in an interrogation-transpond format with signals with known and small internal time delays. In the transponder mode, both signals are direct path signals.

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19 Claims

1. A method of passive ranging and geolocation based on signal emanations from an emitter and from an object, said method comprising the steps of:
- measuring a first time of arrival difference (τ
  
  ₁) of an active ranging and interrogation signal from an emitter and the passive return of a reflected signal from an object illuminated and interrogated by the emitter;
  
  measuring a second time of arrival difference (τ
  
  ₂) of an active answering signal from the object that is responsive to the emitter interrogation and a passive return of the answering signal that is reflected from the emitter;
  
  measuring the respective bearings (θ
  
  ₁, θ
  
  ₂) of the arriving signals;
  
  computing a platform angle (α
  
  ) between the emitter and the object in accordance with a first predefined relationship;
  
  computing a relative range (R_T) between the emitter and the object in accordance with a second predefined relationship;
  
  computing a first range (R) from the platform to the emitter in accordance with a third predefined relationship; and
  
  computing a second range (D) from the platform to the object in accordance with a fourth predefined relationship.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
- - 2. The passive ranging and geolocation method of claim 1 wherein the first predefined relationship in the step of computing a platform angle (α
    - ) comprises the equation α
      
      =θ
      
      ₁ -θ
      
      ₂.
  - 3. The passive ranging and geolocation method of claim 2 wherein the second predefined relationship in the step of computing a relative range (R_T) comprises the equation R_T =c(τ
    - ₁ +τ
      
      ₂)÷
      
      2.
  - 4. The passive ranging and geolocation method of claim 3 wherein the third predefined relationship in the step of computing a second range (D) comprises the equation D=R+R_T -cτ
    - ₂ =cτ
      
      ₂ +R+R_T.
  - 5. The passive ranging and geolocation method of claim 4 wherein the fourth predefined relationship in the step of computing a first range (R) comprises the equation ##EQU4##
  - 6. The passive ranging and geolocation method of claim 1 wherein the signal emanations from an emitter and from the object comprise emanations of electromagnetic signals.
  - 7. The passive ranging and geolocation method of claim 1 wherein the signal emanations from an emitter (12) and from an object (13) comprise emanations of acoustic signals.
  - 8. The passive ranging and geolocation method of claim 1 wherein the step of measuring the first time of arrival difference (τ
    - ₁) comprise the steps of;
      
      detecting the active interrogation signal from the emitter;
      
      starting a reference timer;
      
      detecting an active reply signal from the answering object that is responsive to the interrogation signal and recording the time of detection;
      
      computing a first time delay (τ
      
      ₁) between the first interrogation signal and the first reply signal in accordance with a first predefined relationship.
  - 9. The passive ranging and geolocation method of claim 1 wherein the step of measuring the second time of arrival difference (τ
    - ₂) comprises the steps of;
      
      detecting an active second interrogation signal from the emitter that is responsive to the first reply signal and stopping the reference timer; and
      
      computing the second time delay (τ
      
      ₁) between the first reply signal and the second interrogation signal in accordance with a second predefined relationship.

10. A method of passive ranging and geolocation of a emitter that interrogates an object, which object is actively responsive to the interrogation of the emitter, and wherein the internal response times of the emitter and the object are known, said method comprising the steps of:
- detecting an active first interrogation signal from the emitter;
  
  starting a reference timer;
  
  measuring a first bearing (θ
  
  ₁) to the emitter;
  
  detecting an active first reply signal from an answering object that is responsive to the first interrogation signal and recording the time of detection;
  
  computing a first time delay (τ
  
  ₁) between the first interrogation signal and the first reply signal;
  
  measuring a second bearing (θ
  
  ₂) to the answering object;
  
  detecting an active second interrogation signal from the emitter that is responsive to the first reply signal and stopping the reference timer;
  
  computing a second time delay (τ
  
  ₂) between the active first reply signal and the second interrogation signal;
  
  computing a platform angle (α
  
  ) between the emitter and the answering object;
  
  computing a relative range (R_T) between the emitter and the answering object;
  
  computing a first range (R) to the emitter; and
  
  computing a second range (D) to the answering object.
- View Dependent Claims (11, 12, 13, 14)
- - 11. The passive ranging and geolocation method of claim 10 wherein the first predefined relationship in the step of computing a platform angle (α
    - ) comprises the equation α
      
      =θ
      
      ₁ -θ
      
      ₂.
  - 12. The passive ranging and geolocation method of claim 11 wherein the second predefined relationship in the step of computing a relative range (R_T) comprises the equation R_T =c(τ
    - ₁ +τ
      
      ₂)÷
      
      2.
  - 13. The passive ranging and geolocation method of claim 12 wherein the third predefined relationship in the step of computing a second range (D) comprises the equation D=R+R_T -cτ
    - ₂ =cτ
      
      ₂ +R+R_T.
  - 14. The passive ranging and geolocation method of claim 13 wherein the fourth predefined relationship in the step of computing a first range (R) comprises the equation ##EQU5##

15. A method of passive ranging and geolocation based on signal emanations from multiple objects, said method comprising the steps of:
- detecting an interrogation signal from a first object;
  
  starting a reference timer;
  
  measuring a first bearing (θ
  
  ₁) to the first object;
  
  searching for a first echo signal that is the interrogation signal reflected from a second object;
  
  detecting the first echo signal and stopping the reference timer;
  
  measuring a first time delay (τ
  
  ₁) between the interrogation signal and the first echo signal;
  
  measuring a second bearing (θ
  
  ₂) to the second object;
  
  detecting an active reply signal from the second object;
  
  re-starting the reference timer;
  
  searching for a second echo signal that is the active reply signal of the second object reflected from the first object;
  
  detecting the second echo signal and stopping the reference timer;
  
  measuring a second time delay (τ
  
  ₂) between the active reply signal and the second echo signal;
  
  computing a platform angle (α
  
  ) between the first object and the second object in accordance with a first predefined relationship;
  
  computing a relative range (R_T) between the first object and the second object in accordance with a second predefined relationship;
  
  computing a second range (D) to the second object in accordance with a third predefined relationship; and
  
  computing a first range (R) to the first object in accordance with a fourth predefined relationship.
- View Dependent Claims (16, 17, 18, 19)
- - 16. The passive ranging and geolocation method of claim 15 wherein the first predefined relationship in the step of computing a platform angle (α
    - ) comprises the equation α
      
      =θ
      
      ₁ -θ
      
      ₂.
  - 17. The passive ranging and geolocation method of claim 16 wherein the second predefined relationship in the step of computing a relative range (R_T) comprises the equation R_T =c(τ
    - ₁ +τ
      
      ₂)÷
      
      2.
  - 18. The passive ranging and geolocation method of claim 17 wherein the third predefined relationship in the step of computing a second range (D) comprises the equation D=R+R_T -cτ
    - ₂ =cτ
      
      ₂ +R+R_T.
  - 19. The passive ranging and geolocation method of claim 18 wherein the fourth predefined relationship in the step of computing a first range (R) comprises the equation ##EQU6##

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Current Assignee
Raytheon Company (Rtx Corporation)
Original Assignee
Hughes Aircraft Company (Rtx Corporation)
Inventors
Jelinek, Carl O.
Primary Examiner(s)
Sotomayor, John B.

Application Number

US07/526,924
Time in Patent Office

1,505 Days
Field of Search

342/13, 342/453, 342/146, 342/123, 342/125, 342/126, 342/451, 342/458
US Class Current

342/453
CPC Class Codes

G01S 13/003   Bistatic radar systems; Mul...

G01S 13/78   discriminating between diff...

G01S 5/10   Position of receiver fixed ...

Time delay passive ranging technique

First Claim

5 Assignments

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Abstract

26 Citations

19 Claims

Specification

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Time delay passive ranging technique

First Claim

5 Assignments

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0 Petitions

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Accused Products

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Abstract

26 Citations

19 Claims

Specification

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Use Cases

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Others