Vehicle position tracking technique

US 5,592,181 A
Filed: 05/18/1995
Issued: 01/07/1997
Est. Priority Date: 05/18/1995
Status: Expired due to Term

First Claim

Patent Images

1. A method for tracking a moving transmitter which transmits RF signals, comprising the following steps:

positioning first and second antenna arrays is a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements comprising a plurality of baseline pairs of elements, wherein the element-to-element spacing d of elements in the baseline pairs are different for each baseline pair;

receiving RF signals from the transmitter using the first and second antenna arrays and converting baseline signals from each baseline pair of elements into digital data;

processing the digital data to provide phase data indicative of the electrical phases of signals received at the different baseline pairs of the first and second antenna arrays;

converting the phase data into spatial angle data indicative of angle of arrival of RF signals incident on the baseline pairs of the first and second antenna arrays;

processing the spatial angle data with antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide transmitter position data specifying an estimated position of the transmitter; and

determining sample quality weighting factors and weighting the transmitter position data with said factors to compensate for multipath distorted samples.

View all claims

8 Assignments

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

A method and system for tracking the position of a moving transmitter using angle of arrival measurements from direction finding antenna arrays. Each array includes several elements, with the elements grouped to provide subarrays of different element spacings which are multiple of one half the transmitter wavelength. Ambiguity is rejected by processing angle data received from the subarrays. The signals from the arrays are processed to convert electrical phase delay into spatial angles, the spatial angle data is processed to provide the x,y position, velocity and acceleration of the transmitter. For transmitters mounted in moving vehicles, the system further processes the x,y data and applies a quality weighting factor that filters out multipath factors and permits estimation of vehicle profile information.

44 Citations

View as Search Results

30 Claims

1. A method for tracking a moving transmitter which transmits RF signals, comprising the following steps:
- positioning first and second antenna arrays is a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements comprising a plurality of baseline pairs of elements, wherein the element-to-element spacing d of elements in the baseline pairs are different for each baseline pair;
  
  receiving RF signals from the transmitter using the first and second antenna arrays and converting baseline signals from each baseline pair of elements into digital data;
  
  processing the digital data to provide phase data indicative of the electrical phases of signals received at the different baseline pairs of the first and second antenna arrays;
  
  converting the phase data into spatial angle data indicative of angle of arrival of RF signals incident on the baseline pairs of the first and second antenna arrays;
  
  processing the spatial angle data with antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide transmitter position data specifying an estimated position of the transmitter; and
  
  determining sample quality weighting factors and weighting the transmitter position data with said factors to compensate for multipath distorted samples.
- View Dependent Claims (7, 8, 9, 10, 11, 12)
- - 7. The method of claim 1 further comprising the steps of collecting RF signal transmission signals from said transmitter over a period of time to provide a plurality of samples, and processing the samples received over time to provide data indicative of the velocity and acceleration of the moving transmitter.
  - 8. The method of claim 1 wherein said antenna arrays each include first and second checking baseline pairs of elements which are spaced by the same distance d, said checking baseline pairs having baseline factors c₁ and c₂, and wherein the step of determining sample quality weighting factors includes comparing the electrical phases received at said first and second baseline pairs for a given set of samples, and assigning a small quality weighting factor to a given set of samples if said electrical phases for said first and second baseline pairs are not identical.
  - 9. The method of claim 8 wherein said quality factor provides Gaussian weighting, and is determined in accordance with the following relationship,
    
    space="preserve" listing-type="equation">λ
    
    =exp (-max (β
    
    .sub.1.sup.2, β
    
    .sub.2.sup.2)/2σ
    
    .sup.2)
    
    space="preserve" listing-type="equation">β
    
    .sub.1 =((c.sub.2 /c.sub.1)Δ
    
    φ
    
    .sub.c(1) -Δ
    
    φ
    
    .sub.c(2))mod(-180,
    
    180) at the first antenna array
    
    space="preserve" listing-type="equation">β
    
    .sub.2 =((c.sub.2 /c.sub.1)Δ
    
    φ
    
    .sub.c(1) -Δ
    
    φ
    
    .sub.c(2))mod(-180,
    
    180) at the second antenna arrayλ
    
    represents the weighting factor, σ
    
    is a selected value for the weighting scheme.
- 10. The method of claim 1 wherein said antenna array elements are arranged along respective linear array axes, and wherein said array axes are arranged at respective angles with respect to a nominal direction of vehicle movement in relation to the arrays, said angles in the range of about 30 degrees to 60 degrees.
- 11. The method of claim 1 wherein said spacing d of elements in the baseline pairs is equal to multiples of λ
  - /2, where λ
    
    represents the nominal wavelength of the RF signals.
- 12. The method of claim 11 wherein a first one of the baseline pairs has a spacing d of λ
  - /2.

2. A method for tracking a moving transmitter which transmits RF signals, comprising the following steps:
- positioning first and second antenna arrays is a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements grouped in a plurality of subarrays of elements, wherein the element-to-element spacings of elements in the subarrays are different multiples of one half the transmitter wavelength of operation;
  
  receiving RF signals from the transmitter using the first and second antenna arrays and converting subarray signals from each array signals into digital data;
  
  processing the digital data to provide phase data indicative of the electrical phases of signals received at the different subarrays of the first and second antenna arrays;
  
  converting the phase data into spatial angle data indicative of angle of arrival of RF signals incidenton the subarrays of the first and second antenna arrays;
  
  processing the spatial angle data with antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide information specifying an estimated position of the transmitter; and
  
  determining sample quality weighting factors and weighting the transmitter position data with said factors to compensate for multipath distorted samples.
- View Dependent Claims (18)
- - 18. The method of claim 2 further comprising the steps of collecting RF signal transmission signals from said transmitter over a period of time to provide a plurality of samples, and processing the samples received over time to provide data indicative of the velocity and acceleration of the moving transmitter.

3. A system for tracking a moving transmitter which transmits RF signals, comprising:
- first and second direction finding antenna arrays disposed in a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements comprising a plurality of baseline pairs of elements, wherein the element-to-element spacing d of elements in the baseline pairs are different for each baseline pair;
  
  receiver apparatus for receiving RF signals from the transmitter using the first and second antenna arrays and converting baseline signals from each baseline pair of elements into digital data;
  
  processor apparatus for processing the digital data, said apparatus comprising;
  
  means responsive to the digital data to provide phase data indicative of the electrical phases of signals received at the different base-line pairs of the first and second antenna arrays;
  
  means for converting the phase data into spatial angle data indicative of the spatial angle of arrival of RF signals incident on the baseline pairs of the first and second antenna arrays; and
  
  means for processing the spatial angle data and antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide transmitter position data specifying an estimated position of the transmitter;
  
  means for determining sample quality weighting factors; and
  
  means for weighting the transmitter position data with said factors to compensate for multipath distorted samples.
- View Dependent Claims (19, 20, 21, 22, 23, 24, 25, 26)
- - 19. The system of claim 3 wherein the receiver apparatus collects RF signal transmission signals from said transmitter over a period of time to provide a plurality of samples, and said processor apparatus processes the samples received over time to provide data indicative of the velocity and acceleration of the moving transmitter.
  - 20. The system of claim 19 wherein the processor apparatus further includes means for determining sample quality weighting factors and means for weighting the transmitter position data with said factors to compensate for multipath distorted samples.
  - 21. The system of claim 3 wherein said antenna arrays each include first and second checking baseline pairs of elements which are spaced by the same distance d, said checking baseline pairs having baseline factors c₁ and c₂, and wherein the means for determining sample quality weighting factors includes means for comparing the electrical phases received at said first and second baseline pairs for a given set of samples, and means for assigning a small quality weighting factor to a given set of samples if said electrical phases for said first and second baseline pairs are not identical.
  - 22. The system of claim 21 wherein said quality factor provides Gaussian weighting, and is determined in accordance with the following relationship,
    
    space="preserve" listing-type="equation">λ
    
    =exp (-max (β
    
    .sub.1.sup.2, β
    
    .sub.2.sup.2)/2σ
    
    .sup.2)
    
    space="preserve" listing-type="equation">β
    
    .sub.1 =((c.sub.2 /c.sub.1)Δ
    
    φ
    
    .sub.c(1) -Δ
    
    φ
    
    .sub.c(2))mod(-180,
    
    180) at the first antenna array
    
    space="preserve" listing-type="equation">β
    
    .sub.2 =((c.sub.2 /c.sub.1)Δ
    
    φ
    
    .sub.c(1) -Δ
    
    φ
    
    .sub.c(2))mod(-180,
    
    180) at the second antenna arrayλ
    
    represents the weighting factor, σ
    
    is a selected value for the weighting scheme.
- 23. The system of claim 3 wherein said antenna array elements are arranged along respective linear array axes, and wherein said array axes are arranged at respective angles with respect to a nominal direction of vehicle movement in relation to the arrays, said angles in the range of about 45 degrees to 60 degrees.
- 24. The system of claim 3 wherein said spacing d of elements in the baseline pairs is equal to multiples of λ
  - /2, where λ
    
    represents the nominal wavelength of the RF signals.
- 25. The system of claim 24 wherein a first one of the baseline pairs has a spacing d of λ
  - /2.
- 26. The system of claim 3 wherein no single antenna element comprises each of the plurality of baseline pairs of elements.

4. A method for tracking a moving transmitter which transmits RF signals, comprising the following steps:
- positioning first and second antenna arrays is a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements comprising a plurality of baseline pairs of elements, wherein the element-to-element spacing d of elements in the baseline pairs are different for each baseline pair;
  
  receiving RF signals from the transmitter using the first and second antenna arrays and converting baseline signals from each baseline pair of elements into digital data;
  
  processing the digital data to provide phase data indicative of the electrical phases of signals received at the different baseline pairs of the first and second antenna arrays;
  
  converting the phase data into spatial angle data indicative of angle of arrival of RF signals incident on the baseline pairs of the first and second antenna arrays; and
  processing the spatial angle data with antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide information specifying an estimated position of the transmitter, said processing including finding the intersection of two hyperbolas H₁ and H₂, and wherein the hyperbolas are represented by
  space="preserve" listing-type="equation">H.sub.1 ;
  
  a.sub.1 x.sup.2 +a.sub.2 y.sup.2 +a.sub.3 xy+a.sub.4 x+a.sub.5 y+a.sub.6 =0
  space="preserve" listing-type="equation">H.sub.2 ;
  
  b.sub.1 x.sup.2 +b.sub.2 y.sup.2 +b.sub.3 xy+b.sub.4 x+b.sub.5 y+b.sub.6 =0
  and wherein the transmitter location is at x,y at a solution of the foregoing equations.
- View Dependent Claims (17)
- - 17. The method of claim 4 wherein said solution of said hyperbola equations is determined by substitute for x to establish a quadratic single-variable equation
    
    space="preserve" listing-type="equation">c.sub.1 y.sup.4 +c.sub.2 y.sup.3 +c.sub.3 y.sup.2 +c.sub.4 y+c.sub.5 =0
    and solving for y, and then using (H₁) or (H₂) to find x.

5. A method for tracking a moving transmitter which transmits RF signals, comprising the following steps:
- positioning first and second antenna arrays is a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements comprising a plurality of baseline pairs of elements, wherein the element-to-element spacing d of elements in the baseline pairs are different for each baseline pair, and wherein no single antenna element comprises each of the plurality of baseline pairs of elements;
  
  receiving RF signals from the transmitter using the first and second antenna arrays and converting baseline signals from each baseline pair of elements into digital data;
  
  processing the digital data to provide phase data indicative of the electrical phases of signals received at the different baseline pairs of the first and second antenna arrays;
  
  converting the phase data into spatial angle data indicative of angle of arrival of RF signals incident on the baseline pairs of the first and second antenna arrays; and
  
  processing the spatial angle data with antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide information specifying an estimated position of the transmitter.
- View Dependent Claims (13, 14, 15, 16)
- - 13. The method of claim 5, wherein said antenna arrays each includes four antenna elements arranged along a linear axis, and wherein first and second elements are disposed on one side of an antenna center, and the third and fourth elements are disposed on the opposite side of the center, said elements being symmetrically arranged about the antenna center.
  - 14. The method of claim 13 wherein the second and third antenna elements form the first baseline pair and are spaced apart by λ
    - /2.
  - 15. The method of claim 14 wherein the first and second antenna elements form a second baseline pair and are spaced apart by λ
    - .
  - 16. The method of claim 14 wherein the second and fourth antenna elements form a third baseline pair spaced apart by 1.5λ
    - , and the first and fourth antenna elements form a fourth baseline pair spaced apart by 2.5λ
      
      .

6. A system for tracking a moving transmitter which transmits RF signals, comprising:
- first and second direction finding antenna arrays disposed in a spaced arrangement relative to an area in which the transmitter is moving, each antenna array comprising a plurality of antenna elements arranged in spaced relationship, the elements comprising a plurality of baseline pairs of elements, wherein the element-to-element spacing d of elements in the baseline pairs are different for each baseline pair, and wherein no single antenna element comprises each of the plurality of baseline pairs of elements;
  
  receiver apparatus for receiving RF signals from the transmitter using the first and second antenna arrays and converting baseline signals from each baseline pair of elements into digital data;
  
  processor apparatus for processing the digital data, said apparatus comprising;
  
  means responsive to the digital data to provide phase data indicative of the electrical phases of signals received at the different base-line pairs of the first and second antenna arrays;
  
  means for converting the phase data into spatial angle data indicative of the spatial angle of arrival of RF signals incident on the baseline pairs of the first and second antenna arrays; and
  
  means for processing the spatial angle data and antenna configuration data indicative of the location and geometry of the first and second antenna arrays to provide transmitter position data specifying an estimated position of the transmitter.
- View Dependent Claims (27, 28, 29, 30)
- - 27. The system of claim 6 wherein said antenna arrays each includes four antenna elements arranged along a linear axis, and wherein first and second elements are disposed on one side of an antenna center, and the third and fourth elements are disposed on the opposite side of the center, said elements being symmetrically arranged about the antenna center.
  - 28. The system of claim 27 wherein the second and third antenna elements form the first baseline pair and are spaced apart by λ
    - /2.
  - 29. The system of claim 28 wherein the first and second antenna elements form a second baseline pair and are spaced apart by λ
    - .
  - 30. The system of claim 29 wherein the second and fourth antenna elements form a third baseline pair spaced apart by 1.5λ
    - , and the first and fourth antenna elements form a fourth baseline pair spaced apart by 2.5λ
      
      .

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Microelectronics Technology Inc (MTI Laboratory Inc)
Original Assignee
Hughes Aircraft Company (Rtx Corporation)
Inventors
Cai, Khiem V., O'Connor, Roger J.
Primary Examiner(s)
Tarcza, Thomas H.
Assistant Examiner(s)
PHAN, DAO LINDA

Application Number

US08/443,519
Time in Patent Office

600 Days
Field of Search

342/446, 342/445, 342/442, 342/457
US Class Current

342/457
CPC Class Codes

G01S 3/48 the waves arriving at the a...

G01S 5/04 Position of source determin...

Vehicle position tracking technique

First Claim

8 Assignments

0 Petitions

Accused Products

Abstract

44 Citations

30 Claims

Specification

Solutions

Use Cases

Quick Links

Vehicle position tracking technique

First Claim

8 Assignments

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

44 Citations

30 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links