Intensity area correlation addition to terrain radiometric area correlation

US 4,914,734 A
Filed: 07/21/1989
Issued: 04/03/1990
Est. Priority Date: 07/21/1989
Status: Expired due to Fees

First Claim

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1. A map-matching aircraft navigation system which provides an identification of an aircraft'"'"'s position in latitude and longitude, said map-matching navigation system comprising:

a first radar system which is housed in said aircraft and which transmits radio frequency signals in a point beam which sequentially strikes terrain in a first rectangular matrix in a pattern of points in rows and columns on terrain beneath said aircraft, said radar system receiving terrain echo returns from said pattern of rows and columns to output a first sensed map of said terrain with varying reflectivity coefficients in each of the points in the rows and columns;

a radiometer which is housed in said aircraft and which detects a radiometric temperature image of the terrain in a second rectangular matrix in a pattern of points to output a second sensed map of said terrain with varying measures of thermal emissions and reflected energy; and

a means for comparing said first and second sensed maps respectively with first and second stored reference maps, said first stored reference map containing a third rectangular matrix of rows and columns indicative of expected terrain echo return signals from the terrain over which said aircraft is flying, said comparing means finding a maximum correlation between said first sensed map and said first stored reference map to position and first sensed map on said first stored reference map, said comparing means thereby locating said aircraft on said first stored reference map, said comparing means also identifying each point in said third rectangular matrix with a known corresponding latitude and longitude in order to extract and output said aircraft'"'"'s position in latitude and longitude from its location on said first stored reference map, said comparing means containing a fourth rectangular matrix of rows and columns indicative of expected radiometric temperature image signals from the terrain over which the aircraft is flying, said comparing means finding a maximum correlation between said second sensed map and said second stored reference map to position said second sensed map on said second stored reference map to position said aircraft on said second stored reference map, said comparing means also identifying each point on fourth rectangular matrix with a known corresponding latitude and longitude in order to extract and output said aircraft'"'"'s position in latitude and longitude from its location on said second stored reference map after said second sensed map has been positioned on said second stored reference map.

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Abstract

A system which combines intensity area correlation is disclosed for use with terrain height radar and infrared emissivity systems to give a simultaneous three-mode map matching navigation system. The infrared system senses passive terrain emissions while the height finding radar measures the time between transmission of a radar signal to the ground and receipt of a radar return. The intensity correlator uses the radar returns to sense changes in the reflection coefficient of the terrain. Map matching all three modes simulanteously provides an accurate, highly jam resistant position determination for navigation update.

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6 Claims

1. A map-matching aircraft navigation system which provides an identification of an aircraft'"'"'s position in latitude and longitude, said map-matching navigation system comprising:
- a first radar system which is housed in said aircraft and which transmits radio frequency signals in a point beam which sequentially strikes terrain in a first rectangular matrix in a pattern of points in rows and columns on terrain beneath said aircraft, said radar system receiving terrain echo returns from said pattern of rows and columns to output a first sensed map of said terrain with varying reflectivity coefficients in each of the points in the rows and columns;
  
  a radiometer which is housed in said aircraft and which detects a radiometric temperature image of the terrain in a second rectangular matrix in a pattern of points to output a second sensed map of said terrain with varying measures of thermal emissions and reflected energy; and
  
  a means for comparing said first and second sensed maps respectively with first and second stored reference maps, said first stored reference map containing a third rectangular matrix of rows and columns indicative of expected terrain echo return signals from the terrain over which said aircraft is flying, said comparing means finding a maximum correlation between said first sensed map and said first stored reference map to position and first sensed map on said first stored reference map, said comparing means thereby locating said aircraft on said first stored reference map, said comparing means also identifying each point in said third rectangular matrix with a known corresponding latitude and longitude in order to extract and output said aircraft'"'"'s position in latitude and longitude from its location on said first stored reference map, said comparing means containing a fourth rectangular matrix of rows and columns indicative of expected radiometric temperature image signals from the terrain over which the aircraft is flying, said comparing means finding a maximum correlation between said second sensed map and said second stored reference map to position said second sensed map on said second stored reference map to position said aircraft on said second stored reference map, said comparing means also identifying each point on fourth rectangular matrix with a known corresponding latitude and longitude in order to extract and output said aircraft'"'"'s position in latitude and longitude from its location on said second stored reference map after said second sensed map has been positioned on said second stored reference map.
- View Dependent Claims (2, 3)
- - 2. A map-matching navigation system, as defined in claim 1, including a second radar system which is housed in said aircraft and which transmits radio frequency signals in a point beam which sequentially strikes terrain in a fifth rectangular matrix in a pattern of points and rows and columns on terrain beneath said aircraft, said radar system receiving terrain echo returns from said patterns of rows and columns to output a third sensed map of said terrain with the terrain in said third sensed map characterized by terrain height.
  - 3. A map-matching navigation system, as defined in claim 2, wherein said comparing means comprises:
    - a storage device which outputs said first, second and third stored reference maps along with their known corresponding latitude and longitude for each of the rows and columns in the second, fourth and six rectangular matrices; and
      
      a correlator data processor which receives said first sensed map from said first radar system, said second sensed map from said radiometer, and said third sensed map from said second radar system so that they are respectively correlated with the first, second and third stored reference maps from said storage device to derive said aircraft'"'"'s position, said correlator data processor finding a maximum correlation between said stored reference maps and said sensed maps using a minimum variance correlation function in which the correlation of each point of said sensed maps with each point of said stored reference maps is calculated to yield an offset, said offset indicating where said sensed maps are positioned on said stored referenced maps, said minimum variance correlation function comprising;
      
      ##EQU17## where KC(i,j) is the scene signal-to-noise ratio given by;
      
      ##EQU18## S(k,l) is an l^th sample of a k^th row of the sensed maps;
      
      S is an average value of the sensed map;
      
      S_m (i,j) is an average value of the SM subset which corresponds to reference maps (RM) code m at offset (i,j);
      
      N_s is equal to the number of samples in the sensed map minus a number of no-counts;
      
      N_m (i,j) is a number of sensed maps samples which correspond to reference maps code m at offset (i,j), reduced by a number of no counts which also correspond to m;
      
      γ
      
      _m is a variance of the sensed maps subset which corresponds to reference maps code m at offset (i,j);
      
      ##EQU19## is a sum over all sensed maps samples corresponding to reference maps code m at k, offset (i,j);
      
      K(i,j) is the scene signal-to-noise ratio (SNR) at offset (i,j); and
      
      φ
      
      ²_mv (i,j) is a j^th sample of an i^th row of the correlation function.

4. A map-matching aircraft navigation process which provides an identification of an update of an aircraft'"'"'s position in latitude land longitude, said map-matching navigation process comprising the steps of:
- identifying said aircraft'"'"'s last known position by acquiring it from said aircraft'"'"'s primary navigation system;
  
  acquiring a first sensed map of terrain beneath said aircraft by transmitting radio frequency signals in a point beam which sequentially strikes terrain beneath said aircraft in a pattern of points which forms a first rectangular matrix of rows and columns on terrain beneath said aircraft, said sensed map being composed of a first matrix of terrain echo return signals with varying intensities indicative of varying reflectivity coefficients of said terrain in said pattern of points in said first rectangular matrix of rows and columns;
  
  detecting a second sensed map of the terrain beneath said aircraft by transmitting radio frequency signals in a point beam which sequentially strikes terrain beneath said aircraft in a pattern of points which forms a second rectangular matrix of rows and columns on terrain beneath said aircraft, said sensed map being composed of a second matrix of terrain echo return signals indicative of varying terrain height of said terrain in said pattern of points in said second rectangular matrix of rows and columns;
  
  sensing a third sensed map of the terrain beneath said aircraft using a radiometer which is housed in said aircraft and which detects a radiometric temperature image of the terrain in a third rectangular matrix in a pattern of points to output said third sensed map of said terrain with varying measures of thermal emissions and reflected energy; and
  
  comparing said first, second and third sensed maps respectively with first, second and third stored reference maps which respectively contains third, fourth and fifth rectangular matrices of rows and columns indicaive of expected detected terrain signals from the terrain over which said aircraft is flying, said comparing step including finding a maximum correlation between said first, second and third sensed maps and said first, second and third stored reference maps to position said first second and third sensed maps respectively on said first, second and third reference maps, said comparing step thereby locating said aircraft on said first second and third reference map;
  
  identifying each point in said third, fourth and fifth rectangular matrices with a known corresponding latitude and longitude in order to extract and output said aircraft'"'"'s position in latitude and longitude from its location on said first, second, and third reference maps; and
  
  outputting said corresponding latitude and longtitude of said aircraft'"'"'s position on said stored reference maps to provide said update of said aircraft'"'"'s position.
- View Dependent Claims (5, 6)
- - 5. A map-matching navigation process, as defined in claim 4, wherein said acquiring step includes transmitting said radio frequency signals in an equidistance pattern on either side of the aircraft as well as ahead and behind the aircraft so that said aircraft is located at said first sensed map'"'"'s exact center, said acquiring step thereby enabling said aircraft'"'"'s position to be determined once said first sensed map is positioned on said first stored reference map in said comparing step.
  - 6. A map matching navigation process, as defined in claim 5, wherein said comparing step includes finding a maximum correlation between said first, second and third stored reference maps and said first, second and third sensed maps using a minimum variance correlation function in which the correlation of each point of said first, second and third sensed maps respectively with each point of said first, second and third reference maps is calculated to yield an offset, said offset indicating where said first, second and third sensed maps are positioned on said first, second and third stored referenced maps, said minimum variance correlation function comprising:
    - ##EQU20## where KC(i,j) is the scene signal-to-noise ratio given by;
      
      ##EQU21## S(k,l) is an l^th sample of a k^th row of the selected sensed maps;
      
      S is an average value of the sensed map;
      
      S_m (i,j) is an average value of the SM subset which corresponds to the reference map (RM) code m at offset (i,j);
      
      N_S is equal to the number of samples in the sensed map minus a number of no-counts;
      
      N_m (i,j) is a number of sensed maps samples which correspond to reference maps code m at offset (i,j), reduced by a number of no-counts which also correspond to m;
      
      γ
      
      _m is a variance of the sensed maps subset which corresponds to reference maps code m at offset (i,j);
      
      φ
      
      .sup..sub. mv (i,j) is a j^th sample of an i^th row of the correlation function;
      
      ##EQU22## is a sum over all sensed map samples corresponding to reference maps at code M at offset (i,j) andK(i,j) is the scene signal-to-noise ratio (SNR at offset (i,j).

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Current Assignee
The United States of America As Represented By The Secretary of Agriculture
Original Assignee
United States Of America As Represented By The Secretary Of The Air Force
Inventors
Love, Robert J., Campbell, Richard I.
Primary Examiner(s)
Tarcza, Thomas H.
Assistant Examiner(s)
Sotomayor, John B.

Application Number

US07/388,796
Time in Patent Office

256 Days
Field of Search

342/53, 342/64, 342/351
US Class Current

342/64
CPC Class Codes

G01C 21/005   with correlation of navigat...

G01S 13/86   Combinations of radar syste...

G01S 13/89   for mapping or imaging

Intensity area correlation addition to terrain radiometric area correlation

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Intensity area correlation addition to terrain radiometric area correlation

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6 Claims

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