Data compression and decompression for digital radar landmass simulation

US 4,890,249 A
Filed: 03/16/1988
Issued: 12/26/1989
Est. Priority Date: 03/16/1988
Status: Expired due to Fees

First Claim

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1. A method of real time data retrieval in data radar landmass simulation comprising the steps of:

compressing off line digital feature analysis and digital terrain elevation data as compressed aspect, elevation and reflectivity data bases for the simulation;

separately storing the compressed aspect, elevation and reflectivity data bases for later access and decompression for the simulation;

synchronously and continuously accessing the compressed aspect, elevation and reflectivity data and decompressing and temporarily storing the decompressed data;

generating radar incident vectors;

processing the temporarily stored aspect data to produce surface normals and calculating vector dot products between said radar incident vectors and the surface normals to generate radar aspect returns;

processing the temporarily stored elevation data and calculating shadowing due to elevation and slant range as a function of ground range; and

processing the temporarily stored reflectivity data, the calculated radar aspect returns, shadowing and slant range and calculating terrain radar return.

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Abstract

A unique digital radar landmass simulator (DRLMS) uses different culture data compression techniques and hardware from that used in the conventional DRLMS systems. The application of these techniques to DRLMS results in a system that is small in size and high in performance. During the data base preparation, Defense Mappinig Agency (DMA) Digital Terrain Elevation Data (DTED) and Digital Feature Analysis (DFAD) data are processed and compressed for elevation, reflectivity and aspect channels with different compression schemes. The compressed data is then stored on disks for each channel. Dedicated decompression hardware for each channel then retrieves, decompresses, and reconstructs the data. The culture compression and decompression hardware uses a run length compression technique that results in the capability of presenting a very detailed culture map for the terrain. The elevation compression uses a table look-up technique that generates high resolution terrain data. The coordination of the timing of the several channels in order to generate the final display is accomplished by designating one of the channels as a master channel to maintain synchronism among the channels.

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12 Claims

1. A method of real time data retrieval in data radar landmass simulation comprising the steps of:
- compressing off line digital feature analysis and digital terrain elevation data as compressed aspect, elevation and reflectivity data bases for the simulation;
  
  separately storing the compressed aspect, elevation and reflectivity data bases for later access and decompression for the simulation;
  
  synchronously and continuously accessing the compressed aspect, elevation and reflectivity data and decompressing and temporarily storing the decompressed data;
  
  generating radar incident vectors;
  
  processing the temporarily stored aspect data to produce surface normals and calculating vector dot products between said radar incident vectors and the surface normals to generate radar aspect returns;
  
  processing the temporarily stored elevation data and calculating shadowing due to elevation and slant range as a function of ground range; and
  
  processing the temporarily stored reflectivity data, the calculated radar aspect returns, shadowing and slant range and calculating terrain radar return.
- View Dependent Claims (2, 3, 4)
- - 2. The method recited in claim 1 further comprising the step of inserting target aspect and reflectivity information in the oaloulated terrain radar return at corresponding range positions.
  - 3. The method recited in claim 1 wherein the step of compressing includes compressing off line weather data as a compressed weather data base for the simulation, said compressed weather data base being separately stored for later access and decompression for the simulation, further comprising the step of synchronously and continuously accessing the compressed weather data and decompressing and temporarily storing the data, said step of calculating the terrain radar return including processing said temporarily stored weather data and modifying the calculated radar return based on the weather data.
  - 4. The method recited in claim 1 wherein said reflectivity data is run length compressed, said elevation data is compressed by a differential coding technique, and said aspect data is compressed using a combination of run length coding and differential coding.

5. A digital radar landmass simulator comprising:
- first, second and third channels for storing respectively compressed aspect, elevation and reflectivity data and synchronously and continuously retrieving and decompressing said compressed data in real time, each of said channels including a microprocessor operating as a channel controller, the microprocessors of said channels being connected to a common bus, one of said microprocessors being a master microprocessor and maintaining synchronism of said channels;
  
  means for generating a scan and depression angles and computing radar incident vectors;
  
  aspect computer means connected to said first channel and responsive to decompressed aspect data for processing the data to produce surface normals and calculating vector dot products between said radar incident vectors and the surface normals to generate radar aspect returns;
  
  shadowing and converter means connected to said second channel and responsive to decompressed elevation data for calculating shadowing due to elevation and slant range as a function of ground range;
  
  radar equation means connected to said third channel, said aspect computer means and said shadowing and converter means and responsive to decompressed reflectivity data, said calculated radar aspect returns, shadowing and slant range for calculating terrain radar returns; and
  
  display means connected to said radar equation means and responsive to said calculated terrain radar returns for displaying a simulated radar image.
- View Dependent Claims (6, 7, 8, 9, 10, 11, 12)
- - 6. The digital radar landmass simulator recited in claim 5 further comprising target generator means connected to said radar equation means for inserting target aspect and reflectivity information in the calculated terrain radar return at corresponding range positions.
  - 7. The digital radar landmass simulator recited in claim 5 wherein each of said first, second and third channels comprises:
    - direct access storage means for storing compressed data;
      
      dedicated decompressor means for decompressing said compressed data, said microprocessor accessing compressed data stored in said direct access storage means and supplying the data to said dedicated decompressor means; and
      
      image memory means connected to said dedicated decompressor means for temporarily storing decompressed data, said image memory means including first and second memory areas, data being read from one of said areas as data is written to the other of said areas and then vice versa in alternate data memory cycles.
  - 8. The digital radar landmass simulator as recited in claim 7 further comprising general purpose data processing means for compressing off line digital feature analysis and digital terrain elevation data as compressed aspect, elevation and reflectivity data and temporarily storing said compressed data on the direct access storage devices of said first, second and third channels, respectively.
  - 9. The digital radar landmass simulator as recited in claim 8 wherein said compressed reflectivity data is run length compressed and wherein said dedicated decompressor of said third channel is a run length decompressor.
  - 10. The digital radar landmass simulator as recited in claim 9 wherein said compressed elevation data is compressed using a differential coding technique and said dedicated decompressor of said second channel is a differential code decompressor.
  - 11. The digital radar landmass simulator as recited in claim 9 wherein said compressed aspect data is compressed using a combination of run length compression and a differential coding technique and said dedicated decompressor in said first channel is a hybrid run length and differential decompressor.
  - 12. The digital radar landmass simulator as recited in claim 5 further comprising:
    - a fourth channel for storing compressed weather data and synchronously and continuously retrieving and decompressing said compressed data in real time, said fourth channel including a microprocessor operating as a channel controller and connected to said common bus; and
      
      weather attenuator means connected to said fourth channel for receiving said decompressed weather data and providing an output to said radar equation means to modify said calculated terrain radar returns.

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Current Assignee
Rediffusion Simulation Incorporated
Original Assignee
Hughes Simulation Systems Incorporated (Rtx Corporation)
Inventors
Yen, Craig S.
Primary Examiner(s)
Gruber, Felix D.

Application Number

US07/168,768
Time in Patent Office

650 Days
Field of Search

364/516, 364/518, 364/522, 364/578, 434/2, 434/3, 382/56
US Class Current

703/13
CPC Class Codes

G06T 15/10 Geometric effects

G09B 9/54 Simulation of radar G09B9/4...

Data compression and decompression for digital radar landmass simulation

First Claim

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Abstract

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Data compression and decompression for digital radar landmass simulation

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