The application of LiDAR to synthetic vision system integrity

Campbell, Jacob; Haag, Maarten Uijt de; Vadlamani, A.; Young, Steven D.

doi:10.1109/dasc.2003.1245911

Cited by 8 publications

(6 citation statements)

References 6 publications

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“…Earlier work [2,3,5,6] has used a downward-looking radar altimeter because most aircraft are already equipped with one. The applicability of light detection and ranging (LIDAR) was investigated in [7] and forward-looking, X-band weather radar, configured in terrain mapping mode is used in [8].…”

Section: Prior Work and Current Effortmentioning

confidence: 99%

Terrain Elevation Data Integrity Monitor and Referenced Navigation

Vadlamani

Haag

2009

Journal of Aerospace Computing, Information, and Communication

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Synthetic vision systems provide a synthesized view of the outside world to pilots on displays in the flight deck. Terrain databases onboard aircraft are used as the source of terrain elevation information on synthetic vision system displays. Because the primary function of these displays is to improve flight safety, it is imperative that the terrain data used to generate the imagery conform to a high level of integrity. Otherwise, instead of preventing accidents, the terrain database would be cause of more. Hence, it is necessary to include an integrity monitor function that ensures the terrain data are consistent with the real world. In this paper, we revisit previously proposed concepts and present the development of a 3D spatial data integrity monitor. The framework is also extended to a terrain referenced navigation scheme such that both operations can be performed simultaneously. Presented furthermore is a Kalman filter design and its associated tradeoffs for improving the performance of the integrity monitor and navigation functions. The performance of the integrity monitor and position estimator for navigation is evaluated using flight test data collected in the vicinity of Braxton County airport in West Virginia.

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Section: Prior Work and Current Effortmentioning

confidence: 99%

Terrain Elevation Data Integrity Monitor and Referenced Navigation

Vadlamani

Haag

2009

Journal of Aerospace Computing, Information, and Communication

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“…The measurement errors can be broken into two categories: ranging errors and scan angle errors [9]. In our paper, we will mainly focus on time errors.…”

Section: Laser Range Scanner Errorsmentioning

confidence: 99%

Time Error Correction For Laser Range Scanner Data

Bezet

Cherfaoui

2006

2006 9th International Conference on Information Fusion

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“…As was shown in [1], sole comparison of the vertical components of a real-time generated ALS point cloud with a LIDAR generated terrain database can lead to large, somewhat misleading errors in the presence of even small horizontal errors. The separation of features from the terrain in an ALS generated point cloud allows for processing of the terrain data separate from the feature data.…”

Section: Conclusion/future Workmentioning

confidence: 97%

“…In this paper it was shown that the integrity monitoring techniques used in the radar altimeter methods did not achieve the hypothesized system performance improvements because of the apparent 'noise' introduced to the system from features with sharp gradients like building and trees [1]. This paper distinguishes itself from previous research by identifying features, such as buildings, using the information contained in the high accuracy/high density ALS point cloud.…”

Section: Introductionmentioning

confidence: 94%

“…At the 2003 DASC, Ohio University first explored the use of an ALS based system to provide the terrain database integrity monitor function [1]. In this paper it was shown that the integrity monitoring techniques used in the radar altimeter methods did not achieve the hypothesized system performance improvements because of the apparent 'noise' introduced to the system from features with sharp gradients like building and trees [1].…”

Section: Introductionmentioning

confidence: 98%

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Feature Extraction and Separation in Airborne Laser Scanner Terrain Integrity Monitors

Venable

Campbell

Haag

24th Digital Avionics Systems Conference

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This paper describes the methodology and algorithms used in an implementation of a downward-looking Airborne Laser Scanner (ALS)-based terrain and feature integrity monitor. Using a high accuracy and high resolution ALS sensor, the described integrity monitor can first separate features from the terrain and then use the extracted feature data to detect and observe systematic and blunder errors in a terrain feature database. Two applications are envisioned for such a system-the first is to check the quality and update a terrain feature database and the second is as a real-time monitor on all aircraft which have systems that use terrain feature databases.Real-time terrain database integrity monitors have been studied at the Ohio University Avionics Engineering Center (AEC) for nearly 10 years. The feature integrity monitor is different from previous research performed at Ohio University in that it extracts specific features, such as buildings, roads, and towers, and performs a consistency check between these objects and a stored feature database.To perform the consistency check between the feature database and the ALS data a four-part building extraction algorithm is used. Once the high-frequency building shapes are extracted, they can be compared to the onboard feature database to determine changes and errors. The four-part building extraction algorithm described in this paper has the following characteristics: it works on non-uniformly spaced point-cloud data, it is designed for integrity monitoring rather than complete scene reconstruction, and the automatic feature extraction is not dependent on (but may use if available) a-priori feature shape information. This paper outlines the four-part building extraction algorithm and provides insight into its operation by applying the algorithms to ALS data collected on NASA's DC-8 Airborne Laboratory over Reno, Nevada in 2003.

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The application of LiDAR to synthetic vision system integrity

Cited by 8 publications

References 6 publications

Terrain Elevation Data Integrity Monitor and Referenced Navigation

Terrain Elevation Data Integrity Monitor and Referenced Navigation

Time Error Correction For Laser Range Scanner Data

Feature Extraction and Separation in Airborne Laser Scanner Terrain Integrity Monitors

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