Analytical evaluation of geometric dilution of precision for three-dimensional angle-of-arrival target localization in wireless sensor networks
Published 2020 View Full Article
- Home
- Publications
- Publication Search
- Publication Details
Title
Analytical evaluation of geometric dilution of precision for three-dimensional angle-of-arrival target localization in wireless sensor networks
Authors
Keywords
-
Journal
International Journal of Distributed Sensor Networks
Volume 16, Issue 5, Pages 155014772092047
Publisher
SAGE Publications
Online
2020-05-13
DOI
10.1177/1550147720920471
References
Ask authors/readers for more resources
Related references
Note: Only part of the references are listed.- Efficient Convex Solution for 3-D Localization in MIMO Radars Using Delay and Angle Measurements
- (2019) Seyed Amir Reza Kazemi et al. IEEE COMMUNICATIONS LETTERS
- Performance Metric on the Best Achievable Accuracy for Hybrid TOA/AOA Target Localization
- (2018) Yin-Ya Li et al. IEEE COMMUNICATIONS LETTERS
- Algebraic solution for three-dimensional TDOA/AOA localisation in multiple-input–multiple-output passive radar
- (2018) Ali Noroozi et al. IET Radar Sonar and Navigation
- Cramér–Rao Lower Bound on AoA Estimation Using an RF Lens-Embedded Antenna Array
- (2018) Jae-Nam Shim et al. IEEE Antennas and Wireless Propagation Letters
- Optimal Sensor Placement for 3-D Angle-of-Arrival Target Localization
- (2017) Sheng Xu et al. IEEE TRANSACTIONS ON AEROSPACE AND ELECTRONIC SYSTEMS
- Analysis of sensor-emitter geometry for emitter localisation using TDOA and FDOA measurements
- (2017) Yong-Hee Kim et al. IET Radar Sonar and Navigation
- Distributed Source Localization of Multi-Agent Systems With Bearing Angle Measurements
- (2016) Che Lin et al. IEEE TRANSACTIONS ON AUTOMATIC CONTROL
- Communication Aware Optimal Sensor Motion Coordination for Source Localization
- (2016) Wei Meng et al. IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT
- Continuous Singularity Free Approach to the Three-Dimensional Bearings-Only Tracking Problem
- (2016) Lorenz Schmitt et al. JOURNAL OF GUIDANCE CONTROL AND DYNAMICS
- Angle-of-Arrival Assisted GNSS Collaborative Positioning
- (2016) Bin Huang et al. SENSORS
- Geometric dilution of precision for bearing-only passive location in three-dimensional space
- (2015) Yu Zhong et al. ELECTRONICS LETTERS
- Observability analysis and enhancement of radome aberration estimation with line-of-sight angle-only measurement
- (2015) Min-Guk Seo et al. IEEE TRANSACTIONS ON AEROSPACE AND ELECTRONIC SYSTEMS
- Efficient Closed-Form Algorithms for AOA Based Self-Localization of Sensor Nodes Using Auxiliary Variables
- (2014) Hua-Jie Shao et al. IEEE TRANSACTIONS ON SIGNAL PROCESSING
- Elliptic Localization: Performance Study and Optimum Receiver Placement
- (2014) Liyang Rui et al. IEEE TRANSACTIONS ON SIGNAL PROCESSING
- Optimal sensor placement for target localisation and tracking in 2D and 3D
- (2013) Shiyu Zhao et al. INTERNATIONAL JOURNAL OF CONTROL
- Sensor Networks for Optimal Target Localization with Bearings-Only Measurements in Constrained Three-Dimensional Scenarios
- (2013) David Moreno-Salinas et al. SENSORS
- Observability Criteria for Angles-Only Navigation
- (2009) David C. Woffinden et al. IEEE TRANSACTIONS ON AEROSPACE AND ELECTRONIC SYSTEMS
- GDOP Analysis for Positioning System Design
- (2009) I. Sharp et al. IEEE TRANSACTIONS ON VEHICULAR TECHNOLOGY
- A closed-form formula for GPS GDOP computation
- (2008) Shing H. Doong GPS SOLUTIONS
- Strategies and techniques for node placement in wireless sensor networks: A survey
- (2007) Mohamed Younis et al. Ad Hoc Networks
- Optimal angular sensor separation for AOA localization
- (2007) Kutluyıl Doğançay et al. SIGNAL PROCESSING
Publish scientific posters with Peeref
Peeref publishes scientific posters from all research disciplines. Our Diamond Open Access policy means free access to content and no publication fees for authors.
Learn MoreCreate your own webinar
Interested in hosting your own webinar? Check the schedule and propose your idea to the Peeref Content Team.
Create Now