| A new approach to sensor node localization using RSS measurements in wireless sensor networks G Wang, K Yang IEEE transactions on wireless communications 10 (5), 1389-1395, 2011 | 309 | 2011 |
| Efficient convex relaxation methods for robust target localization by a sensor network using time differences of arrivals K Yang, G Wang, ZQ Luo IEEE transactions on signal processing 57 (7), 2775-2784, 2009 | 271 | 2009 |
| Non-line-of-sight node localization based on semi-definite programming in wireless sensor networks H Chen, G Wang, Z Wang, HC So, HV Poor IEEE Transactions on Wireless Communications 11 (1), 108-116, 2011 | 202 | 2011 |
| On received-signal-strength based localization with unknown transmit power and path loss exponent G Wang, H Chen, Y Li, M Jin IEEE Wireless Communications Letters 1 (5), 536-539, 2012 | 200 | 2012 |
| A semidefinite relaxation method for source localization using TDOA and FDOA measurements G Wang, Y Li, N Ansari IEEE transactions on vehicular technology 62 (2), 853-862, 2013 | 195 | 2013 |
| NLOS error mitigation for TOA-based localization via convex relaxation G Wang, H Chen, Y Li, N Ansari IEEE Transactions on Wireless Communications 13 (8), 4119-4131, 2014 | 177 | 2014 |
| Robust convex approximation methods for TDOA-based localization under NLOS conditions G Wang, AMC So, Y Li IEEE Transactions on Signal processing 64 (13), 3281-3296, 2016 | 169 | 2016 |
| An importance sampling method for TDOA-based source localization G Wang, H Chen IEEE Transactions on Wireless Communications 10 (5), 1560-1568, 2011 | 133 | 2011 |
| Robust NLOS error mitigation method for TOA-based localization via second-order cone relaxation S Zhang, S Gao, G Wang, Y Li IEEE Communications Letters 19 (12), 2210-2213, 2015 | 95 | 2015 |
| A bias-reduced nonlinear WLS method for TDOA/FDOA-based source localization G Wang, S Cai, Y Li, N Ansari IEEE Transactions on Vehicular Technology 65 (10), 8603-8615, 2015 | 83 | 2015 |
| Robust TDOA-based localization for IoT via joint source position and NLOS error estimation G Wang, W Zhu, N Ansari IEEE Internet of Things Journal 6 (5), 8529-8541, 2019 | 75 | 2019 |
| Convex Relaxation Methods for Unified Near-Field and Far-Field TDOA-Based Localization G Wang, KC Ho IEEE Transactions on Wireless Communications 18 (4), 2346-2360, 2019 | 72 | 2019 |
| Improved robust TOA-based localization via NLOS balancing parameter estimation H Chen, G Wang, N Ansari IEEE Transactions on Vehicular Technology 68 (6), 6177-6181, 2019 | 68 | 2019 |
| Nearly optimal sensor selection for TDOA-based source localization in wireless sensor networks Z Dai, G Wang, X Jin, X Lou IEEE Transactions on Vehicular Technology 69 (10), 12031-12042, 2020 | 55 | 2020 |
| Robust weighted least squares method for TOA-based localization under mixed LOS/NLOS conditions W Wang, G Wang, J Zhang, Y Li IEEE Communications Letters 21 (10), 2226-2229, 2017 | 52 | 2017 |
| A semidefinite relaxation method for energy-based source localization in sensor networks G Wang IEEE Transactions on Vehicular Technology 60 (5), 2293-2301, 2011 | 51 | 2011 |
| Second-order cone relaxation for TOA-based source localization with unknown start transmission time G Wang, S Cai, Y Li, M Jin IEEE transactions on vehicular technology 63 (6), 2973-2977, 2013 | 46 | 2013 |
| Accurate semidefinite relaxation method for elliptic localization with unknown transmitter position R Zheng, G Wang, KC Ho IEEE Transactions on Wireless Communications 20 (4), 2746-2760, 2020 | 43 | 2020 |
| Least squared relative error estimator for RSS based localization with unknown transmit power J Shi, G Wang, L Jin IEEE Signal Processing Letters 27, 1165-1169, 2020 | 43 | 2020 |
| Sensor network-based rigid body localization via semi-definite relaxation using arrival time and Doppler measurements J Jiang, G Wang, KC Ho IEEE Transactions on Wireless Communications 18 (2), 1011-1025, 2019 | 41 | 2019 |
Dominic KC HoUniversity of Missouri在 missouri.edu 的电子邮件经过验证
