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IPIN 2019: Pisa, Italy
- Francesco Potortì, Valérie Renaudin, Kyle O'Keefe, Filippo Palumbo:
Short Paper Proceedings of the Tenth International Conference on Indoor Positioning and Indoor Navigation - Work-in-Progress Papers (IPIN-WiP 2019) co-located with the Tenth International Conference on Indoor Positioning and Indoor Navigation (IPIN 2019), Pisa, Italy, September 30th - October 3rd, 2019. CEUR Workshop Proceedings 2498, CEUR-WS.org 2019
Short Papers
- Juri Sidorenko, Volker Schatz, Norbert Scherer-Negenborn, Michael Arens, Urs Hugentobler:
Fusion of time of arrival and time difference of arrival for ultra-wideband indoor localization. 1-8 - Yew Fei Tang:
Pixel-based map matching algorithm for pedestrian dead reckoning system. 9-16 - Phong Xuan Nguyen, Takayuki Akiyama:
Indoor crowd density estimation for efficient monitoring system. 17-24 - Sila Guler, F. Serhan Danis, Ali Taylan Cemgil:
Radio map estimation with neural networks and active learning for indoor localization. 25-31 - Jing Jing Wang, Jun Gyu Hwang, Joon Goo Park:
A novel indoor ranging algorithm based on received signal strength and channel state information. 32-39 - Yangkang Yu, Ling Yang:
A probabilistic fingerprinting method for indoor localization based on RBF network. 40-47 - Feryel Zoghlami, Harald Heinrich, Germar Schneider, Mohamed Ali Hamdi:
Tracking body motions in order to guide a robot using the time of flight technology. 48-55 - Imran Ashraf, Soojung Hur, Yongwan Park:
Smartphone sensors based indoor localization using deep neural networks. 56-63 - Alexandre Vervisch, Nel Samama:
Delta range positioning assisted with satellites. 64-71 - Kengo Teramoto, Ryo Mukainakano, Hiroki Watanabe, Hiromichi Hashizume, Masanori Sugimoto:
3D tracking using smartphones for a marker-based optical motion capture system. 72-79 - Mickael Delamare, Rémi Boutteau, Xavier Savatier, Nicolas Iriart:
Evaluation of a UWB localization system in static and dynamic. 80-86 - Susanna Kaiser:
Successive collaborative SLAM for professional use cases: map learning aspects. 87-94 - Raúl Montoliu, Emilio Sansano-Sansano, Arturo Gascó, Oscar Belmonte, Antonio Caballer:
Senior monitoring: a real case of applying a WiFi fingerprinting-based indoor positioning method for people monitoring. 95-102 - Daichi Kitamura, Naoki Honma, Kazushi Naruke, Atsushi Miura, Yusuke Sugawara:
RSSI-ranging method using pattern diversity and distance-based reliability function. 103-108 - Pedro Álvarez, Noelia Hernández, Fco Javier Fabra, Manuel Ocaña:
A cloud-based parallel system for locating customers in indoor malls. 109-116 - Xinchun Ji, Dongyan Wei, Wen Li, Yi Lu, Hong Yuan:
A GM/DR integrated navigation scheme for road network application. 117-124 - Jose Antonio Lopez-Pastor, Antonio Gómez-Alcaraz, David Cañete-Rebenaque, Alejandro Santos Martínez-Sala, José Luis Gómez-Tornero:
Performance evaluation of direction of arrival RSSI monopulse function in an indoor location system for different Wi-Fi mobile devices. 125-132 - Valentín Barral, Carlos J. Escudero, Pedro Suárez-Casal, José Antonio García-Naya:
Impact of NLOS identification on UWB-based localization systems. 133-140 - Janek Stoeck, Harald Sternberg:
Indoor navigation for a library. 141-148 - Gergely Zachár, Gergely Vakulya, Gyula Simon:
Azimuth estimation for indoor localization using redundant planar circular photodiode array. 149-156 - Wonjoon Son, Lynn Choi:
Vector calibration for magnetic field based indoor localization. 157-164 - Timothy Otim, Luis Enrique Díez, Alfonso Bahillo, Peio López-Iturri, Francisco Falcone:
A comparison of human body wearable sensor positions for UWB-based indoor localization. 165-171 - Chandra Tjhai, Kyle O'Keefe:
Pedestrian dead-reckoning using multiple low-cost inertial/magnetic sensors on lower limbs. 172-179 - Ehab Ghanem, Kyle O'Keefe, Richard Klukas:
Estimating vehicle-to-vehicle relative position and attitude using multiple UWB ranges. 180-186 - Edward T.-H. Chu, Shih-Chia Wang, Chao-Chun Chang, Jane Win-Shih Liu, Jiun Hsu, Hui-Mei Wu:
WPIN: A waypoint-based indoor navigation system. 187-194 - Henk G. Kortier:
In use IMU calibration and pose estimation. 195-202 - Jiazhi Han, Fuxing Yang, Ke Han, Zhongliang Deng, Jingwen Jiang, Jiawen Zhang, Lingjie Shi, Xiao Fu, Jiawei Fu:
5G networks three-dimensional indoor positioning based on improved Chan algorithm. 203-210 - Nico Podevijn, David Plets, Michiel Aernouts, Rafael Berkvens, Luc Martens, Maarten Weyn, Wout Joseph:
Experimental TDoA localisation in real public LoRa networks. 211-218 - Ki-Joune Li, Dean Hintz, Nakju Lett Doh, Mohsen Kalantari, Sung-Hwan Kim, Jeb Benson, Bart De Lathouwer, Scott Serich:
From point cloud to IndoorGML. 219-226 - Vincenzo Di Pietra, Paolo Dabove, Marco Piras, Andrea Lingua:
Evaluation of positioning and ranging errors for UWB indoor applications. 227-234 - Masanari Nakamura, Hiroshi Kameda:
Indoor localization using multiple stereo speakers for smartphones. 235-242 - Yury Bolotin, Alexander Bragin, Ilya Gartseev:
Covariance error analysis for pedestrian dead reckoning with foot mounted IMU. 243-250 - Sara Alshamsi, Ubaid Ahmad, James Aweya, Nawaf I. Almoosa:
A recursive NLOS bias estimation and correction algorithm. 251-258 - Binghao Li, Kai Zhao, Serkan Saydam, Chris Rizos, Qiang Wang, Jian Wang:
Investigation of indoor positioning technologies for underground mine environments. 259-266 - María del Carmen Pérez, David Gualda, Jorge De Vicente-Ranera, José Manuel Villadangos, Jesús Ureña:
Review of UAV positioning in indoor environments and new proposal based on US measurements. 267-274 - Zhan Wang, Xun Zhang, Alain Lambert, Lina Shi, Wenxiao Wang:
A set-membership approach for visible light positioning with fluctuated RSS measurements. 275-282 - Manish Kumar, Kapil Saini, Thierry Roussel:
User requirements for indoor geo-localization system for manufacturing shop floor and selection of appropriate product. 283-290 - Hucheng Wang, Lei Zhang, Zhi Wang, Xiaonan Luo:
Pals: high-accuracy pedestrian localization with fusion of smartphone acoustics and PDR. 291-298 - Yael Landau, Boaz Ben-Moshe, Revital Marbel:
STEPS - indoor visual navigation framework for mobile devices. 299-306 - Miguel Omeñaca Muro, Marouan Mizmizi, Luca Reggiani:
Binary fingerprinting-based positioning systems with uncertainty regions. 307-314 - Francisco Ciudad, Álvaro Hernández, David Gualda, Elena Aparicio-Esteve:
Design and implementation of a remotely configurable ultrasonic local positioning systems. 315-322 - Stefan Knauth:
Smartphone indoor positioning using WiFi, PDR, magnetic fingerprints and particle filtering. 323-330 - Pasungili Ramakrishnan, Herman C. Myburgh:
Mean-offset classifier based Wi-Fi indoor positioning system. 331-338 - Nimalika Fernando, David A. McMeekin, Iain Murray:
Modelling indoor spaces to support vision impaired navigation using an ontology based approach. 339-346 - Howard Fan, Anusha Kilari, Krishna Vemuri, Isaac Daffron, Julian Wang, Vijayavignesh Ramamurthy:
Indoor location for emergency responders using LTE D2D communications waveform. 347-354 - David Gualda, Jesús Ureña, Juan Jesús García, Ana Jiménez, María del Carmen Pérez, Francisco Ciudad:
Coverage analysis of an ultrasonic local positioning system according to the angle of inclination of the beacons structure. 355-361 - David Gualda, José Manuel Villadangos, Jesús Ureña, Antonio Ramón Jiménez Ruiz, Fernando Seco, Álvaro Hernández:
Indoor positioning in large environments: ultrasonic and UWB technologies. 362-369 - Jae Hong Lee, So Young Park, Seong Yun Cho, Chan Gook Park:
Reduction of heading error using dual foot-mounted IMU. 370-376 - Xiaoxuan Wang, Peng Sun, Minlin Chen, Hucheng Wang, Zhi Wang:
A 3-D cooperative base station localization method applied in large complex indoor environment. 377-384 - Takumi Otsuki, Kohei Kanagu, Kota Tsubouchi, Nobuhiko Nishio:
Daily action dead reckoning using smartphone sensors. 385-392 - So Young Park, Jae Hong Lee, Hyunwoong Kang, Chan Gook Park:
Fusion of integration and parametric approach in smartphone-based system for multi-pose. 393-399 - Takayuki Saki, Akihito Hiromori, Hirozumi Yamaguchi, Teruo Higashino:
Occlusion-based trajectory estimation for pedestrians using LiDAR sensors. 400-407 - Shoichi Iizuka, Takeshi Nakayama, Dai Sasakawa, Naoki Honma:
Non-restraint human authentication using MIMO array. 408-415 - Juan Diego Gutiérrez Gallardo, Fernando Aranda-Polo, Teodoro Aguilera Benítez, Fernando Álvarez Franco:
LIMUS: exploration of technological prototypes for location-based services in museums. 416-422 - Yudai Nagama, Takeshi Umezawa, Noritaka Osawa:
Indoor localization based on analysis of environmental ultrasound. 423-430 - Fernando Aranda-Polo, José Parades, Teodoro Aguilera Benítez, Fernando Álvarez Franco:
Improving BLE deterministic fingerprinting by using a weighted k-NN algorithm over filtered RSSI data. 431-438 - Zhaoxu Lu, Fang Zhao, Haiyong Luo, Qu Wang, Wenhua Shao:
A destination prediction algorithm using spatial temporal bidirectional LSTM networks. 439-446 - Chuanhua Lu, Hideaki Uchiyama, Diego Thomas, Atsushi Shimada, Rin-Ichiro Taniguchi:
Multi-pedestrian tracking system based on asynchronized IMUs. 447-454 - Byungmun Kang, Jiseung Jung, DaeEun Kim:
Indoor magnetic positioning with an array of magnetic field sensors. 455-462 - Nobuo Kawaguchi, Junto Nozaki, Takuto Yoshida, Kei Hiroi, Takuro Yonezawa, Katsuhiko Kaji:
End-to-end walking speed estimation method for smartphone PDR using DualCNN-LSTM. 463-470 - Yuqin Wang, Biyu Tang, Lingxiang Zheng, Zhichao Lin:
Autonomous integrity monitoring of a vision based pedestrian dead reckoning system. 471-478
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