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Daichi Kominami
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2020 – today
- 2024
- [c28]Amato Otsuki, Daichi Kominami, Hideyuki Shimonishi, Masayuki Murata, Tatsuya Otoshi:
Adaptive Network Slicing Control Method for Unpredictable Network Variations Using Quality-Diversity Algorithms. CCNC 2024: 819-822 - [c27]Keita Hara, Risa Yoshida, Daichi Kominami, Yuichi Ohsita, Michiko Kaihotsu, Masayuki Murata:
Indoor environment control method for improving well-being using human thermal stress estimated by Yuragi learning. ICCE 2024: 1-6 - [c26]Seishiro Inoue, Masaaki Yamauchi
, Daichi Kominami, Hideyuki Shimonishi, Masayuki Murata:
Genetic Algorithm with Gene Regulatory Networks Based Optimization Method for Distributed Video Analysis System. ICIN 2024: 257-264 - [c25]Haruhito Ando, Daichi Kominami, Ryoga Seki, Masayuki Murata, Hideyuki Shimonishi:
Multimodal Object Recognition Using Bayesian Attractor Model for 2D and 3D data. ICIN 2024: 272-278 - 2023
- [j17]Betty Wutzl
Analysis of the Correlation between Frontal Alpha Asymmetry of Electroencephalography and Short-Term Subjective Well-Being Changes. Sensors 23(15): 7006 (2023) - 2022
- [c24]Ryoga Seki, Daichi Kominami, Hideyuki Shimonishi, Masayuki Murata, Masaya Fujiwaka:
Object Estimation Method for Edge Devices Inspired by Multimodal Information Processing in the Brain. CCNC 2022: 945-946 - [c23]Ryoga Seki, Daichi Kominami, Hideyuki Shimonishi, Masayuki Murata, Masaya Fujiwaka:
Multi-Object Recognition Method Inspired by Multimodal Information Processing in the Human Brain. GLOBECOM (Workshops) 2022: 569-574 - [c22]Yuki Fujita, Daichi Kominami, Hideyuki Shimonishi, Masayuki Murata:
Spreading Factor Allocation Method Adaptive to Changing Environments for LoRaWAN Based on Thermodynamical Genetic Algorithm. IWCMC 2022: 796-801 - [c21]Ryoga Seki, Daichi Kominami, Hideyuki Shimonishi, Masayuki Murata, Masaya Fujiwaka:
Realtime Object Recognition Method Inspired by Multimodal Information Processing in the Brain for Distributed Digital Twin Systems. IWCMC 2022: 913-918 - [c20]Daichi Kominami, Sayaka Nishide, Satoshi Nishimura, Tatsuya Otoshi, Masaaki Kurozumi, Daiki Fukudome, Masao Yamamoto, Masayuki Murata:
Choice-supportive bias affects video viewing experience: Subjective experiment and evaluation. IWQoS 2022: 1-6 - 2020
- [c19]Daichi Kominami, Yohei Hasegawa
Bayesian-based channel quality estimation method for LoRaWAN with unpredictable interference. GLOBECOM 2020: 1-7
2010 – 2019
- 2019
- [j16]Mari Otokura
Evolvable Virtual Network Function Placement Method: Mechanism and Performance Evaluation. IEEE Trans. Netw. Serv. Manag. 16(1): 27-40 (2019) - [c18]Masayoshi Iwamoto, Tatsuya Otoshi, Daichi Kominami, Masayuki Murata:
Rate adaptation with Bayesian attractor model for MPEG-DASH. CCWC 2019: 859-865 - [c17]Yushi Hosokawa, Yasuharu Hirano, Daichi Kominami, Ikkyu Aihara, Masayuki Murata:
Implementation of a real-time sound source localization method for outdoor animal detection using wireless sensor networks. ICSPCS 2019: 1-6 - 2018
- [j15]Takanori Iwai, Daichi Kominami, Masayuki Murata, Ryogo Kubo, Kozo Satoda
Mobile Network Architectures and Context-Aware Network Control Technology in the IoT Era. IEICE Trans. Commun. 101-B(10): 2083-2093 (2018) - [j14]Masaya Murakami
Drawing Inspiration from Human Brain Networks: Construction of Interconnected Virtual Networks. Sensors 18(4): 1133 (2018) - [j13]Naomi Kuze
Hierarchical Optimal Control Method for Controlling Large-Scale Self-Organizing Networks. ACM Trans. Auton. Adapt. Syst. 12(4): 22:1-22:23 (2018) - [j12]Naomi Kuze
Self-Organizing Control Mechanism Based on Collective Decision-Making for Information Uncertainty. ACM Trans. Auton. Adapt. Syst. 13(1): 7:1-7:21 (2018) - [c16]Naomi Kuze
Self-Organizing Control Mechanisms According to Information Confidence for Improving Performance. GLOBECOM 2018: 1-6 - 2017
- [j11]Masaya Murakami
Robustness and efficiency in interconnected networks with changes in network assortativity. Appl. Netw. Sci. 2: 6 (2017) - [j10]Shinya Toyonaga, Daichi Kominami, Masayuki Murata:
Percolation analysis for constructing a robust modular topology based on a binary-dynamics model. Int. J. Distributed Sens. Networks 13(4) (2017) - [c15]Daichi Kominami, Takanori Iwai, Hideyuki Shimonishi, Masayuki Murata:
A control method for autonomous mobility management systems toward 5G mobile networks. ICC Workshops 2017: 498-503 - [c14]Masaya Murakami, Kenji Leibnitz, Daichi Kominami, Tetsuya Shimokawa, Masayuki Murata:
Constructing virtual IoT network topologies with a brain-inspired connectivity model. IMCOM 2017: 78 - [c13]Masaya Murakami, Kenji Leibnitz, Daichi Kominami, Masayuki Murata:
Designing interconnected networks for improving robustness and efficiency. LANMAN 2017: 1-6 - [c12]Saeko Shigaki, Naomi Kuze
Self-organizing wireless sensor networks based on biological collective decision making for treating information uncertainty. WiMob 2017: 167-174 - 2016
- [j9]Shinya Toyonaga, Daichi Kominami, Masayuki Murata:
Virtual Wireless Sensor Networks: Adaptive Brain-Inspired Configuration for Internet of Things Applications. Sensors 16(8): 1323 (2016) - [j8]Naomi Kuze
Controlling Large-Scale Self-Organized Networks with Lightweight Cost for Fast Adaptation to Changing Environments. ACM Trans. Auton. Adapt. Syst. 11(2): 9:1-9:26 (2016) - [c11]Mari Otokura, Kenji Leibnitz, Yuki Koizumi, Daichi Kominami, Tetsuya Shimokawa, Masayuki Murata:
Impact of Fluctuating Goals on Adaptability of Evolvable VNF Placement Method. CANDAR 2016: 304-310 - [c10]Mari Otokura, Kenji Leibnitz, Yuki Koizumi
Application of evolutionary mechanism to dynamic Virtual Network Function Placement. ICNP 2016: 1-6 - 2015
- [c9]Naomi Kuze, Daichi Kominami, Kenji Kashima, Tomoaki Hashimoto, Masayuki Murata
Hierarchical Optimal Control Method for Controlling Self-Organized Networks with Light-Weight Cost. GLOBECOM 2015: 1-7 - 2014
- [j7]Naomi Kuze
A predictive mechanism for enhancing adaptability of self-organised routing. Int. J. Bio Inspired Comput. 6(6): 384-396 (2014) - [c8]Takuya Iwai, Daichi Kominami, Masayuki Murata
Thermodynamics-Based Entropy Adjustment for Robust Self-Organized Network Controls. COMPSAC 2014: 636-637 - [c7]Takuya Iwai, Daichi Kominami, Masayuki Murata
Thermodynamics-Based Strategy to Achieve Balance between Robustness and Performance for Self-Organized Network Controls. SASO 2014: 181-182 - [c6]Naomi Kuze
Enhancing Convergence with Optimal Feedback for Controlled Self-Organizing Networks. VTC Fall 2014: 1-7 - 2013
- [j6]Chuluunsuren Damdinsuren, Daichi Kominami, Masashi Sugano
Lifetime extension based on residual energy for receiver-driven multi-hop wireless network. Clust. Comput. 16(3): 469-480 (2013) - [j5]Shinya Toyonaga, Daichi Kominami, Masashi Sugano
Potential-based routing for supporting robust any-to-any communication in wireless sensor networks. EURASIP J. Wirel. Commun. Netw. 2013: 278 (2013) - [j4]Daichi Kominami, Masayuki Murata
A Design Approach for Controlled Self-Organization-Based Sensor Networks Focused on Control Timescale. Int. J. Distributed Sens. Networks 9 (2013) - [j3]Daichi Kominami, Masashi Sugano
Controlled and self-organized routing for large-scale wireless sensor networks. ACM Trans. Sens. Networks 10(1): 13:1-13:27 (2013) - 2012
- [j2]Daichi Kominami, Masashi Sugano
Robust and Resilient Data Collection Protocols for Multihop Wireless Sensor Networks. IEICE Trans. Commun. 95-B(9): 2740-2750 (2012) - [c5]Tadashi Hayamizu, Daichi Kominami, Masashi Sugano
Performance improvement by collision avoidance of control packets in receiver-driven multihop wireless mesh networks. MASS 2012: 473-474 - 2011
- [j1]Daichi Kominami, Masashi Sugano
Energy-Efficient Receiver-Driven Wireless Mesh Sensor Networks. Sensors 11(1): 111-137 (2011) - [c4]Chuluunsuren Damdinsuren, Daichi Kominami, Masayuki Murata
Lifetime extension based on residual energy for receiver-driven multi-hop wireless network. HPCS 2011: 442-448 - [c3]Daichi Kominami, Masashi Sugano
Controlled potential-based routing for large-scale wireless sensor networks. MSWiM 2011: 187-196 - 2010
- [c2]Daichi Kominami, Masashi Sugano
Energy Saving in Intermittent Receiver-Driven Multi-hop Wireless Sensor Networks. SUTC/UMC 2010: 296-303
2000 – 2009
- 2009
- [c1]Daichi Kominami, Masashi Sugano
Performance evaluation of intermittent receiver-driven data transmission on wireless sensor networks. ISWCS 2009: 141-145
Coauthor Index
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