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Miralda Cuka
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2020 – today
- 2021
- [j16]Miralda Cuka
, Donald Elmazi
Application of fuzzy logic for IoT node elimination and selection in opportunistic networks: performance evaluation of two fuzzy-based systems. World Wide Web 24(3): 929-940 (2021) - 2020
- [j15]Donald Elmazi
Effect of Size of Giant Component for actor node selection in WSANs: A comparison study. Concurr. Comput. Pract. Exp. 32(8) (2020) - [j14]Donald Elmazi
A fuzzy-based approach for event evaluation and actor selection in WSANs. Internet Things 11: 100252 (2020) - [c47]Donald Elmazi
Effect of Task Accomplishment for Actor Node Selection in WSANs: Performance Evaluation and a Comparison Study. AINA 2020: 476-487 - [c46]Miralda Cuka, Donald Elmazi
A Fuzzy Based Simulation System for IoT Node Selection in an Opportunistic Network Considering IoT Node's Unique Encounters as a New Parameter. AINA 2020: 488-498 - [c45]Donald Elmazi
An Event Response Fuzzy-Based System for Actor Node Selection in WSANs. CISIS 2020: 54-62 - [c44]Donald Elmazi
A Fuzzy-Based System for Actor Node Selection in WSANs Considering Task Accomplishment Time as a New Parameter. EIDWT 2020: 53-63 - [c43]Miralda Cuka, Donald Elmazi
IoT Node Selection in Opportunistic Networks: A Fuzzy-Based Approach Considering Node's Successful Delivery Ratio (NSDR) as a New Parameter. EIDWT 2020: 64-72 - [c42]Miralda Cuka, Donald Elmazi
IoT Node Elimination and Selection for Completing Tasks in Opportunistic Networks: A Fuzzy Logic Approach. IMIS 2020: 11-22 - [c41]Miralda Cuka, Donald Elmazi
A Decision-Making System Based on Fuzzy Logic for IoT Node Selection in Opportunistic Networks Considering Node Betweenness Centrality as a New Parameter. INCoS 2020: 36-43 - [c40]Donald Elmazi
Application of Fuzzy Logic for Event Evaluation in WSANs. NBiS 2020: 461-469
2010 – 2019
- 2019
- [j13]Miralda Cuka
IoT node selection in Opportunistic Networks: Implementation of fuzzy-based simulation systems and testbed. Internet Things 8 (2019) - [j12]Miralda Cuka, Donald Elmazi
Implementation and performance evaluation of two fuzzy-based systems for selection of IoT devices in opportunistic networks. J. Ambient Intell. Humaniz. Comput. 10(2): 519-529 (2019) - [j11]Donald Elmazi
Application of Fuzzy Logic for Selection of Actor Nodes in WSANs - Implementation of Two Fuzzy-Based Systems and a Testbed. Sensors 19(24): 5573 (2019) - [c39]Donald Elmazi
Effect of Degree of Centrality Parameter on Actor Selection in WSANs: A Fuzzy-Based Simulation System and Its Performance Evaluation. 3PGCIC 2019: 35-46 - [c38]Donald Elmazi
A Fuzzy-Based System for Actor Node Selection in WSANs Considering Level of Received Signal. AINA 2019: 238-250 - [c37]Miralda Cuka, Donald Elmazi
Selection of IoT Devices in Opportunistic Networks: A Fuzzy-Based Approach Considering IoT Device's Selfish Behaviour. AINA 2019: 251-264 - [c36]Miralda Cuka, Donald Elmazi
A Fuzzy-Based Simulation System for IoT Node Selection in Opportunistic Networks and Testbed Implementation. BWCCA 2019: 32-43 - [c35]Miralda Cuka, Donald Elmazi
IoT Node Selection and Placement: A New Approach Based on Fuzzy Logic and Genetic Algorithm. CISIS 2019: 22-35 - [c34]Donald Elmazi
A Fuzzy-Based System for Selection of Actor Nodes in WSANs Considering Actor Reliability and Load Distribution. EIDWT 2019: 25-38 - [c33]Miralda Cuka, Donald Elmazi
IoT Device Selection in Opportunistic Networks: A Fuzzy Approach Considering IoT Device Failure Rate. EIDWT 2019: 39-52 - [c32]Donald Elmazi
A Fuzzy-Based System for Actor Node Selection in WSANS: Simulation and Experimental Results. IMIS 2019: 11-24 - 2018
- [j10]Miralda Cuka
Effect of node centrality for IoT device selection in opportunistic networks: A comparison study. Concurr. Comput. Pract. Exp. 30(21) (2018) - [j9]Miralda Cuka, Donald Elmazi
Implementation of two fuzzy-based systems for IoT device selection in opportunistic networks: effect of storage parameter on IoT device selection. Int. J. Commun. Networks Distributed Syst. 21(1): 95-114 (2018) - [j8]Keita Matsuo, Miralda Cuka, Takaaki Inaba, Tetsuya Oda, Leonard Barolli, Admir Barolli:
Performance analysis of two WMN architectures by WMN-GA simulation system considering different distributions and transmission rates. Int. J. Grid Util. Comput. 9(1): 75-82 (2018) - [j7]Donald Elmazi
Implementation of intelligent fuzzy-based systems for actor node selection in WSANs: A comparison study considering effect of actor congestion situation. J. High Speed Networks 24(3): 187-199 (2018) - [j6]Admir Barolli, Tetsuya Oda
A GA-based simulation system for WMNs: comparison analysis for different number of flows, client distributions, DCF and EDCA functions. Soft Comput. 22(8): 2547-2555 (2018) - [c31]Miralda Cuka, Donald Elmazi
A Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks Considering Number of Past Encounters. 3PGCIC 2018: 223-237 - [c30]Keita Matsuo, Masafumi Yamada, Kevin Bylykbashi
Implementation of an IoT-Based E-Learning Testbed: Performance Evaluation Using Mean-Shift Clustering Approach Considering Four Types of BrainWaves. AINA Workshops 2018: 203-209 - [c29]Donald Elmazi
Selection of Actor Nodes in Wireless Sensor and Actor Networks: A Fuzzy-Based Approach Considering Number of Obstacles as New Parameter. AINA 2018: 658-666 - [c28]Miralda Cuka, Donald Elmazi
A Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks Considering IoT Device Storage, Waiting Time and Node Centrality Parameters. AINA 2018: 710-716 - [c27]Donald Elmazi
A Fuzzy-Based System for Actor Node Selection in WSANs Considering Load Balancing of Actors. BWCCA 2018: 97-109 - [c26]Donald Elmazi
A Fuzzy-Based Approach for Selection of Actor Nodes in WSANs Considering Size of Giant Component as New Parameter. CISIS 2018: 89-101 - [c25]Miralda Cuka, Donald Elmazi
A Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks Considering IoT Device Storage, Waiting Time and Security Parameters. EIDWT 2018: 94-105 - [c24]Donald Elmazi
Selection of Actor Nodes in Wireless Sensor and Actor Networks Considering Failure of Assigned Task as New Parameter. EIDWT 2018: 106-118 - [c23]Miralda Cuka, Donald Elmazi
A Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks Considering IoT Device Contact Duration, Storage and Remaining Energy. IMIS 2018: 74-85 - [c22]Donald Elmazi
A Fuzzy-Based System for Actor Node Selection in WSANs for Improving Network Connectivity and Increasing Number of Covered Sensors. NBiS 2018: 3-15 - [c21]Miralda Cuka, Donald Elmazi
A Delay-Aware Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks. NBiS 2018: 16-29 - 2017
- [j5]Miralda Cuka, Donald Elmazi
An Integrated Fuzzy-Based System for Cluster-Head Selection and Sensor Speed Control in Wireless Sensor Networks. Int. J. Distributed Syst. Technol. 8(2): 1-14 (2017) - [j4]Ryoichiro Obukata, Miralda Cuka, Donald Elmazi
Design and evaluation of an ambient intelligence testbed for improving quality of life. Int. J. Space Based Situated Comput. 7(1): 8-15 (2017) - [j3]Donald Elmazi
Implementation and comparison of two intelligent systems based on fuzzy logic for actor selection in WSANs: effect of node density on actor selection. Int. J. Space Based Situated Comput. 7(4): 229-238 (2017) - [j2]Masafumi Yamada, Miralda Cuka, Yi Liu, Tetsuya Oda, Keita Matsuo, Leonard Barolli:
Evaluation of an IoT-based e-learning testbed: Performance of OLSR protocol in a NLoS environment and mean-shift clustering approach considering electroencephalogram data. Int. J. Web Inf. Syst. 13(1): 2-13 (2017) - [j1]Miralda Cuka, Ilir Shinko, Evjola Spaho
A simulation system based on ONE and SUMO simulators: Performance evaluation of different vehicular DTN routing protocols. J. High Speed Networks 23(1): 59-66 (2017) - [c20]Miralda Cuka, Donald Elmazi
An Integrated Intelligent System for IoT Device Selection and Placement in Opportunistic Networks Using Fuzzy Logic and Genetic Algorithm. AINA Workshops 2017: 201-207 - [c19]Masafumi Yamada, Miralda Cuka, Yi Liu, Tetsuya Oda, Keita Matsuo, Leonard Barolli:
Performance Evaluation of an IoT-Based E-Learning Testbed Using Mean-Shift Clustering Approach Considering Delta Type of Brain Waves. AINA Workshops 2017: 265-270 - [c18]Ryoichiro Obukata, Miralda Cuka, Donald Elmazi
Performance Evaluation of an AmI Testbed for Improving QoL: Evaluation Using Clustering Approach Considering Distributed Concurrent Processing. AINA Workshops 2017: 271-275 - [c17]Miralda Cuka, Donald Elmazi
Selection of Actor Nodes in Opportunistic Networks: A Fuzzy-Based Approach. AINA 2017: 278-284 - [c16]Donald Elmazi
Effect of Node Density on Actor Selection in WSANs: A Comparison Study for Two Fuzzy-Based Systems. AINA 2017: 865-871 - [c15]Donald Elmazi
Selection of Actor Nodes in Wireless Sensor and Actor Networks Considering Actor-Sensor Coordination Quality Parameter. BWCCA 2017: 87-99 - [c14]Miralda Cuka, Donald Elmazi
Effect of Storage Size on IoT Device Selection in Opportunistic Networks: A Comparison Study of Two Fuzzy-Based Systems. BWCCA 2017: 100-113 - [c13]Masafumi Yamada, Miralda Cuka, Yi Liu, Kevin Bylykbashi, Keita Matsuo, Leonard Barolli:
Performance Evaluation of an IoT-Based E-Learning Testbed Using Mean-Shift Clustering Approach Considering Gamma Type of Brain Waves. BWCCA 2017: 671-681 - [c12]Miralda Cuka, Donald Elmazi
A Delay-Aware Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks. CISIS 2017: 3-13 - [c11]Donald Elmazi
Selection of Actor Nodes in Wireless Sensor and Actor Networks: A Fuzzy-Based System Considering Packet Error Rate as a New Parameter. CISIS 2017: 43-55 - [c10]Miralda Cuka, Kosuke Ozera, Ryoichiro Obukata, Donald Elmazi
Implementation of a GA-based Simulation System for Placement of IoT Devices: Evaluation for a WSAN Scenario. EIDWT 2017: 34-42 - [c9]Tetsuya Oda, Miralda Cuka, Ryoichiro Obukata, Makoto Ikeda, Leonard Barolli:
A User Prediction and Identification System for Tor Networks Using ARIMA Model. EIDWT 2017: 89-97 - [c8]Ryoichiro Obukata, Miralda Cuka, Donald Elmazi
Implementation of an Actor Node for an Ambient Intelligence Testbed: Evaluation and Effects of Actor Node on Human Sleeping Condition. EIDWT 2017: 98-106 - [c7]Masafumi Yamada, Miralda Cuka, Yi Liu, Tetsuya Oda, Keita Matsuo, Leonard Barolli:
Design of a Smart Desk for an IoT Testbed: Improving Learning Efficiency and System Security. IMIS 2017: 27-35 - [c6]Tetsuya Oda, Elis Kulla, Miralda Cuka, Donald Elmazi
Performance Evaluation of a Deep Q-Network Based Simulation System for Actor Node Mobility Control in Wireless Sensor and Actor Networks Considering Different Distributions of Events. IMIS 2017: 36-49 - [c5]Miralda Cuka, Donald Elmazi
A Fuzzy-Based System for Selection of IoT Devices in Opportunistic Networks Considering IoT Device Speed, Storage and Remaining Energy Parameters. INCoS 2017: 16-27 - [c4]Tetsuya Oda, Donald Elmazi
Performance Evaluation of a Deep Q-Network Based Simulation System for Actor Node Mobility Control in Wireless Sensor and Actor Networks Considering Three-Dimensional Environment. INCoS 2017: 41-52 - [c3]Masafumi Yamada, Miralda Cuka, Yi Liu, Tetsuya Oda, Keita Matsuo, Leonard Barolli:
Performance Evaluation of an IoT-Based E-Learning Testbed Using Mean-Shift Clustering Approach Considering Theta Type of Brain Waves. INCoS 2017: 62-72 - [c2]Ryoichiro Obukata, Miralda Cuka, Donald Elmazi
Implementation of an Actor Node for an Ambient Intelligence Testbed Considering Bed Temperature and Room Lighting: Its Effects on Human Sleeping Condition. INCoS 2017: 73-81 - [c1]Donald Elmazi
Effect of Packet Error Rate on Selection of Actor Nodes in WSANs: A Comparison Study of Two Fuzzy-Based Systems. NBiS 2017: 114-126
Coauthor Index
[j16] [j15] [j14] [c47] [c46] [c45] [c44] [c43] [c42] [c41] [c40] [j13] [j12] [j11] [c39] [c38] [c37] [c36] [c35] [c34] [c33] [c32] [j10] [j9] [j8] [j7] [j6] [c31] [c30] [c29] [c28] [c27] [c26] [c25] [c24] [c23] [c22] [c21] [j5] [j4] [j3] [j2] [j1] [c20] [c19] [c18] [c17] [c16] [c15] [c14] [c13] [c12] [c11] [c10] [c9] [c8] [c7] [c6] [c5] [c4] [c3] [c2] [c1]
[j16] [j15] [j14] [c47] [c46] [c45] [c44] [c43] [c42] [c41] [c40] [j13] [j12] [j11] [c39] [c38] [c37] [c36] [c35] [c34] [c33] [c32] [j10] [j9] [j7] [c31] [c29] [c28] [c27] [c26] [c25] [c24] [c23] [c22] [c21] [j5] [j4] [j3] [c20] [c18] [c17] [c16] [c15] [c14] [c12] [c11] [c10] [c8] [c6] [c5] [c4] [c2] [c1]
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