Fuzzy Logic Based Classification for Multifunctional Upper Limb Prostheses

被引:0
|
作者
Celik, Mehmet Serdar [1 ]
Eminoglu, Ilyas [1 ]
机构
[1] Ondokuz Mayis Univ, Elekt Elekt Muhendisligi Bolumu, Samsun, Turkey
来源
2016 MEDICAL TECHNOLOGIES NATIONAL CONFERENCE (TIPTEKNO) | 2015年
关键词
surface EMG; prosthesis; multifunctional upper limb; fuzzy logic; classification;
D O I
暂无
中图分类号
TP39 [计算机的应用];
学科分类号
081203 ; 0835 ;
摘要
This paper investigate a fuzzy logic based high performance surface EMG classification algorithm for multifunctional upper limb prostheses. In this paper, we record 4 channels EMG data with surface electrodes from the forearm and aimed to recognize 8 different upper limb movements using heuristic fuzzy logic methods from these data. We use 50 surface EMG data for every function and evaluate the performance of this method.
引用
收藏
页数:4
相关论文
共 50 条
  • [31] Classification using RBFNs based on fuzzy logic
    Gao, CM
    Shao, MZ
    Gao, SH
    IGARSS 2000: IEEE 2000 INTERNATIONAL GEOSCIENCE AND REMOTE SENSING SYMPOSIUM, VOL I - VI, PROCEEDINGS, 2000, : 2149 - 2151
  • [32] A fuzzy logic based approach for data classification
    Taneja, Shweta
    Suri, Bhawna
    Gupta, Sachin
    Narwal, Himanshu
    Jain, Anchit
    Kathuria, Akshay
    Advances in Intelligent Systems and Computing, 2008, 542 : 605 - 616
  • [33] Optimizing strap designs of upper limb prostheses
    Liu, Ying
    Zhang, Xiufeng
    Zhang, Ning
    Xu, Jianguang
    Yang, Rong
    ADVANCES IN MECHANICAL ENGINEERING, 2018, 10 (07):
  • [34] Clinical Perspectives in Upper Limb Prostheses: An Update
    Aidan D. Roche
    Ben Lakey
    Irene Mendez
    Ivan Vujaklija
    Dario Farina
    Oskar C. Aszmann
    Current Surgery Reports, 7
  • [35] PATTERNS OF ACCEPTANCE AND REJECTION OF UPPER LIMB PROSTHESES
    BURROUGH, SF
    BROOK, JA
    ORTHOTICS AND PROSTHETICS, 1985, 39 (02): : 40 - 47
  • [36] A Decade of Haptic Feedback for Upper Limb Prostheses
    Dey, Abhijit
    Basumatary, Hirakjyoti
    Hazarika, Shyamanta M.
    IEEE TRANSACTIONS ON MEDICAL ROBOTICS AND BIONICS, 2023, 5 (04): : 793 - 810
  • [37] Control strategy for upper-limb prostheses
    Childress, DS
    PROCEEDINGS OF THE 20TH ANNUAL INTERNATIONAL CONFERENCE OF THE IEEE ENGINEERING IN MEDICINE AND BIOLOGY SOCIETY, VOL 20, PTS 1-6: BIOMEDICAL ENGINEERING TOWARDS THE YEAR 2000 AND BEYOND, 1998, 20 : 2273 - 2275
  • [38] Upper limb prostheses: bridging the sensory gap
    Roche, Aidan D. D.
    Bailey, Zachary K. K.
    Gonzalez, Michael
    Vu, Philip P. P.
    Chestek, Cynthia A. A.
    Gates, Deanna H. H.
    Kemp, Stephen W. P.
    Cederna, Paul S. S.
    Ortiz-Catalan, Max
    Aszmann, Oskar C. C.
    JOURNAL OF HAND SURGERY-EUROPEAN VOLUME, 2023, 48 (03) : 182 - 190
  • [39] Clinical Perspectives in Upper Limb Prostheses: An Update
    Roche, Aidan D.
    Lakey, Ben
    Mendez, Irene
    Vujaklija, Ivan
    Farina, Dario
    Aszmann, Oskar C.
    CURRENT SURGERY REPORTS, 2019, 7 (03)
  • [40] Reflections on the present and future of upper limb prostheses
    Farina, Dario
    Amsuess, Sebastian
    EXPERT REVIEW OF MEDICAL DEVICES, 2016, 13 (04) : 321 - 324
12345