Browse > Article

관성측정장치를 이용한 동작분석장치 개발 및 목관절 연구 동향  

Kim, Hyeon-Ho (경희대학교 한의과대학 진단생기능의학교실)
Publication Information
The Magazine of the IEIE / v.43, no.12, 2016 , pp. 57-64 More about this Journal
Keywords
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Canseco K, Albert C, Long J, Khazzam M, Marks R, Harris G. Postoperative foot and ankle kinematics in rheumatoid arthritis. Journal of Experimental & Clinical Medicine. 2011;3(5):233-238.   DOI
2 Rahni AAA, Yahya I. Obtaining translation from a 6-DOF MEMS IMU - an overview. Proceedings of the 2007 IEEE Asia-Pacific Conference on Applied Electromagnetics Proceedings. 2007:1-5.
3 Park Kyue-Nam, Cynn Heon-Seock, Kwon Oh-Yun, Lee Won-Hwee, Ha Sung-Min, Kim Su-Jung, Weon Jong- Hyuck. Effects of the abdominal drawing-in maneuver on muscle activity, pelvic motions, and knee flexion during active prone knee flexion in patients with lumbar extension rotation syndrome. Archives of Physical Medicine and Rehabilitation 2011;92(9):1477-1483.   DOI
4 유경석. V.R.전자기추적센서를 이용한 상지말단의 3차원 회전성분의 운동학적 분석. 한국체육학회지. 2000;39(2):513- 526.
5 Chung PYM, Ng GYF. Comparison between an accelerometer and a three-dimensional motion analysis system for the detection of movement. Physiotherapy. 2011;98(3):256-259.   DOI
6 Liu T, Inoue Y, Shibata K, Tang X. A wearable inertial sensor system for human motion analysis. Proceedings of IEEE International Symposium on Computational Intelligence in Robotics and Automation, CIRA. 2005:409-413.
7 S. Sessa, M. Zecca, Z. Lin, L. Bartolomeo, K. Itoh, H. Ishii, Y. Mukaeda, Y. Suzuki, and A. Takanishi, "Ultra-miniaturized WB-3 Inertial Measurement Unit: Performance evaluation of the attitude estimation," in Proceedings of the IEEE International Conference on Robotics and Biomimetics, 2010;ID 57234620.
8 Wade E, Parnandi A.R, Mataric MJ. Automated administration of the wolf motor function test for post-stroke assessment. Proceedings of the 2010 4th International Conference on Pervasive Computing Technologies for Healthcare, Pervasive Health 2010.
9 Lo G, Ashwin Ram Suresh, Stocco L, Gonzalez-Valenzuela S, Leung VCM. A wireless sensor system for motion analysis of Parkinson's disease patients. Work in Progress workshop at PerCom 2011 IEEE. 2011;372-375.
10 Esser P, Dawes H, Collett J, Feltham MG, Howells K. Assessment of spatio-temporal gait parameters using inertial measurement units in neurological populations. Gait & Posture. 2011;34(4):558-560.   DOI
11 King K, Yoon. SW, Perkins NC, Najafi K. Wireless MEMS inertial sensor system for golf swing dynamics. Sensors and Actuators A: Physical. 2008;141(2):619-630.   DOI
12 Iijima Y, Watanabe K, Kobayashi K, Kurihara Y. Measurement and analysis of tennis swing motion using 3D gyro sensor. Proceedings of the SICE Annual Conference. 2010;274-277.
13 Kim H, Shin SH, Kim JK, Park YJ, Oh HS, Park YB. Cervical Coupling Motion Characteristics in Healthy People Using a Wireless Inertial Measurement Unit. Evidence-Based Complementary and Alternative Medicine. 2013;ID 570428.
14 Miyaoka S, Hirano H, Ashida I, Miyaoka Y, Yamada Y. Analysis of head movements coupled with trunk drift in healthy subjects. Medical and Biological Engineering and Computing. 2005;43(3):395-402.   DOI
15 Pryce R, McDonald N. Prehospital Spinal Immobilization: Effect of Effort on Kinematics of Voluntary Head-neck Motion Assessed using Accelerometry. Prehospital and Disaster Medicine. 2015;31(1):36-42.
16 Schiefer C, Kraus T, Ellegast RP, Ochsmann E. A technical support tool for joint range of motion determination in functional diagnostics - An inter-rater study. Journal of Occupational Medicine and Toxicology. 2015;10:16   DOI
17 Xu X, Chen KB, Lin J-H, Radwin RG. The accuracy of the Oculus Rift virtual reality head-mounted display during cervical spine mobility measurement. Journal of Biomechanics. 2015;48(4):721-724.   DOI
18 E .-M. Malmstrom, M. Karlberg, P. A. Fransson, A. Melander, and M. Magnusson, "Primary and coupled cervical movements: The effect of age, gender, and body mass index. A 3-dimensional movement analysis of a population without symptoms of neck disorders," Spine, 2006;31(2):E44-E50.   DOI
19 C. L. Koerhuis, J. C. Winters, F. C. T. Van der Helm, and A. L. Hof, "Neck mobility measurement by means of the 'Flock of Birds' electromagnetic tracking system," Clin. Biomech., 2003;18(1):14-18.   DOI
20 K. M. Hermann, C. S. Reese, and A. M. Jette, "Relationships among selected measures of impairment, functional limitation, and disability in patients with cervical spine disorders," Phys. Ther., 2001;81(3):903-913.
21 김현호, 김정균, 서재호, 박영재, 박영배, "관성측정장치를 이용한 동태손상증후군의 평가 가능성에 관한 고찰", 대한한의진단학회지, 2011;15(3):223-234.
22 N. Strimpakos, V. Sakellari, G. Gioftsos, M. Papathanasiou, E. Brountzos, D. Kelekis, E. Kapreli, and J. Oldham, "Cervical spine ROM measurements: Optimizing the testing protocol by using a 3D ultrasound-based motion analysis system," Cephalalgia, 2005;25(12):1133-1145.   DOI
23 A. Woodhouse and O. Vasseljen, "Altered motor control patterns in whiplash and chronic neck pain," BMC Musculoskelet. Disord., 2008.
24 V. Feipel, B. Rondelet, J.-P. Le Pallec, and M. Rooze, "Normal global motion of the cervical spine: An electrogoniometric study," Clin. Biomech., 1999;14(7):462-470.   DOI
25 M. J. Pearcy and S. B. Tibrewal, "Axial rotation and lateral bending in the normal lumbar spine measured by threedimensional radiography," Spine, 1984;9(6):582-587.   DOI
26 M. M. Panjabi, T. Oda, J. J. Crisco III, J. Dvorak, and D. Grob, "Posture affects motion coupling patterns of the upper cervical spine," J. Orthop. Res., 1993;11(4):525-536.   DOI
27 C. A. Buck, F. B. Dameron, M. J. Dow, and H. V. Skowlund, "Study of normal range of motion in the neck utilizing a bubble goniometer.," Arch. Phys. Med. Rehabil., 1959;40:390-392.
28 D. Capuano-Pucci, W. Rheault, J. Aukai, M. Bracke, R. Day, and M. Pastrick, "Intratester and intertester reliability of the cervical range of motion device," Arch. Phys. Med. Rehabil., 1991;72(5):338-340.
29 Z. Lin, M. Zecca, S. Sessa, L. Bartolomeo, H. Ishii, K. Itoh, and A. Takanishi, "Development of an ultra-miniaturized inertial measurement unit WB-3 for human body motion tracking," in Proceedings of the 3rd IEEE/SICE International Symposium on System Integration, 2010;ID 5708361.
30 A. M. Sabatini, C. Martelloni, S. Scapellato, and F. Cavallo, "Assessment of Walking Features From Foot Inertial Sensing," IEEE Trans. Biomed. Eng., 2005;52:486-494.   DOI
31 D. Cardarelli, "An integrated MEMS inertial measurement unit," in Proceedings of the 2002 IEEE Position Location and Navigation Symposium, 2002;314-319.
32 Kavanagh JJ, Menz HB. Accelerometry: A technique for quantifying movement patterns during walking. Gait & Posture. 2008;28:1-15.   DOI
33 A. Warnasch, A., Killen, "Low cost, high G, Micro Electro- Mechanical Systems (MEMS), Inertial Measurements Unit (IMU) program," in Proceedings of the 2002 IEEE Position Location and Navigation Symposium, 2002;299-305.
34 R. Y. W. Saber-Sheikh, K., Bryant, E.C., Glazzard, C., Hamel, A., Lee, "Feasibility of using inertial sensors to assess human movement," Man. Ther., 2010;15(1):122-125.   DOI
35 T. Ito, "Walking Motion Analysis Using 3D Acceleration Sensors," in Proceedings of the 2nd UKSim European Symposium on Computer Modelling and Simulation, 2008;ID 4625258.
36 Mayagoitia RE, Nene AV, Veltink PH. Accelerometer and rate gyroscope measurement of kinematics: an inexpensive alternative to optical motion analysis systems. J Biomech. 2002;35(4):537-542.   DOI
37 Moe-Nilssen R. Test-retest reliability of trunk accelerometry during standing and walking. Arch Phys Med Rehabil. 1998;79(11):1377-1385.   DOI
38 Henriksen M, Lund H, Moe-Nilssen R, Bliddal H, Danneskoid-Samsoe B. Test-retest reliability of trunk accelerometric gait analysis. Gait & Posture. 2004;19(3):288- 297.   DOI
39 P. S. Theobald, M. D. Jones, and J. M. Williams, "Do inertial sensors represent a viable method to reliably measure cervical spine range of motion?," Man. Ther., 2013;17(1):92- 96.   DOI
40 J. M. Williams, I. Haq, and R. Y. Lee, "A novel approach to the clinical evaluation of differential kinematics of the lumbar spine," Man. Ther., 2013;18(2):130-135.   DOI
41 Santhiranayagam BK, Lai DTH, Begg RK, Palaniswami M. Correlations between end point foot trajectories and inertial sensor data. IEEE ISSNIP 2010. 2010;315-320.
42 E. Charry, M. Umer, and S. Taylor, "Design and validation of an ambulatory inertial system for 3-D measurements of low back movements," in Proceedings of the 2011 7th International Conference on Intelligent Sensors, Sensor Networks and Information Processing, 2011;58-63.
43 Jasiewicz JM, Treleaven J, Condie P, Jull G. Wireless orientation sensors: Their suitability to measure head movement for neck pain assessment. Manual Therapy. 2007;12(4):380-385.   DOI
44 Findlow A, Goulermas JY, Nester C, Howard D, Kenney LPJ. Predicting lower limb joint kinematics using wearable motion sensors. Gait & Posture. 2008;28(1):120-126.   DOI
45 Guangyi Shi, Yuexian Zoui, Yufeng Jin, Yali Zheng, Li WJ. Multi-category human motion recognition based on MEMS inertial sensing data. Proceedings of the 2009 4th IEEE international Conference on Nano/Micro Engineered and Molecular Systems. 2009;489-493.
46 Parnandi A, Wade E, Mataric M. Motor function assessment using wearable inertial sensors. Proceedings of the 32nd Annual International Conference of the IEEE EMBS. 2010;86-89.
47 Pancani S, Rowson J, Tindale W, Heron N, Langley J, McCarthy AD, Quinn A, Reed H, Stanton A, Shaw PJ, McDermott CJ, Mazza C. Assessment of the Sheffield Support Snood, an innovative cervical orthosis designed for people affected by neck muscle weakness. Clinical Biomechanics. 2016;32:201-206.   DOI
48 Yannick Tousignant-Laflamme, Nicolas B, Alexandre MD, Carol-Anne V. Reliability and criterion validity of two applications of the $iPhone^{TM}$ to measure cervical range of motion in healthy participants. Journal of NeuroEngineering and Rehabilitation. 2013;10:69.   DOI
49 Quek J, Brauer SG, Treleaven J, Pua Y-H, Mentiplay B, Clark RA. Validity and intra-rater reliability of an Android phone application to measure cervical range-of-motion. Journal of NeuroEngineering and Rehabilitation. 2014;11:65.   DOI
50 Milani P, Coccetta CA, Rabini A, Sciarra T, Massazza G, Ferriero G. Mobile smartphone applications for body position measurement in rehabilitation: A review of goniometric tools. PM and R. 2014;6(11):1038-1043.   DOI
51 Boissy P, Shrier I, Briere S, Mellete J, Fecteau L, Matheson GO, Garza D, Meeuwisse WH, Segal E, Boulay J, Steele RJ. Effectiveness of cervical spine stabilization techniques. Clinical Journal of Sport Medicine. 2011;21(2):80-88.   DOI
52 Cuesta-Vargas AI, Williams J. Inertial sensor realtime feedback enhances the learning of cervical spine manipulation: A prospective study. European Spine Journal. 2014;23(11):2314-2320.   DOI