References
- Army Technology. (n. d.). Raytheon XOS 2 Exoskeleton, Second-Generation Robotics Suit. Retrieved October 10, 2018, from https://www.army-technology.com/projects/raytheon-xos-2-exoskeleton-us/
- Chae, H. S., Hong, J. Y., Cho, H. S., Lee, Y. J., Park, S. H., Han, K. H., & Lee, J. H. (2006). The development of usability evaluation for wearable computer: An investigation of smart clothing. Korean Journal of the Science of Emotion & Sensibility, 9(3), 265-276.
- Chiri, A., Vitiello, N., Giovacchini, F., Roccella, S., Vecchi, F., & Carrozza, M. C. (2012). Mechatronic design and characterization of the index finger module of a hand exoskeleton for post-stroke rehabilitation. Mechatronics, IEEE/ASME, 17(5), 884-894.
- Cho, H. K., & Lee, J. H. (2008). The development of sensor based healthcare smart clothing based on usability test. Korean Journal of the Science of Emotion & Sensibility, 11(1), 81-90.
- Cho, H. S., Kim, Y. J., Kim, H. S., Seo, J. H., Lee, S. Y., Lee, J. H., & Hwang, E. S. (2005). A development of the prototypes of smart sportswear for trekking and jogging. Korean Journal of the Science of Emotion & Sensibility, 8(3), 213-220.
- Cho, J. S., Kwon, T. K., & Hong, J. P. (2014). A study of evaluation index development of healthcare rehabilitation device design. Korean Journal of the Science of Emotion & Sensibility, 17(3), 129-142. doi:10.14695/KJSOS.2014.17.3.129
- Cho, K. J., & Lee, J. Y. (2018). Current status of soft robotics technology and research trends. Journal of the Korean Society Mechanical Engineers, 58(1), 42-46.
- Choi, J. S., & Park, J. O. (2018). Smart clothing market status and technology issue. The Magazine of the IEIE, 45(12), 29-36.
- Chu, J. (2013, October 24). 'Anklebot' helps determine ankle stiffness. MIT News. Retrieved October 11, 2018, from http://news.mit.edu/2013/anklebot-helps-determine-ankle-stiffness-1024
- Cyberdyne. (n. d.). HAL Lumbar Type for Care Support. Retrieved November 14, 2019, from https://www.cyberdyne.jp/english/products/Lumbar_CareSupport.html
- Dan, B. J. (2014, March 6). Introduction of Futuristic gait robot, Smart Walker. Social LG Electronics. Retrieved November 12, 2018, from https://social.lge.co.kr/technology/smartwalker/
- 'Development of firefighter's wearable robot, Hyper R1'. (2016, July). KITECH Webzine. Retrieved November 14, 2018, from https://www.kitech.re.kr/promotion/page3-wz.phppub_year=&page=1&pidx=114&idx=126
- Dunne, L. E., & Smyth, B. (2007). Psychophysical elements of wearability. Proceedings of the SIGCHI Conference on Human Factors in Computing Systems (pp. 299-302). San Jose, CA, USA.
- Dunne, L. E., & Smyth, B. (2007). Psychophysical elements of wearability. Proceedings of the SIGCHI Conference on Human Factors in Computing Systems (pp. 299-302). San Jose, CA, USA.
- Ekso BIONICS. (n. d.). EksoVest. Retrieved November 15, 2018, from https://eksobionics.com/eksoworks/eksovest/
- Gemperle, F., Kasabach, C., Stivoric, J., Bauer M., & Matin, R. (1998). Design for wearability. Proceedings of Second International Symposium on Wearable Computers, October 19-20, Pittsburgh, PA, USA: IEEE.
- Ha, J. H. (2016, September 12). The era of wearable robots is coming, a step towards a better world. The Seoul Economic Daily. Retrieved October 9, 2017, from http://www.sedaily.com/NewsView/1L1E1PKKQL
- Han, J. S. (2012). Wearable upper extremity support and rehabilitation robot for repetitive tasks and daily support. Proceedings of HCI Korea, 2012, pp. 1102-1112.
- HEXAR Systems. (n. d.). HEXAR-CR50. Retrieved October 11, 2018, from http://www.hexarsystems.com/new/product/product_p04.php?p_idx=3
- Hocoma. (n. d.). Hocoma. Retrieved November 14, 2018, from https://www.hocoma.com/solutions/armeo-power/
- Honda. (n. d.). Honda Walking Assist Device. Retrieved October 10, 2018, from https://global.honda/products/power/walkingassist.html
- Huh, Y., Jung, H. G., & Ryu, J. C. (2016, July). Trends and prospects in rehabilitation medical devices. KEIT PD Issue Report, pp. 91-111.
- 'H-WEX'. (2017, March 22). Exoskeleton Report. Retrieved November 14, 2018, from https://exoskeletonreport.com/product/h-wex/
- In, H. K. (2017). Agricultural and wearable technology. Korea Robotics Society, 14(2), 30-35.
- In, H. K., Cho, K. J., Kim, Y. J., Yang, S. H., Lee, S. D., & Lee, D. K. (2017). Soft wearable robot to assist laborious farm work unpowered soft wearable robot to assist laborious farm work. Proceedings of Korean Society for Precision Engineering, Spring Conference, Korea.
- Jang, J. H., & Song, W. K. (2016). Current status of technology for wearing robot. Journal of the Korean Society Mechanical Engineers, 56(2), 42-26.
- Kim, B. H., Ahn, J. B., & Kim, J. H. (2012). Promotion strategy for production industry of advertising contents in smart media by focus group interview. Journal of Practical Research in Advertising and Public Relations, 5(2), 60-87.
- Korean Intellectual Property Office. (2017). The Patent Statistics in Korea. Retrieved February 21, 2019, from http://www.kipo.go.kr/ kpo/user.tdfa=user.html.HtmlApp&c=3081&catmenu=m04_06_01
- Lee, W. S. (2016, Fabruary 16). Hand-paralyzed patient can open a can. Dongascience. Retrieved October 11, 2018, from http://dongascience.donga.com/news/view/10370
- 'L'exosquelette Hercule'. (2012, June 11). Direction Generale de L'armement. Retrieved October 10, 2018, from https://www.defense.gouv.fr/dga/mediatheque/photos/l-exosquelette-hercule
- Low, K. H., Liu, X., & Yu, H. (2005). Development of NTU wearable exoskeleton system for assistive technologies. Proceedings of the IEEE International Conference on Mechatronics & Automation, July 29-August 1, 2005, Niagara Falls, Canada.
- Ministry of Trade, Industry and Energy. (2017). Find Korea Route of the Fourth Industrial Revolution: Lectures of department of industry. Retrieved October 09, 2017, from http://www.korearobot.or.kr/wp/?p=8267
- Myomo. (n. d.). Myomo. Retrieved November 12, 2018, from https://myomo.com
- Noh, M. J., & Park, H. H. (2011). Acceptance of the smart clothing according to trend and information innovation. The Journal of the Korea Contents Association, 11(11), 350-363. doi:10.5392/JKCA.2011.11.11.350
- 'Panasonic Power Loader Light exoskeleton takes a load off your back'. (2013, January 8). New Atlas. Retrieved November 16, 2018, from https://newatlas.com/panasonic-power-loader-light-exoskeleton/25682/
- Park, H. J., & Lee, J. H. (2002). An explorative research for possibility of digital wear based on motion-detective input technology as apparel product and suggestion of the design prototypes(2). Science of Emotion & Sensibility, 5(2), 35-50.
- Park, J. E. (2015, August 7). Hyundai presents wearable robot. Etnes. Retrieved October 21, 2018, from https://news.naver.com/main/ read.nhn?oid=030&aid=0002383014
- ReWalk (n. d.). ReWalk. Retrieved October 10, 2018, from https://rewalk.com
- 'Soft Exosuit'. (2014, October 5). Neszter. Retrieved November 14, 2018, from https://neszter.wordpress.com/2014/10/05/soft-robotic-exoskeleton/
- Song, W. G. (2011). Status and prospects of rehabilitation robot. The Journal of Korea Institute of Electronics Engineers, 38(11), 47-54.
- Song, Y. S., & Kim, J. G. (2010). Analysis of patents regarding stabilization technology for steep slope hazards. The Journal of Engineering Geology, 20(3), 257-269.
- Steitz, D. (2012, December 10). NASA's ironman-like exoskeleton could give astronauts, paraplegics improved mobility and strength. NASA. Retrieved October 23, 2018, from https://www.nasa.gov/mission_pages/station/research/news/exoskeleton.html
- Tanaka, T., Satoli, Y., Kaneko, S., Suzuki, Y., Sakamoto, N., & Seki, S. (2008). Smart suit: Soft power suit with semi-active assist mechanism - prototype for supporting waist and knee joint." Proceedings of 2008 International Conference on Control, Automation and Systems (pp. 2002-2005). Seoul, Korea
- Toyama, S., & Yamamoto, G. (2009, October). Development of wearable-agri-robot-mechanism for agricultural work-. In 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems (pp. 5801-5806). IEEE.
- Tratica. (2016). Robotics market forecasts. Boulder.
- Yagi, E., Harada, D., & Kobayashi, M. (2009). Development of an upper limb power assist system using pneumatic actuators for farming lift-up motion. Journal of System Design and Dynamics, 3(5), 2036-2043. doi:10.1299/jsdd.3.781
- Yook, H. M. (2004). Development of usability evaluation criteria for smart jacket design. Unpublished master's thesis, Yonsei University, Seoul.
- You, Y. B., Choi, K. Y., Park, B., & Jeong, E. S. (2013). Technology trend of smart clothing: Based on patent information analysis. The Journal of the Korea Contents Association, 13(4), 440-451. doi: 10.5392/JKCA.2013.13.04.440
- Yun, I. S., Kim, S. J., & Jeong, E. S. (2011). Evaluation of technology activity, innovation and productivity using Korean patent information, Journal of Information Management, 42(2), 151-165. doi:10.1633/JIM.2011.42.2.151