Abstract
Control of articulated robots by biarticular actuation has recently attracted great attention in the research field of robotics. Although many of studies concerned with this issue deal with legged robots or robot arms kinetically interacting with environment such as a floor or an object, motion control of an articulated robot arm with no kinetic interaction is also an interesting topic of biarticular actuation. In the motion control, a major issue is how it is possible for biarticular actuation to contribute to improvement of control; however, showing a clear finding for this issue seems to be considerably difficult. This paper considers a study for exploring that issue. Biarticular actuation usually constitutes a redundant actuation system; therefore, control of a robot arm to a desired posture can be achieved by many combinations of actuator forces. Based on this feature, this paper considers three typical combinations of actuator forces. Point-to-point control of the robot is performed for each of the combinations in simulation, and control performances of the combinations are compared with each other. In addition, the performances are compared with that of monoarticular actuation. In those comparisons, two of the three combinations show similar control performances, which suggests possibility of major contribution of biarticular actuators to motion control of a robot arm. On the other hand, control performance of the other combination is similar to that of monoarticular actuation, rather than those of other two combinations.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.References
Van Ingen Schenau GJ (1989) From rotation to translation: constraints on multi-joint movements and the unique action of bi-articular muscles. Hum Mov Sci 8:301–337
Van Soest AJ, Schwab AL, Bobbert MF, Van Ingen Schenau GJ (1993) The influence of the biarticularity of the gastrocnemius muscle on vertical-jumping achievement. J Biomech 26(1):1–8
Kaneko T, Ogata K, Sakaino S, Tsuji T (2015) Impact force control based on stiffness ellipse method using biped robot equipped with biarticular muscles. In: Proc 2015 IEEE/RSJ Int Conf Intell Robot Syst, pp 2246–2251
Watanabe E, Oku T, Hirai H, Uno K, Uemura M, Miyazaki F (2015) Exploiting invariant structure for controlling multiple muscles in anthropomorphic legs. In: Proc 2015 IEEE-RAS Int Conf Humanoid Robots, pp 88–93
Lahr DF, Yi H, Hong DW (2016) Biologically inspired design of a parallel actuated humanoid robot. Adv Robot. doi:10.1080/01691864.2015.1094408
Kumamoto M, Oshima T, Yamamoto T (1994) Control properties induced by the existence of antagonistic pairs of bi-articular muscles - mechanical engineering model analysis. Hum Mov Sci 13:611–634
Salvucci V, Kimura Y, Oh S, Hori Y (2011) BiWi: Bi-articularly actuated and wire driven robot arm. In: Proc 2011 IEEE Int Conf Mechatron, pp 827–832
Kino H, Kikuchi S, Matsutani Y, Tahara K, Nishiyama T (2013) Numerical analysis of feedforward position control for non-pulley musculoskeletal system: a case study of muscular arrangement of a two-link planar system with six muscles. Adv Robot. doi:10.1080/01691864.2013.824133
Baratcart T, Salvucci V, Koseki T (2015) Experimental verification of two-norm, infinity-norm continuous switching implemented in resolution of biarticular actuation redundancy. Adv Robotics 29(19):1243–1252. doi:10.1080/01691864.2015.1959365
Koba K, Murakami K, Oku T, Uno K, Phatiwuttipat P, Yamashita Y, Uemura M, Hirai H, Miyazaki F (2014) Tacit representation of muscle activities during coordination training: muscle synergy analysis to visualize motor enhancement in virtual trajectory of multi-joint arm movement. In: 2014 5th IEEE RAS & EMBS Int Conf Biomed Robotics Biomechatronics, pp 270–275
Ogihara N, Yamazaki N (2001) Generation of spontaneous reaching movement based on human anatomical constraints. T JSME Ser. C 67(659):2314–2320 (in Japanese)
Morizono T, Tahara K, Kino H (2015) Experimental investigation of contribution of biarticular actuation to mappings between sensory and motor spaces. In: Proc 41st Annual Conf IEEE-IES, pp 3573–3578
Sharon A, Hardt D (1984) Enhancement of robot accuracy using endpoint feedback and a macro-micro manipulator system. In: Proc Am Control Conf, pp 1836–1845
Author information
Authors and Affiliations
Corresponding author
About this article
Cite this article
Morizono, T., Tahara, K. & Kino, H. A study on effect of biarticular muscles in an antagonistically actuated robot arm through numerical simulations. Artif Life Robotics 22, 74–82 (2017). https://doi.org/10.1007/s10015-016-0322-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10015-016-0322-5