TY - GEN
T1 - Adaptive amoeboid locomotion that exploits law of conservation of protoplasmic mass
AU - Umedachi, Takuya
AU - Ishiguro, Akio
PY - 2007/12/1
Y1 - 2007/12/1
N2 - This paper intensively discusses how adaptive locomotion under unstructured and dynamically changing environment can be realized from the perspective of long-distance interaction and local interaction dynamics induced in bodies. To this end, we have focused on the most primitive yet flexible locomotion, amoeboid locomotion. Slime mold and amoeba are well known to exhibit remarkably adaptive behaviors, such as avoiding hazardous condition, and approaching nutrients and humidity, by dynamically changing their morphology. These behaviors induced so-called amoeboid movement, which is driven by the flexible epitheca (i.e. outer skin) and the protoplasm despite of the absence of a central nervous system or specialized organs. In light of these facts, we have conducted simulations of an amoeboid robot, particularly focusing on epitheca consisting of "real-time tunable springs" and "law of conservation of protoplasmic mass", the former of which is used to deal with "local interaction dynamics" and the latter of which is used to deal with "long-distance interaction". Simulation results indicate that the proposed model can induce highly adaptive locomotion according to the situation encountered by dynamically changing its morphology.
AB - This paper intensively discusses how adaptive locomotion under unstructured and dynamically changing environment can be realized from the perspective of long-distance interaction and local interaction dynamics induced in bodies. To this end, we have focused on the most primitive yet flexible locomotion, amoeboid locomotion. Slime mold and amoeba are well known to exhibit remarkably adaptive behaviors, such as avoiding hazardous condition, and approaching nutrients and humidity, by dynamically changing their morphology. These behaviors induced so-called amoeboid movement, which is driven by the flexible epitheca (i.e. outer skin) and the protoplasm despite of the absence of a central nervous system or specialized organs. In light of these facts, we have conducted simulations of an amoeboid robot, particularly focusing on epitheca consisting of "real-time tunable springs" and "law of conservation of protoplasmic mass", the former of which is used to deal with "local interaction dynamics" and the latter of which is used to deal with "long-distance interaction". Simulation results indicate that the proposed model can induce highly adaptive locomotion according to the situation encountered by dynamically changing its morphology.
KW - Amoeboid locomotion
KW - Brain-body interaction
KW - Law of conservation of protoplasmic mass
KW - Real-time tunable spring
KW - Well-balanced coupling between control and mechanical systems
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U2 - 10.1109/SICE.2007.4421343
DO - 10.1109/SICE.2007.4421343
M3 - Conference contribution
AN - SCOPUS:50249138314
SN - 4907764286
SN - 9784907764289
T3 - Proceedings of the SICE Annual Conference
SP - 2150
EP - 2154
BT - SICE Annual Conference, SICE 2007
T2 - SICE(Society of Instrument and Control Engineers)Annual Conference, SICE 2007
Y2 - 17 September 2007 through 20 September 2007
ER -