Development of Hardware Neural Networks IC with Switchable Gait Pattern for Insect-Type Microrobot

The authors are studying Hardware Neural Networks (HNN) for generating a driving waveform of a millimeter size insect-type microrobot. HNN can generate the pulse waveform such as the neural networks of living organisms. In the previous research, the HNN constructed by an Integrated Circuit (IC) could generate only a tripod gait pattern which is necessary to perform the locomotion of the microrobot. The microrobot can move six legs independently; thus, the mechanical structure of the microrobot allows the several gaits by changing the driving waveform. The HNN with switchable gait pattern could perform the different locomotion of the microrobot. In this paper, the authors discuss HNN which can switch the gait pattern of the microrobot. HNN can generate two gait pattern such as the tripod gait pattern and the ripple gait pattern which is typical gaits of insects. The tripod is for fast walking and the ripple is for slow walking, respectively. Usually, six cell body models mutually connected by 18 inhibitory synaptic models were required to generate the tripod gait pattern. Also, six cell body models mutually connected by 30 inhibitory synaptic models were required to generate the ripple gait pattern. The authors simplified the network with proposal excitatory-inhibitory switchable synaptic model. The HNN can simplify as six cell body models connected by two excitatory-inhibitory switchable synaptic model and ten inhibitory synaptic models. In addition, two types of gait patterns can be switched using a single external voltage source. As a result, The HNN generates tripod gait pattern with an external voltage of 3.0 V and ripple gait pattern with an external voltage of -3.0 V.

[1]  Ken Saito,et al.  Neural networks IC controlled multi-legged walking MEMS robot with independent leg mechanism , 2018, Artificial Life and Robotics.

[2]  Andrew Zisserman,et al.  Very Deep Convolutional Networks for Large-Scale Image Recognition , 2014, ICLR.

[3]  Ronald S. Fearing,et al.  DASH: A dynamic 16g hexapedal robot , 2009, 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[4]  Robert J. Wood,et al.  Pop-up assembly of a quadrupedal ambulatory MicroRobot , 2013, 2013 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[5]  Cynthia Ferrell Robust and adaptive locomotion of an autonomous hexapod , 1994, Proceedings of PerAc '94. From Perception to Action.

[6]  Yoshifumi Sekine,et al.  Pulse-type hardware chaotic neuron model and its bifurcation phenomena , 1999, Neural Networks.

[7]  Ken Saito,et al.  Hexapod Type MEMS Microrobot Equipped with an Artificial Neural Networks IC , 2017, J. Robotics Netw. Artif. Life.

[8]  Robert J. Wood,et al.  Spiking neural network (SNN) control of a flapping insect-scale robot , 2016, 2016 IEEE 55th Conference on Decision and Control (CDC).

[9]  T. Brown The intrinsic factors in the act of progression in the mammal , 1911 .

[10]  D. Graham A behavioural analysis of the temporal organisation of walking movements in the 1st instar and adult stick insect (Carausius morosus) , 1972, Journal of comparative physiology.

[11]  Dana E. Vogtmann,et al.  A 25 MG magnetically actuated microrobot walking at > 5 body lengths/sec , 2017, 2017 IEEE 30th International Conference on Micro Electro Mechanical Systems (MEMS).

[12]  Ken Saito,et al.  Synchronization of coupled pulse-type hardware neuron models for CPG model , 2009, 2009 International Joint Conference on Neural Networks.

[13]  Dumitru Erhan,et al.  Going deeper with convolutions , 2014, 2015 IEEE Conference on Computer Vision and Pattern Recognition (CVPR).