Ritsumeikan University researchers develop a soft robotic microfinger that enables interaction with insects through tactile sensing

Human-robot interactions not only allow robots to interact with humans but also with the environment. Microrobots, for instance, can interact with insects and measure the force exerted by them during flight or walking. However, this interaction is not direct, with the microrobots measuring insect behavior primarily. Now, researchers from Japan have developed a soft micro-robotic finger that allows humans to directly interact with insects. This could enable human-environment interaction at previously inaccessible scales.

Humans have always been fascinated by scales different than theirs, from giant objects such as stars, planets and galaxies, to the world of the tiny: insects, bacteria, viruses and other microscopic objects. While the microscope allows us to view and observe the microscopic world, it is still difficult to interact with it directly.

However, human-robot interaction technology might change all that. Microrobots, for instance, can interact with the environment at much smaller scales than us. Microsensors have been used for measuring forces exerted by insects during activities such as flight or walking. However, most studies so far have only focused on measuring insect behavior rather than a direct insect-microsensor interaction.

Against this backdrop, researchers from Ritsumeikan University in Japan have now developed a soft micro-robotic finger that can enable a more direct interaction with the microworld. The study, led by Professor Satoshi Konishi, was published in Scientific Reports on 10 October 2022 “A tactile microfinger is achieved by using a liquid metal flexible strain sensor. A soft pneumatic balloon actuator acts as an artificial muscle, allowing control and finger-like movement of the sensor. With a robotic glove, a human user can directly control the microfingers. This kind of system allows for a safe interaction with insects and other microscopic objects,” explains Prof. Konishi.

Using their newly developed microrobot setup, the research team investigated the reaction force of a pill bug as a representative sample of an insect. The pill bug was fixed in place using a suction tool and the microfinger was used to apply a force and measure the reaction force of the bug’s legs.

The reaction force measured from the legs of the pill bug was approximately 10 mN (millinewtons), which agreed with previously estimated values. While a representative study and a proof-of-concept, this result shows great promise towards realizing direct human interactions with the microworld. Moreover, it can have applications even in augmented reality (AR) technology. Using robotized gloves and micro-sensing tools such as the microfinger, many AR technologies concerning human-environment interactions on the microscale can be realized.

“With our strain-sensing microfinger, we were able to directly measure the pushing motion and force of the legs and torso of a pill bug – something that has been impossible to achieve previously! We anticipate that our results will lead to further technological development for microfinger-insect interactions, leading to human-environment interactions at much smaller scales,” remarks Prof. Konishi.

Indeed, the team at Ritsumeikan University has opened doors to a whole new world for humans to interact with. And we’re just as excited to explore it!

Title of original paper: Active tactile sensing of small insect force by a soft microfinger toward microfinger insect interactions
Journal: Scientific Reports
DOI: 10.1038/s41598-022-21188-2

About Professor Satoshi Konishi from Ritsumeikan University, Japan

Satoshi Konishi received the BS degree in 1991 in Electronics Engineering, the MS degree in 1993 and the PhD degree in 1996 in Electrical Engineering, from the University of Tokyo, Tokyo, Japan. He is currently a Professor at Ritsumeikan University, Japan, where he joined as faculty in 1996. He is also visiting Professor with Shiga University of Medical Science since 2007. His research interests concern microelectromechanical systems (MEMS) covering broad ranges from fundamental to applied fields. His current research focuses on biomedical MEMS, especially multiscale interfaces in biomedical engineering.

Funding information

The authors wish to thank a crowdfunding (Bluebacks Outreach) and Ritsumeikan Global Innovation Research Organization for their partial financial support.