Scientists are developing a translator robot that allows bees and fish to talk to each other for the first time



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Scientists develop a radical translator robot that allows bees and fish to talk to each other for the first time

  • A new robotic robot interface allows bees and fish to communicate
  • The system reads the biological signals of the animals and interprets them Consequently
  • Researchers say technology can help influence animal behavior for the better

Fish and bees can now talk to each other via a "walkie-talkie" system, scientists said.

The communication system between two separate species colonies was made possible using specially designed mini robots and terminals.

Tiny terminals were enshrined in a colony of bees and a robotic fish-robber was planted among a school of fish.

The signals from the two physically separated colonies were then translated into a language that each species can understand.

Researchers have developed a robotic fish that can integrate into schools to translate signals and influence behavior

Researchers have developed a robotic fish that can integrate into schools to translate signals and influence behavior

The terminal located inside the bee colony communicated with each other by fluctuations in air temperature, movements and vibrations, while the spy robot of the school of fish changed from one to another. color, speed and movements.

As a result, the bees began to swarm outside their terminal, while the fish began to change their swimming patterns, counterclockwise.

"The robots acted as if they were negotiators and interpreters at an international conference," said Francesco Mondada, professor at BioRob, at TechXplore.

"Through various information exchanges, the two groups of animals have gradually made a joint decision."

Although the prospect of communicating unusual pairs of species seems to be a more fun exercise than science, researchers say the application of this feat has real applications in the world of biological research.

"This is the first time people have used this type of technology for two different species to communicate," Simon Garnier, a complex systems biologist at The New Jersey Institute of Technology, told The Scientist.

A terminal inside the bee colony communicated by fluctuations in air temperature and other signals, the robot integrated into the school of fish has changed color, speed and movement.

A terminal inside the bee colony communicated by fluctuations in air temperature and other signals, the robot integrated into the school of fish has changed color, speed and movement.

As a result, the bees began to swarm outside their terminal, while the fish began to change their swimming patterns, counterclockwise.

As a result, the bees began to swarm outside their terminal, while the fish began to change their swimming patterns, counterclockwise.

ANIMAL-ROBOT INTERFACE

Robots embedded in both environments were able to collect biological information from both groups.

The machines then translated these signals into understandable information.

After a while, bees and fish began to react to information triggered by each other and to adapt their behavior.

"It's a proof of concept that you can make robots mediate interactions between remote groups."

Scientists explain in particular that the benefits of research are twofold.

The findings could help robotics engineers understand and adapt methods for capturing biological signals from certain animal groups.

In addition, the data could help to better understand how certain animals interact and why.

In a more futuristic perspective, advances in this type of robotic technology could also help develop some types of artificially intelligent robots that biologists could use to improve the lives of animals.

Specifically, the technology could help move animals away from polluted areas or other adverse consequences.

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