Image 1 - Rather than start from scratch after a failed attempt, the robot adapts in the moment to reflexively roll, palm, or pinch an object to get a better hold.

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Robo-gripper grasps by reflex

Creator: MIT

Country: United States of America

Year: 2023

Summary

Rather than start from scratch after a failed attempt, the robot adapts in the moment to reflexively roll, palm, or pinch an object to get a better hold.

Status: Prototype, Research

Operation: Autonomous, Semi-autonomous

Robot Type / Domain: Research

Tasks: pick-and-place

Learn More

Below is from "Jennifer Chu. (2023, April 27). Speedy robo-gripper reflexively organizes cluttered spaces. MIT News Office. Retrieved from https://news.mit.edu/2023/speedy-robo-gripper-reflexively-organizes-spaces-0427"

"When manipulating an arcade claw, a player can plan all she wants. But once she presses the joystick button, it’s a game of wait-and-see. If the claw misses its target, she’ll have to start from scratch for another chance at a prize.

The slow and deliberate approach of the arcade claw is similar to state-of-the-art pick-and-place robots, which use high-level planners to process visual images and plan out a series of moves to grab for an object. If a gripper misses its mark, it’s back to the starting point, where the controller must map out a new plan.

Looking to give robots a more nimble, human-like touch, MIT engineers have now developed a gripper that grasps by reflex. Rather than start from scratch after a failed attempt, the team’s robot adapts in the moment to reflexively roll, palm, or pinch an object to get a better hold. It’s able to carry out these “last centimeter” adjustments (a riff on the “last mile” delivery problem) without engaging a higher-level planner, much like how a person might fumble in the dark for a bedside glass without much conscious thought.

The new design is the first to incorporate reflexes into a robotic planning architecture. For now, the system is a proof of concept and provides a general organizational structure for embedding reflexes into a robotic system. Going forward, the researchers plan to program more complex reflexes to enable nimble, adaptable machines that can work with and among humans in ever-changing settings."

Technical Specifications

Robot Type: Hand / Gripper

Max. Reach: N/A

Max. Payload: N/A

Weight: 1.2 kg

Weight: 2.646 lbs

Max. Speed: N/A

Max. Slope: N/A

Battery Operated? N/A

Average Runtime: N/A

Max. Runtime: N/A

Battery Recharge Time: N/A

Min. Size: N/A

Max. Size: N/A

Mobility: Other

Locomotion Type: N/A

Number of Axes: 7 DoF

Manipulation: N/A

IP Rating: N/A

Operating Temperature: N/A

Open-source? N/A

Price: N/A

Show more specs

DoFs per finger: 4

Material: The finger linkages are made of 7075-T6 aluminum alloy, with ball bearings supporting every joint shaft and routing pulley.

Actuators: Dynamixel XM540 actuator at the wrist. Each finger joint is driven by an antagonistic pair of tungsten cables routed through the finger to Dynamixel XM430 actuators.

Data Transmission / Communication: a custom PCB for the gripper to receive commands from the control computer over a CAN bus

No more specs to show.

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References

SaLoutos, A., Kim, H., Stanger-Jones, E., Guo, M., & Kim, S. (2023). Towards Robust Autonomous Grasping with Reflexes Using High-Bandwidth Sensing and Actuation. arXiv preprint arXiv:2209.11367.

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