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1. Scaling Up Soft Robotics: A Meter-Scale, Modular, and Reconfigurable Soft Robotic System

   https://doi.org/10.1089/soro.2020.0123  

   Li, Shuguang; Awale, Samer A.; Bacher, Katharine E.; Buchner, Thomas J.; Della Santina, Cosimo; Wood, Robert J.; Rus, Daniela (May 2021, Soft Robotics)

   null (Ed.)

   Today’s use of large-scale industrial robots is enabling extraordinary achievement on the assembly line, but these robots remain isolated from the humans on the factory floor because they are very powerful, and thus dangerous to be around. In contrast, the soft robotics research community has proposed soft robots that are safe for human environments. The current state of the art enables the creation of small-scale soft robotic devices. In this article we address the gap between small-scale soft robots and the need for human-sized safe robots by introducing a new soft robotic module and multiple human-scale robot configurations based on this module. We tackle large-scale soft robots by presenting a modular and reconfigurable soft robotic platform that can be used to build fully functional and untethered meter-scale soft robots. These findings indicate that a new wave of human-scale soft robots can be an alternative to classic rigid-bodied robots in tasks and environments where humans and machines can work side by side with capabilities that include, but are not limited to, autonomous legged locomotion and grasping. 

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2. Modular Stimuli‐Responsive Valves for Pneumatic Soft Robots

   https://doi.org/10.1002/aisy.202400659  

   He, Qiguang; Yin, Rui; Hua, Yucong; Shu, Hang; Zhu, Xiaoheng; Haque, A_B_M Tahidul; Ferracin, Samuele; Patel, Saheli; Jiao, Weijian; Raney, Jordan R (November 2024, Advanced Intelligent Systems)

   Pneumatic soft robots have several advantages, including facile fabrication, versatile deformation modes, and safe human–machine interaction. However, pneumatic soft robots typically rely on mechatronics to interact with their environment, which can limit their form factors and reliability. Researchers have considered how to achieve autonomous behaviors using the principles of mechanical computing and physical intelligence. Herein, modular responsive valves that can autonomously regulate airflow within pneumatic soft robots in response to various environmental stimuli, including light, water, and mechanical forces, are described. By combining multiple types of valves, autonomous logic gates and more advanced logical operations can be realized. Finally, it is demonstrated that responsive valves can be integrated with pneumatic soft robots, allowing autonomous morphing and navigation. This framework provides a strategy for creating autonomous pneumatic robots that can respond to multiple stimuli in their environment. 

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3. Multirobot Control Strategies for Collective Transport

   https://doi.org/10.1146/annurev-control-042920-095844  

   Farivarnejad, Hamed; Berman, Spring (May 2022, Annual Review of Control, Robotics, and Autonomous Systems)

   One potential application of multirobot systems is collective transport, a task in which multiple robots collaboratively move a payload that is too large or heavy for a single robot. In this review, we highlight a variety of control strategies for collective transport that have been developed over the past three decades. We characterize the problem scenarios that have been addressed in terms of the control objective, the robot platform and its interaction with the payload, and the robots’ capabilities and information about the payload and environment. We categorize the control strategies according to whether their sensing, computation, and communication functions are performed by a centralized supervisor or specialized robot or autonomously by the robots. We provide an overview of progress toward control strategies that can be implemented on robots with expanded autonomous functionality in uncertain environments using limited information, and we suggest directions for future work on developing such controllers. 

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4. Strain-Based Consensus in Soft, Inflatable Robots

   https://doi.org/10.1109/RoboSoft54090.2022.9762180  

   Nilles, Alexandra; Ceron, Steven; Napp, Nils; Petersen, Kirstin (April 2022, IEEE Intl. Conference on Soft Robotics)

   Soft robots actuate themselves and their world through induced pressure and strain, and can often sense these quantities as well. We hypothesize that coordination in a tightly coupled collective of soft robots can be achieved with purely proprioceptive sensing and no direct communication. In this paper, we target a platform of soft pneumatic modules capable of sensing strain on their perimeter, with the goal of using only the robots' own soft actuators and sensors as a medium for distributed coordination. However, methods for modelling, sensing, and controlling strain in such soft robot collectives are not well understood. To address this challenge, we introduce and validate a computationally efficient spring-based model for two-dimensional sheets of soft pneumatic robots. We then translate a classical consensus algorithm to use only proprioceptive data, test in simulation, and show that due to the physical coupling between robots we can achieve consensus-like coordination. We discuss the unique challenges of strain sensors and next steps to bringing these findings to hardware. These findings have promising potential for smart materials and large-scale collectives, because they omit the need for additional communication infrastructure to support coordination. 

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5. Tube-Balloon Logic for the Exploration of Fluidic Control Elements

   https://doi.org/10.1109/LRA.2022.3156174  

   Tracz, Jovanna A.; Wille, Lukas; Pathiraja, Dylan; Kendre, Savita V.; Pfisterer, Ron; Turett, Ethan; Abrahamsson, Christoffer K.; Root, Samuel E.; Lee, Won-Kyu; Preston, Daniel J.; et al (April 2022, IEEE Robotics and Automation Letters)

   The control of pneumatically driven soft robots typically requires electronics. Microcontrollers are connected to power electronics that switch valves and pumps on and off. As a recent alternative, fluidic control methods have been introduced, in which soft digital logic gates permit multiple actuation states to be achieved in soft systems. Such systems have demonstrated autonomous behaviors without the use of electronics. However, fluidic controllers have required complex fabrication processes. To democratize the exploration of fluidic controllers, we developed tube-balloon logic circuitry, which consists of logic gates made from straws and balloons. Each tube-balloon logic device takes a novice five minutes to fabricate and costs $0.45. Tube-balloon logic devices can also operate at pressures of up to 200 kPa and oscillate at frequencies of up to 15 Hz. We configure the tube-balloon logic device as NOT-, NAND-, and NOR-gates and assemble them into a three-ring oscillator to demonstrate a vibrating sieve that separates sugar from rice. Because tube-balloon logic devices are low-cost, easy to fabricate, and their operating principle is simple, they are well suited for exploring fundamental concepts of fluidic control schemes while encouraging design inquiry for pneumatically driven soft robots. 

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