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8 results on '"Narkhede, Kunal Sanjay"'

1. Reactive Gait Composition with Stability: Dynamic Walking amidst Static and Moving Obstacles

Author

Narkhede, Kunal Sanjay, Motahar, Mohamad Shafiee, Veer, Sushant, and Poulakakis, Ioannis

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

This paper presents a modular approach to motion planning with provable stability guarantees for robots that move through changing environments via periodic locomotion behaviors. We focus on dynamic walkers as a paradigm for such systems, although the tools developed in this paper can be used to support general compositional approaches to robot motion planning with Dynamic Movement Primitives (DMPs). Our approach ensures a priori that the suggested plan can be stably executed. This is achieved by formulating the planning process as a Switching System with Multiple Equilibria (SSME) and proving that the system's evolution remains within explicitly characterized trapping regions in the state space under suitable constraints on the frequency of switching among the DMPs. These conditions effectively encapsulate the low-level stability limitations in a form that can be easily communicated to the planner to guarantee that the suggested plan is compatible with the robot's dynamics. Furthermore, we show how the available primitives can be safely composed online in a receding horizon manner to enable the robot to react to moving obstacles. The proposed framework is applied on 3D bipedal walking models under common modeling assumptions, and offers a modular approach towards stably integrating readily available low-level locomotion control and high-level planning methods., Comment: 20 pages, 11 figures

Published
2023

2. A Sequential MPC Approach to Reactive Planning for Bipedal Robots

Author

Narkhede, Kunal Sanjay, Kulkarni, Abhijeet Mangesh, Thanki, Dhruv Ashwinkumar, and Poulakakis, Ioannis

Subjects
Computer Science - Robotics
Abstract

This paper presents a sequential Model Predictive Control (MPC) approach to reactive motion planning for bipedal robots in dynamic environments. The approach relies on a sequential polytopic decomposition of the free space, which provides an ordered collection of mutually intersecting obstacle free polytopes and waypoints. These are subsequently used to define a corresponding sequence of MPC programs that drive the system to a goal location avoiding static and moving obstacles. This way, the planner focuses on the free space in the vicinity of the robot, thus alleviating the need to consider all the obstacles simultaneously and reducing computational time. We verify the efficacy of our approach in high-fidelity simulations with the bipedal robot Digit, demonstrating robust reactive planning in the presence of static and moving obstacles., Comment: 10 pages, 7 figures

Published
2022

3. A Backstepping control strategy for constrained tendon driven robotic finger

Author

Narkhede, Kunal Sanjay, Bhise, Aashay Anil, Sainul, IA, and Deb, Sankha

Subjects
Computer Science - Systems and Control
Abstract

The task of controlling an underactuated robotic finger with a single tendon and a single actuator is difficult. Methods for controlling the class of underactuated systems are available in the literature. However, this particular system does not fall into the class of underactuated system. This paper presents a design change which introduces kinematic constraints into the system, making the system controllable. Backstepping control strategy is used to control the system. Simulation results are presented for single finger driven by a single actuator., Comment: To appear in the Proceedings of IEEE ICCAR 2019

Published
2018

4. Reactive Gait Composition With Stability: Dynamic Walking Amidst Static and Moving Obstacles.

Author

Narkhede, Kunal Sanjay, Motahar, Mohamad Shafiee, Veer, Sushant, and Poulakakis, Ioannis

Subjects
*BIPEDALISM, *ROBOTIC path planning, *LIMIT cycles, *DYNAMIC stability, *MATHEMATICS, *ROBOT motion
Abstract

This paper presents a modular approach to motion planning with provable stability guarantees for robots that move through changing environments via periodic locomotion behaviors. We focus on dynamic walkers as a paradigm for such systems, although the tools developed in this paper can be used to support general compositional approaches to robot motion planning with dynamic movement primitives (DMPs). By formulating the planning process as a switching system with multiple equilibria (SSME), we prove that the system's evolution remains within explicitly characterized trapping regions in the state space under suitable constraints on the frequency of switching among the DMPs. These conditions encapsulate the low-level stability limitations in a form that can be easily communicated to the planner. Furthermore, we show how the available primitives can be safely composed online in a receding horizon manner to enable the robot to react to moving obstacles. The proposed framework can be applied in a wide class of 3D bipedal walking models, and offers a modular approach for integrating readily available low-level locomotion control and high-level planning methods. [ABSTRACT FROM AUTHOR]

Published
2024
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