Abstract
Continuum robots exhibit great potential in a number of challenging applications where traditional rigid link robots pose certain limitations, e.g., working in unstructured environments. In order to enable the usage of continuum robots in safety-critical applications, such as surgery and nuclear decontamination, it is extremely important to ensure a safe path for the robot's movement. Existing algorithms for continuum robot path planning have certain limitations that need to be addressed. These include the fact that none of the algorithms provide safety assurance parameters and control for path planning. They are computationally expensive, applicable to a specific type of continuum robots, and mostly they do not incorporate design and kinematics constraints. In this paper, we propose a points-based path planning (PoPP) algorithm for continuum robots that computes the path by imposing safety constraints and improves upon the limitations of existing approaches. In the algorithm, we exploit the constant curvature-bending property of continuum robots in their path planning process. The algorithm is computationally efficient and provides a good tradeoff between accuracy and efficiency that can be implemented to enable the safety-critical application of continuum robots. This algorithm also provides information regarding path volume and flexibility in movement. Simulation results confirm that the algorithm possesses promising potential for all types of continuum robots (following the constant curvature-bending property). We believe that this effectively balances the desired safety and efficiency requirements.
Highlights
Robot designers have numerous design options when designing their machines
Continuum robots do not have rigid links/joints but present continuous flexibility in their structure. Because of their continuously bending architecture, continuum robots can manoeuvre through an unstructured congested workspace and can overcome the limitations posed by traditional robots [2, 3, 4]
The potential field method (PFM) algorithm is faster compared to the sine method (SM) algorithm, and enormous research has been carried out
Summary
Robot designers have numerous design options when designing their machines. With time, the number of such design options continues to increase and/or be refined based upon technological advancements, inspiration from nature, and the designer‘s own imagination [1]. This property has been exploited by different research‐ ers to propose different designs and kinematics models of continuum robots [4, 5] They exhibit significant potential in many challenging applications where traditional rigid links/joints-based robots have certain limitations. The proposed methodology does not incorporate the obstacle avoidance and kinematics con‐ straints that continuum robots have This methodology is computationally expensive and is based on continuous deformation for specific shape-based path planning. The main contribution of this paper is the proposed PoPP algorithm for continuum robots, which computes the locally optimal path by imposing safety constraints and improves upon the limitations that have been identified in existing approaches.
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