Abstract
For robots to attain more general-purpose utility, grasping is a necessary skill to master. Such general-purpose robots may use their perception abilities to visually identify grasps for a given object. A grasp describes how a robotic end-effector can be arranged to securely grab an object and successfully lift it without slippage. Traditionally, grasp detection requires expert human knowledge to analytically form the task-specific algorithm, but this is an arduous and time-consuming approach. During the last five years, deep learning methods have enabled significant advancements in robotic vision, natural language processing, and automated driving applications. The successful results of these methods have driven robotics researchers to explore the use of deep learning methods in task-generalised robotic applications. This paper reviews the current state-of-the-art in regards to the application of deep learning methods to generalised robotic grasping and discusses how each element of the deep learning approach has improved the overall performance of robotic grasp detection. Several of the most promising approaches are evaluated and the most suitable for real-time grasp detection is identified as the one-shot detection method. The availability of suitable volumes of appropriate training data is identified as a major obstacle for effective utilisation of the deep learning approaches, and the use of transfer learning techniques is proposed as a potential mechanism to address this. Finally, current trends in the field and future potential research directions are discussed.
Highlights
Recent advancements in robotics and automated systems have led to the expansion of autonomous capabilities and more intelligent machines being utilised in ever more varied applications [1,2].The capability of adapting to changing environments is a necessary skill for task generalised robots [3,4]
The availability of suitable volumes of appropriate training data is identified as a major obstacle for effective utilisation of the deep learning approaches, and the use of transfer learning techniques is proposed as a potential mechanism to address this
We identify the grasp detection sub-system as the key entry point for any robotic grasping research and aim to review current deep learning methods in grasp detection through the subsequent sections of this paper
Summary
Recent advancements in robotics and automated systems have led to the expansion of autonomous capabilities and more intelligent machines being utilised in ever more varied applications [1,2].The capability of adapting to changing environments is a necessary skill for task generalised robots [3,4]. Traditional analytical approaches, known as hard coding, involve manually programming a robot with the necessary instructions to carry out a given task. These control algorithms are modelled based on expert human knowledge of the robot and its environment in the specific task. Direct mapping of results from a kinematic model to the robot joint controller is inherently open-loop and is identified to cause task space drifts. They have, in addition, recommended the use of closed loop control algorithms to address these drifts [2]
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