On Ordering Multi-Robot Task Executions within a Cyber Physical System

Semwal, Tushar; Jha, Shashi Shekhar; Nair, Shivashankar B.

doi:10.1145/3124677

Cited by 14 publications

(4 citation statements)

References 43 publications

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“…Another model, using k-means clustering, works to solve the balanced multi-robot task allocation problem by minimising travel distance while optimising utilisation, which relates to task completion time [44]. Intended for use within a Cyber-Physical System such as a warehouse management system, task execution is asynchronously assigned to multiple robots in an ordering mechanism to allocate interdependent Human-Robot Collaboration (HRC) tasks [45]. The model uses mutual exclusion to allocate tasks, dynamically promoting system accuracy and robustness.…”

Section: Cobot Task Complexitymentioning

confidence: 99%

Task Complexity and the Skills Dilemma in the Programming and Control of Collaborative Robots for Manufacturing

et al. 2023

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While traditional industrial robots participate in repetitive manufacturing processes from behind caged safety enclosures, collaborative robots (cobots) offer a highly flexible and human-interactive solution to manufacturing automation. Rather than operating from within cages, safety features such as force and proximity sensors and programmed protection zones allow cobots to work safely, close to human workers. Cobots can be configured to either stop or slow their motion if they come in contact with a human or obstacle or enter a protection zone, which may be a high pedestrian traffic area. In this way, a task can be divided into sub-processes allocated to the cobot or the human based on suitability, capability or human preference. The flexible nature of the cobot makes it ideal for low-volume, ‘just-in-time’ manufacturing; however, this requires frequent reprogramming of the cobot to adapt to the dynamic processes. This paper reviews relevant cobot programming and control methods currently used in the manufacturing industry and alternative solutions proposed in the literature published from 2018 to 2023. The paper aims to (1) study the features and characteristics of existing cobot programming and control methods and those proposed in the literature, (2) compare the complexity of the task that the cobot is to perform with the skills needed to program it, (3) determine who is the ideal person to perform the programming role, and (4) assess whether the cobot programming and control methods are suited to that person’s skillset or if another solution is needed. The study is presented as a guide for potential adopters of cobots for manufacturing and a reference for further research.

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Section: Cobot Task Complexitymentioning

confidence: 99%

Task Complexity and the Skills Dilemma in the Programming and Control of Collaborative Robots for Manufacturing

et al. 2023

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“…The main task for the AGV was to transport items within the warehouse environment. Semwal et al [103] also introduced a CPS-based testbed warehouse where AGVs communicate with racks equipped with embedded boards with sensors. The communication amongst smart entities happens over Wi-Fi.…”

Section: Category 1: Shopfloor Operational-related Activitiesmentioning

confidence: 99%

A Systematic Review on Technologies for Data-Driven Production Logistics: Their Role from a Holistic and Value Creation Perspective

2021

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A data-driven approach in production logistics is adopted as a response to challenges such as low visibility and system rigidity. One important step for such a transition is to identify the enabling technologies from a value-creating perspective. The existing corpus of literature has discussed the benefits and applications of smart technologies in overall manufacturing or logistics. However, there is limited discussion specifically on a production logistics level, from a systematic perspective. This paper addresses two issues in this respect by conducting a systematic literature review and analyzing 142 articles. First, it covers the gap in literature concerning mapping the application of these smart technologies to specific production logistic activities. Ten groups of technologies were identified and production logistics activities divided into three major categories. A quantitative share assessment of the technologies in production logistics activities was carried out. Second, the ultimate goal of implementing these technologies is to create business value. This is addressed in this research by presenting the “production logistics data lifecycle” and the importance of having a balanced holistic perspective in technology development. The result of this paper is beneficial to build a ground to transit towards a data-driven state by knowing the applications and use cases described in the literature for the identified technologies.

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“…This CPS model has been configured for surgery implementations aiming to minimize the vulnerability of robotic surgery systems. Semwal et al propose a method to deal with the task execution order problem within a CPS that naturally organizes mutual exclusion (Semwal, Jha, & Nair, 2017). The method addresses a decentralized and distributed CPS that includes nodes such as computers, robots, and sensor nodes, and uses mobile software modules that help execute various tasks while also providing mutual exclusion of shared resources.…”

Section: Related Workmentioning

confidence: 99%

Adaptive Operation Model for Interior Smart Logistics in Cyber Physical Systems

Dönmez

Okumuş

Kocamaz

2021

Konya Journal of Engineering Sciences

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Logistics operations are among the main activities in industrial production areas. Today, vehicles that are usually electric and manually operated by a driver are used to perform these operations. Logistics robots are an important alternative that can be used in this field, and their use in integration with cyber physical systems in industrial fields is increasingly common. The biggest advantage of the logistics robots is that they provide autonomous driving capabilities and optimum parameters for the entire system in accordance with industry 4.0 concept. In this study, an adaptive logistics robot system that can be integrated into the Cyber Physical System (CPS) system in an environment with cyber physical system infrastructure has been developed. In this context, positioning, path planning, multi-task allocation, energy management, task prioritization, optimization and obstacle avoidance issues are analyzed and simple solutions are proposed. The experiments have been carried out in eight different configurations and the average distance and energy costs have been improved by 5.1% and 6.6%, respectively.

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On Ordering Multi-Robot Task Executions within a Cyber Physical System

Cited by 14 publications

References 43 publications

Task Complexity and the Skills Dilemma in the Programming and Control of Collaborative Robots for Manufacturing

Task Complexity and the Skills Dilemma in the Programming and Control of Collaborative Robots for Manufacturing

A Systematic Review on Technologies for Data-Driven Production Logistics: Their Role from a Holistic and Value Creation Perspective

Adaptive Operation Model for Interior Smart Logistics in Cyber Physical Systems

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