Design and Implementation of a Wireless Medical Robot for Communication Within Hazardous Environments

Maher, Nashat; El-Sheikh, G. A.; Ouda, Ahmed Nasr; Anis, Wagdy R.; Emara, Tamer

doi:10.1007/s11277-021-08954-7

Cited by 5 publications

(4 citation statements)

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Among these, the Caputo method is the most widely used definition in engineering applications, and is represented by Eq. (2).…”

Section: Fopid Controller Implementationmentioning

confidence: 99%

“…Currently, the developments in science and technology enable the appearance of commercial robots in the industrial field, where the requirement for a programmable vehicle that can move in three-dimensional workspace for tasks execution is getting increasing every day. Wheeled mobile robots have become increasingly important in a range of industrial applications [1][2][3][4][5][6]. In order to achieve such challenging demands, a high efficiency control methodology with fast time response for tracking both speed and orientation angle during the task's execution is required, while mobile robot interactions and their nonlinear structure make it challenging to implement control algorithms.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Improved Path Tracking Control in Mobile Robots Using a Hybrid FOPID Controller with Backstepping Technique: An Experimental Study

Euldji¹,

Rebhi²,

Alkhafaji³

et al. 2023

JESA

View full text Add to dashboard Cite

This study aims to address the challenge of low-cost hardware implementation of a combined backstepping with fractional order PID (FOPID) controller for mobile robots in real-time applications. Moreover, this work proposes a self-designed mobile robot prototype that is easy to realize, low in cost, spares time, and reduces human effort. This robot platform was equipped with two DC motors with quadratic encoders and two passive wheels, controlled by an Arduino mega, where the software code was developed in the Matlab-Simulink environment, using Simulink support package for Arduino. Four case studies were conducted to demonstrate the effectiveness of the suggested methodology. Experimental results demonstrate improved trajectory tracking performance with less tracking error and smooth control efforts, and is capable of handling trajectories with continuous and non-continuous gradients.

show abstract

“…Among these, the Caputo method is the most widely used definition in engineering applications, and is represented by Eq. (2).…”

Section: Fopid Controller Implementationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Improved Path Tracking Control in Mobile Robots Using a Hybrid FOPID Controller with Backstepping Technique: An Experimental Study

Euldji¹,

Rebhi²,

Alkhafaji³

et al. 2023

JESA

View full text Add to dashboard Cite

show abstract

“…Due to their simplicity, affordability, and versatility, WMRs are used in a wide variety of applications. This kind of robot can be utilized for medications and supplies delivery in hospitals and other healthcare facilities [1,2]. For manufacturing and logistics, WMRs can be used to deliver goods and material handling in indoor, urban and suburban areas [3][4][5].…”

Section: Introductionmentioning

confidence: 99%

An Analysis of Sliding Mode Speed Controller for a Differential Drive Wheel Mobile Robot

Vu,

Tran

2024

J. ADV. ENG. COMPUT.

View full text Add to dashboard Cite

In this study, we present a systematically designed Sliding Mode Speed Controller (SMSC) tailored for motors utilized in a Differential Drive Wheel Mobile Robot (DDWMR). Our analysis delves into the critical parameters of the SMSC, including convergence and reaching rates, alongside simulation configurations such as time step. We concurrently consider metrics like rising time, steady-state error, and control ripple factors to optimize performance. Through comprehensive evaluation across various case studies, we demonstrate the efficacy of the fine-tuned SMSC in enhancing the overall performance of the DDWMR. Our simulation results underscore the significance of meticulous parameter tuning, particularly emphasizing the role of time step settings. We find that a smaller time step mitigates chattering phenomena and improves performance, albeit at the cost of increased computational demands and potentially heightened hardware requirements.

show abstract

“…Traditional robots tend to have stiff constructions, which are less safe and flexible [3][4][5]. On the other hand, the soft robot is a novel kind of robot composed of flexible or telescopic materials that has limitless degrees of freedom, remarkable agility, and inherent elasticity [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Dielectric Elastomer-Driven Bionic Inchworm Soft Robot Realizes Forward and Backward Movement and Jump

Jing

Chen

2022

Actuators

View full text Add to dashboard Cite

To produce multi-modal mobility in complicated situations is a significant issue for soft robots. In this study, we show the conception, construction, and operation of an inchworm-impersonating dielectric elastomer-activated soft robot. The robot is small and lightweight, weighing only 3.5 g, and measuring an overall 110 mm by 50 mm by 60 mm (length, width, and height). The three mobility modes for the robot are each equipped with a detailed mechanism. When the excitation voltage is 5 kV, the robot runs forward under a frequency of stimulation of 1–9 Hz, and its direction of motion changes to a backwards motion at >10 Hz. When the excitation voltage of 5.5 kV is applied to the robot, the robot runs forward at 1–12 Hz frequency and moves in the opposite direction at 13 Hz, reaching the fastest reverse speed of 240 mm/s. When the excitation voltage rises to 6 kV, the robot reaches its fastest running speed of 270 mm/s at 14 Hz. Motivated by high voltage and high duty cycle, the robot can jump over obstacles of 5 mm. In order to assess the performance of backward running, the speed achieved by the robot under a 30% duty cycle and a 50% duty cycle was compared, as well as the speed of the robot with or without the use of a counterweight. The robot has a simpler design and construction than earlier soft robots of the same kind, as well as a quicker speed, a wider variety of movement modes, and other notable advantages.

show abstract

Design and Implementation of a Wireless Medical Robot for Communication Within Hazardous Environments

Cited by 5 publications

References 24 publications

Improved Path Tracking Control in Mobile Robots Using a Hybrid FOPID Controller with Backstepping Technique: An Experimental Study

Improved Path Tracking Control in Mobile Robots Using a Hybrid FOPID Controller with Backstepping Technique: An Experimental Study

An Analysis of Sliding Mode Speed Controller for a Differential Drive Wheel Mobile Robot

Dielectric Elastomer-Driven Bionic Inchworm Soft Robot Realizes Forward and Backward Movement and Jump

Contact Info

Product

Resources

About