[{“box”:0,”content”:”[if 992 equals=”Open Access”]n
n
Open Access
nn
n
n[/if 992]n
n
n
n
n
n
Ankit Yadav, Sambhav Sharma, Nazish Ahmed, Naveen Dehariya, Hemant Choubey
n
- n t
n
n
n[/foreach]
n
n[if 2099 not_equal=”Yes”]n
- [foreach 286] [if 1175 not_equal=””]n t
- Student, Student, Student, Student, Student Department of Electronics and Telecommunication Engineering, MITS Gwalior (Deemed to be University), Gwalior, Department of Electronics and Telecommunication Engineering, MITS Gwalior (Deemed to be University), Gwalior, Department of Electronics and Telecommunication Engineering, MITS Gwalior (Deemed to be University), Gwalior, Department of Electronics and Telecommunication Engineering, MITS Gwalior (Deemed to be University), Gwalior, Department of Electronics and Telecommunication Engineering, MITS Gwalior (Deemed to be University), Gwalior Madhya Pradesh, Madhya Pradesh, Madhya Pradesh, Madhya Pradesh, Madhya Pradesh India, India, India, India, India
n[/if 1175][/foreach]
n[/if 2099][if 2099 equals=”Yes”][/if 2099]n
Abstract
nThe number of people who like driving remote-control cars has skyrocketed over time, and many of them are searching for high-performance cars that will give them thrilling experiences. Using a nitro-powered engine, the Nitro Remote Control Car Design and Fabrication project aims to develop a cutting-edge, powerful remote-controlled car with exhilarating performance and speed. The remote control car is designed to provide better customer experience and works well. Thanks to the combination of latest hardware and software, our remote control cars feature intuitive, precise control and advanced performance. Using Smartphone connections, users can work remotely with ease and precision from their cars, from anywhere with an internet connection. Additionally, the integration of autonomous navigation functionality adds convenience and versatility to the system. These concepts highlight the potential uses of technology in various fields such as entertainment, education, and research. Our body aims to define the standards of user interface and performance in the RC car world, pushing boundaries of traditional RC car design.
n
Keywords: Remote Control, mechanics, design, arduino Uno board, fabrication
n[if 424 equals=”Regular Issue”][This article belongs to Journal of Microelectronics and Solid State Devices(jomsd)]
n
n
n
n
n
nn[if 992 equals=”Open Access”] Full Text PDF Download[/if 992] n[if 992 not_equal=”Open Access”]
[/if 992]n[if 992 not_equal=”Open Access”] nnn[/if 992]nn[if 379 not_equal=””]n
Browse Figures
n
n
n[/if 379]n
References
n[if 1104 equals=””]n
- TKS06] Tapan K. Sarkar, History of Wireless, John Wiley & Sons, 2006, pages 276-278, ISBN 0-471-71814-9
- Arduino UNO Link: https://docs.arduino.cc/hardware/uno-rev3/
- Source code from Arduino official web side https://projecthub.arduino.cc/samanfern/bluetooth-controlled-car-c71cd0
- Application for controlling Device – https://bluetooth-rccar.en.softonic.com/andro
- Instruction for assembly and working Step by step information by – SriTu Hobby
- Mittal A., Rana P., Joshi A., & Kothiyal P.: “Methanol Powered Small Wireless Remote Controlled I.C. Engine Driven Car”, Internation al Journal of Machine Engineering a nd Research, Vol. 3, No. 4 (2013), pp. 317-326
- Parnpanomchai C., & Traka rnsiriont N.: “Operating RadioCont rolling Car via the internet Network “, IACSIT International Journal of E ngineering and Technology, Vol. 3, No. 6 (2011), pp. 701-705
- Parnpanomchai C., & Sukkl ay P.: “Operating Radio-Controllin g Cars by Computer”, IACSIT Inter national Journal of Engineering and Technology, Vol. 3, No. 3 (2011), p p. 215-219
- Lombard L.: “SolidWorks 2010 Bible”, Canada (2010), pp. 1045-10 72, ISBN: 978-0-470-55481-4. Av ailable on Web site: http://www.col orado4wheel.com/manuals/Solidw orks%202010%20Bible.pdf, last vis it: 2.07.2014
- De Clerk M, Dangelmaier M, Schmierer G, Spath D. User centered design of interaction techniques for VR-based automotive design reviews. Frontiers in Robotics and AI. 2019 Mar 21;6: 13.
- Fernández Saviñón JF. A usability study of a Tactile-Tangible User Interface for the remote control of a Robotic Element on interactive surfaces.
nn[/if 1104][if 1104 not_equal=””]n
- [foreach 1102]n t
- [if 1106 equals=””], [/if 1106][if 1106 not_equal=””],[/if 1106]
n[/foreach]
n[/if 1104]
nn
nn[if 1114 equals=”Yes”]n
n[/if 1114]
n
n
n
Journal of Microelectronics and Solid State Devices
n
n
n
n
n
n
Volume | 11 | |
[if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] | 01 | |
Received | May 5, 2024 | |
Accepted | May 18, 2024 | |
Published | May 31, 2024 |
n
n
n
n
n
n function myFunction2() {n var x = document.getElementById(“browsefigure”);n if (x.style.display === “block”) {n x.style.display = “none”;n }n else { x.style.display = “Block”; }n }n document.querySelector(“.prevBtn”).addEventListener(“click”, () => {n changeSlides(-1);n });n document.querySelector(“.nextBtn”).addEventListener(“click”, () => {n changeSlides(1);n });n var slideIndex = 1;n showSlides(slideIndex);n function changeSlides(n) {n showSlides((slideIndex += n));n }n function currentSlide(n) {n showSlides((slideIndex = n));n }n function showSlides(n) {n var i;n var slides = document.getElementsByClassName(“Slide”);n var dots = document.getElementsByClassName(“Navdot”);n if (n > slides.length) { slideIndex = 1; }n if (n (item.style.display = “none”));n Array.from(dots).forEach(n item => (item.className = item.className.replace(” selected”, “”))n );n slides[slideIndex – 1].style.display = “block”;n dots[slideIndex – 1].className += ” selected”;n }n”}]