Develop and Design Small Scale UAV

Hairol Nizam Mohd Shah, Muhammad Aiman Mohamad Sebir, Mohd Fairus Abdollah, Mohd Rizuan Baharon, Azhar Ahmad, Mohd Ali Arshad
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Abstract

Nowadays, many people want to buy a small-scale unmanned aerial vehicle (UAV) either for recreational purposes, photography and video editing or for air surveillance. The main issue with conventional small-scale UAVs is that they require experience to operate them. Besides that, the control system also plays important role for its flight stability and endurance for small-scale UAV. The weight of the load and travelling speed also being issued for small-scale UAV. As a result, three objectives were formulated based on the problem statement which are to fabricate the appropriate size of a small-scale UAV in term of its mass and frame size; to design the control system and increase the stability of the small-scale UAV; and to test the flight endurance of the small-scale UAV. This research is conducted through the following methodology, which is designing the quadcopter body mainframe, constructing the circuit diagram, developing the RC transmitter and receiver for Arduino and testing the UAV functionality and flight test. Softwares that were involved in this project are Solidworks, Arduino compiler, Proteus, Processing and Matlab. The equipments that are used are Arduino UNO, MPU-6050 sensor, Li-Po 11.1V battery, Electronic Speed Controller (ESC), brushless DC motor, 2.4 GHZ RC transmitter and 6-channel receiver. The limitation also being found from those experiments. Finally, the results and discussion will show and explain about the early sketch for quadcopter body mainframe including dimension for each part and stress-strain diagram using Solidworks. It also includes the simulation and hardware connection for brushless DC motor and MPU-6050 sensor using Proteus, Arduino compiler, Processing and Matlab software.
开发和设计小型无人机
如今,很多人都想买一架小型无人机(UAV),用于娱乐、摄影和视频编辑或空中监视。传统小型无人机的主要问题是它们需要经验来操作。此外,控制系统对小型无人机的飞行稳定性和续航力也起着重要作用。载荷的重量和飞行速度也被发布给小型无人机。在此基础上制定了3个目标:制造出质量和骨架尺寸合适的小型无人机;设计控制系统,提高小型无人机的稳定性;并测试小型无人机的飞行耐力。本研究通过以下方法进行:设计四轴飞行器主体主机,构建电路图,开发Arduino的RC发射器和接收器,测试无人机功能和飞行测试。本项目涉及的软件有Solidworks, Arduino编译器,Proteus, Processing, Matlab。所使用的设备是Arduino UNO, MPU-6050传感器,Li-Po 11.1V电池,电子调速控制器(ESC),无刷直流电机,2.4 GHZ RC发射器和6通道接收器。这些实验也发现了局限性。最后,结果和讨论将显示和解释关于四轴飞行器主体主机的早期草图,包括每个部分的尺寸和使用Solidworks的应力应变图。利用Proteus、Arduino编译器、Processing和Matlab软件对无刷直流电动机和MPU-6050传感器进行仿真和硬件连接。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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