Detection Brake Condition of Vehicle Using Fuzzy Logic in Visible Light Communication

2020 6th International Conference on Science in Information Technology (ICSITech) Pub Date : 2020-10-21 DOI:10.1109/ICSITech49800.2020.9392048

A. Aditya, Faridatun Ni’mah, H. Mahmudah, Okkie Puspitorini, N. Siswandari, A. Wijayanti

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引用次数: 1

Abstract

The number of motorized vehicles operating in Indonesia is increasing, especially two-wheeled motorized vehicles. This also triggers problems such as traffic jams and accidents. Warning from brake lights is not always effective to prevent collisions. Intelligent Transport System (ITS) offers a solution that is a future trend that refers to wireless communication as a system to detect and prevent accidents. In this research, a Vehicle to Vehicle (V2V) communication system using VLC consists of Leading Vehicle (LV) and Following Vehicle (FV). In LV there is an accelerometer that is used to detect the type of brake, namely No Brake, Brake and Hard Brake. The result of calculation of fuzzy logic data is binary data sent by VLC. VLC transmitter design uses and without lenses send binary data. Binary data is sent by V2V communication between LV and FV using VLC. FV detects binary data using a photodiode in day and night conditions. The performance LV that are fuzzy logic algorithm values used have an accuracy value of 87.5%. The results of brake detection using Fuzzy Logic algorithm are binary data sent 2 second sampling time through visible light communication. The binary data process transmitted process at daytime and night. Result highest accuracy using a lens is 58.33% at daytime and 72.34% at night.

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利用可见光通信中的模糊逻辑检测车辆制动状态

在印度尼西亚运营的机动车辆数量正在增加，特别是两轮机动车辆。这也引发了交通堵塞和事故等问题。刹车灯的警告并不总是有效地防止碰撞。智能交通系统(ITS)提供了一种解决方案，这是未来的趋势，它将无线通信作为一种检测和预防事故的系统。在本研究中，使用VLC的车对车(V2V)通信系统由领先车辆(LV)和跟随车辆(FV)组成。在LV中有一个加速度计，用于检测制动类型，即无制动，制动和硬制动。模糊逻辑数据的计算结果是VLC发送的二进制数据。VLC发射机设计使用和不使用镜头发送二进制数据。使用VLC在LV和FV之间通过V2V通信发送二进制数据。FV在白天和夜间使用光电二极管检测二进制数据。所使用的模糊逻辑算法值的性能LV精度值为87.5%。采用模糊逻辑算法的制动检测结果是2秒采样时间通过可见光通信发送的二进制数据。二进制数据传输过程分白天和夜间进行。结果该镜头在白天和夜间的最高使用精度分别为58.33%和72.34%。

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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来源期刊

2020 6th International Conference on Science in Information Technology (ICSITech)

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