Design and Implementation of IoT-Based Smart Laboratory Using ESP32 and Thingsboard to Improve Security and Safety in POLNEP Informatics Engineering Laboratory

Jurnal ELIT Pub Date : 2022-10-24 DOI:10.31573/elit.v3i2.402

F. Wibowo, S. Suheri, Muhammad Diponegoro, Bangbang Hermanto

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Abstract

The purpose of this research is to design and build an Internet of Things (IoT) based system that can be used to provide early warning when smoke or fire is detected in the building. The system is also expected to be able to provide notifications via mobile devices to technicians and the head of the laboratory when detecting the height of the rainwater overflow that exceeds a certain limit. The urgency of this research is the need for a system by utilizing the latest technology as an effort to improve safety and security for someone who is in the building when there is a fire hazard or for the safety of equipment in the laboratory. The methodology used in this research is to use a product development approach consisting of software and hardware in a project. Broadly speaking, the stages carried out are: (1) Defining project goals; (2) Define project requirements based on project goals; (3) Designing the system architecture; (4) Define User Experience (UX) flow; (5) Identify the parts/stages of development; (6) Assembling hardware and creating program code for each part/stage; (7) Integrating each part/stage; and (8) testing and troubleshooting. The hardware that will be used is the ESP32 microprocessor which is integrated with the IoT Thingsboard platform. The ESP32 microcontroller has been successfully used as an IoT node that is connected to several sensors including environmental sensors (temperature, humidity) DHT22, light intensity sensors (LDR), motion sensors (motion PIR sensors), magnetic switch reed sensors, MQ2 smoke detector sensors, and sensors. water level. On the server side, the Thingsboard platform has been successfully used as an MQTT broker, presenting data in the form of an interactive dashboard, and triggering alarms.

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基于ESP32和Thingsboard的物联网智能实验室设计与实现，提高POLNEP信息学工程实验室的安全性

本研究的目的是设计和构建一个基于物联网(IoT)的系统，该系统可用于在建筑物中检测到烟雾或火灾时提供预警。该系统还可以在发现超过一定限度的雨水溢出高度时，通过移动设备向技术人员和实验室负责人发出通知。这项研究的紧迫性在于需要一种利用最新技术的系统，以提高建筑物中存在火灾危险时的安全性或实验室设备的安全性。本研究使用的方法是在项目中使用由软件和硬件组成的产品开发方法。一般来说，进行的阶段是:(1)确定项目目标;(2)根据项目目标确定项目需求;(3)系统架构设计;(4)定义用户体验(UX)流程;(5)确定开发的部分/阶段;(6)组装硬件，编写各部件/阶段的程序代码;(7)整合各部分/阶段;(8)检测和故障排除。将使用的硬件是与IoT Thingsboard平台集成的ESP32微处理器。ESP32微控制器已成功用作连接多个传感器的物联网节点，包括环境传感器(温度、湿度)DHT22、光强传感器(LDR)、运动传感器(运动PIR传感器)、磁开关簧片传感器、MQ2烟雾探测器传感器和传感器。水位。在服务器端，Thingsboard平台已经成功地用作MQTT代理，以交互式仪表板的形式呈现数据，并触发警报。

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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Jurnal ELIT

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