Academic literature on the topic 'Arduino Wifi module'

Abstract: Our paper deals with the plan and execution of a LASER based smart security system for discovering burglar. The principal edge of using the Laser system is that the burglar is unmindful of the fact that a security system is fix in the entry points like doors and windows since laser rays can travel long distances and are almost imperceptible. When someone go through the laser ray the circuit senses the cutoff and stumble the alarm. The alarming sound does not stop until someone turns it off manually after scrutnizing. It is one of the most economical security apparatus that can be used for indoors as well as outdoors. This apparatus centre of attention is on sending a photo of the burglar into the registered email address for sustainable verification with the help of LDR and WIFI module. It is quite competent and need very minimal power. Important terms: Arduino, LDR module, WIFI module, Piezo buzzer, message alert, laser module security

In this paper, we will deliberate how to control robot car using Wi-Fi module through a webpage using computer or smartphone. The advantage of using robot car is it can be used for various purposes like this project can be modified quite easily to include a spy camera as well that can stream the videos to the user over Wi-Fi. Attempts would be made to use solar cells instead of the regular lithium-ion battery for the project. This robot car can also be used to push the objects from one place to another. This project will be enhanced with better Wi-Fi which would enable long distance communication.

<p>This study aims to improve a remote control panel for numerous electrical devices in smart homes using radio frequency (RF) and wifi. In this study, RF315MHz transceiver module and Arduino Ethernet Shield wifi module are combined by a programmed algorithm to transmit control signals from a central processor to the electrical devices in the smart house. The RF315 MHz transceiver with hard coding is modified to be a soft coding module in which each control channel can switch on/off 256 electrical devices. Then, a remote control panel is developed to control numerous electrical devices based on the requirements of the number of control buttons and the technology in the smart house. Moreover, this proposed method allow to control the electrical devices in the house by various panels. An experimental model with two separate transmission channels using two soft-coded RF315MHz modules has been done to verify the applicability of the proposed method.</p>

With the Covid-19 virus pandemic that has plagued various countries, the need for a system to prevent transmission of the virus is very important. By utilizing IoT technology to be applied to light control systems, it can reduce the spread of the Covid-19 virus. The design of this IoT-based light control system is carried out using the Android application and the Arduino Uno via a Wifi connection and using a PIR sensor that can be connected to the ESP8266 Wifi module. With the PIR motion sensor, it can be implemented as a controller of light intensity with 3 brightness differences.

Media tanaman yang digunakan pada penelitian ini adalah teknik hidroponik dengan memakai tanaman kangkung untuk media pengamatan yang akan dilakukan pada Hydroponics grow room menggunakan lampu LED Grow Light sebagai pengganti cahaya matahari. Dalam sistem kontrol ada 3 input yang akan di proses menjadi output adalah sensor DHT11 sebagai input untuk pembacaan hasil pada program arduino yang akan mengontrol relay terhadap kipas, sensor LDR sebagai input untuk pembacaan hasil pada program arduino yang akan mengontrol relay terhadap lampu, kemudian water level sensor sebagai input untuk pembacaan hasil pada program arduino yang akan mengontrol relay terhadap pompa. Pada sistem monitoring yang akan dihasilkan pada internet web Thinkspeak mempunyai 4 output dari sensor suhu DHT11, sensor kelembaban DHT11, sensor Ultrasonik HC-SR04 untuk mengukur ketinggian tanaman, dan water level sensor untuk mengukur ketinggian air pada baki. Hasil pada pengaturan kontrol otomatis sesuai dengan pembacaan data oleh arduino, yaitu kipas akan hidup (on) ketika suhu >300 dan kelembaban sebesar >60% pada Hydroponics Grow Room. Kemudian pada pompa air akan hidup (on) ketika ketinggian air pada baki hidroponik kurang dari 50 % sesuai dengan setpoint yang dibutuhkan. Selanjutnya adalah kontrol pada lampu LED grow light dan LED bulb ketika sensor LDR mencapai setpoint >500 dalam keadaan terang, dan <500 dalam keadaan gelap. Pada sistem monitoring melalui wifi module esp8266-01 yang terhubung hotspot internet mempunyai waktu update / menerima data di web Thingspeak rata-rata selama 2,4 detik dari waktu pengiriman data melalui arduino dan wifi module esp8266-01. Untuk hasil pengamatan pertumbuhan tanaman kangkung menggunakan pencahayaan LED bulbs memiliki pertumbuhan lebih pesat dibandingkan pertumbuhan tanaman kangkung menggunakan pencahayaan LED grow light. Faktor yang menyebabkan pertumbuhan menggunakan pencahayaan LED bulbs lebih cepat dibandingkan dengan pertumbuhan menggunakan LED grow light adalah adanya pengaruh dari hormon auksin. Jika terkena cahaya LED grow light, auksin menjadi tidak aktif, tetapi apabila terkena cahaya LED bulbs pengaruh auksin menjadi lebih aktif dan menghasilkan kondisi batang dan daun menjadi kuning pucat serta layu.

Abstract— The LPG (Liquefied Petroleum Gas) gas leak detection and monitoring system is an anticipatory measure for safety from hazards such as gas cylinder explosions. This research aims to build a detection system by integrating MQ-6 sensor, Arduino microcontroller and ESP8266. Data can then be displayed on the Blynk application and notifications will be given via the application and email. The process of sending data using SIM800L module GSM/GPRS is a part that serves to communicate between the main monitors with mobile phone and the module ESP8266E ESP 12E WIFI IOT for data transfer in WIFI network . And this system has fulfilled the rules of the Internet of things, making it easier for the community in its application.

Water pollution is a major environmental challenge, with floating waste in rivers and lakes contributing to ecological degradation. Our project, a WiFi-Controlled River Cleaning Boat, aims to provide an efficient and cost-effective solution for manual waste collection from water bodies. Unlike automated systems, our boat operates under direct human control, ensuring adaptability to different cleaning requirements. The system is powered by an ESP8266 WiFi module, enabling wireless control through a mobile application. A L298N motor driver facilitates the movement of the boat, allowing precise maneuvering in water. The boat's structure is designed for stability and ease of operation, incorporating a mechanical collection system to gather floating waste efficiently. By eliminating the need for Arduino and sensors, our design reduces complexity and cost while ensuring robust performance. The WiFi-based control system allows operators to guide the boat remotely, making it an accessible and effective tool for river cleaning. This project offers a practical, scalable, and environmentally friendly approach to maintaining clean water bodies. Key Words: IoT (Internet of Things), Water Surface Cleaning, ESP8266 WiFi Module, L298N Motor Driver, Gear Motors,

Pada setiap rumah pasti memiliki pintu gerbang atau pintu pagar yang dilengkapi dengan penguncinya. Dari hal tersebut, pintu gerbang rumah yang berguna untuk keamanan kondisi rumah maupun keamanan kendaraan pribadi. Pada umumnya untuk membuka pintu gerbang atau pintu pagar serta menguncinya dengan menggunakan manual atau dengan tangan manusia. Dari masalah tersebut, maka penulis membuat suatu prototype pintu gerbang otomatis berbasis mikrokontroler Arduino Uno dan Android sebagai sistem operasi. Suatu sistem pada Android yang dapat berfungsi sebagai saklar dan dapat membuka dan mengunci pintu gerbang dengan secara otomatis, yang di kontrol oleh Android, yang terbuhung pada koneksi Wireless atau Wifi device. Dengan perancangan sistem otomatis pada pintu gerbang yang berbasis mikrokontroler Arduino Uno dan Android sebagai sistem operasinya, maka dapat membantu mempermudah pengguna dalam mengatur untuk membuka dan mengunci pintu gerbang tanpa harus keluar dari kendaraan ataupun keluar rumah.

This study aims to design a Building Automation System that can control electrical devices that are carried out remotely at the same location or via WiFi and Web Server applications, to make it easier for people to control devices located in distant buildings without direct contact and can be accessed. anywhere within range of the local network. The research method used is research and development methods, namely by conducting literature studies and interviews with electrical and arduino experts. The results of the research are a system made using the ESP8266 WiFi module which is set as a station, which connects Arduino to the local internet which will be controlled by the Web Sever application from anywhere with local internet connection range. The Building Automation System that is made can switch Hologen lamps and incandescent lamps and is set using the blynk application that is connected to an internet connection.

Physical parameters, such as temperature and moisture of soil, are important indicators in agriculture. The current study focuses on the development and assembly of an autonomous sensor for soil moisture and temperature through the use of a standard Arduino d1 mini module, equipped with a capacitive humidity sensor. The developed sensor configuration is distinguished with the possibility to transmit data via WiFi communication network and renewable energy system with photovoltaic power panel, which allows the results to be transmitted wirelessly and the sensor to operate autonomously powered by solar energy.

Board games are on the rise and chess is no exception. However, in an increasingly digitalized world these board games lack something in comparison to digitalized games, being able to play with anyone anywhere. This project aimed to combine these two worlds by being a physical game of chess where one could play against an opponent from far away. CheckMate is a robot consisting of an acrylic frame and various electronic components, such as an electromagnet, two stepper motors, a Hall eect sensor and a WiFi module. The electromagnet and Hall eect sensor were able to move using a belt and pulley system. This allowed magnetic pieces to be identified and dragged across the board. The board then communicated the location of all the pieces on the board, using Wifi, to an website that also kept track on whose turn it was. The result of this project was a robot that was able to perform all the moves necessary on the chessboard as well as communicating to the website. When moving a piece from one location to another the piece repelled other pieces on its way. However, this was deemed to be acceptable since the pieces were not moved too large of a distance for the electromagnet to attract them when moved into its square. One move that the robot was not able to perform was castling. The results can therefore bee seen as a starting point toward further developments.<br>Brädspels popularitet stiger och schack är inget undantag. Dock saknar brädspel de digitala spelens möjlighet att spela med vem som helst varsomhelst. Detta projekt ville bygga över klyftorna mellan dessa två världar genom att vara ett fysiskt schackspel med de digitala spelens möjligheter. CheckMate är en robot byggd av akrylplast och diverse elektroniska komponenter sådan som en elektromagnet, två stegmotorer, en halleektsensor och en WiFi-modul. Elektromagneten och halleektsensorn förflyttades via ett system av kuggremmar drivet av stegmotorerna. Elektromagneten användes för att flytta pjäserna på brädet medan halleektsensorn användes vid kartläggning av pjäsernas position på brädet. Brädet kommunicerade, via trådlöst nätverk, till en hemsida som användes för att spara och överföra pjäsernas positioner. Projektet resulterade i en robot som kunde göra alla motsvarande drag hämtat från hemsidan. Dock så repellerade en flyttande pjäs på de stationära pjäserna när den passerade. Detta ansågs dock vara acceptabelt då elektromagneten kunde föra tillbaka pjäserna när den befann sig i dess ruta. Något som projektet ej lyckades utföra var draget rockad. Resultatet av detta projekt kan ses som en startpunkt i en vidareutveckling eller en färdig produkt vid obesvärad spelning.

Future internet will not only comprise computers and computing things but also everything else. IoT is one of the emerging technologies. This chapter explores different kinds of temperature and humidity sensors, their specifications, usefulness, and prospective applications. Arduino boards are also explained in detail. This chapter explores the working principle and applications of different types of humidity sensors. The chapter contains the specification of common temperature and humidity sensors, pinout diagram, and schematic of the interconnection of sensors with Arduino Uno microcontroller. Working and interfacing of the ESP8266 wifi module are also explained. The chapter also provides the architecture and code examples of Android app for sensor data view and manipulation.

Smart assistive devices for blind and visually impaired (B&amp;VI) people are of high interest today since wearable IoT hardware became available for a wide range of users. In the first project, the Raspberry Pi 3 B board measures a distance to the nearest obstacle via ultrasonic sensor HC-SR04 and recognizes human faces by Pi camera, OpenCV library, and Adam Geitgey module. Objects are found by Bluetooth devices of classes 1-3 and iBeacons. Intelligent eHealth agents cooperate with one another in a smart city mesh network via MQTT and BLE protocols. In the second project, B&amp;VIs are supported to play golf. Golf flagsticks have sound marking devices with a buzzer, NodeMcu Lua ESP8266 ESP-12 WiFi board, and WiFi remote control. In the third project, an assistive device supports the orientation of B&amp;VIs by measuring the distance to obstacles via Arduino Uno and HC-SR04. The distance is pronounced through headphones. In the fourth project, the soft-/hardware complex uses Raspberry Pi 3 B and Bytereal iBeacon fingerprinting to uniquely identify the B&amp;VI location at industrial facilities.

The advancement of science and technology is making life easy to live. Nowadays, the world is accepting automation over manual systems. We are already in the future, possibly due to the latest emerging internet technology, IoT (Internet of things). In this coronial period, we humans have understood the importance of hygiene. Nowadays, we care more about making the environment cleaner than ever. In this period of social distancing, we want everything contactless and safe, so here we have come up with an intelligent dustbin! No need to touch the dustbin anymore. Just bring the piece of garbage in front of the dustbin. The lid of the dustbin will open on its own as soon as it detects the amount of waste. This paper presents an automatic light, fan, and intelligent dustbin controller system using IoT. We aim to provide the users remote access to their home appliances. With various sensors tech, we are taking this even further. The whole circuitry used in this project is made with components like Arduino UNO, NodeMCU WiFi module, Servo Motor, Ultrasonic sensor, etc. This project acts as an example of how positively IOT can impact our lives.

Health monitoring is crucial for mitigation, particularly as early sickness identification can reduce suffering and medical expenses. The IoT is a network of interconnected, physical items that can be accessed online. The utilization of IOT devices in several application domains improves the daily lives of consumers. These tools are used to gather data such as blood pressure, sugar level, temperature, and others that are used to assess the patient's overall health. Patients have the comfortable feeling that their doctor is continuously watching over them as a result. Robots are machines that are controlled by software and move about to observe their surroundings using sensors and other technology. This research suggests a robotic system for patient monitoring and assistance. It has become common practice to track and document several medical indicators of patients outside of hospitals. The goal of the research is to develop a system that allows doctors to monitor a patient's body at all times via internet connection. The objective of this system is to use sensors to measure a biological parameter in the patient's body and transfer the results to an IOT cloud platform through a WiFi module. Clinicians are going to able to monitor their patients' well-being on their cellphones because all health-related data will be stored in the cloud. The Arduino Controller is used to carry out this project.

The escalation of regulatory efforts pertaining to air pollution levels is seeing significant growth, emerging as a crucial responsibility for governments in developing nations, with particular emphasis on India. It is important for individuals to possess knowledge on the extent of pollution in their immediate environment and to actively engage in efforts to combat it. Various factors contribute to air pollution, including weather conditions, traffic patterns, the combustion of fossil fuels, and industrial emissions, particularly those from power plants. Among the several constituents of atmospheric composition that contribute to the assessment of air quality, particulate matter has significant importance. When the concentration of this substance is elevated in the atmosphere, it poses significant health risks to individuals. Therefore, it is essential to maintain regular monitoring of its atmospheric concentration in order to exercise control. The identification of this may be achieved by the use of machine learning methods. Consequently, the system would continuously monitor the levels of air pollution in real-time and provide predictions about the future readings within a certain time frame. The data would be sent to the network using WiFi connection. The system consisted of an Arduino UNO V3, an ESP8266 WiFi module, and a MQ2 gas sensor during the first stage of development. This provides assistance to urban planning. Air is an essential component in the existence of human beings. In contemporary society, the escalation of air pollution has become a matter of great concern, leading to the phenomenon of climate change and subsequently imposing detrimental effects on the global population. The atmospheric pollution is attributed to the production of toxic gases by industrial activities and vehicle exhaust, resulting in an escalation of detrimental gases and particulate matter in the surrounding air. The release of diverse harmful gases from industrial and vehicular sources poses a significant threat to both terrestrial organisms and marine ecosystems. The prevalence of health conditions such as stroke, heart illnesses, lung cancer, respiratory disorders, and others is increasing as a consequence of inadequate air quality. The presence of substandard air quality presents a notable hazard to certain vulnerable populations, including children, those with asthma, pregnant women, and the elderly. Furthermore, these pollutants are accountable for the degradation of our infrastructure and cultural landmarks. It is vital for individuals to acquire knowledge about the magnitude of their actions' impact on air quality. According to statistical data from the World Health Organisation (WHO), a significant number of early deaths occur annually on a global scale as a result of air pollution. The findings of several research have shown that particulate matter plays a significant role in the escalation of air pollution. Consequently, air quality has emerged as a significant global problem. Therefore, it is important to consistently check the air quality index in order to cultivate a healthy surrounding environment that is conducive to human habitation

The Internet of Things (IoT) is defined by the interconnection between networks of smart devices (objects) through specific communication standards and protocols. Data retrieved from these objects is loaded on cloud servers where it is analyzed, processed and then accessed by users through simple, intuitive, easy-to-use interfaces. The rapid development of IoT applications will steadily increase the demand for skilled personnel in this field. Under these circumstances, the study of IoT basic notions in classrooms becomes a necessity. Using the Arduino and Raspberry Pi development platforms, a wide range of IoT projects can be developed, according to the students' level. These platforms capture environmental data through an extended array of sensors (temperature, light, pressure, humidity, force, acceleration, rotation, sound, IR, magnetic field, etc.), making it perfectly suited to projects development in the educational STEM field (Science, Technology, Engineering and Matemathics). In this study my aim is to show, based on examples, how several IoT projects can be developed in class using the two above mentioned platforms and I emphasize the didactical aspects associated with this study. For the first project I used the Arduino Uno development board, the DHT11 temperature and humidity sensor, and ESP8266 WiFi module, and showed how the ambient temperature and humidity can be monitored via Internet. The data collected by the sensor was processed by Arduino, sent to the WiFi module and further on a cloud server on the IoT ThingSpeak platform where it was stored, analyzed and graphically represented in real time. In the second project I used a Raspberry Pi development board, a mobile robotic platform powered by two electric motors and equipped with a webcam in order to video monitor, via the Internet, a particular perimeter under observation. The robotic platform on which the surveillance camera is located can be positional controlled using a web browser that can access an HTML page built for this purpose. The final part of this study is dedicated to the assessment of the quality of STEM training results by classes of students who have worked on IoT projects compared with classes that have undergone traditional training courses.

Intravenous simply means “within a vein.” People of all ages who are ill, hurt, dehydrated, or going through surgery use it. Compared to conventional manual techniques, automated IV infusion systems may provide improved accuracy, consistency, efficiency, flexibility, and monitoring increase patient safety, and raise the standard of care delivered by medical professionals. The project’s objective was to design and implement a fully automated low-cost user-friendly portable embedded-based system for monitoring, ceasing, and alerting intravenous infusion. This can be installed in hospitals, clinics, medical offices, ambulatory surgical centers, dialysis centers, nursing homes, and mental health and addiction treatment centers to monitor, cease and alert IV status to medical assistants. Successful design and implementation of an automated system that controls the intravenous infusion, stop the infusion when there’s no fluid inside, sends an alert to the smart device in the nursing room, and continuously updates the intravenous infusion status. Arduino Uno was considered the heart of the device, as it controls all the functions of the device. For connecting the device to the cloud, the ESP826601 WiFi module was used. Blynk was the IoT platform used to display the status of IV infusions. User can enter their username and password using a 4x4 matrix keypad and displays the details via a 16x2 LCD. Based on that, the system was expected to validate the entered user credentials and BMI details to automatically stop the IV infusion and alert medical professionals by monitoring the IV drip infusion. The system’s design and development increased patient safety while decreasing risk elements during infusion. The proposed system can be used to monitor the drip infusion of several patients from the nurse station.

O presente trabalho apresenta uma experiência que está sendo realizada na Universidade Federal de Juiz de Fora (UFJF) com a aplicação de Gêmeos Digitais, por meio de Internet das Coisas (IoT) e Modelagem de Informação da Construção (BIM), conforme proposto por MACHADO (2018), a fim de melhorar a Gestão das Edificações na instituição. A Pró-reitoria de Infraestrutura (PROINFRA) é responsável pela gestão das estruturas e das edificações da UFJF, e está em processo de adaptação de seu escritório para projetos em BIM, bem como no conceito de Gêmeos Digitais. Este cenário favorece e enseja a cooperação entre as áreas de Arquitetura e de Engenharia Elétrica, para alcançar a melhoria e a modernização da gestão de infraestrutura. O escopo deste trabalho visa atender a demanda por sensoriamento ambiental, em tempo real, para poder municiar os profissionais de Arquitetura na construção de modelos que espelham as propriedades reais em ambiente BIM, com finalidade de obter um gêmeo digital. Para tanto, algumas variáveis de interesse da instituição de ensino foram escolhidas para medição, como temperatura, intensidade luminosa, tensão e corrente elétrica, abertura de portas e janelas, entrada e saída de pessoas, e umidade. Para monitoramento das variáveis, sistemas microcontrolados baseado em IoT estão em fase projeto para que as informações sejam armazenadas em nuvem, com uma estampa de tempo e informações de interesse. Para aumentar a confiabilidade da medição, cada sistema terá a possibilidade de armazenamento de informação localmente, através de cartão microSD. Cada equipamento atualizará a medição baseada ou em uma taxa de tempo ajustável ou baseado em eventos – isto é, uma mudança no estado do sistema (uma janela se abriu, uma pessoa saiu ou entrou no ambiente), para alimentar um banco de dados.Neste trabalho, para teste de conceito, foi desenvolvido um protótipo de sensor de temperatura digital, com capacidade de salvamento de dados em nuvem em cartão de memória microSD. O cartão de memória poderá conter um arquivo de configuração Json, que permitirá configurar a taxa de atualização de informação, onde o salvamento será feito e informações sobre rede (IP, SSID, password etc.). Os autores elaboraram o projeto de um sistema embarcado, baseado no microcontrolador ESP32, devido a sua alta capacidade de processamento e confiabilidade, baixo custo, e simplicidade para conexão em rede. O sensor de temperatura escolhido foi o DS18B20, em sua modalidade resistente à água, o que permite que esta medição ambiental possa ser interna ou externa. Este sensor é capaz de medir temperaturas na faixa -55 a 125 °C, o que é adequado para a aplicação, com interface digital I2C, simplificando sua utilização. Foram desenvolvidos o diagrama esquemático e roteamento da placa de circuito impresso através do software Open Source Kicad 6.0, para confecção de um protótipo. O microcontrolador foi programado para realizar as tarefas de medição, acesso ao cartão microSD e conexão Wifi no software Visual Studio Code, com uso de bibliotecas do framework Arduino, ambos de código aberto. O protótipo desenvolvido permite o desenvolvimento de diversos aspectos que serão comuns a todos os sistemas de medição (tensão, corrente, umidade etc.), visto que todos terão a necessidade de conexão Wifi, acesso a cartão microSD, acesso à nuvem etc. Testes preliminares permitiram salvamento das medições com estampa de tempo diretamente pelo Google Sheets, que permite análise direta ou download para utilização em. A estampa de tempo só é possível quando o sistema está conectado à Internet, quando é capaz de solicitar uma estampa de tempo de um servidor NTP (Network Time Protocol ou Protocolo de Tempo para Redes). O protótipo foi concebido com três leds indicadores de estado: o verde para estado do sensor de temperatura, o amarelo para o estado o leitor de cartão microSD, e o vermelho para a conexão wifi. Em caso de falha em algum destes três sistemas, o led respectivo piscará, de modo a alertar o operador. O sistema tem uma pré-configuração embarcada, de modo que será capaz de operar sem um cartão microSD (ou caso o cartão não possuir um arquivo de configuração válido). O sistema será capaz de operar sem cartão microSD, ou sem conexão Wifi (quando a estampa de tempo será perdida). Caso haja uma contingência dupla, ou seja, não haja Wifi ou cartão de memória, o sistema aguardará um tempo predeterminado e reiniciará (para o caso de a Internet ser restabelecida, ou um cartão conectado).Este projeto contemplou profissionais da UFJF e 2 alunas de Treinamento Profissional (um tipo de programa próprio da UFJF, com objetivo de permitir aperfeiçoamento profissional dos alunos em áreas de interesse específico compatíveis com a habilitação cursada) com dedicação de 12 horas semanais. A abordagem de ensino utilizada foi prática, com a metodologia aprendizagem baseada em projetos, onde pode-se destacar as disciplinas de instalações elétricas, desenho auxiliado por computador, instrumentação eletrônica, software embarcado. A equipe que trabalha com a elaboração e produção dos sensores vem desenvolvendo competências do conjunto Técnico relacionadas ao tópico de Hardwares e Equipamentos (t03), ao produzirem os sensores IoT, e ao conjunto de Suporte, ao trabalharem o tópico Suporte à Informação e Redes (s02), ao lidarem com os dados dos sensores e sua interface com o modelo BIM em estágio Colaborativo. O uso geral do modelo BIM aplicado por esta equipe é a Modelagem de Sistemas de Informação (1210) especificamente relacionados aos sensores, e entre os usos de domínio destacamos a Utilização de Energia (4090), Utilização em Tempo Real (7040) e a Interface BIM/IoT (8050) (BIMEXCELENCE.ORG, 2023). Como resultado preliminar, o trabalho permitiu o desenvolvimento de um protótipo para o estudo de gêmeos digitais, aliando esforços entre pesquisadores da Arquitetura e Engenharia Elétrica. O estado atual permite a medição com estampa de tempo de temperatura de um ambiente, interno ou externo. Diversas competências técnicas foram abordadas para os estudantes, como programação, projeto e confecção de placas de circuito impresso, O desenvolvimento deste trabalho deve tornar mais eficaz e eficiente a gestão das edificações da UFJF, com tecnologia nativa da própria instituição, mediante a cooperação da administração superior, Faculdade de Arquitetura e Faculdade de Engenharia.