scholarly journals Tempat Sampah Pintar Berbasis Internet of Things (IoT) Dengan Sistem Teknologi Informasi

2021 ◽  
Vol 3 (1) ◽  
pp. 7-12
Author(s):  
Mualief Ismail ◽  
Riska K. Abdullah ◽  
Syahrir Abdussamad
Keyword(s):  
Internet Of Things ◽  
Object Detection ◽  
Public Awareness ◽  
Web Server ◽  
The State ◽  
Raspberry Pi ◽  
Servo Motor ◽  
Sensor Detection ◽  
The Web

Mengangkat dari permasalahan sampah yang berserakan di sekitar area tong sampah, permasalahan tersebut kini dapat di tangani dengan sebuah penelitian tentang tempat sampah pintar. Metode yang digunakan adalah eksperimen dan perancangan dimana pengujian dilakukan terhadap jarak sensor, ketinggian sampah dan respon data terhadap web server. Tempat sampah ini menggunakan teknologi raspberry pi dan internet of things (IoT) yang bersifat berbasis website.  Sistem akan dibuat dari rangkaian pendukung yaitu, sensor HC-SR04 sebagai pendeteksi objek dan data sampah. Sementara itu, pada output di gunakan motor servo sebagai penggerak penutup tong sampah, selain itu terdapat Web server sebagai pengecekan data sampah dari jarak jauh. Pada bagian selanjutnya terdapat pula output berupa LED sebagai pemberi tahu keadaan tong sampah ketika penuh atau kosong secara langsung. Hal ini dapat membantu tingkat kesadaran masyarakat dalam hal membuang sampah tidak pada tempatnya. Hasil yang diperoleh dalam penelitian ini adalah buka tutup tong sampah dengan setingan perangkat lunak      lebih kecil dari 60 cm terbuka dan lebih besar dari 60 cm tidak terbuka. Selanjutnya hasil pendeteksia sensor terhadap level sampah 8 cm level penuh, 21-28 cm level setengah dan 48 cm level kosong. Dan hasil pengiriman data ke web server semua level sampah terdeteksi sudah sesuai. Taking the problem of garbage scattered around the trash can area, this problem can now be handled with a study on smart trash cans. The method used is experimental and design where testing is carried out on sensor distance, waste height and data response to the web server. This trash can uses raspberry pi technology and internet of things (IoT) which is website-based. The system will be made from a series of supports, namely the HC-SR04 sensor as object detection and garbage data. Meanwhile, at the output, a servo motor is used to drive the trash can cover, besides that there is a Web server for checking waste data remotely. In the next section there is also an output in the form of an LED as a direct notification of the state of the trash can when it is full or empty. This can help the level of public awareness in terms of disposing of waste inappropriately. The results obtained in this study are open and close trash cans with software settings smaller than 60 cm open and larger than 60 cm not open. Furthermore, the sensor detection results for the waste level of 8 cm full level, 21-28 cm half level and 48 cm empty level. And the results of sending data to the web server, all levels of waste detected are appropriate.

scholarly journals Sistem Pengiriman Data dan Tampilan Simulasi Dinamika Perubahan Tekanan Udara Matras Dekubitus dan Koordinat Lokasi Alat Memanfaatkan Web Server

2021 ◽  
Vol 13 (2) ◽  
pp. 81-94
Author(s):  
Christophorus K. Wisma Nugraha ◽  
Hartono Pranjoto ◽  
Lanny Agustine
Keyword(s):  
Internet Of Things ◽  
Web Server ◽  
Raspberry Pi

Pemantauan kesehatan pasien jarak jauh untuk menjelaskan kondisi kesehatan pasien telah mendorong manusia untuk membuat sistem pemantauan kesehatan berbasis IoT (Internet Of Things). Pemantauan dirasa penting untuk pasien yang berbaring di kasur dan tidak bergerak dalam jangka waktu yang lama, karena kondisi tersebut dapat menimbulkan ulkus dekubitus. Untuk mencegah masalah tersebut digunakan matras pereduksi dekubitus yang mengubah titik tumpu pada kulit secara berkala. Ada kondisi saat matras mengalami malafungsi, dan matras tidak lagi mengubah titik tumpu pada kulit secara berkala. Untuk itu perlu adanya pemantauan tekanan kantung udara matras sehingga kondisi tersebut bisa diatasi. Raspberry Pi 3 menjalankan simulasi perubahan siklus tekanan kantung udara pada matras secara periodik. Data simulasi tersebut akan dikirimkan ke server menggunakan modul GPS/GPRS SIM868 dan akan disimpan dalam database. Lokasi alat dapat diketahui dengan menggunakan modul GPS yang terintegrasi dalam modul GPS/GPRS SIM868. Dalam halaman web ditampilkan simulasi kembang kempis kantung udara matras yang diindikasikan dengan warna. Modul GPS/GPRS SIM868 dapat berkomunikasi dengan Raspberry Pi dan dapat mengirimkan data simulasi perubahan siklus tekanan udara pada matras. Pengujian tampilan halaman web dengan siklus simulasi kembang kempis kantung udara dengan indikasi perubahan warna pada matras sudah sesuai dengan data simulasi tekanan kantung udara yang dikirimkan dari Raspberry Pi ke database.

scholarly journals Intelligent Bicycle Race Monitoring System Using IoT

2021 ◽  
pp. 410-416
Author(s):  
Mr. J. Bino ◽  
Dharani V
Keyword(s):  
Internet Of Things ◽  
Web Server ◽  
Open Area ◽  
Transfer Data ◽  
Rf Receiver ◽  
Rf Transmitters ◽  
Rf Transmitter ◽  
Database Server ◽  
The Web ◽  
Extract Information

Internet of Things (IoT) plays a pivotal role in easing the work of people. Internet of Things is a system of interrelated computing devices, mechanical and digital machines, objects, animals, or people that are provided with unique identifiers (UIDs) and the ability to transfer data over a network without requiring human-to-human or human-to-computer interaction. The unique identifiers mentioned above are RF transmitters, which use electromagnetic fields to automatically identify and track tags attached to objects. Using RF technology, we will decrease manually achieved workloads considerably and RF technology is universal, useful, and efficient. The microcontroller is used to extract information from the RF transmitter and send it to the system with the help of a Wi-Fi module. By incorporating these technologies, it helps us in tracking the bicycles and do the required analysis. This project is primarily designed to monitor bicycles in a bicycle club. It is used to identify the location of bicycles that are used within a particular area. The hardware architecture consists of a transmitter, RF receiver, microcontroller, Wi-Fi module, Web server, and database server. The web server and database server are located in the master station. The RF transmitters are distributed around an open area. They are programmed with a unique ID for each bicycle. The communication between the tag reader and the webserver is done via microcontroller and Wi-Fi modules.

scholarly journals Trends in the development of systems for monitoring the state of water bodies and the development of a Geo-information system Dniester on the basis of an industrial ІоТ

2021 ◽  
pp. 67-77
Author(s):  
Leonid Zamikhovskyi ◽  
Olena Zamikhovska ◽  
Mykola Nykolaychuk ◽  
Ivan Levitskyi
Keyword(s):  
Internet Of Things ◽  
Communication Systems ◽  
The State ◽  
Water Bodies ◽  
Raspberry Pi ◽  
Economic Damage ◽  
Automated Control ◽  
Stage Of Development ◽  
State Of Water ◽  
Internet Of Things Technology

The work shows that inadequate and untimely hydrological forecasting of the level of flood development leads to significant annual economic damage and loss of life. The latter requires constant control and monitoring of the state of water bodies, which is possible with modern automated control and monitoring systems. The analysis showed that the information and measurement systems (AIMS) for flood control, which are operated in Ukraine, their quantity, cost and technical characteristics do not provide the information necessary for predicting the development of floods. Analysis of trends in the development of systems for automated control and monitoring of the state of water bodies showed that modern foreign systems that are at the stage of development or testing are based on the use of microcontrollers, "smart" converters of physical quantities, modern communication systems and Internet of Things technology, as well as the use of smartphones with a Raspberry Pi camera for determining the water level in rivers. The development with the use of the industrial Internet of Things of the basic version of the geoinformation system for control and monitoring of the state of water bodies GIS-Dniester is given. The structure, components and functions of GIS-Dniester are considered. The tasks of organizing hardware and software for parameterizing and diagnosing "smart" converters, establishing a communication environment for industrial communication, developing algorithms for collecting, processing and transmitting data, studying the characteristics of measuring signals are being solved. The results of the study of the echo profiles of the XPS10 ultrasonic level sensor with “smart” -converters Multiranger 100, as well as the procedure for working with the GIS-Dniester are presented. The use of the developed GIS-Dniester has shown its effectiveness and reliability in operation.

scholarly journals Ticketing Management System for Football League Match Organizer Based on Near Field Communication (NFC) and Website Integration

2017 ◽  
Vol 4 (1) ◽  
pp. 23-30
Author(s):  
Atok Hardiyanto
Keyword(s):  
Near Field ◽  
Web Server ◽  
Leakage Rate ◽  
Raspberry Pi ◽  
Near Field Communication ◽  
Device Performance ◽  
Test Results ◽  
Average Data ◽  
Reading Distance ◽  
The Web

There is a lot of ticket brokering. The ticket leakage rate can be minimized to a minimum with the help of an automatic gate that will open when the audience balance is sufficient, this is shown on the website.  QoS measurement using Wireshark software from the process of sending data from raspberry pi to the web server. The results showed that the maximum reading distance of the NFC reader was 2.5 cm in the position of the test tag above the reader. Based on the QoS test results, the average data packet sending with very good speed in the ITU-T category is <150 ms. In testing the distance of 26 meters, 5 meters and 3 meters between the stadium internet (wifi) source to the node at the gate because from the 3rd measurement the distance gets <150 ms according to the ITU-T standard. The results obtained are 130,588 ms, 123,493 ms and 116,818 ms. For device performance from the results of NFC testing, motor, LCD and web server can run continuously. The web server can only accommodate users of approximately 100 users at the same time with 3 clicks

scholarly journals KOTAK-KONTAK PINTAR PADA RUMAH CERDAS BERBASIS TEKNOLOGI INTERNET OF THINGS

2019 ◽  
Vol 16 (2) ◽  
pp. 278
Author(s):  
Taufik Akbar ◽  
Gede Suweken ◽  
Gede Indrawan ◽  
Kadek Yota Ernanda Aryanto
Keyword(s):  
Internet Of Things ◽  
Web Server ◽  
Raspberry Pi ◽  
Data Display

Penelitian ini bertujuan untuk merancang kotak kontak pintar pada rumah cerdas berbasis teknologi internet of things (IoT) guna untuk memonitor jumlah konsumsi daya perangkat elektronik pada rumah tangga. Sensor yang digunakan adalah 3 buah sensor arus AC N25 dan 1 buah sensor tegangan ZMPT101B, arduino nano dan Raspberry Pi yang digunakan dalam pemrosesan data, display 2x16 serta web server sebagai tampilan hasil dari konsumsi daya. Adapun pengujian dilakukan menggunakan 3 perangkat elektronik rumah tangga yaitu setrika, kipas Angin dan Satu buah televisi. Terdapat penurunan kemampuan pada sensor arus AC N25 dengan perubahan nilai berkisar 0.7-1 A sehingga harus dilakukan kalibrasi ulang. Perbedaan hasil pengukuran tegangan AC (220 VAC) yang dihasilkan sensor tegangan ZMPT101B, alat ukur Multimeter UT dan alat ukur digital multimeter kyoritsu. Namun perbedaan yang terjadi hanya pada rentang 5 vac, sehingga dapat disimpulkan bahwa alat yang dirancang sudah sesuai dengan tegangan yang ada. Jumlah konsumsi daya  kotak-kontak pintar pada rumah cerdas ini sendiri adalah pada sensor arus 0.125 Watt, sensor tegangan 0.001 Watt dan arduino nano 0.2 Watt.

scholarly journals Pengembangan Smart Home System Berbasis Kecerdasan Buatan untuk Memanajemen Konsumsi Energi Rumah Tangga dengan Pendekatan Finansial

2021 ◽  
Vol 4 (1) ◽  
pp. 1-10
Author(s):  
Ihsan Auditia Akhinov ◽  
Muhammad Ridwan Arif Cahyono
Keyword(s):  
Neural Network ◽  
Artificial Neural Network ◽  
Internet Of Things ◽  
Smart Home ◽  
Web Server ◽  
Black Box ◽  
Raspberry Pi ◽  
Artificial Neural ◽  
Online Web

Teknologi rumah pintar yang dikembangkan saat ini belum sepenuhnya mampu mendukung program konservasi energi yang dicanangkan pemerintah. Selain Saat ini kontrol untuk pengaturan rumah pintar masih dilakukan secara manual, belum sepenuhnya otomatis. Pada penelitian ini akan dibangun sistem rumah pintar yang dikendalikan oleh kecerdasan buatan untuk mengendalikan pemakaian energi berdasarkan besaran nilai tagihan bulanan. ESP32 digunakan sebagai perangkat Internet of Things (IoT) yang berfungsi mendeteksi keberadaan manusia dan mengukur energi listrik yang dikonsumsi. Data-data tersebut disimpan dalam online web server yang dibangun dari Raspberry Pi. Sistem ini dapat dimonitor dan dikendalikan oleh aplikasi berbasis Web. Aplikasi ini sudah diuji dengan menggunakan metode Black Box, hasilnya 100% aplikasi berjalan lancar. Artificial Neural Network diimplementasikan menggunakan bahasa Python, dengan 4 input, 2 layer, dan 4 output dimana masing-masing layer terdiri dari 4 neuron. Variabel masukan yang digunakan dalam ANN yaitu intensitas cahaya, temperatur ruangan, durasi waktu penggunaan ruangan, dan target biaya bulanan, sedangkan keluaran dari ANN ini yaitu durasi penggunaan peralatan listrik, dalam purwarupa ini yaitu durasi penggunaan AC, TV, refrigerator, dan lampu. Sistem sudah mampu berjalan dengan baik, mampu memberikan rekomendasi durasi maksimal penggunaan peralatan listrik dengan tingkat kesalahan sebesar 1,64%.

Implementation of Cloud connected Smart Plug with Energy Monitoring System

2017 ◽  
Vol 8 (3) ◽  
pp. 702
Author(s):  
C. Chennakesavan
Keyword(s):  
Internet Of Things ◽  
Monitoring System ◽  
Smart Home ◽  
Web Server ◽  
Electrical Machines ◽  
Energy Monitoring ◽  
Family Unit ◽  
And Control ◽  
Insight Into ◽  
The Web

<p>Internet of Things (IoT) is the expansion of web administrations. Employments of new advancements in IoT condition are expanding quickly. A Smart Home is additionally one of the uses of IoT. A Smart Switchboard constrains customer’s execution in watching home settings and controlling home machines. This paper shows an approach to manage the progression of Smart Home applications by consolidating IoT with Web server and Cloud organize. The approach concentrates on: (1) implanting insight into sensors utilizing Energia stage [7]; (2) Creating collaborations with brilliant things utilizing Blynk-Cloud stage; (3) expanding information trade proficiency. At the point when these family unit gadgets in brilliant homes interface with the web utilizing legitimate design, then entire framework can be called as Smart Home in IoT condition or IoT based Smart Homes. Keen Homes contains family unit gadgets/home apparatuses could screen and control remotely. In addition, we execute three cases to show the approach's possibility and productivity, i.e., measuring home conditions, observing electrical machines, and controlling home robotization. </p>

scholarly journals Smart Monitoring and Authenticated Door Access from Remote places

2020 ◽  
Vol 8 (5) ◽  
pp. 1775-1780
Keyword(s):  
Remote Monitoring ◽  
Web Server ◽  
Raspberry Pi ◽  
Monitoring And Control ◽  
Web Page ◽  
Embedded Web Server ◽  
Embedded Web ◽  
Remote Monitoring And Control ◽  
And Control ◽  
The Web

Securing our things is an important objective in our day-to-day life. If our belongings are not properly monitored, it may be stolen at any time. Hence the better way is prevention of theft than searching the lost belongings. Recently much importance is given regarding security of our home. There are situations where we may need to provide door access to people when we are away from our home. For example, while working at office, if you want to provide access to a plumber, then remote door access to be provided. By using our proposed work we can monitor our home from remote places and also we can have door access options. An embedded web server is used for the purpose of remote monitoring and control. The system for remote monitoring and control for door access is developed using Raspberry Pi embedded web server. The other components include Passive Infrared sensor (PIR), DC motor and Raspberry Pi camera module. Based on the PIR sensor and camera input, the secure access to the door for any person can be given through remote access. The access to the door can either be provided through application or the concerned web page. Both the application and the web page are password protected. The application is developed as an Android application and it can be installed in any android mobile phone. The web page is developed using PHP which is used as embedded server-side scripting language. After verifying the password the access to control the door is provided. This operation can be used in wide applications where physical presence is not possible all the time.

scholarly journals RANCANG BANGUN WEB SERVER UNTUK MESIN PENGERING RUMPUT LAUT BERBASIS INTERNET OF THINGS

2020 ◽  
Vol 4 (3) ◽  
pp. 29-33
Author(s):  
Tomy Dwi Cahyono ◽  
Eri Sasmita Susanto ◽  
Indra Darmawan
Keyword(s):  
Data Collection ◽  
Internet Of Things ◽  
Software Development ◽  
Web Server ◽  
Black Box ◽  
Literature Study ◽  
Development Method ◽  
Black Box Testing ◽  
The Web ◽  
Main Factor

This study aims to design and build a web server for a machineinternet of things (IoT) based seaweed dryer works to dry the grassfrom wet to dry wire with thermonitory heat. Hot temperatureis the main factor determining the drying duration. This researchusing the waterfall software development method and built withusing PHP 7 and javascript. Methods of data collection using techniquesobservation, interview and literature study and using black box testing methodthat is, testing is done by testing the software in terms of functionality.The result of the research is that the web can be accessed through a website equipped withuser management features so that they can contribute to Samawa employeesinspiration.

scholarly journals MONITORING JADWAL BELAJAR MENGAJAR PRODI TEKNIK MULTIMEDIA DAN JARINGAN DENGAN RASPBERRY PI

2018 ◽  
Vol 3 (1) ◽  
Author(s):  
Syarifah Muliana ◽  
Muhammad Nasir ◽  
Mursyidah Mursyidah
Keyword(s):  
Teaching And Learning ◽  
Web Server ◽  
Raspberry Pi ◽  
Time Data ◽  
Study Program ◽  
Data Set ◽  
Web Based ◽  
Study Programs ◽  
Web Based System ◽  
The Web

Abstrak — Politeknik Negeri Lhokseumawe menyediakan Web server untuk mengakses berbagai macam informasi sekitaran jurusan dan program studi khususnya Prodi Teknik Multimedia dan Jaringan. Web bukan hanya untuk menyampaikan sebatas informasi pada prodi, tetapi juga dapat memonitoring jadwal belajar mengajar meggunakan Raspberry Pi sebagai server mini, pengganti komputer yang biasanya digunakan untuk server. Selama ini monitoring jadwal belajar mengajar dilakukan secara manual, sistem ini dibuat untuk memonitoring secara otomatis. Perancangan sistem berbasis Web dengan pemprograman HTML, PHP, MYSQL dan SMS gateway dengan gammu sebagai servicenya. Operasi yang berjalan dalam SMS gateway ini yaitu, pesan broadcast yang dapat mengirimkan pesan kebanyak tujuan sesuai dengan jadwal dan auto respon atau sistem dapat menerima pesan dan mengirim kembali ke nomor tujuan jika ada secara otomatis. Parameter nilai yang diiambil berdasarkan data waktu yang diatur dalam sistem. Dengan adanya sistem ini dapat mempermudah prodi Teknik Multimedia dan Jaringan dalam memonitoring jadwal belajar mengajar.Kata Kunci : Web, SMS Gateway, Gammu, Raspberry Pi Abstract — Lhokseumawe State  of Polytechnic provides a Web server to access various kinds of information around majors and study programs, especially Multimedia Engineering and Networks. The Web is not just for delivering information on the study program, but also monitoring the schedule of teaching lessons using Raspberry Pi as a mini server, a replacement for computers that are usually used for servers. During this time monitoring of teaching and learning schedule is done manually, this system is made to monitor automatically. Web-based system design with HTML, PHP, MYSQL and SMS gateway programming with gammu as its service. The operation that runs in this SMS gateway is, broadcast messages that can send messages to many destinations in accordance with schedule and auto response or the system can receive messages and send back to the destination number if it exists automatically. The value parameter is retrieved based on the time data set in the system. With this system can facilitate Multimedia Engineering and Network study programs in monitoring teaching and learning schedules.Keywords: Web, SMS Gateway, Gammu, Raspberry Pi

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