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All Journal Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer
Sabriansyah Rizqika Akbar
Fakultas Ilmu Komputer , Universitas Brawijaya
Computer Science & IT Control & Systems Engineering Education Electrical & Electronics Engineering Engineering

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Rancang Bangun Pengenalan Modul Komunikasi dengan Konfigurasi Otomatis Berbasis UART Mukmin Mukmin; Sabriansyah Rizqika Akbar; Dahnial Syauqy
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Wireless communication is a communication technology that uses electromagnetic waves to transmit signals with close distances and long distances. However, the use of wireless communication modules such as ESP8266 and NRF24l01 for wireless data transmission learning media for beginners who hadware use some microcontroller like Arduino constrained during initial configuration. From the problem it is necessary research about making wireless communication module that is Plug and Play (PnP) when connected with microcontroller like Arduino. In this research use 2 wirelesss communication module that is ESP8266 type E-01 and NRF24l01 and use serial communication (UART) to connect to microntroler like Arduino Uno. There is an ATmega 328P chip or ATtiny85 chip as an intermediary / serial communication control from ESP8266 or NRF24l01 to Arduino Uno acting as a core module. The design of communication module testing ESP8266 and NRF24l01 is done in 3 stages of introduction, selection, and transmission of PnP communication module data. In the introduction phase - the selection of communication module using Triple Handshaking process while in the data transmission phase for communication module ESP8266 using MQTT protocol and communication module NRF24101 using RF24 library to do data transmission. For the introduction phase module / handshaking 1 takes 1.5 while the module selection stage of handshaking 2 and 3 takes 0.2 seconds each time. The results of data transmission from 21 times the delivery of communication module is 100%. It is influenced by the delivery of data delivery delay, for ESP8266 given delay of at least 1.1 seconds while NRF24l01 given delay at least 1 second.
Implementasi Sistem Pengenalan Perangkat dan Layanan Sensor dan Aktuator pada Rumah Cerdas Berbasis Arsitektur Publish-Subscribe Hedy Pamungkas; Sabriansyah Rizqika Akbar; Mochammad Hannats Hanafi Ichsan
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Smart home is most popular because approach to human lifestyle but many challenges, such as difficult to use the device in terms connectivity, configuration and integrate between devices. This research using pervasive system who can solve these challenges because it can make the computing processs becomes doesn't feel and run automatically, so don't need to specify a set of device configuration. This system is designed into several parts of the sensor device, actuator and gateway. Sensor and actuator device will recognize their identity to gateway to register the devices using MQTT. Gateway will perform the process of making relationship between both devices based on same location and other identity parameter. Actuator device will perform a specific action based on sensor data. From the result of the testing, each device successfully recognize the identity to gateway and the gateway succeeded in making relationship, so both devices can communicate well. The actuator device successfully receive sensor data within same relation and succeeds to trigger action to lamp. The test result obtained 100% successful, so the pervasive system can be implemented in smart home using MQTT.
Implementasi Pervasive Computing Pada Sistem Monitoring Konsumsi Daya Listrik Stop Kontak Rumah Ikhwan Zulfy; Dahnial Syauqy; Sabriansyah Rizqika Akbar
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Power saving consumption is necessary. The power consumption of a house can be monitored through kWh meters. The usual kWh meter monitors the overall power consumption of the house, it doesn't measure the details of the total power consumption of the home. Therefore we need to monitor the system of electric power consumption in every room of the house. Based on that requirement, an electrical power consumption of the outlet system monitoring is available in every room of the house using pervasive computing method. The system is using some devices that is a smartphone application and 2 node devices comprising NodeMCU v1.0 as the microcontroller and the current YHDT SCT-013-020 sensor. The system requires some nodes and an application device to be connected in the same network through the websocket protocol. Device node and the application are communicating through a router. The node device processes the sensor readings and then sends the data to the application. The application will scan the IP subnet mask, if the IP adresses are detected and configured on port 19105, the IP will be identified as node device. Then the application will request the sensor data to the node device and display its data to the user. After the test results are done, it will be known that the system can perform discovery with an average total time of 11156.3 ms, then it will send and display the data via the websocket protocol and the smartphone application.
Implementasi Modul Antarmuka Perangkat Sensor Dan Komunikasi Pada Uart Dan I2C Dengan Fitur Plug And Play Bunga Boru Hasian Siahaan; Sabriansyah Rizqika Akbar; Dahnial Syauqy
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Currently there are many products from various vendors of IOT service providers in the world. The product that intended here is a sensor and Communication Module. Sensor is a device that can sensing a condition and can provide value of the condition. Communication Module is a devices that can allow two or more microcontrollers like Arduino to communicate. Each sensor and Communication Module from each vendor has its own configuration and also its own way to communicating. While users have a variety of needs that sometimes require to combine various devices. Therefore, it takes a way to connect the various sensors and Communication Modules in one module that is a Interface Module, so that it can be easier in its use. In this study there are four sensors and two Communication Modules that connected to one Interface Module. Installation of sensors and Communication Modules with Plug and play features that eliminate configuration during installation. The path used for the installation of sensors is I2C (Inter Integrated Circuit) through path SDA and SCL. Connecting lines with the Communication Module that is UART (Universal Asynchronous Receiver Transmitter) through path RX (receiver) and TX (transmitter). From the test results, the Interface Module successfully detects the Sensor through the address and detects the Communication Module with the translation of the code. Data successfully received from the sensor and successfully forwarded to the Communication Module without configuration.
Implementasi High Availability pada Gateway Wireless Sensor Network dengan Protokol Komunikasi Message Queuing Telemetry Transport Bagus Prasetyo; Sabriansyah Rizqika Akbar; Widhi Yahya
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 10 (2018): Oktober 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

MQTT-SN is a development of the widely used protocol on the Internet of Things Technology, MQTT. In common MQTT-SN protocol is same as well as MQTT, but MQTT-SN is focused on the sector of wireless sensor network. In MQTT-SN the most prominent is the presence of gateway. Gateway is used to collective data from multiple sensor nodes and forwarding data to broker server. Gateway is the most important part of MQTT-SN technology, because gateway is communicator between sensor node and broker server. Therefor availability of gateway is crucial when facing failure-system or down. This research will be focus on increasing the availability of MQTT server brokers and gateway by implementing Haproxy Load Balancer and Keepalived that installed on 3 Raspberry Pi's as gateways. This system also used multiple broker servers which sharing message or topic for improve availability on broker server side. Research results is brokers and gateways successfully improved availability by using clusterization, balancer traffic, multiple broker implementation and redudancy up to 100% when one of the gateway or broker has a failure.
Implementasi Perangkat Rumah Cerdas Pervasif Menggunakan Komunikasi Websocket dan Struktur Data JSON Ahmad Mustafidul Ibad; Sabriansyah Rizqika Akbar; Dahnial Syauqy
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Perkembangan teknologi telah memicu pergeseran mendasar dalam gaya hidup modern. Salah satu penerapan dalam teknologi yang saat ini banyak dikupas secara mendalam adalah rumah cerdas (smart home). Perangkat dari teknologi rumah cerdas sangat beragam sehingga sulit untuk menyelaraskan kinerja sistem yang dibuat. Hal tersebut diatasi dengan membagi sistem menjadi sub-sistem yang lebih kecil sehingga akan memudahkan dalam manajemen sistem yang dibuat. Hal itu disebut juga sebagai modular system. Adanya self-management devices sangat penting agar perangkat pada rumah cerdas dapat memanajemen dirinya sendiri. Pervasive devices merupakan istilah yang digunakan untuk perangkat yang meresap dalam kehidupan sehari-hari yang memberikan layanan serta kemudahan kepada penggunanya. Untuk mencapai hal itu, pervasive devices harus mampu bekerja secara mandiri. Penelitian ini merancang dan menerapkan sistem yang dapat mendeteksi adanya raspberry pi (pervasive devices) secara otomatis pada jaringan lokal dan secara mandiri sistem dapat menyiapkan serta menyediakan layanan dimana pengguna dapat menggunakan layanan tersebut yaitu kendali led melalui web browser. Teknologi atau metode komunikasi antara web browser dan raspberry pi yang digunakan adalah websocket, sedangkan antara raspberry pi dengan wemos sebagai mikrokontroler untuk led yaitu menggunakan socket UDP (User Datagram Protocol). Pengujian dilakukan dengan menghitung waktu penemuan (discovery time) untuk menemukan raspberry pi pada jaringan lokal serta waktu respon layanan (on off, dimming dan rgb). Dari hasil pengujian, waktu penemuan didapatkan rata-rata waktu sebesar 4,23 detik dan rata-rata waktu respon layanan sebesar 0,52 detik.
Implementasi dan Analisa Performansi Protokol Keamanan TinySec pada Wireless Sensor Network dengan Media Pengiriman Data NRF24L01 melalui Frekuensi Radio Rafi Fajar Hidayat; Sabriansyah Rizqika Akbar; Ari Kusyanti
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Wireless Sensor Network (WSN) is a set of networks consisting of several collaborating nodes for sensing, processing, and exchanging data with the limitations of each node. Issues related to the challenges and obstacles that exist in the WSN, one of them is security, security issues exist caused by the communication model WSN is wireless. In the present study this involves the TinySec security protocol with authentication encryption mode and based of RC5 and CBC-mode encryption algorithms. The change of performance level has become a concern in this research, and the limitations of WSN media used, that is ATmega328p based microcontroller in this research using arduino nano and communication media NRF24L01 through ISM 2.4GHz frequency radio. This research consists of 3 nodes, namely sending node, gateway, and node. Where in this research is designed and implemented so that sending node can do the acquisition of sensor data using air sensor and data can be encrypted at sending node, then sent to gateway node and data can be decrypted by node gateway. Node attacker to know the security level of the sending process, so do listen to the data sent sending node attacker. From the design and implementation of encryption, decryption, and documentation process can be done well, and the process of node to node attacker only ciphetext data.
Kontrol Lampu Berbasis Voice Command Pada Raspberry PI Muhammad Irfan Reza; Sabriansyah Rizqika Akbar; Hurriyatul Fitriyah
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 9 (2018): September 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Smart home is a home that provides comfort, safety and convenience to its inhabitants in the operation of every device in every time. Smart home usually consists of some electronic device such as lamps, fans, air-conditioner, etc. One of the smart home control methods currently developing is voice control. Currently there are some voice control technology that is being developed one of them is the voice control system developed by Amazon.. In this research will be implementing Alexa Voice Service on raspberry pi device so that the device can control the lamp to turn off, turn on, change color, set intensity and do scheduling.Voice commands received on the raspberry will be sent to alexa skills kit via alexa voice service that is installed in raspberry, then voice command that has been received in alexa skills kit will be sent to amazon web service lamba to modeled with JSON format so it can be recognized by system. The formatted data will be published to MQTT Broker. System will subscribe the data as a reference action what will to do. The accuracy of the system's success in translating voice commands to turn off and turn on is 95.8%, to change color is 100%, to set the intensity is 93.3%, to do scheduling is 100%.
Rancang Bangun Pengenalan Modul Sensor dengan Konfigurasi Otomatis Berbasis Komunikasi I2C Nicho Ferdiansyah Kusna; Sabriansyah Rizqika Akbar; Dahnial Syauqy
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 10 (2018): Oktober 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

Wireless Sensor Network is one of the many technologies currently used in various fields. But in fact to be able to make a WSN system can work requires a lot of time, experience and also sufficient knowledge. It is difficult to configure a node to work properly. In order for the sensor node can be used alone the process to be traversed quite complicated, starting from the arrangement of the circuit, wiring, programming and others. Solution to this problem is by applying a Modular WSN system where part of the node is separated into specific modules by type and usability, the module type is divided into core module (controller device), communication module and sensor module. In the existing module itself applied Plug and Play system so that each module can be directly used without having to go through any configuration process. In this study only focuses on the sensor module where the sensor module consists of several different types of sensors. The sensor modules that the PnP system has implemented can be directly used when connected to the controller. The process of detection and identification process is done by utilizing serial communication I2C (Inter Integrated Circuit). From the results of several tests conducted known that the process of detection, data transmission and also the selection of active modules successfully done without experiencing any constraints.
Implementasi Modul Monitoring Kapasitas Baterai Pada Perangkat Embedded Yohana Kristinawati; Sabriansyah Rizqika Akbar; Rizal Maulana
Jurnal Pengembangan Teknologi Informasi dan Ilmu Komputer Vol 2 No 10 (2018): Oktober 2018
Publisher : Fakultas Ilmu Komputer (FILKOM), Universitas Brawijaya

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Abstract

ABSTRACT Nowadays. the topic about energy scarcity issue becomes quite often discussed in the development of modern technologies such as wireless sensor network (WSN). From many of its implementations. WSN's main problem is about energy consumption. This is happened because the power supply of the node only supplied by a battery for its operation, so it has limited energy reserves. If one node dies, it will change the network performance in terms of routing and topology. In this study, a battery capacity measurement module is implemented on an embedded device. If the battery capacity information of the battery is known, then the approximate time of how long the embedded device can continue running will also be know, and so it can support the further development of energy savings on embedded devices. In its implementation. the module uses a resistor shuntto obtain a the value of drop voltage which is then can be used to measure the current flowing on an embedded device using Ohm's Law. When the current is known. the battery capacity can be calculated. Value processing is done by using arduino nano microcontroller. The module then provides battery capacity information in the form of percent value and the current flow value on the embedded device via LCD. It is concluded that the module can measure the current flow of the embedded device and the module can also calculates the battery capacity that used by the embedded device. The module works with a 94,56% accuracy level in measuring battery capacity.
Co-Authors Abirafdi Sukma Nazhifan Achmad Basuki Adhitya Bhawiyuga Adi Pratama Adi Setiyawan Aditya Geraldo Agung Prasetio Agung Setia Budi Agung Widya Gumelar Ahmad Faris Adhnaufal Ahmad Fatchi Machzar Ahmad Fikri Marzuqi Ahmad Mustafidul Ibad Akbar Pandu Segara Aldi Jayadi Andi Dwi Angga Prastya Andi Mohammad Rizki Andreas Widyatmoko Anggi Fajar Andana ari kusyanti Aria Tanzila Harfad Arie Prayogo Pangestu Arief Indra Rivaldy Permana Ariyan Jazmi Arnandha Hadi Pranata Arya Rizky Imansyah Harahap Bagaskara Oki Duwi Saputra Bagus Prasetyo Barlian Henryranu Prasetio Bramantyo Ardi Bunga Boru Hasian Siahaan Dading Firwandhi Sukma Dahnial Syauqy Dea Asmara Gita Dwi Aris Suprayogi Edo Bayu Cahyono Eko Setiawan Elsandio Bramudya Putra Fathoni Era Imanningtyas Faisal Akhmadi Fatwatul Miftahuddin Rizki Fitriyah, Hurriyatul Florensius Tri Putra Simamora Gembong Edhi Setyawan Handy Yusuf Harry Mulya Haryanto Sihombing Hery Julianto Situmorang I Wayan Boby Astagina Naghi Idang Wahyuddin Septiawan Ikhwan Zulfy Imam Syafi'i Al Ghozaly Inayah Wulandari Issa Arwani Jonathan Rovelano Huwae Kasyful Amron Kurnia Ade Prasetia Lulus Bagos Hermawan M. Sandy Anshori M. Sifa'un Ni'am Mahendra Data Maulita Intan Kripsita Moch Rizki Cahyadi Moch. Febryandana Nurfahri Mochamad Hannats Hanafi Ichsan Mochammad Hannats Hanafi Ichsan Mohammad Fauzin Amin Mohammad Kholili Adi Putra Much Rizki Pradana Muhamad Irfanul Hadi Muhamad Nur Arifin Muhammad Aji Guna Darmawan Muhammad Akbar Farisi Muhammad Daffa Firmansyah Muhammad Fatham Mubina Akbar Muhammad Fikri Muhammad Iqbal Muhammad Irfan Reza Muhammad Misbahul Munir Muhammad Rifqi Muzaki Muhammad Rosyid Khulafa Muhammad Rouvan Amiruddin Muhammad Sabilillah Muhammad Taufiq Azra Haromain Muhammad Wingga Woggiasworo Muhammad Zidni Mukmin Mukmin Nicho Ferdiansyah Kusna Pamungkas, Hedy Pinandhita Yudhaprakosa Pramukantoro, Eko Sakti Prasetyo Rizqi Santoso Prastise Titahningsih Primantara Hari Trisnawan Priyambadha, Bayu Puguh Bahtiar Rachmat Eko Prasetyo Rafi Fajar Hidayat Rakhmadhany Primananda Renal Prahardis Revelino Adli Reynald Novaldi Reza Ridlo Nugraha Ricko Anggoro Putra Yustono Ridzhal Hachim Wahyunanto Rifki Karim Ramadhan Riski Julianto Rivaldi Wibowo Rizal Maulana Rizki Septiansyah Rizky Putra Pratama Rizky Septian Damanik Romario Siregar Sofi Hanifah Sultan Achmad Chidir Fajar Syarif Hidayatullah Syifaul Hud'riyah Tugar Aris Andika Prastiyo Raharjo Vatikan Aulia Makkah Wawan Darmawan Widasari, Edita Rosana Widhi Yahya Wifki Ato'ur Rochim Wijaya Kurniawan Wisnu Fajar Dewantara Yandra Charlos Hasugian Yasin Rizqi Afandi Yoga Sugma Pradana Yohana Kristinawati Zakky Ramadhan Zhafran Wadiansyah Zonnete Bryllian Dheo