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Fajar Sidik Permana
PRTA-ORTN Badan Riset dan Inovasi Nasional
Computer Science & IT Control & Systems Engineering Electrical & Electronics Engineering Energy Engineering

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Desain Konseptual Internet Accelerator Laboratory (IAL) untuk Siklotron DECY-13 Frida Iswinning Diah; Idrus Abdul Kudus; Suharni; Fajar Sidik Permana; Taxwim
Jurnal Nasional Teknik Elektro dan Teknologi Informasi Vol 11 No 1: Februari 2022
Publisher : Departemen Teknik Elektro dan Teknologi Informasi, Fakultas Teknik, Universitas Gadjah Mada

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (1068.663 KB) | DOI: 10.22146/jnteti.v11i1.3425

Abstract

Research and Technology Center for Accelerator of Research Organization for Nuclear Energy of National Research and Innovation Agency (PRTA-ORTN – BRIN) has become the Center for Excellence in Science and Technology (PUI), especially in the particle accelerator field. One of the studies is the DECY-13 cyclotron for radioisotopes production used in the medical field for cancer diagnostics. Currently, the DECY-13 cyclotron R&D is in the final stages of the design process. A Cyclotron internet laboratory facility will be implemented to expand the benefits of this R&D. This facility will support the cyclotron training to be more widely accessible and increase capacity building and human resources programs in the nuclear field. Therefore, a preliminary study for DECY-13 cyclotron Internet Accelerator Laboratory (IAL) is needed, which includes the preparation of long-term concepts and the design of IAL. The formulation of the long-term idea follows the established cyclotron road map. In the conceptual design, the users at the early stages are students and cyclotron operators in hospitals. In order to determine the design requirement, the next step is a literature study on online laboratories and the accelerator learning concept that has been applied in other countries. The IAL apparatus identification is based on a review of the DECY-13 cyclotron laboratory's current conditions and future research plans. The conceptual design that has been successfully developed consists of a research roadmap on IAL for long-term research planning and a material syllabus for two target users, namely students and cyclotron operators in hospitals. While the employed IAL component identification is CompactRIO as the primary controller on the cyclotron operating system and as a liaison with the network system. Supporting the network includes database systems, servers, LAN, internet, webcams, and websites or an application to be accessed by users.
Desain Integrasi Sistem Instrumentasi dan Kendali untuk Commissioning Siklotron DECY-13 Frida Iswinning Diah; Fajar Sidik Permana; Emy Mulyani
Jurnal Nasional Teknik Elektro dan Teknologi Informasi Vol 12 No 2: Mei 2023
Publisher : Departemen Teknik Elektro dan Teknologi Informasi, Fakultas Teknik, Universitas Gadjah Mada

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.22146/jnteti.v12i2.5509

Abstract

A cyclotron is a particle beam accelerator used for various applications, one of which is to produce medical radioisotopes. Research Center for Accelerator Technology, Research Organization for Nuclear Energy - National Research and Innovation Agency (Pusat Riset Teknologi Akselerator, Organisasi Riset Tenaga Nuklir - Badan Riset dan Inovasi Nasional, PRTA ORTN-BRIN) is conducting research and development (R&D) for the DECY-13 cyclotron that has reached the stage of testing its primary components. The primary components of the DECY-13 cyclotron consist of seven systems. In commissioning, it is necessary to prepare an integrated instrumentation and control system (ICS) design that unites the operation of all DECY-13 cyclotron’s primary components to produce a particle beam as desired. The integration process was carried out in two stages: determining operating procedures during commissioning and identifying operating parameters; and designing the ICS integration. The process of identifying parameters and determining operating procedures was carried out by studying test data and operating standards for each component to obtain important parameters in operation. Next, the ICS architecture was developed by integrating the operating system on the primary components using the distributed control system (DCS) method. The DCS configuration consisted of three layers, namely the operator, the main control, and the device layers. Communication between the device and the main control layers was carried out using the RS-232 serial communication, while the communication between the main control and the operator layers used the Ethernet. The RS-232 communication between the device and main control layers was used to manage data acquisition, data logging, and operation control. At the operator layer, there was a host-PC that functioned as a data viewer and data logging. This design is expected to be a guide in the implementation of ICS improvements, and realizing ease during commissioning.
Co-Authors Emy Mulyani Frida Iswinning Diah Idrus Abdul Kudus Suharni Taxwim