Programmable Logic Technology

Sistem kontrol elektropneumatik telah banyak digunakan dalam menunjang pekerjaan di dunia industri,perkembangan teknologi ini harus segera direspons oleh dosen pada perguruan tinggi vokasi yang memiliki peran sebagai pencetak calon tenaga ahli siap kerjauntuk mengembangkan media pembelajaran. Penelitian ini bertujuan untuk: (1) menguji kelayakan desain media pembelajaran sistem kontrol elektropneumatik berbasis programmable logic controller, (2) mendeskripsikan respons mahasiswa dalam menggunakan media pembelajaran sistem kontrol elektropneumatik berbasis programmable logic controller dalam kegiatan pembelajaran. Metode yang digunakan pada penelitian ini yaitu menggunakan metode penelitian dan pengembangan Research and Development (R&D) dengan melalui beberapa tahap, yaitu tahap analisis potensi dan masalah, pengumpulan data, desain produk, validasi desain, revisi desain, uji coba produk, revisi produk, dan uji coba pemakaian. Pengumpulan data dilakukan dengan menggunakan lembar validasi ahli yang diberikan oleh 3 orang ahli dan angket respons yang diperoleh dari mahasiswa. Kesimpulan yang diperoleh dari penelitian ini yaitu: (1) desain pembelajaran sistem kontrol elektropneumatik berbasis programmable logic controller mendapatkan nilai validasi yang diberikan oleh para ahli dengan rata-rata nilai 3,51 sehingga menunjukkan bahwa media pembelajaran dalam kategori baik dan layak untuk digunakan dalam proses pembelajaran, (2) respons mahasiswa dalam menggunakan media pembelajaran sistem kontrol elektropneumatik berbasis programmable logic controller dalam kegiatan pembelajaran diperoleh nilai persentase 84,34%mahasiswa memberikan respons menarik, dengan demikian hasil respons mahasiswa termasuk dalam kategori baik.

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An expert systems based automatic control software generator for the Programmable Logic Controller

10.31274/rtd-180813-7500 ◽

1989 ◽

Author(s):

Sangeet Bhatnagar

Keyword(s):

Expert Systems ◽

Automatic Control ◽

Programmable Logic Controller ◽

Programmable Logic ◽

Control Software

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Specification for harmonized system of quality assessment for electronic components. Blank detail specification: programmable logic arrays (PLA)

10.3403/00220734u ◽

2015 ◽

Keyword(s):

Quality Assessment ◽

Programmable Logic ◽

Electronic Components ◽

Programmable Logic Arrays

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The Risk of Industrial Control System Programmable Logic Controller Default Configurations

2020 International Computer Symposium (ICS) ◽

10.1109/ics51289.2020.00093 ◽

2020 ◽

Author(s):

Kuan-Ming Su ◽

I-Hsien Liu ◽

Jung-Shian Li

Keyword(s):

Control System ◽

Programmable Logic Controller ◽

Programmable Logic ◽

Industrial Control System ◽

Industrial Control

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Introduce Ladder Logic and Programmable Logic Controller (PLC)

2020 Annual Conference Northeast Section (ASEE-NE) ◽

10.1109/aseene51624.2020.9292646 ◽

2020 ◽

Author(s):

Nicolas P. DeGuglielmo ◽

Saurav M.S. Basnet ◽

Douglas E. Dow

Keyword(s):

Programmable Logic Controller ◽

Programmable Logic ◽

Ladder Logic

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Petri Net-Based Semi-Compiled Code Generation for Programmable Logic Controllers

Applied Sciences ◽

10.3390/app11157161 ◽

2021 ◽

Vol 11 (15) ◽

pp. 7161

Author(s):

Igor Azkarate ◽

Mikel Ayani ◽

Juan Carlos Mugarza ◽

Luka Eciolaza

Keyword(s):

Code Generation ◽

Resource Sharing ◽

Discrete Event ◽

Transition Function ◽

Discrete Event Dynamic Systems ◽

Programmable Logic ◽

External Software ◽

Implementation Methodology ◽

Event Dynamic ◽

Step Transition

Industrial discrete event dynamic systems (DEDSs) are commonly modeled by means of Petri nets (PNs). PNs have the capability to model behaviors such as concurrency, synchronization, and resource sharing, compared to a step transition function chart or GRAphe Fonctionnel de Commande Etape Transition (GRAFCET) which is a particular case of a PN. However, there is not an effective systematic way to implement a PN in a programmable logic controller (PLC), and so the implementation of such a controller outside a PLC in some external software that will communicate with the PLC is very common. There have been some attempts to implement PNs within a PLC, but they are dependent on how the logic of places and transitions is programmed for each application. This work proposes a novel application-independent and platform-independent PN implementation methodology. This methodology is a systematic way to implement a PN controller within industrial PLCs. A great portion of the code will be validated automatically prior to PLC implementation. Net structure and marking evolution will be checked on the basis of PN model structural analysis, and only net interpretation will be manually coded and error-prone. Thus, this methodology represents a systematic and semi-compiled PN implementation method. A use case supported by a digital twin (DT) is shown where the automated solution required by a manufacturing system is carried out and executed in two different devices for portability testing, and the scan cycle periods are compared for both approaches.

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