|
|
Test benches for microcontroller kits
Hatala, Branislav ; Sýkora, Tomáš (oponent) ; Bradáč, Zdeněk (vedoucí práce)
Táto práca sa zaoberá návrhom a zostrojením testovacej stolice pre mikrokontrolérové kity. Hlavným účelom testovacej stolice je test funkčnosti modulov výukového kitu. Samotná testovacia stolica má modulárny hardvér a umožnuje použitie akéhokoľvek dostačujúceho embedded systému ako svojho systémového jadra. Hardware systému je rozšíritelný na úlohu testovania firmwaru výukových kitov.
|
|
|
Communication Interface for Industry 4.0 testbed
Magáth, Marek ; Fiedler, Petr (oponent) ; Kaczmarczyk, Václav (vedoucí práce)
This diploma thesis deals with the creation of a general communication interface between the smart product and process cells within test bed Barman. The aim is to create distributed production according to the Industry 4.0 concept, where each product manages it’s production itself. The first part deals with the analysis of test bed, where are discussed requirements and method of production. Then with the selection of a communication protocol that would meet Industry 4.0 and distributed control requirements. The result of the research was OPC UA communication protocol. Using this protocol, the product and the process cell will communicate with each other. I chose the appropriate implementation for the selected protocol to be used for creating communication modules of the product and the process cell. Production data will be stored in an RFID chip located in the product. Part of the work is devoted to creation this data structure, which contains the recipe as well as production state data. Creation of RFID reader is the work of another student, with whom I solved the method of data exchange between application of the reader and the communication module of the product. When creating a communication module of the process cell, I solved the design of an information model that describes the entire process cell, and the dynamic creation of nodes in the address space. I have mentioned a few examples of how I worked with a selected implementation of OPC UA and how I used it in both applications. I implemented decentralized search of another process cells in the local network. This feature was easy to implement with OPC UA, specifically with the LDS-ME service. I solved the control of production for the communication module of the product and method of communication with the process cell. And in the last part I deal with manual, which describes how to compile projects correctly, specifically on the Linux operating system, and I have described a way to test the whole solution together with the results.
|
|
|
Test benches for microcontroller kits
Hatala, Branislav ; Sýkora, Tomáš (oponent) ; Bradáč, Zdeněk (vedoucí práce)
Táto práca sa zaoberá návrhom a zostrojením testovacej stolice pre mikrokontrolérové kity. Hlavným účelom testovacej stolice je test funkčnosti modulov výukového kitu. Samotná testovacia stolica má modulárny hardvér a umožnuje použitie akéhokoľvek dostačujúceho embedded systému ako svojho systémového jadra. Hardware systému je rozšíritelný na úlohu testovania firmwaru výukových kitov.
|
|
|
Communication Interface for Industry 4.0 testbed
Magáth, Marek ; Fiedler, Petr (oponent) ; Kaczmarczyk, Václav (vedoucí práce)
This diploma thesis deals with the creation of a general communication interface between the smart product and process cells within test bed Barman. The aim is to create distributed production according to the Industry 4.0 concept, where each product manages it’s production itself. The first part deals with the analysis of test bed, where are discussed requirements and method of production. Then with the selection of a communication protocol that would meet Industry 4.0 and distributed control requirements. The result of the research was OPC UA communication protocol. Using this protocol, the product and the process cell will communicate with each other. I chose the appropriate implementation for the selected protocol to be used for creating communication modules of the product and the process cell. Production data will be stored in an RFID chip located in the product. Part of the work is devoted to creation this data structure, which contains the recipe as well as production state data. Creation of RFID reader is the work of another student, with whom I solved the method of data exchange between application of the reader and the communication module of the product. When creating a communication module of the process cell, I solved the design of an information model that describes the entire process cell, and the dynamic creation of nodes in the address space. I have mentioned a few examples of how I worked with a selected implementation of OPC UA and how I used it in both applications. I implemented decentralized search of another process cells in the local network. This feature was easy to implement with OPC UA, specifically with the LDS-ME service. I solved the control of production for the communication module of the product and method of communication with the process cell. And in the last part I deal with manual, which describes how to compile projects correctly, specifically on the Linux operating system, and I have described a way to test the whole solution together with the results.
|
host ::
RSS.