Rapid prototyping methodology of embedded control-acquisition system

• Autorzy: Augustyn J. , Bień A.
• Języki publikacji: PL

Abstrakty

EN

Modern control and measurement systems are equipped with interfaces to operate in local area networks and are typically intended to perform complicated data processing and control algorithms. The authors propose a digital system for rapid prototyping of target application devices. The concept solution separates the processing and control section from the hardware interface and user interface section. Both sections constitute independent ARM-based controllers interconnected via a direct USB link. Popular libraries can be used and low-level procedures developed, which enhances the system's economic viability. A test unit developed for the purpose of the study was built around a SoC ARM7 microsystem and an off-the-shelf palmtop device. It demonstrated a continuous data stream transfer capability up to 150 kB per second, which was sufficient to monitor the performance of an electricity line.

Słowa kluczowe

EN

embedded system; control and measurement systems; hard real-time systems; USB interface

• Wydawca: Komitet Metrologii i Aparatury Naukowej PAN
• Czasopismo: Metrology and Measurement Systems
• Rocznik: 2012
• Tom: Vol. 19, nr 4
• Strony: 777--786
• Opis fizyczny: Bibliogr. 29 poz., rys.

Twórcy

autor

Augustyn J.

autor

Bień A.

• AGH University of Science and Technology, Faculty of Electrical Engineering, Automatics, Computer Science and Biomedical Engineering, Al. Mickiewicza 30, 30-059 Kraków, Poland,

Bibliografia

• [1] Gamma E., Helm, R. (1995). Design Patterns: Elements of Reusable Object-Oriented Software. Addison Wesley.
• [2] Romeo, F. (2001). Embedded Systems: the Real Story. 38th Design Automation Conference, Plenary Panel. Las Vegas.
• [3] Wrycza, S., Marcinkowski, B., Wyrzykowski K. (2006). UML 2.0 in modelling of information systems. Gliwice, Helion, 456. (in Polish)
• [4] Bulbenkiene, V., Pecko, A., Zulkas, E., Kuprinavicius, A., Sokolov, A., Mumgaudis, G. Energy (2011). Sub-Metering Data Acquisition System. Electronics and electrical engineering, 5, 99-102.
• [5] Chan, S., Teng, J., Chen, C., Chang, D. (2010). Multi-functional power quality monitoring and report-back system. Electrical Power and Energy Systems, 32, 728-735.
• [6] Zhang, L., Wang, Z. (2010). Design of Embedded Control System Based on ARM9 Microcontroller. International Conference on Electrical and Control Engineering, 3579-3582.
• [7] Szrek, J., Wójtowicz, P. (2010). Idea of wheel-legged robot and its control system design. Bull. Pol. Acad. Sci.-Tech. Sci., 58(1), 43-50.
• [8] Cho, M.H., Lee, Ch.H. (2010). Low-Power Real-Time Operating System for ARC (Actual Remote Control) Wearable Device. IEEE Transactions on Consumer Electronics, 56(3), 1602-6909.
• [9] Simarro, R., Coronel, J., Simo, J., Blanes, J.F. (2008). Hierarchical and Distributed Embedded Control Kernel. 17th IFAC World Congress, Coex.
• [10] Yang, J., Gao, Z., Tang, J., Chen, Y. (2010). A Practical Predictive Control Algorithm for Embedded System and Its Application. Journal of Computational Information Systems, 6(11), 3501-3508.
• [11] Ma, L., Xia, F., Peng, Z. (2008). Integrated Design and Implementation of Embedded Control Systems with Scilab. Sensors, 5501-5515.
• [12] Precision USB thermometer probe. (2010). Electronic Temperature Instruments Ltd., http://www.etiltd.com
• [13] Three-axis Hall Magnetometer THM1176 Users Manual. (2008). Metrolab Instruments SA.
• [14] I-Scan® Handheld Pressure Measurement System. (2008). Tekscan, Inc. http://www.tekscan.com/industrial /iscan-handheld.html.
• [15] Augustyn, J., Bień, A. (2009). Real time performance of USB interface in embedded control and measurement systems. Przegląd Elektrotechniczny, 7, 1-7. (in Polish)
• [16] AT91SAM ARM-based FLASH MCU Doc. 6120I. (2011). Atmel.
• [17] AT91SAM ARM-based FLASH MCU SAM3S Series Doc. 6500C. (2011). Atmel.
• [18] Augustyn, J. (2007). Design of embedded systems with application to SAM7S family with ARM7TDMI core. Kraków, Wydawnictwo IGSMiE PAN, 302. (in Polish)
• [19] Franc, H., Šafari, R. (2010). ARM-Cortex Microcontroller fuzzy position control on an automatic door test-bed. 19th International Workshop on Robotics in Alpe-Adria-Danube Region - RAAD, Budapest, 417-422.
• [20] Pal, T., Shekhar, Ch., Sharma, H.D. (2009). Design and Implementation of Embedded Speed Controller on ARM for Micromanufacturing Applications. International Conference on Advances in Computing, Control and Telecommunication Technologies, 406-410.
• [21] Jianmin, H., Kai, G., Hong, Ch., Na, R. (2007). Design of Micro-oxidation power control system based on LPC2119. The Eighth International Conference on Electronic Measurement and Instruments ICEMI, Xian, 849-853.
• [22] FAT: General Overview of On-Disk Format. Version 1.03. (2000). Microsoft Corporation.
• [23] Microsoft Windows Embedded CE 6.0 Intel Atom Processor. (2009). Intel.
• [24] Intel® PXA27x Processor Family Developer’s Manual. (2004). Intel.
• [25] USB CDC/ACM Class Driver for Windows CE, Reference Manual, ver 1.4. (2009). Thesycon Systemsoftware & Consulting GmbH.
• [26] Universal Serial Bus Class Definitions for Communications Devices. Revision 1.2. (Nov. 2007). www.usb.org
• [27] Device Class Definition for Human Interface Devices (HID), Version 1.11. (2001). www.usb.org
• [28] Mini 6410 Hardware Spec, Rev 0.1.0. (Mar. 2011). Guangzho. www.friendlyarm
• [29] Benysek, G., Kazmierkowski, M.P., Popczy., J., Strzelecki, R. (2011). Power electronic systems as a crucial part of Smart Grid infrastructure - a survey. Bull. Pol. Acad. Sci.-Tech. Sci., 59(4), 455-473.