Accurate power control and monitoring in ZYNQ boards

ZYNQ devices combine a dual-core ARM Cortex A9 processor and a FPGA fabric in the same die and in different power domains. In this paper we investigate the run-time power scaling capabilities of these devices using of-the-shelf boards and proposed accurate and fine-grained power control and monitori...

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Main Authors: Beldachi, Arash Farhadi, Nunez-Yanez, Jose L.
Format: Conference Proceeding
Language:English
Subjects:
Adaptive Voltage Scaling
Field programmable gate arrays
FPGA
Hardware
IP networks
Monitoring
Power analysis
Process control
Software
Voltage control
Xilinx
ZYNQ board
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Nunez-Yanez, Jose L.
description ZYNQ devices combine a dual-core ARM Cortex A9 processor and a FPGA fabric in the same die and in different power domains. In this paper we investigate the run-time power scaling capabilities of these devices using of-the-shelf boards and proposed accurate and fine-grained power control and monitoring techniques. The experimental results show that both software and hardware methods are possible and the right selection can yield different results in terms of control and monitoring speeds, accuracy of measurement, power consumption, and area overhead. The results also demonstrate that significant power margins are available in the FPGA device with different voltage configurations possible. This can be used to complement traditional voltage scaling techniques applied to the processor domain to obtain hybrid energy proportional computing platforms.
doi_str_mv 10.1109/FPL.2014.6927415
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identifier ISSN: 1946-147X
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issn 1946-147X
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source IEEE Xplore All Conference Series
subjects Adaptive Voltage Scaling
Field programmable gate arrays
FPGA
Hardware
IP networks
Monitoring
Power analysis
Process control
Software
Voltage control
Xilinx
ZYNQ board
title Accurate power control and monitoring in ZYNQ boards
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