一种可编程芯片系统，用于实时控制大量并行的生物传感器和执行器阵列

The 3rd IEEE International Workshop on System-on-Chip for Real-Time Applications, 2003. Proceedings. Pub Date : 2003-07-22 DOI:10.1109/IWSOC.2003.1213041

A. Romani, F. Campi, S. Ronconi, M. Tartagni, G. Medoro, N. Manaresi

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引用次数: 8

摘要

由于硅技术的进步，微电子芯片实验室设备(loac)的发展现在可以追求。由于这类设备可能集成不同的功能单元，因此控制单元的设计必须非常小心，控制单元必须提供实时控制能力，以便处理由传感器、执行器、信号调理和处理电路组成的复杂系统。此外，可重构性和可扩展性是获得灵活和可重用架构的关键设计特征。本文以FPGA实现现有LOAC控制系统为例，重点介绍了可编程器件方法的优点。该系统已在Altera EPF10K200S器件上实现，工作频率为20MHz。该装置测试成功，现给出实验结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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A system-on-a-programmable-chip for real-time control of massively parallel arrays of biosensors and actuators

The development of microelectronic lab-on-a-chip devices (LOACs) can now be pursued thanks to advances in silicon technology. As these kinds of devices may integrate different functional units, much care has to be put in the design of control units which have to provide real-time control capabilities in order to deal with complex systems composed of sensors, actuators, signal conditioning and processing circuits. Moreover, reconfigurability and expandability are key design features to get a flexible and reusable architecture. The FPGA implementation of a control system for an existing LOAC is presented as a case study with emphasis on the advantages of a programmable device approach. The presented system has been implemented on an Altera EPF10K200S device and the achieved operating frequency is 20MHz. The device was successfully tested and experimental results are hereby shown.

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The 3rd IEEE International Workshop on System-on-Chip for Real-Time Applications, 2003. Proceedings.

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