用于植入式神经信号再生系统的轨到轨运算放大器的设计

Design of a rail-to-rail operational amplifier for implantable neural signal regeneration systems

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摘要为满足治疗中枢神经损伤的植入式神经信号再生系统的低压低功耗要求，设计了该微电子系统的中间级放大和激励的核心电路——恒跨导轨到轨运算放大器。根据系统满摆幅和低功耗的特点，在电路设计中采用了工作在亚阈值区的电流开关跨导控制电路作为输入级，改进的前馈AB类放大器作为输出级。芯片采用中芯国际0．18μm 1P6MCMOS工艺设计完成。仿真和测试结果表明，芯片实现了满摆幅动态范围，跨导恒定，可用于对探测得到的微弱神经信号的放大和激励，满足神经信号再生系统的要求。此芯片电路功耗和体积都很小，满足生物体植入式器件的要求。 According to the low-voltage low-power requirement of the body implatation application of an implantable neu- ral signal regeneration system for treatment of central nerve damages, a constant gm rail-to-rail operational amplifier （ op amp） was designed to meet the the need of the intermediate and stimulation stage of the micrcoelectronic neural signal regeneration system. A current switch transconductance control circuit working in the weak inversion region was used as the input stage while a improved feedforward class AB amplifer was used as the output stage. The chip was implemented in the SMIC 0.18μ m 1P6M CMOS process. The simulation and test results show that the circuit can realize the rail-to-rail dynamic range and the constant transconductance. It is suitable for body implantation be- cause the power consumption and the chip area are very small. It can be used for the amplification of weak neural signal in the neural signal regeneration system.

作者张翼孟桥王志功唐凯

机构地区东南大学射频与光电集成电路研究所

出处《高技术通讯》 CAS CSCD 北大核心 2012年第7期752-757,共6页 Chinese High Technology Letters

基金国家自然科学基金（90307013,90707005）和江苏省自然科学基金（BK2008032）资助项目.

关键词运算放大器满摆幅恒跨导低功耗 operational amplifier, full dynamic range, constant transconductance, low power

分类号 TN722.77 [电子电信—电路与系统]

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参考文献14

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3沈晓燕,杜薇,洪波.控制后肢运动的脊髓神经信号追踪方法研究[J].高技术通讯,2015,25(4):393-396. 被引量：3
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用于植入式神经信号再生系统的轨到轨运算放大器的设计

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