Anup P. Omprakash, Adrian Ildefonso, George N. Tzintzarov, J. Babcock, R. Mukhopadhyay, J. Cressler
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引用次数: 0
摘要
目前的工作展示了使用SiGe-on-SOI异质结双极晶体管(hbt)来实现可以在24°C至300°C范围内工作的模拟构建模块。在这个宽温度范围内校准Mextram紧凑型模型的方法被强调。使用校准过的紧凑型模型,设计、制造了三种不同的模拟模块,一个电流反射镜,一个带隙参考(BGR)电路和一个ab级推挽输出级,并在24°C至300°C范围内进行了测量。级联码电流反射镜具有优异的输出电阻$(>\mathbf{60\ M}\Omega)$和低失配比$(< \mathbf{3}\%)$,最高可达300°C。提出了一种构建宽温BGR的模块化设计方法。设计的BGR在24°C至300°C范围内的温度系数(TC)为88.28 ppm/°C,据作者所知,这是在该温度范围内任何硅基BGR中测量到的最低TC。验证了BGR在300°c下的长期运行,发现输出电压的变化小于0.1%, which makes it robust for high-temperature operation. A Class-AB push-pull output stage is shown operational up to 300°C, and a current drive up to 1 mA and a quiescent current of $\mathbf{21}\ \mu\mathbf{A}$ is measured at 300°C.
Using SiGe-on-SOI HBTs to Build 300°C Capable Analog Circuits
The present work demonstrates the use of SiGe-on-SOI heterojunction bipolar transistors (HBTs) to implement analog building blocks that can operate from 24°Cto 300°C. A method to calibrate a Mextram compact model over this wide-temperature range is highlighted. Using a calibrated compact model, three different analog building blocks, a current mirror, a bandgap reference (BGR) circuit, and a Class-AB push-pull output stage, were designed, fabricated, and measured from 24°Cto 300°C. The cascode current mirror shows excellent output resistance $(>\mathbf{60\ M}\Omega)$ and low mismatch ratio $(< \mathbf{3}\%)$ up to 300°C. A modular design approach for building a wide-temperature BGR is proposed. The designed BGR is shown to have a temperature coefficient (TC) of 88.28 ppm/°Cfrom 24°Cto 300°C, which, to the best of the authors' knowledge, is the lowest measured TC of any silicon-based BGR over this temperature range. Long-term operation of the BGR at 300°Cwas verified, and the output voltage was found to vary by less than 0.1%, which makes it robust for high-temperature operation. A Class-AB push-pull output stage is shown operational up to 300°C, and a current drive up to 1 mA and a quiescent current of $\mathbf{21}\ \mu\mathbf{A}$ is measured at 300°C.
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