在比较器中使用基于反相器的差分放大器的 BiCMOS 有源淬火器

IF 2.2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE IEEE Solid-State Circuits Letters Pub Date : 2023-12-04 DOI:10.1109/LSSC.2023.3338660

B. Goll;M. Hofbauer;H. Zimmermann

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引用次数: 0

摘要

为实现点火单光子雪崩二极管（SPAD）的快速关断，介绍了一种采用 0.35- $\mu \text{m}$ BiCMOS 技术、具有极快淬火回转率的有源淬火电路。图中显示了在一个集成的小型探针焊盘上测量到的淬火瞬态。采用 NPN 晶体管作为淬火开关，可实现 250 ps 的有效淬火时间和 21.1 V/ns 的淬火回转率。比较器中使用的自偏压双反相器差分放大器使这种快速淬火成为可能。通过级联，集成 SPAD 的过量偏置电压可增加一倍，达到 6.6 V，而所用 BiCMOS 工艺的标称电源电压为 3.3 V。SPAD 的主动复位可在 725 ps 内实现。BiCMOS 淬火电路在 40 Mcounts/s 时的功耗为 16.3 mW，空闲状态下的功耗为 3 mW。

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A BiCMOS Active Quencher Using an Inverter-Based Differential Amplifier in the Comparator

For fast switching off of a firing single-photon avalanche diode (SPAD), an active quenching circuit in 0.35-

$\mu \text{m}$

BiCMOS technology with a very fast quenching slew rate is introduced. Quenching transients measured at an integrated small prober pad are shown. An NPN transistor as quenching switch leads to an active quenching time of 250 ps and a quenching slew rate of 21.1 V/ns. A self-biased two-inverter differential amplifier used in the comparator makes this fast quenching possible. By the implementation of cascoding, the excess bias voltage of the integrated SPAD can be doubled to 6.6 V with respect to the nominal supply voltage of 3.3 V of the BiCMOS process used. Active resetting of the SPAD is achieved in 725 ps. The power consumption of the BiCMOS quenching circuit is 16.3 mW at 40 Mcounts/s and 3 mW in the idle state.

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来源期刊

IEEE Solid-State Circuits Letters Engineering-Electrical and Electronic Engineering

CiteScore

4.30

自引率

3.70%

发文量