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A 33-ppm/°C 240-nW 40-nm CMOS Wakeup Timer Based on a Bang-Bang Digital-Intensive Frequency-Locked-Loop for IoT Applications

Ming Ding, Zhihao Zhou, Stefano Traferro, Yao‐Hong Liu, Christian Bachmann, Fabio Sebastiano

2020IEEE Transactions on Circuits and Systems I Regular Papers23 citationsDOI

Abstract

This paper presents a wakeup timer in 40-nm CMOS for Internet-of-Things (IoT) applications based on a bang-bang Digital-intensive Frequency-Locked Loop (DFLL). A self-biased ΣA Digitally Controlled Oscillator (DCO) is locked to an RC time constant via a feedback loop consisting of a single-bit chopped comparator and a digital loop filter, thus maximizing the use of digital circuits while keeping only the RC network and the comparator as the sole analog blocks. Analysis and behavior level simulations of the DFLL have been carried out to guide the optimization of the long-term stability and frequency accuracy of the timer. High frequency accuracy and a 10× enhancement of long-term stability is achieved by the adoption of chopping to reduce the effect of comparator offset and 1/f noise and by the use of ΣA modulation to improve the DCO resolution. Such highly digitized architecture fully exploits the advantages of advanced CMOS processes, thus enabling operation down to 0.7 V and a small area (0.07 mm2). The proposed timer achieves the excellent energy efficiency (0.57 pJ/cycle at 417 kHz at 0.8-V supply) over prior art while keeping excellent on-par long-term stability (Allan deviation floor c20 ppm) and temperature stability (33 ppm/°C at 0.8-V supply).

Topics & Concepts

TimerComparatorCMOSComputer scienceFeedback loopElectronic engineeringElectrical engineeringComputer hardwareVoltageEngineeringMicrocontrollerComputer securityAdvancements in PLL and VCO TechnologiesAnalog and Mixed-Signal Circuit DesignRadio Frequency Integrated Circuit Design
A 33-ppm/°C 240-nW 40-nm CMOS Wakeup Timer Based on a Bang-Bang Digital-Intensive Frequency-Locked-Loop for IoT Applications | Litcius