Abstract
This article presents a data-startable baseband logic featuring a gated oscillator clock and data recovery (GO-CDR) circuit for nanowatt wake-up and data receivers (WuRxs). At each data transition, the phase misalignment between the data coming from the analog front-end (AFE) and the clock is cleared by the GO-CDR circuit, thus allowing the reception of long data streams. Any free-running frequency mismatch between the GO and the bitrate does not limit the number of receivable bits, but only the maximum number of equal consecutive bits (Nm). To overcome this limitation, the proposed system includes a frequency calibration circuit, which reduces the frequency mismatch to ±0.5%, thus enabling the WuRx to be used with different encoding techniques up to Nm = 100. A full WuRx prototype, including an always-on clockless AFE operating in subthreshold, was fabricated with STMicroelectronics 90 nm BCD technology. The WuRx is supplied with 0.6 V, and the power consumption, excluding the calibration circuit, is 12.8 nW during the rest state and 17 nW at a 1 kbps data rate. With a 1 kbps On-Off Keying (OOK) modulated input and −35 dBm of input RF power after the input matching network (IMN), a 10−3 missed detection rate with a 0 bit error tolerance is measured, transmitting 63 bit packets with the Nm ranging from 1 to 63. The total sensitivity, including the estimated IMN gain at 100 MHz and 433 MHz, is −59.8 dBm and −52.3 dBm, respectively. In comparison with an ideal CDR, the degradation of the sensitivity due to the GO-CDR is 1.25 dBm. False alarm rate measurements lasting 24 h revealed zero overall false wake-ups.
Highlights
Energy efficiency is a fundamental metric for all battery-powered devices, such as wireless sensor and actuator network (WSAN) nodes, whose most power-hungry subsystem is usually the RF transceiver
Medium-range WuRxs are used in applications requiring a range of, at most, 100 m, their power consumption typically being in the nanowatt range
We present an implementation in STMicroelectronics 90 nm BCD technology and the experimental results of a nanowatt WuRx, enabling the transmission of long codes based on the gated oscillator clock and data recovery (GO-clock and data recovery (CDR)) architecture we proposed in [11] and including an analog front-end (AFE) with MOSFETs operating in the subthreshold region and a calibration circuit for the gated oscillator (GO)-CDR, which allows the WuRx to process data containing even long streams of equal consecutive bits
Summary
Energy efficiency is a fundamental metric for all battery-powered devices, such as wireless sensor and actuator network (WSAN) nodes, whose most power-hungry subsystem is usually the RF transceiver. To overcome the issues related to the power consumption, maximum packet length, false wake-up tolerance, preamble time and data encoding, in [11], a nanowatt WuRx suitable for receiving infinite bits in addition to a codeword targeting medium-range applications at a 1 kbps data rate was proposed. The delay block DB consisted of a stage equal to the ones oufs1e6d in the GO biased by the same control voltages vbias_p and vbias_n (with the two additional transistors biased as off) followed by an inverting stage to square its output signal (DDin) These choices ensured τd = τp (where τd is the delay between Din and DDin), 3w.2.hGicahteimd OplsiceidllatthoartatnhdeDneelcaeyssBalroyckcondition τd < Tb/2 was always satisfied [11]. The design constraints on the value of τd are τres < τd < Tb/2
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