LAUSR

Ultralow-power (ULP) mm-scale Internet-of-Things (IoT) platforms enable newly emerging applications such as pervasive agricultural monitoring and biosensing. Although there is an increasing interest in node-to-node communication as defined in Bluetooth v5.0, prior research in mm-scale wireless systems is mostly limited to asymmetric node-to-gateway communications. We present a 2.4-GHz node-to-node communication system for an ultra-small wireless sensor node fully integrated within a 4 $\times $ 4 $\times $ 4 mm³ form factor. The system integrates multiple stacked layers including an RF transceiver, a ULP processor, a photovoltaic (PV) cell, a 32-kHz crystal, and a 3-D magnetic dipole antenna. The transceiver front-end circuit is co-designed with a printed 3-D magnetic dipole antenna to form a power oscillator for the transmitter (TX) as well as a $Q$ -enhanced amplifier (QEA) for the receiver (RX). A new carrier frequency-interlocking IF architecture successfully mitigates the TX–RX carrier frequency synchronization challenge that is critical to the mm-scale radio systems. The complete system achieves −94-dBm sensitivity with 97- $\mu \text {W}$ power consumption and −12.6-dBm equivalent isotropically radiated power (EIRP). Standalone operation of a sensor node is demonstrated through bi-directional wireless communication to another sensor node over 1-m distance in real, uncontrolled wireless channels.