This work investigates powering options for implants of sizes ranging from 10 mm by 10 mm down to 1 mm by 1 mm. Wireless power transfer is identified as the most promising option of doing so and is investigated in detail. It is shown, that for a given implant antenna size, an optimum combination of external antenna and frequency of operation exists that minimizes the overall link loss. In combination with limitations on the maximum transmit and received power due to health concerns, the maximum power available to mm-size implants as a function of size is derived. Two different AC-to-DC conversion circuit topologies, covering the expected input power and frequency range, are analyzed in detail and design guidelines for each are given.
Finally, a 1 mm^3 proof-of-concept implementation of a wirelessly powered neural transponder is presented. It was tested in air and in animal and provides enough extra DC power to power a neural sensor front-end while supporting a 2 Mbps radio link. The presented tag is the smallest wireless neural tag reported to date and prooves the feasibility of remotely powered mm-size wireless neural implants.