Capacitive proximity communication with distributed alignment sensing for origami biomedical implants

Abstract: Origami implant design is a 3D integration technique which addresses size and cost constraints in biomedical implants. A capacitive proximity interconnect that enables this technique is presented. The interconnect embeds an alignment sensor that measures link quality directly and simplifies its adaptation to alignment. The sensor and transceiver share functional blocks, saving power and area. Data rates from 10-60 Mbps are achieved over 4-12 µm of parylene-C, with efficiencies up to 0.180 pJ/bit.

“…This design uses capacitively-coupled proximity interconnect, which poses much less of a power and timing problem and is much more amenable to alignment-sensing operations [15]. However, existing approaches use specialized alignment sensors running on a separate set of plates [16], [17], and therefore require more area of the two chips to be aligned (both the alignment sensor and the communication array need to be in alignment), limiting flexibility.…”

Capacitive Proximity Communication With Distributed Alignment Sensing for Origami Biomedical Implants

“…This design uses capacitively-coupled proximity interconnect, which poses much less of a power and timing problem and is much more amenable to alignment-sensing operations [15]. However, existing approaches use specialized alignment sensors running on a separate set of plates [16], [17], and therefore require more area of the two chips to be aligned (both the alignment sensor and the communication array need to be in alignment), limiting flexibility.…”

Capacitive Proximity Communication With Distributed Alignment Sensing for Origami Biomedical Implants

Design considerations for high-density fully intraocular epiretinal prostheses