Abstract
The evolution of microelectronics increased the information acquired by today’s biomedical sensor systems to an extent where the capacity of low-power communication interfaces becomes one of the central bottlenecks. Hence, this paper mathematically analyzes and experimentally verifies novel coil and transceiver topologies for near-field communication interfaces, which simultaneously allow for high data transfer rates, low power consumption, and reduced interference to nearby wireless power transfer interfaces. Data coil design is focused on presenting two particular topologies which provide sufficient coupling between a reader and a wireless sensor system, but do not couple to an energy coil situated on the same substrate, severely reducing interference between wireless data and energy transfer interfaces. A novel transceiver design combines the approaches of a minimalistic analog front-end with a fully digital single-bit sampling demodulator, in which rectangular binary signals are processed by simple digital circuits instead of sinusoidal signals being conditioned by complex analog mixers and subsequent multi-bit analog-to-digital converters. The concepts are implemented using an analog interface in discrete circuit technology and a commercial low-power field-programmable gate array, yielding a transceiver which supports data rates of up to 6.78 MBit/s with an energy consumption of just 646 pJ/bit in transmitting mode and of 364 pJ/bit in receiving mode at a bit error rate of , being 10 times more energy efficient than any commercial NFC interface and fully implementable without any custom CMOS technology.
Highlights
Near-field communication (NFC) has proven to be a reliable data transfer technology in a series of biomedical implants and devices: the communication interface, based on inductive coupling of two coils, is hereby complementing the actual sensor front-end by establishing the connection to the corresponding data processing unit
In the first step of experimental evaluation, the coil parameters were determined by the measurement setup shown in Figure 17 and by the procedure detailed in [28], i.e., the S-parameters of the data coil link were acquired with a vector network analyzer, converted to Z-parameters and subsequently to self-inductance Li = Im( Zii )/ω0 and mutual inductance Mij = Im( Zij )/ω0
We analyzed and experimentally verified a series of design strategies for near-field communication interfaces to enable an operation with high data rate, low power consumption, small footprint, and resilience against interference from wireless power transfer links: First, it was shown that data coil topologies can be optimized for minimal inductive coupling to wireless power transfer coils situated on the same substrate
Summary
Near-field communication (NFC) has proven to be a reliable data transfer technology in a series of biomedical implants and devices: the communication interface, based on inductive coupling of two coils, is hereby complementing the actual sensor front-end by establishing the connection to the corresponding data processing unit. Inductive communication technologies have been applied in biomedical sensor systems to monitor physiological parameters such as heart rate, blood pressure, or gastrointestinal activity [1,2], to analyze biochemical fluids [3,4], to improve hearing in cochlear implants [5], to reestablish vision in retinal implants [6], and to analyze and record neural signals in the context of brain–computer interfaces [7]
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