Ensuring robust and tissue-independent operation of implantable, ingestible, and injectable antennas

In-body bioelectronics relies on antennas to interface with external on- or off-body equipment. In this paper, we address the impedance detuning of in-body antennas caused by nondeterministic electromagnetic properties of biological tissues. The impedance robustness can be improved in two ways. First, by using wideband and multiresonance antennas with an added benefit of higher achievable data rates. Second, by applying specific dielectric-loaded narrow-band microstrip designs that additionally show enhanced radiation performance and robustness to inner components. Fully tissue-independent characteristics can be realized using hybrid slot-patch designs.

Ensuring robust and tissue-independent operation of implantable, ingestible, and injectable antennas

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Analytic Approximation of In-Body Path Loss for Implanted Antennas

Radiation Patterns of RF Wireless Devices Implanted in Small Animals: Unexpected Deformations Due to Body Resonance

Design Methodology for Wideband Bowtie Patch Antenna for 5G mmWave Applications

Radiation Patterns of RF Wireless Devices Implanted in Small Animals: Unexpected Deformations Due to Body Resonance

Analytic Approximation of In-Body Path Loss for Implanted Antennas

Design Methodology for Wideband Bowtie Patch Antenna for 5G mmWave Applications