Tiny sensors, such as temperature and posture sensors, distributed over the body surface will provide more detailed information about the body’s status than a single-point measurement by sensor-loaded wearable devices including smartwatches. Power/data transfer to/from the distributed tiny sensors is an inevitable issue. In this presentation, wireless access to batteryless and antennaless sensors distributed on a conductive textile will be demonstrated. A double-sided conductive textile is used as a power and signal transmission bus. The two conductive surfaces, isolated from each other, work as a transmission line that conveys dc power and radio-frequency (RF) signals simultaneously. In the demonstration system, two RF carriers are modulated with Inter-Integrated Circuit (I2C)-formatted digital signals to transfer bitstreams from each sensor. Hence, the system is compatible with off-the-shelf I2C-interfaced digital sensor ICs. A demonstration system with distributed temperature sensors will be presented as an example of implementation; nevertheless, other various sensors, e.g., humidity sensors, accelerometers, and electromyography sensors, can be utilized in the same system.
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