This paper presents
a textile-based stretchable microstrip patch
antenna with intrinsic strain for e-textiles with seamlessly integrated
multifunctional devices. Several microstrip antennas have been developed
with the patch alone (stretchable up to 40%) or both the patch and
the ground plane (stretchable up to 100%) meshed by using rectangular
serpentine units. The changes in the resonant frequency of the meshed
antennas, as a result of stretching, have been exploited to demonstrate
the intrinsic uniaxial strain sensing. The obtained results indicate
that resonant frequency decreases linearly with increasing applied
strain, suggesting that the designed antennas can also be used as
strain sensors with stretchability up to 100% and a sensitivity of
0.25. The results were validated through full-wave electromagnetic
simulations and a two-dimensional digital image correlation (DIC)
technique to model the antenna deformations during the tensile tests.
In terms of stretchability, the meshed textile patch antenna on a
solid ground plane showed more than a 2-fold improvement compared
to a meshed gold patch antenna, showing a linear frequency shift.
As potential applications, we demonstrate the use of a highly deformable
fully meshed textile antenna as a strain sensor capable of measuring
joint angles of a human limb. To do that, a microwave readout circuit
based on RF to DC rectifier was realized. The rectifier obtained a
peak conversion efficiency of 71% at 10 dBm input power overload resistor
of 3 kΩ.
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