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Nakayama

et al. 2017

Sensors

This paper reports a 3-axis fully integrated differential capacitive tactile sensor surface-mountable on a bus line. The sensor integrates a flip-bonded complementary metal-oxide semiconductor (CMOS) with capacitive sensing circuits on a low temperature cofired ceramic (LTCC) interposer with Au through vias by Au-Au thermo-compression bonding. The CMOS circuit and bonding pads on the sensor backside were electrically connected through Au bumps and the LTCC interposer, and the differential capacitive gap was formed by an Au sealing frame. A diaphragm for sensing 3-axis force was formed in the CMOS substrate. The dimensions of the completed sensor are 2.5 mm in width, 2.5 mm in length, and 0.66 mm in thickness. The fabricated sensor output coded 3-axis capacitive sensing data according to applied 3-axis force by three-dimensional (3D)-printed pins. The measured sensitivity was as high as over 34 Count/mN for normal force and 14 to 15 Count/mN for shear force with small noise, which corresponds to less than 1 mN. The hysteresis and the average cross-sensitivity were also found to be less than 2% full scale and 11%, respectively.

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Surface-mountable capacitive tactile sensors with flipped CMOS-diaphragm on a flexible and stretchable bus line

Sensors and Actuators A: Physical

Bartley

et al. 2016

CMOS-on-LTCC integrated fingertip sensor with 3-axis tactile and thermal sensation for robots

Nakayama

et al. 2017

3-Axis fully-integrated surface-mountable differential capacitive tactile sensor by CMOS flip-bonding

Bartley

et al. 2016

Flipped CMOS-diaphragm capacitive tactile sensor surface mountable on flexible and stretchable bus line

Bartley

et al. 2015