5 research outputs found
Similarity values of between each patient’s symptoms and possible diagnosis.
<p>Similarity values of between each patient’s symptoms and possible diagnosis.</p
Similarity values of between each patient’s symptoms and possible diagnosis.
<p>Similarity values of between each patient’s symptoms and possible diagnosis.</p
Symptoms characteristic for the considered patients in terms of HFLTSs.
<p>Symptoms characteristic for the considered patients in terms of HFLTSs.</p
Similarity values of between each patient’s symptoms and possible diagnosis.
<p>Similarity values of between each patient’s symptoms and possible diagnosis.</p
Precise Engineering of Conductive Pathway by Frictional Direct-Writing for Ultrasensitive Flexible Strain Sensors
Highly
sensitive strain sensors that can detect small strain are in high
demand in the fields of displays, robotics, fatigue detection, body
monitoring, in vitro diagnostics, and advanced therapies. However,
resistive-type sensors that are composed of electrically conductive
sensing films coupled with flexible substrates suffer from the limits
that their gauge factors (GFs) at small strains (e.g., 0.1–1%)
are not high. Herein, through frictional direct-writing of graphite
rod on the composite paper substrates, we produced strain sensors
with extremely high gauge factor at small strains. The sensors exhibited
a gauge factor of 9720 at a small strain of 0.9%, minimum strain detection
up to 0.05%, strain resolution of 0.05%, response time of 40 ms, and
high stability (>5000 bending–unbending cycles). Compared
with the literature results so far, our sensors hold the highest GF
value at small strains. Such high sensitivities are due to the precise
control of narrow two-dimensional percolative conductive pathway,
which means the content of conductive graphite sheets is close to
the conductive percolation threshold. The strain sensors have a rapid
response to microdeformation changes and can monitor various structural
changes, including human motion, through facilitative and effective
installation of device designs