A deterioration determination apparatus according to one or more embodiments may include: an information obtainment unit configured to obtain information on deformation of a suction portion that is configured to hold an object by suction with negative pressure and elastically deforms by the negative pressure; and a deterioration determination unit configured to determine whether or not the suction portion has deteriorated, depending on the deformation of the suction portion occurring when the suction portion holds the object by suction.

Systems and methods may be implemented separately from (and external to) a battery system to detect swollen battery system components within a chassis enclosure of the information handling system, without any physical contact with the battery cells or battery system, and without requiring premature opening of the information handling system chassis enclosure to inspect for battery system swelling. A system user may be automatically warned of detected battery system swelling and/or battery system charging may be automatically terminated upon detected battery system swelling so that information handling system failure and/or system service costs that would otherwise be expended to repair damage caused by swollen battery system components may be prevented.

Provided are a resonator, a method of manufacturing the resonator, and a strain sensor and a sensor array including the resonator. The resonator is provided to extend in a lengthwise direction from a support. The resonator includes a single crystal material and is provided to extend in a crystal orientation that satisfies at least one from among a Young's modulus and a Poisson's ratio, from among crystal orientations of the single crystal material.

A torque sensor according to the present invention includes a strain body, first structure Y-axis connecting portions, second structure X-axis connecting portions and a detection element. The first structure Y-axis connecting portions are disposed on a positive side and a negative side of a Y-axis relative to the strain body, and the second structure X-axis connecting portions are disposed on a positive side and a negative side of an X-axis relative to the second structure. The strain body includes four deformable bodies each including a displacement portion that is displaced in a Z-axis direction by elastic deformation. The deformable bodies are respectively disposed in a first quadrant, a second quadrant, a third quadrant, and a fourth quadrant. The detection element includes a capacitive element that detects a change in capacitance value by a displacement of the displacement portion of each of the deformable bodies in the Z-axis direction.

A textile with an electrically conductive first side and an electrically conductive second side where the two sides are separated by an electrically insulating part of the textile and where the electrically conductivity is provided by a graphene coating on the respective sides and where a capacitance can be formed between the respective conductive sides.

A capacitive strain sensor configured to measure a strain includes a dielectric layer; a first electrode placed on a first face of the dielectric layer; and a second electrode placed on a second face, opposite to the first face, of the dielectric layer. The first electrode is formed of a single-walled carbon nanotube paper, and the single-walled carbon nanotube paper has plural pre-cracks made according to a pattern.

An alignment apparatus and an alignment detection method, which fall within a field of display technology, are disclosed herein. The alignment apparatus includes: a work table; a plurality of alignment rods provided on the work table, wherein a capacitor element is provided inside the alignment rod, and a capacitance of the capacitor element is changeable as the alignment rod deforms; and an alarm element connected to the capacitor element for giving an alarm when it receives a capacitance change value which exceeds a preset threshold value.

A method for determining a health of a display assembly of a foldable electronic device is provided. The method includes detecting a sequence of folds of the display assembly of the foldable electronic device. Further, the method includes determining a first plurality of parameters associated with the sequence of folds of the display assembly. Further, the method includes determining a second plurality of parameters associated with a concentrated load on the display assembly. Further, the method includes determining a residual stress for the display assembly based on the first plurality of parameters and the second plurality of parameters. Further, the method includes determining the health of the display assembly based on the residual stress for the display assembly of the foldable electronic device.

A gas detection device includes a substrate having a main surface and a movable film structure located on, and including a portion thereof spaced from, the main surface of the substrate. The portion of the movable film structure located over and spaced from the substrate includes a first film formed of an insulating material, a patterned second film which deforms as a result of absorbing or adsorbing a predetermined gas, and a patterned third film comprising a resistive heater, at least a portion of the movable film structure spaced from the substrate being movable with respect to the substrate. From the perspective of a direction perpendicular to the main surface of the substrate, at least a portion of a pattern of the second film overlaps at least a portion of a pattern of the third film.

An automated device, in particular a robot, comprises: a movable structure; actuator means, for causing displacements of the movable structure; a control system, which includes a control unit and is able to control the actuator means; and a sensorized covering, which covers at least part of the movable structure and integrates sensor means that include at least one of contact sensor means and proximity sensor means.

The sensorized covering comprises a plurality of covering modules, each having a respective load-bearing structure of a predefined shape associated to which is at least one layer of elastically yielding material. The plurality of covering modules comprises one or more sensorized covering modules, which include respective sensor means. The load-bearing structure of at least some of the covering modules has electrical connector means associated thereto, for enabling separable electrical connection of at least two different covering modules that are adjacent to one another.