Collecting roll data associated with a sensing and mating rolls that form a nip uses first and second pluralities of sensors. Each sensor of the first plurality has a corresponding sensor in the second plurality which is associated with a same respective axial location on the sensing roll but is spaced-apart circumferentially. The sensors are located at axially spaced-apart locations of the sensing roll and generate either a first or second respective signal when entering the nip. Upon receiving a generated signal, a determination is made about which sensor generated the received signal and the membership of that sensor in one of the pluralities. Based upon a rotational position of the mating roll, a determination is made of which tracking segment associated with the mating roll enters the region of the nip concurrently with the signal to store the signal using the determined one tracking segment and the determined membership.

A force detection device includes: a substrate; and a force transmission block. The substrate includes: a mesa gauge arranged on a principal plane of the substrate and providing a bridge circuit; a connection region arranged on the principal plane; and a sealing portion surrounding all around the mesa gauge and connected to the force transmission block. The mesa gauge includes: a first mesa gauge extending in a first direction; and a second mesa gauge extending in a second direction and spaced apart from the first mesa gauge. The connection region electrically connects the one end of the first mesa gauge and the one end of the second mesa gauge.

A sensor device includes a plurality of systems each having a sensor element, and a computation unit configured to calculate as a first value a value of at least one of a force and a moment applied to a detection target in a predetermined axial direction, based on a detection signal detected by the sensor element, and an abnormality determining unit configured to compare the first values calculated by the computation units of the systems with one another, and determine that there is an abnormality if a difference of the first value is greater than or equal to a predetermined amount. The computation unit of at least one of the systems calculates as a second value a value of at least one of a force and a moment applied to the detection target in the axial direction, based on detection signals detected by the sensor elements of the systems.

A pressure-sensitive ink includes an adhesive, conductive particles, and inorganic fillers dispersed in the adhesive. The inorganic fillers include hydrophobic groups, and the inorganic fillers can increase the dispersibility of the conductive particles. The conductive particles can be uniformly dispersed in the adhesive by adding inorganic fillers with hydrophobic groups. The sensitivity and structure stability of a flexible pressure sensing structure are improved, and the noise of the flexible pressure sensing structure is reduced. In addition, the stability and the process yield of the flexible pressure sensing structure are also improved A flexible pressure sensing structure and an electronic device are also disclosed.

A method for determining the state of at least one sensor whose mechanical behaviour is nonlinear as a function of the amplitude of the pressure exerted against the sensor, the sensor and an electromechanical transducer being able to be coupled to a support, the method comprising the steps of: applying an electrical signal at a first amplitude to the terminals of the first electromechanical transducer, and determining a first set of values of a parameter characteristic of the electrical impedance of the first electromechanical transducer in response to the application of the electrical signal; applying the electrical signal at a second amplitude to the terminals of the first electromechanical transducer, and determining a second set of values of the parameter characteristic of the impedance; measuring a deviation between the first set of values and the second set of values; determining a state of the sensor as a function of the deviation between the first set of values and the second set of values.