The present disclosure generally relates to the field of temporal and spatial risk mapping and risk response. More particularly, the present disclosure relates to spatial and temporal mapping of outcomes, risk analysis, and responsive and preventative actions derived through artificial intelligence driven workflow augmentation using spatial and temporal data mapping of data from a plurality of historical and streaming data sources.

A force measurement system is disclosed herein. The force measurement system includes a plurality of force measurement assemblies, at least some of the plurality of force measurement assemblies configured to be independently displaceable from other ones of the plurality of force measurement assemblies such that one or more particular ones of the plurality of force measurement assemblies that are disposed underneath a subject varies over time. Each of the plurality of force measurement assemblies includes a top surface for receiving at least one portion of the body of the subject; and at least one force transducer, the at least one force transducer configured to sense one or more measured quantities and output one or more signals that are representative of forces and/or moments being applied to the top surface of the force measurement assembly by the subject.

A flexible circuit may be provided that allows for the monitoring of a physical object. The flexible circuit includes a plurality of flexible conductive segments that are disposed in a geometric pattern. The flexible conductive segments include nodes, and the physical object is monitored by analyzing changes in electrical resistance in the conductive segments between the nodes. The flexible circuit may also include sensors disposed on the nodes for monitoring additional conditions. A processor monitors the flexible conductive segments and sensors. and may provide an output regarding the status of the physical object.

A tangential force sensor is used instead of a coaxial strain gauge to measure the torque required to produce the rotation of a part. The force sensor is coupled tangentially to the rotating part through a non-slip contact produced by a force applied radially on the part. A progressively increasing tangential force produced by translating the force sensor in a direction normal to the axis of rotation of the part is then applied to initiate and maintain its rotation. The radial force applied to the part is judiciously selected and measured such that the part is engaged with enough friction to ensure a non-slip condition. By measuring the tangential force applied to the part, the torque characteristics of the rotatable part are determined. By sensing and controlling the radial force applied to the part, damage to the part or the mechanism supporting it is avoided.

A bed-leaving sensor for detecting bed-leaving by a user on a bed, including: a sitting position detection member that detects a sitting position of the user based on a detection value of a pressure sensor arranged on the bed; and a bed-leaving behavior detection member that detects bed-leaving behavior of the user with at least one of the following as a condition: (i) the sitting position being detected within a preset bed-leaving expectation region, (ii) a movement volume of a sitting position center of gravity which is a center of gravity of the sitting position exceeding a given threshold value within a given time, and (iii) the sitting position center of gravity moving toward a preset bed-leaving range.

A tactile fur sensing system and a method of operating thereof allow early detection of an impending contact with an object. A plurality of filaments or threads are positioned on a zone or area of a surface of robotic device in a cost-effective manner. One or more sensors are configured to detect electrical resistance and/or displacement of the plurality of filaments or threads. A processor determines that there is contact with an object based on the detected electrical resistance and/or displacement. The detection of electrical resistance can be based on adjustable baseline values and/or adjustable threshold values. A plurality of nubs may alternatively or in addition be positioned on a surface area. Each nub has an outer cast or protection layer defining a cavity therein. At least a portion of a sensor for detecting resistance and/or displacement is positioned within the cavity of the nub.

The present invention makes it possible to, even when a stainless steel is adopted in a diaphragm: prevent the diaphragm and a strain sensor from exfoliating from each other; be hardly susceptible to the influence of temperature in an operating environment; not allow the sensitivity of a pressure sensor to be dominated only by the mechanical characteristic of a material constituting the diaphragm; and increase the degree of freedom in design of members constituting the pressure sensor. A pressure sensor according to the present invention is, in order to solve the above problems, characterized in that: the pressure sensor has a diaphragm deforming by the pressure of a fluid, an elastic body covering the whole surface of the diaphragm and joining to the diaphragm on one side, and a strain sensor being arranged by joining on the other side of the elastic body and on an end side apart from a position corresponding to the center of the diaphragm and detecting the deformation of the elastic body working together with the deformation of the diaphragm as a strain; and the elastic body is formed of a material having a linear expansion coefficient close to the linear expansion coefficient of a material constituting the strain sensor.

A tactile sensor including a first insulating layer, a first sensing layer of a first conductive soft polymer material, a second sensing layer of a second conductive soft polymer material and a second insulating layer. The first sensing layer includes first electrically conductive strip located therein and the first sensing layer is positioned above the first insulating layer. The second sensing layer includes second and third electrically conductive strips located therein and the second sensing layer is positioned above the first sensing layer. The second and third electrically conductive strips are arranged within a first plane located within the second sensing layer, separated by the second conductive soft polymer material. The first and second electrically conductive strips are arranged within a second plane transverse to the first plane, separated by the first conductive soft polymer material. The second insulating layer is positioned above the second sensing layer. The first and second electrically conductive strips are connected to a first impedance measuring device. The second and third electrically conductive strips are connected to a second impedance measuring device.

An article of apparel and method include a structure configured to enclose a human body part, a pressure sensor array including multiple pressure sensors separately positioned at locations within the structure, wherein each pressure sensor is configured to output a signal indicative of an amount of pressure being exerted on the pressure sensor by an external mechanical force, an electronic display, and a controller. The controller is configured to receive signals from the pressure sensors and, based on a sequence and a timing of the signals as received, determine a command related to a function of a device. The electronic display is configured to display information related to the function.

A flexible touch sensor comprises: a first sheet material that has a first major surface, and that has a cushioning property; a second sheet material that includes a conductive material, and that is disposed on the first major surface of the first sheet material; and a conductive wire that is disposed on the first major surface of the first sheet material, and that is sunk into the first sheet material.