Provided are material testing devices and methods for measuring certain physical properties of materials, such as for example, drying, curing, film formation, friction, adhesion, print resistance, and scratch resistance. The testing device includes a platform, a stylus comprising a probe, an angle sensor, a linear position sensor, a control system with a power supply and a control center which may be programmed with testing parameters.

Provided are material testing devices and methods for measuring certain physical properties of materials, such as for example, drying, curing, film formation, friction, adhesion, print resistance, and scratch resistance. The testing device includes a platform, a stylus comprising a probe, an angle sensor, a linear position sensor, a control system with a power supply and a control center which may be programmed with testing parameters.

An information processing apparatus includes a memory in which processing instruction information including data to be processed and setting information is stored; a first executing unit that executes processing of the data to be processed on a basis of a first product and the setting information; a first measurement unit that measures a predetermined item concerning a first processing result of the first executing unit; a second executing unit that executes processing of the data to be processed on a basis of a second product and the setting information; a second measurement unit that measures the item concerning a second processing result of the second executing unit; and an output unit that outputs a result of comparison between the first processing result and the second processing result on a basis of a measurement result of the first measurement unit and a measurement result of the second measurement unit.

An information processing apparatus includes a memory in which processing instruction information including data to be processed and setting information is stored; a first executing unit that executes processing of the data to be processed on a basis of a first product and the setting information; a first measurement unit that measures a predetermined item concerning a first processing result of the first executing unit; a second executing unit that executes processing of the data to be processed on a basis of a second product and the setting information; a second measurement unit that measures the item concerning a second processing result of the second executing unit; and an output unit that outputs a result of comparison between the first processing result and the second processing result on a basis of a measurement result of the first measurement unit and a measurement result of the second measurement unit.

A modified version of a MEMS self-test procedure is presented that can be used to detect the amplitude and frequency of an external vibration from an ambient environment. The method implements processing circuitry that correlates an output sense signal, s(t), with a plurality of periodic signal portions and a plurality of shifted periodic signal portions to generate a plurality of correlation values. A frequency associated with the external vibration is determined based on the plurality of correlation values.

A second core calculates an intervening variable that is defined by an inner function, when a time derivative of a state variable is expressed by a function having the state variable, the inner function, and an observable input variable as independent variables. A first core calculates a function by using respective values of the state variable, the intervening variable, and the input variable, and obtains a value of the state variable by time-integration of a value of the function. In the calculation of the function, the value of the state variable calculated in previous time, a value of the intervening variable calculated by the second core in the previous time, and a value of the input variable inputted in this time are used.

Domain agnostic systems and methods for the capture, storage, and analysis of sensor readings including: collecting gauge readings from a plurality of gauges; storing the gauge readings in a database; normalizing select gauge readings in near-real time at the server from the database of the server in response to a user query; and generating a relationship among the select gauge readings in response to the user query; generating information for configuring an entity that provides feedback in a domain agnostic system, based on said relationship among the select gauge readings; and generating an alert in response to the select gauge readings satisfying a certain condition.

Domain agnostic systems and methods for the capture, storage, and analysis of sensor readings including: collecting gauge readings from a plurality of gauges; storing the gauge readings in a database; normalizing select gauge readings in near-real time at the server from the database of the server in response to a user query; and generating a relationship among the select gauge readings in response to the user query; generating information for configuring an entity that provides feedback in a domain agnostic system, based on said relationship among the select gauge readings; and generating an alert in response to the select gauge readings satisfying a certain condition.

Present embodiments are directed to a tubular stress measurement system including a first sensor configured to detect a parameter indicative of an axial or circumferential position of the plurality of grapples and a calculation system configured to calculate an internal stress on the tubular based on the parameter.

A microelectromechanical acceleration sensor system including a microelectromechanical acceleration sensor element for detecting acceleration values acting on the acceleration sensor element, a sigma-delta analog-to-digital converter for converting the analog output signals of the acceleration sensor element into digital output signals, and a first signal generator element and a second signal generator element. The first signal generator element is connected between the acceleration sensor element and the analog-to-digital converter and being configured to apply a predetermined signal value to the output signals of the acceleration sensor element. The signal value of the first signal generator element corresponding to an acceleration value that is greater than the average gravity acceleration, and the second signal generator element being connected in a signal processing direction downstream from the analog-to-digital converter and being configured to correct the digital output signals of the analog-to-digital converter by the signal value of the first signal generator element.