A method and system for determining an estimation of an anemometric parameter of an aircraft. The anemometric parameter including an angle of attack, a sideslip angle and a calibrated airspeed. The method including obtaining an indication of a secondary surface state of the aircraft; obtaining a position indication of a horizontal primary surface; obtaining a load applied estimation on a corresponding actuator using the position indication of the horizontal primary surface and the position of the corresponding actuator; accessing a lookup table with the indication of the secondary surface state of the aircraft, the load estimation applied on the corresponding actuator, and the position of the corresponding actuator; obtaining an estimation of the anemometric parameter associated with the horizontal primary surface; providing the estimation of the anemometric parameter associated with the horizontal primary surface and wherein the lookup table is generated during a learning phase.

A projection apparatus includes a projection system, a distance measuring sensor that is used to adjust the focal point of the projection system and outputs infrared light in the frontward direction, and an enclosure that houses the projection system and the distance measuring sensor. An exit port of the projection system is disposed at a position which is shifted from the distance measuring sensor in a second direction opposite the first direction. The enclosure has a detection opening via which the infrared light exits. The distance measuring sensor has a detection range over which distance detection is allowed and a non-detection range over which no distance detection is allowed and which is shifted from the detection range toward the distance measurement sensor, and the distance measuring sensor is disposed at a distance from the detection opening, the distance including the non-detection range of the distance measuring sensor.

A water level detection device capable of preventing water from overflowing due to a bumping phenomenon or excessive number of cooking objects and capable of detecting a water level inside a cookware, comprises: a first probe; a second probe; a lean angle sensor configured to detect a lean angle of the first probe and the second probe; a capacitance sensor configured to detect capacitance between the first probe and the second probe; and a processor configured to calculate a danger level of the cookware based on an intensity of a current flowing from the first probe to the second probe and the lean angle of the first probe and the second probe; and configured to determine whether the water level inside the cookware reaches the danger level based on the capacitance between the first probe and the second probe.

Information on a work machine is more accurately obtained through simplified works. An information obtaining system includes a hydraulic excavator, a target portion, a position measurement unit, and an information obtaining unit. The hydraulic excavator includes a revolving unit and a work implement movable relatively to the revolving unit. The target portion is attached to the work implement. The position measurement unit continuously measures positions of the target portion that moves with movement of the work implement relative to the revolving unit. The information obtaining unit obtains three-dimensional information on the hydraulic excavator based on a track of the target portion obtained by measurement.

Aspects of the present invention relate presentation of digital content, in a see-through display, representing a known location in an environment proximate to a head worn computer.

An X-ray diffractometer for obtaining X-ray diffraction angles of diffracted X-rays by detecting with an X-ray detector diffracted X-rays diffracted at a sample when X-rays are emitted at the sample at each angle of the angles about a center point of goniometer circles, the X-ray diffractometer having a pinhole member provided with a pinhole, the pinhole allowing X-rays diffracted from the sample to pass so that the diffracted X-rays pass through the center point of the goniometer circle, and other diffracted X-rays are shielded by the pinhole member.

An X-ray diffractometer for obtaining X-ray diffraction angles of diffracted X-rays by detecting with an X-ray detector diffracted X-rays diffracted at a sample when X-rays are emitted at the sample at each angle of the angles about a center point of goniometer circles, the X-ray diffractometer having a pinhole member provided with a pinhole, the pinhole allowing X-rays diffracted from the sample to pass so that the diffracted X-rays pass through the center point of the goniometer circle, and other diffracted X-rays are shielded by the pinhole member.

A system for control of a device includes at least one sensor module detecting orientation of a user's body part. The at least one sensor module is in communication with a device module configured to command an associated device. The at least one sensor module detects orientation of the body part. The at least one sensor module sends output signals related to orientation of the user's body part to the device module and the device module controls the associated device based on the signals from the at least one sensor module.

A system for control of a device includes at least one sensor module detecting orientation of a user's body part. The at least one sensor module is in communication with a device module configured to command an associated device. The at least one sensor module detects orientation of the body part. The at least one sensor module sends output signals related to orientation of the user's body part to the device module and the device module controls the associated device based on the signals from the at least one sensor module.

The present invention relates to a non-contact potentiometer. The non-contact potentiometer comprises the following parts: a mechanical housing with through-holes; a rotating shaft comprising a top end and a magnet end on which a permanent magnet is fixed and external torque can be applied to the top end, thus driving the rotating shaft and the permanent magnet to rotate around a rotation axis and relative to the housing; a magnetoresistive sensor assembly fixed inside the housing, comprising one or more sensor chips, the sensitivity axis of the sensor chips lies in a sensing plane that is perpendicular to the axis of the rotating shaft, and separated from the permanent magnet by a predetermined distance in the direction parallel to the axis of the rotating shaft, said sensors are used for sensing the magnetic variation produced as the permanent magnet rotates with the rotating shaft thereby generating sensing signals; and three electrical connection terminals, namely a ground terminal, a power terminal, and a signal output terminal. This non-contact potentiometer has the advantages of high precision, low power consumption, and low cost. Additionally, it converts the complex analog signal from the magnetic sensor into a standard digital format that is easy to use.