Systems, methods, and computer-readable media for automatically setting exposure levels in a session based on an active participant. In some embodiments, a method can include detecting faces of one or more participants in one or more images in a captured video feed at a location of the participants illuminated at one or more illumination levels at the location. The one or more detected faces can be associated with brightness levels of the one or more participants based on the one or more illumination levels at the location. Audio input can be received for the one or more participants at the location and a first participant can be identified as an active participant using the audio input. Further, an exposure level of the captured video feed can be set based on the first participant acting as the active participant according to a brightness level in the one or more images associated with a face detection of the first participant in the one or more images.

A device for measuring tread depth includes: an image sensor; first and second depth sensing modules spaced apart along a separation axis, each including (i) an emitter configured to emit a beam of light, and (ii) an optical assembly configured to direct reflections of the beam of light onto a respective region of the image sensor; a controller connected to the image sensor and configured, responsive to the device traversing a treaded surface, to: receive, from the image sensor, a sequence of images corresponding to sequential positions of the device traversing the treaded surface in a travel direction substantially perpendicular to the separation axis, the sequence of images depicting successive reflections of the beams from the treaded surface; determine, for each image in the sequence of images, a first depth measurement and a second depth measurement; and store, in a memory, the first and second depth measurements.

A tire with printed strain sensors includes a pair of bead areas and a ground-contacting tread disposed radially outwardly of the pair of bead areas. Each one of a pair of sidewalls extends from a respective bead area to the tread. A carcass extends toroidally between each of the bead areas radially inwardly of the tread, and an innerliner is formed on an inside surface of the carcass. A pair of resistive strain sensors is printed on the innerliner, and includes a first strain sensor printed on the innerliner at an inboard rim flange area and a second strain sensor printed on the innerliner at an outboard rim flange area.

A tire with printed shear sensors includes a pair of bead areas and a ground-contacting tread disposed radially outwardly of the pair of bead areas. A pair of sidewalls includes an inboard sidewall extending from a first one of the bead areas to the tread and an outboard sidewall extending from a second one of the bead areas to the tread. A carcass extends toroidally between each of the bead areas radially inwardly of the tread, and an innerliner is formed on an inside surface of the carcass. A pair of resistive shear sensors is printed on the innerliner, including a first shear sensor printed in a sidewall zone of the inboard sidewall and a second shear sensor printed in a sidewall zone of the outboard sidewall.

A method for detecting an underflation state of a tire fitted on a vehicle is provided. The method includes determining a first contact patch measurement of a first tire fitted on the vehicle, determining a second contact patch measurement of a second tire fitted on the vehicle, and comparing the first and second contact patch measurements. An underinflation situation is inferred if a difference between the first and second contact patch measurements is greater than a predetermined signalling threshold.

A tire tread detection apparatus and tire pressure detector setting apparatus with tire tread detection function are provided. The tire tread detection apparatus includes a body casing, a driving unit, a measuring member, a position member, and a sense member. The driving unit, the measuring member, and the positioning member are connected. The driving unit is applied for driving the measuring member to protrude outward from the body casing for measuring the tire tread depth of the tire. The sense member generates a measurement signal corresponding to the positioning member, such that the measurement signal indicates a tire tread depth value. Therefore, the tire tread depth is efficiently and accurately acquired.

There is provided a system for determining real-time parameters of an aircraft, the system comprising: at least two sensing apparatus, each of the at least two sensing apparatus including a plurality of in-ground sensors; and at least one processing apparatus to process data received from the at least two sensing apparatus. It is preferable that a positioning of the at least two sensing apparatus is determined by a type of the aircraft being measured.

Systems, methods, and computer-readable media for automatically setting exposure levels in a session based on an active participant. In some embodiments, a method can include detecting faces of one or more participants in one or more images in a captured video feed at a location of the participants illuminated at one or more illumination levels at the location. The one or more detected faces can be associated with brightness levels of the one or more participants based on the one or more illumination levels at the location. Audio input can be received for the one or more participants at the location and a first participant can be identified as an active participant using the audio input. Further, an exposure level of the captured video feed can be set based on the first participant acting as the active participant according to a brightness level in the one or more images associated with a face detection of the first participant in the one or more images.

A sensor module is provided that includes a magnetic sensor and a microcontroller. The magnetic sensor is configured to measure a magnitude of a magnetic field component of an Earth magnetic field projected on a sensing axis of the magnetic sensor and is configured to generate a measurement signal. The magnetic sensor is configured to rotate about an axis through the Earth magnetic field such that the measurement signal oscillates between a first and second extremas as the magnitude of the magnetic field component projected onto the sensing axis changes due to rotation of the magnetic sensor about the axis. The microcontroller is configured to receive the measurement signal, acquire a predetermined number of measurement samples over a sampling period, calculate a variance value of the acquired measurement samples, and determine whether the magnetic sensor is rotating about the axis based on a threshold test of the variance value.

A hand-held device for measuring tire pressure and temperature including a pressure sensor, a temperature sensor, an optical pointer, a processor responsive to an output of the pressure sensor and the temperature sensor, and a display. The processor is configured to output a value on the display indicative of a measured tire pressure.