A tactile sensation providing apparatus includes a contact region to be touched by an operating body, a thermal sensation providing element that is disposed in the contact region and provides at least cold sensation information, and a warm sensation providing element that is disposed in the contact region and provides warm sensation information. The warm sensation providing element is disposed at least in regions that sandwich the thermal sensation providing element.

The present disclosure is directed toward a control system for controlling a heater system. The control system includes a plurality of zone control circuits, at least two auxiliary controllers, and a primary controller. The zone control circuits are operable to provide power to a plurality of heater zones of the heater system and to sense performance characteristics of the zones. The auxiliary controllers are coupled to the plurality of zone control circuits to control power to the plurality of zones and to monitor operation of the heater zones based on the performance characteristics. The primary controller is coupled to the auxiliary controllers and is configured to provide an operation set-point for each of the heater zones based on the performance characteristics. The auxiliary controllers operate the zone control circuits to supply power to the heater system based on the operation set-point.

According to various embodiments, a MEMS device includes a substrate, an electrically movable heating element having a first node coupled to a first terminal of a first voltage source and the second node coupled to a reference voltage source, a first anchor anchoring the first node and a second anchor anchoring the second node of the electrically movable heating element to the substrate, and a cavity between the first anchor and the second anchor and between the electrically movable heating element and the substrate.

According to various embodiments, a MEMS device includes a substrate, an electrically movable heating element having a first node coupled to a first terminal of a first voltage source and the second node coupled to a reference voltage source, a first anchor anchoring the first node and a second anchor anchoring the second node of the electrically movable heating element to the substrate, and a cavity between the first anchor and the second anchor and between the electrically movable heating element and the substrate.

A method for controlling a temperature of a heating element can include: measuring a temperature of the heating element using a temperature sensor; estimating a temperature of the heating element based on a heat transfer model of the heating element; calculating a variation of the estimated temperature and a variation of the measured temperature; and determining whether a failure of the temperature sensor occurs based on the calculated variation of the estimated temperature and the calculated variation of the measured temperature.

A temperature control apparatus includes a heater of which a temperature increases in response to receiving power, a power source supplying alternating current (AC) power to the heater, a temperature sensor sensing the temperature of the heater and outputting a measured temperature value, and a controller controlling the power supply to the heater so that the heater follows a set temperature profile, wherein the controller supplies the power to the heater for first one control period in a variable period consisting of a plurality number of times of control periods (on duty), and stops the power supply to the heater during remaining control periods until the variable period is finished (off duty).

The present invention relates to a snow removing apparatus of an LED traffic signal light. More specifically, the present invention relates to a snow removing apparatus of an LED traffic signal light which detects snow accumulated on the lens of a traffic signal light and heats heating coils installed in the lens to remove snow.

The present invention, to achieve this purpose, is equipped with an infra-red emitting unit; an infra-red receiving unit that is installed inside a lens and receives infra-red reflected from the infra-red emitting unit; a CDS sensor installed inside a lens and which measures visible light to compensate the emitting output of the infra-red emitting unit, and; a heater that is installed in the lens and which is supplied power to generate heat, and is characterized in that the lens has a gentle curvature, with ceramic-coated coil securing grooves formed on the inside of the lens along its inside surface, with heater coils installed by inserting in the coil securing grooves.

We disclose herein an environmental sensor system comprising an environmental sensor comprising a first heater and a second heater in which the first heater is configured to consume a lower power compared to the second heater. The system also comprises a controller coupled with the environmental sensor. The controller is configured to detect if a measured value of a targeted environmental parameter is present. The controller is configured to switch on at least one of the first and second heaters based on the presence and/or result of the measured value of the targeted environmental parameter.

An anti-condensing system includes a control panel configured to electrically couple between a power source and a temperature regulating display unit. The control panel includes a housing defining an interior cavity, a door selectively repositionable to facilitate accessing the interior cavity of the housing, and a circuitry assembly disposed within the interior cavity. The circuitry assembly includes a relay configured to couple to a heating element of the temperature regulating display unit, an overcurrent protection breaker coupled to the relay and directly integrated into the control panel such that the overcurrent protection device can be locked out at the control panel, and a control circuit coupled to the relay. The control circuit is configured to actively control the relay to prevent condensation from forming on the temperature regulating display unit.

The present inventive disclosures are generally directed to an improved means to precisely measure temperature at a location remote from a central controller and a means to control heater and/or cooler power at that remote location with a temperature setpoint that is adjustable at the central-controller location, with a remote device/unit connected to the central controller using no more than two wires, employing specialized time-sliced alternating operating modes via those two wires in which high-accuracy current-based temperature readings are transmitted back to a central controller in one mode, and thermal-device power is provided in the other mode. The improved system is, as a result, both very cost-efficient and mass-efficient for controlling a multitude of thermal zones.