In a device that measures biopotentials of cells in a solution, the solution is controlled at a constant temperature. A measurement device includes a substrate, a sensing control circuit, a temperature sensor, a front surface side heat radiating unit, a back surface side heat radiating unit, and a temperature control unit. A plurality of electrodes each detecting a potential in the solution is arranged on the front surface of the substrate. The sensing control circuit is arranged on the substrate and controls detection of potentials at the plurality of electrodes. The temperature sensor is arranged on the substrate and detects a temperature of the solution. The front surface side heat radiating unit is arranged on the front surface side of the substrate and radiates heat. The back surface side heat radiating unit is arranged on the back surface side that is a surface different from the front surface of the substrate, and radiates heat. The temperature control unit controls the temperature of the solution on the basis of the temperature detected by the temperature sensor.

Because the touch temperature of a wearable computing device (“WCD”) may be an insignificant factor for user experience when the WCD is not being worn by a user, embodiments of the solution seek to modify thermal management policies based on an inferred user proximity state. Exemplary embodiments monitor one or more signals from readily available sensors in the WCD that have primary purposes other than measuring user proximity. Depending on embodiment, the sensors may be selected from a group consisting of a heart rate monitor, a pulse monitor, an O2 sensor, a bio-impedance sensor, a gyroscope, an accelerometer, a temperature sensor, a pressure sensor, a capacitive sensor, a resistive sensor and a light sensor. Using the signals generated by such sensors, relative physical proximity of the WCD to a user may be inferred and, based on the user proximity state, thermal policies either relaxed or tightened.

A thermostatic device for a pipeline of a sanitary water supply or dispensing system and including a temperature meter which detects the temperature of the sanitary water entering the thermostatic device, a flow regulator which regulates a rate of sanitary water exiting from the device, and a control unit. The flow regulator operates in a first operating mode and a second operating mode. The first operating mode is a steady-state operating mode. The second operating mode is a steady-state setting operating mode in which the flow rate of sanitary water leaving the thermostatic device is a minimum flow rate. The control unit is configured to acquire, receive and/or calculate a reference temperature and arrange the switching of the operating mode when the temperature meter detects a temperature of the sanitary water greater than the reference temperature.

An ATM device may include an external frame, a touch screen component coupled to the external frame, and a heating element. The heating element may be positioned such that heat generated by the heating element is directed at the touch screen component. The ATM device may include a temperature sensor configured to detect a temperature of an environment of the ATM device, and may receive temperature measurement data from the temperature sensor, process the temperature measurement data after receiving the temperature measurement data, determine whether the temperature measurement data indicates that a current temperature of the environment satisfies a threshold based on processing the temperature measurement data, and perform an action to control an operating state of the heating element based on determining whether the temperature measurement data indicates that the current temperature of the environment satisfies the threshold.

A heating, ventilation and air conditioning (HVAC) controller, a method of detecting multiplexed input signals and an HVAC system employing the controller or the method. In one embodiment, the HVAC controller includes: (1) a signal conditioner configured to convert received alternating current (AC) input signals into corresponding square wave signals of a digital logic voltage, (2) a multiplexer coupled to the signal conditioner and configured to select one of the square wave signals and (3) a sample analyzer coupled to the multiplexer and configured to evaluate multiple samples of the selected one of the square wave signals to derive a binary state.

An intelligent water outlet device includes a water-temperature regulating valve, a water-output control valve, a power source unit, an input unit, a motor drive unit, a first step motor, a second step motor and a control unit. The power source unit energizes the water outlet device. The input unit selects a temperature value for the water output. The motor drive unit drives the first step motor and second step motor, to rotate an adjusting bar of the water-temperature regulating valve and to push a valve bar of the water-output control valve, respectively. The control unit receives a temperature option and an expected water volume from the input unit, and then controls the first step motor and the second step motor to output warm water with the inputted temperature value and the expected water volume.

A method of controlling signal transmission in a building control system including measuring a number of signal values associated with an environmental variable using a sensor of a wireless device, dynamically determining, by the wireless device, a noise threshold based on the number of signal values, combining a first signal value and a second signal value of the number of signal values using a mathematical relationship to determine a result associated with the first signal value and the second signal value, and periodically transmitting the first signal value from the wireless measurement device to a controller in response to the result exceeding the noise threshold.

A computer-implemented method for progressive profiling in a home automation system is described. Data related to a premises and an occupant of the premises may be analyzed and one or more observations may be made based on the analysis of the data. Upon detecting one or more conditions associated with the one or more observations made, an offer to perform one or more actions may be communicated to the occupant.

The present disclosure relates to a heating, ventilation, and air conditioning (HVAC) system including a sensor system configured to detect heat indications within a plurality of areas of a conditioned space, wherein the sensor system comprise a thermal light detector, and a controller configured to receive feedback from the sensor system and, based on the feedback, control airflow distribution, via an airflow distribution system, such that airflow management for each of the plurality of areas is individually correlated to a heat indication detected for the respective area.

A water circulation system having a feed line, a return line, a string that connects the feed line to the return line is disclosed. A temperature control unit connects the feed line to the return line, a consumer, a valve, at least one temperature sensor and a system control. A method is disclosed which includes the steps of determining a first temperature, a second temperature and a lowering time; detecting the water temperature; controlling the first temperature by controlling the valve; and controlling the second temperature by controlling the valve during the lowering time.