A temperature control method for vehicle seat heating includes: when turning on or switching to a heating level, determining a heating period at present according to a temperature value corresponding to a current Negative Temperature Coefficient (NTC) sensor, the heating period including an initial heating stage, an approaching stage and a steady stage; and segmentally controlling the on-off of a seat heating apparatus according to a heating strategy corresponding to each heating period, so that the seat surface temperature reaches to and stabilizes at an expected target temperature of the level. Further disclosed are a corresponding temperature control apparatus for the vehicle seat heating and a temperature control system for the vehicle seat heating. By adopting the temperature control method for the vehicle seat heating, the seat surface temperature can quickly reach to and stabilize at the expected temperature value, and thus the use experience of a user is improved.

A circuit device that is connected to a temperature detection element that detects a temperature of an object via an external signal line and an external signal ground line includes a connector that is connected to the external signal line and the external signal ground line, an internal signal line that is connected to the external signal line via the connector, an internal signal ground line that is connected to the external signal ground line via the connector, a controlling circuit that is connected to the internal signal line and the internal signal ground line and detects the temperature of the object, and a high-frequency filter that is inserted into at least one of a foremost stage of the internal signal line and a foremost stage of the internal signal ground line as viewed from the connector.

A circuit device that is connected to a temperature detection element that detects a temperature of an object via an external signal line and an external signal ground line includes a connector that is connected to the external signal line and the external signal ground line, an internal signal line that is connected to the external signal line via the connector, an internal signal ground line that is connected to the external signal ground line via the connector, a controlling circuit that is connected to the internal signal line and the internal signal ground line and detects the temperature of the object, and a high-frequency filter that is inserted into at least one of a foremost stage of the internal signal line and a foremost stage of the internal signal ground line as viewed from the connector.

A device comprises a plurality of temperature sensing elements and a control module. The plurality of temperature sensing elements are each arranged proximal to a respective current carrying blade of an electrical plug. The control module receives, from the plurality of temperature sensing elements, a plurality of temperature signals that each indicate a temperature associated with the respective current carrying blades of the electrical plug. The control module also determines a temperature condition of the electrical plug based on the plurality of temperature signals. The control module also communicates an indication of the temperature condition of the electrical plug via an electrical power carrying conductor that supplies electrical power via the electrical plug.

A device comprises a plurality of temperature sensing elements and a control module. The plurality of temperature sensing elements are each arranged proximal to a respective current carrying blade of an electrical plug. The control module receives, from the plurality of temperature sensing elements, a plurality of temperature signals that each indicate a temperature associated with the respective current carrying blades of the electrical plug. The control module also determines a temperature condition of the electrical plug based on the plurality of temperature signals. The control module also communicates an indication of the temperature condition of the electrical plug via an electrical power carrying conductor that supplies electrical power via the electrical plug.

A switch diagnosing apparatus and method capable of effectively diagnosing a charging switch and a discharging switch provided to a battery pack. It is possible to effectively diagnose the state of a switch as at least one of a normal state, an open stuck state, a closed stuck state and a drift state, thereby improving the diagnosing efficiency.

A switch diagnosing apparatus and method capable of effectively diagnosing a charging switch and a discharging switch provided to a battery pack. It is possible to effectively diagnose the state of a switch as at least one of a normal state, an open stuck state, a closed stuck state and a drift state, thereby improving the diagnosing efficiency.

A multi-configuration electronic thermometer operates in any of a plurality of modes, including a rectal mode, an underarm mode and an oral mode. A probe arm swings about an axis that is located closer to one end of an elongate thermometer body than it is to the other end. In a first, rectal configuration, only a limited length of the probe arm extends beyond a front end of the thermometer body. In a second configuration, the probe arm is swung to a position such that its free end is farther from a second end of the body than it was from the first end while in the first configuration. The probe arm is spring-loaded to lock to a user-selected one of the configurations and is torsionally biased to the more compact, first configuration. Different sensing algorithms are used depending on the mode selected.

A multi-configuration electronic thermometer operates in any of a plurality of modes, including a rectal mode, an underarm mode and an oral mode. A probe arm swings about an axis that is located closer to one end of an elongate thermometer body than it is to the other end. In a first, rectal configuration, only a limited length of the probe arm extends beyond a front end of the thermometer body. In a second configuration, the probe arm is swung to a position such that its free end is farther from a second end of the body than it was from the first end while in the first configuration. The probe arm is spring-loaded to lock to a user-selected one of the configurations and is torsionally biased to the more compact, first configuration. Different sensing algorithms are used depending on the mode selected.

A temperature sensor (116) comprises an electrical circuit (204) including a thermistor (206) intended to be placed next to an object (112); a temperature measurement module (222) configured for determining a measured temperature (T_M) of the thermistor (206) from a resistance of the thermistor (206); and a command module (224) configured for providing a command (C) to the electrical circuit (204) for modifying the electrical circuit (204) in a way that changes a current (IT) flowing in the thermistor (206). The temperature sensor (116) further comprises a thermal loss determination module (226) configured for determining a thermal loss (L) of the thermistor (206) from the thermistor measured temperature (T_M) and the command (C); and a temperature estimation module (228) configured for estimating a temperature (T0_E) of the object (112) from the thermistor measured temperature (T_M) and from the thermal loss (L) of the thermistor (TH).