A current detection circuit can include: a detection power switch coupled to a power switch to be detected; a current control circuit configured to control voltages of power terminals of the detection power switch in order to generate a detection current flowing through the detection power switch when the power switch is on; and where a flowing direction of the detection current is consistent with a flowing direction of a current flowing through the power switch.

An arrangement includes a conductor, forming the primary side of a transformer, the secondary side being connected to a rectifier circuit. The rectifier output is connected to a voltage stabilizing circuit for an electronic unit and to a first series circuit formed by a first switching component and a first resistor. In the event of a first voltage value being reached at the first input of the voltage stabilizing circuit, the first switching component is switched to be conductive. The secondary current of the transformer flows via the first resistor to drop an electrical voltage across the first resistor. The electric current of conductor is determinable from the voltage. The use of just one transformer used both for energy generation and for current measurement makes it possible to realize a very compact and small design of a current measuring device having a simple construction.

An apparatus for diagnosing a relay driving circuit includes a sensing unit configured to measure a first measured voltage, a second measured voltage and a third measured voltage respectively applied to one end of the first switch, one end of the second switch and one end of the third switch; and a processor operably coupled to the sensing unit. The processor controls operation states of the first switch, the second switch and the third switch and diagnoses whether the relay driving circuit has a fault based on at least one of the first measured voltage, the second measured voltage and the third measured voltage measured by the sensing unit in a state where a diagnosing circuit is formed by controlling the operation states.

A bidirectional flat clamp device includes a first device node and a second device node. The bidirectional flat clamp device also includes a first switch and a second switch coupled in series between the first and second device nodes. The bidirectional flat clamp device also includes at least one switch driver coupled to the first and second switches. The bidirectional flat clamp device also includes a first current path between the first and second device nodes, the first current path having a first diode, a voltage sensor circuit, and a second diode. The bidirectional flat clamp device also includes a second current path between the first and second device nodes, the second current path having a third diode, the voltage sensor circuit, and a fourth diode.

HVAC components having improved efficiency are described. In one embodiment, excessive sleep current draw in a battery-powered device having a microcontroller is detected by measuring a voltage drop across a MOSFET device coupled in a forward-conducting orientation in series between the battery and the microcontroller, causing a transistor to conduct when the voltage drop exceeds a predetermined threshold to generate a first trigger signal, integrating the first trigger signal to generate a second trigger signal, and generating an interrupt to the microcontroller. In another embodiment, a battery-saving method of operating an HVAC component includes maintaining the HVAC device in the sleep mode, receiving a user input to wake the device, transmitting a data request and returning the HVAC component to the sleep mode, waking up the HVAC device to poll an adjacent network node storing a cached response, displaying the response, and returning the HVAC device to sleep.

An integrated circuit includes an H-bridge circuit having a first output node for coupling to a high-side terminal of an inductor and a second output node for coupling to a low-side terminal of the inductor. A current source is coupled in series with a current sense FET between a digital upper supply voltage and the first output node, wherein during a fast decay mode, a gate of the current sense FET is coupled to be turned on. A current-sense comparator includes a first input coupled to a sensing node between the current source and the current sense FET, a second input coupled to the lower supply voltage and an output coupled to a driver control circuit.

According to one embodiment, a current detecting circuit includes: a normally-ON type first switching element that includes a drain, a source, and a gate; a normally-OFF type second switching element including a drain that is connected to the source of the first switching element, a source that is connected to the gate of the first switching element, and a gate; and a differential amplification circuit that outputs a voltage according to a voltage between the drain and the source of the second switching element.

A power glitch signal detection circuit, a security chip and an electronic apparatus are disclosed. The power glitch signal detection circuit includes a voltage sampling module, wherein the voltage sampling module includes: a first metal oxide semiconductor MOS transistor and a capacitor for sampling a power supply voltage, wherein a gate terminal of the first MOS transistor is connected to the capacitor, a source terminal of the first MOS transistor is connected to a ground voltage. The power glitch signal detection circuit further comprises a second MOS transistor and a signal output module. One terminal of the second MOS transistor is connected to a gate terminal of the first MOS transistor, another terminal of the second MOS transistor is connected to the power supply voltage, and a drain terminal of the second MOS transistor is connected to a drain terminal of the first MOS transistor.

An IC is provided. The IC includes a power grid including M.sub.x layer interconnects extending in a first direction on an M.sub.x layer and M.sub.x+1 layer interconnects extending in a second direction orthogonal to the first direction on an M.sub.x+1 layer, where x>5. In addition, the IC includes a plurality of power switches. Further, the IC includes at least one sensing element located between the M.sub.x layer and the M.sub.x+1 layer and configured to measure a voltage drop to devices powered by the plurality of power switches. The one or more of the plurality of power switches may be located below the power grid. The power switches of the plurality of power switches may be adjacent in the first direction and in the second direction to each sensing element of the at least one sensing element.

A power detection circuit is provided. The power detection circuit includes a comparator circuit operative to generate an output signal in response to an input signal. The output signal is configured to change from a first value to a second value in response to the input signal attaining a first threshold value. The output signal is configured to change from the second value to the first value in response to the input signal subsequently attaining a second threshold value. A current limiting circuit is connected to the comparator circuit and operative to limit a leakage current of the comparator circuit.