An interpolator includes a first delay circuit, a second delay circuit, and a tunable delay circuit. The first delay circuit delays a first input signal for a fixed delay time, so as generate a first output signal. The second delay circuit delays a second input signal for the fixed delay time, so as to generate a second output signal. The tunable delay circuit delays the first input signal for a tunable delay time, so as to generate an output interpolation signal. The tunable delay time is determined according to the first output signal, the second output signal, and the output interpolation signal.

A semiconductor device includes a first transistor, a second transistor, and a third transistor. The first transistor includes a first gate insulator, a first source region and a first drain region, a pair of lightly doped drain (LDD) regions that are each shallower than the first source region and the first drain region, and a first gate electrode. The second transistor includes a second gate insulator, a second source region and a second drain region, a pair of drift regions that encompass the second source region and the second drain region respectively, and a second gate electrode, and the third transistor comprises a third gate insulator, a third source region and a third drain region, and a pair of drift regions that encompass the third source and the third drain regions respectively, and a third gate electrode. The second gate insulator is thinner than the other gate insulators.

In accordance with an embodiment, a method of controlling a switch driver includes energizing a first inductor in a first direction with a first energy; transferring the first energy from the first inductor to a second inductor, wherein the second inductor is coupled between a second switch-driving terminal of the switch driver and a second internal node, and the second inductor is magnetically coupled to the first inductor; asserting a first turn-on signal at the second switch-driving terminal using the transferred first energy; energizing the first inductor in a second direction opposite the first direction with a second energy after asserting the first turn-on signal at the second switch-driving terminal; transferring the second energy from the first inductor to the second inductor; and asserting a first turn-off signal at the second switch-driving terminal using the transferred second energy.

Aspects of the disclosure relate to devices, wireless communication apparatuses, methods, and circuitry for a RF power sensor. One aspect is an apparatus including a power sensor transistor configured to receive a radio frequency (RF) input signal and to generate an output indicative of a power of the RF input signal. The apparatus further includes a current source configured to generate a bias current. Also, the apparatus includes a current mirror, which is formed by the power sensor transistor and a second transistor, configured to provide the bias current to the power sensor transistor. The apparatus further includes a feedback circuit, which is coupled to the power sensor transistor and the second transistor, configured to control a drain current of the second transistor with respect to the bias current.

A waveform conversion circuit for turning a switch device on and off by applying a control signal from a controller to a gate terminal of the switch device is provided. The switch device has the wile terminal, a drain terminal, and a source terminal. The waveform conversion circuit includes a parallel circuit of a first capacitor and a first resistor and a voltage clamp unit. The parallel circuit is coupled between the controller and the gate terminal. The voltage clamp unit is coupled between the gate terminal and the source terminal and configured to clamp a voltage across the gate terminal to the source terminal at a first voltage in an OFF pulse of the control signal and at a second voltage in an ON pulse of the control signal.

According to some aspects, a low-leakage switch is provided. In some embodiments, the low-leakage switch includes a plurality of pass transistors in series that selectively couple two ports of the low-leakage switch and a node biasing circuit coupled to a node between the plurality of pass transistors. In these embodiments, the node biasing circuit may adjust a voltage at the node to change the gate-to-source voltage of the pass transistors and, thereby, reduce the leakage current through the pass transistors when the low-leakage switch is turned off. The node biasing circuit may also include circuitry to reduce the leakage current introduced by the node biasing circuit into the node when the low-leakage switch is turned on.

A semiconductor device includes a hysteresis block configured to generate an output voltage at corresponding disabling enabling voltage levels and a core-voltage-gated (CVG) device configured to receive a core voltage, an input terminal of the hysteresis block is coupled to a control node. The CVG device is configured to alter a control voltage at the control node so as to cause the output voltage of the hysteresis block to be generated at the disabling voltage level in response to the core voltage being at or below a first trigger level. Additionally, the CVG device is configured to alter the control voltage at the control node so as to cause the output voltage of the hysteresis block to be generated at the enabling voltage level in response to the core voltage being at or above a second trigger level, the second trigger level being above the first trigger level.

Provided is a load drive device capable of diagnosing a failure of an output terminal of the load drive device before a charging voltage stabilizes in a configuration in which a capacitor is connected to an output terminal of the load drive device that drives an inductive load. In the load drive device according to the present invention, a capacitor is connected between a load terminal and a ground terminal, and the presence or absence of a failure of the load terminal is diagnosed on the basis of a current flowing between an internal power supply included in a diagnosis circuit and the load terminal.

Provided is a load drive device capable of diagnosing a failure of an output terminal of the load drive device before a charging voltage stabilizes in a configuration in which a capacitor is connected to an output terminal of the load drive device that drives an inductive load. In the load drive device according to the present invention, a capacitor is connected between a load terminal and a ground terminal, and the presence or absence of a failure of the load terminal is diagnosed on the basis of a current flowing between an internal power supply included in a diagnosis circuit and the load terminal.

A regenerative gate charging circuit includes an inductor coupled to a gate of a FET. An output control circuit is coupled to a timing control circuit and a bridged inductor driver, which is coupled to the inductor. A sense circuit is coupled to the gate and to the timing control circuit, which receives a control signal, generates output control signals in accordance with a first timing profile, and transmits the output control signals to the output control circuit. In accordance with the first timing profile, the output control circuit holds switches or controllable current sources of the bridged inductor driver in an ON state for a first period and holds the switches or controllable current sources in an OFF state for a second period. Gate voltages are sampled during the second period and after the first period. The timing control circuit generates a second timing profile using the sampled voltages.