Abstract: A circuit includes a transistor, a first driver, a second driver, and a delay circuit. The transistor includes an array of transistor cells partitioned into a first switch and a second switch. The first driver is configured to control the first switch. The second driver is configured to control the second switch. The delay circuit is coupled between the first driver and the second driver. The delay circuit is configured to delay closure of the second switch until the first switch is closed and a voltage across the first switch is less than a predetermined voltage.

Abstract: Described embodiments include a voltage clamping circuit having a threshold-setting circuit with a threshold input and a threshold output. A switch has a first terminal coupled to the threshold input, a second switch terminal, and a switch control terminal. A first transistor is coupled between the threshold output and the switch control terminal, and has a first control terminal. A second transistor is coupled between the first control terminal and ground, and has a second control terminal. A first driver circuit has a first driver input and a first driver output. A second driver circuit has a second driver input coupled to the first driver input, and a second driver output. A third transistor is coupled between the threshold input and ground, and has a third control terminal that is coupled to the second control terminal and the second switch terminal.

Abstract: A packaged integrated circuit (IC) includes a package substrate, an electronic device on the package substrate, and metal interconnects coupled between the electronic device and the package substrate. The packaged IC also includes an insulation material on the package substrate and encapsulating the electronic device. The insulation material surrounds the metal interconnects. An inductor is over the electronic device and is coupled to the package substrate. A magnetic material is on the insulation material and encapsulates the inductor. The magnetic material is different from the insulation material.

Abstract: Described embodiments include a gate drive circuit with a first transistor coupled between an input voltage terminal and a switching terminal, and having a first control terminal. A second transistor is coupled between the switching terminal and ground, and has a second control terminal. A first driver circuit has a first driver output coupled to the first control terminal, a first positive supply input coupled to a bootstrap voltage terminal, and a first negative supply input coupled to the switching terminal. A second driver circuit has a second driver output coupled to the second control terminal, a second positive supply input coupled to a driver supply, and a first negative supply input coupled to ground. An active clamp circuit is coupled between the driver supply and ground, and prevents a voltage between the driver supply and ground from exceeding a threshold voltage.

Abstract: An integrated circuit is provided which comprises a transistor and a driver coupled to a gate of the transistor. In at least one example, the driver controls an operation of the transistor, wherein the driver is operable in a first configuration as a low-side gate driver for a voltage regulator, and wherein the transistor is operable in the first configuration as a low-side switch for the voltage regulator. In at least one example, the driver is operable in a second configuration as a high-side gate driver for the voltage regulator, and wherein the transistor is operable in the second configuration as a high-side switch for the voltage regulator.

Abstract: A circuit includes a transistor, a first driver, a second driver, and a delay circuit. The transistor includes an array of transistor cells partitioned into a first switch and a second switch. The first driver is configured to control the first switch. The second driver is configured to control the second switch. The delay circuit is coupled between the first driver and the second driver. The delay circuit is configured to delay closure of the second switch until the first switch is closed and a voltage across the first switch is less than a predetermined voltage.

Abstract: An adaptive clamp circuit includes a clamp circuit and a clamp control circuit. The clamp circuit includes a first transistor, a second transistor, and a variable resistor. The first transistor includes a first current terminal, a second current terminal, and a control terminal. The first current terminal is coupled to a switching terminal. The second current terminal is coupled to a ground terminal. The second transistor includes a first current terminal, a second current terminal, and a control terminal. The first current terminal of the second transistor is coupled to the control terminal of the first transistor. The second current terminal of the second transistor is coupled to the switching terminal. The variable resistor is coupled between the control terminal of the second transistor and the ground terminal. The clamp control circuit is coupled between the switching terminal and the variable resistor.

Abstract: An adaptive clamp circuit includes a clamp circuit and a clamp control circuit. The clamp circuit includes a first transistor, a second transistor, and a variable resistor. The first transistor includes a first current terminal, a second current terminal, and a control terminal. The first current terminal is coupled to a switching terminal. The second current terminal is coupled to a ground terminal. The second transistor includes a first current terminal, a second current terminal, and a control terminal. The first current terminal of the second transistor is coupled to the control terminal of the first transistor. The second current terminal of the second transistor is coupled to the switching terminal. The variable resistor is coupled between the control terminal of the second transistor and the ground terminal. The clamp control circuit is coupled between the switching terminal and the variable resistor.

Abstract: A voltage converter includes a switch network, a rectifier, and a transformer coupled between the switch network and the rectifier. The voltage converter includes an adaptive ON-time generation circuit having a control input and a control output, the control input. The adaptive ON-time generation circuit is configured to receive a WAKE signal to turn ON the switch network, generate a signal indicative of an OFF time of the switch network, and determine an ON time for the switch network based on the signal indicative of the OFF time.

Abstract: In described examples of a ramp circuit, a first terminal of a capacitor is coupled to a ramp terminal and a second capacitor terminal is coupled to a return terminal. A charge source has an input terminal coupled to a supply terminal and a charge output terminal. A resistor has a first terminal coupled to the return terminal. A first switch is coupled between the ramp terminal and a second terminal of the resistor. A second switch is coupled between the charge output terminal and the ramp terminal.

Abstract: A rectifier circuit includes a first diode-connected transistor coupled to a first voltage terminal and a second diode-connected transistor coupled to a second voltage terminal. A switch network is coupled between the first diode-connected transistor and the second diode-connected transistor. The switch network has a first switch network terminal adapted to be coupled to a first terminal of a secondary winding of a transformer and has a second switch network terminal adapted to be coupled to a second terminal of the secondary winding of the transformer.

Abstract: An apparatus includes a direct-current to direct-current (DC-DC) converter having an output terminal and at least one electronic switch. The DC-DC converter also includes: 1) a first feedback loop configured to control a voltage at the output terminal by adjusting a first switching parameter of the at least one electronic switch; and 2) a second feedback loop configured to adjust a second switching parameter of the at least one electronic switch. The second feedback loop includes a switched-capacitor circuit configured to determine a threshold signal based on an error between a reference signal and a control signal for the at least one electronic switch. The second feedback loop is configured to adjust the second switching parameter based on a comparison of an on-time signal with the threshold signal.

Abstract: An apparatus includes a direct-current to direct-current (DC-DC) converter having an output terminal and at least one electronic switch. The DC-DC converter also includes: 1) a first feedback loop configured to control a voltage at the output terminal by adjusting a first switching parameter of the at least one electronic switch; and 2) a second feedback loop configured to adjust a second switching parameter of the at least one electronic switch. The second feedback loop includes a switched-capacitor circuit configured to determine a threshold signal based on an error between a reference signal and a control signal for the at least one electronic switch. The second feedback loop is configured to adjust the second switching parameter based on a comparison of an on-time signal with the threshold signal.

Abstract: An apparatus includes a direct-current to direct-current (DC-DC) converter having an output node and at least one electronic switch. The DC-DC converter also includes: 1) a first feedback loop configured to control a voltage at the output node by adjusting a first switching parameter of the at least one electronic switch; and 2) a second feedback loop configured to adjust a second switching parameter of the at least one electronic switch. The second feedback loop includes a switched-capacitor circuit configured to determine a threshold signal based on an error between a reference signal and a control signal for the at least one electronic switch. The second feedback loop is configured to adjust the second switching parameter based on a comparison of an on-time signal with the threshold signal.

Abstract: An apparatus includes a direct-current to direct-current (DC-DC) converter having an output node and at least one electronic switch. The DC-DC converter also includes: 1) a first feedback loop configured to control a voltage at the output node by adjusting a first switching parameter of the at least one electronic switch; and 2) a second feedback loop configured to adjust a second switching parameter of the at least one electronic switch. The second feedback loop includes a switched-capacitor circuit configured to determine a threshold signal based on an error between a reference signal and a control signal for the at least one electronic switch. The second feedback loop is configured to adjust the second switching parameter based on a comparison of an on-time signal with the threshold signal.