Abstract: A method control the in rush current to the hot plug device. The method includes providing a series of turn on pulses to the gates of a plurality of turn on FETs on a hot plug device coupled to a direct current power source, wherein each pulse causes the plurality of FETs to pass current from the direct current power source to a subsystem of the hot plug device, and wherein each pulse has a duration that ends before the impedance of the turn on FETs falls below a safe operating region. The method further includes providing a steady turn on signal to the FETs in response to the output voltage from the FETs to a subsystem of the hot plug device exceeding a predetermined voltage threshold.

Abstract: A hot plug device includes an electronic subsystem and a plurality of main turn on FETs, wherein each main turn on FET includes a gate, a power input for coupling to a power source, and an output for controllably providing power to the electronic subsystem. An auxiliary current path is in parallel with the main turn on FETs and includes a fuse, an impedance element and an auxiliary turn on FET. A turn on controller controls the main turn on FETs and the auxiliary turn on FET. Current is initially through the high impedance auxiliary current path to apply voltage to an output power rail. Subsequently, current is allowed to pass through a plurality of main turn on FETs to the output power rail in response to the output power rail having a voltage exceeding a voltage threshold as a result of using the high impedance auxiliary current path.

Abstract: Managing power modes of a computing system that includes a power supply and computing components, the power supply configured to supply power, through power supply channels, to the computing components, wherein power modes are managed by: operating the computing system in a performance power mode, including allowing each power channel to consume power greater than a predefined maximum power consumption threshold; receiving a signal representing a user's access to the computing components; and operating the computing system in a safety mode, insuring that each of the power supply channels does not consume power greater than the predefined maximum power consumption threshold, including: throttling power consumption of one or more of the computing components; monitoring power consumption of each power supply channel; and shutting down the computing system when at least one power supply channel consumes power greater than the predefined maximum power consumption threshold.

Abstract: Manufacturing a DC-DC converter on a chip includes: providing a die having a p-type top side and an n-type bottom side; removing an interior portion, creating a hole; flipping the interior portion; inserting the interior portion into the hole; fabricating high-side switch cells in the interior portion's top side and low-side switch cells in the exterior portion's top side; sputtering a magnetic material on the entire top side; burrowing tunnels into the magnetic material; and applying conductive material on the magnetic material and within the tunnels, electrically coupling pairs of high-side and low-side switches, with each pair forming a micro-power-switching phase, where the conductive material forms an output node of the phase, and the conductive material in the burrowed tunnels forms, in each phase, a torodial inductor with a single loop coil and, for the plurality of phases, a directly coupled inductor.

Abstract: Manufacturing a DC-DC converter on a chip includes: providing a die having a p-type top side and an n-type bottom side; removing an interior portion, creating a hole; flipping the interior portion; inserting the interior portion into the hole; fabricating high-side switch cells in the interior portion's top side and low-side switch cells in the exterior portion's top side; sputtering a magnetic material on the entire top side; burrowing tunnels into the magnetic material; and applying conductive material on the magnetic material and within the tunnels, electrically coupling pairs of high-side and low-side switches, with each pair forming a micro-power-switching phase, where the conductive material forms an output node of the phase, and the conductive material in the burrowed tunnels forms, in each phase, a torodial inductor with a single loop coil and, for the plurality of phases, a directly coupled inductor.

Abstract: Operating a DC-DC converter that includes: a directly coupled inductor with a first and second coil element, the first and second coil element coupled to an output filter and a load; and power-switching phases, including: a first power-switching phase that includes a high-side and low-side switch, where the high-side switch is configured, when activated, to couple a voltage source to the first coil element and the low-side switch is configured, when activated, to couple the first coil element to a ground voltage; and a second power-switching phase that includes a high-side and low-side switch, where the high-side switch is configured, when activated, to couple the voltage source to the second coil element and the low-side switch is configured, when activated, to couple the second coil element to the ground voltage; and the switches are activated alternatively with no two switches are activated at the same time.

Abstract: A direct current-to-direct current (‘DC/DC’) converter for delivering a load to an electrical component, the DC/DC converter including: a coupled inductor, wherein the coupled inductor receives a source input voltage level and a outputs an output voltage level; a transient winding; and a variable impedance switch coupled to the transient winding, the variable impedance switch configured to operate by adjusting a delivered resistance level in dependence upon a change in the load to be delivered to the electrical component by the DC/DC converter.

Abstract: A direct current-to-direct current (‘DC/DC’) converter for delivering a load to an electrical component, the DC/DC converter including: a coupled inductor, wherein the coupled inductor receives a source input voltage level and a outputs an output voltage level; a transient winding; and a variable impedance switch coupled to the transient winding, the variable impedance switch configured to operate by adjusting a delivered resistance level in dependence upon a change in the load to be delivered to the electrical component by the DC/DC converter.

Abstract: A circuit arrangement includes a transformer, having primary windings and secondary windings, and a high voltage capacitor. A first switching circuit couples the high voltage capacitor to the primary windings. A first controller is operatively coupled to the switching circuit. A second switching circuit couples the secondary windings to an output port. A second controller is operatively coupled to the secondary windings. A high voltage generator is provided to charge the high voltage capacitor.

Abstract: A direct current-to-direct current (‘DC/DC’) converter for delivering a load to an electrical component, the DC/DC converter including: a coupled inductor, wherein the coupled inductor receives a source input voltage level and a outputs an output voltage level; a transient winding; and a variable impedance switch coupled to the transient winding, the variable impedance switch configured to operate by adjusting a delivered resistance level in dependence upon a change in the load to be delivered to the electrical component by the DC/DC converter.

Abstract: A direct current-to-direct current (‘DC/DC’) converter for delivering a load to an electrical component, the DC/DC converter including: a coupled inductor, wherein the coupled inductor receives a source input voltage level and a outputs an output voltage level; a transient winding; and a variable impedance switch coupled to the transient winding, the variable impedance switch configured to operate by adjusting a delivered resistance level in dependence upon a change in the load to be delivered to the electrical component by the DC/DC converter.

Abstract: A circuit arrangement includes a transformer, having primary windings and secondary windings, and a high voltage capacitor. A first switching circuit couples the high voltage capacitor to the primary windings. A first controller is operatively coupled to the switching circuit. A second switching circuit couples the secondary windings to an output port. A second controller is operatively coupled to the secondary windings. A high voltage generator is provided to charge the high voltage capacitor.

Abstract: Operating a DC-DC converter on a chip that includes: micro-power-switching phases and magnetic material, each phase including: a high-side and low-side switch with control inputs for activating the switch, and an output node; where: the output node of each phase extrudes through the magnetic material to form, in each phase, a torodial inductor with a single loop coil, and to form, for the plurality of phases, a directly coupled inductor; the output node of each micro-power-switching phase is coupled to a filter and a load; each high-side switch is configured, when activated, to couple a voltage source to the phase's single loop coil; and the low-side switch of each phase is configured, when activated, to couple the phase's single loop coil to a ground voltage and the switches are alternatively activated where no two switches of any phase are activated at the same time.

Abstract: Operating a DC-DC converter that includes: a directly coupled inductor with a first and second coil element, the first and second coil element coupled to an output filter and a load; and power-switching phases, including: a first power-switching phase that includes a high-side and low-side switch, where the high-side switch is configured, when activated, to couple a voltage source to the first coil element and the low-side switch is configured, when activated, to couple the first coil element to a ground voltage; and a second power-switching phase that includes a high-side and low-side switch, where the high-side switch is configured, when activated, to couple the voltage source to the second coil element and the low-side switch is configured, when activated, to couple the second coil element to the ground voltage; and the switches are activated alternatively with no two switches are activated at the same time.

Abstract: A bus bar distributes power to a plurality of electronic components supported on a printed circuit board. One embodiment of the bus bar comprises a plurality of compressible contact pads made from an electronically conductive polymer, spaced along the bus bar for contacting conductive contacts that are coupled to a power domain or individual electronic component. The pads may be secured to the bus bar and the conductive traces using an electronically conductive epoxy adhesive. Rivets may then be used to secure the bus bar to the printed circuit board and compress the pads, which conform to the printed circuit board to make a reliable electrical connection with the conductive traces. The bus bar further comprises a plurality of current sense points disposed adjacent to the pads for measuring the amount of current provided to each power domain.

Abstract: A bus bar distributes power to a plurality of electronic components supported on a printed circuit board. One embodiment of the bus bar comprises a plurality of compressible contact pads made from an electronically conductive polymer, spaced along the bus bar for contacting conductive contacts that are coupled to a power domain or individual electronic component. The pads may be secured to the bus bar and the conductive traces using an electronically conductive epoxy adhesive. Rivets may then be used to secure the bus bar to the printed circuit board and compress the pads, which conform to the printed circuit board to make a reliable electrical connection with the conductive traces. The bus bar further comprises a plurality of current sense points disposed adjacent to the pads for measuring the amount of current provided to each power domain.

Abstract: Managing power modes of a computing system that includes a power supply and computing components, the power supply configured to supply power, through power supply channels, to the computing components, wherein power modes are managed by: operating the computing system in a performance power mode, including allowing each power channel to consume power greater than a predefined maximum power consumption threshold; receiving a signal representing a user's access to the computing components; and operating the computing system in a safety mode, insuring that each of the power supply channels does not consume power greater than the predefined maximum power consumption threshold, including: throttling power consumption of one or more of the computing components; monitoring power consumption of each power supply channel; and shutting down the computing system when at least one power supply channel consumes power greater than the predefined maximum power consumption threshold.