Abstract: An apparatus for voltage regulation device adjustment includes an external factor module that determines external factors, where the external factors include conditions external to an electronic device that affect operating performance and operating costs. The electronic device includes a voltage regulator device (“VRD”) providing power to one or more components of the electronic device. The apparatus includes a firmware selection module that selects new firmware for the VRD of the electronic device in response to the determined external factors, and a firmware update module that replaces previously installed firmware on the VRD with the new firmware. The new firmware includes control settings for the VRD.

Abstract: An apparatus for voltage regulation device adjustment includes an external factor module that determines external factors, where the external factors include conditions external to an electronic device that affect operating performance and operating costs. The electronic device includes a voltage regulator device (“VRD”) providing power to one or more components of the electronic device. The apparatus includes a firmware selection module that selects new firmware for the VRD of the electronic device in response to the determined external factors, and a firmware update module that replaces previously installed firmware on the VRD with the new firmware. The new firmware includes control settings for the VRD.

Abstract: A method of controlling the inrush current to a hot plug device. The method includes directing current from an input power rail of the hot plug device to an output power rail of the hot plug device through a high impedance auxiliary current path, wherein an electronic subsystem of the hot plug device is coupled to the output power rail. The method further includes allowing current from the input power rail 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 that exceeds a voltage threshold as a result of directing current through the high impedance auxiliary current path.

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: A DC-DC converter includes a directly coupled inductor with coil elements and power-switching phases. Each phase includes a high-side and low-side switch, where the high-side switch couples a voltage source to a coil element and the low-side switch couples the coil element to a ground voltage. Each switch is configured to be alternately activated and no two switches are activated at the same time. A current sensor for the DC-DC converter includes a single current amplifier having inputs and an output. The output provides a current sensing signal. The current sensor also includes a single RC network coupled to one of the power-switching phases and a first input of the current amplifier. The current sensor also includes a resistive ladder. The ladder includes, for each of the other power-switching phases, a resistor coupled in parallel to the RC network resistor and to a second input of the current amplifier.

Abstract: A DC-DC converter includes a directly coupled inductor with coil elements and power-switching phases. Each phase includes a high-side and low-side switch, where the high-side switch couples a voltage source to a coil element and the low-side switch couples the coil element to a ground voltage. Each switch is configured to be alternately activated and no two switches are activated at the same time. A current sensor for the DC-DC converter includes a single current amplifier having inputs and an output. The output provides a current sensing signal. The current sensor also includes a single RC network coupled to one of the power-switching phases and a first input of the current amplifier. The current sensor also includes a resistive ladder. The ladder includes, for each of the other power-switching phases, a resistor coupled in parallel to the RC network resistor and to a second input of the current amplifier.

Abstract: A protection circuit or electronic circuit breaker protects and supplies power to a device load. The protection circuit includes a current mirror, a reference load that models the device load, and a comparator circuit that outputs a signal indicating that a fault has been detected in the device load during turn on. The current mirror provides an amount of current in proportion to the current supplied to the device load. The same proportion is used to calculate the capacitance and resistance of the reference load. Accordingly, if the device load has no fault, the reference voltage remains proportional to the output voltage to the device load. However, if the device load has a fault, the reference voltage will increase faster than the output voltage such that the comparator will generate a fault signal that turns off a transistor pass element that was supplying current to the device load.

Abstract: A method for controlling a voltage regulator includes monitoring an output current and an inductance of an output inductor in a voltage regulator, wherein the voltage regulator includes high-side and low-side field effect transistors both coupled to an input to the first output inductor. The high-side and low-side field-effect transistors are alternately turned on at a switching frequency, wherein only one of the field-effect transistors is turned on at a time. The method measures a change in the inductance of the output inductor resulting from the output inductor reaching current saturation and measures a rate of change in the output current of the output inductor. The switching frequency is controlled as a function of the measured change in the inductance and the measured rate of change in the output current in order to prevent an amount of current through the high-side field-effect transistor from exceeding a maximum operating current setpoint.

Abstract: A protection circuit or electronic circuit breaker protects and supplies power to a device load. The protection circuit includes a current mirror, a reference load that models the device load, and a comparator circuit that outputs a signal indicating that a fault has been detected in the device load during turn on. The current minor provides an amount of current in proportion to the current supplied to the device load. The same proportion is used to calculate the capacitance and resistance of the reference load. Accordingly, if the device load has no fault, the reference voltage remains proportional to the output voltage to the device load. However, if the device load has a fault, the reference voltage will increase faster than the output voltage such that the comparator will generate a fault signal that turns off a transistor pass element that was supplying current to the device load.

Abstract: Dividing a single phase PWM signal into a plurality of phases includes: receiving, from a phase controller by a PWM frequency divider, an input pulse train comprising a period; and dividing, by the PWM frequency divider, the input pulse train amongst a plurality of output phases of the PWM frequency divider, including, at the onset of each period of the input pulse train: providing, on a next output phase of the PWM frequency divider, an output pulse train; and holding all other output phases at a tri-state voltage level.

Abstract: A computer planar includes an enable signal line for providing an enable signal to an external power supply, wherein the external power supply will not turn on unless the enable signal is active high. During normal operation, an auxiliary power source maintains an active high enable signal on the enable signal line, which includes a fuse. However, a fault protection circuit coupled to the enable signal line can pull down the enable signal line in response to a fault, such that the fuse is permanently opened. Once the fuse is open, the external power supply cannot be enabled and further damage to the computer planar is prevented.

Abstract: A method for controlling the in-rush current to a 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: Dividing a single phase PWM signal into a plurality of phases includes: receiving, from a phase controller by a PWM frequency divider, an input pulse train comprising a period; and dividing, by the PWM frequency divider, the input pulse train amongst a plurality of output phases of the PWM frequency divider, including, at the onset of each period of the input pulse train: providing, on a next output phase of the PWM frequency divider, an output pulse train; and holding all other output phases at a tri-state voltage level.

Abstract: A computer program product for controlling the in rush current to a hot plug device. The computer program product includes program instructions that cause a processor to perform a method. 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: 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 toroidal 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: 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: A DC-DC converter includes power-switching phases which each include a high-side and low-side switch. The high-side switch is coupled to the low-side switch at a connection node. The converter also includes a coupled inductor formed of a magnetic core and a conductive sheet. The sheet is formed of a comb structure having a tab and teeth extending from the tab. The conductive sheet is inserted into a slot defined by the magnetic core and extends through the magnetic core with a portion of the tab protruding from the back and a portion of each tooth protruding from the front of the core. Each tooth is coupled to a connection node of a phase and the tab extending through the core forms a toroidal inductor with a single loop coil for each phase, and for all the phases, a directly coupled inductor.

Abstract: A method of controlling the inrush current to a hot plug device. The method includes directing current from an input power rail of the hot plug device to an output power rail of the hot plug device through a high impedance auxiliary current path, wherein an electronic subsystem of the hot plug device is coupled to the output power rail. The method further includes allowing current from the input power rail 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 that exceeds a voltage threshold as a result of directing current through the high impedance auxiliary current path.

Abstract: A method for controlling the in-rush current to a 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 computer planar includes an enable signal line for providing an enable signal to an external power supply, wherein the external power supply will not turn on unless the enable signal is active high. During normal operation, an auxiliary power source maintains an active high enable signal on the enable signal line, which includes a fuse. However, a fault protection circuit coupled to the enable signal line can pull down the enable signal line in response to a fault, such that the fuse is permanently opened. Once the fuse is open, the external power supply cannot be enabled and further damage to the computer planar is prevented.