Patent application number | Description | Published |
20080203817 | Power architecture for battery powered remote devices - Systems and methods that may be employed to provide a high-reliability power architecture for an information handling system and a physically separable (i.e., detachable) remote system. The information handling system may be, for example, a portable information handling system such as a notebook computer. The remote system may be, for example, a battery-powered input or input/output device such as a wireless keyboard configured to wirelessly communicate input/output information with the information handling system, and that is also configured to be physically and electrically coupled to the information handling system to allow a flow of current to be provided from circuitry of the information handling system to circuitry of the remote system. The power architecture may be implemented using multiple (e.g., two) Uninterrupted Power System (UPS) buses. | 08-28-2008 |
20080265683 | METHOD AND CIRCUIT TO OUTPUT ADAPTIVE DRIVE VOLTAGES WITHIN INFORMATION HANDLING SYSTEMS - A method and circuit to output adaptive drive voltages within information handling systems is disclosed. According to one aspect of the disclosure, a method of outputting power within an information handling system can include sensing a load current of a power output stage operable to employ more than one drive voltage level. The method can also include comparing the load current to a threshold current setting, and selecting a first output drive voltage from a plurality of input drive voltages in response to comparing the load current to the threshold current setting. The method can also include coupling the first output drive voltage to the power output stage. | 10-30-2008 |
20090267578 | Static phase shedding for voltage regulators based upon circuit identifiers - Systems and methods are disclosed that provide static phase shedding techniques to improve the efficiency of multi-phase voltage regulators within information handling systems by selecting the number of active phases for the multi-phase voltage regulators using circuit identifiers (IDs) for circuitry configured to be powered by the multi-phase voltage regulators, such as central processing units (CPUs). In one embodiment, processor identifier information related to installed CPUs is used to control the voltage regulator (VR) phase number to provide static phase shedding. This VR control can be implemented in a variety of ways, including the use of conventional analog multi-phase VR controllers and/or digital VR controllers. Dynamic phase shedding can also be used in conjunction with this static phase shedding to further reduce the number of active phases when a processor operates in a low power mode. | 10-29-2009 |
20100250913 | Methods and Systems for Managing A Voltage Regulator - A method for increasing efficiency of a voltage regulator in an information handling system (IHS) is provided. The method may include enabling one or more operating phases associated with the voltage regulator and initializing a switch configuration having at least one high-side switch and at least one low-side switch. In addition, the may method include initializing a dead-time value, sensing a load current, and adjusting the number of operating phases, the switch configuration, or the dead-time value in response to the load current | 09-30-2010 |
20100250973 | Methods and Systems for Initiating Power to An Information Handling System - An information handling system (IHS) is disclosed providing a power supply operable to provide an output current to the IHS during power initiation. The IHS may also include a first power component associated with a first power stage wherein the first power stage may have a first current threshold. Furthermore, the IHS may include a power control logic coupled to the power supply and the first power component. As such, the power control logic may be operable to communicate the first power stage to the power supply, and if the output current does not exceed the first current threshold during the first power stage, the power control logic may be operable to communicate a second power stage having a second current threshold to the power supply. | 09-30-2010 |
20110051479 | Systems and Methods for Controlling Phases of Multiphase Voltage Regulators - A multi-phase voltage regulator is disclosed. The multi-phase voltage regulator includes a voltage regulator controller. Phase output stages are coupled to the voltage regulator controller. The voltage regulator controller and the phase output stages are configured to provide regulated voltages at one or more output nodes. The voltage regulator controller is configured to monitor one or more conditions of the phase output stages and to control one or more of the phase output stages based, at least in part, on the one or more conditions. | 03-03-2011 |
20110080151 | SYSTEM AND METHOD FOR MULTI-PHASE VOLTAGE REGULATION - In accordance with one embodiment of the present disclosure, a multi-phase voltage regulator may comprise a plurality of phases, each phase configured to supply electrical current to one or more information handling resources electrically coupled to the voltage regulator. A controller may be electrically coupled to the plurality of phases. The controller may designate at least one of the plurality of phases as a first state phase, and designate each of the plurality of phases not designated as a first state phase as a second state phase. The controller may alternate the designation of at least two of the plurality of phases between a first state phase and a second state phase. Each first state phase may be configured to supply a first electrical current regardless of electrical current demand. Each second state phase may be configured to supply a second electrical current based on the current demand. | 04-07-2011 |
20110254526 | Voltage Regulator with Optimal Efficiency Selection and a Master-Slave Zero Cross Detection Configuration - A voltage regulator includes a first phase power stage, a second phase power stage, and a controller. The first phase power stage includes a zero cross detection circuit configured to measure a current level for the first phase power stage, and to cause a diode emulation state in the first phase power stage when the current level is substantially equal to zero. The second phase power stage is in communication with the zero cross detection circuit, and configured to enter the diode emulation state in response to receiving a signal from the zero cross detection circuit. The controller is coupled to the first phase power stage and to the second phase power stage. The controller is configured to measure an output current of the voltage regulator and to activate the second phase power stage when the output current is above a first threshold current level. | 10-20-2011 |
20130099766 | Voltage Regulator with Optimal Efficiency Selection and a Master-Slave Zero Cross Detection Configuration - A voltage regulator includes a first phase power stage, a second phase power stage, and a controller. The first phase power stage includes a zero cross detection circuit configured to measure a current level for the first phase power stage, and to cause a diode emulation state in the first phase power stage when the current level is substantially equal to zero. The second phase power stage is in communication with the zero cross detection circuit, and configured to enter the diode emulation state in response to receiving a signal from the zero cross detection circuit. The controller is coupled to the first phase power stage and to the second phase power stage. The controller is configured to measure an output current of the voltage regulator and to activate the second phase power stage when the output current is above a first threshold current level. | 04-25-2013 |
20130106373 | Systems and Methods for Adaptive Body Braking Control in a Voltage Regulator | 05-02-2013 |
20140232420 | Methods And Systems For Defective Phase Identification And Current Sense Calibration For Multi-Phase Voltage Regulator Circuits - Methods and systems are disclosed that may be implemented to complete individual phase current sense calibration of a multi-phase voltage regulator (VR) and/or to detect any and all individual bad phases of such a VR by utilizing the reconfiguration capability of a digital VR controller-based VR in conjunction with an improved test process. The disclosed systems and methods may be employed in one example to identify that all individual phases of the multi-phase VR are operational to contribute to the output of the multi-phase VR using a rotating single phase operation testing mode. Individual phase current sense calibration may also be additionally or alternatively completed while the VR is operating under the rotating single phase operation mode. | 08-21-2014 |
20140253101 | SYSTEM AND METHOD OF MEASURING REAL-TIME CURRENT - A system and method of measuring real-time current is disclosed. The method includes calibrating a voltage measurement device. Calibrating includes measuring a real-time voltage difference between a first measurement node located proximate a first connector on a motherboard and a second measurement node located proximate a second connector on a power supply unit (PSU), the first and the second connectors coupled to provide power to the motherboard. Calibrating further includes averaging the real-time voltage difference for a plurality of measurements; computing a resistance of the coupling based at least on a long-duration averaged current from the PSU and the averaged real-time voltage difference, the resistance varying over time; and reporting the resistance of the coupling to the voltage measurement device. The method also includes measuring a real-time current of the PSU at the voltage measurement device based at least on the resistance of the coupling and the real-time voltage difference. | 09-11-2014 |
20150066234 | SYSTEM AND METHOD FOR MULTI-PHASE VOLTAGE REGULATION - In accordance with one embodiment of the present disclosure, a multi-phase voltage regulator may comprise a plurality of phases, each phase configured to supply electrical current to one or more information handling resources electrically coupled to the voltage regulator. A controller may be electrically coupled to the plurality of phases. The controller may designate at least one of the plurality of phases as a first state phase, and designate each of the plurality of phases not designated as a first state phase as a second state phase. The controller may alternate the designation of at least two of the plurality of phases between a first state phase and a second state phase. Each first state phase may be configured to supply a first electrical current regardless of electrical current demand. Each second state phase may be configured to supply a second electrical current based on the current demand. | 03-05-2015 |