An electronic device includes a controller to receive a signal from an external electronic device, and, based at least in part on the received signal, identify a wireless power scheme among at least two wireless power schemes. During the transmission mode, the controller controls the full bridge circuit to convert DC power to AC power based on a wireless power frequency corresponding to the identified wireless power scheme by controlling at least one transistor of the full bridge circuit, and controls to wirelessly transmit power based on the AC power to the external electronic device. During the reception mode, the controller controls to receive power from the external electronic device, controls the full bridge circuit to convert the received power to DC power by controlling transistors of the full bridge circuit, and controls to provide the converted DC power for the battery of the electronic device.

Methods, systems, and devices for grouping power supplies for a power saving mode are described to configure a memory device with groups of internal power supplies whose voltage levels may be successively modified according to a group order signaled by an on-die timer. For example, when the memory device enters a deep sleep mode, respective voltage levels of a first group of internal power supplies may be modified to respective external power supply voltage levels at a first time, respective voltage levels of a second group of internal power supplies may be modified to respective external power supply voltage levels at a second time, and so on. When the memory device exits the deep sleep mode, the groups of internal voltage supplies may be modified from the respective external power supply voltage levels to respective operational voltage levels in a group order that is opposite to the entry group order.

A method and a system for impact detection in a stationary vehicle are provided. The method includes putting a telematics device into a sleep mode, performing at least one micro wakeup, determining at least one value from at least one sensor during the micro wakeup. The method also includes storing the at least one value, returning to sleep mode, and waking up from the sleep mode. The method further includes sending the at least one value over a network interface to a telematics server. The telematics device which carries out the method has a controller, memory, and network interface. An accident impact profile may be recorded during the micro wakeups and sent during a wakeup duration for analysis by the telematics server.

A distribution system 100 includes a data management apparatus 10 and a plurality of calculators 20 that execute machine learning. The data management apparatus 10 includes a data acquisition unit 11 that acquires information regarding training data held in a memory 21 of each of the calculators 20, from the calculators 20, and a data rearrangement unit 12 that determines training data that is to be held in the memory 21 of each of the calculators 20, based on characteristics of the machine learning processes that are executed by the calculators 20, and the information acquired from the calculators.

The present application describes a power management system for controlling delivery of power to a plurality of processing elements. The power management system includes a plurality of power management circuits arranged between terminals of a power supply. Each power management circuit is configured to connect to a processing element of the plurality of processing elements, and either supply sufficient power to power processing at the processing element, or prevent supply of sufficient power to power processing at the processing element. The power management system includes one or more power controllers arranged to determine whether or not to supply sufficient power to a processing element of the plurality of processing elements to perform processing.

It is t an object of the present invention to provide an improved smart sun tracking systems that are expanding in three different directions, configured with multiple two-axis sun-trackers integrated with various single or step-aside double layers of hybrid Dual faces PV thermal panels to only two swiveling couplers in different directions with two driven main cables in closed loops (North-South and East-West), define the 4-dimension structure, and strong enough to withstand wind loading and the like without the structural reinforcement here to for required. Another object of the present invention is to provide an improved sun tracking systems for solar energy radiation receivers, which can be built from a minimum number of inexpensive parts and minimum maintenance. Additional objects, advantages and novel features of the invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the prior art upon examination of the following or may be learned by application of the invention. The objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims two electric motorized pulley attachments, connecting the closed loops cables to each 3-solar energy radiation receivers' to sub-assembly support beam, mounted on mast pillars at different lengths allow to provide a wide range of adjustments, i.e. wherein the 3-units of solar energy radiation receivers, reversing directions according to the seasons and when is needed. A clockwise and counter-clockwise electric motorized pulley, connected to dual direction main cables design is biased to maintain differential positions. When underneath the 3-units of solar energy radiation receivers connected central support beam which connected to swivel coupler and a pair of differential locations hooks. The smart sun-trackers system comprising multiple two-axis sun-trackers connected with cables in closed loops, provides required forms of multiple at least one or more 3-units of solar energy radiation receiver's mounted above sub-support beam assembly, when the cables are moving back and forth. The mechanism includes an electric motorized pulley shaft rotating in a different direction parallel to the cable portion to which the mechanism is attached. Because the cables connected in 2 different locations attached to the central support beam, allow the central main mast pillars swivel with the same cables length displacement following the movements which occur between all differential step-aside main mast pillars, respectively to North-South positions, providing the ne

It is t an object of the present invention to provide an improved smart sun tracking systems that are expanding in three different directions, configured with multiple two-axis sun-trackers integrated with various single or step-aside double layers of hybrid Dual faces PV thermal panels to only two swiveling couplers in different directions with two driven main cables in closed loops (North-South and East-West), define the 4-dimension structure, and strong enough to withstand wind loading and the like without the structural reinforcement here to for required. Another object of the present invention is to provide an improved sun tracking systems for solar energy radiation receivers, which can be built from a minimum number of inexpensive parts and minimum maintenance. Additional objects, advantages and novel features of the invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the prior art upon examination of the following or may be learned by application of the invention. The objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims two electric motorized pulley attachments, connecting the closed loops cables to each 3-solar energy radiation receivers' to sub-assembly support beam, mounted on mast pillars at different lengths allow to provide a wide range of adjustments, i.e. wherein the 3-units of solar energy radiation receivers, reversing directions according to the seasons and when is needed. A clockwise and counter-clockwise electric motorized pulley, connected to dual direction main cables design is biased to maintain differential positions. When underneath the 3-units of solar energy radiation receivers connected central support beam which connected to swivel coupler and a pair of differential locations hooks. The smart sun-trackers system comprising multiple two-axis sun-trackers connected with cables in closed loops, provides required forms of multiple at least one or more 3-units of solar energy radiation receiver's mounted above sub-support beam assembly, when the cables are moving back and forth. The mechanism includes an electric motorized pulley shaft rotating in a different direction parallel to the cable portion to which the mechanism is attached. Because the cables connected in 2 different locations attached to the central support beam, allow the central main mast pillars swivel with the same cables length displacement following the movements which occur between all differential step-aside main mast pillars, respectively to North-South positions, providing the ne

The described embodiments relate generally to computing devices including liquid crystal displays (LCDs) and more particularly to methods for attaching a cover glass layer to a structural housing while minimizing an amount of stress transferred through the cover glass layer to the LCD module. A continuous and compliant foam adhesive can be used to bond the cover glass layer to a structural. The compliant bond can absorb and distribute local stress concentrations caused by structural loads, mismatched surfaces and differing thermal expansion rates between various structures and cover glass layer. This can reduce stress concentrations in the cover glass layer that can lead to stress induced birefringence in the LCD cell. In other embodiments, the cover glass layer can be attached using magnets or a tongue and groove design.

In one embodiment, a method for managing a dynamic total power level for an information handling system includes: identifying, by a power manager of the information handling system, a first power level associated with a processor subsystem of the information handling system, the first power level based on a cooling capacity associated with the information handling system; identifying, by the power manager, a second power level associated with a graphics processing unit of the information handling system, the second power level based on a performance associated with the processor subsystem; determining, by the power manager, the dynamic total power level based on the first power level and the second power level; and modifying, by the power manager, a fixed total power level based on the dynamic total power level, the dynamic total power level causing the processor subsystem and the GPU to operate within the dynamic total power level.

The invention relates to a nanosecond-scale power resource allocation method and system for microservices. In order to eliminate the macro-control delays, it uses an auto power budgeting module to distribute the limited power resource to each microservice according to its unique power-performance model. On the other side, it deploys an agile power regulation module to bypass the slow power control procedures at the server system layer. By directly invoking the voltage regulation circuit on the processor, this can remove the micro-execution delays. It also leverages a transparent mapping mechanism to coordinate the work of the auto power budgeting module and the agile power regulation module to achieve the optimal allocation of power resources. The present invention can exploit the intra-application variability brought by microservices, thus further break the energy-saving limitation of traditional data centers.