Abstract: A memory temperature controlling method and a memory temperature controlling system are provided. The method includes: performing, by a testing equipment, test modes on a memory storage device, and obtaining a first internal temperature of a memory control circuit unit, a second internal temperature of each memory package and a surface temperature of each memory package to establish a linear relationship expression of the first internal temperature, the second internal temperature and the surface temperature; using, by the memory storage device, the linear relationship expression to calculate a predicted surface temperature of a rewritable non-volatile memory based on a first current internal temperature of the memory control circuit unit and a second current internal temperature of each memory package; adjusting, by the memory storage device, an operating frequency for accessing the rewritable non-volatile memory based on the predicted surface temperature.

Abstract: A memory temperature controlling method and a memory temperature controlling system are provided. The method includes: performing, by a testing equipment, test modes on a memory storage device, and obtaining a first internal temperature of a memory control circuit unit, a second internal temperature of each memory package and a surface temperature of each memory package to establish a linear relationship expression of the first internal temperature, the second internal temperature and the surface temperature; using, by the memory storage device, the linear relationship expression to calculate a predicted surface temperature of a rewritable non-volatile memory based on a first current internal temperature of the memory control circuit unit and a second current internal temperature of each memory package; adjusting, by the memory storage device, an operating frequency for accessing the rewritable non-volatile memory based on the predicted surface temperature.

Abstract: A memory thermal throttling method and a memory thermal throttling system are provided. The method includes: performing, by a testing equipment, test modes on a memory storage device, and obtaining an internal temperature of a memory control circuit unit, a work loading of each memory package and a surface temperature of each memory package to establish a linear relationship between the work loading, the internal temperature, and the surface temperature; storing, by the testing equipment, the linear relationship in the memory storage device; using, by the memory storage device, the linear relationship based on a current internal temperature of the memory control circuit unit and a current work loading of a first memory package of the memory packages to calculate a predicted surface temperature of the first memory package; adjusting, by the memory storage device, an operating frequency for accessing the first memory package based on the predicted surface temperature.

Abstract: A control system and method for improving battery output energy efficiency, and an electronic device are provided. The control system includes: a battery, a charging chip, a voltage conversion module, and a power supply management module. The battery is configured to send, when the control system is not connected to an external power supply, battery voltage to the voltage conversion module by means of the charging chip. The voltage conversion module is configured to receive the battery voltage, determine an operating mode on the basis of the battery voltage, acquire an output voltage corresponding to the operating mode, and output the output voltage to the power supply management module. The power supply management module is configured to convert and output at least one system voltage on the basis of the output voltage, and the at least one system voltage is configured to supply power to a powered system.

Abstract: The present application provides a battery that has application in automotive diagnostic tablets. The battery includes a battery cell, a positive electrode interface, and a negative electrode interface. The positive electrode of the battery cell is connected to the positive electrode interface. The battery further includes a first resistor and a protection chip. A first end of the first resistor is connected to the negative electrode of the battery cell, and the other end of the first resistor is connected to the negative electrode interface. The protection chip includes a power detection end and a communication interface, and the power detection end is connected to the first resistor. The protection chip is used to detect the power information of the battery cell by means of the power detection end, and the power information is sent by means of the communication interface to a microprocessor.

Abstract: A charging apparatus, a charging method, and an electronic device are provided. The charging apparatus includes a first charging module, a second charging module, a microprocessor and a voltage adjustment module. The microprocessor is connected to the first charging module and the second charging module. The voltage adjustment module is connected to the first charging module and the second charging module. The microprocessor is configured for controlling the first charging module and the second charging module to charge a battery. The first charging module is configured for supplying power to a vehicle diagnosis system and charging the battery. The second charging module is configured for charging the battery. A device that needs to be charged is charged by means of both the first charging module and the second charging module, and the charging current is controllable, such that the charging efficiency is improved.

Abstract: A method includes performing by a processor: receiving a plurality of synchrophasor measurements of a power system signal associated with a time interval from a plurality of phasor measurement units (PMUs), respectively, each of the plurality of synchrophasor measurements including a phase angle, frequency value, and a timestamp associated with the synchrophasor measurement; determining, for each of the plurality of PMUs, a dominant mode frequency of a forced oscillation signal component of the power system signal based on the frequency value and the phase angle; determining, for each of the plurality of PMUs, a mode angle of the forced oscillation signal component at the dominant mode frequency; and determining a geographic forced oscillation source location for a source of the forced oscillation signal component based on the plurality of mode angles associated with each of the plurality of PMUs, respectively, and geographic locations of the plurality of PMUs.

Abstract: A method includes performing by a processor: receiving a plurality of synchrophasor measurements of a power system signal associated with a time interval from a plurality of phasor measurement units (PMUs), respectively, each of the plurality of synchrophasor measurements including a phase angle, frequency value, and a timestamp associated with the synchrophasor measurement; determining, for each of the plurality of PMUs, a dominant mode frequency of a forced oscillation signal component of the power system signal based on the frequency value and the phase angle; determining, for each of the plurality of PMUs, a mode angle of the forced oscillation signal component at the dominant mode frequency; and determining a geographic forced oscillation source location for a source of the forced oscillation signal component based on the plurality of mode angles associated with each of the plurality of PMUs, respectively, and geographic locations of the plurality of PMUs.

Abstract: The invention relates to a self-adaptive positive-sequence current quick-break protection method for a petal-shaped power distribution network trunk line. The method comprises the following steps: step 1, calculating a positive-sequence voltage phasor and a positive-sequence current amplitude at a protection installation position when a fault occurs, acquiring and storing a positive sequence impedance value of a protected line; judging a fault type, and judging a fault direction; step 2, when a fault direction element judges that a fault occurs in the forward direction, selecting a self-adaptive current quick-break protection setting formula according to the fault type, and when positive sequence current measured by protection is larger than a protection setting value, judging that the protected line has a short-circuit fault, and making a circuit breaker trip quickly.