An integrated circuit package having an electronic interposer comprising an upper section, a lower section and a middle section, a die side integrated circuit device electrically attached to the upper section of the electronic interposer, a die side heat dissipation device thermally contacting the die side integrated circuit device, a land side integrated circuit device electrically attached to the lower section of the electronic interposer, and a land side heat dissipation device thermally contacting the at least one die side integrated circuit device. The upper section and the lower section may each have between two and four layers and the middle section may be formed between the upper section and the lower section, and comprises up to eight layers, wherein a thickness of each layer of the middle section is thinner than a thickness of any of the layers of the upper section and the lower section.

A method includes, responsive to an application of power to an IC, self-initializing the IC by asserting a reset signal for a reset period. Self-initializing the IC also includes, in response to an expiration of the reset period, deasserting the reset signal. Self-initializing the IC also includes, responsive to deasserting the reset signal, automatically obtaining first temperature data from at least one thermal sensing device associated with a die of the IC, and storing the first temperature data in a storage component of the IC.

An integrated circuit includes a memory and peripheral circuits with a temperature sensor used to automatically adjust operating voltages. The temperature sensor includes a reference circuit that generates a first reference with a first non-zero temperature coefficient and a second reference with a second temperature coefficient having a different magnitude than the first non-zero temperature coefficient. A detector circuit on the integrated circuit, having temperature and process variation compensation, converts a difference between the first and second references into a digital signal indicating temperature on the integrated circuit.

A system for controlling one or more fans, comprising an open loop control system configured to receive a CPU power level and to maintain a fan speed at an open loop fan speed level. A closed loop control system configured to receive the CPU power level and temperature, and to modify the fan speed as a function of the CPU power level and temperature, wherein the fan speed is maintained at a level that is not lower than the open loop fan speed level.

The disclosure relates to technology for determining stress on integrated circuits. These include using ring oscillators formed on the integrated circuit, where one ring oscillator has its frequency dependent on the current flowing through its stages being limited by its NMOS devices and another ring oscillator has its frequency dependent on the current flowing through its stages being limited by its PMOS devices. This allows the stress on the integrated circuit to be determined in different directions along the integrated circuit. A temperature sensor can be used to compensate for temperature dependence on the frequencies of the ring oscillators.

An apparatus can include a first adaptive filter, a second adaptive filter, a filter, and a third adaptive filter. The first adaptive filter can be configured to determine an estimated magnitude of a control signal associated with a control measure based on a magnitude of a signal from a sensor, wherein the signal is indicative of operating temperature of a memory system. The second adaptive filter can be configured to determine an estimated operating temperature based on a magnitude of the control signal. The filter can be configured to determine a change magnitude of the control signal based on a difference between the magnitude of the signal from the sensor and a threshold operating temperature. The third adaptive filter can be configured to determine a throttle rate at which to apply the control signal based on a change magnitude of the control signal.

A method for measuring the oil content of a lithium battery separator by using DSC includes the following steps: taking 5-10 mg of an oil-containing separator sample from the lithium battery separator, and taking 5-10 mg of an oil-free separator sample from an oil-free separator; performing an enthalpy test on the oil-free separator sample at room temperature by using a differential scanning calorimeter to obtain a first enthalpy value, and performing an enthalpy test on the oil-containing separator sample by using the differential scanning calorimeter to obtain a second enthalpy value; subtracting the second enthalpy value from the first enthalpy value to obtain a difference, and then dividing the difference by the first enthalpy value to obtain the oil content of the oil-containing separator sample.

Methods, non-transitory computer-readable storage mediums and electronic devices are provided for controlling temperature. A terminal obtains a target environment temperature value of an environment where the terminal is located. When the terminal is being charged, the terminal determines a target temperature control strategy according to the target environment temperature value. The terminal controls a temperature of the terminal according to the target temperature control strategy.

The present disclosure provides a method for automatically optimizing power consumption. The method includes: (S1) a baseboard management controller determines whether system information is correct or not after powered on. If correct, further proceeding the method. If not correct, stopping further proceeding the method. (S2) the baseboard management controller periodically detects the surface temperature and the internal temperature of the essential element with a first loop cycle and determines whether the surface temperature or the internal temperature is higher than a preset temperature. (S3) If the surface temperature or the internal temperature is higher than the preset temperature, performing a PID adjustment to the fan rotation speed according to the surface temperature or the internal temperature of the essential element. If the surface temperature or the inner temperature is not higher than the preset temperature, performing a stepwise adjustment to the fan rotation speed according to current environment temperature.

According to one embodiment, a controller acquires temperature data periodically while receiving a first mode designating signal, writes the temperature data into a nonvolatile storage while or after the first mode designating signal, acquires temperature data after a lapse of a predetermined time from designation of the second mode, writes the temperature data into the nonvolatile storage while or after a lapse of a predetermined time since the designation of the second mode, acquires temperature data at a timing of changing from the second mode to the first mode, and write the acquired temperature data into the nonvolatile storage at or after the timing of changing from the second mode to the first mode.