A temperature reading from a thermal sensor connected to a memory device is determined. The memory device comprises a plurality of memory cells. At least one of a logical capacity criterion or a physical capacity criterion is determined based on the temperature reading from the thermal sensor. Responsive to determining that at least one of the logical capacity of a first data block of the plurality of memory cells configured as a first memory type satisfies the logical capacity criterion or a physical capacity of the first data block of the plurality of memory cells configured as the first memory type satisfies the physical capacity criterion, data from the first data block is migrated to a second data block of the plurality of memory cells configured as a second memory type.

A temperature distribution measurement apparatus includes a laser light source optically connected to an optical fiber, a photodetector configured to detect light backscattered in the optical fiber, and a temperature distribution measurement unit configured to obtain a true measured temperature distribution by performing correction calculation using a transfer function on a temporary measured temperature distribution obtained based on an output from the photodetector. The temperature distribution measurement unit stores therein data on a transfer function set for each entire length of the optical fiber and for each longitudinal position in the optical fiber. Then, when the length of the optical fiber is changed, the temperature distribution measurement unit changes the transfer function to be used in the correction calculation by using the data on the transfer function.

A system comprising a memory device and a processing device, operatively coupled to the memory device. The processing device is to perform operations including initializing a block family associated with the memory device and measuring an opening temperature of the memory device at initialization of the block family. Responsive to programming a page residing on the memory device, the operations further include associating the page with the block family. The operations further include determining a temperature metric value by integrating, over time, an absolute temperature difference between the opening temperature and an immediate temperature of the memory device. The operations further include closing the block family in response to the temperature metric value being greater than or equal to a specified threshold temperature value.

A power interface device includes a first connecting module, a second connecting module and a processing module. The processing module performs the following: receiving a supply voltage through the first connecting module from a power supply device that employs a fast charging technology and that provides, based on an informing output, the supply voltage having a magnitude dependent on the informing output; generating the informing output; outputting the informing output to the power supply device through the first connecting module; and starting to output the supply voltage to the second connecting module when determining that a condition associated with the magnitude of the supply voltage is met.

A power interface device includes a first connecting module, a second connecting module and a processing module. The processing module performs the following: receiving a supply voltage through the first connecting module from a power supply device that employs a fast charging technology and that provides, based on an informing output, the supply voltage having a magnitude dependent on the informing output; generating the informing output; outputting the informing output to the power supply device through the first connecting module; and starting to output the supply voltage to the second connecting module when determining that a condition associated with the magnitude of the supply voltage is met.

A method of testing a tire is employed in an enclosed system having a drum enclosure connected to a tire enclosure by flexible bellows, the enclosed system configured such that a tire inside the tire enclosure abuts a drum inside the drum enclosure. The method includes rotating the drum at a first angular velocity, thereby causing the tire to rotate at the first angular velocity. The method further includes measuring a temperature at a first location adjacent the tire and blowing cool air into the tire enclosure when the measured temperature exceeds a predetermined temperature threshold. The method also includes measuring a humidity level at a second location and adding moisture in the tire enclosure when the measured humidity level falls below a predetermined humidity threshold.

In some examples, a temperature distribution sensor may include a laser source to emit a laser beam that is tunable over a wavelength range. The wavelength range may be less than a Raman bandwidth in a device under test (DUT), or of-the-order-of the Raman bandwidth in the DUT. A pulsed source may apply a pulse drive signal to the laser beam or to a modulator to modulate the laser beam that is to be injected into the DUT. A bandpass filter may be operatively disposed between the laser source and the DUT, and may be configured to an anti-Stokes wavelength that is narrower than the Raman bandwidth. A photodiode may be operatively disposed between the bandpass filter and the DUT to acquire, from the DUT, anti-Stokes optical time-domain reflectometer traces for two preset wavelengths of the laser beam to determine a temperature distribution for the DUT.

A wind turbine assembly including a rotor system, a generator, a first converter, a second converter, and a controller system. The first converter includes a first bridge circuit having a plurality of switch members each having a controllable switch. The second converter includes a second bridge circuit having a plurality of switch members each having a controllable switch. The controller system is adapted to provide a drying operation for second converter including short circuiting the second converter with the controllable switches of the second bridge in circuit, and supplying power from the generator through the first converter to the short circuited second converter for drying the second converter.

A monitoring and control system is provided. The system includes a plurality of sensors for obtaining readings associated with food items, such as temperature readings, freshness indications, and the like. The system is scalable and configurable with each sensor being capable of functioning as an individual sensor and/or as part of a grouping of sensors. The system is configured to obtain a variety of information, such as ambient air temperature, dwell time of food items, moisture levels, and the like, thereby enabling the system to recognize current and future concerns. The system provides audio and visual warnings and visual displays. In some embodiments, the system performs one or more physical operation based on one or more detected condition. The system is further configured to distinguish between accurate readings and inaccurate readings and/or to otherwise determine if an obstacle is preventing a sensor from obtaining an accurate reading.

A communication network may include a first computer and a second computer configured for communication with each other. The second computer may include a project manager module configured to receive computing projects from the first computer and manage the execution of work tasks for the computing projects. The project manager may throttle performance if needed to prevent negative impact on the performance of other applications also being executed on the second computer, such as a video game. Rewards for performing the work tasks may be automatically converted from a first cryptocurrency to a second currency such as a video game currency.