[Object] Provided is an electronic component handling apparatus capable of controlling a DUT temperature within an appropriate range even in a DUT in which a sudden temperature change occurs under test.

[Solving Means] An electronic component handling apparatus 50 includes: a temperature adjuster 70 adjusting a temperature of a DUT 90; a first calculator 86 calculating the temperature of the DUT 90 on the basis of a detection result of a temperature detection circuit 92; a temperature controller 87 controlling the temperature adjuster 70; and a first receiver 81 receiving a first signal S.sub.1 output from a tester 10, in which a temperature control performed by the temperature controller 87 includes a first temperature control based on the temperature of the DUT 90 calculated by the first calculator 86 and a second temperature control different from the first temperature control and the temperature controller 87 switches the temperature control of the DUT 90 from the first temperature control to the second temperature control when the first receiver receives the first signal after the first temperature control starts.

A method for providing a thermal feedback, includes executing a virtual reality application providing a virtual space that includes a virtual area to which an area temperature attribute is assigned, and a virtual object to which an object temperature attributed is assigned. An area event that reflects that a player character enters the virtual area is detected. A feedback device is controlled to output thermal feedback associated to the area temperature attribute when the area event is detected, the feedback device outputting the thermal feedback using a thermoelectric element performing a thermoelectric operation. An object event reflecting the player character is influenced by the virtual object is detected. The feedback device is controlled to override the thermal feedback associated to the area temperature attribute and output thermal feedback associated to the object temperature when the object is detected while the player character is in the virtual area.

A method for providing a thermal feedback, includes executing a virtual reality application providing a virtual space that includes a virtual area to which an area temperature attribute is assigned, and a virtual object to which an object temperature attributed is assigned. An area event that reflects that a player character enters the virtual area is detected. A feedback device is controlled to output thermal feedback associated to the area temperature attribute when the area event is detected, the feedback device outputting the thermal feedback using a thermoelectric element performing a thermoelectric operation. An object event reflecting the player character is influenced by the virtual object is detected. The feedback device is controlled to override the thermal feedback associated to the area temperature attribute and output thermal feedback associated to the object temperature when the object is detected while the player character is in the virtual area.

A hair perming device and its temperature control circuit are disclosed. The temperature control circuit for a hair perming device is electrically connected with a heater of the hair penning device and comprises a main control module and a trigger module. The main control module controls the trigger module to be switched on such that a control signal outputted by the main control module can be sent to the heater for heating, and meanwhile for detects a working state of the trigger module. When a failure of the trigger module is detected, the main control module controls the trigger module to be switched off such that a continuous heating of the heater is stopped. When a failure of the trigger module is detected, the electrical power supply path of the heater is disconnected, and a continuous heating of the heater is stopped for avoiding excessive high temperature.

Technologies for managing the efficiency of workload execution in a managed node include a managed node that includes one or more processors that each include multiple cores. The managed nodes is to execute threads of workloads assigned to the managed node, generate telemetry data indicative of an efficiency of execution of the threads, determine, as a function of the telemetry data, an adjustment to a configuration of the threads among the cores to increase the efficiency of the execution of the threads, and apply the determined adjustment. Other embodiments are also described and claimed.

An iterative computer-implemented method and laboratory apparatus for calibrating and controlling the temperature: at a user device, remote from the apparatus: receiving a series of programming inputs from a user at a programming interface application on the user device; receiving a set of sensor measurements from the apparatus; automatically generating a set of control instructions for the apparatus based on a programming input of the series and the set of sensor measurements; and sending the set of control instructions to the apparatus; at the apparatus: receiving the set of control instructions from the user device; operating the apparatus based on the set of control instructions; recording a second set of sensor measurements during the apparatus operation; and sending the second set of sensor measurements to the user device; to the user device.

An iterative computer-implemented method and laboratory apparatus for calibrating and controlling the temperature: at a user device, remote from the apparatus: receiving a series of programming inputs from a user at a programming interface application on the user device; receiving a set of sensor measurements from the apparatus; automatically generating a set of control instructions for the apparatus based on a programming input of the series and the set of sensor measurements; and sending the set of control instructions to the apparatus; at the apparatus: receiving the set of control instructions from the user device; operating the apparatus based on the set of control instructions; recording a second set of sensor measurements during the apparatus operation; and sending the second set of sensor measurements to the user device; to the user device.

Examples may include racks for a data center and sleds for the racks, the sleds arranged to house physical resources for the data center. The sleds can house physical resources and heat sinks thermally coupled to the physical resources. The physical resources are arranged on the sleds and the heat sinks are configured so as to limit thermal shadowing between physical resources to reduce interference with airflow provided by fans of the racks.

Drapes for covering fluid heating devices having basins. Some drapes have a set of at least one positioning component trapped between the drape basin layer and the drape device layer by a set of bonds. The positioning component aligns the drape with the basin bottom. Optionally, the drape may have a low-slip film for basin contact and a non-slip film for at least a portion of the drape beyond the basin. Alternatively, a single layer drape may have a set of at least one positioning component bonded to the drape. Some drapes have basin-shaped sterile vented barrier with vents to allow the sterile vented barrier to be inserted into the basin and to vent air out of the basin. The heating system for the fluid heating device may interrupt electricity provided to a heating element when a temperature sensed at an air gap detector exceeds a high temperature setpoint.

An electromagnetic shielding module and a display device are disclosed. The electromagnetic shielding module includes an electromagnetic shielding film and a temperature adjusting circuit, and the temperature adjusting circuit is configured for adjusting a temperature of the electromagnetic shielding film.