In a device that measures biopotentials of cells in a solution, the solution is controlled at a constant temperature. A measurement device includes a substrate, a sensing control circuit, a temperature sensor, a front surface side heat radiating unit, a back surface side heat radiating unit, and a temperature control unit. A plurality of electrodes each detecting a potential in the solution is arranged on the front surface of the substrate. The sensing control circuit is arranged on the substrate and controls detection of potentials at the plurality of electrodes. The temperature sensor is arranged on the substrate and detects a temperature of the solution. The front surface side heat radiating unit is arranged on the front surface side of the substrate and radiates heat. The back surface side heat radiating unit is arranged on the back surface side that is a surface different from the front surface of the substrate, and radiates heat. The temperature control unit controls the temperature of the solution on the basis of the temperature detected by the temperature sensor.

In a device that measures biopotentials of cells in a solution, the solution is controlled at a constant temperature. A measurement device includes a substrate, a sensing control circuit, a temperature sensor, a front surface side heat radiating unit, a back surface side heat radiating unit, and a temperature control unit. A plurality of electrodes each detecting a potential in the solution is arranged on the front surface of the substrate. The sensing control circuit is arranged on the substrate and controls detection of potentials at the plurality of electrodes. The temperature sensor is arranged on the substrate and detects a temperature of the solution. The front surface side heat radiating unit is arranged on the front surface side of the substrate and radiates heat. The back surface side heat radiating unit is arranged on the back surface side that is a surface different from the front surface of the substrate, and radiates heat. The temperature control unit controls the temperature of the solution on the basis of the temperature detected by the temperature sensor.

Embodiments of the invention may provide an improved method for pre-heating an electronic device such as an information handling system, when internal temperatures are below safe operating ranges. To do so, the system selectively heats the entire device or select zones of the electronic device for a predetermined amount of time when the system is restarted after a period of time sufficient to bring the system to ambient temperatures. The predetermined amount of time is determined based on measured ambient temperatures. Using a table that corresponds the ambient temperatures to a time that a component needs to heat up to a nominal temperature in a zone, the predetermined time can be calculated.

Embodiments of the invention may provide an improved method for pre-heating an electronic device such as an information handling system, when internal temperatures are below safe operating ranges. To do so, the system selectively heats the entire device or select zones of the electronic device for a predetermined amount of time when the system is restarted after a period of time sufficient to bring the system to ambient temperatures. The predetermined amount of time is determined based on measured ambient temperatures. Using a table that corresponds the ambient temperatures to a time that a component needs to heat up to a nominal temperature in a zone, the predetermined time can be calculated.

A unit which combines a remotely programmable controller with an integral temperature and level sensor for controlling the temperature and level of a given liquid. The device comprises one temperature sensor, to measure a liquid's temperature and to provide an electrical output; one level sensor, to measure a liquid's level and provide an electrical output; a programmable scaling and control module, for receiving the electrical outputs of the temperature sensor and level sensor as input signals, for scaling the temperature signal as a function of temperature and a scale-selection input, and for implementing a control logic to process the sensor signals into two respective control signals; two electronic switching devices, to electrically interface one of the two control signals to an external heater or cooling unit and the other one of the two control signals to an auxiliary device, such as a pump or alarm.

A temperature sensing system includes N temperature sensing circuits, each including a diode, that are connected in series, wherein N is an integer greater than one. A control module includes a first terminal that communicates with one of the N temperature sensing circuits, that receives a combined voltage of the N temperature sensing circuits at the first terminal, and that calculates an average temperature of the N temperature sensing circuits based on the combined voltage.

A temperature sensing system includes N temperature sensing circuits, each including a diode, that are connected in series, wherein N is an integer greater than one. A control module includes a first terminal that communicates with one of the N temperature sensing circuits, that receives a combined voltage of the N temperature sensing circuits at the first terminal, and that calculates an average temperature of the N temperature sensing circuits based on the combined voltage.

A system includes a multi-stage cryocooler having multiple stages and a temperature control system configured to regulate temperatures of the multiple stages of the multi-stage cryocooler. The temperature control system includes an input interface configured to receive (i) temperature setpoints for the stages of the multi-stage cryocooler and (ii) temperature information corresponding to temperatures measured at the stages of the multi-stage cryocooler. The temperature control system also includes processing circuitry configured to determine temperature errors and calculate at least one of a compressor stroke error and a pressure-volume phase error. The temperature control system further includes at least one controller configured to adjust at least one of a compressor setting and a pressure-volume phase of the multi-stage cryocooler.

An electrical circuit is provided in a casing. The electrical circuit includes a capacitor having a particular function needed for realizing the electrical circuit. The electrical circuit includes an electrical component configured to generate heat due to energization. A flow creator creates, in the casing, an air flow that flows in a direction from the electrical component to the capacitor such that air heated by heat generation of the electrical component flows to the capacitor. A controller controls the flow creator. The capacitor has a characteristic that capacitance monotonically decreases or monotonically increases as temperature rises, in a part of a temperature range in which the electrical circuit operates. The controller detects a capacitance change due to a temperature change of the capacitor caused by the air heated by the heat generation, and controls the flow creator based on a detection result of the capacitance change.

An electrical circuit is provided in a casing. The electrical circuit includes a capacitor having a particular function needed for realizing the electrical circuit. The electrical circuit includes an electrical component configured to generate heat due to energization. A flow creator creates, in the casing, an air flow that flows in a direction from the electrical component to the capacitor such that air heated by heat generation of the electrical component flows to the capacitor. A controller controls the flow creator. The capacitor has a characteristic that capacitance monotonically decreases or monotonically increases as temperature rises, in a part of a temperature range in which the electrical circuit operates. The controller detects a capacitance change due to a temperature change of the capacitor caused by the air heated by the heat generation, and controls the flow creator based on a detection result of the capacitance change.