Abstract: An active temperature control system for a DUT utilizes a heat sink containing HFE7100 liquid and an electric heater. The liquid is cooled below the set point and the heater is used to bring the DUT up to the set point. Set points in the range of ?10 degrees C. to +110 degrees C. can be achieved. The heat sink utilizes only a single coolant for all of the set points, allowing set points to be changed within a few minutes. At a given set point, the heater provides a quick response to offset the effect of self-heating and keep the set point deviation to within a few degrees C. Power following techniques can be utilized to achieve the quick response.

Abstract: A system and method for controlling a temperature of a device during testing with a thermal controller and a heat exchanger includes measuring an instantaneous power consumption of the device during testing. The heat exchanger is controlled with the thermal controller using the measured instantaneous power consumption by the device to regulate the temperature of the device during testing, wherein the heat exchanger is in conductive contact with the device.

Abstract: An active temperature control system for a DUT utilizes a heat sink containing HFE7100 liquid and an electric heater. The liquid is cooled below the set point and the heater is used to bring the DUT up to the set point. Set points in the range of −10 degrees C. to +110 degrees C. can be achieved. The heat sink utilizes only a single coolant for all of the set points, allowing set points to be changed within a few minutes. At a given set point, the heater provides a quick response to offset the effect of self-heating and keep the set point deviation to within a few degrees C. Power following techniques can be utilized to achieve the quick response.

Abstract: A system and method for controlling a temperature of a device during testing with a thermal controller and a heat exchanger includes measuring an instantaneous power consumption of the device during testing. The heat exchanger is controlled with the thermal controller using the measured instantaneous power consumption by the device to regulate the temperature of the device during testing, wherein the heat exchanger is in conductive contact with the device.

Abstract: A method of controlling a temperature of a semiconductor device during testing is used with a system including a heater and a heat sink and a temperature control system. The semiconductor device is thermally coupled to the heater, which is thermally coupled to a heat sink. The heat sink defines a chamber, and the chamber is adapted to have a liquid flowing through the chamber. The temperature control system is coupled to the heater and the heat sink. In the method, the temperature of the semiconductor device is moved to approximately a first set point temperature. The temperature of the semiconductor device is moved to approximately a second set point temperature, from approximately the first set point temperature, by changing a temperature of the heater and maintaining the liquid flowing into the chamber at a substantially constant temperature.

Abstract: A method for controlling a device temperature measures a parameter related to device power consumption and utilizes the parameter to control the device temperature. This can be achieved with a system including a heat exchanger, a power monitor, and a circuit which controls the temperature setting of the heat exchanger. The circuit uses as inputs the power level, heat exchanger temperature, and set point. The system thus eliminates the need for temperature sensing devices in or connected to a chip, responds to the temperature of the device and not the package, can be used for high volume chip manufacturing, does not require significant surface area of a device for temperature sensing, and eliminates the need for chip power profiles. Significantly, the system allows a set point to be maintained with minimal overshoot or undershoot.

Abstract: A method for controlling the temperature of a DUT during a testing operation, includes a) measuring a parameter related to power consumption by the DUT during testing, such as current consumption; and b) using the parameter related to power consumption to operate a temperature control device to compensate for temperature change due to changes in power consumption by the DUT during testing. The control can be closed loop or open loop with control signals incorporated into a test program. Apparatus for controlling the temperature of a DUT during testing, includes a) a device for measuring a parameter related to power consumption by the DUT during testing; b) a temperature control device which operates to control the temperature of the DUT during test; and c) a device for controlling operation of the temperature control device according to the measured parameter related to power consumption.

Abstract: An active temperature control system for a DUT utilizes a heat sink containing HFE7100 liquid and an electric heater. The liquid is cooled below the set point and the heater is used to bring the DUT up to the set point. Set points in the range of −10 degrees C. to +110 degrees C. can be achieved. The heat sink utilizes only a single coolant for all of the set points, allowing set points to be changed within a few minutes. At a given set point, the heater provides a quick response to offset the effect of self-heating and keep the set point deviation to within a few degrees C. Power following techniques can be utilized to achieve the quick response.

Abstract: A method for controlling a device temperature measures a parameter related to device power consumption and utilizes the parameter to control the device temperature. This can be achieved with a system including a heat exchanger, a power monitor, and a circuit which controls the temperature setting of the heat exchanger. The circuit uses as inputs the power level, heat exchanger temperature, and set point. The system thus eliminates the need for temperature sensing devices in or connected to a chip, responds to the temperature of the device and not the package, can be used for high volume chip manufacturing, does not require significant surface area of a device for temperature sensing, and eliminates the need for chip power profiles. Significantly, the system allows a set point to be maintained with minimal overshoot or undershoot.

Abstract: A method of controlling a temperature of a semiconductor device during testing is used with a system including a heater and a heat sink and a temperature control system. The semiconductor device is thermally coupled to the heater, which is thermally coupled to a heat sink. The heat sink defines a chamber, and the chamber is adapted to have a liquid flowing through the chamber. The temperature control system is coupled to the heater and the heat sink. In the method, the temperature of the semiconductor device is moved to approximately a first set point temperature. The temperature of the semiconductor device is moved to approximately a second set point temperature, from approximately the first set point temperature, by changing a temperature of the heater and maintaining the liquid flowing into the chamber at a substantially constant temperature.

Abstract: A handler for a device under test (“DUT”) includes a rotating table which supports up to eight DUTs. The DUTs are held in place over openings in the table and separate heat exchangers contact the individual DUTs through the openings and conductively control the temperature of the DUTs. Six of the DUTs are in conditioning stations and are lifted off of the rotary table until they contact separate spring-loaded pads. One of the DUTs is in a test station and it is lifted off of the rotary table until it contacts a test head, at which point testing is performed. The temperature of each of the DUTs is controlled throughout the process.