Abstract: Probe systems and methods including active environmental control are disclosed herein. The methods include placing a substrate, which includes a device under test (DUT), on a support surface of a chuck. The support surface extends within a measurement environment that is at least partially surrounded by a measurement chamber. The methods further include determining a variable associated with a moisture content of the measurement environment and receiving a temperature associated with the measurement environment. The methods also include supplying a purge gas stream to the measurement chamber at a purge gas flow rate and selectively varying the purge gas flow rate such that a dew point temperature of the measurement environment is within a target dew point temperature range. The methods further include providing a test signal to the DUT and receiving a resultant signal from the DUT. The systems include probe systems that perform the methods.

Abstract: In a method and a device for testing a test substrate under defined thermal conditions, a substrate that is to be tested is held by a temperature-controllable chuck and is set to a defined temperature; the test substrate is positioned relative to test probes by at least one positioning device; and the test probes make contact with the test substrate for testing purposes. At least one component of the positioning device that is present in the vicinity of the temperature-controlled test substrate is set to a temperature that is independent of the temperature of the test substrate by a temperature-controlling device, and this temperature is held constant.

Abstract: In a method and a device for testing a test substrate under defined thermal conditions, a substrate that is to be tested is held by a temperature-controllable chuck and is set to a defined temperature; the test substrate is positioned relative to test probes by at least one positioning device; and the test probes make contact with the test substrate for testing purposes. At least one component of the positioning device that is present in the vicinity of the temperature-controlled test substrate is set to a temperature that is independent of the temperature of the test substrate by a temperature-controlling device, and this temperature is held constant.

Abstract: In a method and a device for testing a test substrate under defined thermal conditions, a substrate that is to be tested is held by a temperature-controllable chuck and is set to a defined temperature; the test substrate is positioned relative to test probes by at least one positioning device; and the test probes make contact with the test substrate for testing purposes. At least one component of the positioning device that is present in the vicinity of the temperature-controlled test substrate is set to a temperature that is independent of the temperature of the test substrate by a temperature-controlling device, and this temperature is held constant.

Abstract: A probe holder has a manipulator, a probe arm arranged on the manipulator, and a probe needle that is at least indirectly connected to the probe arm. To increase the number of contacts of a substrate to be tested and to make it possible to test a plurality of contacts in etched trenches of semiconductor elements in a group of wafers, the probe arm is connected to a needle support on which the probe needle and at least one second probe needle are arranged.

Abstract: The invention relates to a method for testing several electronic components (1) of a repetitive pattern under defined thermal conditions in a prober, which comprises a chuck (10) for holding the components (1) and special holding devices (15) for holding individual probes (12). For testing, the components (1) are adjusted to a defined temperature, the probes (12) and a first electronic component (1) are positioned relative to each other by means of at least one positioning device, contact pads (3) of the electronic component (1) are subsequently contacted by the probes (12) so that the component (1) can be tested and then the positioning and the contacting can be repeated for testing another component (1) of the repetitive pattern.

Abstract: A chuck with triaxial construction comprises a receiving surface for a test substrate and arranged below the receiving surface: an electrically conductive first surface element, an electrically conductive second surface element electrically insulated therefrom, and an electrically conductive third surface element electrically insulated therefrom, and, between the first and the second surface element, a first insulation element and, between the second and the third surface element, a second insulation element.

Abstract: A focused multi-planar image acquisition in real time even while a test object is moving, is achieved with a system and a method for a focused multi-planar image acquisition in a prober. When a surface of a test object is positioned laterally in relation to tips of separated probe needles, a microscope is focused on the surface of the test object at a first time and on a plane of the probe needles at a second time. The objective lens is provided with a microscope objective lens focusing system, which can focus the objective lens, independently of a vertical adjustment drive of the microscope, on the surface of the test object in a first focal plane and in a second focal plane, which is on a level with the probe needle tips.

Abstract: The invention relates to a method for testing several electronic components (1) of a repetitive pattern under defined thermal conditions in a prober, which comprises a chuck (10) for holding the components (1) and special holding devices (15) for holding individual probes (12). For testing, the components (1) are adjusted to a defined temperature, the (12) and a first electronic component (1) are positioned relative to each other by means of at least one positioning device, contact pads (3) of the electronic component (1) are subsequently contacted by the probes (12) so that the component (1) can be tested and then the positioning and the contacting can be repeated for testing another component (1) of the repetitive pattern.

Abstract: A focused multi-planar image acquisition in real time even while a test object is moving, is achieved with a system and a method for a focused multi-planar image acquisition in a prober. When a surface of a test object is positioned laterally in relation to tips of separated probe needles, a microscope is focused on the surface of the test object at a first time and on a plane of the probe needles at a second time. The objective lens is provided with a microscope objective lens focusing system, which can focus the objective lens, independently of a vertical adjustment drive of the microscope, on the surface of the test object in a first focal plane and in a second focal plane, which is on a level with the probe needle tips.

Abstract: A probe holder has a manipulator, a probe arm arranged on the manipulator, and a probe needle that is at least indirectly connected to the probe arm. To increase the number of contacts of a substrate to be tested and to make it possible to test a plurality of contacts in etched trenches of semiconductor elements in a group of wafers, the probe arm is connected to a needle support on which the probe needle and at least one second probe needle are arranged.

Abstract: In a method and a device for testing a test substrate under defined thermal conditions, a substrate that is to be tested is held by a temperature-controllable chuck and is set to a defined temperature; the test substrate is positioned relative to test probes by at least one positioning device; and the test probes make contact with the test substrate for testing purposes. At least one component of the positioning device that is present in the vicinity of the temperature-controlled test substrate is set to a temperature that is independent of the temperature of the test substrate by a temperature-controlling device, and this temperature is held constant.

Abstract: A method and an apparatus are provided which make it possible, when testing chips arranged on a wafer, to be able to test optionally both additional components arranged on horizontal boundary lines and on vertical boundary lines. The additional components arranged on horizontal boundary lines are tested in a first position of the wafer. For testing the additional components arranged on vertical boundary lines, the wafer is rotated about its vertical axis through 90° relative to the first position into a second position. The apparatus comprises a housing and, in the housing, at least one test probe for making contact with an electronic component, a chuck for moving the wafer and a rotatably mounted additional plate operatively connected to the chuck.

Abstract: A method and apparatus are provided for assembly of several semiconductor components on a target substrate. At least two semiconductor components are removed from a dispenser by a transfer device and simultaneously mounted in predefined target positions on the target substrate. The apparatus includes positioning units for positioning of the semiconductor components relative to the target substrate. Feed of the target substrate occurs by a first positioning unit into an assembly area where the semiconductor components are mounted on the target substrate in a first X direction, and feed of the transfer device with the semiconductor components occurs by a second positioning unit into the assembly area in a second Y direction. Both directions deviate from each other and the assembly area represents vicinity of the intersection point of the X and Y directions. Removal of the process target substrate from the assembly area continues its feed movement.

Abstract: A prober is described that is suitable for testing of semiconductor substrates under atmospheric conditions that deviate from ambient conditions. The prober includes a chuck for mounting of a semiconductor substrate and a probe holder for mounting of test tips for electrical contacting of the semiconductor substrate. The semiconductor substrate and test tips are arranged within a housing sealed relative to the surrounding atmosphere. The housing comprises two housing parts joined with a seal. The seal can be inflated with two different pressures and is less deformable at higher pressure. For testing of the semiconductor substrate, coarse positioning of the semiconductor substrate relative to the test tips occurs under atmospheric conditions and then fine positioning with the sealed housing and deformable seal before the lower deformability of the seal is produced at higher pressure in the seal and the semiconductor substrate is contacted by the test tips and tested.

Abstract: The invention relates to a system and a method for capturing images in a prober. According to the invention, the surface of a test object is illuminated in succession with light of a first, second and third color; and an image capturing device records a gray scale image of the surface; and a composite image is produced from the three gray scale images by means of an image evaluating device. The object of the invention is to qualitatively improve the image capturing, in order to raise the positioning accuracy by means of an improved display, as a result of which, finely structured test objects can be used. This object of the invention is achieved in that the lighting device is designed as a unit, which can be controlled by the image evaluating unit and which produces at least three colors and which exhibits at least one light emitting diode (LED) as the lighting means.

Abstract: A device for testing thin elements, such as wafers or individual substrates, while at the same time offering a facility for inspecting the reverse side of the thin elements is provided in which any deflection of the substrate as a consequence of high contact power of the probe card is avoided and which is also suitable for substrate diameters of 200 mm and above. The device includes a stable plate with a central opening positioned on the basic construction, a frame which can be moved and/or turned on the plate in an x/y direction and, if required, in a theta direction, a highly-rigid substrate support which can be mounted in the frame, and substrates which can be mounted on the substrate support, wherein the mounting is effected through a vacuum, using mechanical elements (clamping ring, clamping foil or other suitable clamping elements), gel pack pads, or adhesive etc.

Abstract: A wafer probe station is provided with a wafer chuck, a wafer fastened on the chuck by vacuum suction, and a probe needle arrangement above the wafer to test the wafer at high frequencies by contacting selected pads on the wafer and alternately pads on a calibration substrate also fastened on the wafer chuck. A procedure for reproduction of a calibration position of an aligned and afterwards displaced calibration substrate uses first and second measurement systems to calculate a new offset position of the calibration substrate after a second wafer is loaded on the wafer chuck. In a last step, the wafer chuck is driven by a 4axis manipulator stage to the new calibration position from the recent position.

Abstract: A probe station allows for effective EMI shielding of the passage of the probe through the wall of the housing of such probe station. The probe is freely movable in the X, Y and Z directions. The probe station comprises a housing having at least one aperture through which a probe can extend, a chuck for supporting a test device, the chuck being arranged inside the housing, at least one probe support for supporting a probe, the probe support being arranged relative to the housing such that a first portion of the probe extends into the housing through one of said apertures, at least one positioning mechanism enabling at least one of said probe and said chuck to move relative to the other, and is characterized in that at least one electrically conductive, elastic bellows is attached to the edge of an aperture which provides a variable passage for the probe.

Abstract: A device for testing thin elements, such as wafers or individual substrates, while at the same time offering a facility for inspecting the reverse side of the thin elements is provided in which any deflection of the substrate as a consequence of high contact power of the probe card is avoided and which is also suitable for substrate diameters of 200 mm and above. The device includes a stable plate with a central opening positioned on the basic construction, a frame which can be moved and/or turned on the plate in an x/y direction and, if required, in a theta direction, a highly-rigid substrate support which can be mounted in the frame, and substrates which can be mounted on the substrate support, wherein the mounting is effected through a vacuum, using mechanical elements (clamping ring, clamping foil or other suitable clamping elements), gel pack pads, or adhesive etc.