Abstract: The invention generally relates to a method and device for contacting contact areas (22) with probe tips (18) in a tester. The contact areas (22), which are arranged on a substrate (6), and the probe tips (18) are positioned relative to each other and then brought in contact with each other by an advancing motion. In order to detect a secure contact for each of the probe tips (18), the contacting between the probe tips (18) and the contact areas (22) is observed from at least two observation directions (34), which include an observation angle ? in a range of 0 to 180°.

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: The invention generally relates to a method and device for contacting contact areas (22) with probe tips (18) in a tester. The contact areas (22), which are arranged on a substrate (6), and the probe tips (18) are positioned relative to each other and then brought in contact with each other by an advancing motion. In order to detect a secure contact for each of the probe tips (18), the contacting between the probe tips (18) and the contact areas (22) is observed from at least two observation directions (34), which include an observation angle ? in a range of 0 to 180°.

Abstract: A method is provided for increasing the accuracy of the positioning of a first object relative to a second object. The method overcomes the disadvantageous influence of thermal drift between a first and a second object during a positioning of a first object on a second object. The method finds applications in manufacturing, for example, in the manufacturing of semiconductor components. The method utilizes recognition of structures on the second object which have a minimum structure width. At a first instant, using one recognition procedure, the first object is positioned on the second object in a desired position. The relative displacement of the two objects is determined at the first instant and on at least one subsequent instant. A second recognition procedure may be used for this purpose. The second recognition procedure may have a resolution accuracy which is different than the resolution accuracy of the first resolution procedure. The second recognition procedure may be a pattern recognition method.

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 probe holder in which the probe needle has a slight horizontal offset under the action of a vertical force comprises a probe holder for a probe needle, wherein the holder is adapted, for fastening and electrical contact-connection, on a carrier device of a test apparatus and has a holder arm having a needle holder at the free end thereof to fasten the probe needle, and a fastening arm for connecting the holder arm to the carrier device. The holder arm and fastening arm are connected to one another by a parallel guide whereby horizontal offset of the needle tip on account of external forces can be reduced or even prevented making it easier for the probe needle to carry out a vertical yielding movement, with almost no rotation of the probe needle about a horizontal axis.

Abstract: A method is provided for increasing the accuracy of the positioning of a first object relative to a second object. The method overcomes the disadvantageous influence of thermal drift between a first and a second object during a positioning of a first object on a second object. The method finds applications in manufacturing, for example, in the manufacturing of semiconductor components. The method utilizes recognition of structures on the second object which have a minimum structure width. At a first instant, using one recognition procedure, the first object is positioned on the second object in a desired position. The relative displacement of the two objects is determined at the first instant and on at least one subsequent instant. A second recognition procedure may be used for this purpose. The second recognition procedure may have a resolution accuracy which is different than the resolution accuracy of the first resolution procedure. The second recognition procedure may be a pattern recognition method.

Abstract: In a method and an apparatus for measuring temperature-controlled electronic components in a test station, a component to be measured is held and positioned using a chuck, has a temperature-controlled and directed fluid flow applied to it and is electrically contact-connected using probes and is measured. The setting of the temperature of the component to the temperature at which the measurement is intended to be carried out is effected solely using a directed fluid flow at a defined temperature.

Abstract: A probe for temporarily electrically contacting a solar cell for testing purposes, has at least one elastic, electrically conductive contact element for producing the electrical contact, at least one reference sensor for indicating a distance of the contact element to an external reference surface using an electrical signal of the reference sensor, and a mounting plane to which the tip of the contact element is oriented. The probe ensures a secure electrical contact of the solar cell in a testing station with minimal mechanical stress, and is also suitable for use in an industrial continuous production method.

Abstract: In a method and devices for forming a temporary electrical contact to a solar cell for testing purposes, probes form a contact to the electrode terminals of a solar cell held by a sample holder. The probes are held by a probe holder and exhibit an elastic, electrically conductive contact element and at least one reference sensor. In order to form a contact, the solar cell and the probes are positioned in relation to each other, and then a probe is placed on an electrode terminal of the solar cell. To this end, a feed motion of the probe is carried out until a reference sensor of the probe generates a reference signal upon reaching a predefined distance. Then the feed motion is continued by a predefined path that goes beyond the contact element making contact with the electrode terminal, in order to carry out an overtravel.

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: A method is provided for increasing the accuracy of the positioning of a first object relative to a second object. The method overcomes the disadvantageous influence of thermal drift between a first and a second object during a positioning of a first object on a second object. The method finds applications in manufacturing, for example, in the manufacturing of semiconductor components. The method utilizes recognition of structures on the second object which have a minimum structure width. At a first instant, using one recognition procedure, the first object is positioned on the second object in a desired position. The relative displacement of the two objects is determined at the first instant and on at least one subsequent instant. A second recognition procedure may be used for this purpose. The second recognition procedure may have a resolution accuracy which is different than the resolution accuracy of the first resolution procedure. The second recognition procedure may be a pattern recognition method.

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: A probe holder in which the probe needle has a slight horizontal offset under the action of a vertical force comprises a probe holder for a probe needle, wherein the holder is adapted, for fastening and electrical contact-connection, on a carrier device of a test apparatus and has a holder arm having a needle holder at the free end thereof to fasten the probe needle, and a fastening arm for connecting the holder arm to the carrier device. The holder arm and fastening arm are connected to one another by a parallel guide whereby horizontal offset of the needle tip on account of external forces can be reduced or even prevented making it easier for the probe needle to carry out a vertical yielding movement, with almost no rotation of the probe needle about a horizontal axis.

Abstract: In a method and an apparatus for measuring temperature-controlled electronic components in a test station, a component to be measured is held and positioned using a chuck, has a temperature-controlled and directed fluid flow applied to it and is electrically contact-connected using probes and is measured. The setting of the temperature of the component to the temperature at which the measurement is intended to be carried out is effected solely using a directed fluid flow at a defined temperature.

Abstract: An apparatus for testing substrates reduces the area required and the costs which arise with the testing of substrates, in particular semiconductor wafers, during the production process. The apparatus includes testing arrangements comprising a chuck, a chuck drive, control electronics, probe or probe board holding means with a handling system, a substrate magazine station and an alignment station. The testing arrangements include at least two testing arrangements, both of which are all jointly operatively connected to the handling system, the substrate magazine station and the alignment station.

Abstract: A method of contacting a contact area with the tip of a contact needle (contact tip) in a prober and the arrangement of such a prober, is based on the object of ensuring reliable contacting and direct observation of the establishment of the contact between the contact tip and the contact area when contacting contact pads of small dimensions. The prober substantially includes a base frame with a movement device including a clamping fixture for receiving a semiconductor wafer and also contact needles, which are arranged opposite the free surface of the semiconductor wafer. The contacting of the contact tips initially requires a horizontal positioning of the semiconductor wafer, so that the contact area and the contact tip are one above the other and at a distance from each other, and subsequently moving vertically in the direction of the contact tip, until a contact of the contact tips with the contact area is established.

Abstract: A test apparatuss for testing substrates at low temperatures has a chuck, which can be displaced in the working area by means of a chuck drive, the temperature of which can be controlled using heating and cooling means. The chuck has a receiving surface for receiving a test substrate and holding means for fixing a substrate carrier which receives the test substrate. Spatially and thermally defined test conditions are maintained with minimal energy and labor costs both at room temperatures and at low temperatures. This is achieved by providing a vacuum chamber which surrounds the working area of the chuck. The chuck is on one side thermally decoupled from the uncooled chuck drive and on the other side is thermally connected in a releasable manner to the test substrate. The cooled chuck and the cooled test substrate are shielded from the thermal radiation of the surrounding uncooled assemblies by means of a directly cooled thermal radiation shield.

Abstract: The invention, which relates to a test apparatus with loading device which has a chuck, which is provided with a bearing surface for a test substrate and with a chuck drive, by means of which the chuck can be displaced with a working area, and which has a receiving means for receiving test substrates, which can be displaced from a working area of the chuck to a receiving position outside the working area, is based on the object of increasing the accuracy of the movement of the chuck. Moreover, in the case of test apparatus with a controlled atmosphere, a further object is to prevent the chuck from being exposed to the open-air atmosphere.