Abstract: A hybrid probe design is presented that includes a torsion element and a bending element. These elements allow the probe to store the displacement energy as torsion or as bending. The probe includes a base, a torsion element, a bending element, and a tip. The probe elastically deforms to absorb the displacement energy as the probe tip contacts the DUT contact pad. The bending element absorbs some of the displacement energy through bending. Because the torsion element and the bending element join at an angle, a portion of the displacement energy is transferred to the torsion element causing it to twist (torque). The torsion element can also bend to accommodate the storage of energy through torsion and bending. Adjusting the position of a pivot can alter the probe's energy absorption characteristics. One or more additional angular elements may be added to change the energy absorption characteristics of the probe.

Abstract: A novel forked probe design for use in a novel probe card is presented that comprises a forked bending element that more efficiently stores displacement energy. Specifically, the novel probe card comprising a substrate and a forked probe connected to the substrate. The forked probe includes a base that is connected to the substrate and a forked bending element connected to the base, wherein the forked bending element comprises at least a first prong connected to a second prong through a prong connecting structure and a handle connected to the prong connecting structure. Connected to the first prong is the probe tip that is adapted to make contact with the DUT. Refinements to the probe card include that the first and second prongs are adapted to bend such that each prong elastically stores a portion of the displacement energy when the probe tip contacts the DUT. Also, the forked bending element may be manufactured using photolithography and using layered photolithography.

Abstract: A novel planarizing probe card for testing a semiconductor device is presented. The probe card is adapted to come into contact with a probe card mount that is in adjustable contact with the prober. The probe card includes a printed circuit board affixed to a stiffener and a probe head that is in electrical contact with the printed circuit board. The probe head also includes a plurality of probe contactor tips that define a first plane. The stiffener further contains at least two planarizing adjusters that comes into contact with the probe card mount. The adjusters may be actuated to alter the position of first plane. A surface of the semiconductor device under test may define a second plane, and the adjusters may be adjusted to position the first plane to be substantially parallel to the second plane.

Abstract: A novel method and structure for counter-balancing a lateral force exerted by a probe card onto a device under test (“DUT”) is disclosed. Many DUTs (particularly memory devices) are tested in parallel (i.e., many die at a time) and have unequal numbers of contact pads on top vs. bottom and/or right vs. left sides of the die. The probe card used to test the DUT would necessarily have an uneven distribution of probes that match the contact pads and, as a consequence, may exert a net lateral force on the DUT. By manipulating the individual characteristics of the individual probes, a probe card may be constructed that zeroes the lateral force. Characteristics such as the direction and stiffness of the individual probes can be varied to zero the net lateral force.

Abstract: A novel probe design is presented that comprises a plurality of pivots. These pivots allow the probe to store the displacement energy more efficiently. The novel probe comprises a substrate, and a probe connected to the substrate. The probe further comprises a base that is connected to the substrate, a bending element connected to the base and a probe tip connected to the bending element. In one embodiment, the plurality of pivots may be connected to the substrate such that a portion of the probe may contact the plurality of pivots while the probe tip contacts the device. In another embodiment, the plurality of pivots is connected to the bending element, such that the plurality of pivots may contact the substrate while the probe tip contacts the device. The bending element may also comprise a forked bending element connected to the base, such as the forked bending structure described in co-pending and related patent application Ser. No. 11/855,094.

Abstract: A novel forked probe design for use in a novel probe card is presented that comprises a forked bending element that more efficiently stores displacement energy. Specifically, the novel probe card comprising a substrate and a forked probe connected to the substrate. The forked probe includes a base that is connected to the substrate and a forked bending element connected to the base, wherein the forked bending element comprises at least a first prong connected to a second prong through a prong connecting structure and a handle connected to the prong connecting structure. Connected to the first prong is the probe tip that is adapted to make contact with the DUT. Refinements to the probe card include that the first and second prongs are adapted to bend such that each prong elastically stores a portion of the displacement energy when the probe tip contacts the DUT. Also, the forked bending element may be manufactured using photolithography and using layered photolithography.

Abstract: A novel device and method for repairing MEMS systems, including probe cards for use in semiconductor testing is disclosed. In one embodiment, a probe card for use with a diagnostic computer for testing semiconductor wafers comprises a substrate, a plurality of operational probes connected to the substrate, wherein the plurality of operational probes are adapted to make an electrical connection with the diagnostic computer and a plurality of replacement probes connected to the substrate, wherein the plurality of operational probes and the plurality of replacement probes are constructed in substantially the same manufacturing process. Also disclosed is a novel probe card that can be repaired.

Abstract: A novel device for testing semiconductor chips is disclosed. A benefit with all the embodiments described herein is that the device may experience zero (or near zero) nascent force. The device may be comprised of a printed circuit board (PCB) that has at least one PCB piercing structure, a probe contactor substrate that has at least one substrate piercing structure, wherein the substrate piercing structure is electrically connected to a probe contactor, and an interposer that has at least one electrical via made of a conductive elastomer. When the PCB piercing structure and the substrate piercing structure pierce the elastomer, the PCB becomes electrically connected to the probe contactor. Instead of the piercing structure, the PCB or the probe contractor substrate may be adhered to the elastomer by an adhesive, such that the PCB becomes electrically connected to the probe contactor. The PCB piercing structure and the substrate piercing structure may include a flying lead wire, soldered pins or pressed pins.

Abstract: A novel probe design is presented that increases a probe tolerance to stress fractures. Specifically, what is disclosed are three features increase stress tolerance. These features include a various union angle interface edge shapes, pivot cutouts and buffers.

Abstract: A novel hybrid probe design is presented that comprises a torsion element and a bending element. These elements allow the probe to store the displacement energy as torsion or as bending. The novel hybrid probe comprises a probe base, a torsion element, a bending element, and a probe tip. The probe elastically deforms to absorb the displacement energy as the probe tip contacts the DUT contact pad. The bending element absorbs some of the displacement energy through bending. Because the torsion element and the bending element join at an angle, a portion of the displacement energy is transferred to the torsion element causing it to twist (torque). The torsion element can also bend to accommodate the storage of energy through torsion and bending. Also, adjusting the position of a pivot can be manipulated to alter the energy absorption characteristics of the probe. One or more additional angular elements may be added to change the energy absorption characteristics of the probe.

Abstract: A novel information system for optimizing a phase in the lifespan of a probe card for semiconductor wafer testing, by receiving, storing, and disseminating probe card data over a network between the probe card customer and supplier. The system optimizes the ordering of a probe card by a customer, the manufacture of the probe card by a supplier, and the performance and repair of the probe card during its lifespan. The information system includes at least one server that is coupled to a network, where the server receives, stores, and disseminates historical information gathered during the order, manufacture, performance, and repair phases of many probe cards. An application on the server receives current information from a probe card customer or supplier, calculates a variety of metrics based on this information, compares the metric to historical data already stored in the system, and communicates the results of the comparison and the historical data to a system user.

Abstract: A probe card assembly has a probe contactor substrate having a plurality of probe contactor tips thereon and a probe card wiring board with an interposer disposed between the two. Support posts contacting the probe contactor substrate are vertically adjustable until secured by a locking mechanism which is coupled to the probe card wiring board. When the posts are secured in a fixed position, the position is one in which the plane of the plurality of probe contactor substrates is substantially parallel to a predetermined reference plane.

Abstract: A novel method for providing bump structures that can be formed by conventional stud bump bonding techniques is disclosed. The bumps can be arranged in a buttressed configuration that allows for substantial lateral and vertical contact loads, and substantial heights. A side-by-side configuration may be used to build a stacked bump contact that is substantially taller and stronger than is possible under current techniques. Other arrangements can be selected to optimize the load bearing capacity in any direction or combination of directions.

Abstract: The present invention relates to a probe for making electrical connection to a contact pad on a microelectronic device. A foot having a length, a thickness, a width, a proximal end, and a distal end, is connected to a substrate. The length of the foot is greater than its width. A torsion bar having a length, a width, a thickness, a proximal end, and a distal end, is connected to the distal end of the foot at the proximal end of torsion bar. The torsion bar lies in a first plane. A spacer having a length, a width, and a thickness, is connected to the distal end of the torsion bar. An arm having a length, a width, a thickness, a proximal end, and a distal end is connected to said spacer at the arms proximal end. The arm lies in a second plane and the second plane is in a different plane than the first plane. A first post having a top side and a bottom side is connected to the arm near the distal end of the arm. A tip is electrically connected to the top side of the post.

Abstract: A probe card assembly has a probe contractor substrate having a plurality of probe contractor tips thereon and a probe card wiring board with an interposer disposed between the two. Support posts contacting the probe contractor substrate are vertically adjustable until secured by a locking mechanism which is coupled to the probe card wiring board. When the posts are secured in a fixed position, the position is one in which the plane of the plurality of probe contractor substrates is substantially parallel to a predetermined reference plane.

Abstract: A novel structure for a probe card that comprises a deformable metal or other deformable material for detecting excess overdrive and a method for using the same are disclosed. This detection structure may be positioned on the substrate along the bending path of the probe, such that should the probe experience excess overdrive, then the detection structure will permanently deform where it is hit by any portion of the probe. Alternatively, the detection structure may be embedded in the substrate, and may also function as a fiducial for alignment detection. Inspection of the probe card, and specifically the detection structure, will reveal whether any probe has experienced excess overdrive. Should the inspection reveal that certain regions of the card experienced excess overdrive, this may indicate a planarity problem that affects production line yield.

Abstract: The present invention relates to a probe for making electrical connection to a contact pad on a microelectronic device. A foot having a length, a thickness, a width, a proximal end, and a distal end, is connected to a substrate. The length of the foot is greater than its width. A torsion bar having a length, a width, a thickness, a proximal end, and a distal end, is connected to the distal end of the foot at the proximal end of torsion bar. The torsion bar lies in a first plane. A spacer having a length, a width, and a thickness, is connected to the distal end of the torsion bar. An arm having a length, a width, a thickness, a proximal end, and a distal end is connected to said spacer at the arms proximal end. The arm lies in a second plane and the second plane is in a different plane than the first plane. A first post having a top side and a bottom side is connected to the arm near the distal end of the arm. A tip is electrically connected to the top side of the post.

Abstract: A novel probe card that comprises a set of fiducials and a method for using the same are disclosed. The set of fiducials comprises a first fiducial and a second fiducial fixed relative to the probe card substrate. Comparing the relative positions of the fiducials determines whether the probes are in proper alignment. This can be performed by the unaided eye or by using a low powered microscope. This novel probe card may also be used with computer vision alignment methods, thus enhancing the speed and accuracy of the computer vision method.

Abstract: A probe card assembly has a probe contactor substrate having a plurality of probe contactor tips thereon and a probe card wiring board with an interposer disposed between the two. Support posts contacting the probe contactor substrate are vertically adjustable until secured by a locking mechanism which is coupled to the probe card wiring board. When the posts are secured in a fixed position, the position is one in which the plane of the plurality of probe contactor substrates is substantially parallel to a predetermined reference plane.

Abstract: The present invention relates to a process for forming microstructures on a substrate. A plating surface is applied to a substrate. A first layer of photoresist is applied on top of the plating base. The first layer of photoresist is exposed to radiation in a pattern to render the first layer of photoresist dissolvable in a first pattern. The dissolvable photoresist is removed and a first layer of primary metal is electroplated in the area where the first layer of photoresist was removed. The remainder of the photoresist is then removed and a second layer of photoresist is then applied over the plating base and first layer of primary metal. The second layer of photoresist is then exposed to a second pattern of radiation to render the photoresist dissolvable and the dissolvable photoresist is removed. The second pattern is an area that surrounds the primary structure, but it does not entail the entire substrate. Rather it is an island surrounding the primary metal.