An apparatus is provided. The apparatus includes a stage and a plate disposed on the stage. The apparatus further includes a pressure film sensor that is formed on the plate and configured to detect a contact force between a plurality of needles on a probe head of a probe card and the pressure film sensor. The apparatus still includes a distance detector that is configured to detect a distance between the pressure film sensor and the needles. In addition, the apparatus includes an adjustment driver that is configured to adjust the probe card based on the detected contact force of the pressure film sensor.

Disclosed is a probe card for testing a wafer. The probe card includes a substrate and a block including an insulation portion and a conducting portion disposed on the insulation portion. Here, the insulation portion includes a via and a probe pin which comes into contact with an object to be tested. The conducting portion includes a contact point electrically connected to the substrate and a conducting pattern passing through the via and electrically connecting the contact point to the probe pin. A pitch between a plurality of such probe pins is smaller than a pitch between a plurality of such contact points. The block includes a plurality of unit blocks. The plurality of unit blocks each include the insulation portion and the conducting portion, and at least parts of the insulation portions of the unit blocks are arranged while being spaced apart from each other.

Proposed is an anodic aluminum oxide structure made of anodic aluminum oxide and, more particularly, is an anodic aluminum oxide structure that minimizes damage to a material in the vicinity of a conductor and prevents a problem of delamination between the conductor and a member existing thereon.

An inspection apparatus includes: a probe card having a probe to be in contact with an object to be inspected; an upper module having a mounting portion on which the object to be inspected is mounted; a movement mechanism that is configured to support the upper module to be liftable and lowerable and that is able to move the upper module in a horizontal direction; and a lifting and lowering mechanism that is provided under the movement mechanism and that is able to push up the upper module toward the probe card, wherein an axis passing through a point of action of a pushing force when the lifting and lowering mechanism pushes up the upper module and an axis passing through a point of action of a load received by the probe card are arranged at positions to be common.

Proposed is a probe card. The probe card according to the present disclosure includes: a circuit board; a probe head having a guide plate, and through which a plurality of probes pass; and a connection member electrically connecting the circuit board and the probes to each other, wherein an insulating part of the connection member and the guide plate are made of an anodic aluminum oxide film formed by anodizing a metal as a base material.

A probe card and a wafer testing assembly thereof are provided. The wafer testing assembly includes a printed circuit board, a space transformer, a plurality of copper pillars and a plurality of strengthening structure units. The printed circuit board includes a bottom surface and a plurality of first contacts arranged on the bottom surface. The space transformer includes a top surface and a plurality of second contacts. The second contacts are arranged on the top surface and corresponding to the first contacts. The copper pillars are respectively arranged between the first contacts and the second contacts. Two ends of each of the copper pillars are respectively electrically connected to the first contacts and the second contacts. The strengthening structure units are arranged on the bottom surface of the printed circuit board and respectively surrounding the copper pillars.

The disclosed apparatus may include support portions, a frame (such as a base) configured to maintain the support portions in a spaced-apart configuration, a sample holder configured to receive a sample, and a probe assembly including micromanipulators configured to position one or more probes in contact with the sample. The sample holder may rotate between the support portions, and the probe assembly may rotate with the sample holder so that the one or more probes may maintain contact with a sample in the sample holder as the sample holder is rotated, for example, to expose a portion of the sample for processing. Various other methods, systems, and computer-readable media are also disclosed.

A circuit board includes an insulating substrate having a first surface and a second surface opposite to the first surface, a solid conductor located inside the insulating substrate, a first via conductor connected to the solid conductor from a side of the first surface, and a second via conductor connected to the solid conductor from a side of the second surface. The solid conductor has a cutout that intersects a line segment that connects a node of the first via conductor and a node of the second via conductor to each other.

A semiconductor test apparatus according to the present disclosure includes: a stage on which a wafer is to be mounted; a pressurizing wall disposed on a surface of a probe card opposing the stage, extending toward the stage, and having an opening; a mark disposed on a lower surface of the pressurizing wall opposing the stage; a probe disposed in the opening; an air tube to force air into the opening; a detector to detect first spacing between a tip of the probe and the mark; and a controller to control second spacing between the wafer and the lower surface of the pressurizing wall based on the first spacing, wherein, when an electrical property of each of chips of the wafer is measured, the second spacing is controlled to be predetermined spacing by the controller, and the air is forced into the opening through the air tube.

A method for releasing contact between probes and a substrate is provided. In a state where the probes are pressed against the substrate to be in contact with the substrate, a pressure is reduced in an inspection space that is surrounded by a substrate support having thereon the substrate, a tubular member attracting and holding the substrate support through a seal member, and a frame to which a probe card is fixed. The method includes raising an alignment mechanism to a predetermined position to be close to the substrate support, subsequently stopping the pressure reduction of the inspection space and supporting the substrate support by the alignment mechanism located at the predetermined position while preventing release of the contact, subsequently lowering the alignment mechanism supporting the substrate support to release the contact, and subsequently stopping the attracting and holding of the substrate support by the tubular member.