What is disclosed are methods and structures of an improved probe card assembly to inspect micro devices.

A probe card has an edge sensor. The edge sensor has a first needle and a second needle. The first needle and the second needle are in contact with each other when the first needle and a wafer are not in contact with each other, and the first needle and the second needle are not in contact with each other when the first needle and the wafer are in contact with each other. The probe card has a resistor connected between the first needle and the second needle.

The present invention relates to an improved probe for precisely positioning a probe tip at a measurement point. For this purpose, an image capturing device such as a camera may be firmly arranged at the probe. The image capturing device may capture image data around an area of the probe tip. The captured image data may be provided to a user during positioning the probe tip at the desired measuring point.

A measurement system is described. The measurement system comprises a measurement device and a probe unit, wherein the measurement device comprises an image analysis circuit or module. The probe unit comprises at least one image sensor, wherein the at least one image sensor is connected to the image analysis module in a signal transmitting manner. The image sensor is configured to capture an image of a measurement area being associated with a device under test. The image analysis module is configured to analyze the image captured and to determine at least one characteristic quantity of the image captured via an image analysis technique. The image analysis module is further configured to gather an information concerning a test position of the probe unit from the at least one characteristic quantity. Further, a method for operating a measurement system is described.

An electronic apparatus includes: an electronic module; and a flexible substrate electrically connected to the electronic module. The flexible substrate includes: a base film; a plurality of first contact pads arranged at one end on the base film in a first direction, and electrically connected to the electronic module; a plurality of second contact pads arranged at an other end on the base film in the first direction; a plurality of first wires arranged on the base film, and each electrically connecting one of the first contact pads and one of the second contact pads together; and a plurality of third contact pads arranged on the base film, each of the third contact pads being positioned along the first direction between one of the first contact pads and one of the second contact pads, and being electrically connected to one of the first wires.

A method for testing a semiconductor device comprises obtaining an alignment signal between one or more auxiliary pins of a test probe and one or more auxiliary pads of a test key of the semiconductor device before a probing test of the semiconductor device. The obtaining of the alignment signal comprises: performing a vertical alignment between the one or more auxiliary pins of the test probe and the one or more auxiliary pads of the test key; and gradually reducing a vertical distance between the one or more auxiliary pins of the test probe and the one or more auxiliary pads of the test key for bringing into an electrical contact until the alignment signal there-between satisfies an alignment condition.

Provided is a technique capable of improving test efficiency of semiconductor devices. A test apparatus includes a probe card having a plurality of measurement sites that contact with a plurality of semiconductor devices formed on a semiconductor wafer; a control unit configured to generate map information, probe-card form information, and contact-position information, the map information including position information and peculiar information of the semiconductor devices on the semiconductor wafer, the probe-card form information including arrangement information of the measurement sites, the contact-position information indicating a contact position that is a range of the semiconductor device tested at one time by the probe card based on constrained-condition information of limiting contact with the probe card; and a position control unit configured to control a relative position between the probe card and the semiconductor wafer based on the contact-position information.

The present disclosure provides a radio frequency thimble for production testing, in engagement connection with a test socket. The radio frequency thimble comprises: a housing, a probe, a light transmission member, and a color recognition sensor. The probe is located in a cavity of the housing. An accommodation hole is provided in the probe. The light transmission member is installed in the accommodation hole. A first end of the light transmission member is exposed at an end portion of the probe. A second end of the light transmission member is connected to the color recognition sensor. The light transmission member is used to transmit, to the color recognition sensor, light reflected by a reflective surface near the end portion of the probe. The color recognition sensor is used to recognize the color of the reflected light and determine whether the end portion of the probe is aligned with a terminal.

An electronic device according to various embodiments may include: a board; a communication circuit disposed on one face of the board and configured to process a communication signal in a designated frequency band; an antenna disposed on the one face of the board or inside the board; a connector disposed on another face of the board, and including a first contact electrically connected to a first signal path through which the communication circuit is configured to transmit a signal to the antenna in a first direction, and a second contact electrically connected to a second signal path through which the communication circuit configured to transmit a signal to the antenna in a second direction; and conductive pads disposed on the another face of the board spaced apart from the connector, and including at least two first pads corresponding to the first contact and at least two second pads corresponding to the second contact.

The present invention relates to an improved probe for precisely positioning a probe tip at a measurement point. For this purpose, an image capturing device such as a camera may be firmly arranged at the probe. The image capturing device may capture image data around an area of the probe tip. The captured image data may be provided to a user during positioning the probe tip at the desired measuring point.