Disclosed is a guide plate for a probe card guiding a probe pin of the probe card and a manufacturing method thereof, and the probe card having the same. Particularly, the guide plate and a manufacturing method thereof, and the probe card securing reliability of the probe card are intended to be provided, wherein probe pins are easily inserted into the guide plate, and pin insertion holes into which the probe pins are inserted are precisely formed in a small size.

A packaged electronic device has a die with a load circuit, a resistor and an analog to digital converter (ADC). The resistor is coupled between a supply node of the die and a power input of the load circuit. The ADC has a first input coupled to a first terminal of the resistor, and a second input coupled to a second terminal of the resistor to measure a voltage across the resistor while a supply voltage is applied to the supply node to determine a load current conducted by the load circuit. A method of manufacturing a packaged electronic device includes wafer processing to fabricate the load circuit, the resistor and the ADC on or in a die area of the wafer with the resistor coupled between the power input of the load circuit and the supply node of the die area.

A packaged electronic device has a die with a load circuit, a resistor and an analog to digital converter (ADC). The resistor is coupled between a supply node of the die and a power input of the load circuit. The ADC has a first input coupled to a first terminal of the resistor, and a second input coupled to a second terminal of the resistor to measure a voltage across the resistor while a supply voltage is applied to the supply node to determine a load current conducted by the load circuit. A method of manufacturing a packaged electronic device includes wafer processing to fabricate the load circuit, the resistor and the ADC on or in a die area of the wafer with the resistor coupled between the power input of the load circuit and the supply node of the die area.

A skate on a tip of a probe for testing electrical devices is a reduced thickness probe tip contact. Such a skate can advantageously increase contact pressure, but it can also undesirably reduce probe lifetime due to rapid mechanical wear of the skate. Here multilayer skate probes are provided where the overall shape of the probe tip is a smooth curved surface, as opposed to the conventional fin-like skate configuration. The skate layer is the most mechanically wear-resistant layer in the structure, so abrasive processing of the probe tip leads to a probe skate defined by the skate layer. The resulting probes provide the advantage of increased contact pressure without the disadvantage of reduced lifetime.

A skate on a tip of a probe for testing electrical devices is a reduced thickness probe tip contact. Such a skate can advantageously increase contact pressure, but it can also undesirably reduce probe lifetime due to rapid mechanical wear of the skate. Here multilayer skate probes are provided where the overall shape of the probe tip is a smooth curved surface, as opposed to the conventional fin-like skate configuration. The skate layer is the most mechanically wear-resistant layer in the structure, so abrasive processing of the probe tip leads to a probe skate defined by the skate layer. The resulting probes provide the advantage of increased contact pressure without the disadvantage of reduced lifetime.

A method is provided for producing a printed circuit board including at least one conductor element, which extends between connection points in the printed circuit board. In order to increase the productivity of a known method for producing a printed circuit board including at least one conductor element, which extends between connection points in the printed circuit board, the method comprises the following steps: Step A: providing a mold having at least one receptacle for a conductor element; Step B: arranging a conductor element in the receptacle of the mold; Step C: connecting the conductor element arranged in the receptacle of the mold to an electrically conductive sheetlike element at positions of the intended connection points; Step D: embedding the conductor element, which is connected to the electrically conductive sheetlike element, into insulating material; and Step E: working out the connection points from the electrically conductive sheetlike element.

An integrated circuit (IC) device, such as a wafer, die, or the like, includes a viscoelastic pad upon a contact. The viscoelastic pad includes a viscoelastic material and an electrically conductive material within the viscoelastic material. The viscoelastic pad provides for a probe needle of an IC device tester to be electrically connected to the IC device contact without the probe needle directly contacting the IC device contact. The viscoelastic pad may be probed multiple instances by the probe needle and may be washed or otherwise removed from the IC device after testing is completed. The viscoelastic pad may be formed upon the IC device by forming the viscoelastic material within a mask, aligning the viscoelastic pad to the IC device contact, and ejecting the viscoelastic material from the mask upon the IC device contact.

An integrated circuit (IC) device, such as a wafer, die, or the like, includes a viscoelastic pad upon a contact. The viscoelastic pad includes a viscoelastic material and an electrically conductive material within the viscoelastic material. The viscoelastic pad provides for a probe needle of an IC device tester to be electrically connected to the IC device contact without the probe needle directly contacting the IC device contact. The viscoelastic pad may be probed multiple instances by the probe needle and may be washed or otherwise removed from the IC device after testing is completed. The viscoelastic pad may be formed upon the IC device by forming the viscoelastic material within a mask, aligning the viscoelastic pad to the IC device contact, and ejecting the viscoelastic material from the mask upon the IC device contact.

A test socket for a device under test (DUT) is disclosed in several embodiments. One embodiment shows a test socket base (16) with apertures (30) for insertion of test pin insert blocks (28). The blocks are inserted topin or bottomin and are provided with registration bosses 80 and teeth 92 or other means for maintaining registration. Blocks are provided with dielectric constants to achieve different frequency response relative to other pins. To achieve great EMI and cross talk isolation, the socket may be made of aluminum with hard anodize coating to insulate test pins (32) from the housing.

A test socket for a device under test (DUT) is disclosed in several embodiments. One embodiment shows a test socket base (16) with apertures (30) for insertion of test pin insert blocks (28). The blocks are inserted topin or bottomin and are provided with registration bosses 80 and teeth 92 or other means for maintaining registration. Blocks are provided with dielectric constants to achieve different frequency response relative to other pins. To achieve great EMI and cross talk isolation, the socket may be made of aluminum with hard anodize coating to insulate test pins (32) from the housing.