Abstract: A system and method for aligning a probe, such as a wafer-level test probe, with wafer contacts is disclosed. An exemplary method includes receiving a wafer containing a plurality of alignment contacts and a probe card containing a plurality of probe points at a wafer test system. A historical offset correction is received. Based on the historical offset correct, an orientation value for the probe card relative to the wafer is determined. The probe card is aligned to the wafer using the orientation value in an attempt to bring a first probe point into contact with a first alignment contact. The connectivity of the first probe point and the first alignment contact is evaluated. An electrical test of the wafer is performed utilizing the aligned probe card, and the historical offset correction is updated based on the orientation value.

Abstract: A system and method for aligning a probe, such as a wafer-level test probe, with wafer contacts is disclosed. An exemplary method includes receiving a wafer containing a plurality of alignment contacts and a probe card containing a plurality of probe points at a wafer test system. A historical offset correction is received. Based on the historical offset correct, an orientation value for the probe card relative to the wafer is determined. The probe card is aligned to the wafer using the orientation value in an attempt to bring a first probe point into contact with a first alignment contact. The connectivity of the first probe point and the first alignment contact is evaluated. An electrical test of the wafer is performed utilizing the aligned probe card, and the historical offset correction is updated based on the orientation value.

Abstract: A method of inserting dummy patterns includes providing a window area comprising a main pattern. The main pattern includes first patterns of a first type of features, and second patterns of a second type of features. The first and the second types are different types. The method further includes globally inserting first dummy patterns throughout the window area, wherein the first dummy patterns are dummy patterns of the first type of features; enlarging the main pattern to generate an enlarged main pattern, wherein the enlarged main pattern occupies an enlarged region of the window area; removing the portion of the first dummy patterns in the enlarged region from the first dummy patterns to generate first inversed dummy patterns; and combining the first patterns in the main pattern with the first inversed dummy patterns to generate first mask patterns for the first type of features.

Abstract: A method of inserting dummy patterns includes providing a window area comprising a main pattern. The main pattern includes first patterns of a first type of features, and second patterns of a second type of features. The first and the second types are different types. The method further includes globally inserting first dummy patterns throughout the window area, wherein the first dummy patterns are dummy patterns of the first type of features; enlarging the main pattern to generate an enlarged main pattern, wherein the enlarged main pattern occupies an enlarged region of the window area; removing the portion of the first dummy patterns in the enlarged region from the first dummy patterns to generate first inversed dummy patterns; and combining the first patterns in the main pattern with the first inversed dummy patterns to generate first mask patterns for the first type of features.

Abstract: An integrated circuit structure includes a semiconductor wafer; integrated circuit devices in the semiconductor wafer; and a plurality of test pads on a top surface of the semiconductor wafer and connected to the integrated circuit devices. Test pads are grouped in pairs, with the test pads in a same pair are interconnected.

Abstract: A testline structure made for integrated circuit tests is presented. The structure includes an array of testline pads formed in the scribe line area or integrated circuit die area on a semiconductor substrate, a plurality of test devices formed under the pads area, and a select circuit selectively connecting one of the test devices. The testline structure of this invention enables access to a large number of test devices through the same number of pads as on a conventional testline and can be employed to conduct parametric, reliability, and functional tests on the same. A source measurement unit (SMU) in a conventional integrated circuit tester is employed to sense and force predetermined test conditions on the test device terminals and conduct accurate Kelvin tests on the selected device. A method of using this testline structure is also presented.

Abstract: An integrated circuit structure includes a semiconductor wafer; integrated circuit devices in the semiconductor wafer; and a plurality of test pads on a top surface of the semiconductor wafer and connected to the integrated circuit devices. Test pads are grouped in pairs, with the test pads in a same pair are interconnected.

Abstract: A method of inserting dummy patterns includes providing a window area comprising a main pattern. The main pattern includes first patterns of a first type of features, and second patterns of a second type of features. The first and the second types are different types. The method further includes globally inserting first dummy patterns throughout the window area, wherein the first dummy patterns are dummy patterns of the first type of features; enlarging the main pattern to generate an enlarged main pattern, wherein the enlarged main pattern occupies an enlarged region of the window area; removing the portion of the first dummy patterns in the enlarged region from the first dummy patterns to generate first inversed dummy patterns; and combining the first patterns in the main pattern with the first inversed dummy patterns to generate first mask patterns for the first type of features.

Abstract: A testline structure made for integrated circuit tests is presented. The structure includes an array of testline pads formed in the scribe line area or integrated circuit die area on a semiconductor substrate, a plurality of test devices formed under the pads area, and a select circuit selectively connecting one of the test devices. The testline structure of this invention enables access to a large number of test devices through the same number of pads as on a conventional testline and can be employed to conduct parametric, reliability, and functional tests on the same. A source measurement unit (SMU) in a conventional integrated circuit tester is employed to sense and force predetermined test conditions on the test device terminals and conduct accurate Kelvin tests on the selected device. A method of using this testline structure is also presented.

Abstract: A network based integrated circuit testline generating system and method of using the same is described. The system includes a user interface for generating and submitting requests which specify types and configurations of needed testlines for device parametric test. A testline generator receives the requests and creates a layout data base which includes layout information of needed testlines.

Abstract: A method and structure is disclosed to measure spacing and misalignment of features in semiconductor integrated circuits. Three equally spaced, parallel first level conductive lines are formed on a first insulating layer with staircase patterns projecting both out of and into the inner edges of the outer lines. A second insulating layer is deposited and step contact vias are opened through the second insulating layer over the steps of the staircase patterns. The inner edge of the step contact via coincides with the inner edge of the step. Contact pad vias are opened through the second insulating layer over the outer lines and the step contact vias and the contact pad vias are filled with conductive material. A second level conductive line is formed over the second insulating layer parallel to said first level conductive lines and above the central first level conductive line.