Abstract: Disclosed is, a method for detecting electrical defects on test structures of a semiconductor die. The semiconductor die includes a plurality of electrically-isolated test structures and a plurality of non-electrically-isolated test structures. Voltages are established for the plurality of electrically-isolated test structures. These voltages are different than the voltages of the plurality of non-electrically-isolated test structures. A region of the semiconductor die is continuously inspected in a first direction thereby obtaining voltage contrast data indicative of whether there are defective test structures. The voltage contrast data is analyzed to determine whether there are one or more defective test structures.

Abstract: Disclosed is a semiconductor die having a lower test structure formed in a lower metal layer of the semiconductor die. The lower conductive test structure has a first end and a second end. The first end is coupled to a predetermined voltage level. The semiconductor die also includes an insulating layer formed over the lower metal layer. The die further includes an upper test structure formed in an upper metal layer of the semiconductor die. The upper conductive test structure is coupled with the second end of the lower conductive test structure. The upper metal layer is formed over the insulating layer. In a specific implementation, the first end of the lower test structure is coupled to ground. In another embodiment, the semiconductor die also includes a substrate and a first via coupled between the first end of the lower test structure and the substrate. In yet another aspect, the lower test structure is an extended metal line, and the upper test structure is a voltage contrast element.

Abstract: Disclosed is a semiconductor die having a lower test structure formed in a lower metal layer of the semiconductor die. The lower conductive test structure has a first end and a second end. The first end is coupled to a predetermined voltage level. The semiconductor die also includes an insulating layer formed over the lower metal layer. The die further includes an upper test structure formed in an upper metal layer of the semiconductor die. The upper conductive test structure is coupled with the second end of the lower conductive test structure. The upper metal layer is formed over the insulating layer. In a specific implementation, the first end of the lower test structure is coupled to ground. In another embodiment, the semiconductor die also includes a substrate and a first via coupled between the first end of the lower test structure and the substrate. In yet another aspect, the lower test structure is an extended metal line, and the upper test structure is a voltage contrast element.

Abstract: Disclosed is a method of inspecting a sample. The sample is illuminated with an incident beam, thereby causing voltage contrast within structures present on the sample. Voltage contrast is detected within the structures. Information from the detected voltage contrast is stored, and position data concerning the location of features corresponding to at least a portion of the stored voltage contrast information is also stored. In a specific embodiment, the features represent electrical defects present on the sample. In another embodiment, the stored position data is in the form of a two dimensional map. In another aspect, the sample is re-inspected and the stored position data is used in analyzing data resulting from the re-inspection.

Abstract: Disclosed is a method of inspecting a sample. At least a portion of the sample is illuminated. Signals received from the illuminated portion are detected, and the detected signals are processed to find defects present on the sample. The processing of the detected signals is optimized, at least in part, based upon results obtained from voltage contrast testing. In one implementation, the illumination is an optical illumination. In another embodiment, the processing comprises automated defect classification, and setup of the automated classification is optimized using the results obtained from voltage contrast testing. In another implementation, the results relate to a probability that a feature present on the sample represents an electrical defect.

Abstract: A memory system is provided with a simple flexible control arrangement for assigning locations in an alternate memory as replacements for previously identified defective fault areas in main memory. The assignment of the replacement locations in the alternate memory is made on a selective basis taking into consideration the defect status of other failure independent bit positions of a data word and the power of the ECC code which is used in connection with the memory system. A relatively small writable index, which is addressed by a subset of the main memory address signals, provides a partial address and control fields to the alternate memory in accordance with control data transferred from the host system.

Abstract: Disclosed is a test site for an integrated circuit chip including a CCD register. Two serial CCD registers are spaced from each other at incrementally variable intervals. The first register receives a serial bit stream having a first binary value while the second serial register receives a bit stream having a second binary value. Data is transferred in parallel from the second register to determine the point at which the spacing between the two registers is sufficiently close to permit undesirable cross-talk.

Abstract: An electrical defect density monitor for semiconductor device fabrication utilizing a silicide of a formed transitional metal (such as platinum silicide) on a surface of a silicon substrate as a resistor in parallel with the resistance of the underlying substrate, including diffused regions, to improve measurement sensitivity of high sheet resistivity areas. The measurement can be employed for measuring the integrity of diffused regions and/or of dielectric coatings.

Abstract: A semiconductor defect monitoring structure employs a series of electrically testable serpentine stripe patterns having different widths and spacing in order to determine the distribution of the density of defects by size. Metal stripe patterns are superposed and rotated 90.degree. with respect to diffusion stripe patterns in a semiconductor wafer. A set of four field effect transistor devices are connected to each stripe pattern in such a way that tests may be made for all defects without interference between adjacent patterns. The defect monitoring structure helps to determine defects such as opens in diffusion and metallization, shorts in metallization, shorts in diffusion, pinholes in a thin oxide, and pinholes in a thick oxide.