Patent application number | Description | Published |
20090327986 | GENERATING RESPONSES TO PATTERNS STIMULATING AN ELECTRONIC CIRCUIT WITH TIMING EXCEPTION PATHS - Improved responses can be generated to scan patterns (e.g., test patterns) for an electronic circuit designs having timing exception paths by more accurately determining the unknown values that propagate to observation points in the circuit, where the response is captured. For instance, the responses are determined more accurately by analyzing the effect of sensitizing a timing exception path during each time frame associated with a scan pattern. Path sensitization can be determined based on observing whether values injected at starting points of the timing exception paths due to signal transitions and glitches propagate to their end points. The response can be updated by masking the affected end points and propagating unknown values further in the circuit to determine whether they are captured at observation points of the circuit. For instance, the methods and systems described herein may result in reduced unknowns, improved test coverage and test compression. | 12-31-2009 |
20100185908 | Speed-Path Debug Using At-Speed Scan Test Patterns - Speed-path debug techniques based on at-speed scan test patterns. Potential speed paths are identified based upon detected at-speed scan pattern failures and unknown X-value simulation. When the number of identified speed paths is large, the suspect speed paths are ranked. | 07-22-2010 |
20100274518 | Diagnostic Test Pattern Generation For Small Delay Defect - Methods of diagnostic test pattern generation for small delay defects are based on identification and activation of long paths passing through diagnosis suspects. The long paths are determined according to some criteria such as path delay values calculated with SDF (Standard Delay Format) timing information and the number of logic gates on a path. In some embodiments of the invention, the long paths are the longest paths passing through a diagnosis suspect and reaching a corresponding failing observation point selected from the failure log, and N longest paths are identified for each of such pairs. | 10-28-2010 |
20120174049 | TIMING-AWARE TEST GENERATION AND FAULT SIMULATION - Disclosed herein are exemplary methods, apparatus, and systems for performing timing-aware automatic test pattern generation (ATPG) that can be used, for example, to improve the quality of a test set generated for detecting delay defects or holding time defects. In certain embodiments, timing information derived from various sources (e.g. from Standard Delay Format (SDF) files) is integrated into an ATPG tool. The timing information can be used to guide the test generator to detect the faults through certain paths (e.g., paths having a selected length, or range of lengths, such as the longest or shortest paths). To avoid propagating the faults through similar paths repeatedly, a weighted random method can be used to improve the path coverage during test generation. Experimental results show that significant test quality improvement can be achieved when applying embodiments of timing-aware ATPG to industrial designs. | 07-05-2012 |
20140047404 | TIMING-AWARE TEST GENERATION AND FAULT SIMULATION - Disclosed herein are exemplary methods, apparatus, and systems for performing timing-aware automatic test pattern generation (ATPG) that can be used, for example, to improve the quality of a test set generated for detecting delay defects or holding time defects. In certain embodiments, timing information derived from various sources (e.g. from Standard Delay Format (SDF) files) is integrated into an ATPG tool. The timing information can be used to guide the test generator to detect the faults through certain paths (e.g., paths having a selected length, or range of lengths, such as the longest or shortest paths). To avoid propagating the faults through similar paths repeatedly, a weighted random method can be used to improve the path coverage during test generation. Experimental results show that significant test quality improvement can be achieved when applying embodiments of timing-aware ATPG to industrial designs. | 02-13-2014 |
20140246705 | Programmable Leakage Test For Interconnects In Stacked Designs - Aspects of the invention relate to techniques of testing interconnects in stacked designs for leakage defects. Logic “1” or “0” is first applied to one end of an interconnect during a first pulse. Then, logic value at the one end is captured, which triggered by an edge of a second pulse. The first pulse precedes the second pulse by a time period being selected from a plurality of delay periods. The plurality of delay periods is generated by a device shared by a plurality of interconnects. | 09-04-2014 |
20140347088 | Method and Circuit Of Pulse-Vanishing Test - Various aspects of the disclose techniques relate to techniques of testing interconnects in stacked designs. A single-pulse signal, generated by a first circuit state element on a first die, is applied to a first end of an interconnect and captured at a second end of the interconnect using a clock port of a second circuit state element on a second die. A faulty interconnect may cause the single-pulse signal too distorted to reach the threshold voltage of the second circuit element. | 11-27-2014 |
20150323600 | TIMING-AWARE TEST GENERATION AND FAULT SIMULATION - Disclosed herein are exemplary methods, apparatus, and systems for performing timing-aware automatic test pattern generation (ATPG) that can be used, for example, to improve the quality of a test set generated for detecting delay defects or holding time defects. In certain embodiments, timing information derived from various sources (e.g. from Standard Delay Format (SDF) files) is integrated into an ATPG tool. The timing information can be used to guide the test generator to detect the faults through certain paths (e.g., paths having a selected length, or range of lengths, such as the longest or shortest paths). To avoid propagating the faults through similar paths repeatedly, a weighted random method can be used to improve the path coverage during test generation. Experimental results show that significant test quality improvement can be achieved when applying embodiments of timing-aware ATPG to industrial designs. | 11-12-2015 |