Abstract: In embodiments of the disclosed technology, diagnosis of a circuit is performed using compactor signatures (a technique referred to herein as “signature-based diagnosis”). Signature-based diagnosis typically does not require a test step that bypasses the compactor. Compactor signatures can be read from a compactor on a per-pattern basis, and an expected signature can be loaded into a compactor while an actual signature is being read from the compactor. Error functions can be used to describe relationships between errors in scan cell values and per-pattern compactor signatures, and the functions can be used to help generate a list of fault candidates in a circuit design.

Abstract: A built-in self-test (BIST) circuit is disclosed that allows high fault coverage. Additionally, a method is disclosed for implementing the BIST circuit. In one aspect, the BIST circuit includes a plurality of scan chains that receive test patterns used in testing the integrated circuit. A pseudo random pattern generator provides test patterns to the scan chains. Weight select logic is positioned between the scan chains and the pseudo random pattern generator and controls the weightings of the test patterns that are loaded in the scan chains. In another aspect, the weight select logic can switch the weightings of the test patterns on a per-scan-cell basis. Thus, as the scan chains are loading, the weight select logic can effectively switch between test patterns being loaded into the scan chains.

Abstract: A method and apparatus for testing an integrated circuit using built-in self-test (BIST) techniques is described. In one aspect, a BIST circuit comprises a scan monitor with hold logic and a signature generation element. The hold logic is operable to suspend signature generation in the signature generation element at any desired point in the test sequence. In some embodiments, the hold logic comprises a scan-loadable signature hold flip-flop which allows the logic BIST controller to be restarted from any selected pattern within a pattern range and to run to any subsequent pattern. The BIST session can be run incrementally, testing and reporting intermediate MISR signatures. External automatic testing equipment can suspend signature generation at selected times during a BIST session to prevent tainting of the signature generation element. The hold logic also may comprise a rotating hold ring to suspend signature generation during predetermined shift cycles.

Abstract: A built-in self-test (BIST) circuit is disclosed that allows high fault coverage. Additionally, a method is disclosed for implementing the BIST circuit. In one aspect, the BIST circuit includes a plurality of scan chains that receive test patterns used in testing the integrated circuit. A pseudo random pattern generator provides test patterns to the scan chains. Weight select logic is positioned between the scan chains and the pseudo random pattern generator and controls the weightings of the test patterns that are loaded in the scan chains. In another aspect, the weight select logic can switch the weightings of the test patterns on a per-scan-cell basis. Thus, as the scan chains are loading, the weight select logic can effectively switch between test patterns being loaded into the scan chains.

Abstract: Various new and non-obvious apparatus and methods for testing an integrated circuit are disclosed. In one exemplary embodiment, a control point is selected in an integrated circuit design. Scan cells in the integrated circuit design are identified that can be loaded with a set of fixed values in order to propagate a desired test value to the control point. The integrated circuit design is modified to include circuit components configured to load the scan cells in the integrated circuit design with the set of fixed values during a test phase. The one or more scan cells may be identified by justifying the control point to the scan cells, thereby determining values that the scan cells must output in order to drive the control point to the desired test value. Computer-readable media comprising computer-executable instructions for causing a computer to perform any of the disclosed methods or computer-readable design information for any of the disclosed apparatus are also disclosed.

Abstract: Various new and non-obvious apparatus and methods for testing an integrated circuit are disclosed. In one exemplary embodiment, a control point is selected in an integrated circuit design. Scan cells in the integrated circuit design are identified that can be loaded with a set of fixed values in order to propagate a desired test value to the control point. The integrated circuit design is modified to include circuit components configured to load the scan cells in the integrated circuit design with the set of fixed values during a test phase. The one or more scan cells may be identified by justifying the control point to the scan cells, thereby determining values that the scan cells must output in order to drive the control point to the desired test value. Computer-readable media comprising computer-executable instructions for causing a computer to perform any of the disclosed methods or computer-readable design information for any of the disclosed apparatus are also disclosed.

Abstract: A built-in-self-test (BIST) circuit is discussed for selecting tristate nets with substantially uniform distribution using a tristate testing control device (TTCD). The circuit allows the deterministic testing of tristate nets in the context of pseudo-random BIST. A feedback shift register is described that activates a single tristate or set of tristate at a time in order to avoid bus contention. Another TTCD embodiment uses a counter and decoder. A test mode switching unit (TMSU) coupled between the TTCD and the tristate net selects test or functional mode for tristate enables. Parallel multiplexers are discussed as one embodiment of a TMSU. Another TMSU embodiment describes even better test coverage. A method, which may be performed on a distributed computer system, is discussed for identifying tristate nets within a net-list and adding a TTCD and a TMSU to the net-list.

Abstract: A built-in-self-test (BIST) circuit is discussed for selecting tristate nets with substantially uniform distribution using a tristate testing control device (TTCD). The circuit allows the deterministic testing of tristate nets in the context of pseudo-random BIST. A feedback shift register is described that activates a single tristate or set of tristate at a time in order to avoid bus contention. Another TTCD embodiment uses a counter and decoder. A test mode switching unit (TMSU) coupled between the TTCD and the tristate net selects test or functional mode for tristate enables. Parallel multiplexers are discussed as one embodiment of a TMSU. Another TMSU embodiment describes even better test coverage. A method, which may be performed on a distributed computer system, is discussed for identifying tristate nets within a net-list and adding a TTCD and a TMSU to the net-list.

Abstract: A method and apparatus for testing an integrated circuit using built-in self-test (BIST) techniques is described. In one aspect, a BIST circuit comprises a scan monitor with hold logic and a signature generation element. The hold logic is operable to suspend signature generation in the signature generation element at any desired point in the test sequence. In some embodiments, the hold logic comprises a scan-loadable signature hold flip-flop which allows the logic BIST controller to be restarted from any selected pattern within a pattern range and to run to any subsequent pattern. The BIST session can be run incrementally, testing and reporting intermediate MISR signatures. External automatic testing equipment can suspend signature generation at selected times during a BIST session to prevent tainting of the signature generation element. The hold logic also may comprise a rotating hold ring to suspend signature generation during predetermined shift cycles.