Patent application number | Description | Published |
20090249147 | FAULT DIAGNOSIS OF COMPRESSED TEST RESPONSES - Methods, apparatus, and systems for diagnosing failing scan cells from compressed test responses are disclosed herein. For example, in one nonlimiting exemplary embodiment, at least one error signature comprising multiple bits (including one or more error bits) is received. Plural potential-error-bit-explaining scan cell candidates are evaluated using a search tree. A determination is made as to whether one or more of the evaluated scan cell candidates explain the error bits in the error signature and thereby constitute one or more failing scan cells. An output is provided of any such one or more failing scan cells determined. Tangible computer-readable media comprising computer-executable instructions for causing a computer to perform any of the disclosed methods are also provided. Tangible computer-readable media comprising lists of failing scan cells identified by any of the disclosed methods are also provided. | 10-01-2009 |
20090254786 | Accurately Identifying Failing Scan Bits In Compression Environments - X-masking registers are added in front of a compactor in test data compression environment to remove unknown values. The X-masking registers block out some chains due to unknown values and select other chains to feed the compactor. This X-masking capability is used to select one scan cell to observe at a time after a failure is observed at the compactor output. | 10-08-2009 |
20100138708 | DECOMPRESSORS FOR LOW POWER DECOMPRESSION OF TEST PATTERNS - Disclosed below are representative embodiments of methods, apparatus, and systems used to generate test patterns for testing integrated circuits. Embodiments of the disclosed technology can be used to provide a low power test scheme and can be integrated with a variety of compression hardware architectures (e.g., an embedded deterministic test (“EDT”) environment). Certain embodiments of the disclosed technology can reduce the switching rates, and thus the power dissipation, in scan chains with no hardware modification. Other embodiments use specialized decompression hardware and compression techniques to achieve low power testing. | 06-03-2010 |
20100306609 | Low Power Decompression Of Test Cubes - Disclosed below are representative embodiments of methods, apparatus, and systems used to generate test patterns for testing integrated circuits. Embodiments of the disclosed technology can be used to provide a low power test scheme and can be integrated with a variety of compression hardware architectures (e.g., an embedded deterministic test (“EDT”) environment). Certain embodiments of the disclosed technology can reduce the switching rates, and thus the power dissipation, in scan chains with no hardware modification. Other embodiments use specialized decompression hardware and compression techniques to achieve low power testing. | 12-02-2010 |
20110166818 | LOW POWER SCAN TESTING TECHNIQUES AND APPARATUS - Disclosed below are representative embodiments of methods, apparatus, and systems used to reduce power consumption during integrated circuit testing. Embodiments of the disclosed technology can be used to provide a low power test scheme and can be integrated with a variety of compression hardware architectures (e.g., an embedded deterministic test (“EDT”) architecture). Among the disclosed embodiments are integrated circuits having programmable test stimuli selectors, programmable scan enable circuits, programmable clock enable circuits, programmable shift enable circuits, and/or programmable reset enable circuits. Exemplary test pattern generation methods that can be used to generate test patterns for use with any of the disclosed embodiments are also disclosed. | 07-07-2011 |
20110320999 | DECOMPRESSORS FOR LOW POWER DECOMPRESSION OF TEST PATTERNS - Disclosed below are representative embodiments of methods, apparatus, and systems used to generate test patterns for testing integrated circuits. Embodiments of the disclosed technology can be used to provide a low power test scheme and can be integrated with a variety of compression hardware architectures (e.g., an embedded deterministic test (“EDT”) environment). Certain embodiments of the disclosed technology can reduce the switching rates, and thus the power dissipation, in scan chains with no hardware modification. Other embodiments use specialized decompression hardware and compression techniques to achieve low power testing. | 12-29-2011 |
Patent application number | Description | Published |
20130290795 | Test Scheduling With Pattern-Independent Test Access Mechanism - Disclosed are representative embodiments of methods, apparatus, and systems for test scheduling for testing a plurality of cores in a system on circuit. Test data are encoded to derive compressed test patterns that require small numbers of core input channels. Core input/output channel requirement information for each of the compressed test patterns is determined accordingly. The compressed patterns are grouped into test pattern classes. The formation of the test pattern classes is followed by allocation circuit input and output channels and test application time slots that may comprise merging complementary test pattern classes into clusters that can work with a particular test access mechanism. The test access mechanism may be designed independent of the test data. | 10-31-2013 |
20140372818 | Test-Per-Clock Based On Dynamically-Partitioned Reconfigurable Scan Chains - Aspects of the invention relate to a test-per-clock scheme based on dynamically-partitioned reconfigurable scan chains. Every clock cycle, scan chains configured by a control signal to operate in a shifting-launching mode shift in test stimuli one bit and immediately applies the newly formed test pattern to the circuit-under-test; and scan chains configured by the control signal to operate in a capturing-compacting-shifting mode shift out one bit of previously compacted test response data while compacting remaining bits of the previously compacted test response data with a currently-captured test response to form currently compacted test response data. A large number of scan chains may be configured by the control signal to work in a mission mode. After a predetermined number of clock cycles, a different control signal may be applied to reconfigure and partition the scan chains for applying different test stimuli. | 12-18-2014 |
20140372819 | Scan Chain Configuration For Test-Per-Clock Based On Circuit Topology - Aspects of the invention relate to generating scan chain configurations for test-per-clock based on circuit topology. With various implementations of the invention, weight vectors between scan chains in a circuit are first determined. Based on the weight vectors, a scan chain configuration is generated by assigning some scan chains in the scan chains to a stimuli group and some other scan chains in the scan chains to a compacting group. Here, the stimuli group comprises scan chains to operate in a shifting-launching mode, and the compacting group comprises scan chains to operate in a capturing-compacting-shifting mode. | 12-18-2014 |
20140372820 | Fault-Driven Scan Chain Configuration For Test-Per-Clock - Aspects of the invention relate to using fault-driven techniques to generate scan chain configurations for test-per-clock. A plurality of test cubes that detect a plurality of faults are first generated. Scan chains for loading specified bits of the test cubes are then assigned to a stimuli group. From the plurality of test cubes, a test cube that detects a large number of faults that do not propagate exclusively to scan chains in the stimuli group is selected. One or more scan chains that are not in the stimuli group and are needed for observing the large number of faults are assigned to a compacting group. The number of scan chains either in the compacting group or in both of the compacting group and the stimuli group may be limited to a predetermined number. | 12-18-2014 |
20140372821 | Scan Chain Stitching For Test-Per-Clock - Various aspects of the present invention relate to scan chain stitching techniques for test-per-clock. With various implementations of the invention, a plurality of scan cell partitions are generated based on combinational paths between scan cells. Scan cells may be assigned to one or more pairs of scan cell partitions based on combinational paths between the scan cells. Each pair of the scan cell partitions comprises one stimuli partition and one compacting partition. Using the plurality of scan cell partitions generated, scan chains are formed based on at least information of combinational paths between scan cell partitions in the plurality of scan cell partitions. The formed scan chains are to be dynamically divided into three groups during a test, which are configured to operate in a shifting-launching mode, a capturing-compacting-shifting mode and a mission mode, respectively. | 12-18-2014 |
20140372824 | Test Generation For Test-Per-Clock - Aspects of the invention relate to test generation techniques for test-per-clock. Test cubes may be generated by adding constraints to a conventional automatic test pattern generator. During a test cube merging process, a first test cube is merged with one or more test cubes that are compatible with the first test cube to generate a second test cube. The second test cube is shifted by one bit along a direction of scan chain shifting to generate a third test cube. The third test cube is then merged with one or more test cubes in the test cubes that are compatible with the third test cube to generate a fourth test cube. The shifting and merging operations may be repeated for a predetermined number of times. | 12-18-2014 |