Abstract:
According to exemplary methods and systems of the present principles, the location of defective field repairable units (FRUS) of a circuit that have varying sizes or varying numbers of scan cells may be identified by employing tiles including scan cells from different FRUS. A set of test patterns may be scanned through the scan cells such that cells belonging to FRUs within a tile may be concealed while analyzing the response of scan cells in the tile contributed by a different FRU. Further, defective tiles are discoverable at any tile location and in any quantity within a maximal capacity using a compressed signature. In addition, signature registers that process data at a rate that is faster than the scan shift rate of the circuit may be employed during compression to multiply a circuit response by a plurality of components of a compression matrix during one scan shift cycle.
Abstract:
Implementations of the present principles are directed to test output compaction arrangements and a methods of generating control patterns for unknown blocking. The specified bits in the control patterns, which when using linear feedback shift register (LFSR) reseeding determines control data volume and LFSR size, are preferably organized in a manner so as to balance the number of specified bits in the control patterns across test patterns.
Abstract:
Disclosed is a logic testing system that includes a decompressor and a tester in communication with the decompressor. The tester is configured to store a seed and locations of scan inputs and is further configured to transmit the seed and the locations of scan inputs to the decompressor. The decompressor is configured to generate a test pattern from the seed and the locations of scan inputs. The decompressor includes a first test pattern generator, a second test pattern generator, and a selector configured to select the test pattern generated by the first test pattern generator or the test pattern generated by the second test pattern generator using the locations of scan inputs.
Abstract:
A method includes selecting at least one regular scan cell that is replaced with a corresponding one of an enhanced scan cell in a scan chain for scan based delay testing of the digital circuit, controlling the enhanced scan cell with a skewed load approach, and controlling regular scan cells of the scan chain with a broadside approach. More specifically, this reduces test sequence lengths and achieves higher delay fault coverage, without having to pay high cost to drive all scan cells by the skewed load approach, which requires a faster switching than the broadside approach. No additional pins are required for driving enhanced scan cells because the drive signal for switching the enhanced scan cells is derived from the signal for driving the regular scan cells.
Abstract:
The present invention is directed to a logic testing architecture with an improved decompression engine and a method of decompressing scan chains for testing logic circuits.
Abstract:
Disclosed is a logic testing system that includes a decompressor and a tester in communication with the decompressor. The tester is configured to store a seed and locations of scan inputs and is further configured to transmit the seed and the locations of scan inputs to the decompressor. The decompressor is configured to generate a test pattern from the seed and the locations of scan inputs. The decompressor includes a first test pattern generator, a second test pattern generator, and a selector configured to select the test pattern generated by the first test pattern generator or the test pattern generated by the second test pattern generator using the locations of scan inputs.
Abstract:
A test output compaction arrangement and a method of generating control patterns for unknown blocking is herein disclosed. The specified bits in the control patterns, which when using linear feedback shift register (LFSR) reseeding determines control data volume and LFSR size, are preferably organized in a manner so as to balance the number of specified bits in the control patterns across test patterns.
Abstract:
A method includes obtaining an equivalent core of multiple cores in a System-on-Chip circuit, and applying linear-feedback shift register LFSR reseeding for compressing test data of the equivalent core.
Abstract:
According to exemplary methods and systems of the present principles, the location of defective field repairable units (FRUS) of a circuit that have varying sizes or varying numbers of scan cells may be identified by employing tiles including scan cells from different FRUS. A set of test patterns may be scanned through the scan cells such that cells belonging to FRUs within a tile may be concealed while analyzing the response of scan cells in the tile contributed by a different FRU. Further, defective tiles are discoverable at any tile location and in any quantity within a maximal capacity using a compressed signature. In addition, signature registers that process data at a rate that is faster than the scan shift rate of the circuit may be employed during compression to multiply a circuit response by a plurality of components of a compression matrix during one scan shift cycle.
Abstract:
Disclosed is a logic testing system that includes a decompressor and a tester in communication with the decompressor. The tester is configured to store a seed and locations of scan inputs and is further configured to transmit the seed and the locations of scan inputs to the decompressor. The decompressor is configured to generate a test pattern from the seed and the locations of scan inputs. The decompressor includes a first test pattern generator, a second test pattern generator, and a selector configured to select the test pattern generated by the first test pattern generator or the test pattern generated by the second test pattern generator using the locations of scan inputs.