A Built-in Self-Diagnosis and Repair Design With Fail Pattern Identification for Memories

With the advent of deep-submicrometer VLSI technology, the capacity and performance of semiconductor memory chips is increasing drastically. This advantage also makes it harder to maintain good yield. Diagnostics and redundancy repair methodologies thus are getting more and more important for memori...

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Veröffentlicht in:	IEEE transactions on very large scale integration (VLSI) systems 2011-12, Vol.19 (12), p.2184-2194
Hauptverfasser:	SU, Chin-Lung, HUANG, Rei-Fu, WU, Cheng-Wen, LUO, Kun-Lun, WU, Wen-Ching
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithm design and analysis Applied sciences Built-in self-repair (BISR) Built-in self-test Circuit faults Compressing Design engineering Design for testability design-for-testability (DFT) Design. Technologies. Operation analysis. Testing Electronics Electronics industry Exact sciences and technology Faults Integrated circuits Integrated circuits by function (including memories and processors) memory diagnostics memory repair memory testing Redundancy Repair Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Semiconductor memory Semiconductors Studies Testing, measurement, noise and reliability Very large scale integration yield enhancement
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container_title	IEEE transactions on very large scale integration (VLSI) systems
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creator	SU, Chin-Lung HUANG, Rei-Fu WU, Cheng-Wen LUO, Kun-Lun WU, Wen-Ching
description	With the advent of deep-submicrometer VLSI technology, the capacity and performance of semiconductor memory chips is increasing drastically. This advantage also makes it harder to maintain good yield. Diagnostics and redundancy repair methodologies thus are getting more and more important for memories, including embedded ones that are popular in system chips. In this paper, we propose an efficient memory diagnosis and repair scheme based on fail-pattern identification. The proposed diagnosis scheme can distinguish among row, column, and word faults, and subsequently apply the Huffman compression method for fault syndrome compression. This approach reduces the amount of data that need to be transmitted from the chip under test to the automatic test equipment (ATE) without losing fault information. It also simplifies the analysis that has to be performed on the ATE. The proposed redundancy repair scheme is assisted by fail-pattern identification approach and a flexible redundancy structure. The area overhead for our built-in self-repair (BISR) design is reasonable. Our repair scheme uses less redundancy than other redundancy schemes under the same repair rate requirement. Experimental results show that the area overhead of the BISR design is only 4.1% for an 8 K × 64 memory and is in inverse proportion to the memory size.
doi_str_mv	10.1109/TVLSI.2010.2073489
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subjects	Algorithm design and analysis Applied sciences Built-in self-repair (BISR) Built-in self-test Circuit faults Compressing Design engineering Design for testability design-for-testability (DFT) Design. Technologies. Operation analysis. Testing Electronics Electronics industry Exact sciences and technology Faults Integrated circuits Integrated circuits by function (including memories and processors) memory diagnostics memory repair memory testing Redundancy Repair Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices Semiconductor memory Semiconductors Studies Testing, measurement, noise and reliability Very large scale integration yield enhancement
title	A Built-in Self-Diagnosis and Repair Design With Fail Pattern Identification for Memories
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