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Accession number:        20161502242722
        Title:        Structure of partial-DNA cyclic memory for embryonics cell
        Authors:        Zhu, Sai1 Email author szhumail@163.com; Cai, Jinyan1 Email author radarc@126.com; Meng, Yafeng1; Li, Danyang1
        Author affiliation:        1 Department of Electronic and Optical Engineering, Mechanical Engineering College, Shijiazhuang, China
        Corresponding author:        Cai, Jinyan (radarc@126.com)
        Source title:        Guofang Keji Daxue Xuebao/Journal of National University of Defense Technology
        Abbreviated source title:        Guofang Keji Daxue Xuebao
        Volume:        38
        Issue:        1
        Issue date:        February 28, 2016
        Publication year:        2016
        Pages:        78-85
        Language:        Chinese
        ISSN:        10012486
        CODEN:        GKDXEM
        Document type:        Journal article (JA)
        Publisher:        National University of Defense Technology
        Abstract:        In order to reduce the hardware cost of embryonics system on the promise of ensuring system reliability, a novel genome memory structure-partial-DNA cyclic memory was presented, and only part of the system's DNA was stored. The embryonics array's functional differentiation and self repairing were achieved through the gene cyclic and non-cyclic shift in the cell and between cells, and the genes stored in memory were updated during the self repairing process. In this memory structure, the gene backups were set according to actual demand of system reliability and hardware cost, which were independent from the number of idle resources in embryonics array. Theoretical analysis and simulation results show that the new genome memory structure can not only achieve embryonics array's functional differentiation and self-repair, but also can ensure system reliability and reduce hardware cost, and it has a high practical engineering value. © 2016, National University of Defense Technology. All right reserved.
        Number of references:        15
        Main heading:        Cost benefit analysis
        Controlled terms:        Cost engineering - Cost reduction - Costs - DNA - Genes - Hardware - Reconfigurable hardware - Reliability - Reliability analysis - Repair
        Uncontrolled terms:        Analysis and simulation - Cyclic shifts - Embryonics - Hardware cost - Memory structure - Practical engineering - Self repairing - System reliability
        Classification code:        461.2 Biological Materials and Tissue Engineering - 605 Small Tools and Hardware - 721.3 Computer Circuits - 911 Cost and Value Engineering; Industrial Economics - 913.5 Maintenance
        DOI:        10.11887/j.cn.201601014
        Database:        Compendex
                Compilation and indexing terms, © 2016 Elsevier Inc，

Accession number:        20163402737339
        Title:        A novel gene memory structure for bio-inspired electronic cell
        Authors:        Cai, Jin-Yan1 Email author radarc@126.com; Zhu, Sai1; Meng, Ya-Feng1
        Author affiliation:        1 Department of Electronic and Optical Engineering, Ordnance Engineering College, Shijiazhuang; Hebei; 050003, China
        Source title:        Tien Tzu Hsueh Pao/Acta Electronica Sinica
        Abbreviated source title:        Tien Tzu Hsueh Pao
        Volume:        44
        Issue:        8
        Issue date:        August 1, 2016
        Publication year:        2016
        Pages:        1915-1923
        Language:        Chinese
        ISSN:        03722112
        CODEN:        TTHPAG
        Document type:        Journal article (JA)
        Publisher:        Chinese Institute of Electronics
        Abstract:        Gene memory is an important part of electronic cell, and the existing genes memory structure cannot take into account the reliability and hardware cost. A novel gene memory structure named partial-DNA cyclic memory was presented, and only part of the system's entire DNA was stored with correlated redundancy. The lost genes caused by faulty cells could be obtained through gene update according to the faulty cells' neighbor cells. The stored gene number is independent form the scale of embryonics array and target circuit, and can be set according to actual demand in design process. Theoretical analysis and simulation results show that the novel gene memory not only to achieve the embryonics array's functional differentiation and self-repair, but also reducing hardware overhead while keeping system reliability. The proposed gene memory can be used to design larger scale self-repair chip. © 2016, Chinese Institute of Electronics. All right reserved.
        Number of references:        11
        Main heading:        Genes
        Controlled terms:        DNA - Hardware - Reconfigurable hardware - Reliability analysis - Repair
        Uncontrolled terms:        Analysis and simulation - Electronic cells - Embryonics - Hardware overheads - Memory structure - Self repair - System reliability - Target circuits
        Classification code:        461.2 Biological Materials and Tissue Engineering - 605 Small Tools and Hardware - 721.3 Computer Circuits - 913.5 Maintenance
        DOI:        10.3969/j.issn.0372-2112.2016.08.021
        Database:        Compendex
                Compilation and indexing terms, © 2016 Elsevier Inc.