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In order to reduce test and repair cost in advanced system-on-chip products, wireless built-in self-repair (BISR) techniques for embedded memories are proposed in this paper. The redundant memory is divided into spare rows, spare column group blocks, and spare words which are used to replace faulty cells in the main memory. Based on this redundancy architecture, a BISR scheme suitable for built-in...
Present and future semiconductor technologies are characterized by increasing parameters variations as well as an increasing susceptibility to external disturbances. Transient errors during system operation are no longer restricted to memories but also affect random logic, and a robust design becomes mandatory to ensure a reliable system operation. Self-checking circuits rely on redundancy to detect...
In this paper a BISR architecture for embedded memories is presented. The proposed scheme utilises a multiple bank cache-like memory for repairs. Statistical analysis is used for minimisation of the total resources required to achieve a very high fault coverage. Simulation results show that the proposed BISR scheme is characterised by high efficiency and low area overhead, even for high defect densities...
Networks on chips (NoCs) provide a mechanism for handling complex communications in the next generation of integrated circuits. At the same time, lower yield in nano-technology, makes self repair communication channels a necessity in design of digital systems. This paper proposes a reliable NoC architecture based on specific application mapped onto an NoC. This architecture is capable of recovering...
In this paper, we present a new technique to improve the reliability of H-tree SRAM memories. This technique deals with the SRAM power-bus monitoring by using built-in current sensor (BICS) circuits that detect abnormal current dissipation in the memory power-bus. This abnormal current is the result of a single-event upset (SEU) in the memory and it is generated during the inversion of the state of...
Built-in self test (BIST) and built-in self repair (BISR) techniques have been developed for memory blocks in recent years. Such techniques are suited to enhance production yield, but also to facilitate long-term dependable circuits though self repair in the field of application. BISR for logic circuits has shown to be much more complex, for which only a few approaches have been published so far....
A high level of redundancy is required to deal with the challenge of high defect and fault rates in nano environments. The reconfigurability of nano devices and the regular structure of nano fabrics make reconfiguration based repair an essential approach for both defect and fault tolerance. Ideally, repair based approaches have the best hardware efficiency when full sharing of redundancy is achievable...
This paper describes a methodology for building a reliable internet core router that considers the vulnerability of its electronic components to single event upset (SEU). It begins with a set of meaningful system level metrics that can be related to product reliability requirements. A specification is then defined that can be effectively used during the system architecture, silicon and software design...
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