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Fault Discrimination Algorithm for Busbar Differential Protection Relaying Using Partial Operating Current CharacteristicsHossain, Monir 16 December 2016 (has links)
Differential protection is the unit protection system which is applied to protect a particular unit of power systems. Unit is known as zone in protection terminology which is equivalent to simple electrical node. In recent time, low impedance current differential protection schemes based on percentage restrained characteristics are widely used in power systems to protect busbar systems. The main application issue of these schemes is mis-operation due to current transformer (CT) saturation during close-in external faults. Researchers have suggested various solution of this problem; however, individually they are not sufficient to puzzle out all mis-operational scenarios. This thesis presents a new bus differential algorithm by defining alternative partial operating current characteristics of a differential protection zone and investigating its performance for all practical bus faults. Mathematical model of partial operating current and operating principle of the proposed bus differential relay are described in details. A CT saturation detection algorithm which includes fast and late CT saturation detection techniques is incorporated in relay design to increase the sensitivity of partial operating current based internal-external fault discriminator for high impedance internal faults. Performance of the proposed relay is validated by an extensive test considering all possible fault scenarios.
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Fault diagnosis of VLSI designs: cell internal faults and volume diagnosis throughputFan, Xiaoxin 01 December 2012 (has links)
The modern VLSI circuit designs manufactured with advanced technology nodes of 65nm or below exhibit an increasing sensitivity to the variations of manufacturing process. New design-specific and feature-sensitive failure mechanisms are on the rise. Systematic yield issues can be severe due to the complex variability involved in process and layout features. Without improved yield analysis methods, time-to-market is delayed, mature yield is suboptimal, and product quality may suffer, thereby undermining the profitability of the semiconductor company. Diagnosis-driven yield improvement is a methodology that leverages production test results, diagnosis results, and statistical analysis to identify the root cause of yield loss and fix the yield limiters to improve the yield.
To fully leverage fault diagnosis, the diagnosis-driven yield analysis requires that the diagnosis tool should provide high-quality diagnosis results in terms of accuracy and resolution. In other words, the diagnosis tool should report the real defect location without too much ambiguity. The second requirement for fast diagnosis-driven yield improvement is that the diagnosis tool should have the capability of processing a volume of failing dies within a reasonable time so that the statistical analysis can have enough information to identify the systematic yield issues.
In this dissertation, we first propose a method to accurately diagnose the defects inside the library cells when multi-cycle test patterns are used. The methods to diagnose the interconnect defect have been well studied for many years and are successfully practiced in industry. However, for process technology at 90nm or 65nm or below, there is a significant number of manufacturing defects and systematic yield limiters lie inside library cells. The existing cell internal diagnosis methods work well when only combinational test patterns are used, while the accuracy drops dramatically with multi-cycle test patterns. A method to accurately identify the defective cell as well as the failing conditions is presented. The accuracy can be improved up to 94% compared with about 75% accuracy for previous proposed cell internal diagnosis methods.
The next part of this dissertation addresses the throughput problem for diagnosing a volume of failing chips with high transistor counts. We first propose a static design partitioning method to reduce the memory footprint of volume diagnosis. A design is statically partitioned into several smaller sub-circuits, and then the diagnosis is performed only on the smaller sub-circuits. By doing this, the memory usage for processing the smaller sub-circuit can be reduced and the throughput can be improved. We next present a dynamic design partitioning method to improve the throughput and minimize the impact on diagnosis accuracy and resolution. The proposed dynamic design partitioning method is failure dependent, in other words, each failure file has its own design partition. Extensive experiments have been designed to demonstrate the efficiency of the proposed dynamic partitioning method.
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Ajuste e ensaio de sistemas de proteção de geradores síncronos. / Regeneration of productive systems through dynamic reallocation of resources with functional flexibility.Omar Chayña Chayña Velásquez 28 May 2015 (has links)
Os sistemas de proteção dos elementos da rede elétrica desempenham um papel de fundamental importância na segurança e confiabilidade dos sistemas de potência. A não atuação ou a atuação incorreta dos relés de proteção durante uma falta localizada em um componente da rede pode transformar-se em um evento sistêmico de grandes proporções (blecaute). Esses eventos trazem riscos e elevados prejuízos econômicos à sociedade. A proteção dos geradores síncronos, apesar do alto custo e complexidade deste tipo de equipamento, não recebe a mesma atenção na literatura que a dedicada à proteção de outros elementos da rede, como, por exemplo, a das linhas de transmissão. Isso decorre do menor número de geradores existentes na rede e também da ideia que as faltas neste tipo de equipamento são menos frequentes. Este trabalho aborda os principais aspectos envolvidos com o projeto de um sistema de proteção para geradores síncronos de grande porte. Incialmente, discutese os principais conceitos associados com os geradores, de interesse para a tarefa de proteção. Particular atenção é dedicada às formas de aterramento e aos critérios adotados para projeto do resistor de aterramento utilizado nesse equipamento. Em seguida, apresentam-se as principais funções de proteção aplicáveis aos geradores, particularmente aquelas voltadas para a detecção de faltas nos enrolamentos do estator. Discute-se também os critérios de ajustes dos parâmetros dessas funções. Descreve-se o uso de uma plataforma laboratorial, baseada em simulador de tempo real (RTDS), para ensaio e análise do sistema de proteção visando validar seu correto desempenho frente às possíveis condições operativas que podem ser encontradas em campo. Finalmente, utilizando os conceitos desenvolvidos ao longo do trabalho, desenvolve-se um estudo de caso, onde é realizado o projeto e implementação do sistema de proteção dos geradores de uma usina hidrelétrica hipotética. Para avaliar e analisar o desempenho do sistema de proteção dessa rede exemplo, parametrizou-se o IED G60 (GE) e realizou-se inúmeras simulações na plataforma de testes proposta. / Protection systems play a critical role in the safety and reliability of electric power systems. The non-operation or wrong operation of protective relays during a fault in a network element can evolve to a systemic event in large scale (blackout). These events bring risks and high economic losses to society. Despite the high cost and complexity, the protection of synchronous generators has not received much attention in the literature devoted to protection of other network elements, such as transmission lines. This stems from the smaller number of generators in the network and also the idea that the faults in this type of equipment are less frequent. This research discusses the main aspects involved in the design of a protection system for large synchronous generators. Initially, it discusses the key concepts of interest to the generation protection. Particular attention is given to grounding techniques and the criteria adopted for the design of grounding resistors used in those equipment. Then the main protection functions applicable to generators are presented, particularly those related to fault detection in the stator windings. The criteria for setting the parameters of these functions are also discussed. After that, the use of a laboratory shelf, based on Real-Time Digital Simulator (RTDS) for testing and analysis of the protection system, is described in order to validate the correct performance in face of possible operating conditions in the field. Finally, a study case is developed using the concepts developed throughout the research. Then, the design and implementation of the protection system of generators of a hypothetical hydroelectric plant are carried out. To evaluate and analyze the performance of this example network protection system, parameterized up IED G60 (GE) and held numerous simulations in the proposed test platform.
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Ajuste e ensaio de sistemas de proteção de geradores síncronos. / Regeneration of productive systems through dynamic reallocation of resources with functional flexibility.Chayña Velásquez, Omar Chayña 28 May 2015 (has links)
Os sistemas de proteção dos elementos da rede elétrica desempenham um papel de fundamental importância na segurança e confiabilidade dos sistemas de potência. A não atuação ou a atuação incorreta dos relés de proteção durante uma falta localizada em um componente da rede pode transformar-se em um evento sistêmico de grandes proporções (blecaute). Esses eventos trazem riscos e elevados prejuízos econômicos à sociedade. A proteção dos geradores síncronos, apesar do alto custo e complexidade deste tipo de equipamento, não recebe a mesma atenção na literatura que a dedicada à proteção de outros elementos da rede, como, por exemplo, a das linhas de transmissão. Isso decorre do menor número de geradores existentes na rede e também da ideia que as faltas neste tipo de equipamento são menos frequentes. Este trabalho aborda os principais aspectos envolvidos com o projeto de um sistema de proteção para geradores síncronos de grande porte. Incialmente, discutese os principais conceitos associados com os geradores, de interesse para a tarefa de proteção. Particular atenção é dedicada às formas de aterramento e aos critérios adotados para projeto do resistor de aterramento utilizado nesse equipamento. Em seguida, apresentam-se as principais funções de proteção aplicáveis aos geradores, particularmente aquelas voltadas para a detecção de faltas nos enrolamentos do estator. Discute-se também os critérios de ajustes dos parâmetros dessas funções. Descreve-se o uso de uma plataforma laboratorial, baseada em simulador de tempo real (RTDS), para ensaio e análise do sistema de proteção visando validar seu correto desempenho frente às possíveis condições operativas que podem ser encontradas em campo. Finalmente, utilizando os conceitos desenvolvidos ao longo do trabalho, desenvolve-se um estudo de caso, onde é realizado o projeto e implementação do sistema de proteção dos geradores de uma usina hidrelétrica hipotética. Para avaliar e analisar o desempenho do sistema de proteção dessa rede exemplo, parametrizou-se o IED G60 (GE) e realizou-se inúmeras simulações na plataforma de testes proposta. / Protection systems play a critical role in the safety and reliability of electric power systems. The non-operation or wrong operation of protective relays during a fault in a network element can evolve to a systemic event in large scale (blackout). These events bring risks and high economic losses to society. Despite the high cost and complexity, the protection of synchronous generators has not received much attention in the literature devoted to protection of other network elements, such as transmission lines. This stems from the smaller number of generators in the network and also the idea that the faults in this type of equipment are less frequent. This research discusses the main aspects involved in the design of a protection system for large synchronous generators. Initially, it discusses the key concepts of interest to the generation protection. Particular attention is given to grounding techniques and the criteria adopted for the design of grounding resistors used in those equipment. Then the main protection functions applicable to generators are presented, particularly those related to fault detection in the stator windings. The criteria for setting the parameters of these functions are also discussed. After that, the use of a laboratory shelf, based on Real-Time Digital Simulator (RTDS) for testing and analysis of the protection system, is described in order to validate the correct performance in face of possible operating conditions in the field. Finally, a study case is developed using the concepts developed throughout the research. Then, the design and implementation of the protection system of generators of a hypothetical hydroelectric plant are carried out. To evaluate and analyze the performance of this example network protection system, parameterized up IED G60 (GE) and held numerous simulations in the proposed test platform.
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