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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Timing vulnerability factor analysis in master-slave D flip-flops / Análise do fator de vulnerabilidade temporal em flip-flops mestre-escravo do tipo D

Zimpeck, Alexandra Lackmann January 2016 (has links)
O dimensionamento da tecnologia trouxe consequências indesejáveis para manter a taxa de crescimento exponencial e levanta questões importantes relacionadas com a confiabilidade e robustez dos sistemas eletrônicos. Atualmente, microprocessadores modernos de superpipeline normalmente contêm milhões de dispositivos com cargas nos nós cada vez menores. Esse fator faz com que os circuitos sejam mais sensíveis a variabilidade ambiental e aumenta a probabilidade de um erro transiente acontecer. Erros transientes em circuitos sequenciais ocorrem quando uma única partícula energizada deposita carga suficiente perto de uma região sensível. Flip-Flops mestreescravo são os circuitos sequencias mais utilizados em projeto VLSI para armazenamento de dados. Se um bit-flip ocorrer dentro deles, eles perdem a informação prévia armazenada e podem causar um funcionamento incorreto do sistema. A fim de proporcionar sistemas mais confiáveis que possam lidar com os efeitos da radiação, este trabalho analisa o Fator de Vulnerabilidade Temporal (Timing Vulnerability Factor - TVF) em algumas topologias de flip-flops mestre-escravo em estágios de pipeline sob diferentes condições de operação. A janela de tempo efetivo que o bit-flip ainda pode ser capturado pelo próximo estágio é definido com janela de vulnerabilidade (WOV). O TVF corresponde ao tempo que o flip-flop é vulnerável a erros transientes induzidos pela radiação de acordo com a WOV e a frequência de operação. A primeira etapa deste trabalho determina a dependência entre o TVF com a propagação de falhas até o próximo estágio através de uma lógica combinacional com diferentes atrasos de propagação e com diferentes modelos de tecnologia, incluindo também as versões de alto desempenho e baixo consumo. Todas as simulações foram feitas sob as condições normais pré-definidas nos arquivos de tecnologia. Como a variabilidade se manifesta com o aumento ou diminuição das especificações iniciais, onde o principal problema é a incerteza sobre o valor armazenado em circuitos sequenciais, a segunda etapa deste trabalho consiste em avaliar o impacto que os efeitos da variabilidade ambiental causam no TVF. Algumas simulações foram refeitas considerando variações na tensão de alimentação e na temperatura em diferentes topologias e configurações de flip-flops mestre-escravo. Para encontrar os melhores resultados, é necessário tentar diminuir os valores de TVF, pois isso significa que eles serão menos vulneráveis a bit-flips. Atrasos de propagação entre dois circuitos sequenciais e frequências de operação mais altas ajudam a reduzir o TVF. Além disso, estas informações podem ser facilmente integradas em ferramentas de EDA para ajudar a identificar os flip-flops mestre-escravo mais vulneráveis antes de mitigar ou substituí-los por aqueles tolerantes a radiação. / Technology scaling has brought undesirable issues to maintain the exponential growth rate and it raises important topics related to reliability and robustness of electronic systems. Currently, modern super pipelined microprocessors typically contain many millions of devices with ever decreasing load capacitances. This factor makes circuits more sensitive to environmental variations and it is increased the probability to induce a soft error. Soft errors in sequential circuits occur when a single energetic particle deposits enough charge near a sensitive node. Master-slave flip-flops are the most adopted sequential elements to work as registers in pipeline and finite state machines. If a bit-flip happens inside them, they lose the previous stored information and may cause an incorrect system operation. To provide reliable systems that can cope with radiation effects, this work analysis the Timing Vulnerability Factor (TVF) of some master-slave D flip-flops topologies in pipeline stages under different operating conditions. The effective time window, which the bit-flip can still be captured by the next stage, is defined as Window of Vulnerability (WOV). TVF corresponds to the time that a flip-flop is vulnerable to radiation-induced soft errors according to WOV and clock frequency. In the first step of this work, it is determined the dependence between the TVF with the fault propagation to the next stage through a combinational logic with different propagation delays and with different nanometer technological models, including also high performance and low power versions. All these simulations were made under the pre-defined nominal conditions in technology files. The variability manifests with an increase or decreases to initial specification, where the main problem is the uncertainty about the value stored in sequential. In this way, the second step of this work evaluates the impact that environmental variability effect causes in TVF. Some simulations were redone considering supply voltage and temperature variations in different master-slave D flip-flop topologies configurations. To achieve better results, it is necessary to try to decrease the TVF values to reduce the vulnerability to bit-flips. The propagation delay between two sequential elements and higher clock frequencies collaborates to reduce TVF values. Moreover, all the information can be easily integrated into Electronic Design Automation (EDA) tools to help identifying the most vulnerable master-slave flip-flops before mitigating or replacing them by radiation hardened ones.
2

Efficient modeling of soft error vulnerability in microprocessors

Nair, Arun Arvind 11 July 2012 (has links)
Reliability has emerged as a first class design concern, as a result of an exponential increase in the number of transistors on the chip, and lowering of operating and threshold voltages with each new process generation. Radiation-induced transient faults are a significant source of soft errors in current and future process generations. Techniques to mitigate their effect come at a significant cost of area, power, performance, and design effort. Architectural Vulnerability Factor (AVF) modeling has been proposed to easily estimate the processor's soft error rates, and to enable the designers to make appropriate cost/reliability trade-offs early in the design cycle. Using cycle-accurate microarchitectural or logic gate-level simulations, AVF modeling captures the masking effect of program execution on the visibility of soft errors at the output. AVF modeling is used to identify structures in the processor that have the highest contribution to the overall Soft Error Rate (SER) while running typical workloads, and used to guide the design of SER mitigation mechanisms. The precise mechanisms of interaction between the workload and the microarchitecture that together determine the overall AVF is not well studied in literature, beyond qualitative analyses. Consequently, there is no known methodology for ensuring that the workload suite used for AVF modeling offers sufficient SER coverage. Additionally, owing to the lack of an intuitive model, AVF modeling is reliant on detailed microarchitectural simulations for understanding the impact of scaling processor structures, or design space exploration studies. Microarchitectural simulations are time-consuming, and do not easily provide insight into the mechanisms of interactions between the workload and the microarchitecture to determine AVF, beyond aggregate statistics. These aforementioned challenges are addressed in this dissertation by developing two methodologies. First, beginning with a systematic analysis of the factors affecting the occupancy of corruptible state in a processor, a methodology is developed that generates a synthetic workload for a given microarchitecture such that the SER is maximized. As it is impossible for every bit in the processor to simultaneously contain corruptible state, the worst-case realizable SER while running a workload is less than the sum of their circuit-level fault rates. The knowledge of the worst-case SER enables efficient design trade-offs by allowing the architect to validate the coverage of the workload suite and select an appropriate design point, and to identify structures that may potentially have high contribution to SER. The methodology induces 1.4X higher SER in the core as compared to the highest SER induced by SPEC CPU2006 and MiBench programs. Second, a first-order analytical model is proposed, which is developed from the first principles of out-of-order superscalar execution that models the AVF induced by a workload in microarchitectural structures, using inexpensive profiling. The central component of this model is a methodology to estimate the occupancy of correct-path state in various structures in the core. Owing to its construction, the model provides fundamental insight into the precise mechanism of interaction between the workload and the microarchitecture to determine AVF. The model is used to cheaply perform sizing studies for structures in the core, design space exploration, and workload characterization for AVF. The model is used to quantitatively explain results that may appear counter-intuitive from aggregate performance metrics. The Mean Absolute Error in determining AVF of a 4-wide out-of-order superscalar processor using model is less than 7% for each structure, and the Normalized Mean Square Error for determining overall SER is 9.0%, as compared to cycle-accurate microarchitectural simulation. / text
3

Timing vulnerability factor analysis in master-slave D flip-flops / Análise do fator de vulnerabilidade temporal em flip-flops mestre-escravo do tipo D

Zimpeck, Alexandra Lackmann January 2016 (has links)
O dimensionamento da tecnologia trouxe consequências indesejáveis para manter a taxa de crescimento exponencial e levanta questões importantes relacionadas com a confiabilidade e robustez dos sistemas eletrônicos. Atualmente, microprocessadores modernos de superpipeline normalmente contêm milhões de dispositivos com cargas nos nós cada vez menores. Esse fator faz com que os circuitos sejam mais sensíveis a variabilidade ambiental e aumenta a probabilidade de um erro transiente acontecer. Erros transientes em circuitos sequenciais ocorrem quando uma única partícula energizada deposita carga suficiente perto de uma região sensível. Flip-Flops mestreescravo são os circuitos sequencias mais utilizados em projeto VLSI para armazenamento de dados. Se um bit-flip ocorrer dentro deles, eles perdem a informação prévia armazenada e podem causar um funcionamento incorreto do sistema. A fim de proporcionar sistemas mais confiáveis que possam lidar com os efeitos da radiação, este trabalho analisa o Fator de Vulnerabilidade Temporal (Timing Vulnerability Factor - TVF) em algumas topologias de flip-flops mestre-escravo em estágios de pipeline sob diferentes condições de operação. A janela de tempo efetivo que o bit-flip ainda pode ser capturado pelo próximo estágio é definido com janela de vulnerabilidade (WOV). O TVF corresponde ao tempo que o flip-flop é vulnerável a erros transientes induzidos pela radiação de acordo com a WOV e a frequência de operação. A primeira etapa deste trabalho determina a dependência entre o TVF com a propagação de falhas até o próximo estágio através de uma lógica combinacional com diferentes atrasos de propagação e com diferentes modelos de tecnologia, incluindo também as versões de alto desempenho e baixo consumo. Todas as simulações foram feitas sob as condições normais pré-definidas nos arquivos de tecnologia. Como a variabilidade se manifesta com o aumento ou diminuição das especificações iniciais, onde o principal problema é a incerteza sobre o valor armazenado em circuitos sequenciais, a segunda etapa deste trabalho consiste em avaliar o impacto que os efeitos da variabilidade ambiental causam no TVF. Algumas simulações foram refeitas considerando variações na tensão de alimentação e na temperatura em diferentes topologias e configurações de flip-flops mestre-escravo. Para encontrar os melhores resultados, é necessário tentar diminuir os valores de TVF, pois isso significa que eles serão menos vulneráveis a bit-flips. Atrasos de propagação entre dois circuitos sequenciais e frequências de operação mais altas ajudam a reduzir o TVF. Além disso, estas informações podem ser facilmente integradas em ferramentas de EDA para ajudar a identificar os flip-flops mestre-escravo mais vulneráveis antes de mitigar ou substituí-los por aqueles tolerantes a radiação. / Technology scaling has brought undesirable issues to maintain the exponential growth rate and it raises important topics related to reliability and robustness of electronic systems. Currently, modern super pipelined microprocessors typically contain many millions of devices with ever decreasing load capacitances. This factor makes circuits more sensitive to environmental variations and it is increased the probability to induce a soft error. Soft errors in sequential circuits occur when a single energetic particle deposits enough charge near a sensitive node. Master-slave flip-flops are the most adopted sequential elements to work as registers in pipeline and finite state machines. If a bit-flip happens inside them, they lose the previous stored information and may cause an incorrect system operation. To provide reliable systems that can cope with radiation effects, this work analysis the Timing Vulnerability Factor (TVF) of some master-slave D flip-flops topologies in pipeline stages under different operating conditions. The effective time window, which the bit-flip can still be captured by the next stage, is defined as Window of Vulnerability (WOV). TVF corresponds to the time that a flip-flop is vulnerable to radiation-induced soft errors according to WOV and clock frequency. In the first step of this work, it is determined the dependence between the TVF with the fault propagation to the next stage through a combinational logic with different propagation delays and with different nanometer technological models, including also high performance and low power versions. All these simulations were made under the pre-defined nominal conditions in technology files. The variability manifests with an increase or decreases to initial specification, where the main problem is the uncertainty about the value stored in sequential. In this way, the second step of this work evaluates the impact that environmental variability effect causes in TVF. Some simulations were redone considering supply voltage and temperature variations in different master-slave D flip-flop topologies configurations. To achieve better results, it is necessary to try to decrease the TVF values to reduce the vulnerability to bit-flips. The propagation delay between two sequential elements and higher clock frequencies collaborates to reduce TVF values. Moreover, all the information can be easily integrated into Electronic Design Automation (EDA) tools to help identifying the most vulnerable master-slave flip-flops before mitigating or replacing them by radiation hardened ones.
4

Timing vulnerability factor analysis in master-slave D flip-flops / Análise do fator de vulnerabilidade temporal em flip-flops mestre-escravo do tipo D

Zimpeck, Alexandra Lackmann January 2016 (has links)
O dimensionamento da tecnologia trouxe consequências indesejáveis para manter a taxa de crescimento exponencial e levanta questões importantes relacionadas com a confiabilidade e robustez dos sistemas eletrônicos. Atualmente, microprocessadores modernos de superpipeline normalmente contêm milhões de dispositivos com cargas nos nós cada vez menores. Esse fator faz com que os circuitos sejam mais sensíveis a variabilidade ambiental e aumenta a probabilidade de um erro transiente acontecer. Erros transientes em circuitos sequenciais ocorrem quando uma única partícula energizada deposita carga suficiente perto de uma região sensível. Flip-Flops mestreescravo são os circuitos sequencias mais utilizados em projeto VLSI para armazenamento de dados. Se um bit-flip ocorrer dentro deles, eles perdem a informação prévia armazenada e podem causar um funcionamento incorreto do sistema. A fim de proporcionar sistemas mais confiáveis que possam lidar com os efeitos da radiação, este trabalho analisa o Fator de Vulnerabilidade Temporal (Timing Vulnerability Factor - TVF) em algumas topologias de flip-flops mestre-escravo em estágios de pipeline sob diferentes condições de operação. A janela de tempo efetivo que o bit-flip ainda pode ser capturado pelo próximo estágio é definido com janela de vulnerabilidade (WOV). O TVF corresponde ao tempo que o flip-flop é vulnerável a erros transientes induzidos pela radiação de acordo com a WOV e a frequência de operação. A primeira etapa deste trabalho determina a dependência entre o TVF com a propagação de falhas até o próximo estágio através de uma lógica combinacional com diferentes atrasos de propagação e com diferentes modelos de tecnologia, incluindo também as versões de alto desempenho e baixo consumo. Todas as simulações foram feitas sob as condições normais pré-definidas nos arquivos de tecnologia. Como a variabilidade se manifesta com o aumento ou diminuição das especificações iniciais, onde o principal problema é a incerteza sobre o valor armazenado em circuitos sequenciais, a segunda etapa deste trabalho consiste em avaliar o impacto que os efeitos da variabilidade ambiental causam no TVF. Algumas simulações foram refeitas considerando variações na tensão de alimentação e na temperatura em diferentes topologias e configurações de flip-flops mestre-escravo. Para encontrar os melhores resultados, é necessário tentar diminuir os valores de TVF, pois isso significa que eles serão menos vulneráveis a bit-flips. Atrasos de propagação entre dois circuitos sequenciais e frequências de operação mais altas ajudam a reduzir o TVF. Além disso, estas informações podem ser facilmente integradas em ferramentas de EDA para ajudar a identificar os flip-flops mestre-escravo mais vulneráveis antes de mitigar ou substituí-los por aqueles tolerantes a radiação. / Technology scaling has brought undesirable issues to maintain the exponential growth rate and it raises important topics related to reliability and robustness of electronic systems. Currently, modern super pipelined microprocessors typically contain many millions of devices with ever decreasing load capacitances. This factor makes circuits more sensitive to environmental variations and it is increased the probability to induce a soft error. Soft errors in sequential circuits occur when a single energetic particle deposits enough charge near a sensitive node. Master-slave flip-flops are the most adopted sequential elements to work as registers in pipeline and finite state machines. If a bit-flip happens inside them, they lose the previous stored information and may cause an incorrect system operation. To provide reliable systems that can cope with radiation effects, this work analysis the Timing Vulnerability Factor (TVF) of some master-slave D flip-flops topologies in pipeline stages under different operating conditions. The effective time window, which the bit-flip can still be captured by the next stage, is defined as Window of Vulnerability (WOV). TVF corresponds to the time that a flip-flop is vulnerable to radiation-induced soft errors according to WOV and clock frequency. In the first step of this work, it is determined the dependence between the TVF with the fault propagation to the next stage through a combinational logic with different propagation delays and with different nanometer technological models, including also high performance and low power versions. All these simulations were made under the pre-defined nominal conditions in technology files. The variability manifests with an increase or decreases to initial specification, where the main problem is the uncertainty about the value stored in sequential. In this way, the second step of this work evaluates the impact that environmental variability effect causes in TVF. Some simulations were redone considering supply voltage and temperature variations in different master-slave D flip-flop topologies configurations. To achieve better results, it is necessary to try to decrease the TVF values to reduce the vulnerability to bit-flips. The propagation delay between two sequential elements and higher clock frequencies collaborates to reduce TVF values. Moreover, all the information can be easily integrated into Electronic Design Automation (EDA) tools to help identifying the most vulnerable master-slave flip-flops before mitigating or replacing them by radiation hardened ones.
5

Comprendre la contribution de la dépression dans le processus du décrochage scolaire : une investigation empirique sur les effets de médiation et de modération

Quiroga, Cintia January 2008 (has links)
Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal.
6

Comprendre la contribution de la dépression dans le processus du décrochage scolaire : une investigation empirique sur les effets de médiation et de modération

Quiroga, Cintia January 2008 (has links)
Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal
7

Est-ce que le Contrôle est un facteur de protection ou de vulnérabilité pour le décrochage scolaire chez les adolescents?

Langer, Caroline 10 1900 (has links)
Cette étude visait principalement à examiner si le Contrôle (« Conscientiousness ») modère la relation prédictive entre différents facteurs de risque et le décrochage chez les adolescents. Les données de l’étude Stratégie d’Intervention Agir Autrement (SIAA) ont été employées. L’échantillon compte 1864 adolescents âgés de 15 ans provenant de 62 écoles secondaires québécoises. Des analyses de régression logistique ont confirmé le pouvoir prédictif de certains facteurs de risque connus du décrochage (indiscipline scolaire, statut socioéconomique faible, engagement scolaire faible, rendement scolaire faible, retard scolaire, désengagement scolaire des amis et des relations conflictuelles avec les enseignants). Les analyses ont aussi révélé que le Contrôle modère la relation entre les relations conflictuelles avec les enseignants et le décrochage et s’avère donc un facteur de vulnérabilité. En effet, un adolescent qui a un niveau élevé de Contrôle est plus à risque de décrocher lorsqu’il a des relations conflictuelles avec les enseignants. / This study’s main goal is to determine if Conscientiousness moderates the relation between risk factors and dropping out of high school. This project is a secondary analysis of the data from the “Stratégie d’Intervention Agir Autrement” (SIAA) study. The sample includes 1864 15 years old adolescents who go to 62 different high schools in Quebec. Logistic regression analyses confirmed the importance of different risk factors in high school dropping out such as disobedience in school, socioeconomic status, commitment to school, performance in school, grade retention, friends’ lack of school commitment, and conflicting relationships with teachers. Moreover, it was revealed that Conscientiousness moderated the relation between conflicting relationships with teachers and dropping out and was therefore a vulnerability factor. Indeed, an adolescent who has a high level of Conscientiousness is more at risk of dropping out when s/he has conflicting relationships with his or her teachers.
8

Est-ce que le Contrôle est un facteur de protection ou de vulnérabilité pour le décrochage scolaire chez les adolescents?

Langer, Caroline 10 1900 (has links)
Cette étude visait principalement à examiner si le Contrôle (« Conscientiousness ») modère la relation prédictive entre différents facteurs de risque et le décrochage chez les adolescents. Les données de l’étude Stratégie d’Intervention Agir Autrement (SIAA) ont été employées. L’échantillon compte 1864 adolescents âgés de 15 ans provenant de 62 écoles secondaires québécoises. Des analyses de régression logistique ont confirmé le pouvoir prédictif de certains facteurs de risque connus du décrochage (indiscipline scolaire, statut socioéconomique faible, engagement scolaire faible, rendement scolaire faible, retard scolaire, désengagement scolaire des amis et des relations conflictuelles avec les enseignants). Les analyses ont aussi révélé que le Contrôle modère la relation entre les relations conflictuelles avec les enseignants et le décrochage et s’avère donc un facteur de vulnérabilité. En effet, un adolescent qui a un niveau élevé de Contrôle est plus à risque de décrocher lorsqu’il a des relations conflictuelles avec les enseignants. / This study’s main goal is to determine if Conscientiousness moderates the relation between risk factors and dropping out of high school. This project is a secondary analysis of the data from the “Stratégie d’Intervention Agir Autrement” (SIAA) study. The sample includes 1864 15 years old adolescents who go to 62 different high schools in Quebec. Logistic regression analyses confirmed the importance of different risk factors in high school dropping out such as disobedience in school, socioeconomic status, commitment to school, performance in school, grade retention, friends’ lack of school commitment, and conflicting relationships with teachers. Moreover, it was revealed that Conscientiousness moderated the relation between conflicting relationships with teachers and dropping out and was therefore a vulnerability factor. Indeed, an adolescent who has a high level of Conscientiousness is more at risk of dropping out when s/he has conflicting relationships with his or her teachers.

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