Atmospheric singular vectors and teleconnections

Will, Andreas, Harlander, Uwe, Metz, Werner

31 January 2017

Bekanntlich sind atmosphärische Rossbywellezüge (RWTs) Lösungen der Singular Vector Analyse eines gedämpften, barotropen Modells mit Nordwinter Grundströmen. In den SV Basen der verwendeten 40 DJF Grundströme konnten nur wenige wachsende den Rossbywellenzügen ähnliche (RWT Moden) Singulären Vektoren (SVen) gefunden werden. Die RWT Moden kommen nur in wenigen Gebieten der Erde vor. Die instabilste Mode entwickelt sich in der Region des Nordpazifiks (NPACs) innerhalb von 4 Tagen in jedem der verwendeten beobachteten DJF Grundströme. Alle anderen RWT Moden kommen nur bei Verwendung einiger der Grundströme vor. Ihre Entwicklungspfade sind eindeutig für Entwicklungszeiten bis zu 96 h und streuen für längere Zeiten. Die NPAC Mode erklärt zum Optimierungszeitpunkt 96 h bis zu 60 % der atmosphärischen kinetischen Energie (KE) auf der 300 hPa Fläche in der NPAC Region. Es konnte auch gezeigt werden, daß die Zeitreihe des beobachteten Wachstums der NPAC Mode mit dem berechneten Wachstum (den Eigenwerten) konsistent ist. Interessanterweise zeigt die NPAC-KE zum Optimierungszeitpunkt 96 h auch eine schwach signifikante Korrelation mit dem PNA-Index, die für die Optimierungszeit 144 h nicht mehr existiert. Die Ergebnisse legen die Vermutung nahe, daß die verwendeten Grundströme die Entwicklung der RWT Moden bis zu einer Entwicklungszeit von 4 Tagen dominieren und daß die finite Instabilität maßgeblich zur Entwicklung der beobachteten NPAC Rossbywellenzüge in der Atmosphäre beiträgt. Die Ergebnisse geben Hinweise darauf, daß die NPAC mode auch einen Beitrag zur Entwicklung der PNA leistet.

Rossbywelle

singulärer Vektor

Rossby wave

singular vector

ddc:551

Atmospheric singular vectors and teleconnections

Will, Andreas, Harlander, Uwe, Metz, Werner

31 January 2017

Bekanntlich sind atmosphärische Rossbywellezüge (RWTs) Lösungen der Singular Vector Analyse eines gedämpften, barotropen Modells mit Nordwinter Grundströmen. In den SV Basen der verwendeten 40 DJF Grundströme konnten nur wenige wachsende den Rossbywellenzügen ähnliche (RWT Moden) Singulären Vektoren (SVen) gefunden werden. Die RWT Moden kommen nur in wenigen Gebieten der Erde vor. Die instabilste Mode entwickelt sich in der Region des Nordpazifiks (NPACs) innerhalb von 4 Tagen in jedem der verwendeten beobachteten DJF Grundströme. Alle anderen RWT Moden kommen nur bei Verwendung einiger der Grundströme vor. Ihre Entwicklungspfade sind eindeutig für Entwicklungszeiten bis zu 96 h und streuen für längere Zeiten. Die NPAC Mode erklärt zum Optimierungszeitpunkt 96 h bis zu 60 % der atmosphärischen kinetischen Energie (KE) auf der 300 hPa Fläche in der NPAC Region. Es konnte auch gezeigt werden, daß die Zeitreihe des beobachteten Wachstums der NPAC Mode mit dem berechneten Wachstum (den Eigenwerten) konsistent ist. Interessanterweise zeigt die NPAC-KE zum Optimierungszeitpunkt 96 h auch eine schwach signifikante Korrelation mit dem PNA-Index, die für die Optimierungszeit 144 h nicht mehr existiert. Die Ergebnisse legen die Vermutung nahe, daß die verwendeten Grundströme die Entwicklung der RWT Moden bis zu einer Entwicklungszeit von 4 Tagen dominieren und daß die finite Instabilität maßgeblich zur Entwicklung der beobachteten NPAC Rossbywellenzüge in der Atmosphäre beiträgt. Die Ergebnisse geben Hinweise darauf, daß die NPAC mode auch einen Beitrag zur Entwicklung der PNA leistet.

Rossbywelle, singulärer Vektor

Rossby wave, singular vector

info:eu-repo/classification/ddc/551

ddc:551

Aplicação de métodos estáticos para estudo do colapso de tensão em Sistemas Elétricos de Potência / not available

Guedes, Renato Braga de Lima

18 August 2000

Este trabalho descreve os métodos e os resultados encontrados a partir da implementação de métodos estáticos para análise da estabilidade de tensão em sistemas elétricos de potência. A determinação da margem de estabilidade de tensão foi feita através do cálculo do menor valor singular da matriz jacobiana associada às equações de fluxo de carga, comumente utilizado como índice estático de colapso de tensão. As não linearidades e descontinuidades relatadas nas referências estudadas e encontradas nos testes realizados, levaram-nos a propor o uso da razão entre o menor e o maior valores singulares da mesma matriz jacobiana, na expectativa de que este índice tivesse um comportamento menos instável do que o menor valor singular, o que não foi confirmado nos testes realizados. Identifica-se também as regiões do sistema elétrico mais afetadas pela instabilidade, o que é feito através da determinação da barra crítica do sistema e da classificação das barras de carga em ilhas de controle de tensão. A barra crítica é identificada através do cálculo do vetor tangente do sistema, conforme proposto nas referências citadas no trabalho. Como alternativa ao vetor tangente para a identificação da barra crítica, propôs-se usar o vetor singular à direita associado ao menor valor singular da matriz jacobiana. A comparação da capacidade de identificação da barra crítica por esses dois vetores mostrou uma clara vantagem do uso do vetor tangente. A rotina para identificação das ilhas de controle de tensão foi adaptada a partir de um método desenvolvido para a análise de coerência em barras de carga, e os resultados encontrados foram bastante satisfatórios. Os métodos implementados foram testados em diversas situações, com o objetivo de se analisar os efeitos dos modelos de carga ZIP com elevadas parcelas de impedância constante, dos limitadores de potência reativa dos geradores e da repartição do incremento da carga de potência ativa entre os geradores. / This work describes the methods and results got from the implementation of static methods for power systems voltage stability analisys. The power system voltage stability margin was predicted by the smallest load flow jacobian\'s singular value, commonly used as a prediction index to voltage stability. lt is investigated the use of ratio of the smallest single value by the biggest one as voltage colapse index, assuming that it\'s less unstable than the singular value itself, specialy near the collapse point. The results presented shown a clear advantage of using the smallest singular value instead of this singular value rate. The identification of the system\'s regions affected by the voltage drop is made by the tangent vector and by the voltage island identification method proposed on this work. Is compared the ability to identify system\'s critical bus by the tangent vector and right singular vetor of the smallest jacobian\'s singular value. In this case, tests results show the superiority of tangent vector. All the simulations presented are compared to allow the analysis of the voltage dependents load models (with high percentual of constant impedances), reactive limiters and generators load sharing efects over the smallest singular value, the rate of the smallest single value by the biggest one, voltage island classification and the critical bus identification.

Estabilidade de tensão

Ilha de controle de tensão

Singular value

Singular vector

Tangent vector

Valor singular

Vetor singular

Vetor tangente

Voltage control island

Voltage stability

Time-Frequency Based Detection of Newborn EEG Seizure

Hassanpour, Hamid

January 2004

Neurological diseases in newborns are usually first revealed by seizures, which are characterised by a synchronous discharge of a large number of neurons. Failure to control seizures may lead to brain damage or even death. The importance of this problem prompted many researchers to look for accurate automatic methods for seizure detection. Nonstationarity and multicomponent behaviour of newborn EEG signals made this task very challenging. The significant overlap in the characteristic of background and seizure activities in newborn EEG signals added to the difficulty of seizure detection. This research uses time-frequency based methods for automatic seizure detection. Since time-frequency signal analysis methods use joint representation in both time and frequency domains, they proved to be very suitable for analysis and processing of nonstationary and multicomponent signals such as newborn EEG. Before using any seizure detector, the EEG data is pre-processed in order to reduce the noise effects using a time-frequency based technique. The proposed method is based on the singular value decomposition (SVD) technique applied to the matrix representing the time-frequency distribution (TFD) of the EEG signal. It has been shown that by appropriately filtering the singular vectors associated with the TFD, one can effectively enhance the desired information embedded in the signal. Neonatal EEG seizures can have signatures in both low frequency (lower than 10 Hz) and high frequency (higher than 70 Hz) areas. The seizure detection techniques proposed in the literature concentrated on using either low frequency or high frequency signatures but not both simultaneously. These methods tend to miss the seizures that reveal themselves only in one of the two frequency areas. In this research, we propose a detection method that uses seizure features in both low and high frequency areas. To detect EEG seizures using the low frequency signatures, an SVD-based technique is employed. The technique uses the estimated distribution function of the singular vectors associated with the time-frequency distribution of EEG epochs to discriminate between seizure and nonseizure patterns. The high frequency signatures of seizures are mostly the result of spike events in the EEG signals. To detect these spike events, the signal is mapped into the TF domain. The high instantaneous energy of spikes is reflected as a localised energy in the high frequency area of the TF domain. Consequently, a spike can be seen as a ridge in this area of the TF domain. It has been shown that during seizure activity there is regularity in the distribution of the interspike intervals. This feature has been used as the basis for discriminating between seizure and nonseizure patterns. The performance results obtained by applying the proposed methods on EEG signals extracted from a number of newborns show the superiority of these methods over the existing ones.

electroencephalogram

seizure

time-frequency signal processing

spike

detection

enhancement

singular value decomposition

singular vector

density function

histogram

Jensen function

filtering

seizure migration

Aplicação de métodos estáticos para estudo do colapso de tensão em Sistemas Elétricos de Potência / not available

Renato Braga de Lima Guedes

18 August 2000

Este trabalho descreve os métodos e os resultados encontrados a partir da implementação de métodos estáticos para análise da estabilidade de tensão em sistemas elétricos de potência. A determinação da margem de estabilidade de tensão foi feita através do cálculo do menor valor singular da matriz jacobiana associada às equações de fluxo de carga, comumente utilizado como índice estático de colapso de tensão. As não linearidades e descontinuidades relatadas nas referências estudadas e encontradas nos testes realizados, levaram-nos a propor o uso da razão entre o menor e o maior valores singulares da mesma matriz jacobiana, na expectativa de que este índice tivesse um comportamento menos instável do que o menor valor singular, o que não foi confirmado nos testes realizados. Identifica-se também as regiões do sistema elétrico mais afetadas pela instabilidade, o que é feito através da determinação da barra crítica do sistema e da classificação das barras de carga em ilhas de controle de tensão. A barra crítica é identificada através do cálculo do vetor tangente do sistema, conforme proposto nas referências citadas no trabalho. Como alternativa ao vetor tangente para a identificação da barra crítica, propôs-se usar o vetor singular à direita associado ao menor valor singular da matriz jacobiana. A comparação da capacidade de identificação da barra crítica por esses dois vetores mostrou uma clara vantagem do uso do vetor tangente. A rotina para identificação das ilhas de controle de tensão foi adaptada a partir de um método desenvolvido para a análise de coerência em barras de carga, e os resultados encontrados foram bastante satisfatórios. Os métodos implementados foram testados em diversas situações, com o objetivo de se analisar os efeitos dos modelos de carga ZIP com elevadas parcelas de impedância constante, dos limitadores de potência reativa dos geradores e da repartição do incremento da carga de potência ativa entre os geradores. / This work describes the methods and results got from the implementation of static methods for power systems voltage stability analisys. The power system voltage stability margin was predicted by the smallest load flow jacobian\'s singular value, commonly used as a prediction index to voltage stability. lt is investigated the use of ratio of the smallest single value by the biggest one as voltage colapse index, assuming that it\'s less unstable than the singular value itself, specialy near the collapse point. The results presented shown a clear advantage of using the smallest singular value instead of this singular value rate. The identification of the system\'s regions affected by the voltage drop is made by the tangent vector and by the voltage island identification method proposed on this work. Is compared the ability to identify system\'s critical bus by the tangent vector and right singular vetor of the smallest jacobian\'s singular value. In this case, tests results show the superiority of tangent vector. All the simulations presented are compared to allow the analysis of the voltage dependents load models (with high percentual of constant impedances), reactive limiters and generators load sharing efects over the smallest singular value, the rate of the smallest single value by the biggest one, voltage island classification and the critical bus identification.

Estabilidade de tensão

Ilha de controle de tensão

Valor singular

Vetor singular

Vetor tangente

Singular value

Singular vector

Tangent vector

Voltage control island

Voltage stability

Classification analytique de germes de champs de vecteurs tridimensionnels doublement résonants et applications aux équations de Painlevé / Analytic classification of germs of three-dimensional doubly-resonant vector fields and applications to Painlevé equations

Bittmann, Amaury

10 October 2016

On considère des germes de champs de vecteurs holomorphes singuliers trimimensionnels, appelés noeud-cols doublement résonants. Ces champs de vecteurs correspondent à des systèmes différentiels bidimensionnels à singularité irrégulière, et dont la partie linéaire possède deux valeurs propres non-nulles opposées. Ce type de singularité apparait par exemple à l'infini dans les équations de Painlevé PI,...,PV après compactification à poids de l'espace, pour des valeurs génériques des paramètres. Depuis Boutroux, l'étude de ces singularités a générè de nombreux travaux de recherche. Récemment, plusieurs auteurs ont fournis des informations nouvelles, en étudiant notamment les phénomènes de Stokes non-linéaires et quasi-linéaires associés, en donnant des formules de connexion. Les coefficients de Stokes quasi-linéaires sont invariants sous l'action de changement de coordonnées analytiques locaux, mais ne forment pas un système complet d'invariants analytiques. L'objectif de ce travail de thèse est de fournir une classification analytique générale et complète des noeud-cols doublement résonants. L'idée pour cela est d'adapter les travaux de Martinet et Ramis, généralisés ensuite par Stolovitch. Dans une première partie on fournit une classification formelle, i.e. sous l'action de changements de coordonnées formels, en exhibant des formes normales formelles. Dans un second temps, on étudiera l'existence de normalisations sectorielles (analytiques sur des secteurs), généralisant ainsi un théorème de Hukuhara-Kimura-Matuda. Enfin, on étudiera les recollements entre ces applications normalisantes dans les domaines d'intersections: c'est ce que l'on appellera les difféomorphismes de Stokes. Il s'agira là d'étudier des isotropies sectorielles de la forme normale. On verra que la donnée d'une forme normale formelle et d'un couple de difféomorphismes de Stokes fournira un système complet d'invariants analytiques. Enfin, dans une quatrième et dernière partie, nous calculerons certains de ces invariants pour la singularité irrégulière à l'infini de la première équation de Painlevé. / We consider germs of analytic singular vector fields in dimension three, called doubly-resonant saddle-nodes. These vector fields correspond to irregular two-dimensional systems with a pair of two opposite non-zero eigenvalues. This king of singularity appears for instance at infinity in Painlevé equations PI,...,PV, after a weighted compactifcation, for generic values of the parameters. Since Boutroux, the study of these singularities has generated many researches. Recently, several authors provided new informations, by studying for instance the associated non-linear and quasi-lineair Stokes phenomenas and by giving connection formulas. Quasi-linéaire Stokes coefficients are invariant under local analytic change of coordinates, but do not form a complete set of invariants for analytic classification. The goal of this work is to provide a complete analytic classification of doubly-resonant saddle-nodes. The idea for this is to adapt the works of Martinet and Ramis, generalized then by Stolovitch. In the first part, we give a formal classification, based on the existence on unique formal normal forms. In the second part, we prove the existence of sectorial nomalizing maps (analytic over sectors), generalizing a theorem by Hukuhara-Kimura-Matuda. In the third part, we study the Stokes diffeomorphisms, and more generaly the sectorials isotropies of the normal form. We obtain a complet set of analytic invariants. Finally, in the fourth part, we compute some of these invariants in the case of the first Painlevé equation.

Champs de vecteurs singuliers

Équations différentielles

Résonance

Équations de Painlevé

Classification analytique

Formes normales

Singular vector fields

Differential equations

Resonance

Painlevé equations

Normal forms

515.3

516.3