Caracterização do reservatório Marlim por inversão acústica / Marlim reservoir characterization by acoustic impendance

Tatiane Moura do Nascimento

30 August 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Exploracionistas tem grande interesse em sistemas turbidíticos, pois em geral estes compõem prolíficos plays exploratórios. No entanto, estes potenciais reservatórios se encontram muitas vezes perto ou abaixo de resolução sísmica. Dessa forma, no processo de inversão, é importante integrar os dados sísmicos com qualidade de resolução obtida a partir do seu pré-condicionamento, para que o resultado final possua características detalhadas das camadas. O pré-condicionamento possibilita melhora na resolução dos dados sísmicos, através da atenuação dos ruídos aleatórios. Como objetivo final, foi realizada a inversão acústica em dados sísmicos post stack, migrados em tempo, a um sistema de turbiditos na Bacia de Campos. O principal objetivo da inversão sísmica é transformar o dado de reflexão em propriedades petrofísicas quantitativas. A inversão para impedância acústica é comumente utilizada para predição de porosidade. O fluxo de trabalho proposto foi dividido em cinco estágios principais: pré-condicionamento sísmico do dado 3D, correlação poço-sísmica, construção do modelo de baixa frequência, inversão do dado, e estimativa da porosidade. Os resultados mostraram que o cubo de impedância acústica invertido possui resolução muito superior quando comparado com o dado em amplitude sísmica, possibilitando melhor visualização das feições geológicas do Campo de Marlim. Além de suas limitações, como desconsiderando os efeitos das variações de fluido e variações litológicas complexas sobre a relação porosidade/impedância, o método fornece uma ferramenta confiável para exploração sísmica. Detalhes mais precisos das propriedades petrofísicas podem ser obtidos através de métodos de inversão mais sofisticados, a partir de dados pre stack. / Exploracionists has great interest in turbidite systems, since these generally comprise prolific exploration plays. However, these potential reservoirs are often near or below seismic resolution. Thus, the inversion process is important to integrate the seismic data quality of the resolution obtained from its preconditioning, so that the end result has detailed characteristics of the layers. The preconditioning enables improved resolution of seismic data, through mitigation of random noise. As the final goal, the inversion was performed acoustic post stack seismic data, migrated time, to a system of turbidites in Campos Basin. The main purpose of seismic inversion is to transform the given reflection in quantitative petrophysical properties. The inversion for acoustic impedance is commonly used to predict porosity. The flow of the proposed work was divided into five main stages: pre-conditioning the seismic 3D data, well-tie correlation, construction of the model of low frequency, inversion of data and estimation of porosity. The results showed that the inverted acoustic impedance cube has much higher resolution compared to the seismic amplitude data, allowing greater visualization of geological features in the Marlim Field. Besides its limitations as ignoring the effects of changing the fluid and complex lithological variations on the relationship porosity / impedance, the method provides a reliable tool for seismic exploration. More precise details of petrophysical properties can be obtainedthrough inversion methods starting from sophisticated pre-stack data.

Impedância acústica

Inversão

Marlim

Inversion

Acoustic impedance

Marlim

GEOLOGIA

Caracterização do reservatório Marlim por inversão acústica / Marlim reservoir characterization by acoustic impendance

Tatiane Moura do Nascimento

30 August 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Exploracionistas tem grande interesse em sistemas turbidíticos, pois em geral estes compõem prolíficos plays exploratórios. No entanto, estes potenciais reservatórios se encontram muitas vezes perto ou abaixo de resolução sísmica. Dessa forma, no processo de inversão, é importante integrar os dados sísmicos com qualidade de resolução obtida a partir do seu pré-condicionamento, para que o resultado final possua características detalhadas das camadas. O pré-condicionamento possibilita melhora na resolução dos dados sísmicos, através da atenuação dos ruídos aleatórios. Como objetivo final, foi realizada a inversão acústica em dados sísmicos post stack, migrados em tempo, a um sistema de turbiditos na Bacia de Campos. O principal objetivo da inversão sísmica é transformar o dado de reflexão em propriedades petrofísicas quantitativas. A inversão para impedância acústica é comumente utilizada para predição de porosidade. O fluxo de trabalho proposto foi dividido em cinco estágios principais: pré-condicionamento sísmico do dado 3D, correlação poço-sísmica, construção do modelo de baixa frequência, inversão do dado, e estimativa da porosidade. Os resultados mostraram que o cubo de impedância acústica invertido possui resolução muito superior quando comparado com o dado em amplitude sísmica, possibilitando melhor visualização das feições geológicas do Campo de Marlim. Além de suas limitações, como desconsiderando os efeitos das variações de fluido e variações litológicas complexas sobre a relação porosidade/impedância, o método fornece uma ferramenta confiável para exploração sísmica. Detalhes mais precisos das propriedades petrofísicas podem ser obtidos através de métodos de inversão mais sofisticados, a partir de dados pre stack. / Exploracionists has great interest in turbidite systems, since these generally comprise prolific exploration plays. However, these potential reservoirs are often near or below seismic resolution. Thus, the inversion process is important to integrate the seismic data quality of the resolution obtained from its preconditioning, so that the end result has detailed characteristics of the layers. The preconditioning enables improved resolution of seismic data, through mitigation of random noise. As the final goal, the inversion was performed acoustic post stack seismic data, migrated time, to a system of turbidites in Campos Basin. The main purpose of seismic inversion is to transform the given reflection in quantitative petrophysical properties. The inversion for acoustic impedance is commonly used to predict porosity. The flow of the proposed work was divided into five main stages: pre-conditioning the seismic 3D data, well-tie correlation, construction of the model of low frequency, inversion of data and estimation of porosity. The results showed that the inverted acoustic impedance cube has much higher resolution compared to the seismic amplitude data, allowing greater visualization of geological features in the Marlim Field. Besides its limitations as ignoring the effects of changing the fluid and complex lithological variations on the relationship porosity / impedance, the method provides a reliable tool for seismic exploration. More precise details of petrophysical properties can be obtainedthrough inversion methods starting from sophisticated pre-stack data.

Impedância acústica

Inversão

Marlim

Inversion

Acoustic impedance

Marlim

GEOLOGIA

Investigating subsurface heterogeneities and its impact on the variation in interval velocities : implications to velocity modelling in the Bredasdorp basin

Hashim, Muazzam Ali

January 2015

>Magister Scientiae - MSc / Velocity modelling forms an integral part of the seismic interpretation process initially completed in two-way time. In order for a representative depth conversion, it is obligatory to construct a velocity model that serves the bridge between velocity and respective two-way time. This study deals with the investigation of subsurface heterogeneities and its impact on the variation of velocities. Interpretation of time domain reflection data results in one or more seismic horizons, however these horizons should represent the variation in subsurface geology as a result of acoustically different layers displaying varying reflection amplitudes. The purpose of this study was fulfilled by examining the variation of these velocities in relation to the geology and its significance towards building a velocity model. It is evident that complexities, such as an existing heterogeneous subsurface is present in the study area. Using velocities only considered at formation well tops, as a result, does not completely honour the variation in these velocities. The velocity profile as calculated from the sonic log was characterized into zones representing unique velocity trends. The analyses to understand the impact of subsurface heterogeneities on the velocities was completed by the application of seismic facies analysis which entailed the study of the seismic reflector patterns and amplitudes; a study of the lithologies present and the generation of mineral plots using available wireline logs, all of which in close relation to the variation in velocities. The characterized zones, as a result have shown that shaly sediments are typically associated with higher velocities (~2800 – 4600m/s) compared to sandstones of lower densities. Mineral plots however, have also indicated that where quartz minerals were present (specifically zone L), sandstones as a result have shown higher velocities (~4800m/s) as compared to the shales (~3600m/s). These higher velocities are also associated with more organised seismic reflectors with brighter amplitudes and strong contrasts in acoustic impedance as shown by the seismic. Uniform velocities were observed in zones such as zone Ia, typically associated with a low acoustic impedance contrast and minimal variation in its lithological make-up. The integrated investigation of subsurface heterogeneities has shown that velocities vary to a substantial degree as a result of existing subsurface heterogeneities. The variation of these velocities are hence significant enough that it should be considered when constructing a velocity model which aims to respect the geology of the study area. The result of understanding the relation between the geology and resultant velocities may prove to advance the results of the velocity model in a manner that it is more complete and representative of the subsurface.

Heterogeneity

Velocity modelling

Interval velocities

Acoustic impedance

Seismic facies

Padrão de análise da timpanometria com sonda de 226 Hz na criança considerando a pressão do pico de máxima compliância e a compliância estática / Tympanometry analysis standard with 226 Hz of age six months to three years considering the pressure of the peak of maximum compliance and the static compliance

Alana Ribeiro de Melo

08 May 2017

A análise precisa dos resultados da timpanometria é essencial para determinar a condição da orelha média, principalmente em crianças nos primeiros anos de vida. Assim, o objetivo deste estudo foi apresentar um padrão de análise da timpanometria com sonda de 226 Hz para a faixa etária de seis meses a três anos, considerando a pressão do pico de máxima compliância e a compliância estática. Foram analisados prontuários de crianças de seis meses a três anos de idade atendidas no período de outubro de 2012 a fevereiro de 2016 no Centro de Pesquisas Audiológicas - Seção de Implante Coclear do Hospital de Reabilitação de Anomalias Craniofaciais e na Clínica de Audiologia Infantil da Clínica de Fonoaudiologia da Faculdade de Odontologia de Bauru, ambos da Universidade de São Paulo. A casuística foi dividida em dois grupos: grupo sem alteração de orelha média, composto por 224 orelhas, e o grupo com alteração de orelha média, composto por 59 orelhas. Foram considerados para análise os valores de pressão do pico de máxima compliância (daPa) e de compliância estática (ml) obtidos na timpanometria com sonda de 226Hz. No grupo sem alteração, o Teste Correlação Mann Whitney revelou que não houve diferença significante entre os sexos para pressão do pico de máxima compliância (p=0,782) e para a compliância estática (p=0,085). Também não houve correlação dos valores de pressão (p=0,678) e compliância (p=0,079) com a idade, de acordo com o Teste Correlação de Spearman. Considerando o intervalo entre os percentis 2,5 e 97,5 obtidos para a pressão e compliância nos grupos sem e com alteração, observou-se uma faixa de valores comum aos dois grupos, ou seja, os valores contidos nesta faixa não conseguiram classificar a orelha média como normal ou alterada. De acordo com os percentis 2,5 e 97,5, foi possível estabelecer uma faixa de normalidade para a pressão do pico de máxima compliância, de +52 daPa a -100 daPa, e para compliância estática, de 0,20 ml a 0,68 ml. Enquanto que na faixa de alteração, os valores variaram de -259 a 17,52 daPa para pressão e de 0,04 a 0,41 ml para a compliância. Assim, uma faixa de intersecção foi identificada, correspondente ao intervalo de -100 a 17,52 daPa para pressão do pico de máxima compliância e de 0,2 a 0,41 ml para a compliância estática. A análise dos dados demonstrou que a timpanometria com sonda de 226 Hz apresentou alta sensibilidade e baixa especificidade na faixa etária de seis meses a três anos. / Accurate analysis of tympanometry results is essential to determine the condition of the middle ear, especially in children in their first years of life. Thus, this study aimed at presenting a standard analysis of tympanometry with a 226 Hz probe for the age range six months to three years, taking into account the pressure of the peak of maximum compliance and static compliance. The records of 6-month to three-year old children assisted from October 2012 to February 2016 at the Audiology Research Center - Cochlear Implant Section of the Craniofacial Anomalies Rehabilitation Hospital and at the Children\'s Audiology Clinic of the Audiology and Speech-Language Pathology Clinic of the Bauru Dentistry School, both of the University of São Paulo, were analyzed. The sample was divided into two groups: a group with no middle ear alteration comprising 224 ears and the group with middle ear alteration composed of 59 ears. For analysis, the pressure values of the maximum compliance peak (daPa) and static compliance (ml) obtained in the tympanometry with a 226Hz probe were considered. In the group with no alteration, the Mann Whitney Correlation Test showed no significant difference between the genders for the maximum compliance peak pressure (p = 0.782) and for static compliance (p = 0.085). No difference was seen, either, for pressure (p = 0.678) and compliance (p = 0.079) values, according to age, by using the Spearman Correlation Test. Considering the interval between percentiles 2,5 and 97,5 obtained for pressure and compliance in the groups without and with alteration, a range of values common for the two groups was observed, that is, the values contained in this range could not classify the Middle ear as normal or altered. According to percentiles 2,5 and 97,5, it was possible to establish a range of normality for the pressure of the maximum compliance peak, from +52 daPa to -100 daPa, and for static compliance, from 0.20 ml to 0.68 ml, while in the alteration range, values ranged from -259 to 17,52 daPa for pressure and from 0,04 to 0,41 ml for compliance. Thus, an intersection range was identified, corresponding to the interval of -100 to 17,52 daPa for the pressure of the maximum compliance peak and 0,2 to 0,41 ml for the static compliance. Data analysis showed that tympanometry with a 226 Hz probe presented high sensitivity and low specificity in the 6-month to 3-year age range.

Complacência

Orelha média

Testes de impedância acústica

Acoustic impedance tests

Compliance

Middle ear

Use of Phase and Amplitude Gradient Estimation for Acoustic Source Characterization and Localization

Lawrence, Joseph Scott

01 July 2018

Energy-based acoustic quantities provide vital information about acoustic fields and the characterization of acoustic sources. Recently, the phase and amplitude gradient estimator (PAGE) method has been developed to reduce error and extend bandwidth of energy-based quantity estimates. To inform uses and applications of the method, analytical and experimental characterizations of the method are presented. Analytical PAGE method bias errors are compared with those of traditional estimation for two- and three-microphone one-dimensional probes. For a monopole field when phase unwrapping is possible, zero bias error is achieved for active intensity using three-microphone PAGE and for specific acoustic impedance using two-microphone PAGE. A method for higher-order estimation in reactive fields is developed, and it is shown that a higher-order traditional method outperforms higher-order PAGE for reactive intensity in a standing wave field. Extending the applications of PAGE, the unwrapped phase gradient is used to develop a method for directional sensing with improved bandwidth and arbitrary array response.

acoustic intensity

reactive intensity

specific acoustic impedance

directional pressure

bandwidth extension

Astrophysics and Astronomy

Physical systems for the active control of transformer noise

Li, Xun

January 2000

Traditional means of controlling sound radiated by electrical power transformers involve the construction of large expensive barriers or full enclosures, which cause maintainability and cooling problems. One promising alternative is to use active noise control to cancel the noise. This thesis is concerned with one of the many problems which need to be investigated to develop a practical active noise cancellation system for transformers. This work, in particular, is concerned with the physical system design which includes the selection of the control source types and the evaluation of the near-field sensing strategies. Loudspeakers have been widely used in the past as an acoustic source for canceling transformer noise. The principal disadvantage of using loudspeakers is that to achieve global noise control, a large number, driven by a multi-channel controller, are required. However, if large panels are used in place of loudspeakers as control sources, it is possible that the number of the control sources and complexity of the controller could be reduced substantially. In addition to reducing the number of control sources and simplifying their application, panel sound sources could also overcome some disadvantages of the loudspeakers, such as limited life and deterioration due to the weather. Thus, part of the work described in this thesis is concerned with the development of a resonant curved panel with a backing cavity as an acoustic type source. The advantages of using a curved panel rather than a flat panel are twofold: first a curved panel is more easily excited by the extensional motion of the piezoelectric patch actuators; and second, it is more difficult to adjust the resonance frequencies of the efficient modes of a flat panel than of a curved panel. The analytical models for the design of the panel cavity systems have been developed. As an example, a resonant curved panel with a backing cavity system was constructed and the sound radiation of the system was measured. Results show that a resonant panel-cavity sound source could be used as an alternative to a number of loudspeakers for active cancellation of electric power transformer noise. Due to the advantages of using the vibration type control sources, two types of vibration control sources (inertial electrodynamic shakers and piezoelectric patch actuators) were considered and the mechanical output of the inertial shakers has been compared with that of the piezoelectric actuators. In contrast with the piezoelectric actuators, the resonance frequencies of the inertial shakers can be tuned to the frequencies of interest using simple tuning procedures, so that the output efficiency of the shakers can be increased. The output performance was evaluated for two types of actuators by measuring the structural response of either a panel or a transformer when excited by the actuators at half their rated voltage input. Results demonstrated that a much larger output amplitude at the frequency of interest can be achieved by the tuned inertial type actuators. Two near-field sensing strategies, the minimization of the sum of the sound intensities and the minimization of the sum of the squared sound pressures, have been studied. A quadratic expression was derived for the minimization of the sum of the sound intensities in the near-field. To evaluate the control performances achieved using both sensing strategies, a flat-panel was modelled with a harmonic point force disturbance and several point force control sources. Simulation results show that the control performance could be improved by minimizing the sum of the sound intensities in the hydrodynamic near-field, provided that a very large number of error sensors were used, otherwise better results were achieved using near-field squared pressure sensing. Both sensing strategies were used to predict the noise reductions that resulted for the active noise control of a small transformer in the laboratory environment and for a large electrical power transformer on site. To optimize the locations of the control sources (for the large transformer on site) and the locations of the error sensors (for the small transformer in the laboratory environment), a genetic algorithm (GA), which is an evolutionary optimization technique, was employed as a search procedure to optimize the control source and error sensor locations. The results showed that the control source locations and/or the error sensor locations must be optimized to achieve the maximum sound reduction for either error sensing strategy, especially for the sound intensity minimization; otherwise, the sound field level may increase after control due to the character of the cost function (the sum of the sound intensities). The simulation results were experimentally validated for the small transformer in the laboratory environment. Due to the limitation of the number of controller channels, the control performance was only evaluated for squared pressure minimization. The results demonstrated that for the case of 8 control sources and 8 error sensors, at 100 Hz, an average sound pressure reduction of 15.8 dB was achieved when evaluated at 528 monitoring locations at 0.25 m intervals on a surface that surrounded the transformer. / Thesis (Ph.D.)--Engineering (Department of Mechanical Engineering), 2000.

Modelling and Characterization of Perforates in Lined Ducts and Mufflers

Elnady, Tamer

January 2004

Increased national and international travel over the lastdecades has caused an increase in the global number ofpassengers using different means of transportation. Greateffort is being directed to improving the noisy environment inthe residential community. This is to face the growing strictnoise requirements which are implemented by international noiseregulatory authorities, governments, and local airports. Thereis also a strong competition between different manufacturers tomake their products quieter. The propulsion system in anaircraft is the major source of noise during relevant flightconditions. The engine noise in a vehicle dominates the totalradiated noise at low speeds especially inside cities. Manyrecent studies on noise reduction involve the use of perforatedplates in the air and gas flow ducting connected to the engine.This thesis deals with the modelling of perforates as anabsorbent. There are many difficulties in using liners in theseapplications. The most important is that there is no largesurface area to which the linings may be applied. Equally, theenvironment in which linings have to survive is hostile.Therefore, liners have to be carefully tailored in order toachieve the most efficient attenuation. The full-scalesimulation testing, which is usually necessary to define thenoise attenuation produced by a liner installation, is bothtime-consuming and expensive. Therefore, a need for accuratemodels is a must. This thesis fills some gaps in the impedancemodelling of perforated liners. It also concentrates on thosecomplicated situations of sound propagation in ducts that weresolved earlier using Finite Element Methods. Alternateanalytical solutions to these problems are developed here,which gives more physical insight into the results. The key design parameter of perforates is the acousticimpedance. The impedance is what determines their efficiency toabsorb sound waves. A semi empirical impedance model wasdeveloped to be capable of accurately predicting the linerimpedance as a function of its physical properties and thesurrounding conditions. It was compared to all previous modelsin the literature. Nothing in the literature has been reportedon the effect of temperature on the perforate impedance,therefore a complete study was performed. A new inverseanalytical impedance measurement technique was proposed. It isbased on educing the impedance value based on the measurementof the attenuation across a lined duct section. Twoapplications were further considered: The effect of hard stripsin lined ducts on there attenuation properties; and themodelling of perforations in a complicated automotive mufflersystem. Keywords:Perforates–Liners–Acousticimpedance–Hot stream liners–Hard splices–Mufflers–Lined ducts–Collocation–Flowduct.

Perforates

Liners

Acoustic impedance

Hot stream liners

Hard splices

Mufflers

Lined ducts

Collocation

Flow duct.

In Situ Measurements of Acoustic Properties of Surfaces

Mallais, Scott

January 2009

The primary goal of this work is to measure the acoustic properties of a surface in situ. This generally involves sound pressure measurements and a calculation of the acoustic reflection factor of a surface, which may then be used to calculate the acoustic impedance or the acoustic absorption coefficient. These quantities are of use in acoustic simulations, architectural design, room acoustics and problems in noise control. It is of great interest to determine the performance of a particular surface where it is used, as opposed to measurements conducted in a laboratory. In situ measurements are not trivial, caution must be taken to ensure that high signal-to-noise levels are achieved and that the reflections of sound from the measurement environment are taken into consideration. This study presents five measurement methods that may be applied in situ. The acoustic absorption coefficient is calculated for each method on various surfaces spanning the whole range of absorption. Emphasis is placed on frequency resolution, in order to determine absorption characteristics in the bass region (50 Hz to 200 Hz). Advantages and disadvantages of each method are demonstrated and discussed. Finally, the in situ implementation of the surface pressure method is presented and measurements are made in order to test the limitations of this approach.

acoustic absorption

absorption coefficient

in situ

acoustic impedance

in situ measurements

measurement of acoustic absorption

Physics

In Situ Measurements of Acoustic Properties of Surfaces

Mallais, Scott

January 2009

The primary goal of this work is to measure the acoustic properties of a surface in situ. This generally involves sound pressure measurements and a calculation of the acoustic reflection factor of a surface, which may then be used to calculate the acoustic impedance or the acoustic absorption coefficient. These quantities are of use in acoustic simulations, architectural design, room acoustics and problems in noise control. It is of great interest to determine the performance of a particular surface where it is used, as opposed to measurements conducted in a laboratory. In situ measurements are not trivial, caution must be taken to ensure that high signal-to-noise levels are achieved and that the reflections of sound from the measurement environment are taken into consideration. This study presents five measurement methods that may be applied in situ. The acoustic absorption coefficient is calculated for each method on various surfaces spanning the whole range of absorption. Emphasis is placed on frequency resolution, in order to determine absorption characteristics in the bass region (50 Hz to 200 Hz). Advantages and disadvantages of each method are demonstrated and discussed. Finally, the in situ implementation of the surface pressure method is presented and measurements are made in order to test the limitations of this approach.

acoustic absorption

absorption coefficient

in situ

acoustic impedance

in situ measurements

measurement of acoustic absorption

Physics

Development Of An Effective Single Layer Micro-perforated Sound Absorber

Onen, Onursal

01 October 2008

Micro-perforated sound absorbers with sub-millimeter size holes can provide high absorption coefficients. Various types of micro-perforated absorbers are now available in literature for different applications. This thesis presents results of work on the development of an effective single layer micro-perforated sound absorber from the commercial composite material Parabeam with micro diameter holes drilled on one side. Parabeam is used as a structural material made from a fabric woven out of a E-glass yarn and consists of two decklayers bonded together by vertical piles in a sandwich structure with piles (thick fibers) woven into the decklayers. The thesis includes, the analytical model developed for prediction of absorption coefficients, finite element solution using commercial software MSC.ACTRAN and experimental results obtained from impedance tube measurements. Different absorption characteristics can be achieved by variations in hole diameter and hole spacing. Based on the developed models, an optimization is performed to obtain an efficient absorber configuration. It has been anticipated that several different and interesting applications can be deduced by combining structural and sound absorption properties of this new micro-perforated absorber along with conventional fibrous absorbers.

TJ Mechanical Engineering. 1-1570