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Mission-Oriented Seismic Research Program: Annual Meeting and Technical Review

Mission-Oriented Seismic Research Program: Annual Meeting and Technical Review. M-OSRP Annual Meeting 20-21 April, 2005 University of Houston. Introduction. 1. Welcome 2. Program objectives, projects and progress. Program Objectives. To address and solve prioritized

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Mission-Oriented Seismic Research Program: Annual Meeting and Technical Review

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  1. Mission-Oriented Seismic Research Program: Annual Meeting and Technical Review M-OSRP Annual Meeting 20-21 April, 2005 University of Houston

  2. Introduction 1. Welcome 2. Program objectives, projects and progress

  3. Program Objectives To address and solve prioritized seismic E&P challenges

  4. Seismic E&P The objective is to use reflected seismic data to make useful inferences about the subsurface; in particular, to locate and delineate hydrocarbon targets

  5. Categories of Events Primary Free-surfacemultiple Internal multiple

  6. Let’s discuss the meaning and relevance of a word that you will hear during these presentations: Non-linear

  7. A method (or seismic objective) is non-linear in a processing senseif a multiplication of data by data (and, in general, sums of such products) is required to achieve a given goal.

  8. There are two kinds of non-linearity: (1) Intrinsic (2) Circumstantial Intrinsic non-linearity is always present while circumstantial depends on your ability to bring accurate and adequate information to a given problem.

  9. These two types can occur simultaneously. The inverse scattering series is a multidimensional direct inversion method that addresses both types of non-linearity.

  10. --It provides the only direct inversion method for the intrinsic non-linearity (e.g., non-linear AVO) with a known overburden

  11. --It provides the only direct method where only the situational non-linearity is the issue (e.g., migration without the correct velocity ) and internal multiple elimination with absolutely no subsurface information, whatsoever.

  12. --It provides the only direct multidimensional method where both types of non-linear issues are present (e.g., non-linear AVO in the presence of an unknown overburden)

  13. In each of these cases it is unique in its ability, and there is no other candidate method able to achieve one of those isolated objectives, let alone those in combination.

  14. Although powerful and impressive, it has prerequisites for useful, impactful application. Among them: The source signature in water; Deghosted data; Wave theory data collection The inverse scattering series doesn’t directly provide its own prerequisites. The extinction theorem provides that opportunity for (1) and (2).

  15. FS Marine events didn’t experience the earth experienced the earth no ghost ghost primaries + internal multiples free surface multiples primaries internal multiples locate invert

  16. FS Tools Marine events Green’s theorem Scattering Series experienced the earth didn’t experience the earth no ghost ghost primaries + internal multiples free surface multiples primaries internal multiples locate invert

  17. Before we go to the ISS, let’s take a look at a few simple examples of these non-linear ideas.

  18. Consider the simplest seismic problem 1 R The reflection coefficient, R, is given in terms of C0 and C1 as

  19. Let

  20. Hence C1-C0 is non-linear in R and no apriori information circumstance about the target can change that fact. It is convenient in scattering theory to characterize the difference betweenC0 and C1 as

  21. Where for the one reflector problem the relationship becomes and is a number. Given C0and we can find C1, just as before given C0 and we find C1.

  22. The inverse problem (in this representation) is to find (given C0) fromR

  23. Similarly equation (1) can be solved for in terms of R and a Taylor series for R in terms of results in Hence, the simplest inverse problem to imagine is non-linear.

  24. Other issues and conditions that determine form of linear or non-linearity in inverse scattering processing 1. Type and extent of a-priori information 2. Whetherthe processing objective is output as data in time or as a function of space, x, y and z.

  25. To illustrate issue 1 Consider multiples, ocean bottom multiples in particular If you provide source character and location, ocean bottom and ocean top properties, and receiver properties and location, you can predict the multiple and subtract it from your data. Ocean top R S Ocean bottom

  26. The method is linear in the data • Data without = data – predicted multiple And apriori information is complete In the free-surface multiple removal method only a single piece of apriori information is provided, the free surface, and the algorithm is non-linear in the data

  27. D = Df + Df2 + Df3 +∙∙∙ ∙∙∙ ∙∙∙ Where Dfand D correspond to data with and without free surface multiple, respectively. One term Df2 added to Dfeliminates every multiple reflector at the free surface

  28. The inverse scattering internal multiple removal method operates with absolutely no a priori information, whatsoever. To eliminate oneorder of internal multiples (from all interfaces at once) requires an infinite series -- and the first term of that elimination series is an attenuator that has a specific cubicmultiplicative communication of the entire data without free surface multiples.

  29. That first term attenuator presents the exact time of every first order internal multiple (including converted waves) using only water speed of all primaries and internal multiples. We can summarize the multiples, a priori information, and non-linearity relationship.

  30. Multiples

  31. The issue for multiple prediction is time and amplitude. • Primaries The ultimate objective for imaging primaries in depth is a spatial map of reflectors where (at each point on the interface) a function is provided that provides either an image dependent reflection coefficient with respect to the normal to the reflector or, in general, a scattering operator, when the interface is, e.g., undulating or diffracting.

  32. Given perfect overburden information this objective is achievable in a linear manner. Green’s theorem, Fourier methods and finite difference wave migration are among the linear imaging algorithms that can achieve that objective, with perfect overburden information.

  33. The output for primaries requires a correctly located image in space and an exact amplitude function (of angle) at each point on the reflector. • In addition to imaging, the inversion objective for primaries is to determine medium property changes across the reflectors. • The fact that the input to inverse methods is data in time, makes the output in space of structure and parameter estimation more daunting than operations like multiple removal in time

  34. Given perfect overburden information, the linear migration and/or migration – inversion will not correctly predict changes in material properties across the reflector • With an inadequate velocity model the output of linear migration –inversion will image at the wrong spatial location and will have overburden transmission errors added to the linear approximate value of the earth property changes • The first term in the inverse series is migration –inversion with the reference medium velocity.

  35. The terms in the inverse series addressing intrinsic non-linearity are always turned on and ready to go. • In contrast, the terms in the series addressing circumstantial non-linearity decide whether their services are needed/required and only light up and go into action when the data decides an issue warrants an intervention. • The latter properties represent the epitome of purposeful perturbation.

  36. In the case of lack of a priori information internal multiple require an infinite series to predict the correct amplitude, the first term has the correct time and the approximate amplitude. • In contrast, the first term in the imaging series for primaries produces the conventional migration, with the wrong depth and the wrong amplitude. A cascaded series is required to achieve the exact depth; useful results are obtained using a leading order uncascaded portion of that imaging subseries. • Let’s take a look at the inverse-series now.

  37. Scattering Theory • Scattering theory is perturbation theory • Relates differences in media to differences in wavefield

  38. Scattering Theory (cont’d.) • Inverse Series, V as power series in data, (fs)m

  39. Four Tasks of Direct Inversion (1) Free surface demultiple (2) Internal demultiple (3) Image reflectors at depth (4) Determine medium properties

  40. Concepts developed (1) Tasks within inversion (2) Subseries (3) Purposeful perturbation

  41. Intervention and the ISS for practical objectives • Isolated tasks (restatement of the problem). • Definition of events. • Time output --- G0 sandwich. • Extension to new definitions of primaries and multiples.

  42. Intrinsic and circumstantial non-linearity • Intrinsic non-linearity and circumstantial non-linearity involve very different actions within the series • Circumstantial non-linearity to achieve a task without adequate a-priori information immediately triggers a call for a more inclusive and extensive data involvement in the non-linear communication than the corresponding task requires in the case of adequate a-priori information and linear processing. Furthermore, the same absence of a-priori information requires a different type of communication with the more inclusive data, depending upon whether you are addressing, e.g., a depth imaging or a target identification (AVO) problem.

  43. A purely intrinsic non-linearity doesn’t require a more inclusive or extensive data set to achieve its task (in comparison to the corresponding linear case). It requires specific non-linear communication between the same data that produces the linear approximate • The first term in the inverse series is linear in the data (by definition). Hence, it is assuming that overburden a-priori information is adequate and that the intrinsic non-linear is replaceable by the linear approximate

  44. The second term in the inverse series deals with both types of non-linearity, to quadratic order – the intrinsic is always on – and the circumstantial determines if the situation warrants its intervention, for both imaging and inversion

  45. Given an event event t Is it a Primary or multiple?

  46. Given that the event is a primary event t • Depth image? • Non-linear AVO? • When the overburden is unknown

  47. Model type • Another expression you will encounter here is model type • Model type connotes the number and set of physical properties and their dimension of spatial variability, required to define your model • Our objective is to provide algorithms for field data application • Inverse-scattering multiple removal methods are independent of assumed earth model type • As we develop new methods for imaging and inverting primaries we examine the model type issue and progress the development and evaluation of concepts through a set of ever more complex and realistic models

  48. Program agenda

  49. Program agenda

  50. FS Marine events didn’t experience the earth experienced the earth no ghost ghost primaries + internal multiples free surface multiples primaries internal multiples locate invert

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