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Lecture 24 Exemplary Inverse Problems including Vibrational Problems

Lecture 24 Exemplary Inverse Problems including Vibrational Problems. Syllabus.

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Lecture 24 Exemplary Inverse Problems including Vibrational Problems

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  1. Lecture 24 Exemplary Inverse ProblemsincludingVibrational Problems

  2. Syllabus Lecture 01 Describing Inverse ProblemsLecture 02 Probability and Measurement Error, Part 1Lecture 03 Probability and Measurement Error, Part 2 Lecture 04 The L2 Norm and Simple Least SquaresLecture 05 A Priori Information and Weighted Least SquaredLecture 06 Resolution and Generalized Inverses Lecture 07 Backus-Gilbert Inverse and the Trade Off of Resolution and VarianceLecture 08 The Principle of Maximum LikelihoodLecture 09 Inexact TheoriesLecture 10 Nonuniqueness and Localized AveragesLecture 11 Vector Spaces and Singular Value Decomposition Lecture 12 Equality and Inequality ConstraintsLecture 13 L1 , L∞ Norm Problems and Linear ProgrammingLecture 14 Nonlinear Problems: Grid and Monte Carlo Searches Lecture 15 Nonlinear Problems: Newton’s Method Lecture 16 Nonlinear Problems: Simulated Annealing and Bootstrap Confidence Intervals Lecture 17 Factor AnalysisLecture 18 Varimax Factors, Empircal Orthogonal FunctionsLecture 19 Backus-Gilbert Theory for Continuous Problems; Radon’s ProblemLecture 20 Linear Operators and Their AdjointsLecture 21 Fréchet DerivativesLecture 22 Exemplary Inverse Problems, incl. Filter DesignLecture 23 Exemplary Inverse Problems, incl. Earthquake LocationLecture 24 Exemplary Inverse Problems, incl. Vibrational Problems

  3. Purpose of the Lecture • solve a few exemplary inverse problems • tomography • vibrational problems • determining mean directions

  4. Part 1 • tomography

  5. tomography: data is line integral of model function y assume ray path is known ray i x di = ∫ray im(x(s), y(s)) ds

  6. discretization: model function divided up into M pixels mj

  7. data kernelGij = length of ray i in pixel j

  8. data kernelGij= length of ray i in pixel j here’s an easy, approximate way to calculate it

  9. start with G set to zero ray i then consider each ray in sequence

  10. divide each ray into segments of arc length ∆s ∆s and step from segment to segment

  11. determine the pixel index, say j, that the center of each line segment falls within add ∆s to Gij repeat for every segment of every ray

  12. You can make this approximation indefinitely accurate simply bydecreasing the size of ∆s(albeit at the expense of increase the computation time)

  13. Suppose that there are M=L2voxelsA ray passes through about L voxelsG has NL2 elementsNL of which are non-zeroso the fraction of non-zero elements is1/Lhence G is very sparse

  14. In a typical tomographic experimentsome pixels will be missed entirelyand some groups of pixels will be sampled by only one ray

  15. In a typical tomographic experimentsome pixels will be missed entirelyand some groups of pixels will be sampled by only one ray the value of these pixels is completely undetermined only the average value of these pixels is determined hence the problem is mixed-determined (and usually M>N as well)

  16. soyou must introduce some sort of a priori information to achieve a solutionsaya priori information that the solution is smallor a priori information that the solution is smooth

  17. Solution Possibilities • Damped Least Squares (implements smallness): Matrix G is sparse and very large use bicg() with damped least squares function 2. Weighted Least Squares (implements smoothness): Matrix F consists ofG plus second derivative smoothing use bicg()with weighted least squares function

  18. Solution Possibilities • Damped Least Squares: Matrix G is sparse and very large use bicg() with damped least squares function 2. Weighted Least Squares: Matrix F consists ofG plus second derivative smoothing use bicg()with weighted least squares function test case has very good ray coverage, so smoothing probably unnecessary

  19. sources and receivers True model y x

  20. just a “few” rays shown else image is black Ray Coverage y y x x

  21. Data, plotted in Radon-style coordinates distance r of ray to center of image minor data gaps angleθof ray Lesson from Radon’s Problem: Full data coverage need to achieve exact solution

  22. True model Estimated model y x

  23. Estimated model Estimated model y streaks due to minor data gaps they disappear if ray density is doubled x

  24. but what if the observational geometry is poorso that broads swaths of rays are missing ?

  25. complete angular coverage (A) (B) y y x x (C) (D) r y θ x

  26. incomplete angular coverage (A) (B) y y x x (C) (D) r y θ x

  27. Part 2 • vibrational problems

  28. statement of the problem Can you determine the structure of an object just knowing the characteristic frequencies at which it vibrates? frequency

  29. the Fréchet derivativeof frequency with respect to velocity is usually computed using perturbation theoryhence a quick discussion of what that is ...

  30. perturbation theory a technique for computing an approximate solution to a complicated problem, when 1. The complicated problem is related to a simple problem by a small perturbation 2. The solution of the simple problem must be known

  31. simple example

  32. we know the solution to this equation: x0=±c

  33. Here’s the actual vibrational problemacoustic equation withspatially variable sound velocity v

  34. acoustic equation withspatially variable sound velocity v patterns of vibration or eigenfunctions or modes frequencies of vibration or eigenfrequencies

  35. v(x) = v(0)(x) + εv(1)(x) + ... • assume velocitycan be written as a perturbation • around some simple structure • v(0)(x)

  36. eigenfunctions known to obey orthonormality relationship

  37. now represent eigenfrequencies and eigenfunctions as power series in ε

  38. now represent eigenfrequencies and eigenfunctions as power series in ε represent first-order perturbed shapes as sum of unperturbed shapes

  39. plug series into original differential equation group terms of equal power of ε solve for first-order perturbation ineigenfrequenciesωn(1) and eigenfunction coefficients bnm • (use orthonormality in process)

  40. result

  41. result for eigenfrequencies write as standard inverse problem

  42. standard continuousinverse problem

  43. standard continuousinverse problem perturbation in the eigenfrequencies are the data perturbation in the velocity structure is the model function

  44. standard continuousinverse problem data kernel or Fréchet derivative depends upon the unperturbed velocity structure, the unperturbed eigenfrequency and the unperturbed mode

  45. 1D organ pipe open end, p=0 unperturbed problem has constant velocity 0 perturbed problem has variable velocity closed end dp/dx=0 h x

  46. p1 p2 p3 p=0 0 modes h dp/dx=0 x x x x frequencies 𝜔 𝜔1 𝜔2 𝜔3 0

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