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Hank Childs, University of Oregon Lecture #2 Fields, Meshes, and Interpolation (Part 1)

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1 Hank Childs, University of Oregon Lecture #2 Fields, Meshes, and Interpolation (Part 1)

2 I’m back Next travel: Oct 26 th – Will announce plan as we get closer

3 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

4 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

5 Project #1 Goal: write a specific image Due: “today” % of grade: 2% How is project #1 going?

6 Project #2 Will assign on Monday Don’t want to have to rush through lecture … will only make things confusing.

7 Office Hours Who wants OH today?

8 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Fields – Meshes – Interpolation

9 Scientific Visualization An interdisciplinary branch of science – primarily concerned with the visualization of three- dimensional phenomena (architectural, meteorological, medical, biological, etc.) – the emphasis is on realistic renderings of volumes, surfaces, illumination sources, and so forth, perhaps with a dynamic (time) component. It is also considered a branch of computer science that is a subset of computer graphics. The purpose of scientific visualization is to graphically illustrate scientific data to enable scientists to understand, illustrate, and glean insight from their data. Source: wikipedia

10 Information Visualization The study of (interactive) visual representations of abstract data to reinforce human cognition. – The abstract data include both numerical and non- numerical data, such as text and geographic information. Source: wikipedia

11 SciVis vs InfoVis “it’s infovis when the spatial representation is chosen, and it’s scivis when the spatial representation is given” (A) (B) (E) (C) (D)

12 What sorts of data? Of course, lots of other data too…

13 What Is Visualization Used For? 3 Main Use Cases: – Communication – Confirmation – Exploration

14 How Visualization Works Many visual metaphors for representing data – How to choose the right tool from the toolbox? This course: – Describe the tools – Describe the systems that support the tools

15 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

16 Computer Graphics Defined: pictorial computer output produced, through the use of software, on a display screen, plotter, or printer.

17 What is computer graphics good for? Ed Angel book: – Display of information – Design – Simulation and animation – User interfaces

18 The Basics of Using a Graphics System You define: – Geometric primitives, typically a triangle mesh – Coloring for those geometry primitives – A model for a camera (where you are and what you are looking at) And then: – Communicate this information using an interface (e.g., OpenGL) – And something (e.g., GPU) renders the scene VTK will do this for us. Visualization: We will focus on transforming data to geometric primitives.

19 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

20 Elements of a Visualization Legend Provenance Information Reference CuesDisplay of Data

21 Elements of a Visualization What is the value at this location? How do you know? What data went into making this picture?

22 Where does temperature data come from? Iowa circa 1980s: people phoned in updates 6:00pm: Grandma calls in 80F. 6:00pm: Grandma’s friend calls in 82F. What is the temperature along the white line?

23 What is the temperature at points between Ralston and Glidden? D=0, Ralston, IA Distance D=10 miles, Glidden, IA ~ ~ Temperature 80F 82F 81F

24 Ways Visualization Can Lie Data Errors: Data collection is inaccurate Data collected too sparsely Visualization Program Visualization Errors: Illusion of certainty Poor choices of parameters

25 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

26 Fields & Spaces Fields are defined over “spaces”. – We will be considering 2D & 3D spaces. Defined by an origin and three vectors (or two vectors) that define orientation.

27 Scalar Fields Defined: associate a scalar with every point in space. What is a scalar? – A: a real number Examples: – Temperature – Density – Pressure The temperature at 41.2324° N, 98.4160° W is 66F. Fields are defined at every location in a space (example space: USA)

28 Vector Fields Defined: associate a vector with every point in space. What is a vector? – A: a direction and a magnitude Examples: – Velocity The velocity at location (5, 6) is (-0.1, -1) The velocity at location (10, 5) is (-0.2, 1.5) Typically, 2D spaces have 2 components in their vector field, and 3D spaces have 3 components in their vector field.

29 Vector Fields Representing dense data is hard and requires special techniques.

30 More fields (discussed later in course) Tensor fields Functions Volume fractions Multi-variate data

31 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

32 Mesh What we want

33 An example mesh

34 Where is the data on this mesh? (for today, it is at the vertices of the triangles)

35 An example mesh Why do you think the triangles change size?

36 Anatomy of a computational mesh Meshes contain: – Cells – Points This mesh contains 3 cells and 13 vertices Pseudonyms: Cell == Element == Zone Point == Vertex == Node

37 Types of Meshes Curvilinear Adaptive Mesh Refinement Unstructured We will discuss all of these mesh types more later in the course.

38 Rectilinear meshes Rectilinear meshes are easy and compact to specify: – Locations of X positions – Locations of Y positions – 3D: locations of Z positions Then: mesh vertices are at the cross product. Example: – X={0,1,2,3} – Y={2,3,5,6} Y=6 Y=5 Y=3 Y=2 X=1X=0X=2X=3

39 Rectilinear meshes aren’t just the easiest to deal with … they are also very common

40 Quiz Time A 3D rectilinear mesh has: – X = {1, 3, 5, 7, 9} – Y = {2, 3, 5, 7, 11, 13, 17} – Z = {1, 2, 3, 5, 8, 13, 21, 34, 55} How many points? How many cells? = 5*7*9 = 315 = 4*6*8 = 192 Y=6 Y=5 Y=3 Y=2 X=1X=0X=2X=3

41 Definition: dimensions A 3D rectilinear mesh has: – X = {1, 3, 5, 7, 9} – Y = {2, 3, 5, 7, 11, 13, 17} – Z = {1, 2, 3, 5, 8, 13, 21, 34, 55} Then its dimensions are 5x7x9

42 How to Index Points Motivation: many algorithms need to iterate over points. for (int i = 0 ; i < numPoints ; i++) { double *pt = GetPoint(i); AnalyzePoint(pt); }

43 Schemes for indexing points Logical point indices Point indices What would these indices be good for?

44 How to Index Points Problem description: define a bijective function, F, between two sets: – Set 1: {(i,j,k): 0<=i<nX, 0<=j<nY, 0<=k<nZ} – Set 2: {0, 1, …, nPoints-1} Set 1 is called “logical indices” Set 2 is called “point indices” Note: for the rest of this presentation, we will focus on 2D rectilinear meshes.

45 How to Index Points Many possible conventions for indexing points and cells. Most common variants: – X-axis varies most quickly – X-axis varies most slowly F

46 Bijective function for rectilinear meshes for this course int GetPoint(int i, int j, int nX, int nY) { return j*nX + i; } F

47 Bijective function for rectilinear meshes for this course int *GetLogicalPointIndex(int point, int nX, int nY) { int rv[2]; rv[0] = point % nX; rv[1] = (point/nX); return rv; // terrible code!! }

48 int *GetLogicalPointIndex(int point, int nX, int nY) { int rv[2]; rv[0] = point % nX; rv[1] = (point/nX); return rv; } F

49 Quiz Time #2 A mesh has dimensions 6x8. What is the point index for (3,7)? What are the logical indices for point 37? int GetPoint(int i, int j, int nX, int nY) { return j*nX + i; } int *GetLogicalPointIndex(int point, int nX, int nY) { int rv[2]; rv[0] = point % nX; rv[1] = (point/nX); return rv; // terrible code!! } = 45 = (1,6)

50 Quiz Time #3 A vector field is defined on a mesh with dimensions 100x100 The vector field is defined with double precision data. How many bytes to store this data? = 100x100x2x8 = 160,000

51 Bijective function for rectilinear meshes for this course int GetCell(int i, int j int nX, int nY) { return j*(nX-1) + i; }

52 Bijective function for rectilinear meshes for this course int *GetLogicalCellIndex(int cell, int nX, int nY) { int rv[2]; rv[0] = cell % (nX-1); rv[1] = (cell/(nX-1)); return rv; // terrible code!! }

53 Outline Projects & OH Intro – SciVis vs InfoVis – Very, very basics of computer graphics The Data We Will Study – Overview – Fields – Meshes – Interpolation

54 Linear Interpolation for Scalar Field F Goal: have data at some points & want to interpolate data to any location

55 Linear Interpolation for Scalar Field F A B F(B) F(A) X F(X)

56 Linear Interpolation for Scalar Field F General equation to interpolate: – F(X) = F(A) + t*(F(B)-F(A)) t is proportion of X between A and B – t = (X-A)/(B-A) A B F(B) X F(X) F(A)

57 Quiz Time #4 General equation to interpolate: – F(X) = F(A) + t*(F(B)-F(A)) t is proportion of X between A and B – t = (X-A)/(B-A) F(3) = 5, F(6) = 11 What is F(4)? = 5 + (4-3)/(6-3)*(11-5) = 7

58 Bilinear interpolation for Scalar Field F F(0,0) = 10 F(1,0) = 5 F(1,1) = 6 F(0,1) = 1 What is value of F(0.3, 0.4)? F(0.3, 0) = 8.5 F(0.3, 1) = 2.5 = 6.1 General equation to interpolate: F(X) = F(A) + t*(F(B)-F(A)) Idea: we know how to interpolate along lines. Let’s keep doing that and work our way to the middle.

59 Rayleigh Taylor Instability

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