triangulation supplemental

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Triangulation Supplemental

From O’Rourke (Chs. 1&2)

Fall 2005

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Contents

• Ear clipping algorithm

• Triangulating monotonic polygons

• Monotonic decomposition via trapezoidalization

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Ear Clipping

• Go around the polygon to check whether a diagonal can be drawn from (i-1) to (i+1)

• Diagonal check:– No edge crossing AND inside P

What is the time

complexity in the worst case?

4

0

1

2

3

4

5

6

7

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Think…

• Can every simple polygon be triangulated?

• Does every simple polygon have at two ears (so that ear clipping algorithm can work)?

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Validity of Diagonal

• No edge crossing– Each potential diagonal

(i-1, i+1) need to check with ? edges

• “In-Cone” check:– local geometry

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Triangulating Monotonic Polygons

• Linear time algorithm: O(n)• Fact on monotonic polygons

– Def: a vertex is called reflex if its internal angle is strictly greater than

– Def: cusp• A reflex vertex whose adjacent vertices v- and v+ are

either both above or below v.

– Lemma: • If a polygon P has no cusps, then it is monotone.

Why?

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Algorithm Ideas:

• Cut off triangles from the top in a greedy fashion– At each step, the first available triangle removed

• For each vertex v, connect v to all the vertices above it and visible via a diagonal, and remove the top portion of the polygon thereby triangulated

• Continue with the next vertex below v

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Case 1:

Case 2a, 2b:

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Sort by y-coordinate reflex chain: {1,2} v = 3

1

2

5

3

4

7

8

6

Triangulate Monotone Polygon

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Case 2b: chain {1,2,3} v = 4

v = 3 chain: {1,2}

[same side, non-convex]1

2

5

3

4

7

8

6

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Case 2b: chain {1,2,3,4} v = 5

v = 4 chain: {1,2,3}

[same side, non-convex]1

2

5

3

4

7

8

6

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1

2

5

3

4

7

8

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Case 1: diagonal (5,2) reflex chain {1,2,3,4}

v = 5 chain: {1,2,3,4}

[opposite side]

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1

2

5

3

4

7

8

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Case 1: diagonal (5,3) reflex chain {2,3,4}

v = 5 chain: {2,3,4}

[opposite side]

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1

2

5

3

4

7

8

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Case 1: diagonal (5,4) reflex chain {3,4} reflex chain {4,5} v = 6

v = 5 chain: {3,4}

[opposite side]

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1

2

5

3

4

7

8

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Case 2b: reflex chain {4,5,6} v = 7

v = 6 chain: {4,5}

[same side, non-convex]

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1

2

5

3

4

7

8

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Case 2a: diagonal (7,5) reflex chain {4,5,6}

v = 7 chain: {4,5,6}

[same side, convex]

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1

2

5

3

4

7

8

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Case 2a: diagonal (7,4) reflex chain {4,5} reflex chain {4,7} v = 8

v = 7 chain: {4,5}

[same side, convex]

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1

2

5

3

4

7

8

6

v = 8 chain: {4,7}

[lowest vertex; stop]

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0

1

2

3

4

5

67

8

9

1011

12

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{0,1,2}

{0,1,2,3}

{0,1,2,3,4}

{0,1,2,3,4}

{4,5}{4,6}

{6,7}

{7,8}

{7,9}

{4,5}

{6,7}

{7,8}

{9,10}

{7,9}

{4,6}

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Trapezoidalization

• Accomplish monotonic subdivision via horizontal trapezoidalization

• Supporting vertices: the vertices through which the horizontal lines are drawn

• Assume P be a polygon with no two vertices on a horizontal line– Each trapezoid has exactly two supporting vertices: one on t

op, one on bottom– Remove cusps by connecting the supporting vertex to the op

posite vertexAssume no two points h

ave same y coord.

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The support line stops at the boundary

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Trapezoidalization via Plane Sweep

• Time complexity: O(n log n)

• Maintain a balanced tree of edges

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Sweep Line Events

(…, a, c, b, …)

(…, a, d, b, …)

(…, a, c, d, b, …)

(…, a, b, …)

(…, a, b, …)

(…, a, c, d, b, …)

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Summary

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Review Questions

1. Analyze the worst case complexity of ear clipping algorithm

2. Analyze the time complexity of the algorithm for triangulating monotone polygon

3. Triangulate (and keep track of the reflex chain) of the polygon on the next page

4. Decompose the polygon on page 24 into monotonic pieces using trapezoidalization

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Monotone-ization

• If the polygon has no cusp, it is monotone and can be triangulated immediately.

• [seek an orientation where the polygon is monotone]

• Decompose into monotone pieces via horizontal trapezoidalization

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Three Types of Event Points

(…, a, c, b, …)

(…, a, d, b, …)

(…, a, c, d, b, …)

(…, a, b, …)

(…, a, b, …)

(…, a, c, d, b, …)

Regular

Upward cusp

Downward cusp

replace

remove

insert

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Making Trapezoids

• Regular point: Extend toward material side until a boundary is reached

• Cusps: extend both sides until boundaries are reached

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a

b c

de f g

hi

j

{bc}

{aj}

{ajih}

{ajicdh}u.cusp

{ajicdg}{acdg}d.cusp{acdefg}u.cusp{bcdefg}{bcde}

{}

Upward cusp: connect to support vertex aboveDownward cusp: connect to support vertex below[implementation]