CSE325 Computer Science and Sculpture Prof. George Hart.

Slides:

Advertisements

Similar presentations

CSE325 Computers and Sculpture

Advertisements

© T Madas. We can extend the idea of rotational symmetry in 3 dimensions:

Prisms and Pyramids By Harrison.

Procedural Content Tiling

By: Andrew Shatz & Michael Baker Chapter 15. Chapter 15 section 1 Key Terms: Skew Lines, Oblique Two lines are skew iff they are not parallel and do not.

Regular Polytopes in Four and Higher Dimensions

CSE325 Computer Science and Sculpture Prof. George Hart.

Section 2.4 Three Dimensional Shapes MA418 McAllister Spring 2009.

4.5 Platonic Solids Wednesday, February 25, 2009.

Geometry Chapter 20. Geometry is the study of shapes Geometry is a way of thinking about and seeing the world. Geometry is evident in nature, art and.

Solid Freeform Fabrication of Aesthetic Objects George W. Hart Stony Brook University Dept. Computer Science.

VOCABULARY GEOMETRIC FIGURES. POLYGON Is a closed plane figure formed by three or more line segments that meet at points called vertices.

Chapter 12 Surface Area and Volume. Topics We Will Discuss 3-D Shapes (Solids) Surface Area of solids Volume of Solids.

The Fish-Penguin-Giraffe Algebra A synthesis of zoology and algebra.

CSE325 Computer Science and Sculpture Prof. George Hart.

Chapter 12 Surface Area and Volume. Topics We Will Discuss 3-D Shapes (Solids) Surface Area of solids Volume of Solids.

9-4 Geometry in Three Dimensions  Simple Closed Surfaces  Regular Polyhedra  Cylinders and Cones.

Geometric Solids A three dimensional figure that has three dimensions: length, width, and height. cylinder Rectangular prism cube pyramid cone.

Platonic Solids. So What is Our Topic?  It’s math (go figure!)  It’s hands on (so you get to play!)  There’s candy involved  There are some objects.

What is a Tessellation? A tessellation is a pattern of repeating figures that fit together with NO overlapping or empty spaces. Tessellations are formed.

GEOMETRY Bridge Tips: Be sure to support your sides when you glue them together. Today: Over Problem Solving 12.1 Instruction Practice.

Geometry: Part 2 3-D figures.

MATERIALS SCIENCE &ENGINEERING Anandh Subramaniam & Kantesh Balani Materials Science and Engineering (MSE) Indian Institute of Technology, Kanpur

Name the polygon by the number of sides.

Vertex – A point at which two or more edges meet Edge – A line segment at which two faces intersect Face – A flat surface Vertices, Edges, Faces.

Wedneday, March 5 Chapter13-5 Symmetry. There are many types of symmetry.

UNIT 9.  Geometrical volumes, like the one you can see on this page (in this picture), can be easily reproduced in real sizes by precise drawings. 

Chapter 12 Section 1 Exploring Solids Using Properties of Polyhedra Using Euler’s Theorem Richard Resseguie GOAL 1GOAL 2.

Frameworks math manipulative by Rob Lovell. Frameworks math manipulative Rob Lovell Contents What are Frameworks? How can a teacher use them? Why would.

Do you know what these special solid shapes are called?

Polyhedron Platonic Solids Cross Section

Warm Up Week 6. Section 12.1 Day 1 I will use the properties of polyhedra. Cross section The intersection of a plane slicing through a solid.

Warm-up Assemble Platonic Solids.

Solid Geometry Polyhedron A polyhedron is a solid with flat faces (from Greek poly- meaning "many" and -edron meaning "face"). Each flat surface (or "face")

Space Figures & Cross-Sections

Polygons Shapes with many sides! Two-dimensional Shapes (2D) These shapes are flat and can only be drawn on paper. They have two dimensions – length.

Level3456 Angles I can identify right angles I can recognise, measure and draw acute and obtuse angles I know that the sum of the angles on a line is 180.

Ch 12 and 13 Definitions. 1. polyhedron A solid with all flat surfaces that enclose a single region of space.

Geometry Mathematical Reflection 1A

Section 12-1 Exploring Solids. Polyhedron Three dimensional closed figure formed by joining three or more polygons at their side. Plural: polyhedra.

12.1 Exploring Solids.

Space Figures and Nets Section 6-1 Notes and vocabulary available on my home page.

11-1 Space Figures and Cross Sections Objectives To recognize polyhedra and their parts To visualize cross sections of space figures.

Introduction to 3D Solids and Solids of Revolution Some 3D shapes can be formed by revolving a 2D shape around a line (called the axis of revolution).

11.1 Notes Space Figures and Cross Sections. Identifying Nets and Space Figures A polyhedron is a 3-dimensional figure whose surfaces are polygons. -

Name the polygon by the number of sides.

Geometric Solids POLYHEDRONS NON-POLYHEDRONS.

Goal 1: Using Properties of Polyhedra Goal 2: Using Euler’s Theorem

REPRESENTATION OF SPACE

Chapter 11 Extending Geometry

What do they all have in common?

Finding Volumes.

Geometric Shapes, Lines of Symmetry, & Right Angles

11.4 Three-Dimensional Figures

Filter paper parts of a circle: fold to find…

The (regular, 3D) Platonic Solids

12-1 Properties of Polyhedra

Warm Up Classify each polygon. 1. a polygon with three congruent sides

11.1 Space Figures and Cross Sections

Solid Geometry.

Surface Area and Volume

Investigation 2 Polygonal Prisms

Solid Geometry.

Concept 52 3-D Shapes.

11.4 Three-Dimensional Figures

Solid Geometry.

Presentation transcript:

CSE325 Computer Science and Sculpture Prof. George Hart

Orderly Tangles One interesting transformation of a Platonic solid is to form an “orderly tangle” by rotating and translating the faces in a symmetric manner. This can provide the foundation for visually interesting sculptural forms.

Derivation from Regular Polyhedron Rotate facesSlide in or out

Regular Polylinks Symmetric linkages of regular polygons Alan Holden built models –Cardboard or dowels Holden wrote: –Shapes, Spaces and Symmetry,1971 –“Regular Polylinks”, 1980 –Orderly Tangles, 1983 Table of lengths 4 Triangles

Generates Template to Print and Cut 4 Triangles

Robert J. Lang

Rinus Roelofs

Carlo Sequin

Regular Polylinks 4 Triangles6 Squares Left and right hand forms

Paper or Wood Models 6 Squares

Solid Freeform Fabrication 6 Squares

Theo Geerinck

Rinus Roelofs

Regular Polylinks 6 Pentagons - size scaled

Square Cross Section 6 Pentagons

Rinus Roelofs

Paper or Wood Models

Charles Perry, sculptor 1976, 12 tons, 20’ edge3 nested copies

Regular Polylinks 12 Pentagons

Rinus Roelofs

Wooden Puzzles Taiwan –Teacher Lin –Sculptor Wu Square cross sections Simple lap joint No glue Trial and error to determine length 12 Pentagons

Second Puzzle from Lin and Wu 10 Triangles

Many Analogous Puzzles Possible Each regular polylink gives a puzzle Also can combine several together: –Different ones interweaved –Same one nested Need critical dimensions to cut lengths No closed-form formulas for lengths Wrote program to: –Determine dimensions –Output templates to print, cut, assemble –Output STL files for solid freeform fabrication

Carlo Sequin

Five rectangles — one axis of 5-fold symmetry

Software Demo Soon to be available on class website

Combinations 4 Triangles + 6 Squares

Combinations 12 Pentagons + 10 Triangles

Models Difficult for Dowels 30 Squares around icosahedral 2-fold axes

Other Polygon Forms 8 Triangles

Spiraling Polygons 10 layers, each 6 Squares

Charles Perry Eclipse, 1973, 35’ tall

Things too Complex to Make 10 Spirals connect opposite faces of icosahedron

Curved Components Central Inversion 4 Triangles20 Triangles