Chapter 3 Orthographic Projection - People.utm.my
Chapter 3 Orthographic Projection
TOPICS Object representation Multiview projection Glass box concept Orthographic projection of point, line, plane, surface and object. Line convention
OBJECT REPRESENTATION Axonometric projection Multiview projection
MULTIVIEW PROJECTION Width Depth Adjacent view(s) is needed to fulfill the size description. Height Height can be presented only two in each view. Depth Three principle dimensions of an object Width Depth
TO OBTAIN MULTIVIEW REPRESENTATION OF AN OBJECT 1. Revolve the object with respect to observer. 2. The observer move around the object.
REVOLVE THE OBJECT Top view Front view Right side view
OBSERVER MOVE AROUND Top view Front view Right side view
THE GLASS BOX CONCEPT Rear view Left side view Bottom view
Depth History Width Height
MULTIVIEW PROJECTION Click on the picture to play video
MULTIVIEW PROJECTION Click on the picture to play video
MULTIVIEW PROJECTION Click on the picture to play video
MULTIVIEW PROJECTION Click on the picture to play video
Orthographic Projection of Object Features
OBJECT FEATURES Edges are lines that represent the boundary between two faces. Corners Represent the intersection of two or more edges. Edge Corner Edge No corner No edge No corner
OBJECT FEATURES Surfaces are areas that are bounded by edges or limiting element. Limiting element is a line that represents the last visible part of the curve surface. Surface Surface Limit Surface Limit
PROJECTION OF POINT(S) BT BT AT AT Equal distance B A AF BF BR AR AF BF AR BR
PROJECTION OF LINE True length BT AT BT Equal length AT B A AF BF Point BR AR AF BF AR BR True length NORMAL LINE
PROJECTION OF LINE True length BT AT BT Equal length AT B A A AF BF BR AR AF BF AR BR Foreshortened Foreshortened INCLINED LINE
PROJECTION OF LINE Foreshortened BT AT BT B BR BF AT B A AF Equal length BF BR A AR Foreshortened AF AR Foreshortened OBLIQUED LINE
PROJECTION OF PLANE True size CT BT CT AT Equal length BT C B CR A BF AF,CF Edge AT BF AR,BR AF,CF AR,BR CR Edge NORMAL PLANE
PROJECTION OF PLANE Foreshortened CT BT CT AT C Equal length CR CF BT AT C B CF CR A BF AF Foreshortened AR,BR Edge BF AF AR,BR INCLINED PLANE
PROJECTION OF PLANE Foreshortened CT BT CT AT C Equal length B BF CR CF BT AT C B CF BR BF A AF Foreshortened BR CR AR Foreshortened AF AR OBLIQUED PLANE
PROJECTION OF OBJECT The views are obtained by projecting all object features to the picture plane. You have to project the remaining surfaces which are invisible too !
PROJECTION OF OBJECT s s s
PROJECTION OF OBJECT
Line Convention
LINE CONVENTION Precedence of coincide lines. Hidden line drawing. Center line drawing.
PRECEDENCE OF LINE Order of importance Visible line Hidden line Center line
HIDDEN LINE PRACTICE Hidden line should join a visible line, except it extended from the visible line. Leave space Correct Join No !
HIDDEN LINE PRACTICE Hidden line should join a visible line, except it extended from the visible line. Leave space Leave space Correct No !
HIDDEN LINE PRACTICE Hidden line should intersect to form L and T corners. L T Correct No !
HIDDEN LINE PRACTICE Hidden arcs should start on a center line.
CENTER LINE PRACTICE In circular view, short dash should cross at the intersections of center line. For small hole, center line is presented as thin continuous line. Center line should not extend between views. Leave space Leave space
CENTER LINE PRACTICE Leave the gap when centerline forms a continuation with a visible or hidden line Center line should always start and end with long dash. Leave space Leave space Leave space Leave space
Orthographic Projection. TOPICS Object representation Glass box concept Line convention Orthographic projection of point, line, plane, surfaceand object. Multiview projection. OBJECT REPRESENTATION Axonometric projection Multiview projection. MULTIVIEW PROJECTION Three principle dimensions
orthographic projection is to imagine an object contained inside a glass box. Orthographic Projection There is a total of six glass walls surrounding the object. Each wall represents a projection plane onto which a two- dimensional object view will be created. Orthographic Projection Also referred to as a plane of projection
Orthographic projection is a technique that is used to create multiview drawings. Orthographic projection. is any projection of the features of an object onto an imaginary plane of projection. The . projection plane, projection line, glass box, multiview drawing Created Date:
Part One: Heir of Ash Chapter 1 Chapter 2 Chapter 3 Chapter 4 Chapter 5 Chapter 6 Chapter 7 Chapter 8 Chapter 9 Chapter 10 Chapter 11 Chapter 12 Chapter 13 Chapter 14 Chapter 15 Chapter 16 Chapter 17 Chapter 18 Chapter 19 Chapter 20 Chapter 21 Chapter 22 Chapter 23 Chapter 24 Chapter 25 Chapter 26 Chapter 27 Chapter 28 Chapter 29 Chapter 30 .
Orthographic Projection When the projectors are parallel to each other and also perpendicular to the plane, the projection is called orthographic projection. 1 A plane of projection (POP) is a plane on which a particular view is projected. 2 Three such planes, perpendicular to each oth
A multiview orthographic projection is a drawing technique in which up to six images of an object are produced (illustrated). With each drawing the object is behind the plane of projection and the object is positioned in such a way that only two of its dimensions are shown. The parallel lines of sight go through the projection plane and the .
6 Multi -View Drawing 84. UNIT 6 . MULTI-VIEW DRAWING . Learning Competencies: Up on completion of this unit you should be able to: Explain the importance of multi-view drawings; Define the concept of projection; Explain the concept of orthographic projection; Identify the three main projection planes; Describe the methods of orthographic projection;
Orthographic Projection Parallel Projection Affine cameras. Affine cameras A general affine camera combines the effects of an affine transformation of the 3D space, orthographic projection, and an affine transformation of the image: Affine projection is a linear mapping translation in
AutoCAD .NET Developer’s Guide Stephen Preton Autodesk Developer Technical Services Team (DevTech)
