Computer Viewing. CITS3003 Graphics & Animation. E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

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1 Computer Viewing CITS3003 Graphics & Animation E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

2 Objectives Introduce the mathematics of projection Introduce OpenGL viewing functions Look at alternate viewing APIs E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

3 Computer Viewing There are three aspects of the viewing process, all of which are implemented in the pipeline, - Positioning the camera Setting the model-view matrix - Selecting a lens Setting the projection matrix - Clipping Setting the view volume E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

4 The OpenGL Camera In OpenGL, initially the object and camera frames are the same - The default model-view matrix is an identity The camera is located at the origin and points in the negative zz direction OpenGL also specifies a default view volume that is a cube with sides of length 2 centered at the origin - The default projection matrix is an identity E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

5 The Default Projection The default projection is orthogonal The default clipping volume is a cube of side = 2 centred at the origin. 2 clipped out zz = 0 E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

6 Moving the Camera Frame If we want to visualize objects that have both positive and negative zz values we can either - Move the camera in the positive zz direction Translate the camera frame - Move the objects in the negative zz direction Translate the world frame Both of these views are equivalent and are determined by the model-view matrix owant a translation (Translate(0.0,0.0,-d);) owant dd > 0, i.e., we move the objects in the zz direction. E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

7 Moving Camera back from Origin default frames frames after translation by dd where dd > 0 E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

8 Moving the Camera We can move the camera to any desired position by a sequence of rotations and translations Example: side view at the +xx axis looking towards the origin - Rotate the camera - Move it away from origin - Model-view matrix CC = TTTT E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

9 Moving the Camera OpenGL code Remember that the last transformation specified is first to be applied // Using mat.h mat4 t = Translate (0.0, 0.0, -d); mat4 ry = RotateY(90.0); mat4 m = t*ry; E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

10 The LookAt() Function camera is located at a point e called the eye point, specified in the object frame, and it is pointed at a second point a, called the at point. E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

11 The LookAt() Function The GLU library contains the function glulookat which can be used to form the required model-view matrix. glulookat(eyex, eyey, eyez, centrex, centrey, centrez, upx, upy, upz) We need to define the eye (camera) position, the centre (fixation point), and an up direction. All are of type GLdouble. Alternatively, we can use LookAt() defined in mat.h - The function returns a mat4 matrix. - Can concatenate with modeling transformations Example: Type: GLfloat mat4 mv = LookAt(vec4 eye, vec4 at, vec4 up); E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

12 The LookAt() Function (cont.) mat4 viewmat = LookAt(eye, at, up); E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

13 Other Viewing APIs The LookAt() function is only one possible API for positioning the camera Others include - View reference point, view plane normal, view up (PHIGS, GKS-3D) - Yaw, pitch, roll (angles) - Elevation, azimuth, twist (angles) - Direction angles E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

14 PROJECTION E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

15 Default Orthographic Projection The default projection in the eye (camera) frame is orthogonal For a point pp = xx, yy, zz, 1 T within the default view volume, it is projected to pp pp = (xxxx, yyyy, zzzz, wwww) T, where xx pp = xx, yyyy = yy, zzzz = 0, wwww = 1 i.e., we can define MM = and we can then write PP pp = MMMM In practice, we can let MM = II and set zz term to 0 later E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

Orthogonal Viewing The OpenGL orthogonal viewing function is: glortho(left, right, bottom, top, near, far) Alternatively, we can use Ortho() defined in mat.

16 Orthogonal Viewing The OpenGL orthogonal viewing function is: glortho(left, right, bottom, top, near, far) Alternatively, we can use Ortho() defined in mat.h: Type: GLdouble mat4 Ortho(left,right,bottom,top,near,far) Type: Glfloat Should be +ive near and far are measured from camera E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

17 Simple Perspective In orthographic projection, the camera s focal length is considered to be infinite (i.e., the camera lens is at infinity) In perspective projection, the camera s focal length dd is finite A simple perspective projection: - Center of projection is at the origin - Projection plane zz = dd, where dd < 0 E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

18 Simple Perspective (cont.) Consider the top and side views (top view) (side view) i.e., xx pp = xx pp dd = xx zz xx zz/dd yy pp dd = yy zz i.e., yy pp = yy zz/dd zz pp = dd Recall: the OpenGL synthetic camera model in an earlier lecture E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

19 Simple Perspective (cont.) Consider qq = MMpp where MM = /dd 0 and pp = qq = xx yy zz 1 xx yy zz zz/dd In OpeGL, this is the w term E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

20 Perspective Division However, since ww = zz dd 1, so we must divide by w to return back to nonhomogeneous coordinates. This perspective division yields xx pp = xx yy zz/dd dd = yy zz zz/dd pp = dd which are the desired perspective equations, as on slide 18. E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

21 Perspective Viewing To define a perspective transformation matrix for the camera, we can use mat4 Frustum(left,right,bottom,top,near,far) defined in mat.h: All are of type GLfloat Combines perspective projection and clipping E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

22 Perspective Viewing Using Field of View With Frustum() it is often difficult to get the desired view. Another way to get perspective projection is: mat4 Perpective(fovy, aspect, near, far) which often provides a better interface front plane All are of type GLfloat Note: aspect = w/h fovy is an angle in degrees E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

23 References Interactive Computer Graphics A Top-Down Approach with Shader-Based OpenGL by Edward Angel and Dave Shreiner, 6 th Ed, 2012 Secs Classical and Computer Viewing; Orthographic Projections; Perspective Viewing Sec Viewing with a Computer Sec Positioning of the Camera Frame; The Look- At Function Sec Orthographic Projections; Parallel Viewing with OpenGL; Orthogonal-Projection Matrices; (optional) An Interactive Viewer Secs Projections Perspective-Projection Matrices E. Angel and D. Shreiner: Interactive Computer Graphics 6E Addison-Wesley

Computer Viewing Computer Graphics I, Fall 2008

Computer Viewing Computer Graphics I, Fall 2008 Computer Viewing 1 Objectives Introduce mathematics of projection Introduce OpenGL viewing functions Look at alternate viewing APIs 2 Computer Viewing Three aspects of viewing process All implemented in