540 likes | 601 Views
Output Primitives. Dr. S.M. Malaek Assistant: M. Younesi. Output Primitives. Output Primitives: Basic geometric structures (points, straight line segment, circles and other conic sections, quadric surfaces, spline curve and surfaces, polygon color areas, and character strings)
E N D
Output Primitives Dr. S.M. Malaek Assistant: M. Younesi
Output Primitives • Output Primitives: Basic geometric structures (points, straight line segment, circles and other conic sections, quadric surfaces, spline curve and surfaces, polygon color areas, and character strings) • These picture components are often defined in a continuous space.
Output Primitives • In order to draw the primitive objects, one has to first scan convert the object. • Scan convert: Refers to he operation of finding out the location of pixels to the intensified and then setting the values of corresponding bits, in the graphic memory, to the desired intensity code.
Output Primitives • Each pixel on the display surface has a finite size depending on the screen resolution and hence a pixelcannot represent a single mathematical point.
Scan Converting A Point • A mathematical point (x,y) needs to be scan converted to a pixel at location (x´, y´).
Scan Converting A Point • x´=Round(x) and y´=Round(y) • All points that satisfy: are mapped to pixel (x´,y´)
Scan Converting A Point • x´=Round(x+0.5) and y´=Round(y+o.5) • All points that satisfy: are mapped to pixel (x´,y´)
Scan Converting A Line • The Cartesian slope- intercept equation for a straight line is:
Scan Converting A Line • These equation form the basic for determining deflection voltage in analog devices. |m|<1 |m|>1
Scan Converting A Line • On raster system, lines are plotted with pixels, and step size (horizontal & vertical direction) are constrained by pixel separation.
Scan Converting A Line • We must sample a line at discrete positions and determine the nearest pixel to the line at each sampled position. X2
Digital Differential Analyzer (DDA Algorithm)
DDA Algorithm • Algorithm is an incremental scan conversion method. • Based on calculating either or • If |m|<1,
DDA Algorithm • If |m|>1, • If
Bresenham’s Line Algorithm • A highly efficient incremental method for scan converting lines. • Using only incrementalinteger calculation. By testing the sign of an integer parameter, whose value is proportional to the difference between the separation of two pixel positions from the actual line path.
Bresenham’s Line Algorithm • A highly efficient incremental method for scan converting lines. • Using only incrementalinteger calculation. By testing the sign of an integer parameter, whose value is proportional to the difference between the separation of two pixel positions from the actual line path.
yk+1 yk+1 yk+1 } } } d2 d2 d2 y y y } } } d1 d1 d1 yk yk yk xk+1 xk+1 xk+1 Bresenham’s Line Algorithm
Bresenham’s Line Algorithm d1 = y - yk = m (xk + 1) + b - yk d2 = (yk + 1) - y = yk + 1 - m (xk + 1) –b d1 - d2 = 2 m (xk + 1) - 2 yk + 2b -1
Bresenham’s Line Algorithm Pk = ΔX ( d1 - d2) = 2 ΔY . xk - 2 ΔX . yk + c c = constante = 2 ΔY + ΔX (2b -1)
Let's get rid of multiplications Pk+1 = 2 ΔY . xk+1 - 2 ΔX .y + c Pk+1 - Pk = 2 ΔY (xk+1 - xk) -2 ΔX (yk+1 - yk) (get rid of the constance) Pk+1 = Pk + 2 ΔY - 2 ΔX (yk+1 - yk) Pk+1 = Pk + 2ΔY or = Pk + 2(ΔY – ΔX( with (yk+1 - yk) = 0 or 1 depending on Pk sign
Bresenham’s Line Algorithm P0 =ΔX (d1-d2) =ΔX[2m(x0+1)-2y0+2b-1] =ΔX[2(mx0+b-y0)+2m-1] P0=2ΔY -ΔX m=Δy/x 0
Bresenham’s Line Algorithm • Example: Digitize the line with endpoint (20,10) and (30,18) • ΔX=10 ΔY= 8 • P0=2ΔY –Δx=6 • 2ΔY =16 • 2(ΔY – ΔX)=-4 P0=2ΔY –ΔX Pk+1 = Pk + 2ΔY or = Pk + 2(ΔY – ΔX(
Circle Generation Algorithms • The equation of a circle: We could solve for y in terms of x
Circle Generation Algorithms • Computation can be reduced by considering the symmetry of circles 8 -Way symmetry
Circle Generation Algorithms • As in the line algorithm, we sample at unit intervals and determine the closet pixel position to the circle path at each step.
Circle Generation Algorithms • Points are generated from 90º to 45º, moves will be made only in the +x and –y direction. • positive x direction over this octant and use a decision parameter
Circle Generation Algorithms • We define a circle function:
Circle Generation Algorithms • Midpoint • Consider the coordinates of the point halfway between pixel T and pixel S Midpoint
Circle Generation Algorithms • We use it to define a decision parameter
Circle Generation Algorithms • If is negative, the midpoint is inside the pixel, and we choose pixel T. • If we choose pixel S.
Circle Generation Algorithms • Parameter for the next step is: • since
Circle Generation Algorithms • If T is chosen ( ) we have: • If pixel S is chosen ( ) we have
Circle Generation Algorithms In terms of
Circle Generation Algorithms Initial value for the decision parameter using the original function of (0,r( When r is an integer we can simply set
Circle Generation Algorithms • Example: A circle radius r=10 • x=0 to x=y • P0=1-r = -9
Character Generation Letters, numbers, and other character can be displayed in a variety of size and styles.
Character Generation • Typeface: The overall design style for a set of characters is call typeface:Zar, nazanin, Titr. • Font: Referred to a set of cast metal character forms in a particular size and forma:10 point Zar.
Character Generation • Two different representation are used for storing computer fonts: • Bitmap font (or bitmapped font) • Outline font
Bitmap font • Bitmap font (or bitmapped font): A simple method for representing the character shapes in a particular typeface is to use rectangular grid pattern.
Bitmap font • The character grid only need to be mapped to a frame buffer position. • Bitmap fonts required more space, because each variation (size and format) must be stored in a font cash. Italic Bold