In the mathematical subfield of numerical analysis a Bzier curve is a parametric curve important in computer graphics. A numerically stable method to evaluate Bzier curves is de Casteljau's algorithm.

Generalizations of Bzier curves to higher dimensions are called Bzier surfaces; the Bzier triangle is a special case.

Bzier curves are also formed by many common forms of string art, where strings are looped across a frame of nails.

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## History

Bzier curves were widely publicized in 1962 by the French engineer Pierre Bzier who used them to design automobile bodies. The curves were developed in 1959 by Paul de Casteljau using de Casteljau's algorithm.

## Definition

Given n+1 points Pi in R3 a Bzier curve of degree n is a parametric curve

[itex]\mathbf{B}:[0,1] \to \mathbb{R}^3[itex]

composed of Bernstein basis polynomials of degree n

[itex]\mathbf{B}(t)= \sum_{i=0}^n \mathbf{P}_{i} b_{i,n}(t) \mbox{ , } t \in [0,1][itex]

with the Bernstein basis polynomials defined as

[itex]b_{i,n}(t):= {n \choose i} t^i (1-t)^{n-i} \qquad \mbox{ , } i=0,\ldots n.[itex]

(for the Bernstein polynomials we adopt the convention that 00 = 1)

Pi is called control point for the Bzier curve. A polygon can be constructed by connecting the Bzier points with lines, starting with P0 and finishing with Pn. This polygon is called the Bzier polygon.

## Notes

• The starting point of the curve is P0 and the ending point is Pn
• The Bzier curve is completely contained in the convex hull of the control points.
• If and only if all control points lie on the curve it is a straight line.
• The start (end) of the curve is tangent to the first (last) section of the Bzier polygon.
• A curve can be split at any point into 2 subcurves, or into arbitrarily many subcurves, each of which is also a Bzier curve.
• A circle cannot be exactly formed by a Bzier curve. Not even a circular arc. (However, often a Bzier curve is an adequate approximation to a small enough circular arc).
• The curve at a fixed offset from a given Bzier curve ("parallel" to that curve, like the offset between tracks in a railroad) cannot be exactly formed by a Bzier curve (except in some trivial cases). However, there are heuristic methods that usually give an adequate approximation for practical purposes.

## Examples

### Linear Bzier curves

Bzier "curve" of degree 1:

Given two control points P0 and P1 a linear Bzier curve is just a straight line between those two points. The curve is given by

[itex]\mathbf{B}(t)=(1-t)\mathbf{P}_0 + t\mathbf{P}_1 \mbox{ , } t \in [0,1].[itex]

Bzier curve of degree 2:

A quadratic Bzier curve is the path traced by the function B(t). For points A, B, and C,

[itex]\mathbf{B}(t) = (1 - t)^{2}\mathbf{A} + 2t(1 - t)\mathbf{B} + t^{2}\mathbf{C} \mbox{ , } t \in [0,1].[itex]

TrueType fonts use Bzier splines composed of the quadratic Bzier curves.

### Cubic Bzier curves

Bzier curve of degree 3:

Four points A, B, C and D in the plane or in three-dimensional space define a cubic Bzier curve. The curve starts at A going toward B and arrives at D coming from the direction of C. In general, it will not pass through B or C; these points are only there to provide directional information. The distance between A and B determines "how long" the curve moves into direction B before turning towards D.

The parametric form of the curve is:

[itex]\mathbf{B}(t)=\mathbf{A}(1-t)^3+3\mathbf{B}t(1-t)^2+3\mathbf{C}t^2(1-t)+\mathbf{D}t^3 \mbox{ , } t \in [0,1].[itex]

Modern imaging systems like PostScript, Metafont and GIMP use Bzier splines composed of cubic Bzier curves for drawing curved shapes.

## Application in computer graphics

Bzier curves are widely used in computer graphics to model smooth curves. As the curve is completely contained in the convex hull of its control points, the points can be graphically displayed and used to manipulate the curve intuitively. Affine transformations such as translation, scaling and rotation can be applied on the curve by applying the respective transform on the control points of the curve.

The most important Bzier curves are quadratic and cubic curves. Higher degree curves are more expensive to evaluate and there is no analytic formula to calculate the roots of polynomials of degree 5 and higher. When more complex shapes are needed low order Bzier curves are patched together (obeying certain smoothness conditions) in the form of Bzier splines.

The following code is a simple practical example showing how to plot a cubic Bezier curve in C. Note, this simply computes the coefficients of the polynomial and runs through a series of t values from 0 to 1 - in practice this is how it is usually done, even though neat algorithms such as deCasteljau's are often cited in graphics discussions, etc. This is because in practice a linear algorithm like this is faster and less resource-intensive than a recursive one like deCasteljau's. The following code has been factored to make its operation clear - an optimization in practice would be to compute the coefficients once and then re-use the result for the actual loop that computes the curve points - here they are recomputed every time, which is less efficient but helps to clarify the code.

The resulting curve can be plotted by drawing lines between successive points in the curve array - the more points, the smoother the curve.

/******************************************************
Code to generate a cubic Bezier curve
Warning - untested code
*******************************************************/

typedef struct
{
float x;
float y;
}
Point2D;

/******************************************************
cp is a 4 element array where:
cp[0] is the starting point, or A in the above diagram
cp[1] is the first control point, or B
cp[2] is the second control point, or C
cp[3] is the end point, or D

t is the parameter value, 0 <= t <= 1
*******************************************************/

Point2D PointOnCubicBezier( Point2D* cp, float t )
{
float   ax, bx, cx;
float   ay, by, cy;
float   tSquared, tCubed;
Point2D result;

/* calculate the polynomial coefficients */

cx = 3.0 * (cp[1].x - cp[0].x);
bx = 3.0 * (cp[2].x - cp[1].x) - cx;
ax = cp[3].x - cp[0].x - cx - bx;

cy = 3.0 * (cp[1].y - cp[0].y);
by = 3.0 * (cp[2].y - cp[1].y) - cy;
ay = cp[3].y - cp[0].y - cy - by;

/* calculate the curve point at parameter value t */

tSquared = t * t;
tCubed = tSquared * t;

result.x = (ax * tCubed) + (bx * tSquared) + (cx * t) + cp[0].x;
result.y = (ay * tCubed) + (by * tSquared) + (cy * t) + cp[0].y;

return result;
}

/*****************************************************************************
ComputeBezier fills an array of Point2D structs with the curve points
generated from the control points cp. Caller must allocate sufficient memory
for the result, which is <sizeof(Point2D) * numberOfPoints>
******************************************************************************/

void	ComputeBezier( Point2D* cp, int numberOfPoints, Point2D* curve )
{
float   t, dt;
int	  i;

dt = 1.0 / ( numberOfPoints - 1 );

for( i = 0, t = 0; i < numberOfPoints; i++, t += dt)
curve[i] = PointOnCubicBezier( cp, t );
}


## Rational Bzier curves

Some curves that seem simple, like the circle, cannot be described by a Bzier curve or a piecewise Bzier curve (though in practice the difference is small and may be tolerable). To describe some of these other curves, we need additional degrees of freedom.

The rational Bzier curve adds weights that can be adjusted. The numerator is a weighted Bernstein form Bzier curve and the denominator is a weighted sum of Bernstein polynomials.

Given n+1 control points Pi, the rational Bzier curve can be described by:

[itex]

\mathbf{B}(t) = \frac{ \sum_{i=0}^n b_{i,n}(t) \mathbf{P}_{i}w_i } { \sum_{i=0}^n b_{i,n}(t) w_i } [itex] or simply

[itex]

\mathbf{B}(t) = \frac{ \sum_{i=0}^n {n \choose i} t^i (1-t)^{n-i}\mathbf{P}_{i}w_i } { \sum_{i=0}^n {n \choose i} t^i (1-t)^{n-i}w_i }. [itex]

## References

• Art and Cultures
• Countries of the World (http://www.academickids.com/encyclopedia/index.php/Countries)
• Space and Astronomy