a class surface q&a
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A Class surfacing and its importance:A class surfaces are those aesthetic/ free form surfaces, which are visible to us
(interior/exterior), having an optimal aesthetic shape and high surface quality.
Mathematically class A surface are those surfaces which are curvature continuous whileproviding the simplest mathematical representation needed for the desired shape/form anddoes not have any undesirable waviness.
Curvature continuity: It is the continuity between the surfaces sharing the same boundary.Curvature continuity means that at each point of each surface along the common boundary has
the same radius of curvature.
Why Class A is needed:We all understand that today products are not only designed considering the functionality but
special consideration are given to its form/aesthetics which can bring a desire in ones mind to
own that product. Which is only possible with high-class finish and good forms. This is the
reason why in design industries Class A surface are given more importance.
UNDERSTANDINGUnderstanding for Class A surfaces:
1. The fillets - Generally for Class A, the requirement is curvature continuous and Uniform flow
of flow lines from fillet to parent surface value of 0.005 or better (Position 0.001mm and
tangency to about 0.016 degrees).
2. The flow of the highlight lines - The lines should form a uniform family of lines. Gradually
widening or narrowing but in general never pinching in and out.
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3. The control points should form a very ordered structure - again varying in Angle from one
Row to the next in a gradual manner (this will yield the good Highlights required).
4. For a Class A model the fillet boundary should be edited and moved to form a Gentle line -
and then re-matched into the base surface.
5. Matched iso-params in U & V direction are also a good representation of class A.
6. The degree (order) of the Bezier fillets should generally be about 6 (also for arc Radius
direction) sometimes you may have to go higher.
7. Also you have to take care of Draft angle, symmetry, gaps and matching of surfaces Created
with parent or reference surfaces.
8. Curvature cross-section needles across the part - we make sure the rate of Change of
curvature (or the flow of the capping line across the top of the part) is Very gentle and well
behaved.
The physical meaning:
Class A refers to those surfaces, which are CURVATURE continuous to each other at their
respective boundaries. Curvature continuity means that at each "point" of each surface along
the common boundary has the same radius of curvature.
This is different to surfaces having;
Tangent continuity - which is directional continuity without radius continuity - like fillets.
Point continuity - only touching without directional (tangent) or curvature equivalence.
In fact, tangent and point continuity is the entire basis most industries (aerospace,
shipbuilding, BIW etc ). For these applications, there is generally no need for curvature.
By definition:
Class A surface refers to those surfaces which are VISIBLE and abide to the physical meaning, in
a product. This classification is primarily used in the automotive and increasingly in consumer
goods (toothbrushes, PalmPC's, mobile phones, washing machines, toilet lids etc). It is a
requirement where aesthetics has a significant contribution. For this reason the exterior of
automobiles are deemed Class-A. BIW is NOT Class-A. The exterior of you sexy toothbrush is
Class-A, the interior with ribs and inserts etc is NOT Class-A.
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QUESTION:What is Body_in_white?
What is class A surface?
Are the interior trim (A,B,C pillar, dash board, center console, handles) of a car using class A
surface?
Anybody using the basic design bundle of UG for class A surfacing? UG\Shape Studio?
How does it compare with Catia?
Ans:1A class A surface is anything that you the customer sees. i.e. exterior panels and interior
surfaces.
A Class B surface is something that is not always visible i.e. the underside of a fascia that you
would have to bend down to see.
A Class C surface is the back side of a part of a surface that is permanently covered by another
part.
BIW is stuff like the body side etc..
Ans:2Actually 'body in white' is the term used to describe the whole vehicle body after it has been
welded/bolted together before it is painted or any parts are attached on the fit up line.
Ans:3We also use it to mean after it has been painted - I always assumed that the white bit refers to
primer. Next step is to fit the windscreen and backlight, when it becomes the glazed body in
white, or BIW+G.
ANS: 4BIW - Some surfaces are Class A, i.e. body side, roof, sill appliqu.
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I heard some time ago from a old designer that the term BIW comes from when cars were built
from wood, they were painted white as it gives the frame a uniform color so imperfections were
easily visible.
Ans:5BIW meaning Body In White is so called due to its appearance after the application of the primer
to the entirely Body panel assembled vehicle just before going into the painting process.
Usually the primer is white or silver grey which gives the so called name.
ANS: 6Catia is mostly used for BIW design (Ford switching to catia, and Toyota). Is this because it
could easily create quintic surfaces? With UG with Design bundle only, most of the surfaces
created are cubic.
ANS: 7A class surface means- it is not just seen surface and unseen surface In normal no technicalwords,
A class surface means
It is smooth looking reflective surface with no distortion of light highlights, which moves in a
smooth uniform designer intended formations.
when you create - car body panel, due to their complex shapes it not possible to create the
surface with one single face /patch so you make multiple face/patch ( surface is a group of
face/patch added together.)
when these things are added, at the boundary of joining you need to have connectivity and
continuation of minimum order two.
for example
In case one, at the connecting boundary of two patches you have common boundary but it is
sharp corner. this does not qualify as A class surface.
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In case two - at the connecting boundary of two patches have common boundary and no
sharp corner - but you have tangent continuity, this also does not qualify as A class surface.
In case two - at the connecting boundary of two patches have common boundary and no
sharp corner - you have tangent continuity and curvature continuity this does qualify as Aclass surface.
( sine curve is good example for curvature continuity. but you can not call it a A class surface )
reason is very simple the real requirement of aesthetic and good looking and designer
intended shape is not there.
ANS: 8
For obtaining Class-A surfaces, CATIA is more commonly used due to its inherent ability to
model very high quality surfaces in general. But, any engineering software (CATIA, UG, IDEAS,
Pro-E, etc) cannot develop a Class-A surface. This being due to engineering calculations
involved in any surface generated by such softwares. For pure Class-A surfaces you would need
styling softwares like Alias, Studio, etc.
The use of any software would depend on the level of expectations placed on you. If your
projects need only the modeling of the trim, generic engg softwares will do, but if you intend to
go down right from styling, you would need Studio, etc.
ANS: 9IHO, Catia V4 has added a tool called Blend surf that is able to obtain virtual curvature
continuity. Previously, even styling was comfortable with models- and hence tools- defining
fillets with conics, and many OEMs still accept this for Class-A surfaces. Catia V5 has GUI
interfaces to impose curvature continuity the same way that Alias-Wave front Studio Tools (Auto
Studio) does. They are both based on piece-wise polynomial equations, for what its worth.
While a conic fillet is not technically curvature continuous, there are many vehicles, including
luxury models, that have utilized them for Class-A surfaces and downstream- parts.
Considering the tolerances in creating molds and dies and then producing parts from them.... a
sheet metal panel is not a math model.
ANS: 10It is true that it is tough to make good curvature continuous surface in UG, but not impossible.
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Remember one thing A-class doesn't mean just curvature continuity. and smooth reflections on
CAD surface. it is lot more than that. Imagine. what happens to your A class surface in case
pressed sheet metal body panel. and molded plastic components.
They have to retain there intended smoothness and other characteristics to remain A class. toachieve this lot of other things has to be taken care while designing A class surfaces.
For example :
1- Line features on body side external panel and feature on hood panel which is very
common, are to be designed to avoid skidding while they are pressed. like wise
2 -Flange width and other things are to be taken care while designing fenders wheel arch
area for avoiding bulging effect and skidding effect.
3 - Fuel lid opening area, plunged flange for bulge effect.
4 - Panel stretching needs to be taken care. Lot many other things go in designing A class
sheet metal panels for door , roof etc.
5 - In case of plastic, sink marks and other things.
ANS: 11In Europe a 'A' class surface is generally taken to be the visible side of any component /
assembly - a 'B' class surface generally relates to the opposite (or inside) face of an 'A' surface -
i.e. the surface which defines the thickness of the part, and is where the mounting and
reinforcing detail tends to be located. 'B' class surfaces can also be referred to as 'engineering
surfaces. I have not personally heard of any surface being referred to as a 'C' type.
Catia, while it is ok for surfacing tends to be more used for generating engineering surface
detail and solid models - software packages like ICEMSURF tend to be more used for
generating visual quality surfaces.
ANS: 12True A-class surfacing - especially on vehicle exteriors goes further than G2 or "curvature"
continuity.
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G3 is often sought on the more major block surfaces. G3 deals with curvature "acceleration", i.e.
the rate of change of curvature across a boundary.
G2 means as has been described before that the curvature value is the same across a boundary.
G3 means that the surface curvature leading to the boundary is changing shape at the same
rate. Its like driving a car round a bend, you start off straight then gently add steering lock to
the point where you need no more, then you gently wind off the steering until you're straight
again. If you look at the curve your car made, this would be G3.
A-Class and B-class would refer to surface quality required for the component which is
different to A-side and B-side which refers to which is the visible/non visible part of a
component.
ICEM surf is considered the best tool for speedy A-class surfacing due to the sophistication of
its real-time diagnostics.
The consequence:The consequence of these surfaces apart from visually and physically aesthetic shapes is the
way they reflect the real world. What would one expect to see across the boundary of pairs of
point continuity, tangent continuity and curvature continuity surfaces when reflecting a straight
and dry tree stump in the desert????
#Point Continuity (also known as G0 continuity) - will produce a reflection on one surface, thenat the boundary disappear and re-appear at a location slightly different on the other surface.
The same reflective phenomenon will show when there is a gap between the surfaces (the line
markers on a road reflecting across the gap between the doors of a car).
#Tangent Continuity (also known as G1 continuity) - will produce a reflection on one surface,
then at the boundary have a kink and continue. Unlike Point continuity the reflection (repeat
REFLECTION) is continuous but has a tangent discontinuity in it. In analogy, it is "like" a greater
than symbol.
#Curvature Continuity (also known as G2 continuity, Alias can do G3!) - this will produce the
unbroken and smooth reflection across the boundary.
#To achieve the same Class 'A' surfaces that automotive manufacturers demand, consumer
product manufacturers have availed themselves of the same advanced surface modeling tools.
What is a Class 'A' surface? The simple answer is that it is a perfectly smooth surface with no
anomalies, in which all adjoining surfaces have curvature continuity. This means that where two
surfaces meet, the graduation of one into the other is achieved without discernible abrupt
transitions. The techniques used to create Class 'A' surfaces typically reside in top level surface
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modeling software developed for the motor industry, rather than mid-range mechanical CAD
packages that have evolved from 3D solid modeling for mechanical assemblies.
Analyzing A Class SurfaceHighlight plot :Highlight is the behavior of the form or Shape of a surface when a light or nature reflects on it.This reflection of light or nature gives you an understanding about the quality of surface. This
reflection required should be natural, streamline and with uniformity.
Designer Fillets:If you take two adjoining 2D lines, or a couple of tangential surfaces, the intersection between
them can be turned into an arc (2D) or a fillet (3D), each of which is inserted with a constant
radius. However the transition from each line or surface can often be too abrupt for the design.
According to Mike Lang, Technical Director of VX, fillets should look simple - you shouldn't see
a fillet line in a model. They should also be simple to create. "Achieving tangent and curvature
continuity in complex shapes on other systems is hard work.
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A reduction in the weight of a curve will allow it to retain its tangency, but sharpen the change
in curvature. This can be seen most effectively by reducing the weight almost to zero.
Fairings- the shape of the curve - can be influenced by energy, variation, jerk, bend or tension- each of which will produce a subtle difference in the mathematical fit through the curve.
Echo Attributes:Part of the process of obtaining Class 'A' surfaces is being able to see what's happening to the
curve or the surface as it is being developed.
Increasing the scale of the iso lines allows designers to pick up smaller imperfections in
surfaces. Where blue iso lines lose their curve they change to white. The shifting colors of
Gaussian shading are also particularly adept at detecting subtle blemishes. Echo Attributes also
has numerous other modifiable elements, including the ability to apply colors to lines and
surfaces, and to alter the transparency of the surface. Curvature plots on non-designer fillets
show regular arcs, unlike designer fillets that show the weighting of the curve at each point.
"good design work relies on good wire frame technology. If you don't have basic curve
geometry, you won't be able to produce a good surface.
Designers must always go through the routine of checking curves, especially if the design has
come in from an outside source - perhaps containing older style Bezier curves with lots of
points.
Bezier CurvesThe following describes the mathematics for the so called Bezier curve. It is attributed and
named after a French engineer, Pierre Bezier, who used them for the body design of the Renault
car in the 1970's. They have since obtained dominance in the typesetting industry.
Consider N+1 control points pk (k=0 to N) in 3 space. The Bezier parametric curve function is
of the form.
B(u) is a continuous function in 3 space defining the curve with N discrete control points Pk.
u=0 at the first control point (k=0) and u=1 at the last control point (k=N).
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Notes:The curve in general does not pass through any of the control points except the first and last.
From the formula B(0) = P0 and B(1) = PN.
The curve is always contained within the convex hull of the control points, it never oscillates
wildly away from the control points.
If there is only one control point P0, i.e.: N=0 then B(u) = P0 for all u.
If there are only two control points P0 and P1, i.e.: N=1 then the formula reduces to a line
segment between the two control points.the term shown below is called a blending function since it blends the control points to form
the Bezier curve.
The blending function is always a polynomial one degree less than the number of control
points. Thus 3 control points results in a parabola, 4 control points a cubic curve etc.
Closed curves can be generated by making the last control point the same as the first control
point. First order continuity can be achieved by ensuring the tangent between the first two
points and the last two points are the same.
Adding multiple control points at a single position in space will add more weight to that point"pulling" the Bezier curve towards it.
As the number of control points increases it is necessary to have higher order polynomials and
possibly higher factorials. It is common therefore to piece together small sections of Bezier
curves to form a longer curve. This also helps control local conditions, normally changing the
position of one control point will affect the whole curve. Of course since the curve starts and
ends at the first and last control point it is easy to physically match the sections. It is also
possible to match the first derivative since the tangent at the ends is along the line between the
two points at the end.
Second order continuity is generally not possible.
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3.The curve always lies within the convex hull of the control points. Thus the curve is always
"well behaved" and does not oscillating erratically.
4.Closed curves are generated by specifying the first point the same as the last point. If the
tangents at the first and last points match then the curve will be closed with first order
continuity.
In addition, the curve may be pulled towards a control point by specifying it multiple times. BEZIER SURFACEThe Bezier surface is formed as the Cartesian product of the blending functions of two
orthogonal Bezier curves.
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Where Pi,j is the i,jth control point. There are Ni+1 and Nj+1 control points in the i and j
directions respectively.
The corresponding properties of the Bezier curve apply to the Bezier surface.
- The surface does not in general pass through the control points except for the corners of the
control point grid.
- The surface is contained within the convex hull of the control points.
Along the edges of the grid patch the Bezier surface matches that of a Bezier curve through the
control points along that edge.
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Closed surfaces can be formed by setting the last control point equal to the first. If the tangents
also match between the first two and last two control points then the closed surface will have
first order continuity.
While a cylinder/cone can be formed from a Bezier surface, it is not possible to form a sphere.A little history of Surface ModelingA little history
Surface modeling was developed in the automotive and aerospace industries in the late 1970s
to design and manufacture complex shapes. Nurbs -- nonuniform rational B-splines -- and
cubic-surface formats appeared early and remain the primary spline and surface formats used
throughout the CAD industry. Nurbs and cubics are supported by IGES (Initial Graphics
Exchange Specification), a neutral file format for exchanging data between CAD systems.
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Nurbs and cubic formats are represented in a computer by polynomial equations generated by a
CAD system, and onscreen through the location and shape of curves and surfaces. For example,
the equation of a line, a first-degree polynomial, has this form
Y = ax + b
The equation for a parabola, a second-degree polynomial, has the form
Y = ax2 + bx + c
And the equation of a cubic spline, a third-degree polynomial, looks like
Y = ax3 + bx2 + cx + d
The more terms in the polynomial equation, the more "shape" the curve or surface has.
The data structure of a Nurbs curve or surface is comprised of points, weights, and parameter
values that define a control net which is tangent to the curve or surface. The control net on a
Nurbs surface is a rectangular grid of connected straight-line elements which define the
tangency of the surface at positions along the control net. The points in the database which
describe the control net are not actually on the surface, they are at the vertices of the control
net. Weights in the Nurbs data structure determine the amount of surface deflection toward or
away from its control point.
Cubic data structures use third-degree polynomials that describe points actually on the curve
or surface. Therefore, the Nurbs control net is an abstraction of the underlying surface, whereas
the cubic equation is the surface.
Nurbs and cubic formats each have advantages and disadvantages. Nurbs equations model
more complex shapes by increasing the degree of the exponents in the polynomial, thus
increasing the memory required to store and evaluate the equation. Cubic equations, on the
other hand, require less storage and can capture complex shapes by adding more cubic
segments to the spline or surface. Nurbs and cubic equations are said to be "piecewise" and"parametric," which means the curve or surface is a sequence of connected segments that use
parametric u and v values ranging from 0 to 1 or 0 to n (number of segments) to calculate
points along the curve or surface.
Nurbs and cubic formats each have advantages and disadvantages. Nurbs equations model
more complex shapes by increasing the degree of the exponents in the polynomial, thus
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increasing the memory required to store and evaluate the equation. Cubic equations, on the
other hand, require less storage and can capture complex shapes by adding more cubic
segments to the spline or surface. Nurbs and cubic equations are said to be "piecewise" and
"parametric," which means the curve or surface is a sequence of connected segments that use
parametric u and v values ranging from 0 to 1 or 0 to n (number of segments) to calculate
points along the curve or surface.
Ultimately, a good CAD system shields users from having to know too much about the
mathematics that represent the underlying surfaces. In addition, surface modelers should:
Provide enough tools to completely define any feature on the part using surfaces.
Have many functions for defining the different shapes of surfaces including ruled, revolved,
lofted, extruded, swept, offset, filleted, blended, planar boundary, and drafted. Each of thesefunctions have further variations.
For example, offset surfaces should allow for constant or tapered offsets. Draft-surface
functions should let users input curves to define the draft surface, or allow using curves on a
surface whereby the draft angle is referenced off a surface-normal vector at points along the
curve. The lofted surface should allow for the input of cross-section curves or for the input of
curves both along and across the surface.
Support functions such as surface trimming, extending, intersecting, projecting, polygon
tessellation, IGES translation, coordinate-system transformations, and editing.
Allow extracting surface data such as flow curves, vectors, and planes, among other functions.
Have a set of tools for defining points, planes, vectors, and splines used with surface modeling.
Most surface creation functions need user inputs to define surfaces.
Two useful surface-modeling functions are the controlled sweep and the draft surface. A
controlled sweep forces a profile curve to remain perpendicular to the sweep path by using a
control surface. Without a control surface in the construction of a swept surface, the profile
curve typically wants to lay down or spin around the sweep path. A properly defined control
surface solves the problem.
A draft surface is similar to a controlled sweep in that it uses curves lying on one surface to
create another. The resultant draft surface passes through the input curve and is composed of
straight-line elements radiating from the reference surface at an angle to the surface normal
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vectors taken at points along the input curve. A draft-surface function can build one surface
perpendicular to another, along a curve.
A Comparison Between Solid-Surface Modeling:While surface modelers excel at defining complex shapes, solid modeling is good at quickly
building primitive geometry. Primitive geometry consists of basic surfaces such as planes,
cylinders, cones, spheres, and tori. Surface modeling is not as fast at creating simple part
geometry, but if your solid modeler can't easily model a feature, such as a fillet, surface
modeling can almost always finish the part.
And for every solid-modeling function there is a counterpart in surface modeling. Nurbs
surfaces can be incorporated into an existing solid model by "stitching" the Nurbs surface to
the solid model. Some parts can be completely defined by a solid modeler as a collection of
primitive surfaces, while other parts require Nurbs surfaces to fully define the geometry. Most
parts manufactured with tooling require some kind of Nurbs surface to support production.
Reverse engineering is heavily dependent on Nurbs surfaces to capture digitized points into
surfaces.
In addition, Nurbs-surface files generated over the last 20 years are circulating in IGES format
between vendors and subcontractors. These files support the design of parts in one system and
manufacturing in another. Solid modeling will not replace Nurbs-surface modeling because the
two work hand in hand to complete part geometry.
TYPES OF CONTINUTYContinuity is a measure of how well two curves or surfaces "flow" into each other.
POSITION (G0)
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This type of continuity between curves implies that the endpoints of the curves have the same
X,Y, and Z position in the world space. This is the minimum requirement for obtaining G0.
TANGENT (G1)
This type of continuity between curves implies that the tangent CVs must be on one line.
CURVATURE (G2)
This continuity type impacts the third CV of the curve. All three CVs have to be considered in
order to maintain a smooth curvature comb.
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If a curvature comb does not have a smooth transitional line. In order to improve the curvature
comb, manually modify the position of the three CVs that constitute the G2 continuity.
Surface Blending:
Surface Blending is one of the most critical functions of any surface design package. With
Surface Blending you can construct a large complex smooth objects such as a car body or a
face. Higher order blending (G2, G3, etc.) can be used to construct surfaces which have very
nice reflective and aesthetic qualities. Higher order blending is used extensively in auto body
design and industrial design.
Blending Two Surfaces Using Derivative Surface Technology:The top image shows two surfaces with corresponding derivative surfaces constructed from
them. Just below that we show just a G1 derivative surface. The type of derivative surface and
its magnitude can be changed to produce different blending surfaces. The image on the right
shows a simple G1 blend of these two surfaces.
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Change Strength of One of Derivative SurfacesIn this image we have increased the strength of the left derivative surface by a factor of 2.
Change Continuity of Derivative Surfaces and Resulting BlendThe above images show a G2 continuity on the top and G3 continuity just below it. Note that
the higher continuity in this case causes the surface to have a sharper ripple in it. This can
easily be adjusted by changing the strength of the Derivative Surface.
Adjust Strength of G3 Continuity
Here we have adjusted the strength of the G3 continuity to a smaller value. Below you can see a
larger image with G3 continuity. It is impossible to visually tell where one surface begins and
the other ends. The reflective qualities of a high continuity blend are far superior to lower
continuity blending.
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What Does NURBS Mean?NURBS, Non-Uniform Rational B-Splines, are mathematical representations of 3-D geometrythat can accurately describe any shape from a simple 2-D line, circle, arc, or curve to the most
complex 3-D organic free-form surface or solid. Because of their flexibility and accuracy,
NURBS models can be used in any process from illustration and animation to manufacturing.
NURBS geometry has five important qualities that make it an ideal choice for computer-aided
modeling.
There are several industry standard ways to exchange NURBS geometry. This means that
customers can and should expect to be able to move their valuable geometric models between
various modeling, rendering, animation, and engineering analysis programs. They can store
geometric information in a way that will be usable 20 years from now.
NURBShave a precise and well-known definition. The mathematics and computer science ofNURBS geometry is taught in most major universities. This means that specialty software
vendors, engineering teams, industrial design firms, and animation houses that need to create
custom software applications, can find trained programmers who are able to work with NURBS
geometry.
NURBS can accurately represent both standard geometric objects like lines, circles, ellipses,
spheres, and tori, and free-form geometry like car bodies and human bodies.
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The amount of information required for a NURBS representation of a piece of geometry is much
smaller than the amount of information required by common faceted approximations.
The NURBS evaluation rule, discussed below, can be implemented on a computer in a way that
is both efficient and accurate.
DegreeThe degree is a positive whole number.
This number is usually 1, 2, 3 or 5, but can be any positive whole number. NURBS lines and
polylines are usually degree 1, NURBS circles are degree 2, and most free-form curves are
degree 3 or 5. Sometimes the terms linear, quadratic, cubic, and quintic are used. Linear means
degree 1, quadratic means degree 2, cubic means degree 3, and quintic means degree 5.
You may see references to the order of a NURBS curve. The order of a NURBS curve is positive
whole number equal to (degree+1). Consequently, the degree is equal to order-1.
It is possible to increase the degree of a NURBS curve and not change its shape. Generally, it is
not possible to reduce a NURBS curves degree without changing its shape.
Control PointsThe control points are a list of at least degree+1 points.
One of easiest ways to change the shape of a NURBS curve is to move its control points.
The control points have an associated number called a weight . With a few exceptions, weights
are positive numbers. When a curves control points all have the same weight (usually 1), the
curve is called non-rational, otherwise the curve is called rational. The R in NURBS stands for
rational and indicates that a NURBS curve has the possibility of being rational. In practice, most
NURBS curves are non-rational. A few NURBS curves, circles and ellipses being notable
examples, are always rational.
KnotsThe knots are a list of degree+N-1 numbers, where N is the number of control points.
Sometimes this list of numbers is called the knot vector. In this term, the word vector does not
mean 3-D direction.
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This list of knot numbers must satisfy several technical conditions. The standard way to ensure
that the technical conditions are satisfied is to require the numbers to stay the same or get
larger as you go down the list and to limit the number of duplicate values to no more than the
degree. For example, for a degree 3 NURBS curve with 11 control points, the list of numbers
0,0,0,1,2,2,2,3,7,7,9,9,9 is a satisfactory list of knots. The list 0,0,0,1,2,2,2,2,7,7,9,9,9 is
unacceptable because there are four 2s and four is larger than the degree.
The number of times a knot value is duplicated is called the knots multiplicity. In the preceding
example of a satisfactory list of knots, the knot value 0 has multiplicity three, the knot value 1
has multiplicity one, the knot value 2 has multiplicity three, the knot value 3 has multiplicity
one, the knot value 7 has multiplicity two, and the knot value 9 has multiplicity three. A knot
value is said to be a full-multiplicity knot if it is duplicated degree many times. In the example,
the knot values 0, 2, and 9 have full multiplicity. A knot value that appears only once is called a
simple knot. In the example, the knot values 1 and 3 are simple knots.
If a list of knots starts with a full multiplicity knot, is followed by simple knots, terminates with
a full multiplicity knot, and the values are equally spaced, then the knots are called uniform. For
example, if a degree 3 NURBS curve with 7 control points has knots 0,0,0,1,2,3,4,4,4, then the
curve has uniform knots. The knots 0,0,0,1,2,5,6,6,6 are not uniform. Knots that are not
uniform are called non-uniform. The N and U in NURBS stand for non-uniform and indicate that
the knots in a NURBS curve are permitted to be non-uniform.
Duplicate knot values in the middle of the knot list make a NURBS curve less smooth. At the
extreme, a full multiplicity knot in the middle of the knot list means there is a place on the
NURBS curve that can be bent into a sharp kink. For this reason, some designers like to add and
remove knots and then adjust control points to make curves have smoother or kinkier shapes.
Since the number of knots is equal to (N+degree-1), where N is the number of control points,
adding knots also adds control points and removing knots removes control points. Knots can
be added without changing the shape of a NURBS curve. In general, removing knots will change
the shape of a curve.
Knots and Control PointsA common misconception is that each knot is paired with a control point. This is true only for
degree 1 NURBS (polylines). For higher degree NURBS, there are groups of 2 x degree knots that
correspond to groups of degree+1 control points. For example, suppose we have a degree 3
NURBS with 7 control points and knots 0,0,0,1,2,5,8,8,8. The first four control points are
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grouped with the first six knots. The second through fifth control points are grouped with the
knots 0,0,1,2,5,8. The third through sixth control points are grouped with the knots
0,1,2,5,8,8. The last four control points are grouped with the last six knots.
Some modelers that use older algorithms for NURBS evaluation require two extra knot valuesfor a total of degree+N+1 knots. When Rhino is exporting and importing NURBS geometry, it
automatically adds and removes these two superfluous knots as the situation requires.
EQUATIONAL DEFINITIONALNURBS-Curve:A nonuniform rational B-Spline curve defined by
where p is the order, Ni,p are the B-Spline basis functions, Pi are control points, and the Weight
Wi of Pi is the last ordinate of the homogeneous point Piw. These curves are closed under
perspective transformations and can represent conic Sections exactly.
NURBS-Surface:A nonuniform rational B-spline surface of degree (p, q) is defined by.
where Ni,p and Nj,q are the B-Spline basis functions, Pi,j are control points, and the Weight Wi,j
of Pi,j is the last ordinate of the homogeneous point Pi,jw.
The Advantage of Using B-spline Curves:B-spline curves require more information (i.e., the degree of the curve and a knot vector) and a
more complex theory than Bezier curves. But, it has more advantages to offset this
shortcoming. First, a B-spline curve can be a Bezier curve. Second, B-spline curves satisfy all
important properties that Bezier curves have. Third, B-spline curves provide more control
flexibility than Bezier curves can do. For example, the degree of a B-spline curve is separated
from the number of control points. More precisely, we can use lower degree curves and still
maintain a large number of control points. We can change the position of a control point
without globally changing the shape of the whole curve (local modification property). Since B-
spline curves satisfy the strong convex hull property, they have a finer shape control. Moreover,
there are other techniques for designing and editing the shape of a curve such as changing
knots. However, keep in mind that B-spline curves are still polynomial curves and polynomial
curves cannot represent many useful simple curves such as circles and ellipses. Thus, a
generalization of B-spline, NURBS, is required.