Difference between revisions of "A Survey of Implicit Constraints in Primitives"
Homovulgaris (talk | contribs) m (→Implict Constraints by Primitive) |
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# B.C = 0 | # B.C = 0 | ||
# C.A = 0 | # C.A = 0 | ||
+ | |||
+ | ===rec (Right elliptical cylinder)=== | ||
+ | |||
+ | 3 types: Non-negativity/Modulus comparison, Perpendicularity, Vector equality | ||
+ | |||
+ | Constraints: | ||
+ | # |H| > 0 | ||
+ | # |A| > 0 | ||
+ | # |B| > 0 | ||
+ | # A = C | ||
+ | # B = D | ||
+ | # A.B = 0 | ||
+ | # H.A = 0 | ||
+ | # H.B = 0 | ||
+ | |||
+ | ===rhc (Right hyperbolic cylinder)=== | ||
+ | |||
+ | 3 types: Non-negativity/Modulus comparison, Perpendicularity | ||
+ | |||
+ | Constraints: | ||
+ | # |H| > 0 | ||
+ | # |B| > 0 | ||
+ | # |R| > 0 | ||
+ | # H.B = 0 | ||
+ | |||
+ | ===rpc (Right parabolic cylinder)=== | ||
+ | |||
+ | 2 types: Non-negativity/Modulus comparison, Perpendicularity | ||
+ | |||
+ | Constraints: | ||
+ | # |H| > 0 | ||
+ | # |B| > 0 | ||
+ | # |R| > 0 | ||
+ | # H.B = 0 | ||
===sph (Sphere)=== | ===sph (Sphere)=== |
Revision as of 14:55, 5 August 2008
Contents
Types of Implicit Parameters
At the level of constraint networks, calculations are done in terms of Variables or indpendent real values / floating point numbers. But in the construction of geometry these are clustered together in terms of implicit parameters. Typical implicit parameters are
- Vectors - A 3 dimensional vector is a 3-tuple which is used to hold direction as well as magnitude. In BRL-CAD primitives, they may represent
- Radius vectors ( Center of a sphere)
- Direction vectors (Direction of a plane)
Types of Implicit Constraints
An enumeration of the set of contraints observed in the primitives below
- Modulus Comparison : Comparison of the modulus of a vector to a real number ( 0 for non-negativity ) or the modulus of another vector
- Perpendicularity of Vectors
Implict Constraints by Primitive
ell (Ellipse)
Ellipse is built using the Center (radius vector V) and 3 Vectors (A, B, C st. |A| = radius) 2 types: Non-negativity/Modulus comparison, Perpendicularity Constraints:
- |A| > 0
- |B| > 0
- |C| > 0
- A.B = 0
- B.C = 0
- C.A = 0
rec (Right elliptical cylinder)
3 types: Non-negativity/Modulus comparison, Perpendicularity, Vector equality
Constraints:
- |H| > 0
- |A| > 0
- |B| > 0
- A = C
- B = D
- A.B = 0
- H.A = 0
- H.B = 0
rhc (Right hyperbolic cylinder)
3 types: Non-negativity/Modulus comparison, Perpendicularity
Constraints:
- |H| > 0
- |B| > 0
- |R| > 0
- H.B = 0
rpc (Right parabolic cylinder)
2 types: Non-negativity/Modulus comparison, Perpendicularity
Constraints:
- |H| > 0
- |B| > 0
- |R| > 0
- H.B = 0
sph (Sphere)
Sphere is a particular case of the ellipse
Constraints: 2 types: Modulus comparison, Perpendicularity
- |A| > 0
- |B| > 0
- |C| > 0
- |A| = |B|
- |A| = |C|
- |B| = |C|
- A.B = 0
- B.C = 0
- C.A = 0
tgc (Truncated General Cone)
Constraints: 5 types: Modulus comparison, Logical Combination, Perpendicularity, Non-planarity, Parallelism
- |H| > 0
- |A| & |B| not zero together
- |B| & |D| not zero togehter
- |A|*|B| and |C|*|D| not zero together
- H is nonplanar to AB plane
- A.B = 0
- C.D = 0
- A || C ( A is parallel to C )
tor (Torus)
Tor is built using the following input fields
V V from origin to center H Radius Vector, Normal to plane of torus. |H| = R2 A, B perpindicular, to CENTER of torus. |A|==|B|==R1 F5, F6 perpindicular, for inner edge (unused) F7, F8 perpindicular, for outer edge (unused)
Constraints: 2 types: Modulus comparison, Perpendicularity
- |A| = |B|
- A.B = 0
- B.H = 0
- H.A = 0
- |H| > 0
- |H| < |A|