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PK_BSURF_sf_t |
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struct PK_BSURF_sf_s
{
int u_degree; --- The degree in u = order-1.
int v_degree; --- The degree in v = order-1.
int n_u_vertices; --- The number of vertices in u.
int n_v_vertices; --- The number of vertices in v.
int vertex_dim; --- The dimension of each vertex.
PK_LOGICAL_t is_rational; --- True if the surface is rational
double *vertex; --- The vertices.
PK_BSURF_form_t form; --- The surface shape.
int n_u_knots; --- The number of distinct knot
--- values in u.
int n_v_knots; --- The number of distinct knot
--- values in v.
int *u_knot_mult; --- The multiplicities in u.
int *v_knot_mult; --- The multiplicities in v.
double *u_knot; --- The distinct knot values in u.
double *v_knot; --- The distinct knot values in v.
PK_knot_type_t u_knot_type; --- Enum describing the u knot set.
PK_knot_type_t v_knot_type; --- Enum describing the v knot set.
PK_LOGICAL_t is_u_periodic; --- Periodic in u.
PK_LOGICAL_t is_v_periodic; --- Periodic in v.
PK_LOGICAL_t is_u_closed; --- Closed in u.
PK_LOGICAL_t is_v_closed; --- Closed in v.
PK_self_intersect_t self_intersecting; --- Yes no or maybe.
PK_convexity_t convexity; --- Yes no or maybe.
};
typedef struct PK_BSURF_sf_s PK_BSURF_sf_t;
This data structure is the standard form for a b-surface. See the
documentation below for the relationship between this data structure and STEP.
Specific Errors:
PK_ERROR_bad_value unreadable value
PK_ERROR_bad_knots illegal knot multiplicity
or knot set not monotonic increasing
PK_ERROR_wrong_number_knots knots inconsistent with vertices
PK_ERROR_bad_dimension dimension < 1 polynomial or < 2 rational
PK_ERROR_weight_le_0 one of the weights is zero or negative
Used in:
PK_BSURF_ask
PK_BSURF_create
Converting between PK_BSURF_sf_t and STEP:
This form is easily convertible to the STEP standard, but there are a
number of important differences, designed to make its use simpler and more
efficient.
'vertex_dim':
This field gives the number of doubles per vertex in the array 'vertex'.
Allowable values are 3 and 4. A value of 3 implies a 3-d polynomial
surface. A value of 4 implies a 3-d rational surface. The STEP
"cartesian_point" entity allows 1, 2 or 3.
'is_rational':
This field is set to true if the surface is rational. In this case the
vertex_dim field must be 4, and the weights must be included in the
'vertex' array. The STEP standard uses a distinct entity subtype
"rational_b_spline_surface".
'vertex':
If the surface is polynomial, dimension 3, then the values in this field
represent the vertices explicitly, in the order [x1, y1, z1, x2, y2, ...]
respectively. If it is rational, dimension 4, then the cartesian points
are multiplied by the weights, so that the values in this field represent
x1w1, y1w1, z1w1, w1, x2w2, y2w2, ...]. The vertices are so arranged that
they vary most quickly with v and then with u. The STEP standard uses a
separate array of weights, and does not multiply the cartesian points by
the weights.
'form':
See the documentation of 'PK_BSURF_form_t'.
This field corresponds to the field of the same name in the STEP
"b_spline_surface" entity, except for the 'PK_BSURF_form_unset_c' value
which does not exist in the STEP standard.
'u_knot_mult' 'v_knot_mult' 'u_knot' and 'v_knot':
'u_knot_mult' and 'v_knot_mult' are arrays of length 'n_u_knots' and
'n_v_knots' respectively, giving the number of times each knot is to be
repeated. The minimum multiplicity allowed for any knot is 1. The maximum
multiplicity allowed other than for the first and last knot is the degree
in that parameter. The maximum allowed for the first or last knot is the
degree+1.
'u_knot' and 'v_knot' are arrays of length 'n_u_knots' and 'n_v_knots'
respectively. The values must be distinct and form a strictly increasing
set.
See the documentation below for an explanation of the required total
number of knots.
These arrays correspond exactly to the fields "u_multiplicities"
"v_multiplicities" "u_knots" and "v_knots" in the STEP entity sub-type
"b_spline_surface_with_knots".
'u_knot_type' and 'v_knot_type':
See the documentation for 'PK_knot_type_t'. The STEP standard does not
contain a field corresponding to these. The information described is
conveyed by the use of entity subtypes, such as "bezier_surface". The
values 'PK_knot_bezier_ends_c' and 'PK_knot_non_uniform_c' have no
corresponding subtype. A surface of one of these types would be translated
to STEP as a "bspline_surface_with_knots". For a surface to be translated
as, for instance "uniform_surface", both knot types would have to be
uniform. Otherwise it would default to the more general
"bspline_surface_with_knots".
'is_u_periodic' and 'is_v_periodic':
If either of these fields is set to true, the parametrisation of the
surface "wraps around". It implies that the surface is closed in that
direction, with G1 continuity at the seam. This field does not exist in
the STEP standard.
See the documentation below for additional requirements for the knot sets
of a periodic b-surface.
'is_u_closed' and 'is_v_closed':
One or both of these fields being set to true does not necessarily imply
that the parametrisation is periodic. They correspond to the fields of the
same name in the STEP entity "b_spline_surface".
'self_intersecting':
See the documentation of PK_self_intersect_t.
This corresponds to the field "self_intersect" in the STEP entity
"b_spline_surface", except that the STEP standard does not provide for an
unset value.
'convexity':
See the documentation of PK_convexity_t.
This field has no correspondence in the STEP "b_spline_surface" entity.
Surfaces being converted from STEP should be given a value of
'PK_convexity_unset_c'.
The number of knots:
The knot set referred to here is the "expanded knot set" obtained by repeating
each value in the array 'u_knot' or 'v_knot' the number of times given by the
corresponding element in 'u_knot_mult' or 'v_knot_mult'.
A NURBS surface of degree n in one of its parameters defined over k values
k-1 intervals) in that parameter requires a further n values at either end of
that knot set in order for the necessary k+n-1 b-spline basis functions to be
fully defined. These additional values are commonly known as the "imaginary
knots". Thus the total number of knots p is related to the total number of
basis functions and hence the number m of control vertices in that direction
the number of rows or collumns) by the expression p = m+n+1.
Periodic Surfaces:
A periodic surface must be so constructed as to preserve G1 continuity
(of tangent direction) at the seam.
In addition, it is recommended that a periodic surface be constructed
with C(n-1) continuity at the seam (where n is the degree). This would
give C2 continuity at the seam for a cubic. This is most easily achieved
by making the "expanded knot set" "wrap around" in the sense that the
intervals between the first n+1 knots (n "imaginary" knots and one "real"
knot) should be the same as the corresponding intervals between the last
n+1 "real" knots, and the intervals between the last n+1 knots (one "real"
knot and n "imaginary" knots) should be the same as those between the first
n+1 "real" knots.
The "period" of such a surface is the parameter interval separating the first
and last "real" knots in the periodic parameter direction.
if indices begin at 0:
period = u_or_v - u_or_v
k+n-1 n
for i = 0 to n:
u_or_v - period = u_or_v
k+n+i-1 n+i
u_or_v + period = u_or_v
i k+i-1