Title of Invention

COMPUTER AIDED DESIGN SYSTEM AND METHOD .

Abstract There is disclosed a computer aided design system and a computer aided design method capable of significantly increasing the utility value of a computer aided design model and efficiency of the design / production process by employing the theory of surfaces guaranteeing the continuity of a free curve / curved surface. The method involves executing a point sequence extraction processing for extracting a plurality of point sequences on a curved surface, a division processing for generating a curved surface from a point sequence by using another computer aided design system and dividing the curved surface into a predetermined number of meshes, a primary standard amount calculation processing for calculating a primary standard amount defined by a tangent vector forming a mesh tangent plane, a secondary standard amount calculation processing for calculating a secondary standard amount defined by a tangent vector and a mesh normal vector, and a storage processing for storing the point sequence information, the first standard amount, and the second standard amount.
Full Text DESCRIPTION
COMPUTER AIDED DESIGN SYSTEM AND METHOD
TECHNICAL FIELD
The present invention relates to a computer aided design system
and a computer aided design method which transform the shape of a
member into an objective curved surface shape.
BACKGROUND ART
Today, there is a desire to shorten processes from
planning, to design and production to respond to consumer
demand. In order to improve the efficiency of design and
production processes, the use of CG (Computer Graphics) and
CAD (Computer Aided Design) systems is popular. In order to
depict shapes having complex curved lines or curved surface
shapes, such as for motor vehicles, domestic electric
appliances or the like, on a computer, the following
processing methods have conventionally existed.
The first is solid modeling, where simple shapes called
primitives, are held in a computer, and operations to combine
the shapes with each other are repeated in order to express
complex shapes. A primitive is for example a column, a cube,
a hexahedron, a torus, a ball, or the like, and in the solid
modeling, shapes are represented by set operations on these
primitives. Therefore, in order to produce a complex shape

many steps are required and precise calculations are required.
The second is surface modeling, which utilizes an
algorithm such as a bezier, b-spline, rational bezier, NURBS
(Non-Uniform Rational b-spline), or the like in order to
perform operations such as cutting or connecting lines or
surfaces, and by repeating these operations complex free
curved lines or curved surfaces are represented.
However, even with a model where there are no problems
from the point of representation with the solid model or
surface model described above, in some cases problems may
occur in the case where it is used by a downstream application
such as CAM, CAE, or the like. This is caused by differences
between the support element to be supported by the produced
computer graphics, and the support element to be supported by
the other computer graphics, computer aided design, and
downstream applications, and differences in shape definition,
or the like. The model is corrected via an application such
as a translator which modifies these differences (Japanese
Unexamined Patent Publication Nos. 2001-250130, Hei 11-65628,
Hei 10-69506, Hei 4-134571, Hei 4-117572, and Hei 1-65628).
DISCLOSURE OF INVENTION
However, the above described correcting operations are
extremely ineffective for shortening the design and production
processes. The reasons for requiring the corrections vary
depending on each case, but the point which becomes a problem,
particularly in the production stage is that the

representations of all curved lines and curved surfaces are
approximated by Euclidean geometry in a conventional computer
graphics or computer aided design system. For example, in the
case where a saddle type tabulated cylinder surfaces shown in
FIG. 6 is generated by a sweep operation, a long line in the
lower slope part of the saddle and a short line in the central
part of the saddle exist. Therefore, this sweep operation is
a transformation accompanied with graphical expansion and
contraction in order to maintain the continuity of the curved
surface generated. However, in the conventional computer
graphics or computer aided design system, this expansion and
contraction is not considered, and the internal representation
is approximately represented as a cylinder type. Therefore,
if the computer graphics model or computer aided design model
which are actually approximately represented by such Euclidean
geometry, are passed to a CAE, the error occurring here
becomes a problem in production.
The present invention has been devised to solve such
problems, with an object of providing a computer aided design
system and a computer aided design program which can greatly
utilize a computer graphics model or a computer aided design
model, and can improve the efficiency of design and production
processes.
A computer aided design system of the present invention
comprises : a point sequence information extraction device which
extracts a plurality of point sequences on a curved surface ; a
dividing device which generates a curved surface from said point

sequences using another computer aided design system and divides said
curved surface into a predetermined number of meshes; a first
fundamental form computing device for computing coefficients of the
first fundamental form defined by a tangent vector which forms a
tangent plane of said mesh; a second fundamental form computing
device for computing coefficients of the second fundamental form
defined by said tangent vector and a normal vector of said mesh; a
principal curvature computing device which computes a principal
curvature of said mesh based on said coefficients of the first
fundamental form and coefficients of the second fundamental form; a
line of curvature computing device which computes a line of curvature
showing a principal direction of said mesh based on said principal
curvature; a feature point / feature line analyzing device which
extracts a point or a line which become a reference point or a
reference line of transformation defined by changing patterns of one
or more feature quantities among five feature quantities showing
features of said curved surface comprising a Gaussian curvature and a
mean curvature computed based on said principal curvature, said
principal direction, said line of curvature, and said coefficients of
the first fundamental form and coefficients of the second fundamental
form,- a girth length computing device which computes a girth length
based on a curvature computed from said co-efficients of the first
fundamental form and coefficients of the second fundamental form;
and a reproducing device which transforms said line of curvature for

said girth length in said line of curvature direction, with said
feature point or feature line as a transformation reference, and
reproduces said mesh or said curved surface.
Furthermore, the computer aided design system of the present
invention further comprises : a converting device which extracts a
plurality of point sequences on a curved surface from the reproduced
mesh or curved surface, and converts the point sequences according to
a graphical representation algorithm in another computer aided design
system.
A computer aided design method of the present invention executes
on a computer : a point sequence information extraction process for
extracting a plurality of point sequences on a curved surface; a
dividing process for generating a curved surface from said point
sequences using another computer aided design system, and dividing
said curved surface into a predetermined number of meshes; a first
fundamental form computing process for computing coefficients of the
first fundamental form defined by a tangent vector which forms a
tangent plane of said mesh; a second fundamental form computing
process for computing coefficients of the second fundamental form
defined by said tangent vector and a normal vector of said mesh; a
principal curvature computing process for computing a principal
curvature of said mesh based on said coefficients of the first
fundamental form and coefficients of the second fundamental form; a
line of curvature computing process for computing a line of curvature

showing a principal direction of said mesh based on said principal
curvature; a feature point / feature line analyzing process for
extracting a point or a line which become a reference point or a
reference line of transformation defined by changing patterns of one
or more feature quantities among five feature quantities showing
features of said curved surface comprising a Gaussian curvature and a
mean curvature computed based on said principal curvature, said
principal direction, said line of curvature, and said coefficients of
the first fundamental form and coefficients of the second fundamental
form; a girth length computing process for computing a girth length
based on a curvature computed from said coefficients of the first
fundamental form and coefficients of the second fundamental form;
and a reproducing process for transforming said line of curvature for
said girth length in said line of curvature direction, with said
feature point or feature line as a transformation reference, and
reproducing said mesh or said curved surface.
Moreover, the computer aided design method of the present
invention is a computer aided design method for further executing on
a computer : a converting process for extracting a plurality of point
sequences on a curved surface from said reproduced mesh or curved
surface, and converting said point sequences according to a graphical
representation algorithm in another computer aided design system.

A computer graphics system of the present invention comprises :a
point sequence information extraction device which extracts a
plurality of point sequences on a curved surface; a dividing device
which generates a curved surface from said point sequences using
another computer graphics system, and divides said curved surface
into a predetermined number of meshes; a first fundamental form
computing device for computing coefficients of the first fundamental
form defined by a tangent vector which forms a tangent plane of said
mesh; a second fundamental form computing device for computing
coefficients of the second fundamental form defined by said tangent
vector and a normal vector of said mesh; and a principal curvature
computing device which computes a principal curvature of said mesh
based on said coefficients of the first fundamental form and
coefficients of the second fundamental form; a line of curvature
computing device which computes a line of curvature showing a
principal direction of said mesh based on said principal curvature;
a feature point / feature line analyzing device which extracts a
point or a line which become a reference point or a reference line of
transformation defined by changing patterns of one or more feature
quantities among five feature quantities showing features of said
curved surface comprising a Gaussian curvature and a mean curvature
computed based on said principal curvature, said principal direction,
said line of curvature, and said coefficients of the first
fundamental form and coefficients of the second fundamental form; a

girth length computing device which computes a girth length based on
a curvature computed from said coefficients of the first fundamental
form and coefficients of the second fundamental form; and a
reproducing device which transforms said line of curvature for said
girth length in said line of curvature direction, with said feature
point or feature line as a transformation reference, and reproduces
said mesh or said curved surface.
Moreover, the computer graphics method of the present invention,
executes on a computer : a point sequence information extraction
process for extracting a plurality of point sequences on a curved
surface; a dividing process for generating a curved surface from
said point sequences using another computer graphics system, and
dividing said curved surface into a predetermined number of meshes;
a first fundamental form computing process for computing coefficients
of the first fundamental form defined by a tangent vector which forms
a tangent plane of said mesh; a second fundamental form computing
process for computing coefficients of the second fundamental form
defined by said tangent vector and a normal vector of said mesh; a
principal curvature computing process for computing a principal
curvature of said mesh based on said coefficients of the first
fundamental form and coefficients of the second fundamental form; a
line of curvature computing process for computing a line of curvature
showing a principal direction of said mesh based on said principal
curvature; a feature point / feature line analyzing process for

extracting a point or a line which become a reference point or a
reference line of transformation defined by changing patterns of one
or more feature quantities among five feature quantities showing
features of said curved surface comprising a Gaussian curvature and a
mean curvature computed based on said principal curvature, said
principal direction, said line of curvature, and said coefficients of
the first fundamental form and coefficients of the second fundamental
form; a girth length computing device for computing a girth length
based on a curvature computed from said coefficients of the first
fundamental form and coefficients of the second fundamental form;
and a reproducing process for transforming said line of curvature for
said girth length in said line of curvature direction, with said
feature point or feature line as a transformation reference, and
reproducing said mesh or said curved surface.
The present invention demonstrates the following effects.
Since it comprises: the point sequence information
extraction device which extracts a plurality of point
sequences on a curved surface; the dividing device which
generates a curved surface from the point sequences using
another computer graphics system or computer aided design
system, and divides the curved surface into a predetermined
number of meshes; the first fundamental form computing device
for computing coefficients of the first fundamental form
defined by a tangent vector which forms a tangent plane of the

mesh; the second fundamental form computing device for
computing coefficients of the second fundamental form defined
by the tangent vector and a normal vector of the mesh; and the
memory device which stores the point sequence information, the
coefficients of the first fundamental form and the
coefficients of the second fundamental form, then by adopting
a curved surface theory which ensures the continuity of a
free-form line/free-form surface, a computer graphics model or
a computer aided design model can be widely utilized, and the
efficiency of design and production processes can be improved.
Moreover, since it further comprises: the principal
curvature computing device which computes a principal
curvature of the mesh based on the coefficients of the first
fundamental form and the coefficients of the second
fundamental form; the line of curvature computing device which
computes a line of curvature showing a principal direction of
the mesh based on the principal curvature; the feature
point/feature line analyzing device which extracts a point or
a line which become a reference point or a reference line of
transformation defined by changing patterns of one or more
feature quantities among five feature quantities showing
features of the curved surface comprising a Gaussian curvature
and a mean curvature computed based on the principal
curvature, the principal direction, the line of curvature, and
the coefficients of the first fundamental form and the
coefficients of the second fundamental form; and the girth length computing device which computes a girth length based on

a curvature computed from the coefficients of the first
fundamental form and the coefficients of the second
fundamental form, then a computer graphics or computer aided
design model analyzed by the curved surface theory can be
reproduced and converted into another computer graphics or
computer aided design model.
Furthermore, since it further comprises: the reproducing
device which transforms the line of curvature for the girth
length in the line of curvature direction, with the feature
point or the feature line as the transformation reference, and
reproduces the mesh or the curved surface, then a computer
graphics or computer aided design model analyzed by the curved
surface theory can be reproduced.
Moreover, since it further comprises: the converting
device which extracts a plurality of point sequences on a
curved surface from the reproduced mesh or curved surface, and
converts the point sequences according to a graphic expression
algorithm in another computer graphics or computer aided
design system, then a computer graphics or computer aided
design model analyzed by the curved surface theory can be
converted into another computer graphics or computer aided
design model.
ACCOMPANYING
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a block diagram showing a configuration of a
computer aided design system of the present embodiment.
FIG. 2 is an explanatory diagram showing a situation for

dividing a curved surface into an m x n mesh and defining
fundamental vectors Su and Sv.
FIG. 3 is an explanatory diagram shewing planes in which
a unit tangent vector t and an unit normal vector n extend.
FIG. 4 is a flowchart showing a processing flow from
free-form surface analysis to data transfer, by an analysis
program 1.
FIG. 5 is an explanatory diagram showing an aspect of
curvature change.
FIG. 6 is an explanatory diagram shewing classifications
of mean curvature and Gaussian curvature.
FIG. 7 is an explanatory diagram showing isoclinic
orthogonal lines.
FIG. 8 is an explanatory diagram showing principal
curvature extremum lines.
FIG. 9 is an explanatory diagram showing isoclinic
extremum lines and aspects of Gaussian curvature distribution.
FIG. 10 is an explanatory diagram showing lines of
curvature.
BEST MODE FOR CARRYING OUT THE INVENTION
Hereunder is a description of an embodiment of a computer
aided design system of the present invention, with reference
to the drawings. FIG. 1 is a block diagram showing a
configuration of the computer aided design system of the
present embodiment. The computer aided design system of the
present embodiment comprises; a central processor such as

central processing unit (CPU) or the like (not shown), a
storage memory such as a ROM, RAM, or the like mot shown), a
database 10, a graphic display processing section 11, a
display section 12, an output section 13, and a communication
section (not shown).
The CPU reads out an analysis program 1, a converting
program 2, and a reproducing program 3 stored in a ROM and
executes a series of processes related to free-form surface
analysis, conversion, and reproduction. The RAM is a
semiconductor memory in which the CPU primarily stores data.
The analysis program 1 is a program which executes in the
CPU, a process for reading in actual measurement value data 20
of a three-dimensional shaped body by CAT (computer aided
testing) or the like, or other computer aided design format
data 21 (graphics data represented for example by a surface
model such as a solid model, a bezier, a b-spline, a rational
bezier, or a NURBS), creating a point sequence information
table 30, a table 31 of coefficients of the first fundamental
form, and a table 32 of coefficients of the second fundamental
form, and then storing this in the database 10.
The point sequence information table 30 comprises point
sequence information (u, v) for on a curved surface expressed
in a parameter form of;
S(U, v)= {X (U, V), y(U, V), Z(u, V)} 0≤ U, V≤1 .... (equation 1)
as shown in FIG. 2. For example, assuming that u = 0, 1/m,
2/m, to m-1/m (m is a natural number) and v = 0, 1/n, 2/n, to

n-1/n (n is a natural number), the curved surface shown in
FIG. 2 is divided into an m x n mesh. In this case, the point
sequence information (u, v) becomes an mn data sequences from
the mesh ID1 to IDmn.
The table 31 of coefficients of the first fundamental
form comprises coefficients of the first fundamental form E,
F, and G derived from the following equations. In the case
where u and v described above have a functional relation, then
s (u, v) denotes a curved line on the curved surface, the
partial derivative δs/δu = Su denotes a tangent vector of a
curved line of u = constant, and the partial derivative δs/δv
= Sv denotes a tangent vector of a curved line of v =
constant. At this time, the fundamental vectors Su and Sv
form a tangent plane of the curved surface. Moreover, a
vector ds linking two points on the curved surface, from s (u,
v) to s (u+du, v+dv), is represented by:
ds = Sudu + svdv .... (equation 2)
Here, the square of the absolute value of ds is
represented by:
(ds)2 = ds • ds = Su2 (du)2+ 2su • Svdudv + sv2 (dv)2... (equation 3)
The coefficients of the first fundamental form described
above are defined from the fundamental vector of the curved
surface by the following equation:
E = Su2, F = Su • Sv. G = Sv2... (equation 4)
The coefficients of the first fundamental form E, F, and
G described above are uniquely determined for the respective


meshes in this way. The table 31 of coefficients of the first
fundamental form stores the values for the respective meshes
ID1 to IDmn.
Moreover, combining the abovementioned equation 3 and
equation 4 gives:

The table 32 of coefficients of the second fundamental
form comprises coefficients of the second fundamental form L,
M, and N derived from the following equations. Assuming that
ω is an angle between the fundamental vectors Su and Su, then
their inner product F, and the absolute value H of the vector
product of the fundamental vectors, are represented as follows
using the coefficients of the first fundamental form:

Then using this calculated value H, the unit normal
vector n on the curved surface is represented by:

Moreover, as shown in FIG. 3, the pencil of lines of the
tangent vectors at a point P on the curved surface exists in
this tangent plane, and a unit tangent vector t of these is
represented by the following equation:

The plane determined by t and n as shown in FIG. 3 is

called a normal plane.
The curvature k at the point P on this normal section
plane is called a normal curvature. Differentiating t for the
arc length s on the normal section plane gives:

Multiplying both equations by the normal vector, and
introducing the following coefficients of the second
fundamental form:

The coefficients of the second fundamental form L, M, and
N described above are uniquely determined for the respective
meshes in this way. The table 32 of coefficients of the
second fundamental form stores the values for the respective
meshes ID1 to IDmn.
If equation 5 is substituted in equation 12, the
following equation is obtained.

From the above, the normal curvature is computed from the
coefficients of the first fundamental form and the
coefficients of the second fundamental form.

The converting program 2 is a program which executes on a
computer a process for; reading out the necessary information
for a free-form surface from the point sequence information
table 30, the table 31 of coefficients of the first
fundamental form, and the table 32 of coefficients of the
second fundamental form, then creating free-form surface data,
and transforming this into a form which an other computer
aided design application can interpret.
The reproducing program 3, similarly to the converting
program 2, is a program which executes on a computer a process
for; reading out the necessary information for a free-form
surface from the point sequence information table 30, the
table 31 of coefficients of the first fundamental form, and
the table 32 of coefficients of the second fundamental form,
then creating free-form surface data, and outputting to the
graphic display processing section 11.
The database 10 stores the above described point sequence
information table 30, the table 31 of coefficients of the
first fundamental form, and the table 32 of coefficients of
the second fundamental form, and writes in the output result
of the analysis program 1 in association with a mesh ID
described later.
The graphic display processing section 11 performs
graphic display processing on the output results from the
reproducing program, and other computer aided design
applications.
The display section 12 displays the output results of the

graphic display processing section 11.
The output section 13 outputs the output results of the
graphic display processing section 11 to the communication
section, other recording media, or the like. The
communication section transfers data such as the point
sequence information, the coefficients of the first
fundamental form, and the coefficients of the second
fundamental form stored in the database 1 to other severs or
clients via a network such as a LAN, the Internet, or the
like.
Next is a description of a series of processing flows
related to the free-form surface analysis, conversion, and
reproduction by the computer aided design system of the
present embodiment, with reference to the drawings. FIG. 4 is
a flowchart showing a processing flow from free-form surface
analysis to data transfer, by the analysis program 1.
By the user's operation, the CPU receives an analyze
command for the actual measurement value data 20 or other
computer aided design format data 21, reads out the analysis
program 1 from ROM, and executes the free-form surface
analyzing process. Firstly, the CPU performs a process for
extracting a plurality of point sequences on a curved surface
such as a two-dimensional NURBS surface, bicubic surface, or
the like, held by the actual measurement value data 20 or the
other computer aided design format data 21. Then, a curved
surface is generated from this point sequence using the other
computer aided design system (step S1 in FIG. 4), and the

curved surface is divided into a predetermined mn mesh number
as shown in FIG. 2, after which the respective mesh parts are
standardized by fundamental vectors Su and Sv. The point
sequence information (u, v) generated during the
standardization is written in the point sequence information
table 30 held by the database 10, in association with the mesh
ID.
Next, the CPU executes differential geometric analysis
processing. That is, it performs processing for computing the
coefficients of the first fundamental form E, F, and G defined
by the fundamental vectors Su and Sv which form the tangent
plane of the mesh. The computed coefficients of the first
fundamental form E, F and G, similarly to the point sequence
information, are written in the table 31 of coefficients of
the first fundamental form held by the database 10, in
association with the mesh ID. Moreover, the CPU performs a
process for computing the coefficients of the second
fundamental form L, M, and N defined by the fundamental
vectors Su and Sv and an unit normal vector n of the mesh.
The computed coefficients of the second fundamental form L, M,
and N, similarly to the coefficients of the first fundamental
form E, F and G, are written in the table 32 of coefficients
of the second fundamental form held by the database 10, in
association with the mesh ID.
Moreover, the CPU performs processing for computing an
integrable condition which is a condition where the
differential equation representing the above described mesh is

continuous at the respective boundaries of the mesh, in other
words, a condition where this differential equation has a
unique solution.
Now, the curved surface coordinates (u, v) described
above are substituted by (u1, u2) and the point is made p (u1,
u2). If a curved line formed by fixing u2 and moving ul is
called a ul curved line, and a curved line formed by fixing ul
and moving u2 is called a u2 curved line, then assuming that p
(u1, u2) on the curved surface is the initial point, then the
tangent vector along the ul curved line and the u2 curved line
can be calculated as follows:

Then, the unit normal vector n can be calculated from el
and e2 as follows:

In this way, three vectors {el, e2, n} are defined for
the respective points on the curved surface.
For the respective points, first fundamental quantities
E, F and G are defined as follows:

Then, a first fundamental tensor (gij, i, j = 1, 2) is
defined as follows:

Moreover, four numerical sets gij, i, j = 1, 2 are defined

as follows.

Furthermore, for the respective points, second
fundamental quantities L, M and N are defined as follows:

Then, a second fundamental tensor (hij, i, j = 1, 2) is
defined as follows:

Now, if the dynamic frame {e1, e2, n} is differentiated
by the curved surface coordinates (u1, u2), structural
equations of a curved surface shown by the following two
equations (Gaussian equation of equation 21 and Weingarten's
equation of equation 22) are obtained:

where equation 23 exhibits the Christoffel symbol.
The integrable condition of these structural equations 21
and 22 is shown by the following two equations (the Gaussian
equation of equation 24 and the Mainardi-Codazzi's equation of
equation 25):



where equation 26 exhibits the Riemann-Christoffel curvature
tensor.
In the case where the first fundamental tensor (gij, i, j
= 1, 2) and the second fundamental tensor (hij, i, j = 1, 2)
are applied as the function of the curved surface coordinate
(u1, u2) and they satisfy the Gaussian equation and the
Mainardi-Codazzi's equation described above, the shape of the
curved surface having such g±j and h^ is uniquely determined
(refer to Bonnet's fundamental theory). Therefore, the
respective meshes become C2 continuous.
The CPU performs these arithmetic processes and
calculates the integrable condition described above (step S2).
Next, the CPU executes a line of curvature analyzing
process, a feature line analyzing process, and a
curvature/girth length converting process (step S3). Firstly,
the principal curvatures k1 and K2 in the mesh are calculated
based on the coefficients of the first fundamental form E, F
and G, and the coefficients of the second fundamental form L,
M and N by the line of curvature analyzing process (step S4).
That is to say, firstly the extremum of the curvature K1
described above is calculated. The shape of the normal
section plane, which is the line of intersection of the normal

plane and the curved surface, changes together with the
tangential direction, and accompanied by this, the normal
curvature also changes. This shape returns to the initial
condition when the normal plane is half rotated. Now,
assuming that;

and rewriting K as the function k (y) of y, gives:

From this quadratic equation of
becomes the extremum. Then, if equation 15 is differentiated
in this condition for the extremum, and K and γ are rewritten

is obtained. Then, if it is substituted in equation 16,

is obtained. The following relations are obtained from these
equations:

If equation 18 is modified,


is obtained. The coefficient of K is positive from equation
7. Assuming that the roots are k1 and K2, the value becomes
the principal curvature as shown in FIG. 5.
Next, the Gaussian curvature or the mean curvature are
calculated based on the principal curvature (step S5). That
is, from the relation of the roots and the coefficients of the
quadratic equation,

is expressed. Here, Km is the mean curvature and K0 is the
Gaussian curvature. When Kq = 0, this is the case where the
curved surface becomes the developable surface as shown in
FIG. 6, and the line of curvature on the curved surface
becomes a straight line. In the present embodiment, the point
where this Gaussian curvature becomes zero is assumed to be
the reference point of transformation described later.
As an appropriate point for the reference point of
transformation other than this point, for example, lines of
curvature, borderlines (ridgelines), isoclinic orthogonal
lines shown in FIG. 7, principal curvature extremum lines
shown in FIG. 8, isoclinic extremum lines shown in FIG. 9, or
umbilicus points may be selected. These are points or lines
which become a reference point or a reference line of
transformation defined by changing patterns of one or more

feature quantities among the principal curvature, the
principal direction, the Gaussian curvature, the mean
curvature and the line of curvature, which are feature
quantities showing the feature of the curved surface. It is
possible to calculate these based on the coefficients of the
first fundamental form and the coefficients of the second
fundamental form.
Moreover, the line of curvature showing the principal
direction of the mesh is calculated based on the principal
curvature. That is, eliminating from equation 19 gives:

Both these two equations are equations of the line of
curvature and the quadratic equation so that Y1 and Y2 have the
following relations:

At a point on the curved surface, the curvature becomes
the extremum in the direction determined by Y1 and Y2. The
tangent vector on the curved surface is (Sudu + Svdv) and the
inner product of the two tangent vectors corresponding to Y1
and Y2 becomes:

If inside the bracket {} is converted then:


becomes zero. That is, it is found that the two tangential
directions of the normal section plane of the principal
curvature become orthogonal. This direction is called the
principal direction. In the case where this direction and the
tangent line on the curved surface are matched, this becomes
the lines of curvature shown in FIG. 10.
From the above, the calculation process of the line of
curvature showing the principal direction of the mesh is
performed.
Next, the curvature/girth length converting process is
performed (step S6). That is, the CPU calculates the girth
length based on the curvature which is calculated based on the
coefficients of the first fundamental form E, F, and G and the
coefficients of the second fundamental form L, M, and N.
Along the line of curvature calculated by the line of
curvature calculating process described above, the radius of
curvature is calculated from the curvature (1/r), and the
girth length of the line of curvature is expanded and
contracted in each calculation interval.
From the above, the analyzing process is performed.
Next, after the point sequence information, the
coefficients of the first fundamental form, and the
coefficients of the second fundamental form, which were
generated and extracted at step S1 and step S2, have been
collected (Yes in step S7), the CPU performs the curved
surface data transferring process (step S9). On the other
hand, in the case where such information has not been

completed, the database evaluating process is performed (No in
step S7). That is, the shape reproduced based on the
principal direction, the reference position (point, line, or
the like), the transformed amount, that were calculated at
steps S4 to S6, and the shape reproduced based on the point
sequence information, the coefficients of the first
fundamental form, and the coefficients of the second
fundamental form are compared, and in the case where they
match (Yes in step S8), the curved surface data transferring
process is performed (step S9). Moreover, in the case where
they do not match (No in step S8), an accuracy improving
process by approximation and interpolation is performed. That
is, the initial curved surface is approximated and
interpolated so that it becomes doubly differentiable, and the
processes described above are repeatedly performed again from
step SI. Then, at the stage where the comparative evaluation
in step S8 is matched, the flow shifts to the curved surface
data transferring process.
The curved surface data is transferred to the converting
program 2 or the reproducing program 3 shown in FIG. 1. If
the CPU receives a convert command, it executes the converting
program 2. That is, firstly assuming that a point selected as
a feature point or a feature line, where the Gaussian
curvature becomes zero, is the transformation reference, the
line of curvature is expansion and contraction transformed by
the girth length in the line of curvature direction so that
the mesh or the curved surface is reproduced. Then, a

plurality of point sequences on the curved surface are
extracted from the reproduced mesh or curved surface, and the
point sequences are converted according to a graphical
representation algorithm in an other computer aided design
system. The converted graphics data is reproduced by the
other computer aided design application 22 and then output to
the graphic display processing section 11. The graphic
display processing section 11 performs graphic display
processing of the data output from the computer aided design
application 22 and outputs this to the display section 12.
The display section 12 receives the input of the display data
and displays this.
Moreover, if the CPU receives a reproduction command, it
executes the reproducing program 3. The reproducing program
makes the CPU to execute the processes in the converting
program except for the converting process. That is, assuming
that a point where the Gaussian curvature becomes zero, is the
transformation reference, the line of curvature is expansion
and contraction transformed by the girth length in the line of
curvature direction so that the mesh or the curved surface is
reproduced. Then, the reproduced graphics data is output to
the graphic display processing section 11, and after display
processing, it is displayed in the display section 12.
As described above, according to the computer aided
design system of the present embodiment, an effect can be
obtained where a free-form surface can be analyzed, converted
and reproduced while retaining the continuity of the C2

continuous. Therefore, an effect can be obtained where the
utility value of a computer aided design model can be greatly
increased, and the efficiency of the design and production
processes can be improved.
In the computer aided design system of the present
embodiment, the description is for a series of processes
related to free-form surface analysis, conversion, and
reproduction in a computer aided design model. However, the
computer aided design system of the present invention is not
limited to this, and is applicable to a computer graphics
system, or a system and a program which performs graphical
representation using a computer.
Moreover, in the computer aided design system of the
present embodiment, as shown in FIG. 2, as a suitable example,
a curved surface is divided into meshes, and then standardized
by the fundamental vectors Su and Sv, so that the free-form
surface analysis, conversion, and reproduction are performed
by a u, v parameter form which uses point sequence information
(u, v). However, the computer aided design system of the
present invention is not limited to this, and coordinate
values for (x, y, z) coordinate parameters may be used.
The computer aided design system described above contains
a computer system inside. Moreover steps of a series of
processes related to the aforementioned free-form surface
analysis, conversion, and reproduction are stored in a
computer readable recording media in program format. A
computer reads out and executes this program, to thereby

perform the above processes. Here, the computer readable
recording media is for example a magnetic disk, magneto-
optical disk, CD-ROM, DVD-ROM, semiconductor memory or the
like. Moreover, the arrangement may be such that this
computer program is delivered to a computer by a communication
line, and the computer which receives this delivery, executes
the program.

WE CLAIM :
1. A computer aided design system, comprising :
a point sequence information extraction device which extracts a plurality of point sequences on
a curved surface;
a dividing device which generates a curved surface from said point sequences using another
computer aided design system and divides said curved surface into a predetermined number of meshes :
a first fundamental form computing device for computing coefficients of the first fundamental
form defined by a tangent vector which forms a tangent plane of said mesh;
a second fundamental form computing device for computing coefficients of the second
fundamental form defined by said tangent vector and a normal vector of said mesh;
a principal curvature computing device which computes a principal curvature of said mesh
based on said coefficients of the first fundamental form and coefficients of the second fundamental
form :
a line of curvature computing device which computes a line of curvature showing a principal
direction of said mesh based on said principal curvature;
a feature point / feature line analyzing device which extracts a point or a line which become a
reference point or a reference line of transformation defined by changing patterns of one or more
feature quantities among five feature quantities showing features of said curved surface comprising a
Gaussian curvature and a mean curvature computed based on said principal curvature, said principal
direction, said line of curvature, and said coefficients of the first fundamental form and coefficients of
the second fundamental form;
a girth length computing device which computes a girth length based on a curvature computed
from said co-efficients of the first fundamental form and coefficients of the second fundamental form :
and
a reproducing device which transforms said line of curvature for said girth length in said line of
curvature direction, with said feature point or feature line as a transformation reference, and reproduces
said mesh or said curved surface.
2. A computer aided design system as claimed in claim 1, having :
a converting device which extracts a plurality of point sequences on a curved surface from said

reproduced mesh or curved surface, and converts said point sequences according to a graphical
representation algorithm in another computer aided design system.
3. A computer aided design method for executing on a computer, comprising :
a point sequence information extraction process for extracting a plurality of point sequences on
a curved surface;
a dividing process for generating a curved surface from said point sequences using another
computer aided design system, and dividing said curved surface into a predetermined number of
meshes;
a first fundamental form computing process for computing coefficients of the first fundamental
form defined by a tangent vector which forms a tangent plane of said mesh;
a second fundamental form computing process for computing coefficients of the second
fundamental form defined by said tangent vector and a normal vector of said mesh :
a principal curvature computing process for computing a principal curvature of said mesh based
on said coefficients of the first fundamental form and coefficients of the second fundamental form;
a line of curvature computing process for computing a line of curvature showing a principal
direction of said mesh based on said principal curvature.
a feature point / feature line analyzing process for extracting a point or a line which become a
reference point or a reference line of transformation defined by changing patterns of one or more
feature quantities among five feature quantities showing features of said curved surface comprising a
Gaussian curvature and a mean curvature computed based on said principal curvature, said principal
direction, said line of curvature, and said coefficients of the first fundamental form and coefficients of
the second fundamental form;
a girth length computing process for computing a girth length based on a curvature computed
from said coefficients of the first fundamental form and coefficients of the second fundamental form;
and
a reproducing process for transforming said line of curvature for said girth length in said line of
curvature direction, with said feature point or feature line as a transformation reference, and
reproducing said mesh or said curved surface.

4. A computer aided design method as claimed in claim 3 for executing on a computer, which
involves :
a converting process for extracting a plurality of point sequences on a curved surface from said
reproduced mesh or curved surface, and converting said point sequences according to a graphical
representation algorithm in another computer aided design system.
5. A computer graphics system, comprising :
a point sequence information extraction device which extracts a plurality of point sequences on
a curved surface;
a dividing device which generates a curved surface from said point sequences using another
computer graphics system, and divides said curved surface into a predetermined number of meshes;
a first fundamental form computing device for computing coefficients of the first fundamental
form defined by a tangent vector which forms a tangent plane of said mesh;
a second fundamental form computing device for computing coefficients of the second
fundamental form defined by said tangent vector and a normal vector of said mesh; and
a principal curvature computing device which computes a principal curvature of said mesh
based on said coefficients of the first fundamental form and coefficients of the second fundamental
form;
a line of curvature computing device which computes a line of curvature showing a principal
direction of said mesh based on said principal curvature;
a feature point / feature line analyzing device which extracts a point or a line which become a
reference point or a reference line of transformation defined by changing patterns of one or more
feature quantities among five feature quantities showing features of said curved surface comprising a
Gaussian curvature and a mean curvature computed based on said principal curvature, said principal
direction, said line of curvature, and said coefficients of the first fundamental form and coefficients of
the second fundamental form;
a girth length computing device which computes a girth length based on a curvature computed
from said coefficients of the first fundamental form and coefficients of the second fundamental form;
and

a reproducing device which transforms said line of curvature for said girth length in said line of
curvature direction, with said feature point or feature line as a transformation reference, and reproduces
said mesh or said curved surface.
6. A computer graphics method for executing on a computer, comprising :
a point sequence information extraction process for extracting a plurality of point sequences on
a curved surface;
a dividing process for generating a curved surface from said point sequences using another
computer graphics system, and dividing said curved surface into a predetermined number of meshes;
a first fundamental form computing process for computing coefficients of the first fundamental
form defined by a tangent vector which forms a tangent plane of said mesh;
a second fundamental form computing process for computing coefficients of the second
fundamental form defined by said tangent vector and a normal vector of said mesh;
a principal curvature computing process for computing a principal curvature of said mesh based
on said coefficients of the first fundamental form and coefficients of the second fundamental form;
a line of curvature computing process for computing a line of curvature showing a principal
direction of said mesh based on said principal curvature;
a feature point / feature line analyzing process for extracting a point or a line which become a
reference point or a reference line of transformation defined by changing patterns of one or more
feature quantities among five feature quantities showing features of said curved surface comprising a
Gaussian curvature and a mean curvature computed based on said principal curvature, said principal
direction, said line of curvature, and said coefficients of the first fundamental form and coefficients of
the second fundamental form;
a girth length computing device for computing a girth length based on a curvature computed
from said coefficients of the first fundamental form and coefficients of the second fundamental form :
and
a reproducing process for transforming said line of curvature for said girth length in said line of
curvature direction, with said feature point or feature line as a transformation reference, and
reproducing said mesh or said curved surface.

7. A computer aided design system as claimed in claim I, having :
a memory device which stores said point sequence information, said coefficients of the first
fundamental form and said coefficients of the second fundamental form.
8. A computer aided design method as claimed in claim 3, for executing on a computer, involving:
a storage process for storing said point sequence information, said coefficients of the first
fundamental form and said coefficients of the second fundamental form.

There is disclosed a computer aided design system and a computer aided design
method capable of significantly increasing the utility value of a computer aided design
model and efficiency of the design / production process by employing the theory of
surfaces guaranteeing the continuity of a free curve / curved surface. The method
involves executing a point sequence extraction processing for extracting a plurality of
point sequences on a curved surface, a division processing for generating a curved
surface from a point sequence by using another computer aided design system and
dividing the curved surface into a predetermined number of meshes, a primary standard
amount calculation processing for calculating a primary standard amount defined by a
tangent vector forming a mesh tangent plane, a secondary standard amount calculation
processing for calculating a secondary standard amount defined by a tangent vector and
a mesh normal vector, and a storage processing for storing the point sequence
information, the first standard amount, and the second standard amount.

Documents:

514-KOLNP-2005-(05-09-2012)-FORM-27.pdf

514-KOLNP-2005-CORRESPONDENCE.pdf

514-KOLNP-2005-FORM 27.pdf

514-KOLNP-2005-FORM-27.pdf

514-kolnp-2005-granted-abstract.pdf

514-kolnp-2005-granted-assignment.pdf

514-kolnp-2005-granted-claims.pdf

514-kolnp-2005-granted-correspondence.pdf

514-kolnp-2005-granted-description (complete).pdf

514-kolnp-2005-granted-drawings.pdf

514-kolnp-2005-granted-examination report.pdf

514-kolnp-2005-granted-form 1.pdf

514-kolnp-2005-granted-form 13.pdf

514-kolnp-2005-granted-form 18.pdf

514-kolnp-2005-granted-form 3.pdf

514-kolnp-2005-granted-form 5.pdf

514-kolnp-2005-granted-gpa.pdf

514-kolnp-2005-granted-reply to examination report.pdf

514-kolnp-2005-granted-specification.pdf


Patent Number 227335
Indian Patent Application Number 514/KOLNP/2005
PG Journal Number 02/2009
Publication Date 09-Jan-2009
Grant Date 06-Jan-2009
Date of Filing 28-Mar-2005
Name of Patentee MITSUBISHI HEAVY INDUSTRIES, LTD.
Applicant Address 16-5, KONAN 2-CHOME, MINATO-KU, TOKYO
Inventors:
# Inventor's Name Inventor's Address
1 MIURA MASAMI C/O NAGASAKI RESEARCH & DEVELOPMENT CENTER, MISUBISHI HEAVY INDUSTRIES LTD. 717-1, FUKAHORI-MACHI 5-CHOME, NAGASAKI, NAGASAKI-KEN 851-0392
2 KAWANO TAKAYUKI C/O CHORYO ENGNEERING CO., LTD. 717-1, FUKAHORI-MACHI 5-CHOME, NAGASAKI, NAGASAKI-KEN 851-0392
3 SASAKI YUICHI C/O NAGASAKI RESEARCH & DEVELOPMENT CENTER, MITSUBISHI HEAVY INDUSTRIES LTD. 717-1, FUKAHORI-MACHI 5-CHOME, NAGASAKI, NAGASAKI-KEN 851-0392
4 NAKAHAMA TAKESHI C/O PAL CORPORATION LTD. 8-20, ASAHI-MACHI, NAGASAKI, NAGASAKI-KEN 852-0054
5 YOSHIDA YASUHIKO C/O CITEC CORPOATION LTD. 28-1, NIHONGI-CHO FUTATSUIKE, ANJO, AICHI-KEN 446-0054
PCT International Classification Number G06F 17/50
PCT International Application Number PCT/JP2003/012748
PCT International Filing date 2003-10-06
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2002-292585 2002-10-04 Japan