ORTHOGONAL SIMPLIFICATION OF OBJECTS REPRESENTED

BY THE EXTREME VERTEX MODEL

Irving Cruz-Mat

ıas

and Dolors Ayala

1,2

Universitat Polit

ecnica de Catalunya, Barcelona, Spain

Institut de Bioenginyeria de Catalunya, Barcelona, Spain

Keywords:

Simpliﬁcation, LOD, Bounding Volumes, Orthogonal Polyhedra, Binary Volumes.

Abstract:

This work presents a new approach to simplify objects. It is restricted to orthogonal pseudo-polyhedra (OPP)

and binary volumes. The method produces a level-of-detail (LOD) sequence of OPP and it is incremental. Any

object in this sequence is a bounding OPP of the previous objects. The sequence ﬁnishes with the minimum

axis-aligned bounding box. OPP are represented by the Extreme Vertices Model. Simpliﬁcation is achieved

using a new approach called merging faces that relies on the application of 2D Boolean operations.

1 INTRODUCTION

The large size and complexity of models often af-

fects the computation speed-up of their characteris-

tics. Simpliﬁcation techniques can diminish this prob-

lem. Moreover, in some cases it is advantageous to

exchange an exact geometric representation of an ob-

ject for an approximated one, which can be processed

more efﬁciently. Bounding structures are a widely

used speciﬁc typology of model simpliﬁcation to ac-

celerate tasks as collision detection, distance compu-

tation or any basic set membership operation.

We present a new approach to simplify objects.

It is restricted to OPP and therefore it can be ap-

plied to binary volumes or 3D images represented

by OPP. From an initial OPP, the method computes

a LOD sequence of bounding volumes that are also

OPP. The sequence ends with a convex OPP that is

the axis-aligned minimum bounding box (AABB) of

all the sequence. We will denote as BOPP (bounding

OPP) such bounding structures. All the BOPP of se-

quence satisfy two important characteristics required

for bounding structures: (1) any object contains the

previous one and (2) all of them, as well as the

original object, have the same AABB. In this work,

OPP are represented by the Extreme Vertices Model

(EVM), a complete model that stores a subset of their

vertices (called extreme vertices) and performs fast

Boolean operations. The simpliﬁcation is achieved

using a new approach called merging faces that relies

on the application of 2D Boolean operations over the

OPP faces, which are orthogonal pseudo-polygons.

2 RELATED WORK

There has been an extensive research on methods

for model simpliﬁcation, recent works are based on

quadrilateral meshes (Tarini et al., 2010), as well as

methods for LOD sequences of triangular and tetra-

hedral meshes (Ripolles et al., 2009). In contrast to

these methods that rely on geometric operations, sim-

pliﬁcation can follow other strategies like morpholog-

ical operators as ﬁlleting and rounding (Williams and

Rossignac, 2007). Alternative representations can be

used as octrees (Vanderhyde and Szymczak, 2008) in

such a way that the geometry as well as the topology

can be simpliﬁed, or BSP (Huang and Wang, 2010)

obtaining a LOD sequence with a decreasing number

of nodes. Simpliﬁcation strategies have also been de-

veloped for B-Rep models (Sun et al., 2010), and for

point clouds (Pauly et al., 2002).

In some cases it is desirable to compute an ap-

proximation that is also a bounding volume. Bound-

ing volumes are used in many applications as collision

detection, ray tracing (Wald et al., 2007), graphics in-

teraction (Jim

enez et al., 2011) and volume of inter-

est computation (Fuchs et al., 2010). Works concern-

ing bounding volumes use the most classical ones, as

spheres (Gagvani and Silver, 2000) and AABB (Zach-

mann, 2002), or hybrid bounding volumes (Chang

et al., 2010).

The so-called vertex representation (Esperanc¸a

and Samet, 1998) is used to represent orthogonal

polyhedra that are used as bounding structures and

a 2D simpliﬁcation method based on this model has

193

Cruz-Matías I. and Ayala D..

ORTHOGONAL SIMPLIFICATION OF OBJECTS REPRESENTED BY THE EXTREME VERTEX MODEL.

DOI: 10.5220/0003861301930196

In Proceedings of the International Conference on Computer Graphics Theory and Applications (GRAPP-2012), pages 193-196

ISBN: 978-989-8565-02-0

 2012 SCITEPRESS (Science and Technology Publications, Lda.)

also been devised (Esperanc¸a and Samet, 1997). Our

method has the similarity with this one that orthog-

onal faces are displaced, but our strategy and opera-

tions are completely new. We merge the faces geome-

try by applying Boolean operations. Moreover our ap-

proach deals with general 3D orthogonal objects with

any number of shells, cavities and through holes.

3 EXTREME VERTICES MODEL

The EVM is a very concise representation scheme in

which any OPP can be described using only a subset

of its vertices: the extreme vertices (EV). The EVM

can be created easily from the voxel model. Let Q

be a ﬁnite set of points in E

. The ABC-sorted set

of Q is the set resulting from sorting Q according to

A, then to B, and then to C-coordinate. Let P be an

OPP: A brink is the maximal uninterrupted segment

built out of a sequence of collinear and contiguous

two-manifold edges of P and its ending vertices are

the EV. A cut (C) of P is the set of EV lying on a

plane perpendicular to a main axis of P. A slice is the

prismatic region between two consecutive cuts, and a

section (S) is its base polygon. Sections can be com-

puted from cuts and vice versa. For i = 1 . . . n :

(P) = S

(P) =

0, S

(P) = S

i−1

(P) ⊗

∗

(P) (1)

(P) = S

i−1

(P) ⊗

∗

(P) (2)

where n is the number of cuts and ⊗

∗

denotes the reg-

ularized xor operation. The overline symbolizes the

project operator, that from a d-dimensional set of ver-

tices lying on a plane produces a (d-1)-dimensional

set of vertices. As the ⊗

∗

operation can be expressed

as union of differences, Equation 2 can be written as:

(P) = (S

i−1

(P)−

∗

(P))∪ (S

(P)−

∗

i−1

(P)) (3)

and any cut can be decomposed into its forward dif-

ference (FD) and backward difference (BD):

(P) = S

i−1

(P) −

∗

(P) (4)

(P) = S

(P) −

∗

i−1

(P)

(P) is the set of C

(P) faces whose normal vec-

tor points to the positive side of the coordinate axis

perpendicular to C

(P) and BD

(P) the opposite. Fig-

ure 2(b) shows an object with all its EV, cuts (C

) and sections (in yellow). Arrows on cuts indicate

whether they are FD or BD.

There is a platform that uses the EVM for most

volume operations, as it is efﬁcient for Boolean op-

erations. All Boolean operations are carried out by

applying recursively the same operation over the 2D

OPP sections. The base case performs this operation

in 1D. The xor operation is the faster one, as it is a

simple point-wise xor without section computation.

For details concerning EVM see (Aguilera, 1998).

4 ALGORITHM OVERVIEW

Our method takes as input an EVM represented OPP.

Let B(P) be the BOPP of an OPP P, and o

be the

initial object. A ﬁnite sequence o

, o

, . . . , o

of OPP

is generated that follows the following properties:

1. Subset property: B(o

) = o

i+1

, i = 0. . . p −1, and,

therefore, o

⊆ o

i+1

, i = 0 . . . p − 1

2. o

= AABB(o

), i = 0 . . . p

It is an incremental approach, i.e., we compute o

i+1

from o

, i = 0 . . . p −1. The main idea follows a merg-

ing faces strategy. Cuts in an ABC-sorted EVM are

perpendicular to A-coordinate axis. If cut faces are

displaced towards the contiguous cut and both sets of

faces are merged, the total number of vertices (EV and

non-EV) will never increase. So, the simpliﬁcation al-

gorithm receives an EVM P, which corresponds to the

initial object o

and the desired maximum number of

EV n in the simpliﬁed model, and returns an EVM

Q corresponding to the BOPP o

, which has no more

than n EV. The method computes all the o

between 1

and k, where the merging faces strategy applies a dis-

placement of d = i voxels to compute o

. Therefore,

to compute o

the algorithm performs k iterations.

The merging faces process is applied to the current

ABC-sorting of P that only coarsens the OPP in the A-

coordinate, then it is necessary to repeat the process

for the other two main directions. So, we can take any

three sortings with different A-coordinate, as shown in

the following pseudocode:

EVM Simplification(EVM P, int n){

EVM Q = P;

for(int d=1; Q->Get_nev() >= n; d++){

Q->SetSorting(XYZ); Q=mergingFaces(Q,d);

Q->SetSorting(YXZ); Q=mergingFaces(Q,d);

Q->SetSorting(ZXY); Q=mergingFaces(Q,d);}

return Q; }

Get nev returns the number of EV of the correspond-

ing object. The mergingFaces function receives an

EVM object and a distance d, and returns another

EVM object, where consecutive cuts with distance

<= d between them have been processed. When

n = 8 the algorithm ﬁnishes with the AABB.

5 MERGING FACES APPROACH

Given the ABC-sorted EVM representation of an

OPP, pairs of consecutive cuts along the A-coordinate

GRAPP 2012 - International Conference on Computer Graphics Theory and Applications

194

axis are extracted and processed with a sequential

scan. Let C

and C

be two consecutive cuts and FD

, FD

and BD

their corresponding forward and

backward differences. A coarser OPP is achieved by

displacing BD

to the position of BD

, and, similarly,

displacing FD

to the position of FD

. Since the

displacement is done in the direction of the respec-

tive normal vectors, and it is restricted by the cuts of

the initial object, the model will never extend beyond

these cuts. Thus, this process satisﬁes the subset prop-

erty. So, the merging process performs the union of

those faces with normal vector in the same direction

that belong to two consecutive cuts, i.e.:

newC

= BD

∪

∗

, newC

= FD

∪

∗

(5)

where newC

and newC

are the pair of cuts that re-

place C

and C

respectively. Now, for objects with

cavities, Equation 5 is not enough. For example, ap-

plying this equation to the object in Figure 1, the same

OPP without any coarsening is obtained. In order to

deal with this case, the void space must be detected

with the expression:

vSpace(C

) = FD

∩

∗

(6)

as BD

and BD

are sets of faces whose normal vector

points to the opposite direction of FD

and FD

, but

only FD

and BD

contribute to form a void space

between the cuts. If a void space is detected, it must

be removed from newC

and newC

in order to close

it. Then, combining Equation 5 with Equation 6:

newC

= (BD

∪

∗

) −

∗

(FD

∩

∗

) (7)

newC

= (FD

∪

∗

) −

∗

(FD

∩

∗

)

Figure 1: 2D example with a single hole. Left: faces to be

displaced in order to close the hole. Right: resulting BOPP.

Figure 2 shows a 3D example where applying

Equation 8, newC

0 and newC

gets a new value

(see Figure 2(c)), which partially closes the hole. The

result of this process is an object with a concavity (see

Figure 2(d)), which will be closed in the next sweep.

As this last operation contributes just to close void

spaces, it guaranties the subset property. Now, there

are two EVM properties that make possible to per-

form unions and differences as simple point-wise xor

operations (Aguilera, 1998).

• P1: Let P and Q be two OPP such that P ∩ Q =

0, having evm(P) and evm(Q) as their respective

models, then evm(P ∪ Q) = evm(P) ⊗ evm(Q).

• P2: Let P and Q be two OPP such that P ⊇ Q,

with evm(P) and evm(Q) as their respective mod-

els, then evm(P − Q) = evm(P) ⊗ evm(Q).

According to these properties and as FD

∩

∗

0, BD

∩

∗

0, vSpace ⊆ newC

and vSpace ⊆

newC

, Equation 7 can be rewritten in order to be

faster to compute as:

newC

= BD

⊗

∗

⊗

∗

(FD

∩ BD

) (8)

newC

= FD

⊗

∗

⊗

∗

(FD

∩ BD

)

In Figure 1, FD

= BD

, vSpace(C

) = FD

. Then, applying Equation 8, newC

= BD

newC

0 and the hole is closed.

Observe the Figure 2(b), where if C

= C

and

= C

, newC

and newC

will be exactly the same

as C

and C

respectively. This happens when FD

0, which is the condition to establish that there

are no faces to be displaced to get a coarser model.

In these cases, C

is omitted and copied to the re-

sulting model. On the other hand, the merging faces

function process only those pairs of cuts with distance

<= d. Formally, given the pair (C

= C

i+1

if FD

= BD

0, or distance(C

) > d, then C

copied to the resulting BOPP, and the method contin-

ues with the pair (C

= C

i+1

= C

i+2

). In the other

case, the pair (C

) is processed with Equation 8.

The merging faces process takes cuts in pairs:

= C

i+1

), i = 1, i < n − 1, i = i + 2, i.e.

ﬁrst the pair (C

), then (C

), and so on.

(a)

(b)

newC

∅

newC

Figure 2: A 3D OPP with holes. (a) Original object. (b)

EVM encoding (EV, cuts and sections), where cuts C

and

are the sets of faces to be displaced in a ﬁrst step. (c)

Resulting cuts and (d) object after applying Equation 8.

ORTHOGONAL SIMPLIFICATION OF OBJECTS REPRESENTED BY THE EXTREME VERTEX MODEL

195

6 EXPERIMENTAL RESULTS

We have tested the merging faces method in several

cases. Table 1 shows a compilation of some models

with their corresponding size, the maximum d in or-

der to get the AABB and time to get it. Figure 3 de-

picts some results of simplifying two models, both de-

picted BOPP have less than 10% of EV of the original

model. The algorithm was executed on a PC Intel(R)

Pentium(R) CPU 3.20GHz with 3.2Gb of RAM.

Table 1: Information of some models used in the experi-

ments. Size in voxels; d: max value to get AABB

Model Size d Time (sec)

Binzilla 83x35x58 35 0.41

Camel 39x125x127 34 1.20

Venus 148x148x512 33 16.24

Athene 350x195x512 64 17.69

Figure 3: Some results. From left to right: Original

(12,602 EV) and BOOP (1,148 EV) of Camel model, origi-

nal (179,400 EV) and BOPP (15,100 EV) of Athene model.

7 CONCLUSIONS

We have described an approach for orthogonal sim-

pliﬁcation of models represented by the EVM, which

is based on the application of efﬁcient Boolean opera-

tions. Our approach deals with OPP with any number

of holes and connected components, and computes a

LOD sequence of BOPP. This sequence satisﬁes com-

mon properties of bounding structures. Directions for

future work include the design of alternatives where

individual faces of FD and BD are taken into account.

We also plan to study a lossless simpliﬁcation ap-

proach based on the presented one.

ACKNOWLEDGEMENTS

This work was partially supported by the national

project TIN2008-02903 of the Spanish government. I.

Cruz-Mat

ıas acknowledges the MAEC-AECID grant

from the Spanish government.

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