7 research outputs found
Digital relief generation from 3D models
It is difficult to extend image-based relief generation to high-relief generation, as the images contain insufficient height information. To generate reliefs from three-dimensional (3D) models, it is necessary to extract the height fields from the model, but this can only generate bas-reliefs. To overcome this problem, an efficient method is proposed to generate bas-reliefs and high-reliefs directly from 3D meshes. To produce relief features that are visually appropriate, the 3D meshes are first scaled. 3D unsharp masking is used to enhance the visual features in the 3D mesh, and average smoothing and Laplacian smoothing are implemented to achieve better smoothing results. A nonlinear variable scaling scheme is then employed to generate the final bas-reliefs and high-reliefs. Using the proposed method, relief models can be generated from arbitrary viewing positions with different gestures and combinations of multiple 3D models. The generated relief models can be printed by 3D printers. The proposed method provides a means of generating both high-reliefs and bas-reliefs in an efficient and effective way under the appropriate scaling factors
Computer Assisted Relief Generation - a Survey
In this paper we present an overview of the achievements accomplished to date in the field of computer aided relief
generation. We delineate the problem, classify the different solutions, analyze similarities, investigate the evelopment and review the approaches according to their particular relative strengths and weaknesses. In consequence this survey is likewise addressed to researchers and artists through providing valuable insights into the theory behind the different concepts in this field and augmenting the options available among the methods presented with regard to practical application
Bas-relief modelling from enriched detail and geometry with deep normal transfer
Detail-and-geometry richness is essential to bas-relief modelling. However, existing image-based and model-based bas-relief modelling techniques commonly suffer from detail monotony or geometry loss. In this paper, we introduce a new bas-relief modelling framework for detail abundance with visual attention based mask generation and geometry preservation, which benefits from our two key contributions. For detail richness, we propose a novel semantic neural network of normal transfer to enrich the texture styles on bas-reliefs. For geometry preservation, we introduce a normal decomposition scheme based on Domain Transfer Recursive Filter (DTRF). Experimental results demonstrate that our approach is advantageous on producing bas-relief modellings with both fine details and geometry preservation
Of assembling small sculptures and disassembling large geometry
This thesis describes the research results and contributions that have been achieved
during the authorâs doctoral work. It is divided into two independent parts, each
of which is devoted to a particular research aspect.
The first part covers the true-to-detail creation of digital pieces of art, so-called
relief sculptures, from given 3D models. The main goal is to limit the depth of the
contained objects with respect to a certain perspective without compromising the
initial three-dimensional impression. Here, the preservation of significant features
and especially their sharpness is crucial. Therefore, it is necessary to overemphasize
fine surface details to ensure their perceptibility in the more complanate relief.
Our developments are aimed at amending the flexibility and user-friendliness
during the generation process. The main focus is on providing real-time solutions
with intuitive usability that make it possible to create precise, lifelike and
aesthetic results. These goals are reached by a GPU implementation, the use of
efficient filtering techniques, and the replacement of user defined parameters by
adaptive values. Our methods are capable of processing dynamic scenes and allow
the generation of seamless artistic reliefs which can be composed of multiple
elements.
The second part addresses the analysis of repetitive structures, so-called symmetries,
within very large data sets. The automatic recognition of components
and their patterns is a complex correspondence problem which has numerous applications
ranging from information visualization over compression to automatic
scene understanding. Recent algorithms reach their limits with a growing amount
of data, since their runtimes rise quadratically. Our aim is to make even massive
data sets manageable. Therefore, it is necessary to abstract features and to develop
a suitable, low-dimensional descriptor which ensures an efficient, robust, and purposive
search. A simple inspection of the proximity within the descriptor space
helps to significantly reduce the number of necessary pairwise comparisons. Our
method scales quasi-linearly and allows a rapid analysis of data sets which could
not be handled by prior approaches because of their size.Die vorgelegte Arbeit beschreibt die wissenschaftlichen Ergebnisse und BeitrÀge,
die wÀhrend der vergangenen Promotionsphase entstanden sind. Sie gliedert sich
in zwei voneinander unabhÀngige Teile, von denen jeder einem eigenen Forschungsschwerpunkt gewidmet ist.
Der erste Teil beschÀftigt sich mit der detailgetreuen Erzeugung digitaler
Kunstwerke, sogenannter Reliefplastiken, aus gegebenen 3D-Modellen. Das Ziel
ist es, die Objekte, abhÀngig von der Perspektive, stark in ihrer Tiefe zu limitieren,
ohne dass der Eindruck der rÀumlichen Ausdehnung verloren geht. Hierbei
kommt dem Aufrechterhalten der SchÀrfe signifikanter Merkmale besondere
Bedeutung zu. DafĂŒr ist es notwendig, die feinen Details der ObjektoberflĂ€che
ĂŒberzubetonen, um ihre Sichtbarkeit im flacheren Relief zu gewĂ€hrleisten. Unsere
Weiterentwicklungen zielen auf die Verbesserung der FlexibilitÀt und Benutzerfreundlichkeit
wÀhrend des Enstehungsprozesses ab. Der Fokus liegt dabei
auf dem Bereitstellen intuitiv bedienbarer Echtzeitlösungen, die die Erzeugung
prÀziser, naturgetreuer und visuell ansprechender Resultate ermöglichen. Diese
Ziele werden durch eine GPU-Implementierung, den Einsatz effizienter Filtertechniken
sowie das Ersetzen benutzergesteuerter Parameter durch adaptive Werte
erreicht. Unsere Methoden erlauben das Verarbeiten dynamischer Szenen und die
Erstellung nahtloser, kunstvoller Reliefs, die aus mehreren Elementen und Perspektiven
zusammengesetzt sein können.
Der zweite Teil behandelt die Analyse wiederkehrender Stukturen, sogenannter
Symmetrien, innerhalb sehr groĂer DatensĂ€tze. Das automatische Erkennen
von Komponenten und deren Muster ist ein komplexes Korrespondenzproblem
mit zahlreichen Anwendungen, von der Informationsvisualisierung ĂŒber Kompression
bis hin zum automatischen Verstehen. Mit zunehmender Datenmenge
geraten die etablierten Algorithmen an ihre Grenzen, da ihre Laufzeiten quadratisch
ansteigen. Unser Ziel ist es, auch massive DatensÀtze handhabbar zu machen.
Dazu ist es notwendig, Merkmale zu abstrahieren und einen passenden
niedrigdimensionalen Deskriptor zu entwickeln, der eine effiziente, robuste und
zielfĂŒhrende Suche erlaubt. Eine simple Betrachtung der Nachbarschaft innerhalb
der Deskriptoren hilft dabei, die Anzahl notwendiger paarweiser Vergleiche signifikant
zu reduzieren. Unser Verfahren skaliert quasi-linear und ermöglicht somit
eine rasche Auswertung auch auf Daten, die fĂŒr bisherige Methoden zu groĂ waren