source: GTP/trunk/Lib/Vis/Preprocessing/manual/Bib/minimum.bib @ 2066

% wanted

@TechReport{fussell88a,
        author =       "Donald Fussell and K. R. Subramanian",
        title =        "Fast Ray Tracing Using {K}-{D} Trees",
        institution =  "U. of Texas, Austin, Dept. Of Computer Science",
        type =         "Technical Report",
        number =       "TR-88-07",
        month =        mar,
        year =         "1988",
        keywords =     "hierarchies",
}

@INPROCEEDINGS{Heckbert92discon,
AUTHOR={Paul S. Heckbert},
TITLE={Discontinuity Meshing for Radiosity},
BOOKTITLE={Third Eurographics Workshop on Rendering},
MONTH={May},
YEAR={1992},
ADDRESS={Bristol, UK},
PAGES={203-216},
KEYWORDS={radiosity, adaptive mesh, visibility},
}

@InProceedings{kaplan85a,
        author =       "M. Kaplan",
        title =        "Space-Tracing: {A} Constant Time Ray-Tracer",
        pages =        "149--158",
        booktitle =    "SIGGRAPH '85 State of the Art in Image Synthesis seminar
 notes",
        year =         "1985",
        month =        jul,
        publisher =    "Addison Wesley",
        keywords =     "ray tracing cull",
}


% collected

@InProceedings{Greene93a,
  author =       "N. Greene and M. Kass and G. Miller",
  title =        "Hierarchical {Z}-Buffer Visibility",
  booktitle =    "Computer Graphics (Proceedings of SIGGRAPH '93)",
  year =         "1993",
  pages =        "231--238"
}

@InProceedings{thibault87a,
author =       "William C. Thibault and Bruce F. Naylor",
title =        "Set Operations on Polyhedra Using Binary Space
Partitioning Trees",
pages =        "153--162",
booktitle =      "Proceedings of SIGGRAPH '87",
volume =       "21",
year =         "1987",
month =        jul,
keywords =     "polyhedra, set operations, geometric modeling,
geometric search, point location",
}

@InProceedings{Coorg96b
, author =      "Coorg, Satyan and Teller, Seth"
, title =       "Temporally Coherent Conservative Visibility"
, booktitle =   "Proceedings of the Twelfth Annual ACM Symposium on Computational Geometry"
, year =        1996
, optaddress =  "Philadelphia, PA"
, month =       may
, documentURL = "http://graphics.lcs.mit.edu/~satyan/pubs/temporalvis-cg96.ps.Z"
, pages = "78--87"
}

@InProceedings{Coorg97,
  author =       "Satyan Coorg and Seth Teller",
  title =        "Real-Time Occlusion Culling for Models with Large
                 Occluders",
  pages =        "83--90",
  ISBN =         "0-89791-884-3",
  booktitle =    "Proceedings of the Symposium on Interactive 3{D}
                 Graphics",
  optmonth =        apr # "27--30~",
  publisher =    "ACM Press",
  optaddress =      "New York",
  year =         "1997",
}

@InProceedings{Rohlf:1994:IPH,
  author =       "John Rohlf and James Helman",
  booktitle =    "Proceedings of SIGGRAPH '94",
  title =        "{IRIS} Performer: {A} High Performance Multiprocessing
                 Toolkit for Real--{T}ime 3{D} Graphics",
  pages =        "381--395",
  month =        jul,
  year =         "1994",
}

@InProceedings{Airey90,
  author =       "Airey, John M. and Rohlf, John H. and {Brooks, Jr.}, Frederick P.",
  title =        "Towards Image Realism with Interactive Update Rates in
                 Complex Virtual Building Environments",
  pages =        "41--50",
  booktitle =    "1990 Symposium on Interactive 3D Graphics",
  organization = "ACM SIGGRAPH",
  year =         "1990",
  optmonth =        mar,
  keywords =     "model-space subdivision, potentially visible,
                 radiosity, adaptive refinement",
}

@inproceedings{Teller93a
, author =      "Teller, S. and Hanrahan, P."
, title =       "Global visibility algorithms for illumination computations"
, booktitle =   "Proceedings of SIGGRAPH '93"
, year =        1993
, pages =       "239--246"
, keywords =    "hidden surface removal, visibility space, radiosity,
                 global illumination, algorithmic triage"
, documentURL = "http://www.cs.princeton.edu/staff/seth/visglobillum.ps.Z"
, abstractURL = "http://www.cs.princeton.edu/gfx/papers/visglob"
}

@InProceedings{Teller91a
, author =      "S. J. Teller and C. H. S{\'e}quin"
, title =       "Visibility Preprocessing For Interactive Walkthroughs"
, booktitle =   "Proceedings of SIGGRAPH '91"
, month =       jul
, year =        1991
, pages =       "61--69"
, keywords =     "architectural simulation, linear programming, superset visibility"
}

@phdthesis{Teller92b
, author =       "Teller, Seth Jared"
, title =       "Visibility Computations in Densely Occluded Polyhedral Environments"
, school =      "Dept. of Computer Science, University of California"
, address =     "Berkeley"
, year =        1992
, keywords =    "graphics, visibility preprocessing, linear programming, spatial decomposition, visibility graphs, Plucker coordinates"
, documentURL =  "ftp://tr-ftp.cs.berkeley.edu/pub/tech-reports/csd/csd-92-708/all.ps"
, note =         "Also available as Technical Report UCB//CSD-92-708"
}

@article{Yagel95a
, author =      "Yagel, R. and Ray, W."
, year =        1995
, title =       "Visibility Computation for Efficient Walkthrough of Complex Environments"
, journal =     "Presence: Teleoperators and Virtual Environments"
, volume =      5
, number =      1
, page =        "45-60"
, documentURL = "http://www.cis.ohio-state.edu/volviz/Papers/1995/presence.ps.gz"
}

@techreport{Georges95a
, author        = "Georges, Chris"
, title         = "Obscuration Culling on Parallel Graphics Architectures"
, institution = "Department of Computer Science, University of N. Carolina, Chapel Hill"
, number        = "TR95-017"
, year          = 1995
, documentURL   = "ftp://ftp.cs.unc.edu/pub/publications/techreports/95-017.ps.Z"
}

@InProceedings{Chin:1992:FOP,
  author =       "Norman Chin and Steven Feiner",
  title =        "Fast object-precision shadow generation for areal
                 light sources using {BSP} trees",
  pages =        "21--30",
  booktitle =    "Computer Graphics (1992 Symposium on Interactive 3D
                 Graphics)",
  volume =       "25",
  number =       "2",
  year =         "1992",
  month =        mar,
  editor =       "David Zeltzer",
  conference =   "held in Boston; 29 March - 1 April 1992",
  keywords =     "shadow volume, area light source, penumbra, umbra",
  annote =       "",
}

@Article{Moravec:1981:GWT,
  author =       "Hans P. Moravec",
  title =        "{3D} Graphics and the Wave Theory",
  journal =      "Computer Graphics",
  volume =       "15",
  number =       "3",
  pages =        "289--296",
  month =        aug,
  year =         "1981",
  coden =        "CGRADI, CPGPBZ",
  ISSN =         "0097-8930",
  annote =       "A general overview of a new way of viewing light for
                 computer graphics. He suggests using waves as the
                 basis, and discusses the computational requirements and
                 new capabilities. illumination by wave fronts, rather
                 than light rays \\ A continuing trend in computer
                 representation of three dimensional synthetic scenes is
                 the ever more accurate modelling of complex
                 illumination effects. Such effects provide cues
                 necessary for a convincing illusion of reality. The
                 best current methods simulate multiple specular
                 reflections and refractions, but handle at most one
                 scattering bounce per light ray. They cannot accurately
                 simulate diffuse light sources, nor indirect lighting
                 via scattering media, without prohibitive increases in
                 the already very large computing costs. \\ Conventional
                 methods depend implicitly on a {\em particle} model;
                 light propagates in straight and conceptually
                 infinitely thin rays. This paper argues that a {\em
                 wave} model has important computational advantages for
                 the complex situations. In this approach, light is
                 represented by wave fronts which are stored as two
                 dimensional arrays of complex numbers. \\ The
                 propagation of such a front can be simulated by a
                 linear transform. Several advantages accrue.
                 Propagations in a direction orthogonal to the plane of
                 a front are convolutions which can be done by FFT in
                 $O(n \log n)$ time rather than the $n^{2}$ time for a
                 similar operation using rays. A typical speedup is
                 about 10,000. The wavelength of the illumination sets a
                 resolution limit which prevents unnecessary computation
                 of elements smaller than will be visible. The generated
                 wavefronts contain multiplicities of views of the
                 scene, which can be individually extracted by passing
                 them through different simulated lenses. Lastly the
                 wavefront calculations are ideally suited for
                 implementation on available array processors, which
                 provide more cost effective calculation for this task
                 than general purpose computers. \\ The wave method
                 eliminates the aliasing problem; the wavefronts are
                 inherently spatially filtered, but substitutes
                 diffraction effects and depth of focus limitations in
                 its stead.",
  conference =   "held in Dallas, Texas; July 1981",
  keywords =     "I30 wave theory, effects, parallel processing",
}


@Article{Rajkumar:1996:RFBSP,
  author =       {A. Rajkumar and B.F. Naylor and F. Feisullin and L. Rogers},
  title =        {Predicting RF coverage in large environments using
ray--beam tracing and partitioning tree represented geometry},
  journal =      {Wireless Netwoks},
  year =         {1996},
  volume =       {2},
  pages =        {143--154},
}

@TechReport{Teller:1998:FC,
  author =       {Seth Teller and John Alex},
  title =        {Frustum casting for progressive, interactive rendering},
  institution =  {MIT},
  year =         {1998},
  number =       {MIT LCS TR--740},
  month =        {January},
}

@InProceedings{Lukaszewski98,
  author =       "A. Lukaszewski and A. Formella",
  title =        "Fast Penumbra Calculation in Ray Tracing",
  booktitle =    "Proceedings of WSCG'98, the 6th International
                 Conference in Central Europe on Computer Graphics and
                 Visualization '98",
  pages =        "238--245",
  month =        feb,
  year =         "1998",
  keywords =     "shadow computation, stochastic ray tracing, bounding
                 volumes",
}



@TechReport{Havran97:rep,
  author = {Havran, V.},
  title = {Spatial Data Structures for Visibility Computation},
  institution = {CTU--FEE Prague},
  number = {DC-PSR-97-05},
  month = {May},
  year = {1997},
  note = {Postgraduate Study Report, 34 pages, also available as
          ftp://www.cgg.cvut.cz/{}outgoing/havran/minimum/{}dc-psr-97-04.ps.gz},
}

@PhdThesis{Grant92,
  author =       "Charles W. Grant",
  title =        "Visibility Algorithms in Image Synthesis",
  school =       "U. of California, Davis",
  year =         "1992",
  keywords =     "z buffer, ray tracing, shadow, taxonomy",
  annote =       "partial electronic version available from
                 grant1@llnl.gov, A successor to
                 Sutherland-Sproull-Schumacker, Comput. Surv. 74",
}

@InProceedings{Berg93,
  author =       "M. de Berg",
  title =        "Generalized hidden surface removal",
  pages =        "1--10",
  ISBN =         "0-89791-582-8",
  editor =       "ACM-SIGACT ACM-SIGGRAPH",
  booktitle =    "Proceedings of the 9th Annual Symposium on
                 Computational Geometry ({SCG} '93)",
  address =      "San Diego, CA, USA",
  month =        may,
  year =         "1993",
  publisher =    "ACM Press",
}

@Article{Franklin:1990:POH,
  author =       "W. Randolph Franklin and Mohan S. Kankanhalli",
  editor =       "Forest Baskett",
  title =        "Parallel Object-Space Hidden Surface Removal",
  journal =      "Computer Graphics",
  volume =       "24",
  number =       "4",
  pages =        "87--94",
  month =        aug,
  year =         "1990",
  coden =        "CGRADI, CPGPBZ",
  ISSN =         "0097-8930",
  conference =   "held in Dallas, Texas; 6--10 August 1990",
}

@Book{Foley90,
  author =       "James D. Foley and Andries van Dam and Steven K.
                 Feiner and John F. Hughes",
  title =        "Computer Graphics: Principles and Practice",
  edition =      "2nd",
  pages =        "1174",
  publisher =    "Addison-Wesley Publishing Co.",
  address =      "Reading, MA",
  year =         "1990",
  mrnumber =     "B.Foley.90",
  ISBN =         "0-201-12110-7",
  contents =     "(not listed)",
}

@InProceedings{Zhang:1997:FBC,
  author =       "Hansong Zhang and Kenneth E. {Hoff III}",
  title =        "Fast Backface Culling Using Normal Masks",
  booktitle =    "1997 Symposium on Interactive {3D} Graphics",
  pages =        "103--106",
  year =         "1997",
  editor =       "Michael Cohen and David Zeltzer",
  month =        apr,
  organization = "ACM SIGGRAPH",
  note =         "ISBN 0-89791-884-3",
}

@Article{tvcg-1997-21,
  author =       "Kalpathi R. Subramanian and Bruce F. Naylor",
  title =        "{Converting Discrete Images to Partitioning Trees}",
  journal =      "IEEE Transactions on Visualization and Computer
                 Graphics",
  volume =       "3",
  number =       "3",
  month =        jul,
  year =         "1997",
  pages =        "273--?",
  abstract =     "The discrete space representation of most scientific
                 datasets (pixels, voxels, etc.), generated through
                 instruments or by sampling continuously defined fields,
                 while being simple, is also verbose and structureless.
                 We propose the use of a particular spatial structure,
                 the {\em binary space partitioning tree}, or, simply,
                 {\em partitioning tree}, as a new representation to
                 perform efficient geometric computation in discretely
                 defined domains. The ease of performing affine
                 transformations, set operations between objects, and
                 correct implementation of transparency (exploiting the
                 visibility ordering inherent to the representation)
                 makes the partitioning tree a good candidate for
                 probing and analyzing medical reconstructions, in such
                 applications as surgery planning and prostheses design.
                 The multiresolution characteristics of the
                 representation can be exploited to perform such
                 operations at interactive rates by smooth variation of
                 the amount of geometry. Application to ultrasound data
                 segmentation and visualization is proposed. The paper
                 describes methods for constructing partitioning trees
                 from a discrete image/volume data set. Discrete space
                 operators developed for edge detection are used to
                 locate discontinuities in the image from which
                 lines/planes containing the discontinuities are fitted
                 by using either the Hough transform or a hyperplane
                 sort. A multiresolution representation can be generated
                 by ordering the choice of hyperplanes by the magnitude
                 of the discontinuities. Various approximations can be
                 obtained by pruning the tree according to an error
                 metric. The segmentation of the image into edgeless
                 regions can yield significant data compression. A
                 hierarchical encoding schema for both lossless and
                 lossy encodings is described.",
  keywords =     "-Partitioning trees, BSP trees, space partitioning,
                 miltiresolution representations, image reconstruction,
                 image coding, scientific visualization, MRI
                 visualization",
  tvcg-abstract-url = "http://www.computer.org/tvcg/tg1997/v0273abs.htm",
  tvcg-pdf-url = "http://pdf.computer.org/tg/books/tg1997/pdf/v0273.pdf",
}

@InProceedings{Murali:1997:CSB,
  author =       "T. M. Murali and Thomas A. Funkhouser",
  title =        "Consistent Solid and Boundary Representations from
                 Arbitrary Polygonal Data",
  booktitle =    "1997 Symposium on Interactive {3D} Graphics",
  pages =        "155--162",
  year =         "1997",
  editor =       "Michael Cohen and David Zeltzer",
  month =        apr,
  organization = "ACM SIGGRAPH",
  note =         "ISBN 0-89791-884-3",
}



@InProceedings{Stewart:1998:AVM,
  author =       {A. J. Stewart and T. Karkanis},
  title =        {Computing the approximate visibility map, with applications to form factors and discontinuity meshing},
  booktitle =    "Proceedings of the Ninth
                 Eurographics Workshop on Rendering",
  pages =        "57--68",
  year  =        "1998",
}


@Article{Bishop:1998:DPG,
  author =       "Lars Bishop and Dave Eberly and Turner Whitted and
                 Mark Finch and Michael Shantz",
  title =        "Designing a {PC} Game Engine",
  journal =      "IEEE Computer Graphics and Applications",
  volume =       "18",
  number =       "1",
  pages =        "46--53",
  month =        jan # "\slash " # feb,
  year =         "1998",
  coden =        "ICGADZ",
  ISSN =         "0272-1716",
  bibdate =      "Thu Feb 26 12:06:17 MST 1998",
  url =          "http://computer.org/cga/cg1998/g1046abs.htm;
                 http://dlib.computer.org/cg/books/cg1998/pdf/g1046.pdf",
  acknowledgement = ack-nhfb,
}


@TechReport{Wimmer:1998:FWIC,
  author =       {M. Wimmer and M. Giegl and D. Schmalstieg},
  title =        {Fast Walkthroughs with Image Caches and Ray Casting},
  institution =  {Institut f\"ur Computergraphik, TU Wien},
  year =         {1998},
  number =       {TR-186-2-98-30},
  month =        {December},
}

@TechReport{Wonka:1999:OSFW,
  author =       {P. Wonka and D. Schmalstieg},
  title =        {Occluder Shadows for Fast Walkthroughs of
                  Urban Environments},

  institution =  {Institut f\"ur Computergraphik, TU Wien},
  year =         {1999},
  number =       {TR-186-2-99-03},
  month =        {January},
}

@TechReport{Szirmay-Kalos98a,
  author =       "Laszlo Szirmay-Kalos",
  title =        "Global Ray-bundle Tracing",
  institution =  "Vienna University of Technology",
  type =         "Technical Report,",
  number =       "TR-186-2-98-18",
  address =      "Vienna",
  year =         "1998",
}

@InProceedings{Szirmay-Kalos98b,
  author =       "Laszlo Szirmay-Kalos and Werner Purgathofer",
  title =        "Global Ray-bundle Tracing with Hardware Acceleration",
  booktitle =    "Ninth Eurographics Workshop on Rendering",
  address =      "Vienna, Austria",
  month =        jun,
  year =         "1998",
  keywords =     "hardware",
}

@InProceedings{Snyder:1998:VSC,
  author =       "John Snyder and Jed Lengyel",
  title =        "Visibility Sorting and Compositing Without Splitting
                 for Image Layer Decomposition",
  booktitle =    "SIGGRAPH 98 Conference Proceedings",
  editor =       "Michael Cohen",
  series =       "Annual Conference Series",
  year =         "1998",
  organization = "ACM SIGGRAPH",
  publisher =    "Addison Wesley",
  month =        jul,
  pages =        "219--230",
  note =         "ISBN 0-89791-999-8",
  keywords =     "visibility sorting, compositing, nonsplitting layered
                 decomposition, occlusion cycle, occlusion graph,
                 sprite, kd-tree",
  annote =       "We present an efficient algorithm for visibility
                 sorting a set of moving geometric objects into a
                 sequence of image layers which are composited to
                 produce the final image. Instead of splitting the
                 geometry as in previous visibility approaches, we
                 detect mutual occluders and resolve them using an
                 appropriate image compositing expression or merge them
                 into a single layer. Such an algorithm has many
                 applications in computer graphics; we demonstrate two:
                 rendering acceleration using image interpolation and
                 visibility-correct depth of field using image blurring.
                 We propose a new, incremental method for identifying
                 mutually occluding sets of objects and computing a
                 visibility sort among these sets. Occlusion queries are
                 accelerated by testing on convex bounding hulls; less
                 conservative tests are also discussed. Kd-trees formed
                 by combinations of directions in object or image space
                 provide an initial cull on potential occluders, and
                 incremental collision detection algorithms are adapted
                 to resolve pairwise occlusions, when necessary. Mutual
                 occluders are further analyzed to generate an image
                 compositing expression; in the case of nonbinary
                 occlusion cycles, an expression can always be generated
                 without merging the objects into a single layer.
                 Results demonstrate that the algorithm is practical for
                 real-time animation of scenes involving hundreds of
                 objects each comprising hundreds or thousands of
                 polygons.",
}

@InProceedings{Plantinga:1990:RTH,
  author =       "Harry Plantinga and Charles R. Dyer and W. Brent
                 Seales",
  title =        "Real-Time Hidden-Line Elimination for a Rotating
                 Polyhedral Scene Using the Aspect Representation",
  pages =        "9--16",
  booktitle =    "Proceedings of Graphics Interface '90",
  year =         "1990",
  month =        may,
  conference =   "held in Halifax, Nova Scotia; 14-18 May 1990",
}

@PhdThesis{Chrysantho1996a,
  author =       "Yiorgos Chrysanthou",
  school =       "QMW, Dept of Computer Science",
  title =        "Shadow Computation for 3{D} Interaction and
                 Animation",
  year =         "1996",
  keywords =     "Technical Report No. 715",
  month =        jan,
  scope =        "ace",
}



@PhdThesis{Campbell91,
  author =       "A. T. {Campbell, III}",
  title =        "Modeling Global Diffuse Illumination for Image
                 Synthesis",
  school =       "CS Dept, University of Texas at Austin",
  year =         "1991",
  month =        dec,
  note =         "Tech. Report TR-91-39",
  keywords =     "mesh generation, radiosity, penumbra, shadow",
  pages =        "155",
  abstract =     "Rapid developments in the design of algorithms for
                 rendering globally illuminated scenes have taken place
                 in the past five years. Net energy methods such as
                 radiosity algorithms have become effective at computing
                 the energy balance for scenes containing diffusely
                 reflecting objects. Such methods first break up a scene
                 description into a large set of elements, or possibly
                 several levels of elements. Energy transfers among
                 these elements are then determined using a variety of
                 means. While much progress has been made in the design
                 of energy transfer algorithms, little or no attention
                 has been paid to the proper generation of the mesh of
                 surface elements. This dissertation presents a
                 technique for adaptively creating a mesh of surface
                 elements as the energy transfers are computed. The
                 method allows large numbers of small elements to be
                 placed at parts of the scene where the most active
                 energy transfers occur without requiring that other
                 parts of the scene be subdivided needlessly to the same
                 degree. As a result, the computational effort in the
                 energy transfer computations can be concentrated where
                 it has the most effect. Since the sources of direct and
                 indirect illumination in the scene are polygonal
                 elements, the effects of light sources with finite area
                 must be computed. Most methods simplify the problem by
                 approximating the area source with a collection of
                 point sources. We present an object space algorithm to
                 model illumination from polygonal light sources
                 analytically. The result is a collection of
                 smooth-shaded polygonal facets that may be rendered
                 from any viewing position. Binary Space Partitioning
                 trees are used to compute umbra and penumbra boundaries
                 efficiently. Fast analytic techniques are developed for
                 illumination calculations. Numerical optimization
                 methods ensure that the shading function is sampled
                 finely enough to find all significant illumination
                 gradations. Illumination calculations are optimized to
                 concentrate computational effort on parts of the scene
                 where they are most needed.",
}

@PhdThesis{Drettakis94-SSRII,
  author =       "George Drettakis",
  month =        jan,
  year =         "1994",
  title =        "Structured {Sampling} and {Reconstruction} of
                 {Illumination} for {Image} {Synthesis}",
  number =       "293",
  address =      "Toronto, Ontario",
  school  =  "Department of Computer Science, University of
                 Toronto",
  type =         "{CSRI} {Technical} {Report}",
  comments =     "available via anonymous ftp as:
                 ftp.csri.toronto.edu:csri-technical-reports/293 and via
                 the World Wide Web at:
                 http://safran.imag.fr/Membres/George.Drettakis/pub.html",
}

@Article{Schroeder:1993:FFB,
  author =       "P. Schroeder and P. Hanrahan",
  title =        "On the Form Factor between Two Polygons",
  journal =      "Computer Graphics",
  volume =       "27",
  number =       "{Annual Conference Series}",
  pages =        "163--164",
  year =         "1993",
  bibdate =      "Thu Feb 6 10:16:14 MST 1997",
  acknowledgement = ack-nhfb,
  keywords =     "ACM; computer graphics; SIGGRAPH",
}

@PhdThesis{Funkhouser93phd,
  author =       "Thomas A. Funkhouser",
  title =        "Database and Display Algorithms for Interactive
                 Visualization of Architectural Models",
  school =       "CS Division, UC Berkeley",
  year =         "1993",
  keywords =     "multiresolution, architectural walkthrough",
}

@Book{Boissonnat98,
  author =       {J.-D. Boissonnat and M. Yvinec},
  title =        {Algorithmic Geometry},
  publisher =    {cambridge University Press},
  year =         1998,
  where =        {A19}
}




@Misc{Chrysanthou:1998:VP,
  author =       {Y. Chrysanthou and D. Cohen-Or and E. Zadicario},
  title =        {Viewspace Partitioning of Densely Occluded Scenes},
  howpublished = {Abstract of a video presentation,
at the 13th Annual ACM Symposium on Computational Geometry, Minnesota, pages 413--414},
  month =        {June},
  year =         {1998},
}


@Unpublished{Sagadic,
  author =       {Amela Sagadic},
  title =        {An Algorithm for Invariant Polygon Visibility Orderings},
  note =         {Downloaded from the WWW}
}

@Unpublished{Teichmann:WV,
  author =       {Marek Teichmann and Seth Teller},
  title =        {A Weak Visibility Algorithm with an Application to an Interactive Walkthrough},
  note =         {Downloaded from the WWW}
}

@inproceedings{Tanaka91,
       author =       "Toshimitsu Tanaka and Tokiichiro Takahashi",
       title =        "Shading with Area Light Sources",
       booktitle =    "Eurographics '91",
       publisher =    "North-Holland",
       pages =        "235--246, 535--537",
       month =        sep,
       year =         "1991",
       annote = "no shadows",
     }

@InProceedings{Wang98,
  author =       {Yigang Wang and Hujun Bao and Qunsheng Peng},
  title =        {Accelerated Walkthroughs of Virtual Environments Based on
Visibility Preprocessing and Simplification},
  booktitle =    {Eurographics '98},
  volume =       {17},
  number =       {3},
  year =         {1998},
  pages =        {187--194},
}

@InProceedings{Nechvile99,
  author =       {Karel Nechv\'\i{}le and Petr Tobola},
  title =        {Local Approach to Dynamic Visibility in a Plane},
  booktitle =    {Proceedings of WSCG'99, the 7th International
                 Conference in Central Europe on Computer Graphics and
                 Visualization '99},
  year =         {1999},
  pages =        {202--208},
}
@InProceedings{Tobola99,
  author =       {Petr Tobola and Karel Nechv\'\i{}le},
  title =        {Linear Size BSP trees for Scenes with Low Directional Density},
  booktitle =    {Proceedings of WSCG'99, the 7th International
                 Conference in Central Europe on Computer Graphics and
                 Visualization '99},
  year =         {1999},
  pages =        {297--304},
}

@InProceedings{grant85a,
  author =       "C. W. Grant",
  title =        "Integrated Analytic Spatial and Temporal Anti-Aliasing
                 for Polyhedra in 4-Space",
  pages =        "79--84",
  booktitle =      "Computer Graphics (SIGGRAPH '85 Proceedings)",
  volume =       "19",
  number =       "3",
  year =         "1985",
  month =        jul,
  editor =       "B. A. Barsky",
  conference =   "held in San Francisco, CA; 22--26 July 1985",
  keywords =     "I37 anti-aliasing, temporal, I37 anti-aliasing, I37
                 visible surface algorithms",
}

@InProceedings{Schilling:1997:TRT,
  author =       "Andreas Schilling",
  title =        "Toward Real-Time Photorealistic Rendering: Challenges
                 and Solutions",
  booktitle =    "1997 SIGGRAPH / Eurographics Workshop on Graphics
                 Hardware",
  editor =       "Steven Molnar and Bengt-Olaf Schneider",
  year =         "1997",
  organization = "ACM SIGGRAPH / Eurographics",
  publisher =    "ACM Press",
  address =      "New York City, NY",
  month =        aug,
  pages =        "7--16",
  note =         "ISBN 0-89791-961-0",
  keywords =     "antialiasing, bump mapping, environment mapping,
                 anisotropic filtering",
  annote =       "A growing number of real-time applications need
                 graphics with photorealistic quality, especially in the
                 field of training (virtual operation, driving and
                 flight simulation), but also in the areas of design or
                 ergonomic research. We take a closer look at main
                 deficiencies of today's real time graphics hardware and
                 present solutions for several of the identified
                 problems in the areas of antialiasing and texture-,
                 bump- and reflection mapping. In the second part of the
                 paper, a new method for antialiasing bump maps is
                 explained in more detail.",
}

@Article{Greene:1994:EAR,
  author =       "N. Greene and M. Kass",
  title =        "Error-Bounded Antialiased Rendering of Complex
                 Environments",
  journal =      "Computer Graphics",
  volume =       "28",
  number =       "{Annual Conference Series}",
  pages =        "59--66",
  month =        jul,
  year =         "1994",
  coden =        "CGRADI",
  ISSN =         "0097-8930",
  bibdate =      "Thu Feb 6 08:30:20 MST 1997",
  acknowledgement = ack-nhfb,
  keywords =     "ACM; computer graphics; SIGGRAPH",
}

@InProceedings{Bartz98,
  author =       {Dirk Bartz and Michael Meissner and Tobias H\"uttner},
  title =        {Extending Graphics Hardware for Occlusion Queries in OpenGL},
  booktitle =    {Proceedings of the 1998 Workshop on Graphics Hardware},
  pages =        {97--104},
  year  =        {1998},
}


@Article{Clark:1976:HGM,
  author =       "James H. Clark",
  title =        "Hierarchical Geometric Models for Visible Surface
                 Algorithms",
  journal =      "Communications of the ACM",
  volume =       "19",
  number =       "10",
  pages =        "547--554",
  month =        oct,
  year =         "1976",
  coden =        "CACMA2",
  ISSN =         "0001-0782",
  bibdate =      "Tue Mar 25 13:26:09 MST 1997",
  abstract =     "By using an extension of traditional structure
                 information, or a geometric hierarchy, five significant
                 improvements to current techniques of computer picture
                 production are possible. First, the range of complexity
                 of an environment is greatly increased while the
                 visible complexity of any given scene is kept within a
                 fixed upper limit. Second, a meaningful way is provided
                 to vary the amount of detail presented in a scene.
                 Third, ``clipping'' becomes a very fast logarithmic
                 search for the resolvable parts of the environment
                 within the field of view. Fourth, frame to frame
                 coherence and clipping define a graphical ``working
                 set,'' or fraction of the total structure that should
                 be present in primary store for immediate access by the
                 visible surface algorithm. Finally, the geometric
                 structure suggests a recursive descent, visible surface
                 algorithm in which the computation time potentially
                 grows linearly with the visible complexity of the
                 scene.",
  acknowledgement = ack-nhfb,
  classcodes =   "C5540 (Terminals and graphic displays); C6130B
                 (Graphics techniques)",
  classification = "723; 921",
  corpsource =   "Univ. of California, Santa Cruz, CA, USA",
  journalabr =   "Commun ACM",
  keywords =     "algorithms; computer graphics; geometric models;
                 hidden surface; hierarchical data structures; image
                 processing; mathematical techniques --- Combinatorial
                 Mathematics; model; visible surface algorithms",
  treatment =    "A Application; P Practical; T Theoretical or
                 Mathematical",
}

@Book{Skiena:1998:ADM,
  author =       "Steven S. Skiena",
  title =        "The Algorithm Design Manual",
  publisher =    "Spring{\-}er-Ver{\-}lag",
  address =      "Berlin, Germany~/ Heidelberg, Germany~/ London, UK~/
                 etc.",
  pages =        "xvi + 486",
  year =         "1998",
  ISBN =         "0-387-94860-0",
  LCCN =         "QA76.9.A43S55 1997",
  bibdate =      "Tue Feb 10 10:51:27 1998",
  price =        "US\$54.95",
  acknowledgement = ack-nhfb,
}


@Book{Blinn:1996:JBC,
  author =       "Jim Blinn",
  title =        "{Jim Blinn}'s Corner: {A} Trip Down the Graphics
                 Pipeline",
  publisher =    "Morgan Kaufmann Publishers",
  address =      "Los Altos, CA 94022, USA",
  pages =        "vii + 214",
  year =         "1996",
  ISBN =         "1-55860-387-5",
  LCCN =         "T385.B585 1996",
  bibdate =      "Tue Jan 28 14:26:03 1997",
  note =         "This book is a collection of columns from the journal
                 IEEE Computer Graphics and Applications.",
  acknowledgement = ack-nhfb,
}

@Book{Blinn:1998:JBC,
  author =       "Jim Blinn",
  title =        "{Jim Blinn}'s Corner: Dirty Pixels",
  publisher =    "Morgan Kaufmann Publishers",
  address =      "Los Altos, CA 94022, USA",
  pages =        "256",
  year =         "1998",
  ISBN =         "1-55860-455-3",
  LCCN =         "T385.B586 1998",
  bibdate =      "Tue Jan 28 14:26:03 1997",
  note =         "This book is a collection of columns from the journal
                 IEEE Computer Graphics and Applications.",
  acknowledgement = ack-nhfb,
}


@Book{Prep85,
  author =       "F. P. Preparata and M. I. Shamos",
  title =        "Computational Geometry~: An Introduction",
  publisher =    "Springer-Verlag",
  year =         "1985",
}

@ARTICLE{Gigus90,
    AUTHOR    = "Ziv Gigus and Jitendra Malik",
    TITLE     = "Computing the aspect graph for line drawings of polyhedral objects",
    JOURNAL   = "IEEE Transactions on Pattern Analysis and Machine Intelligence",
    VOLUME    = 12,
    NUMBER    = 2,
    MONTH     = Feb,
    YEAR      = 1990,
    PAGES     = "113--122"
}

@Article{Blinn:1998:JBCc,
  author =       "Jim Blinn",
  title =        "Jim Blinn's Corner: Ten More Unsolved Problems in
                 Computer Graphics",
  journal =      "IEEE Computer Graphics \& Applications",
  year =         "1998",
  volume =       "18",
  number =       "5",
  month =        sep # " -- " # oct,
  note =         "ISSN 0272-1716",
}