In order to handle spatial data efficiently, as required in computer aided design and geo-data applications, a database system needs an index mechanism that will help it retrieve data items quickly according to their spatial locations However, traditional indexing methods are not well suited to data objects of non-zero size located m multi-dimensional spaces In this paper we describe a dynamic index structure called an R-tree which meets this need, and give algorithms for searching and updating it. We present the results of a series of tests which indicate that the structure performs well, and conclude that it is useful for current database systems in spatial applications

R-trees: a dynamic index structure for spatial searching

Data analysis plays an indispensable role for understanding various phenomena. Cluster analysis, primitive exploration with little or no prior knowledge, consists of research developed across a wide variety of communities. The diversity, on one hand, equips us with many tools. On the other hand, the profusion of options causes confusion. We survey clustering algorithms for data sets appearing in statistics, computer science, and machine learning, and illustrate their applications in some benchmark data sets, the traveling salesman problem, and bioinformatics, a new field attracting intensive efforts. Several tightly related topics, proximity measure, and cluster validation, are also discussed.

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Survey of clustering algorithms

From the Publisher: 
The accessible presentation of this book gives both a general view of the entire computer vision enterprise and also offers sufficient detail to be able to build useful applications. Users learn techniques that have proven to be useful by first-hand experience and a wide range of mathematical methods. A CD-ROM with every copy of the text contains source code for programming practice, color images, and illustrative movies. Comprehensive and up-to-date, this book includes essential topics that either reflect practical significance or are of theoretical importance. Topics are discussed in substantial and increasing depth. Application surveys describe numerous important application areas such as image based rendering and digital libraries. Many important algorithms broken down and illustrated in pseudo code. Appropriate for use by engineers as a comprehensive reference to the computer vision enterprise.

Computer vision : a modern approach = 计算机视觉 : 一种现代的方法

One of the greatest challenges faced by designers of digital systems is optimizing the communication and interconnection between system components. Interconnection networks offer an attractive and economical solution to this communication crisis and are fast becoming pervasive in digital systems. Current trends suggest that this communication bottleneck will be even more problematic when designing future generations of machines. Consequently, the anatomy of an interconnection network router and science of interconnection network design will only grow in importance in the coming years.

This book offers a detailed and comprehensive presentation of the basic principles of interconnection network design, clearly illustrating them with numerous examples, chapter exercises, and case studies. It incorporates hardware-level descriptions of concepts, allowing a designer to see all the steps of the process from abstract design to concrete implementation.

·Case studies throughout the book draw on extensive author experience in designing interconnection networks over a period of more than twenty years, providing real world examples of what works, and what doesn't.

·Tightly couples concepts with implementation costs to facilitate a deeper understanding of the tradeoffs in the design of a practical network.

·A set of examples and exercises in every chapter help the reader to fully understand all the implications of every design decision.

Table of Contents


Chapter 1 Introduction to Interconnection Networks 
1.1 Three Questions About Interconnection Networks 
1.2 Uses of Interconnection Networks 
1.3 Network Basics 
1.4 History 
1.5 Organization of this Book 

Chapter 2 A Simple Interconnection Network 
2.1 Network Specifications and Constraints 
2.2 Topology 
2.3 Routing 
2.4 Flow Control 
2.5 Router Design 
2.6 Performance Analysis 
2.7 Exercises 

Chapter 3 Topology Basics 
3.1 Nomenclature 
3.2 Traffic Patterns 
3.3 Performance 
3.4 Packaging Cost 
3.5 Case Study: The SGI Origin 2000 
3.6 Bibliographic Notes 
3.7 Exercises 

Chapter 4 Butterfly Networks 
4.1 The Structure of Butterfly Networks 
4.2 Isomorphic Butterflies 
4.3 Performance and Packaging Cost 
4.4 Path Diversity and Extra Stages 
4.5 Case Study: The BBN Butterfly 
4.6 Bibliographic Notes 
4.7 Exercises 

Chapter 5 Torus Networks 
5.1 The Structure of Torus Networks 
5.2 Performance 
5.3 Building Mesh and Torus Networks 
5.4 Express Cubes 
5.5 Case Study: The MIT J-Machine 
5.6 Bibliographic Notes 
5.7 Exercises 
Chapter 6 Non-Blocking Networks 
6.1 Non-Blocking vs. Non-Interfering Networks 
6.2 Crossbar Networks 
6.3 Clos Networks 
6.4 Benes Networks 
6.5 Sorting Networks 
6.6 Case Study: The Velio VC2002 (Zeus) Grooming Switch 
6.7 Bibliographic Notes 
6.8 Exercises 

Chapter 7 Slicing and Dicing 
7.1 Concentrators and Distributors 
7.2 Slicing and Dicing 
7.3 Slicing Multistage Networks 
7.4 Case Study: Bit Slicing in the Tiny Tera 
7.5 Bibliographic Notes 
7.6 Exercises 

Chapter 8 Routing Basics 
8.1 A Routing Example 
8.2 Taxonomy of Routing Algorithms 
8.3 The Routing Relation 
8.4 Deterministic Routing 
8.5 Case Study: Dimension-Order Routing in the Cray T3D 
8.6 Bibliographic Notes 
8.7 Exercises 

Chapter 9 Oblivious Routing 
9.1 Valiant's Randomized Routing Algorithm 
9.2 Minimal Oblivious Routing 
9.3 Load-Balanced Oblivious Routing 
9.4 Analysis of Oblivious Routing 
9.5 Case Study: Oblivious Routing in the
Avici Terabit Switch Router(TSR) 
9.6 Bibliographic Notes 
9.7 Exercises 

Chapter 10 Adaptive Routing 
10.1 Adaptive Routing Basics 
10.2 Minimal Adaptive Routing 
10.3 Fully Adaptive Routing 
10.4 Load-Balanced Adaptive Routing 
10.5 Search-Based Routing 
10.6 Case Study: Adaptive Routing in the
Thinking Machines CM-5 
10.7 Bibliographic Notes 
10.8 Exercises 

Chapter 11 Routing Mechanics 
11.1 Table-Based Routing 
11.2 Algorithmic Routing 
11.3 Case Study: Oblivious Source Routing in the
IBM Vulcan Network 
11.4 Bibliographic Notes 
11.5 Exercises 

Chapter 12 Flow Control Basics 
12.1 Resources and Allocation Units 
12.2 Bufferless Flow Control 
12.3 Circuit Switching 
12.4 Bibliographic Notes 
12.5 Exercises 

Chapter 13 Buffered Flow Control 
13.1 Packet-Buffer Flow Control 
13.2 Flit-Buffer Flow Control 
13.3 Buffer Management and Backpressure 
13.4 Flit-Reservation Flow Control 
13.5 Bibliographic Notes 
13.6 Exercises 

Chapter 14 Deadlock and Livelock 
14.1 Deadlock 
14.2 Deadlock Avoidance 
14.3 Adaptive Routing 
14.4 Deadlock Recovery 
14.5 Livelock 
14.6 Case Study: Deadlock Avoidance in the Cray T3E 
14.7 Bibliographic Notes 
14.8 Exercises 

Chapter 15 Quality of Service 
15.1 Service Classes and Service Contracts 
15.2 Burstiness and Network Delays 
15.3 Implementation of Guaranteed Services 
15.4 Implementation of Best-Effort Services 
15.5 Separation of Resources 
15.6 Case Study: ATM Service Classes 
15.7 Case Study: Virtual Networks in the Avici TSR 
15.8 Bibliographic Notes 
15.9 Exercises 

Chapter 16 Router Architecture 
16.1 Basic Router Architecture 
16.2 Stalls 
16.3 Closing the Loop with Credits 
16.4 Reallocating a Channel 
16.5 Speculation and Lookahead 
16.6 Flit and Credit Encoding 
16.7 Case Study: The Alpha 21364 Router 
16.8 Bibliographic Notes 
16.9 Exercises 

Chapter 17 Router Datapath Components 
17.1 Input Buffer Organization 
17.2 Switches 
17.3 Output Organization 
17.4 Case Study: The Datapath of the IBM Colony
Router 
17.5 Bibliographic Notes 
17.6 Exercises 

Chapter 18 Arbitration 
18.1 Arbitration Timing 
18.2 Fairness 
18.3 Fixed Priority Arbiter 
18.4 Variable Priority Iterative Arbiters 
18.5 Matrix Arbiter 
18.6 Queuing Arbiter 
18.7 Exercises 

Chapter 19 Allocation 
19.1 Representations
19.2 Exact Algorithms
19.3 Separable Allocators 
19.4 Wavefront Allocator 
19.5 Incremental vs. Batch Allocation 
19.6 Multistage Allocation 
19.7 Performance of Allocators 
19.8 Case Study: The Tiny Tera Allocator 
19.9 Bibliographic Notes 
19.10 Exercises

Chapter 20 Network Interfaces 
20.1 Processor-Network Interface 
20.2 Shared-Memory Interface 
20.3 Line-Fabric Interface 
20.4 Case Study: The MIT M-Machine Network Interface 
20.5 Bibliographic Notes 
20.6 Exercises 

Chapter 21 Error Control 411
21.1 Know Thy Enemy: Failure Modes and Fault Models 
21.2 The Error Control Process: Detection, Containment,
and Recovery 
21.3 Link Level Error Control 
21.4 Router Error Control 
21.5 Network-Level Error Control 
21.6 End-to-end Error Control 
21.7 Bibliographic Notes 
21.8 Exercises 

Chapter 22 Buses 
22.1 Bus Basics 
22.2 Bus Arbitration 
22.3 High Performance Bus Protocol 
22.4 From Buses to Networks 
22.5 Case Study: The PCI Bus 
22.6 Bibliographic Notes 
22.7 Exercises 

Chapter 23 Performance Analysis 
23.1 Measures of Interconnection Network Performance 
23.2 Analysis 
23.3 Validation
23.4 Case Study: Efficiency and Loss in the
BBN Monarch Network 
23.5 Bibliographic Notes 
23.6 Exercises 

Chapter 24 Simulation 
24.1 Levels of Detail 
24.2 Network Workloads 
24.3 Simulation Measurements 
24.4 Simulator Design 
24.5 Bibliographic Notes 
24.6 Exercises 

Chapter 25 Simulation Examples 495
25.1 Routing
25.2 Flow Control Performance 
25.3 Fault Tolerance 

Appendix A Nomenclature 
Appendix B Glossary 
Appendix C Network Simulator

Principles and Practices of Interconnection Networks

Highly detailed geometric models are rapidly becoming commonplace in computer graphics. These models, often represented as complex triangle meshes, challenge rendering performance, transmission bandwidth, and storage capacities. This paper introduces the progressive mesh (PM) representation, a new scheme for storing and transmitting arbitrary triangle meshes. This efficient, lossless, continuous-resolution representation addresses several practical problems in graphics: smooth geomorphing of level-of-detail approximations, progressive transmission, mesh compression, and selective refinement. In addition, we present a new mesh simplification procedure for constructing a PM representation from an arbitrary mesh. The goal of this optimization procedure is to preserve not just the geometry of the original mesh, but more importantly its overall appearance as defined by its discrete and scalar appearance attributes such as material identifiers, color values, normals, and texture coordinates. We demonstrate construction of the PM representation and its applications using several practical models

Progressive meshes

We describe an adaptive display algorithm for interactive frame rates during visualization of very complex virtual environments. The algorithm relies upon a hierarchical model representation in which objects are described at multiple levels of detail and can be drawn with various rendering algorithms. The idea behind the algorithm is to adjust image quality adaptively to maintain a uniform, user-specified target frame rate. We perform a constrained optimization to choose a level of detail and rendering algorithm for each potentially visible object in order to generate the “best” image possible within the target frame time. Tests show that the algorithm generates more uniform frame rates than other previously described detail elision algorithms with little noticeable difference in image quality during visualization of complex models. CR

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Adaptive display algorithm for interactive frame rates during visualization of complex virtual environments

Manipulation in immersive virtual environments is difficult partly because users must do without the haptic contact with real objects they rely on in the real world to orient themselves and their manipulanda. To compensate for this lack, we propose exploiting the one real object every user has in a virtual environment, his body. We present a unified framework for virtual-environment interaction based on proprioception, a person's sense of the position and orientation of his body and limbs. We describe three forms of body-relative interaction: • Direct manipulation—ways to use body sense to help control manipulation • Physical mnemonics—ways to store/recall information relative to the body • Gestural actions—ways to use body-relative actions to issue commands Automatic scaling is a way to bring objects instantly within reach so that users can manipulate them using proprioceptive cues. Several novel virtual interaction techniques based upon automatic scaling and our proposed framework of proprioception allow a user to interact with a virtual world intuitively, efficiently, precisely, and lazily. We report the results of both informal user trials and formal user studies of the usability of the body-relative interaction techniques presented. CR

/pdf/moving-objects-in-space-exploiting-proprioception-in-virtual-44v79fnu5r.pdf

Moving objects in space: exploiting proprioception in virtual-environment interaction

The number of polygons comprising interesting architectural models is many more than can be rendered at interactive frame rates. However, due to occlusion by opaque surfaces (e.g., walls), only a small fraction of a typical model is visible from most viewpoints.We describe a method of visibility preprocessing that is efficient and effective for axis-aligned or axial architectural models. A model is subdivided into rectangular cells whose boundaries coincide with major opaque surfaces. Non-opaque portals are identified on cell boundaries, and used to form an adjacency graph connecting the cells of the subdivision. Next, the cell-to-cell visibility is computed for each cell of the subdivision, by linking pairs of cells between which unobstructed sightlines exist.During an interactive walkthrough phase, an observer with a known position and view cone moves through the model. At each frame, the cell containing the observer is identified, and the contents of potentially visible cells are retrieved from storage. The set of potentially visible cells is further reduced by culling it against the observer's view cone, producing the eye-to-cell visibility. The contents of the remaining visible cells are then sent to a graphics pipeline for hidden-surface removal and rendering.Tests on moderately complex 2-D and 3-D axial models reveal substantially reduced rendering loads.

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Visibility preprocessing for interactive walkthroughs

This paper presents a simple-to-use mechanism for the creation of complex smoothly shaped surfaces of any genus or topology. The work described here is the result of research into the fairness of curves and surfaces specified through geometric interpolarity constraints. Constraints consist of positions and, optionally, surface normals and surface curvatures. The outcome of our investigation is a recommendation for the use of nonlinear optimization techniques that minimize a fairness functional based on the variation of curvature. The approach produces very high quality surfaces with predictable, intuitive behavior, while generating, where possible, simple shapes, such as cylinders, spheres, or tori which are commonly used in geometric modeling. From a designer''s point of view, this approach allows the specification of a desired surface in the most natural way. Though computationally intense, the techniques described have now become practical because of the wide availability of very fast work stations. As the processing power available on each desk-top further increases, the techniques described here will become real-time and interactive.

Functional optimization for fair surface design

A silicon compilation system for CMOS operational amplifiers (OPASYN) is discussed. The synthesis system takes as inputs system-level specifications, fabrication-dependent technology parameters, and geometric layout rules. It produces a design-rule-correct compact layout of an optimized operational amplifier. The synthesis proceeds in three stages: (1) heuristic selection of a suitable circuit topology; (2) parametric circuit optimization based on analytic models; and (3) mask geometry construction using a macro cell layout style. The synthesis process is fast enough for the program to be used interactively at the system design level by system designers who are inexperienced in operational amplifier design. >

Carlo H. Séquin

Papers

Adaptive display algorithm for interactive frame rates during visualization of complex virtual environments

Moving objects in space: exploiting proprioception in virtual-environment interaction

Visibility preprocessing for interactive walkthroughs

Functional optimization for fair surface design

OPASYN: a compiler for CMOS operational amplifiers