2. Conference On Computing Frontiers 2005: Ischia, Italy

Autonomic and organic computing

• Dietmar Fey, Daniel Schmidt:
  Marching-pixels: a new organic computing paradigm for smart sensor processor arrays. 1-9
  
• Thorsten Schöler, Christian Müller-Schloer:
  First steps towards organic computing systems: monitoring an adaptive protocol stack with a fuzzy classifier system. 10-20
  

Supercomputing part 1

• Amirali Baniasadi:
  Balancing clustering-induced stalls to improve performance in clustered processors. 21-27
  
• John Feo, David Harper, Simon Kahan, Petr Konecny:
  ELDORADO. 28-34
  

Non-conventional computing

• Alexis De Vos, Yvan Van Rentergem:
  Reversible computing: from mathematical group theory to electronical circuit experiment. 35-44
  
• Daniel B. Miller, Edward Fredkin:
  Two-state, reversible, universal cellular automata in three dimensions. 45-51
  
• Tommaso Toffoli, Lev B. Levitin:
  Specific ergodicity: an informative indicator for invertible computational media. 52-58
  

Grid computing part 1

• Niklas Therning, Lars Bengtsson:
  Jalapeno: secentralized grid computing using peer-to-peer technology. 59-65
  
• Li Chunlin, Li Layuan:
  A two level market model for resource allocation optimization in computational grid. 66-71
  

Reconfigurable computing (part 1)

• Humberto Calderon, Stamatis Vassiliadis:
  Reconfigurable universal SAD-multiplier array. 72-76
  
• Martin Thuresson, Per Stenström:
  Evaluation of extended dictionary-based static code compression schemes. 77-86
  

Grid computing part 2

• Cécile Germain-Renaud, Dephine Monnier-Ragaigne:
  Grid result checking. 87-96
  
• Kurt Maly, Mohammad Zubair, Vamshi Chilukamarri, Pratik Kothari:
  GRID Based Federated Digital Library. 97-105
  

Reconfigurable computing part 2

• João M. P. Cardoso:
  Dynamic loop pipelining in data-driven architectures. 106-115
  
• Martin Schulz, Brian S. White, Sally A. McKee, Hsien-Hsin S. Lee, Jürgen Jeitner:
  Owl: next generation system monitoring. 116-124
  
• Valentina Salapura, Randy Bickford, Matthias A. Blumrich, Arthur A. Bright, Dong Chen, Paul Coteus, Alan Gara, Mark Giampapa, Michael Gschwind, Manish Gupta, Shawn Hall, Ruud A. Haring, Philip Heidelberger, Dirk Hoenicke, Gerard V. Kopcsay, Martin Ohmacht, Rick A. Rand, Todd Takken, Pavlos Vranas:
  Power and performance optimization at the system level. 125-132
  

Quantum computing

• Mihai Udrescu, Lucian Prodan, Mircea Vladutiu:
  Improving quantum circuit dependability with reconfigurable quantum gate arrays. 133-144
  
• Claudia Roberta Calidonna, Adele Naddeo:
  Using a hybrid CA based model for a flexible qualitative qubit simulation: fully frustrated josephson junction ladder (JJL) application. 145-151
  

high performance embedded architectures part 1

• Mathias Spjuth, Martin Karlsson, Erik Hagersten:
  Skewed caches from a low-power perspective. 152-160
  
• Nasir Mohyuddin, Rashed Bhatti, Michel Dubois:
  Controlling leakage power with the replacement policy in slumberous caches. 161-170
  
• Asadollah Shahbahrami, Ben H. H. Juurlink, Stamatis Vassiliadis:
  Matrix register file and extended subwords: two techniques for embedded media processors. 171-179
  

Compilers and operating systems

• Masayo Haneda, Peter M. W. Knijnenburg, Harry A. G. Wijshoff:
  Optimizing general purpose compiler optimization. 180-188
  
• K. Ananda Vardhan, Y. N. Srikant:
  Transition aware scheduling: increasing continuous idle-periods in resource units. 189-198
  
• Soraya Ghiasi, Tom W. Keller, Freeman L. Rawson III:
  Scheduling for heterogeneous processors in server systems. 199-210
  
• Tipp Moseley, Alex Shye, Vijay Janapa Reddi, Matthew Iyer, Dan Fay, David Hodgdon, Joshua L. Kihm, Alex Settle, Dirk Grunwald, Daniel A. Connors:
  Dynamic run-time architecture techniques for enabling continuous optimization. 211-220
  

Workload characterization of emerging applications

• Alberto Ferrante, Vincenzo Piuri, Fabien Castanier:
  A QoS-enabled packet scheduling algorithm for IPSec multi-accelerator based systems. 221-229
  
• Malik Silva:
  Sparse matrix storage revisited. 230-235
  

Pervasive computing

• Venu K. Murthy, E. V. Krishnamurthy:
  Contextual information management using contract: based workflow. 236-245
  
• Faruk Bagci, Holger Schick, Jan Petzold, Wolfgang Trumler, Theo Ungerer:
  Communication and security extensions for a ubiquitous mobile agent system (UbiMAS). 246-251
  

Supercomputing part 2

• Steve Carr, Soner Önder:
  A case for a working-set-based memory hierarchy. 252-261
  
• Jarek Nieplocha, Manojkumar Krishnan, Bruce Palmer, Vinod Tipparaju, Yeliang Zhang:
  Exploiting processor groups to extend scalability of the GA shared memory programming model. 262-272
  

Special purpose architectures

• Edward Fredkin:
  A computing architecture for physics. 273-279
  
• Jörg Platte, Edwin Naroska:
  A combined hardware and software architecture for secure computing. 280-288
  

High performance embedded architectures (part 2)

• Fredrik Warg, Per Stenström:
  Reducing misspeculation overhead for module-level speculative execution. 289-298
  
• Braxton Thomason, Craig Chase:
  Partially ordered epochs for thread-level speculation. 299-306
  
• Christine Rochange, Pascal Sainrat:
  A time-predictable execution mode for superscalar pipelines with instruction prescheduling. 307-314
  

Open topics

• Lambert Schaelicke, Kyle Wheeler, Curt Freeland:
  SPANIDS: a scalable network intrusion detection loadbalancer. 315-322
  
• Lucian Prodan, Mihai Udrescu, Mircea Vladutiu:
  Reliability assessment in embryonics inspired by fault-tolerant quantum computation. 323-333
  
• Chunrong Lai, Shih-Lien Lu, Yurong Chen, Trista Chen:
  Improving branch prediction accuracy with parallel conservative correctors. 334-341
  
• Thomas R. Puzak, Allan Hartstein, Philip G. Emma, Viji Srinivasan:
  When prefetching improves/degrades performance. 342-352
  

Temperature, energy, and complexity-aware designs

• Kuo-Su Hsiao, Chung-Ho Chen:
  An efficient wakeup design for energy reduction in high-performance superscalar processors. 353-360
  
• Nana B. Sam, Martin Burtscher:
  On the energy-efficiency of speculative hardware. 361-370
  
• Salvador Petit, Julio Sahuquillo, Jose M. Such, David R. Kaeli:
  Exploiting temporal locality in drowsy cache policies. 371-377
  
• Michael J. Geiger, Sally A. McKee, Gary S. Tyson:
  Drowsy region-based caches: minimizing both dynamic and static power dissipation. 378-384
  

Perspectives on reversible computing

• Michael P. Frank:
  Introduction to reversible computing: motivation, progress, and challenges. 385-390
  
• Erik DeBenedictis:
  Reversible logic for supercomputing. 391-402
  

Novel implementation technologies

• Craig S. Lent, Sarah E. Frost, Peter M. Kogge:
  Reversible computation with quantum-dot cellular automata (QCA). 403
  
• Erik Forsberg:
  The electron waveguide y-branch switch: a review and arguments for its use as a base for reversible logic. 404-406
  

Adiabatic and energy-recovery circuits

• Visvesh S. Sathe, Juang-Ying Chueh, Joohee Kim, Conrad H. Ziesler, Suhwan Kim, Marios C. Papaefthymiou:
  Fast, efficient, recovering, and irreversible. 407-413
  
• Stephan Henzler, Thomas Nirschl, Matthias Eireiner, Ettore Amirante, Doris Schmitt-Landsiedel:
  Making adiabatic circuits attractive for todays VLSI industry by multi-mode operation-adiabatic mode circuits. 414-420
  
• Seokkee Kim, Soo-Ik Chae:
  Implementation of a simple 8-bit microprocessor with reversible energy recovery logic. 421-426
  
• Jürgen Fischer, Philip Teichmann, Doris Schmitt-Landsiedel:
  Scaling trends in adiabatic logic. 427-434
  

Reversible computing theory

• Paul M. B. Vitányi:
  Time, space, and energy in reversible computing. 435-444
  
• Lev B. Levitin, Tommaso Toffoli:
  Thermodynamical cost of reversible computing. 445-446