| Foreword | |
| Software Engineering | |
| Method Components Logic | p. 3 |
| HEP Software Design : How to Reconcile the Immediate Needs and the Trends for the Future? | p. 19 |
| SLAC B-Factory Computing | p. 23 |
| Using Meta-Case Technology to Build a Methods Specific Environment | p. 33 |
| METRONOME: a Qualimetric Tool Integrated into Concerto | p. 39 |
| A Formal Specification Language for Object-Oriented Designs | p. 47 |
| Using Object Oriented Analysis and Design to Study the SSCL SDC Computing System | p. 53 |
| Experience with the Object Oriented Approach for the New Delphi Online Event Display | p. 77 |
| Experience with Mixed Language Programming | p. 87 |
| The MC++ Toolkit | p. 97 |
| The Use of Prolog for Real-Time Software Design | p. 103 |
| An Encounter with F90 | p. 109 |
| HippoDraw and Hippoplotamus | p. 119 |
| The Delphi Histogram Presenter | p. 125 |
| Improving Comparative HEP Data Analysis | p. 135 |
| Analysis of X Protocol and the Underlying Networking Interface | p. 141 |
| Using Motif in RD13 | p. 149 |
| World-Wide Web: An Information Infrastructure for High-Energy Physics | p. 157 |
| VERDI: Visual Entity Relationship Data Interface | p. 165 |
| HEPDB : A Database Management Package for High Energy Physics Experiments | p. 171 |
| Parallel Distributed GEANT | p. 177 |
| The PS197 Electronic Runbook | p. 183 |
| Software Engineering in the Development of the NA38/CERN Data Acquisition System | p. 189 |
| Using ISIS and META for Run Control in RD13 | p. 199 |
| Experience with MODSIM II | p. 203 |
| Software Tools for Transputer Networks | p. 209 |
| Data Acquisition System for Small to Medium Size Experiments | p. 215 |
| Porting PAW on PC's under MS DOS | p. 221 |
| PAW/GKS Implementation on IBM PC under MS DOS | p. 227 |
| GEANT Implementation on IBM PC under MS DOS | p. 233 |
| Summary of the Topical Workshop on Software Engineering | p. 235 |
| Genetic Algorithms | |
| Evolutionary Algorithms: Some Very Old Strategies for Optimization and Adaptation | p. 247 |
| Optimizing Monte Carlo Generator Parameters Using Genetic Algorithms | p. 255 |
| A Knowledge-Directed Genetic Algorithm for the Reconstruction of Physical Events | p. 267 |
| Neural Networks | |
| Neural Networks for Pattern Recognition: Introduction and Comparison to Other Techniques | p. 277 |
| Tutorial on Neural Network Applications in High Energy Physics: A 1992 Perspective | p. 287 |
| Neural Networks in High Energy Physics: Algorithms and Results | p. 327 |
| Feedforward Networks: from Theory to Technology | p. 341 |
| A Comparison Study of Binary Feedforward Neural Networks and Digital Circuits | p. 347 |
| The Need for Neural Networks at LHC/SSC | p. 353 |
| Status of Neural Net Triggers at Fermilab Tevatron | p. 361 |
| Simulation Packages for Neural Networks | p. 367 |
| Second Level Neural Network Trigger in the H1 Experiment | p. 375 |
| Analog Neural Networks in an Upgraded Muon Trigger for the D[actual symbol not reproducible] Detector | p. 381 |
| Implementation of a Second-Level Neural Network Trigger | p. 387 |
| A Neural Network for e/[pi] Classification in a Calorimeter | p. 391 |
| Pion-Kaon Separation with a Feed-Forward Neural Network | p. 397 |
| Classification of Jets from [actual symbol not reproducible] Collisions at Tevatron Energies | p. 405 |
| Jets Recognition and Tagging with Neural Networks | p. 411 |
| Tagging of Z Decays into b-Quarks in the ALEPH Detector using Multivariate Methods: Discriminant Analyses Artificial Neural Network | p. 419 |
| B-Quark Tagging using Neural Networks and Comparison with a Classical Method | p. 425 |
| B Tagging with Neural Networks: an Alternative Use of Single Particle Information for Discriminating Jet Events | p. 435 |
| Delphi Results on the Measurement of the Partial Hadronic Widths of the Z[superscript 0] using Neural Networks | p. 443 |
| Track Finding with Boolean Nets | p. 449 |
| Pattern Recognition in HEP with Neural Network Techniques | p. 455 |
| Neurocomputing Methods for Pattern Recognition in High Energy and Nuclear Physics | p. 461 |
| Cerenkov Ring Recognition using Adaptable and Non-Adaptable Network | p. 467 |
| Neural Network Based Event Selection in the Integral [gamma]-Ray Telescope | p. 473 |
| Neural Networks and Expert Systems to Solve the Problems of Large Amounts of Experimental Data at JET | p. 479 |
| Microelectronics for Neural Networks | p. 485 |
| Nonlinear Digital Signal Processing Using the Datawave Processor | p. 493 |
| Expert Systems | |
| Event Reconstruction Using Embedded Expert Systems | p. 501 |
| Distributed Cooperative Architecture for Accelerator Operation | p. 507 |
| Knowledge Acquisition and Maintenance for the KEK PF LINAC Diagnosis and Operation Support System | p. 517 |
| Beam: an Expert System for Control and Diagnosis of Particle Channel Equipment | p. 523 |
| Safety on High Energy Physic Experiments by an Expert System. Temporal and Statistical Aspects | p. 529 |
| Dexpert: an Expert System for Read-Out Error Recovery in the Aleph Data Acquisition System | p. 537 |
| The Delphi Experiment Control System | p. 543 |
| DELPHI Experiment Control Integration | p. 553 |
| Implementation Strategies for a Parallel Expert Diagnostic System | p. 559 |
| Experimental Control - A Communication Problem | p. 565 |
| Blackboard Architecture and Qualitative Model in a Computer Aided Assistant Designed to Define Computers for HEP Computing | p. 571 |
| Symbolic Manipulation | |
| Which Feynman Diagrams are Algebraically Computable? | p. 579 |
| Techniques for the Automatic Manipulation of Amplitudes and Loops | p. 585 |
| Physics Monte Carlo Generators for LEP: a Systematic Approach | p. 597 |
| Methods of Calculation of Higher Power Corrections in QCD | p. 609 |
| Computeralgebraic Calculation of 2-loop Selfenergies in the Electroweak Standard Model | p. 617 |
| Numerical Approach to Loop Integrals | p. 625 |
| Renormalization Group Calculations in QED and QCD: the Four-Loop Level | p. 631 |
| The Problem of the Tensor Treatment in Computer Algebra | p. 639 |
| The Computation of One-Loop Contributions in Y.M Theories with Class III Non Relativistic Gauges | p. 647 |
| Symbolic and Numerical Techniques in a Large Calculation: Electro-Weak Corrections to e[superscript +]e[superscript -] [actual symbol not reproducible] W[superscript +]W[superscript-] [actual symbol not reproducible]4 Fermions | p. 653 |
| GRACE and CHANEL: Automatic Calculation of Cross Sections | p. 659 |
| CompHEP: Integrated System for Automatic Calculations in High Energy Physics | p. 665 |
| The Symbolic-Numerical Interface in CompHEP Project: Interface with BASES | p. 671 |
| Computeralgebraic Generation of Feynman Graphs and Amplitudes | p. 677 |
| Computeralgebraic Generation and Calculation of Feynman Graphs using FeynArts and FeynCalc | p. 683 |
| The Interaction between Form and High Energy Physics | p. 689 |
| Physica: A Mathematica Package for the Symbolic Calculation of Tree Order Processes | p. 703 |
| A Mathematica Package for Computing Operator Product Expansions | p. 709 |
| TRACER - A Mathematica Package for [Gamma]-Algebra in Arbitrary Dimensions | p. 715 |
| HIP: Symbolic High Energy Physics Calculations using Maple | p. 721 |
| An Intelligent User Interface for Computer Algebra Using a Common Lisp Object Oriented Expert System | p. 727 |
| Sensor Collapses [gamma]5-traces by Using the Schouten Identity | p. 733 |
| An Algorithm for Calculating Traces of Gamma Matrices in a Compact Form | p. 739 |
| Monte Carlo Integration Packages BASES and DICE | p. 745 |
| The Expert Evaluations Method: How to Apply it in Theoretical High-Energy Physics | p. 751 |
| Calculations in the Calculus of Modern Differential Geometry on a Computer | p. 757 |
| Analytical Model of Final Focus Structures for Flat and Round Beams at the Interaction Point | p. 763 |
| List of Participants | p. 775 |
| Table of Contents provided by Blackwell. All Rights Reserved. |
