Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Electromagnetic interactions
- 3 Nuclear interactions
- 4 Particle beams
- 5 Targets
- 6 Fast electronics
- 7 Scintillation counters
- 8 Cerenkov counters
- 9 Proportional chambers
- 10 Drift chambers
- 11 Sampling calorimeters
- 12 Specialized detectors
- 13 Triggers
- 14 Detector systems
- 15 Some fundamental measurements
- Appendix A Physical constants
- Appendix B Periodic table of the elements
- Appendix C Probability and statistics
- Appendix D Cross sections and probability
- Appendix E Two-body scattering in the LAB frame
- Appendix F Motion of ions in a combined electric and magnetic field
- Appendix G Properties of structural materials
- Author index
- Subject index
13 - Triggers
- Frontmatter
- Contents
- Preface
- 1 Introduction
- 2 Electromagnetic interactions
- 3 Nuclear interactions
- 4 Particle beams
- 5 Targets
- 6 Fast electronics
- 7 Scintillation counters
- 8 Cerenkov counters
- 9 Proportional chambers
- 10 Drift chambers
- 11 Sampling calorimeters
- 12 Specialized detectors
- 13 Triggers
- 14 Detector systems
- 15 Some fundamental measurements
- Appendix A Physical constants
- Appendix B Periodic table of the elements
- Appendix C Probability and statistics
- Appendix D Cross sections and probability
- Appendix E Two-body scattering in the LAB frame
- Appendix F Motion of ions in a combined electric and magnetic field
- Appendix G Properties of structural materials
- Author index
- Subject index
Summary
A well-designed trigger is an essential ingredient for a successful particle physics experiment. The trigger must efficiently pass the events under study without permitting the data collection systems to become swamped with similar but uninteresting background events. Since the design of a trigger depends critically on the intent of the experiment and is strongly influenced by the choice of beam parameters, target, geometry, and so forth, it is impossible to give a prescription here on how to set up a trigger for any situation. Instead, we must content ourselves in this chapter with considering some general classes of trigger elements and with examining some specific examples in more detail. It should be mentioned that some experiments do not use a trigger. For example, neutrino experiments sometimes accept any event that occurs within a gate following the acceleration cycle.
General considerations
A trigger is an electronic signal indicating the occurrence of a desired temporal and spatial correlation in the detector signals. The desired correlation is determined by examining the physical process of interest in order to find some characteristic signature that distinguishes it from other processes that will occur simultaneously. Most triggers involve a time correlation of the form B · F, where B is a suitably delayed signal indicating the presence of a beam particle and F is a signal indicating the proper signature in the final state. The time coincidence increases the probability that the particles all come from the same event.
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- Information
- Introduction to Experimental Particle Physics , pp. 303 - 324Publisher: Cambridge University PressPrint publication year: 1986