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Physics Of Experiment Instrumentation Using Matlab Apps, The: With Companion Media Pack 2nd ed. [Kietas viršelis]

(Fermi Nat'l Accelerator Lab, Usa)
  • Formatas: Hardback, 264 pages
  • Išleidimo metai: 19-Apr-2021
  • Leidėjas: World Scientific Publishing Co Pte Ltd
  • ISBN-10: 9811232431
  • ISBN-13: 9789811232435
Kitos knygos pagal šią temą:
Physics Of Experiment Instrumentation Using Matlab Apps, The: With Companion Media Pack 2nd ed.Didesnis paveikslėlis
  • Formatas: Hardback, 264 pages
  • Išleidimo metai: 19-Apr-2021
  • Leidėjas: World Scientific Publishing Co Pte Ltd
  • ISBN-10: 9811232431
  • ISBN-13: 9789811232435
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9789811232435.html
Raktažodžiai:

Some twenty years ago the author published a book entitled The Physics of Particle Detectors. Much has evolved since that time, not in the basic physics, but in the complexity, number and versatility of the detectors in common use in both experiments, beam-lines and accelerators. Those changes have been heavily influenced by the concurrent dramatic changes in the microelectronics industry. In parallel, the use of computer-aided teaching has also greatly improved. The present volume explores the physics needed to understand the full suite of front-end devices in use today. In particular the physics explanation is made concurrently with the specific device being discussed, thus making the coupling more immediate. That study is made more interactive by using newer educational tools now available such as dynamic Matlab Apps.

Preface v
Introduction vii
1 Getting Started with Matlab
1(6)
1.1 Command Window
1(2)
1.2 Editor
3(2)
1.3 Online Resources
5(2)
2 Basic Physics Processes
7(28)
2.1 Physics Constants and Properties of Materials
7(1)
2.2 Atoms
8(5)
2.3 Nuclei
13(3)
2.4 Motion in Electric and Magnetic Fields
16(9)
2.5 Magnetic Lens -- Quadrupole
25(3)
2.6 Quadrupole Doublet -- (x, y) Focus
28(4)
2.7 Special Relativity
32(3)
3 Detector and Beam Instrumentation
35(86)
3.1 Photoelectric Effect `
35(3)
3.2 Photomultiplier Tube (PMT) and Scintillator
38(3)
3.3 Magnetic Shielding
41(2)
3.4 Silicon PMT
43(2)
3.5 Time of Flight -- β
45(3)
3.6 Cerenkov Counters -- β
48(4)
3.7 Scattering
52(5)
3.8 Ionization and Energy Loss -- β
57(5)
3.9 Transition Radiation -- γ
62(6)
3.10 Compton Scattering -- γ
68(4)
3.11 Bremsstrahlung and Pair Production -- γ
72(8)
3.12 Critical Energy and Muons -- γ, β
80(3)
3.13 Neutrino Beams and Muons
83(1)
3.14 Electromagnetic Cascade -- X0, Δi
84(5)
3.15 Drift and Diffusion -- x, y
89(6)
3.16 Detector Gas Gain
95(6)
3.17 Solid State Detectors
101(11)
3.18 Coaxial Cables
112(2)
3.19 Particle Tracking -- x, α, p
114(4)
3.20 General Purpose Experiments
118(3)
4 Accelerator Instrumentation
121(92)
4.1 Summary of Accelerator Parameters -- α, β, γ, ε
121(8)
4.2 FODO
129(5)
4.3 Dispersion -- δ
134(4)
4.4 Acceleration -- y, Δε Δ&ph;
138(7)
4.5 Electric Fields at β-1
145(2)
4.6 Fourier Series and FFT
147(4)
4.7 Induced Charge -- Beam Pipe
151(4)
4.8 Beam Position Monitor -- x, y
155(2)
4.9 Transverse Beam Position -- ε δ
157(4)
4.10 BPM and "Accelerator" Tune -- μ, Q, β
161(3)
4.11 Quad Kick and Beta -- β, σ
164(6)
4.12 Multiturn and Phase -- Q, Β, &lapha;
170(4)
4.13 External Loss Monitors
174(2)
4.14 Beam Current Transformer
176(4)
4.15 Beam Emittance -- ε
180(4)
4.16 Luminosity Measurement
184(6)
4.17 Longitudinal Acceptance -- δ, η
190(4)
4.18 Strip Lines
194(4)
4.19 Synchrotron Radiation -- γ
198(7)
4.20 Laser Backscatter -- ε0
205(3)
4.21 Optical Transition Radiation -- γ
208(5)
5 Summary
213(2)
Appendix A Matlab Scripts 215(14)
Appendix B Physics Constants 229(2)
Appendix C Properties of Elements 231(2)
Appendix D Index of Refraction -- Gases and Liquids 233(1)
Appendix E Table of Symbols 234(3)
Appendix F Acronyms 237(2)
References 239(4)
Index 243