Springer Nature, 2020

Cham, Switzerland : , : Springer Nature Switzerland AG. : , : imprint : SpringerOne, , [2020]

©2020

3-030-35318-4

1 online resource (IX, 1078 pages) : illustrations; digital, PDF file(s)

539.73

Particle acceleration

Physical measurements

Measurement   

Elementary particles (Physics)

Quantum field theory

Nuclear physics

Heavy ions

Nuclear energy

Particle Acceleration and Detection, Beam Physics

Measurement Science and Instrumentation

Elementary Particles, Quantum Field Theory

Nuclear Physics, Heavy Ions, Hadrons

Nuclear Energy

Inglese

Includes bibliographical references.

Chapter 1. Introduction -- Chapter 2. The Interaction of Radiation with Matter -- Chapter 3. Scintillation Detectors for Charged Particles and Photons -- Chapter 4. Gaseous Detectors -- Chapter 5. Solid State Detectors -- Chapter 6. Calorimetry -- Chapter 7. Particle Identification: Time-of-Flight, Cherenkov and Transition Radiation Detectors -- Chapter 8. Neutrino Detectors -- Chapter 9. Nuclear Emulsions -- Chapter 10. Signal Processing for Particle Detectors --

Chapter 11. Detector Simulation -- Chapter 12. Triggering and High-Level Data Selection -- Chapter 13. Pattern Recognition and Reconstruction -- Chapter 14. Distributed Computing -- Chapter 15. Statistical Issues in Particle Physics -- Chapter 16. Integration of Detectors Into a Large Experiment: Examples From ATLAS andCMS -- Chapter 17. Neutrino Detectors under Water and Ice -- Chapter 18. Space Borne Experiments -- Chapter 19. Cryogenic Detectors -- Chapter 20. Detectors in Medicine and Biology -- Chapter 21. Solid State Detectors for High Radiation Environments -- Chapter 22. Future Developments of Detectors.

This second open access volume of the handbook series deals with detectors, large experimental facilities and data handling, both for accelerator and non-accelerator based experiments. It also covers applications in medicine and life sciences. A joint CERN-Springer initiative, the “Particle Physics Reference Library” provides revised and updated contributions based on previously published material in the well-known Landolt-Boernstein series on particle physics, accelerators and detectors (volumes 21A,B1,B2,C), which took stock of the field approximately one decade ago. Central to this new initiative is publication under full open access.

Hoboken, N.J. : , : John Wiley & Sons, , 2013

©2013

1-118-40257-X

1-283-94994-6

1-118-33268-7

1 online resource (458 pages) : illustrations

624.2/52

Bridges - Design and construction

Bridges - Evaluation

Bridges - Maintenance and repair

Load factor design

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Cover; Title Page; Copyright; Contents; Preface; Chapter 1 Introduction; 1.1 Bridge Engineering and Highway Bridge Network; 1.2 Types of Highway Bridges; 1.3 Bridge Construction and Its Relation to Design; 1.4 AASHTO Specifications and Design and Evaluation Methods; 1.5 Goals for Bridge Design and Evaluation; 1.6 Preliminary Design versus Detailed Design; 1.7 Organization of This Book; References; Chapter 2 Requirements for Bridge Design and Evaluation; 2.1 General Requirements; 2.2 Limit States; 2.2.1 General Formulation of Limit State Load Combination; 2.2.2 Strength Limit State

2.2.3 Extreme-Event Limit State; 2.2.4 Service Limit State; 2.2.5 Fatigue and Fracture Limit State; 2.3 Constructability; 2.4 Safety; 2.4.1 Uncertainty in Design and Evaluation; 2.4.2 Modeling Uncertainty Using Probability Theory; 2.4.3 Reliability Index for Quantifying Bridge Reliability or Safety; 2.4.4 Reliability Considerations for Bridge Design and Evaluation (Load Rating); 2.4.5 Calibration for AASHTO LRFD Specifications; 2.4.6 Determination of Load and Resistance Factors for AASHTO LRFD Specifications; 2.4.7 Calibration for AASHTO LRFR Specifications

2.4.8 Future Research Work for Calibration; 2.5 Serviceability; 2.5.1 Clearance; 2.5.2 Durability; 2.5.3 Maintainability; 2.5.4 Rideability; 2.5.5 Deformation Control; 2.5.6 Utilities; 2.5.7 Allowance for Future Widening; 2.6 Inspectability; 2.7 Economy; 2.8 Aesthetics; 2.9 Summary; References; Problems; Chapter 3 Loads, Load Effects, and Load Combinations; 3.1 Introduction; 3.2 Permanent Loads; 3.2.1 Dead Loads DC, DW, and DD; 3.2.2 Permanent Earth Loads EH, EV, and ES; 3.2.3 Other Permanent Loads; 3.3 Transient Loads; 3.3.1 Vehicle-Related Transient Loads

3.3.2 Non-Vehicle-Related Transient Loads; 3.4 Load Combinations; 3.4.1 General Formulation of Load Combination; 3.4.2 Strength Limit States and Load Factors; 3.4.3 Extreme-Event Limit States and Load Factors; 3.4.4 Service Limit States and Load Factors; 3.4.5 Fatigue Limit States; References; Problems; Chapter 4 Superstructure Design; 4.1 Introduction; 4.2 Highway Bridge Superstructure Systems; 4.2.1 Beam Bridges; 4.2.2 Truss Bridges; 4.2.3 Arch Bridges; 4.2.4 Cable-Stayed Bridges; 4.2.5 Suspension Bridge Systems; 4.3 Primary Components of Highway Bridge Superstructure; 4.4 Deck Systems

4.4.1 Reinforced Concrete Slab System; 4.4.2 Timber Deck System; 4.4.3 Metal Grid Deck System; 4.4.4 Orthotropic Steel Deck System; 4.4.5 Fiber-Reinforced Polymer Deck System; 4.5 Deck-Supporting Systems; 4.5.1 Prestressed Concrete Beams; 4.5.2 Steel Beams; 4.5.3 Slab Superstructure; 4.5.4 Steel Trusses; 4.5.5 Concrete Arches; 4.5.6 Steel Arches; 4.6 Design of Reinforced Concrete Deck Slabs; 4.6.1 Design Requirement and Parameters; 4.6.2 General Traditional Design Method and Empirical Design Method; 4.6.3 Traditional Design; 4.6.4 Dead- and Live-Load Effects for Interior Bays; 4.6.5 Strength I and Service I Limit State Design for Interior Bays

A succinct, real, world approach to complete bridge system design and evaluation/b/ Load and Resistance Factor Design (LRFD) and Load and Resistance Factor Rating (LRFR) are design and evaluation methods that have replaced or offered alternatives to other traditional methods as the new standards for designing and load, rating U.S. highway bridges. Bridge Design and Evaluation covers complete bridge systems (substructure and superstructure) in one succinct, manageable package. It presents real, world bridge examples demonstrating both their design and evaluation using LRFD and LRFR. Designed for a 3, to 4,credit undergraduate or graduate, level course, it presents the fundamentals of the topic without expanding needlessly into advanced or specialized topics. Important features include: Exclusive focus on LRFD and LRFR/Hundreds of photographs and figures of real bridges to connect the theoretical with the practical. Design and evaluation examples from real bridges including actual bridge plans and drawings and design methodologies/Numerous exercise problems/Specific design for a 3, to 4,credit course at the undergraduate or graduate level/The only bridge engineering textbook to cover the important topics of bridge evaluation and rating, Bridge Design and Evaluation is the most up, to, date and inclusive introduction available for students in civil engineering specializing in structural and transportation engineering