Jan 30, 2002 - A SCADA system is a software package that integrates the different components .... the IT helpdesk (Windows, Linux, WWW, applications e.g. Exceed, etc.) ... Application dependant help will be organised in ST-MA (Free Piquet ...
Some of the SGML layouts will automatically number the bibliography list. To gain ...... . If the output dev
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May 15, 2018 - [16] M. Wobisch, K. Chakravarthula, R. Dhullipudi, L. Sawyer, and M. ...... J. Lorenz112, N. Lorenzo Martinez5, M. Losada22, P.J. Lösel112,.
May 16, 2018 - 1 ATLAS uses a right-handed coordinate system with its origin at the nominal .... new jet kinematic variables are calculated. A final ...... 121Department of Physics, New York University, New York NY; United States of America.
Jan 23, 2018 - Japan; CNRST, Morocco; NWO, Netherlands; RCN, Norway; MNiSW .... and P. Skands, PYTHIA 6.4 physics and manual, JHEP 05 (2006) 026,.
Jan 1, 2019 - 2019 CERN for the benefit of the ATLAS Collaboration. ...... 6. 10. 7. 10. ATLAS. -1. = 13 TeV, 36.1 fb s. ) search b. tqH(b. Pre-Fit. â¬. â¬. Data.
Nov 30, 2018 - Htt. Vtt. Single top. *+jets γ. Z/. Diboson. NP & fake lep. Syst. ATLAS. -1. = 13 TeV ...... [42] A. D. Martin, W. J. Stirling, R. S. Thorne and G. Watt, .... [83] ATLAS Collaboration, ATLAS Computing Acknowledgements, ATL-GEN-PUB-2016
Aug 8, 2016 - In CRST, the requirement on the invariant mass of the two highest-weight b-tagged jets, mbb, is used to reject t¯tcontamination from the control ...
Mar 8, 2018 - excluded assuming three generations of mass-degenerate sleptons. ...... Low-Energy Predictions in Supersymmetric Grand Unified Theories, ...... 77 Oliver Lodge Laboratory, University of Liverpool, Liverpool, United Kingdom.
Jul 6, 2018 - B. Ali. 138. ,. G. Alimonti. 66a. , J. Alison. 36. , S.P. Alkire. 145. , C. Allaire. 128 ... J.P. Araque. 136a ...... R.M. Faisca Rodrigues Pereira. 136a.
Sep 19, 2018 - of two same-flavor opposite-sign leptons l with |mll â mZ | < 25GeV. ...... [37] ATLAS Collaboration, Trigger Menu in 2016, ATL-DAQ-PUB-2017-001, ...... 134Department of Physics, University of Pennsylvania, Philadelphia PA; ...
Nov 20, 2018 - 2018 CERN for the benefit of the ATLAS Collaboration. ... 6.1 Reconstruction of prompt hadronic jets and missing transverse momentum. 10.
Oct 4, 2018 - Japan; CNRST, Morocco; NWO, Netherlands; RCN, Norway; ...... and P. Z. Skands, PYTHIA 6.4 physics and manual, JHEP 05 (2006) 026,.
Jul 30, 2018 - Oskar Klein Centre, Stockholm; Sweden. 44Deutsches .... 113Max-Planck-Institut für Physik (Werner-Heisenberg-Institut), München; Germany.
Aug 7, 2018 - Many theories beyond the Standard Model (SM) are motivated by the ...... [65] ATLAS Collaboration, Optimisation of the ATLAS b-tagging ...
Jun 7, 2018 - be taken manually by experts, or subject to certain criteria the DCS system can ...... Japan; CNRST, Morocco; NWO, Netherlands; RCN, Norway; ...
Sep 3, 2018 - 95% CL limit on. Obs. Obs. Obs. Obs. Obs. Obs. = 200 GeV. X for m Ï1 ...... of Physics, TOBB University of Economics and Technology, Ankara; ...
Jul 18, 2018 - the same quark couplings and chiral structure as the SM Z boson but only ...... [65] ATLAS Collaboration, Performance of missing transverse ...
Oct 12, 2018 - Morocco; NWO, Netherlands; RCN, Norway; MNiSW and NCN, Poland; .... P. Z. Skands, PYTHIA 6.4 physics and manual, JHEP 05 (2006) 026,.
Jan 3, 2010 - The energy per particle emitted into dξ dÏ dÏ is given by Hofmann [4]: ...... 4 Albert Hofmann, The Physics of Synchrotron Radiation, Cambridge ...
Mar 17, 1970 - 1. ATOMIC AND MOLECULAR PHYSICS. 1.1 The hydrogen atom ... 3.4.3 Becoming neutrons ... 2 -. The electron, circling arcund the proton, has a potential energy V ... Here r is the average distance from the proton, and p is the no- .... In
Oct 8, 2010 - sion line brings the RF power down to the tunnel, 60 m underground, where ...... real diodes change the rectifiers operation considerably at RF ...
Unit Delay 2.4.3 Discrete-Time Integrator Block 2.4.4 Simple Discrete System Models 2.4.5 Discrete Transfer Function Block 2.4.6 Discrete State-Space Block Nonlinear Blocks Hybrid Block Diagrams Summary References
32
Quick Start
3.1 3.2 3.3 3.4
3.5
Introduction Typographical Conventions 3.1.1 Building a Simple Model A More Complicated Model The Simulink Help System 3.4.1 Opening the User's Guide Browser User's Guide Browser Window . . . . 3.4.2 Summary References
4 Model Building
4.1 4.2 4.3
4.4
4.5
Introduction 4.1.1 Elements of a Model Opening a Model Model Window 4.3.1 Zooming 4.3.2 Block Data Tips 4.3.3 Simulink Block Library Manipulating Blocks 4.4.1 Resizing a Block 4.4.2 Rotating a Block 4.4.3 Copying a Block within a Model 4.4.4 Deleting Blocks 4.4.5 Selecting Multiple Blocks 4.4.6 Changing a Block Label 4.4.7 Changing Label Location 4.4.8 Hiding a Label .4.4.9 Adding a Drop Shadow 4.4.10 Using Color 4.4.11 Configuring Blocks Signal Lines 4.5.1 Moving a Segment 4.5.2 Moving a Vertex 4.5.3 Deleting a Signal Line 4.5.4 Splitting a Signal Line 4.5.5 Labeling a Signal Line
4.5.6 Moving or Copying a Signal Line Label 4.5.7 Editing a Signal Line Label 4.5.8 Signal Label Propagation Annotations ................. . Adding Annotations 4.6.1 Annotation Formatting 4.6.2 Adding Sources Common Sources 4.7.1 4.7.2 From Workspace Block 4.7.3 From File Input Block Adding Sinks Scope Block 4.8.1 4.8.2 XY Graph Data Types Configuring the Simulation 4.10.1 Solver Page 4.10.2 Workspace 1/0 Page 4.10.3 Diagnostics Page 4.10.4 Advanced Page Running a Simulation Printing a Model 4.12.1 Printing to the Printer Using Menus 4.12.2 Embedding the Model in a Document 4.12.3 Using the MATLAB Print Command Model Building Summary Summary References
5 Continuous Systems 5.1 Introduction 5.2 Scalar Linear Systems 5.2.1 Integrator Block 5.2.2 Transfer Function Blocks 5.3 Vector Linear Systems 5.3.1 Vector Signal Lines 5.3.2 State-Space Block 5.4 Modeling Nonlinear Systems 5.4.1 Function Blocks Summary 5.5 References 6 Discrete-Time Systems Introduction 6.1 Scalar Linear Discrete-Time Systems 6.1.1 Unit Delay 6.1.2 Discrete-Time Integrator 6.1.3 Discrete Transfer Function Blocks 6.1.4
Contents xiii 8.7 Optimization Toolbox and Simulink 8.8 Other Toolboxes Useful with Simulink 8.9 Summary References
9 Callbacks 9.1 Introduction 9.2 Callback Function Overview 9.2.1 Callback Installation Dialog Boxes 9.2.2 Installing Callbacks Using set_param 9.3 Model Construction Commands 9.3.1 Finding the Name of the Current Block 9.3.2 Finding the Name of the Current Model 9.3.3 Finding the Name of the Current System 9.3.4 Setting Parameter Values 9.3.5 Reading Parameter Values 9.4 Graphical User Interfaces with Callbacks 9.4.1 Graphic User Interface Callback 9.4.2 Programming Issues 9.5 Callback-Based Animation 9.6 Summary References 10 S-Functions
10.1 Introduction 10.2 S-Function Block 10.3 S-Function Overview 10.4 M-file S-Functions 10.4.1 Initialization (f lag = 0) 10.4.2 Continuous State Derivatives (f lag = 1) 10.4.3 Discrete State Updates (f lag = 2) 10.4.4 Block Outputs (f lag = 3) 10.4.5 Next Sample Time (f lag = 4) . . .... 10.4.6 Terminate (f lag = 9) 10.4.7 Programming Considerations 10.4.8 M-file S-Function Examples 10.5 C Language S-Functions 10.5.1 C File Header 10.5.2 Initializing the Simulation Structure 10.5.3 Defining Sample Times and Offsets 10.5.4 Accessing Model Variables . . . . . . . ...... . . 10.5.5 Setting Initial Conditions 10.5.6 Setting the Output Vector 10.5.7 Updating the Discrete States 10.5.8 Computing the State Derivatives 10.5.9 End-of-Simulation Tasks 10.5.10 C S-Function File Trailer
