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Avd. f. byggnadsmekanik · LTH · Box 118, 221 00 · Lund · Tel: 046-222 73 70 · Fax: 046-222 44 20 · www.byggmek.lth.se · xp5097(9905) Examensarbete vid Byggnadsmekanik och Teknisk geologi STOKASTISK FE-MODELLERING AV GRUNDVATTENFLÖDE I SPRICKAKVIFER Syftet med detta examensarbete är att utveckla en metod som med hjälp av data från uppmätta grundvattennivåer kan karakterisera en akvifers ström- ning

https://www.byggmek.lth.se/fileadmin/byggnadsmekanik/education/masterprojects/descriptions/xp5097.pdf - 2026-04-21

Avd. f. byggnadsmekanik · LTH · Box 118, 221 00 · Lund · Tel: 046-222 73 70 · Fax: 046-222 44 20 · www.byggmek.lth.se · xp5099(9909) Examensarbete vid Byggnadsmekanik UTVECKLING AV TAKSTOLSPROGRAM Examensarbetet går ut på att utveckla ett takstolsprogram som tar hänsyn till styvheten i spikplåtsförband. Dagens kommersiella takstolsprogram räknar med antingen fullständig sam- verkan eller helt efte

https://www.byggmek.lth.se/fileadmin/byggnadsmekanik/education/masterprojects/descriptions/xp5099.pdf - 2026-04-21

LUND UNIVERSITY | LUND INSTITUTE OF TECHNOLOGY Division of Structural Mechanics | Sweden 1998 | Report TVSM-3035 METHODS FOR AIRCRAFT NOISE AND VIBRATION ANALYSIS MATS GUSTAVSSON LUND UNIVERSITY | LUND INSTITUTE OF TECHNOLOGY Division of Structural Mechanics | Sweden 1998 | Report TVSM-3035 CODEN: LUTVDG / (TVSM-3035) / 1-81 / (1998) | ISSN 0281-6679 METHODS FOR AIRCRAFT NOISE AND VIBRATION ANALYS

https://www.byggmek.lth.se/fileadmin/byggnadsmekanik/publications/tvsm3000/web3035.pdf - 2026-04-21

Structural Mechanics Department of Mechanics and Materials PER-ERIK AUSTRELL och MARTIN JÖNSSON ANALYS AV NÅGRA AXIALSYMMETRISKA GUMMIKOMPONENTER Rapport inom NUTEK-VAMP Denna sida skall vara tom! Copyright © 1999 by Structural Mechanics, LTH, Sweden. Printed by Universitetstryckeriet, Lund, Sweden. For information, address: Division of Structural Mechanics, LTH, Lund University, Box 118, SE-221 0

https://www.byggmek.lth.se/fileadmin/byggnadsmekanik/publications/tvsm7000/web7129.pdf - 2026-04-21

Structural Mechanics SIMON AICHER, PER JOHAN GUSTAFSSON (Editor), PEER HALLER and HANS PETERSSON FRACTURE MECHANICS MODELS FOR STRENGTH ANALYSIS OF TIMBER BEAMS WITH A HOLE OR A NOTCH - A Report of RILEM TC-133 Denna sida skall vara tom!

https://www.byggmek.lth.se/fileadmin/byggnadsmekanik/publications/tvsm7000/web7134.pdf - 2026-04-21

Microsoft Word - Rapport provningsresultat 2006 Part1 Ver2.doc Structural Mechanics Report TV SM -7149 PER JO H A N G U STA FSSO N TESTS O F FU LL SIZE R U B B ER FO IL A D H ESIV E JO IN TS PER JOHAN GUSTAFSSON TESTS OF FULL SIZE RUBBER FOIL ADHESIVE JOINTS Detta är en tom sida! Copyright © 2007 by Structural Mechanics, LTH, Sweden. Printed by KFS i Lund AB, Lund, Sweden, May 2007. For informatio

https://www.byggmek.lth.se/fileadmin/byggnadsmekanik/publications/tvsm7000/web7149.pdf - 2026-04-21

Adaptive Control Bo Bernhardsson and K. J. Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and K. J. Åström Adaptive Control Adaptive Control 1 Introduction 2 Model Reference Adaptive Control 3 Recursive Least Squares Estimation 4 The Self-Tuning Regulator 5 Real Adaptive Controllers 6 Summary Bo Bernhardsson and K. J. Åström Adaptive Control Introduction Adapt to adjus

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/AdaptiveControl.pdf - 2026-04-21

IQC toolbox IQC toolbox Gustav Nilsson May 25, 2016 IQC - Integral Quadratic Constraints • A unifying framework for systems analysis • Generalizes stability theorems such as small gain theorem and passivity theorem • Generalizes many concepts from robust control analysis • (Fairly) easy to build computer tools (convex optimization) Outline • Some theory on IQC • IQCβ toolbox • Live demo ICQ - Theo

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/GustavNilssonIQC.pdf - 2026-04-21

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https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/KTH_labmanual.pdf - 2026-04-21

() Pole Placement Design Bo Bernharsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernharsson and Karl Johan Åström Pole Placement Design Pole Placement Design 1 Introduction 2 Simple Examples 3 Polynomial Design 4 State Space Design 5 Robustness and Design Rules 6 Model Reduction 7 Oscillatory Systems 8 Summary Theme: Be aware where you place them! Bo Bernharss

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/PolePlacement.pdf - 2026-04-21

() Robust Control, H∞, ν and Glover-McFarlane Bo Bernharsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernharsson and Karl Johan Åström Robust Control, H∞, ν and Glover-McFarlane Robust Control 1 MIMO performance 2 Robustness and the H∞-norm 3 H∞-control 4 ν-gap metric 5 Glover-MacFarlane Theme: You get what you ask for! Bo Bernharsson and Karl Johan Åström Rob

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/Robust.pdf - 2026-04-21

ACC 1990 Benchmark Example References ACC 1990, pp. 961-962, The problem ACC 1990, pp. 963-973, Several Solutions ACC 1991, pp. 1931-1932, Mats Liljas design and comments The problem is to design a controller for a scalar linear system consisting of two-mass spring system. There are 4 states.

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/acc90.html - 2026-04-21

Aircraft dynamics with wind gust turbulence References Anderson and Moore p 222 The problem is to damp out the turbulence giving forward and aft acceleration on an aircraft. The model is of order 6. There is one input: rudder position. Matlab-code Model and code in fig822.m .

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/anderson222.html - 2026-04-21

ex02.dvi Exercise Session 2 1. Describe your results on Handin 1. 2. Sketch the Nichols curves for the following systems 1 s(s + 1)(s + 10) , 1 1 − s , exp (−s) 1 + s , 1 − s s(1 + s) , 1 s2 + 2ζs + 1 , (ζ small) For what feedback gains is the closed loop system stable? 3. Plot the root-loci for the following systems s s2 − 1 , (s + 1)2 s3 , 1 s(s2 + 2ζs + 1) , (ζ small) 4. Transform the systems i

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ex02.pdf - 2026-04-21

ex4.dvi Exercise 4 Poleplacement and PID 1. Use Euclid’s algorithm to find all solutions to the equation 7x+ 5y = 6 where x and y are integers. 2. Use Euclid’s algorithm to find all solutions to the equation s2 x(s) + (0.5s+ 1)y(s) = 1 where x(s) and y(s) are polynomials. Use the results to find a solution to the equation s2 f (s) + (0.5s+ 1)(s) = (s2 + 2ζcω cs+ω2 c)(s 2 + 2ζoωos+ω2 o) such that t

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ex4.pdf - 2026-04-21

ex6.dvi Exercise 6 LQG and H∞ 1. Use the appropriate Riccati equation to prove the Kalman filter identity R2 + C2(sI − A)−1 R1(−sI − AT)−1CT 2 = [Ip + C2(sI − A)−1 L]R2[Ip + C2(−sI − AT)−1 L]T Use duality to deduce the return difference formula Q2 + BT(−sI − AT)−1Q1(sI − A)−1B = [Im + K(−sI − AT)−1B]T Q2[Im + K(sI − A)−1B] 2. Consider the Doyle-Stein LTR example from the LQG lecture G(s) = s+ 2 (s

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ex6.pdf - 2026-04-21

Extremum-seeking Control Extremum-seeking Control Tommi Nylander and Victor Millnert May 25, 2016 1 / 14 Short introduction I Non-model based real-time optimization I When limited knowledge of the system is available I E.g. a nonlinear equilibrium map with a local minimum I Popular around the middle of the 1950s I Revival with proof of stability 1 I Very attractive with the increasing complexity o

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/extremum-seeking-tommi-victor.pdf - 2026-04-21

() Gain Scheduling Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Gain Scheduling Gain Scheduling What is gain scheduling ? How to find schedules ? Applications What can go wrong ? Some theoretical results LPV design via LMIs Conclusions To read: Leith & Leithead, Survey of Gain-Scheduling Analysis & Design To try ou

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/gainscheduling.pdf - 2026-04-21

() Handin 1 Bo Bernhardsson, K. J. Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson, K. J. Åström Handin 1 Handin 1 - goals Get some practice using the Matlab control system toolbox (or similar) Get started with some control design Bo Bernhardsson, K. J. Åström Handin 1 Example - Double Integrator Consider the double integrator y = 1 s2 u controlled with state-feedback +

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/handin1.pdf - 2026-04-21

() Handin 3 Consider the (broomstick) system p2 s2 − p2 with p = 6 rad/s ((1 feet). Hint: You might find it useful to read or watch Gunter Stein’s Bode Lecture. a) Find a stabilizing controller achieving pT(iω)p < (Ωa/ω) 2, when ω > Ωa = 10 rad/s Ms := max ω pS(iω)p < 10 b) Try to get as low Ms you can, while maintaining the requirement on T. Bonus: Try to find a theoretical lower bound on Ms (the

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/handin3.pdf - 2026-04-21