Apply for The Good Lecture Apply for The Good Lecture Av Caroline Cabot - Publicerad den 11 augusti 2023 The Good Lecture is an elective course within the qualifying programme in teaching and learning in higher education at Lund University. Next course starts autumn 2023 and last day to apply is 14 August. The Good Lecture is an elective course within the qualifying programme in teaching and learn

https://www.ahu.lu.se/article/apply-for-the-good-lecture/ - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/artiklar/28 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/artiklar/6 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/bocker/6 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/bocker/8 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/kapitel/6 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/konferensbidrag/6 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/recensioner/7 - 2025-05-04

Publications | Department of Archaeology and Ancient History

https://www.ark.lu.se/en/research/publications/recensioner/9 - 2025-05-04

() Bottom-Up Architectures Bo Bernhardsson and K. J. ÃĚstrÃűm Department of Automatic Control LTH, Lund University Bo Bernhardsson and K. J. ÃĚstrÃűm Bottom-Up Architectures Bottom-Up Architectures 1 Introduction 2 Basic Architectures 3 Large Parameter Variations 4 Otto J. M. Smith’s Specials 5 Miscellaneous 6 Soft Computing 7 Summary Theme: Brick by brick. Bo Bernhardsson and K. J. ÃĚstrÃűm Botto

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/BottomUp.pdf - 2025-05-04

() Iterative Learning Control (ILC) Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Iterative Learning Control (ILC) ILC ILC - the main idea Time Domain ILC approaches Stability Analysis Example: The Milk Race Frequency Domain ILC Example: Marine Vibrator Material: Bo Bernhardsson and Karl Johan Åström Iterative Learn

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ILC.pdf - 2025-05-04

Control System Design - Interaction Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Control System Design - Interaction Interaction 1 Introduction 2 Interaction of Simple Loops 3 Multivariable zeros 4 Decoupling 5 Parallel Systems 6 Summary Theme: When the wires get crossed Bo Bernhardsson and Karl Johan Åström Contro

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/Interaction.pdf - 2025-05-04

() Loop Shaping Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Loop Shaping Loop Shaping 1 Introduction 2 Loop shaping design 3 Bode’s ideal loop transfer funtion 4 Minimum phase systems 5 Non-minimum phase systems 6 Fundamental Limitations 7 Performance Assessment 8 Summary Theme: Shaping Nyquist and Bode Plots Bo B

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/Loopshaping.pdf - 2025-05-04

() Model Predictive Control (MPC) Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Model Predictive Control (MPC) Model Predictive Control (MPC) MPC Problem Setup and Parameters Optimization Problem MPC Tools How to get Integral Action Example - Quad Tank Explicit MPC and CVXGEN Material: Rawlings (2000), Tutorial over

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/MPC.pdf - 2025-05-04

Control System Design - PID Control Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Control System Design - PID Control Control System Design - PID Control 1 Introduction 2 The Basic Controller 3 Performance and Robustness 4 Tuning Rules 5 Relay Auto-tuning 6 Limitations of PID Control 7 Summary Theme: The most common

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/PIDControl.pdf - 2025-05-04

() Control System Design - A Perspective Bo Bernhardsson Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson Karl Johan Åström Control System Design - A Perspective Control System Design - A Perspective 1 Introduction 2 Integrated System and Control Design 3 Control Principles 4 Requirements and Methods 5 Summary Theme: Many things to think about. Bo Bernhardsson

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/Perspective.pdf - 2025-05-04

() Requirements Bo Bernhardsson and Karl Johan Åström Department of Automatic Control LTH, Lund University Bo Bernhardsson and Karl Johan Åström Requirements Requirements and Limitations 1 Introduction 2 The basic feedback system 3 A broad view of control system design 4 Command signal following - System inversion 5 Disturbances 6 Process uncertainty 7 Robustness 8 Summary Theme: Requirements

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/Requirements.pdf - 2025-05-04

ex01.dvi Exercise Session 1 1. To evaluate a controlled system the maximum values of the sensitivity function and the complementary sensitivity functions have been computed giving max ω |S(iω)| = 2.45, max ω |T (iω)| = 1.70 Use these numbers to estimate the largest amplification of disturbances that may occur. Also provide an estimate of the precision in the transfer function required for the clos

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ex01.pdf - 2025-05-04

ex3.dvi Exercise Session 3 1. Describe your results on Handin 2. 2. a) Show that state feedback control u = −Lx̂ + lryr, where x̂ is given by a Kalman filter, can be written as U(s) = −Cfb(s)Y (s) + Cff (s)Yr(s) with Cfb(s) = L(sI − A + BL − KC)−1K Cff (s) = (I − L(sI − A + BL − KC)−1B)lr = (I + L(sI − A + KC)−1B)−1lr b) Show that the controller above can be written as R(s)U = −S(s)Y + T (s)Yr wit

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ex3.pdf - 2025-05-04

ex5.dvi Exercise 5 BottomUp and Interaction 1. Explain why the standard Smith predictor does not work for processes with integration or unstable dynamics. 2. Smith’s controller for a process P(s) = P0(s)e −sL with time delay is given by C(s) = C0(s)Cpred(s), Cpred(s) = 1 1+ P0(s)C0(s)(1− e−sL) where C0 is the nominal controller for the process P0 without delay and L is the time delay. The transfer

https://www.control.lth.se/fileadmin/control/Education/DoctorateProgram/ControlSystemsSynthesis/2016/ex5.pdf - 2025-05-04