After successful completion of the course, students are able to set up and evaluate econometric energy demand models. Furthermore, students are able to develop and solve optimization models (linear, non-linear, dynamic).

06.03.2023 (Haas): Introduction, overview of model types, objective functions, solution approaches

13.03.2023 (Haas): Modeling of energy policy instruments, introduction to econometrics, econometric demand models

27.03.2023 (Perger): Continuation - econometric demand models (cross-sectional / time-series analyzes), exercise 1

17.04.2023 (Golab): Linear optimization: theory and introduction

24.04.2023 (Golab): Source-code development (Python) incl. LP/MILP example in energy economics, exercise 2

08.05.2023 (Golab): Dual / primal optimization model

15.05.2023 (Golab): Example in energy economics: power plant dispatch (incl. consideration of duality), exercise 3

22.05.2023 (Zwickl-Bernhard): Nonlinear optimization

05.06.2023 (Zwickl-Bernhard/Auer): Selected examples in energy economics - nonlinear optimzation, exercise 4 (part 1); Introduction into dynamic optimization

12.06.2023 (Auer): Continuation of dynamic optimization; Selected examples in energy economics - dynamic optimzation, exercise 4 (part 2)

19.06.2023 (Auer): Application of dynamic optimization - theory of optimal resource depletion (fossil, renewable); discussion of the exercises

26.06.2023 (Auer): Written exam

Basic principles and application of:

• Econometric methods (regression analysis, ...)
• Linear optimization (simplex algorithm, optimization in Python, ...)
• Non-linear optimization (Karush-Kuhn-Tucker conditions, ...)
• Dynamic optimization (Bellman equation with recursive function, ...)

in the form of

• Presentation of the theoretical principles
• Discussion with students
• Joint working out of case studies
• Calculation of own exercise examples
• Written elaboration/exercises of homeworks
• Development of own source codes in Python

The overall grade (100% of the total achievable points) consists of 2 parts:

50% of the total points can be achieved from the 4 exercises that have to be worked out and delivered during this course. The number of points per exercise can vary and will be announced at the presentation of the exercises.

50% of the total points can be achieved in the written exam at the end of the semester. This written exam consists of 5 questions (10% each), the vast majority of these questions being simple (arithmetical) examples, using the basic principles of econometrics and optimization.

IMPORTANT:

BOTH in the exercises AND in the written exam, HALF of the number of possible points must be achived in order to get a POSITIVE overall grade of this course. It is not enough to achieve a total of more than 50% of the possible total points of this course, but less than 25% in one of the two parts.

In this course great emphasis is put on understanding the basic principles in modeling in general and in econometrics and optimization in particular.

In the written exam, a non-programmable calculator is allowed, but not mandatory. The (arithmetic) examples are designed in such a way that the determination of extensive quantitative results is not in the foreground. Rounding of results is allowed / desired.

Physical attendance in this course is HIGHLY (!) recommended; not least to better understand the theoretical background/methodologies and to avoid misunderstandings in the excercise tasks and delivery rountines

The following documents are available for download on TUWEL:

- Script: Energy modeling and analyzes

- ppt slide set per lecture/unit

- Several necessary documents in the context of the exercises (research questions, Python files, submission)

- In general, no special knowledge is required

- Analytical thinking and willingness to learn autonomous source-code development in Python must be present

- There should be interest in interdependences in energy economics