CompPhysics
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 # Quantum Computing and Quantum Machine Learning 
 
-The first part of the course (project 1 and till mid march) has its focus on studies of
-quantum-mechanical many-particle systems using quantum computing
-algorithms and quantum computers. The second part is optional and
-depends on the interests and backgrounds of the participants. Two main
-themes can be covered:
-- Quantum machine learning algorithms, implementations and studies
-- Realization and studies of entanglement in physical systems
+The first part of the course (project 1 and till mid march) has its
+focus on studies of quantum-mechanical many-particle systems using
+quantum computing algorithms and quantum computers. The second part is
+optional and depends on the interests and backgrounds of the
+participants. The lectures cover mainly quantum machine learning
+algorithms with an emphasis on variational quantum algorithms for
+NISQ-era quantum computers.  We discuss for example quantum for
+neural networks, quantum support vector machines, quantum Boltzmann
+machines and the QAOA algorithm. Fault-tolerant algorithms like
+quantum Fourier transforms, quantum phase estimation and the HHL
+algorithm are also discussed.
+
+
 - Advanced VQE and hamiltonian systems
+
 ### Possible  textbooks:
 - Maria Schuld and Francesco Petruccione, Machine Learning with Quantum Computers, see https://link.springer.com/book/10.1007/978-3-030-83098-4
 - Wolfgang Scherer, Mathematics of Quantum Computing, see https://link.springer.com/book/10.1007/978-3-030-12358-1
@@ -158,4 +165,5 @@ themes can be covered:
 
 ## May 18-22, 2026
   - Quantum Boltzmann machines (continued from previous week) and summary of course and discussion of and work on project 2
-  - Teaching material in different formats at https://github.com/CompPhysics/QuantumComputingMachineLearning/tree/gh-pages/doc/pub/week17, see PDF file and jupyter-notebook. The jupyter-notebook is a companion to the PDF file
+  - Teaching material in different formats at https://github.com/CompPhysics/QuantumComputingMachineLearning/tree/gh-pages/doc/pub/week17, see PDF file and jupyter-notebook. The jupyter-notebook is a companion to the PDF file
+  - Video of summary lecture at https://youtu.be/us6iGf1niBE