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18cs493 [2018-07-05] – [Synopsis] Martin Ziegler18cs493 [2018-07-25] (current) – written exam Martin Ziegler
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 in E3-1 #3444 in E3-1 #3444
 ==== Synopsis ==== ==== Synopsis ====
-  - {{18cs493a.pdf|Introduction and Motivation}} +  - {{18cs493a.pdf|Introduction and Motivation}} ({{18cs493a.ppt|ppt}}) 
-  - {{18cs493b.pdf|Discrete Computation}}: +  - {{18cs493b.pdf|Discrete Computation}} ({{18cs493b.ppt|ppt}})
     * Halting Problem     * Halting Problem
     * Un/Semi/Decidability/Enumerability      * Un/Semi/Decidability/Enumerability 
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     * Complexity classes P, NP, EXP     * Complexity classes P, NP, EXP
     * (Polynomial-time) Reduction     * (Polynomial-time) Reduction
-  - Computing over the Reals+  - {{18cs493c.pdf|Computing over the Reals}} ({{18cs493c.ppt|ppt}})
      * Computable Real numbers: non/equivalent notions      * Computable Real numbers: non/equivalent notions
      * Equality, real sequences and limits      * Equality, real sequences and limits
      * Computing real functions, Effective Weierstrass Theorem      * Computing real functions, Effective Weierstrass Theorem
      * Computational cost, compactness, and continuity      * Computational cost, compactness, and continuity
-     * Root finding and uncomputable argmax +     * Uncomputable derivative 
-     * Uncomputable derivative/wave equation+  - {{18cs493d.pdf|Exact Real Computation}} ({{18cs493d.ppt|ppt}})
      * Non-extensionality, discrete enrichment      * Non-extensionality, discrete enrichment
-  - Real Complexity Theory 
-     * Real arithmetic, join, maximum, integral 
-     * Polynomial-time un/computable reals 
-     * Polynomial-time un/computable functions 
-     * Maximizing smooth functions and P/NP 
-     * Riemann Integration and #P, ODEs and PSPACE 
-     * Complexity Phase Transition and Gevrey's Hierarchy 
-  - Practice of Exact Real Computation 
-     * iRRAM library 
      * Semantics of tests and choose()      * Semantics of tests and choose()
 +     * iRRAM library
      * Example Algorithms      * Example Algorithms
 +  - {{18cs493e.pdf|Real Complexity Theory}} ({{18cs493e.ppt|ppt}})
 +     * Polynomial-time reals
 +     * Polynomial-time functions
 +     * Maximizing smooth functions and P/NP
 +     * Riemann Integration and #P, ODEs and PSPACE
  
 ==== Reading List ==== ==== Reading List ====
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   * Norbert Müller: [[https://doi.org/10.1007/3-540-45335-0_14|The iRRAM: Exact Arithmetic in C++]] (2000).   * Norbert Müller: [[https://doi.org/10.1007/3-540-45335-0_14|The iRRAM: Exact Arithmetic in C++]] (2000).
   * Norbert Müller: [[http://www.informatik.uni-trier.de/iRRAM/|iRRAM C++ Library]].   * Norbert Müller: [[http://www.informatik.uni-trier.de/iRRAM/|iRRAM C++ Library]].
-  * [[http://theoryofcomputation.asia/18TODAI/todai.ppt|Slides (to be updated)]]+
 ==== Suggested Literature ==== ==== Suggested Literature ====
   * Ker-I Ko: Complexity Theory of Real Functions, Birkhäuser (1991).   * Ker-I Ko: Complexity Theory of Real Functions, Birkhäuser (1991).
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   * Akitoshi Kawamura, Florian Steinberg, Martin Ziegler: On the Computational Complexity of the Dirichlet Problem for Poisson's Equation, Mathematical Structures in Computer Science (2017).   * Akitoshi Kawamura, Florian Steinberg, Martin Ziegler: On the Computational Complexity of the Dirichlet Problem for Poisson's Equation, Mathematical Structures in Computer Science (2017).
  
 +==== E-Learning ====
 +  * [[http://klms.kaist.ac.kr/|KLMS]]
 +  * {{18cs493i.pdf|Homework #1}} consists of four problems to be solved and submitted in English by midnight of July 9 (Monday) via [[mailto:cs493@theoryofcomputation.asia|email]].
 +  * {{18cs493ii.pdf|Homework #2}} consists of one large problem to be solved and submitted in English **on paper** in the lecture on July 17 (Tuesday) 
 +  * {{18cs493iii.pdf|Homework #3}} consists of two problems. Problem 6 is to be solved and submitted in English **on paper** in the lecture on July 24 (Tuesday). Problem 7 is to be solved and submitted in English via [[mailto:cs493@theoryofcomputation.asia|email]] before the lecture on July 24 (Tuesday).
 +  * {{18cs493exam.pdf|Written Exam}} on July 25 with 30% bonus points