SOLUTION: SOLUTION: SOLUTION:
|
|
- Mark Ferguson
- 5 years ago
- Views:
Transcription
1
2
3 Convert R and S into nondeterministic finite automata N1 and N2. Given a string s, if we know the states N1 and N2 may reach when s[1...i] has been read, we are able to derive the states N1 and N2 may reach when s[1...i+1] has been read. Consider the following nondeterministic Turing machine M which tries to guess a string on which exactly one of N1 and N2 accepts. Instead of storing the guessed string, M keeps guessing the next bit of the string and forget about its previous bits. Upon guessing the next bit, M updates the states N1 and N2 may reach after reading the string guessed so far. If after guessing some bit, M finds that exactly one of N1 and N2 may reach an accepting state while the other cannot, M declares N1 and N2 are different and accepts. Note that M runs in polynomial space although it may fail to halt. Clearly N1 and N2 differ if and only if M(R,S) has an accepting
4 computation branch. Applying Savitch's theorem that NPSPACE=PSPACE=coNPSPACE will do the job. Solution: To show GM PSPACE, we assume that P is a grid of X,O and empty with input length is O(n 2 ). Now we will write algorithm, it accept incase of winning strategy for player X with starting point is P. Algorithm: 1. Potential X moves without marking on all spaces i in position P.
5 i. Change the position to p by putting the X marker on space i. if there is 5 X s in a row, accept (good move), if board is full now and no one is winner, reject. ii. else Potential O moves without marking on all spaces j in position P. a. Change the position to P by putting the O on space j. if there is 5 O s in a row or board full and no one is winner then loop to next i, move to step1, poor move by putting an X on i. b. else run GM(p ). if accept then loop to next j and go to step b.,if iii. rejects then loop to the next I and go to step1. If GM(p ) accept due to all j, i good move for X, all possible O moves has been covered, accept. 2. Reject, if no i in step 1 causes accept, bad move from this point, hence reject. We can reuse the space, so O(n 2 ) deep. We require to store configurations P,P at each level, it means we need O(n 2 ) space for maximum n 2 moves. Total space required is O (n 4 ) for polynomial time input length O (n 2 ). Now consider the given problem with 19 X19 grid mean 19 2 spaces on the board with 3 19X19 configurations. It is a big enough. In complexity theory even though a number is too bigger but any expression without variable is just a small constant. We can fit things into our complexity classes by generalizing things to variable length. So we prefer to generalize things to variable length. We have risk of input too small if configuration down as n. if we want to know winning strategy from the start because no markers have been placed. There is required to much space to write down the number n with input length log n. Might be O(n 4 ) spaces are still required for algorithm but it exponential in our input length, this shows that GM PSPACE Solutions: P NP P-SPACE NP P-SPACE Given every NP-Hard language is also PSPACE-Hard want to show that NP =PSPACE. From our assumption we know that if every NP-Hard is also PSPACEHard we know that then every NP-Complete language is also PSPACE-Hard since NP-Hard contains all of the NP-complete problems by definition. So we also know that SAT is PSPACE-Hard. And from the assumption that for any A in PSPACE, A reduces to SAT. Claim then we can solve A in NP. Create a TM, N as follows. on input x, do Compute f(x), the poly-time reduction between A and SAT. Decide whether f(x) is satisfiable, if so, accept, otherwise reject. Claim N decides A since x is in A iff f(x) is in SAT. Also notice that N is an NP machine since computing SAT is in NP
6 Solution: We will reduce TQBF to PUZZLE. Consider any TQBF instance in its CNF form. Let m denote the number of clauses and n denote the number of variables. We will consider an instance of PUZZLE with n cards, each of which corresponds to one of the variables and in the same order as the quantifiers in the TQBF instance. The box have m holes all on the right column. We will define each card as follows: For each row i, the card would have exactly one hole on the right for row i if letting the variable to be true would satisfies the i th clause; it would have exactly one hole on the left if letting the variable to be false would satisfies the clause; let there be two holes otherwise. Each step, the player chooses one side of the cards and hence choose the truth assignment for the corresponding variable (front for true, and back for false). The TQBF instance is satisfied if-and-only-if for each row at least one of the cards blocks the hole, that is, at least one of the literals in the clause has value true.
7 Solution: We first note that the game can have only 2n 2 configurations, defined by position of the cat, position of the mouse and if it is cat s turn. So, we can construct a directed graph consisting of 2n 2 nodes where each node corresponds to a game configuration and there is an edge from node u to node v, if we can go from configuration corresponding to u to configuration corresponding to v in one move. Now following algorithm solves HAPPY-CAT. 1. Mark all nodes (a, a, x) where a is a node in G, and x {true, false}. 2. If for a node u = (a, b, ture), there is a node v = (c, b, false) which is marked and (u, v) is an edge then mark u. 3. If for a node u = (a, b, false), all nodes v = (a, c, false) are marked and (u, v) is an edge then mark u. 4. Repeat steps 2 and 3 until no new nodes are marked. 5. Accept if start node s = (c, m, true) is marked. The algorithm takes O(n 2 ) time to perform step 1, O(n 2 ) time per iteration of the loop and loop is executed O(n 2 ) times. Hence runs in polynomial time. Solution. We know that the class L contains all problems requiring only a fixed number of counters/pointers to solve them. The language A requires one counter. Initially, the counter is 0, and, as the head moves to the right along the tape, the counter is incremented by 1 if the symbol read is (, and it is decremented by 1 if the symbol read is ). If the counter ever becomes negative we reject the string (more closing parentheses then opening ones). If the counter is positive after reading the last symbol in the string, we reject (more opening parentheses then closing ones). Otherwise, we accept.
8
9
10 Solution I show that BIPARTITE NL. Since NL = conl, the desired result follows. An undirected graph G is not bipartite, if and only if G contains an odd cycle. Given G, we then search for odd cycles non deterministically using log-space. First nondeterministically choose a vertex u V(G) and remember u till the end of all branches of computation originating from the selection of u. Also maintain a current vertex v and a count i. Initially set v := u and i := 0. While i < m (where m is the number of vertices in G) repeat: If v has degree 0, reject, else nondeterministically choose an edge (v, v0) E(G). Increment i and set v := v0. If i is odd and v = u, accept. Otherwise, repeat the loop with the new v. If the loop terminates (i.e., if i > m), reject. It is clear that this nondeterministic algorithm detects odd cycles in G. On the other hand, if G does not contain an odd cycle, all branches of computation reject. We need to provide storage only for the vertices u, v, v 0 and for the counter i. This can be achieved in log-space only.
11 First, A_NFA is in NL, as we can, on input NFA M and x, non deterministically choose one next state transition. The variables recording "how much of x has been read" and "what state M is in" are only logarithmically long. To show A_NFA NL-hard, we need only show that PATH log-space reduces to A_NFA: Given as input a directed graph G=(V,E) and two of its nodes, x and y, we construct an NFA N with its states corresponding to G's nodes, its transitions under alphabet 0 corresponding to G's directed edges. Then, for N's accepting state (the state representing y), we let it go back to itself on all input alphabets, and, for other states, upon reading a 1, we go into a "trap" state which is deemed to reject. It can now be shown that x goes to y in G iff on input ( V of 0's), N accepts. This completes the proof.
12
Theory of Computation Space Complexity. (NTU EE) Space Complexity Fall / 1
Theory of Computation Space Complexity (NTU EE) Space Complexity Fall 2016 1 / 1 Space Complexity Definition 1 Let M be a TM that halts on all inputs. The space complexity of M is f : N N where f (n) is
More informationAdvanced topic: Space complexity
Advanced topic: Space complexity CSCI 3130 Formal Languages and Automata Theory Siu On CHAN Chinese University of Hong Kong Fall 2016 1/28 Review: time complexity We have looked at how long it takes to
More information6.045 Final Exam Solutions
6.045J/18.400J: Automata, Computability and Complexity Prof. Nancy Lynch, Nati Srebro 6.045 Final Exam Solutions May 18, 2004 Susan Hohenberger Name: Please write your name on each page. This exam is open
More informationCSE 555 HW 5 SAMPLE SOLUTION. Question 1.
CSE 555 HW 5 SAMPLE SOLUTION Question 1. Show that if L is PSPACE-complete, then L is NP-hard. Show that the converse is not true. If L is PSPACE-complete, then for all A PSPACE, A P L. We know SAT PSPACE
More informationCSE200: Computability and complexity Space Complexity
CSE200: Computability and complexity Space Complexity Shachar Lovett January 29, 2018 1 Space complexity We would like to discuss languages that may be determined in sub-linear space. Lets first recall
More information6.840 Language Membership
6.840 Language Membership Michael Bernstein 1 Undecidable INP Practice final Use for A T M. Build a machine that asks EQ REX and then runs M on w. Query INP. If it s in P, accept. Note that the language
More informationIntroduction to Computational Complexity
Introduction to Computational Complexity George Voutsadakis 1 1 Mathematics and Computer Science Lake Superior State University LSSU Math 400 George Voutsadakis (LSSU) Computational Complexity September
More informationLecture 22: PSPACE
6.045 Lecture 22: PSPACE 1 VOTE VOTE VOTE For your favorite course on automata and complexity Please complete the online subject evaluation for 6.045 2 Final Exam Information Who: You On What: Everything
More informationSpace Complexity. The space complexity of a program is how much memory it uses.
Space Complexity The space complexity of a program is how much memory it uses. Measuring Space When we compute the space used by a TM, we do not count the input (think of input as readonly). We say that
More informationSpace is a computation resource. Unlike time it can be reused. Computational Complexity, by Fu Yuxi Space Complexity 1 / 44
Space Complexity Space is a computation resource. Unlike time it can be reused. Computational Complexity, by Fu Yuxi Space Complexity 1 / 44 Synopsis 1. Space Bounded Computation 2. Logspace Reduction
More informationLecture 20: PSPACE. November 15, 2016 CS 1010 Theory of Computation
Lecture 20: PSPACE November 15, 2016 CS 1010 Theory of Computation Recall that PSPACE = k=1 SPACE(nk ). We will see that a relationship between time and space complexity is given by: P NP PSPACE = NPSPACE
More informationExam Computability and Complexity
Total number of points:... Number of extra sheets of paper:... Exam Computability and Complexity by Jiri Srba, January 2009 Student s full name CPR number Study number Before you start, fill in the three
More informationLecture 23: More PSPACE-Complete, Randomized Complexity
6.045 Lecture 23: More PSPACE-Complete, Randomized Complexity 1 Final Exam Information Who: You On What: Everything through PSPACE (today) With What: One sheet (double-sided) of notes are allowed When:
More informationOutline. Complexity Theory. Example. Sketch of a log-space TM for palindromes. Log-space computations. Example VU , SS 2018
Complexity Theory Complexity Theory Outline Complexity Theory VU 181.142, SS 2018 3. Logarithmic Space Reinhard Pichler Institute of Logic and Computation DBAI Group TU Wien 3. Logarithmic Space 3.1 Computational
More informationCOMPLEXITY THEORY. PSPACE = SPACE(n k ) k N. NPSPACE = NSPACE(n k ) 10/30/2012. Space Complexity: Savitch's Theorem and PSPACE- Completeness
15-455 COMPLEXITY THEORY Space Complexity: Savitch's Theorem and PSPACE- Completeness October 30,2012 MEASURING SPACE COMPLEXITY FINITE STATE CONTROL I N P U T 1 2 3 4 5 6 7 8 9 10 We measure space complexity
More informationSpace Complexity. Huan Long. Shanghai Jiao Tong University
Space Complexity Huan Long Shanghai Jiao Tong University Acknowledgements Part of the slides comes from a similar course in Fudan University given by Prof. Yijia Chen. http://basics.sjtu.edu.cn/ chen/
More informationan efficient procedure for the decision problem. We illustrate this phenomenon for the Satisfiability problem.
1 More on NP In this set of lecture notes, we examine the class NP in more detail. We give a characterization of NP which justifies the guess and verify paradigm, and study the complexity of solving search
More informationTime to learn about NP-completeness!
Time to learn about NP-completeness! Harvey Mudd College March 19, 2007 Languages A language is a set of strings Examples The language of strings of all zeros with odd length The language of strings with
More informationThe space complexity of a standard Turing machine. The space complexity of a nondeterministic Turing machine
298 8. Space Complexity The space complexity of a standard Turing machine M = (Q,,,, q 0, accept, reject) on input w is space M (w) = max{ uav : q 0 w M u q av, q Q, u, a, v * } The space complexity of
More information6.045J/18.400J: Automata, Computability and Complexity Final Exam. There are two sheets of scratch paper at the end of this exam.
6.045J/18.400J: Automata, Computability and Complexity May 20, 2005 6.045 Final Exam Prof. Nancy Lynch Name: Please write your name on each page. This exam is open book, open notes. There are two sheets
More information6.045: Automata, Computability, and Complexity (GITCS) Class 15 Nancy Lynch
6.045: Automata, Computability, and Complexity (GITCS) Class 15 Nancy Lynch Today: More Complexity Theory Polynomial-time reducibility, NP-completeness, and the Satisfiability (SAT) problem Topics: Introduction
More information1 PSPACE-Completeness
CS 6743 Lecture 14 1 Fall 2007 1 PSPACE-Completeness Recall the NP-complete problem SAT: Is a given Boolean formula φ(x 1,..., x n ) satisfiable? The same question can be stated equivalently as: Is the
More informationCS154, Lecture 13: P vs NP
CS154, Lecture 13: P vs NP The EXTENDED Church-Turing Thesis Everyone s Intuitive Notion of Efficient Algorithms Polynomial-Time Turing Machines More generally: TM can simulate every reasonable model of
More informationTheory of Computation. Ch.8 Space Complexity. wherein all branches of its computation halt on all
Definition 8.1 Let M be a deterministic Turing machine, DTM, that halts on all inputs. The space complexity of M is the function f : N N, where f(n) is the maximum number of tape cells that M scans on
More informationU.C. Berkeley CS278: Computational Complexity Professor Luca Trevisan 9/6/2004. Notes for Lecture 3
U.C. Berkeley CS278: Computational Complexity Handout N3 Professor Luca Trevisan 9/6/2004 Notes for Lecture 3 Revised 10/6/04 1 Space-Bounded Complexity Classes A machine solves a problem using space s(
More informationCSC 5170: Theory of Computational Complexity Lecture 4 The Chinese University of Hong Kong 1 February 2010
CSC 5170: Theory of Computational Complexity Lecture 4 The Chinese University of Hong Kong 1 February 2010 Computational complexity studies the amount of resources necessary to perform given computations.
More informationCS154, Lecture 13: P vs NP
CS154, Lecture 13: P vs NP The EXTENDED Church-Turing Thesis Everyone s Intuitive Notion of Efficient Algorithms Polynomial-Time Turing Machines More generally: TM can simulate every reasonable model of
More informationCSCE 551 Final Exam, April 28, 2016 Answer Key
CSCE 551 Final Exam, April 28, 2016 Answer Key 1. (15 points) Fix any alphabet Σ containing the symbol a. For any language L Σ, define the language a\l := {w Σ wa L}. Show that if L is regular, then a\l
More informationChapter 1 - Time and Space Complexity. deterministic and non-deterministic Turing machine time and space complexity classes P, NP, PSPACE, NPSPACE
Chapter 1 - Time and Space Complexity deterministic and non-deterministic Turing machine time and space complexity classes P, NP, PSPACE, NPSPACE 1 / 41 Deterministic Turing machines Definition 1.1 A (deterministic
More informationNotes on Space-Bounded Complexity
U.C. Berkeley CS172: Automata, Computability and Complexity Handout 6 Professor Luca Trevisan 4/13/2004 Notes on Space-Bounded Complexity These are notes for CS278, Computational Complexity, scribed by
More informationMTAT Complexity Theory October 13th-14th, Lecture 6
MTAT.07.004 Complexity Theory October 13th-14th, 2011 Lecturer: Peeter Laud Lecture 6 Scribe(s): Riivo Talviste 1 Logarithmic memory Turing machines working in logarithmic space become interesting when
More informationBBM402-Lecture 11: The Class NP
BBM402-Lecture 11: The Class NP Lecturer: Lale Özkahya Resources for the presentation: http://ocw.mit.edu/courses/electrical-engineering-andcomputer-science/6-045j-automata-computability-andcomplexity-spring-2011/syllabus/
More informationINAPPROX APPROX PTAS. FPTAS Knapsack P
CMPSCI 61: Recall From Last Time Lecture 22 Clique TSP INAPPROX exists P approx alg for no ε < 1 VertexCover MAX SAT APPROX TSP some but not all ε< 1 PTAS all ε < 1 ETSP FPTAS Knapsack P poly in n, 1/ε
More informationIntro to Theory of Computation
Intro to Theory of Computation LECTURE 25 Last time Class NP Today Polynomial-time reductions Adam Smith; Sofya Raskhodnikova 4/18/2016 L25.1 The classes P and NP P is the class of languages decidable
More informationNotes on Space-Bounded Complexity
U.C. Berkeley CS172: Automata, Computability and Complexity Handout 7 Professor Luca Trevisan April 14, 2015 Notes on Space-Bounded Complexity These are notes for CS278, Computational Complexity, scribed
More informationLecture 8. MINDNF = {(φ, k) φ is a CNF expression and DNF expression ψ s.t. ψ k and ψ is equivalent to φ}
6.841 Advanced Complexity Theory February 28, 2005 Lecture 8 Lecturer: Madhu Sudan Scribe: Arnab Bhattacharyya 1 A New Theme In the past few lectures, we have concentrated on non-uniform types of computation
More information6.841/18.405J: Advanced Complexity Wednesday, February 12, Lecture Lecture 3
6.841/18.405J: Advanced Complexity Wednesday, February 12, 2003 Lecture Lecture 3 Instructor: Madhu Sudan Scribe: Bobby Kleinberg 1 The language MinDNF At the end of the last lecture, we introduced the
More informationComplexity Theory 112. Space Complexity
Complexity Theory 112 Space Complexity We ve already seen the definition SPACE(f(n)): the languages accepted by a machine which uses O(f(n)) tape cells on inputs of length n. Counting only work space NSPACE(f(n))
More informationComplexity (Pre Lecture)
Complexity (Pre Lecture) Dr. Neil T. Dantam CSCI-561, Colorado School of Mines Fall 2018 Dantam (Mines CSCI-561) Complexity (Pre Lecture) Fall 2018 1 / 70 Why? What can we always compute efficiently? What
More informationLogarithmic space. Evgenij Thorstensen V18. Evgenij Thorstensen Logarithmic space V18 1 / 18
Logarithmic space Evgenij Thorstensen V18 Evgenij Thorstensen Logarithmic space V18 1 / 18 Journey below Unlike for time, it makes sense to talk about sublinear space. This models computations on input
More informationPSPACE COMPLETENESS TBQF. THURSDAY April 17
PSPACE COMPLETENESS TBQF THURSDAY April 17 Definition: Language B is PSPACE-complete if: 1. B PSPACE 2. Every A in PSPACE is poly-time reducible to B (i.e. B is PSPACE-hard) QUANTIFIED BOOLEAN FORMULAS
More informationCOL 352 Introduction to Automata and Theory of Computation Major Exam, Sem II , Max 80, Time 2 hr. Name Entry No. Group
COL 352 Introduction to Automata and Theory of Computation Major Exam, Sem II 2015-16, Max 80, Time 2 hr Name Entry No. Group Note (i) Write your answers neatly and precisely in the space provided with
More informationComputability and Complexity CISC462, Fall 2018, Space complexity 1
Computability and Complexity CISC462, Fall 2018, Space complexity 1 SPACE COMPLEXITY This material is covered in Chapter 8 of the textbook. For simplicity, we define the space used by a Turing machine
More informationLecture Notes Each circuit agrees with M on inputs of length equal to its index, i.e. n, x {0, 1} n, C n (x) = M(x).
CS 221: Computational Complexity Prof. Salil Vadhan Lecture Notes 4 February 3, 2010 Scribe: Jonathan Pines 1 Agenda P-/NP- Completeness NP-intermediate problems NP vs. co-np L, NL 2 Recap Last time, we
More informationTime to learn about NP-completeness!
Time to learn about NP-completeness! Harvey Mudd College March 19, 2007 Languages A language is a set of strings Examples The language of strings of all a s with odd length The language of strings with
More informationLecture 16: Time Complexity and P vs NP
6.045 Lecture 16: Time Complexity and P vs NP 1 Time-Bounded Complexity Classes Definition: TIME(t(n)) = { L there is a Turing machine M with time complexity O(t(n)) so that L = L(M) } = { L L is a language
More informationCOMP/MATH 300 Topics for Spring 2017 June 5, Review and Regular Languages
COMP/MATH 300 Topics for Spring 2017 June 5, 2017 Review and Regular Languages Exam I I. Introductory and review information from Chapter 0 II. Problems and Languages A. Computable problems can be expressed
More informationCS5371 Theory of Computation. Lecture 23: Complexity VIII (Space Complexity)
CS5371 Theory of Computation Lecture 23: Complexity VIII (Space Complexity) Objectives Introduce Space Complexity Savitch s Theorem The class PSPACE Space Complexity Definition [for DTM]: Let M be a DTM
More informationNotes for Lecture Notes 2
Stanford University CS254: Computational Complexity Notes 2 Luca Trevisan January 11, 2012 Notes for Lecture Notes 2 In this lecture we define NP, we state the P versus NP problem, we prove that its formulation
More informationLecture 24: Randomized Complexity, Course Summary
6.045 Lecture 24: Randomized Complexity, Course Summary 1 1/4 1/16 1/4 1/4 1/32 1/16 1/32 Probabilistic TMs 1/16 A probabilistic TM M is a nondeterministic TM where: Each nondeterministic step is called
More informationComplexity Theory VU , SS The Polynomial Hierarchy. Reinhard Pichler
Complexity Theory Complexity Theory VU 181.142, SS 2018 6. The Polynomial Hierarchy Reinhard Pichler Institut für Informationssysteme Arbeitsbereich DBAI Technische Universität Wien 15 May, 2018 Reinhard
More informationOutline. Complexity Theory EXACT TSP. The Class DP. Definition. Problem EXACT TSP. Complexity of EXACT TSP. Proposition VU 181.
Complexity Theory Complexity Theory Outline Complexity Theory VU 181.142, SS 2018 6. The Polynomial Hierarchy Reinhard Pichler Institut für Informationssysteme Arbeitsbereich DBAI Technische Universität
More informationChapter 2. Reductions and NP. 2.1 Reductions Continued The Satisfiability Problem (SAT) SAT 3SAT. CS 573: Algorithms, Fall 2013 August 29, 2013
Chapter 2 Reductions and NP CS 573: Algorithms, Fall 2013 August 29, 2013 2.1 Reductions Continued 2.1.1 The Satisfiability Problem SAT 2.1.1.1 Propositional Formulas Definition 2.1.1. Consider a set of
More informationPOLYNOMIAL SPACE QSAT. Games. Polynomial space cont d
T-79.5103 / Autumn 2008 Polynomial Space 1 T-79.5103 / Autumn 2008 Polynomial Space 3 POLYNOMIAL SPACE Polynomial space cont d Polynomial space-bounded computation has a variety of alternative characterizations
More informationCSCI3390-Lecture 14: The class NP
CSCI3390-Lecture 14: The class NP 1 Problems and Witnesses All of the decision problems described below have the form: Is there a solution to X? where X is the given problem instance. If the instance is
More information1 More finite deterministic automata
CS 125 Section #6 Finite automata October 18, 2016 1 More finite deterministic automata Exercise. Consider the following game with two players: Repeatedly flip a coin. On heads, player 1 gets a point.
More informationCS154, Lecture 15: Cook-Levin Theorem SAT, 3SAT
CS154, Lecture 15: Cook-Levin Theorem SAT, 3SAT Definition: A language B is NP-complete if: 1. B NP 2. Every A in NP is poly-time reducible to B That is, A P B When this is true, we say B is NP-hard On
More information9. PSPACE 9. PSPACE. PSPACE complexity class quantified satisfiability planning problem PSPACE-complete
Geography game Geography. Alice names capital city c of country she is in. Bob names a capital city c' that starts with the letter on which c ends. Alice and Bob repeat this game until one player is unable
More information9. PSPACE. PSPACE complexity class quantified satisfiability planning problem PSPACE-complete
9. PSPACE PSPACE complexity class quantified satisfiability planning problem PSPACE-complete Lecture slides by Kevin Wayne Copyright 2005 Pearson-Addison Wesley Copyright 2013 Kevin Wayne http://www.cs.princeton.edu/~wayne/kleinberg-tardos
More informationFORMAL LANGUAGES, AUTOMATA AND COMPUTATION
FORMAL LANGUAGES, AUTOMATA AND COMPUTATION DECIDABILITY ( LECTURE 15) SLIDES FOR 15-453 SPRING 2011 1 / 34 TURING MACHINES-SYNOPSIS The most general model of computation Computations of a TM are described
More informationP = k T IME(n k ) Now, do all decidable languages belong to P? Let s consider a couple of languages:
CS 6505: Computability & Algorithms Lecture Notes for Week 5, Feb 8-12 P, NP, PSPACE, and PH A deterministic TM is said to be in SP ACE (s (n)) if it uses space O (s (n)) on inputs of length n. Additionally,
More informationNotes on Complexity Theory Last updated: October, Lecture 6
Notes on Complexity Theory Last updated: October, 2015 Lecture 6 Notes by Jonathan Katz, lightly edited by Dov Gordon 1 PSPACE and PSPACE-Completeness As in our previous study of N P, it is useful to identify
More informationCSE 135: Introduction to Theory of Computation NP-completeness
CSE 135: Introduction to Theory of Computation NP-completeness Sungjin Im University of California, Merced 04-15-2014 Significance of the question if P? NP Perhaps you have heard of (some of) the following
More information1 Computational Problems
Stanford University CS254: Computational Complexity Handout 2 Luca Trevisan March 31, 2010 Last revised 4/29/2010 In this lecture we define NP, we state the P versus NP problem, we prove that its formulation
More informationCSCE 551 Final Exam, Spring 2004 Answer Key
CSCE 551 Final Exam, Spring 2004 Answer Key 1. (10 points) Using any method you like (including intuition), give the unique minimal DFA equivalent to the following NFA: 0 1 2 0 5 1 3 4 If your answer is
More informationChapter 9. PSPACE: A Class of Problems Beyond NP. Slides by Kevin Wayne Pearson-Addison Wesley. All rights reserved.
Chapter 9 PSPACE: A Class of Problems Beyond NP Slides by Kevin Wayne. Copyright @ 2005 Pearson-Addison Wesley. All rights reserved. 1 Geography Game Geography. Alice names capital city c of country she
More informationPolynomial time reduction and NP-completeness. Exploring some time complexity limits of polynomial time algorithmic solutions
Polynomial time reduction and NP-completeness Exploring some time complexity limits of polynomial time algorithmic solutions 1 Polynomial time reduction Definition: A language L is said to be polynomial
More informationUmans Complexity Theory Lectures
Umans Complexity Theory Lectures Lecture 12: The Polynomial-Time Hierarchy Oracle Turing Machines Oracle Turing Machine (OTM): Deterministic multitape TM M with special query tape special states q?, q
More informationCS5371 Theory of Computation. Lecture 24: Complexity IX (PSPACE-complete, L, NL, NL-complete)
CS5371 Theory of Computation Lecture 24: Complexity IX (PSPACE-complete, L, NL, NL-complete) Objectives PSPACE-complete languages + Examples The classes L and NL NL-complete languages + Examples PSPACE-complete
More informationSpace Complexity. Master Informatique. Université Paris 5 René Descartes. Master Info. Complexity Space 1/26
Space Complexity Master Informatique Université Paris 5 René Descartes 2016 Master Info. Complexity Space 1/26 Outline Basics on Space Complexity Main Space Complexity Classes Deterministic and Non-Deterministic
More informationThe Cook-Levin Theorem
An Exposition Sandip Sinha Anamay Chaturvedi Indian Institute of Science, Bangalore 14th November 14 Introduction Deciding a Language Let L {0, 1} be a language, and let M be a Turing machine. We say M
More informationAnswers to the CSCE 551 Final Exam, April 30, 2008
Answers to the CSCE 55 Final Exam, April 3, 28. (5 points) Use the Pumping Lemma to show that the language L = {x {, } the number of s and s in x differ (in either direction) by at most 28} is not regular.
More informationUNIT-IV SPACE COMPLEXITY
UNIT-IV SPACE COMPLEXITY Time and space are two of the most important considerations when we seek practical solutions to many computational problems. Space complexity shares many of the features of time
More informationComputer Sciences Department
Computer Sciences Department 1 Reference Book: INTRODUCTION TO THE THEORY OF COMPUTATION, SECOND EDITION, by: MICHAEL SIPSER Computer Sciences Department 3 ADVANCED TOPICS IN C O M P U T A B I L I T Y
More informationChapter 7: Time Complexity
Chapter 7: Time Complexity 1 Time complexity Let M be a deterministic Turing machine that halts on all inputs. The running time or time complexity of M is the function f: N N, where f(n) is the maximum
More informationTIME COMPLEXITY AND POLYNOMIAL TIME; NON DETERMINISTIC TURING MACHINES AND NP. THURSDAY Mar 20
TIME COMPLEXITY AND POLYNOMIAL TIME; NON DETERMINISTIC TURING MACHINES AND NP THURSDAY Mar 20 COMPLEXITY THEORY Studies what can and can t be computed under limited resources such as time, space, etc Today:
More informationLecture 4 : Quest for Structure in Counting Problems
CS6840: Advanced Complexity Theory Jan 10, 2012 Lecture 4 : Quest for Structure in Counting Problems Lecturer: Jayalal Sarma M.N. Scribe: Dinesh K. Theme: Between P and PSPACE. Lecture Plan:Counting problems
More informationLecture 7: The Polynomial-Time Hierarchy. 1 Nondeterministic Space is Closed under Complement
CS 710: Complexity Theory 9/29/2011 Lecture 7: The Polynomial-Time Hierarchy Instructor: Dieter van Melkebeek Scribe: Xi Wu In this lecture we first finish the discussion of space-bounded nondeterminism
More informationCS5371 Theory of Computation. Lecture 23: Complexity VIII (Space Complexity)
CS5371 Theory of Computation Lecture 23: Complexity VIII (Space Complexity) Objectives Introduce Space Complexity Savitch s Theorem The class PSPACE Space Complexity Definition [for DTM]: Let M be a DTM
More informationCS Lecture 29 P, NP, and NP-Completeness. k ) for all k. Fall The class P. The class NP
CS 301 - Lecture 29 P, NP, and NP-Completeness Fall 2008 Review Languages and Grammars Alphabets, strings, languages Regular Languages Deterministic Finite and Nondeterministic Automata Equivalence of
More informationCSCI3390-Lecture 16: NP-completeness
CSCI3390-Lecture 16: NP-completeness 1 Summary We recall the notion of polynomial-time reducibility. This is just like the reducibility we studied earlier, except that we require that the function mapping
More informationNP Complete Problems. COMP 215 Lecture 20
NP Complete Problems COMP 215 Lecture 20 Complexity Theory Complexity theory is a research area unto itself. The central project is classifying problems as either tractable or intractable. Tractable Worst
More informationComplexity Theory Part II
Complexity Theory Part II Time Complexity The time complexity of a TM M is a function denoting the worst-case number of steps M takes on any input of length n. By convention, n denotes the length of the
More informationComputability and Complexity
Computability and Complexity Lecture 5 Reductions Undecidable problems from language theory Linear bounded automata given by Jiri Srba Lecture 5 Computability and Complexity 1/14 Reduction Informal Definition
More informationCS 580: Algorithm Design and Analysis. Jeremiah Blocki Purdue University Spring 2018
CS 580: Algorithm Design and Analysis Jeremiah Blocki Purdue University Spring 2018 Chapter 9 PSPACE: A Class of Problems Beyond NP Slides by Kevin Wayne. Copyright @ 2005 Pearson-Addison Wesley. All rights
More informationPolynomial Time Computation. Topics in Logic and Complexity Handout 2. Nondeterministic Polynomial Time. Succinct Certificates.
1 2 Topics in Logic and Complexity Handout 2 Anuj Dawar MPhil Advanced Computer Science, Lent 2010 Polynomial Time Computation P = TIME(n k ) k=1 The class of languages decidable in polynomial time. The
More informationTheory of Computation
Theory of Computation Dr. Sarmad Abbasi Dr. Sarmad Abbasi () Theory of Computation 1 / 38 Lecture 21: Overview Big-Oh notation. Little-o notation. Time Complexity Classes Non-deterministic TMs The Class
More informationComplexity Theory. Jörg Kreiker. Summer term Chair for Theoretical Computer Science Prof. Esparza TU München
Complexity Theory Jörg Kreiker Chair for Theoretical Computer Science Prof. Esparza TU München Summer term 2010 Lecture 5 NP-completeness (2) 3 Cook-Levin Teaser A regular expression over {0, 1} is defined
More informationNP-Completeness. Sections 28.5, 28.6
NP-Completeness Sections 28.5, 28.6 NP-Completeness A language L might have these properties: 1. L is in NP. 2. Every language in NP is deterministic, polynomial-time reducible to L. L is NP-hard iff it
More informationQuantum Computing Lecture 8. Quantum Automata and Complexity
Quantum Computing Lecture 8 Quantum Automata and Complexity Maris Ozols Computational models and complexity Shor s algorithm solves, in polynomial time, a problem for which no classical polynomial time
More informationThe Class NP. NP is the problems that can be solved in polynomial time by a nondeterministic machine.
The Class NP NP is the problems that can be solved in polynomial time by a nondeterministic machine. NP The time taken by nondeterministic TM is the length of the longest branch. The collection of all
More information1 Deterministic Turing Machines
Time and Space Classes Exposition by William Gasarch 1 Deterministic Turing Machines Turing machines are a model of computation. It is believed that anything that can be computed can be computed by a Turing
More informationFinish K-Complexity, Start Time Complexity
6.045 Finish K-Complexity, Start Time Complexity 1 Kolmogorov Complexity Definition: The shortest description of x, denoted as d(x), is the lexicographically shortest string such that M(w) halts
More informationUndecidable Problems. Z. Sawa (TU Ostrava) Introd. to Theoretical Computer Science May 12, / 65
Undecidable Problems Z. Sawa (TU Ostrava) Introd. to Theoretical Computer Science May 12, 2018 1/ 65 Algorithmically Solvable Problems Let us assume we have a problem P. If there is an algorithm solving
More informationFriday Four Square! Today at 4:15PM, Outside Gates
P and NP Friday Four Square! Today at 4:15PM, Outside Gates Recap from Last Time Regular Languages DCFLs CFLs Efficiently Decidable Languages R Undecidable Languages Time Complexity A step of a Turing
More informationLecture 8: Complete Problems for Other Complexity Classes
IAS/PCMI Summer Session 2000 Clay Mathematics Undergraduate Program Basic Course on Computational Complexity Lecture 8: Complete Problems for Other Complexity Classes David Mix Barrington and Alexis Maciel
More informationCS5371 Theory of Computation. Lecture 12: Computability III (Decidable Languages relating to DFA, NFA, and CFG)
CS5371 Theory of Computation Lecture 12: Computability III (Decidable Languages relating to DFA, NFA, and CFG) Objectives Recall that decidable languages are languages that can be decided by TM (that means,
More information1 Deterministic Turing Machines
Time and Space Classes Exposition by William Gasarch 1 Deterministic Turing Machines Turing machines are a model of computation. It is believed that anything that can be computed can be computed by a Turing
More informationComputability and Complexity Theory: An Introduction
Computability and Complexity Theory: An Introduction meena@imsc.res.in http://www.imsc.res.in/ meena IMI-IISc, 20 July 2006 p. 1 Understanding Computation Kinds of questions we seek answers to: Is a given
More information