Talks%20on%20parts%20of%204%20papers. - PowerPoint PPT Presentation

About This Presentation
Title:

Talks%20on%20parts%20of%204%20papers.

Description:

W[1]-Hard problem. n ratio approximation. This problem is clearly finding a Directed Steiner tree and a reverse directed Steiner tree. The Directed Steiner Tree ... – PowerPoint PPT presentation

Number of Views:110
Avg rating:3.0/5.0
Slides: 66
Provided by: rutg173
Learn more at: https://crab.rutgers.edu
Category:

less

Transcript and Presenter's Notes

Title: Talks%20on%20parts%20of%204%20papers.


1
Optimal running times for exact solutions and
approximated solutions
  • Talks on parts of 4 papers.
  • 1) M. Hajiaghayi, Khandekar and K.
  • 2) M. Cygan, K
  • 3) R Chitnis, M. Hajiaghayi, K
  • 4) M. Hajiaghayi, K and some students of M.
    Hajiaghayi

2
The Exponential Time Hypotesis
  • The 3-SAT problem with n variables and m clauses
    can not be solved in time
  • 2o(n)
  • Due to Impagliazzo, Paturi and Zane. FOCS 1998.
    Do you think its false?
  • Lemma of Calabro, Impagliazzo and Paturi
  • The 3-SAT problem with n variables and m clauses
    can not be solved in time 2o(m)
  • This is called the Sparsification Lemma.

3
The subject of this talk
  • What can we prove under the Exponential Time
    Hypothesis?
  • Many problems have optimum running time
    algorithms under this assumption.
  • We later present such a result in connectivity.
    Tight lower bound that uses the Exponential Time
    Hypothesis

4
Why do we need the ETH?
  • How can we prove that there is no f(k)?poly(n)
    algorithm for Clique?
  • The assumption of PNP implies that f(k) is
    polynomial in n. To show Clique? FPT we need to
    show P?NP.
  • Instead assume the much stronger ETH assumption.

5
Harder (but natural) subject
  • If you want approximation ratio of ? for some
    problem what is the best possible running time?
  • You need to do two things
  • First give an approximation ratio of ? in some
    time t(n).
  • Then show that approximation of ?, with time
    better than t(n) would contradict the ETH. We
    start with this.

6
How do we lower bound the time for approximation?
  • In approximation algorithms I do not think
    somebody tried to show that in linear time you
    can not get better than 2 ratio for Vertex Cover.
    Should we create a new subject? If its possible
    to prove such things.
  • Using the ETH this may be possible.
  • Needs knowledge far from FPT.
  • Needs a knowledge of almost linear PCP and about
    gap reductions and about deep theorems in
    Inapproximability theory.
  • See more later.

7
The directed Steiner problems
s
6
3
1
1
2
1
1
4
6
3
1
3
2
4
5
2
4
8
The directed Steiner problems
  • Optimum solution with all terminals

s
3
1
1
2
1
3
1
2
4
9
What is known
  • A very important problem in Approximation
    Algorithms. Key for other problems.
  • This problem is FPT by the cost of the optimum
    solution.
  • It admits n? for every ?.
  • In the next slide I will give the correct credit
    for this result. Never done.

10
Approximation
  • The best approximation algorithm for the problem
    was designed in SODA 1997 by K,Peleg. The credit
    (by mistake) is given to Charikar et al. Implies
    ratio f(?)?n? for any ?.
  • In SODA 1998 Charikar et al used the same
    algorithm. Said explicitly that Implies ratio
    f(?) n? for any ? for the Directed Steiner tree.
  • Charikar et al better f(?) term.
  • Charikar et al also implied that the problem has
    log3 n ratio, time quasi-polynomial in n.

11
Does this imply that there is polynomial time
polylogarithmic ratio?
  • At the time such an algorithm was considered as a
    sign that a polynomial polylogarithmic
    approximation exists.
  • A paper by Chandra Chekuri and Martin Pal under
    the ETH, P?Quasi-P
  • Conjecture (Kortsarz) Under the ETH there is no
    polynomial time polylogarithmic ratio
    approximation for the Directed Steiner Tree
    problem.

12
Linear reductions
  • It turns out that linear reductions are crucial
    for Fixed Parameter Inapproximability.
  • This is known for quite some time.
  • This means a reduction from SAT with m cluases
    and n variables that creates a gap.
  • The size of the instance of the new problem is
    O(mn)
  • Unfortunately, if the ETH is correct there are
    almost no linear reductions.

13
Example for what is not possible
  • Unfortunately, a linear reduction from PCP to
    Set-Cover implies that ETH fails.
  • If we had that we could show that Set-Cover
    admits no (r(k),t(k)) FPT-approximation for any
    r,t.
  • There is a linear reduction from SAT to Clique.
    This does not help because first we need to do a
    gap reduction from SAT to 3-SAT.

14
What almost linear hardness do we know?
  • SAT with n variables and m clauses.
  • An almost linear reduction is a reduction to
    Label-Cover of size m1o(1)
  • Known (Dinur). Reduction of size m?polylog(m) to
    Label-Cover, gap 2.
  • The projection game conjecture
  • Moskowitz Reduction to Label-cover of size m?2
    log1-? m but gap nc for some c.

15
Remark about the Strongly conneceted subgraph
problem.
  • W1-Hard problem. n? ratio approximation
  • This problem is clearly finding a Directed
    Steiner tree and a reverse directed Steiner tree.
  • The Directed Steiner Tree problem is FPT when
    parameterized by the optimum solution
  • A rare case in which FPT time improves
    drastically the approximation ratio.
  • As we saw, ratio 2 is possible in time
    t(k)?poly(n).
  • Due to Chitnis, Hajiaghayi, K.

16
If you want a ratio ? for Directed Steiner Tree
what time is needed?
  • M. Cygan, K
  • If you want a ratio of ln n/2 the time required
    is roughly 2sqrtn?log n
  • Using the ETH we show that this time is optimal
    (the exponent can not be o(sqrtn)).

17
If you want a ratio ? for Directed Steiner Tree
what time is needed?
  • The upper bound is designing an algorithm.
  • The problematic part is the lower bound. Relies
    on Almost Linear PCP, Projection Game conjecture.
    Different kind of knowledge.
  • Maybe because of that I found very very few
    results of this kind.

18
Paper Hajiaghayi Khandekar ,K
  • In this paper we define a new way to use the
    known definition for Fixed Parameter
    Inapproximability.
  • We call this method inapproximability in opt
  • The definition requires kopt(I) for some I.
  • The definition was heavily influenced by talks
    with Cygan and Marx.

19
Why would we want kopt(I)?
  • Since approximation is in opt,
  • inapproximability should also be in opt. This
    is the logical counter statement.
  • We were trying to avoid reduction under FPT?
    W1, FPT?W2.
  • The ETH implies both statements above.
  • Far reaching consequences.

20
Proofs under FPT ?Wi
  • ETH implies FPT? W1, FPT? W2.
  • We are given that no time t(k) is enough.
  • The value is usually k versus k1 for
    minimization. Hard to get strong hardness.
  • The proof above reduces k below any given
    function. Thus k is not related to any opt(I).

21
Proofs under FPT ?Wi
  • However, if approximation in opt why not
    inapproximabiliy in opt?
  • Also our definition does not throw all problems
    in the same bin.
  • Does not seem logical that all prolems behave the
    same. Completely different problems.
  • By our definition we get a much richer behavior.
  • Each problem, its own behavior.

22
Method Gap reductions
  • Start with SAT. A yes instance goes to value X
    for our problem.
  • A no instance goes to value larger than ??X, ?gt1
    for our problem.
  • Important can produce huge gaps, solving the k
    versus k1 issue.

23
Method Gap reductions
  • Polynomial algorithm with ratio ? implies PNP
  • A ? approximation algorithm with running time
    2o(mn) implies that the ETH fails.

24
Method Gap reductions
  • A good (?(opt), t(opt)) ratio needs gap
    preserving reduction that makes opt very small.
    Not well understood.
  • We gave the first super exponential time
    inapproximability for Clique and Set Cover.
  • In fact for Clique Almost doubly exponential.

25
Properties
  • FPT?W1, FPT ? W2 does not imply anything on
    the optimum solution of any instance.
  • The problems are not thrown in the same bin.
  • In fact for every problem we check what kind of
    gap reduction do we have?
  • For every problem is there a gap preserving
    (increasing, slightly decreasing) reduction that
    makes opt very small? The latter is the new
    technical challenge.

26
Time to show the exact result with optimum time
we proved
  • It looks for simple variants of Directed Steiner
    Network that can be solved exactly.
  • Its seem that there are not many.
  • The lower bounds do not use almost linear PCP but
    rather something standard in FPT theory.

27
The Directed Steiner network problem
  • Let the vertices be 1,2,..,n
  • Given G(V,E) and a demand dij for every i and j
    (could be 0) and cost c(e) for every e.
  • The goal is to select a subgraph G(V,E) so that
    there are dij edge disjoint paths from i to j
    (separately). Use minimum cost.
  • Hopeless problem to approximate.
  • For Directed Steiner Forest Feldman,K,Nutov
    gave an O(n3/4) ratio. But that is it.
  • What are the simplest solvable cases?

28
A problem that we do not know anything for
  • Given a graph G(V,E) with unit costs (makes a
    difference!) and a root s output minimum cost
    subgraph that contains 2 edge disjoint paths from
    s to the other terminals.
  • Our usual trick (Set Families, Uncrossable,
    Weakly Super Modular functions, Laminar Basic
    Feasible solution) do not work.
  • The idea of starting with Directed Steiner tree
    and then add edges to give two paths from s to
    all vertices seems to badly fail.

29
A simple solvabable problem
  • Given a DIRECTED graph G(V,E) and two nodes s
    and t find a minimum cost graph so that there is
    a path from s to t and from t to s
  • The paths may not be edge disjoint.
  • Minimize the number of vertices in the solution
    (reduction from the edge case).
  • We generalize this problem, and gave a tight
    upper lower bound on the time.
  • Even the solution of the above non trivial.

30
The solution may be complex
31
The solution may be complex
  • Not shortest path.

32
A token game
  • We will have two tokes both in s.
  • One tokens, f goes on edges in the regular way.
  • This creates the path from s to t.
  • A second token called b goes in the wrong
    direction. This token would create a path from t
    to s.
  • Bring the two tokens from (s,s) to (t,t).
  • Due to Jon Feldman.

33
How do tockens move?
  • Token f moving forward (u,x)? (v,x) for an edge
    with (u,v).
  • Token b moves backward (creating an t to s path)
    (x,u)?(x,v) for the edge (v,u) adding a back
    edge in the path from t to s.
  • If both tokens reach t in the best way, we solved
    the problem.

34
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
35
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
36
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
37
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
38
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
39
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
40
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
41
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
42
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
(t,y)
43
An example that does not cause problems
  • Edges (s,q), (q,p), (p,x), (x,t) (r,u) (r,y)
  • (u,t), (r,u), (y,r), (t,y) ,(p,x)

(s,u)
(s,s)
(p,u)
(p,r)
(x,r)
(t,t)
(t,r)
(q,u)
q
p
s
x
t
(t,y)
s
u
r
y
t
44
Making sure we do not over count
  • At the moment we enter a vertex, this vertex is
    declared a dead vertex.
  • At every moment there must be a path
  • from the location of f to t using live
    vertices.
  • And there must be a back path from b into t of
    live vertices.

45
Getting stuck because f,b dead vertices
  • The backward needs x. The forward needs y.

s
f
x
b
y
t
46
Getting stuck because of dead vertices
  • The following three paths must exist

s
f
b
x
y
t
47
Getting stuck because of dead vertices
  • This contradicts f needing y to get to t.

s
f
b
x
y
t
48
Getting stuck because of dead vertices
  • We now move (x,y) to (y,x). Clearly a must.

s
f
b
x
y
t
49
Getting stuck because of dead vertices
  • We move from (x,y) to (y,x) but with one edge.

s
f
b
x
y
alive
alive
t
50
The shortest path algorithm
  • We make the graph with all pairs vertices and
    edges as discussed.
  • We add edges from (x,y) to (w,y)
  • with cost c the cost of the shortest path
    from x to w. Since direct edge move, dead
    vertices do not present a problem.
  • We apply the Dijkstras algorithm to find the
    shortest path on the graph of pairs, finding the
    optimum

51
We solve s,t, k disjoint paths for s to t
one from t to s
  • We have a structural lemma
  • Pity even for (2,2) does not work (we give an
    example that the structural lemma is false)
  • We solve this generalization in time nO(k).
  • We show that under the ETH there is no f(k)no(k)
  • Quite complex in my opinion. Uses the grid tiling
    problem.

52
How do we get the hardness
  • Chen et al showed a nice result about k-clique
    no exact solution in time f(k)? no(k) for any f.
  • Marx reduction from k-clique to Grid Tiling.
  • This reduction has surprising number of
    applications.
  • Many in planar graphs.

53
How do we get the hardness
  • We reduce from Grid Tiling to our problem with
    linear blowup
  • The time lower bound follows.
  • This is also a W1-hardness reduction.
  • Are there other problems that use a reduction
    from Grid Tiling for W1 hardness?
  • Seems a complex reduction to me.

54
Some rules we suggest
  • Do not prove FPT approximation unless the problem
    is both Wi-hard for i1 and has poor
    approximation. If one of the two statements is
    not true, what is the point?
  • Reductions should have only super exponential
    time in opt (or k). Otherwise we just translate a
    hardness to FPT terms.
  • Also, makes no sense to apply FPT-inapproximabilit
    y if the optimum is a constant.

55
FPT theory people study approximation!
  • We feel that what we called inapproximability in
    opt is the right counter statement to
    approximation in opt. In our opinion hardness
    in opt is better.
  • Gives more interesting behavior.
  • Gives large gaps/hardness.
  • Needs knowledge in proving hardness of
    approximation.

56
FPT people study approximation!
  • Given a problem, FPT people usually know if it
    is Wi-hard for i1.
  • But what about hardness?
  • Thus you have to either know the approximation
    lower bound if exists, or prove an
    inapproximability result.
  • There are excellent books and lecture notes in
    Approximation Algorithms.

57
People who work in Approximation study FPT!
  • When you study a new problem, check if it is in
    FPT.
  • Or perhaps it is Wi-hard for i1.
  • Fortunately Nice slides by Marx.
  • A new state of the art book by Cygan et al.
  • People in approximation can make papers on the
    topic of my talk optimal time for a required
    ? approximation.

58
Some tools used in FPT proofs
  • Kernelization, Crown Reduction, Sunflower, Lemma,
    Bounded Tree search, Branching Vectors, all can
    give FPT algorithms for Vertex cover.
  • Forbidden subgraphs (Triangle Free Graphs)
  • Iterative compression (Bipartite Deletion)
    Graph Minors (k-leaves spanning tree) , Color
    Coding (k length paths), Dynamic Programming
    (Steiner tree), Important Separators (Multiway
    Cut), Treewidth

59
More open problems than known results
  • Fellows conjecture Clique And Set-Cover admit no
    (?(k),t(k)) approximation for any ?,t.
  • I believe this conjecture (even in opt).
  • May require a Parameterized PCP
  • I talked to Dinur, Khot and other experts.
  • All told me in a very polite way

60
More open problems than known results
  • Fellows conjecture Clique And Set-Cover admit no
    (?(k),t(k)) approximation for any ?,t.
  • I believe this conjecture.
  • May require a Parameterized PCP
  • I talked to Dinur, Khot and other experts.
  • All told me in a very polite way Please get a
    hobby and leave us alone.

61
More open problems than known results
  • Fellows conjecture Clique And Set-Cover admit no
    (?(k),t(k)) approximation for any ?,t.
  • I believe this conjecture.
  • May require a Parameterized PCP
  • I talked to Dinur, Khot and other experts.
  • All told me in a very polite way Please get a
    hobby and leave us alone.
  • However there is now a simple PCP and simple
    parallel repetition theorems.

62
A problem I do not know anything about
  • Say that optlogloglog n. Is the Set-Cover and
    Clique NPC under this value?
  • What about if optlog n.
  • Better results can we show an inapproximability
    for optlog n.
  • According to the Fellows conjecture we should not
    be able to give any approximation thus the above
    value of opt do not matter.
  • Current PCP even the best possible (and not
    known) gives double exponential time in opt lower
    bound.

63
What do I do with the directed Steiner tree
problem?
  • How can we prove my conjecture?
  • No polynomial time polylogarithmic ratio
    algorithm under ETH.
  • The Directed Steiner tree has roughly log2 n
    lower bound. Can we get exact running times for c
    log2 n approximations?
  • A log3 n inapproximability I have no idea how to
    prove.

64
Any questions?
65
Any questions?
  • Thank You
Write a Comment
User Comments (0)
About PowerShow.com