color coding
TRANSCRIPT
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Color Coding and Chromatic Coding
Venkatesh Raman
The Institute of Mathematical Sciences
3 March 2014
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 1 / 17
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Randomized Algorithms
Let Π ⊆ Σ∗ be a problem.
Algorithm
x ∈ Σ∗
x ∈ Π?(Output correct answer with good probability)
Here we are interested in randomized algorithms for parameterizedproblems taking running time f (k)|x |O(1) with constant successprobability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 2 / 17
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Randomized Algorithms
Let Π ⊆ Σ∗ be a problem.
Algorithm
x ∈ Σ∗
x ∈ Π?(Output correct answer with good probability)
Here we are interested in randomized algorithms for parameterizedproblems taking running time f (k)|x |O(1) with constant successprobability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 2 / 17
![Page 4: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/4.jpg)
Randomized Algorithms
Let Π ⊆ Σ∗ be a problem.
Algorithm
x ∈ Σ∗
x ∈ Π?(Output correct answer with good probability)
Here we are interested in randomized algorithms for parameterizedproblems taking running time f (k)|x |O(1) with constant successprobability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 2 / 17
![Page 5: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/5.jpg)
Randomized Algorithms
Let Π ⊆ Σ∗ be a problem.
Algorithm
x ∈ Σ∗
x ∈ Π?(Output correct answer with good probability)
Here we are interested in randomized algorithms for parameterizedproblems taking running time f (k)|x |O(1) with constant successprobability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 2 / 17
![Page 6: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/6.jpg)
Randomized Algorithms
Let Π ⊆ Σ∗ be a problem.
Algorithm
x ∈ Σ∗
x ∈ Π?(Output correct answer with good probability)
Here we are interested in randomized algorithms for parameterizedproblems taking running time f (k)|x |O(1) with constant successprobability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 2 / 17
![Page 7: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/7.jpg)
Randomized Algorithms
Let Π ⊆ Σ∗ be a problem.
Algorithm
x ∈ Σ∗
x ∈ Π?(Output correct answer with good probability)
Here we are interested in randomized algorithms for parameterizedproblems taking running time f (k)|x |O(1) with constant successprobability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 2 / 17
![Page 8: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/8.jpg)
Randomized Algorithm for UFVS
Definition (Feedback Vertex Set)
Let G = (V ,E ) be an undirected graph. S ⊆ V is called feedback vertexset if G \ S is a forest.
Undirected Feedback Vertex Set (UFVS)
Input: An undirected graph G = (V ,E ) and a positive integer kParameter: kQuestion: Does there exists a feedback vertex set of size at most k
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 3 / 17
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Randomized Algorithm for UFVS
Definition (Feedback Vertex Set)
Let G = (V ,E ) be an undirected graph. S ⊆ V is called feedback vertexset if G \ S is a forest.
Undirected Feedback Vertex Set (UFVS)
Input: An undirected graph G = (V ,E ) and a positive integer kParameter: kQuestion: Does there exists a feedback vertex set of size at most k
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 3 / 17
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Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
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Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 4 / 17
![Page 12: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/12.jpg)
Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 4 / 17
![Page 13: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/13.jpg)
Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 4 / 17
![Page 14: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/14.jpg)
Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 4 / 17
![Page 15: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/15.jpg)
Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 4 / 17
![Page 16: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/16.jpg)
Randomized Algorithm for UFVS
Do the following preprocessing rules
Delete degree ≤ 1 vertices.
Short circuit degree 2 vertices.
Add vertex x to FVS, if x has self loop.
Now we can assume every vertex in G has degree ≥ 3.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 4 / 17
![Page 17: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/17.jpg)
Randomized Algorithm for UFVS
Claim : If G is graph with minimum degree ≥ 3, then number of edgesincident to any FVS F is ≥ E(G)
2 .
Proof: Let
V≤1 = set of degree ≤ 1 vertices in H,
V2 = set of degree 2 vertices in H, and
V≥3 = set of degree ≥ 3 vertices in H.
Number of edges between H and F ,
E (H,F ) ≥ 2V≤1 + V2
> V≤1 + V2 + V≥3 (∵ V≤1 > V≥3)
= V (H)> E (H).
F
H=G - F ;
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 5 / 17
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Randomized Algorithm for UFVS
Claim : If G is graph with minimum degree ≥ 3, then number of edgesincident to any FVS F is ≥ E(G)
2 .
Proof:
Let
V≤1 = set of degree ≤ 1 vertices in H,
V2 = set of degree 2 vertices in H, and
V≥3 = set of degree ≥ 3 vertices in H.
Number of edges between H and F ,
E (H,F ) ≥ 2V≤1 + V2
> V≤1 + V2 + V≥3 (∵ V≤1 > V≥3)
= V (H)> E (H).
F
H=G - F ;
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 5 / 17
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Randomized Algorithm for UFVS
Claim : If G is graph with minimum degree ≥ 3, then number of edgesincident to any FVS F is ≥ E(G)
2 .
Proof: Let
V≤1 = set of degree ≤ 1 vertices in H,
V2 = set of degree 2 vertices in H, and
V≥3 = set of degree ≥ 3 vertices in H.
Number of edges between H and F ,
E (H,F ) ≥ 2V≤1 + V2
> V≤1 + V2 + V≥3 (∵ V≤1 > V≥3)
= V (H)> E (H).
F
H=G - F ;
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 5 / 17
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Randomized Algorithm for UFVS
Claim : If G is graph with minimum degree ≥ 3, then number of edgesincident to any FVS F is ≥ E(G)
2 .
Proof: Let
V≤1 = set of degree ≤ 1 vertices in H,
V2 = set of degree 2 vertices in H, and
V≥3 = set of degree ≥ 3 vertices in H.
Number of edges between H and F ,
E (H,F ) ≥ 2V≤1 + V2
> V≤1 + V2 + V≥3 (∵ V≤1 > V≥3)
= V (H)> E (H).
F
H=G - F ;
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 5 / 17
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Randomized Algorithm for UFVS
Claim : If G is graph with minimum degree ≥ 3, then number of edgesincident to any FVS F is ≥ E(G)
2 .
Proof: Let
V≤1 = set of degree ≤ 1 vertices in H,
V2 = set of degree 2 vertices in H, and
V≥3 = set of degree ≥ 3 vertices in H.
Number of edges between H and F ,
E (H,F ) ≥ 2V≤1 + V2
> V≤1 + V2 + V≥3 (∵ V≤1 > V≥3)
= V (H)> E (H).
F
H=G - F ;
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 5 / 17
![Page 22: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/22.jpg)
Randomized Algorithm for UFVS
Claim : If G is graph with minimum degree ≥ 3, then number of edgesincident to any FVS F is ≥ E(G)
2 .
Proof: Let
V≤1 = set of degree ≤ 1 vertices in H,
V2 = set of degree 2 vertices in H, and
V≥3 = set of degree ≥ 3 vertices in H.
Number of edges between H and F ,
E (H,F ) ≥ 2V≤1 + V2
> V≤1 + V2 + V≥3 (∵ V≤1 > V≥3)
= V (H)> E (H).
F
H=G - F ;
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 5 / 17
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Randomized Algorithm for UFVS
AlgorithmInitially we set S ← ∅. Now run the following steps k times.
1: Apply preprocessing rules and create an equivalent instance (G ′, k ′)
2: Pick an edge e, u.a.r (i.e with probability 1E(G ′))
3: Choose an end point of e, u.a.r (i.e with probability 12) into S and
delete it from the graph.
Now if S is a FVS, output S , otherwise output No.
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Analysis
If the input instance is No instance Pr[Algorithm output No] = 1.Let the input instance is Yes instance and F is a FVS od size ≤ k .
Pr[Choosing an edge incident to F in step 2] ≥ 1
2
Pr[Chosen vertex is in F in step 3] ≥ 1
2· 1
2
Pr[S=F] ≥ 1
4k
Now we repeat the algorithm 4k times.
Pr[Algorithm fails in all repetitions] ≤(1− 1
4k
)4k ≤ 1e .
Pr[Algorithm succeed at least once] ≥ 1− 1e ≥
12
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Color Coding
This technique is introduced by Alon et al. (1995)
This technique is used to solve constant treewidth k-sized subgraphisomorphism problem.
We illustrate this technique by applying to k-path
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Color Coding
This technique is introduced by Alon et al. (1995)
This technique is used to solve constant treewidth k-sized subgraphisomorphism problem.
We illustrate this technique by applying to k-path
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k-path
k-path
Input: An undirected graph G and a positive integer kParameter: kQuestion: Does there exists a path on k vertices in G
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Colorful path
v6
v7
v5
v1
v4
v2
v3v6
v7
v5
v1
v4
v2
v3
colorful path on 5 vertices in the graph G ?
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Colorful path
v6
v7
v5
v1
v4
v2
v3v6
v7
v5
v1
v4
v2
v3
colorful path on 5 vertices in the graph G ?
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Algorithm for k-path
Color each vertex of the input graph G , u.a.r using from the set of kcolors, [k]
Check whether there exists a colorful k-path in the colored graph andoutput Yes/No accordingly
Running Time : Time to check colorful k-path × nO(1)
Probability of success
If (G , k) is a No instance, the probability of success is 1.
If (G , k) is an Yes instance, the probability of success is at least k!kk .
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Algorithm for k-path
Color each vertex of the input graph G , u.a.r using from the set of kcolors, [k]
Check whether there exists a colorful k-path in the colored graph andoutput Yes/No accordingly
Running Time : Time to check colorful k-path × nO(1)
Probability of success
If (G , k) is a No instance, the probability of success is 1.
If (G , k) is an Yes instance, the probability of success is at least k!kk .
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 11 / 17
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Algorithm for k-path
Color each vertex of the input graph G , u.a.r using from the set of kcolors, [k]
Check whether there exists a colorful k-path in the colored graph andoutput Yes/No accordingly
Running Time : Time to check colorful k-path × nO(1)
Probability of success
If (G , k) is a No instance, the probability of success is 1.
If (G , k) is an Yes instance, the probability of success is at least k!kk .
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 11 / 17
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Algorithm for k-path
Color each vertex of the input graph G , u.a.r using from the set of kcolors, [k]
Check whether there exists a colorful k-path in the colored graph andoutput Yes/No accordingly
Running Time : Time to check colorful k-path × nO(1)
Probability of success
If (G , k) is a No instance, the probability of success is 1.
If (G , k) is an Yes instance, the probability of success is at least k!kk .
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 11 / 17
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DP for Checking colorful k-path
We introduce 2k · |V (G )| Boolean variables:
x(v ,C ) = TRUE for some v ∈ V (G ) and C ⊆ [k]m
There is path ends at v where each color in C appearsexactly once and no other color appears.
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DP for Checking colorful k-path
Clearly, x(v , {color(v)}) = TRUE. Recurrence for vertex v with color r :
x(v ,C ) =∨
uv∈E(G)
x(u,C \ {r})
If we know every x(v ,C ) with |C | = i , then we can determine everyx(v ,C ) with |C | = i + 1. All the values can be determined in timeO(2k · |E (G )|).
There is a colorful path ends at t ⇐⇒ x(t, [k]) = TRUE for some t.
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Analysis for k-path
The algorithm for k-path has
Running time 2knO(1)
Success probability
at least k!kk if (G , k) is an Yes instance
1 if (G , k) is an No instance
Now run the algorithm kk
k! (≤ ek) times and output Yes if at least once weget an Yes answer, otherwise output No.
Probability of failure ≤(1− k!
kk
)kk/k! ≤ e−1
k-path can be solved in randomized (2e)knO(1) time, with constant suc-cess probability.
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Analysis for k-path
The algorithm for k-path has
Running time 2knO(1)
Success probability
at least k!kk if (G , k) is an Yes instance
1 if (G , k) is an No instance
Now run the algorithm kk
k! (≤ ek) times and output Yes if at least once weget an Yes answer, otherwise output No.
Probability of failure ≤(1− k!
kk
)kk/k! ≤ e−1
k-path can be solved in randomized (2e)knO(1) time, with constant suc-cess probability.
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Analysis for k-path
The algorithm for k-path has
Running time 2knO(1)
Success probability
at least k!kk if (G , k) is an Yes instance
1 if (G , k) is an No instance
Now run the algorithm kk
k! (≤ ek) times and output Yes if at least once weget an Yes answer, otherwise output No.
Probability of failure ≤(1− k!
kk
)kk/k! ≤ e−1
k-path can be solved in randomized (2e)knO(1) time, with constant suc-cess probability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 14 / 17
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Analysis for k-path
The algorithm for k-path has
Running time 2knO(1)
Success probability
at least k!kk if (G , k) is an Yes instance
1 if (G , k) is an No instance
Now run the algorithm kk
k! (≤ ek) times and output Yes if at least once weget an Yes answer, otherwise output No.
Probability of failure ≤(1− k!
kk
)kk/k! ≤ e−1
k-path can be solved in randomized (2e)knO(1) time, with constant suc-cess probability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 14 / 17
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Analysis for k-path
The algorithm for k-path has
Running time 2knO(1)
Success probability
at least k!kk if (G , k) is an Yes instance
1 if (G , k) is an No instance
Now run the algorithm kk
k! (≤ ek) times and output Yes if at least once weget an Yes answer, otherwise output No.
Probability of failure ≤(1− k!
kk
)kk/k! ≤ e−1
k-path can be solved in randomized (2e)knO(1) time, with constant suc-cess probability.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 14 / 17
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Derandomization
Suppose we have a list of colorings col1, col2, . . . , colm such that forany S ⊆ V with |S | = k there exists i , coli is one-to-one on S , theninstead of random coloring we can use these list of colorings to get adeterministic algorithm.
Such a list of colorings is called an (n, k)-family of perfect hashfunctions
There exists an (n, k)-family of perfect hash functions of sizeekkO(log k) log2 n and can be constructed in time linear in the outputsize
k-path can be solved deterministically in (2e)kkO(log k)nO(1) time.
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Derandomization
Suppose we have a list of colorings col1, col2, . . . , colm such that forany S ⊆ V with |S | = k there exists i , coli is one-to-one on S , theninstead of random coloring we can use these list of colorings to get adeterministic algorithm.
Such a list of colorings is called an (n, k)-family of perfect hashfunctions
There exists an (n, k)-family of perfect hash functions of sizeekkO(log k) log2 n and can be constructed in time linear in the outputsize
k-path can be solved deterministically in (2e)kkO(log k)nO(1) time.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 15 / 17
![Page 43: Color Coding](https://reader034.vdocuments.net/reader034/viewer/2022052505/556216bcd8b42a00138b53a1/html5/thumbnails/43.jpg)
Derandomization
Suppose we have a list of colorings col1, col2, . . . , colm such that forany S ⊆ V with |S | = k there exists i , coli is one-to-one on S , theninstead of random coloring we can use these list of colorings to get adeterministic algorithm.
Such a list of colorings is called an (n, k)-family of perfect hashfunctions
There exists an (n, k)-family of perfect hash functions of sizeekkO(log k) log2 n and can be constructed in time linear in the outputsize
k-path can be solved deterministically in (2e)kkO(log k)nO(1) time.
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Derandomization
Suppose we have a list of colorings col1, col2, . . . , colm such that forany S ⊆ V with |S | = k there exists i , coli is one-to-one on S , theninstead of random coloring we can use these list of colorings to get adeterministic algorithm.
Such a list of colorings is called an (n, k)-family of perfect hashfunctions
There exists an (n, k)-family of perfect hash functions of sizeekkO(log k) log2 n and can be constructed in time linear in the outputsize
k-path can be solved deterministically in (2e)kkO(log k)nO(1) time.
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 15 / 17
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Chromatic Coding
Venkatesh Raman (IMSc) Randomized Techniques in FPT 3 March 2014 16 / 17
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Thank You
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