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The Min Cost Flow Problem
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The Min Cost Flow problem
• We want to talk about multi-source, multi-sink
flows than just “flows from s to t”.
• We want to impose lower bounds as well as
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• We want to impose lower bounds as well as
capacities on a given arc. Also, arcs should have
costs.
• Rather than maximize the value (i.e. amount) of
the flow through the network we want to
minimize the cost of the flow.
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Flow Networks with Costs
• Flow networks with costs are the problem instances of the min cost flow problem.
• A flow network with costs is given by
1) a directed graph G = (V,E)
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1) a directed graph G = (V,E)2) capacities c: E → R.
3) balances b: V → R.
4) costs k: V × V → R. k(u,v) = -k(v,u).
• Convention: c(u,v)=0 for (u,v) not in E.
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Feasible Flows
• Given a flow network with costs, a feasible flow is a feasible solution to the min cost flow problem.
• A feasible flow is a map f: V × V → R satisfying
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capacity constraints: ∀ (u,v): f(u,v) ≤ c(u,v).
Skew symmetry: ∀ (u,v): f(u,v) = – f(v,u).
Balance Constraints: ∀ u ∈ V: ∑v ∈ V f(u,v) =b(u)
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Cost of Feasible Flows
• The cost of a feasible flow f is
cost(f)= ½ ∑(u,v) ∈ V × V k(u,v) f(u,v)
• The Min Cost Flow Problem: Given a
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• The Min Cost Flow Problem: Given a flow network with costs, find the feasible flow f that minimizes cost(f).
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Max Flow Problem vs. Min Cost
Flow Problem
Max Flow Problem
Problem Instance:c: E → R+.
Min Cost Flow Problem
Problem Instance:c: E → R.
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→
Special vertices s,t.
Feasible solution:∀ u∈V–{s,t}: ∑v ∈ V f(u,v) = 0
Objective:
Maximize |f(s,V)|
→
Maps b,k.
Feasible solution:∀ u∈V: ∑v ∈ V f(u,v) = b(u)
Objective:
Minimize cost(f)
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Negative Capacities
• c(u,v) < 0.
• Let l(v,u) = – c(u,v).
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• f(u,v) ≤ c(u,v) iff f(v,u) ≥ – c(u,v) = l(v,u).
• l(v,u) is a lower bound on the net flow from v to
u for any feasible flow.
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Balance Constraints
• Vertices u with b(u)>0 are producing flow.
• Vertices u with b(u)<0 are consumingflow
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flow
• Vertices u with b(u)=0 are shipping flow.
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.
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Can we solve the max-flow problem using software
for the min-cost flow problem?
Unknown Balance!! Unknown Balance!!
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All other costs 0, all balances 0.
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Capacity 29, Cost -1Capacity 29, Cost 0
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Circulation networks
• Flow networks with b ≡ 0 are called
circulation networks.
• A feasible flow in a circulation network is
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• A feasible flow in a circulation network is called a feasible circulation.
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Unknown Balances!!
Unknown Balances!!
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Integrality theorem for min cost flow
If a flow network with costs has integral capacities and balances and a feasible flow in the network exists, then there is a minimum cost feasible flow which is
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minimum cost feasible flow which is integral on every arc.
(shown later by “type checking”)
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Assignment problem
• Given integer weight matrix
(w(i,j)), 1 ≤ i,j ≤ n.
π
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• Find a permutation π on {1,..,n} maximizing
∑i w(i,π(i)).
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Min cost flow model of Ahuja et al
• Ahuja operates with non-reduced flows, we work
with reduced flows (net flows). They do not
require flows and costs to be skew-symmetric.
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Unreduced vs net flows
2 4-2
2
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Unreduced flow Net flow
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Min cost flow model of Ahuja
• Ahuja operates with non-reduced flows, we work with reduced flows (net flows). They do not require flows and costs to be skew symmetric.
• The difference matters only bidirectional arcs
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• The difference matters only bidirectional arcs (an arc from u to v and an arc from v to u) with positive capcity in each direction.
• One can translate (reduce) the Ahuja version to our version (exercise).
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Tanker Scheduling Problem
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Capacity 4, Cost 1All balances 0
Capacity 1, Cost 0
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Capacity 1, Lower Bound 1, Cost 0
Capacity 1, Cost 0
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Hopping Airplane Problem
• An airplane must travel from city 1, to city 2, to
city 3, .., to city n. At most p passengers can be
carried at any time.
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• bij passengers want to go from city i to city j and
will pay fij for the trip.
• How many passengers should be picked up at
each city in order to maximize profits?
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Local Search Pattern
LocalSearch(ProblemInstance x)
y := feasible solution to x;
while ∃∃∃∃ z ∊N(y): v(z)<v(y) do
y := z;
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y := z;
od;
return y;
N(y) is a neighborhood of y.
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Local search checklist
Design:
• How do we find the first feasible solution?
• Neighborhood design?
• Which neighbor to choose?
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Analysis:• Partial correctness? (termination ⇒correctness)
• Termination?
• Complexity?
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The first feasible flow?
• Because of negative capacities and balance
constraints, finding the first flow is non-trivial.
• The zero flow may not work and there may not
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• The zero flow may not work and there may not
be any feasible flow for a given instance.
• We can find the first feasible flow, if one exists,
by reducing this problem to a max flow problem.
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Neighborhood design
• Given a feasible flow, how can we find a slightly different (and hopefully slightly better) flow?
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All other costs 0, all balances 0.
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Capacity 29, Cost -1Capacity 29, Cost 0
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The residual network
• Let G=(V,E,c,b,k) be a flow network with costs and let f be a flow in G.
• The residual network Gf is the flow
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• The residual network Gf is the flow network with costs inherited from G and edges, capacities and balances given by:
Ef = {(u,v) ∈ V × V| f(u,v) < c(u,v)}
cf(u,v) = c(u,v) - f(u,v) ≥ 0
bf(u)=0
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Lemma 3
Let
• G=(V,E,c,b,k) be a flow network with costs
• f be a feasible flow in G
• Gf be the residual network
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• Gf be the residual network
• f’ be a feasible flow in Gf
Then
• f+f’ is a feasible flow in G with cost(f+f’)=cost(f)+cost(f’)
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Lemma 4
Let
• G=(V,E,c,b,k) be a flow network with costs
• f be a feasible flow in G
• f’ be a feasible flow in G
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• f’ be a feasible flow in G
Then
• f’-f is a feasible flow in Gf
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Cycle Flows
• Let C = (u1 → u2 → u3 … → uk=u1) be a
simple cycle in G.
• The cycle flow γCδ is the circulation
defined by
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defined by
γCδ(ui, ui+1) = δ
γCδ(ui+1, ui) = - δ
γCδ(u,v) = 0 otherwise.
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Augmenting cycles
• Let G be a flow network with costs and Gf
the residual network.
• An augmenting cycle
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• An augmenting cycleC=(u1, u2, …, ur = u1) is a simple cycle in Gf for which
cost(γCδ)<0 where δ is the minimum
capacity cf(ui, ui+1), i = 1…r-1
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Klein’s algorithm for min cost flow
MinCostFlow(G)
Using max flow algorithm, find feasible flow f in G (if no such flow exist, abort).
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while(∃ augmenting cycle C in Gf){
δ = min{cf(e) | e on C}
f := f + γCδ
}
output f
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Klein’s algorithm
• If Klein’s algorithm terminates it produces a feasible flow in G (by Lemma 3).
• Is it partially correct?
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• Is it partially correct?
• Does it terminate?
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Circulation Decomposition Lemma
Let G be a circulation network with no negative capacities. Let f be a feasible circulation in G. Then, f may be written as a sum of cycle flows:
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a sum of cycle flows:
f = γC1δ1 + γC2
δ2 + … + γCmδm
where each cycle flow is a feasible circulation in G.
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CDL ⇒ Partial Correctness of Klein
• Suppose f is not an minimum cost flow in G. We should show that Gf has an augmenting cycle.
• Let f * be a minimum cost flow in G.
• f * - f is a feasible circulation in G of strictly negative cost
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• f * - f is a feasible circulation in Gf of strictly negative cost (Lemma 4).
• f * - f is a sum of cycle flows, feasible in Gf (by CDL).
• At least one of them must have strictly negative cost.
• The corresponding cycle is an augmenting cycle.
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Termination
• Assume integer capacities and balances.
• For any feasible flow f occuring in Klein’s algorithm and any u,v, the flow f(u,v) is an integer between –c(v,u) and c(u,v).
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• Thus there are only finitely many possibilities for f.
• In each iteration, f is improved – thus we never see an old f again.
• Hence we terminate.
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Integrality theorem for min cost flow
If a flow network with costs has integral capacities and balances and a feasible flow in the network exists, then there is a minimum cost feasible flow which is
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minimum cost feasible flow which is integral on every arc.
Proof by “type checking” Klein’s algorithm
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Complexity
• How fast can we perform a single iteration of the local search?
• How many iterations do we have?
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• How many iterations do we have?
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Complexity of a single iteration
• An iteration is dominated by finding an augmenting cycle.
• An augmenting cycle is a cycle
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• An augmenting cycle is a cycle (u1, u2, … ur=u1) in Gf with
∑i k(ui ,ui+1) < 0
• How to find one efficiently? Exercise 7.
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Number of iterations
• As Ford-Fulkerson, Klein’s algorithm may use an exponential number of iterations, if care is not taken choosing the augumentation (Exercise 6).
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augumentation (Exercise 6).
• Fact: If the cycle with minimum average edge cost is chosen, there can be at most O(|E|2 |V| log |V|) iterations.
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Generality of Languages
Min Cost Flow
Linear Programs
Reduction
Klein’salgorithm
Simplex Algorithm,
Interior Point Algorithms
AlgorithmIn
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asin
g g
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lity
Decre
asin
g e
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Algorithm
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Maximum
Cardinality
Matching
Max (s,t)-Flow
Hopcroft-Karp (dADS)
Reduction
Reduction
Edmonds-Karp
Algorithm
Algorithm
Incre
asin
g g
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lity
Decre
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