We consider the problem of estimating the value of MAX-CUT in a graph in the streaming model of computation. At one extreme, there is a trivial 2-approximation for this problem that uses only O(log n) space, namely, count the number of edges and output half of this value as the estimate for the size of the MAX-CUT. On the other extreme, for any fixed epsilon > 0, if one allows (O) over tilde (n) space, a (1 + epsilon)-approximate solution to the MAX-CUT value can be obtained by storing an (O) over tilde (n)-size sparsifier that essentially preserves MAX-CUT value. Our main result is that any (randomized) single pass streaming algorithm that breaks the 2-approximation barrier requires Omega(n)-space, thus resolving the space complexity of an...
We study the maximum matching problem in the random-order semi-streaming setting. In this problem, t...
In this paper we obtain improved upper and lower bounds for the best approximation factor for Sparse...
In a recent breakthrough, Paz and Schwartzman (SODA'17) presented a single-pass (2+epsilon)-approxim...
This talk will begin with tutorial-style material, and then focus on the following result. $1+\Omeg...
We show that the exact computation of a minimum or a maximum cut of a given graph G is out of reach ...
We present a streaming algorithm that makes one pass over the edges of an unweighted graph pre-sente...
Consider the following gap cycle counting problem in the streaming model: The edges of a 2-regular n...
Graph Sparsification in the Semi-Streaming Model Analyzing massive data sets has been one of the key...
We study the communication complexity of evaluating functions when the input data is randomly alloca...
We consider the problem of estimating the size of a maximum matching when the edges are revealed in ...
Estimating the size of the maximum matching is a canonical problem in graph analysis, and one that h...
We study the problem of estimating the size of a matching when the graph is revealed in a streaming ...
We study the problem of approximating the value of a Unique Game instance in the streaming model. A ...
Despite the large amount of work on solving graph problems in the data stream model, there do not ex...
The last decade witnessed the extensive studies of algorithms for data streams. In this model, the i...
We study the maximum matching problem in the random-order semi-streaming setting. In this problem, t...
In this paper we obtain improved upper and lower bounds for the best approximation factor for Sparse...
In a recent breakthrough, Paz and Schwartzman (SODA'17) presented a single-pass (2+epsilon)-approxim...
This talk will begin with tutorial-style material, and then focus on the following result. $1+\Omeg...
We show that the exact computation of a minimum or a maximum cut of a given graph G is out of reach ...
We present a streaming algorithm that makes one pass over the edges of an unweighted graph pre-sente...
Consider the following gap cycle counting problem in the streaming model: The edges of a 2-regular n...
Graph Sparsification in the Semi-Streaming Model Analyzing massive data sets has been one of the key...
We study the communication complexity of evaluating functions when the input data is randomly alloca...
We consider the problem of estimating the size of a maximum matching when the edges are revealed in ...
Estimating the size of the maximum matching is a canonical problem in graph analysis, and one that h...
We study the problem of estimating the size of a matching when the graph is revealed in a streaming ...
We study the problem of approximating the value of a Unique Game instance in the streaming model. A ...
Despite the large amount of work on solving graph problems in the data stream model, there do not ex...
The last decade witnessed the extensive studies of algorithms for data streams. In this model, the i...
We study the maximum matching problem in the random-order semi-streaming setting. In this problem, t...
In this paper we obtain improved upper and lower bounds for the best approximation factor for Sparse...
In a recent breakthrough, Paz and Schwartzman (SODA'17) presented a single-pass (2+epsilon)-approxim...