AbstractLet f(x1, …, xk) be a Boolean function that k parties wish to collaboratively evaluate, where each xi is a bit-string of length n. The ith party knows each input argument except xi; and each party has unlimited computational power. They share a blackboard, viewed by all parties, where they can exchange messages. The objective is to minimize the number of bits written on the board. We prove lower bounds of the form Ω(n · c−k), for the number of bits that need to be exchanged in order to compute some (explicitly given) polynomial time computable functions. Our bounds hold even if the parties only wish to have a 1 % advantage at guessing the value of f on random inputs. The lower bound proofs are based on discrepancy upper bounds for s...
AbstractConsider the “Number in Hand” multiparty communication complexity model, where k players hol...
We revisit the question of minimizing the randomness complexity of protocols for secure multiparty c...
We exhibit an explicit function f: {0,1}n → {0,1} that can be computed by a nonde-terministic number...
AbstractLet f(x1, …, xk) be a Boolean function that k parties wish to collaboratively evaluate, wher...
In 1989, Babai, Nisan and Szegedy gave a construction of a pseudorandom generator for logspace, base...
AbstractWe derive a general technique for obtaining lower bounds on the multiparty communication com...
In this paper we prove lower bounds on randomized multiparty communication complexity, both in the b...
International audienceWe consider multiparty information-theoretic private protocols, and specifical...
In the `Number-on-Forehead\u27 (NOF) model of multiparty communication, the input is a k times m bo...
Communication complexity is an area of complexity theory that studies an abstract model of computati...
We prove that almost all Boolean function has a high $k$--party communication complexity. The 2--par...
AbstractWe obtain the first non-trivial time–space tradeoff lower bound for functions f:{0, 1}n→{0, ...
We extend recent techniques for time-space tradeoff lower bounds using multiparty communication comp...
We prove two classes of lower bounds on the communication complexity of information-theoretically se...
We define a model of size-S R-way branching programs with oracles that can make up to S distinct ora...
AbstractConsider the “Number in Hand” multiparty communication complexity model, where k players hol...
We revisit the question of minimizing the randomness complexity of protocols for secure multiparty c...
We exhibit an explicit function f: {0,1}n → {0,1} that can be computed by a nonde-terministic number...
AbstractLet f(x1, …, xk) be a Boolean function that k parties wish to collaboratively evaluate, wher...
In 1989, Babai, Nisan and Szegedy gave a construction of a pseudorandom generator for logspace, base...
AbstractWe derive a general technique for obtaining lower bounds on the multiparty communication com...
In this paper we prove lower bounds on randomized multiparty communication complexity, both in the b...
International audienceWe consider multiparty information-theoretic private protocols, and specifical...
In the `Number-on-Forehead\u27 (NOF) model of multiparty communication, the input is a k times m bo...
Communication complexity is an area of complexity theory that studies an abstract model of computati...
We prove that almost all Boolean function has a high $k$--party communication complexity. The 2--par...
AbstractWe obtain the first non-trivial time–space tradeoff lower bound for functions f:{0, 1}n→{0, ...
We extend recent techniques for time-space tradeoff lower bounds using multiparty communication comp...
We prove two classes of lower bounds on the communication complexity of information-theoretically se...
We define a model of size-S R-way branching programs with oracles that can make up to S distinct ora...
AbstractConsider the “Number in Hand” multiparty communication complexity model, where k players hol...
We revisit the question of minimizing the randomness complexity of protocols for secure multiparty c...
We exhibit an explicit function f: {0,1}n → {0,1} that can be computed by a nonde-terministic number...