Add to ORKGWe give the first exponential separation between quantum and bounded-error randomized one-way communication complexity. Specifically, we define the Hidden Matching Problem HMn: Alice gets as input a string x ∈ {0, 1} n and Bob gets a perfect matching M on the n coordinates. Bob’s goal is to output a tuple 〈i, j, b 〉 such that the edge (i, j) belongs to the matching M and b = xi ⊕ xj. We prove that the quantum one-way communication complexity of HMn is O(log n), yet any randomized one-way protocol with bounded error must use Ω ( √ n) bits of communication. No asymptotic gap for one-way communication was previously known. Our bounds also hold in the model of Simultaneous Messages (SM) and hence we provide the first exponential separation bet...
We give an exponential separation between one-way quantum and classical communication protocols for ...
AbstractThis work studies the quantum query complexity of Boolean functions in an unbounded-error sc...
Although a quantum state requires exponentially many classical bits to describe, the laws of quantum...
We give a tight lower bound of Omega(\sqrt{n}) for the randomized one-way communication complexity o...
We give a tight lower bound of Ω( n) for the randomized one-way communication complexity of the Bool...
© 2018, Springer International Publishing AG. We explore multi-round quantum memoryless communicatio...
We consider the problem of bounded-error quantum state identification: given either state α0 or stat...
We study the simultaneous message passing model of communication complexity. Building on the quantum...
We give an exponential separation between one-way quan-tum and classical communication protocols for...
We give an exponential separation between one-way quantum and classical communication protocols for ...
We give an exponential separation between one-way quantum and classical communication protocols for ...
Classical Communication complexity has been intensively studied since its conception two decades ag...
Communication is a universal process by which two or more individuals exchange information. A commun...
Communication is a universal process by which two or more individuals exchange information. A commun...
We use the venerable "fooling set" method to prove new lower bounds on the quantum communication com...
We give an exponential separation between one-way quantum and classical communication protocols for ...
AbstractThis work studies the quantum query complexity of Boolean functions in an unbounded-error sc...
Although a quantum state requires exponentially many classical bits to describe, the laws of quantum...
We give a tight lower bound of Omega(\sqrt{n}) for the randomized one-way communication complexity o...
We give a tight lower bound of Ω( n) for the randomized one-way communication complexity of the Bool...
© 2018, Springer International Publishing AG. We explore multi-round quantum memoryless communicatio...
We consider the problem of bounded-error quantum state identification: given either state α0 or stat...
We study the simultaneous message passing model of communication complexity. Building on the quantum...
We give an exponential separation between one-way quan-tum and classical communication protocols for...
We give an exponential separation between one-way quantum and classical communication protocols for ...
We give an exponential separation between one-way quantum and classical communication protocols for ...
Classical Communication complexity has been intensively studied since its conception two decades ag...
Communication is a universal process by which two or more individuals exchange information. A commun...
Communication is a universal process by which two or more individuals exchange information. A commun...
We use the venerable "fooling set" method to prove new lower bounds on the quantum communication com...
We give an exponential separation between one-way quantum and classical communication protocols for ...
AbstractThis work studies the quantum query complexity of Boolean functions in an unbounded-error sc...
Although a quantum state requires exponentially many classical bits to describe, the laws of quantum...