Your search keyword '"Harrow, Aram W."' showing total 11 results

1. Adversarial Hypothesis Testing and a Quantum Stein’s Lemma for Restricted Measurements.

Author

Brandao, Fernando G. S. L., Harrow, Aram W., Lee, James R., and Peres, Yuval

Subjects

*QUANTUM entropy, *QUANTUM states, *QUANTUM information theory, *ERROR rates, *HYPOTHESIS, *TOPOLOGICAL entropy, *QUANTUM cryptography

Abstract

Recall the classical hypothesis testing setting with two sets of probability distributions $P$ and $Q$. One receives either $n$ i.i.d. samples from a distribution $p \in P$ or from a distribution $q \in Q$ and wants to decide from which set the points were sampled. It is known that the optimal exponential rate at which errors decrease can be achieved by a simple maximum-likelihood ratio test which does not depend on $p$ or $q$ , but only on the sets $P$ and $Q$. We consider an adaptive generalization of this model where the choice of $p \in P$ and $q \in Q$ can change in each sample in some way that depends arbitrarily on the previous samples. In other words, in the $k^{th}$ round, an adversary, having observed all the previous samples in rounds $1,\ldots,k-1$ , chooses $p_{k} \in P$ and $q_{k} \in Q$ , with the goal of confusing the hypothesis test. We prove that even in this case, the optimal exponential error rate can be achieved by a simple maximum-likelihood test that depends only on $P$ and $Q$. We then show that the adversarial model has applications in hypothesis testing for quantum states using restricted measurements. For example, it can be used to study the problem of distinguishing entangled states from the set of all separable states using only measurements that can be implemented with local operations and classical communication (LOCC). The basic idea is that in our setup, the deleterious effects of entanglement can be simulated by an adaptive classical adversary. We prove a quantum Stein’s Lemma in this setting: In many circumstances, the optimal hypothesis testing rate is equal to an appropriate notion of quantum relative entropy between two states. In particular, our arguments yield an alternate proof of Li and Winter’s recent strengthening of strong subadditivity for von Neumann entropy. [ABSTRACT FROM AUTHOR]

Published

2020

2. Expected Communication Cost of Distributed Quantum Tasks.

Author

Anshu, Anurag, Garg, Ankit, Harrow, Aram W., and Yao, Penghui

Subjects

HUFFMAN codes, DATA compression, QUANTUM mechanics, PROBABILITY theory, INFORMATION theory, CRYPTOGRAPHY

Abstract

A central question in the classical information theory is that of source compression, which is the task where Alice receives a sample from a known probability distribution and needs to transmit it to the receiver Bob with small error. This problem has a one-shot solution due to Huffman, in which the messages are of variable length and the expected length of the messages matches the asymptotic and independent identically distributed (i.i.d.) compression rate of the Shannon entropy of the source. In this paper, we consider a quantum extension of above task, where Alice receives a sample from a known probability distribution and needs to transmit a part of a pure quantum state (that is associated with the sample) to Bob. We allow entanglement assistance in the protocol, so that the communication is possible through classical messages, for example using quantum teleportation. The classical messages can have a variable length, and the goal is to minimize their expected length. We provide a characterization of the expected communication cost of this task, by giving a lower bound that is near optimal up to some additive factors. A special case of above task, and the quantum analogue of the source compression problem, is when Alice needs to transmit the whole of her pure quantum state. Here, we show that there is no one-shot interactive scheme which matches the asymptotic and i.i.d. compression rate of the von Neumann entropy of the average quantum state. This is a relatively rare case in the quantum information theory where the cost of a quantum task is significantly different from its classical analogue. Furthermore, we also exhibit similar results for the fully quantum task of quantum state redistribution, employing some different techniques. We show implications for the one-shot version of the problem of quantum channel simulation. [ABSTRACT FROM AUTHOR]

Published

2018

3. ENTANGLEMENT SPREAD AND CLEAN RESOURCE INEQUALITIES.

Author

HARROW, ARAM W.

Subjects

QUANTUM entanglement, MATHEMATICAL inequalities, QUANTUM information theory, INFORMATION resources, DECOHERENCE (Quantum mechanics)

Published

2010

4. The Quantum Reverse Shannon Theorem and Resource Tradeoffs for Simulating Quantum Channels.

Author

Bennett, Charles H., Devetak, Igor, Harrow, Aram W., Shor, Peter W., and Winter, Andreas

Subjects

QUANTUM information theory, CHANNEL coding, COMPUTER simulation, GENERALIZATION, MEMORYLESS systems

Abstract

Dual to the usual noisy channel coding problem, where a noisy (classical or quantum) channel is used to simulate a noiseless one, reverse Shannon theorems concern the use of noiseless channels to simulate noisy ones, and more generally the use of one noisy channel to simulate another. For channels of nonzero capacity, this simulation is always possible, but for it to be efficient, auxiliary resources of the proper kind and amount are generally required. In the classical case, shared randomness between sender and receiver is a sufficient auxiliary resource, regardless of the nature of the source, but in the quantum case, the requisite auxiliary resources for efficient simulation depend on both the channel being simulated, and the source from which the channel inputs are coming. For tensor power sources (the quantum generalization of classical memoryless sources), entanglement in the form of standard ebits (maximally entangled pairs of qubits) is sufficient, but for general sources, which may be arbitrarily correlated or entangled across channel inputs, additional resources, such as entanglement-embezzling states or backward communication, are generally needed. Combining existing and new results, we establish the amounts of communication and auxiliary resources needed in both the classical and quantum cases, the tradeoffs among them, and the loss of simulation efficiency when auxiliary resources are absent or insufficient. In particular, we find a new single-letter expression for the excess forward communication cost of coherent feedback simulations of quantum channels (i.e., simulations in which the sender retains what would escape into the environment in an ordinary simulation), on nontensor-power sources in the presence of unlimited ebits but no other auxiliary resource. Our results on tensor power sources establish a strong converse to the entanglement-assisted capacity theorem. [ABSTRACT FROM AUTHOR]

Published

2014

5. A Communication-Efficient Nonlocal Measurement With Application to Communication Complexity and Bipartite Gate Capacities.

Author

Harrow, Aram W. and Leung, Debbie W.

Subjects

*QUANTUM entanglement, *COMPUTER networks, *SIMULATION methods & models, *QUANTUM theory, *INFORMATION theory, *COMPUTER network protocols, *DATA transmission systems

Abstract

Two dual questions in quantum information theory are to determine the communication cost of simulating a bipartite unitary gate, and to determine their communication capacities. We present a bipartite unitary gate with two surprising properties: 1) simulating it with the assistance of unlimited EPR pairs requires far more communication than with a better choice of entangled state, and 2) its communication capacity is far lower than its capacity to create entanglement. This suggests that 1) unlimited EPR pairs are not the most general model of entanglement assistance for two-party communication tasks, and 2) the entangling and communicating abilities of a unitary interaction can vary nearly independently. The technical contribution behind these results is a communication-efficient protocol for measuring whether an unknown shared state lies in a specified rank-one subspace or its orthogonal complement. [ABSTRACT FROM PUBLISHER]

Published

2011

6. Quantum de Finetti Theorems Under Local Measurements with Applications

Author

Fernando G. S. L. Brandão, Aram W. Harrow, Massachusetts Institute of Technology. Department of Physics, Harrow, Aram W., Massachusetts Institute of Technology. Center for Theoretical Physics, and Harrow, Aram W

Subjects

FOS: Computer and information sciences, FOS: Physical sciences, 0102 computer and information sciences, Quantum entanglement, Quantum capacity, Computational Complexity (cs.CC), Information theory, 01 natural sciences, Combinatorics, Quantum state, 0103 physical sciences, 0101 mathematics, Quantum information, 010306 general physics, Quantum, Mathematical Physics, Mathematics, Discrete mathematics, Quantum Physics, Quantum discord, 010102 general mathematics, Statistical and Nonlinear Physics, Quantum tomography, Computer Science - Computational Complexity, Multipartite, 010201 computation theory & mathematics, Qubit, Quantum algorithm, Quantum Physics (quant-ph), Quantum complexity theory

Abstract

Quantum de Finetti theorems are a useful tool in the study of correlations in quantum multipartite states. In this paper we prove two new quantum de Finetti theorems, both showing that under tests formed by local measurements one can get a much improved error dependence on the dimension of the subsystems. We also obtain similar results for non-signaling probability distributions. We give the following applications of the results: We prove the optimality of the Chen-Drucker protocol for 3-SAT, under the exponential time hypothesis. We show that the maximum winning probability of free games can be estimated in polynomial time by linear programming. We also show that 3-SAT with m variables can be reduced to obtaining a constant error approximation of the maximum winning probability under entangled strategies of O(m^{1/2})-player one-round non-local games, in which the players communicate O(m^{1/2}) bits all together. We show that the optimization of certain polynomials over the hypersphere can be performed in quasipolynomial time in the number of variables n by considering O(log(n)) rounds of the Sum-of-Squares (Parrilo/Lasserre) hierarchy of semidefinite programs. As an application to entanglement theory, we find a quasipolynomial-time algorithm for deciding multipartite separability. We consider a result due to Aaronson -- showing that given an unknown n qubit state one can perform tomography that works well for most observables by measuring only O(n) independent and identically distributed (i.i.d.) copies of the state -- and relax the assumption of having i.i.d copies of the state to merely the ability to select subsystems at random from a quantum multipartite state. The proofs of the new quantum de Finetti theorems are based on information theory, in particular on the chain rule of mutual information., 39 pages, no figure. v2: changes to references and other minor improvements. v3: added some explanations, mostly about Theorem 1 and Conjecture 5. STOC version. v4, v5. small improvements and fixes

Published

2017

7. The Quantum Reverse Shannon Theorem and Resource Tradeoffs for Simulating Quantum Channels

Author

Charles H. Bennett, Andreas Winter, Aram W. Harrow, Peter W. Shor, Igor Devetak, Massachusetts Institute of Technology. Department of Mathematics, Massachusetts Institute of Technology. Department of Physics, Harrow, Aram W., and Shor, Peter W.

Subjects

Channel code, Computer science, 020206 networking & telecommunications, Data_CODINGANDINFORMATIONTHEORY, 02 engineering and technology, Quantum entanglement, Library and Information Sciences, Topology, 01 natural sciences, Computer Science Applications, Channel capacity, symbols.namesake, Shannon–Hartley theorem, Qubit, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, symbols, 010306 general physics, Quantum information science, Quantum, Randomness, Computer Science::Information Theory, Information Systems, Communication channel

Abstract

Dual to the usual noisy channel coding problem, where a noisy (classical or quantum) channel is used to simulate a noiseless one, reverse Shannon theorems concern the use of noiseless channels to simulate noisy ones, and more generally the use of one noisy channel to simulate another. For channels of nonzero capacity, this simulation is always possible, but for it to be efficient, auxiliary resources of the proper kind and amount are generally required. In the classical case, shared randomness between sender and receiver is a sufficient auxiliary resource, regardless of the nature of the source, but in the quantum case, the requisite auxiliary resources for efficient simulation depend on both the channel being simulated, and the source from which the channel inputs are coming. For tensor power sources (the quantum generalization of classical memoryless sources), entanglement in the form of standard ebits (maximally entangled pairs of qubits) is sufficient, but for general sources, which may be arbitrarily correlated or entangled across channel inputs, additional resources, such as entanglement-embezzling states or backward communication, are generally needed. Combining existing and new results, we establish the amounts of communication and auxiliary resources needed in both the classical and quantum cases, the tradeoffs among them, and the loss of simulation efficiency when auxiliary resources are absent or insufficient. In particular, we find a new single-letter expression for the excess forward communication cost of coherent feedback simulations of quantum channels (i.e., simulations in which the sender retains what would escape into the environment in an ordinary simulation), on nontensor-power sources in the presence of unlimited ebits but no other auxiliary resource. Our results on tensor power sources establish a strong converse to the entanglement-assisted capacity theorem.

Published

2014

8. Local tests of global entanglement and a counterexample to the generalized area law

Author

Mario Szegedy, Aram W. Harrow, Dorit Aharonov, Daniel Nagaj, Zeph Landau, Umesh Vazirani, Massachusetts Institute of Technology. Department of Physics, and Harrow, Aram W.

Subjects

Quantum Physics, Property (philosophy), Quantum state, Computer science, Law, Bipartite graph, FOS: Physical sciences, State (functional analysis), Quantum entanglement, Quantum Physics (quant-ph), Constant (mathematics), Quantum, Counterexample

Abstract

We introduce a technique for applying quantum expanders in a distributed fashion, and use it to solve two basic questions: testing whether a bipartite quantum state shared by two parties is the maximally entangled state and disproving a generalized area law. In the process these two questions which appear completely unrelated turn out to be two sides of the same coin. Strikingly in both cases a constant amount of resources are used to verify a global property., National Science Foundation (U.S.) (Grant CCF-1111382), United States. Army Research Office (Contract W911NF-12-1-0486)

Published

2014

9. Product-State Approximations to Quantum States

Author

Fernando G. S. L. Brandão, Aram W. Harrow, Massachusetts Institute of Technology. Center for Theoretical Physics, Massachusetts Institute of Technology. Department of Physics, and Harrow, Aram W

Subjects

Discrete mathematics, Sublinear function, Statistical and Nonlinear Physics, 0102 computer and information sciences, Quantum entanglement, 01 natural sciences, symbols.namesake, 010201 computation theory & mathematics, Quantum state, Bounded function, 0103 physical sciences, symbols, Statistical physics, 010306 general physics, Ground state, Hamiltonian (quantum mechanics), Probabilistically checkable proof, Quantum, Mathematical Physics, Mathematics

Abstract

We show that for any many-body quantum state there exists an unentangled quantum state such that most of the two-body reduced density matrices are close to those of the original state. This is a statement about the monogamy of entanglement, which cannot be shared without limit in the same way as classical correlation. Our main application is to Hamiltonians that are sums of two-body terms. For such Hamiltonians we show that there exist product states with energy that is close to the ground-state energy whenever the interaction graph of the Hamiltonian has high degree. This proves the validity of mean-field theory and gives an explicitly bounded approximation error. If we allow states that are entangled within small clusters of systems but product across clusters then good approximations exist when the Hamiltonian satisfies one or more of the following properties: (1) high degree, (2) small expansion, or (3) a ground state where the blocks in the partition have sublinear entanglement. Previously this was known only in the case of small expansion or in the regime where the entanglement was close to zero. Our approximations allow an extensive error in energy, which is the scale considered by the quantum PCP (probabilistically checkable proof) and NLTS (no low-energy trivial-state) conjectures. Thus our results put restrictions on the possible Hamiltonians that could be used for a possible proof of the qPCP or NLTS conjectures. By contrast the classical PCP constructions are often based on constraint graphs with high degree. Likewise we show that the parallel repetition that is possible with classical constraint satisfaction problems cannot also be possible for quantum Hamiltonians, unless qPCP is false. The main technical tool behind our results is a collection of new classical and quantum de Finetti theorems which do not make any symmetry assumptions on the underlying states., National Science Foundation (U.S.) (Grants CCF-0916400, CCF-1111382, and CCF-1452616), United States. Army Research Office (contract W911NF-12-1-0486), Leverhulme Trust (Visiting Professorship VP2- 2013-041)

Published

2014

10. Adversarial hypothesis testing and a quantum stein's lemma for restricted measurements

Author

Yuval Peres, James R. Lee, Fernando G. S. L. Brandão, Aram W. Harrow, Massachusetts Institute of Technology. Department of Physics, and Harrow, Aram W.

Subjects

FOS: Computer and information sciences, Stein's lemma, Computer Science - Information Theory, FOS: Physical sciences, Von Neumann entropy, 02 engineering and technology, Quantum entanglement, Library and Information Sciences, 01 natural sciences, Combinatorics, Quantum state, 0103 physical sciences, FOS: Mathematics, 0202 electrical engineering, electronic engineering, information engineering, Quantum information, 010306 general physics, Statistical hypothesis testing, Mathematics, Discrete mathematics, Quantum Physics, LOCC, Information Theory (cs.IT), Probability (math.PR), 020206 networking & telecommunications, Quantum relative entropy, Computer Science Applications, Separable state, Probability distribution, Quantum Physics (quant-ph), Mathematics - Probability, Information Systems

Abstract

Recall the classical hypothesis testing setting with two convex sets of probability distributions P and Q. One receives either n i.i.d. samples from a distribution p ∈ P or from a distribution q ∈ Q and wants to decide from which set the points were sampled. It is known that the optimal exponential rate at which errors decrease can be achieved by a simple maximum-likelihood ratio test which does not depend on p or q, but only on the sets P and Q. We consider an adaptive generalization of this model where the choice of p ∈ P and q ∈ Q can change in each sample in some way that depends arbitrarily on the previous samples. In other words, in the kth round, an adversary, having observed all the previous samples in rounds 1, ..., κ-1, chooses p[subscript κ] ∈ P and q[subscript κ] ∈ Q, with the goal of confusing the hypothesis test. We prove that even in this case, the optimal exponential error rate can be achieved by a simple maximum-likelihood test that depends only on P and Q. We then show that the adversarial model has applications in hypothesis testing for quantum states using restricted measurements. For example, it can be used to study the problem of distinguishing entangled states from the set of all separable states using only measurements that can be implemented with local operations and classical communication (LOCC). The basic idea is that in our setup, the deleterious effects of entanglement can be simulated by an adaptive classical adversary. We prove a quantum Stein's Lemma in this setting: In many circumstances, the optimal hypothesis testing rate is equal to an appropriate notion of quantum relative entropy between two states. In particular, our arguments yield an alternate proof of Li and Winter's recent strengthening of strong subadditivity for quantum relative entropy., National Science Foundation (U.S.) (Grant CCF-1111382), United States. Army Research Office (Contract W911NF-12-1-0486)

Published

2014

11. Product-state approximations to quantum ground states

Author

Fernando G. S. L. Brandão, Aram W. Harrow, Massachusetts Institute of Technology. Department of Physics, and Harrow, Aram W.

Subjects

Discrete mathematics, PCP theorem, Quantum Physics, Open problem, FOS: Physical sciences, 0102 computer and information sciences, Quantum entanglement, 01 natural sciences, Planar graph, symbols.namesake, 010201 computation theory & mathematics, 0103 physical sciences, symbols, 010306 general physics, Ground state, Hamiltonian (quantum mechanics), Quantum Physics (quant-ph), Quantum, Constraint satisfaction problem, Mathematics

Abstract

The local Hamiltonian problem consists of estimating the ground-state energy (given by the minimum eigenvalue) of a local quantum Hamiltonian. First, we show the existence of a good product-state approximation for the ground-state energy of 2-local Hamiltonians with one or more of the following properties: (1) high degree, (2) small expansion, or (3) a ground state with sublinear entanglement with respect to some partition into small pieces. The approximation based on degree is a surprising difference between quantum Hamiltonians and classical CSPs (constraint satisfaction problems), since in the classical setting, higher degree is usually associated with harder CSPs. The approximation based on low entanglement, in turn, was previously known only in the regime where the entanglement was close to zero. Since the existence of a low-energy product state can be checked in NP, the result implies that any Hamiltonian used for a quantum PCP theorem should have: (1) constant degree, (2) constant expansion, (3) a "volume law" for entanglement with respect to any partition into small parts. Second, we show that in several cases, good product-state approximations not only exist, but can be found in polynomial time: (1) 2-local Hamiltonians on any planar graph, solving an open problem of Bansal, Bravyi, and Terhal, (2) dense k-local Hamiltonians for any constant k, solving an open problem of Gharibian and Kempe, and (3) 2-local Hamiltonians on graphs with low threshold rank, via a quantum generalization of a recent result of Barak, Raghavendra and Steurer. Our work introduces two new tools which may be of independent interest. First, we prove a new quantum version of the de Finetti theorem which does not require the usual assumption of symmetry. Second, we describe a way to analyze the application of the Lasserre/Parrilo SDP hierarchy to local quantum Hamiltonians., Comment: 44 pages. v2: proof of thm 6 corrected

Published

2013