We show that the entropy of a message can be tested in a device-independent way. Specifically, we consider a prepare-and-measure scenario with classical or quantum communication, and develop two different methods for placing lower bounds on the communication entropy, given observable data. The first method is based on the framework of causal inference networks. The second technique, based on convex optimization, shows that quantum communication provides an advantage over classical, in the sense of requiring a lower entropy to reproduce given data. These ideas may serve as a basis for novel applications in device-independent quantum information processing
We develop a semidefinite programming method for the optimization of quantum networks, including bot...
A central question for causal inference is to decide whether a set of correlations fits a given caus...
We show that quantum-to-classical channels, i.e., quantum measurements, can be asymptotically simula...
21 (+6) pages, 4 (+2) figuresThe rates of several device-independent (DI) protocols, including quant...
Device-independent cryptography goes beyond conventional quantum cryptography by providing security ...
The field of device-independent quantum information processing concerns itself with devising and ana...
When quantum resources (apparatus) are distributed in two or more geograph-ically separated location...
A fundamental problem in statistics and learning theory is to test properties of distributions. We s...
We consider the problem of characterizing the set of input-output correlations that can be generated...
One of the predominant challenges when engineering future quantum information processors is that lar...
Quantum mechanics and information theory are among the most important scientific discoveries of the ...
In most communication schemes, information is transmitted via travelling modes of electromagnetic ra...
Entropies have been immensely useful in information theory. In this Thesis, several results in quan...
A central question for causal inference is to decide whether a set of correlations fits a given caus...
This book provides the reader with the mathematical framework required to fully explore the potentia...
We develop a semidefinite programming method for the optimization of quantum networks, including bot...
A central question for causal inference is to decide whether a set of correlations fits a given caus...
We show that quantum-to-classical channels, i.e., quantum measurements, can be asymptotically simula...
21 (+6) pages, 4 (+2) figuresThe rates of several device-independent (DI) protocols, including quant...
Device-independent cryptography goes beyond conventional quantum cryptography by providing security ...
The field of device-independent quantum information processing concerns itself with devising and ana...
When quantum resources (apparatus) are distributed in two or more geograph-ically separated location...
A fundamental problem in statistics and learning theory is to test properties of distributions. We s...
We consider the problem of characterizing the set of input-output correlations that can be generated...
One of the predominant challenges when engineering future quantum information processors is that lar...
Quantum mechanics and information theory are among the most important scientific discoveries of the ...
In most communication schemes, information is transmitted via travelling modes of electromagnetic ra...
Entropies have been immensely useful in information theory. In this Thesis, several results in quan...
A central question for causal inference is to decide whether a set of correlations fits a given caus...
This book provides the reader with the mathematical framework required to fully explore the potentia...
We develop a semidefinite programming method for the optimization of quantum networks, including bot...
A central question for causal inference is to decide whether a set of correlations fits a given caus...
We show that quantum-to-classical channels, i.e., quantum measurements, can be asymptotically simula...