We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n bits of true randomness from a seed of O(log n) uniform bits. The bits generated are certifiably random based only on a simple statistical test that can be performed by the user, and on the assumption that the devices obey the no-signaling principle. No other assumptions are placed on the devices' inner workings. A modified protocol uses a seed of O(log^3 n) uniformly random bits to generate n bits of true randomness even conditioned on the state of a quantum adversary who may have had prior access to the devices, and may be entangled with them
Quantum theory allows for randomness generation in a device-independent setting, where no detailed d...
Device-independent randomness expansion protocols aim to expand a short uniformly random string into...
The ultimate random number generators are those certified to be unpredictable -- including to an adv...
We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n...
We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n...
We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n...
The concept of randomness plays an important part in many disciplines. On the one hand, the question...
A recent sequence of works, initially motivated by the study of the nonlocal properties of entanglem...
Randomness is a fundamental concept, with implications from security of modern data systems, to fund...
The generation of certifiable randomness is the most fundamental information-theoretic task that mea...
The generation of certifiable randomness is the most fundamental information-theoretic task that mea...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
The generation of certifiable randomness is one of the most promising applications of quantum techno...
Measurements on entangled quantum systems necessarily yield outcomes that are intrinsically unpredic...
Quantum random number generators can provide genuine randomness by appealing to the fundamental prin...
Quantum theory allows for randomness generation in a device-independent setting, where no detailed d...
Device-independent randomness expansion protocols aim to expand a short uniformly random string into...
The ultimate random number generators are those certified to be unpredictable -- including to an adv...
We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n...
We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n...
We introduce a protocol through which a pair of quantum mechanical devices may be used to generate n...
The concept of randomness plays an important part in many disciplines. On the one hand, the question...
A recent sequence of works, initially motivated by the study of the nonlocal properties of entanglem...
Randomness is a fundamental concept, with implications from security of modern data systems, to fund...
The generation of certifiable randomness is the most fundamental information-theoretic task that mea...
The generation of certifiable randomness is the most fundamental information-theoretic task that mea...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
The generation of certifiable randomness is one of the most promising applications of quantum techno...
Measurements on entangled quantum systems necessarily yield outcomes that are intrinsically unpredic...
Quantum random number generators can provide genuine randomness by appealing to the fundamental prin...
Quantum theory allows for randomness generation in a device-independent setting, where no detailed d...
Device-independent randomness expansion protocols aim to expand a short uniformly random string into...
The ultimate random number generators are those certified to be unpredictable -- including to an adv...