Your search keyword '"Napoli, Carmine"' showing total 26 results

1. The Bose-Marletto-Vedral experiment with nanodiamond interferometers: an insight on entanglement detection

Author

Di Pietra, Giuseppe, Piacentini, Fabrizio, Bernardi, Ettore, Moreva, Ekaterina, Napoli, Carmine, Degiovanni, Ivo Pietro, Genovese, Marco, Vedral, Vlatko, and Marletto, Chiara

Subjects

Quantum Physics, General Relativity and Quantum Cosmology

Abstract

Recently, it has been proposed a new method [arXiv:2405.21029] to detect quantum gravity effects, based on generating gravitational entanglement between two nano-diamonds with Nitrogen-Vacancy defects, in a magnetically trapped configuration. Here we analyse in detail the proposed experimental setup, with a particular focus on implementing the detection of the gravitationally-induced entanglement using an optical readout based on measuring the position of the nano-diamonds and its complementary basis. We also summarise some of the key theoretical and experimental ideas on which this proposed scheme is based., Comment: 8 pages, 2 figures

Published

2024

2. Table-top nanodiamond interferometer enabling quantum gravity tests

Author

Vicentini, Marta, Bernardi, Ettore, Moreva, Ekaterina, Piacentini, Fabrizio, Napoli, Carmine, Degiovanni, Ivo Pietro, Manzin, Alessandra, and Genovese, Marco

Subjects

Quantum Physics

Abstract

Unifying quantum theory and general relativity is the holy grail of contemporary physics. Nonetheless, the lack of experimental evidence driving this process led to a plethora of mathematical models with a substantial impossibility of discriminating among them or even establishing if gravity really needs to be quantized or if, vice versa, quantum mechanics must be "gravitized" at some scale. Recently, it has been proposed that the observation of the generation of entanglement by gravitational interaction, could represent a breakthrough demonstrating the quantum nature of gravity. A few experimental proposals have been advanced in this sense, but the extreme technological requirements (e.g., the need for free-falling gravitationally-interacting masses in a quantum superposition state) make their implementation still far ahead. Here we present a feasibility study for a table-top nanodiamond-based interferometer eventually enabling easier and less resource-demanding quantum gravity tests. With respect to the aforementioned proposals, by relying on quantum superpositions of steady massive (mesoscopic) objects our interferometer may allow exploiting just small-range electromagnetic fields (much easier to implement and control) and, at the same time, the re-utilization of the massive quantum probes exploited, inevitably lost in free-falling interferometric schemes., Comment: 8 pages, 5 figures

Published

2024

3. Quantum enhanced non-interferometric quantitative phase imaging

Author

Ortolano, Giuseppe, Paniate, Alberto, Boucher, Pauline, Napoli, Carmine, Soman, Sarika, Pereira, Silvania F., Berchera, Ivano Ruo, and Genovese, Marco

Subjects

Quantum Physics, Physics - Optics

Abstract

Quantum entanglement and squeezing have significantly improved phase estimation and imaging in interferometric settings beyond the classical limits. However, for a wide class of non-interferometric phase imaging/retrieval methods vastly used in the classical domain e.g., ptychography and diffractive imaging, a demonstration of quantum advantage is still missing. Here, we fill this gap by exploiting entanglement to enhance imaging of a pure phase object in a non-interferometric setting, only measuring the phase effect on the free-propagating field. This method, based on the so-called "transport of intensity equation", is quantitative since it provides the absolute value of the phase without prior knowledge of the object and operates in wide-field mode, so it does not need time-consuming raster scanning. Moreover, it does not require spatial and temporal coherence of the incident light. Besides a general improvement of the image quality at a fixed number of photons irradiated through the object, resulting in better discrimination of small details, we demonstrate a clear reduction of the uncertainty in the quantitative phase estimation. Although we provide an experimental demonstration of a specific scheme in the visible spectrum, this research also paves the way for applications at different wavelengths, e.g., X-ray imaging, where reducing the photon dose is of utmost importance., Comment: arXiv admin note: text overlap with arXiv:2109.10095

Published

2023

4. Quantum-enhanced pattern recognition

Author

Ortolano, Giuseppe, Napoli, Carmine, Harney, Cillian, Pirandola, Stefano, Leonetti, Giuseppe, Boucher, Pauline, Losero, Elena, Genovese, Marco, and Ruo-Berchera, Ivano

Subjects

Quantum Physics, Physics - Optics

Abstract

The challenge of pattern recognition is to invoke a strategy that can accurately extract features of a dataset and classify its samples. In realistic scenarios this dataset may be a physical system from which we want to retrieve information, such as in the readout of optical classical memories. The theoretical and experimental development of quantum reading has demonstrated that the readout of optical memories can be dramatically enhanced through the use of quantum resources (namely entangled input-states) over that of the best classical strategies. However, the practicality of this quantum advantage hinges upon the scalability of quantum reading, and up to now its experimental demonstration has been limited to individual cells. In this work, we demonstrate for the first time quantum advantage in the multi-cell problem of pattern recognition. Through experimental realizations of digits from the MNIST handwritten digit dataset, and the application of advanced classical post-processing, we report the use of entangled probe states and photon-counting to achieve quantum advantage in classification error over that achieved with classical resources, confirming that the advantage gained through quantum sensors can be sustained throughout pattern recognition and complex post-processing. This motivates future developments of quantum-enhanced pattern recognition of bosonic-loss within complex domains.

Published

2023

5. Quantum-enhanced strategies for surface and phase discrimination

Author

Napoli, Carmine

Subjects

QC20 Mathematical physics

Abstract

The ability to perform high precision measurements underpins a plethora of applications. Several techniques for force sensing, phase estimation and discrimination, as well as surface reconstruction for complex features of three-dimensional samples, have been developed in recent years. The main aim of this thesis is to investigate metrology enhancements due to quantum resources (probes and measurements), by using quantum parameter estimation and channel discrimination techniques. The thesis focuses on two main scenarios. In the first one, we deal with three-dimensional superlocalisation. By using tools from multiparameter quantum metrology, we show that a simultaneous estimation of all three components of the separation between two incoherent point sources in the paraxial approximation is achievable by a single quantum measurement, with a precision saturating the ultimate limit stemming from the quantum Cramér-Rao bound. Such a precision is not degraded in the sub-wavelength regime, thus overcoming the traditional limitations of classical direct imaging derived from Rayleigh's criterion. Our results are qualitatively independent of the point spread function of the imaging system, and quantitatively illustrated in detail for Gaussian beams. In this case, we show that a method of measuring the position of each photon at the imaging plane based on discrimination in terms of Hermite-Gaussian spatial modes reaches the quantum precision bound in the limit of infinitesimal separation. In the second part of the thesis, we investigate the role of quantum coherence as a resource for channel discrimination tasks. We consider a probe state of arbitrary dimension entering a black box, in which a phase shift is implemented, with the unknown phase randomly sampled from a finite set of predetermined possibilities. At the output, an optimal measurement is performed in order to guess which specific phase was applied in the process. We show that the presence of quantum coherence (superposition with respect to the eigenbasis of the generator of the phase shift) in the input probe directly determines an enhancement in the probability of success for this task, compared to the use of incoherent probes. We prove that such a quantum advantage is exactly quantified by the robustness of coherence, a full monotone with respect to the recently formulated resource theories of quantum coherence, whose properties and applications are developed and explored in detail.

Published

2021

6. Structural and Diagnostic Investigations on Materials and Plasters of the Biblioteca Umanistica of the University of Florence

Author

Gallo, Chiara, D’Agostino, Luciano, Messuti, Nicolino, Napoli, Carmine, Quarta, Marco, Valentini, Daniela, Caliano, Eduardo, Öchsner, Andreas, Series Editor, da Silva, Lucas F. M., Series Editor, Altenbach, Holm, Series Editor, Furferi, Rocco, editor, Giorgi, Rodorico, editor, Seymour, Kate, editor, and Pelagotti, Anna, editor

Published

2022

7. Towards superresolution surface metrology: Quantum estimation of angular and axial separations

Author

Napoli, Carmine, Piano, Samanta, Leach, Richard, Adesso, Gerardo, and Tufarelli, Tommaso

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Instrumentation and Detectors, Physics - Optics

Abstract

We investigate the localization of two incoherent point sources with arbitrary angular and axial separations in the paraxial approximation. By using quantum metrology techniques, we show that a simultaneous estimation of the two separations is achievable by a single quantum measurement, with a precision saturating the ultimate limit stemming from the quantum Cram\'er-Rao bound. Such a precision is not degraded in the sub-wavelength regime, thus overcoming the traditional limitations of classical direct imaging derived from Rayleigh's criterion. Our results are qualitatively independent of the point spread function of the imaging system, and quantitatively illustrated in detail for the Gaussian instance. This analysis may have relevant applications in three-dimensional surface measurements., Comment: 6+2 pages, 2 figures; new results for arbitrary point spread functions

Published

2018

8. Robustness of asymmetry and coherence of quantum states

Author

Piani, Marco, Cianciaruso, Marco, Bromley, Thomas R., Napoli, Carmine, Johnston, Nathaniel, and Adesso, Gerardo

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter, Mathematical Physics, Physics - Computational Physics

Abstract

Quantum states may exhibit asymmetry with respect to the action of a given group. Such an asymmetry of states can be considered as a resource in applications such as quantum metrology, and it is a concept that encompasses quantum coherence as a special case. We introduce explicitly and study the robustness of asymmetry, a quantifier of asymmetry of states that we prove to have many attractive properties, including efficient numerical computability via semidefinite programming, and an operational interpretation in a channel discrimination context. We also introduce the notion of asymmetry witnesses, whose measurement in a laboratory detects the presence of asymmetry. We prove that properly constrained asymmetry witnesses provide lower bounds to the robustness of asymmetry, which is shown to be a directly measurable quantity itself. We then focus our attention on coherence witnesses and the robustness of coherence, for which we prove a number of additional results; these include an analysis of its specific relevance in phase discrimination and quantum metrology, an analytical calculation of its value for a relevant class of quantum states, and tight bounds that relate it to another previously defined coherence monotone., Comment: 14 pages, 1 figure. Close to published version. Matlab code included in the source. See also the companion letter arXiv:1601.03781

Published

2016

9. Robustness of coherence: An operational and observable measure of quantum coherence

Author

Napoli, Carmine, Bromley, Thomas R., Cianciaruso, Marco, Piani, Marco, Johnston, Nathaniel, and Adesso, Gerardo

Subjects

Quantum Physics, Condensed Matter - Other Condensed Matter, Mathematical Physics, Physics - Computational Physics

Abstract

Quantifying coherence is an essential endeavour for both quantum foundations and quantum technologies. Here the robustness of coherence is defined and proven a full monotone in the context of the recently introduced resource theories of quantum coherence. The measure is shown to be observable, as it can be recast as the expectation value of a coherence witness operator for any quantum state. The robustness of coherence is evaluated analytically on relevant classes of states, and an efficient semidefinite program that computes it on general states is given. An operational interpretation is finally provided: the robustness of coherence quantifies the advantage enabled by a quantum state in a phase-discrimination task., Comment: 5 pages, 1 figure. Close to published version. Matlab code included in the source. See also the companion article arXiv:1601.03782

Published

2016

10. Quantum-Enhanced Pattern Recognition

Author

Ortolano, Giuseppe, primary, Napoli, Carmine, additional, Harney, Cillian, additional, Pirandola, Stefano, additional, Leonetti, Giuseppe, additional, Boucher, Pauline, additional, Losero, Elena, additional, Genovese, Marco, additional, and Ruo-Berchera, Ivano, additional

Published

2023

11. Quantum enhanced non-interferometric quantitative phase imaging

Author

Ortolano, Giuseppe, primary, Paniate, Alberto, additional, Boucher, Pauline, additional, Napoli, Carmine, additional, Soman, Sarika, additional, Pereira, Silvania F., additional, Ruo-Berchera, Ivano, additional, and Genovese, Marco, additional

Published

2023

12. Quantum enhanced non-interferometric quantitative phase imaging

Author

Ortolano, Giuseppe (author), Paniate, Alberto (author), Boucher, Pauline (author), Napoli, Carmine (author), Soman, S. (author), Pereira, S.F. (author), Ruo-Berchera, Ivano (author), Genovese, Marco (author), Ortolano, Giuseppe (author), Paniate, Alberto (author), Boucher, Pauline (author), Napoli, Carmine (author), Soman, S. (author), Pereira, S.F. (author), Ruo-Berchera, Ivano (author), and Genovese, Marco (author)

Abstract

Quantum entanglement and squeezing have significantly improved phase estimation and imaging in interferometric settings beyond the classical limits. However, for a wide class of non-interferometric phase imaging/retrieval methods vastly used in the classical domain, e.g., ptychography and diffractive imaging, a demonstration of quantum advantage is still missing. Here, we fill this gap by exploiting entanglement to enhance imaging of a pure phase object in a non-interferometric setting, only measuring the phase effect on the free-propagating field. This method, based on the so-called “transport of intensity equation", is quantitative since it provides the absolute value of the phase without prior knowledge of the object and operates in wide-field mode, so it does not need time-consuming raster scanning. Moreover, it does not require spatial and temporal coherence of the incident light. Besides a general improvement of the image quality at a fixed number of photons irradiated through the object, resulting in better discrimination of small details, we demonstrate a clear reduction of the uncertainty in the quantitative phase estimation. Although we provide an experimental demonstration of a specific scheme in the visible spectrum, this research also paves the way for applications at different wavelengths, e.g., X-ray imaging, where reducing the photon dose is of utmost importance., ImPhys/Pereira group

Published

2023

13. Colors, Materials, and Techniques in Historical Buildings in Rome: Diagnostic Investigations and Case Studies.

Author

Caliano, Eduardo, Gallo, Chiara, Messuti, Nicolino, and Napoli, Carmine

Subjects

HISTORIC buildings, PRESERVATION of architecture, COLORS, CONSTRUCTION planning, CONSERVATION & restoration, COLOR

Abstract

In the last few years, the study of the surface color of historical buildings has progressed as part of conservation and restoration efforts to comply with the aesthetics of historical and pre-existing materials. The main critical element related to this type of study is represented by the succession of various interventions of restoration and maintenance over time that has altered the original aesthetics of monuments by using materials and colors selected according to criteria, trends, and needs of succeeding historical eras. In this paper, the investigation of plasters and colored finishing layers applied on two historical buildings located in Rome and dating to the early 1900s is reported. Results were obtained through a specific diagnostic investigation plan focused on microscopic, morphological, and chemical characterizations of plasters and colored layers detected on the monument surfaces. All post-intervention phases and dates have been identified by comparing the results obtained with historical data. Important information was uncovered that helps in tracing the original aesthetic conception of the buildings and in planning restoration approaches which can be compatible both aesthetically and materially with the original work. [ABSTRACT FROM AUTHOR]

Published

2023

14. Colors, Materials, and Techniques in Historical Buildings in Rome: Diagnostic Investigations and Case Studies

Author

Caliano, Eduardo, primary, Gallo, Chiara, additional, Messuti, Nicolino, additional, and Napoli, Carmine, additional

Published

2022

15. Bimodal antibody-titer decline following BNT162b2 mRNA anti-SARS-CoV-2 vaccination in healthcare workers of the INT – IRCCS "Fondazione Pascale" Cancer Center (Naples, Italy).

Author

Isgrò, Maria Antonietta, Trillò, Giusy, Russo, Luigi, Tornesello, Anna Lucia, Buonaguro, Luigi, Tornesello, Maria Lina, Miscio, Leonardo, Normanno, Nicola, Bianchi, Attilio Antonio Montano, Buonaguro, Franco Maria, Cavalcanti, Ernesta, the anti-COVID-19 INT Task Force, Rea, Domenica, Di Capua, Lucia, Labonia, Francesco, Meola, Serena, Piscopo, Annamaria, Arpino, Sergio, Di Napoli, Carmine, and Esposito, Gerardo

Subjects

SPECIALTY hospitals, COVID-19, IMMUNIZATION, SARS-CoV-2, COVID-19 vaccines, VIRAL load, CANCER treatment, TREATMENT effectiveness, IMMUNOASSAY, MESSENGER RNA, VIRAL antibodies

Abstract

Background: Both SARS-CoV-2 mRNA-based vaccines [BNT162b2 (Pfizer-BioNTech) and mRNA-1273 (Moderna)] have shown high efficacy, with very modest side effects in limiting transmission of SARS-CoV-2 and in preventing the severe COVID-19 disease, characterized by a worrying high occupation of intensive care units (ICU), high frequency of intubation and ultimately high mortality rate. At the INT, in Naples, only the BNT162b2/Pfizer vaccine has been administered to cancer patients and healthcare professionals aged 16 and over. In the present study, the antibody response levels and their decline were monitored in an interval of 6–9 months after vaccine administration in the two different cohorts of workers of the INT – IRCCS "Fondazione Pascale" Cancer Center (Naples, Italy): the group of individuals previously infected with SARS-CoV-2 and vaccinated with a single dose; and that of individuals negative for previous exposure to SARS-CoV-2 vaccinated with two doses 21 days apart. Methods: Specific anti-RBD (receptor-binding domain) titers against trimeric spike glycoprotein (S) of SARS-CoV-2 by Roche Elecsys Anti-SARS-CoV-2 S ECLIA immunoassay were determined in serum samples of 27 healthcare workers with a previously documented history of SARS-CoV-2 infection and 123 healthcare workers without, during antibody titers' monitoring. Moreover, geometric mean titers (GMT) and relative fold changes (FC) were calculated. Results: Bimodal titer decline was observed in both previously infected and uninfected SARS-CoV-2 subjects. A first rapid decline was followed by a progressive slow decline in the 6/9 month-period before the further vaccine boost. The trend was explained by 2 different mathematical models, exponential and power function, the latter revealing as predictive of antibody titer decline either in infected or in not previously infected ones. The value of the prolonged lower vaccine titer was about 1 log below in the 6/9-month interval after the single dose for previously infected individuals with SARS-CoV-2 and the two doses for those not previously infected. The titer change, after the boost dose administration, on the other hand, was ≥ 1.5 FC higher than the titers at the 6/9-month time-points in both cohorts. A similar quantitative immune titer was observed in both cohorts 8 days after the last boost dose. The subsequent immunoresponse trend remains to be verified. Discussion: The results show that a very rapid first decline, from the highest antibody peak, was followed by a very slow decline which ensured immune protection lasting more than 6 months. The apparent absence of adverse effects of the rapid decline on the vaccine's immune protective role has been related to a large majority of low avidity antibodies induced by current vaccines. High avidity antibodies with prolonged anti-transmission efficacy show a longer half-life and are lost over a longer interval period. The cellular immunity, capable of preventing severe clinical diseases, lasts much longer. The unbalanced dual activity (cellular vs humoral) while effective in limiting ICU pressure and overall mortality, does not protect against transmission of SARS-CoV-2, resulting in high circulation of the virus among unvaccinated subjects, including the younger population, and the continuous production of variants characterized by changes in transmissibility and pathogenicity. The high mutation rate, peculiar to the RNA virus, can however lead to a dual opposite results: selection of defective and less efficient viruses up to extinction; risk of more efficiently transmitted variants as the current omicron pandemic. Conclusions: In conclusion the current bimodal antibody-titer decline, following BNT162b2 mRNA anti-SARS-CoV-2 vaccination, needs a further extended analysis to verify the protective borderline levels of immunity and the optimal administration schedule of vaccine boosters. Our current results can contribute to such goal, besides a direct comparison of other FDA-approved and candidate vaccines. [ABSTRACT FROM AUTHOR]

Published

2022

16. New protocols of quantum imaging at INRIM

Author

Deacon, Keith S., Meyers, Ronald E., Napoli, Carmine, Paniate, Alberto, Ruo Berchera, Ivano, and Genovese, Marco

Published

2024

17. IoT-HC: A Novel IoT Architecture for the Hybrid Cloud

Author

De Napoli, Carmine, primary, Forestiero, Agostino, additional, Fortino, Giancarlo, additional, Giordano, Andrea, additional, Guerrieri, Antonio, additional, Lagana, Demetrio, additional, Lupi, Giovanni, additional, Mastroianni, Carlo, additional, and Spataro, Leonardo, additional

Published

2019

18. Towards Superresolution Surface Metrology: Quantum Estimation of Angular and Axial Separations

Author

Napoli, Carmine, primary, Piano, Samanta, additional, Leach, Richard, additional, Adesso, Gerardo, additional, and Tufarelli, Tommaso, additional

Published

2019

19. Non-Destructive Survey Systems on Masonry: The Case of the Walls in the Archaeological Site of Canne della Battaglia

Author

Caliano, Eduardo, primary, Napoli, Carmine, additional, Messuti, Nicolino, additional, and Faieta, Rosangela, additional

Published

2018

20. Business scenarios for hierarchical workload management in data centers

Author

Cuzzocrea, Alfredo, primary, De Napoli, Carmine, additional, Forestiero, Agostino, additional, Lagana', Demetrio, additional, Lupi, Giovanni, additional, Mastroianni, Carlo, additional, and Spataro, Leonardo, additional

Published

2017

21. Robustness of asymmetry and coherence of quantum states

Author

Piani, Marco, primary, Cianciaruso, Marco, additional, Bromley, Thomas R., additional, Napoli, Carmine, additional, Johnston, Nathaniel, additional, and Adesso, Gerardo, additional

Published

2016

22. Robustness of Coherence: An Operational and Observable Measure of Quantum Coherence

Author

Napoli, Carmine, primary, Bromley, Thomas R., additional, Cianciaruso, Marco, additional, Piani, Marco, additional, Johnston, Nathaniel, additional, and Adesso, Gerardo, additional

Published

2016

23. Robustness of coherence: an operational and observable measure of quantum coherence

Author

Napoli, Carmine, Bromley, Thomas R., Cianciaruso, Marco, Piani, Marco, Johnston, Nathaniel, Adesso, Gerardo, Napoli, Carmine, Bromley, Thomas R., Cianciaruso, Marco, Piani, Marco, Johnston, Nathaniel, and Adesso, Gerardo

Abstract

Quantifying coherence is an essential endeavour for both quantum foundations and quantum technologies. Here the robustness of coherence is defined and proven a full monotone in the context of the recently introduced resource theories of quantum coherence. The measure is shown to be observable, as it can be recast as the expectation value of a coherence witness operator for any quantum state. The robustness of coherence is evaluated analytically on relevant classes of states, and an efficient semidefinite program that computes it on general states is given. An operational interpretation is finally provided: the robustness of coherence quantifies the advantage enabled by a quantum state in a phase discrimination task.

24. Robustness of asymmetry and coherence of quantum states

Author

Piani, Marco, Cianciaruso, Marco, Bromley, Thomas R., Napoli, Carmine, Johnston, Nathaniel, Adesso, Gerardo, Piani, Marco, Cianciaruso, Marco, Bromley, Thomas R., Napoli, Carmine, Johnston, Nathaniel, and Adesso, Gerardo

Abstract

Quantum states may exhibit asymmetry with respect to the action of a given group. Such an asymmetry of states can be considered as a resource in applications such as quantum metrology, and it is a concept that encompasses quantum coherence as a special case. We introduce explicitly and study the robustness of asymmetry, a quantifier of asymmetry of states that we prove to have many attractive properties, including efficient numerical computability via semidefinite programming, and an operational interpretation in a channel discrimination context. We also introduce the notion of asymmetry witnesses, whose measurement in a laboratory detects the presence of asymmetry. We prove that properly constrained asymmetry witnesses provide lower bounds to the robustness of asymmetry, which is shown to be a directly measurable quantity itself. We then focus our attention on coherence witnesses and the robustness of coherence, for which we prove a number of additional results; these include an analysis of its specific relevance in phase discrimination and quantum metrology, an analytical calculation of its value for a relevant class of quantum states, and tight bounds that relate it to another previously defined coherence monotone.

25. Quantum-enhanced strategies for surface and phase discrimination

Author

Napoli, Carmine and Napoli, Carmine

Abstract

The ability to perform high precision measurements underpins a plethora of applications. Several techniques for force sensing, phase estimation and discrimination, as well as surface reconstruction for complex features of three-dimensional samples, have been developed in recent years. The main aim of this thesis is to investigate metrology enhancements due to quantum resources (probes and measurements), by using quantum parameter estimation and channel discrimination techniques. The thesis focuses on two main scenarios. In the first one, we deal with three-dimensional superlocalisation. By using tools from multiparameter quantum metrology, we show that a simultaneous estimation of all three components of the separation between two incoherent point sources in the paraxial approximation is achievable by a single quantum measurement, with a precision saturating the ultimate limit stemming from the quantum Cramér-Rao bound. Such a precision is not degraded in the sub-wavelength regime, thus overcoming the traditional limitations of classical direct imaging derived from Rayleigh's criterion. Our results are qualitatively independent of the point spread function of the imaging system, and quantitatively illustrated in detail for Gaussian beams. In this case, we show that a method of measuring the position of each photon at the imaging plane based on discrimination in terms of Hermite-Gaussian spatial modes reaches the quantum precision bound in the limit of infinitesimal separation. In the second part of the thesis, we investigate the role of quantum coherence as a resource for channel discrimination tasks. We consider a probe state of arbitrary dimension entering a black box, in which a phase shift is implemented, with the unknown phase randomly sampled from a finite set of predetermined possibilities. At the output, an optimal measurement is performed in order to guess which specific phase was applied in the process. We show that the presence of quantum coherence (super

26. Business Scenarios for Hierarchical Workload Management in Data Centers

Author

Agostino Forestiero, Demetrio Laganà, Carlo Mastroianni, Carmine De Napoli, Leonardo Spataro, Alfredo Cuzzocrea, Giovanni Lupi, Cuzzocrea, Alfredo Massimiliano, Napoli, Carmine De, Forestiero, Agostino, Lagana’, Demetrio, Lupi, Giovanni, Mastroianni, Carlo, and Spataro, Leonardo

Subjects

Big Data, business.industry, Computer science, Distributed computing, Big data, 020206 networking & telecommunications, Workload, Cloud computing, 02 engineering and technology, Energy consumption, Cloud Computing, Workload Management, Workload management, Software, 020204 information systems, Data Centers, Scalability, 0202 electrical engineering, electronic engineering, information engineering, Data center, business, Data Center

Abstract

Increasing the efficiency of workload management in data centers is essential to achieve several business and technical goals, such as reduction of costs, energy consumption and carbon emissions. Many solutions are available for workload management in a single data center, but there is still much space for the development of frameworks that are able to manage the workload in a distributed scenario, with multiple sites and data centers. In this paper, we present the main benefits of hierarchical solutions, in which the problem is decomposed into two layers, a lower layer that focuses on the workload management within each single data center, and an upper layer that orchestrates the management of the workload on a multi-site environment. We focus on the main advantages of hierarchical approaches, i.e., autonomous management, scalability and modularity, and illustrate how and to which extent these advantages can be exploited in some emerging business scenarios, i.e., geographical data centers, software data centers and Hybrid Cloud.