Joint Seminar on Quantum Information and Technologies
2012/2013 | 2013/2014 | 2014/2015 | 2015/2016 | 2016/2017 | 2017/2018 | 2018/2019 | 2019/2020 | 2020/2021 | 2021/2022 | 2022/2023 | 2023/2024 | Seminar YouTube channel
until 2023/2024 Quantum Information Seminar
2021-11-18 (Thursday)
room 1.03, Pasteura 5 at 11:15 
Michał Parniak (QOT CENT UW)Achieving non-classical states of mechanical oscillators
2021-11-04 (Thursday)
room 1.03, Pasteura 5 at 11:15
Marcin Pawłowski (Uniwersytet Gdański, International Centre for Theory of Quantum Technologies)Quantum random number generators: theory and practice
The Seminar will take a HYBRID form. It will take place in room 1.03 but will be simmultaneously tranmitted via ZOOM under the following link: https://zoom.us/j/92894130767 (Passcode: R6Vx6E)
2021-10-28 (Thursday)
room 1.03, Pasteura 5 at 11:15
Lewis Clark (QOT CENT UW)Enhancing the performance of optomechanical sensors by continuous photon-counting
The Seminar will take a HYBRID form. It will take place in room 1.03 but will be simmultaneously tranmitted via ZOOM under the following link: https://zoom.us/j/92894130767 (Passcode: R6Vx6E)
Optomechanical systems are rapidly becoming one of the most promising platforms for observing quantum behaviour, even approaching macroscopic systems. These systems are well understood at both a theoretical and experimental level. The potential for using such devices for applications such as quantum sensing is thus high, and some work has already been carried out to understand how such devices can be used. Motivated by the recent interest in using continuous measurements and Bayesian inference as a tool for quantum sensing, we apply these techniques to an optomechanical system in this work. We find that even with a single quantum trajectory of photon-click events, we are capable of accurately inferring optomechanical parameters being sensed, such as the internal frequency of the mechanical oscillator or its light-coupling strength, with average precision that can surpass the bound set by the quantum Fisher information for a single-shot measurement in reasonable amounts of time. Our work thus presents a novel approach to quantum sensing in optomechanical systems, having potential to guide the design of future devices.
Optomechanical systems are rapidly becoming one of the most promising platforms for observing quantum behaviour, even approaching macroscopic systems. These systems are well understood at both a theoretical and experimental level. The potential for using such devices for applications such as quantum sensing is thus high, and some work has already been carried out to understand how such devices can be used. Motivated by the recent interest in using continuous measurements and Bayesian inference as a tool for quantum sensing, we apply these techniques to an optomechanical system in this work. We find that even with a single quantum trajectory of photon-click events, we are capable of accurately inferring optomechanical parameters being sensed, such as the internal frequency of the mechanical oscillator or its light-coupling strength, with average precision that can surpass the bound set by the quantum Fisher information for a single-shot measurement in reasonable amounts of time. Our work thus presents a novel approach to quantum sensing in optomechanical systems, having potential to guide the design of future devices.
2021-10-21 (Thursday)
room 1.03, Pasteura 5 at 11:15
Yink Loong Len (QOT UW)Quantum metrology with imperfect measurements
The Seminar will take a HYBRID form. It will take place in room 1.03 but will be simmultaneously tranmitted via ZOOM under the following link: https://zoom.us/j/92894130767 (Passcode: R6Vx6E)
2021-10-14 (Thursday)
room 1.03, Pasteura 5 at 11:15
Marcin Jarzyna (Centre for Quantum Optical Technologies UW)Quantum limits to polarization measurement of classical light
The Seminar will take a HYBRID form. It will take place in room 1.03 but will be simmultaneously tranmitted via ZOOM under the following link: https://zoom.us/j/92894130767 (Passcode: R6Vx6E)
Abstract: In this talk I will discuss the quantum limit to a polarization measurement of a classical coherent light. This is a multiparameter estimation problem with a crucial feature of noncommuting optimal observables corresponding to each parameter which prohibits them to be measured simultaneously. I explicitly minimize the quantum Holevo-Cramer-Rao bound which tackles this issue and show that it can be saturated by conventional receivers for certain parameters values. Finally, I will discuss the issue of global phase reference and how its presence changes the precision of polarization measurement.
Abstract: In this talk I will discuss the quantum limit to a polarization measurement of a classical coherent light. This is a multiparameter estimation problem with a crucial feature of noncommuting optimal observables corresponding to each parameter which prohibits them to be measured simultaneously. I explicitly minimize the quantum Holevo-Cramer-Rao bound which tackles this issue and show that it can be saturated by conventional receivers for certain parameters values. Finally, I will discuss the issue of global phase reference and how its presence changes the precision of polarization measurement.
2021-10-07 (Thursday)
room 1.03, Pasteura 5 at 11:15
Janis Noetzel (Technische Universitaet Muenchen)An OSI layer inspired perspective on quantum information processing
The Seminar will take a HYBRID form. It will take place in room 1.03 but will be simmultaneously tranmitted via ZOOM under the following link: https://zoom.us/j/92894130767 (Passcode: R6Vx6E)
Abstract: In this talk we briefly summarize some approaches to using quantum information processing methods in the sense of a ´plugin to a communication network. With this approach we aim at sharpening the focus on the idea of near-term hybrid network scenarios, where quantum information processing aims at assisting networks with minimum changes to the existing structure. Some approaches are highlighted in more detail, in particular we add some precision to the idea of using quantum communication methods to reduce energy consumption.
Abstract: In this talk we briefly summarize some approaches to using quantum information processing methods in the sense of a ´plugin to a communication network. With this approach we aim at sharpening the focus on the idea of near-term hybrid network scenarios, where quantum information processing aims at assisting networks with minimum changes to the existing structure. Some approaches are highlighted in more detail, in particular we add some precision to the idea of using quantum communication methods to reduce energy consumption.