We study the fundamental bounds on precision measurements of parameters contained in a time-dependent nonlinear optomechanical Hamiltonian, which includes the nonlinear light-matter coupling, a mechanical displacement term, and a single-mode mechanical squeezing term. By using a recently developed method to solve the dynamics of this system, we derive a general expression for the quantum Fisher information and demonstrate its applicability through three concrete examples: estimation of the strength of a nonlinear light-matter coupling, the strength of a time-modulated mechanical displacement, and a single-mode mechanical squeezing parameter, all of which are modulated at resonance. Our results can be used to compute the sensitivity of a non...
This thesis examines the optimal estimation of parameters in a variety of quantum oscillator models,...
We introduce a scheme to reconstruct an arbitrary quantum state of a mechanical oscillator network. ...
Backaction-evading measurements of mechanical motion can achieve precision below the zero-point unce...
We study the fundamental bounds on precision measurements of parameters contained in a time-dependen...
We study the fundamental bounds on precision measurements of parameters contained in a time-dependen...
We exploit local quantum estimation theory to investigate the measurement of linear (g1) and quadrat...
We exploit local quantum estimation theory to investigate the measurement of linear (g1) and quadrat...
In this thesis we investigate nonlinear quantum effects and squeezing in cavity optomechanical syste...
We present a table-top quantum estimation protocol to measure the gravitational acceleration g by us...
Hybrid optomechanical systems are emerging as a fruitful architecture for quantum technologies. Henc...
Position measurement is central to cavity quantum optomechanics and underpins a wide array of sensin...
Optomechanical system, a hybrid system where mechanical and optical degrees of freedom are mutually ...
We derive a standard quantum limit for probing mechanical energy quantization in a class of systems ...
This thesis examines the optimal estimation of parameters in a variety of quantum oscillator models,...
It has been predicted and experimentally demonstrated that by injecting squeezed light into an optom...
This thesis examines the optimal estimation of parameters in a variety of quantum oscillator models,...
We introduce a scheme to reconstruct an arbitrary quantum state of a mechanical oscillator network. ...
Backaction-evading measurements of mechanical motion can achieve precision below the zero-point unce...
We study the fundamental bounds on precision measurements of parameters contained in a time-dependen...
We study the fundamental bounds on precision measurements of parameters contained in a time-dependen...
We exploit local quantum estimation theory to investigate the measurement of linear (g1) and quadrat...
We exploit local quantum estimation theory to investigate the measurement of linear (g1) and quadrat...
In this thesis we investigate nonlinear quantum effects and squeezing in cavity optomechanical syste...
We present a table-top quantum estimation protocol to measure the gravitational acceleration g by us...
Hybrid optomechanical systems are emerging as a fruitful architecture for quantum technologies. Henc...
Position measurement is central to cavity quantum optomechanics and underpins a wide array of sensin...
Optomechanical system, a hybrid system where mechanical and optical degrees of freedom are mutually ...
We derive a standard quantum limit for probing mechanical energy quantization in a class of systems ...
This thesis examines the optimal estimation of parameters in a variety of quantum oscillator models,...
It has been predicted and experimentally demonstrated that by injecting squeezed light into an optom...
This thesis examines the optimal estimation of parameters in a variety of quantum oscillator models,...
We introduce a scheme to reconstruct an arbitrary quantum state of a mechanical oscillator network. ...
Backaction-evading measurements of mechanical motion can achieve precision below the zero-point unce...
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