Search results for "Direct-conversion receiver"

showing 3 items of 3 documents

Homodyne Solid-State Biased Coherent Detection of Ultra-Broadband Terahertz Pulses with Static Electric Fields.

2021

We present an innovative implementation of the solid-state-biased coherent detection (SSBCD) technique, which we have recently introduced for the reconstruction of both amplitude and phase of ultra-broadband terahertz pulses. In our previous works, the SSBCD method has been operated via a heterodyne scheme, which involves demanding square-wave voltage amplifiers, phase-locked to the THz pulse train, as well as an electronic circuit for the demodulation of the readout signal. Here, we demonstrate that the SSBCD technique can be operated via a very simple homodyne scheme, exploiting plain static bias voltages. We show that the homodyne SSBCD signal turns into a bipolar transient when the stat…

HeterodyneFour-wave mixing Solid-state device THz pulse detectionTerahertz radiationTHz pulse detectionGeneral Chemical Engineering02 engineering and technology01 natural sciencesSignalSettore ING-INF/01 - ElettronicaArticlelcsh:Chemistry010309 opticsOptics0103 physical sciencesDemodulationGeneral Materials Sciencesolid-state deviceElectronic circuitPhysicsbusiness.industryAmplifierSettore ING-INF/02 - Campi Elettromagnetici021001 nanoscience & nanotechnologyDirect-conversion receiverlcsh:QD1-999four-wave mixing0210 nano-technologybusinessVoltageNanomaterials (Basel, Switzerland)
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Characterization of Hong-Ou-Mandel bunched states by quantum homodyne tomography

2014

We experimentally demonstrate quantum homodyne tomography of Hong-Ou-Mandel bunched states, which are created by dynamically adjusting emission timings of two heralded single photons using coupled cavities.

PhysicsDirect-conversion receiverPhotonPhoton statisticsHomodyne detectionQuantum mechanicsPhysics::OpticsPhysics::Accelerator PhysicsCoherent statesQuantum PhysicsTomographyQuantumCharacterization (materials science)
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Phase Locking between Two All-Optical Quantum Memories.

2020

Optical approaches to quantum computation require the creation of multi-mode photonic quantum states in a controlled fashion. Here we experimentally demonstrate phase locking of two all-optical quantum memories, based on a concatenated cavity system with phase reference beams, for the time-controlled release of two-mode entangled single-photon states. The release time for each mode can be independently determined. The generated states are characterized by two-mode optical homodyne tomography. Entanglement and nonclassicality are preserved for release-time differences up to 400 ns, confirmed by logarithmic negativities and Wigner-function negativities, respectively.

PhysicsQuantum PhysicsMulti-mode optical fiberbusiness.industryPhase (waves)FOS: Physical sciencesPhysics::OpticsGeneral Physics and AstronomyQuantum entanglement01 natural sciencesDirect-conversion receiverQuantum stateQuantum mechanics0103 physical sciencesPhotonicsQuantum Physics (quant-ph)010306 general physicsbusinessQuantumQuantum computerPhysical review letters
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