74 research outputs found
Asynchronous, Photometric Feature Tracking using Events and Frames
We present a method that leverages the complementarity of event cameras and
standard cameras to track visual features with low-latency. Event cameras are
novel sensors that output pixel-level brightness changes, called "events". They
offer significant advantages over standard cameras, namely a very high dynamic
range, no motion blur, and a latency in the order of microseconds. However,
because the same scene pattern can produce different events depending on the
motion direction, establishing event correspondences across time is
challenging. By contrast, standard cameras provide intensity measurements
(frames) that do not depend on motion direction. Our method extracts features
on frames and subsequently tracks them asynchronously using events, thereby
exploiting the best of both types of data: the frames provide a photometric
representation that does not depend on motion direction and the events provide
low-latency updates. In contrast to previous works, which are based on
heuristics, this is the first principled method that uses raw intensity
measurements directly, based on a generative event model within a
maximum-likelihood framework. As a result, our method produces feature tracks
that are both more accurate (subpixel accuracy) and longer than the state of
the art, across a wide variety of scenes.Comment: 22 pages, 15 figures, Video: https://youtu.be/A7UfeUnG6c
Improving the light-harvesting of amorphous silicon solar cells with photochemical upconversion
Single-threshold solar cells are fundamentally limited by their ability to
harvest only those photons above a certain energy. Harvesting below-threshold
photons and re-radiating this energy at a shorter wavelength would thus boost
the efficiency of such devices. We report an increase in light harvesting
efficiency of a hydrogenated amorphous silicon (a-Si:H) thin-film solar cell
due to a rear upconvertor based on sensitized triplet–triplet-annihilation in
organic molecules. Low energy light in the range 600–750 nm is converted to
550–600 nm light due to the incoherent photochemical process. A peak
efficiency enhancement of (1.0 ± 0.2)% at 720 nm is measured under irradiation
equivalent to (48 ± 3) suns (AM1.5). We discuss the pathways to be explored in
adapting photochemical UC for application in various single threshold devices
Efficient aberrations pre-compensation and wavefront correction with a deformable mirror in the middle of a petawatt-class CPA laser system
AbstractIn this paper, we describe the experimental validation of the technique of correction of wavefront aberration in the middle of the laser amplifying chain. This technique allows the correction of the aberrations from the first part of the laser system, and the pre-compensation of the aberrations built in the second part. This approach will allow an effective aberration management in the laser chain, to protect the optical surfaces and optimize performances, and is the only possible approach for multi-petawatt laser system from the technical and economical point of view. This approach is now possible after the introduction of new deformable mirrors with lower static aberrations and higher dynamic than the standard devices
Improving the light-harvesting of second generation solar cells with photochemical upconversion
Photovoltaics (PV) offer a solution for the development of sustainable energy
sources, relying on the sheer abundance of sunlight: More sunlight falls on
the Earth’s surface in one hour than is required by its inhabitants in a year.
However, it is imperative to manage the wide distribution of photon energies
available in order to generate more cost efficient PV devices because single
threshold PV devices are fundamentally limited to a maximum conversion
efficiency, the Shockley-Queisser (SQ) limit. Recent progress has enabled the
production of c-Si cells with efficiencies as high as 25%,1 close to the
limiting efficiency of ∼30%. But these cells are rather expensive, and
ultimately the cost of energy is determined by the ratio of system cost and
efficiency of the PV device. A strategy to radically decrease this ratio is to
circumvent the SQ limit in cheaper, second generation PV devices. One
promising approach is the use of hydrogenated amorphous silicon (a-Si:H),
where film thicknesses on the order of several 100nm are sufficient.
Unfortunately, the optical threshold of a-Si:H is rather high (1.7-1.8 eV) and
the material suffers from light-induced degradation. Thinner absorber layers
in a-Si:H devices are generally more stable than thicker films due to the
better charge carrier extraction, but at the expense of reduced conversion
efficiencies, especially in the red part of the solar spectrum (absorption
losses). Hence for higher bandgap materials, which includes a-Si as well as
organic and dye-sensitized cells, the major loss mechanism is the inability to
harvest low energy photons
Effect of a back reflector
Photochemical upconversion is applied to a hydrogenated amorphous silicon
solar cell in the presence of a back-scattering layer. A custom-synthesized
porphyrin was utilized as the sensitizer species, with rubrene as the emitter.
Under a bias of 24 suns, a peak external quantum efficiency (EQE) enhancement
of ~2 % was observed at a wavelength of 720 nm. Without the scattering layer,
the EQE enhancement was half this value, indicating that the effect of the
back-scatterer is to double the efficacy of the upconverting device. The
results represent an upconversion figure of merit of 3.5 × 10–4 mA cm–2 sun–2,
which is the highest reported to date
Recent progress with hot carrier solar cells
Hot carrier solar cells offer one of the most promising options for high performance “third generation” photovoltaic devices. For successful operation, these need to be thin, strongly absorbing, radioactively efficient devices in a simple 2-terminal configuration. Nonetheless, they offer potential performance close to the maximum possible for solar conversion, equivalent to a multi-cell stack of six or more tandem cells possibly without some of the limitations, such as spectral sensitivity. However, hot carrier cells offer some quite fundamental challenges in implementation that our team is addressing in an internationally collaborative effort
Carrier thermalization dynamics in single zincblende and wurtzite InP nanowires
Using transient Rayleigh scattering (TRS) measurements, we obtain photoexcited carrier thermalization dynamics for both zincblende (ZB) and wurtzite (WZ) InP single nanowires (NW) with picosecond resolution. A phenomenological fitting model based on direct band-to-band transition theory is developed to extract the electron-hole–plasma density and temperature as a function of time from TRS measurements of single nanowires, which have complex valence band structures. We find that the thermalization dynamics of hot carriers depends strongly on material (GaAs NW vs InP NW) and less strongly on crystal structure (ZB vs WZ). The thermalization dynamics of ZB and WZ InP NWs are similar. But a comparison of the thermalization dynamics in ZB and WZ InP NWs with ZB GaAs NWs reveals more than an order of magnitude slower relaxation for the InP NWs. We interpret these results as reflecting their distinctive phonon band structures that lead to different hot phonon effects. Knowledge of hot carrier thermalization dynamics is an essential component for effective incorporation of nanowire materials into electronic devices
22 W average power multiterawatt femtosecond laser chain enabling 1019 W/cm2 at 100 Hz
International audienceWe measure the wavefront distortions of a high peak power ultrashort (23 fs) laser system under high average power load. After 6 min-100 Hz operation of the laser at full average power (> 22 W after compression), the thermally induced wave-front distortions reach a steady state and the far-field profile of the laser beam no longer changes. By means of a deformable mirror located after the vacuum compressor, we apply a static pre-compensation to correct those aberrations allowing us to demonstrate a dramatic improvement of the far-field profile at 100 Hz with the reduction of the residual wavefront distortions below λ/16 before focusing. The applied technique provides 100 Hz operation of the femtosecond laser chain with stable pulse characteristics, corresponding to peak intensity above 10 19 W/cm 2 and average power of 19 W on target, which enables the study of relativistic optics at high repetition rate using a moderate f-number focusing optics (f/4.5)
Laser Induced Damage of dielectrics down to few cycle pulse duration: test bench and measurements
Conference on High-Power, High-Energy, and High-Intensity Laser Technology; and Research Using Extreme Light - Entering New Frontiers with Petawatt-Class Lasers, Prague, CZECH REPUBLIC, APR 15-17, 2013International audienceResults of laser induced damage threshold (LIDT) of fused silica, sapphire and Ti:Sa crystals in single shot mode in the femtosecond regime down to few optical cycles (<10 fs) are presented. Different approaches to determine LIDT are described and compared. Our methodology yields accurate determination of damage/ablation threshold of any material (or component) irradiated by pulsed laser, as well as complementary physical results characterizing laser-matter interaction and/or concerning the deterministic character of femtosecond damage. It is shown that the abrupt decrease of both damage and ablation thresholds observed with ultra-short pulses (<30 fs) is related to the significance of tunnel ionization in the ultrashort regime. Moreover, the results indicate that the laser damage occurrence is more deterministic below 30 fs
Étude et développement d'une source de pompage optique VUV de forte puissance pour l'amplification d'impulsions laser femtosecondes sur la transition XeF(C-A)
Le rayonnement UV-VUV issu d'un plasma généré par une décharge électrique de forte
puissance dans un milieu gazeux (ici XeF) est capable d'exciter de grands volumes de différents milieux
lasers. Nous présentons une nouvelle source optique UV-VUV de forte puissance basée sur une décharge
multi-canaux réalisée sur la surface d'un diélectrique ainsi que les premiers résultats d'amplification
d'impulsions femtosecondes obtenus dans le milieu actif d'un laser photolytique XeF(C-A). Ce milieu est
très attractif pour développer des systèmes lasers hybrides de forte puissance (petawatt) dans le domaine
du visible. En effet, la transition XeF(C-A) est caractérisée par une bande spectrale très large dans le
bleu-vert (460-520 nm) permettant d'amplifier des impulsions optiques d'une durée de l'ordre de 10 fs
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