50 research outputs found
RecolorNeRF: Layer Decomposed Radiance Fields for Efficient Color Editing of 3D Scenes
Radiance fields have gradually become a main representation of media.
Although its appearance editing has been studied, how to achieve
view-consistent recoloring in an efficient manner is still under explored. We
present RecolorNeRF, a novel user-friendly color editing approach for the
neural radiance fields. Our key idea is to decompose the scene into a set of
pure-colored layers, forming a palette. By this means, color manipulation can
be conducted by altering the color components of the palette directly. To
support efficient palette-based editing, the color of each layer needs to be as
representative as possible. In the end, the problem is formulated as an
optimization problem, where the layers and their blending weights are jointly
optimized with the NeRF itself. Extensive experiments show that our
jointly-optimized layer decomposition can be used against multiple backbones
and produce photo-realistic recolored novel-view renderings. We demonstrate
that RecolorNeRF outperforms baseline methods both quantitatively and
qualitatively for color editing even in complex real-world scenes.Comment: To appear in ACM Multimedia 2023. Project website is accessible at
https://sites.google.com/view/recolorner
SeamlessNeRF: Stitching Part NeRFs with Gradient Propagation
Neural Radiance Fields (NeRFs) have emerged as promising digital mediums of
3D objects and scenes, sparking a surge in research to extend the editing
capabilities in this domain. The task of seamless editing and merging of
multiple NeRFs, resembling the ``Poisson blending'' in 2D image editing,
remains a critical operation that is under-explored by existing work. To fill
this gap, we propose SeamlessNeRF, a novel approach for seamless appearance
blending of multiple NeRFs. In specific, we aim to optimize the appearance of a
target radiance field in order to harmonize its merge with a source field. We
propose a well-tailored optimization procedure for blending, which is
constrained by 1) pinning the radiance color in the intersecting boundary area
between the source and target fields and 2) maintaining the original gradient
of the target. Extensive experiments validate that our approach can effectively
propagate the source appearance from the boundary area to the entire target
field through the gradients. To the best of our knowledge, SeamlessNeRF is the
first work that introduces gradient-guided appearance editing to radiance
fields, offering solutions for seamless stitching of 3D objects represented in
NeRFs.Comment: To appear in SIGGRAPH Asia 2023. Project website is accessible at
https://sites.google.com/view/seamlessner
Stability Analysis and Event-Triggered Control for IT2 Discrete-time Positive Polynomial Fuzzy Networked Control Systems with Time Delay
Synthesis of Pyrazolo[3,4-d]pyrimidine Derivatives and Evaluation of their Src Kinase Inhibitory Activities
A series of pyrazolo[3,4-d]pyrimidine derivatives was synthesized and evaluated for the Src kinase inhibitory activities. Compound 6e and 10c exhibited inhibition of Src kinase with an IC50 value of 5.6 and 5.1 μM, respectively. Hydroxamate derivative 15a was found to be a metal-mediated inhibitor for human Csk with an IC50 value of 2.0 μM showing 56-fold selectivity over Src kinase inhibition
Novel Ge–Ga–Te–CsBr Glass System with Ultrahigh Resolvability of Halide
International audienceCO2 molecule, one of the main molecules to create new life, should be probed accurately to detect the existence of life in exoplanets. The primary signature of CO2 molecule is approximately 15 μm, and traditional S- and Se-based glass fibers are unsuitable. Thus, Te-based glass is the only ideal candidate glass for far-infrared detection. In this study, a new kind of Te-based chalcohalide glass system was discovered with relatively stable and large optical band gap. A traditional melt-quenching method was adopted to prepare a series of (Ge15Ga10Te75)100-x (CsBr)x chalcogenide glass samples. Experiment results indicate that the glass-forming ability and thermal properties of glass samples were improved when CsBr was added in the host of Ge–Ga–Te glass. Ge–Ga–Te glass could remarkably dissolve CsBr content as much as 85 at.%, which is the highest halide content in all reports for Te-based chalcohalide glasses. Moreover, ΔT values of these glass samples were all above 100 °C. The glass sample (Ge15Ga10Te75)65 (CsBr)35 with ΔT of 119 °C was the largest, which was 7 °C larger than that of Ge15Ga10Te75 host glass. The infrared transmission spectra of these glasses show that the far-infrared cut-off wavelengths of (Ge15Ga10Te75)100-x (CsBr)x chalcogenide glasses were all beyond 25 μm. In conclusion, (Ge15Ga10Te75)100-x (CsBr)x chalcogenide glasses are potential materials for far-infrared optical applicatio
Novel NaI improved Ge–Ga–Te far-infrared chalcogenide glasses
International audienceIn this study, a novel Te-based glass system was investigated. Some properties of Ge–Ga–Te–NaI chalcogenide glasses such as physical, thermal and optical transmitting were discussed. XRD patterns show this glass system with best amorphous state can dissolve content of NaI as much as 35 at.%. The lowest cut-off wavelength of glass samples is 1645 nm which is the smallest wavelength among the reported Te-based glasses doping with halide. DSC curves indicate that all glass samples have good thermal stabilities (ΔT > 100 °C) and the highest ΔT value corresponding to (Ge15Ga10Te75)85(NaI)15 glass is 120 °C which is 8 °C greater than that of Ge–Ga–Te host glass. The infrared spectra manifest Ge–Ga–Te–NaI chalcogenide glass system has a wide infrared transmission window between 1.6 μm and 20 μm. Consequently, Ge–Ga–Te–NaI glasses can be a candidate material for far infrared optic imaging and bio-sensing application
Comprehensively Surveying Structure and Function of RING Domains from Drosophila melanogaster
Using a complete set of RING domains from Drosophila melanogaster, all the solved RING domains and cocrystal structures of RING-containing ubiquitin-ligases (RING-E3) and ubiquitin-conjugating enzyme (E2) pairs, we analyzed RING domains structures from their primary to quarternary structures. The results showed that: i) putative orthologs of RING domains between Drosophila melanogaster and the human largely occur (118/139, 84.9%); ii) of the 118 orthologous pairs from Drosophila melanogaster and the human, 117 pairs (117/118, 99.2%) were found to retain entirely uniform domain architectures, only Iap2/Diap2 experienced evolutionary expansion of domain architecture; iii) 4 evolutionary structurally conserved regions (SCRs) are responsible for homologous folding of RING domains at the superfamily level; iv) besides the conserved Cys/His chelating zinc ions, 6 equivalent residues (4 hydrophobic and 2 polar residues) in the SCRs possess good-consensus and conservation- these 4 SCRs function in the structural positioning of 6 equivalent residues as determinants for RING-E3 catalysis; v) members of these RING proteins located nucleus, multiple subcellular compartments, membrane protein and mitochondrion are respectively 42 (42/139, 30.2%), 71 (71/139, 51.1%), 22 (22/139, 15.8%) and 4 (4/139, 2.9%); vi) CG15104 (Topors) and CG1134 (Mul1) in C3HC4, and CG3929 (Deltex) in C3H2C3 seem to display broader E2s binding profiles than other RING-E3s; vii) analyzing intermolecular interfaces of E2/RING-E3 complexes indicate that residues directly interacting with E2s are all from the SCRs in RING domains. Of the 6 residues, 2 hydrophobic ones contribute to constructing the conserved hydrophobic core, while the 2 hydrophobic and 2 polar residues directly participate in E2/RING-E3 interactions. Based on sequence and structural data, SCRs, conserved equivalent residues and features of intermolecular interfaces were extracted, highlighting the presence of a nucleus for RING domain fold and formation of catalytic core in which related residues and regions exhibit preferential evolutionary conservation
The Digital Children of the COVID-19 Pandemic : The Potential of Tangible Technology to Address the Barriers to Children’s Active Play caused by the COVID-19 Pandemic
The COVID-19 pandemic impacted people and communities worldwide. To stem the transmission of the disease, governments around the world implemented preventative measures such as lockdowns, and curfews; which resulted in the closures of public spaces (such as playgrounds and parks), recreational facilities (such as gyms and swimming pools), and the cessation of organized activities (such as playgroups and sports). Around the world, the message was clear – ‘stay at home’. To supplement children’s day-to-day routines, many activities transitioned online including school and active play activities (i.e. dance, martial arts, yoga). During this period of pandemic lockdown, children experienced greater levels of physical inactivity and higher levels of screen time. We position tangible technologies as a possible solution to reduce or alleviate the barriers that pandemic children experience when engaging in active play
Digital toys as tangible, embodied, embedded interactions
Our research aims to explore the potential that tangible, embedded, embodied interactions (TEIs) has in enabling children’s (age 3-5 years old) active play. This paper describes our study of 66 commercially available digitally augmented toys that have the potential to get children moving, and how these digital toys may be conceptualised as TEIs. During our analysis, the type and persistence of digital feedback from the toys was an important factor in our conceptualisation of these toys as tangible and embodied. We also encounter issues when conceptualising children’s toys, particularly toys for pretend play, as embedded interaction. These findings offer the opportunity to refine our definition of embeddedness to capture children’s play and highlights the importance of designing toys with strong feedback for physical activity
Tapered Chalcogenide-Tellurite Hybrid Microstructured Fiber For Mid-Infrared Supercontinuum Generation
Fibers exhibiting flattened and decreasing dispersion are important in nonlinear applications. Such fibers are difficult to design, particularly in soft glass. In this work, we develop a preliminary design of a highly nonlinear tapered hybrid microstructured optical fiber (TH-MOF) with chalcogenide glass core and tellurite glass microstructure cladding. We then numerically studied its dispersion, loss, and nonlinearity-related optical properties under fundamental mode systematically using the infinitesimal method. The designed TH-MOF exhibits low chromatic dispersion that is similar to a convex function with two zero-dispersion wavelengths and decreases with fiber length from 2 to 5 m band. The potential use of the TH-MOF in nonlinear applications is demonstrated numerically by a supercontinuum spectrum of 20 dB bandwidth covering 1.96-4.76 m generated in 2-cm-long TH-MOF using near 3.25-m fs-laser pump