430 research outputs found
Image Denoising via Style Disentanglement
Image denoising is a fundamental task in low-level computer vision. While
recent deep learning-based image denoising methods have achieved impressive
performance, they are black-box models and the underlying denoising principle
remains unclear. In this paper, we propose a novel approach to image denoising
that offers both clear denoising mechanism and good performance. We view noise
as a type of image style and remove it by incorporating noise-free styles
derived from clean images. To achieve this, we design novel losses and network
modules to extract noisy styles from noisy images and noise-free styles from
clean images. The noise-free style induces low-response activations for noise
features and high-response activations for content features in the feature
space. This leads to the separation of clean contents from noise, effectively
denoising the image. Unlike disentanglement-based image editing tasks that edit
semantic-level attributes using styles, our main contribution lies in editing
pixel-level attributes through global noise-free styles. We conduct extensive
experiments on synthetic noise removal and real-world image denoising datasets
(SIDD and DND), demonstrating the effectiveness of our method in terms of both
PSNR and SSIM metrics. Moreover, we experimentally validate that our method
offers good interpretability
Towards a Self-Organizing Digital Business Ecosystem: Examining IT-Enabled Boundary Spanning Practice of China’s LeEco
The emergence of digital business platforms, ecosystems and non-linear value chains fosters hyper-connections among human actors, organizations, and processes. Such digital moves have brought cross-industry convergence and the blurring of business ecosystem boundaries, bringing about the possibility of overlapping business ecosystems, generating complex socio-technical issues. In this research-in-progress paper, we unpack the processes of how China’s LeEco develop from an emergent digital platform to a self-organizing digital business ecosystem. Drawing on theoretical notions of boundary spanning practice, we posit that towards a self-organizing digital business ecosystem, managers must seek to instill a conducive environment that reinforces, reciprocates and reproduces digital infrastructure through organizational coalition, congruence and hybridity respectively. Towards theoretical and practitioner contributions, ongoing analysis seeks to unpack the process of managing overlapping digital business ecosystems, the conditions under which they operate, the role of digital infrastructure in transition across organizational forms, the implications and outcomes
Diffusion Probabilistic Priors for Zero-Shot Low-Dose CT Image Denoising
Denoising low-dose computed tomography (CT) images is a critical task in
medical image computing. Supervised deep learning-based approaches have made
significant advancements in this area in recent years. However, these methods
typically require pairs of low-dose and normal-dose CT images for training,
which are challenging to obtain in clinical settings. Existing unsupervised
deep learning-based methods often require training with a large number of
low-dose CT images or rely on specially designed data acquisition processes to
obtain training data. To address these limitations, we propose a novel
unsupervised method that only utilizes normal-dose CT images during training,
enabling zero-shot denoising of low-dose CT images. Our method leverages the
diffusion model, a powerful generative model. We begin by training a cascaded
unconditional diffusion model capable of generating high-quality normal-dose CT
images from low-resolution to high-resolution. The cascaded architecture makes
the training of high-resolution diffusion models more feasible. Subsequently,
we introduce low-dose CT images into the reverse process of the diffusion model
as likelihood, combined with the priors provided by the diffusion model and
iteratively solve multiple maximum a posteriori (MAP) problems to achieve
denoising. Additionally, we propose methods to adaptively adjust the
coefficients that balance the likelihood and prior in MAP estimations, allowing
for adaptation to different noise levels in low-dose CT images. We test our
method on low-dose CT datasets of different regions with varying dose levels.
The results demonstrate that our method outperforms the state-of-the-art
unsupervised method and surpasses several supervised deep learning-based
methods. Codes are available in https://github.com/DeepXuan/Dn-Dp
Ethyl 3-bromo-1-(3-chloropyridin-2-yl)-1H-pyrazole-5-carboxylate
The title compound, C11H9BrClN3O2, is an intermediate in the synthesis of Rynaxypyre, a new insecticidal anthranilic diamide used as a potent and selective ryanodine receptor activator. The dihedral angle between the aromatic ring planes is 78.7 (2)°
Electrostatic effect due to patch potentials between closely spaced surfaces
The spatial variation and temporal variation in surface potential are
important error sources in various precision experiments and deserved to be
considered carefully. In the former case, the theoretical analysis shows that
this effect depends on the surface potentials through their spatial
autocorrelation functions. By making some modification to the quasi-local
correlation model, we obtain a rigorous formula for the patch force, where the
magnitude is proportional to with the distance between two parallel plates, the mean
patch size, and the scaling coefficient from to . A
torsion balance experiment is then conducted, and obtain a 0.4 mm effective
patch size and 20 mV potential variance. In the latter case, we apply an adatom
diffusion model to describe this mechanism and predicts a
frequency dependence above 0.01 . This prediction meets well with a
typical experimental results. Finally, we apply these models to analyze the
patch effect for two typical experiments. Our analysis will help to investigate
the properties of surface potentials
Combined Search for Lorentz Violation in Short-Range Gravity
Short-range experiments testing the gravitational inverse-square law at the submillimeter scale offer uniquely sensitive probes of Lorentz invariance. (See article for remainder of abstract.
SaPt-CNN-LSTM-AR-EA: a hybrid ensemble learning framework for time series-based multivariate DNA sequence prediction
Biological sequence data mining is hot spot in bioinformatics. A biological sequence can be regarded as a set of characters. Time series is similar to biological sequences in terms of both representation and mechanism. Therefore, in the article, biological sequences are represented with time series to obtain biological time sequence (BTS). Hybrid ensemble learning framework (SaPt-CNN-LSTM-AR-EA) for BTS is proposed. Single-sequence and multi-sequence models are respectively constructed with self-adaption pre-training one-dimensional convolutional recurrent neural network and autoregressive fractional integrated moving average fused evolutionary algorithm. In DNA sequence experiments with six viruses, SaPt-CNN-LSTM-AR-EA realized the good overall prediction performance and the prediction accuracy and correlation respectively reached 1.7073 and 0.9186. SaPt-CNN-LSTM-AR-EA was compared with other five benchmark models so as to verify its effectiveness and stability. SaPt-CNN-LSTM-AR-EA increased the average accuracy by about 30%. The framework proposed in this article is significant in biology, biomedicine, and computer science, and can be widely applied in sequence splicing, computational biology, bioinformation, and other fields
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