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Low-Resolution Infrared and High-Resolution Visible Image Fusion Based on U-NETLin, Hsuan 11 August 2022 (has links)
No description available.
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Improving Unreal Engine Imagery using Generative Adversarial Networks / Förbättring av Unreal Engine-renderingar med hjälp av Generativa MotståndarnätverkJareman, Erik, Knast, Ludvig January 2023 (has links)
Game engines such as Unreal Engine 5 are widely used to create photo-realistic renderings. To run these renderings at high quality without experiencing any performance issues,high-performance hardware is often required. In situations where the hardware is lacking,users may be forced to lower the quality and resolution of renderings to maintain goodperformance. While this may be acceptable in some situations, it limits the benefit that apowerful tool like Unreal Engine 5 can provide. This thesis aims to explore the possibilityof using a Real-ESRGAN, fine-tuned on a custom data set, to increase both the resolutionand quality of screenshots taken in Unreal Engine 5. By doing this, users can lower theresolution and quality of their Unreal Engine 5 rendering while still being able to generatehigh quality screenshots similar to those produced when running the rendering at higherresolution and higher quality. To accomplish this, a custom data set was created by randomizing camera positionsand capturing screenshots in an Unreal Engine 5 rendering. This data set was used to finetune a pre-trained Real-ESRGAN model. The fine-tuned model could then generate imagesfrom low resolution and low quality screenshots taken in Unreal Engine 5. The resultingimages were analyzed and evaluated using both quantitative and qualitative methods.The conclusions drawn from this thesis indicate that images generated using the finetuned weights are of high quality. This conclusion is supported by quantitative measurements, demonstrating that the generated images and the ground truth images are similar.Furthermore, visual inspection conducted by the authors confirms that the generated images are similar to the reference images, despite occasional artifacts.
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Molecular Size and Charge Effects on Nucleocytoplasmic Transport Studied By Single-Molecule MicroscopyGoryaynov, Alexander G. 03 April 2013 (has links)
No description available.
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EVALUATION OF INTERPOLATION AND REGISTRATION TECHNIQUES IN MAGNETIC RESONANCE IMAGE FOR ORTHOGONAL PLANE SUPER RESOLUTION RECONSTRUCTIONMahmoudzadeh, Amir Pasha January 2012 (has links)
No description available.
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A Unified Approach to GPU-Accelerated Aerial Video Enhancement TechniquesCluff, Stephen Thayn 12 February 2009 (has links) (PDF)
Video from aerial surveillance can provide a rich source of data for analysts. From the time-critical perspective of wilderness search and rescue operations, information extracted from aerial videos can mean the difference between a successful search and an unsuccessful search. When using low-cost, payload-limited mini-UAVs, as opposed to more expensive platforms, several challenges arise, including jittery video, narrow fields of view, low resolution, and limited time on screen for key features. These challenges make it difficult for analysts to extract key information in a timely manner. Traditional approaches may address some of these issues, but no existing system effectively addresses all of them in a unified and efficient manner. Building upon a hierarchical dense image correspondence technique, we create a unifying framework for reducing jitter, enhancing resolution, and expanding the field of view while lengthening the time that features remain on screen. It also provides for easy extraction of moving objects in the scene. Our method incorporates locally adaptive warps which allows for robust image alignment even in the presence of parallax and without the aid of internal or external camera parameters. We accelerate the image registration process using commodity Graphics Processing Units (GPUs) to accomplish all of these tasks in near real-time with no external telemetry data.
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High-resolution imaging of kidney tissue samplesUnnersjö-Jess, David January 2017 (has links)
The kidney is one of the most important and complex organs in the human body, filtering hundreds of litres of blood daily. Kidney disease is one of the fastest growing causes of death in the modern world, and this motivates extensive research for better understanding the function of the kidney in health and disease. Some of the most important cellular structures for blood filtration in the kidney are of very small dimensions (on the sub-200 nm scale), and thus electron microscopy has been the only method of choice to visualize these minute structures. In one study, we show for the first time that by combining optical clearing with STED microscopy, protein localizations in the slit diaphragm of the kidney, a structure around 75 nanometers in width, can now be resolved using light microscopy. In a second study, a novel sample preparation method, expansion microscopy, is utilized to physically expand kidney tissue samples. Expansion improves the effective resolution by a factor of 5, making it possible to resolve podocyte foot processes and the slit diaphragm using confocal microscopy. We also show that by combining expansion microscopy and STED microscopy, the effective resolution can be improved further. In a third study, influences on the development of the kidney were studied. There is substantial knowledge regarding what genes (growth factors, receptors etc.) are important for the normal morphogenesis of the kidney. Less is known regarding the physiology behind how paracrine factors are secreted and delivered in the developing kidney. By depleting calcium transients in explanted rat kidneys, we show that calcium is important for the branching morphogenesis of the ureteric tree. Further, the study shows that the calcium-dependent initiator of exocytosis, synaptotagmin, is expressed in the metanephric mesenchyme of the developing kidney, indicating that it could have a role in the secretion of paracrine growth factors, such as GDNF, to drive the branching. / <p>QC 20170523</p>
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Development of fast-dissociating recombinant antibodies for high-density multiplexed IRIS super-resolution microscopy / 多重高密度超解像顕微鏡IRISのための迅速解離リコンビナント抗体の開発Zhang, Qianli 24 November 2022 (has links)
京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24304号 / 生博第487号 / 新制||生||65(附属図書館) / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 渡邊 直樹, 教授 見学 美根子, 教授 今吉 格 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM
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Automated system design for the efficient processing of solar satellite images. Developing novel techniques and software platform for the robust feature detection and the creation of 3D anaglyphs and super-resolution images for solar satellite images.Zraqou, Jamal Sami January 2011 (has links)
The Sun is of fundamental importance to life on earth and is studied by scientists from many disciplines. It exhibits phenomena on a wide range of observable scales, timescales and wavelengths and due to technological developments there is a continuing increase in the rate at which solar data is becoming available for study which presents both opportunities and challenges. Two satellites recently launched to observe the sun are STEREO (Solar TErrestrial RElations Observatory), providing simultaneous views of the SUN from two different viewpoints and SDO (Solar Dynamics Observatory) which aims to study the solar atmosphere on small scales and times and in many wavelengths. The STEREO and SDO missions are providing huge volumes of data at rates of about 15 GB per day (initially it was 30 GB per day) and 1.5 terabytes per day respectively. Accessing these huge data volumes efficiently at both high spatial and high time resolutions is important to support scientific discovery but requires increasingly efficient tools to browse, locate and process specific data sets.
This thesis investigates the development of new technologies for processing information contained in multiple and overlapping images of the same scene to produce images of improved quality. This area in general is titled Super Resolution (SR), and offers a technique for reducing artefacts and increasing the spatial resolution. Another challenge is to generate 3D images such as Anaglyphs from uncalibrated pairs of SR images. An automated method to generate SR images is presented here. The SR technique consists of three stages: image registration, interpolation and filtration. Then a method to produce enhanced, near real-time, 3D solar images from uncalibrated pairs of images is introduced.
Image registration is an essential enabling step in SR and Anaglyph processing. An accurate point-to-point mapping between views is estimated, with multiple images registered using only information contained within the images themselves. The performances of the proposed methods are evaluated using benchmark evaluation techniques. A software application called the SOLARSTUDIO has been developed to integrate and run all the methods introduced in this thesis. SOLARSTUDIO offers a number of useful image processing tools associated with activities highly focused on solar images including: Active Region (AR) segmentation, anaglyph creation, solar limb extraction, solar events tracking and video creation.
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Key-Frame Based Video Super-Resolution for Hybrid CamerasLengyel, Robert 11 1900 (has links)
This work focuses on the high frequency restoration of video sequences captured by a hybrid camera, using key-frames as high frequency samples. The proposed method outlines a hierarchy to the super-resolution process, and is aimed at maximizing both speed and performance. Additionally, an advanced image processing simulator (EngineX) was developed to fine tune the algorithm. / Super-resolution algorithms are designed to enhance the detail level of a
particular image or video sequence. However, it is very difficult to achieve in
practice due to the problem being ill-posed, and often requires regularization
based on assumptions about texture or edges. The process can be aided using
high-resolution key-frames such as those generated from a hybrid camera. A
hybrid camera is capable of capturing footage in multiple spatial and temporal
resolutions. The typical output consists of a high resolution stream captured at
low frame rate, and a low resolution stream captured at a high frame rate.
Key-frame based super-resolution algorithms exploit the spatial and temporal
correlation between the high resolution and low resolution streams to
reconstruct a high resolution and high frame rate output stream.
The proposed algorithm outlines a hierarchy to the super-resolution process,
combining several different classical and novel methods. A residue formulation
decides which pixels are required to be further reconstructed if a particular
hierarchy stage fails to provide the expected results when compared to the low
resolution prior. The hierarchy includes the optical flow based estimation which
warps high frequency information from adjacent key-frames to the current frame.
Specialized candidate pixel selection reduces the total number of pixels
considered in the NLM stage. Occlusion is handled by a final fallback stage in
the hierarchy. Additionally, the running time for a CIF sequence of 30 frames
has been significantly reduced to within 3 minutes by identifying which pixels
require reconstruction with a particular method.
A custom simulation environment implements the proposed method as well as many
common image processing algorithms. EngineX provides a graphical interface where
video sequences and image processing methods can be manipulated and combined.
The framework allows for advanced features such as multithreading, parameter
sweeping, and block level abstraction which aided the development of the
proposed super-resolution algorithm. Both speed and performance were fine tuned
using the simulator which is the key to its improved quality over other traditional
super-resolution schemes. / Thesis / Master of Applied Science (MASc)
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Deep Learning Approaches for Automatic Colorization, Super-resolution, and Representation of Volumetric DataDevkota, Sudarshan 01 January 2023 (has links) (PDF)
This dissertation includes a collection of studies that aim to improve the way we represent and visualize volume data. The advancement of medical imaging has revolutionized healthcare, providing crucial anatomical insights for accurate diagnosis and treatment planning. Our first study introduces an innovative technique to enhance the utility of medical images, transitioning from monochromatic scans to vivid 3D representations. It presents a framework for reference-based automatic color transfer, establishing deep semantic correspondences between a colored reference image and grayscale medical scans. This methodology extends to volumetric rendering, eliminating the need for manual intervention in parameter tuning. Next, it delves into deep learning-based super-resolution for volume data. By leveraging color information and supplementary features, the proposed system efficiently upscales low-resolution renderings to achieve higher fidelity results. Temporal reprojection further strengthens stability in volumetric rendering. The third contribution centers on the compression and representation of volumetric data, leveraging coordinate-based networks and multi-resolution hash encoding. This approach demonstrates superior compression quality and training efficiency compared to other state-of-the-art neural volume representation techniques. Furthermore, we introduce a meta-learning technique for weight initialization to expedite convergence during training. These findings collectively underscore the potential for transformative advancements in large-scale data visualization and related applications.
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