7 research outputs found
Large-Scale Study of Perceptual Video Quality
The great variations of videographic skills, camera designs, compression and
processing protocols, and displays lead to an enormous variety of video
impairments. Current no-reference (NR) video quality models are unable to
handle this diversity of distortions. This is true in part because available
video quality assessment databases contain very limited content, fixed
resolutions, were captured using a small number of camera devices by a few
videographers and have been subjected to a modest number of distortions. As
such, these databases fail to adequately represent real world videos, which
contain very different kinds of content obtained under highly diverse imaging
conditions and are subject to authentic, often commingled distortions that are
impossible to simulate. As a result, NR video quality predictors tested on
real-world video data often perform poorly. Towards advancing NR video quality
prediction, we constructed a large-scale video quality assessment database
containing 585 videos of unique content, captured by a large number of users,
with wide ranges of levels of complex, authentic distortions. We collected a
large number of subjective video quality scores via crowdsourcing. A total of
4776 unique participants took part in the study, yielding more than 205000
opinion scores, resulting in an average of 240 recorded human opinions per
video. We demonstrate the value of the new resource, which we call the LIVE
Video Quality Challenge Database (LIVE-VQC), by conducting a comparison of
leading NR video quality predictors on it. This study is the largest video
quality assessment study ever conducted along several key dimensions: number of
unique contents, capture devices, distortion types and combinations of
distortions, study participants, and recorded subjective scores. The database
is available for download on this link:
http://live.ece.utexas.edu/research/LIVEVQC/index.html
Domain-Specific Fusion Of Objective Video Quality Metrics
Video processing algorithms like video upscaling, denoising, and compression are now increasingly optimized for perceptual quality metrics instead of signal distortion. This means that they may score well for metrics like video multi-method assessment fusion (VMAF), but this may be because of metric overfitting. This imposes the need for costly subjective quality assessments that cannot scale to large datasets and large parameter explorations. We propose a methodology that fuses multiple quality metrics based on small scale subjective testing in order to unlock their use at scale for specific application domains of interest. This is achieved by employing pseudo-random sampling of the resolution, quality range and test video content available, which is initially guided by quality metrics in order to cover the quality range useful to each application. The selected samples then undergo a subjective test, such as ITU-T P.910 absolute categorical rating, with the results of the test postprocessed and used as the means to derive the best combination of multiple objective metrics using support vector regression. We showcase the benefits of this approach in two applications: video encoding with and without perceptual preprocessing, and deep video denoising & upscaling of compressed content. For both applications, the derived fusion of metrics allows for a more robust alignment to mean opinion scores than a perceptually-uninformed combination of the original metrics themselves. The dataset and code is available at https://github.com/isize-tech/VideoQualityFusion
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Statistical and perceptual properties of images and videos with applications
The visual brain is optimally designed to process images from the natural environment that we perceive. Describing the natural environment statistically helps in understanding how the brain encodes those images efficiently. The Natural Scene Statistics (NSS) of the luminance component of images is the basis of several univariate statistical models. Such models were the fundamental building blocks of multiple visual applications, ranging from the design of faithful image and video quality models to the development of perceptually optimized image enhancing techniques. Towards advancing this area, I studied the bivariate statistical properties of images and developed the first of its kind closed-form model that describes the correlation of spatially separated bandpass image samples. I found that the model was useful in tackling different problems such as blindly assessing the quality of images and assessing 3D visual discomfort of stereo images. Provided the success of NSS in tackling image processing problems, I decided to use them as a tool to tackle the blind video quality assessment (VQA) problem. First, I constructed a video quality database, the LIVE Video Quality Challenge Database (LIVE-VQC). This database is the largest across several key dimensions: number of unique contents, distortions, devices, resolutions, and videographers. For collecting the subjective scores, I constructed a new framework in Amazon Mechanical Turk. A massive number of subjects from across the globe participated in my study. Those efforts resulted in a VQA database that serves as a great benchmark for real-world videos. Next, I studied the spatio-temporal statistics of a wide variety of natural videos and created a space-time completely blind VQA model that deploys a directional temporal NSS model to predict quality. My newly created model outperforms all previous completely blind VQA models on the LIVE-VQCElectrical and Computer Engineerin
Delivery of 360° videos in edge caching assisted wireless cellular networks
In recent years, 360° videos have become increasingly popular on commercial social platforms, and are a vital part of emerging Virtual Reality (VR) applications. However, the delivery of 360° videos requires significant bandwidth resources, which makes streaming of such data on mobile networks challenging. The bandwidth required for delivering 360° videos can be reduced by exploiting the fact that users are interested in viewing only a part of the video scene, the requested viewport. As different users may request different viewports, some parts of the 360° scenes may be more popular than others. 360° video delivery on mobile networks can be facilitated by caching popular content at edge servers, and delivering it from there to the users. However, existing edge caching schemes do not take full potential of the unequal popularity of different parts of a video, which renders them inefficient for caching 360° videos. Inspired by the above, in this thesis, we investigate how advanced 360° video coding tools, i.e., encoding into multiple quality layers and tiles, can be utilized to build more efficient wireless edge caching schemes for 360° videos. The above encoding allows the caching of only the parts of the 360° videos that are popular in high quality. To understand how edge caching schemes can benefit from 360° video coding, we compare the caching of 360° videos encoded into multiple quality layers and tiles with layer-agnostic and tile-agnostic schemes. To cope with the fact that the content popularity distribution may be unknown, we use machine learning techniques, for both Video on Demand (VoD), and live streaming scenarios. From our findings, it is clear that by taking into account the aforementioned 360° video characteristics leads to an increased performance in terms of the quality of the video delivered to the users, and the usage of the backhaul links
Smart Sensor Technologies for IoT
The recent development in wireless networks and devices has led to novel services that will utilize wireless communication on a new level. Much effort and resources have been dedicated to establishing new communication networks that will support machine-to-machine communication and the Internet of Things (IoT). In these systems, various smart and sensory devices are deployed and connected, enabling large amounts of data to be streamed. Smart services represent new trends in mobile services, i.e., a completely new spectrum of context-aware, personalized, and intelligent services and applications. A variety of existing services utilize information about the position of the user or mobile device. The position of mobile devices is often achieved using the Global Navigation Satellite System (GNSS) chips that are integrated into all modern mobile devices (smartphones). However, GNSS is not always a reliable source of position estimates due to multipath propagation and signal blockage. Moreover, integrating GNSS chips into all devices might have a negative impact on the battery life of future IoT applications. Therefore, alternative solutions to position estimation should be investigated and implemented in IoT applications. This Special Issue, “Smart Sensor Technologies for IoT” aims to report on some of the recent research efforts on this increasingly important topic. The twelve accepted papers in this issue cover various aspects of Smart Sensor Technologies for IoT