BIQ2021: A Large-Scale Blind Image Quality Assessment Database

The assessment of the perceptual quality of digital images is becoming increasingly important as a result of the widespread use of digital multimedia devices. Smartphones and high-speed internet are just two examples of technologies that have multiplied the amount of multimedia content available. Thus, obtaining a representative dataset, which is required for objective quality assessment training, is a significant challenge. The Blind Image Quality Assessment Database, BIQ2021, is presented in this article. By selecting images with naturally occurring distortions and reliable labeling, the dataset addresses the challenge of obtaining representative images for no-reference image quality assessment. The dataset consists of three sets of images: those taken without the intention of using them for image quality assessment, those taken with intentionally introduced natural distortions, and those taken from an open-source image-sharing platform. It is attempted to maintain a diverse collection of images from various devices, containing a variety of different types of objects and varying degrees of foreground and background information. To obtain reliable scores, these images are subjectively scored in a laboratory environment using a single stimulus method. The database contains information about subjective scoring, human subject statistics, and the standard deviation of each image. The dataset's Mean Opinion Scores (MOS) make it useful for assessing visual quality. Additionally, the proposed database is used to evaluate existing blind image quality assessment approaches, and the scores are analyzed using Pearson and Spearman's correlation coefficients. The image database and MOS are freely available for use and benchmarking

A blind stereoscopic image quality evaluator with segmented stacked autoencoders considering the whole visual perception route

Most of the current blind stereoscopic image quality assessment (SIQA) algorithms cannot show reliable accuracy. One reason is that they do not have the deep architectures and the other reason is that they are designed on the relatively weak biological basis, compared with findings on human visual system (HVS). In this paper, we propose a Deep Edge and COlor Signal INtegrity Evaluator (DECOSINE) based on the whole visual perception route from eyes to the frontal lobe, and especially focus on edge and color signal processing in retinal ganglion cells (RGC) and lateral geniculate nucleus (LGN). Furthermore, to model the complex and deep structure of the visual cortex, Segmented Stacked Auto-encoder (S-SAE) is used, which has not utilized for SIQA before. The utilization of the S-SAE complements weakness of deep learning-based SIQA metrics that require a very long training time. Experiments are conducted on popular SIQA databases, and the superiority of DECOSINE in terms of prediction accuracy and monotonicity is proved. The experimental results show that our model about the whole visual perception route and utilization of S-SAE are effective for SIQA

Image Quality Assessment: Addressing the Data Shortage and Multi-Stage Distortion Challenges

Visual content constitutes the vast majority of the ever increasing global Internet traffic, thus highlighting the central role that it plays in our daily lives. The perceived quality of such content can be degraded due to a number of distortions that it may undergo during the processes of acquisition, storage, transmission under bandwidth constraints, and display. Since the subjective evaluation of such large volumes of visual content is impossible, the development of perceptually well-aligned and practically applicable objective image quality assessment (IQA) methods has taken on crucial importance to ensure the delivery of an adequate quality of experience to the end user. Substantial strides have been made in the last two decades in designing perceptual quality methods and three major paradigms are now well-established in IQA research, these being Full-Reference (FR), Reduced-Reference (RR), and No-Reference (NR), which require complete, partial, and no access to the pristine reference content, respectively. Notwithstanding the progress made so far, significant challenges are restricting the development of practically applicable IQA methods. In this dissertation we aim to address two major challenges: 1) The data shortage challenge, and 2) The multi-stage distortion challenge. NR or blind IQA (BIQA) methods usually rely on machine learning methods, such as deep neural networks (DNNs), to learn a quality model by training on subject-rated IQA databases. Due to constraints of subjective-testing, such annotated datasets are quite small-scale, containing at best a few thousands of images. This is in sharp contrast to the area of visual recognition where tens of millions of annotated images are available. Such a data challenge has become a major hurdle on the breakthrough of DNN-based IQA approaches. We address the data challenge by developing the largest IQA dataset, called the Waterloo Exploration-II database, which consists of 3,570 pristine and around 3.45 million distorted images which are generated by using content adaptive distortion parameters and consist of both singly and multiply distorted content. As a prerequisite requirement of developing an alternative annotation mechanism, we conduct the largest performance evaluation survey in the IQA area to-date to ascertain the top performing FR and fused FR methods. Based on the findings of this survey, we develop a technique called Synthetic Quality Benchmark (SQB), to automatically assign highly perceptual quality labels to large-scale IQA datasets. We train a DNN-based BIQA model, called EONSS, on the SQB-annotated Waterloo Exploration-II database. Extensive tests on a large collection of completely independent and subject-rated IQA datasets show that EONSS outperforms the very state-of-the-art in BIQA, both in terms of perceptual quality prediction performance and computation time, thereby demonstrating the efficacy of our approach to address the data challenge. In practical media distribution systems, visual content undergoes a number of degradations as it is transmitted along the delivery chain, making it multiply distorted. Yet, research in IQA has mainly focused on the simplistic case of singly distorted content. In many practical systems, apart from the final multiply distorted content, access to earlier degraded versions of such content is available. However, the three major IQA paradigms (FR, RR, and, NR) are unable to take advantage of this additional information. To address this challenge, we make one of the first attempts to study the behavior of multiple simultaneous distortion combinations in a two-stage distortion pipeline. Next, we introduce a new major IQA paradigm, called degraded reference (DR) IQA, to evaluate the quality of multiply distorted images by also taking into consideration their respective degraded references. We construct two datasets for the purpose of DR IQA model development, and call them DR IQA database V1 and V2. These datasets are designed on the pattern of the Waterloo Exploration-II database and have 32,912 SQB-annotated distorted images, composed of both singly distorted degraded references and multiply distorted content. We develop distortion behavior based and SVR-based DR IQA models. Extensive testing on an independent set of IQA datasets, including three subject-rated datasets, demonstrates that by utilizing the additional information available in the form of degraded references, the DR IQA models perform significantly better than their BIQA counterparts, thereby establishing DR IQA as a new paradigm in IQA