Perceptual Quality of Point Clouds with application to Compression

Evangelos Alexiou
EPFL, 2021
Thèse EPFL

Résumé

Modern information technologies and human-centric communication systems employ advanced content representations for richer portrayals of the real world. The newly adopted imaging modalities offer additional information cues and permit the depiction of realistic sceneries, enabling immersive experiences and promoting the engagement of the user with the content. In this context, point clouds have emerged as an attractive option to represent immersive media. This type of visual data has seen a revived interest in the recent years, following the release of low-cost depth sensors and the wide integration of modern graphics processing units in mobile phones and personal computers. Point clouds can be naturally employed in extended reality applications that involve 6 degree-of-freedom interactions, allowing adjustments of the 3-D visual information in a per-point basis. At the same time, complexity reductions are promoted when compared to mesh modelling counterpart, due to the absence of connectivity information and the elimination of corresponding constraints from acquisition to rendering.

Yet, the vast amount of information that is required for faithful content representations implies the necessity for efficient data structures and compression algorithms. In particular, new coding schemes must be designed in order to reduce the amount of data and by extension the costs in processing, storage, and transmission of point clouds, while lossy compression solutions should restrain degradations for more appealing results. Furthermore, adequate subjective quality evaluation methodologies tailored to the nature of this 3D imaging modality are essential in order to obtain ground-truth data, and to better understand the impact of compression and rendering artifacts in visual quality. The development of high-performing objective metrics is also fundamental to accurately predict the perceptual quality of degraded models.

In this thesis, we address the aforementioned challenges by proposing new subjective quality assessment methodologies that better simulate realistic use-cases of 3D model consumption. We examine several aspects related to point cloud visualization and display means, by exploring different rendering approaches and by introducing experimental set-ups that offer different degrees of interactivity to the end-user. The behavior of human observers in 6 degrees-of-freedom virtual reality scenes is analysed, and visual attention maps are constructed using head and gaze trajectories recorded from eye-tracking experiments. Moreover, navigation data obtained from interactive subjective evaluations in desktop arrangements are exploited to improve image-based quality metrics, whose performance is examined in predicting visual impairments on point cloud contents. In the same line of research, we design novel point-based quality predictors for point cloud topology and texture degradations, and we rigorously analyse their performance using several subjectively annotated data sets. Furthermore, adopting well-established subjective evaluation methodologies, state-of-the-art compression solutions are benchmarked and best practices for rate allocation between geometry and texture encoding are derived. Lastly, a learning-based point cloud compression solution for encoding of both geometric and color information is proposed, and the impact of a series of parameters is examined on the obtained performance to pave the path for future efforts on the field.

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https://infoscience.epfl.ch/record/284835?ln=fr

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Evangelos Alexiou
EPFL, 2021
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/284835?ln=fr

À propos de ce résultat

Concepts associés (22)

Concepts associés

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Publications associées (7)

Publications associées

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Digital images are becoming increasingly successful thanks to the development and the facilitated access to systems permitting their generation (i.e. camera, scanner, imaging software, etc). A digital image basically corresponds to a 2D discrete set of regularly spaced samples, called pixels, where each pixel contains the light intensity information (e.g., luminance, chrominance) of a very localized spatial region of the image. In the case of natural images, pixel values are acquired through one or several arrays of MOS semiconductors (Charge Couple Devices, CCDs), each generating an electrical information proportional to the incoming light intensity. The initial finalities of digital images were the storage on a dedicated medium (e.g., camera's memory, computer's hard drive, CDROM), eventual transmissions, and final display on a screen or printing. With such a narrow scope, the principal goal of image processing and coding tools was to face storage and transmission bandwidth limitations thanks to efficient compression algorithms reducing the image representation size. However, with recent developments in computing, algorithmic and telecommunication domains, many new applications (i.e. web-publishing, remote browsing etc.) have arisen. They generally require additional and enhanced features (i.e. progressive decoding, random-access, region of interest support, robustness to transmission errors, etc.) and have motivated the creation of a new generation of coding algorithms which, besides their good compression performance, present many other useful features. Hence, digital images are almost never represented as a simple set of pixel values (i.e. raw representation) but, instead, under a specific compact way (i.e. compressed or coded representation), chosen according to features it brings to the considered application. A compressed version of an image is obtained by removing as much spatial, visual and statistical redundancies as possible, thanks to appropriate coding methods, while keeping an acceptable visual quality. Noting that natural images have most of their energy concentrated in low frequency components, recent coding algorithms generally first decompose the image into a specific frequency domain DCT, DWT, etc). The goal is to obtain a representation, where few coefficients are sufficient for reconstructing the image with a good quality. The precision of transformed coefficients is then generally reduced by quantization in order to make them more compressible by an entropy coder, aiming at removing statistical redundancies of quantization indexes. The ultimate compressed representation, called codestream, is usually obtained by a rate-allocation process that tries to achieve the best trade-off between the compression ratio and the reconstructed image quality. JPEG 2000, the new still image coding standard developed by the Joint Photographic Experts Group JPEG), is based on these state-of-the-art compression techniques, but is also designed to fulfill many requirements of recent applications. It only normalizes the decoding algorithm and consequently let some liberty for designing encoders optimized for some specific features or for building extensions that take profit from its compressed domain specifics. The success of the JPEG 2000 standard will not only depend on its intrinsic performance, but also on its ability to comply with specific demands of actual and future imaging applications. Thus, among the major concerns of image content providers are the security of the transmission over networks and of the image itself: with current facilities to instantly access on-line digital libraries from anywhere in the world, to perfectly copy and to easily modify the content of an image, solutions must be found in order to permit, at one hand, Intellectual Property Right (IPR) protection and image integrity verification and, at the other hand, the development of dedicated tools favoring exchange and purchase of images over communication networks. It is worth pointing out that some cryptographic-based solutions to these problems already exist. However, they need to be adapted to the digital image and its compressed domain representation in order to take full advantage from their specifics and to avoid restraining fields of applications. The JPEG 2000 coding algorithm is mainly based on Discrete Wavelet Transform (DWT), embedded scalar quantization and adaptive arithmetic coding. From a terminology point of view, this means that compressed domain representation can indifferently refer to either wavelet coefficients, or quantized wavelet coefficients, or bit streams (i.e. entropy coded group of quantization indexes) or the codestream (i.e. aggregation of bit streams and headers containing necessary decoding information). The choice of the appropriate compressed domain actually depends on the considered application. The quality of a JPEG 2000 image, at a given compression ratio, mainly depends on the rate-allocation procedure used at the encoder side. Such a procedure applies on entropy coded quantization indexes and favors groups of quantization indexes (i.e. code-blocks) offering the best rate-distortion trade-offs. However, this does not necessary correspond to the most interesting part of the image, from an end-observer point of view. Hence, the standard provides with ways to define Regions Of Interest (ROI) which are prioritized during the encoding process in order to exhibit a higher quality than the rest (i.e. background) at any decoding time. This feature applies either in the quantized wavelet domain or at the bit stream level, but its parameters are generally not very explicit for a standard end-user and only provide with a rough control of the decoded ROI quality. Consequently, the first objective of this thesis is to create and also extend compressed domain tools for controlling the quality of a JPEG 2000 ROI. In the meantime, several image processing techniques, such as watermarking, are applied directly in the spatial domain or in a specific transform space defined from the spatial domain. However, since digital images are preferably available under a compressed/encoded format, which we assume to be JPEG 2000 in this thesis, their implementation first imply decompressing the image, then apply the considered processing task and finally re-encode the resulting image. Such a scheme has two main drawbacks: First, it generally implies time and complexity overheads compared to equivalent methods (if they exist) in the JPEG 2000 compressed domain. Such effects become important when the scheme is repeatedly applied on multiple images. Second, since encoding and decoding operations are generally lossy, the introduced distortion can become non negligible whenever several processing tasks are repeated on a same image. These observations lead to the second objective of this thesis, which is to adapt or create a watermarking algorithm dedicated to the JPEG 2000 compressed domain. Finally, there are imaging algorithms, such as authentication and access control, that already exist and could be directly applied to JPEG 2000 images but, because they do not take into account the coding algorithm specifics, they either decrease compression performance or remove useful features of the encoded representation (scalability, random access, etc). This leads to the third objective of this thesis, which is to adapt, create and combine authentication and access control algorithms with JPEG 2000 coding and decoding. Thus, the common goal of the three objectives described above is the deep integration of selected processing and security algorithms into a JPEG 2000 codec in order to provide with minimum complexity, JPEG 2000 compliant codestreams and an unified framework for many imaging applications.

EPFL2003

Chargement

Towards neural network approaches for point cloud compression

Evangelos Alexiou, Touradj Ebrahimi, Kuan Tung

Point cloud imaging has emerged as an efficient and popular solution to represent immersive visual information. However, the large volume of data generated in the acquisition process reveals the need of efficient compression solutions in order to store and transmit such contents. Several standardization committees are in the process of finalizing efficient compression schemes to cope with the large volume of information that point clouds require. At the same time, recent efforts on learning-based compression approaches have been shown to exhibit good performance in the coding of conventional image and video contents. It is currently an open question how learning-based coding performs when applied to point cloud data. In this study, we extend recent efforts on the matter by exploring neural network implementations for separate, or joint compression of geometric and textural information from point cloud contents. Two alternative architectures are presented and compared; that is, a unified model that learns to encode point clouds in a holistic way, allowing fine-tuning for quality preservation per attribute, and a second paradigm consisting of two cascading networks that are trained separately to encode geometry and color, individually. A baseline configuration from the best-performing option is compared to the MPEG anchor, showing better performance for geometry and competitive performance for color encoding at low bit-rates. Moreover, the impact of a series of parameters is examined on the network performance, such as the selection of input block resolution for training and testing, the color space, and the loss functions. Results provide guidelines for future efforts in learning-based point cloud compression.

2020

Chargement

Context-based Quality of Experience in Immersive Multimedia

Anne-Flore Nicole Marie Perrin

Since 1895, when the Lumière brothers came out with the projected cinematograph, motion pictures and more generally multimedia contents have considerably improved and are still experiencing a very dynamic development. Advances involved improving various modalities that influence the Human Visual System (HVS) or the human perception. Indeed, migrations concerning audio, resolution, color, brightness, depth representations and frame rate have been performed or are being implemented. A high-quality multimedia content targets at least an acceptable level of consumer¿s satisfaction. It assumes to be a combination of sensory stimuli whose goal is to entertain, to educate or to inform, and can convey an artistic intent. Measuring the end-user satisfaction is a challenge as it is a complex multi-dimensional concept. To understand, measure and predict user satisfaction, researchers focused on the perceived quality of multimedia contents. Quality is the expression of an individual comparison and judgment process. It is based on inherent characteristics of a stimulus. It turns out that network-related impairments, major distortions in content delivery, are not considered when evaluating contents¿ inherent features. The quality measure considering the entire service pipeline (including delivery) is referred to as QoS. A more user-centric quality concept has been created under the consideration that not only technical quality and delivery artifacts influence an experience. Accordingly, QoE represents the user¿s degree of delight or annoyance for an application or service in regards to his prior knowledge, expectations and current state. This work addresses the design of new methodologies for QoE subjective evaluation. The research includes identification, definition and investigation on influence factors of QoE. Possibility to predict QoE using physiological signals gathered during subjective assessment is also considered. This thesis is positioned as a framework for the assessment of emerging technologies. Its main focus is on HDR and Wide Color Gamut (WCG) representations, for these emerging technologies provide faithful and realistic content; immersive technologies, such as 360 imaging and VR gaming; as well as the combination of typical multimedia representations (e.g. Standard Resolution (SD), High Definition (HD) and 4K contents along with no audio, stereo and surround audio). From conducted experiments on HDR and WCG, important recommendations came out for these technologies¿ deployment regarding representation and compression strategies while indicating future directions for QoE assessment. We designed a new subjective methodology for 360¿ HDR contents. It investigates which dimensions should be included in immersive and realistic contents evaluation while considering representation constraints (e.g., no spatial pair comparison possible for 360¿ contents). Expectations and novelty effect evaluations, two emerging-technologies-related aspects that can bias QoE-centric subjective assessment, have been implemented in the context of Virtual Reality (VR) gaming. Finally, attempts to predict the SoP, an important QoE-related notion when analyzing physiological signals (brain activity (Electroencephalography (EEG)), heart activity (Electrocardiography (ECG)) and respiration) have been performed for various multimedia consumption scenarios (in terms of quality, resolution and sound systems as well as typical use cases).

EPFL2019

Chargement

Context-based Quality of Experience in Immersive Multimedia

Anne-Flore Nicole Marie Perrin

EPFL2019

EPFL2003