ECC Video: An Active Second Error Control Approach for Error Resilience in Video Coding

Du, Bing Bing

January 2003

To support video communication over mobile environments has been one of the objectives of many engineers of telecommunication networks and it has become a basic requirement of a third generation of mobile communication systems. This dissertation explores the possibility of optimizing the utilization of shared scarce radio channels for live video transmission over a GSM (Global System for Mobile telecommunications) network and realizing error resilient video communication in unfavorable channel conditions, especially in mobile radio channels. The main contribution describes the adoption of a SEC (Second Error Correction) approach using ECC (Error Correction Coding) based on a Punctured Convolutional Coding scheme, to cope with residual errors at the application layer and enhance the error resilience of a compressed video bitstream. The approach is developed further for improved performance in different circumstances, with some additional enhancements involving Intra Frame Relay and Interleaving, and the combination of the approach with Packetization. Simulation results of applying the various techniques to test video sequences Akiyo and Salesman are presented and analyzed for performance comparisons with conventional video coding standard. The proposed approach shows consistent improvements under these conditions. For instance, to cope with random residual errors, the simulation results show that when the residual BER (Bit Error Rate) reaches 10-4, the video output reconstructed from a video bitstream protected using the standard resynchronization approach is of unacceptable quality, while the proposed scheme can deliver a video output which is absolutely error free in a more efficient way. When the residual BER reaches 10-3, the standard approach fails to deliver a recognizable video output, while the SEC scheme can still correct all the residual errors with modest bit rate increase. In bursty residual error conditions, the proposed scheme also outperforms the resynchronization approach. Future works to extend the scope and applicability of the research are suggested in the last chapter of the thesis.

ECC video

active second error control

error resilience

video coding

video communication

mobile environments

GSM

movile radio channels

second error correction

error correction coding

punctured convolutional

bit error rate

Technological Acceptance of an Avatar Based Interview Training Application : The development and technological acceptance study of the AvBIT application.

Dalli, Kevin Charles

January 2021

This thesis expands on previous research and designs of avatar-based child interview training software. The goal of the thesis was to identify requirements, identify technologies and evaluate the likelihood of acceptance of a distribution ready software that would enhance role-play training exercises commonly used for child interview training. After identifying the requirements needed to create this type of application the needed technologies for solving those requirements were identified and one prototype and two production ready applications were developed. The production ready versions were distributed in an official capacity through AvBIT Labs Ab. Each version was evaluated using the technological acceptance model (TAM) in order to determine likelihood of acceptance in relevant industries. The TAM survey, USE survey and correspondence with experts were used to evaluate missing requirements and the likelihood of software acceptance. The research conducted in this thesis directly contributed to the founding of AvBIT Labs AB and the distribution of the AvBIT application to both governmental and non-governmental organizations, seeking to enhance their child interview training, throughout Europe.

Avatar

Interview Training

Interrogation Training

Child Interview Training

Web RTC

Web Development

Audio/Video Communication

Interactive Training

Distance Learning

Technological Acceptance Model

USE Survey

Vulnerable Sector

Immersion

Education

Role-play.

Media and Communication Technology

Medieteknik

Error relilient video communications using high level M-QAM. Modelling and simulation of a comparative analysis of a dual-priority M-QAM transmission system for H.264/AVC video applications over band-limited and error-phone channels.

Abdurrhman, Ahmed B.M.

January 2010

An experimental investigation of an M level (M = 16, 64 and 256) Quadrature Amplitude Modulation (QAM) transmission system suitable for video transmission is presented. The communication system is based on layered video coding and unequal error protection to make the video bitstream robust to channel errors. An implementation is described in which H.264 video is protected unequally by partitioning the compressed data into two layers of different visual importance. The partition scheme is based on a separation of the group of pictures (GoP) in the intra-coded frame (I-frame) and predictive coded frame (P frame). This partition scheme is then applied to split the H.264-coded video bitstream and is suitable for Constant Bit Rate (CBR) transmission. Unequal error protection is based on uniform and non-uniform M-QAM constellations in conjunction with different scenarios of splitting the transmitted symbol for protection of the more important information of the video data; different constellation arrangements are proposed and evaluated to increase the capacity of the high priority layer. The performance of the transmission system is evaluated under Additive White Gaussian Noise (AWGN) and Rayleigh fading conditions. Simulation results showed that in noisy channels the decoded video can be improved by assigning a larger portion of the video data to the enhancement layer in conjunction with non-uniform constellation arrangements; in better channel conditions the quality of the received video can be improved by assigning more bits in the high priority channel and using uniform constellations. The aforementioned varying conditions can make the video transmission more successful over error-prone channels. Further techniques were developed to combat various channel impairments by considering channel coding methods suitable for layered video coding applications. It is shown that a combination of non-uniform M-QAM and forward error correction (FEC) will yield a better performance. Additionally, antenna diversity techniques are examined and introduced to the transmission system that can offer a significant improvement in the quality of service of mobile video communication systems in environments that can be modelled by a Rayleigh fading channel.

Modelling and simulation

Comparative analysis

Band-limited channels

Error-phone channels

Layered video coding

Unequal error protection

Mobile video communication systems

Antenna diversity techniques