% Jesus Aguilar-Armijo
% Encoding: utf-8
@InProceedings{AguilarArmijo2021a,
  author = {Jesus Aguilar-Armijo},
  booktitle = {Proceedings of the 12th ACM Multimedia Systems Conference},
  title = {{Multi-access Edge Computing for Adaptive Bitrate Video Streaming}},
  year = {2021},
  month = {jun},
  pages = {378--382},
  publisher = {ACM},
  abstract = {Video streaming is the most used service in mobile networks and its usage will continue growing in the upcoming years. Due to this increase, content delivery should be improved as a key aspect of video streaming service, supporting higher bandwidth demand while assuring high quality of experience (QoE) for all the users. Multi-access edge computing (MEC) is an emerging paradigm that brings computational power and storage closer to the user. It is seen in the industry as a key technology for 5G mobile networks, with the goals of reducing latency, ensuring highly efficient network operation, improving service delivery and offering an improved user experience, among others. In this doctoral study, we aim to leverage the possibilities of MEC to improve the content delivery of video streaming services. We present four main research questions to target the different challenges in content delivery for HTTP Adaptive Streaming.},
  doi = {10.1145/3458305.3478460},
  url = {https://dl.acm.org/doi/10.1145/3458305.3478460}
}
@InProceedings{AguilarArmijo2021,
  author = {Jesus Aguilar-Armijo and Christian Timmerer and Hellwagner, Hermann},
  booktitle = {2021 IEEE 46th Conference on Local Computer Networks (LCN)},
  title = {{EADAS: Edge Assisted Adaptation Scheme for HTTP Adaptive Streaming}},
  year = {2021},
  month = {oct},
  pages = {487--494},
  publisher = {IEEE},
  abstract = {Mobile networks equipped with edge computing nodes enable access to information that can be leveraged to assist client-based adaptive bitrate (ABR) algorithms in making better adaptation decisions to improve both Quality of Experience (QoE) and fairness. For this purpose, we propose a novel on-the-fly edge mechanism, named EADAS (Edge Assisted Adaptation Scheme for HTTP Adaptive Streaming), located at the edge node that assists and improves the ABR decisions on-the-fly. EADAS proposes (i) an edge ABR algorithm to improve QoE and fairness for clients and (ii) a segment prefetching scheme. The results show a QoE increase of 4.6%, 23.5%, and 24.4% and a fairness increase of 11%, 3.4%, and 5.8% when using a buffer-based, a throughput-based, and a hybrid ABR algorithm, respectively, at the client compared with client-based algorithms without EADAS. Moreover, QoE and fairness among clients can be prioritized using parameters of the EADAS algorithm according to service providers’ requirements.},
  doi = {10.1109/lcn52139.2021.9524883},
  keywords = {Edge Computing, HTTP Adaptive Streaming, Network-assisted Video Streaming, Quality of Experience},
  url = {https://ieeexplore.ieee.org/document/9524883}
}
@InProceedings{AguilarArmijo2020,
  author = {Jesus Aguilar-Armijo and Babak Taraghi and Christian Timmerer and Hellwagner, Hermann},
  booktitle = {2020 IEEE International Symposium on Multimedia (ISM)},
  title = {{Dynamic Segment Repackaging at the Edge for {HTTP} Adaptive Streaming}},
  year = {2020},
  month = {dec},
  pages = {17--24},
  publisher = {IEEE},
  abstract = {Adaptive video streaming systems typically support different media delivery formats, e.g., MPEG-DASH and HLS, replicating the same content multiple times into the network. Such a diversified system results in inefficient use of storage, caching, and bandwidth resources. The Common Media Application Format (CMAF) emerges to simplify HTTP Adaptive Streaming (HAS), providing a single encoding and packaging format of segmented media content and offering the opportunities of bandwidth savings, more cache hits and less storage needed. However, CMAF is not yet supported by most devices. To solve this issue, we present a solution where we maintain the main advantages of CMAF while supporting heterogeneous devices using different media delivery formats. For that purpose, we propose to dynamically convert the content from CMAF to the desired media delivery format at an edge node. We study the bandwidth savings with our proposed approach using an analytical model and simulation, resulting in bandwidth savings of up to 20% with different media delivery format distributions.

We analyze the runtime impact of the required operations on the segmented content performed in two scenarios: the classic one, with four different media delivery formats, and the proposed scenario, using CMAF-only delivery through the network. We compare both scenarios with different edge compute power assumptions. Finally, we perform experiments in a real video streaming testbed delivering MPEG-DASH using CMAF content to serve a DASH and an HLS client, performing the media conversion for the latter one.},
  doi = {10.1109/ism.2020.00009},
  keywords = {CMAF, Edge Computing, HTTP Adaptive Streaming (HAS)}
}