TY - GEN
T1 - From QoS distributions to QoE distributions
T2 - 6th IEEE Conference on Network Softwarization, NetSoft 2020
AU - Hosfeld, Tobias
AU - Heegaard, Poul E.
AU - Varela, Martin
AU - Skorin-Kapov, Lea
AU - Fiedler, Markus
N1 - Publisher Copyright:
© 2020 IEEE.
PY - 2020/6
Y1 - 2020/6
N2 - In the context of QoE management, network and service providers commonly rely on models that map system QoS conditions (e.g., system response time, paket loss, etc.) to estimated end user QoE values. Observable QoS conditions in the system may be assumed to follow a certain distribution, meaning that different end users will experience different conditions. On the other hand, drawing from the results of subjective user studies, we know that user diversity leads to distributions of user scores for any given test conditions (in this case referring to the QoS parameters of interest). Our previous studies have shown that to correctly derive various QoE metrics (e.g., Mean Opinion Score (MOS), quantiles, probability of users rating 'good or better', etc.) in a system under given conditions, there is a need to consider rating distributions obtained from user studies, which are often times not available. In this paper we extend these findings to show how to approximate user rating distributions given a QoS-to-MOS mapping function and second order statistics. Such a user rating distribution may then be combined with a QoS distribution observed in a system to finally derive corresponding distributions of QoE scores. We provide two examples to illustrate this process: 1) analytical results using a Web QoE model relating waiting times to QoE, and 2) numerical results using measurements relating packet losses to video stall pattern, which are in turn mapped to QoE estimates.
AB - In the context of QoE management, network and service providers commonly rely on models that map system QoS conditions (e.g., system response time, paket loss, etc.) to estimated end user QoE values. Observable QoS conditions in the system may be assumed to follow a certain distribution, meaning that different end users will experience different conditions. On the other hand, drawing from the results of subjective user studies, we know that user diversity leads to distributions of user scores for any given test conditions (in this case referring to the QoS parameters of interest). Our previous studies have shown that to correctly derive various QoE metrics (e.g., Mean Opinion Score (MOS), quantiles, probability of users rating 'good or better', etc.) in a system under given conditions, there is a need to consider rating distributions obtained from user studies, which are often times not available. In this paper we extend these findings to show how to approximate user rating distributions given a QoS-to-MOS mapping function and second order statistics. Such a user rating distribution may then be combined with a QoS distribution observed in a system to finally derive corresponding distributions of QoE scores. We provide two examples to illustrate this process: 1) analytical results using a Web QoE model relating waiting times to QoE, and 2) numerical results using measurements relating packet losses to video stall pattern, which are in turn mapped to QoE estimates.
UR - http://www.scopus.com/inward/record.url?scp=85091961030&partnerID=8YFLogxK
U2 - 10.1109/NetSoft48620.2020.9165426
DO - 10.1109/NetSoft48620.2020.9165426
M3 - Conference contribution
AN - SCOPUS:85091961030
T3 - Proceedings of the 2020 IEEE Conference on Network Softwarization: Bridging the Gap Between AI and Network Softwarization, NetSoft 2020
SP - 51
EP - 56
BT - Proceedings of the 2020 IEEE Conference on Network Softwarization
A2 - De Turck, Filip
A2 - Chemouil, Prosper
A2 - Wauters, Tim
A2 - Zhani, Mohamed Faten
A2 - Cerroni, Walter
A2 - Pasquini, Rafael
A2 - Zhu, Zuqing
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 29 June 2020 through 3 July 2020
ER -