학술논문

Age-Critical Long Erasure Coding-CCSDS File Delivery Protocol for Dual-Hop S-IoT
Document Type
Periodical
Source
IEEE Internet of Things Journal IEEE Internet Things J. Internet of Things Journal, IEEE. 10(19):17070-17084 Oct, 2023
Subject
Computing and Processing
Communication, Networking and Broadcast Technologies
Delays
Relays
Satellites
Receivers
Internet of Things
Protocols
Signal to noise ratio
Age of Information (AoI)
consultative committee for space data system (CCSDS) file delivery protocol
long erasure coding
partially observable Markov decision process (POMDP)
Satellite Internet of Things (S-IoT)
Language
ISSN
2327-4662
2372-2541
Abstract
The upcoming Satellite Internet of Things (S-IoT) can provide status updates relaying for ground user equipment (UE). However, the S-IoT cannot utilize the conventional hybrid automatic retransmission request (HARQ) for reliable transmission due to the high bit error rate (BER) and long propagation latency. The consultative committee for space data systems (CCSDSs) has proposed the CCSDS file delivery protocol (CFDP) to relieve the long propagation latency, and the CFDP utilizes retransmission to guarantee the reliability. In this article, we propose two age-critical long erasure coding-CFDP (LEC-CFDP) schemes to realize dual-hop timely status updates in S-IoT via a relay satellite over shadowed Rician (SR) fading channel, where the satellite and destination can select the deferred or asynchronous mode to adjust the number of inserted long erasure codes (LECs) packets, called D-LEC CFDP and A-LEC CFDP, respectively. Furthermore, the satellite can select half-duplex or full-duplex relay mode, i.e., LEC-h CFDP or LEC-f CFDP to forward packets to the destination. We derive a closed-form expression for the Peak Age of Information (PAoI) and an approximation expression for the expected end-to-end delay for the D-LEC-f CFDP scheme. Moreover, we propose an A-LEC-f CFDP scheme to further improve the PAoI, and model it as a partially observable Markov decision process (POMDP) problem, which can be solved by a low-complexity point-based informed bound (PIB) algorithm. Simulation results verify the accuracy of the theoretical derivations and illustrate that the A-LEC-f CFDP scheme can achieve lower end-to-end delay and PAoI in comparison with the existing schemes.