Graph Attention Networks for Channel Estimation in RIS-assisted
Satellite IoT Communications
- URL: http://arxiv.org/abs/2104.00735v1
- Date: Thu, 1 Apr 2021 19:15:04 GMT
- Title: Graph Attention Networks for Channel Estimation in RIS-assisted
Satellite IoT Communications
- Authors: K\"ur\c{s}at Tekb{\i}y{\i}k, G\"une\c{s} Karabulut Kurt, Ali R{\i}za
Ekti, Halim Yanikomeroglu
- Abstract summary: Direct-to-satellite (DtS) communication has gained importance recently to support globally connected Internet of things (IoT) networks.
This study proposes graph attention networks (GATs) for the challenging channel estimation problem.
- Score: 22.345609845425493
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Direct-to-satellite (DtS) communication has gained importance recently to
support globally connected Internet of things (IoT) networks. However,
relatively long distances of densely deployed satellite networks around the
Earth cause a high path loss. In addition, since high complexity operations
such as beamforming, tracking and equalization have to be performed in IoT
devices partially, both the hardware complexity and the need for high-capacity
batteries of IoT devices increase. The reconfigurable intelligent surfaces
(RISs) have the potential to increase the energy-efficiency and to perform
complex signal processing over the transmission environment instead of IoT
devices. But, RISs need the information of the cascaded channel in order to
change the phase of the incident signal. This study proposes graph attention
networks (GATs) for the challenging channel estimation problem and examines the
performance of DtS IoT networks for different RIS configurations under GAT
channel estimation.
Related papers
- Lightweight Deep Learning-Based Channel Estimation for RIS-Aided Extremely Large-Scale MIMO Systems on Resource-Limited Edge Devices [0.0]
We propose a lightweight deep learning framework for efficient cascaded channel estimation in XL-MIMO systems.<n>Our framework significantly improves estimation accuracy and reduces computational complexity, regardless of the increasing number of antennas and RIS elements.
arXiv Detail & Related papers (2025-07-13T13:42:42Z) - Over-the-Air Edge Inference via End-to-End Metasurfaces-Integrated Artificial Neural Networks [29.28415364984592]
We propose a framework of Metasurfaces-Integrated Neural Networks (MINNs) for Edge Inference (EI)
MINNs can significantly simplify EI requirements, achieving near-optimal performance with $50$dB lower testing signal-to-noise ratio compared to training.
arXiv Detail & Related papers (2025-03-31T21:14:09Z) - Hierarchical Learning and Computing over Space-Ground Integrated Networks [40.19542938629252]
We propose a hierarchical learning and computing framework to provide global aggregation services for locally trained models on ground IoT devices.
We formulate a network energy problem for model aggregation, which turns out to be a Directed Steiner Tree (DST) problem.
We propose a topologyaware energy-efficient routing (TAEER) algorithm to solve the DST problem by finding a minimum spanning arborescence on a substitute directed graph.
arXiv Detail & Related papers (2024-08-26T09:05:43Z) - Satellite Federated Edge Learning: Architecture Design and Convergence Analysis [47.057886812985984]
This paper introduces a novel FEEL algorithm, named FEDMEGA, tailored to mega-constellation networks.
By integrating inter-satellite links (ISL) for intra-orbit model aggregation, the proposed algorithm significantly reduces the usage of low data rate and intermittent GSL.
Our proposed method includes a ring all-reduce based intra-orbit aggregation mechanism, coupled with a network flow-based transmission scheme for global model aggregation.
arXiv Detail & Related papers (2024-04-02T11:59:58Z) - Artificial Intelligence Techniques for Next-Generation Mega Satellite
Networks [37.87439415970645]
This article introduces the application of AI techniques for integrated terrestrial satellite networks, particularly massive satellite network communications.
It details the unique features of massive satellite networks, and the overarching challenges concomitant with their integration into the current communication infrastructure.
This entails applying AI for forecasting the highly dynamic radio channel, spectrum sensing and classification, signal detection and demodulation, inter-satellite and satellite access network optimization, and network security.
arXiv Detail & Related papers (2022-06-02T13:56:32Z) - Time-Varying Channel Prediction for RIS-Assisted MU-MISO Networks via
Deep Learning [15.444805225936992]
Reconfigurable intelligent surface (RIS) has become a promising technology to improve the signal transmission quality of wireless communications.
However, accurate, low-latency and low-pilot-overhead channel state information (CSI) acquisition remains a considerable challenge in RIS-assisted systems.
We propose a three-stage joint channel decomposition and prediction framework to require CSI.
arXiv Detail & Related papers (2021-11-09T07:26:51Z) - Deep Learning Aided Routing for Space-Air-Ground Integrated Networks
Relying on Real Satellite, Flight, and Shipping Data [79.96177511319713]
Current maritime communications mainly rely on satellites having meager transmission resources, hence suffering from poorer performance than modern terrestrial wireless networks.
With the growth of transcontinental air traffic, the promising concept of aeronautical ad hoc networking relying on commercial passenger airplanes is potentially capable of enhancing satellite-based maritime communications via air-to-ground and multi-hop air-to-air links.
We propose space-air-ground integrated networks (SAGINs) for supporting ubiquitous maritime communications, where the low-earth-orbit satellite constellations, passenger airplanes, terrestrial base stations, ships, respectively, serve as the space-, air-,
arXiv Detail & Related papers (2021-10-28T14:12:10Z) - RIS-assisted UAV Communications for IoT with Wireless Power Transfer
Using Deep Reinforcement Learning [75.677197535939]
We propose a simultaneous wireless power transfer and information transmission scheme for IoT devices with support from unmanned aerial vehicle (UAV) communications.
In a first phase, IoT devices harvest energy from the UAV through wireless power transfer; and then in a second phase, the UAV collects data from the IoT devices through information transmission.
We formulate a Markov decision process and propose two deep reinforcement learning algorithms to solve the optimization problem of maximizing the total network sum-rate.
arXiv Detail & Related papers (2021-08-05T23:55:44Z) - Phase Configuration Learning in Wireless Networks with Multiple
Reconfigurable Intelligent Surfaces [50.622375361505824]
Reconfigurable Intelligent Surfaces (RISs) are highly scalable technology capable of offering dynamic control of electro-magnetic wave propagation.
One of the major challenges with RIS-empowered wireless communications is the low-overhead dynamic configuration of multiple RISs.
We devise low-complexity supervised learning approaches for the RISs' phase configurations.
arXiv Detail & Related papers (2020-10-09T05:35:27Z) - Intelligent Reflecting Surface Aided Wireless Communications: A Tutorial [64.77665786141166]
Intelligent reflecting surface (IRS) is an enabling technology to engineer the radio signal prorogation in wireless networks.
IRS is capable of dynamically altering wireless channels to enhance the communication performance.
Despite its great potential, IRS faces new challenges to be efficiently integrated into wireless networks.
arXiv Detail & Related papers (2020-07-06T13:59:09Z) - Integrating LEO Satellite and UAV Relaying via Reinforcement Learning
for Non-Terrestrial Networks [51.05735925326235]
A mega-constellation of low-earth orbit (LEO) satellites has the potential to enable long-range communication with low latency.
We study the problem of forwarding packets between two faraway ground terminals, through an LEO satellite selected from an orbiting constellation.
To maximize the end-to-end data rate, the satellite association and HAP location should be optimized.
We tackle this problem using deep reinforcement learning (DRL) with a novel action dimension reduction technique.
arXiv Detail & Related papers (2020-05-26T05:39:27Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.