Joint Sensing, Communication, and AI: A Trifecta for Resilient THz User
Experiences
- URL: http://arxiv.org/abs/2305.00135v1
- Date: Sat, 29 Apr 2023 00:39:50 GMT
- Title: Joint Sensing, Communication, and AI: A Trifecta for Resilient THz User
Experiences
- Authors: Christina Chaccour, Walid Saad, Merouane Debbah, and H. Vincent Poor
- Abstract summary: A novel joint sensing, communication, and artificial intelligence (AI) framework is proposed so as to optimize extended reality (XR) experiences over terahertz (THz) wireless systems.
- Score: 118.91584633024907
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: In this paper a novel joint sensing, communication, and artificial
intelligence (AI) framework is proposed so as to optimize extended reality (XR)
experiences over terahertz (THz) wireless systems. The proposed framework
consists of three main components. First, a tensor decomposition framework is
proposed to extract unique sensing parameters for XR users and their
environment by exploiting then THz channel sparsity. Essentially, THz band's
quasi-opticality is exploited and the sensing parameters are extracted from the
uplink communication signal, thereby allowing for the use of the same waveform,
spectrum, and hardware for both communication and sensing functionalities.
Then, the Cramer-Rao lower bound is derived to assess the accuracy of the
estimated sensing parameters. Second, a non-autoregressive multi-resolution
generative artificial intelligence (AI) framework integrated with an
adversarial transformer is proposed to predict missing and future sensing
information. The proposed framework offers robust and comprehensive historical
sensing information and anticipatory forecasts of future environmental changes,
which are generalizable to fluctuations in both known and unforeseen user
behaviors and environmental conditions. Third, a multi-agent deep recurrent
hysteretic Q-neural network is developed to control the handover policy of
reconfigurable intelligent surface (RIS) subarrays, leveraging the informative
nature of sensing information to minimize handover cost, maximize the
individual quality of personal experiences (QoPEs), and improve the robustness
and resilience of THz links. Simulation results show a high generalizability of
the proposed unsupervised generative AI framework to fluctuations in user
behavior and velocity, leading to a 61 % improvement in instantaneous
reliability compared to schemes with known channel state information.
Related papers
- Latent Diffusion Model-Enabled Real-Time Semantic Communication Considering Semantic Ambiguities and Channel Noises [18.539501941328393]
This paper constructs a latent diffusion model-enabled SemCom system, and proposes three improvements compared to existing works.
A lightweight single-layer latent space transformation adapter completes one-shot learning at the transmitter.
An end-to-end consistency distillation strategy is used to distill the diffusion models trained in latent space.
arXiv Detail & Related papers (2024-06-09T23:39:31Z) - Semi-supervised Anomaly Detection via Adaptive Reinforcement Learning-Enabled Method with Causal Inference for Sensor Signals [15.249261198557218]
Semi-supervised anomaly detection for sensor signals is critical in ensuring system reliability in smart manufacturing.
This paper innovatively constructs a counterfactual causal reinforcement learning model, termed Triple-Assisted Causal Reinforcement Learning Anomaly Detector (Tri-CRLAD)
Experimental results across seven diverse sensor signal datasets demonstrate that Tri-CRLAD outperforms nine state-of-the-art baseline methods.
arXiv Detail & Related papers (2024-05-11T06:10:05Z) - Incorporating Gradients to Rules: Towards Lightweight, Adaptive Provenance-based Intrusion Detection [11.14938737864796]
We propose CAPTAIN, a rule-based PIDS capable of automatically adapting to diverse environments.
We build a differentiable tag propagation framework and utilize the gradient descent algorithm to optimize these adaptive parameters.
The evaluation results demonstrate that CAPTAIN offers better detection accuracy, less detection latency, lower runtime overhead, and more interpretable detection alarms and knowledge.
arXiv Detail & Related papers (2024-04-23T03:50:57Z) - Agent-driven Generative Semantic Communication with Cross-Modality and Prediction [57.335922373309074]
We propose a novel agent-driven generative semantic communication framework based on reinforcement learning.
In this work, we develop an agent-assisted semantic encoder with cross-modality capability, which can track the semantic changes, channel condition, to perform adaptive semantic extraction and sampling.
The effectiveness of the designed models has been verified using the UA-DETRAC dataset, demonstrating the performance gains of the overall A-GSC framework.
arXiv Detail & Related papers (2024-04-10T13:24:27Z) - Causal Semantic Communication for Digital Twins: A Generalizable
Imitation Learning Approach [74.25870052841226]
A digital twin (DT) leverages a virtual representation of the physical world, along with communication (e.g., 6G), computing, and artificial intelligence (AI) technologies to enable many connected intelligence services.
Wireless systems can exploit the paradigm of semantic communication (SC) for facilitating informed decision-making under strict communication constraints.
A novel framework called causal semantic communication (CSC) is proposed for DT-based wireless systems.
arXiv Detail & Related papers (2023-04-25T00:15:00Z) - Neuro-Symbolic Artificial Intelligence (AI) for Intent based Semantic
Communication [85.06664206117088]
6G networks must consider semantics and effectiveness (at end-user) of the data transmission.
NeSy AI is proposed as a pillar for learning causal structure behind the observed data.
GFlowNet is leveraged for the first time in a wireless system to learn the probabilistic structure which generates the data.
arXiv Detail & Related papers (2022-05-22T07:11:57Z) - Model-based Deep Learning Receiver Design for Rate-Splitting Multiple
Access [65.21117658030235]
This work proposes a novel design for a practical RSMA receiver based on model-based deep learning (MBDL) methods.
The MBDL receiver is evaluated in terms of uncoded Symbol Error Rate (SER), throughput performance through Link-Level Simulations (LLS) and average training overhead.
Results reveal that the MBDL outperforms by a significant margin the SIC receiver with imperfect CSIR.
arXiv Detail & Related papers (2022-05-02T12:23:55Z) - Rethinking the Tradeoff in Integrated Sensing and Communication:
Recognition Accuracy versus Communication Rate [21.149708253108788]
Integrated sensing and communication (ISAC) is a promising technology to improve the band-utilization efficiency.
There exists a tradeoff between the sensing and communication performance.
This paper formulates and solves a multi-objective optimization problem which simultaneously maximizes the recognition accuracy and the communication data rate.
arXiv Detail & Related papers (2021-07-20T17:00:35Z) - Feeling of Presence Maximization: mmWave-Enabled Virtual Reality Meets
Deep Reinforcement Learning [76.46530937296066]
This paper investigates the problem of providing ultra-reliable and energy-efficient virtual reality (VR) experiences for wireless mobile users.
To ensure reliable ultra-high-definition (UHD) video frame delivery to mobile users, a coordinated multipoint (CoMP) transmission technique and millimeter wave (mmWave) communications are exploited.
arXiv Detail & Related papers (2021-06-03T08:35:10Z)
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.