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Generating High Dimensional User-Specific Wireless Channels using Diffusion Models

generative-ai › diffusion

📄 Abstract

Abstract: Deep neural network (DNN)-based algorithms are emerging as an important tool for many physical and MAC layer functions in future wireless communication systems, including for large multi-antenna channels. However, training such models typically requires a large dataset of high-dimensional channel measurements, which are very difficult and expensive to obtain. This paper introduces a novel method for generating synthetic wireless channel data using diffusion-based models to produce user-specific channels that accurately reflect real-world wireless environments. Our approach employs a conditional denoising diffusion implicit model (cDDIM) framework, effectively capturing the relationship between user location and multi-antenna channel characteristics. We generate synthetic high fidelity channel samples using user positions as conditional inputs, creating larger augmented datasets to overcome measurement scarcity. The utility of this method is demonstrated through its efficacy in training various downstream tasks such as channel compression and beam alignment. Our diffusion-based augmentation approach achieves over a 1-2 dB gain in NMSE for channel compression, and an 11dB SNR boost in beamforming compared to prior methods, such as noise addition or the use of generative adversarial networks (GANs).

Authors (4)

Taekyun Lee

Juseong Park

Hyeji Kim

Jeffrey G. Andrews

Submitted

September 5, 2024

arXiv Category

cs.IT

arXiv PDF

Key Contributions

This paper introduces a novel method using diffusion models (specifically cDDIM) to generate high-dimensional, user-specific wireless channel data. By conditioning on user positions, it accurately reflects real-world environments and creates augmented datasets to overcome the difficulty and expense of obtaining real channel measurements.

Business Value

Accelerates the development and deployment of advanced wireless communication systems (e.g., 5G/6G) by providing realistic synthetic data for training and testing DNNs, reducing reliance on costly physical measurements.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate, requires expertise in both diffusion models and wireless communication systems. The generated data can be used in existing simulation frameworks.

Limitations Addressed

The difficulty and expense of obtaining large datasets of high-dimensional wireless channel measurements required for training DNN-based communication algorithms.

Performance Gains

Generates synthetic high-fidelity channel samples that accurately reflect real-world wireless environments, enabling larger augmented datasets.

Technical Tags

wireless channelsdiffusion modelsgenerative modelshigh-dimensional datauser-specific channelsconditional generationchannel measurementsDNNs

Research Topics

Wireless CommunicationsGenerative AIDeep LearningSignal Processing

Methods & Architectures

conditional denoising diffusion implicit model (cDDIM)user position conditioningdata augmentation Diffusion ModelsDeep Neural Networks (DNNs)

Applications & Tasks

Wireless Communication Systems 5G/6G Networks Antenna Array Design Wireless Channel ModelingData GenerationMeasurement Scarcity generating high-dimensional user-specific wireless channelscreating synthetic channel dataovercoming measurement scarcity

Related Fields

TelecommunicationsMachine LearningSignal ProcessingGenerative AI

Keywords

wireless channelsdiffusion modelsgenerative modelshigh-dimensionaluser-specificchannel measurementsDNNcDDIM5G6Gchannel modeling

Academic Context

#Wireless Communications#Generative AI#Deep Learning#Signal Processing

Commercial Potential

Potential Products

Synthetic wireless channel data generation platformsSimulation tools for wireless networksDesign tools for antenna arrays

Target Industries

TelecommunicationsSemiconductorsWireless InfrastructureResearch and Development

Use Case Examples

Simulating complex multi-antenna channel conditions for algorithm testingGenerating diverse channel data for training adaptive wireless systemsAccelerating the design cycle for new wireless hardware

Competitive Edge

Leverages diffusion models, a state-of-the-art generative technique, for wireless channel modeling, potentially offering higher fidelity and more realistic data than traditional methods.

Market Opportunity

Large, within the telecommunications infrastructure and R&D market.

Revenue Models

Directthrough licensing of the generation technology or as part of simulation software.

Resource Requirements

Compute Needs

High, for training diffusion models on high-dimensional data.

Data Requirements

Requires some real wireless channel measurements or detailed channel models to condition the generation process.

Deployment Constraints

Computational cost of generating data, need for accurate conditioning information (e.g., user locations).

Scalability

Scalability depends on the diffusion model implementation and the dimensionality of the channel.

Production Readiness

Maturity Level

Research

Time to Market

Medium, for integration into simulation and design tools.

Patent Potential

Moderate, for the specific application of diffusion models to wireless channel generation.

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