GAN network for cross-domain channel estimation in the 5G communication system
Advanced signal processing algorithms and sophisticated device generation processes in wireless communication systems enable block-based wireless communication systems with good communication performance. However, as the individual modules are designed for different purposes and situations, it is...
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Format: | Thesis-Master by Coursework |
Language: | English |
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Nanyang Technological University
2021
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Online Access: | https://hdl.handle.net/10356/149449 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | Advanced signal processing algorithms and sophisticated device generation processes
in wireless communication systems enable block-based wireless communication
systems with good communication performance. However, as the individual
modules are designed for different purposes and situations, it is easy to achieve
optimal performance on a particular module, but difficult to optimize the whole
system. Recently, due to the successful applications of deep learning in other
fields, researchers have considered its application to communication systems in order
to improve systems performance.
In this report, random functions and channel models are used to generate training
and test data. Deep learning-based autoencoders and decoders are used as
replacements for the signal processing modules in conventional wireless communication
systems. The channel distribution is modeled using conditional generative
adversarial networks. Generative adversarial networks consist of two parts, a
generator, and a discriminator. It aims to generate images similar to the target
images by random sampling from the latent space. Using the real channel output
as training data, we can model the channel distribution and build an end-to-end
communication system with a structure of autoencoder - conditional generative adversarial
network - decoder, which is based on deep neural networks. Simulation
results show that the deep learning-based structure can achieve global optimality
through an end-to-end loss function. Comparison with the theoretical BER curve
also shows this to be a promising communication architecture.
Keywords: Deep learning, deep neural network, autoencoder, conditional generative
adversarial network. |
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