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arxiv: 1809.01733 · v4 · pith:J6M4FM2Enew · submitted 2018-09-04 · 💻 cs.IT · cs.LG· eess.SP· math.IT· stat.ML

Deep Joint Source-Channel Coding for Wireless Image Transmission

classification 💻 cs.IT cs.LGeess.SPmath.ITstat.ML
keywords channeldeepjsccimagetransmissionvaluesbandwidthcoding
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We propose a joint source and channel coding (JSCC) technique for wireless image transmission that does not rely on explicit codes for either compression or error correction; instead, it directly maps the image pixel values to the complex-valued channel input symbols. We parameterize the encoder and decoder functions by two convolutional neural networks (CNNs), which are trained jointly, and can be considered as an autoencoder with a non-trainable layer in the middle that represents the noisy communication channel. Our results show that the proposed deep JSCC scheme outperforms digital transmission concatenating JPEG or JPEG2000 compression with a capacity achieving channel code at low signal-to-noise ratio (SNR) and channel bandwidth values in the presence of additive white Gaussian noise (AWGN). More strikingly, deep JSCC does not suffer from the ``cliff effect'', and it provides a graceful performance degradation as the channel SNR varies with respect to the SNR value assumed during training. In the case of a slow Rayleigh fading channel, deep JSCC learns noise resilient coded representations and significantly outperforms separation-based digital communication at all SNR and channel bandwidth values.

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