DeepJSCC-Q: Constellation Constrained Deep Joint Source-Channel Coding
- URL: http://arxiv.org/abs/2206.08100v1
- Date: Thu, 16 Jun 2022 11:43:50 GMT
- Title: DeepJSCC-Q: Constellation Constrained Deep Joint Source-Channel Coding
- Authors: Tze-Yang Tung, David Burth Kurka, Mikolaj Jankowski, Deniz Gunduz
- Abstract summary: We show that DeepJSCC-Q can achieve similar performance to prior works that allow any complex valued channel input.
DeepJSCC-Q preserves the graceful degradation of image quality in unpredictable channel conditions.
- Score: 6.55705721360334
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Recent works have shown that modern machine learning techniques can provide
an alternative approach to the long-standing joint source-channel coding (JSCC)
problem. Very promising initial results, superior to popular digital schemes
that utilize separate source and channel codes, have been demonstrated for
wireless image and video transmission using deep neural networks (DNNs).
However, end-to-end training of such schemes requires a differentiable channel
input representation; hence, prior works have assumed that any complex value
can be transmitted over the channel. This can prevent the application of these
codes in scenarios where the hardware or protocol can only admit certain sets
of channel inputs, prescribed by a digital constellation. Herein, we propose
DeepJSCC-Q, an end-to-end optimized JSCC solution for wireless image
transmission using a finite channel input alphabet. We show that DeepJSCC-Q can
achieve similar performance to prior works that allow any complex valued
channel input, especially when high modulation orders are available, and that
the performance asymptotically approaches that of unconstrained channel input
as the modulation order increases. Importantly, DeepJSCC-Q preserves the
graceful degradation of image quality in unpredictable channel conditions, a
desirable property for deployment in mobile systems with rapidly changing
channel conditions.
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