Jakob Thrane scite author profile

Accurate channel models are essential to evaluate mobile communication system performance and optimize coverage for existing deployments. The introduction of various transmission frequencies for 5G imposes new challenges for accurate radio performance prediction. This paper compares traditional channel models to a channel model obtained using Deep Learning (DL)-techniques utilizing satellite images aided by a simple path loss model. Experimental measurements are gathered and compose the training and test set. This paper considers path loss modelling techniques offered by state-of-the-art stochastic models and a ray-tracing model for comparison and evaluation. The results show that 1) the satellite images offer an increase in predictive performance by ≈ 0.8 dB, 2) The model-aided technique offers an improvement of ≈ 1 dB, and 3) that the proposed DL model is capable of improving path loss prediction at unseen locations for 811 MHz with ≈ 1 dB and ≈ 4.7 dB for 2630 MHz.

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Machine Learning Techniques for Optical Performance Monitoring From Directly Detected PDM-QAM Signals

Thrane

Wass

Piels

et al. 2017

J. Lightwave Technol.

150

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Linear signal processing algorithms are effective in dealing with linear transmission channel and linear signal detection, while the nonlinear signal processing algorithms, from the machine learning community, are effective in dealing with nonlinear transmission channel and nonlinear signal detection. In this paper, a brief overview of the various machine learning methods and their application in optical communication is presented and discussed. Moreover, supervised machine learning methods, such as neural networks and support vector machine, are experimentally demonstrated for in-band optical signal to noise ratio (OSNR) estimation and modulation format classification, respectively. The proposed methods accurately evaluate optical signals employing up to 64 quadrature amplitude modulation (QAM), at 32 Gbaud, using only directly-detected data.

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Drive Test Minimization Using Deep Learning with Bayesian Approximation

Thrane

Artuso

Zibar

et al. 2018

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Deep Learning-based Signal Strength Prediction Using Geographical Images and Expert Knowledge

Thrane

Sliwa

Wietfeld

et al. 2020

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Methods for accurate prediction of radio signal quality parameters are crucial for optimization of mobile networks, and a necessity for future autonomous driving solutions. The power-distance relation of current empirical models struggles with describing the specific local geo-statistics that influence signal quality parameters. The use of empirical models commonly results in an over-or under-estimation of the signal quality parameters and require additional calibration studies.In this paper, we present a novel model-aided deep learning approach for path loss prediction, which implicitly extracts radio propagation characteristics from top-view geographical images of the receiver location. In a comprehensive evaluation campaign, we apply the proposed method on an extensive real-world data set consisting of five different scenarios and more than 125.000 individual measurements.It is found that 1) the novel approach reduces the average prediction error by up to 53 % in comparison to ray-tracing techniques, 2) A distance of 250 − 300 meters spanned by the images offer the necessary level of detail, 3) Predictions with a root-mean-squared error of ≈ 6 dB is achieved across inherently different data sources.

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Gaussian Process Regression for WDM System Performance Prediction

Wass¹,

Thrane²,

Piels³

et al. 2017

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Jakob Thrane

Model-Aided Deep Learning Method for Path Loss Prediction in Mobile Communication Systems at 2.6 GHz

Machine Learning Techniques for Optical Performance Monitoring From Directly Detected PDM-QAM Signals

Drive Test Minimization Using Deep Learning with Bayesian Approximation

Deep Learning-based Signal Strength Prediction Using Geographical Images and Expert Knowledge

Gaussian Process Regression for WDM System Performance Prediction

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