Abstract
This article proposes and evaluates a technique to predict the level of interference in wireless networks. We design a recursive predictor that estimates future interference values by filtering measured interference at a given location. The predictor's parameterization is done offline by translating the autocorrelation of interference into an autoregressive moving average (ARMA) representation. This ARMA model is inserted into a steady-state Kalman filter enabling nodes to predict with low computational effort. Results show a good accuracy of predicted values versus true values for relevant time horizons. Although the predictor is parameterized for Poisson-distributed nodes, Rayleigh fading, and fixed message lengths, a sensitivity analysis shows that it also tends to work well in more general network scenarios. Numerical examples for underlay device-to-device communications, a common wireless sensor technology, and coexistence scenarios of Wi-Fi and LTE illustrate its broad applicability. The predictor can be applied as part of interference management to improve medium access, scheduling, and radio resource allocation.
Highlights
T HE management of interference has always been a key issue in wireless systems [1]
We study the prediction performance for parameter values that are typical in two wireless technologies: Long Term Evolution (LTE) used for cellular systems [41] and IEEE 802.15.4 used for wireless sensor networks (WSN) [42]
The predictor is designed for predicting the interference arising from the Wi-Fi deployment alone and its performance is affected by the interference generated by the LTE system operating in the same band
Summary
T HE management of interference has always been a key issue in wireless systems [1]. Negative effects of interference are averted by radio resource management, medium access control, scheduling, and decoding techniques. Some properties — including mean interference, higher-order statistics, and distributions — can be calculated in a given setup using stochastic geometry [2]–[8] These results consider the spatial features of wireless networks, which makes them fundamentally different from “classical” pieces of work on interference modeling and analysis [9], [10]. The specific contributions are as follows: 1) A method is presented to map the autocorrelation function of interference into an autoregressive moving average (ARMA) model suited for performing forecasts from previous interference observations This mapping is calculated for Poisson distributed nodes, Rayleigh fading, and random medium access with fixed message lengths.
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