Govaers, F.F.GovaersDegen, C.C.DegenWild, K.K.WildGarcia-Ariza, P.P.Garcia-ArizaTrautwein, U.U.TrautweinKäske, M.M.KäskeHäfner, S.S.HäfnerThomä, R.R.ThomäHoppe, R.R.Hoppe2022-03-122022-03-122013https://publica.fraunhofer.de/handle/publica/383060In many applications of public safety, security, and emergency scenarios electromagnetic emitters such as cell phones have to be located. However, in urban environments an effective and reliable localization in a noncooperative case is a challenging task due to the propagation properties of the electromagnetic waves. In particular scenarios, buildings, vegetation and other obstacles (partly metallic ones such a lamp posts or signs) lead to shadowing, diffraction, and reflection of the signal. As a consequence the emitted wave is often measured as a superposition of the signal taking multiple paths. Therefore conventional direction finding (DF) approaches are likely to fail the localization task in these multi-path. The research project ""Emitter Localization in Multi-Path Environments"" (EiLT) [1] has the aim to develop the next generation of DF systems for surveillance and spectrum control in urban scenarios taking advantage of ray-tracing techniques, high resolution channel parameter estimation, wideband polarimetric DF antennas and data fusion algorithms.enconference paper