@inproceedings{WeberChristFelhaueretal.2014, author = {Christian Weber and Andreas Christ and Tobias Felhauer and Lothar Sch{\"u}ssele}, title = {A novel algorithm for channel segmentation based on a Lloyd-Max quantization}, series = {20th International Conference on Microwaves, Radar, and Wireless Communications (MIKON)}, organization = {IEEE}, doi = {10.1109/MIKON.2014.6900011}, pages = {1 -- 4}, year = {2014}, abstract = {Signal detection and bandwidth estimation, also known as channel segmentation or information channel estimation, is a perpetual topic in communication systems. In the field of radio monitoring this issue is extremely challenging, since unforeseeable effects like fading occur accidentally. In addition, most radio monitoring devices normally scan a wide frequency range of several hundred MHz and have to detect a multitude of different signals, varying in signal power, bandwidth and spectral shape. Since narrowband sensing techniques cannot be directly applied, most radio monitoring devices use Nyquist wideband sensing to discover the huge frequency range. In practice, sensing is normally conducted by an FFT sweep spectrum analyzer that delivers the power spectral density (PSD) values to the radio monitoring system. The channel segmentation is the initial step of a comprehensive signal analysis in a radio monitoring system based on the PSD values. In this paper, a novel approach for channel segmentation is presented that is based on a quantization and a histogram evaluation of the measured PSD. It will be shown that only the combination of both evaluations will lead to an successful automatic channel segmentation. The performance of the proposed algorithm is shown in a real radio monitoring szenario.}, language = {en} }