@article{scholars3589, year = {2013}, number = {6}, volume = {28}, note = {cited By 1}, pages = {469--478}, journal = {Applied Computational Electromagnetics Society Journal}, title = {Equivalent circuit models for propagation analysis of in-building power line communications systems}, abstract = {In-building power line transmission measurements show potential for low attenuation propagation above 30 MHz. These measurements show that frequency bands can exist having low or minimum attenuation above 100 MHz. A simple high-frequency propagation model for analysis of in-building communications up to 900 MHz, which can be implemented using a commercial circuit simulator, is described. This physics-based model is extracted using broadband data from both time-and frequency-domain network transmission (S21) measurements. The novelty of this modeling approach is that different propagation modes such as electromagnetic coupling, waveguide propagation through the wiring conduit, and fading are included. An RF circuit model in a simulator environment is useful for analyzing a wide range of communication problems at the circuit, subsystem, and system levels.}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-84886934493&partnerID=40&md5=ca5452d57ddb837660a80ce60ba3c55e}, keywords = {Commercial circuit simulators; Communication problems; Equivalent circuit model; Network transmission; Physics-based modeling; Power line communications; Propagation modeling; Waveguide propagation, Circuit theory; Communication; Electric lines; Frequency bands; Frequency response; Models; Wave propagation; Waveguides, Circuit simulation}, author = {Hakimi, A. and Ellis, G. A.}, issn = {10544887} }