Based on a theoretical model of the propagation of electromagnetic waves through a hypersonically induced plasma, it has been demonstrated that the classical radiofrequency communications blackout that is experienced during atmospheric reentry can be mitigated through the appropriate control of an external magnetic field of nominal magnitude. The model is based on the kinetic equation treatment of Vlasov and involves an analytical solution for the electric and magnetic fields within the plasma allowing for a description of the attendant transmission, reflection and absorption coefficients. The ability to transmit through the magnetized plasma is due to the magnetic windows that are created within the plasma via the well-known whistler modes of propagation. The case of 2 GHz transmission through a re-entry plasma is considered. The coefficients are found to be highly sensitive to the prevailing electron density and will thus require a dynamic control mechanism to vary the magnetic field as the plasma evolves through the re-entry phase. Manning, Robert M. Glenn Research Center NASA/TM-2009-216096, E-17149 WBS 599489.02.07.03.04.02.02 WAVE PROPAGATION; ELECTROMAGNETIC WAVE TRANSMISSION; RADIO TRANSMISSION; RADIO FREQUENCIES; MICROWAVE TRANSMISSION; ABSORPTIVITY; MAGNETIC FIELDS; COEFFICIENTS; REFLECTANCE