Abstract: Systems and methods for securing orthogonal frequency division multiplexing (OFDM) transmission of data are discussed herein. Computing devices can sense the signal strength of frequencies on an OFDM wireless channel. The computing device can determine which of the frequencies are fading frequencies failing below a threshold. A transmitting computing device can send artificial data on the failing frequencies and genuine data on the remaining frequencies. Artificial data can be designed to mitigate peak-average-power ratio (PAPR) to have an additional benefit without using extra resource.

Abstract: System and method based upon an OFDM symbol, including a cyclic prefix (CP), that is received after being transmitted over a multiple access channel, wherein the CP is removed, and a Hann window is applied to the symbol. FFT is then applied to the Hann windowed symbol to obtain the frequency domain subcarriers. The pilot symbols are filtered accordingly to obtain Hann windowed pilots to estimate effective channel. Inter-carrier interference is calculated and removed.

Abstract: System and method based upon an OFDM symbol, including a cyclic prefix (CP), that is received after being transmitted over a multiple access channel, wherein the CP is removed, and a Hann window is applied to the symbol. FFT is then applied to the Hann windowed symbol to obtain the frequency domain subcarriers. The pilot symbols are filtered accordingly to obtain Hann windowed pilots to estimate effective channel. Inter-carrier interference is calculated and removed.

Abstract: Systems and methods for securing orthogonal frequency division multiplexing (OFDM) transmission of data are discussed herein. Computing devices can sense the signal strength of frequencies on an OFDM wireless channel. The computing device can determine which of the frequencies are fading frequencies failing below a threshold. A transmitting computing device can send artificial data on the failing frequencies and genuine data on the remaining frequencies. Artificial data can be designed to mitigate peak-average-power ratio (PAPR) to have an additional benefit without using extra resource.

Abstract: Examples of information beamforming technology for visible light communication (VLC) systems are provided. A VLC system can include an array of light emitting diode (LED) elements that can emit omni-directional light and control circuitry that can control individual LED elements of the array to sinusoidally vary the intensity of the omni-directional light emitted from the individual LED elements. A data carrying light beam can be generated within an information beam region by constructively combining sinusoidal intensity variations of the emitted omni-directional light and uniform intensity light can be generated outside the information beam region by destructively combining the sinusoidal intensity variations. The VLC system can include an optical detector that can detect sinusoidal intensity variations of a data carrying light beam and generate an output signal corresponding to the sinusoidal intensity variations.

Abstract: Systems and methods for securing orthogonal frequency division multiplexing (OFDM) transmission of data are discussed herein. Transceivers can sense the signal strength of frequencies on an OFDM wireless channel. The transceivers can determine which of the frequencies are fading frequencies failing below a threshold. A transmitting transceiver can send artificial data on the failing frequencies and genuine data on the remaining frequencies. Artificial data can be designed to mitigate peak-average-power ratio (PAPR) to have an additional benefit without using extra resource.

Abstract: Examples of information beamforming technology for visible light communication (VLC) systems are provided. A VLC system can include an array of light emitting diode (LED) elements that can emit omni-directional light and control circuitry that can control individual LED elements of the array to sinusoidally vary the intensity of the omni-directional light emitted from the individual LED elements. A data carrying light beam can be generated within an information beam region by constructively combining sinusoidal intensity variations of the emitted omni-directional light and uniform intensity light can be generated outside the information beam region by destructively combining the sinusoidal intensity variations. The VLC system can include an optical detector that can detect sinusoidal intensity variations of a data carrying light beam and generate an output signal corresponding to the sinusoidal intensity variations.

Abstract: In various embodiments, the present invention presents a physical layer (PHY) authentication technique for implantable medical devices (IMDs) that does not use existing methods of cryptology. Instead, a friendly jamming mechanism is established and malicious attempts by adversaries are prevented, without sharing any secured information, such as secret keys. In addition to ensuring authentication, the invention also provides advantages in terms of decreasing processing complexity of IMDs and enhances overall communications performance.

Abstract: Systems and methods for securing orthogonal frequency division multiplexing (OFDM) transmission of data are discussed herein. Transceivers can sense the signal strength of frequencies on an OFDM wireless channel. The transceivers can determine which of the frequencies are fading frequencies failing below a threshold. A transmitting transceiver can send artificial data on the failing frequencies and genuine data on the remaining frequencies. Artificial data can be designed to mitigate peak-average-power ratio (PAPR) to have an additional benefit without using extra resource.

Abstract: Systems and methods for securing orthogonal frequency division multiplexing (OFDM) transmission of data are discussed herein. Transceivers can sense the signal strength of frequencies on an OFDM wireless channel. The transceivers can determine which of the frequencies are fading frequencies failing below a threshold. A transmitting transceiver can send artificial data on the failing frequencies and genuine data on the remaining frequencies. Artificial data can be designed to mitigate peak-average-power ratio (PAPR) to have an additional benefit without using extra resource. Finally, receiving transceiver can transceiver receive the genuine data while discarding any date received on the failing frequencies.