Embodiments of the present invention provide methods, systems, and computer-readable storage medium for managing access to an application on a mobile computing device. In an embodiment, a method includes receiving a request from a user to return to the application and return to a previous screen of the application on the mobile computing device, and determining, using a processor, whether the previous screen of the application was in a secured area of the application. If it was in the secured area, then an authentication protocol is triggered prior to allowing the user to return to the previous screen in the secured area of the application on the mobile computing device. In another embodiment, geolocation dependent information is provided to a user via an application on a mobile computing device.

A system for reception of electromagnetic waves in a spectrum in which interference with radio frequencies of other electronics devices occurs comprising a transmitter; at least one receiver configured to receive the received signal; each received signal organized into a digital vector; at least one memory portion configured to store a plurality of received signals in a vector form; the vectors being combined into a matrix, each vector of the matrix being a digital data record representing a received signal; at least one processor operatively connected to the at least one memory portion; the at least one processor configured to estimate that portion of the received signal attributable to noise; the at least one processor operating to jointly estimate a minimal number of distinctive noise patterns and minimize the simplicity of the data of interest; the at least processor operating to process the noise and data of interest separately.

A technology related to a distributed antenna system is disclosed. In an exemplary embodiment, a distributed antenna system may include a master unit and a plurality of remote units. The master unit may be interfaced with a wireless communications network and perform a bidirectional simultaneous digital radio frequency distribution of a wireless signal. The plurality of remote units may be each coupled to the master unit, and each perform a wireless transmission or reception of a split radio frequency signal to or from terminals located within a coverage. The master unit and the plurality of remote units may transmit or receive digital radio frequency signals in a wavelet transform domain. The master unit may determine whether the digital radio frequency signal, transmitted by each of the remote units, is normal, and merge the digital radio frequency signals.

Methods for communicating are disclosed. A method includes obtaining at least one input communication symbol selected from a set of communication symbols, converting the at least one input communication symbol into at least one transmittable waveform using at least one defined spiral waveform function, and transmitting the at least one transmittable waveform over a communication channel. Example spiral waveform functions include spline-based piecewise functions and Archimedes spiral functions.

A compressed sensing method based on non-uniform wavelet bandpass sampling. A K-sparse signal of interest is projected onto a sequence of waveforms succeeding one another at the bandpass sampling rate, the waveforms belonging to an overcomplete dictionary, the parameters of the waveforms depending on the characteristics of the bands of the signal. The correlation values are then non-uniformly sampled to provide a compressed representation of the signal.

Systems and methods for performing wavelength conflict detection are provided. These are to detect situations in optical networks where two instances of the same wavelength channel have been added. Wavelength conflict detection is performed for each of a plurality of possible wavelength channels that could be present in an optical signal, each wavelength channel that is present modulated by a pilot tone signal with a respective pilot tone frequency, the pilot tone signal carrying M-ary pilot tone data, M=2.sup.n, n?1, with a respective one of M different sequences being used to represent each of M possible data values over a data value period. Conflict detection for each wavelength channel involves performing correlation peak detection using each of the M different sequences to determine correlation peaks for each of the M different sequences, and, based on the determined correlation peaks, determining whether multiple instances of the wavelength channel are present in the optical signal.

Systems and methods are provided for broadcasting a for broadcasting a modulated signal. A plurality of peaks is detected within a waveform envelope signal of the modulated signal. For each of the plurality of peaks, a pulse having substantial spectral content that is outside of a passband of a high power filter is constructed. The constructed pulse for each peak is subtracted from its associated peak to provide a peak-reduced signal. The peak-reduced signal is amplified at a power amplifier to provide an amplified signal. The amplified signal is filtered at the high power filter to provide a filtered signal. The filtered signal is broadcast at an associated antenna.

Systems and methods are provided for broadcasting a for broadcasting a modulated signal. A plurality of peaks is detected within a waveform envelope signal of the modulated signal. For each of the plurality of peaks, a pulse having substantial spectral content that is outside of a passband of a high power filter is constructed. The constructed pulse for each peak is subtracted from its associated peak to provide a peak-reduced signal. The peak-reduced signal is amplified at a power amplifier to provide an amplified signal. The amplified signal is filtered at the high power filter to provide a filtered signal. The filtered signal is broadcast at an associated antenna.

A compressed sensing method based on non-uniform wavelet bandpass sampling. A K-sparse signal of interest is projected onto a sequence of waveforms succeeding one another at the bandpass sampling rate, the waveforms belonging to an overcomplete dictionary, the parameters of the waveforms depending on the characteristics of the bands of the signal. The correlation values are then non-uniformly sampled to provide a compressed representation of the signal.

A method and system for detecting pulsed communication signals, the method and system includes obtaining a time-frequency representation of a received training data signal, the received training data signal representative of a known/training bitstream associated with a transmitted pulse signal; using a scalogram process to convert the time-frequency representation of the received training data signal into a plurality of training images, and training a deep learning architecture platform with the plurality of training images to generate a classification model representative of a plurality of high bit states and a plurality of low bit states included in the plurality of training images. The disclosed method and system uses the CWT process to obtain a time-frequency representation of a target data signal, and uses the scalogram process to convert the time-frequency representation of the received target data signal into a plurality of respective target images representative of each of the bit states in the incoming target data signal bitstream; and using the trained deep learning architecture platform, classifies each of the plurality of respective target images as one of a high bit state and a low bit state; and generates an output bitstream based on the plurality of respective target images associated with the incoming data signal, wherein the incoming target data signal is one or both of turbo encoded and multipulse pulse position modulation (MPPM) encoded.