Abstract: A system includes a first antenna and a second antenna. The first antenna includes an antenna section. The antenna section includes a first antenna segment, a second antenna segment adjacent to the first antenna segment, and a notch circuit disposed within a notch between the first antenna segment and the second antenna segment. The notch circuit prevents a first frequency of a signal from passing from the first antenna segment to the second antenna segment while allowing a second frequency from the signal to pass from the first antenna segment to the second antenna segment. The second antenna is disposed proximate to the first antenna. The first antenna occupies a second near field region of the second antenna and the second antenna occupies a first near field region of the first antenna.

Abstract: A tapered slot antenna includes a cavity, first and second antenna flanges, a tapered slot, and first and second current wings. The first and second antenna flanges can be disposed on a first half and a second half of the tapered slot antenna, respectively. The second antenna flange can be electrically coupled to the first antenna flange, the first and second antenna flanges tapering from a greater flange width proximate to a top of the tapered slot antenna to a lesser flange width proximate to the cavity. The first current wing can be disposed on the first half of the antenna and the second current wing can be disposed on the second side of the antenna. The first and second sidewalls can be disposed on the first and second halves of the tapered slot antenna, respectively, can taper from the top to a bottom of the tapered slot antenna.

Abstract: An antenna installation having an antenna and a wire assembly. The antenna has a first end and a second end, with the antenna having a radiative distribution pattern and RF input characteristics. The wire assembly is positioned in close proximity to the antenna. The wire assembly includes a conductor and an RF insulative wrap. The conductor has a first end and a second end and at least one conductive element extending between the first end and the second end. The RF insulative wrap encircles the conductor between the first end and the second end. The RF insulative wrap includes a magnetic sheet having a magnetic metal powder within a polymer matrix. A method of preparing a wire assembly as well as the wire assembly itself are likewise disclosed.

Abstract: An antenna comprises an axial helical radiating element and a corrugated ground plane. The axial helical radiating element provides a radiation pattern substantially parallel to a primary axis of rotation of the helical radiating element. The corrugated ground plane, disposed proximate to a back region of the antenna, comprises corrugations to increase an electrical length of travel for radial standing waves between an axial helical input, at which the axial helical radiating element is coupled to the corrugated ground plane, to an outer edge of the corrugated ground plane.

Abstract: An apparatus is comprised of a processor, a fast-locking Phase-Locked Loop Waveform Generator (PLLWG), an amplifier circuit, and a voltage controlled oscillator (VCO). The processor generates data program signals to program the PLLWG and generates a trigger command signal instructing the PLLWG to generate an analog tuning signal. The PLLWG, coupled to the processor, generates the analog tuning signal based on the trigger command signal. The amplifier circuit, coupled to the PLLWG, receives the analog tuning signal, amplify the analog tuning signal, and generates a control voltage. The VCO, coupled to the amplifier circuit, receives the control voltage and amplifies the control voltage to generate an amplified Radio Frequency (RF) channel frequency signal.

Abstract: An apparatus includes a processor, a Phase-Locked Loop Waveform Generator (PLLWG), a Voltage Controlled Oscillator (VCO), a demodulator, signal conditioning circuitry, and an Analog-to-Digital Converter (ADC). The processor generates control command signals, receives a digital data input signal, and performs spectrum analysis on the digital data input signal. The PLLWG is coupled to the processor, receives the control command signals, and generates a charge pump output signal based on the control command signals. The VCO is coupled to the PLLWG, receives a tuning signal based on the charge pump output signal, and outputs a VCO output signal based on the tuning signal. The demodulator receives an incoming modulated signal and the VCO output signal, and outputs an analog output signal based on the incoming modulated signal and the VCO output signal. The ADC converts the analog output signal into the digital data input signal.

Abstract: An anti-drone weapon having a housing and at least one antenna positioned within the housing. The at least one antenna capable of operating at a frequency at least between 400 MHz and 6 GHz. In some configurations, a power supply, processor and control circuitry and a control panel, within the housing. In some configurations, the at least one antenna includes three antenna, including, a double helical antenna, a quasi-yagi antenna and a log-periodic antenna.

Abstract: A system includes a first antenna and a second antenna. The first antenna includes an antenna section. The antenna section includes a first antenna segment, a second antenna segment adjacent to the first antenna segment, and a notch circuit disposed within a notch between the first antenna segment and the second antenna segment. The notch circuit prevents a first frequency of a signal from passing from the first antenna segment to the second antenna segment while allowing a second frequency from the signal to pass from the first antenna segment to the second antenna segment. The second antenna is disposed proximate to the first antenna. The first antenna occupies a second near field region of the second antenna and the second antenna occupies a first near field region of the first antenna.

Abstract: Hand held equipment has a body and a heat sink. The body defines an outer surface and a heat source therewithin. The heat sink forms a portion of the outer surface and is positioned in close proximity to the heat source so as to conduct heat therefrom. The heat sink has a base, a plurality of fins and a coating having low thermal conductivity (which may be a ceramic coating). The base has a lower and an upper surface. The lower surface is in close proximity to the heat source. The plurality of fins has a proximal end meeting the upper surface of the base, and a distal end extending away from the base. Each of the plurality of fins define a cross-sectional area and terminate at an outward surface. The coating extends over at least a portion of the outward surface of the plurality of fins. A heat sink is likewise disclosed.

Abstract: A tapered slot antenna includes a cavity, first and second antenna flanges, a tapered slot, and first and second current wings. The first and second antenna flanges can be disposed on a first half and a second half of the tapered slot antenna, respectively. The second antenna flange can be electrically coupled to the first antenna flange, the first and second antenna flanges tapering from a greater flange width proximate to a top of the tapered slot antenna to a lesser flange width proximate to the cavity. The first current wing can be disposed on the first half of the antenna and the second current wing can be disposed on the second side of the antenna. The first and second sidewalls can be disposed on the first and second halves of the tapered slot antenna, respectively, can taper from the top to a bottom of the tapered slot antenna.

Abstract: An apparatus includes a processor, a Phase-Locked Loop Waveform Generator (PLLWG), a Voltage Controlled Oscillator (VCO), a demodulator, signal conditioning circuitry, and an Analog-to-Digital Converter (ADC). The processor generates control command signals, receives a digital data input signal, and performs spectrum analysis on the digital data input signal. The PLLWG is coupled to the processor, receives the control command signals, and generates a charge pump output signal based on the control command signals. The VCO is coupled to the PLLWG, receives a tuning signal based on the charge pump output signal, and outputs a VCO output signal based on the tuning signal. The demodulator receives an incoming modulated signal and the VCO output signal, and outputs an analog output signal based on the incoming modulated signal and the VCO output signal. The ADC converts the analog output signal into the digital data input signal.

Abstract: An apparatus that is comprised of a controller, a digital-to-analog converter (DAC), a temperature sensor, an analog-to-digital converter (ADC), and a voltage controlled oscillator (VCO). The controller to reads temperature data proportional to a temperature of the VCO, reads previously-calculated calibration data based on the read temperature data, determines a frequency command signal based on the read previously-calculated calibration data, and outputs the frequency command signal. The DAC converts the frequency command signal into a frequency analog signal. The temperature sensor produces the temperature signal. The ADC converts the temperature signal into the temperature data. The VCO produces an output frequency based on the frequency analog signal.

Abstract: A method and apparatus utilize a data connector, a connection adapter, and a matching transformer. The data connector receives a data signal from a communication line. The connection adapter, coupled to the data connector, receives the data signal with the data connector, adapts the data signal from the data connector to a coax connector, and communicates the data signal to the coax connector. The matching transformer, coupled to a coax cable, performs impedance matching between a first impedance associated with the coax connector and a second impedance associated with the coax cable communicating the data signal.

Abstract: An apparatus is comprised of a processor, first and second first Phase-Locked Loop Waveform Generators (PLLWGs), first and second Voltage Controlled Oscillators (VCOs), and a Radio Frequency (RF) switch. The processor generates first and second data program signals to program the first PLLWG and the second PLLWG, respectively, and generates a first and second trigger command signals instructing the first and second PLLWGs to generate first and second analog tuning signals, respectively. The first PLLWG, coupled to the processor, generates the first analog tuning signal. The second PLLWG, coupled to the processor, generates the second analog tuning signal. The first VCO, coupled to the first PLLWG, generates a first channel frequency signal. The second VCO, coupled to the second PLLWG, generates a second channel frequency signal. The RF switch selectively outputs one of a first pre-switch frequency signal and a second pre-switch frequency signal.

Abstract: An apparatus that is comprised of a controller, a digital-to-analog converter (DAC), a temperature sensor, an analog-to-digital converter (ADC), and a voltage controlled oscillator (VCO). The controller to reads temperature data proportional to a temperature of the VCO, reads previously-calculated calibration data based on the read temperature data, determines a frequency command signal based on the read previously-calculated calibration data, and outputs the frequency command signal. The DAC converts the frequency command signal into a frequency analog signal. The temperature sensor produces the temperature signal. The ADC converts the temperature signal into the temperature data. The VCO produces an output frequency based on the frequency analog signal.

Abstract: To provide greater efficiency in connecting and establishing communicational equipment, the communicational system type can be automatically detected and the communicational equipment can configure itself in accordance with the automatically detected communicational type. Additionally, to accommodate dynamic reconfiguration, or changes to the communicational type after an initial configuration, the communicational type can be automatically monitored and the communicationally equipment automatically reconfigured if changes are detected. Different sets of comparator circuitry can be utilized to compare the voltages observed at known inputs to known thresholds of different communicational types to automatically detect the communicational type being utilized by existing equipment to which the newly-connected equipment is communicationally coupled.

Abstract: An apparatus is comprised of a processor, a tuning voltage generator, a tuning circuit, an amplifier, and a voltage-controlled oscillator (VCO). The processor generates a tuning voltage command and a modulation command signal. The tuning voltage generator, coupled to the processor, receives the tuning voltage command and generates a baseline analog tuning signal based on the received tuning voltage command. The amplifier, coupled to the tuning voltage generator, receives the baseline analog tuning signal and the modulation signal, and generates a tuning signal based on the received baseline analog tuning signal and the received modulation command signal. The VCO, coupled to the amplifier, receives the tuning signal, generates a modulated radio frequency output signal based on the received tuning signal, and outputs the modulated radio frequency output signal, the modulated radio frequency output signal emulating a communication waveform.

Abstract: An adapter system suited suitable for use in association with legacy military connectors including an adapter board assembly and an electrical cable connector. The adapter board assembly includes a pair of legacy connectors and a high density connector. A connector attachment block is attached to the adapter board assembly. The electrical cable connector includes a first side coupling assembly, a second side coupling assembly and a cable member extending therebetween. The first side coupling includes a connector matingly electrically attachable to the high density connector of the adapter board assembly, and a housing attachable to the connector attachment block. The adapter board assembly and the electrical cable connector are likewise separately disclosed.