Techniques are disclosed for determining the presence of pulse jams in an identification friend or foe (IFF) system. In an embodiment, a plurality of jamming pulse rates are determined. Each of the plurality of jamming pulse rates is a count of jamming pulses entering the IFF system during a corresponding integration period. Each of the plurality of jamming pulse rates is a count of jamming pulses associated with non-valid signals entering the IFF system. An average jamming pulse rate is computed based on the plurality of jamming pulse rates. The average jamming pulse rate is then compared against a pulse jam threshold to determine whether a pulse jam is present (or not present) in the IFF system.

Techniques are disclosed for determining the presence of pulse jams in an identification friend or foe (IFF) system. In an embodiment, a plurality of jamming pulse rates are determined. Each of the plurality of jamming pulse rates is a count of jamming pulses entering the IFF system during a corresponding integration period. Each of the plurality of jamming pulse rates is a count of jamming pulses associated with non-valid signals entering the IFF system. An average jamming pulse rate is computed based on the plurality of jamming pulse rates. The average jamming pulse rate is then compared against a pulse jam threshold to determine whether a pulse jam is present (or not present) in the IFF system.

A radar (30) is an FMCW radar. A determination unit (901) of the radar (30) executes at least one program of an attenuation determination program (324a), which determines whether an abnormal attenuation is present in a beat signal (S305), and a frequency characteristic determination program (325a), which determines whether an anomaly is present in a frequency characteristic of the beat signal (S305). The radar (30) can determine whether the beat signal (S305) is abnormal by software by executing the attenuation determination program (324a) and the frequency characteristic determination program (325a).

A radar (30) is an FMCW radar. A determination unit (901) of the radar (30) executes at least one program of an attenuation determination program (324a), which determines whether an abnormal attenuation is present in a beat signal (S305), and a frequency characteristic determination program (325a), which determines whether an anomaly is present in a frequency characteristic of the beat signal (S305). The radar (30) can determine whether the beat signal (S305) is abnormal by software by executing the attenuation determination program (324a) and the frequency characteristic determination program (325a).

The present application generally relates to a method and apparatus for obtaining crash or near crash related data in a motor vehicle. In particular, the system is operative to determine a proximity to a railway crossing in response to a vehicle location and a map, to detect an object using a radar, to confirm the presence of the object using a visual detecting system in response to the proximity to the railway crossing being less than a threshold distance, to generate a vehicle control signal in response to confirming the presence of the object using the visual detecting system, and to control an assisted driving equipped vehicle in response to the vehicle control system.

The present application generally relates to a method and apparatus for obtaining crash or near crash related data in a motor vehicle. In particular, the system is operative to determine a proximity to a railway crossing in response to a vehicle location and a map, to detect an object using a radar, to confirm the presence of the object using a visual detecting system in response to the proximity to the railway crossing being less than a threshold distance, to generate a vehicle control signal in response to confirming the presence of the object using the visual detecting system, and to control an assisted driving equipped vehicle in response to the vehicle control system.

A method for processing signals of active sensor systems including processing an emitted signal to include at least one distinguishing feature, the emitted signal emitted by an active sensor system adapted to intercept a reflection of the emitted signal, and to analyze the reflection of the emitted signal for determining at least one parameter of at least one object located in a space, analyzing an intercepted portion to verify the at least one distinguishing feature in the intercepted portion, and processing the intercepted portion as the reflection of the emitted signal when the at least one distinguishing feature is verified.

A method for processing signals of active sensor systems including processing an emitted signal to include at least one distinguishing feature, the emitted signal emitted by an active sensor system adapted to intercept a reflection of the emitted signal, and to analyze the reflection of the emitted signal for determining at least one parameter of at least one object located in a space, analyzing an intercepted portion to verify the at least one distinguishing feature in the intercepted portion, and processing the intercepted portion as the reflection of the emitted signal when the at least one distinguishing feature is verified.

A secure wireless transceiver, such as a link 16 transceiver, receives signals using an antenna array having an SOC associated with each antenna element in the array. The SOC's digitize and channelize received data for transmission to a message nulling system that mitigates jamming. The antenna array can be conformal, and can replace an existing Link 16 blade. The disclosed transceiver can be a modified CMN-4 transceiver with digitizing and channelizing moved to the SoC's, and replaced by the nulling system. The transceiver uses applicable TRANSEC information to assign received data to the logical Link 16 channels before nulling, and embodiments apply nulling only to channels of interest, thereby improving the nulling and reducing side lobes. Embodiments distinguish between desired and unwanted signals based on known Link 16 signal features and/or situational awareness, rather than signal amplitudes, thereby enabling nulling of even weak jamming signals.

A secure wireless transceiver, such as a link 16 transceiver, receives signals using an antenna array having an SOC associated with each antenna element in the array. The SOC's digitize and channelize received data for transmission to a message nulling system that mitigates jamming. The antenna array can be conformal, and can replace an existing Link 16 blade. The disclosed transceiver can be a modified CMN-4 transceiver with digitizing and channelizing moved to the SoC's, and replaced by the nulling system. The transceiver uses applicable TRANSEC information to assign received data to the logical Link 16 channels before nulling, and embodiments apply nulling only to channels of interest, thereby improving the nulling and reducing side lobes. Embodiments distinguish between desired and unwanted signals based on known Link 16 signal features and/or situational awareness, rather than signal amplitudes, thereby enabling nulling of even weak jamming signals.