Patent Application
20170299685
Various communication systems may benefit from suitable antenna systems. For example, unmanned aircraft may benefit from systems and methods for providing a distributed airborne collision avoidance system antenna array.
Traditional Traffic Alert/Collision Avoidance System (TCAS) directional antennas are comprised of an array of precisely spaced radiating elements contained within a radome. The spacing of the elements is largely determined by the frequency of operation and the desired radiation pattern. Current TCAS antennas also require an optimal location on an aircraft and are typically larger than would be desired. As an example, the MQ-1 Predator has a fuel bladder running down the spine of the aircraft, so the installation of a typical TCAS antenna may not be suitable in this location, even though this may be the optimal installation location for performance. For many unmanned aircraft systems (UAS), a flexible, lightweight detect and avoid antenna, which is not subject to specific installation constraints, may be required. For example, the conventional antenna may need to be installed on top of an air intake on a Predator and may realize bearing issues caused by reflections or obstructions from the rear fins of the Predator.
More particularly, a conventional directional antenna may be too large for many class 3 UAS vehicles, and the ideal antenna location may not be available, due to engineering, aerodynamic, or balance issues.
According to certain embodiments, an apparatus can include a transceiver configured to transmit and receive avionics signals at a host vehicle. The apparatus can also include an interface configured to communicate with an array of a plurality of avionics receivers, wherein the avionics receivers are configured to receive the avionics signals at the host vehicle.
In certain embodiments, an apparatus can include a receiver configured to receive avionics signals at a host vehicle. The apparatus can also include a processor configured to digitize the received avionics signals. The apparatus can further include an interface configured to communicate data with an associated transceiver of the host vehicle, wherein the associated transceiver is configured to process digitized signals received from an array of a plurality of avionics receivers at the host vehicle.
A system, according to certain embodiments, can include a transceiver configured to transmit and receive avionics signals at a host vehicle. The system can also include a plurality of devices each comprising a receiver configured to receive avionics signals at the host vehicle, a processor configured to digitize the received avionics signals, and an interface configured to communicate data with the transceiver. The transceiver can include an interface configured to communicate with the devices.
For proper understanding of the invention, reference should be made to the accompanying drawings, wherein:
Certain embodiments of the present invention may provide a distributed antenna system that may utilize an array of monopole antennas with integrated receivers and digital signal processing (DSP) functionality at one or more of the antennas. The monopole antennas with integrated receivers and DSP functionality are herein referred to as “smart antennas.” The smart antennas may be mounted remotely from each other, but may still be networked together utilizing high speed Ethernet data busses such that the individual signals from each smart antenna can be summed in the appropriate phase relationship to form a directional antenna pattern. The signals can be simultaneously combined in multiple phase relationships such that bearing can be determined. The smart antennas may be installed in various spatial geometries to take advantage of improved installation locations.
The distributed antenna system according to certain embodiments of the present invention may provide maximum flexibility in the installation of the array configuration on a vehicle, such as an aircraft. The configuration of the antenna array on the aircraft can be dynamic and may be adapted to fit numerous aircraft types and overcome many installation difficulties.
ACAS Xu is an unmanned variant of the Federal Aviation Administration (FAA) ACAS X standard for collision-avoidance systems for commercial, general-aviation and unmanned aircraft. ACAS Xu can perform active surveillance and coordination as well as passive surveillance using ADS-B messages received from other ACAS/TCAS-equipped aircraft.
In the configuration shown in
In order for the antenna array to correctly determine bearing, the relative electrical phase of each of the antennas in the array may be calibrated. This phase calibration process may begin by having the relative geometry of the antennas configured in the software at the time of installation, or at any other desired time. The relative geometry can provide a baseline estimate for the calibration data. Following the initialization of the geometry data, a fine electrical calibration may follow with an external signal source transmitting an appropriate signal waveform from various angles around the aircraft. A conventional TCAS ramp tester can be utilized to simulate traffic at very specific angles around the aircraft. This data received from the simulated traffic can then be used to improve the calibration data necessary for the bearing detection. The calibration may also be performed without any relative geometrical information being previously entered.
For continuous maintenance of the calibration data, an additional real time calibration routine can be implemented utilizing the measured bearing from the active surveillance and the calculated bearing from the passive surveillance function (e.g., Automatic Dependent Surveillance-Broadcast (ADS-B)) and updating the calibration data using these sources of known bearing. U.S. Pat. No. 9,024,812 and U.S. Pat. No. 8,798,911 describe methods of using bearing determined from the ADS-B signals to provide a correction to the bearing measured by the directional antenna. However certain embodiments of the present invention use the ADS-B signals to determine the relative phases of the received signals at each antenna for a given bearing to accomplish the calibration process.
Also, or alternatively, the real-time calibration can be used for other purposes, such as to detect a fault in one or more of the antennas in the array, to detect tampering with the array, and/or to detect positional spoofing by the target aircraft.
The antenna array can be interconnected by a high speed data bus 150. The high speed data bus 150 can be Ethernet, optical, serial, Low Voltage Differential Signaling (LVDS) or potentially wireless. The high speed data bus 150 can be physical or logical bus arrangement. Alternatively, each of the remote receivers 110, 120 and 130 may be able to communicate only with the transceiver 140 over the high speed data bus 150, but not with one another. The high speed data bus 150 may be configured to operate securely using encryption.
Various implementations of the above-described systems and methods are possible. For example, an apparatus can include a transceiver configured to transmit and receive avionics signals at a host vehicle. The avionics signals can include signals such as ADS-B signals or other signals that are transmitted between or among aircraft or that are transmitted from aircraft to air traffic controllers. As an additional example, all the smart antennas in the array may include transceivers such that the transmission may be directional or omnidirectional. The host vehicle may be an aircraft, such as a UAS or an Unmanned Aerial Vehicle (UAV).
The apparatus can also include an interface configured to communicate with an array of a plurality of avionics receivers. The avionics receivers can be configured to receive the avionics signals at the host vehicle. The interface can be a network interface configured to operate over a bus, such as an Ethernet bus, optical bus, serial bus, or another data bus.
The apparatus can further include a processor configured to determine a relative bearing of a target vehicle to the host vehicle based on at least one signal characteristic of the received avionics signal as received at the transceiver and at least one signal characteristic of each of the received avionics signals as received at the plurality of avionics receivers. The signal characteristic may be phase, time of arrival, or the like.
The processor can also be configured to calculate a relative bearing from data contained in the received avionics signals. For example, the processor can use global positioning system (GPS) data in the received avionics signals and GPS data regarding the host vehicle, together with bearing information about the host vehicle, to calculate a relative bearing of the target vehicle.
The processor can be further configured to compare the calculated relative bearing to the determined relative bearing and self-calibrate based on the comparison. The calibration can involve determining a difference between the measured value of bearing based on the signal characteristics and the calculated value of bearing based on the GPS data. The processor can then make changes to how the measured value is determined based on the determined difference. For example, the processor can infer a different relative geometry of the array of receivers based on the determined difference. Thus, for example, different phase compensations can be assigned to the received phase values associated with the signals respectively received at the various receivers. Tuning of the phase compensations or other aspects of the calculation can be done until the measured value is within a predetermined threshold of the calculated value. The threshold can be set based on a combination of distance and angular accuracy desired. For example, at 200 nautical miles (nm) the angular threshold may be relatively small, whereas at 2 nm the angular threshold may be relatively larger. Alternatively, a single angular threshold may be used for all ranges or distances from the host vehicle.
The apparatus can also include a clock configured to be in synchronization with clocks of the array of receivers. The determined relative bearing can be based on synchronization between the apparatus clock and the clocks in the receivers within the array.
The apparatus can further include a memory configured with relative geometry of the transceiver and the array of receivers. The processor can be configured to determine the relative bearing based on the relative geometry. The relative geometry can be stored in software or firmware. The memory can be non-transitory memory. The memory can be a flash memory, a hard disc drive, or any other read only memory (ROM) or random access memory (RAM). The memory can be on a same chip as the processor or may be separate from the processor. The processor can be an application specific integrated circuit (ASIC), a single core or multi-core central processing unit (CPU), or any other processing device implemented as desired.
An apparatus, according to certain embodiments of the present invention can include a receiver configured to receive avionics signals at a host vehicle. The apparatus can also include a processor configured to digitize the received avionics signals. Associated hardware can include hardware that downconverts a received radio frequency (RF) signal to a baseband frequency. The hardware can also include an analog to digital converter configured to convert the analog baseband signal into a corresponding digital signal. The processor can be configured to perform additional processing, such as extracting data from the signal. Extracted data can include phase information.
The apparatus can include an interface configured to communicate data with an associated transceiver of the host vehicle. The associated transceiver can be configured to process digitized signals received from an array of a plurality of avionics receivers at the host vehicle. The interface can be configured to communicate the digitized baseband signal, a modified form of the digitized baseband signal, such as a sampled or gated representation of the digitized baseband signal, or data based on the digitized baseband signal. The gated representation may be sent, for example, only when a sufficiently strong RF signal is detected. The data based on the digitized baseband signal may include the data contained in the signal as well as metadata about the signal, such as time of arrival of the signal.
The apparatus can also include a clock synchronized to a clock of the transceiver. The data communicated over the interface can include metadata such as respective clock values associated with the received avionics signals.
The receiver, the processor, and the interface can be housed in a case of a corresponding antenna. For example, a single unitary box can house all these components, with a port for external communication, such as digital communication.
A system can include both of the above-described apparatuses in combination. Furthermore, the system can include a bus. The bus can be configured to permit communication between the apparatuses. For example, the bus can be configured to data communication in digital form from each of the receivers to the transceiver.
The method can also include, at 320, installing, at a plurality of locations of the host vehicle, a plurality of devices each comprising a receiver configured to receive avionics signals at the host vehicle, a processor configured to digitize the received avionics signals, and an interface configured to communicate data with the transceiver. The transceiver can include an interface configured to communicate with the devices. The plurality of locations are selectable without regard to the first location. For example, the locations may be selected at the whim or convenience of the installer, or for aerodynamic or balance reasons.
The transceiver and plurality of devices can form an antenna array system configured to self-calibrate. The self-calibration can occur as described above, for example with reference to
The method can also include, at 330, rearranging the plurality of devices after an initial installation. The antenna array system can be configured to self-calibrate without explicit indication of the rearrangement. For example, the above-described self-calibration techniques can be used to take into account any arbitrary geometry amongst the plurality of devices.
Certain embodiments of the present invention may have various benefits and/or advantages. For example, certain embodiments of the present invention can involve much smaller packaging than a conventional directional antenna. Moreover, certain embodiments of the present invention can provide additional flexibility over current architectures.
One having ordinary skill in the art will readily understand that the invention as discussed above may be practiced with steps in a different order, and/or with hardware elements in configurations which are different than those which are disclosed. Therefore, although the invention has been described based upon these preferred embodiments, it would be apparent to those of skill in the art that certain modifications, variations, and alternative constructions would be apparent, while remaining within the spirit and scope of the invention.
This application is related to and claims the benefit and priority of U.S. Provisional Patent Application No. 62/233,868, which was filed Sep. 28, 2015, titled “SYSTEMS AND METHODS FOR PROVIDING A DISTRIBUTED AIRBORNE COLLISION AVOIDANCE SYSTEM ANTENNA ARRAY,” which is hereby incorporated herein by reference in its entirety.
| Number | Date | Country | |
|---|---|---|---|
| 62233868 | Sep 2015 | US |
