BACKGROUND OF THE INVENTION
Traffic Collision Avoidance Systems (TCAS) use two antennas, one on the top and one on the bottom of an aircraft, each of which is used to estimate the relative beaing between own aircraft and an intruder. Each traditional TCAS antenna has four elements, which are placed orthogonally on the same plane as shown in FIG. 1. A TCAS system interrogates the transponder on other aircraft. The transponders of other aircraft respond with a reply which may contain altitude or other information. The TCAS uses the reply signal and its multi-element directional antenna to estimate the relative bearing of the other aircraft. In some systems the phase difference of the reply signal received at elements E1 and E3 is proportional to the sine function value of the intruder's bearing angle, and the phase difference between elements E2 and E4 is proportional to cosine function value of the intruder's bearing angle. (Where E1 E3 pair and the E2 E4 pair are orthongonal). The system can estimate the bearing from the signals received on one multi-element antenna. Although this is an adequate setup for determining bearing, it is redundant, costly and comes with a weight penalty because of the two antennas and eight antenna elements needed.
SUMMARY OF THE INVENTION
The present invention provides methods for calculating bearing while reducing the number of TCAS antenna elements. The bearing calculation attempts to optimally combine data from two-element antennas mounted on both top and bottom antennas.
Without shared signal data between the antennae, the traditional method of computing bearing via atan2 can result in ambiguity. In order to address this deficiency, the present invention uses the information in the SinPhase and CosPhase signals to compute the bearing using alternative algorithms.
BRIEF DESCRIPTION OF THE DRAWINGS
Preferred and alternative embodiments of the present invention are described in detail below with reference to the following drawings:
FIG. 1 illustrates a prior art antenna set-up for a vehicle;
FIG. 2-1 is a schematic diagram of an aircraft having a system formed in accordance with an embodiment of the present invention;
FIG. 2-2 illustrates an antenna set-up for the aircraft shown in FIG. 2-1;
FIGS. 3-1 and 3-2 show a flow diagram of an example process performed by the system shown in FIG. 2-1;
FIG. 4 is a geometric diagram illustrating the relationship of elements of the antennas used in the system shown in FIG. 2-1;
FIG. 5 is a graph illustrating optimum processing based on estimated bearing angles of a target vehicle; and
FIG. 6 illustrates a bearing estimate formed in accordance with an alternate method.
DETAILED DESCRIPTION OF ONE EMBODIMENT
FIG. 2-1 illustrates an example aircraft 10 having a Traffic Collision Avoidance System (TCAS) 20 formed in accordance with an embodiment of the present invention. The TCAS 20 includes a first two element antenna 24 located on the top of the aircraft 10, a second two element antenna 26 on the bottom of the aircraft 10 and a TCAS processor 30 that is in signal communication with the antennea 24, 26. The processor 30 performs bearing detection based on signals received from the antennas 24, 26. The bearing value detected is sent to another device for output, such as a display device 32.
As shown in FIG. 2-2, a first axis that links the two elements E1, E3 of the first antenna 24 may be orthogonal to a second axis that links the two elements E2, E4 of the second antenna 26. The vertical axis doesn't necessarily run through aircraft center of gravity.
FIGS. 3-1, 3-2 illustrate a first example process 80 (Switching algorithm) performed by the processor 30 that uses antenna pattern and received signal strength to calculate the bearing angle. First at a block 82, a TCAS broadcast is received at the antennas 24, 26. Next at a block 84, the processor 30 receives signals from the elements of the antennas 24, 26 then measures phase and amplitude of the signal from each element. Then, signal-to-noise ratio (SNR) is estimated from the signal received by each element. Also, signal level, signal phase variance, elevation angle, etc. are estimated from the signal received by each element. However, the SNRs from the top two elements are likely similar and the same for the bottom two antenna elements. So one can make a general assumption that the signal from top two antenna elements have the same SNR, and the signal from the bottom two antenna elements have the same SNR.
At decision block 88, the processor 30 determines if the SNR associated with top antenna is greater than or equal to the SNR associated with bottom antenna. If the condition in decision block 88 is true, then at a block 92, a critical angle, a quadrant difference of the critical angle and a first bearing angle are determined based on the SNRs, phase variance, and/or phase measurements. Then at decision block 94 the processor 30 determines if the first bearing angle is within a first set of bearing ranges based on the quadrant difference of the critical angle. If the first bearing angle is within the first set of bearing ranges, the first bearing angle is outputted to an output device, at block 96. If the first bearing angle is not within the first set of bearing range, a second bearing angle is calculated, at block 100, then outputted, at a block 102.
At a block 104, if at the decision block 88, the top antenna SNR is less than the bottom antenna SNR, the action performed at block 92 is repeated, See block 104. Next at decision block 108, the processor 30 determines if the first bearing angle is within a second set of bearing ranges based on the quadrant difference of the critical angle. If the first bearing angle is within the second set of bearing ranges, the first bearing angle is outputted, at block 96. If the first bearing angle is not within the second set of bearing ranges, a third bearing angle is calculated based on the SNRs and phase measurements, at a block 110. At a block 112, the third bearing angle is outputted.
FIG. 4 illustrates an example antenna configuration 120 (top down view), where R denotes the electrical phase distance from each antenna element to a center, β is the bearing angle of an intruder vehicle. E1 and E3 are located in the top antenna 24 and E2 and E4 are in the bottom antenna 26. The SinPhase coming out of the top antenna 24 is:
The CosPhase coming out of the bottom antenna 26 is:
where α is the elevation angle of the target vehicle relative to the antenna plane.
The Cramer-Rao lower bound for estimation variances of SinPhase and CosPhase are Vars and Varc, respectively.
Notation
represents the Signal-to-Noise Ratio (SNR) of SinPhase, notation
represents the SNR of CosPhase, and L is the number of pulses which are used in the phase estimation. For illustration purpose, SINPHASE is from top antenna and COSPHASE is from bottom antenna.
The noisy normalized SinPhase and CosPhase outputs are
y=sin β ns (5)
x=cos β nc (6)
The estimation variances of y and x are σy2 and σx2, respectively
In order to calculate β, three possible example estimators are listed below.
The definitions of a tan 2(y,x), a sin (y) and a cos (x) are as follows.
The Maximum Likelihood Estimate (MLE) of β is the value {circumflex over (β)} which maximizes:
or, taking the derivative with respect to {circumflex over (β)},
Note: {circumflex over (β)} depends only on
y, x, and σy/σx=10−(RPLy−RPLx)/20
RPL is reply or signal level in dB.
Solutions for a particular value of (y, x) are shown below for various values σy/σx (which is exhibited as the aspect ratio of the ellipses 150, FIG. 6). A bearing estimate is represented by the angle of a line 152, and is determined by the point of tangency of the ellipse with the unit circle 154. For limiting cases of interest, the estimate goes to previously discussed closed form solutions, as highlighted in FIG. 6. Also, as (y, x) approaches the unit circle 154, all solutions become identical
(lim√{square root over (y2+x2)}→1{circumflex over (β)}={circumflex over (β)}1={circumflex over (β)}2={circumflex over (β)}3), independent of σy/σx.
While one embodiment of the invention has been illustrated and described, as noted above, many changes can be made without departing from the spirit and scope of the invention. Accordingly, the scope of the invention is not limited by the disclosure of one embodiment. Instead, the invention should be determined entirely by reference to the claims that follow.