The present relates to a method and system for multisource target correlation and, more particularly to a method and system for multisource air/ground traffic control target correlation.
The recent advent of the use of Automatic Dependent Surveillance—Broadcast (ADS-B), an advanced air ground traffic control system, has facilitated the integration of this system with the pre-existing Traffic Information System (TIS).
ADS-B is a technology which allows aircraft to broadcast information such as identification, position, altitude. This broadcast information may be directly received and processed by other aircraft or received and processed by ground systems for use in improved situational awareness, conflict avoidance and airspace management. ADS-B incorporates the use of Global Positioning System (GPS) or other similar navigation systems as a source of position data. By using GPS or the like, ADS-B has the capacity to greatly improve the efficiency and safety of the National Airspace System.
ADS-B provides for an automatic and periodic transmission of flight information from an in-flight aircraft to either other in-flight aircraft or ground systems. The ADS-B transmission will typically comprise information items such as altitude, flight ID, GPS (Global Positioning System) position, velocity, altitude rate, etc. The transmission medium for ADS-B can implement VHF, 1090 MHz (Mode S), UHF (UAT), or a combination of systems.
TIS is a technology in which air traffic control Secondary Surveillance Radar (SSR) on the ground transmits traffic information about nearby aircraft to any suitably equipped aircraft within the SSR range. The transmissions are addressed to a particular aircraft, and are sent together with altitude or identity interrogations. This lets an aircraft receive information about nearby aircraft, which do not have ADS-B capability, but are being interrogated by the SSR radar. The TIS information, like ADS-B information, is directed to a CDTI display for the benefit of the flight crew.
Traffic alert and Collision Avoidance Systems (TCAS) functionality can be improved with the GPS positioning capabilities of the ADS-B system. Such GPS position information will aid TCAS in determining more precise range and bearing at longer ranges. With greater precision, commercial aircraft can achieve higher safety levels and perform enhanced operational flying concepts such as in-trail climbs/descents, reduced vertical separation, and closely sequenced landings.
Additionally, ADS-B can also be used to extend traffic surveillance over greater distances. Previous technology limited surveillance ranges to a maximum of about 40 nautical miles (nm). ADS-B, since it does not require an active TCAS interrogation to determine range and bearing, will not be subject to a power limitation. As a result, in general, the ADS-B receiver capability determines surveillance range. For example, if the ADS-B receiver can process an ADS-B transmission out to 100 nm, then 100 nm is the effective range.
However, for ADS-B to be fully effective it must be implemented on both the aircraft transmitting and receiving ABS-B and all target aircraft within range. If one aircraft has ADS-B and the other does not, neither aircraft can achieve the full benefits of its use. Each aircraft remains “blind” to the other. For full implementation of ADS-B to occur all existing aircraft would require new technologies and equipment, including GPS sensors, some form of ADS-B transceiver, upgraded displays to present ADS-B target aircraft, and some form of data concentrator to collect and process all the appropriate ADS-B data. This would require most of the aircraft flying today to be extensively re-wired and re-equipped with new hardware.
As a result of the problems related to integrating ADS-B into the present fleet of aircraft, ADS-B equipped aircraft, as well as non-ADS-B equipped aircraft, must be capable of receiving positioning information from Traffic Information System (TIS) messages transmitted from ground stations. The ADS-B and TIS position information are processed in-flight, and the position of surrounding targets is displayed graphically on a cockpit display of traffic information (CDTI) unit located in each aircraft.
Because TIS information does not possess the same level of resolution quality as that of ADS-B and because of signal interference, it is possible that the traffic information for the same set of surrounding aircraft reported by TIS and ADS-B do not match. An on-board computer must correlate this conflicting traffic information and display one symbol (e.g., icon) on the CDTI for each actual aircraft. It is known that a suitable TIS/ADS-B correlation algorithm may be constructed based on the MIT Lincoln Lab's report 42PM-DataLink-0013 (hereafter referred to as the MIT Algorithm). The MIT Algorithm comprises essentially three steps:
In step 1, the similarity between each TIS target and each ADS-B target is set as a binary logic function in which the bearing, range, relative altitude and track of each TIS and ADS-B target is compared to evaluate the similarity. Since binary logic rigidly produces the output of either yes (1) or no (0) to each comparison, it may fail to correlate two aircraft if only one single condition of the logic narrowly fails. For example, if one target makes a 45 degree turn according to ADS-B and a 47 degree turn according to TIS then the result is a no (0) in step 1 of the MIT algorithm and the targets are not correlated (i.e., two targets appear on the CDTI). This binary inflexibility significantly reduces the accuracy of the MIT algorithm, especially when targets are performing maneuvers. It is believed by those skilled in the art that the MIT algorithm may only produce a successful correlation rate of about 75 percent.
Therefore, an unresolved need exists for a more accurate and reliable method for correlating TIS and ADS-B target information.
The present invention provides improved correlation between targets from two different target reporting sources, such as TIS and ADS-B, in an air traffic awareness system. A method or system according to the invention compares selected components of a TIS report to the corresponding components of an ADS-B report, produces a confidence level on each component comparison, and combines the confidence levels to determine whether to declare the two targets similar. The individual components of the TIS and ADS-B reports may be range (between “ownship” and a reported target), bearing, track angle, and relative altitude.
In a preferred embodiment, the systems and methods according to the invention use a fuzzy logic (probability model) to produce a continuous confidence level on each component comparison. Generally described, the continuous confidence level of each component is computed based on a comparison between the respective TIS component and a predetermined TIS value(s). The predetermined TIS value is, typically, derived empirically from flight test data. Once the comparison is performed, the continuous confidence level of each component is defined as a function of the ADS-B component. A total confidence level is derived by summing the continuous confidence levels of each component. The total confidence level is then compared to a predefined threshold level to determine whether the TIS and ADS-B targets are similar.
Once a determination is made that targets are similar a correlation array is constructed, a correlation process ensues whereby a selection of nearest TIS target to ADS-B target is performed and CDTI is presented to the pilot in the form of target display.
The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art.
The present invention provides improved systems and methods for correlating TIS target and ADS-B targets in an air/ground traffic control system to minimize or eliminate the display of two icons for the same target on the CDTI of an aircraft. The present invention essentially improves the MIT correlation algorithm by replacing the MIT binary logic method of correlation for evaluating the similarity of received targets with a fuzzy logic probability model.
As shown in
As an initial matter, a brief discussion of the information comprising a TIS broadcast and an ADS-B broadcast is provided. Each TIS message or broadcast that is sent from the ground radar station will typically comprise the following information for each target aircraft:
Each extended ADS-B message or broadcast that is sent from an equipped aircraft will typically comprise the following information fields:
The ownship receives and uses the above ADS-B message data, in addition to its own position and altitude data, to calculate components equivalent to the Bearing, Range, Relative Altitude and Track components of the TIS message.
As discussed above in the Background of the Invention, the currently implemented TIS/ADS-B correlation algorithm is constructed based on MIT Lincoln Lab's report 42PM-DataLink-0013. In a simplified format the three steps in the MIT's algorithm can be defined as follows:
The MIT algorithm implements a combined binary logic function to administer step 1. In doing so the MIT algorithm compares the information fields of bearing, range, relative altitude, and track of each TIS and ADS-B target to evaluate the similarity of each TIS and ADS-B target. As discussed above, the MIT algorithm binary logic function for step 1 reduces the chance of correlating TIS/ADS-B targets, especially when aircraft maneuver.
In accordance with the present invention, a method for correlating between ADS-B and TIS target information is provided. The method comprises comparing selected components of a TIS report to the components of an ADS-B report, typically range, bearing, relative altitude and track angle. Once the comparison is completed then the method produces a confidence level on each component comparison, and combines the confidence levels produced by comparing the components to produce a total confidence level used to determine whether to declare the targets similar.
The present invention replaces the MIT binary logic approach with a fuzzy logic implementation. As is known by those of ordinary skill in the art, fuzzy logic comprises a probability model that produces a continuous confidence level on each comparison. That is, rather than producing a binary output (i.e., “0” or “1”), the output can be any real number. The confidence levels produced on each comparison are combined to make up the final correlation decision. Specifically, the combined confidence levels are compared to an empirically determined threshold to determine if the targets are similar.
In accordance with the present invention, the following exemplary pseudo code demonstrates the fuzzy logic used in evaluating the similarity of individual TIS and ADS-B target and producing a confidence level. For the purpose of the pseudo code TISR, TISB, TIST, and TISA are defined as the range, bearing and, track angle, and relative altitude reported in a TIS report, respectively. Likewise, DR, DB, DT, and DA are defined as the range, bearing, track angle, and relative altitude reported in an ADS-B report.
Thus, as described in the flow diagram of
If the threshold level of confidence has been met then, at step 120, the aircraft are determined to be similar and, proceeding to step 130, they are candidates for further correlation under step 2 of the MIT algorithm (storing the evaluated similarities into a correlation array) and, at step 140, step 3 of the MIT algorithm (correlating the nearest TIS target with the nearest ADS-B target). Once the remaining portion of the MIT algorithm has correlated the targets, then, at step 150, a single icon is displayed on the CDTI to represent one target.
If the threshold level of confidence has not been met then, at step 160, the aircraft are determined to be dissimilar and, step 170 ensues, two icons are displayed on CDTI to represent two separate targets.
In accordance with the present invention, the following pseudo code and corresponding flow diagrams illustrate the check functions that are implemented to evaluate the similarities of range, bearing, track angle, and relative altitude between one TIS and one ADS-B report.
Check Function for Range
An illustrative embodiment of the pseudo code for the check function for range is defined as follows, with TISR being the range for the TIS report and DR being the range for the ADS-B report.
Thus, as described in the flow diagram of
Once the temporary check value has been assigned then, at step 260, an analysis is made to determine if the temporary check value is greater than or equal to a predetermined value, in this instance the predetermined check value is zero. If the step 260 analysis determines that the temporary check value is greater than or equal to the predetermined value then, at step 270, the check range is defined as a first predetermined function, in this embodiment the check range is defined as (I+(the temporary check multiplied by 0.15)). If the step 260 analysis determines that the temporary check value is less than the predetermined check value then, at step 280, the check range is defined as second predetermined function, in this embodiment the check range is defined as (1+(the temporary check multiplied by 1.5)).
Check Function for Bearing
An illustrative embodiment of the pseudo code for the check function for bearing is defined as follows, with TISB being the bearing for the TIS report and DB being the bearing for the ADS-B report.
Thus, as described in the flow diagram of
Once a temporary check function has been defined then, at step 360, an analysis is made to determine if the temporary check function is greater than or equal to a predetermined temporary check function value, in this embodiment this value is zero. If it is determined that the temporary check function is greater than or equal to the predetermined value then, at step 370, the check bearing function is defined by a first check bearing equation, in this embodiment the first check function equation is (1+(temporary check multiplied by 0.1)). If it is determined that the temporary check function is less than the predetermined value then, at step 380, the check bearing function is defined by a second bearing equation, in this embodiment the second check function equation is (1+(temporary check multiplied by 0.08)).
Check Function for Relative Altitude
An illustrative embodiment of the pseudo code for the check function for relative altitude is defined as follows, with TISA being the relative altitude for the TIS report and DA being the relative altitude for the ADS-B report.
Thus, as described in the flow diagram of
Check Function for Track Angle
An illustrative embodiment of the pseudo code for the check function for track angle is defined as follows, with DT being the track angle for the ADS-B report.
Thus, as described in the flow diagram of
It should be noted that the various determinations, functions and equations shown in the pseudo code and accompanying flow charts (
Once all check functions (i.e. continuous confidence levels) for range, bearing, relative altitude and track angle have been derived and a confidence level output has been determined by summing the check functions and comparing the summed total to a predetermined threshold value, then a correlation array is constructed with said outputs. The step of constructing the correlation array corresponds to step 2 of the MIT algorithm. Finally, a correlation process allows for the selection of the nearest TIS target to each ADS-B target that is similar. This step of correlation corresponding to step 3 of the MIT algorithm. The corresponding TIS and ADS-B target(s) can then be presented to the pilot via the CDTI.
Many modifications and other embodiments of the invention will come to mind to one skilled in the art to which this invention pertains having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the invention is not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
The present application is a continuation application of U.S. patent application Ser. No. 10/361,305, filed Feb. 10, 2003, which claims priority from U.S. Pat. No. 6,810,322 which issued Oct. 26, 2004, which claims priority from U.S. Provisional Patent Application Ser. No. 60/217,230, filed on Jul. 10, 2000.
Number | Name | Date | Kind |
---|---|---|---|
3887916 | Goyer | Jun 1975 | A |
4196474 | Buchanan et al. | Apr 1980 | A |
4782450 | Flax | Nov 1988 | A |
4789865 | Litchford | Dec 1988 | A |
4970518 | Cole, Jr. | Nov 1990 | A |
5077673 | Brodegard et al. | Dec 1991 | A |
5157615 | Brodegard et al. | Oct 1992 | A |
5208591 | Ybarra et al. | May 1993 | A |
5285380 | Payton | Feb 1994 | A |
5374932 | Wyschogrod et al. | Dec 1994 | A |
5459469 | Schuchman et al. | Oct 1995 | A |
5477225 | Young et al. | Dec 1995 | A |
5493309 | Bjornholt | Feb 1996 | A |
5519618 | Kastner et al. | May 1996 | A |
5557278 | Piccirillo et al. | Sep 1996 | A |
5596332 | Coles et al. | Jan 1997 | A |
5798726 | Schuchman et al. | Aug 1998 | A |
5883586 | Tran et al. | Mar 1999 | A |
6064335 | Eschenbach | May 2000 | A |
6542810 | Lai | Apr 2003 | B1 |
6810322 | Lai | Oct 2004 | B1 |
Number | Date | Country | |
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20060030994 A1 | Feb 2006 | US |
Number | Date | Country | |
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60217230 | Jul 2000 | US |
Number | Date | Country | |
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Parent | 10361305 | Feb 2003 | US |
Child | 10928039 | US |