DIFFERENTIAL GPS LANDING ASSISTANCE SYSTEM
BACKGROUND OF THE INVENTTON This invention pertains to a landing assistance system for aircraft. More particularly, the present invention is related to landing assistance systems which assist control of an aircraft, either manually or by autopilot, for piloting an aircraft along a predetermined glide path associated with a particular landing strip or runway. The invention is particularly directed to an aircraft landing system wherein the precise position of the aircraft and its deviation from a prescribed glide path is determined in a relatively simple yet highly accurate manner.
Today's commercial aircraft commonly incorporate MLS (Microwave Landing System) or ILS (Instrument Landing System). These landing assistance systems are particularly important during those aircraft landings under adverse visibility conditions. Such systems, therefore, assist the pilot in enhancing safe landings. In ILS and MLS type landing assistance systems, associated with each landing strip is the employment of electromagnetic wave generating equipment for radiating a plurality of electromagnetic wave beams having electromagnetic characteristics which define a glide path for a specific landing strip. The aircraft includes appropriate signal receiving equipment depending upon the system employed for deteπnining the position of the aircraft relative to the glide path as defined by the electromagnetic wave generating equipment. In turn, onboard aircraft signal processing equipment may be utilized to provide data to the human pilot through landing indicating equipment, or else be given to an automatic pilot control system, referred to as an autopilot. Another type of landing assistance system using satellite positioning data is shown and described in U.S. Patent 4,894,655, issued to J.C. Jognet et al. The landing assistance system described therein incorporates a differential GPS satellite positioning system well established and known in the prior art which incorporates a fixed ground station having a known reference position. The fixed ground station is located in the vicinity of a landing strip. The fixed ground station contains a receiver for receiving satellite signal data from a plurality of satellites from which pseudo range data and pseudo range rate data, herein referred to as satellite data, are derived therefrom. From the satellite range data, a measured or estimated global position of the ground station receiver may be determined. In differential GPS systems, the ground station further includes a computing device for comparing the theoretical range between the known reference global position of the ground station and the position of the satellites to derive correction data representative of the error, if any, in the pseudo range and pseudo range rate data. In turn, other remote GPS stations can
correct their calculated position by correcting the satellite data with use of the correction data to determine a "corrected" global position of the remote GPS station. The fixed ground station also includes a data link signal transmitter, e.g., an RF transmitter, for transmitting on a MLS radio channel GPS correction data, landing strip data associated with the landing strip including the magnetic alignment, the coordinates of the desired approach end of the landing strip, and the identity of the landing strip. Further, as part of the landing assistance system, the aircraft incorporates an onboard receiver for determining its calculated position based on substantially the same GPS-like data. Secondly, the onboard equipment also includes a receiver for receiving the correction data and the aforementioned landing strip data. In turn, a conventional onboard computer determines the landing guidance data which may be given to the human pilot by landing indicating equipment, or utilized as inputs to an autopilot.
A disadvantage of the aforementioned GPS aided landing system is the inherent ambiguity in the magnetic alignment heading of the runway as well as a clear definition of glide path.
BRIEF DESCRIPTION OF THE INVENTION An object of the present invention is to obviate any ambiguity of landing zone data transmitted to an aircraft incorporating GPS assisted landing approach equipment.
In the present invention, a ground station is located in the vicinity of the landing strip and has a known reference global position. The ground station includes a global positioning system forming in part a differential global positioning system well known in the art. The ground station includes a receiver for deteπnining a calculated global position of the ground station as a function of the satellite range data measurements derived from the data received from selected ones of the GPS system satellites. The ground station further includes a computer or the like for determining real time correction data characteristic of any errors in the range data measurements which cause any deviation between the reference global position and the calculated global position of the ground station. Further, the ground station includes a data link apparatus such as a radio signal transmitter for transmitting the correction data and also the global position of at least first and second points which define a selected glide path intended to be followed by aircraft for the particular landing strip. The landing system in accordance with the present invention further includes a station onboard the aircraft. The onboard equipment includes (i) a first receiver for receiving satellite signals for determining satellite range data derived from the satellite signals, and (ii) a second receiver employed for receiving data from the data link
apparatus so as to receive the correction data and the actual global position of the first and second points which define the glide path associated with a particular landing strip. Lastly, the onboard station includes a computing means for processing the correction data and the global position of the first and second points, and the satellite range data for (i) deriving a corrected global position of the aircraft as a function of the correction data and the aircraft satellite range data, and (ii) deriving the lateral deviation and vertical deviation of the corrected global position of the aircraft from the selected glide path as a function of the actual global position of the first and second points and the corrected global position of the aircraft.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective illustration of one embodiment of the inventive system of the present invention depicting the geometric relationship in a three dimensional coordinate system of the component parts thereof with respect to the airport landing strip and an approaching aircraft.
Figure 2 is block diagram of one embodiment of the present invention. Figure 3 is data packet diagram illustrating the information transmitted and received through a data link in accordance with the present invention.
Figure 4 is a system block diagram of the present invention with landing indicating equipment, or alternately an autopilot.
Figure 5 is a system block diagram of the present invention with a flight management system and autopilot.
Figure 6 is a block diagram of another embodiment of the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Global positioning systems incorporating the use of satellites are now well known in the art. Such systems, for example NAVSTAR-GPS (Global Positioning System), are rapidly being utilized for a determination of the position of mobile units, for example, among others, land vehicles, aircraft, and survey equipment. Common to these global positioning systems is the use of a receiver on a mobile unit for receiving particular data transmitted from a plurality of satellites from which the satellite range data, i.e., the pseudo range and pseudo range rate data, may be determined with respect to each of a plurality of satellites. Further, from the satellite range data and known position of the satellites at the time of transmission of the data, the position of the mobile unit in the World Geodetic System Coordinates may be determined. Herein, it should be recognized by those skilled in the art that the World Geodetic System is an Earth-centered, Earth-fixed coordinate system, which can be converted to any other coordinate system the user requires. Sometimes, the
aforementioned coordinate system is referred to as the WGS84 earth centered, earth fixed, rectangular coordinate frame. Herein , the World Geodetic System coordinates should be presumed.
Referring now to Figure 1, a first preferred embodiment of the subject inventive system is disclosed which will serve to illustrate the basic technique common to all forms of the invention. Further, in the exposition which follows, all coordinates of the points referred to are assumed to be in the World Geodetic System as are generally available in GPS systems of the variety generally described above.
Referring now to the Drawing of Figure 1, it is desired that an aircraft landing on a particular landing strip follow a selected glide path as defined by the line segment between points B and D. Point D is herein referred to as the runway threshold crossing point and lies in a plane M which is perpendicular to a vector passing through the Earth Center and the runway threshold crossing point D. Point A is defined as the present position of the aircraft. Points B' and A' correspond to the projection of points A and B normal to the plane M. In the exposition which follows, all projection are those normal to plane M, or alternatively projections normal to a line segment or vector.
Terms used commonly used with ILS and MLS landing assistance systems are vertical and lateral deviation, the latter sometimes referred to as cross-track error. These terms are all related to the "center" electromagnetic beam which defines the glide path in a manner as aforesaid. In the present exposition, lateral deviation is defined as the lateral distance from the desired ground track, where the desired ground track is defined as the projection of the glide path BD normal to the plane M and is shown as line segment B'D. In Figure 1, the lateral deviation, "LD", is illustrated as line segment A'C , the normal drawn from point A1 to line segment
B'D, i.e., the desired ground track. Point C corresponds to the projection of point C on line segment BD, where line segment CC is normal to the plane M. Lastly, vertical deviation, "VD", is the difference between the altitude of the aircraft at point A and the altitude at point C as already defined. As is well known to those skilled in the art, knowing quantities of lateral deviation and vertical deviation from the desired glide path is sufficient information for deriving signals appropriate for either landing signal indication equipment or autopilot.
Illustrated in Figure 2 is a landing system in accordance with the present invention. Thereshown are a plurality of satellites 22, 24, 26 and 28 which each transmit signals containing data for determining satellite range data between a remote receiver and each one of the plurality of satellites. Ground station 30 includes a GPS receiver 32, a computing device 34 and data link transmitter 36. GPS receiver 32
82
may be any of a variety of GPS receivers well known in the art for selectively receiving a plurality of satellite signals for subsequent determination of a calculated global position of the ground station as a function of the satellite range data, i.e,, th pseudo range and pseudo range rate data derived from signals from selected ones of the satellites in a well known manner. GPS receiver 32 includes an output 33 presented to computing device 34 for providing data representative of the satellite range data derived from the satellite signals as measured from the ground station, an is designated in Figure 2 as "R(}(s)". In turn, computing device 34 receives the satellite range data for deteπnining, if so desired, the coordinates of the ground station, identified as G (x, y, z) which represents particular coordinates Gx, Gy and
Gz-
Computing device 34 further receives input data representative of the actual coordinates of the ground station, namely G'x, G'y and G'z. At a particular instant, computing device 34 processes the satellite range data on signal line 33 with the known ground station coordinates for deriving satellite correction data designated
"C(s)", and provides a data output indicative thereof on signal line 35. Here C(s) is the usual satellite correction data associated with differential GPS systems known in the art, and generally represents those satellite positioning systems errors contained the satellite range data. Such errors include, among others, errors caused by the satellite clocks, the satellite's position, and ionospheric and atmospheric delays. As well understood in the art, a second satellite signal receiver in the vicinity of the ground station may correct it's range and range rate data utilizing the satellite correction data in order to calculate a more accurate calculated global position of the second satellite signal receiver. The data link transmitter 36 serves to transmit the correction data to any mobile unit which includes a receiver means for establishing the data link between t ground station and the mobile unit. The data link transmitter may be any of a variet of radio transmitters, or the like, for establishing the data link between the ground station and the mobile unit. In the present invention, the mobile unit is an aircraft indicated in Figure 2 b the dashed block 40 which includes a GPS receiver 42 and a data link receiver 44. GPS receiver 42, similar to receiver 32, provides an output on signal line 43 representative of the satellite range data derived from the satellite signals as measure from the aircraft position, and is designated in Figure 2 as
Data link receiver 44 receives as data from data link transmitter 36, the transmitted data including the correction data C(s) and other such data associated wi differential GPS systems. Data link receiver 44 presents this on the aircraft on sign line 45b, which in turn is presented as an input to computing device 46. Computing
device 46 includes computing section 46a which is intended to compute a corrected global position of the air craft A (x, y, z) as a function of the satellite range data and the correction data C(s) in accordance with well known procedures for differential GPS positioning systems. As figuratively illustrated in Figure 2, computing device 46 generates an output representative of the corrected global position of the aircraft designated A (x, y, z), and the computing device 46 makes use of such information as indicated by the arrow 47a.
It should be recognized by those skilled in the art that GPS receiver 42 and GPS receiver 32 are substantially the same and may be commonly purchased from the TRIMBLE firm and many other firms as known to those skilled in the art. Further, the description of the block diagram illustrated in Figure 2 refers to separate computing sections, signal lines, and specific blocks, etc. However, as is known to those skilled in the art, there are a variety of known analog and digital implementations, including microprocessor based systems, for transferring and processing data in accordance with the present invention.
It also should be recognized by those skilled in die art that the preceding exposition has generally described a differential GPS system wherein the ground station transmits correction data C(s) in the form of satellite range and range rate data errors, and the aircraft corrects the GPS receiver range and range rate data before the aircraft position is first calculated. However, it should be understood that other differential GPS schemes beyond that shown herein are within the scope of the present invention. Therefore, the differential GPS system of Figure 2 has only been illustrated in a manner to facilitate an understanding of the present invention, and therefore is only exemplary in nature. In accordance wid the present invention, ground station 30 is intended to be located in the vicinity of the landing strip in order to enhance the differential GPS solution for the aircraft's position A (x, y, z). Also, herein the correction data has been derived by the computing device 34 at the ground station and subsequently transmitted by the data link transmitter 36. As is well understood in the art, the actual correction data could be computed in computing device 46 by data transmission of the calculated global position of the ground station and the known position of the ground station G' (x, y, z), as well as other identifying data so as to optimize the corrected global position of the aircraft, specifically that designated by A (x, y, z). All such schemes are intended to be within the spirit and scope of the present invention.
As indicated earlier, associated with the landing strip is a selected desired glide path for aircraft approaches, as already depicted in Figure 1. This includes the orientation of the ground track (i.e., line segment B'D) relative to World Geodetic
System, the glide slope angle (the angle between line segments B'D and glide path line segment BD), and, of course, the glide path itself including the runway threshold crossing point D and point B, where points B and D define the desired glide path. All of this information may be supplied to the aircraft through the data link transmitter 36 by transmitting only the desired flight path coordinates B (x, y, z) and the runway threshold crossing point D (x, y, z). In the preferred embodiment, the runway threshold crossing point is generally a point in space having an altitude of approximately 50 feet from the Earth's surface and the glide slope angle is typically 3°. However, in the present invention, any of these parameters may be changed at any time by simply designating the geodesic coordinates B (x, y, z) and the runway threshold crossing point D (x, y, z).
Again referring now to Figure 2, data link receiver 44 includes data output means 45b for presenting data inputs B (x, y, z) and D (x, y, z) to computing device 46. Computing device 46 serves multifunctions by appropriately executing a set of instructions in a manner well known in the art. For illustrative purposes, computing device 46 includes "sections" for executing certain tasks, and generally refers to portions of a computer program. Computing device 46 includes means for processing the correction data, C(s), the actual global position of the points B and D, and the calculated global position of the aircraft for (i) deriving a corrected global position of the aircraft A (x, y, z) as a function of the correction data, namely C(s) and the satellite range data RA(S), and (ii) derives the lateral deviation, "LD", and the vertical deviation, "VD", between the corrected global position of the aircraft and the selected glide path (BD) as a function of the actual global position of points B and D, and the corrected global position of the aircraft A (x, y, z) in a manner as will now be described.
First, the global position correction section 46a of computing device 46 calculates the corrected global position of the aircraft A (x, y, z). The determination of the corrected global position A (x, y, z) is done in a manner well known in the art in differential GPS, and will not be described herein.
The landing guidance section 46b for calculating the lateral and vertical deviation will now be mathematically described with reference to Figure 1. It should be assumed in the following exposition that computer means 46 includes the necessary software and hardware in order to instrument the mathematical expressions which follow.
The first step executed by computing device 46 is the quantification of the unit normal vector N, passing through the center of the earth "O", and normal to the landing strip surface, plane M, at the selected altitude of the runway threshold
crossing point D. The unit vector N is a vector which is collinear with a vector OD where O is the center of the Earth having coordinates (0, 0, 0) and the runway crossing point D having coordinates (Dx, Dy, Dz). Accordingly, the unit normal vector is:
(D-O)
(1) N Nxx + Nyy + Nzz
I D-O I
(Dx-0)x + (Dy-0)y + (Dz-0)z [ (Dx-0)2 + (Dy-0)2 + (Dz-0)2 ] 4
The altitude difference between the selected altitude of the runway crossing point D (i.e., plane M) and the aircraft's present position A(x, y, z) is illustrated as the length of line segment dl. Distance dl is die length of line segment A '-A which is a line normal to the plane M. The position of the aircraft relative to the runway threshold crossing point D is identified as vector VI. From vector algebra:
(2) VI = A-D
= (Ax-Dx)x + (Ay-Dy)y + (Az-Dz)z
It follows that the distance dl is: (3) dl = I VI dot N I
= | (V1XNX + VlyNy + V1ZNZ) |
In order to calculate the lateral deviation, "LD", of the aircraft relative to the ground track B'-D, vectors describing the projection normal to plane M of the glide path vector V2, namely vector V4, and the aircraft position vector VI, namely vector V3, are first determined. Vector V3 is a vector from point D to point A' , which is the same as the projection of vector VI into plane M. Accordingly:
(4) V3 = Vl-A'A = Vl-dlN
= [ Vlx-(dlNx) ] x + [ Vly-(dlNy) ] y + [ Vlz-(dlNz) ] z
Next, the ground track vector V4 is determined. This is accomplished by first calculating the distance d2 which is the distance between points B and B' , where B' is in the plane M. Distance d2 is the altitude of the glide patii identification point B above the runway threshold crossing point D. From vector analysis, it follows:
(5) d2 = |V2 dot N |
= | (V2XNX + V2yNy + V2ZNZ) |
where vector V2 is the glide path vector from point D, having coordinates Dx, Dy, Dz, to point B, having coordinates Bx, By, Bz, and N is the unit vector defined above. That is: (V2 = B - D)
It should be noted here that vector V2 is a selected glide path for a particular landing strip or runway, and is, of course, known. Further, vector V2 is defined by the known selected point coordinates "B" and "D" chosen for the particular runway.
Next, the ground track vector V4, is a vector from point D to point B' where point B' has coordinates (B'x, B'y, B'z). Since V4 is the projection of vector V2 into plane M, from vector analysis it follows:
(6) V4 = V2-d2N
= (V2x-d2Nx)x + (V2y-d2Ny)y + (V2z-d2Nz)z
The lateral deviation, "LD", may now be determined as a function of the cross product of vectors V3 onto vector V4 as follows:
(V3xV4) dot N
(7) lateral deviation = LD =
IV4I where N is defined in equation (1) and where:
(8) V3xV4 = (V3yV4z-V4yV3z)x + (V3xV4z-V4xV3z) +
(V3xV4y-V4xV3y)z
and
(9) |V4 | = (V4χ2 + V4y2 + V4z2)! 2
The sign of the lateral deviation comes directly from the sign of the result of equation (7). That is, if the sign is positive, the lateral deviation is in the same direction as illustrated in Figure 1 , and an opposite sign indicates that the lateral deviation is a lateral deviation relative to the desired glide path opposite than that as illustrated.
The distance of the aircraft from the runway threshold crossing point D along the desired ground track is indicated by die distance d3, die length of the line segment between points D and C . Distance d3 may be determined as follows:
| V3 dot V4 |
(10) d3 = —
IV4 I
(V3XV4X + V3yV4y + V3ZV4Z)
Distance d4, die distance between points C and C, defines the desired altitude of die aircraft along the desired glide path BD. The distance d4 may be determined by a simple ratio of similar triangles as follows: d2 d4
(11)
IV4 I d3
from (11) it follows:
(d2) (d3) (12) d4 = |V4 |
Accordingly, the vertical deviation as previously defined may now be determined. That is, die vertical deviation, "VD", is d e difference between the distance dl , which is a function of the present position of the aircraft, and die distance d4 which is the desired position of the aircraft on glide padi BD, thus:
(13) Vertical Deviation = dl-d4
In the previous discussion, it has been shown that two points B and D define a glide pa i relative to the runway threshold crossing point D. In turn, knowledge of the actual global position coordinates of these two points, namely D(x, y, z) and B(x, y, z), and knowledge of the position of the aircraft defined by d e coordinates A(x, y, z) is the only information required by die onboard computer 46 for calculating die lateral deviation, "LD", and vertical deviation, "VD", relative to the selected glide padi defined by points B and D.
In turn, data representative of LD and VD may be subsequently processed by control signal processing section 46c of computer device 40 for generating autopilot data 50 for autopilot 60 as will now be further described.
As is well understood in die prior art, existing ILS systems provide steering signals to the autopilot in signal quantity units called Difference in Depth of Modulation (DDMs). More specifically, on-board ILS systems components provide steering signals referred to as lateral deviation DDM and vertical deviation DDM. As is well known, these steering signals are derived from die electromagnetic signal intensities of different frequencies radiated by transmitters in the vicinity of the landing strip. The vertical and the lateral deviation DDMs are essentially proportional to the actual lateral deviation and d e vertical deviation as described witii reference to Figure 1. Accordingly, die lateral deviation and die vertical deviation derived above may be scaled to provide the "look and feel" of a DDM so that such signals can be fed directly into an autopilot in place of standard and customary ILS signals commonly employed in such systems, as well as in MLS systems.
However, in the present invention, the scaled DDM signals can be further characterized by gain control signals as a function of die ground track distance relative to die runway threshold crossing point D, namely distance d3 defined between points C and D, or alternatively the magnitude of vector V3. In this situation, computer 46 can provide information which simulates an ILS beam lateral and vertical difference in deptii of modulation DDM as follows:
LD
(14) DDM (Lateral) = *G(d)
F(d)
where:
LD is die lateral deviation expressed in equation (7),
F(d) = Lateral deviation scale factor which is a function of die distance of die aircraft from die runway tiireshold crossing point, and
G(d) = DDM scale factor which is a function of the distance of die aircraft from the runway threshold crossing point. In a real application of die GPS system this factor may simplify to a constant.
Vert Dev
DDM (Vertical) = *K(d)
J(d)
where:
VD is the vertical deviation expressed in equation (14),
J(d) = Vertical Deviation Scale factor which is a function of die distance of die aircraft from the runway direshold crossing point.
and
K(d) = DDM scale factor which is a function of die distance of the aircraft from the runway direshold crossing point.
Of course, the distance selected may be odier than that determined relative to die runway threshold crossing point, e.g., a point on die ground at die end of d e runway, and is wid n the spirit and scope of die present invention.
Control signal processing section 46c may perform me computation as just described, or otiier control schemes as desired to properly direct autopilot 60.
In accordance widi the present invention, die onboard station, which includes die GPS receiver, the data link receiver and computing device, may determine me glide padi and control signals for subsequent flight control without die use of an extensive data base and witii no flight management system involvement. In me present invention a flight management system may still be used to fly die curved approach to die final straight-in segment, i.e., die glide padi, or an additional point or points from the fixed ground station could be used to construct a curve. In this embodiment, the aircraft implementation may be designed in such a way iat when the ILS or MLS function was engaged in die final approach segment die autopilot would use a localizer and glide slope deviations, i.e., lateral deviation and vertical deviation, supplied by die onboard independent computer 46 dirough the ILS/MLS input to me autopilot. The final flight segment can then be started at an altitude high enough to assure that die flight management system will be disengaged before the aircraft has descended below presently allowable altitudes as is done in today's architecture.
The advantages, among others, in accordance widi the present invention allow for a "drop in" replacement for ILS or MLS systems. It allows for a glide pa i change in the glide slope as transmitted by die ground station by transmission of the global position of points B (x, y, z) and D (x, y, z).
In contrast with present day autopilots which respond to DDMs derived from electromagnetic wave signals, autopilots may be redesigned to permit use of only the
"calculated" lateral deviation (LD), vertical deviation (VD), and distance (d3) from the runway direshold crossing point derived in manner in accordance widi d e present invention, as opposed to me less accurate or reliable differences in depdi modulation signals modified by appropriate controlled gain functions in the usual ILS and MLS systems.
As is apparent to those skilled in d e art, when the ground station transmits the actual global position coordinates of the runway threshold crossing point D, and a second point B, where B and D define the glide padi, diere is no need for any database requiring knowledge of specific glide padis corresponding to specific airport runways. This, of course, reduces the need for additional hardware on die aircraft and reduces die criticality of existing hardware. Therefore, only the hardware of die present invention needs to be FAA certified, whereas d e existing aircraft navigation hardware, e.g. inertial nav and autopilot hardware, does not need to be re-certified. More specifically, since the system does not require any modification to die autopilot or the flight management system in its present form, mere is not a need for recertification of any other hardware odier than die GPS receiver and data link receiver in accordance widi d e present invention.
It should be recognized by diose skilled in me art that a single fixed ground station may provide data of a plurality of runways so diat approaching aircraft may select the appropriate glide pad for a specific runway by a simple channel selection of die data link transmitter/receiver system.
Figure 3 shows one example of a message which may be transmitted by die data link transmitter 36. The message may include healti /integrity data 310, ephemeris data 320, runway coordinates/runway identification data 330 followed by satellite correction data 340, i.e., pseudo range corrections, i.e., C(s). The health/integrity message provides die required information used to confirm the validity of d e satellite signals used by bod die ground station and aircraft position determinations in a manner which is customary. Ephemeris data provides satellite orbital information to the aircraft to ensure diat the ground station and aircraft are operating from the same set of ephemeris data. The pseudo range corrections provide differential correction information used for increasing GPS accuracy in accordance widi known art. The runway coordinates/identification provides die aircraft with runway coordinates, e.g., B(x, y, z) and D(x, y, z), from which to calculate die final approach and flight padi as described widi reference to Figure 1. Further, the runway coordinates/identification information may contain otiier enhancement information such as me runway identifier, runway direshold crossing height in terms of its actual global position, and runway threshold crossing altitude as desired.
Figure 4 is another block diagram similar to Figure 2. In die following Figures, similar functioning component shown in die Figures as those in Figure 2 have retained d e same numeral designation. In Figure 4, thereshown is the scenario wherefore an aircraft is not equipped widi a flight management system or autopilot. In this situation, die pilot may input the ILS receiver frequency in a manual control 430 as an input to die data link receiver 44 for appropriately obtaining the desired coordinates for the glide padi associated widi die runway having die inputted ILS frequency. As before, the computer device 46 calculates die lateral and vertical deviation from the desired glide padi (B-D) and provides diem as input to a landing display altitude director indicator 440 for manual flight aircraft approaches.
Also shown in Figure 4 is an alternate arrangement including an aircraft equipped widi an autopilot 60 but is not equipped widi a flight management system. This system operates in a similar manner except that die determined lateral and vertical deviations from the glide padi are made for control of the autopilot in addition to signals to die flight director.
Shown in Figure 5, similar to Figure 4, is a system in accordance widi die present invention in which the aircraft includes a flight management system 610, including input controller 640, with autopilot 60. This system functions similar to that in Figure 4 except that the corrected global position of die aircraft A (x, y, z) is fed into the flight management system 610, and die flight management system 610 can electronically control or provide die runway selection identifier into die data link receiver for proper runway coordinate point information selection.
Illustrated in Figure 6 is ano ier embodiment of die present invention in which the similar function components as tiiose shown in Figure 2 have retained die same numeral designations. In Figure 6, the data link transmitter further includes inputs from approach curvature data block 700. Block 700 provides actual global position data, P(n), for constructing a flight path approach curvature intended to be flown by an aircraft before descending down die glide padi. In turn, data link receiver 44 provides data on signal line 45c to computing device 46 having a curvature deviation section 46c. Since in the present invention die corrected global position of die aircraft is known, die curvature deviation section may dien compute d e deviations between d e current aircraft position and die known approach curvature points P(n). In turn, curvature deviation signal processing section 48c of computer device 46 may subsequently provide signal inputs to an autopilot 60 or omer navigating or indicating equipment 70.
It should be understood mat tiiere are many types of receivers for differential as well as non-differential positioning by satellite which can be incorporated in die system of die present invention. Further, ere are many types of data link
transmitters and receivers which may be incorporated in die present invention and may have a plurality of channels and/or frequencies which may be utilized, including mose incorporated in ILS and MLS systems.
Furthermore, it should be recognized d at only one ground station has been associated widi one landing strip or runway, however, it is within die scope of die present invention diat die data link transmitter may transmit a variety of distinct data packets corresponding to a plurality of landing strips on eidier the same frequency channel or a plurality of different channels, and is also intended to be widiin the scope of d e present invention. It should be noted diat die vector analysis presented is an exact method for an earth centered sphere. However, it is widiin the scope of the present invention to incorporate other mathematical expressions beyond diat shown herein to arrive at the same intended function as disclosed herein, i.e., lateral and vertical deviation from the desired glide pad . For example, corrections may be required for an "elliptical" earth, or otiier fixed coordinate system for global positioning reference system.
Lastly, although it has been shown diat only two points need be communicated from the ground station to die aircraft to define die glide padi, one being the runway threshold crossing point, o ier information may also be transmitted and is intended to be widiin d e spirit and scope of die present invention, such as provided by various enhancements not shown herein, but useful to tiiose artisans in flight management.