A new system’s geo-referencing from space is entirely free from any GNSS (GPS or equivalent) systems. The system addresses to various strategic and economic applications such as in remote clock synchronism, aircraft and balloon navigation, missile and smart bombs tracking, satellite orbital determination and remote target geo-positioning. The new geometry concept corresponds to an “inverted GPS” configuration, utilizing four ground-based reference stations, synchronized in time, installed at well known geodesic coordinates and a repeater in space, carried by an aircraft, balloon, satellite, etc. Signal transmitted by one of the reference bases is retransmitted by the transponder, received back by the four bases, producing four ranging measurements which are corrected for the time delays undergone in every retransmission. A minimization function was derived to compare the repeater’s positions referred to at least two groups of three reference bases, to correct for the signal transit time at the repeater and propagation delays, and consequently to provide the accurate repeater position for each time interaction. Once the repeater’s coordinates are known, the other determinations and applications become straightforward. The system solving algorithm and process performance has been demonstrated by simulations adopting a practical example with the transponder carried by an aircraft moving over bases and a target on the ground. Effects produced by reference clock synchronism uncertainties at the four bases on the measurements are reviewed.
A very well known principle to determine indirectly the distance of a remote object utilizes the echo of a transmitted signal, which propagation speed is known. A remote repeater with three dimensional positions can be geometrically determined in relation to at least three transmitters at known position coordinates. This principle led to the concept of a geo-referencing system [
The cause (a) is generally sufficiently well predicted by models for propagation in various media (ionosphere, troposphere) as well as in space (see for example Refs. [
Causes (b) and (c) can be measured directly, with sufficiently high accuracy, depending on the quality of the instruments that are utilized. The cause (d) however is undetermined since the remote object, carrying the transponder, is inaccessible for direct measurements. There are various long distance wireless transmission options using electromagnetic waves, such as the radio waves. The signals are sent to great distances using retransmission repeating links represented by a transponder or repeater. At the transponders that the signals are received, they may or may not be stored or processed, be amplified, and then retransmitted at a frequency which may be the same, or different from the incoming frequency. The signal transit time at the transponder is affected by several sources. It undergoes changes in its internal signal propagation thermal dependent physical characteristics, which can change with time, changes in internal digital processing time which may be different for distinct coded time messages, when it is the case, or for each sequence of signals used to determine its distance of the repeater.
Other known time changes need to be considered on fast moving transponders carried by satellites for example. Doppler path change caused by frequency shifts in the direction of the repeater [
On the other hand, passive transponders, such as the signal scattered reflection by meteor trails in the upper terrestrial atmosphere in the VHF frequency band [
Therefore for accurate ranging measurements, it becomes essential requirements to know the precise knowledge of the path length changes due to propagation as well as time changes for each coded time signal interaction at the transponder, for applications in time synchronization, navigation and remote positioning.
The new system consists in four reference bases on the ground at known geodesic position coordinates, synchronized among themselves, and a repeater in space. The method to determine delays compares the positions of the repeater referred to at least two distinct sets of three of the four reference bases on the ground [
With a time signals transmitting site located at base A, the other reference bases B, C, D and a target in P, the segments measurements obtained are [
where the parameters to be determined are the coded time signal transit time at the repeater dR and the propagation path delays, DpdAR, DpdBR, DpdCR, DpdDR.
AR, BR, CR, DR and PR are the distances of bases A, B, C, D and of the target P to the repeater R, respectively, expressed as a function of time variations caused by the signal transit at the repeater dR, to be determined, and corrected for the respective propagation path delays DpdAR, DpdBR, DpdCR, DpdDR and DpdPR; DtA, DtB, DtC , DtD and DtP are the time differences effectively measured at bases A, B, C and D, as well as at the target P, respectively, with respect to their clocks; dAt is the time variation due to signal transit in circuits and cables when transmitted from base A, previously measured and known; dAr, dBr, dCr, dDr and dPr are the time variations due to the coded time signal transits on circuits and cables when received at bases A, B, C, D and P, respectively, previously measured and known; and c is the speed in free space of the electromagnetic waves that transport the coded time signal.
Since the repeater’s position in the sky is not known a priori, the time variations dR at the repeater and the path delays can, in practice, be determined simultaneously. As we determine dR, the approximate repeater’s position is determined, and consequently the elevation angles it is seen from each one of the four bases are defined. The propagation path delays for each distances AR, BR, CR and DR are found utilizing the repeater’s elevation angles as seen from the bases applied to a selected propagation model to derive the fully corrected repeater’s position. Therefore the values for path delays DpdAR, DpdBR, DpdCR, and DpdDR are added to the system of Equations (1), which become a function of dR only. The value of DpdPR will be found similarly but afterwards, when the target position is determined.
The coordinates of the repeater platform R in relation to the x, y and x coordinate axis to be found using the known algorithm [
The pair of systems of equations to obtain the repeaters’ coordinates in relation to bases A, B, C and A, B, D (2) allow us to formulate the discrepancy between the repeater’s positions caused by the transit time dR value given by the following expression [
The closest value found for dR for every time signal interaction at the repeater corresponds to the minimum value obtained for f(dR) with varying values of dR. This can be found by a number of well known numerical calculation methods, such as by iterative procedures or by successive approximations, as it will be shown in the simulations later in this paper. The accuracy of dR determinations will be in the limit of the instrumental accuracies utilized for the coordinate’s determination. The same procedure may be repeated simultaneously, using measurements at bases A, C, and D, improving the accuracy by averaging the two independent estimates for dR.
The path delays for each distance AR, BR, CR and DR, caused by propagation in the medium, DpdAR, DpdBR, DpdCR, and DpdDR, are derived at the same time calculations are performed to determine dR, adopting the respective elevation angles the repeater is seen from each one of the four bases, which were determined during calculations. For the path delay derivation, an adequate propagation model must be adopted, depending on the frequency band used for the coded time signals transmissions. At higher SHF and EHF radio bands, for example, the corrections are due to propagation in the lower atmosphere [
where c is the speed of light, tatm the atmosphere zenith delay, and H the object elevation angle with respect to the horizon. At low frequency bands, at VHF and UHF and to a certain extent at L-band, the path delay corrections are mostly caused by propagation in the upper atmosphere, ionosphere and plasmasphere [
Every transmitted coded time signal will be also received at other targets, as the example P given in
where the segments AR and PR are measured by ranging, dAt and dPr are experimentally determined and known, and dR, DpdAR and DpdPR are determined by the method described here. The clock time correction at P, needed for synchronization will be Dtp – Dp, where Dp is the theoretical correct time expected for the clock at position P.
This application can be extended to synchronize clocks at various actuators simultaneously. These may be telecommunications re-transmitters which essential requirement is to operate synchronized to prevent cross-talks and mutual message garbling interferences. The precision of clock corrections can be close to the accuracy attained in the synchronization of reference bases A, B, C and D.
The values of dR and of DpdAR, DpdBR, DpdCR, and DpdDR found with this method are introduced in the system of equations [
The remote target coordinates corrected for time delays at the repeater and due to propagation are readily calculated using the known algorithm [
A new software has been specifically developed [
An updated practical application is shown in
The minimization of the repeater position discrepancy process, i.e., the iterative minimization of function (2) performed by the new software, has been done adopting an initial value for transit time and setting an upper and lower range for its variation. The correct time delay at the repeater is found at the end of the minimization process. To proceed with simulations the bases and target position coordinates were converted into the ECEF (Earth-Centered, Earth-Fixed) coordinates system, using datum WGS84 [
ter of the Earth, the axis Z points to the North, axis X points to Greenwich meridian (where latitude = 0 degrees). The altitude is taken as the distance perpendicular and above the surface of the ellipsoid [
To demonstrate initially the functionality of the algorithm and of the software application we have assumed that the exact coordinates for the bases are previously known, as well as for the target, and for the respective assumed positions for the aircraft carrying the repeater. The time delays due to the signal propagation in the medium were introduced in the following step, assuming a propagation model. The calculations of delays at the repeater, of the repeater’s position, and propagation path delays relative to each base were obtained by simultaneous iterations since these variables are interdependent. To obtain a new position for the repeater the path delay lengths were then added, after the model expressed by equation (3), for the approximate calculated elevation angle the repeater as observed from the reference bases and target at every iteration. The process has been repeated until obtaining the convergence of values. The results obtained with the simulation software assuming known positions and synchronized clocks, demonstrate the full algorithm functionality, exhibiting discrepancies in the repeater’s position and in the target position less than 0.001 mm . This value, of course, is just for the algorithm test demonstration. In practice the discrepancies are larger, depending primarily on reference and target clocks synchronization uncertainties, as it will be shown in the following section.
The results obtained from the above simulations demonstrate the algorithm applicability. For previously assumed known base’s and target coordinates, the clocks of the system perfectly synchronized, the ideal error at the receiving location is practically zero.
The major source of uncertainties in the determinations is related to errors between clocks and/or in delays miscalculations. The two sources can be added together within a certain approximation. To perform simulations of the clocks (and/or delays) uncertainties on the determinations of dR and of path delays we have introduced here a realistic Gaussian distribution of errors generating random values for clock/delay uncertainties at the four reference bases and at the target, within a plausible time interval.
We adopted here clock accuracies consistent with realistic compact simple and compact rubidium clocks available in the marked, exhibiting short term stability (typically one month) of the order of 10−11 s, and long term stability (one year) of few nanoseconds (see for example Refs. [
The resulting system error distributions are shown in
We have presented the functionality, tested the algorithm and simulated the performance of a new independent and GPS-free space’s geo-referencing system. This is a powerful space’s geo-referencing system and method to be used for remote clock synchronization, the navigation of various types of platforms carrying at repeater, and remote target positioning and with very high accuracy.
The system concept may roughly be seen as an “inverted GPS geometry”, using at least four reference bases at known locations on the ground and a remote transponder in space. With this configuration, it is possible to eliminate the most critical errors caused by time delays of signals transiting by the repeater, and others caused by the signal propagation in the medium. Special software has been developed to demonstrate the new system’s functionality and performance. It has demonstrated the accuracy of the analytical algorithm solutions for practical application.
Although the new system is not intended to be regarded as a replacement of the well settled and commercially
successful space geo-referencing based on GNSS, specially GPS (and equivalent systems such as GLONASS, COMPASS, Galileo), it may bring profound impact on a number of commercial and strategic applications, for its competitive simpler implementation; for its independence from complex and expensive permanent geo-ref- erence’s satellite orbital ephemeris updating needed because of irregular earth rotation, such as the regular support from geodetic very long baseline interferometry (VLBI) monitoring. It can also be used as a back-up replacement of existing systems on critical disturbance situations (environmental or operational). It is able to be used independently from any other space-based positioning systems for certain strategic uses such as aircraft and balloon navigation, missile and smart bombs tracking.
In sum, the new system provides means, with certain advantages over existing space based systems, to synchronize accurately remote clock at locations where the coordinates are known. The accuracies might be better than those obtained by the new generation of GPS timing receivers (of tens of ns) [
This system can also be used to determine the coordinates of an unknown remote target. This requires measurements of its distance to the repeater at four distinct instants, provided that the respective repeater’s positions are not part of a straight line. Or alternatively, at the same instant, if four repeaters are simultaneously available on the target’s field of view. This possibility might be particularly relevant as a back-up to other space-based GNSS geo-referencing or for independent applications of strategic interest.
This research was partially supported by Brazil agencies CNPq, CAPES and FAPESP (grant No. 2012/21023-6).