This application generally relates to a satellite navigation receiver having improved ambiguity resolution. In particular, this application relates to a precise point positioning real-time kinematic (PPP-RTK) satellite navigation receiver and associated methods that perform integer ambiguity resolution that is stable, robust, and accurate with fast initialization.
Global navigation satellite systems (GNSS) utilize satellites to enable a receiver to determine position, velocity, and time with very high accuracy and precision using signals transmitted from the satellites. Such GNSS include the Global Positioning System (GPS), GLONASS, and Galileo. The signals transmitted from the satellites include one or more carrier signals at separate known frequencies, such as a first carrier (L1), a second carrier (L2), and an additional third carrier (L5) in the GPS. A code, such as a pseudo-random (PN) noise code modulated with information, may modulate a carrier of the signal, and may be unique to each satellite. Because the satellites have known orbital positions with respect to time, the signals can be used to estimate the relative position between an antenna of a receiver and each satellite, based on the propagation time of one or more signals received from four or more of the satellites. In particular, the receiver can synchronize a local replica of the carrier and code transmitted in a signal to estimate the relative position.
The most accurate GNSS systems are referred to as precise point positioning real-time kinematic (PPP-RTK) or global RTK. The algorithms used in PPP-RTK systems are a combination of the algorithms used in local RTK systems and PPP systems. Both local RTK systems and PPP systems can achieve high accuracy by determining carrier phase related ambiguities. In local RTK systems, a roving receiver receives real-time corrections from a nearby local reference station, such as through a radio link. Because the local reference station has a known precise location, it can help determine the precise location of the roving receiver. In PPP systems, a roving receiver receives corrections that are globally applicable, which eliminates the need for local reference stations. The corrections can include information regarding the position and clock error of satellites, so that the roving receiver can receive information regarding the precise location of the satellites to help determine the precise location of the receiver. PPP systems have a global network of reference stations that are used to develop the global corrections, which are then transmitted to the roving receiver.
PPP-RTK systems involve integer ambiguity resolution at the global network of reference stations and at the roving receiver. PPP-RTK systems are often used in applications such as precision farming, military navigation, and marine offshore positioning, due to its improved navigation accuracy and simplified infrastructure (i.e., eliminating the need for local reference stations). However, current PPP-RTK systems do not typically have real-time integer ambiguity resolution that is simultaneously stable, robust, and accurate, and with fast initialization times.
Accordingly, there is an opportunity for a satellite navigation receiver that addresses these concerns. More particularly, there is an opportunity for a satellite navigation receiver and associated methods that can provide improved integer ambiguity resolution and more accurate positioning information.
The systems and methods described herein may result in a mobile receiver with improved integer ambiguity resolution and more accurate positioning information. The real-time integer ambiguity resolution described herein may be simultaneously stable, robust, and accurate, and have fast initialization times. For example, a modified version of the best integer equivariant (BIE) process may enable the mobile receiver to perform the integer ambiguity resolution more optimally. The modified BIE process described below may compute sums of weights and weighted sums of candidate narrow lane integer ambiguities during a search of the candidate narrow lane integer ambiguities. This may eliminate the need to store a large number of candidates or choose artificial thresholds to control the number of candidates to explore or store. The modified BIE process may also utilize an adaptive weight scaling during the search of the candidate narrow lane integer ambiguities. This may mitigate potential numerical issues attributable to a possible large dynamic range in weight magnitudes of the candidates. The modified BIE process may further utilize dynamic thresholds to control when to terminate the search of the candidates. In this way, only those candidates whose weight is large enough to have a meaningful numerical impact are included.
Other features described herein also enable the mobile receiver to perform the integer ambiguity resolution more optimally. For example, the output of the modified BIE process may also be time-domain smoothed to provide a solution which is smoother in ambiguity space, and therefore also provide a position solution that is smoother in time. As another example, transitions between an ambiguity-determined solution to a float solution, when necessary, may be smoothed in time. As a further example, a weighting scheme may dynamically blend the ambiguity-determined solution and the float solution to leverage the advantages of both solutions, such as faster pull-in, higher accuracy, and more stable and smooth performance. The weighting scheme may utilize particular figures-of-merit and other heuristics to perform the blending.
The description that follows describes, illustrates and exemplifies one or more particular embodiments of the invention in accordance with its principles. This description is not provided to limit the invention to the embodiments described herein, but rather to explain and teach the principles of the invention in such a way to enable one of ordinary skill in the art to understand these principles and, with that understanding, be able to apply them to practice not only the embodiments described herein, but also other embodiments that may come to mind in accordance with these principles. The scope of the invention is intended to cover all such embodiments that may fall within the scope of the appended claims, either literally or under the doctrine of equivalents.
It should be noted that in the description and drawings, like or substantially similar elements may be labeled with the same reference numerals. However, sometimes these elements may be labeled with differing numbers, such as, for example, in cases where such labeling facilitates a more clear description. Additionally, the drawings set forth herein are not necessarily drawn to scale, and in some instances proportions may have been exaggerated to more clearly depict certain features. Such labeling and drawing practices do not necessarily implicate an underlying substantive purpose. As stated above, the specification is intended to be taken as a whole and interpreted in accordance with the principles of the invention as taught herein and understood to one of ordinary skill in the art.
In any of the above referenced drawings of this document, any arrow or line that connects any blocks, components, modules, multiplexers, memory, data storage, accumulators, data processors, electronic components, oscillators, signal generators, or other electronic or software modules may comprise one or more of the following items: a physical path of electrical signals, a physical path of an electromagnetic signal, a logical path for data, one or more data buses, a circuit board trace, a transmission line; a link, call, communication, or data message between software modules, programs, data, or components; or transmission or reception of data messages, software instructions, modules, subroutines or components.
In embodiments, the receiver 11 described herein may comprise a computer-implemented system or method in which one or more data processors process, store, retrieve, and otherwise manipulate data via data buses and one or more data storage devices (e.g., accumulators or memory) as described in this document and the accompanying drawings. As used in this document, “configured to, adapted to, or arranged to” mean that the data processor or receiver 11 is programmed with suitable software instructions, software modules, executable code, data libraries, and/or requisite data to execute any referenced functions, mathematical operations, logical operations, calculations, determinations, processes, methods, algorithms, subroutines, or programs that are associated with one or more blocks set forth in
Precise point positioning (PPP) includes the use of precise satellite orbit and clock corrections provided wirelessly via correction data, rather than through normal satellite broadcast information (ephemeris and clock data) that is encoded on the received satellite signals, to determine a relative position or absolute position of a mobile receiver. PPP may use correction data that is applicable to a wide geographic area. Although the resulting positions can be accurate within a few centimeters using state-of-the-art algorithms, conventional precise point positioning can have a long convergence time of up to tens of minutes to stabilize and determine the float or integer ambiguity values necessary to achieve the purported (e.g., advertised) steady-state accuracy. Hence, such long convergence time is typically a limiting factor in the applicability of PPP.
As shown in
In an embodiment, the receiver front-end module 40 includes a radio frequency (RF) front end 42 coupled to an analog-to-digital converter 46. The receiver front-end module 40 or the RF front end 42 may receive a set of carrier signals from one or more satellite transmitters on satellites. The analog-to-digital converter 46 may convert the set of carrier signals into digital signals, such as digital baseband signals or digital intermediate frequency signals for processing by the electronic data processing system 129.
In an embodiment, the electronic data processing system 129 includes a baseband processing module 48 (e.g., baseband/intermediate frequency processing module) and a navigation positioning estimator 50. For example, the baseband processing module 48 and the navigation positioning estimator 50 may be stored in a data storage device 155.
In an embodiment, the baseband processing module 48 may include a measurement module 161 that includes a carrier phase measurement module 151 and/or a code phase measurement module 153. The carrier phase measurement module 151 may facilitate the measurement of the carrier phase of one or more carrier signals received by the receiver 11. Similarly, the code phase measurement module 153 may facilitate the measurement of the code phase of one or more code signals that modulate the carrier signals received by the receiver 11.
The navigation positioning estimator 50 can use the carrier phase measurements and/or the code phase measurements to estimate the range between the receiver 11 and one or more satellites, or estimate the position (e.g., three dimensional coordinates) of the receiver 11 with respect to one or more satellites (e.g., four or more satellites). The ambiguities refer to the differences in the measurements, such as between-satellite single differences. The code phase measurements or carrier phase measurements can be converted from propagation times, between each satellite and the receiver 11 that is within reception range of the receiver, to distances by dividing the propagation time by the speed of light, for example.
In the electronic data processing system 129, the data storage device 155 may be coupled to a data bus 157. An electronic data processor 159 may communicate with the data storage device 155 and the correction wireless device 44 via the data bus 157. As used herein, the data processor 159 may include one or more of the following: an electronic data processor, a microprocessor, a microcontroller, an application specific integrated circuit (ASIC), digital signal processor (DSP), a programmable logic device, an arithmetic logic unit, or another electronic data processing device. The data storage device 155 may include electronic memory, registers, shift registers, volatile electronic memory, a magnetic storage device, an optical storage device, or any other device for storing data.
In an embodiment, the navigation positioning estimator 50 includes a precise position estimator, such as a precise point position (PPP) estimator or a wide area differential global navigation satellite system (GNSS) position estimator. The navigation positioning estimator 50 may receive correction data from the correction wireless device 44, which is a receiver or transceiver capable of communication with a wireless satellite communications device.
The mobile receiver described herein assumes that two frequencies are available and used for navigation. However, it is contemplated that the described concepts may be extended to cover scenarios with more than two frequencies, and to be usable with any GNSS systems.
The following description uses a notation system where individual terms may be related to a specific frequency, satellite, or receiver. The notation uses subscripts and superscripts to distinguish these elements and uses the location of the subscript or superscript to distinguish the elements, where frequency is designated by a numerical right subscript, receiver is designated by a left subscript, and satellite is designated by a left superscript. For example, the term RkXi refers to a frequency I, a receiver R, and a satellite k. A right superscript retains the usual meaning of an exponent. However, not all subscripts and superscripts may be designated for each term. As such, when an element is not relevant to the context of a particular equation, the subscript and/or superscript may be dropped.
In addition, the following description utilizes parameters and notation, including fi as a frequency in hertz, λi as a wavelength of fi in meters, Pi as a measured pseudorange in meters, Φi as a measured carrier phase in cycles, N as an integer number of ambiguity cycles, as a non-integer (float) number of ambiguity cycles, and c as the speed of light in meters/second. Differences between satellite pairs are represented using ∇ with left superscripts indicate the satellites involved. For example, the term i,j∇x is equal to ix−jx.
Baseband processing at block 301 may be performed by the baseband processing module 48. The baseband processing may measure the pseudorange Pi and carrier phase Φ1 of one or more received satellite signals. The uncorrected pseudorange Pi and carrier phase Φ1 measurements, where the frequency i=1, 2, . . . , may be given as:
where k=1, 2, . . . is the index of the satellite; ρ is the geometric range in meters; B is the pseudorange bias in meters; b is the carrier phase bias in meters; I is the ionospheric error in meters-Hz2; ϵP,i is the pseudorange noise error in meters (including white noise, multipath, and remaining modeling errors); ϵΦ,i is the carrier measurement noise error in meters (including white noise, multipath, and remaining modeling errors); τ is the clock error in meters; Rτ is the receiver clock error and is specific to a given GNSS system; T is the tropospheric delay in meters; δPC is the phase center offset and variation in meters; δT is the error due to tidal forces and polar motion in meters; OR is the relativistic effect on satellite clock in meters; δS is the relativistic effect on signal propagation (the Shapiro delay) in meters; and δPW is the phase windup error in meters.
An alternative to having a receiver clock error Rτ for each GNSS system is to estimate one clock for a designated primary constellation (e.g., GPS) and relative receiver clock offsets between the primary constellation and the other GNSS constellations. The tropospheric delay T is typically divided into a dry component Tdry and a wet component Twet. The dry component Tdry can be accurately modeled using an a priori troposphere model, such as GPT2 (Global Pressure and Temperature). The remaining wet component Twet after removing an a priori wet model can be further estimated by one zenith bias with a mapping function bias and/or two additional horizontal gradient coefficients.
In blocks 302 and 303, the pseudorange Pi and the carrier phase Φi from the baseband processing block 301 may be processed with models and measurement combinations to eliminate and/or reduce a subset of the error terms in equations (1), (2), and (3). For the ranging codes and the navigation message to travel from a satellite 10 to the receiver, they must be modulated onto a carrier frequency. In the case of GPS, two frequencies are utilized: one at 1575.42 MHz (10.23 MHz×154) called L1; and a second at 1227.60 MHz (10.23 MHz×120) called L2. Both L1 and L2 are in the satellite L-band.
The signals transmitted by GLONASS satellites 10 are derived from the fundamental frequencies of 1602 MHz for L1 and 1246 MHz for L2. Each GLONASS satellite 10 transmits on a different frequency using FDMA (frequency division multiple access) and according to a designated frequency channel number. The L1 center frequency for GLONASS is given by:
kf1=1602 MHz+kn×0.5625 MHz, (4)
where kn is the frequency channel number of satellite k, and where kn∈{−7, 6, . . . , 6}. The L2 center frequency for GLONASS is given by:
kf2=1246 MHz+kn×0.4375 MHz. (5)
In PPP systems, a float solution is based on processing ionosphere-free (IF) combinations of both the pseudorange Pi and the carrier phase Φi on the two frequencies, as given by:
where RBIF is the receiver ionosphere-free code bias, which is the ionosphere-free combination of the L1 receiver code bias and the L2 receiver code bias. There is a receiver ionosphere-free code bias per receiver and constellation for all visible CDMA satellites.
For GLONASS satellites, an additional inter-channel code bias may need to be estimated, if the magnitude of the inter-channel code bias is significant. In this case, the ionosphere-free pseudorange measurement is given as:
PIF=D+kBIF+RBIF+RkCGLN+kϵP,IF, (10)
where CGLN is the GLONASS code bias in meters.
In PPP systems, one goal is to have a coherent model for receiver clock and bias terms. The measurement compensation may include compensating the measurements using broadcast satellite ephemeris and clock, compensating the measurements for the deterministic terms (e.g., δPC, δT, δR, δS, and δPW), and compensating the measurements for the PPP corrections for the satellite orbit and clock.
In blocks 302 and 303, it is assumed there is a common receiver clock term for both the pseudorange Pi and the carrier phase Φi. The receiver ionosphere-free code bias RBIF may be considered a nuisance parameter and be naturally absorbed into the receiver clock error Rτ. In addition, the PPP corrections for the satellite clocks inherently account for the satellite pseudorange bias terms kBIF (but not for the receiver-dependent GLONASS channel bias or the system bias between GPS and GLONASS). The receiver carrier phase bias RbIF may not be easily estimated separately in the float solution and is therefore absorbed into each of the resulting float ambiguity terms. The PPP corrections include additional terms for each satellite that enable compensation of each measurement for satellite carrier phase biases kbIF, which are not constant over time.
In block 304, a recursive estimator (e.g., a Kalman filter) may compute a float solution and corresponding zero-difference ionospheric-free float ambiguity values. The float solution may consist of a state vector X and a covariance matrix P for terms such as position, clock bias, tropospheric delay, and floating ambiguity values. The position of the receiver may be updated at each interval (e.g., epoch) using the recursive estimator in block 304, based on the compensated ionosphere-free measurements from block 303. The float solution from block 304 does not itself involve ambiguity resolution.
The float solution may be determined using simplified ionosphere-free measurement equations. For GPS, such equations are given as:
{tilde over (P)}IF=·+τ+M(kE)Twet+kϵ{tilde over (P)}
{tilde over (Φ)}IFλIF=·+τ+M(kE)Twet+kIFλNL+kϵ{tilde over (Φ)}
For GLONASS, such equations are given as:
{tilde over (P)}IF=−·+τ+ΔτGLN+kCGLN+M(kE)Twet−kϵ{tilde over (P)}
{tilde over (Φ)}IFλIF=·+τ+ΔτGLN+M(kE)Twet+kIFλNL+kϵ{tilde over (Φ)}
In equations (11)-(14), is the receiver position, k is the position of satellite k, and is the receiver to satellite line-of-sight vector, where =/∥∥ and −. Also, τ is the receiver clock error (relative to GPS) in meters; Twet is the residual zenith tropospheric wet delay; E is the elevation angle from the receiver to the satellite; M(⋅) is the elevation wet mapping function that maps zenith tropospheric delay to the line-of-sight; kIF is the float ambiguity; λNL is the narrow lane wavelength and is defined as
ΔτGLN is a slowly varying term for the system bias between GPS and GLONASS; kCGLN is the GLONASS ionosphere-free code bias in meters; kϵ{tilde over (P)}
kIFλNL=NIFλIF+RbIF. (15)
The state vector of Kalman filter may consist of the collection of elements: receiver position , , receiver clock error τ, system bias ΔτGLN, ionosphere-free code bias kCGLN, tropospheric delay T, and float ambiguity kIF. The total active states may include three states for the receiver velocity and be given by 6+1+1+NGLN+1+(NGPS+NGLN). There may be a total of 9+NGPS+2NGLN active states in the Kalman filter at any time, where NGPS and NGLN represent the number of GPS and GLONASS satellites in view of the receiver, respectively. The number of states may increase by two if tropospheric gradient terms are included.
The Kalman filter may have time update and measurement update operations, as is known in the art. The process noise added to the states may include a small amount of fully correlated noise (e.g., 0.04 cycles2 per second) because the receiver phase bias RbIF has been absorbed into the zero-difference floating ambiguity states.
The state vector X and the covariance matrix P of the Kalman filter can be referred to as the float solution. The purpose of ambiguity determination as described herein is to result in corrections to the float solution (i.e., ΔX, ΔP). The corrected state vector may be given by X+ΔX with covariance P−ΔP. The corrected state vector may contain an improved estimate of the position, among other things, such as clock bias, tropospheric delay, and floating ambiguity values.
Ambiguity determination may be performed using wide lane and narrow lane measurement combinations, due to the relatively small ionosphere-free wavelength λIF, e.g., approximately 0.6 cm for GPS. The wide lane ambiguities may be determined in block 305 and the narrow lane ambiguities may be determined in block 306. The wide lane wavelength may be given by:
and the narrow lane wavelength may be given by:
Accordingly, the wide lane wavelength may be approximately 86.2 cm for GPS and 84.2 cm for GLONASS, and the narrow lane wavelength may be approximately 10.7 cm for GPS and 10.5 cm for GLONASS.
The wide lane ambiguity NWL is defined as:
NWLN1−N2 (18)
and may be determined first, and the narrow lane ambiguity NNL may be determined based on the wide lane ambiguity NWL. In particular, because:
the narrow lane ambiguity (i.e., any one of N1, N2, or NNL) can be found using one of the following relationships:
Accordingly, once the wide lane ambiguity NWL is determined, equations (20)-(22) may be utilized to find an expression to determine a narrow lane ambiguity. For example, using N2 as the narrow lane ambiguity, N2 can be found by rewriting equation (21) as:
Because the narrow lane wavelengths λNL are much longer than the ionosphere-free wavelengths λIF, ambiguity resolution is more easily performed. It should be noted that equations (20) and (22) could also be rewritten to find N1 or NNL as the narrow lane ambiguity. Without loss of generality, in the description that follows, N2 is used as the narrow lane ambiguity. For simplicity and clarity, the subscript “NL” is used for the narrow lane ambiguity.
Accordingly, at block 305, the between-satellite single-difference wide lane ambiguities NWL may be resolved using the Melbourne-Wubbena combination. The Melbourne-Wubbena combination is a geometry-free, ionospheric-free linear combination of phase and code measurements from a single receiver, and is given as:
and can be written for GPS as:
λWLMW=λWLNWL+kBWL+RBWL+ϵWL, (25)
and written for GLONASS as:
λWLMW=λWLNWL+kBWL+RBWL+kIFBWL+ϵWL, (26)
where kBWL, and RBWL, are the satellite and receiver wide lane biases, respectively, that are a collection of the original biases with various scaling factors. The term kIFBWL represents the inter-frequency bias term that models the effect of GLONASS code channel biases on the wide lane measurement combination. The inter-frequency bias may vary from receiver to receiver, and may also vary in different installations (e.g., due to varying antenna and cabling setups). The magnitude of the inter-frequency bias is typically less than 0.1 cycles per frequency number difference. It can be assumed that the GLONASS code bias-related terms can be accurately modeled by a term that is linear in the GLONASS frequency number. As such, the inter-frequency bias kIFBWL, may be approximately equal to K*kn, where kn∈{−7, 6, . . . , 6} and K is an unknown slowly varying coefficient for a given receiver.
In block 305, undifferenced Melbourne-Wubbena measurements may be used to estimate one wide lane ambiguity state per visible satellite. Typically, the wide lane satellite biases kBWL are broadcast in real-time within correction data and can be used for measurement compensation. The receiver wide lane biases RBWL may be lumped into the float wide lane ambiguity state WL. Accordingly, the float wide lane ambiguity state WL, is no longer an integer. However, the between-satellite single-differences k,m∇WL for GPS are integers and can be resolved in their single-difference form. For GLONASS, it is necessary to remove the inter-frequency bias contribution from the single-difference form in order to recover the integer.
Because the float ambiguity states contain the wide lane ambiguity and the receiver bias, some amount of fully correlated process noise is typically applied in the dynamic update of the Kalman filter. The single differential wide-lane ambiguity and the variance-covariance can be derived based on the undifferenced float ambiguity states and variance-covariance in block 305 after a reference satellite for each constellation is chosen. A standard ambiguity resolution process can be applied for single-difference ambiguities k,m∇WL. Techniques for solving this type of ambiguity resolution are known in the art. Ambiguity resolution validation may also be performed in block 305. After ambiguity resolution validation is performed, a single-difference integer ambiguity constraint can be applied to wide lane float estimator.
Narrow lane ambiguities may be determined based on the wide lane ambiguities determined in block 305 and the ionospheric-free float ambiguity values from block 304. Ultimately, single-difference float narrow lane ambiguities may be computed that are used to fix or determine precise ambiguity values. The updated values may then be used to correct the state vector and covariance matrix of the float solution (i.e., compute ΔX, ΔP) in order to update the position of the receiver.
In block 306, initial estimates of the narrow lane ambiguities may be computed. The steps performed in block 306 are shown in the process 306 of
At step 404, it may be determined whether a condition exists for transitioning to the float solution from block 304 as the narrow lane ambiguity values. The conditions at step 404 may include whether the age of the PPP corrections is above a certain threshold (e.g., three minutes), whether there are not enough satellites available as candidates, and whether a suitable reference satellite is available. If such a condition exists at step 404, then the process 306 continues to step 410 to transition to the float solution.
Transitioning to the float solution at step 410 may be performed to ensure that the transition is relatively smooth and not too rapid. Because the state vector after applying the correction due to ambiguity determination is given by X+ΔX, the difference between the float solution and the solution after ambiguity determination is given by the offset ΔX and using the float solution is equivalent to setting the offset ΔX to zero. Therefore, an offset ΔXt may be utilized to perform the transition, where the offset ΔXt has been stored at a previous interval. Starting at the interval when the transition is begun, the subsequent position change may be limited at each interval by a term related to the offset ΔXt. In particular, the position change may be limited to not vary by more than a magnitude ϵ that is a small predetermined value. The transition may be made over N steps, where N is the rounded-off value of ∥ΔXt∥/ϵ. Accordingly, at step 401, for k=1 . . . N, the float solution can be transitioned to by the end of the transition period, where
Returning to step 404 in
The estimated float narrow lane ambiguities k,m∇NL may be considered as noisy measurements of the integers k,m∇NNL.
Returning to
z=HNN+Hξξ+ηz, (28)
where z is the measurement vector, N is the integer ambiguity vector, ξ is the vector of real-valued parameters, ηz is measurement noise, N∈q, ξ∈p with HN and Hξ being the corresponding design matrices and the noise assumed to be zero-mean normally distributed. The float solution after a least-squares adjustment may be given as:
The BIE solution may be given by:
The steps performed in block 307 are shown in the process 307 of
The weighting at step 506 may be adaptively scaled so that a large dynamic range in weight magnitudes of the candidates is avoided. For a given choice of χ02, scaled weights can be defined as
Presuming that for any χ02∈ the ambiguity determined position solution BIE can be written as:
and therefore as:
The choice of χ02 may be dynamically changed during the search to be the minimum χ02 of all the candidates that have been visited during the search at that point. For each candidate visited during the search, partial sums of the numerator and denominator terms of equation (29) can therefore be accumulated.
In addition, because the sum of weights Σw(z) and the weighted sum τz·w(z) are generated during the search, only the candidates with large enough weights to have a significant numerical impact may be included. For example, if z1 represents the best solution (i.e., where χ12 is a minimum) found so far in a search with w(z1) as its corresponding weight, and zc is an integer vector candidate at a current node of the search with a corresponding weight w(zc), then the candidate zc can be considered not significant when w(zc)<<w(z1). Candidates may be included during the search as long as:
w(zc)≥εw(z1), (40)
where ε is a small threshold, such as 10−6.
This is equivalent to:
During the search, at step 508, determined ambiguity values k,m∇NL,BIE can be formed based on the weighted sums of the candidate narrow lane integer ambiguities and the sum of weights. It can also be determined at step 508 whether there are candidates remaining with weights greater than a predetermined threshold. If there are still candidates remaining at step 508, then the process 307 may return to step 506 to continue the search and repeat step 506 on the next candidate. If there are no candidates remaining at step 508, then the process 307 may continue to step 510 to finalize the search, such as by applying a reverse Z-transform, for example. The determined ambiguity values k,m∇NL,BIE may be utilized to form a constraint that can be applied to the float solution in order to calculate an ambiguity determined position solution (ΔXBIE,ΔPBIE) at step 512.
The steps performed in step 512 are shown in the process 600 of
At step 606, the Kalman gain K may be computed based on the design matrix H and the covariance matrix P of the Kalman filter, as given by:
K=PHT(HPHT)−1. (42)
Correction terms may be formed at steps 608 and 610. In particular, at step 608, a state correction term ΔXBIE=KAN, and at step 610 a covariance correction term ΔPBIE=KHP. The state correction term ΔXBIE and the covariance correction term ΔPBIE may form the ambiguity determined position solution. The state vector can be corrected by adding the state correction term ΔXBIE(i.e., X+ΔXBIE), and the covariance matrix can be corrected by subtracting the covariance correction term ΔPBIE (i.e., P−ΔPBIE).
Returning to
The steps performed at step 702 are shown in the process 702 of
At step 802, unavailable satellites may be removed from being used in the time-domain smoothing. An unavailable satellite may include satellites that the receiver can no longer receive signals from. At step 804, it may be determined whether the reference satellite has changed from a previous interval. If the reference satellite has changed at step 804, then the process 702 continues to step 814 to calculate time-domain smoothed ambiguity values for the new reference satellite and satellites other than the removed unavailable satellites. The old reference satellite may be denoted as m0 and the new reference satellite may be denoted as m1. In addition, the difference in integer ambiguities between the new reference satellite m1 and a given satellite k may be given by:
k,m
At step 814, if the new reference satellite was not used in a previous interval, then the time-domain smoothed ambiguity values for the old reference satellite m0, the new reference satellite m1, and a given satellite k may be calculated by:
kNL,SBIE(t−1)=kNL,SBIE(t−1)−m
kC(t−1)=0 (45)
m
m
m
m
If the new reference satellite m1 was used in a previous interval, then the time-domain smoothed ambiguity values for the old reference satellite m0, the new reference satellite m1, and a given satellite k may be adjusted by:
kNL,SBIE(t−1)=kNL,SBIE(t−1)−m
kC(t−1)=min(kC(t−1),m
m
m
m
Following step 814 or if the reference satellite has not changed at step 804, then the process 702 continues to step 806. At step 806, it may be determined whether new satellites should be used in the time-domain smoothing. New satellites may include the satellites which were not used in utilized in a previous interval. If it is determined that no new satellites should be used at step 806, then the process 702 continues to step 812, as described below. However, if it is determined that new satellites should be used at step 806, then the process 702 continues to step 808. At step 808, time-domain smoothed ambiguity values k,m∇NL,BIE may be calculated for the new satellites k having a reference satellite m (where k≠m), as given by:
kNL,SBIE(t−1)=k,m∇NL,BIE(t) (55)
kC(t−1)=0. (56)
Following step 808, the time-domain smoothed ambiguity values for the new satellites may be adjusted at step 810 by a bias between the estimated float narrow lane ambiguities k,mNL and time-domain smoothed ambiguity values k,m∇NL,BIE from a previous interval. By adjusting with the bias, the initial bias may be minimized between the estimated float narrow lane ambiguities k,mNL and time-domain smoothed ambiguity values k,m∇NL,BIE from the previous interval. This may be calculated by:
kNL,SBIE(t−1)=kNL,SBIE(t−1)+k,m
where
The term kΔNL,BIAS in equation (58) represents the respective undifferenced float ambiguity entries in the state vector increment ΔXSBIE of the ambiguity determined position solution from the prior interval.
At step 812, the time-domain smoothed ambiguity values for all of the satellites may be updated based on the determined ambiguity values k,m∇NL,BIE. Step 812 may be performed following step 810 or if no new satellites were determined to be needed at step 806. In some embodiments, an exponential filter such as a recursive estimator may be utilized but in other embodiments, other techniques for smoothing may be utilized. The update of the time-domain smoothed ambiguity values k,m∇NL,SBIE may be performed according to the following for each satellite k:
Following step 702, an ambiguity determined position solution (ΔXSBIE,ΔPSBIE) may be calculated at step 704 based on the smoothed ambiguity values k,m∇NL,SBIE. Step 704 may include the steps described above with relation to the process 600 of
K=PHT(HPHT+R)−1 (62)
where the covariance matrix R=diag(var(0.7BIE)) is computed as a function of the weights used in the search performed at block 307 of
Returning to
ΔXWSBIE=
ΔPWSBIE=
As can be seen from equations (53) and (54), when
The weighting may be determined based on one or more factors. The factors may include a minimum variance solution, an acceptability factor a that indicates whether the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) is acceptable, a convergence indicator of the float solution, and/or a look-up table that is indexed by ranges of corresponding error variances and corresponding figures of merit of the float solution and the ambiguity determined position solution (ΔXSBIE,ΔPSBIE).
The minimum variance solution factor may minimize an error variance g of a combination of the float solution and the ambiguity determined position solution (ΔXSBIE,ΔPSBIE). The error variances may be three dimensional position variances that are computed as a trace of the corresponding three dimensional position covariance matrix. The error variance of the float solution may be denoted as σFLOAT2 and the error variance of the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) may be denoted as σSBIE2. The minimum variance weighting between the float solution and the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) may be given by:
ΔX=gΔXSBIE, (65)
where
The error variance g will be limited according to 0≤
The acceptability factor a may indicate whether the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) is acceptable and be limited according to 0≤α≤1. The acceptability factor a may be smaller when the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) is unacceptable and may be larger when it is acceptable. The acceptability factor a may be dependent on a quality of the ambiguity determined position solution (ΔXSBIE,ΔPSBIE), such as based on the magnitude of the quadratic form of the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) and the ratio test. The ratio test can be defined as the ratio of the quadratic form of the second best solution to the best solution. When the ratio is large, it can indicate that the best solution is the correct solution.
The quadratic form of the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) may be very large if there are problems with determining ambiguity values. In this case, the acceptability factor a may be 0. However, if the ratio test is large and the quadratic form is small, then the ambiguity determined position solution (ΔXSBIE,ΔPSBIE) may be deemed more reliable and have an acceptability factor a of 1. In between these cases, the acceptability factor a may by found by a smooth function which decreases from 1 to 0 as the ratio decreases and the quadratic form increases.
The convergence indicator factor may indicate whether the float solution has reached a steady state. In this case, the convergence indicator may be greater when the float solution has reached a steady state or is close to a steady state, and conversely may be less in other situations.
In embodiments, the weighting factor
Returning to the process 350 of
At step 906, an estimated position jump in the weighted smoothed ambiguity determined position solution (ΔXWSBIE,ΔPWSBIE) may be calculated. The estimated position jump may be calculated by comparing the change in position since the last interval to the change according to an estimate using the integrated carrier phase that infers positions between the intervals using carrier phase time differences, as is known in the art. At step 908, it may be determined whether the estimated position jump from step 906 is greater than a predetermined threshold. If the estimated position jump is greater than the threshold, then the process 350 may continue to step 912 to transition to the float solution. However, if the estimated position jump is not greater than the threshold, then the process 350 may continue to step 910.
At step 910, the navigation output showing the position of the receiver may be updated at block 312 by adjusting the float solution from block 304 with the weighted smoothed ambiguity determined position solution (ΔXWSBIE,ΔPWSBIE). The state vector can be corrected by adding the state correction term ΔXWSBIE (i.e., X+ΔXWSBIE), and the covariance matrix can be corrected by subtracting the covariance correction term ΔPWSBIE (i.e., P−ΔPWSBIE).
Transitioning to the float solution at step 912 may be performed to ensure that the transition is relatively smooth and not too rapid. At each interval, an offset ΔXWSBIE is typically stored. The offset can be denoted as ΔXt at a subsequent interval when the decision to transition to the float solution is made. Accordingly, at a time t, the transition may be started and ΔXtΔXWSBIE(t−1). Starting at the interval when the transition is begun, the position change may be limited at each interval due to the offset ΔXt. In particular, the position change may be limited to not vary by more than a magnitude ϵ that is a small predetermined value. The transition may be made over N steps, where N is the rounded-off value of ∥ΔXt∥/ϵ. Accordingly, at step 401, for k=1 . . . N, the float solution can be transitioned to by the end of the transition period, where
Any process descriptions or blocks in figures should be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps in the process, and alternate implementations are included within the scope of the embodiments of the invention in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those having ordinary skill in the art.
This disclosure is intended to explain how to fashion and use various embodiments in accordance with the technology rather than to limit the true, intended, and fair scope and spirit thereof. The foregoing description is not intended to be exhaustive or to be limited to the precise forms disclosed. Modifications or variations are possible in light of the above teachings. The embodiment(s) were chosen and described to provide the best illustration of the principle of the described technology and its practical application, and to enable one of ordinary skill in the art to utilize the technology in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the embodiments as determined by the appended claims, as may be amended during the pendency of this application for patent, and all equivalents thereof, when interpreted in accordance with the breadth to which they are fairly, legally and equitably entitled.
This application claims priority from U.S. Provisional Patent Application Ser. No. 62/310,297, which was filed on Mar. 18, 2016, which is incorporated herein by reference.
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Number | Date | Country | |
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20170269229 A1 | Sep 2017 | US |
Number | Date | Country | |
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62310297 | Mar 2016 | US |