Measurement-based perturbation theory and differential equation parameter estimation with applications to satellite gravimetry
•Estimating unknown differential equation parameters has been essential in many areas of science and engineering, which has been best known as the dynamical numerical integration method in geodesy and aerospace engineering. I prove that the method, originating from Gronwall [28] on Ann Math almost 1...
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| description | •Estimating unknown differential equation parameters has been essential in many areas of science and engineering, which has been best known as the dynamical numerical integration method in geodesy and aerospace engineering. I prove that the method, originating from Gronwall [28] on Ann Math almost 100 years ago and currently implemented and used in statistics, chemical engineering and satellite gravimetry and many other areas of science and engineering, is mathematically erroneous and physically not permitted;•I present three different methods to derive local solutions to the Newton’s nonlinear differential equations of motion of satellites, given unknown initial values and unknown force parameters. They are mathematically correct and can be used to estimate unknown differential equation parameters, with applications in gravitational modelling from satellite tracking measurements. These solution methods are generally applicable to any differential equations with unknown parameters;•I develop the measurement-based perturbation theory and construct global uniformly convergent solutions to the Newton’s nonlinear differential equations of motion of satellites, given unknown initial values and unknown force parameters. From the physical point of view, the global uniform convergence of the solutions implies that they are able to exploit the complete/full advantages of unprecedented high accuracy and continuity of satellite orbits of arbitrary length and thus will automatically guarantee theoretically the production of a high-precision high-resolution global standard gravitational models from satellite tracking measurements of any types; and finally,•I develop an alternative method by reformulating the problem of estimating unknown differential equation parameters, or the mixed initial-boundary value problem of satellite gravimetry with unknown initial values and unknown force parameters as a standard condition adjustment model with unknown parameters.
The numerical integration method has been routinely used by major institutions worldwide, for example, NASA Goddard Space Flight Center and German Research Center for Geosciences (GFZ), to produce global gravitational models from satellite tracking measurements of CHAMP and/or GRACE types. Such Earth’s gravitational products have found widest possible multidisciplinary applications in Earth Sciences. The method is essentially implemented by solving the differential equations of the partial derivatives of the orbit |
| doi_str_mv | 10.1016/j.cnsns.2017.11.021 |
| format | Article |
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The numerical integration method has been routinely used by major institutions worldwide, for example, NASA Goddard Space Flight Center and German Research Center for Geosciences (GFZ), to produce global gravitational models from satellite tracking measurements of CHAMP and/or GRACE types. Such Earth’s gravitational products have found widest possible multidisciplinary applications in Earth Sciences. The method is essentially implemented by solving the differential equations of the partial derivatives of the orbit of a satellite with respect to the unknown harmonic coefficients under the conditions of zero initial values. From the mathematical and statistical point of view, satellite gravimetry from satellite tracking is essentially the problem of estimating unknown parameters in the Newton’s nonlinear differential equations from satellite tracking measurements. We prove that zero initial values for the partial derivatives are incorrect mathematically and not permitted physically. The numerical integration method, as currently implemented and used in mathematics and statistics, chemistry and physics, and satellite gravimetry, is groundless, mathematically and physically. Given the Newton’s nonlinear governing differential equations of satellite motion with unknown equation parameters and unknown initial conditions, we develop three methods to derive new local solutions around a nominal reference orbit, which are linked to measurements to estimate the unknown corrections to approximate values of the unknown parameters and the unknown initial conditions. Bearing in mind that satellite orbits can now be tracked almost continuously at unprecedented accuracy, we propose the measurement-based perturbation theory and derive global uniformly convergent solutions to the Newton’s nonlinear governing differential equations of satellite motion for the next generation of global gravitational models. Since the solutions are global uniformly convergent, theoretically speaking, they are able to extract smallest possible gravitational signals from modern and future satellite tracking measurements, leading to the production of global high-precision, high-resolution gravitational models. By directly turning the nonlinear differential equations of satellite motion into the nonlinear integral equations, and recognizing the fact that satellite orbits are measured with random errors, we further reformulate the links between satellite tracking measurements and the global uniformly convergent solutions to the Newton’s governing differential equations as a condition adjustment model with unknown parameters, or equivalently, the weighted least squares estimation of unknown differential equation parameters with equality constraints, for the reconstruction of global high-precision, high-resolution gravitational models from modern (and future) satellite tracking measurements.</description><identifier>ISSN: 1007-5704</identifier><identifier>EISSN: 1878-7274</identifier><identifier>DOI: 10.1016/j.cnsns.2017.11.021</identifier><language>eng</language><publisher>Amsterdam: Elsevier B.V</publisher><subject>Condition adjustment with parameters ; Convergence ; Derivatives ; Differential equation parameter estimation ; Differential equations ; Earth gravitation ; Earth sciences ; Earth’s gravity field ; GRACE (experiment) ; Gravimetry ; Gravitation ; High resolution ; Initial conditions ; Integral equations ; Mathematical models ; Measurement-based perturbation ; Nonlinear differential equations ; Nonlinear equations ; Nonlinear Volterra’s integral equations ; Numerical analysis ; Numerical integration ; Parameter estimation ; Perturbation methods ; Perturbation theory ; R&D ; Random errors ; Research & development ; Satellite gravimetry ; Satellite orbits ; Satellite tracking ; Satellites ; Space exploration ; Space flight ; Studies ; Tracking control systems</subject><ispartof>Communications in nonlinear science & numerical simulation, 2018-06, Vol.59, p.515-543</ispartof><rights>2017 The Author(s)</rights><rights>Copyright Elsevier Science Ltd. Jun 2018</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c420t-2a084325601d66c954800b399afee4392e2cdc3a0bfd443b2e2288f7f4a9de6c3</citedby><cites>FETCH-LOGICAL-c420t-2a084325601d66c954800b399afee4392e2cdc3a0bfd443b2e2288f7f4a9de6c3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://dx.doi.org/10.1016/j.cnsns.2017.11.021$$EHTML$$P50$$Gelsevier$$Hfree_for_read</linktohtml><link.rule.ids>315,781,785,3551,27929,27930,46000</link.rule.ids></links><search><creatorcontrib>Xu, Peiliang</creatorcontrib><title>Measurement-based perturbation theory and differential equation parameter estimation with applications to satellite gravimetry</title><title>Communications in nonlinear science & numerical simulation</title><description>•Estimating unknown differential equation parameters has been essential in many areas of science and engineering, which has been best known as the dynamical numerical integration method in geodesy and aerospace engineering. I prove that the method, originating from Gronwall [28] on Ann Math almost 100 years ago and currently implemented and used in statistics, chemical engineering and satellite gravimetry and many other areas of science and engineering, is mathematically erroneous and physically not permitted;•I present three different methods to derive local solutions to the Newton’s nonlinear differential equations of motion of satellites, given unknown initial values and unknown force parameters. They are mathematically correct and can be used to estimate unknown differential equation parameters, with applications in gravitational modelling from satellite tracking measurements. These solution methods are generally applicable to any differential equations with unknown parameters;•I develop the measurement-based perturbation theory and construct global uniformly convergent solutions to the Newton’s nonlinear differential equations of motion of satellites, given unknown initial values and unknown force parameters. From the physical point of view, the global uniform convergence of the solutions implies that they are able to exploit the complete/full advantages of unprecedented high accuracy and continuity of satellite orbits of arbitrary length and thus will automatically guarantee theoretically the production of a high-precision high-resolution global standard gravitational models from satellite tracking measurements of any types; and finally,•I develop an alternative method by reformulating the problem of estimating unknown differential equation parameters, or the mixed initial-boundary value problem of satellite gravimetry with unknown initial values and unknown force parameters as a standard condition adjustment model with unknown parameters.
The numerical integration method has been routinely used by major institutions worldwide, for example, NASA Goddard Space Flight Center and German Research Center for Geosciences (GFZ), to produce global gravitational models from satellite tracking measurements of CHAMP and/or GRACE types. Such Earth’s gravitational products have found widest possible multidisciplinary applications in Earth Sciences. The method is essentially implemented by solving the differential equations of the partial derivatives of the orbit of a satellite with respect to the unknown harmonic coefficients under the conditions of zero initial values. From the mathematical and statistical point of view, satellite gravimetry from satellite tracking is essentially the problem of estimating unknown parameters in the Newton’s nonlinear differential equations from satellite tracking measurements. We prove that zero initial values for the partial derivatives are incorrect mathematically and not permitted physically. The numerical integration method, as currently implemented and used in mathematics and statistics, chemistry and physics, and satellite gravimetry, is groundless, mathematically and physically. Given the Newton’s nonlinear governing differential equations of satellite motion with unknown equation parameters and unknown initial conditions, we develop three methods to derive new local solutions around a nominal reference orbit, which are linked to measurements to estimate the unknown corrections to approximate values of the unknown parameters and the unknown initial conditions. Bearing in mind that satellite orbits can now be tracked almost continuously at unprecedented accuracy, we propose the measurement-based perturbation theory and derive global uniformly convergent solutions to the Newton’s nonlinear governing differential equations of satellite motion for the next generation of global gravitational models. Since the solutions are global uniformly convergent, theoretically speaking, they are able to extract smallest possible gravitational signals from modern and future satellite tracking measurements, leading to the production of global high-precision, high-resolution gravitational models. By directly turning the nonlinear differential equations of satellite motion into the nonlinear integral equations, and recognizing the fact that satellite orbits are measured with random errors, we further reformulate the links between satellite tracking measurements and the global uniformly convergent solutions to the Newton’s governing differential equations as a condition adjustment model with unknown parameters, or equivalently, the weighted least squares estimation of unknown differential equation parameters with equality constraints, for the reconstruction of global high-precision, high-resolution gravitational models from modern (and future) satellite tracking measurements.</description><subject>Condition adjustment with parameters</subject><subject>Convergence</subject><subject>Derivatives</subject><subject>Differential equation parameter estimation</subject><subject>Differential equations</subject><subject>Earth gravitation</subject><subject>Earth sciences</subject><subject>Earth’s gravity field</subject><subject>GRACE (experiment)</subject><subject>Gravimetry</subject><subject>Gravitation</subject><subject>High resolution</subject><subject>Initial conditions</subject><subject>Integral equations</subject><subject>Mathematical models</subject><subject>Measurement-based perturbation</subject><subject>Nonlinear differential equations</subject><subject>Nonlinear equations</subject><subject>Nonlinear Volterra’s integral equations</subject><subject>Numerical analysis</subject><subject>Numerical integration</subject><subject>Parameter estimation</subject><subject>Perturbation methods</subject><subject>Perturbation theory</subject><subject>R&D</subject><subject>Random errors</subject><subject>Research & development</subject><subject>Satellite gravimetry</subject><subject>Satellite orbits</subject><subject>Satellite tracking</subject><subject>Satellites</subject><subject>Space exploration</subject><subject>Space flight</subject><subject>Studies</subject><subject>Tracking control systems</subject><issn>1007-5704</issn><issn>1878-7274</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp9kLlOxDAQhiMEEucT0FiiThgfm6OgQIhLAtFAbTn2BLzKJmHsgLbh2TGEmmoO_d8cf5adcig48PJ8XdghDKEQwKuC8wIE38kOeF3VeSUqtZtygCpfVaD2s8MQ1pCoZqUOsq9HNGEm3OAQ89YEdGxCijO1JvpxYPENR9oyMzjmfNchJZ03PcP3eRFMhswGIxLDEP1maX76-MbMNPXe_jYCiyMLJmLf-4jslcyHTxBtj7O9zvQBT_7iUfZyc_18dZc_PN3eX10-5FYJiLkwUCspViVwV5Y2XV4DtLJpTIeoZCNQWGelgbZzSsk21aKuu6pTpnFYWnmUnS1zJxrf53SpXo8zDWmlFqCEkFyCSiq5qCyNIRB2eqL0Em01B_1jtF7rX6P1j9Gac52MTtTFQmF64MMj6WA9DhadJ7RRu9H_y38D-wuLzQ</recordid><startdate>201806</startdate><enddate>201806</enddate><creator>Xu, Peiliang</creator><general>Elsevier B.V</general><general>Elsevier Science Ltd</general><scope>6I.</scope><scope>AAFTH</scope><scope>AAYXX</scope><scope>CITATION</scope></search><sort><creationdate>201806</creationdate><title>Measurement-based perturbation theory and differential equation parameter estimation with applications to satellite gravimetry</title><author>Xu, Peiliang</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c420t-2a084325601d66c954800b399afee4392e2cdc3a0bfd443b2e2288f7f4a9de6c3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Condition adjustment with parameters</topic><topic>Convergence</topic><topic>Derivatives</topic><topic>Differential equation parameter estimation</topic><topic>Differential equations</topic><topic>Earth gravitation</topic><topic>Earth sciences</topic><topic>Earth’s gravity field</topic><topic>GRACE (experiment)</topic><topic>Gravimetry</topic><topic>Gravitation</topic><topic>High resolution</topic><topic>Initial conditions</topic><topic>Integral equations</topic><topic>Mathematical models</topic><topic>Measurement-based perturbation</topic><topic>Nonlinear differential equations</topic><topic>Nonlinear equations</topic><topic>Nonlinear Volterra’s integral equations</topic><topic>Numerical analysis</topic><topic>Numerical integration</topic><topic>Parameter estimation</topic><topic>Perturbation methods</topic><topic>Perturbation theory</topic><topic>R&D</topic><topic>Random errors</topic><topic>Research & development</topic><topic>Satellite gravimetry</topic><topic>Satellite orbits</topic><topic>Satellite tracking</topic><topic>Satellites</topic><topic>Space exploration</topic><topic>Space flight</topic><topic>Studies</topic><topic>Tracking control systems</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Xu, Peiliang</creatorcontrib><collection>ScienceDirect Open Access Titles</collection><collection>Elsevier:ScienceDirect:Open Access</collection><collection>CrossRef</collection><jtitle>Communications in nonlinear science & numerical simulation</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Xu, Peiliang</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Measurement-based perturbation theory and differential equation parameter estimation with applications to satellite gravimetry</atitle><jtitle>Communications in nonlinear science & numerical simulation</jtitle><date>2018-06</date><risdate>2018</risdate><volume>59</volume><spage>515</spage><epage>543</epage><pages>515-543</pages><issn>1007-5704</issn><eissn>1878-7274</eissn><abstract>•Estimating unknown differential equation parameters has been essential in many areas of science and engineering, which has been best known as the dynamical numerical integration method in geodesy and aerospace engineering. I prove that the method, originating from Gronwall [28] on Ann Math almost 100 years ago and currently implemented and used in statistics, chemical engineering and satellite gravimetry and many other areas of science and engineering, is mathematically erroneous and physically not permitted;•I present three different methods to derive local solutions to the Newton’s nonlinear differential equations of motion of satellites, given unknown initial values and unknown force parameters. They are mathematically correct and can be used to estimate unknown differential equation parameters, with applications in gravitational modelling from satellite tracking measurements. These solution methods are generally applicable to any differential equations with unknown parameters;•I develop the measurement-based perturbation theory and construct global uniformly convergent solutions to the Newton’s nonlinear differential equations of motion of satellites, given unknown initial values and unknown force parameters. From the physical point of view, the global uniform convergence of the solutions implies that they are able to exploit the complete/full advantages of unprecedented high accuracy and continuity of satellite orbits of arbitrary length and thus will automatically guarantee theoretically the production of a high-precision high-resolution global standard gravitational models from satellite tracking measurements of any types; and finally,•I develop an alternative method by reformulating the problem of estimating unknown differential equation parameters, or the mixed initial-boundary value problem of satellite gravimetry with unknown initial values and unknown force parameters as a standard condition adjustment model with unknown parameters.
The numerical integration method has been routinely used by major institutions worldwide, for example, NASA Goddard Space Flight Center and German Research Center for Geosciences (GFZ), to produce global gravitational models from satellite tracking measurements of CHAMP and/or GRACE types. Such Earth’s gravitational products have found widest possible multidisciplinary applications in Earth Sciences. The method is essentially implemented by solving the differential equations of the partial derivatives of the orbit of a satellite with respect to the unknown harmonic coefficients under the conditions of zero initial values. From the mathematical and statistical point of view, satellite gravimetry from satellite tracking is essentially the problem of estimating unknown parameters in the Newton’s nonlinear differential equations from satellite tracking measurements. We prove that zero initial values for the partial derivatives are incorrect mathematically and not permitted physically. The numerical integration method, as currently implemented and used in mathematics and statistics, chemistry and physics, and satellite gravimetry, is groundless, mathematically and physically. Given the Newton’s nonlinear governing differential equations of satellite motion with unknown equation parameters and unknown initial conditions, we develop three methods to derive new local solutions around a nominal reference orbit, which are linked to measurements to estimate the unknown corrections to approximate values of the unknown parameters and the unknown initial conditions. Bearing in mind that satellite orbits can now be tracked almost continuously at unprecedented accuracy, we propose the measurement-based perturbation theory and derive global uniformly convergent solutions to the Newton’s nonlinear governing differential equations of satellite motion for the next generation of global gravitational models. Since the solutions are global uniformly convergent, theoretically speaking, they are able to extract smallest possible gravitational signals from modern and future satellite tracking measurements, leading to the production of global high-precision, high-resolution gravitational models. By directly turning the nonlinear differential equations of satellite motion into the nonlinear integral equations, and recognizing the fact that satellite orbits are measured with random errors, we further reformulate the links between satellite tracking measurements and the global uniformly convergent solutions to the Newton’s governing differential equations as a condition adjustment model with unknown parameters, or equivalently, the weighted least squares estimation of unknown differential equation parameters with equality constraints, for the reconstruction of global high-precision, high-resolution gravitational models from modern (and future) satellite tracking measurements.</abstract><cop>Amsterdam</cop><pub>Elsevier B.V</pub><doi>10.1016/j.cnsns.2017.11.021</doi><tpages>29</tpages><oa>free_for_read</oa></addata></record> |
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| subjects | Condition adjustment with parameters Convergence Derivatives Differential equation parameter estimation Differential equations Earth gravitation Earth sciences Earth’s gravity field GRACE (experiment) Gravimetry Gravitation High resolution Initial conditions Integral equations Mathematical models Measurement-based perturbation Nonlinear differential equations Nonlinear equations Nonlinear Volterra’s integral equations Numerical analysis Numerical integration Parameter estimation Perturbation methods Perturbation theory R&D Random errors Research & development Satellite gravimetry Satellite orbits Satellite tracking Satellites Space exploration Space flight Studies Tracking control systems |
| title | Measurement-based perturbation theory and differential equation parameter estimation with applications to satellite gravimetry |
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