
Previous Article
Deflating irreducible singular Mmatrix algebraic Riccati equations
 NACO Home
 This Issue

Next Article
Partial Newton methods for a system of equations
Introduction to the theory of splines with an optimal mesh. Linear Chebyshev splines and applications
1.  Prof. N. E. Zhukovsky Central Aerohydrodynamic Institute (TsAGI), Zhukovsky str., 1, Zhukovsky, Moscow region, 140180, Russian Federation 
2.  Moscow Institute of Physics and Technology (State University) (MIPT), Institutsky Lane 9, Dolgoprudny, Moscow region, 141700, Russian Federation 
References:
[1] 
G. A. Amir'yants, N. A. Vladimirova, V. M. Gadetskiy, V. K. Isaev and S. V. Skorodumov, The nonlinear problems of integrated aerodynamic modelling, Nonlinear dynamic analysis (NDA2), Second International congress, Theses of lectures, MAI, Moscow, (2002), 269. Google Scholar 
[2] 
D. L. Barrow, C. K. Chui, P. W. Smith and J. D. Ward, Unicity of best approximation by second order splines with variable knots, Mathematics of Computation, 32 (1978), 1125. Google Scholar 
[3] 
P. L. Chebyshev, Questions about the least quantities related to the approximate representation of functions, Full. Works, USSR Academy of Sciences Publ., MoscowLeningrad, 2 (1948). (In Russian). Google Scholar 
[4] 
P. L. Chebyshev, The theory of mechanisms known as parallelograms, Full. Works, USSR Academy of Sciences Publ., MoscowLeningrad, 2 (1948). (In Russian). Google Scholar 
[5] 
M. G. Cox, An algorithm for approximating convex functions by means of first  degree splines, Computer J., 14 (1971). Google Scholar 
[6] 
V. K. Dzyadyk, "Introduction to the Theory of Uniform Approximation of Functions by Polynomials," Nauka, Moscow, 1977. (In Russian). Google Scholar 
[7] 
E. A. Fedosov, The programs of development of systems of air traffic management in Europe and the U. S. SESAR and NextGen (Analytical review of the materials of foreign sources of information), General Editor (O. V. Degtyaryov and I. F. Zubkova compilers), State Scientific Center of Russian Federation State ScientificResearch Institute of Aviation Systems Federal State Unitary Enterprise (FSUE) GosNIIAS, Moscow, (2011), 256. (In Russian). Google Scholar 
[8] 
V. V. Filatov, On Chebyshev approximation by cubic splines, Computer Systems, (56), Mathem. Institute, Siberian Branch of the USSR AS, Novosibirsk, 1973. (In Russian). Google Scholar 
[9] 
A. I. Grebennikov, "The Method of Splines and Solving Illposed Problems in Approximation Theory," Lomonosov MSU Press, Moscow, 1983. (In Russian). Google Scholar 
[10] 
K. Ichida and T. Kiuopo, Segmentation of planar curve, Electronics and Communication in Japan, 58d (1975). Google Scholar 
[11] 
V. K. Isaev, "Geometrical Fundamentals of the CAE/CAD/CAMsystem for Wind Tunnel Models," Doctoral Dissertation, TsAGIMAI, Moscow, 1991. (In Russian). Google Scholar 
[12] 
V. K. Isaev, Pontryagin maximum principle and controlled processes of Hermitian interpolation, Modern problems of mathematics, mathematical analysis, algebra, topology. Dedicated to academician L. S. Pontryagin to his 75 anniversary, Steklov mathematical institute Proceedings, Science, Moscow, 167 (1985), 156166. (In Russian). Google Scholar 
[13] 
V. K. Isaev, To the theory of optimal splines, Applied Mathematics and Computation (Special Issue in Honor of George Leitmann on his 86th Birth year), 217 (2010), 10951109. doi: 10.1016/j.amc.2010.05.051. Google Scholar 
[14] 
V. K. Isaev, B. Kh. Davidson, E. N. Khobotov and V. V. Zolotukhin, On construction of multilevel intellectual air traffic management system, Proceedings of the Third International Conference "Managing the multilarge systems development MLSD'2009," V. A. Trapeznikov Institute of control problems of RAS (October 59, 2009, Moscow, Russia), Moscow, I (2009), 290292. (In Russian). Google Scholar 
[15] 
V. K. Isaev and G. Leitmann, Brief comments on the halfcentennial history (19572007), Differential Equations and Topology: International conference dedicated to the Centennial Anniversary of L. S. Pontryagin (19081988), Theses of lectures, MAX Press, Moscow, (2008), 255256. Google Scholar 
[16] 
V. K. Isaev and S. A. Plotnikov, On approximation of functions by splines of the first degree, Methods of spline functions in numerical analysis (Computer Systems), Mathem. Institute, Siberian Branch of the USSR AS, Novosibirsk, (1983), 2734. (In Russian). Google Scholar 
[17] 
V. K. Isaev and S. A. Plotnikov, The algorithm of polygonal approximation to a given accuracy and a minimal number of nodes, Recent advances in the machining of curved surfaces on CNC machines, LDNTP Press, Leningrad, (1983), 4247. (In Russian). Google Scholar 
[18] 
V. K. Isaev and S. A. Plotnikov, The inverse problem of optimal Chebyshev approximation of geometric information, Trudy TsAGI, 2344 (1987), 340. Google Scholar 
[19] 
V. K. Isaev and S. A. Plotnikov, The reverse Chebyshev problem and Chebyshev splines, Optimal control and differential equations: To the seventieth anniversary from the day of birth of academician E. F. Mishchenko, Proceed. MIRAN 211, Science, Fizmatlit, Moscow, (1995), 164185, (In Russian). Google Scholar 
[20] 
V. K. Isaev, S. A. Plotnikov, V. P. Sitnikov and N. V. Shcherbakov, "Some Problems of Optimization of Trajectories Machining Parts with Complex Technical Forms," Experience and prospects for effective use of technological equipment with CNC, LDNTP Press, Leningrad, 1982. (In Russian). Google Scholar 
[21] 
V. K. Isaev, V. P. Sitnikov, V. A. Sukhnev, I. G. Karimullin, S. V. Skorodumov, V. V. Sonin, V. V. Lubashevskiy, O. E. Baryshnikov, V. E. Zaytsev, E. N. Khobotov, L. I. Shustova and V. M. Platov, Research on creation of the CAE/CAD/CAMsystem for wind tunnel models in TsAGI: ASIM (19701980), ASIM+ (19801992), Problems of creation of perspective airspace technique, Fizmatlit, Moscow, (2005), 498502. (In Russian). Google Scholar 
[22] 
V. K. Isaev and V. V. Zolotukhin, Some problems of 2Dmaneuvering to ensure the vortex safety of an aircraft, Aerospace MAI Journal, 16 (2009), 510. (In Russian). Google Scholar 
[23] 
V. K. Isaev and V. V. Zolotukhin, Construction of plane maneuvers the aircrafts to ensure the air traffic safety, Proceedings on the VIII Internatonal conference on nonequilibrium processes in nozzles and jets (NPNJ 2010) (May, 2531 2010 Alushta), MAIPRINT Publishing House, Moscow, (2010), 489490. (In Russian). Google Scholar 
[24] 
V. K. Isaev and V. V. Zolotukhin, Construction of plane maneuvers the aircrafts to ensure air traffic safety, X AllRussian Congress on the fundamental problems of theoretical and applied mechanics. (Nizhny Novgorod, August, 2430, 2011) Nizhny Novgorod, IV (2011), 441442. (In Russian). Google Scholar 
[25] 
V. K. Isaev and V. V. Zolotukhin, Intellect air traffic management system based on the Free Flight concept, Managing the development of largescale systems (MLSD'2011): Proceedings of the V International Conference "Managing the multilarge systems development MLSD'2009", Establishment of the RAS V.A. Trapeznikov Institute of control problems (October, 35, 2011, Moscow, Russia), Moscow, I (2011), 3941. (In Russian). Google Scholar 
[26] 
V. K. Isaev and V. V. Zolotukhin, The basics of construction a multilevel intellectual air traffic management system based on the concept of free flight, Proceedings of the XVII International Conference on Computational Mechanics and Modern Applied Software Syste ms (CMMASS'2011), (Alushta, 2531 May, 2011), Moscow, MAIPRINT Publishing House, (2011), 749751. (In Russian). Google Scholar 
[27] 
H. M. Johnson and A. A. Uogt, Geometric method for approximating convex arc, SIAM J. Appl. Math., 38 (1980), 317325. doi: 10.1137/0138027. Google Scholar 
[28] 
Yu. L. Ketkov, On optimal methods of piecewise linear approximation, Proceedings of the USSR universities, Radiophysics, 9 (1966), 12021209. (In Russian). Google Scholar 
[29] 
A. K. Khmelyov, "The Methods of Approximation of Functions and Curves by Splines with a Minimum Number of Nodes and Applications to the problem of design surface of the wind tunnel models," PhD thesis, TsAGI, 1989. (In Russian). Google Scholar 
[30] 
Yoshisuke Kirozumi and W. A. Dawis, Poligonal approximation by minimax method, Computer Graphics and Image Proc., 19 (1982), 248264. Google Scholar 
[31] 
N. P. Korneichuk, "Splines in Approximation Theory," Nauka, Moscow, 1984. (In Russian). Google Scholar 
[32] 
U. Montanari, A note on minimal length polygonal approximation to a digitized contour, Comm. ACM, 13 (1970), 4147. Google Scholar 
[33] 
T. Pavlidis, Poligonal approximations by Newton's method, IEEE Trans. Comput., C26 (1977) 801807. Google Scholar 
[34] 
T. Pavlidis and S. L. Horowitz, Segmentation of plane curves, IEEE Trans. Comput., C23 (1974), 860870. Google Scholar 
[35] 
G. M. Phillips, Algorithms for piecewise straight line approximations, Computer J., 11 (1968), 110111. Google Scholar 
[36] 
S. A. Plotnikov, "Development of Methods for Optimal Approximation of Geometric Information in the CNC Systems," PhD thesis, MIPT, 1986. (In Russian). Google Scholar 
[37] 
S. A. Plotnikov, On the optimal approximation to a given accuracy of the trajectories of discrete control systems,, Depon. VINITI, (): 3690. Google Scholar 
[38] 
B. A. Popov, The accuracy of approximation by uniform splines (absolute error), PMI UAS, Lviv, (1983), 50. (In Russian). Google Scholar 
[39] 
B. A. Popov, The accuracy of the approximation by uniform splines (weighted error), PMI UAS, Lviv, (1983), 50. (In Russian). Google Scholar 
[40] 
B. A. Popov and G. S. Tesler, Approximation of functions for technical applications, Nauk. Thought, Kiev, (1980), 352. (In Russian). Google Scholar 
[41] 
U. E. Ramer, An iterative procedure for the polygonal approximation of plane curves, Computer Graphics and Image Proc., 1 (1972), 244256. Google Scholar 
[42] 
Ey. Ya. Remez, "Fundamentals of Numerical Methods of Chebyshev Approximation," Nauk. Dumka, Kiev, 1969. (In Russian). Google Scholar 
[43] 
Ey. Ya. Remez, "General Computational Methods of Chebyshev Approximation," UAS Publ., Kiev, 1957. (In Russian). Google Scholar 
[44] 
Ey. Ya. Remez and Gavrilyuk, Computational design of several approaches to the approximate construction of solutions of Chebyshev problems with nonlinear input parameters, Ukrain Math.J., 12 (1960), (In Russian). Google Scholar 
[45] 
B. M. Shumilov, On local approximation by splines of firstdegree, Methods of Spline Functions (Computing systems), Mathem. Institute, Siberian Branch of the USSR AS, Novosibirsk, 75 (1978), 1622. (In Russian). Google Scholar 
[46] 
H. A. Simon, Rational choice and the structure of the environment, Psychological Review, 63 (1956), 129138. Google Scholar 
[47] 
J. Sklansky, R. L. Chazin and B. J. Hansen, Minimum perimeter polygons of digitized silhuettes, IEEE Trans. Comput., C.21 (1972), 445448. Google Scholar 
[48] 
J. Sklansky and V. Gonzales, "Fast Polygonal Approximation of Digitized Curves," PRIP Proceed., 1979. Google Scholar 
[49] 
W. C. Stirling, "Satisficing Games and Decision Making: With Applications to Engineering and Computer Science," Cambridge University Press, Cambridge, 2003. doi: 10.1017/CBO9780511543456. Google Scholar 
[50] 
I. Tomek, Two algorithms for piecewise liner continuous approximations of functions of one variable, IEEE Trans. Comput., C23 (1974), 445448. Google Scholar 
[51] 
H. Werner, "An Introduction to Nonlinear Splines," Proc. of NATO Advanced Study Institute, Calgary, Dosdrecht, 1979. Google Scholar 
[52] 
C. M. Williams, An efficient algorithm for the piecewse linear approximation of planar curves, Computer Graphics and Image Proc., 8 (1978), 286293. Google Scholar 
[53] 
Yu. S. Zav'yalov, B. I. Kvasov and V. L. Miroshnichenko, "Methods of Spline Functions," Nauka, Moscow, 1980, (In Russian). Google Scholar 
[54] 
Yu. S. Zav'yalov, V. A. Leus and V. A. Skorospelov, "Splines in Engineering Geometry," Mashinostroenie, 1985, (In Russian). Google Scholar 
[55] 
V. V. Zolotukhin, Simulation of vortex wakes in the problems of air traffic control, Software and Systems, 1 (2011), 126129. (In Russian). Google Scholar 
[56] 
V. V. Zolotukhin, V. K. Isaev and B. Kh. Davidson, Some relevant problems of air traffic management, Proceedings of MIPT, 1 (2009), 94114. (In Russian). Google Scholar 
[57] 
V. V. Zolotukhin and V. K. Isaev, Application of the satisficing game theory to construct a system to ensure air traffic safety, Proceedings of the Russian scientifictechnical seminar "State and prospects of development of automated systems for planning the using airspace in the Russian Federation (PUAS2011)", November, 2224, FSUE "GosNIIAS", GosNIIAS Press, Moscow, (2011), 237244. (In Russian). Google Scholar 
[58] 
V. V. Zolotukhin and V. K. Isaev, Methods and models of air traffic management, Problems of Mechanical Engineering, Proceedings of the conference, A. A. Blagonravov Institute of machine sciences of RAS, Moscow, (2008), 231235. (In Russian). Google Scholar 
[59] 
V. V. Zolotukhin and V. K. Isaev, Using the theory of coalitional games to avoid conflicts between aircrafts, Proceedings of the 53rd MIPT conference "Modern Problems of Fundamental and Applied Sciences", Part III, Aerophysics and space research, Moscow, MIPT, 2 (2010), 7879. (In Russian). Google Scholar 
show all references
References:
[1] 
G. A. Amir'yants, N. A. Vladimirova, V. M. Gadetskiy, V. K. Isaev and S. V. Skorodumov, The nonlinear problems of integrated aerodynamic modelling, Nonlinear dynamic analysis (NDA2), Second International congress, Theses of lectures, MAI, Moscow, (2002), 269. Google Scholar 
[2] 
D. L. Barrow, C. K. Chui, P. W. Smith and J. D. Ward, Unicity of best approximation by second order splines with variable knots, Mathematics of Computation, 32 (1978), 1125. Google Scholar 
[3] 
P. L. Chebyshev, Questions about the least quantities related to the approximate representation of functions, Full. Works, USSR Academy of Sciences Publ., MoscowLeningrad, 2 (1948). (In Russian). Google Scholar 
[4] 
P. L. Chebyshev, The theory of mechanisms known as parallelograms, Full. Works, USSR Academy of Sciences Publ., MoscowLeningrad, 2 (1948). (In Russian). Google Scholar 
[5] 
M. G. Cox, An algorithm for approximating convex functions by means of first  degree splines, Computer J., 14 (1971). Google Scholar 
[6] 
V. K. Dzyadyk, "Introduction to the Theory of Uniform Approximation of Functions by Polynomials," Nauka, Moscow, 1977. (In Russian). Google Scholar 
[7] 
E. A. Fedosov, The programs of development of systems of air traffic management in Europe and the U. S. SESAR and NextGen (Analytical review of the materials of foreign sources of information), General Editor (O. V. Degtyaryov and I. F. Zubkova compilers), State Scientific Center of Russian Federation State ScientificResearch Institute of Aviation Systems Federal State Unitary Enterprise (FSUE) GosNIIAS, Moscow, (2011), 256. (In Russian). Google Scholar 
[8] 
V. V. Filatov, On Chebyshev approximation by cubic splines, Computer Systems, (56), Mathem. Institute, Siberian Branch of the USSR AS, Novosibirsk, 1973. (In Russian). Google Scholar 
[9] 
A. I. Grebennikov, "The Method of Splines and Solving Illposed Problems in Approximation Theory," Lomonosov MSU Press, Moscow, 1983. (In Russian). Google Scholar 
[10] 
K. Ichida and T. Kiuopo, Segmentation of planar curve, Electronics and Communication in Japan, 58d (1975). Google Scholar 
[11] 
V. K. Isaev, "Geometrical Fundamentals of the CAE/CAD/CAMsystem for Wind Tunnel Models," Doctoral Dissertation, TsAGIMAI, Moscow, 1991. (In Russian). Google Scholar 
[12] 
V. K. Isaev, Pontryagin maximum principle and controlled processes of Hermitian interpolation, Modern problems of mathematics, mathematical analysis, algebra, topology. Dedicated to academician L. S. Pontryagin to his 75 anniversary, Steklov mathematical institute Proceedings, Science, Moscow, 167 (1985), 156166. (In Russian). Google Scholar 
[13] 
V. K. Isaev, To the theory of optimal splines, Applied Mathematics and Computation (Special Issue in Honor of George Leitmann on his 86th Birth year), 217 (2010), 10951109. doi: 10.1016/j.amc.2010.05.051. Google Scholar 
[14] 
V. K. Isaev, B. Kh. Davidson, E. N. Khobotov and V. V. Zolotukhin, On construction of multilevel intellectual air traffic management system, Proceedings of the Third International Conference "Managing the multilarge systems development MLSD'2009," V. A. Trapeznikov Institute of control problems of RAS (October 59, 2009, Moscow, Russia), Moscow, I (2009), 290292. (In Russian). Google Scholar 
[15] 
V. K. Isaev and G. Leitmann, Brief comments on the halfcentennial history (19572007), Differential Equations and Topology: International conference dedicated to the Centennial Anniversary of L. S. Pontryagin (19081988), Theses of lectures, MAX Press, Moscow, (2008), 255256. Google Scholar 
[16] 
V. K. Isaev and S. A. Plotnikov, On approximation of functions by splines of the first degree, Methods of spline functions in numerical analysis (Computer Systems), Mathem. Institute, Siberian Branch of the USSR AS, Novosibirsk, (1983), 2734. (In Russian). Google Scholar 
[17] 
V. K. Isaev and S. A. Plotnikov, The algorithm of polygonal approximation to a given accuracy and a minimal number of nodes, Recent advances in the machining of curved surfaces on CNC machines, LDNTP Press, Leningrad, (1983), 4247. (In Russian). Google Scholar 
[18] 
V. K. Isaev and S. A. Plotnikov, The inverse problem of optimal Chebyshev approximation of geometric information, Trudy TsAGI, 2344 (1987), 340. Google Scholar 
[19] 
V. K. Isaev and S. A. Plotnikov, The reverse Chebyshev problem and Chebyshev splines, Optimal control and differential equations: To the seventieth anniversary from the day of birth of academician E. F. Mishchenko, Proceed. MIRAN 211, Science, Fizmatlit, Moscow, (1995), 164185, (In Russian). Google Scholar 
[20] 
V. K. Isaev, S. A. Plotnikov, V. P. Sitnikov and N. V. Shcherbakov, "Some Problems of Optimization of Trajectories Machining Parts with Complex Technical Forms," Experience and prospects for effective use of technological equipment with CNC, LDNTP Press, Leningrad, 1982. (In Russian). Google Scholar 
[21] 
V. K. Isaev, V. P. Sitnikov, V. A. Sukhnev, I. G. Karimullin, S. V. Skorodumov, V. V. Sonin, V. V. Lubashevskiy, O. E. Baryshnikov, V. E. Zaytsev, E. N. Khobotov, L. I. Shustova and V. M. Platov, Research on creation of the CAE/CAD/CAMsystem for wind tunnel models in TsAGI: ASIM (19701980), ASIM+ (19801992), Problems of creation of perspective airspace technique, Fizmatlit, Moscow, (2005), 498502. (In Russian). Google Scholar 
[22] 
V. K. Isaev and V. V. Zolotukhin, Some problems of 2Dmaneuvering to ensure the vortex safety of an aircraft, Aerospace MAI Journal, 16 (2009), 510. (In Russian). Google Scholar 
[23] 
V. K. Isaev and V. V. Zolotukhin, Construction of plane maneuvers the aircrafts to ensure the air traffic safety, Proceedings on the VIII Internatonal conference on nonequilibrium processes in nozzles and jets (NPNJ 2010) (May, 2531 2010 Alushta), MAIPRINT Publishing House, Moscow, (2010), 489490. (In Russian). Google Scholar 
[24] 
V. K. Isaev and V. V. Zolotukhin, Construction of plane maneuvers the aircrafts to ensure air traffic safety, X AllRussian Congress on the fundamental problems of theoretical and applied mechanics. (Nizhny Novgorod, August, 2430, 2011) Nizhny Novgorod, IV (2011), 441442. (In Russian). Google Scholar 
[25] 
V. K. Isaev and V. V. Zolotukhin, Intellect air traffic management system based on the Free Flight concept, Managing the development of largescale systems (MLSD'2011): Proceedings of the V International Conference "Managing the multilarge systems development MLSD'2009", Establishment of the RAS V.A. Trapeznikov Institute of control problems (October, 35, 2011, Moscow, Russia), Moscow, I (2011), 3941. (In Russian). Google Scholar 
[26] 
V. K. Isaev and V. V. Zolotukhin, The basics of construction a multilevel intellectual air traffic management system based on the concept of free flight, Proceedings of the XVII International Conference on Computational Mechanics and Modern Applied Software Syste ms (CMMASS'2011), (Alushta, 2531 May, 2011), Moscow, MAIPRINT Publishing House, (2011), 749751. (In Russian). Google Scholar 
[27] 
H. M. Johnson and A. A. Uogt, Geometric method for approximating convex arc, SIAM J. Appl. Math., 38 (1980), 317325. doi: 10.1137/0138027. Google Scholar 
[28] 
Yu. L. Ketkov, On optimal methods of piecewise linear approximation, Proceedings of the USSR universities, Radiophysics, 9 (1966), 12021209. (In Russian). Google Scholar 
[29] 
A. K. Khmelyov, "The Methods of Approximation of Functions and Curves by Splines with a Minimum Number of Nodes and Applications to the problem of design surface of the wind tunnel models," PhD thesis, TsAGI, 1989. (In Russian). Google Scholar 
[30] 
Yoshisuke Kirozumi and W. A. Dawis, Poligonal approximation by minimax method, Computer Graphics and Image Proc., 19 (1982), 248264. Google Scholar 
[31] 
N. P. Korneichuk, "Splines in Approximation Theory," Nauka, Moscow, 1984. (In Russian). Google Scholar 
[32] 
U. Montanari, A note on minimal length polygonal approximation to a digitized contour, Comm. ACM, 13 (1970), 4147. Google Scholar 
[33] 
T. Pavlidis, Poligonal approximations by Newton's method, IEEE Trans. Comput., C26 (1977) 801807. Google Scholar 
[34] 
T. Pavlidis and S. L. Horowitz, Segmentation of plane curves, IEEE Trans. Comput., C23 (1974), 860870. Google Scholar 
[35] 
G. M. Phillips, Algorithms for piecewise straight line approximations, Computer J., 11 (1968), 110111. Google Scholar 
[36] 
S. A. Plotnikov, "Development of Methods for Optimal Approximation of Geometric Information in the CNC Systems," PhD thesis, MIPT, 1986. (In Russian). Google Scholar 
[37] 
S. A. Plotnikov, On the optimal approximation to a given accuracy of the trajectories of discrete control systems,, Depon. VINITI, (): 3690. Google Scholar 
[38] 
B. A. Popov, The accuracy of approximation by uniform splines (absolute error), PMI UAS, Lviv, (1983), 50. (In Russian). Google Scholar 
[39] 
B. A. Popov, The accuracy of the approximation by uniform splines (weighted error), PMI UAS, Lviv, (1983), 50. (In Russian). Google Scholar 
[40] 
B. A. Popov and G. S. Tesler, Approximation of functions for technical applications, Nauk. Thought, Kiev, (1980), 352. (In Russian). Google Scholar 
[41] 
U. E. Ramer, An iterative procedure for the polygonal approximation of plane curves, Computer Graphics and Image Proc., 1 (1972), 244256. Google Scholar 
[42] 
Ey. Ya. Remez, "Fundamentals of Numerical Methods of Chebyshev Approximation," Nauk. Dumka, Kiev, 1969. (In Russian). Google Scholar 
[43] 
Ey. Ya. Remez, "General Computational Methods of Chebyshev Approximation," UAS Publ., Kiev, 1957. (In Russian). Google Scholar 
[44] 
Ey. Ya. Remez and Gavrilyuk, Computational design of several approaches to the approximate construction of solutions of Chebyshev problems with nonlinear input parameters, Ukrain Math.J., 12 (1960), (In Russian). Google Scholar 
[45] 
B. M. Shumilov, On local approximation by splines of firstdegree, Methods of Spline Functions (Computing systems), Mathem. Institute, Siberian Branch of the USSR AS, Novosibirsk, 75 (1978), 1622. (In Russian). Google Scholar 
[46] 
H. A. Simon, Rational choice and the structure of the environment, Psychological Review, 63 (1956), 129138. Google Scholar 
[47] 
J. Sklansky, R. L. Chazin and B. J. Hansen, Minimum perimeter polygons of digitized silhuettes, IEEE Trans. Comput., C.21 (1972), 445448. Google Scholar 
[48] 
J. Sklansky and V. Gonzales, "Fast Polygonal Approximation of Digitized Curves," PRIP Proceed., 1979. Google Scholar 
[49] 
W. C. Stirling, "Satisficing Games and Decision Making: With Applications to Engineering and Computer Science," Cambridge University Press, Cambridge, 2003. doi: 10.1017/CBO9780511543456. Google Scholar 
[50] 
I. Tomek, Two algorithms for piecewise liner continuous approximations of functions of one variable, IEEE Trans. Comput., C23 (1974), 445448. Google Scholar 
[51] 
H. Werner, "An Introduction to Nonlinear Splines," Proc. of NATO Advanced Study Institute, Calgary, Dosdrecht, 1979. Google Scholar 
[52] 
C. M. Williams, An efficient algorithm for the piecewse linear approximation of planar curves, Computer Graphics and Image Proc., 8 (1978), 286293. Google Scholar 
[53] 
Yu. S. Zav'yalov, B. I. Kvasov and V. L. Miroshnichenko, "Methods of Spline Functions," Nauka, Moscow, 1980, (In Russian). Google Scholar 
[54] 
Yu. S. Zav'yalov, V. A. Leus and V. A. Skorospelov, "Splines in Engineering Geometry," Mashinostroenie, 1985, (In Russian). Google Scholar 
[55] 
V. V. Zolotukhin, Simulation of vortex wakes in the problems of air traffic control, Software and Systems, 1 (2011), 126129. (In Russian). Google Scholar 
[56] 
V. V. Zolotukhin, V. K. Isaev and B. Kh. Davidson, Some relevant problems of air traffic management, Proceedings of MIPT, 1 (2009), 94114. (In Russian). Google Scholar 
[57] 
V. V. Zolotukhin and V. K. Isaev, Application of the satisficing game theory to construct a system to ensure air traffic safety, Proceedings of the Russian scientifictechnical seminar "State and prospects of development of automated systems for planning the using airspace in the Russian Federation (PUAS2011)", November, 2224, FSUE "GosNIIAS", GosNIIAS Press, Moscow, (2011), 237244. (In Russian). Google Scholar 
[58] 
V. V. Zolotukhin and V. K. Isaev, Methods and models of air traffic management, Problems of Mechanical Engineering, Proceedings of the conference, A. A. Blagonravov Institute of machine sciences of RAS, Moscow, (2008), 231235. (In Russian). Google Scholar 
[59] 
V. V. Zolotukhin and V. K. Isaev, Using the theory of coalitional games to avoid conflicts between aircrafts, Proceedings of the 53rd MIPT conference "Modern Problems of Fundamental and Applied Sciences", Part III, Aerophysics and space research, Moscow, MIPT, 2 (2010), 7879. (In Russian). Google Scholar 
[1] 
A. Marigo, Benedetto Piccoli. Cooperative controls for air traffic management. Communications on Pure & Applied Analysis, 2003, 2 (3) : 355369. doi: 10.3934/cpaa.2003.2.355 
[2] 
Lino J. AlvarezVázquez, Néstor GarcíaChan, Aurea Martínez, Miguel E. VázquezMéndez. Optimal control of urban air pollution related to traffic flow in road networks. Mathematical Control & Related Fields, 2018, 8 (1) : 177193. doi: 10.3934/mcrf.2018008 
[3] 
Dengfeng Sun, Issam S. Strub, Alexandre M. Bayen. Comparison of the performance of four Eulerian network flow models for strategic air traffic management. Networks & Heterogeneous Media, 2007, 2 (4) : 569595. doi: 10.3934/nhm.2007.2.569 
[4] 
Giulia Cavagnari, Antonio Marigonda, Benedetto Piccoli. Optimal synchronization problem for a multiagent system. Networks & Heterogeneous Media, 2017, 12 (2) : 277295. doi: 10.3934/nhm.2017012 
[5] 
David W. K. Yeung, Yingxuan Zhang, Hongtao Bai, Sardar M. N. Islam. Collaborative environmental management for transboundary air pollution problems: A differential levies game. Journal of Industrial & Management Optimization, 2021, 17 (2) : 517531. doi: 10.3934/jimo.2019121 
[6] 
Rui Li, Yingjing Shi. Finitetime optimal consensus control for secondorder multiagent systems. Journal of Industrial & Management Optimization, 2014, 10 (3) : 929943. doi: 10.3934/jimo.2014.10.929 
[7] 
Richard Carney, Monique Chyba, Chris Gray, George Wilkens, Corey Shanbrom. Multiagent systems for quadcopters. Journal of Geometric Mechanics, 2021 doi: 10.3934/jgm.2021005 
[8] 
Yinfei Li, Shuping Chen. Optimal traffic signal control for an $M\times N$ traffic network. Journal of Industrial & Management Optimization, 2008, 4 (4) : 661672. doi: 10.3934/jimo.2008.4.661 
[9] 
Brendan Pass. Multimarginal optimal transport and multiagent matching problems: Uniqueness and structure of solutions. Discrete & Continuous Dynamical Systems, 2014, 34 (4) : 16231639. doi: 10.3934/dcds.2014.34.1623 
[10] 
Zhiyong Sun, Toshiharu Sugie. Identification of Hessian matrix in distributed gradientbased multiagent coordination control systems. Numerical Algebra, Control & Optimization, 2019, 9 (3) : 297318. doi: 10.3934/naco.2019020 
[11] 
Hongru Ren, Shubo Li, Changxin Lu. Eventtriggered adaptive faulttolerant control for multiagent systems with unknown disturbances. Discrete & Continuous Dynamical Systems  S, 2021, 14 (4) : 13951414. doi: 10.3934/dcdss.2020379 
[12] 
Alexandre Bayen, Rinaldo M. Colombo, Paola Goatin, Benedetto Piccoli. Traffic modeling and management: Trends and perspectives. Discrete & Continuous Dynamical Systems  S, 2014, 7 (3) : iii. doi: 10.3934/dcdss.2014.7.3i 
[13] 
Maria Colombo, Antonio De Rosa, Andrea Marchese, Paul Pegon, Antoine Prouff. Stability of optimal traffic plans in the irrigation problem. Discrete & Continuous Dynamical Systems, 2021 doi: 10.3934/dcds.2021167 
[14] 
Zhongqiang Wu, Zongkui Xie. A multiobjective lion swarm optimization based on multiagent. Journal of Industrial & Management Optimization, 2022 doi: 10.3934/jimo.2022001 
[15] 
Emiliano Cristiani, Elisa Iacomini. An interfacefree multiscale multiorder model for traffic flow. Discrete & Continuous Dynamical Systems  B, 2019, 24 (11) : 61896207. doi: 10.3934/dcdsb.2019135 
[16] 
Yuri B. Gaididei, Carlos Gorria, Rainer Berkemer, Peter L. Christiansen, Atsushi Kawamoto, Mads P. Sørensen, Jens Starke. Stochastic control of traffic patterns. Networks & Heterogeneous Media, 2013, 8 (1) : 261273. doi: 10.3934/nhm.2013.8.261 
[17] 
SeungYeal Ha, Dohyun Kim, Jaeseung Lee, Se Eun Noh. Emergent dynamics of an orientation flocking model for multiagent system. Discrete & Continuous Dynamical Systems, 2020, 40 (4) : 20372060. doi: 10.3934/dcds.2020105 
[18] 
Nadia Loy, Andrea Tosin. Boltzmanntype equations for multiagent systems with label switching. Kinetic & Related Models, 2021, 14 (5) : 867894. doi: 10.3934/krm.2021027 
[19] 
Yujing Wang, Changjun Yu, Kok Lay Teo. A new computational strategy for optimal control problem with a cost on changing control. Numerical Algebra, Control & Optimization, 2016, 6 (3) : 339364. doi: 10.3934/naco.2016016 
[20] 
Simone Göttlich, Ute Ziegler. Traffic light control: A case study. Discrete & Continuous Dynamical Systems  S, 2014, 7 (3) : 483501. doi: 10.3934/dcdss.2014.7.483 
Impact Factor:
Tools
Metrics
Other articles
by authors
[Back to Top]