JM Vega - Escuela Técnica Superior de Ingenieros Aeronáuticos

JM Vega - Escuela Técnica Superior de Ingenieros Aeronáuticos

VEGA DE PRADA
JOSÉ-MANUEL
APELLIDOS
NOMBRE(S)
Situación actual y dirección de correo:
Catedrático de Matemática Aplicada
E.T.S.I. Aeronáuticos. Universidad Politécnica de Madrid
Plaza Cardenal Cisneros, 3. 28040-Madrid. ESPAÑA
Fecha y lugar de nacimiento:
Nationalidad:
01-02-52. Madrid, ESPAÑA
Español
Formación académica (grados, fechas, universidades)
Doctor Ingeniero Aeronáutico, 1977, Univ. Politécnica de Madrid
Director de Tesis: Amable Liñán.
Licenciado en Ciencias Matemáticas, 1976, Univ. Complutense de Madrid
Ingeniero Aeronáutico, 1974, Univ. Politécnica de Madrid
Puestos ocupados (entidades, puestos, fechas)
1987-hoy,
Catedrático, Univ. Politécnica de Madrid
1999-2005,
Visiting Scholar, Univ. California, Berkeley
1981-1987,
Profesor Titular, Univ. Politécnica de Madrid
1979-1981,
Prof. Adjunto Interino, Univ. Politécnica de Madrid
1978-1979,
Research Associate, Northwestern University, Evanston, Illinois
1975-1979,
Profesor Encargado de Curso, Univ. Politécnica de Madrid
Lı́neas de investigación
(i)
Campo principal
(ii)
Otros campos
(iii)
Temas
Matemática Aplicada
Combustion, Mecánica de Fluidos
Dinámica de ondas no lineales, Flujos termocapillares, Formación de patrones,
Ecuaciones en derivadas parciales, Sistemas de reacción-difusión,
Ondas en el agua, Teorı́a de capa lı́mite, Flujos aerodinámicos
Publicaciones
A. En revistas
1. J.M. Vega y A. Liñán, Isothermal n-th order reaction in catalytic pellets: Effect of external mass transfer
resistance, Chem. Eng. Sci., 34 (1979) 1319- 1322.
2. A.K. Kapila, B.J. Matkowsky y J.M. Vega, Reactive-diffusive system with Arrhenius kinetics: peculiarities
of the spherical geometry, SIAM J. Appl. Math., 38 (1980) 382-401.
3. J.M. Vega y A. Liñán, Singular Langmuir-Hinshelwood reaction-diffusion problems: Strong adsorption
under quasi-isothermal conditions, SIAM J. Appl. Math., 42 (1982) 1047-1068.
4. J.M. Vega, Singular Langmuir-Hinshelwood reaction-diffusion problems: Strongly nonisothermal conditions, SIAM J. Appl. Math., 43 (1983) 1367-1389.
5. J.M. Vega y A. Liñán, Large activation energy analysis of the ignition of self-heating porous bodies, Combust. Flame, 57 (1984) 247-253.
6. I.E. Parra y J.M. Vega, Local nonlinear stability of the steady state in an isothermal catalyst, SIAM J.
Appl. Math., 48 (1988) 854-881.
7. J.M. Vega, Invariant regions and global asymptotic stability in an isothermal catalysts, SIAM J. Math.
Anal., 19 (1988) 774-796.
8. C. Alvarez-Pereira y J.M. Vega, Global stability of a premixed reaction zone, SIAM J. Math. Anal., 21
(1990) 884-904.
9. L.L. Bonilla, F.J. Higuera y J.M. Vega, Stability of stationary solutions of extended convection-diffusionreaction equations on a finite segment, Appl. Math. Lett., 4 (1991) 41-44.
10. L.L. Bonilla y J.M. Vega, On the stability of wavefronts and solitary space charge waves in extrinsic
semiconductors under current bias, Phys. Lett. A, 156 (1991) 179-182.
11. I.E. Parra y J.M. Vega, Multiple solutions of some semi-linear elliptic equations in slender cylindrical
domains, J. Differ. Equations, 100 (1992) 225-256.
12. F.J. Mancebo y J.M. Vega, Weakly nonuniform thermal effects in a porous catalyst: asymptotic models
and local nonlinear stability of the steady states, SIAM J. Appl. Math., 52 (1992) 1238-1259.
13. C. Alvarez-Pereira y J.M. Vega On the pulsating instability of two-dimensional flames, Eur. J. Appl.
Math., 3 (1992) 55-73.
14. J.M. Vega, Multidimensional travelling wavefronts in a model from Combustion theory and in related
problems, Differ. Integral Eq., 6 (1993) 131-153.
15. J.M. Vega, The asymptotic behavior of the solutions of some semilinear elliptic equations in cylindrical
domains, J. Differ. Equations, 102 (1993) 119-152.
16. F.J. Mancebo y J.M. Vega, An asymptotic justification of a model of isothermal catalysts, J. Math. Anal.
Appl., 175 (1993) 523-536.
17. J.M. Vega, Travelling wavefronts of reaction-diffusion equations in cylindrical domains, Commun. Part.
Diff. Eq., 18 (1993) 505-531.
18. J.M. Vega, On the amplitude equations arising at the onset of the oscillatory instability in pattern formation, SIAM J. Math. Anal., 24 (1993) 603-617.
19. J.M. Vega, On the uniqueness of multidimensional travelling fronts of some semilinear equations, J. Math.
Anal. Appl., 177 (1993) 481-490.
20. M. Higuera, J.A. Nicolás y J.M. Vega, Linear oscillations of weakly dissipative axisymmetric liquid bridges,
Phys. Fluids, 6 (2) (1994) 438-450.
21. D. Rivas and J.M. Vega, Dynamics of axisymmetric slender liquid bridges in isorotation, Advances in
Space Research, 16 (7) (1995) pp. 33-36.
22. C. Martel y J.M. Vega, Finite size effects near the onset of the oscillatory instability, Nonlinearity, 9 (5)
(1996) 1129-1171.
23. J.A. Nicolás y J.M. Vega, Weakly nonlinear oscillations of nearly-inviscid axisymmetric liquid bridges, J.
Fluid Mech., 328 (1996) 95-128.
24. F.J. Mancebo y J.M. Vega, The asymptotic justification of a non-local 1-D model arising in porous catalysts
theory, J. Differ. Equations 134 (1997) 68-103.
25. C. Martel y J.M. Vega, Global stability properties of a hyperbolic system arising in pattern formation,
Nonlinear Anal.-TMA 29 (4) (1997) 439-460.
26. J.A. Nicolás, D. Rivas y J.M. Vega, The interaction of thermocapillary convection and low-frequency
vibration in nearly-inviscid liquid bridges, Z. angew. Math. Phys.(ZAMP) 48 (1997) 389-423.
27. J.A. Nicolás, D. Rivas y J.M. Vega, On the steady streaming flow due to high frequency vibration in nearly
inviscid liquid bridges, J. Fluid Mech., 354 (1998) 147-174.
28. C. Martel y J.M. Vega, Dynamics of a hyperbolic system that applies at the onset of the oscillatory
instability, Nonlinearity, 11 (1998) 105-142.
29. C. Martel, J.A. Nicolás y J.M. Vega, Surface-wave damping in a brimful circular cylinder, J. Fluid Mech.,
360 (1998) 213-228.
30. C. Martel, J.A. Nicolás and J.M. Vega, Corrigendum: Surface-wave damping in a brimful circular cylinder,
J. Fluid Mech., 373 (1998) 379-379.
31. F.J. Mancebo, J.A. Nicolás y J.M. Vega, Chaotic oscillations in a nearly inviscid, axisymmetric capillary
bridge at 2:1 parametric resonance, Phys. Fluids, 10 (5) (1998), 1088-1103.
32. J.M. Vega, F.J. Higuera y P.D. Weidmann, Quasi-steady vortical structures in vertically vibrating soap
films, J. Fluid Mech., 372 (1998) 213-230.
33. F.J. Mancebo y J.M. Vega, A model of porous catalyst accounting for incipiently non-isothermal effects,
J. Differ. Equations, 151 (1999) 79-110.
34. C. Martel, E. Knobloch y J.M. Vega, Dynamics of counter-propagating waves in parametrically forced
systems, Physica D, 137 (2000) 94-123.
35. J.A. Nicolás y J.M. Vega, Linear oscillations of axisymmetric viscous liquid bridges, Z. angew. Math.
Phys.(ZAMP), 51(2000) 701–731.
36. J.A. Nicolás y J.M. Vega, A note on the effect of surface contamination in water wave damping, J. Fluid
Mech., 410(2000) 367–373.
37. V. Lapuerta, F.J. Mancebo y J.M. Vega, Weakly-nonlinear analysis of the Rayleigh-Taylor instability in
a vertically vibrated, large aspect ratio container. Nonlinear Anal.-TMA, 47(2001) 3515–3520.
38. J.M. Vega, E. Knobloch y C. Martel, Nearly inviscid Faraday waves in annular containers of moderately
large aspect ratio. Physica D, 154 (2001) 313–336.
39. V. Lapuerta, F.J. Mancebo y J.M. Vega, On the control of Rayleigh-Taylor instability by vertical vibration
in large aspect ratio containers. Phys. Rev. E, 64 (2001) 016318-1–016318-17.
40. M. Higuera, J.A. Nicolás y J.M. Vega, Weakly nonlinear nonaxisymmetric oscillations of capillary bridges
at small viscosity. Phys. Fluids, 14 (2002) 3251-3271.
41. E. Martı́n, C. Martel y J.M. Vega, Drift instability of standing Faraday waves. J. Fluid Mech., 467 (2002)
57-79.
42. F. Varas y J.M. Vega, Linear stability of a plane front in solid combustion at large heat of reaction. SIAM
J. Appl. Math, 62 (2002) 1810-1822.
43. J. Hernández, F. J. Mancebo y J.M. Vega, On the linearization of some singular, nonlinear elliptic problems
and applications. Ann. I. H. Henry Poincaré-AN 19 (2002) 777-813.
44. V. Lapuerta, C. Martel y J.M. Vega, Weakly-dissipative Faraday waves in 2-D large aspect ratio annuli.
Physica D 173 (2002) 178-203.
45. F.J. Mancebo y J.M. Vega, Faraday instability threshold in large-aspect-ratio containers. J. Fluid Mech.
467 (2002) 307-330.
46. M. Higuera, J.M. Vega y E. Knobloch, Coupled amplitude-streaming flow equations for nearly inviscid
Faraday waves in small aspect ratio containers. J. Nonlinear Science 12 (2002) 505-551.
47. E. Knobloch, C. Martel y J.M. Vega, Coupled mean flow-amplitude equations for nearly inviscid parametrically driven surface waves, Annals of the New York Academy of Sciences 974 (2002), 201-219.
48. C. Martel, J.M. Vega y E. Knobloch, Dynamics of counterpropagating waves in parametrically driven
systems: dispersion vs. advection. Physica D, Physica D 174 (2003), 198-217.
49. J.A. Nicolás y J.M. Vega, Three-dimensional streaming flows driven by oscillatory boundary layers, Fluid
Dynamics Research 32 (2003), 119-139.
50. J.M. Vega y E. Knobloch, Dynamics of counterpropagating waves in parametrically forced, large aspect
ratio, nearly conservative systems with nonzero detuning. Fluid Dynamics Research 33 (2003), 113-140.
51. E. Martı́n, C. Martel y J.M. Vega, Mean flow effects in the Faraday instability. Int. J. Mod. Phys. B17
(2003), 4278-4283.
52. F.J. Mancebo, J.M. Vega, Standing wave description of nearly conservative, parametrically excited waves
in extended systems. Physica D 197 (2004), 346-363.
53. M. Higuera, E. Knobloch y J.M. Vega, Relaxation oscillations in a nearly inviscid Faraday system. Theor.
Comp. Fluid Dynamics 18 (2004), 323-333.
54. J.M. Vega, S. Rüdiger y J. Viñals, A phenomenological model of weakly damped Faraday curves and the
associated mean flow. Phys. Rev. E 70 (2004), 046306.
55. M. Higuera, E. Knobloch y J. M. Vega, Dynamics of nearly inviscid Faraday waves in almost circular
containers. Physica D 201 (2005), 83-120.
56. J. M. Vega, Instability of the steady states of some Ginzburg-Landau-like equations with real coefficients.
Nonlinearity, 18 (2005), 1425-1441.
57. E. Martı́n y J. M. Vega, The effect of surface contamination on the drift instability of standing Faraday
waves. J. Fluid Mech., 546 (2006), 203-225.
58. U. Thiele, J. M. Vega y E. Knobloch Long wave Marangoni-Bénard instability with vibration. J. Fluid
Mech., 546 (2006), 61-87.
59. F.J. Mancebo y J.M. Vega, Viscous Faraday waves in 2D large aspect ratio containers. J. Fluid Mech.,
560 (2006), 369-393.
60. J. Sánchez, M. Net y J.M. Vega, Amplitude equations close to a triple-(+1) bifurcation point of D4 symmetric periodic orbits in O(2) equivariant systems, Discrete and Continuous Dynamical Systems,
Serie B, 6(2006), 1357-1380.
61. J. Hernández, F.J. Mancebo y J.M. Vega, Positive solutions for singular nonlinear elliptic equations,
Proceedings of the Royal Society of Edinburgh, 137A (2007), 41-62.
62. F. Varas y J.M. Vega, Modulated surface waves in large aspect ratio, horizontally vibrated containers, J.
Fluid Mech., 569 (2007), 271-304.
63. L. S. Lorente , J. M. Vega y A. Velazquez Generation of Aerodynamic Databases using High Order Singular
Value Decomposition, J. Aircraft, (2007), aceptado.
B. Congresos y monografı́as:
64. J.M. Vega and A. Liñán, Técnicas de perturbaciones en la teorı́a de reactores catalı́ticos, Anales de
Quı́mica, Suplemento 1, (1978), pp.36-46.
65. J.M. Perales y J.M. Vega, Almost-cylindrical isorotating liquid bridges for small Bond numbers, European
Space Agency, SP-191 (1983) pp. 247-252.
66. J.M. Vega y I.E. Parra, Stability and Hopf bifurcation in isothermal catalysts, Lectures in Applied Mathematics 24-II, pp. 3-26, American Mathematical Society, 1986.
67. C. Martel y J.M. Vega, Finite geometry effects at the oscillatory instability, Chaos & Complexity, pp. 283284, Edit. Frontiers, 1993.
68. J.A. Nicolás, D. Rivas y J.M. Vega, Control of thermocapillary convection in nearly-inviscid liquid bridges
by low-frequency vibration: theory, Proceedings of the Second European Symposium Fluids in Space,
(1996) pp. 153-158.
69. J.A. Nicolás, D. Rivas y J.M. Vega, Control of thermocapillary convection in nearly-inviscid liquid bridges
by low-frequency vibration: numerics, Proceedings of the Second European Symposium Fluids in Space,
(1996) pp. 390-395 .
70. F.J. Mancebo y J.M. Vega, The quasi-isothermal limit in porous catalysts, Lecture Notes in Pure and
Appl. Math. 194, pp. 241-256, Marcel Dekker, 1997.
71. M.J. Higuera, J.M. Vega y E. Knobloch, Interaction of nearly-inviscid, multi-mode Faraday waves and
mean flows, in ‘Coherent Structures in Complex Systems’, L.L. Bonilla, G. Platero, D. Reguera y J.M.
Rubi Eds., Springer-Verlag, 2001.
72. E. Knobloch y J.M. Vega, Nearly inviscid Faraday waves. ‘Geometry, Mechanics and Dynamics, Volume
in honor of J.E. Marsden’, P. Newton, P. Holmes and A. Weinstein (eds), Springer-Verlag, pp. 181–222
(2002).
73. J.M. Vega, Interaction of viscous mean flows and surface waves at low viscosity. ‘Progress in Industrial
Mathematics’, A.D. Fitt Ed., Springer-Verlag, pp.67-76 (2004).
74. J.M. Vega, Viscous effects in parametrically excited water waves. ‘Simplicity, rigor and Relevance in Fluid
Mechanics, a Volume in honor of Amable Liñán’, F.J. Higuera, J. Jiménez y J.M. Vega. (eds.), Int. Center
for Num. Methods in Engineering, pp. 282-300 (2004)
75. S. Rüdiger y J.M. Vega, Model equations of weakly damped Faraday curves. ‘Dynamics and Bifurcation of
Patterns in Dissipative Systems’, G. Dangelmayr y I. Oprea (eds.), World Scientific Series on Nonlinear
Science, Vol. 12. World Scientific (2004).
76. L.L. Bonilla, A Liñán y J.M. Vega, La Matemática Aplicada: entre lo divino y lo humano. Sociedad
Española de Matemática Aplicada 29 (2004), 7-11.
77. M. Higuera, E. Knobloch and J.M. Vega. Nearly inviscid Faraday waves in containers with broken symmetry. International Workshop on Hysteresis and Multi-scale Asymptotics, M.P. Mortell, R.E. O’Malley
Jr., A.V. Pokrovskii and V.A. Sobolev (eds), J. Phys: Conference Series 22, 67-92 (2005).
78. L.L. Bonilla, A Liñán y J.M. Vega, Comentario sobre la Matemática Aplicada en España. La Gaceta de
la R.S.M.E., 8 (2005) 45-50.
79. J. Hernández, F.J. Mancebo y J.M. Vega, Nonlinear singular elliptic problems: Recent results and open
problems, Progress in Nonlinear Differential Equations and Their Applications Vol. 64 , 227-242, Birkhuser
Verlag, Basilea (2005).
80. C. Martel, E. Valero y J.M. Vega, Stabilization of Toolmien-Schlichting waves by mode interaction.
‘Progress in Industrial Mathematics’, L.L. Bonilla Ed., Springer-Verlag, en imprenta (2007).
Proyectos de investigación subencionados (tı́tulo del proyecto, duración, Investigador principal):
1. Columnas lı́quidas en condiciones de ingravidez. Comisión Nacional de Investigación del Espacio (Contrato
CONIE 514-83). 1982- 1983. IP: Ignacio Da Riva
2. Estructura y estabilidad de procesos de combustión. Comisión Asesora de Investigación Cientı́fica y Técnica
(Contrato N/r 2291-83). 1984-1987. IP: Amable Liñán.
3. Dinámica de procesos de combustión. DGICYT (Contrato PB 86/0497). 1987-1990. IP: Amable Liñán.
4. Problemas básicos de combustión en microgravedad. CICYT (Contrato ESP 187/90). 1991-1993. IP:
Amable Liñán
5. Algunos problemas de reacción-difusión relacionados con la teorı́a de flujos reactantes. DGICYT (Contrato
PB 90-0271). 1991-1993. IP: José Manuel Vega.
6. Nonlinear wave dynamics in semiconductors. Theory, numerics and experiments. OTAN (Nato Collaborative Research Grant, Ref. CRG 900284). 1992-1992. IP: Luis López Bonilla.
7. Ondas viajeras en algunos problemas de mecánica de fluidos y combustión. DGICYT (Ref. PB94-0416).
1995-1998. IP: José Manuel Vega.
8. Nonlinear spatio-temporal structures in semiconductors, fluids and oscillator ensembles.
Comunidad
Económica Europea (Programa Human Capital and Mobility, Ref. ERB 4050PL930458). 1994-1997.
IP: Luis López Bonilla.
9. Oscilaciones débilmente no lineales en puentes lı́quidos. DGICYT (PB93 0046). 1994-1997. IP: José
Antonio Nicolás.
10. Oscilaciones débilmente no lineales en puentes lı́quidos. DGICYT (PB96-0130). 1997-1998. IP: José
Antonio Nicolás.
11. The weakly-nonlinear description of the Faraday instability. OTAN (Collaborative Research Grant, Ref.
CRG970032). 1997-1998. IP: José Manuel Vega.
12. Weakly-nonlinear description of parametric instabilities in vibrating flows. NASA (Microgravity Fluid
Physics Research and Flight Experiment Opportunities, Grant NAG3-2152). 1997-2001. IP: Edgar
Knobloch.
13. Ondas gravitatorio-capilares en recipientes finitos y flujos medios asociados. MEC-DGI (BFM2001-2363)
2001-2003. IP: José Manuel Vega.
14. Dispersion effects in nonlinear light propagation in 1D fiber grating. European Office of Aerospace Research
and Development (FA8655-02-M-4087). 2002-2003. IP: Carlos Martel.
15. Structure and dynamics of free surface flows with heating and vibration. NASA (Microgravity Fluid
Physics Research and Flight Experiment Opportunities, Grant NNC04GA476). 2002-2006. IP: Edgar
Knobloch.
16. Theoretical study of mode superposition/interaction to control laminar flow instabilities. Airbus (CAFEDA:
Control of Aerodynamic flows for environmetally driven aircraft). 2003-2208. IP: José Manuel Vega.
17. Dinámica débilmente no lineal de ondas contrapropagatorias en sistemas invariantes frente a reflexiones
y traslaciones. MEC-DGES (MTM2004). 2004-2007. IP: José Manuel Vega.
18. Predicción y control de la transición laminar-turbulento en capas lı́mite mediante herramientas analı́ticas
y numéricas. Ministerio de Ciencia y Tecnologı́a (FIT-370200-2004). 2004-2207. IP: José Manuel Vega.
19. Aeroacústica Computacional para la Predicción y Control de Ruido. Ministerio de Ciencia y Tecnologı́a
(CIT-370200-2005-17). 2005-2006. IP: Adel Abbas.
20. Development of Advanced Microcooling Devices. Airbus-France. 2006. IP: Ángel Velázquez.
21. Advanced Modelling of Aerodynamic Data Bases. Airbus-España. 2006-2009. IP: Ángel Velázquez.
Tesis doctorales dirigidas:
1. Efectos Térmicos Incipientes en Catalizadores Porosos. Francisco Javier Mancebo Cortés. Universidad
Politécnica de Madrid, 1993. Apto “Cum Laude”.
2. La inestabilidad Oscilatoria y sus Aplicaciones en Mecánica de Fluidos y Combustión. Carlos Martel
Escobar. Universidad Politécnica de Madrid, 1995. Apto “Cum Laude”. Ésta tesis obtuvo el Premio
Joven 2000 de la Universidad Complutense de Madrid, y el Premio Extraordinario de Doctorado de la
Universidad Politécnica de Madrid.
3. Interacción entre ondas de Faraday y flujos medios. Elena Martı́n Ortega. Universidad Politécnica de
Madrid, 2002. Apto “Cum Laude”.
Datos adicionales:
1. Miembro de la Ponencia de Fı́sica y Matemáticas de la ANEP durante los años 1994-1997.
2. Miembro de la Comisión del Plan Nacinal de Fı́sica, nombrado por la Dirección General de Investigación.
3. Referee para las numerosas revistas cientı́ficas. Entre otras, para Chemical Engineering Science, SIAM
Journal on Applied Mathematics, SIAM Journal on Mathematical Analysis, Annals Institut Henri Poincaré,
Analyse non-lineaire, Journal of Differential Equations, Nonlinearity, Physica A, Physica D, Combustion
Science and Modelling, Physics Letters A, Europhysics Letters, Physics of Fluids, Journal of Physics A,
Journal of Fluid Mechanics, Fluid Dynamics Research, European Journal of Mechanics.
4. Referee para la National Science Foundation y evaluador para la Agencia Nacional de Evaluación
5. Coorganizador de congresos y reuniones cientı́ficas:
• Fluid Mechanics: A Workshop in Honor of Amable Liñán, Granada, 16-18 de septiembre de 2004.
Con F.J. Higuera y J.J. Jiménez.
• Recent Advances in Nonlinear Partial Differential Equations and Applications, Toledo, 7-10 de Junio
de 2006. Con L.L. Bonilla, A. Carpio y S. Venakides.
• European Consortium on Mathematics in Industry 2006 (ECMI2006). Leganés, 10-14 de julio de
2006. Con L.L. Bonilla y A. Carpio.
6. Premio de la Fundación General de la Universidad Politécnica de Madrid a la Investigación y el Desarrollo
Tecnológico en 1994.
7. En la actualidad, en posesin de cinco sexenios y seis quinquenios.
8. Director del Departamento de Matemática de la Ingenierı́a Aeronáutica, de la E.T.S.I. Aeronáuticos (de
01.12.81 a 01.03.84, y de 30.11.95 a 14.04.2003).