Ingegneria Meccanica | FLUIDODINAMICA NUMERICA

cod. 0622300002

FLUIDODINAMICA NUMERICA

	0622300002
	DIPARTIMENTO DI INGEGNERIA INDUSTRIALE

	MECHANICAL ENGINEERING
	2015/2016

PERCORSO COMUNE

	OBBLIGATORIO
	YEAR OF COURSE 1
	YEAR OF DIDACTIC SYSTEM 2012
	PRIMO SEMESTRE

TEACHING UNITS

	SSD	CFU	HOURS	ACTIVITY	TYPE OF ACTIVITY
	ING-IND/06	9	90	LESSONS	SUPPLEMENTARY COMPULSORY SUBJECTS

PROFESSORS

	FLAVIO GIANNETTI T Curriculum
	PAOLO LUCHINI Curriculum

	Objectives
	THE COURSE AIMS TO PROVIDE STUDENTS WITH KNOWLEDGE OF THE MAIN NUMERICAL METHODS USED IN ENGINEERING, TAKING INSPIRATION FROM TYPICAL PROBLEMS OF MULTI-DIMENSIONAL FLUID DYNAMICS IN WHICH THESE TECHNIQUES ARE USED.

	Prerequisites
	QUADRATURE FORMULAS, NUMERICAL SOLUTION OF LINEAR SYSTEMS, DISCRETE AND CONTINUOUS FOURIER TRANSFORM

	Contents
	NUMERICAL SIMULATION OF LUMPED PARAMETER SYSTEMS. NUMERICAL SOLUTION OF TIME AND SPACE DEPENDENT PROBLEMS. NUMERICAL SOLUTION OF TWO AND THREE DIMENSIONAL SPATIAL PROBLEMS. PARABOLIC, ELLITTIC AND HYPERBOLIC PROBLEMS. SPECTRAL TECHNIQUES. COMPUTATION OF BOUNDARY-LAYER FLOWS. LOW REYNOLDS NUMBER FLOWS. NUMERICAL SOLUTION OF THE INCOMPRESSIBLE NAVIER-STOKES EQUATIONS. CONSERVATION LAWS IN COMPRESSIBLE FLOW. IRROTATIONAL FLOW AROUND AERODYNAMIC BODIES. BOUNDARY ELEMENT METHOD.

NUMERICAL SIMULATION OF LUMPED PARAMETER SYSTEMS. NUMERICAL SOLUTION OF TIME AND SPACE DEPENDENT PROBLEMS. NUMERICAL SOLUTION OF TWO AND THREE DIMENSIONAL SPATIAL PROBLEMS. PARABOLIC, ELLITTIC AND HYPERBOLIC PROBLEMS. SPECTRAL TECHNIQUES. COMPUTATION OF BOUNDARY-LAYER FLOWS. LOW REYNOLDS NUMBER FLOWS. NUMERICAL SOLUTION OF THE INCOMPRESSIBLE NAVIER-STOKES EQUATIONS. CONSERVATION LAWS IN COMPRESSIBLE FLOW. IRROTATIONAL FLOW AROUND AERODYNAMIC BODIES. BOUNDARY ELEMENT METHOD.

	Teaching Methods
	THE COURSE IS BASED ON LECTURES AND CLASSROOM EXERCISES. THE EXERCISES WILL BE CARRIED OUT WITH THE INVOLVEMENT OF THE STUDENTS AND WILL CONSIST OF THE NUMERICAL SOLUTION OF SOME TYPICAL PROBLEMS IN FLUID DYNAMICS

	Verification of learning
	ORAL EXAMINATION

	Texts
	1) R. J. LEVEQUE: FINITE DIFFERENCE METHODS FOR ORDINARY AND PARTIAL DIFFERENTIAL EQUATIONS (SIAM 2007) 2) S. K. GODUNOV, V. S. RIABENKI: DIFFERENCE SCHEMES (ELSEVIER 1987) 3) M.QUADRIO E P. LUCHINI: AERODINAMICA. (DISPENSE POLITECNICO DI MILANO), 4) ANDERSON : COMPUTATIONAL FLUID DYNAMICS . (MCGRAW HILL, 1995) 5) R. J. LEVEQUE: NUMERICAL METHODS FOR CONSERVATION LAWS. (BIRKHAUSER, 1992) 6) P. WESSELING : PRINCIPLES OF COMPUTATIONAL FLUID DYNAMICS. (SPRINGER)

Texts

1) R. J. LEVEQUE: FINITE DIFFERENCE METHODS FOR ORDINARY AND PARTIAL DIFFERENTIAL EQUATIONS (SIAM 2007)
2) S. K. GODUNOV, V. S. RIABENKI: DIFFERENCE SCHEMES (ELSEVIER 1987)
3) M.QUADRIO E P. LUCHINI: AERODINAMICA. (DISPENSE POLITECNICO DI MILANO),
4) ANDERSON : COMPUTATIONAL FLUID DYNAMICS . (MCGRAW HILL, 1995)
5) R. J. LEVEQUE: NUMERICAL METHODS FOR CONSERVATION LAWS. (BIRKHAUSER, 1992)
6) P. WESSELING : PRINCIPLES OF COMPUTATIONAL FLUID DYNAMICS. (SPRINGER)