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Summer School 2007B. Rossetto1 French Summer School Phnom Penh 2007 Mechanics I ROSSETTO Bruno Institut Universitaire de Technologie Université du Sud-Toulon-Var.

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Presentation on theme: "Summer School 2007B. Rossetto1 French Summer School Phnom Penh 2007 Mechanics I ROSSETTO Bruno Institut Universitaire de Technologie Université du Sud-Toulon-Var."— Presentation transcript:

1 Summer School 2007B. Rossetto1 French Summer School Phnom Penh 2007 Mechanics I ROSSETTO Bruno Institut Universitaire de Technologie Université du Sud-Toulon-Var (France) tél. + 336 08 45 48 54 email: rossetto@univ-tln.frrossetto@univ-tln.fr site: http://rossetto.univ-tln.frhttp://rossetto.univ-tln.fr

2 Summer School 2007B. Rossetto2 Mechanics I  Summary Chap. 1 – Coordinates Chap. 2 – Vectors Chap. 3 – Differential operators Chap. 4 – Forces. Equilibrium Chap. 5 – Kinematics. Particle motion Chap. 6 – Relative motion Chap. 7 – System of particles Chap. 8 – Rigid body motion

3 Summer School 2007B. Rossetto3 Mechanics I  References M. Alonso and E. J. Finn, Fundamental University Physics, vol. 1 Mechanics, Addison Wesley (1969) C. Kittel, W. D. Knight, M. A. Ruderman, The Berkeley Course on Physics, vol. 1 Mechanics, Mc Graw Hill, (1965) R. W. Feynmann, M. Leighton and M. Sands, The Feynmann Lectures on Physics, vol 1, Mainly Mechanics, Radiation and Heat, Addison Wesley, early 1960s)

4 Summer School 2007B. Rossetto4 1. Coordinates  Cartesian x y 0 2-dim. 1 - Origin 0 2 - System of orthogonal axis (0xy) 3 - Unit vectors and x y 0 z 3-dim. Orientation of the three-dimensional system of coordinates: - screw rule - right hand rule

5 Summer School 2007B. Rossetto5 1. Coordinates  Orientation rules x y z y z x

6 Summer School 2007B. Rossetto6 1. Coordinates  Orientation rules x y z y x z

7 Summer School 2007B. Rossetto7 1. Coordinates x y 0  Polar (2-dim.)   Cylindrical (3-dim.) P(r,) x 0 z  P(r,,z) P(r,) and For both: and  3-dim.:

8 Summer School 2007B. Rossetto8 1. Coordinates  Transformations  r x y z 0 r z 1 – From polar to cartesian x = r cos y = r sin z = z 1 – From cartesian to polar z = z

9 Summer School 2007B. Rossetto9 1. Coordinates  Spherical   r r sin  x y z 0 z 2 - Transformations 1 - Definitions

10 Summer School 2007B. Rossetto10 1. Coordinates System of coordinates Differential line elements along the coordinate axis of the system Cartesian (x, y, z)dx, dy, dz Cylindrical (r, , z)dr, r d, dz (cf applications 2, 4) Spherical (r, , )dr, r sind, r d (cf applications 5, 6) Definition of radian (for the disk : = 2 radians) r 0 r  A B From this definition:

11 Summer School 2007B. Rossetto11 1. Applications (1) 1 – Triangle area from the equation b pb = h x 0 h r x 0 -r 2 – Surface of a disk from the equation If b is the basis and h the height: - Find the equation of the line OA - Use a property of integrals A - Find the equation of the circle - Use a property of integrals

12 Summer School 2007B. Rossetto12 1. Applications (1) 1 – Triangle area from the equation b f(x) = px pb = h x 0 h r x 0 -r 2 – Surface of a disk from the equation If b is the basis and h the height: Equation: f(x)=px

13 Summer School 2007B. Rossetto13 1. Applications (1) 1 – Triangle area from the equation b f(x) = px pb = h x 0 h r x 0 -r 2 – Surface of a disk from the equation Let If b is the basis and h the height:

14 Summer School 2007B. Rossetto14 1. Applications (2) 0 r d r  r 2 - Surface of a disk using polar cordinates The contribution to the area of the sector having r as length and  as angle is the aerea of the triangle having r as basis and rd as height: r 0 r dd A B 1 - Length of a circonference Contribution of the angle d to the length: Total length: sum of contributions: Total area : A= dA=

15 Summer School 2007B. Rossetto15 1. Applications (2) 0 r d r  r 2 - Area of a disk using polar cordinates The contribution to the area of the sector having r as length and  as angle is the aerea of the triangle having r as basis and rd as height: Total aerea : r 0 r dd A B 1 - Length of a circonference Contribution of the angle d to the length: Total length :

16 Summer School 2007B. Rossetto16 1. Applications (3) 1 – Surface of a triangle (base b, height: h) b f(x)=px pb=h x 0 h 2 – Surface of the ellipse 0 a b dA= A= Contribution of the infinitesimal surface dy.dx : dA = Equation:

17 Summer School 2007B. Rossetto17 1. Applications (3) 1 – Surface of a triangle (base b, height: h) b f(x)=px pb=h x 0 h 2 – Surface of the ellipse 0 a b Area: Contribution of the infinitesimal surface dy.dx : dA = dy.dx

18 Summer School 2007B. Rossetto18 1. Applications (4)  x y z  Cylinder area 0 r x y z 0 dz h rd 1 - Double integral: contribution of the element of length r d height dz: rddz 2 - Simple integral: contribution of the element of length 2r height: dz: 2rdz dz dA= A= dA= A=

19 Summer School 2007B. Rossetto19 1. Applications (4)  x y z  Cylinder area 0 r x y z 0 dz h rd 1 - Double integral: contribution of the element of length r d height dz: dA=rddz 2 - Simple integral: contribution of the element of length 2r height: dz: dA=2rdz dz

20 Summer School 2007B. Rossetto20 1. Applications (5)   r sin  x y z rd r length: 2 r sin, width: r d Total area: A=  Sphere area using symetries (simple integral): contribution of the element:  Sphere area using double integral Contribution of the element lenght : r sin d, width: r d r sin  0 0  r rd rsind Area : A = sum of contributions dA=

21 Summer School 2007B. Rossetto21 1. Applications (5)   r sin  x y z rd r length: 2 r sin, width: r d dA = 2 r 2 sin d Total area:  Sphere area using symetries (simple integral): contribution of the element:  Sphere area using double integral Contribution of the element lenght : r sin d, width: r d r sin  0 0  r rd rsind dA = r 2 sin d d

22 Summer School 2007B. Rossetto22 1. Applications (6)  r r sin  x y z r d r sin d r  Sphere volume (or mass if homogeneous) Contribution of the element length : r sin d weidth : r d height : dr r sin  0 0  

23 Summer School 2007B. Rossetto23 1. Applications (6)  r r sin  x y z r d r sin d r  Sphere volume (or mass if homogeneous) Contribution of the element length : r sin d weidth : r d height : dr r sin  0 0  

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