mathematics of the cassini’s journey to saturn
DESCRIPTION
MATHEMATICS OF THE CASSINI’S JOURNEY TO SATURN. Michael P. Wnuk NASA Visiting Scientist at Jet Propulsion Laboratory/ California Institute of Technology. Launch of Cassini on October 15, 1997 Two-stage rockets Titan IV-B and Centaur are used. - PowerPoint PPT PresentationTRANSCRIPT
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Michael P. Wnuk
NASA Visiting Scientist at Jet Propulsion Laboratory/ California Institute of
Technology
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Launch of Cassini on October 15, 1997Two-stage rockets Titan IV-B and Centaur are used
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Assembling the spacecraft at JPL/Caltech, Pasadena, California
8Cassini spacecraft
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CASSINI AT SATURN
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2cassini
9362 129 117
129 9652 52 kg m
117 52 3982
I
2
9314 0 0
0 9703 0 kg m
0 0 3978diaI
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Mathematical representation of rigid body motion with 6 degrees of freedom
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CCONTENTS 1. Introduction. An Overview of Cassini Mission - Cassini as a Link Between Newton’s Orbital Mechanics and the Space Exploration Program in 21st Century 2. Numbers, Functions and Operators- Numbers, - Functions,- Operators,- Differential Equations3. Calculus Underlying Orbital Mechanics- Motion in the central force field- Orbits of planets and spaceships- Navigating the Spaceship 4. Scalars, Vectors, Quaternions, Matrices and Tensors- Scalars that describe Cassini mission- Vectors and quaternions pertinent to the mission- Matrices and tensors applicable to the mission
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Orbital and escape velocities
• First two cosmic constants
1/ 2 1/ 2 1/ 26
2
0
9.81 6.37*10 7.91 / sec sec
E Eorb
E E h
GM gR m kmv m
R h h R
1/ 2
1/ 2
1176
211.187
sec
2 19.0310.29
1.85 sec sec
Eesc
E h o
fly by Eesc
E h km
GM kmv
R h
GM km kmv
R h
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Decrease of the orbital and escape velocity with an increasing distance from Earth
• Velocity (orbital or escape) at the Earth’s surface is assumed as the normalization constant
0 5 10 15 200.2
0.4
0.6
0.8
1
F x( )
x
1/ 2
2
1 /E
escE
gRv
h R
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Other constants pertinent to Orbital Mechanics
• Escape from the solar system/ escape from our galaxy
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8 3 1 2
7.9 , 11.2 , 16 , 150sec sec sec sec
29.8sec
250sec
150 , 5.97224*10 , 6370 ,sec
6.67422*10 , 6370 , 6378.1
I II III IV
orbitalEarth
galacticSS
IV E E
ave equatorial
geosynch
km km km kmv v v v
kmv
kmv
kmv M g R km
G cm g s R km R km
h
1135,785.9 , 10 , 318 , 100galaxy sun jupiter earth saturn Ekm M M M M M M
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The original sketch drawn by Jean-Dominique Cassini in 1676 (top), and the picture of Saturn received via radio signal from Voyager 2 in 1981 (bottom).
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The original sketch drawn by Jean-Dominique Cassini in 1676 (top), and the picture of Saturn received via radio signal from Voyager 2 in 1981 (bottom).
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Saturn as seen by Cassini’s camera, December 2007
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A swing-by event by the Cassini spacecraft required an encounter with the planet Earth. Cassini’s altitude at the point of closest approach was 1176 km above the surface of Earth, less than the altitude of geostationary communication satellites that orbit Earth at 35,786 km above the sea level. The speed of Cassini spacecraft, though, equaled then 19.03 km/s, which exceeded the escape velocity at this particular height (10.29 km/sec) by a factor of 1.85.
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Our own planet and the Cassini spaceship during the “swingby” maneuver on August 18, 1999.
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Closest approach to Venus for a gravitational assist maneuver on April 26, 1998.
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Jupiter Fly-by on December 30, 2000
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Equation of the transfer ellipse:
1 2 1 cos
Radius of the outer circular orbit, which is the geostationary orbit, Rg= 42,164.1 km.
Radius of the parking orbit, Rp= 14,984.3 km.
Eccentricity of the transfer orbit is defined by the second Carl constant.
Ratio of radii of geostationary and parking orbits is very close to the Euler number e=2.718281828.
Transfer maneuver using Carl elliptical orbitTransfer maneuver using Carl elliptical orbit involving involving eccentricity that equals the second Carl constant, eccentricity that equals the second Carl constant, ..
Transfer maneuver using Carl elliptical orbitTransfer maneuver using Carl elliptical orbit involving involving eccentricity that equals the second Carl constant, eccentricity that equals the second Carl constant, ..
second Carl constant
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Examples of application of first two Carl constants.Examples of application of first two Carl constants.The shape of the transfer orbits is determined The shape of the transfer orbits is determined
by the Carl eccentricities, S and by the Carl eccentricities, S and ..
Examples of application of first two Carl constants.Examples of application of first two Carl constants.The shape of the transfer orbits is determined The shape of the transfer orbits is determined
by the Carl eccentricities, S and by the Carl eccentricities, S and ..
Eccentricities of the transfer orbits are either S or
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MGB[$] = English pounds MPL[$] = Polish zloties
MDE[$] = German marks MSL[$] = Slovenian tolars
MI[$$] = Italian liras MF[$$] = French francs
MRU[$] = Russian rubles MMX[$] = Mexican dollars
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BBlack box representation of the action oof a function (a), and an operator (b).
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INPUT OUTPUT
Concept of an operator, W, and an inverse operator, W–1.
Operator W(wicked witchin bad mood)
W
Operator W–1
(wicked witchin good mood)
W–1
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Population increase over three characteristic time intervals according to Eq. (6). Note that the starting number was 10, while the characteristic time T = 9 months.
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A decaying wave-form is the solution of the differential equation subject to the initial conditions x(0)=0 and v(0)=1. Note that the wave is contained within an exponentially decreasing envelope
35Velocity of the vibratory system consistent with the solution of the differential equation, shown here as a function of time.
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Damper
C
k
Mass
x
Fext
m
c
cdx/dt kx
mC
x
Fext
Free body diagramrevealing all forces
Block of mass m suspended on a spring and a viscous damper and set into a vibratory motion
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Two functions are shown x1(t) and x2(t). They resulted as the solutions to
the initial value problem and the boundary values problem, respectively. Note that they both satisfy the second order differential equation (8).
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Polar coordinates used to describe motion under central force condition. Quantities shown in (a) are used to define the initial conditions, while (b) shows two unit vectors aligned with the radial and transverse axes, er and e.
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Newtonian Orbital Mechanics (1)
• Acceleration vector along trajectory
( ) r
d dr da t e r e
dt dt dt
22 2
2 2( ) 2r
d r d d dr da t r e r e
dt dt dt dt dt
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Newtonian Orbital Mechanics (2)
• Governing differential equations
2 22
2 2
2
22 0
EgRd r dr
dt dt r
d dr drdt dt dt
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Newtonian Orbital Mechanics (3)
• Two DE equations reduce to just one equation
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2 20 0
EgRd uu
d r v
1( )
( )u
r
2
2 20 0
( ) sin cos EgRu A B
r v
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Newtonian Orbital Mechanics (4)
• Solutions depend on the eccentricity and they turn out to be conical sections
0
2 20 0
2
(1 )( )
1 cos
1E
rr
r v
gR
43=0 circle, =1 parabola, 0<<1ellipse, >1 hyperbola
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Example of perturbation of an elliptical orbit of a planetoid (or a spacecraft) circling the Sun caused by an interaction with Earth’s gravitational field. This so-called “close encounter” event visibly alters the original orbit, as seen by the segment ABCD of the trajectory depicted in the figure. A “three body problem” has to be considered between points A and D, where an exchange of the mutual forces between three objects (Sun, Earth and the planetoid) must be accounted for. The closed form solution to such a problem is not available. In the Cassini mission this situation occurs each time the spaceship enters the “sphere of influence” of another planet on its path, such as Earth, Venus and Jupiter, which are used to accomplish a gravitational assist maneuver.
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Transition from order to chaosDEMO
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Phase diagram for a dynamic system consisting of a nonlinear pendulum subjected to viscous damping , and governed by the following nonlinear differential equation of the second order: d2/dt2 = -sin- d/dt. The graph is “well-behaved” and there is no indication of any instabilities or chaotic behavior.
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This viewgraphs shows the phase diagrams when we deal with chaos, i.e., when the amplitude f is greater than the critical value of 1.87. Yet, in this totally chaotic type of motion, it is possible to find order at a deeper level (as revealed by the existence of an attractor, see the next Viewgraph).
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Existence of the attractor, though, is indicative of the certain rules that apply to this chaotic motion. Attractor shown here is an example of a Poincare section, which has a fractal dimension of 2.52.
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YAW
i j
x
PITCH
P
P’
ROLLy
O
k
Cartesian coordinate system (x, y, z) with the corresponding unit vectors (i, j, k). A vector PP’ can be represented by its components [PP’x , PP’y , PP’z], or by this equation: PP’ = (PP’x)i + (PP’y)j + (PP’z)k. If plane (x, y) is chosen as the plane in which Earth circles the Sun, the (x, y, z) coordinates shown here represent J2000 inertial reference frame. Unit vector h and the rotation q are used to define a quaternion.
51Entities used in navigation of a spacecraft.
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MATHEMATICSOF THE CASSINI’S
JOURNEY TO SATURN
(1997 – 2004…2010)
Michael P. WnukNASA Visiting Scientist at JPL/Caltech
July 2000
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SSuggested Reading John A. Wood, 1979, “The Solar System”, publ. by Prentice-Hall, New Jersey.2 Anthony Bedford and Wallace Fowler, 1995, “Engineering Mechanics – Dynamics”, publ. by Addison-Wesley, USA.3 David A. Vallado and Wayne D. McClain, 1997, “Fundamentals of Astrodynamics and Applications”, in Space Technology Series, publ. by McGraw-Hill, USA.4 Michael P. Wnuk and Carl Swopes, 1999, “From Pyramids and Fibonacci Sequence to the Laws of Chaos”, publ. by Akapit Publishers, Krakow, Poland.5 Levin Santos, 2000, “Weighing the Earth. Physicists Close in on Newton’s Big G” in the “Sciences”, July/August 2000, publ. by New York Academy of Sciences, p.11.
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