secular perturbations -eccentric and mean anomalies -kepler’s equation -f,g functions -universal...
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Secular Perturbations
-Eccentric and Mean anomalies-Kepler’s equation-f,g functions -Universal variables for hyperbolic and eccentric orbits-Disturbing function-Low eccentricity expansions for Disturbing function-Secular terms at low eccentricity-Precession of angle of perihelion-Apsidal resonance-Pericenter glow models for eccentric holes in circumstellar disks
(Created by: Zsolt Sandor & Peter Klagyivik,
Eötvös Lorand University)
r
a
f = true anomaly
f
Ellipse
b
center of ellipse
Sun is focal pointb=semi-minor axisa=semi-major axis
Relationship between Eccentric, True and Mean anomalies
• Using expressions for x,y in terms of true and Eccentric anomalies we find that
So if you know E you know f and can find position in orbit
Write dr/dt in terms of n, r, a, e Then replace dr/dt with function depending on E, dE/dt
Mean Anomaly and Kepler’s equation
• New angle M defined such that or • Integrate dE/dt finding
Kepler’s equationMust be solved to integrate orbit in time.
The mean anomaly is not an angle defined on the orbital planeIt is an angle that advances steadily in time It is related to the azimuthal angle in the orbital plane, for a circular orbit, the two are the same and f=M
– Change t, increase M. – Compute E numerically using Kepler’s equation– Compute f using relation between E and f– Rotate to take into account argument of perihelion– Calculate x,y in plane of orbit– Rotate two more times for inclination and longitude of ascending node
to final Cartesian position
Kepler’s equationMust be solved to integrate orbit in time.
Procedure for integrating orbit or for converting orbital elements to a Cartesian position:
Inclination and longitude of ascending node
• Sign of terms depends on sign of hz.• I inclination.
– retrograde orbits have π/2<I<π– prograde have 0<I<π/2
• Ω longitude of ascending node, where orbit crosses ecliptic
• Argument of pericenter ω is with respect to theline of nodes (where orbit crosses ecliptic)
h angular momentum vector
Orbit in space• line of nodes: intersection of
orbital plane and reference plane (ecliptic)
• Longitude of ascending node Ω: angle between line of nodes (ascending side) and reference line (vernal equinox)
• ω “argument of pericenter” is not exactly the same thing as we discussed before ϖ – longitude of pericenter. ω is not measured in the ecliptic. ϖ=Ω+ω but these angles not in a plane unless I=0 Anomaly : in orbital plane and w.r.t. pericenter
Longitude: in ecliptic w.r.t. vernal equinoxArgument: some other angle
Orbit in space
Rotations• In plane of orbit by argument of pericenter ω in
(x,y) plane• In (y,z) plane by inclination I• In (x,y) plane by longitude of ascending node Ω• 3 rotations required to compute Cartesian
coordinates given orbital elements
Cartesian to orbital elements
• To convert from Cartesian coordinates to Orbital elements:– Compute a,e using energy and angular momentum– Compute inclination and longitude of ascending node
from components of angular momentum vector– From current radius and velocity compute f– Calculate E from f– Calculate M from numerical solution of Kepler’s equation– Calculate longitude of perihelion from angle of line of
nodes in plane of orbit
The angular momentum vector
relation between inclination, longitude of ascending node and angular momentum.Convention is to flip signs of hx,hy if hz is negative
Force
• component perpendicular to orbital plane
• component in orbital plane perpendicular to r
• component along radiusorthogonal coordinate system
Torque
Fr contributes no torqueTo vary |h| a torque in z direction is need, only depends on Fθ - only forces in the plane vary eccentricityTo vary direction of h a force in direction of z is needed
instantaneous variationsOften integrated over orbit to estimate precession rate
f and g functions
• Position and velocity at a later time can be written in terms of position and velocity at an earlier time. Numerically more efficient as full orbital solution not required.
Differential form of Kepler’s equationProcedure for computing f,g functions
• Compute a, e from energy and angular momentum.
• Compute E0 from position• Compute ΔE by solving
numerically the differential form of Kepler’s equation.
• Compute f,g, find new r.• Compute • One of these could be
computed from the other 3 using conservation of angular momentum
Subtract Kepler’s equation at two different times to find:
)
Universal variables• Desirable to have integration
routines that don’t require testing to see if orbit is bound.
• Converting from elliptic to hyperbolic orbits is often of matter of substituting sin, cos for sinh, cosh
• Described by Prussing and Conway in their book “Orbital Mechanics”, referring to a formulation due to Battin.
x is determined by Solving a differential form of Kepler’s equation in universal variables
Differential Kepler’s equation in universal variables
• x solves (universal variable differential Kepler equation
• Special functions needed:
Solving Kepler’s equation
• Iterative solutions until convergence• Rapid convergence (Laguerre method is cubic)• Only 7 or so iterations needed for double
precision (though this could be tested more rigorously and I have not written my routines with necessarily good starting values).
Orbital elements
• a,e,I M,ω,Ω (associated angles)• As we will see later on action variables related to the
first three will be associated with action angles associated with the second 3.
• For the purely Keplerian system all orbital elements are constants of motion except M which increases with
• Problem: If M is an action angle, what is the associated momentum and Hamiltonian?
Keplerian Hamiltonian
• Problem: If M is an action angle, what is the associated action momentum and Hamiltonian?
• Assume that • From Hamilton’s equations
• Energy
Keplerian Hamiltonian
• Solving for constants
• Unperturbed with only 1 central mass• We have not done canonical transformations to do
this so not obvious we will arrive exactly with these conjugate variables when we do so.
Working in Heliocentric coordinates• Consider a central stellar mass M*, a planet mp and a third low
mass body. “Restricted 3 body problem” if all in the same plane
• We start in inertial frame (R*, Rp, R) and then transform to heliocentric coordinates (rp, r)
Replace accelerations in inertial frame with expressions involving acceleration of star.Then replace acceleration of star with thisso we gain a term
Disturbing function
New potential, known as a disturbing function – due to planetGradient w.r.t to r not rp
Direct termIndirect term -- because planet has perturbed position of Sun and we are not working an inertial frame but a heliocentric one—
- Reduces 2:1 resonance strength. - Contributes to slow m=1 eccentric modes of self-gravitating disks
Force from Sun
Direct and Indirect terms
• For a body exterior to a planet it is customary to write
• For a body interior to a planet:
• In both cases the direct term• Convention ratio of semi-major axes
Lagrange’s Planetary equations
• One can use Hamilton’s equations to find the equations of motion
• If written in terms of orbital elements these are called Lagrange’s equations
• These are time derivatives of the orbital elements in terms of derivatives of the disturbing function
• To relate Hamilton’s equations to Lagrange’s equations you can use the Jacobian of derivatives of orbital elements in terms of Poincare coordinates
Secular terms
• Expansion to second order in eccentricity • Neglecting all terms that contain mean longitudes• Should be equivalent to averaging over mean anomaly• Indirect terms all involve a mean longitude so average to zero
Laplace coefficients which are a function of α
I have dropped terms with inclination here – there are similar ones with inclination
Similar term for other body
Evolution in e
• Lagrange’s equations (ignoring inclination)
• Convenient to make a variable change
• Writing out the derivatives
Equations of motion• For two bodies
• With solutions depending on eigenvectors es,ef and eigenvalues gs,gf of matrix A (s,f: slow and fast)
– Slow: both components of eigenvector with same sign, – Fast: components of eigenvector have opposite sign
Both objects
ef,1
ef,2
es,1
es,2
Anti aligned, fast, Δϖ=π Aligned and slow, Δϖ=0
apsidal alignment
How can angular momentum be conserved with this?
Predicting evolution from orbital elements
• Unknowns – magnitudes of the 2 eigenvectors– 2 phases
• From current orbital elements
Animation of the eccentricity evolution of HD 128311
(Created by: Zsolt Sandor & Peter Klagyivik, Eötvös Lorand University)
Both together in a differential coordinate system
radius = e1e2
Slow only
Apsidal aligned, non circulating, can have one object with nearly zero eccentricity. “Libration”
Circulating
fast only
Note orbits on this plot should not be ellipses
Examples of near separatrix motionFor exatrasolar planets
Libration Circulation
In both cases one planet drops to near zero eccentricity
ee
ΔϖΔϖ
Time Time
one planet
different lines consistent with data
Simple Hamiltonian systemsTerminology
2( , ) cos( )
2
pH p K
2 2( , ) ( , )
2 2
is constant
0 is conserved
p qH p q H I I
H dI dtH dI
Idt
Harmonic oscillator
Pendulum
Stable fixed point
Libration
Oscillationp
Separatrix
pq
I
Multiple planet systemsRV systems
• No obvious correlation mass ordering vs semi-major axis• Mostly 2 planets but some with 3, 5• Eccentric orbits, but lower eccentricity than single planet
systems• Rasio, Ford, Barnes, Greenberg, Juric have argued that
planet scattering explains orbital configurations• Subsequent evolution of inner most object by tidal forces• Many systems near instability line• Lower eccentricity for multiple planet systems• Lower mass systems have lower eccentricities
Mass and Eccentricity distribution of multiple planet systems
High eccentricity planets tend to reside in single planetary systems
Hamiltonian view
massless object near a single planet
Fixed point at Aligned with planetEccentricity does not depend on planet mass but does on planet eccentricity
Poincaré momentum
μ = mp/M*
-
Expand around fixed point
• First transfer to canonical coordinates using h,k• Then transfer to coordinate system with a shift
h’=h-hf, k’=k-kf
• Harmonic motion about fixed point: that’s the free eccentricity motion
Free and Forced eccentricity
• Massless body in proximity to a planet
eforced
efreeForce eccentricity depends on planet’s eccentricity and distance to planet but not on planet’s mass.Mass of planet does affect precession rate.Free eccentricity size can be chosen.
Multiple Planet systemHamiltonian view
• Single interaction term involving two planets• All semi-major axes and eccentricities are
converted to mometa• Three low order secular terms, involving Γ1,Γ2,
(Γ1Γ2)1/2
• Hamilton’s equation give evolution consistent with two eigenvectors previously found.
More generally on epicyclic motion
Low epicyclic amplitude expansion
For a good high epicyclic amplitude approximation see a nice paper by Walter Dehnen using a second order expansion but of the Hamiltonian times a carefully chosen radial function
As long as there are no commensurabilities between radial oscillation periods and orbital period this expansion can be carried out
Low eccentricity Expansions
• Functions of radius and angle can be written in terms of the Eccentric anomaly
is an odd function
Bessel function of the first kind
This can be shown by integrating and using Kepler’s equation (see page 38 M+D)
Low eccentricity expansions continued
found by integrating Fourier coefficients by parts and using integral forms for the Bessel function
Expansion of the Disturbing function
• in plane
if
writing the dot product in terms of orbital angles
ψ angle between defined here
Angular factors
• When inclination is not zero we define
• Ψ is small if inclinations are small and can be expanded in powers of the sin of the inclinations
Expansion of the disturbing function -Continued
• Expand the disturbing function as a series of
times inclinations, angular factors and some radii• Use low eccentricity and inclination expansions for
these factors• Expand powers of Δ0 in terms of powers of ρ0
assuming that
these are satisfied at low eccentricity
Laplace coefficients
• This is a Fourier expansion
• These are called Laplace coefficients, closely related to elliptic functions
• Can be evaluated by series expansion in α or in 1-α• They diverge as α 1
separating the radial information from the angle information
Expansion of Disturbing function
• Disturbing function is written in terms of an expansion of derivatives of Laplace coefficients and cosines of arguments
First term!
• Useful relations can be found by manipulating the integral definition of the Laplace coefficients, e.g.
for j=0
SimplificationUsing relations between coefficients derived by Brouwer & Clemens
As we used in our discussion of secular perturbations
Using them we find that secular low order secular terms are
More generally
• Expanding the disturbing function in terms of Poincare coordinates
• D’Alembert rules– flipping signs of all angles preserves series so only
cosines needed– rotating coordinate system preserves series
Expansion of the Disturbing functionIn Summary
Expansion of the disturbing function assuming• low eccentricities, low inclinationsRadial factors written in terms of Laplace
coefficients and their derivativesEach argument and order of e,i gives a functionBoth direct and indirect terms can be expandedExpansion functions listed in appendix by M+D
Reading:
• Murray and Dermott Chap 2• Murray and Dermott Chap 6,7• Prussing and Conway Chap 2 on universal variables• Wright et al. 2008, “Ten New and Updated Multi-planet
Systems, and a Survey of Exoplanetary Systems” astroph-arXiv:0812.1582v2
• Malhotra, R. 2002, ApJ, 575, L33, A Dynamical Mechanism for Establishing Apsidal Resonance
• Barnes and Greenberg, “Extrasolar Planet Interactions”, astro-ph/0801.3226