Three parameters describe the characteristics
of a planetary transit:
- the period of recurrence of the transit;
- the duration of the transit.and
- the fractional change in brightness of the
star.
The Planet's Orbital Period
The period, P, is used to determine
the semi-major axis, a, given that the stellar mass, M*,
is known from the spectral type of the star. Kepler's Third Law
is used to calculate the semi-major axis:
The Transit Duration
For transits across the center of the star
the transit duration is given by:
 ,
where d* is the stellar diameter in
solar diameters, M* is the stellar mass in solar masses
and a is the orbital semi-major axis in AU. The duration
does not tell us anything physically about the planet. However,
like the transit depth, the duration must by consistent for all
the transits of a given planet-star combination. If not, then
one suspects that there are multiple planets in the system that
are being detected or some other non-transit phenomena is taking
place.
The Transit Depth, i.e., the Planet's Size
The fractional change in brightness or transit
depth is equal to the ratio of the area of the planet to the
area of the star. This measurement is used to calculate the size
of the planet given that the size of the star is known from its
spectral type.
The table below lists the duration
and transit depth (equal to the ratio of the planet area to the
area of the Sun) for several cases. Single transits of giant
planets have depths on the order of 1%. These transits are so
large that follow-up verification can be done from the ground.
Transit Properties of Solar System Objects
| Planet |
Orbital
Period
P (years) |
Semi-
Major Axis
a (A.U.) |
Transit
Duration
(hours) |
Transit
Depth
(%) |
Geometric
Probability
(%) |
Inclination
Invariant Plane
(deg) |
| Mercury |
0.241 |
0.39 |
8.1 |
0.0012 |
1.19 |
6.33 |
| Venus |
0.615 |
0.72 |
11.0 |
0.0076 |
0.65 |
2.16 |
| Earth |
1.000 |
1.00 |
13.0 |
0.0084 |
0.47 |
1.65 |
| Mars |
1.880 |
1.52 |
16.0 |
0.0024 |
0.31 |
1.71 |
| Jupiter |
11.86 |
5.20 |
29.6 |
1.01 |
0.089 |
0.39 |
| Saturn |
29.5 |
9.5 |
40.1 |
0.75 |
0.049 |
0.87 |
| Uranus |
84.0 |
19.2 |
57.0 |
0.135 |
0.024 |
1.09 |
| Neptune |
164.8 |
30.1 |
71.3 |
0.127 |
0.015 |
0.72 |
| |
P2M*= a3 |
13 sqrt(a) |
%=(dp/d*)2 |
d*/D |
phi |
Note: M* is in solar masses Mo, dp is
the diameter of the planet. Pluto has been ignored.
Signal-to-Noise Dependence
Our instrument is designed to produce an SNR=8
sigma for an Earth-size planet orbiting an mv=12 solar-like star with 4 near-grazing transits having
a duration of 6.5 hrs. The signal-to-noise (SNR) varies as (nt)1/2, where t is the transit
duration and n is the number of transits which equals
the mission life divided by the orbital period. Thus, for a given
star and using Kepler's third law, the SNR relative to that at
1 AU, SNR1AU,
increases with decreasing a as a-1/2:
Geometric Probability
Transits can only be detected if the planetary
orbit is near the line-of-sight (LOS) between the observer and
the star. This requires that the planet's
orbital pole be within an angle of d*/a (part 1 of the
figure below) measured from the center of the star and perpendicular
to the LOS, where d* is the stellar diameter (= 0.0093
AU for the Sun) and a is the planet's orbital radius.
This is possible for all 2pi angles
about the LOS, i.e., for a total of 4pi d*/2a steradians
of pole positions on the celestial sphere (part 2 of figure).
Thus the geometric probability for seeing
a transit for any random planetary orbit is simply d*/2a
(part 3 of figure) (Borucki and Summers, 1984, Koch and Borucki,
1996).
For the Earth and Venus this is 0.47% and
0.65% respectively (see above Table). Because grazing transits
are not easily detected, those with a duration less than half
of a central transit are ignored. Since a chord equal to half
the diameter is at a distance of 0.866 of the radius from the
center of a circle, the usable transits account for 86.6% of
the total. If other planetary systems are similar to our solar
system in that they also contain two Earth-size planets in inner
orbits, and since the orbits are not co-planar to within 2d*/D,
the probabilities can be added. Thus, approximately 0.011 x 0.866
= 1% of the solar-like stars with planets should show Earth-size
transits.
Probability for Detection of Multiple Planets Per System
Current models for planetary system formation
assume that the planets are formed out of a common nebula with
the star and that the orbital planes should have small relative
inclinations. For the solar system, these inclinations are on
the order of a few degrees (see table above). Similarly, the
inclinations are also small for the inner moons of Jupiter, Saturn
and Neptune. If one were to view the system near either node
of the intersection of the orbital planes of two planets, then
both planets would be observed. For small relative inclinations
of the planes, (phi1 + phi2) < d*/a, both planets would always
be observed, and for (phi1 + phi2)/ >= d*/a the probability
for seeing a second planet in the system is given by (Koch and
Borucki, 1996):
For the Venus-Earth combination, there is
a 12% chance of seeing both planets. Thus, there appears to be
a significant chance that multiple-planetary systems can be seen.
This result should lead to a further refinement of the models
that describe both the frequency of planet formation as well
as the co-planarity of their orbits.
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