Article citationsMore>>
Ballard, S., Fabrycky, D., Fressin, F., Charbonneau, D., Desert, J.-M., Torres, G., Marcy, G., Burke, C.J., Isaacson, H., Henze, C., Steffen, J.H., Ciardi, D.R., Howell, S.B., Cochran, W.D., Endl, M., Bryson, S.T., Rowe, J.F., Holman, M.J., Lissauer, J.J., Jenkins, J.M., Still, M., Ford, E.B., Christiansen, J.L., Middour, C.K., Haas, M.R., Li, J., Hall, J.R., McCauliff, S., Batalha, N.M., Koch, D.G. and Borucki, W.J. (2011) The Kepler-19 System: A Transiting 2.2 R⊕ Planet and a Second Planet Detected via Transit Timing Variations. The Astrophysical Journal, 743, 200.
https://doi.org/10.1088/0004-637X/743/2/200
has been cited by the following article:
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TITLE:
A Simulation of Transit Timing Variation
AUTHORS:
Ziyue Zeng
KEYWORDS:
Exoplanet, Transit Timing Variation, Transit Timing, Kepler-19 System
JOURNAL NAME:
Journal of Applied Mathematics and Physics,
Vol.7 No.8,
August
23,
2019
ABSTRACT: Exoplanet transit timing variation is a method to find exoplanets. To understand this method better, I wrote a computer program in python to simulate the transit of exoplanets. I use my program to simulate the transit timing variation observed in the Kepler-19 system. I make a simple simulation of Kepler-19 system, and this simulation shows that the variation in transit timing due to other planets is very obvious for Kepler-19b, the transiting planet, which means the transit timing variation method is very useful for finding exoplanet in Kepler-19 system. The whole paper is an illustration for that. The simulation I make is relatively simple but it still corresponds to the law of TTV, and because of its simplicity, it can help more people understand.
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