1. 星網計劃 The NETS Project: The NEtwork of Transit Survey 江瑛貴 Ing-Guey Jiang National Tsing-Hua Univ., Taiwan

2. Outline 1.Introduction 2.Why transit ? 3.Why another transit survey ? 4.Tsing-Hua Station 5.The Previous Progress 6.The Next Step

6. Why Transit ? It is simple & fast can scan more stars It can determine the planetary orbital plane And also size & mass of planets It could be done by smaller telescopes So, the cost is low The timing of transit might be useful

8. TrES Network The Trans-atlantic Exoplanet Survey (TrES) Wide-field photometric surveys by small telescopes Maximizing the monitered stars Minimizing the time required of large telescopes 3 small telescopes (10 cm) at (1) Tenerife, Spain; (2) Lowell Observatory, Arizona; (3) Mount Palomar, California field of view: 6 degree Spatial resolution: 11 arcsec/pixel

9. TrES-2

10. HAT-P-9b HAT: Hungarian-made Automated Telescope NATnet: 6 small (11 cm), wide field (8 by 8 deg) telescpes Data was taken in 2004 and 2005 Transit was found from data Then, do following up

13. Why Another Transit Survey ? The current on-going projects can only monitor up to a few tens thousand stars To do a better job, we hope to monitor 10,000,000 (for 7 cm telescope) or 160,000,000 (for 12 cm telescope) stars This will improve the statistics in the field of exoplanets We hope to constrain long period exoplanets, too We need a lot of time but small telescopes

14. Another Way of Sky Survey ? Permanent non-tracking fixed telescopes Drift Scan Scan stars while the Earth Rotating Can monitor much more stars automatically Use an array of telescopes to continue the monitoring It only suitable for certain events if the time scales are right Data analysis is slightly more complicated

15. Would we miss any planets ? Yes, but … (comparing with other projects) For short period planets, the transit event would repeat. We will detect them finally. For long period planets, the transit probability is much lower, so need to scan much more stars. We get some constraints on the number of possible planets with longer periods

16. Tsing-Hua Station

21. Image Taken at Tsing-Hua

22. Preliminary Analysis Sky Backgroud 3000 ADU Many stars have 40000 to 50000 ADU So, S/N is more than 10 It is possible to do observations at Tsing-Hua Station Flux variation is about several percent The same order as O’Donovan et al. (2006)

23. a light curve

24. The Previous Progress Oct. 2006: A prototype CCD-lens system is constructed Jan. 2007: It took some testing data at Lulin Feb. 2007: Starting the code development for data analysis (on going) March 2007: Starting to plan the enclosure April 2007: Observe with other telescopes Oct. 2007: Theoretical Modeling of light curve

36. The More Previous Progress July 2007: Weather Station arrived Aug. 2007: WebCam (USB and PCI) Nov. 2007: New Computer Dec. 2007: Constructing the Enclosure March 2008: Code for Enclosure Control June 2008: CCD Install Nov. 2008: Tsing-Hua Station Working

37. The Automatic Observation Setting the time interval of observation Open the enclosure on time Only open when weather & UPS are o.k. Start CCD whenever the enclosure is open Stop CCD, stop taking images Close due to weather condition, UPS Close and stop observation when time is up

38. The Weather: Humidity

39. The Weather: Temperature

40. Enclosure Testing

41. The Next Step Developing the data pipeline Developing the codes With the HAT results and our testing data, it is feasible. We shall prepare to construct an oversea station, which will lead to scientific data We shall think/talk about following up facilities