• 천문학회보
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• 제41권1호
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• pp.54.1-54.1
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• 2016

Multi-wavelength variability is a staple of active galactic nuclei (AGN). Optical variability probes the nature of the central engine of AGN at smaller linear scales than conventional imaging and spectroscopic techniques. Previous studies have shown that optical variability is more prevalent at longer timescales and at shorter wavelengths. Intra-night variability can be explained through the damped random walk model but small samples and inhomogeneous data have made constraining this model hard. To understand the properties and physical mechanism of intra-night optical variability, we are performing the KMTNet Active Nuclei Variability Survey (KANVaS). Using KMTNet, we aim to study the intra-night variability of ~1000 AGN at a magnitude depth of ~19mag in R band over a total area of ${\sim}24deg^2$ on the sky. Test data in the COSMOS, XMM-LSS, and S82-2 fields was obtained over 4, 6, and 8 nights respectively during 2015, in B, V, R, and I bands. Each night was composed of 5-13 epoch with ~30 min cadence and 80-120 sec exposure times. As a pilot study, we analyzed data in the COSMOS field where we reach a magnitude depth of ~19.5 in R band (at S/N~100) with seeing varying between 1.5-2.0 arcsec. We used the Chandra-COSMOS catalog to identify 166 AGNs among 549 AGNs at B<23. We performed differential photometry between the selected AGN and nearby stars, achieving photometric uncertainty ~0.01mag. We employ various standard time-series analysis tools to identify variable AGN, including the chi-square test. Preliminarily results indicate that intra-night variability is found for ~17%, 17%, 8% and 7% of all X-ray selected AGN in the B, V, R, and I band, respectively. The majority of the identified variable AGN are classified as Type 1 AGN, with only a handful of Type 2 AGN showing evidence for variability. The work done so far confirms there are more variable AGN at shorter wavelengths and that intra-night variability most likely originates in the accretion disk of these objects. We will briefly discuss the quality of the data, challenges we encountered, solutions we employed for this work, and our updated future plans.

• 한국측량학회지
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• 제32권5호
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• pp.539-550
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• 2014

고해상도 위성영상은 정밀한 DEM과 지형도를 제작하기 위해서 지상기준점으로 기하학적인 처리와 보정이 이루어져야만 한다. 우리나라에는 국토지리정보원에 의해 수천 개의 국가 통합기준점이 국토 전역에 걸쳐 설치되고 분포되어 있다. 따라서 통합기준점은 국토지리정보원의 국가기준점발급시스템에서 쉽게 검색되고 다운로드 받을 수 있다. 본 연구는 웹 포털사이트의 스카이뷰와 로드뷰를 이용하여 영상에서 통합기준점 검색과 식별 방법을 제시하였다. 그리고 고해상도 위성영상의 RPC 보정을 위한 통합기준점 효용성을 분석하기 위해, 한 개 통합기준점(영상의 단순 이동 보정용 기준점으로 활용함) 만으로 KOMPSAT-3 영상의 제공 RPC를 보정하였다. 그 결과, RPC 보정후의 위치결정 오차는 거의 한 화소와 1m 내외를 보였다. 이 실험을 통해, 위성 또는 항공영상에 의한 매핑 작업을 통합기준점이 지상 기준점 측량을 대체할 수 있을 것이다.

• Journal of Astronomy and Space Sciences
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• 제33권3호
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• pp.185-196
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• 2016

New multiband BVRI light curves of NSVS 1461538 were obtained as a byproduct during the photometric observations of our program star PV Cas for three years from 2011 to 2013. The light curves indicate characteristics of a typical W-subtype W UMa eclipsing system, displaying a flat bottom at primary eclipse and the O'Connell effect, rather than those of an Algol/b Lyrae eclipsing variable classified by the northern sky variability survey (NSVS). A total of 35 times of minimum lights were determined from our observations (20 timings) and the SuperWASP measurements (15 ones). A period study with all the timings shows that the orbital period may vary in a sinusoidal manner with a period of about 5.6 yr and a small semi-amplitude of about 0.008 day. The cyclical period variation can be interpreted as a light-time effect due to a tertiary body with a minimum mass of 0.71 M_⊙. Simultaneous analysis of the multiband light curves using the 2003 version of the Wilson-Devinney binary model shows that NSVS 1461538 is a genuine W-subtype W UMa contact binary with the hotter primary component being less massive and the system shows a low mass ratio of q(m_c/m_h)=3.51, a high orbital inclination of 88.7°, a moderate fill-out factor of 30 %, and a temperature difference of ΔT=412 K. The O'Connell effect can be similarly explained by cool spots on either the hotter primary star or the cool secondary star. A small third-light corresponding to about 5 % and 2 % of the total systemic light in the B and V bandpasses, respectively, supports the third-body hypothesis proposed by the period study. Preliminary absolute dimensions of the system were derived and used to look into its evolutionary status with other W UMa binaries in the mass-radius and mass-luminosity diagrams. A possible evolution scenario of the system was also discussed in the context of the mass vs mass ratio diagram.

• 천문학회보
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• 제41권1호
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• pp.58.2-58.2
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• 2016

The NISS (Near-infrared Imaging Spectrometer for Star formation history) onboard NEXTSat-1 is the near-infrared instrument optimized to the first small satellite of NEXTSat series. The capability of both imaging and low spectral resolution spectroscopy with the Field of View of $2{\times}2deg.$ in the near-infrared range from 0.9 to $3.8{\mu}m$ is a unique function of the NISS. The major scientific mission is to study the cosmic star formation history in local and distant universe. The Flight Model of the NISS is being developed and tested. After an integration into NEXTSat-1, it will be tested under the space environment. The NISS will be launched in 2017 and it will be operated during 2 years. As an extension of the NISS, SPEHREx (Spectro-Photometer for the History of the Universe Epoch of Reionization, and Ices Explorer) is the NASA SMEX (SMall EXploration) mission proposed together with KASI (PI Institute: Caltech). It will perform an all-sky near-infrared spectral survey to probe the origin of our Universe; explore the origin and evolution of galaxies, and explore whether planets around other stars could harbor life. The SPHEREx is designed to have wider FoV of $3.5{\times}7deg.$ as well as wider spectral range from 0.7 to $4.8{\mu}m$. After passing the first selection process, SPHEREx is under the Phase-A study. The final selection will be made in the end of 2016. Here, we report the current status of the NISS and SPHEREx missions.

• 천문학논총
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• 제30권2호
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• pp.665-669
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• 2015

The Kepler mission has shown that small planets are extremely common. It is likely that nearly every star in the sky hosts at least one rocky planet. We just need to look hard enough-but this requires vast amounts of telescope time. MINERVA (MINiature Exoplanet Radial Velocity Array) is a dedicated exoplanet observatory with the primary goal of discovering rocky, Earth-like planets orbiting in the habitable zone of bright, nearby stars. The MINERVA team is a collaboration among UNSW Australia, Harvard-Smithsonian Center for Astrophysics, Penn State University, University of Montana, and the California Institute of Technology. The four-telescope MINERVA array will be sited at the F.L. Whipple Observatory on Mt Hopkins in Arizona, USA. Full science operations will begin in mid-2015 with all four telescopes and a stabilised spectrograph capable of high-precision Doppler velocity measurements. We will observe ~100 of the nearest, brightest, Sun-like stars every night for at least five years. Detailed simulations of the target list and survey strategy lead us to expect $15{\pm}4$ new low-mass planets.

• 천문학논총
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• 제32권1호
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• pp.225-230
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• 2017

The extragalactic background suggests half the energy generated by stars was reprocessed into the infrared (IR) by dust. At z~1.3, 90% of star formation is obscured by dust. To fully understand the cosmic star formation history, it is critical to investigate infrared emission. AKARI has made deep mid-IR observation using its continuous 9-band filters in the NEP field ($5.4deg^2$), using ~10% of the entire pointed observations available throughout its lifetime. However, there remain 11,000 AKARI infrared sources undetected with the previous CFHT/Megacam imaging (r ~25.9ABmag). Redshift and IR luminosity of these sources are unknown. These sources may contribute significantly to the cosmic star-formation rate density (CSFRD). For example, if they all lie at 1< z <2, the CSFRD will be twice as high at the epoch. We are carrying out deep imaging of the NEP field in 5 broad bands (g, r, i, z, and y) using Hyper Suprime-Camera (HSC), which has 1.5 deg field of view in diameter on Subaru 8m telescope. This will provide photometric redshift information, and thereby IR luminosity for the previously-undetected 11,000 faint AKARI IR sources. Combined with AKARI's mid-IR AGN/SF diagnosis, and accurate midIR luminosity measurement, this will allow a complete census of cosmic star-formation/AGN accretion history obscured by dust.

• 천문학논총
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• 제36권3호
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• pp.47-63
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• 2021

와이즈/네오와이즈 자료를 사용하여 1형 활동은하핵의 근적외선 장기 변광 특성을 살펴보았다. 활동은하핵은 밀리퀘이사 목록을 사용해 가시광에서의 등급 제한을 두어 선정하였고, 여러 번의 다중시점 측광 자료를 확보하기 위해 황도북극과 황도남극에 가까운 대상으로 한정하였다. 이후 와이즈와 네오와이즈 데이터베이스에서 해당 대상들의 측광 자료를 추출하였다. 일부 근적외선에서 검출되지 않은 경우와 관측 횟수가 지나치게 적은 경우를 제외하고 총 73개의 1형 퀘이사 및 활동은 하핵, 140개의 측광학적으로 선택된 활동은하핵 후보에 대해 W1 (3.4 ㎛), W2 (4.6 ㎛) 밴드 광도곡선을 구성하고 이를 이용해 변광 분석을 수행하였다. 변광 여부를 판단하기 위해 초과 분산 값과 변광의 유의확률 P_var를 계산하였다. 초과 분산이 포아송 오차에 의해 추정되는 오차값보다 큰 경우, 그리고 P_var이 0.95보다 크거나 같은 경우를 변광으로 판단했는데, 활동은하핵 73개 중 19개, 활동은하핵 후보 140개 중 12개가 W1, W2 밴드 모두에서 변광 대상으로 판단되었다. W1 밴드보다 W2 밴드에서 변광 대상으로 판단되는 숫자가 작게 나타났는데, 이는 긴 파장으로 갈수록 변광의 정도가 작아짐을 시사하는 것으로 보인다. 약 9 ~ 26%의 대상들이 근적외선 변광을 보였다. 감쇠 랜덤워크 모형을 사용하여 변광 폭(σ)과 완화 시간(τ), W1과 W2 밴드 사이의 시간 지연 등을 추정하였다. 변광 폭 및 완화시간은 W1 등급과 큰 상관관계를 보이지 않았으며, 두 변수 사이에도 특별히 두드러지는 상관관계가 나타나지 않았다. 단, 감쇠 랜덤워크 모형을 사용해서 시간 규모를 추정할 때 광도곡선의 분량이 충분한지를 감안하면, 완화시간이 짧은 대상들에 대해서는 변광 폭과 완화시간이 음의 상관관계를 보인다고도 볼 수 있다. 대상의 개수가 통계적으로 유의미한 결과를 제시하기에는 부족하다. X선 광도와 변광 특성을 비교했을 때에는 상관관계를 찾아보기 어려웠으나, 앞으로 얻어질 X선 탐사자료와 전천 스펙트럼 탐사자료와 결합한 추가 연구가 기대된다. 전체 대상 중에서는 시간에 따라 (W1-W2) 색이 변하는 것으로 판단되는 흥미로운 대상이 4개가 존재했는데, 이들의 특성에 대해서는 추후 연구가 더 필요할 것으로 전망한다.