A photometric study of the BAO-CCD BVRI system

Chin. Astron. Astrophys. A translation of

@ Pergamon Press Ltd Printed in Great Britain

(1992)16/2,226-253

02751062/92$10.00+.00

Acta AstrophysSin.(l992)12/1,47-53

A photometric JIANG

study of the BAO-CCD system*

Zhao-ji

LI Yong

Beijing Astronomical

CHEN

BVRI

Jian-sheng

Observatory, Chinese Academy of Sciences Beijing 100080

Abstract The BAO Schmidt telescope with a Thomson CCD of 576 x 384 pixels was used for BVRI photometry. 9 secondary photometric standard stars in 3 CCD frames were observed on Oct. 31, 1989, to establish the color equations. Some problems relevant to the capability of CCD photometry are discussed. Key words:

CCD-photometry-color

equations

1. INTRODUCTION Magnitudes and color indices are the important quantities used in many astrophysical researches. Photographic techniques can provide photometry for large field with low accuracy, while photoelectric photometry, on the other hand, can reach high precision but , in most cases, is limited to measuring one object at a time. Since the astronomical application of large format CCD, it soon became clear that as a detector, CCD combines the advantages of photographic plates and photomultiplier tubes, namely: two dimensional detection, good linear response, high quantum efficiency, and large dynamic range. In addition, with digitized CCD output from the entire frame, one can use more sophisticate statistic method to determine accurately the local sky background and can optimize the selection of the aperture for photometry to raise the S/N ratio. However, for CCD photometry, one have to take care of the readout noise as well as the noise introduced from the flat-field correction. With the improvements in performance of CCD and the developments of image processing techniques, the precision of CCD photometry is being improved and an accuracy of up to 0.0015 magnitude is obtained in the study of CCD surface photometry in M67 l

This

work

Received

was

partly

supported

19991November

by National

5; revised

version

Natural received

Science 1991

Foundation.

September

18

aCCD Photometry

227

(Gilliland & Brown[‘l), which is comparable to that of photoelectric photometry. It is undoubted that the usage of CCD for both two dimensional surface photometry as well as for large ensembles of stars is very promising. Taking advantage of fast focal ratio and large field, we have carried out CCD multi-color photometry using the 60/90 cm Schmidt telescope at Beijing Astronomical Observatory(BA0). As the first step of the study for BAO CCD photometric system, we established, in this paper, the color equations and discuss some problems relevant to the performance and capability of CCD photometry.

2. OBSERVATION The red-sensitive Thomson CCD chip of 576 x 384 pixels, attached to the BAO 60/90 cm Schmidt telescope gives a field of about 25’ x 17’. Detailed descriptions of the system can be found in Wei et r~L(~l. BVRI filters were used. Table 1 lists their parameters. Nine secondary photometric standard stars of Moffett & BarnesI (Table 2), which fall into 3 separate CCD frames, were observed on Oct. 31, 1989 in BVRI four colors. These stars are located near the equator and have magnitudes around 10. For each frame, 11 CCD exposures in each color were taken, resulting in a total number of 132 CCD exposures. In order to get as high as possible a signal-to-noise ratio, the exposures were taken out of focus to lengthen the exposure time and to avoid saturation of bright stars. The integration time is arranged as follows: 15s or 20s for B, 6s or 8s for V, 4s or 5s for R, and 2s for I, respectively. Table

1.

Filter

Specification

B

GG385/2

+ BGlt/l

V

GG495/2

+ BG18/2 + KG312

+ BGIt./l

R

RG610/2 + BG20/2 f

I

RG9/3

Table R.A. (1980)

STAR

2.

Dec.

9 Secondary

Standard

R.A. (1989.8)

I

+ KG312 KG312

Stare Dec.

SP. (YPC

433

0

IS

52

+o

54

13

0

56

22.3

+0

57

23.6

G2

107

0

S5

49

+0

59

.28

0

56

19.3

i-0

02

38.6

GO

I

508

0

5s

49

-l-l

03

05.

o

56

19.3

+l

06

15.6

FS

1

510

0

56

06

-i-l

00

31

0

56

36.2

+1

03

41.5

G5

101

1

52 .16

+0

16

30

1

52

46.4

+0

19

23.3

GYP

103

1

52

19

30

17

21

1

52

49.4

+o

20

14.3

G8

241

I

54

17

+o

30

40

1

54

47.4

+0

33

32.5

G2

326

1 53

48

+0

41

I2

1

54

18.4

+O

44

04.7

F6

3

332

1

01

+o

34

20

1

53

31.4

+o

37

13.0

F8

3

53

Frame

1

1 Frame

2 2

Frame

3

JIANG

Zhao-ji et al.

3. DATA

REDUCTION

The raw CCD frames were reduced in an usual way, i.e. bias subtracted and flat-field corrected. Then the local sky background for each standard star was determined as follows. An array of 65 x 65 pixels centering at the star was extracted and a histogram built with ADU per pixel as the abscissa and frequency as the ordinate. Then the histogram is fitted by a Gaussian curve. The ADU number corresponding to the peak of the Gaussian curve was adopted as the local background for the star. The aperture size for the standard star is 15 x 15 pixels. The data array of each standard star and the local sky background are thus used to calculate the instrumental magnitude according to the formula: instrumental

= 20-2.51og(C(ADU-S#Y)/integration

magnitude

time(in

second))

C means the sum for all the pixels within the aperture. The constant 20 is artificially chosen to make the instrumental magnitudes close to the actual ones(the data not presented here due to limited space). Let the color equations be [*I(‘1: V-v=hr(B-V)+h~.X”+hs B - v =

h4(b

-

v)

+

h5

* &,”

+

h6

V - R = h7(u - r) + h8 . Xv, + hg V - I = hlo(v - i) t hll .X,;

t hlz

where BVRI and bvri denote magnitudes in the standard system(Table 3) and the instrumental system, respectively; h1,4,,,10 are color coefficients, h2,5,8,11 are extinction coefficients and h3,6,9,12 are zero points. Xs are mean air masses. Table 3. BVRI

Photoelectric

Standard Magnitudes vol. 84( 1979)

Moffett and Barnes

B-V

1

V-R

AJ

(R--l

Star

V

B-V

433

11.665

+0.684

0.029

.0.025

0.025

507

11.349

+0.961

0.031

0.020

0.018

508

11.678

+0.553

0.012

0.031

0.024

510

9.987

+1.065

0.01s

0.020

0.007

101

9.736

+0.651

0.018

0.016

0.014

103

8.829

+1.166

0.011

0.013

0.016

241

9.405

+0.8S2

0.018

0.019

0.02s

326

9.563

+0.4so

0.023

0.008

0.012

332

9.797

+0.506

0.017

0.014

0.032

(standard

deviations)

CCD Photometry

229

The equation system can be solved by iterative method. Fig. 1 Uustrates tive process. After 15 iterations, we get the solution as follows: V - v

=

O.O14(B - V) - 0.223X,

B - V

=

=

=

- 1.433 0.052

0.008

l.l84(v

- r) - 0.090X,,

+ 0.065

0.004

0.018

V-I

0.022

1.481(b - v) - 0.144& 0.031

V - R

- 0.151

0.003

0.009

0.011

1.185(~ - i) - 0.160X”; 0.013

+ 0.394

0.005

We also present the standard deviation equation. The obtained color equations magnitudes of 9 standard stars to BVRI Table 4, which gives us an estimation of

I

0.010

for each coefficient in second line of each were used to transform the instrumental standard system. The result was listed in our photometric precision.

I

Let hr=O

the itera-

h4,7,1o =

11

1 Taking hr,+r,ro aa constant, we obtain the values of hs,s,s,ii respectively by the leastsquare method. I t Taking hs.5.s.r 1 as constant, we ob&.the values of hl,r,t,lo

respectively by the leastsquare method and then get the values of hs,s,g,is No

11

Yt?S

stop

Fig. 1

JIANG Zhao-ji et al.

230

Table 4. BVRI Star

V

CCD Photometric

V-R

B-V

Magnitudes

v-1

N

by color equations(this V

(

B-V

1

(standard 433

11.683

507

11.352

508

11.698

V-R

paper) (

V-l

deviations)

0.564

0.922

11

0.019

0.067

0.018

0.035

0.924

0.745

1.231

11

0.010

0.077

0.025

0.027

0.546

0.501

0.817

11

0.018

0.072

0.032

0.027

0.631

510

9.964

1.059

0.814

1.327

11

0.022

0.030

0.025

0.022

101

9.734

0.668

0.538

0.883

11

0.018

0.022

0.009

0.019 0.019

103

8.834

1.173

0.847

1.397

11

0.014

0.023

0.Ol.J

241

9.415

0.850

0.718

1.191

11

0.012

0.036

0.015

0.016

326

9.549

0.494

0.395

0.664

11

0.015

0.026

0.012

0.013

332

9.780

0.543

0.468

0.764

11

0.019

0.024

0.012

0.020

B-V ccd

0.4

0.6 V-R

V

ted

0.8 ccd

‘-’ ccd Fig. 2

CCD Photometry

231

4. DISCUSSION 1. We plot in Fig.2, for the 9 standard stars, the magnitudes given by Moffett & Barnes[31 against the magnitudes calculated by our color equations derived above to show the goodness of the fitting. We have also studied the problem in another way. The instrumental magnitudes of the 9 standards for each color were corrected for the atmosphere extinction. The extinction coefficients were obtained with the CCD

I

K-0.30&.01

X (AIR

lIEiS)

Fig. 3 Table L. CCD Photomath rtar

Magnitudes (MO-CCD

(1989,[email protected]) I

R

v

B

watt)

433

13.2482

0.0424

11.8249

0.0152

Jt.4225

0.0109

11.3602

0.0217

507

13.1143

0.0474

11.4963

0.0083

10.9012

0.0142

10.7911

0.0202

SO8

13.1878

0.0495

11.8253

0.0134

11.5i69

0.0116

11.4873

0.0130

II0

11.8029

0.0232

to. 1249

0.0161

9.4639

0.0107

9.3069

0.0149

tot

33.3t3e

0.0286

9.8943

0.0207

9.4842

0.0170

9.4326

0.0170

to3

10.7476

0.0226

e.9921

0.0153

8.3082

0.0157

a.1120

0.0190

241

11.0643

0.0363

9.s354

0.0161

a.9at3

0.0198

8.8474

0.0211

326

10.9477

0.0289

9.668s

0.0196

9.4113

0.0124

9.4434

0.0174

332

Il.2415

0.0320

9.9242

0.0260

9.1770

0.0229

9.177s

0.02te

232

JIANG Zhao-ji et al.

K=O.995i.O06 I

1

10

12

’ (baoccdsyrtcm)

-

X=1.014*

, 8

1 a

12

10 R (boo,ccd ryslcm)

0.4 -

Fig.

‘QE”

4

Curve of BAO Tbomsm

Fig. 5

10

’

CCD -

(bawccd

syrtem)

016

233

CCD Photometry

photometric data of the 9 standards taken at different zenith distances on the same night. Fig.3 shows the results of the star No. 510 for 4 colors. The extinction corrected instrumental magnitudes are listed in Table 5. We again plot the magnitudes given by Moffett & Barnes131 against the magnitudes in Table 5 in Fig. 4. The data can well be fitted by a straight line indicating the reliability of the photometric system. 2. It is notable that the color coefficient of the B - V relation in color equations is 1.481, far greater than 1. This means that the sensitivity of our CCD-filter combination bias to longer wa.velength in B. We believe that such a bias is not due to the filters themselves but due to the fast drop of CCD quantum efficency toward shorter wavelengths within the B ba.nd where most of the ADU numbers detected are coming from the longer wavelength part. In fact, the integration time for B color is about 10 times as long as that for I color. We thank Dr. SUN Yi-li of Beijing Astronomical Observatory and Dr. YAO Bao-an of Shanghai Astronomical Observatory for their valuable discussions and help. We also thank BAO CCD group for providing the quantum efficiency curve of the Thomson chip. Acknowledgement

References

c31 r41

Gillilond, R.L.. Brown, T.M., PASP, lOO(l988). Wei, M., Chen, J., Jiang, Z., PASP, 102(1990), Moffett, T.J., Barnes. T.G.. AJ, S4(1979),628 Schild, R.E., PASP. 95(1983), 1021

[51

Hiltner,

111 [21

W.A..

in Astronomical

Techniques,

754 698

(1962),

Chapter

8, 178