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E. Grocheva and A. Kiselev
Photographic Astrometry Department, Pulkovo Observatory,
S.Petersburg, 196140, Russia, Email: gl@spb.iomail.lek.ru
We shall present methods which allow the identification of physical binary stars in a probabilistic sense. The application of probability theory provides a more complete picture of the frequency of stellar binarity than simple methods based only on proximity or proper motion. We will also present preliminary results from the application of these methods to Pulkovo's observation program of binary star systems, and outline how such methods might be applied to present and future high precision astrometric catalogues.
We propose to use the real distribution of proper motions for estimation of P. Let the probability of finding the primary component in the area equal 1 as a probability of a reliable event. The probability P of finding n components in a small area may be represented as:
(1) |
where
- probability of finding n stars in small area limited with angular distance for the case of a random distribution, (Deutsch,1962):
(2) |
n - is multiplicity of a star system;
- is area where N stars are randomly disposed;
- probability of the proximity of proper motions and ;
- error of determination of proper motions.
Let be a random vector, , where , . If takes on a value from the cell , then we say that random vector takes the value . Hence, vector may take the following values:
Let the probabilities that takes one or another value be equal correspondingly top11,p12,..,pnn.
and i.e., the density of probability of the random vector is known. In the case of statistical estimation of probabilities the quantities pij are the relative frequencies , then is equal to:(3) |
where is the Borel's set, where the tips of vectors are situated at:
(4) |
Now we will describe a procedure for the solution of this problem without a concrete realisation.
according to (1) -(3).
The distribution of proper motions was derived from the PPM catalogue for stars of the North-polar area. The parameters of the distributions are in Table 1. The predominance of negative motions, especially of , is readily observable. This is due to the location of the North-polar area relative to the Solar apex. We chose 76 double stars from Pulkovo's observation program and calculated the probabilities of a random distribution for these pairs. There are 8 physical and 12 optical systems among them (Grocheva,1996 & Catalogue of relative positions and motions of 200 visual double stars,1988). The proper motions of these pairs was obtained by using the catalogue ``Carte du Ciel'' and modern observations with the 26''refractor. The precision of is 0''.005 /yr.
Mean | Variance | max | min | ||
-0''.0006 | 0.047 | 1''.545 | -2''.97 | ||
-0''.0059 | 0.041 | 0''.818 | -1''.74 | ||
Analysing the resulting probabilities we conclude that only the probability of random proximity of proper motions can be used to identify true physical binaries. Multiplication by corrupts the probability pattern. Figure 1 shows probabilities on a logarithmic scale (we numbered the pairs of this sample from 1 to 76 and used these numbers as x-coordinates). We see that probabilities for physical pairs are less than 0.01, whilst those for optical ones are large. Hence, the quantity may be used to identify physical binaries and the limit of probability of proper motions proximity S/N is 0.01 for physical pairs. It turned out that only 27 physical binaries were among the sample of 76 double stars.
The technique presented identifies physical binaries. This method has a simple algorithm and can be used for the automatic treatment of large stellar catalogues. We are pleased to also note that this method requires only minimal data such as positions and proper motions. This method was used to correct the Pulkovo's program of binary star observations.
Deutsch, A. N., 1962, ``The visual double stars''. in The course of astrophysics and stellar astronomy, p.60, Moscow, (in Russian).
Catalogue of relative positions and motions of 200 visual double stars.,1988, Saint-Petersburg, (in Russian).
Grocheva, E. A., 1996, ``Physical and optical double stars...'', Workshop The Visual Double Stars.., Spain.
Aitken, R. G., 1932, New General Catalogue of Double Stars, Edinburgh
Next: Modelling Spectro-photometric Characteristics of
Eclipsing Binaries
Up: Computational Astrophysics
Previous: Modelling Spectro-photometric Characteristics of Nonradially Pulsating Stars
Table of Contents -- Index -- PS reprint -- PDF reprint