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Stellar Paths Photographic Astrometry with Long-Focus Instruments

This is the latest effort in a sequence of presentations begun in 1949 with a series of lectures on long-focus photographic astrometry given by the author as Fulbright professor in Paris at the invitation by the late H. Mineur, at that time Director of the Institut d' Astrophysique. These earli...

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Bibliographic Details
Main Author: Kamp, P.
Format: eBook
Language:English
Published: Dordrecht Springer Netherlands 1981, 1981
Edition:1st ed. 1981
Series:Astrophysics and Space Science Library
Subjects:
Astronomy / Observations
Astronomy, Observations And Techniques
Online Access:
Collection: Springer Book Archives -2004 - Collection details see MPG.ReNa
Table of Contents:
  • (g) Derivation of conventional from geometric elements
  • 11. Path of Star with Orbital Motion. Photocenter.
  • (a) Resolved astrometric binary; mass-ratio
  • (b)Unresolved astrometric binary; photocenter and photocentric orbit
  • (c)Alternate analysis: parallactic and apparent orbit. Orbital factors
  • 12. Mass-Ratio and Masses. Harmonic Relation
  • (a) Fractional mass, mass-ratio. Harmonic relation
  • (b) Mass-luminosity relation
  • (c) Mass-ratio determination for long-period visual binary: Example: 61Cygni
  • (d) Derivation of harmonic relation
  • 13. Perturbations in Stellar Paths. History. Analysis
  • (a) History. Discovery
  • (b)Orbital analysis: dynamical and geometric elements
  • (c) Mass-function. Orbital constant. Dynamicalinterpretation
  • (d)Once more: systematic errors
  • (e) Perturbations in visual binaries
  • 14. Unseen Astrometric Companions. Illustrations
  • (a) Review
  • (b) Illustrations
  • 15. Unseen astrometric Companions. General.
  • (a) Mass-luminosity relation
  • (b) Number- and mass-density
  • 16. Planetary Companions. Barnard’s Star
  • (a) Introduction
  • (b) Barnard’s star: history, general data
  • (c) Early results for perturbation
  • (d) Latest Sproul solution for parallax, proper motion, and quadratic time effect
  • (e) Normal points and weights
  • (f) Orbital solutions
  • (g) Dynamical interpretation
  • (h)Possible influence of reference stars
  • 17. Long-period eclipsing binaries: VV Cephei and Epsilon Aurigae.
  • (a) Apparent orbit vs annual parallax
  • (b) Concept of orbital parallax
  • (c)VV Cephei
  • (d) Epsilon Aurigae
  • (e) Summary
  • 18. Epilogue. Attainable Accuracy. Substellar and Planetary Detectability
  • (a)Review
  • (b)Separating small perturbations from random errors
  • (c)Long-range telescope stability
  • (d)Substellar and planetary detection capability and probability
  • 1. Astrometry: Historical Highlights.
  • (a) Fundamental astronomy. Long-focus photographic astrometry
  • (b) Precession, Heliocentric viewpoint. Kepler’s three laws, proper motions., Stellar Aberration., Nutation
  • (c) Solar motion. Binary stars. Parallax. Perturbations
  • (d) The two star streams or preferential motion, Asymmetry. High velocity stars. The galactocentric viewpoint. Galactic rotation
  • 2. Long-focus Photographic Astrometry. Telescope; Measuring Machine
  • (a) Telescope. Refractors: dispersion, focal ratio, coma, spherical aberration; Rayleigh’s criterion
  • (b) The USNO reflector
  • (c) Measuring machines. The SAMM and SCAN machines at USNO
  • (d) The Grant machine at Sproul Observatory
  • 3. Observational Errors. Instrumental Equation
  • (a)Accidental errors
  • (b)Systematic errors
  • (c) Instrumental equation: Sproul refractor
  • (d) Time of night effect
  • 4. Stellar Paths. Reduction of Measurements
  • (a)Image plane and tangential plane; Equatorial and standard coordinates
  • (b)Scale, orientation and tilt effects
  • (c)Reference stars: Standard frame, linear plate constants
  • (d)Dependences; geometric accuracy
  • 5. Path of single star. Relative Parallax, Proper Motion, Quadratic Time Effect.
  • (a) At the telescope
  • (b) Plate weight; plate, night, year, measurement errors, double plates, night weights
  • (c) Analysis for relative parallax, proper motion and quadratic time effect
  • (d) Attainable accuracy
  • (e) Calculation of accuracy of quadratic time effect
  • 6. Reduction to Absolute. Accuracy: Cosmic Errors.
  • (a) Dependence background of reference stars; spurious acceleration
  • (b) Reduction to fixed background
  • (c) Observational and cosmic errors
  • (d) Accuracy of reduction to absolute quadratic time effect
  • (e) Reduction to absolute parallax
  • 7.Parallax Results for Nearest Stars. H-R Diagrams
  • (a) Review
  • (b)H-R diagrams
  • (c) Stars nearer than 5 parsec
  • 8. Perspective Secular Changes in Proper Motion, Radial Velocity, and Parallax
  • (a) Introduction
  • (b) Basic considerations and relations
  • (c) Changes of ?, V, and p with time
  • (d) Changes of d?t/dt, dV/dt, and dp/dt with time or anomaly
  • (e) Determination of perspective secular acceleration. Examples: Barnard’s star and van Maanen’s star
  • (f) Astrometric determination of radial velocity
  • (g) Evaluation and elimination of quadratic time effect
  • 9. Reduction from Heliocentric to Barycentric.
  • (a) Perturbation of solar path
  • (b) Heliocentric and barycentric parallax factors
  • (c)Illustration: Barnard’s star
  • 10. Visual Binaries, Orbital Elements.
  • (a) Introduction
  • (b) Multiple exposure technique
  • (c) Kepler’s problem. Elliptical rectangular coordinates
  • (d) Apparent and true orbits. Orbital elements
  • (e) Derivation of dynamical elements
  • (f) Derivation of geometric elements. Thiele - Innes constants

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