scholarly journals Problem of Using Lunar Positional Observations for Determination of Zero-Points of Fundamental Star Catalogues

1990 ◽  
Vol 141 ◽  
pp. 93-93
Author(s):  
V. A. Fomin
Keyword(s):  
Marginal Zone ◽  
Precise Determination ◽  
The Moon ◽  
Star Catalogue ◽  
Secular Variations ◽  
Image Position ◽  
The Right ◽  
Right Ascension ◽  
Zero Points

The long series of meridian observations of the Moon can be used for the precise determination of the equinox- and equator-corrections of a star catalogue. Systematic errors of different charts of the lunar marginal zone used for the reduction of the lunar limb observations have no influence on the determination of the secular variations of the zero-points of the fundamental coordinate system.From meridian observations of the lunar limb made during the interval 1923-1977 in Washington, Greenwich, Cape and Tokyo the following estimate is found for the correction to the right ascension system of the FK4 catalogue: which is in disagreement with the values used for the compilation of the FK5 catalogue.

Nonlinear integral inequalities of the Volterra type

1992 ◽  
Vol 111 (3) ◽  
pp. 599-608 ◽  
Author(s):  
Ryszard Szwarc
Keyword(s):  
Power Function ◽  
Integral Inequality ◽  
Integral Inequalities ◽  
Volterra Type ◽  
Identity Function ◽  
Right Hand ◽  
Half Axis ◽  
Image Position ◽  
The Right ◽  
Zero Points

We are studying the integral inequalitywhere all functions appearing are defined and increasing on the right half-axis and take the value zero at zero. We are interested in determining when the inequality admits solutions u(x) which are non-vanishing in a neighbourhood of zero. It is well-known that if ψ(x) is the identity function then no such solution exists. This due to the fact that the operator defined by the integral on the right-hand side of the equation is linear and compact. So if we are interested in non-trivial solutions it is natural to require that ψ(x) > 0 at least for all non-zero points in some neighbourhood of zero. One of the typical examples is the power function ψ(x) = xα, where α < 1. This situation was explored in [2]. The functions a(x) that admit non-zero solutions were characterized by Bushell in [1]. For a general approach to the problem we refer to [2], [3] and [4].

scholarly journals On the determination of the difference of longitude, by means of the magnetic telegraph. By Elias Loomie, Esq., in a letter to Lieut.-Col. Sabine, R. A., For. Sec. R. S. Communicated by Lieut.-Col. Sabine, R. A., For. Sec. R. S

1851 ◽  
Vol 5 ◽  
pp. 787-789
Keyword(s):  
New York ◽  
Usual Manner ◽  
Series Of Experiments ◽  
The Difference ◽  
The Times ◽  
The Right ◽  
Time Pieces ◽  
Right Ascension ◽  
Source Of Error

The writer first refers to a series of experiments made under the direction of Professor Bache, for the determination of the difference of longitude between New York, Philadelphia and Washington, by means of the magnetic telegraph. By this series of experiments he considers it established that, by means of Morse’s telegraph, two clocks distant from each other 200 miles, can be compared together with the same precision as if they were placed side by side; and that the difference of longitude of two places can be determined with the same precision as the relative error of the clocks. These results were so satisfactory that Professor Bache determined to pro­secute them more extensively, and during the past summer comparisons have been made between New York and Cambridge observatory near Boston. The plan of operation this season was more matured than during the former. The comparisons were all made between a solar chronometer at Cambridge and a sidereal clock at New York. At ten o’clock in the evening, the two observatories having been put in telegraphic communication, when the seconds hand of the solar chronometer came round to 60 s , a signal was given at Cambridge, by pressing the key of the telegraph-register; at the same instant a click was heard at New York, and the time was recorded according to the sidereal clock. At the end of 10 s a second signal was given, which was also recorded at New York; at the end of another 10 s a third signal was given, and so on for sixty seconds. The Cambridge astronomer then commenced beating seconds by striking the key of the telegraph-register in coincidence with the beats of his chronometer. The New York astronomer compared the signals received with the beats of his clock, and waited for a coincidence. When the beats were sensibly synchronous the time was recorded, and the astronomer waited six minutes for another coincidence of beats. The Cambridge astronomer continued beating seconds for fifteen minutes , during which time the New York observer was sure of two coincidences, and might obtain three. When these were concluded, the New York astronomer in the same manner gave signals for one minute at intervals of 10 s , and then beat seconds for fifteen minutes, during which time the Cambridge astronomer obtained four or five coincidences upon his chronometer. This mode of comparison was practised every night, and it is considered that the uncertainty in the comparison of the time-pieces cannot exceed two or three hundredths of a second on any night; and in a series of comparisons the error may be regarded as entirely eliminated. Another mode of comparison which was practised is that of telegraphing star transits. A list of stars which culminate near our zenith at intervals of five or six minutes was prepared, and the observers, both at New York and Cambridge, were furnished with a copy. They then proceeded as follows: Cambridge selected two stars from the list, which we wall call A and B, and struck the key of his register at the instant when the star A passed each of the seven wires of his transit. These signals were heard at New York, and the times recorded. Cambridge then observed the transit of star B in the ordinary manner without telegraphing. New York then observed the transit of star A on his meridian in the usual manner; and struck his key at the instant the star B passed each of the seven wires of his transit, which signals were heard and recorded at Cambridge. The difference of longitude between New York and Cambridge is nearly twelve minutes, affording ample time for all these observations. Thus New York obtained upon his own clock the times of transit of star A over the meridians of Cambridge and New York; and Cambridge obtained upon his chronometer the times of transit of star B over the same meridians. The difference of these times gives the difference of longitude independent of the right ascension of the stars. Both observers then reversed the axis of their transit instruments; Cambridge selected a second pair of stars from the list, and the same series of observations was repeated as with the first pair. The error of collimation was thus eliminated, and by confining the observations to stars within about five degrees of the zenith, the influence of azimuthal error was avoided. The level being read at every reversal, the correction for it was applied by computation. In this manner it is hoped to eliminate every possible source of error, except that which arises from the personal habits of the observers. In order to eliminate this error, a travelling observer worked for a time at Cambridge and compared with the Cambridge astronomer; then came to New York and compared with the New York astronomer; then returned to Cambridge again, and so on as often as was thought necessary. Finally, at the conclusion of the campaign all the observers were to meet at Cambridge and make a general comparison of their modes of observation.

Of the Right and Left Hand (1646): Sir Thomas Browne's historical survey of ‘handedness”

2005 ◽  
Vol 22 (1) ◽  
pp. 30-32
Author(s):  
Caoimhghin S Breathnach
Keyword(s):  
Left Hemisphere ◽  
Large Scale ◽  
Precise Determination ◽  
Antidepressant Effect ◽  
Hemispheric Asymmetries ◽  
Left Hand ◽  
Left Handedness ◽  
The Right ◽  
Reproducible Manner

‘Handedness’ as an expression of cerebral lateralisation is valuable in analysis of hemispheric asymmetries, carrying implications for implementation (as well as interpretation) of complex cognitive functions. In recent decades it has become possible to categorise handedness in a reproducible manner and, independently, to estimate accurately the degree of language lateralisation of the brain. These advances have re-focussed attention on cerebral organisation and hemispheric asymmetries, and there is now considerable interest in the neuropsychology of left-handedness. Because of procedural and ethical constraints there are relatively few large scale studies on language dominance, whereas handedness has been studied extensively in recent decades. Language is represented in the left hemisphere in all but 1% of right-handers, and in 60% of left-handers; in 15% of right-handers speech representation was bilateral.Precise determination of handedness or lateralisation does not appear to have been assessed in major studies of electroconvulsive therapy (ECT). Results in 29 reports, when the electrodes were placed over either the non-dominant or both hemispheres, were tabulated and briefly discussed by d'Elia and Raotma, but the criterion of lateral dominance assignment was not clearly specified; the unilateral and bilateral placements were equally efficacious in their antidepressant effect. d'Elia, who introduced unilateral therapy in 1970, accepted the assumption that the left hemisphere was ‘dominant’, but later workers were more circumspect.

A Device to Determine Position Rapidly Without Calculation

1956 ◽  
Vol 9 (1) ◽  
pp. 11-16
Author(s):  
Leo Randić
Keyword(s):  
Sidereal Time ◽  
Outer Circle ◽  
The Earth ◽  
Geographical Latitude ◽  
The Difference ◽  
Celestial Sphere ◽  
The Right ◽  
Right Ascension ◽  
Nautical Almanac

The problem of the determination of the observer's position on the Earth can be most easily solved in terms of the equatorial coordinates of the observer's zenith. From Fig. 1, in which the inner circle represents the Earth and the outer circle the celestial sphere, it can be seen that the zenithal point on the celestial sphere is its intersection with the prolongation of the radius to the observer's position. The geographical latitude of the observer is equal to the declination of the observer's zenith, and the geographical longitude is equal to the difference between Greenwich sidereal time (G.S.T.) and the right ascension of the observer's zenith. We can obtain G.S.T. by interpolation from a nautical almanac or directly from a separate watch or clock set to keep sidereal time.

scholarly journals Cycloplegic Effects on the Cylindrical Components of the Refraction

2021 ◽  
Vol 2021 ◽  
pp. 1-6
Author(s):  
Athar Zareei ◽  
Milad Abdolahian ◽  
Shahram Bamdad
Keyword(s):  
Precise Determination ◽  
Lower Amount ◽  
Healthy Individuals ◽  
Male And Female ◽  
Near Vision ◽  
Before And After ◽  
The Mean ◽  
The Right ◽  
Age Range

It is important to predict which astigmatic patients require separate refraction for near vision. This study compared cylindrical components changes by cyclopentolate 1% for the low and high amount of astigmatism. The right eyes of 1014 healthy individuals (307 males and 707 females) with cylindrical refractive power more than −0.5 diopter on autorefractometer were selected. Both male and female patients in the age range of 17–45 years were refracted before and after cycloplegia, using 1% cyclopentolate. All volunteers were classified into 2 subgroups including the lower astigmatism group (−2.25 to −0.50) and the higher astigmatic group (−2.50 to over). Alpines’ method was used to compare the effect of cycloplegic drop on cylindrical power. The mean age in the lower astigmatism group (29.58; 95% CI: 29.18 to 29.99 years) was not significantly different from the higher astigmatic group (29.85; 95% CI: 29.07 to 30.62) and there were no significant differences in gender between these two groups ( P = 0.54 ). Differences between wet and dry refraction in J0 (−0.03; 95% CI:−0.06 to −0.008) and J45 (−0.03; 95% CI:−0.06 to −0.01) were significant only in the higher astigmatic group. Axis changes by the cycloplegic drop in the lower astigmatism group were 3.51 (CI: 3.22 to 3.81) and axis changes by the cycloplegic drop in the higher astigmatism group were 2.21 (CI: 1.73 to 2.49). In patients with a lower amount of astigmatism (−2.25 to −0.50), additional near subjective refraction could be done for precise determination of axis and in patients with a higher amount of astigmatism (−2.50 to over), near subjective refraction might be done for precise determination of power.

scholarly journals Evaluation Methods of Swot Analysis / Metody Vyhodnocení Swot Analýzy

2012 ◽  
Vol 58 (2) ◽  
pp. 23-31 ◽  
Author(s):  
Michal Vaněk ◽  
Milan Mikoláš ◽  
Kateřina Žváková
Keyword(s):  
Strategic Management ◽  
Comparative Advantage ◽  
Swot Analysis ◽  
Selection Process ◽  
Influence Factors ◽  
Precise Determination ◽  
Strategic Orientation ◽  
Public Discussion ◽  
The Right

Abstract Strategic management is an integral part of top management. By formulating the right strategy and its subsequent implementation, a managed organization can attract and retain a comparative advantage. In order to fulfil this expectation, the strategy also has to be supported with relevant findings of performed strategic analyses. The best known and probably the most common of these is a SWOT analysis. In practice, however, the analysis is reduced to mere presentation of influence factors, which does not allow more precise determination of a strategic concept. The content of the article tries to remove this drawback, submitting for public discussion two possible approaches to evaluate the SWOT analysis providing important information for the selection process of an organization's strategic orientation.

scholarly journals Where is the Equinox ?

1979 ◽  
Vol 81 ◽  
pp. 133-143 ◽  
Author(s):  
W. Fricke
Keyword(s):  
The Earth ◽  
Celestial Equator ◽  
The Difference ◽  
Rotation Of The Earth ◽  
The Right ◽  
Important Evidence ◽  
Right Ascension ◽  
Fundamental Reference ◽  
Made In

Within the work being carried out at Heidelberg on the establishment of the new fundamental reference coordinate system, the FK5, the determination of the location of celestial equator and the equinox form an important part. The plane of the celestial equator defined by the axis of rotation of the Earth and the plane of the ecliptic defined by the motion of the Earth about the Sun are both in motion due to various causes. The intersection of the equator and the ecliptic, the dynamical equinox, is therefore in motion. Great efforts have been made in the past to determine the location and motion of the dynamical equinox by means of observations of Sun, Moon and planets in such a manner that the dynamical equinox can serve as the origin of the right ascension system of a fundamental catalogue. The results have not been satisfactory, and we have some important evidence that the catalogue equinox of the FK4 is not identical with the “dynamical equinox”. Moreover, is has turned out that the difference α(DYN) - α(FK4) = E(T) depends on the epoch of observation T. Duncombe et al. (1974) have drawn attention to the possible confusion between the catalogue equinox and dynamical equinox; they mention the difference between two Earth longitude systems, one established by the SAO using star positions on the FK4 and the other one established by the JPL using planetary positions measured from the dynamical equinox. This is undoubtedly one legitimate explanation of the difference, even if other sources of errors may also have contributed.

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