Parallax
Parallax is the change of angular position of two
stationary points relative to each other as seen by an observer,
due to the motion of said observer. Or more simply put, it is the
apparent shift of an object against a background due to a change in
observer position.
Distance measurement by parallax is a special case of the principle of
triangulation, where one can solve for all the sides and angles in
a network of triangles if, in addition to all the angles in the
network, the length of only one side has been measured. Thus, the
careful measurement of the length of one baseline can fix the scale
of a triangulation network covering the whole nation. In parallax, the
triangle is extremely long and narrow, and by measuring both its
shortest side and the small top angle (the other two being close to
90 degrees), the long sides (in practice equal) can be determined.
The two points mentioned in the definition above will be at different
distances from the observer. The visual effect of parallax is caused by
the fact that light follows straight lines. When the observer views
the nearer point, the line of his vision toward that point is at a
given angle within the full arc of his vision. For example, let us
say that the view straight ahead is zero degrees, and one point,
nearer the observer, is at minus five degrees while a point which is
farther away is at minus two degrees. The apparent angular distance
between the points is a subjective three degrees to the viewer. If
the viewer moves ten meters to his right, the angular direction to the
nearer object, as it is on a shorter radius, will change more than the
angular direction to the farther object. So, for instance, when the
angular direction to the nearer object is at minus ten degrees, the
father object may only have moved to minus three degrees. Now the
subjective angular difference in position is seven degrees. The
objects appear to have moved relative to each other.
It is because of this effect that, in a moving car, one can look at
distant mountains and see them seem to move (retard) in position
beneath a seemingly motionless moon. The moon is at such a distance
that the subjective angular change in position (direction) relative to an
earth-bound observer is extremely slight, even as many miles are
covered. The mountains, much closer, exhibit a much greater apparent
change in angular position.
Put differently and somewhat more generally, distant objects appear to
move with the car. This can be explained as follows: looking out from
a car perpendicular to its motion, all objects move backward relative
to the car, and for nearby objects the speed of change in direction is
what the observer considers the normal consequence of his own
movement; however, for distant objects this backward change in
absolute direction is slow and much less obvious than the forward change in
direction relative to nearby objects. It seems as if distant objects
move parallel to the car with the same speed or only a little slower.
With a nearby object in front of you, gaze at infinity. Cover one eye
with your hand. Then move your hand to cover your other eye instead. The
nearby object will seem to jump horizontally.
It is this effect that allows us -- and certain other animals such as
cats -- to see depth. It is used in simple stereo viewing devices,
such as the Viewmaster(TM) used to view stereoscopic scenery in the
form of two images taken from adjacent locations. The Apollo
astronauts on the Moon knew how to take such stereo pairs, clicking
two frames of the same object in locations shifted slightly
horizontally with respect to each other.
A way to allow a crowd of people simultaneously to view a stereoscopic
scene, is to provide them with anaglyphic glasses. One glass is
red, the other green, and the stereo scene is produced by the printing
process in a corresponding fashion. It is generally believed that such
scenes are of necessity monochrome -- red for the left image, green
for the right --, but this is not quite true: working colour
anaglyphic scenes have been produced.
Instructions for self-producing anaglypic glasses by copying colour
onto an overhead projector sheet can be easily obtained. Better quality
glasses can also be purchased inexpensively from many science shops or
internet mail orders.
If an optical instrument -- telescope, microscope, theodolite -- is
imprecisely focused, the cross-hairs will appear to move with respect
to the object focused on if one moves one's head horizontally in front
of the eyepiece. This is why it is important, especially when
performing measurements, to carefully focus in order to 'eliminate the
parallax', and to check by moving one's head.
Also in non-optical measurements, e.g., the thickness of a ruler can
create parallax in fine measurements. One is always cautioned in
science classes to "avoid parallax." By this it is meant that one
should always take measurements with one's eye on a line directly
perpendicular to the ruler, so that the thickness of the ruler does
not create error in positioning for fine measurements. A similar
error can occur when reading the position of a pointer against a scale
in an instrument such as a galvanometer. To help the user to
avoid this problem, the scale is sometimes printed above a narrow
strip of mirror, and the user positions his eye so that the
pointer obscures its own reflection. This guarantees that the user's
line of sight is perpendicular to the mirror and therefore to the
scale.
In photography, one also talks about the parallax of a camera
viewfinder: for nearby objects, a viewfinder mounted on top of the
camera will show something different from what the lens 'sees', and
people's heads may be cut off. The problem does not exist for the
single lens reflex camera, where the viewfinder looks (with the
aid of a movable mirror) through the same lens as is used for taking
the photograph.
Aerial photograph pairs, when viewed through a stereo viewer, offer a
spectacular stereo effect of landscape and buildings. High buildings
appear to 'keel over' in the direction away from the centre of the
photograph. Measuring this effect, also called parallax, allows one,
if the flying height and the distance between the aircraft's exposure
locations is known, to deduce the building's height.
Example of lunar parallax: Occultation of Pleiades by the Moon
A primitive way to determine the lunar parallax from one location is
by using a lunar eclipse. The full shadow of the Earth on the Moon has
an apparent radius of curvature equal to the difference between the
apparent radii of the Earth and the Sun as seen from the Moon. This
radius can be seen to be equal to 0.75 degrees, from which (with the
solar apparent radius 0.25 degrees) we get an Earth apparent radius of
1 degree. This yields for the Earth-Moon distance 60 Earth radii or
384.000 km.
Another way to use parallax to determine the distance to the moon would be to take two pictures of the moon at exactly the same time from two locations on earth, and compare the position of the moon relative to the visible stars. Using the orientation of the earth, and those two points, and a perpendicular displacement, a distance to the moon can be triangulated.
After Johannes Kepler discovered his Third Law, it was possible to build a scale model of the whole solar system, but without the scale. To fix the scale, it suffices to measure one distance within the solar system, e.g., the mean distance from the Earth to the Sun or astronomical unit (AU). When done by triangulation, this is referred to as the solar parallax, the difference in position of the Sun as seen from the Earth's centre and a point one Earth radius away, i.e., the angle subtended at the Sun by the Earth mean radius. Knowing the solar parallax and the mean Earth radius allows one to calculate the AU, the first, small step on the long road of establishing the size -- and thus the minimum age -- of the visible Universe.
It was proposed by Edmund Halley in 1716, that the transit of Venus over the solar disc be used to derive the solar parallax. And so it was done in 1761 and 1769. There is the famous story of the French astronomer Guillaume Le Gentil, who travelled to India to observe the 1761 event, but didn't reach his destination in time due to war. He stayed on for the 1769 event, but then there were clouds blocking the Sun...
Stellar parallax motion
On an interstellar scale, parallax created by the different orbital positions of the Earth causes the stars to seem to move.
The annual parallax is defined as the difference in position of a star as seen from the Earth and Sun, i.e. the angle subtended at a star by the mean radius of the Earth's orbit around the Sun. Given two points on opposite ends of the orbit, the parallax is half the maximum parallactic shift evident from the star viewed from the two points. The parsec is the distance for which the annual parallax is 1 arcsecond. A parsec equals 3.26 light years.
The distance of an object (in parsecs) can be computed as the reciprocal of the parallax. For instance, the nearest star, Alpha Centauri, has a parallax of 0.750". Therefore the distance is 1/0.750=1.33 parsecs or about 4.3 light years.
; Computation :
Measurements of the annual parallax as the earth goes through its orbit was the first reliable way to determine the distances to the closest stars. This method was first used by Friedrich Wilhelm Bessel in 1838 when he measured the distance to 61 Cygni, and it remains the standard for calibrating other measurement methods (after the size of the orbit of the earth is measured by radar reflection on other planets). In 1989, a satellite called "Hipparcos" was launched with the main
purpose of obtaining parallaxes and proper motions of nearby stars, increasing the reach of the method ten-fold.
The open stellar cluster 'Hyades' (Rain Stars) in Taurus extends over such a large part of the sky, 20 degrees, that the proper motions as derived from astrometry appear to converge with some precision to a perspective point north of Orion. Combining the observed apparent (angular) proper motion in seconds of arc with the also observed true (absolute) receding motion as witnessed by the Doppler redshift of the stellar spectral lines, allows us to estimate the distance of the cluster and its member stars in much the same way as using annual parallax.
Dynamic parallax has sometimes also been used to determine the distance to a supernova, when the optical wave front of the outburst was seen to propagate through the surrounding dust clouds at an apparent angular velocity, when we know its true propagation velocity to be that of light.
All these various astronomical parallax methods allow us to establish
the first rungs on the cosmic scale ladder, out to a few hundred light
years. Beyond that, other methods must be taken into use: e.g.,
"spectroscopic parallaxes" -- not really parallaxes at all. It is a
prototype of a "standard candle" method, where we observe the
apparent brightness of an object we know, based on some physical
theory, the true brightness of. For groups of stars we have the
Hertzsprung-Russell diagram which allows us to derive a star's
absolute brightness or magnitude from its spectral type. The
observed (apparent) brightness or magnitude being , we can then
derive its parallax by
Further methods, mostly of the "standard candle" variety,
are the variable stars called Cepheids -- the
absolute brightness of which depends on their observed period of
variation --, supernova brightnesses, spherical cluster sizes and
brightnesses, complete galaxy brightnesses etc. These are all much
more uncertain as they are not based on simple geometry. Yet,
parallaxes are the basis of everything, as they allow the calibration
of these more uncertain methods in the Solar neighbourhood.Definition
Use in distance measurement
By observing parallax,
measuring angles, and using geometry; one can
determine the distance to various objects. When this is in
reference to stars, the effect is known as stellar parallax.
The first measurements of a stellar parallax were made by
Bessel, in 1838.Informal introduction
Parallax of the human eye
Parallax and measurement instruments
Photogrammetric parallax
Lunar parallax
Solar parallax
Stellar parallax
The fact that stellar parallax was so small that it was unobservable at the time was used as the main scientific argument against heliocentrism during the early modern age; it did not then occur to many people that the stars are so very much further away from us than the planets of the solar system as to render that argument useless.Dynamic or moving-cluster parallax
The scale of the Universe
called "spectroscopic parallax".