Eyepiece

Several properties of an eyepiece are likely to be of interest to a user of an optical instrument, when comparing eyepieces and deciding which eyepiece suits their needs.

Eyepieces are optical systems where the entrance pupil is invariably located outside of the system. They must be designed for optimal performance for a specific distance to this entrance pupil (i.e. with minimum aberrations for this distance). In a refracting astronomical telescope the entrance pupil is usually close to the object glass. This is usually many feet distant from the eyepiece; whereas with a microscope eyepiece the entrance pupil is close to the back focal plane of the objective, mere inches from the eyepiece. Hence microscope eyepieces must be corrected differently from telescope eyepieces and are not interchangeable with optimum performance.

Elements are the individual lenses. The first eyepieces had only one element which delivered highly distorted images. Two and three-element designs were invented soon after, and quickly became standard due to the improved image quality. Today, engineers assisted by computer-aided drafting software have designed eyepieces with seven or eight elements that deliver exceptionally large, sharp views.

Internal reflections, sometimes called scatter cause the light passing through an eyepiece to disperse and reduce the contrast of the image projected by the eyepiece.

One solution to scatter is to use thin film coatings over the surface of the element. These thin, one or two wavelengths deep, coatings work to reduce reflections and scattering by changing the refraction of the light passing through the element. Some coatings may also absorb light that is not being passed through the lens in a process called total internal reflection where the light incident on the film is at a shallow angle.

Chromatic aberration is caused because light of different colours does not bend the same amount when passing from one medium to another. With an eyepiece, chromatic aberration occurs due to the transition between glass and air. Blue light, seen through a eyepiece element, will not focus to the same plane as red light. The effect can create a "ring" of colour around point sources of light, and results in a general blurriness to the image.

The problem can be reduced in several ways. One method is to apply a thin film to the eyepiece element that corrects. The more traditional approach, however, is to eliminate the aberration by using multiple elements of different types of glass and curvature.

Longitudinal chromatic aberration is much a more pronounced effect of main optical telescope elements, because the focal lengths are so long. Microscopes, whose focal lengths are generally shorter, do not tend to suffer from this effect.

In general, any eyepiece that corrects for chromatic aberration will correct both types.

The focal length of an eyepiece is the distance from the principal plane of the eyepiece where parallel rays of light converges to a single point. When in use, the focal length of an eyepiece, combined with the focal length of the telescope or microscope to which it is attached, determines the magnification. It is usually expressed in millimetres when referring to the eyepiece alone. When interchanging a set of eyepieces on a single instrument, however, some users prefer to refer to identify each eyepiece by the magnification produced.

For telescope, the angular magnification produced by the combination of a particular eyepiece and telescope or microscope combination can be calculated with the following formula:

${\displaystyle \mathrm {MA} ={\frac {f_{O}}{f_{E}}}}$ 

where:

• ${\displaystyle \mathrm {MA} }$  is the calculated angular magnification.
• ${\displaystyle f_{O}}$  is the focal length of the telescope objective.
• ${\displaystyle f_{E}}$  is the focal length of the eyepiece, expressed in the same units of measurement as ${\displaystyle f_{T}}$ .

For a compound microscope the corresponding formula is

${\displaystyle \mathrm {MA} ={\frac {DD_{\mathrm {EO} }}{f_{O}f_{E}}}={\frac {D}{f_{E}}}\times {\frac {D_{\mathrm {EO} }}{f_{O}}}}$ 

where

• ${\displaystyle D}$  is the distance of closest distinct vision (usually 250mm)
• ${\displaystyle D_{\mathrm {EO} }}$  is the distance between the back focal plane of the objective and the back focal plane of the eyepiece (called tube length) typically 160mm for a modern instrument.
• ${\displaystyle f_{O}}$  is the objective focal length and ${\displaystyle F_{E}}$  is the eyepiece focal length.

Magnification increases, therefore, when the focal length of the eyepiece is shorter, or when the focal length of the instrument is longer. For example, a 25 mm eyepiece in a telescope with a 1200 mm focal length would magnify objects 48 times. A 4 mm eyepiece in the same telescope would magnify 300 times.

Telescope eyepieces tend to be referred to by their focal length, by amateur astronomers. In astronomy, the focal length is usually expressed using millimetres, and typically ranges from about 3 mm to 50 mm. The actual magnification delivered at these focal lengths depends on the telescope.

Some astronomers do, however, prefer to specify the resulting magnification power, rather than the focal length, when describing the eyepiece used for observations. It is often more convenient to express magnification in observation reports, as it gives a more immediate impression of what view the observer actually saw. Due to its dependence on properties of the particular telescope in use, however, magnification power alone is meaningless for describing a telescope eyepiece.

By convention Microscope eyepieces are usually specified by power instead of focal length. Microscope eyepiece power ${\displaystyle P_{\mathrm {E} }}$  and objective power ${\displaystyle P_{\mathrm {O} }}$  are defined by

${\displaystyle P_{\mathrm {E} }={\frac {D}{f_{E}}},\qquad P_{\mathrm {O} }={\frac {D_{\mathrm {EO} }}{f_{O}}}}$ 

thus from the expression given earlier for the angular magnification of a compound microscope

${\displaystyle \mathrm {MA} =P_{\mathrm {E} }\times P_{\mathrm {O} }}$ 

This definition of power relies upon an arbitrary decision to split the angular magnification of the instrument into separate factors for the eyepiece and the objective. Historically Abbe described microscope eyepieces using a different decomposition in terms of angular magnification of the eyepiece and `initial magnification' of the objective. While convenient for the optical designer, this turned out to be less convenient from the viewpoint of practical microscopy and was abandoned.

Common eyepiece powers are 8X, 10X, 15X, and 20X. These powers assume the generally accepted visual distance of closest focus ${\displaystyle D}$  of 250 mm, so the focal length of the eyepiece can be calculated by dividing the eyepiece power into 250 mm. Although the accepted standard focal length is 250 mm, microscopes are now built with 160 mm focal lengths, to allow for them to be more compact. Modern instruments may also use objectives designed for an infinite tube length (with an auxiliary correction lens in the tube).

The total angular magnification of a microscope image is calculated by multiplying the eyepiece power by the objective power. For example, a 10X eyepiece with a 40X objective will magnify the image 400 times.

In some eyepiece types, such as Ramsden eyepieces (described in more detail below), the focal plane is located outside of the eyepiece in front of the field lens. This is therefore accessible as a location for a graticule or micrometer crosswires. In the Huygenian eyepiece the focal plane is located between the eye and field lenses inside the eyepiece and is hence not accessible.

The field of view, often abbreviated FOV, describes the area of a target (measured as an angle from the location of viewing) that can be seen when looking through an eyepiece. The field of view seen through an eyepiece varies, depending on the magnification achieved when connected to a particular telescope of microscope, and also on properties of the eyepiece itself. Eyepieces are differentiated by their field stop, which is the narrowest aperture that light entering the eyepiece must pass through to reach the field lens of the eyepiece.

Due to the effects of these variables, the term "field of view" nearly always refers to one of two meanings.

• Actual field of view is the angular size of the amount of sky that can be seen through an eyepiece when used with a particular telescope, producing a specific magnification. It is typically between one tenth of a degree, and two degrees.
• Apparent field of view is a derived constant value for a given eyepiece. By itself, the apparent field of view is only an abstract value, but it can be used to calculate what the actual field of view will be when the eyepiece is combined with a telescope to produce a particular magnification. The measurement ranges from 35 to over 80 degrees. The apparent field of view of an eyepiece is often stated in eyepiece specifications, as it provides a convenient method for a user to calculate the actual field of view with their own telescope.

It is common for users of an eyepiece to want to calculate the actual field of view, because it indicates how much of the sky will be visible when the eyepiece is used with their telescope. The most convenient method of calculating the actual field of view depends on whether the apparent field of view is known.

If the apparent field of view is known, the actual field of view can be calculated as:

${\displaystyle FOV_{C}={\frac {FOV_{P}}{mag}}}$ 

or

${\displaystyle FOV_{C}={\frac {FOV_{P}}{({\frac {f_{T}}{f_{E}}})}}}$ 

where:

• ${\displaystyle FOV_{C}}$  is the actual field of view, calculated in the unit of angular measurement in which ${\displaystyle FOV_{P}}$  is provided.
• ${\displaystyle FOV_{P}}$  is the apparent field of view.
• ${\displaystyle mag}$  is the magnification.
• ${\displaystyle f_{T}}$  is the focal length of the telescope. The focal length of the telescope objective is the diameter of the objective times the focal ratio. It represents the distance at which the mirror or objective lens will cause light to converge on a single point.
• ${\displaystyle f_{E}}$  is the focal length of the eyepiece, expressed in the same units of measurement as ${\displaystyle f_{T}}$ .

If the apparent field of view is unknown, the actual field of view can be calculated as:

${\displaystyle FOV_{C}={\frac {57.3d}{f_{T}}}}$ 

where:

• ${\displaystyle FOV_{C}}$  is the actual field of view, calculated in degrees.
• ${\displaystyle d}$  is the diameter of the eyepiece field stop in mm.
• ${\displaystyle f_{T}}$  is the focal length of the telescope, in mm.

There are three standard barrel sizes for telescopes. The two main barrel sizes are usually expressed using inches, because the amateur telescope began in the United States.

1. The smallest standard barrel size is 24.5 mm (0.965 inches). The only telescopes still manufactured with this size, however, are low-quality telescopes usually found in toy stores and malls. Many of these eyepieces are plastic, and some even have plastic lenses. High-quality eyepieces with this barrel size are hard to find.
2. Eyepieces with barrel sizes of 1¼ inches (31.75 mm) are the most commonly used. The practical upper limit on focal lengths for eyepieces with 1¼ inch (31.75 mm) barrels is about 32 mm. With longer focal lengths, the edges of the barrel itself intrude into the view limiting its size. With focal lengths longer than 32 mm, the available field of view is cut to below 50 degrees, which most amateurs consider to be too small.
3. Eyepieces with 2 inch (50.8 mm) barrels are also available. The Larger 2 inch (50.8 mm) size helps alleviate the limit on focal lengths. The upper limit of focal length with 2 inch eyepieces is about 50 mm. The trade-off is that these eyepieces are usually more expensive, and won't fit in some telescopes.

Microscopes have standard barrel sizes measured in millimeters: 23.5 mm and 30 mm, slightly smaller than telescope barrels.

The eye needs to be held at a certain distance behind the eye lens of an eyepiece to see images properly through it. This distance is called the eye relief. A larger eye relief means that the optimum position is further from the eyepiece, making it easier to view an image. However if the eye relief is too large it can be uncomfortable to hold the eye in the correct position for an extended period of time, for which reason some eyepieces with long eye relief have cups behind the eye lens to aid the observer in maintaining the correct observing position. The eye pupil should coincide with the Ramsden disc, the image of the of the entrance pupil, which in the case of an astronomical telescope corresponds to the object glass.

Eye relief typically ranges from about 2 mm to 20 mm, depending on the construction of the eyepiece. Long focal-length eyepieces usually have ample eye relief, but short focal-length eyepieces are more problematic. Until recently, and still quite commonly, eyepieces of a short-focal length have had a short eye relief. Good design guidelines suggest a minimum of 5-6 mm to accommodate the eyelashes of the observer to avoid discomfort. Modern designs with many lens elements, however, can correct for this, and viewing at high power becomes more comfortable. This is especially the case for spectacle wearers, who may need up to 20 mm of eye relief to accommodate their glasses.

Technology has developed over time and there are a variety of eyepiece designs for use with optical telescopes. They vary in their internal lens configuration and different designs are sometimes more appropriate both for different types of viewing, and for different types of telescope. Eyepiece designs include Huygens, Ramsden, Orthoscopic, Kellner, RKE, Erfle, Plössl, and Nagler. Several of these are described in more detail below.

The two-elements Huygens eyepiece was invented by Christiaan Huygens in the 17th century. This optical design is now considered as obsolete, however these eyepieces are often being sold with the cheapest telescopes. Huygens eyepieces suffer from short eye relief, high image distortion (especially on short focus telescopes), chromatic aberration and have very narrow apparent field of view. On the other hand, they can be very useful for solar projection since they don't use cement to hold the lens elements.

Huygens eyepieces consist of two planoconvex lenses with the plane sides towards the eye separated by an air gap. The lenses are called the eye lens and the field lens. It is usually designed for zero transverse chromatic aberration. The focal plane is located between the two lenses. If the lenses are made of glass of the same refractive index, to be used with a relaxed eye and a telescope with an infinitely distant objective then the separation is given by:

${\displaystyle d={\frac {1}{2}}(f_{A}+f_{B})}$ 

where ${\displaystyle f_{A}}$  and ${\displaystyle f_{B}}$  are the focal lengths of the component lenses.

The Ramsden eyepiece, created by Jesse Ramsden, comprises two plano convex lenses of the same focal length and glass, placed less than one focal length apart. The separation varies between different designs, but is typically somewhere between 7/10 and 7/8 of the focal length of the lenses, the choice being a trade off between residual transverse chromatic aberration (at low values) and at high values running the risk of the field lens touching the focal plane when used by a an observer who works with a close virtual image such as a myopic observer, or a young person whose accommodation is able to cope with a close virtual image (this is a serious problem when used with a micrometer as it can result in damage to the instrument). A separation of exactly 1 focal length is also inadvisable since it renders the dust on the field lens disturbingly in focus. The two curved surfaces face inwards. The focal plane is thus located outside of the eyepiece and is hence accessible as a location where a graticule, or micrometer crosshairs may be placed. Because a separation of exactly one focal length would be required to correct transverse chromatic aberration, it is not possible to correct the Ramsden design completely for transverse chromatic aberration. The design is slightly better than Huygens but still not up to today’s standards. It remains highly suitable for use with instruments operating using near monochromatic light sources e.g. polarimeters.

Carl Kellner designed this first modern achromatic eyepiece in 1850. Kellner eyepieces are a 3-lens design. An achromatic doublet is used in place of the eye lens in the Ramsden design to correct the residual transverse chromatic aberration. They are inexpensive and have fairly good image from low to medium power and are far superior to Huygenian or Ramsden design. The biggest problem of Kellner eyepieces was internal reflections. Today's anti-reflection coatings make these usable, economical choices for small to medium aperture telescopes with focal ratio f/6 or longer.

An RKE eyepiece is an adaptation of a Kellner eyepiece designed by Dr. David Rank for the Edmund Scientific Corporation, who marketed it throughout the late 1960s and early 1970s. This design provides slightly wider field of view than classic Kellner design. There is some ambiguity about what RKE stands for. Some speculation suggests that it stands for Rank Kellner Eyepiece or Rank Kellner Edmund. Alternative speculation suggests that it stands for Reversed Kellner Eyepiece, because certain elements within the eyepiece have been reversed from the Kellner design on which it is based.

The 4-element Orthoscopic eyepiece invented by Ernst Abbe in 1880 uses a triplet field lens and a double convex eye lens. Orthos have nearly perfect image quality, good eye relief but a little bit narrow apparent field of view (about 45°). Even today these eyepieces are superior to most others, for planetary and lunar viewing.

Erfles were invented during the first world war for military purposes, described in US patent by Erfle number 1,478,704 of Aug 1921. They are a 5-element design which is a logical extension to wider fields of the four lens military eyepiece design. Erfle eyepieces are designed to have wide field of view (about 60 degrees), but they are unusable on high powers because they suffer from astigmatism and ghost images. However, on low powers (20mm and up) they are excellent. Erfles are very popular because they have large eye lenses, good eye relief and can be very comfortable to use.

By far the most popular eyepiece design today. The Plössl eyepiece covers a range of eyepieces with at least 4 optical elements. Usually consisting of two sets of doublets, a convex and concave element sandwiched together, the lens provides a wide eye relief along with a large FOV. These two properties make this lens ideal for a variety of observational purposes including deep sky and planetary viewing.

The chief disadvantage of the Plössl optical design is tiny short relief which is about 70-80% of focal length. The short eye relief is more critical in short focal lengths when it starts to be uncomfortable for viewing.

This eyepiece is one of the more expensive to manufacture because of the quality of glass, and the need for well matched convex and concave lenses to prevent internal reflections. Due to this fact, the quality of different Plössl eyepieces balances. There are notable differences between cheap Plössl's with simplest anti-reflection coatings and well made ones.

Originally designed by G. S. Plossl in 1860, several versions can be found on the amateur astronomy market. Al Nagler owner of Tele Vue Optics created a large demand in the amateur market for this eyepiece when he designed a high quality Plössl in the 1980s.

• A. E. Conrady, Applied Optics and Optical Design, Volume I, Oxford 1929.
• R. Kingslake, Lens Design Fundamentals, Academic Press 1978.

• Barlow lens
• Microscope
• Optical telescope

John Savard's Eyepiece Page

A list of eyepieces with some details of their construction.

Peoria Astronomical Society Eyepiece page

A list of eyepieces with some details of their construction.

Astro-Tom.com Eyepiece Article

A list of eyepieces with some details of their construction.