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Eyeglasses can correct
numerous
refraction problems. The most
common are
nearsightedness,
farsightedness,
astigmatism and
presbyopia.
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| Concave
and convex lenses compensate for
defects in the eye, bending
light rays to place them
precisely on the retin and
correcting vison. |
A concave lens is
thinner in the center and thicker on the
edges. It bends light so that it
converges further back in the eye,
reaching the
retina and correcting
nearsightedness. A convex lens is
thicker in the center and thinner on the
edges, opposite from a concave lens. It
bends light to converge further forward
in the eye, landing on the retina and
correcting farsightedness. Concave and
convex lenses can be used separately and
in combination to correct a variety of
vision problems.
Lens varieties
include:
- Single-vision
lenses -
Single-vision lenses have the same
focusing power over the surface of
the whole lens. They may be
prescribed for distance, near or
reading-only vision.
- Bifocals -
Bifocals
meet dual vision needs. The lenses
are sectioned into two or three
parts that correct vision at
different distances. The upper part
generally has the power you need to
see in the distance (or has no
correction), while the bottom
portion has the strength you need to
read. The line between the sections
of the lens bothers some people, as
objects appear to jump when eyes
cross the line.
 |
| Bifocals
provide near vision correction,
and may alo provid distance
correction in the upper portion. |
- Trifocals -
Trifocals
meet vision needs at three
distances. Similar to bifocals on
the top and bottom, there is a
middle section designed for vision
just beyond reading distance.
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| Trifocals
correct vision at three times
the distances. |
- Progressives -
These are
similar to bifocals and trifocals
but the variance in the lenses is
more gradual, correcting vision at
every distance and eliminating
visible lines
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|
Progressive lenses correct at
multiple distances and provide a
gradual transition instead of
visable lines and abrupt shifts.
Some distortion may be noticed
in the lower corners. |
Choosing Lens
Materials
Lenses are made from several materials.
There are a great many lens formulas and
coatings with different performance
characteristics.
- Glass -
Original material
used for glasses, these lenses are
made mainly of sand (silicon
dioxide) plus various elements (such
as titanium dioxide for thinness).
Glass lenses are long lasting and
naturally scratch-resistant. They
are heavy and breakable but can be
treated for shock resistance.
- Standard
plastic -
Developed in the 1960s, plastic
lenses are made of a hard resin that
is light and impact resistant. It is
thick and easily scratched unless
treated with a protective coating.
- Mid-index
plastic -
First used in the early 1990s,
higher index refraction means this
material reduces lens thickness
without compromising optical
performance. It is recommended for
light to moderate prescriptions. A
protective treatment can reduce
scratches.
- High-index
plastic -
The third wave of plastic materials
provides an even higher index of
refraction. It is ideal for those
with moderate to severe correction
needs because higher power
prescriptions can be made lighter
and thinner. A protective treatment
can reduce scratches.
- Polycarbonate
- The
newest lens material is an
acrylic-like resin that is used for
airplane windshields. It is the
thinnest, lightest and most
impact-resistance of all lens
materials, and comes with a scratch
resistant coating. Polycarbonates
are also inherently good at
filtering UV rays.
Selecting Lens
Treatments
All of these materials can be treated to
better protect your eyes, improve your
vision, increase the durability of your
lenses, and enhance appearance.
Scratch-resistant coatings, ultraviolet
light blockers, anti-reflectives, tints
and edge treatments can be combined to
meet your individual needs.
-
Scratch-resistant coatings -
Plastics and
polycarbonates are usually treated
with anti-scratch varnish. The
coating can be used on the front,
back, or both sides of the lens.
- Ultraviolet
light blockers -
While some materials
are better than others at filtering
damaging ultraviolet light, the only
way to get 100 percent protection is
with specific UV treatments.
-
Anti-reflective -
Anti-reflective
treatments (AR) have two purposes:
eliminate the glare others see when
looking at you, and eliminate
reflections and glare that you
experience when looking through your
lenses. Together, these effects
improve your appearance, comfort and
safety. Users typically notice less
glare from fluorescent lighting,
computer screens and car lights.
Contrast and detail are improved,
reducing eye strain and headaches.
AR-coated lenses used to attract
more dust and show dirt and smudges
more easily than non-AR coated
lenses. But today, many AR
treatments include a final coating
that better repels dust and dirt and
makes lenses easier to clean.
- All-in-ones -
The newest
option is an "all in one" coating,
combining the advantages of
scratch-resistance, anti-reflection,
and smudge resistance to offer the
ultimate lens treatment.
- Tints -
Lenses can be
tinted or colored for a variety of
reasons. Most often tints are
intended to filter out some light,
as in sunglasses. The right tint for
you will depend upon your vision
needs and your sensitivity to light.
- Clear -
Lenses
with no tint allow the maximum
amount of visible light to reach
the eye.
- Color -
Lenses
are available in virtually every
color imaginable. The color
chosen can be for sun
protection, personal style and
to enhance sight. Sun protection
colors are usually grey or
brown. Polarized lenses
eliminate the most reflective
glare and are recommended for
driving and around water.
- Gradient -
Gradient lenses have a darker
tint on the top and gradually
get lighter toward the bottom of
the lens. They are usually
chosen for appearance and sun
protection.
-
Photochromic -
These lenses are
clear when indoors and dark when
in the sun. The tint is
activated in only a few moments.
They are convenient and
comfortable, minimizing the need
for both clear and sunglasses.
- Edge treatment
- Lenses
are cut to fit the shape of the
frame. This leaves a frosted, rough
edge. This is especially noticeable
with higher prescriptions that
result in thicker lenses. The edges
can be polished to provide a
finished look, or left with the
frosted look.
Sources
"Polycarbonate," L'Opto85, Mar
1997, pp 23-25
Benjamin, WJ, ed. Borish's clinical
refraction. Philadelphia, PA: WB
Saunders, 1998, pp. 868-76
Fowler,C. "Why Not Make Your Own
Varifocal Lens?" Optician, 1998,
vol. 216, no. 569, pp. 18-20
Malaval, C, ed. "Seeing the World Past,"
Essilor, Paris: Creapress, 1997,
pp. 42-29 & 70-89
"Markets," SPC, 1999, vol. 99,
pp. 3-6 & 31-32
"Markets," SPC, 1999, vol. 102,
pp. 3-6
Mercier, J-L, Miege, C, LeSaux G,
Chauveau J-L. "The Design Loop for
Progressive Lenses," Points de Vue,
Apr, 1996. pp. 22-27 |
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