Near point

In visual perception, the near point is the closest point at which an object can be placed and still form a focused image on the retina, within the eye's accommodation range. The other limit to the eye's accommodation range is the far point.

A normal eye is considered to have a near point at about 11 cm (4.3 in) for a 30 year old. The near point is highly age dependent (see accommodation). A person with hyperopia or presbyopia would have a near point that is further than normal.

Sometimes, near point is given in diopters (see Presbyopia § Mechanism), which refers to the inverse of the distance. For example a normal eye would have a near point of ${\frac {1}{11\ {\text{cm}}}}=9\ {\text{diopters}}$ .

Vision correction

A person with hyperopia has a near point further than comfortable, (i.e. 25 cm) $NP > 25 cm$ , and hence is unable to bring an object 25 cm away into sharp focus. A corrective lens can be used to correct hyperopia by imaging an object at distance $D = 25 cm$ onto a virtual image at the patient's near point. From the thin lens formula, the required lens will have optical power $P$ given by[1]

$P\approx {\frac {1}{D}}-{\frac {1}{\mathit {NP}}}$ .

The calculation can be further improved by taking into account the distance between the spectacle lens and the human eye, which is usually about 1.5 cm:

$P={\frac {1}{D-0.015\;{\text{m}}}}-{\frac {1}{{\mathit {NP}}-0.015\;{\text{m}}}}$ .

For example, if a person has $NP = 1 m$ , then the optical power needed is $P = +3.24 diopters$ where one diopter is the reciprocal of one meter.

References

"Vision Correction | Physics". courses.lumenlearning.com. Retrieved 2019-12-05.

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[1] "Vision Correction | Physics". courses.lumenlearning.com. Retrieved 2019-12-05.