Zoom lens systems

Abstract

Zoom lens systems for use with moderately large image formats, such as those found in instant photography cameras, are provided. The systems include three lens units arranged in a negative/positive/negative power sequence and have a fixed aperture stop associated with the unit nearest the image. The positive unit is used for zooming and either the first or the third negative unit is used for compensating and focusing. Alternatively, the negative unit nearest the image is used for compensating and the negative unit farthest from the image is used for focusing. The systems achieve a long back focal length, a short front vertex to image distance, and in their simplest embodiments can consist of just three lens elements.

Description

FIELD OF THE INVENTION

This invention relates to zoom lens systems and, in particular, to zoom lens systems for use with moderately large image formats such as those found in instant photography cameras.

BACKGROUND OF THE INVENTION

For general photographic applications, it has been commonly accepted that a practical and economical zoom lens construction is one in which a first unit is used for focusing and two middle units are used for zooming and compensating. Such constructions also include a rearmost unit which contains an iris diaphragm which remains stationary during zooming. This type of lens construction has been used for most telephoto zoom lenses for 35 millimeter single-lens-reflex (SLR) cameras. The construction has provided fixed relative apertures (f-numbers) during zooming and the mechanical convenience of a fixed stop location.

However, with zoom lens ranges extended to include the wide angle region, the consequences of a fixed rear unit were found to be too severe. In particular, the front unit became large and thus heavy and expensive. Also, aberrations became excessive, thus requiring an increased number of lens elements. To overcome these problems, zoom lens systems were developed in which the aperture stop, and thus the exit pupil, moved during zooming. These systems were able to achieve a focal length range extending from about 0.8 to about 1.6 of the film diagonal while still having both a small diameter and a short length. In practice, the 0.8 to 1.6 range was adequate for most applications.

In a 35 millimeter SLR camera, the user views the object to be photographed by means of a viewing system, which includes a movable mirror that initially resides in the optical path following the zoom lens system to divert the image of the object to a viewing screen. This mirror is removed from the optical path prior to exposing the film. By texturing the viewing screen so that it produces a diffuse image, changes in the location of the exit pupil of the zoom lens system can be made effectively imperceptible to the user. Accordingly, for such applications, there is no need to fix the exit pupil location during zooming.

Instant photography cameras or other moderately large image formats impose requirements on zoom lens systems which are more difficult to satisfy than those imposed by 35 millimeter SLR cameras. For example, instant photography cameras use a film format substantially larger than that employed in a 35 millimeter camera, e.g., a diagonal greater than about 90 millimeters as opposed to a diagonal of about 42 millimeters as in conventional 35 millimeter film. If a conventional 35 millimeter SLR viewing system were to be used with such an instant photography camera, the result would be an impractically large camera body.

Consequently, viewing systems have been developed for instant photography cameras in which optical components, such as Fresnel mirrors, are introduced into the optical path between the taking lens and the viewing system's eye lens in order to reduce the size of the image presented to the eye lens. These viewing systems form an image at infinity which can be easily viewed by the user. Also, they image the exit pupil of the taking lens into the user's eye. As a result, the location of the exit pupil of a zoom lens system used with such a viewing system needs to remain substantially fixed with zooming so that the ultimate exit pupil of the zoom lens/viewing system combination remains at the user's eye throughout the zooming range.

As described below, in accordance with the invention, a fixed exit pupil is achieved by means of 1) a fixed aperture stop location for the zoom lens system and 2) locating the aperture stop at the image end of the zoom lens system. This arrangement is in itself advantageous for an instant photography camera because it provides an ideal location for the camera's shutter, namely, at the fixed location of the zoom lens system's aperture stop.

In addition to imposing the requirement that the exit pupil of a zoom lens system remains substantially fixed during zooming, instant photography cameras also impose the requirement that the f-number of the zoom lens system needs to vary in a controlled manner as zooming takes place. This requirement arises from the fact that in its preferred embodiments, the battery contained in the film pack of an instant photography camera provides all the power required for operation of the camera's various functions, including the power for the electronic flash. As a result, the amount of power allocated for the flash is limited by design. This, in turn, means that the amount of increase in the flash output available to compensate for decreases in the aperture of a zoom lens is also limited. This problem becomes more acute at the wide angle setting of the zoom lens, i.e., at the short focal length setting, since filling a wide angle with a flash requires more power than filling a narrow angle.

In general, a zoom lens system for an instant photography camera should have a f-number of about f/10 when the focal length is approximately equal to the film diagonal. For shorter focal lengths, the f-number should decrease, e.g., to approximately f/8. For longer focal lengths, a larger f-number, e.g., f/14, may be acceptable, especially if the camera's electronic flash has a variable angular output.

In addition to the above requirements, a zoom lens system for an instant photography camera should have: 1) a long back focal length sufficient for insertion of one mirror and in some cases three mirrors, e.g., a back focal length about 1.3 times the focal length at the wide angle position for a one mirror system and a back focal length about 1.7 times the focal length at the wide angle position for a three mirror system, 2) as short a front vertex to image distance as possible so as to minimize the storage size of the camera, and 3) small lens diameters in order to minimize weight and cost, e.g., for a 90 millimeter film diagonal, a maximum lens diameter of about 40 millimeters.

Instant photography cameras, however, do have certain characteristics which can be advantageously employed in designing a zoom lens system. In particular, due to the characteristics of instant photography color film, full color correction is in general not needed, e.g., a transverse chromatic aberration of approximately 0.125 millimeters can be tolerated.

In accordance with the invention, this characteristic allows for the use of lens units having strong optical powers and few optical elements. This combination can be employed in the zoom lens systems of the invention because the lens units need not be individually color corrected. Rather, color correction sufficient to satisfy the relatively relaxed requirements of instant photography color film can be achieved through the interaction of the units making up the zoom lens system, even though those units are not themselves individually color corrected.

DESCRIPTION OF THE PRIOR ART

Tachihara et al., U.S. Pat. No. 4,412,725, shows a zoom lens system having two lens units and a fixed aperture stop located after the second lens unit. This system does not include a third lens unit having a negative power. In terms of the requirements of a zoom lens system for an instant photography camera, the Tachihara lens lacks a sufficiently long back focal length and a sufficiently short overall length. Also, the lens system of this patent has a highly complex structure.

Zoom lens systems employing three lens units having a negative/positive/negative power arrangement are shown in U.S. Pat. Nos. 4,586,793, 4,198,127 and 4,304,466, and Japanese Patent Publications Nos. 64-72114 and 62-124516. In each of these designs, the aperture stop moves with the second lens unit.

U.S. Pat. No. 4,776,228 shows a zoom lens system employing three lens units in which the aperture stop is in the third lens unit. The aperture stop, however, moves during zooming and the third lens unit in this case has a positive power.

In view of the foregoing, it is an object of this invention to provide zoom lens systems suitable for use in instant photography cameras, as well as other optical systems having moderately large image formats. More particularly, it is an object of the invention to provide zoom lens systems which have some or all of the following properties: 1) an overall simple construction so that the system can be manufactured economically; 2) a long back focal length; 3) a short overall length; 4) lens elements having small diameters; 5) a substantially fixed exit pupil location during zooming; 6) a substantially fixed aperture stop location during zooming; and 7) a predetermined f-number variation during zooming.

SUMMARY OF THE INVENTION

The invention in accordance with certain of its aspects is a zoom lens system for forming an image. From object to image space, the zoom lens system comprises:

(a) a first lens unit having a negative optical power; (b) a second lens unit which is on the image side of the first lens unit and has a positive optical power; (c) a third lens unit which is on the image side of the second lens unit and has a negative optical power; and (d) an aperture stop which is on the image side of the second lens unit;

wherein:

the second lens unit is moveable to change the magnification of the lens system;

either the first lens unit or the third lens unit is 5moveable to focus the lens system and to compensate for changes in focus resulting from movement of the second lens unit; and

the aperture stop is substantially fixed during zooming of the lens system.

In accordance with other aspects of the invention,the zoom lens system comprises:

(a) a first lens unit having a negative optical power; (b) a second lens unit which is on the image side of the first lens unit and has a positive optical power; (c) a third lens unit which is on the image side of the second lens unit and has a negative optical power; and (d) an aperture stop which is on the image side of the second lens unit;

wherein:

the first lens unit is moveable to focus the lens system;

the second lens unit is moveable to change the magnification of the lens system;

the third lens unit is moveable to compensate for changes in focus resulting from movement of the second lens unit; and

the aperture stop is substantially fixed during zooming of the lens system.

As used herein, an aperture stop is considered to be substantially fixed if its motion during zooming is less than about 0.05 times f.sub.max and preferably is less than about 0.01 times f.sub.max, where f.sub.max is the system's maximum effective focal length. As indicated above, the aperture stop is located on the image side of the second lens unit and can be before the third lens unit, part of the third lens unit, or after the third lens unit.

In accordance with certain preferred embodiments of the invention, the zoom lens system has some or all of the following properties: (1) the third lens unit is a single lens element; (2) the third lens unit is a single lens element and that element has an index of refraction which is higher than the index of refraction of any other lens element in the lens system; (3) the first lens unit is a single lens element; (4) the first lens unit is a single lens element and that element has at least one aspheric surface; (5) the second lens unit comprises only positive lens elements; (6) the first, second, and third lens units are each a single lens element; (7) the first lens unit is a single lens element, the second lens unit is two positive lens elements, and the third lens unit is a single lens element; (8) the lens system has a maximum effective focal length f.sub.max and a minimum effective focal length f.sub.min and the size of the aperture stop is adjustable to increase the effective aperture of the lens system as the effective focal length of the lens system decreases from f.sub.max to f.sub.min ; (9) the first lens unit has a power whose absolute value is .vertline..PHI..sub.1 .vertline., the second lens unit has a power .PHI..sub.2, the third lens unit has a power whose absolute value is .vertline..PHI..sub.3 .vertline., and the ratio of (.vertline..PHI..sub.1 .vertline.+.vertline..PHI..sub.3 .vertline.)/.PHI..sub.2 is between about 1.0 and about 1.5; (10) the second lens unit has a focal length f.sub.2 and the ratio of f.sub.2 /f.sub.max is between about 0.10 and about 0.35; (11) the first lens unit has a focal length whose absolute value is .vertline.f.sub.1 .vertline., the third lens unit has a focal length whose absolute value is .vertline.f.sub.3 .vertline., and (a) the ratio of .vertline.f.sub.1 .vertline. to f.sub.min is less than about 0.9, and (b) the ratio of .vertline. f.sub.3 .vertline. to f.sub.min is less than about 1.0; (12) the ratio of the magnification of the aperture stop by the first and second lens units at f.sub.min to the magnification of the aperture stop by the first and second lens units at f.sub.max is less than about 2.0; and (13) the ratio of the back focal length (BFL) to f.sub.min is greater than about 1.2.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute part of the specification, illustrate the preferred embodiments of the invention, and together with the description, serve to explain the principles of the invention. It is to be understood, of course, that both the drawings and the description are explanatory only and are not restrictive of the invention. Briefly, the subject matter of the drawings is as follows:

FIGS. 1 through 10 are schematic side views of zoom lens systems constructed in accordance with the invention. The upper portion of each of these drawings shows the lens system in its f.sub.min configuration, and the lower portion shows it in its f.sub.max configuration. The upper portions also show the location of the aperture stop.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

As discussed above, the present invention relates to zoom lens systems for use with image diagonals of moderate size such as those found in instant photography cameras. The lens systems of the invention include three lens units of more or less complexity and performance: a first negative unit which can be used for focusing and also compensating; a second positive unit which moves to change the magnification of the system during zooming; and a third negative unit with which the aperture stop is associated and which can also be moved for compensating or focusing.

The design of the lens systems of the invention is particularly flexible in that while the second unit is the primary zooming unit, either the first or third unit can be used as a compensator, allowing the other to remain fixed in position during zooming. When used as a compensator, a unit's movement serves to compensate for the change in focus caused by movement of the second unit during zooming.

Preferably, the powers of the units are arranged so that the zoom lens systems have a long back focal length (BFL) and a short front vertex to image distance (FVD). To achieve the long BFL and short FVD, as well as to provide small diameters for the lens elements, relatively strong negative powers are used for the first and third units. In this connection, the ratio of .vertline.f.sub.1 .vertline. to f.sub.min is preferably less than about 0.9 and the ratio of .vertline.f.sub.3 .vertline. to f.sub.min is preferably less than about 1.0. Put other ways, the ratio of (.vertline..PHI..sub.1 .vertline.+.vertline..PHI..sub.3 .vertline.)/.PHI..sub.2 is preferably between about 1.0 and about 1.5, and/or the ratio of f.sub.2 /f.sub.max is preferably between about 0.10 and about 0.35.

In addition, it is desirable to maintain a relatively constant value for the pupil magnification of the combined first and second units during zooming. Preferably, this value is near 1.0. In particular, the ratio of the magnification of the aperture stop by the combined first and second lens units at f.sub.min to the magnification of the aperture stop by the combined first and second lens units at f.sub.max is preferably less than about 2.0. Stated another way, the ratio of the size of the aperture stop, for a constant aperture stop size, as seen through the first and second units at f.sub.min and f.sub.max is preferably less than about 2.0.

When the zoom lens system satisfies the foregoing condition, the change in the off-axis aberrations of the lens system with zooming is minimized, thus allowing the overall design of the lens system to be simplified. Specifically, near unity pupil magnification, small pupil magnification changes during zooming help reduce aberrations for off-axis image positions. This can most easily be seen if pupil magnification is expressed as an angular ratio u.sub.pr /u'.sub.pr rather than the equivalent size ratio y'/y, where u.sub.pr is the paraxial principal ray entrance angle at the entrance pupil and u'.sub.pr is the corresponding angle at the aperture stop. If u.sub.pr =u'.sub.pr the principal rays do not deviate and the aberration contribution is reduced. If the value of u'.sub.pr is considerably greater or smaller than u.sub.pr then the aberration contributions are increased. While these increased aberrations can be corrected by using other lens units of the system, for a zoom lens, the lens units are moving so both the compensating aberrations and the aberrations of the unit itself are changing. For this reason, complex designs are needed to correct the units for off-axis aberrations, unless the pupil magnification changes during zooming are small, and preferably the pupil magnification is small for each of the units.

If the zoom range is not too large (e.g., 2:1 or less), the lens systems of the invention can consist of only three lens elements, some of which have aspherical surfaces to achieve acceptable aberration correction.

As the zoom range is increased, the complexity of the design also increases. Divided power or additional aspheres first come into play, and then as the lens powers further increase, lens elements are introduced for color correction. These color correction lens elements have powers opposite to the power of the unit in which they are inserted.

Because the sum of the powers of the units making up the system is generally negative, a difference in refractive index is used to correct for Petzval curvature. Preferably, this is done by using a high index material for the power element of the third unit, e.g., a material having an index of refraction greater than about 1.6. The higher index of refraction material can be a flint type glass. This element can be readily fabricated in glass since it generally does not need to have an aspherical surface.

The lens systems of the invention provide wide latitude with regard to the use of aspherical surfaces in the second unit. The first unit, on the other hand, generally should include an asphere or the addition of positive elements to provide for distortion correction. Elements including aspheres are preferably fabricated of plastic materials which can be economically molded to the needed shapes. For smaller zoom ranges (e.g., 2:1) only a singlet lens is required for the first lens unit. This element should have a large Abbe value, e.g., an Abbe value above about 55, to reduce lateral color.

For use with an electronic flash, the size of the aperture stop can be made adjustable so as to increase the effective aperture of the system as the effective focal length decreases from f.sub.max to f.sub.min. For example, the f-number of the lens system can decrease from about 14 to about 8 as zooming takes place.

FIGS. 1 to 10 illustrate various lens systems constructed in accordance with the invention and referred to herein as Examples 1 to 10, respectively. Corresponding prescriptions appear in Tables 1 to 10, respectively. Summaries of the various properties of these lens systems are set forth in Tables 11-13.

The glasses and plastics referred to in the prescription tables are set forth in Table 14, where the glass names are the SCHOTF designations. Equivalent glasses made by other manufacturers can be used in the practice of the invention. The aspheric coefficients set forth in the prescription tables are for use in the following equation: ##EQU1## where z is the surface sag at a distance y from the optical axis of the system, c is the base curvature of the lens at the optical axis, and k is a conic constant which is zero for the lens systems of FIGS. 1-10 except where noted.

The abbreviations used in the tables are as follows: SN--surface number; CLR. AP.--clear aperture; ZP--zoom position; f/--infinity f-number; EFL--effective focal length; f.sub.min --minimum effective focal length of the lens system corresponding to the system's wide angle position; f.sub.max --maximum effective focal length of the lens system; .PHI..sub.1 =1/f.sub.1, .PHI..sub.2 =1/f.sub.2, and .PHI..sub.3 =1/f.sub.3, where f.sub.1, f.sub.2, and f.sub.3 are the focal lengths of the first, second, and third lens units, respectively; .PHI.=.PHI..sub.1 +.PHI..sub.2 +.PHI..sub.3 ; f/.sub.min --infinity f-number at f.sub.min ; f/.sub.max --infinity f-number at f.sub.max ; BFL--back focal length; FVD--front vertex to image distance; FVD.sub.min --minimum front vertex to image distance; PMR--ratio of entrance pupil magnification at f.sub.min to entrance pupil magnification at f.sub.max ; FIELD--half angle field of view; and HFOV--half angle field of view at f.sub.min. Surfaces, lens elements, and lens units are identified by "S", "L" and "U" numbers, respectively, in the figures.

All dimensions given in the tables are in millimeters. Thickness values in the prescription tables represent the distance between the surface with which the thickness value is aligned and the next higher surface number. They thus correspond to either lens thicknesses or lens spacings depending upon the surface number with which the thickness is associated.

Without intending to limit it in any manner, the present invention will be more fully described by the following examples.

EXAMPLES 1 and 2

Examples 1 and 2 illustrate embodiments of the invention employing three elements in which the second element is used to change the system's magnification and either the first element (Example 1) or the third element (Example 2) is used for compensating and focusing. In the Example 2 embodiment, if desired, the first element can be used for focusing, rather than the third element.

EXAMPLE 3

Example 3 illustrates a variation of the lens system of Example 1 wherein the second lens unit includes two positive lens elements. This configuration avoids the thick lens element of Example 1.

EXAMPLES 4 and 5

The lens systems of Examples 4 and 5 employ a compound second lens unit which provides improved color correction. These systems have a somewhat greater focal length range than the systems of Examples 1-3. The system of Example 4 has a constant f/10 relative aperture during zooming, while that of Example 5 varies from f/8 to f/14 as the focal length of the system increases from its minimum to its maximum focal length.

EXAMPLE 6

Example 6 illustrates a lens system having a focal length range on the order of 2:1 and a field of view of more than 60.degree..

EXAMPLES 7 through 10

Examples 7 through 10 illustrate lens systems having increased f.sub.max values achieved through the addition of elements to the second unit in Example 7 and to the first and second units in Examples 8 through 10.

Although preferred and other embodiments of the invention have been described herein, other embodiments will be evident to those skilled in the art without departing from the scope of the invention as defined by the following claims.

TABLE 1__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 3304.1212 2.50000 FK5 39.582 27.9640 zoom 33.633 29.4444 19.82802 ACRYLIC 22.374 -29.4988 zoom 18.315 69.3003 1.24499 SF14 12.266 27.5475 12.26__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 2.8963E-06 -3.7344E-09 4.2323E-12 2.5231E-15 -3.0762E-18 -8.1682E-21 0.03 -6.0912E-06 -5.4378E-08 1.5967E-10 9.0665E-14 -7.7705E-15 1.5054E-17 -1.04 9.6052E-06 -1.6273E-07 1.4385E-09 -3.6565E-12 -9.5067E-14 6.5097E-16 0.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 4 EFL__________________________________________________________________________ 1 42.151 0.300 78.0 2 23.239 5.576 105.0 3 16.417 8.497 120.0__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 30.0.degree. f/10.00 EFL: 77.9795 FVD: 184.968 BFL: 118.944SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 23.0.degree. f/10.00 EFL: 104.973 FVD: 171.333 BFL: 118.945SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 20.0.degree. f/10.00 EFL: 119.973 FVD: 167.436 BFL: 118.949__________________________________________________________________________ TABLE 2__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 879.6939 2.50000 FK5 39.742 26.2774 zoom 33.523 33.6184 18.53512 ACRYLIC 22.764 -31.4526 zoom 19.695 51.6391 1.24499 SF14 13.526 26.2562 13.14__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 3.2383E-06 -5.9305E-09 5.5323E-12 7.3400E-15 7.2597E-19 -2.7735E-20 0.03 -7.2431E-06 -4.4641E-08 2.0719E-10 -3.8373E-13 -1.0862E-14 4.6448E-17 -1.04 5.4039E-06 -1.5831E-07 1.6836E-09 -3.2557E-12 -9.9817E-14 5.6546E-16 0.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 4 EFL__________________________________________________________________________ 1 42.077 3.535 78.0 2 27.491 7.330 104.9 3 21.588 9.956 119.9__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 30.0.degree. f/10.00 EFL: 77.9616 FVD: 185.001 BFL: 117.108SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 23.0.degree. f/10.00 EFL: 104.936 FVD: 184.922 BFL: 127.980SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 20.0.degree. f/10.00 EFL: 119.925 FVD: 184.978 BFL: 131.154__________________________________________________________________________ TABLE 3__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 -103.8660 2.26500 494527 39.702 42.0302 zoom 34.703 23.1953 6.00000 ACRYLIC 26.194 175.1887 7.42601 24.975 -197.0454 6.00000 ACRYLIC 21.756 -24.8371 zoom 20.577 246.3657 1.12796 769272 9.968 40.7847 10.27__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 5.9157E-06 -6.0045E-09 4.9235E-12 3.0532E-15 -3.1568E-18 -1.0484E-20 0.03 -4.9716E-06 -3.5214E-08 -1.1278E-10 4.2662E-13 2.2850E-15 -1.5653E-17 -1.06 2.2366E-05 -2.0536E-07 2.4019E-09 -4.5486E-12 -1.8443E-13 1.0407E-15 0.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 6 EFL__________________________________________________________________________ 1 27.902 0.191 75.0 2 14.133 4.518 95.2 3 1.930 10.912 125.0__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 32.0.degree. f/10.00 EFL: 75.0204 FVD: 146.290 BFL: 95.3778SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 23.0.degree. f/10.00 EFL: 95.2262 FVD: 136.847 BFL: 95.3769SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 19.0.degree. f/10.00 EFL: 125.036 FVD: 131.042 BFL: 95.3809__________________________________________________________________________ TABLE 4__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 -90.6780 2.50000 FK5 42.842 41.1559 zoom 37.753 26.5909 24.05444 ACRYLIC 32.194 -22.8423 0.05000 30.195 -27.7884 2.99731 SF6 27.446 -42.6129 zoom 27.177 117.7337 1.24499 LAF7 14.088 33.7431__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 5.5697E-06 -1.2045E-08 2.3217E-11 -3.4428E-16 -7.4003E-17 7.9976E-20 0.03 -7.7342E-06 -4.6162E-09 -7.8872E-11 2.7589E-14 2.3366E-15 -8.9471E-18 0.04 4.1044E-06 -3.7268E-08 7.6259E-11 -3.5244E-14 -2.2513E-15 6.2032E-18 -1.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 6 EFL__________________________________________________________________________ 1 46.564 2.626 87.0 2 24.115 10.989 124.4 3 12.493 18.945 160.0__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 28.7.degree. f/10.00 EFL: 87.0056 FVD: 204.008 BFL: 123.972SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 20.0.degree. f/10.00 EFL: 124.409 FVD: 189.924 BFL: 123.973SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 14.5.degree. f/10.00 EFL: 160.014 FVD: 186.260 BFL: 123.975__________________________________________________________________________ TABLE 5__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 -86.6143 2.50000 FK5 43.002 37.9708 zoom 37.653 26.8378 24.61778 ACRYLIC 30.744 -22.8222 0.10000 26.495 -27.8741 2.99731 SF6 24.876 -44.0898 zoom 24.447 85.1771 1.24499 LAF7 17.128 31.8936 17.06__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 6.0043E-06 -1.2203E-08 2.3691E-11 -6.6761E-16 -7.7958E-17 8.4597E-20 0.03 -7.4588E-06 -2.4378E-09 -8.4643E-11 5.8913E-15 2.3318E-15 -8.5728E-18 0.04 3.6131E-06 -3.5276E-08 6-8102E-11 -8.9469E-14 -2.2129E-15 7.6557E-18 -1.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 6 EFL__________________________________________________________________________ 1 44.413 3.481 87.0 2 24.047 13.104 124.4 3 13.504 22.259 160.0__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 28.7.degree. f/8.00 EFL: 86.9996 FVD: 203.999 BFL: 124.644SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 20.0.degree. f/10.00 EFL: 124.401 FVD: 193.258 BFL: 124.647SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 14.5.degree. f/14.00 EFL: 160.004 FVD: 191.872 BFL: 124.650__________________________________________________________________________ TABLE 6__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 -102.1942 2.25000 FK5 41.262 30.5801 zoom 35.213 36.8083 17.79691 ACRYLIC 27.814 -20.8846 4.78050 27.625 -19.0006 2.69758 SF1 20.606 -50.7864 0.09000 21.227 -122.7282 4.38399 ACRYLIC 21.218 -18.6433 zoom 21.669 99.5783 1.12049 LAK21 15.5110 24.7527 15.48__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 7.3493E-06 -1.9966E-08 4.8102E-11 5.6056E-15 -2.5309E-16 3.0932E-19 0.03 -1.7524E-05 -2.7058E-08 -1.5959E-10 1.5065E-13 -5.6647E-16 -1.1933E-17 0.04 -2.0584E-06 -2.0890E-08 -4.4171E-11 -2.0239E-13 -6.8139E-16 4.3780E-18 -1.07 -1.9145E-05 -1.0011E-07 2.8882E-10 -2.4453E-12 -4.9412E-14 -3.9265E-16 0.08 -1.5868E-05 -2.3140E-08 -4.7459E-10 1.8169E-12 -8.6775E-15 -4.4529E-16 0.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 6 EFL__________________________________________________________________________ 1 35.376 0.016 78.0 2 15.339 7.402 112.0 3 4.443 14.944 148.1__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 31.0.degree. f/8.00 EFL: 78.0157 FVD: 183.625 BFL: 115.113SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 21.5.degree. f/10.00 EFL: 112.037 FVD: 170.991 BFL: 115.131SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 15.0.degree. f/14.00 EFL: 148.092 FVD: 167.675 BFL: 115.168__________________________________________________________________________ TABLE 7__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 -109.0711 2.50000 BK7 42.682 38.6965 zoom 37.673 35.0238 6.64671 ACRYLIC 30.074 -39.3508 3.97927 29.875 -37.6384 6.65000 ACRYLIC 27.336 -20.1876 1.09379 27.157 -21.9180 2.99731 645346 24.988 -144.6422 2.58450 25.319 -121.9281 4.87110 ACRYLIC 25.2510 -21.8807 zoom 25.3211 104.9711 1.24499 748402 17.1712 31.4413__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________1 4.0293E-06 -6.6558E-09 1.0255E-11 1.9775E-15 -3.4542E-17 3.2103E-20 0.03 -1.0308E-05 -1.3218E-08 -7.6350E-11 6.5145E-14 1.4877E-15 -7.0070E-18 0.06 -2.3701E-06 -7.6668E-09 -8.1017E-12 1.8288E-15 -1.0832E-16 -2.4292E-18 -1.09 -1.6883E-05 2.2446E-09 1.0884E-11 4.2466E-13 4.4431E-15 1.2455E-17 0.010 -1.1815E-05 1.3151E-08 -6.4491E-11 2.7035E-13 3.0739E-15 1.7923E-17 0.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 4 EFL__________________________________________________________________________ 1 42.741 0.018 87.0 2 20.114 8.465 124.4 3 4.937 19.854 176.8__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 28.7.degree. f/8.00 EFL: 87.0036 FVD: 204.007 BFL: 128.680SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 20.0.degree. f/10.00 EFL: 124.446 FVD: 189.828 BFL: 128.682SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 13.0.degree. f/14.00 EFL: 176.782 FVD: 186.041 BFL: 128.683__________________________________________________________________________ TABLE 8__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 78.1313 2.07373 LAK9 41.232 30.0012 7.26503 36.613 -111.9979 1.03687 ACRYLIC 36.764 143.9730 0.00000 36.445 111.3747 4.00000 SF6 36.446 275.4295 zoom 35.877 43.2028 3.11060 ACRYLIC 28.748 -2163.1731 0.00000 28.539 31.1591 9.33179 FK5 27.4010 -26.5027 1.03687 SF57 26.1911 -37.4162 zoom 26.3512 -147.4270 1.24499 FK5 17.0213 19.8176 16.88__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________4 -8.7926E-07 2.4773E-09 -8.3346E-12 -4.9026E-15 4.8379E-17 -4.0489E-20 0.07 -6.4937E-06 3.1109E-09 -7.4365E-11 8.8832E-14 1.5862E-15 -5.3996E-18 0.0__________________________________________________________________________ZOOM SPACINGSZP SN 6 11 EFL__________________________________________________________________________1 60.188 2.738 87.02 32.791 5.967 124.23 9.477 11.998 185.94 0.172 16.723 223.5__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 28.7.degree. f/10.00 EFL: 86.9646 FVD: 244.408 BFL: 152.442SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 20.0.degree. f/10.00 EFL: 124.220 FVD: 220.099 BFL: 152.241SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 13.0.degree. f/10.00 EFL: 185.864 FVD: 202.397 BFL: 151.822SYSTEM FIRST ORDER PROPERTIES, POS 4FIELD: 11.0.degree. f/10.00 EFL: 223.549 FVD: 197.540 BFL: 151.545__________________________________________________________________________ TABLE 9__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 40.5401 2.00000 LAK9 42.082 23.3550 8.45088 36.443 367.7721 2.00000 SK5 36.374 139.7349 0.01330 35.475 104.7151 4.33358 812267 35.326 3313.9972 1.61359 34.277 -88.4707 1.00000 ACRYLIC 34.348 87.0517 zoom 33.199 23.8377 9.00000 FK5 26.2110 -27.7117 1.00000 818246 25.9411 -45.3598 0.00000 26.1112 57.3203 3.00000 ACRYLIC 25.0113 -179.9489 zoom 24.5214 -109.1347 1.20072 466785 16.0115 20.1359 15.28__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________8 -4.3960E-06 8.5580E-09 -5.7343E-11 3.9639E-14 3.7415E-16 -6.1515E-19 0.012 -1.2049E-05 -2.2237E-08 1.5713E-10 -6.1636E-13 -8.1341E-15 4.1693E-17 -1.0__________________________________________________________________________ZOOM SPACINGS ZP SN 2 6 EFL__________________________________________________________________________ 1 53.567 1.821 84.0 2 28.675 5.277 119.9 3 7.830 11.616 179.9 4 0.166 16.011 217.0__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 29.3.degree. f/10.00 EFL: 83.9520 FVD: 238.913 BFL: 149.913SYSTEM FIRST ORDER PROPERTIES, POS 2FIELD: 20.0.degree. f/10.00 EFL: 119.924 FVD: 217.468 BFL: 149.904SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 13.0.degree. f/10.00 EFL: 179.928 FVD: 202.998 BFL: 149.941SYSTEM FIRST ORDER PROPERTIES, POS 4FIELD: 11.0.degree. f/10.00 EFL: 217.038 FVD: 199.822 BFL: 150.033__________________________________________________________________________ TABLE 10__________________________________________________________________________LENS SYSTEM PRESCRIPTIONSN RADIUS THICKNESS MATERIAL CLR. AP.__________________________________________________________________________1 51.6505 2.00000 LAK9 40.592 24.9630 8.45088 35.363 -273.0997 2.00000 SK5 35.114 48.1838 0.01338 33.805 36.2373 4.33358 633365 33.876 77.9128 zoom 33.187 49.9913 1.50000 ACRYLIC 25.418 -1491.0411 0.00000 25.509 27.8996 9.00000 FK5 26.8710 -19.9804 1.00000 765268 26.8211 -26.9290 zoom 27.2712 -301.1807 1.20072 657572 16.2713 20.2215 15.58__________________________________________________________________________ASPHERICAL SURFACE DATASN AD AE AF AG AH AI k__________________________________________________________________________7 -1.3501E-05 -3.6849E-08 1.4171E-10 -1.1897E-13 -5.5400E-15 1.3771E-17 -2.0__________________________________________________________________________ZOOM SPACINGSZP SN 6 11 EFL__________________________________________________________________________1 56.512 2.980 84.02 30.802 5.516 120.03 8.902 10.179 180.04 0.166 13.774 217.0__________________________________________________________________________SYSTEM FIRST ORDER PROPERTIES, POS 1FIELD: 29.3.degree. f/10.00 EFL: 84.0001 FVD: 239.000 BFL: 150.010SYSTEM FIRST ORDER PROPERTIES, POS 2 FIELD: 20.0.degree. f/10.00 EFL: 120.001 FVD: 215.828 BFL: 150.011SYSTEM FIRST ORDER PROPERTIES, POS 3FIELD: 13.0.degree. f/10.00 EFL: 180.007 FVD: 198.595 BFL: 150.016SYSTEM FIRST ORDER PROPERTIES, POS 4FIELD: 11.0.degree. f/10.00 EFL: 217.017 FVD: 193.461 BFL: 150.022__________________________________________________________________________ TABLE 11__________________________________________________________________________Example f.sub.min f.sub.max .PHI..sub.1 .PHI..sub.2 .PHI..sub.3 FVD.sub.min BFL PMR__________________________________________________________________________1 78 120 -.0173 .0297 -.0166 167 119 1.542 78 120 -.0180 .0275 -.0141 185 117-131 1.373 75 125 -.0166 .0308 -.0157 131 95 1.664 87 160 -.0174 .0262 -.0159 186 124 1.845 87 160 -.0186 .0265 -.0147 192 125 1.846 78 148 -.0209 .0308 -.0194 168 115 1.927 87 177 -.0182 .0268 -.0165 186 129 2.058 87 224 -.0179 .0341 -.0281 198 152 2.069 84 217 -.0193 .0355 -.0275 200 150 2.5710 84 217 -.0198 .0393 -.0347 193 150 2.54__________________________________________________________________________ TABLE 12__________________________________________________________________________Example .PHI. .vertline.f.sub.1 .vertline./f.sub.min .vertline.f.sub.3 .vertline./f.sub.min BFL/f.sub.min (.vertline..PHI..sub.1 .vertline. + .vertline..PH I..sub.3 .vertline.)/.PHI..sub.2 f.sub.2 /f.sub.max__________________________________________________________________________1 -.004 0.74 0.77 1.53 1.14 0.282 -.005 0.71 0.91 1.50-1.68 1.17 0.303 -.002 0.80 0.85 1.27 1.05 0.264 -.007 0.66 0.72 1.43 1.27 0.245 -.007 0.62 0.78 1.44 1.26 0.246 -.010 0.61 0.66 1.47 1.31 0.227 -.008 0.63 0.70 1.48 1.29 0.218 -.012 0.64 0.41 1.75 1.35 0.139 -.011 0.62 0.43 1.79 1.32 0.1310 -.015 0.60 0.34 1.79 1.39 0.12__________________________________________________________________________ TABLE 13______________________________________Example f/.sub.min f/.sub.max HFOV______________________________________1 10 10 30.degree.2 10 10 30.degree.3 10 10 32.degree.4 10 10 29.degree.5 8 14 29.degree.6 8 14 31.degree.7 8 14 29.degree.8 10 10 29.degree.9 10 10 29.degree.10 10 10 29.degree.______________________________________ TABLE 14______________________________________Material N.sub.e V.sub.e______________________________________FK5 1.489142 70.2ACRYLIC 1.493538 57.3SF14 1.768587 26.3494527 1.493538 52.7769272 1.768587 27.2SF6 1.812647 25.2LAF7 1.754580 34.7SF1 1.723102 29.3LAK21 1.643036 59.9BK7 1.518720 64.0645346 1.644907 34.6748402 1.747949 40.2LAK9 1.694011 54.5SF57 1.855032 23.7SK5 1.591422 61.0812267 1.811503 26.7818246 1.818330 24.6466785 1.465539 78.5633365 1.633423 36.5765268 1.765396 26.8657572 1.657255 57.2______________________________________

Claims

1. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third lens unit which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said second lens unit is moveable to change the magnification of the lens system;

said first lens unit is moveable to focus the lens system and to compensate for changes in focus resulting from movement of said second lens unit; and

said aperture stop is fixed during zooming of the lens system.

2. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third lens unit which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said second lens unit is moveable to change the magnification of the lens system;

said third lens unit is moveable to focus the lens system and to compensate for changes in focus resulting from movement of said second lens unit; and

said aperture stop is fixed during zooming of the lens system.

3. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third lens unit which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said first lens unit is moveable to focus the lens system;

said second lens unit is moveable to change the magnification of the lens system;

said third lens unit is moveable to compensate for changes in focus resulting from movement of said second lens unit; and

the aperture stop is fixed during zooming of the lens system.

4. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power whose absolute value is .vertline..PHI..sub.1 .vertline.;

(b) a second lens unit which is on the image side of said first lens unit, said second lens unit having a positive optical power .PHI..sub.2 ; and

(c) a third lens unit which is on the image side of said second lens unit, said third lens unit having a negative optical power whose absolute value is .vertline..PHI..sub.3 .vertline.;

wherein:

said second lens unit is moveable to change the magnification of the lens system; and

the ratio of (.vertline..PHI..sub.1 .vertline.+.vertline..PHI..sub.3 .vertline.)/.PHI..sub.2 is between about 1.0 and about 1.5.

5. A zoom lens system for forming an image, said system having a maximum effective focal length f.sub.max and comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit, said second lens unit having a positive optical power and a focal length f.sub.2 ; and

(c) a third lens unit which is on the image side of said second lens unit and has a negative optical power;

wherein:

said second lens unit is moveable to change the magnification of the lens system; and

the ratio of f.sub.2 /f.sub.max is between about 0.10 and about 0.35.

6. A zoom lens system for forming an image, said system having a maximum effective focal length f.sub.max and a minimum effective focal length f.sub.min, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third lens unit which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said second lens unit is moveable to change the magnification of the lens system; and

the ratio of the magnification of tile aperture stop by said first and second lens units at f.sub.min to the magnification of the aperture stop by said first and second lens units at f.sub.max is less than about 2.0.

7. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third single lens unit consisting of a single lens element which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said second lens unit is moveable to change the magnification of the lens system;

said first lens unit is moveable to focus the lens system and to compensate for changes in focus resulting from movement of said second lens unit; and

said aperture stop is fixed during zooming of the lens system.-Please

8. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third lens unit consisting of a single lens element which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said second lens unit is moveable to change the magnification of the lens system;

said third lens unit is moveable to focus the lens system and to compensate for changes in focus resulting from movement of said second lens unit; and

said aperture stop is fixed during zooming of the lens system.

9. A zoom lens system for forming an image, said system comprising:

(a) a first lens unit having a negative optical power;

(b) a second lens unit which is on the image side of said first lens unit and has a positive optical power;

(c) a third lens unit consisting of a single lens element which is on the image side of said second lens unit and has a negative optical power; and

(d) an aperture stop which is on the image side of said second lens unit;

wherein:

said first lens unit is moveable to focus the lens system;

said second lens unit is moveable to change the magnification of the lens system;

said third lens unit is moveable to compensate for changes in focus resulting from movement of said second lens unit; and

the aperture stop is fixed during zooming of the lens system.

10. The zoom lens system of claim 7, 8, or 9 wherein the index of refraction of said single lens element is higher than the index of refraction of any other lens element in the lens system.

11. The zoom lens system of claim 10 wherein the index of refraction of said single lens element is greater than about 1.6.

12. The zoom lens system of claim 7, 8, or 9 wherein said first lens unit is a single lens element.

13. The zoom lens system of claim 12 wherein said single lens element has at least one aspheric surface.

14. The zoom lens system of claim 12 wherein said single lens element has an Abbe value above about 55.

15. The zoom lens system of claim 7, 8, or 9 wherein said second lens unit comprises only positive lens elements.

16. The zoom lens system of claim 7, 8, or 9 wherein said first, second, and third lens units are each a single lens element.

17. The zoom lens system of claim 7, 8, or 9 wherein said first lens unit is a single lens element, said second lens unit is two positive lens elements, and said third lens unit is a single lens element.

18. The zoom lens system of claim 7, 8, or 9 wherein the lens system has a maximum effective focal length f.sub.max and a minimum effective focal length f.sub.min and the size of the aperture stop is adjustable to increase the effective aperture of the lens system as the effective focal length of the lens system decreases from f.sub.max to f.sub.min.

19. The zoom lens system of claim 7, 8, or 9 wherein the lens system has a minimum effective focal length f.sub.min, said first lens unit has a focal length whose absolute value is .vertline.f.sub.1 .vertline., said third lens unit has a focal length whose absolute value is .vertline.f.sub.3 .vertline., and the ratio of .vertline.f.sub.1 .vertline. to f.sub.min is less than about 0.9 and the ratio of .vertline.f.sub.3 .vertline. to f.sub.min is less than about 1.0.

20. The zoom lens system of claim 7, 8, or 9 wherein said first lens unit has a power .PHI..sub.1, said second lens unit has a power .PHI..sub.2, said third lens unit has a power .PHI..sub.3, and the stun of .PHI..sub.1 +.PHI..sub.2 +.PHI..sub.3 is negative.

21. The zoom lens system of claim 7, 8, or 9 wherein the lens system has a back focal length BFL and a minimum effective focal length f.sub.min, and the ratio of BFL to f.sub.min is greater than about 1.2.

22. The zoom lens system of claim 7, 8, or 9 wherein said aperture stop is on the image side of said third lens unit.