IMAGING OPTICAL SYSTEM AND IMAGE PROJECTION APPARATUS

BACKGROUND
Technical Field

The present disclosure relates to an imaging optical system that forms an image through a lens system including multiple lens elements, and also relates to an image projection apparatus including the imaging optical system.

Background Art

Patent literature 1 discloses a lens system that receives light from an input side to form an intermediate image, and then forms a final image on an output side. This lens system includes a first optical system and a first sub-system that allows the first optical system to bring an object into focus. The first sub-system includes a first lens and a second lens. The first lens is placed on the intermediate image at the closest position to the input side, and moves during the focusing action. The second lens is placed on the intermediate image at the closest position to an output side, and moves during the focusing action. The structure discussed above allows achieving a focusing function more excellent than before.

CITATION LIST
Patent Literature

PTL: Unexamined Japanese Patent Application Publication No. 2015-179270

SUMMARY

The present disclosure provides an imaging optical system excellent in focusing performance, and also provides an image projection apparatus including the imaging optical system.

The imaging optical system includes a plurality of lens groups, the plurality of lens groups each including at least one lens and moving such that spaces between each one of the lens groups change during a zooming action. The imaging optical system conjugates a conjugate point on a magnification side of the imaging optical system and an intermediate imaging position inside the imaging optical system, and conjugates a conjugate point on a reduction side of the imaging optical system and the intermediate imaging position. The imaging optical system includes a first lens group located at a furthest place on the magnification side and a rear group in this order from the magnification side toward the reduction side. The first lens group includes a field curvature correction lens group moving along an optical axis when an amount of a field curvature is changed, and a focusing lens group moving along the optical axis during a focusing action from an infinity focus state to a proximate focus state.

The imaging optical system satisfies condition (4) below:

|{(1−βcw²)×βcrw²}/{(1−βfw²)×βfrw²}|<0.2 (4)

where, βcw is a paraxial lateral magnification, at a wide angle end, of the field curvature correction lens group moving along the optical axis when the amount of the field curvature is changed,

βcrw is a paraxial lateral magnification, at the wide angle end, of every lens located farther on the reduction side than the field curvature correction lens group moving along the optical axis when the amount of the field curvature is changed, βfw is a paraxial lateral magnification, at the wide angle end, of the focusing lens group moving along the optical axis during the focusing action, and

βfrw is a paraxial lateral magnification, at the wide angle end, of every lens located farther on the reduction side than the focusing lens group moving along the optical axis during the focusing action.

The imaging optical system disclosed here can form an image excellent in imaging performance.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a placement of lenses at a wide angle end, where an infinity focus state is achieved, of the imaging optical system in accordance with the first embodiment.

FIG. 2 shows a placement of lenses at a wide angle end for indicating a light path of the imaging optical system in accordance with the first embodiment.

FIG. 3 shows longitudinal aberration diagrams each indicating that an object distance of the imaging optical system in accordance with the first embodiment is infinity.

FIG. 4 shows longitudinal aberration diagrams at a projection size of 200 inches of the imaging optical system in accordance with the first embodiment.

FIG. 5 shows longitudinal aberration diagrams at a projection size of 70 inches of the imaging optical system in accordance with the first embodiment.

FIG. 6 shows a placement of lenses at a wide angle end, where an infinity focus state is achieved, of an imaging optical system in accordance with a second embodiment.

FIG. 7 shows a placement of lenses at a wide angle end for indicating a light path of the imaging optical system in accordance with the second embodiment.

FIG. 8 shows longitudinal aberration diagrams each indicating that an object distance of the imaging optical system in accordance with the second embodiment is infinity.

FIG. 9 shows longitudinal aberration diagrams at a projection size of 200 inches of the imaging optical system in accordance with the second embodiment.

FIG. 10 shows longitudinal aberration diagrams at a projection size of 70 inches of the imaging optical system in accordance with the second embodiment.

FIG. 11 shows a placement of lenses at a wide angle end, where an infinity focus state is achieved, of an imaging optical system in accordance with a third embodiment.

FIG. 12 shows a placement of lenses at a wide angle end for indicating a light path of the imaging optical system in accordance with the third embodiment.

FIG. 13 shows longitudinal aberration diagrams each indicating that an object distance of the imaging optical system in accordance with the third embodiment is infinity.

FIG. 14 shows longitudinal aberration diagrams at a projection size of 200 inches of the imaging optical system in accordance with the third embodiment.

FIG. 15 shows longitudinal aberration diagrams at a projection size of 70 inches of the imaging optical system in accordance with the third embodiment.

DESCRIPTION OF EMBODIMENTS

The embodiments will be detailed hereinafter with reference to the accompanying drawings. Descriptions more than necessary will be omitted sometimes. For instance, detailed descriptions of well-known matters will be omitted, or duplicable descriptions about substantially the same structures will be omitted sometimes. These omissions will avoid redundancy in the descriptions and help ordinary skilled persons in the art understand the present disclosure with ease.

The accompanying drawings and the descriptions below are provided for the ordinary skilled persons in the art to fully understand the present disclosure, and not to mention, these materials do not intend to limit the scope of the claims.

FIG. 1 shows a placement of lenses of the imaging optical system in accordance with the first embodiment. FIG. 6 shows a placement of lenses of the imaging optical system in accordance with the second embodiment. FIG. 11 shows a placement of lenses of the imaging optical system in accordance with the third embodiment. In each one of these three drawings, unilateral arrows marked below the lens-groups indicate that the lens-group is a focusing lens group, and the directions of the arrows indicate a moving direction of the focusing lens group from the infinity focus state to the proximity focus state. The left side indicates a magnification side, and the right side indicates a reduction side. The mark of (+), or (−) indicates a positive power or a negative power of each one of the lens-groups. The straight line marked on the right-most side indicates a position of subject image S. The letter “P” at the left side of subject image S indicates an optical element including such as a color separation prism, color combining prism, optical filter, plane parallel glass, crystal low-pass filter, or infrared cut filter.

FIG. 2 is an optical sectional view illustrating a light path of the imaging optical system in accordance with the first embodiment. FIG. 7 is an optical sectional view illustrating a light path of the imaging optical system in accordance with the second embodiment. FIG. 12 is an optical sectional view illustrating a light path of the imaging optical system in accordance with the third embodiment. MI indicates an intermediate imaging position, and forms a boundary between the magnification side and the reduction side. Magnifying optical system Op is disposed on the magnification side from MI, and relay optical system OI is disposed on the reduction side from MI. Magnifying optical system Op conjugates a magnification conjugate point (projected image) on the magnification side and intermediate imaging position MI inside the imaging optical system. Relay optical system OI conjugates a reduction conjugate point (subject image S) on the reduction side and intermediate imaging position MI inside the imaging optical system.

FIG. 3 shows longitudinal aberration diagrams each indicating that an object distance of the imaging optical system in accordance with the first embodiment is infinity. FIG. 8 shows longitudinal aberration diagrams each indicating that an object distance of the imaging optical system in accordance with the second embodiment is infinity. FIG. 13 shows longitudinal aberration diagrams each indicating that an object distance of the imaging optical system in accordance with the third embodiment is infinity. The marks (a), (b), and (c) in each one of the diagrams indicate the aberration diagrams each of which focal length of the imaging optical system disclosed hero is on an wide angle end, on an intermediate position, and on a telephoto end. The wide angle end refers to a state of the shortest focal length, the intermediate stat refers to a state of an intermediate focal length, and the telephoto end refers to a state of the longest focal length. Assume that focal length in the shortest focal length state is fw, and that in the longest focal length state is fr, then the following equation (1) prescribes the focal length fm in the intermediate focal length state:

fm=√{square root over ((f_w*f_r))} Equation (1)

FIG. 4 shows longitudinal aberration diagrams at a projection size of 200 inches (×145.1) of the imaging optical system in accordance with the first embodiment. FIG. 9 shows longitudinal aberration diagrams at a projection size of 200 inches (×145.1) of the imaging optical system in accordance with the second embodiment. FIG. 14 shows longitudinal aberration diagrams at a projection size of 200 inches (×145.1) of the imaging optical system in accordance with the third embodiment. The marks (a), (b), and (c) in each one of the diagrams indicate the aberration diagrams each of which focal length of the imaging optical system disclosed here is on an wide angle end, on an intermediate position, and on a telephoto end.

FIG. 5 shows longitudinal aberration diagrams at a projection size of 70 inches (×50.8) of the imaging optical system in accordance with the first embodiment. FIG. 10 shows longitudinal aberration diagrams at a projection size of 70 inches (×50.8) of the imaging optical system in accordance with the second embodiment. FIG. 15 shows longitudinal aberration diagrams at a projection size of 70 inches (×50.8) of the imaging optical system in accordance with the third embodiment. The marks (a), (b), and (c) in each one of the diagrams indicate the aberration diagrams each of which focal length of the imaging optical system disclosed here is on an wide angle end, on an intermediate position, and on a telephoto end.

Each one of the aberration diagrams includes a spherical aberration diagram, astigmatism diagram, and distortion diagram in this order from the left to the right. In the spherical aberration diagram, the lateral axis represents the spherical aberration (SA mm), and the vertical axis represents F-number (numbers marked with F in the diagrams). In the spherical aberration diagram, the solid line, broken line, and long-dash line represent the characteristics of d-line, F-line, and C-line respectively. In the astigmatism diagram, the lateral axis represents the astigmatism (AST mm), and the vertical axis represents an image height (marked with H). In the astigmatism diagram, the solid line shows the characteristics of sagittal plane (marked with s), the broken line shows the characteristics of meridional plane (marked with m). In the distortion diagram, the vertical axis represents a distortion (DIS %), and the vertical axis represents an image height (marked with II).

In the embodiments below, a subject image, formed by an image forming element including such as liquid crystal or DMD (Digital Micro-mirror Device), is projected onto a screen by a projector (image projection apparatus), and this projector employs the imaging optical system. The screen (not shown) lies on an extension line of the magnification side. The imaging optical system magnifies subject image S formed by a liquid crystal panel disposed on the reduction side, and projects it onto the screen.

The imaging optical system disclosed here includes first lens group G1 of positive power, second lens group G2 of positive power, third lens group G3 of positive power, and fourth lens group G4 of positive power in this order from the magnification side to the reduction side.

First lens group G1 is formed of first front-side sub-lens group G1f and first rear-side sub-lens group G1r. First lens group G1 is formed of 16 lenses numbered first lens L1 through sixteenth lens L16. First front-side sub-lens group C1f is formed of third lens L3, which is an aspherical lens and located furthest on the magnification side among other aspherical lenses, and other lenses located farther on the magnification side than lens L3. First rear-side sub-lens group G1r is formed of the lenses disposed toward the reduction side from aspherical third lens L3.

First lens group G1 includes the following lenses located from the magnification side toward the reduction side in this order:

negative first lens L1;

positive meniscus second lens L2 of which convex faces toward the magnification side;

negative meniscus third lens L3 of which convex faces toward the magnification side;

positive meniscus fourth lens L4 of which convex faces toward the magnification side;

negative fifth lens L5;

positive meniscus sixth lens L6 of which convex faces toward the reduction side;

biconvex seventh lens L7;

biconvex eighth lens L8;

negative meniscus ninth lens L9 of which convex faces toward the reduction side;

biconvex tenth lens L10;

positive eleventh lens L11;

positive meniscus twelfth lens L12 of which convex faces toward the magnification side;

negative thirteenth lens L13;

negative meniscus fourteenth lens L14 of which convex faces toward the reduction side;

positive meniscus fifteenth lens L15 of which convex faces toward the reduction side; and

positive meniscus sixteenth lens L16 of which convex faces toward the reduction side.

Third lens L3 has an aspherical surface on the reduction side, and on its magnification side there are first lens L1 of negative power and second lens L2 of positive power. A greater effective diameter of the aspherical lens invites greater difficulty in manufacturing the aspherical lens. In the imaging optical system of the present disclosure, the aspherical surface is formed on third lens L3, whereby the curvature of field as well as the distortion can be reduced. On top of that, second lens L2 located next to lens L3 on the magnification side has positive power, so that the effective diameter of the aspherical lens can be reduced. Sixteenth lens L16 has positive power and moves along the optical axis during the focusing action, viz. it forms a focusing lens group.

First lens group CG includes a field-curvature correction lens group formed of eighth lens L8 of positive power and ninth lens L9 of negative power. This correction lens group corrects a change in the field curvature, the change being incurred by the movements of each one of the lens groups during the focusing action. In this case, eighth lens L8 and ninth lens L9 move along the optical axis, and they can move toward the magnification side or the reduction side depending on a moving amount of the sixteenth lens L16 (i.e. focusing lens group) for focusing or a correction amount of the field curvature. Since the field curvature correction lens group is formed of one sheet of negative lens and one sheet of positive lens, this simple structure allows correcting the curvature of field as well as reducing a change in sensitivity of focusing.

Second lens group G2 is formed of biconvex seventeenth lens L17.

Third lens group G3 is formed of eighteenth lens L18 through twenty-second lens L22. Those lenses are located from the magnification side toward the reduction side in the following order:

negative meniscus eighteenth lens 18 of which convex faces toward the reduction side;

negative nineteenth lens L19;

biconvex twentieth lens L20;

biconvex twenty-first lens L21; and

positive meniscus twenty-second lens L22 of which convex faces toward the magnification side.

Between sixteenth lens L16 and seventeenth lens L17, flare-cut aperture Af is placed.

Fourth lens group G4 is formed of aperture A, twenty-third lens L23 through twenty-ninth lens L29, and prism P. Those members are disposed from the magnification side toward the reduction side in the following order: biconcave lens L23;

biconvex lens L24;

biconcave lens L25;

biconcave lens L26;

biconvex lens L27;

biconvex lens L28;

biconvex lens L29; and

prism P.

Fifth lens L5 desirably has the specifications below:

- High transmittance, Abbe number <30, and absorption coefficient <0.008 at a wavelength of 400 nm of transmitted light.
  
  This absorption coefficient can be found from the following expression:

−1/t×ln(I/I₀)

where, t is a travel distance of light through the lens, I_Ois an intensity of the light before it enters the lens, and I is an intensity of the light after it travels by distance t.

First lens L1 and third lens L3, both are of negative power, disposed on the magnification side of fifth lens L5 desirably have the following specifications:

- Abbe number ≥30, or
- Absorption coefficient ≥0.008 at the wavelength=400 nm of transmitted light.

When the imaging optical system zooms from the wide angle end to the telephoto end, first lens group G1 is fixed relatively to an image surface of subject image S. Second lens group G2 simply moves toward the magnification side with respect to the image surface of subject image S. Third lens group G3 simply moves toward the magnification side with respect to the image surface of subject image S. Fourth lens group G4 is fixed relatively to the image surface of subject image S.

Then an intermediate image is formed at intermediate imaging position MI within first lens group G1. To be more specific, intermediate imaging position MI is located between thirteenth lines L13 and fourteenth lens L14. First lens group G1 carries out two actions here, viz. an action of a field lens for guiding marginal rays toward the reduction side before and after the intermediate imaging, and an action of a projection lens.

The imaging optical system in accordance with the present embodiment includes multiple lens-groups each having at least one lens. During a zooming action, the lens-groups move such that spaces between each one of the groups change. The imaging optical system conjugates a conjugate point on the magnification side and an intermediate imaging position inside the imaging optical system. The imaging optical system conjugates a conjugate point on the reduction side and the intermediate imaging position inside the imaging optical system. The imaging optical system includes the first lens group and a rear lens group in this order from the magnification side toward the reduction side. The first lens group is located furthest on the magnification side, and includes a field curvature correction lens group and a focusing lens group. The field curvature correction lens group moves along the optical axis for correcting an amount of field curvature. The focusing lens group moves along the optical axis during an action of focusing from an infinite focus state to a proximate focus state. The conditions that should be satisfied by the imaging optical system are introduced below:

First lens group G 1 of the imaging optical system in accordance with the present disclosure satisfies the condition (1) below:

1.5<f1b/f1<4.0 (1)

where, fib is a focal length of first rearside sub-lens group located farther on the reduction side than the aspherical lens located furthest on the magnification side in the first lens group,

f1 is a focal length of the first lens group.

Condition (1) prescribes the relation between first rearside sub-lens group G1r and first lens group G1, where sub-lens group G1r is located farther on the reduction side than the aspherical lens located furthest on the magnification side in first lens group G1. Satisfaction of condition (1) will invite this advantage: correcting the field curvature and the distortion easily with the effective diameter of aspherical third lens L3 being reduced. Falling below the lower limit of condition (1) allows the first rearside sub-lens group G1r located farther on the reduction side than third lens L3 to exert excessively strong power (greater refracting power), so that the corrections of the field curvature and the distortion become difficult. To the contrary, excess over the upper limit of condition (1) allows the first rearside sub-lens group G1r located farther on the reduction side than aspherical third lens L3 of first lens group G1 to exert extremely weak power, so that the effective diameter of aspherical third lens L3 adjacent to first rearside sub-lens group G1r becomes greater, which adversely invites a higher manufacturing cost.

Satisfaction of condition (1a) below more positively achieves the advantage discussed above.

2.0<f1b/f1<3.5 (1a)

The imaging optical system satisfies the condition (2) below.

0.01<|d/fw|<1.50 (2)

where, d is a space on the optical axis between the lens of negative power and the lens of positive power located farther on the magnification side than the aspherical lens located furthest on the magnification side in the first lens group, and

fw is a focal length of the total system at the wide angle end.

Condition (2) prescribes the spaces between each one of the lenses located farther on the magnification side than the aspherical lens of first lens group G1. Satisfaction of condition (2) will invite this advantage: reducing the effective diameters of the aspherical lens and other lenses located farther on the magnification side than the aspherical lens while the field curvature and the distortion are corrected improvingly. Falling below the lower limit of condition (2) will make a space too short between the negative lens and the positive lens located farther on the magnification side than the aspherical lens, so that the filed curvature and the distortion cannot be corrected sufficiently. To the contrary, excess over an upper limit of condition (2) will invite adversely a greater effective diameter of the aspherical lenses and other lenses located farther on the magnification side.

On top of that, satisfaction of condition (2a) below more positively achieves the foregoing advantage.

0.05<|d/fw|<1.00 (2a)

The imaging optical system in accordance with the present disclosure satisfies the condition (3) below:

0.5<(R1f+R1r)/(R1f−R1r)<5.0 (3)

where, R1f is a curvature radius of the surface, facing the magnification side, of the spherical lens of negative power located farther on the magnification side than the aspherical lens located furthest, among other aspherical lenses, on the magnification side, and

R1r is a curvature radius of the surface, facing the reduction side, of the spherical lens of negative power located farther on the magnification side than the aspherical lens located furthest, among other aspherical lenses, on the magnification side.

Condition (3) prescribes a shaping factor of the spherical lenses of negative power located farther on the magnification side than the aspherical lens. Satisfaction of condition (3) will invite this advantage: reducing the effective diameters of the lenses while the field curvature and the distortion can be corrected. Falling below the lower limit of condition (3) will invite an insufficient correction of the field curvature and the distortion. To the contrary, excess of the upper limit of condition (3) will invite adversely greater effective diameters of the lenses located farther on the magnification side than the aspherical lens.

Satisfaction of condition (3a) below more positively achieves the foregoing advantage.

0.7<(R1f+R1r)/(R1f−R1r)<3.5 (3a)

The imaging optical system of the present disclosure satisfies condition (4) below:

|{(1−βcw²)×βcrw²)}/{(1−βfw²)×βfrw²}|<0.2 (4)

where, βcw is a paraxial lateral magnification, at a wide angle end, of a field curvature correction lens-group moving along the optical axis in the case of an amount of field curvature being changed.

βcrw is a paraxial lateral magnification, at the wide angle end, of each of the lenses located farther on the reduction side than the field curvature correction lens-group moving along the optical axis in the case of the amount of the field curvature being changed, βfw is a paraxial lateral magnification, at the wide angle end, of the focusing lens-group moving along the optical axis during the focusing action, and

βfrw is a paraxial lateral magnification, at the wide angle end, of every lens located farther on the reduction side than the focusing lens-group moving along the optical axis during the focusing action.

Condition (4) relates to focusing sensitivities of the field curvature lens group and the focusing lens group. Satisfaction of condition (4) will invite this advantage: preventing the focus from being out of focus even if the field curvature correction lens-group is moved during the adjustment of an amount of field curvature. Excess over an upper limit of condition (4) will invite an out-of-focus when the field curvature correction lens-group is moved, so that the correction of the field curvature and the focusing become difficult.

Satisfaction of condition (4a) below more positively achieves the foregoing advantage.

|{(1−βcw²)×βcrw²}/{(1−βfw²)×βfrw²}|<0.15 (4a)

The imaging optical system of the present disclosure satisfies condition (5) below:

|ff/fc|<0.8 (5)

where, ff is a focal length of the focusing lens group moving along the optical axis during the focusing action, and

fc is a focal length of the field curvature correction lens-group moving along the optical axis when an amount of the field curvature is changed.

Condition (5) prescribes the focal length of the field curvature correction lens-group with respect to the focal length of the focusing lens group. Satisfaction of condition (5) will invite this advantage: weakening influence of the field curvature correction lens-group to the focusing sensitivity. Excess over an upper limit of condition (5) will adversely invite stronger power of the field curvature correction lens-group, so that the focus becomes out of focus when the field curvature correction lens-group is moved.

Satisfaction of condition (5a) below more positively achieves the foregoing advantage.

|ff/fc|<0.6 (5a)

First lens group G1 satisfies condition (6) below:

|fc/f1|<0.3 (6)

where, f1 is a focal length of first lens group G1

Condition (6) prescribes the focal length of the field curvature correction lens-group with respect to the focal length of first lens group G1. Satisfaction of condition (6) will invite this advantage: reducing a change in the focus position with respect to an amount of movement of the field curvature correction lens-group, so that an out-of-focus can be prevented even if the field curvature correction lens-group moves for correcting the field curvature. Excess over an upper limit of condition (6) will invite an out-of-focus when the correction lens-group moves, so that the correction of the field curvature as well as an adjustment of focus becomes difficult.

Satisfaction of condition (6a) below more positively achieves the foregoing advantage.

|fc/f1|<0.2 (6a)

The imaging optical system of the present disclosure satisfies condition (7) below:

3.0<f1/fp<15.0 (7)

where, f1 is a composite focal length at a wide angle end of a relay optical system located farther on the reduction side than the intermediate imaging position, and

fp is a composite focal length at a wide angle end of a relay optical system located farther on the magnification side than the intermediate imaging position.

Condition (7) prescribes a magnifying optical system and the relay optical system. Satisfaction of condition (7) will invite this advantage: lowering various aberrations in the imaging optical system as well as downsizing the same system. Falling below a lower limit of condition (7) will invite a difficulty in generally parallelizing a chief ray and other rays given off from a surface of the image on the reduction side. Excess over an upper limit of condition (7) will adversely invite a difficulty in reducing effective diameters of the lenses located on the magnification side.

Satisfaction of condition (7a) below more positively achieves the foregoing advantage.

4.0<f1/fp<12.0 (7a)

The imaging optical system of the present disclosure satisfies condition (8) below:

2.0<|f4/ft|<10.0 (8)

where, f4 is a focal length of the fourth lens group; and

ft is a focal length of the total system at the telephoto end.

Condition (8) prescribes the power of fourth lens group G4. Satisfaction of condition (8) will invite this advantage: shortening the total length while the light given off from the image surface on the reduction side and deviated from the optical axis can be generally parallelized to the optical axis. Falling below a lower limit of condition (8) will make it impossible to parallelize a chief ray of the light deviated from the optical axis with the optical axis. Excess over an upper limit of condition (8) will invite a difficulty in shortening the total length.

Satisfaction of condition (8a) below more positively achieves the foregoing advantage.

3.0<|f4/ft|<6.5 (8a)

The imaging optical system of the present disclosure satisfies condition (9) below:

0.4<f4/bf<1.0 (9)

where, bf is a distance from a lens surface located furthest on the reduction side to an image surface on the reduction side.

Condition (9) prescribes a back focus. Satisfaction of condition (9) will invite this advantage: shortening the total length while the chief ray of the light deviated from the optical axis and given off from the image surface on the reduction side can be parallelized with the optical axis. Falling below a lower limit of condition (9) will lengthen the back focus, so that the shortening of the total length becomes difficult. Excess over an upper limit of condition (9) will make it impossible to parallelize the chief ray of the light, deviated from the optical axis and given off the image surface on the reduction side, with the optical axis.

Satisfaction of condition (9a) below more positively achieves the foregoing advantage.

0.55<f4/bf<0.8 (9a)

The imaging optical system of the present disclosure satisfies condition (10) below:

Φht/Φs<0.9 (10)

where, Φht is an effective diameter of the lens having the following specifications:

Abbe number <30, and light absorption coefficient of the light having 400 nm wavelength <0.008,

Φs is an aperture diameter of aperture stop.

Condition (10) prescribes the lenses of which effective diameters are smaller than an aperture diameter. Satisfaction of condition (10) will invite this advantage: preventing the lenses located near to an entrance pupil and having the smaller effective diameters from being affected by a temperature rise due to condensed light. Excess over an upper limit of condition (10) will invite a greater effective diameter of the lenses, and increase the cost thereof.

Satisfaction of condition (10a) below more positively achieves the foregoing advantage.

Φht/Φs<0.6 (10a)

The imaging optical system of the present disclosure satisfies condition (11) below:

0.1<|fht/fw|<100.0 (11)

where, fht is a focal length of a lens having a high transmittance.

Condition (11) prescribes a focal length of the lens having the following specification:

Abbe number <30, and

light absorption coefficient of the light having 400 nm wavelength <0.08. Satisfaction of condition (11) will invite this advantage: correcting a chromatic aberration excellently. Falling below a lower limit of condition (11) will lower the correction effect of the chromatic aberration, and excess over an upper limit of condition (11) will invite frequent occurrences of the chromatic aberration.

Satisfaction of condition (11a) below more positively achieves the foregoing advantage.

0.8<|fht/fw|<50.0 (11a)

As discussed above, the embodiment is demonstrated hereinbefore as an example of the techniques disclosed in the present patent application.

Nevertheless, the techniques of the present disclosure are not limited to the foregoing example, but are applicable to other embodiments in which changes, replacements, additions, or omissions are carried out appropriately.

Embodiments 1-3 of the imaging optical system with numerical simulations are demonstrated hereinafter. In each one of the numerical simulations, a unit of length is expressed in mm (millimeter), a unit of angle of view is expressed in ° (degree). In each one of the numerical simulations, the following abbreviations are used:

r=curvature radius, d=face-to-face dimension, nd=refractive index with respect to d line, and vd=Abbe number with respect to d line.

In each one of the numerical simulations, the face marked with * is an aspherical face, and its shape is defined with the following equation (2).

$\begin{matrix} Z = \frac{h^{2} / r}{1 + \sqrt{1 - (1 + κ) {(h / r)}^{2}}} + \sum A_{n} h^{n} & Equation (2) \end{matrix}$

where, Z is a distance from a point on an aspherical face, located above the optical axis with a height h, to the tangent plane at the vertex of the aspherical face;

h is a height from the optical axis;

r is curvature radius at the vertex;

κ is a cone constant; and

An is a nth aspherical coefficient

First Embodiment with Numerical Simulation

A throw ratio of the imaging optical system in accordance with the first embodiment is 0.7 at the wide angle end and 0.9 at the telephoto end. The throw ratio is found by this formula: projecting distance/lateral size of an image projected on a screen, where the projecting distance measures from a lens surface located furthest on the magnification side (closest to the screen) of the imaging optical system to the screen along the projecting direction.

The image height used in the following data is set equal to or greater than 17.5 mm which is a diagonal dimension of the image forming element, because the design is drawn on the assumption that the optical axis of the imaging optical system can be shifted with respect to the image forming element.

Tables 1-10 show the lens data used in this first embodiment. Tables 2 and 3 list a series of surface data. The diameter of the aperture stop is 43. 318 mm.

TABLE 1

Focal

length

of lens/

Absorption

Focal

coefficient

Effective

length

@400

diameter/
Focal
of wide

Lens glass
α = −(1/t)
Effective
Aperture
length
angle

material
*ln(l/10)
diameter
diameter
of lens
end

L1
EFL6
0.0041
106.496
2.46
−92.02
4.19

L2
TAF3
0.0030
80.392
1.86
105.60
4.81

L3
KPBK40
0.0009
68.002
1.57
−55.66
2.54

L4
PBH56
0.0039
46.430
1.07
303.34
13.82

L5
PBH56
0.0039
22.078
0.51
−31.56
1.44

L6
TAC8
0.0015
26.224
0.61
53.72
2.45

L7
FCD100
0.0003
34.094
0.79
61.15
2.78

L8
FCD100
0.0003
38.568
0.89
61.43
2.80

L9
P8H56
0.0039
41.198
0.96
−59.58
2.71

L10
FCD1
0.0005
57.492
1.33
149.41
6.81

L11
FDS90SG
0.0192
63.794
1.47
87.88
4.00

L12
FDS90SG
0.0192
55.060
1.27
79.06
3.60

L13
TAFD25
0.0158
50.298
1.16
−44.37
2.02

L14
FDS90SG
0.0192
45.098
1.04
−47.29
2.15

L15
FD140
0.0208
55.768
1.29
253.23
11.53

L16
FDS90SG
0.0192
68.456
1.58
81.94
3.73

L17
FC5
0.0002
51.540
1.19
161.72
7.37

L18
TAFD25
0.0158
43.758
1.01
−126.82
5.78

L19
NBFD15
0.0090
45.244
1.04
−129.39
5.89

L20
FCD100
0.0003
48.940
1.13
86.39
3.93

L21
FCD1
0.0005
49.420
1.14
263.82
12.02

L22
FC5
0.0002
48.884
1.13
312.22
14.22

L23
NBF1
0.0016
43.180
1.00
−154.18
7.02

L24
PBH56
0.0039
44.224
1.02
50.58
2.30

L25
BACD18
0.0013
42.770
0.99
−55.25
2.52

L26
EFD2
0.0057
61.660
1.42
−42.19
1.92

L27
FCD100
0.0003
67.598
1.56
106.28
4.84

L28
FCD100
0.0003
79.724
1.84
146.59
6.68

L29
FCD100
0.0003
83.052
1.92
192.94
8.79

P
NBK7
0.0003
75.552
1.74
∞
∞

TABLE 2

Surface data

Effective

Surface number
r
d
nd
vd
radius

Object surface
∞

1
1566.213
5
1.56732
42.8
53.248

2
50.4642
5.2599

40.3

3
60.3617
14.264
1.8042
46.5
40.196

4
186.7145
0.2

38.752

5
62.3334
4
1.5176
63.5
34.001

6*
19.2718
18.3912

25.523

7
69.2944
21
1.84139
24.6
23.215

8
81.9474
12.4326

15.262

9
−23.122
4.9867
1.84139
24.6
9.102

10
−196.311
1.0239

11.039

11
−79.0965
5.5792
1.72916
54.7
11.372

12
−26.9757
0.2

13.112

13
91.423
8.6607
1.437
95.1
16.122

14
−36.6678
3.5

17.047

15
120.8847
10.5867
1.437
95.1
18.994

16
−33.5863
0.5438

19.284

17
−33.2628
3
1.84139
24.6
19.188

18
−102.948
22.0847

20.749

19
371.5186
8.6914
1.497
81.6
28.22

20
−92.0884
18.705

28.746

21
67.6708
10.283
1.84666
23.8
31.897

22
695.7607
0.2

31.337

23
36.4317
10.6602
1.84666
23.8
27.53

24
69.2215
3.3563

25.605

25
155.025
9.9187
1.90366
31.3
25.149

26
30.8893
18.6872

18.885

27
−37.3495
3
1.84666
23.8
19.735

28
−576.499
10.649

22.549

29
−43.0978
8.6626
1.76182
26.6
24.784

30
−38.2896
3.3195

27.884

31
−122.818
13.4628
1.84666
23.8
33.082

32
−46.5597
12

34.228

TABLE 3

Surface data (continued)

Effective

Surface number
r
d
nd
vd
radius

Object surface
∞

33
∞
Variable

30.253

34
144.3081
7.2259
1.48749
70.4
25.77

35
−170.905
Variable

25.455

36
−100.506
3
1.90366
31.3
21.424

37
−828.752
1.8955

21.879

38
484.9338
3
1.8061
33.3
22.283

39
85.6041
0.2

22.622

40
81.097
19.643
1.437
95.1
22.779

41
−65.4274
0.2

24.47

42
182.2892
5.3394
1.497
81.6
24.71

43
−462.549
0.2

24.645

44
116.1663
4.999
1.48749
70.4
24.442

45
483.7295
Variable

24.112

46(Aperture)
∞
0.7496

21.659

47
−933.889
3
1.7433
49.2
21.59

48
130.809
21.5887

21.245

49
70.684
8.9114
1.84139
24.6
22.112

50
−100.786
0.2

21.791

51
−138.501
3
1.63854
55.4
21.385

52
47.7388
12.0688

19.89

53
−35.9132
21
1.64769
33.8
20.138

54
140.5798
0.8751

30.83

55
163.1947
17.9493
1.437
95.1
31.389

56
−62.7453
0.2

33.799

57
265.2442
16.1256
1.437
95.1
39.196

58
−82.8947
0.2

39.862

59
107.2858
13.6246
1.437
95.1
41.526

60
−378.576
22

41.326

61
∞
153.8
1.5168
64.2
37.776

62
∞
3

23.048

Image surface
∞

TABLE 4

Aspheric data

Sixth surface

K
−9.80E−01

A4
3.86E−06

A6
−5.26E−10

A8
−1.89E−12

A10
−3.41E−15

TABLE 5

Various data when the projecting distance is infinity

Zoom ratio: 1.28091

Wide angle
Intermediate
Telephoto

Focal length
−21.956
−24.7178
−28.1237

F-number
−2.50403
−2.50346
−2.50738

Angle of view
−45.8706
−42.4981
−38.8464

Image height
22.6
22.6
22.6

d33
79.6946
64.1547
47.8148

d35
2
10.6202
17.6792

d45
2
8.9196
18.2005

TABLE 6

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
49.16019

2
34
161.7153

3
36
170.849

4
46
111.0949

TABLE 7

Various data at projection size of 200 inches (145.1 times)

Zoom ratio: 1.28078

Wide angle
Intermediate
Telephoto

Focal length
−21.9822
−24.7327
−28.1545

F-number
−2.5039
−2.50364
−2.50718

Angle of view
−45.8361
−42.4934
−38.8176

Image height
22.6
22.6
22.6

d0
3151.354
3550.512
4046.908

d14
3.211
3.034
3.2411

d18
22.3737
22.5507
22.3436

d30
3.4543
3.3805
3.424

d33
79.5598
64.0937
47.7103

d35
2
10.6202
17.6792

d45
2
8.9196
18.2005

TABLE 8

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
96.36227

2
15
−7888.86

3
19
52.9806

4
31
81.9355

5
34
161.7153

6
36
170.849

7
46
111.0949

TABLE 9

Various data at projection size of 70 inches (50.8 times)

Zoom ratio: 1.28057

Wide angle
Intermediate
Telephoto

Focal length
−22.0305
−24.7842
−28.2116

F-number
−2.50364
−2.50337
−2.50681

Angle of view
−45.7727
−42.4368
−38.7637

Image height
22.6
22.6
22.6

d0
1079.914
1219.598
1393.301

d14
2.6681
2.5284
2.7802

d18
22.9166
23.0563
22.8045

d30
3.7029
3.6023
3.6185

d33
79.3112
63.8719
47.5158

d35
2
10.6202
17.6792

d45
2
8.9196
18.2005

TABLE 10

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
96.36227

2
15
−7888.86

3
19
52.9806

4
31
81.9355

5
34
161.7153

6
36
170.849

7
46
111.0949

Second Embodiment with Numerical Simulation

The throw ratio of the imaging optical system used in the second embodiment is 0.5 at the wide angle end, and 0.6 at the telephoto end.

Tables 11-20 show the lens data used in this second embodiment. Tables 12 and 13 list a series of surface data. The diameter of the aperture stop is 45. 444 mm.

TABLE 11

Focal

length

of lens/

Absorption

Focal

coefficient

Effective

length

@400

diameter/
Focal
of wide

Lens glass
α = −(1/t)
Effective
Aperture
length
angle

material
*ln(l/10)
diameter
diameter
of lens
end

L1
TAF3
0.0030
130.000
2.86
−150.25
9.52

L2
TAFD55
0.0289
99.500
2.19
347.57
22.03

L3
LBAL42
0.0005
68.000
1.50
−39.67
2.51

L4
PBH56
0.0039
41.606
0.92
163.65
10.37

L5
PBH56
0.0039
20.700
0.46
−28.25
1.79

L6
TAC8
0.0015
24.110
0.53
52.68
3.34

L7
FCD100
0.0003
29.748
0.65
52.20
3.31

L8
FCD100
0.0003
35.630
0.78
51.53
3.27

L9
PBH56
0.0039
36.422
0.80
−39.74
2.52

L10
FCD1
0.0005
43.638
0.96
123.59
7.83

L11
FDS90SG
0.0192
50.958
1.12
90.09
5.71

L12
FDS90SG
0.0192
48.080
1.06
48.55
3.08

L13
NBFD13
0.0066
42.934
0.94
−41.48
2.63

L14
FDS90SG
0.0192
44.714
0.98
−43.30
2.74

L15
TAFD35
0.0129
55.002
1.21
98.88
6.27

L16
EFD10
0.0159
66.944
1.47
108.62
6.88

L17
FCS
0.0002
51.674
1.14
171.53
10.87

L18
TAFD35
0.0129
50.432
1.11
−105.06
6.66

L19
TAF1
0.0017
51.232
1.13
−159.74
10.12

L20
FCD100
0.0003
51.670
1.14
78.08
4.95

L21
FCD1
0.0005
50.334
1.11
324.81
20.59

L22
FC5
0.0002
49.754
1.09
553.98
35.11

L23
NBF1
0.0016
46.598
1.03
−257.64
16.33

L24
PBH56
0.0039
44.904
0.99
52.45
3.32

L25
BACED5
0.0021
43.078
0.95
−53.36
3.38

L26
EFD2
0.0057
58.248
1.28
−40.61
2.57

L27
FCD100
0.0003
65.168
1.43
104.04
6.59

L28
FCD100
0.0003
77.274
1.70
134.21
8.51

L29
FCD100
0.0003
81.102
1.78
182.17
11.54

P
NBK7
0.0003
73.952
1.63
∞
∞

TABLE 12

Surface data

Effective

Surface number
r
d
nd
vd
radius

Object surface
∞

1
118.3107
6
1.8042
46.5
65

2
58.4276
10.8776

50.078

3
77.9176
26.5758
2.001
29.1
49.75

4
83.2721
0.2

36.969

5
57.1273
4
1.58313
59.4
34

6*
16.0409
21.0418

23.42

7
194.9286
28
1.84139
24.6
20.803

8
−438.146
2.2008

10.244

9
−27.1956
12.3593
1.84139
24.6
9.732

10
227.7262
1.1456

10.35

11
−109.596
4.8425
1.72916
54.7
9.827

12
−28.9728
0.2

12.055

13
53.8677
10.6735
1.437
95.1
14.788

14
−37.1852
3.5

14.874

15
79.9752
9.8193
1.437
95.1
17.715

16
−30.1758
0.6027

17.815

17
−29.464
3
1.84139
24.6
17.659

18
−259.411
4.0739

18.211

19
749.8122
6.6666
1.497
81.6
21.233

20
−66.7077
17.5544

21.819

21
152.7199
7.2323
1.84666
23.8
25.466

22
−149.065
0.2

25.479

23
33.7104
11.4596
1.84666
23.8
24.04

24
158.1885
3.0257

22.63

25
−4504.14
4.5988
1.8061
40.7
21.467

26
33.7038
20.7922

17.749

27
−34.3854
3
1.84666
23.8
19.188

28
−576.499
9.7401

22.357

29
−54.6338
9.2866
1.91082
35.2
25.416

30
−36.7612
5.9771

27.501

31
−89.2723
14.3951
1.72825
28.3
31.666

32
−44.789
12

33.472

TABLE 13

Surface data (continued)

Effective

Surface number
r
d
nd
vd
radius

Object surface
∞

33
∞
Variable

29.135

34
206.6891
6.145
1.48749
70.4
22.871

35
−139.063
Variable

25.837

36
−71.7241
3
1.91082
35.2
21.769

37
−292.053
6.7329

25.216

38
208.8528
3
1.7725
49.6
24.222

39
77.0832
0.2

25.616

40
74.2605
12.7526
1.437
95.1
25.721

41
−59.8229
0.2

25.835

42
189.2688
4.9689
1.497
81.6
25.167

43
−1088.05
0.2

25.046

44
166.1841
4.1667
1.48749
70.4
24.877

45
428.5025
Variable

24.584

46(Aperture)
∞
0.6779

22.722

47
−1443.38
3
1.7433
49.2
23.299

48
220.9991
29.6526

22.405

49
76.8369
8.3363
1.84139
24.6
22.452

50
−98.5493
0.2

22.114

51
−143.016
3
1.65844
50.9
21.539

52
46.9613
11.3479

18.989

53
−34.3436
19.1043
1.64769
33.8
20.385

54
136.908
0.8345

29.124

55
158.7202
14.1737
1.437
95.1
31.712

56
−61.99
0.2

32.584

57
258.816
15.1777
1.437
95.1
38.257

58
−74.4845
0.2

38.637

59
112.9
12.5797
1.437
95.1
40.551

60
−260.816
22

40.463

61
∞
153.8
1.5168
64.2
36.976

62
∞
3

23.014

Image surface
∞

TABLE 14

Aspheric data

Sixth surface

K
−7.11E−01

A4
−1.00E−06

A6
−5.25E−09

A8
2.48E−12

A10
−3.33E−14

TABLE 15

Various data when the projecting distance is infinity

Zoom ratio: 1.19381

Wide angle
Intermediate
Telephoto

Focal length
−15.7791
−17.1001
−18.8374

F-number
−2.5032
−2.50293
−2.50544

Angle of view
−54.9671
−52.8069
−50.1085

Image height
22.6
22.6
22.6

d33
82.3079
71.207
58.2442

d35
2
7.0208
11.5349

d45
2
8.08
16.5286

TABLE 16

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
37.09378

2
34
171.52818

3
36
225.39504

4
46
115.74054

TABLE 17

Various data at projection size of 200 inches (145.1 times)

Zoom ratio: 1.19383

Wide angle
Intermediate
Telephoto

Focal length
−15.782
−17.0983
−18.841

F-number
−2.50301
−2.50288
−2.50513

Angle of view
−55.0287
−52.8726
−50.1466

Image height
22.6
22.6
22.6

d0
2241.422
2432.517
2685.48

d14
3.1581
3.124
3.2117

d18
4.4157
4.4498
4.3621

d30
6.157
6.1005
6.1249

d33
82.128
71.0835
58.0964

d35
2
7.0208
11.5349

d45
2
8.08
16.5286

TABLE 18

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
39.98678

2
15
−216.188

3
19
48.74835

4
31
108.6161

5
34
171.5282

6
36
225.395

7
46
115.7405

TABLE 19

Various data at projection size of 70 inches (50.8 times)

Zoom ratio: 1.19392

Wide angle
Intermediate
Telephoto

Focal length
−15.7865
−17.1036
−18.8478

F-number
−2.50268
−2.50251
−2.5046

Angle of view
−55.1443
−52.9658
−50.216

Image height
22.6
22.6
22.6

d0
752.5299
819.3999
907.9235

d14
2.5291
2.5419
2.6795

d18
5.0448
5.0319
4.8943

d30
6.4822
6.4041
6.4019

d33
81.8027
70.78
57.8195

d35
2
7.0208
11.5349

d45
2
8.08
16.5286

TABLE 20

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
39.98678

2
15
−216.188

3
19
48.74835

4
31
108.6161

5
34
171.5282

6
36
225.395

7
46
115.7405

Third Embodiment with Numerical Simulation

The throw ratio of the imaging optical system used in this third embodiment is 0.9 at the wide angle end, and 1.1 at the telephoto end.

Tables 21-30 show the lens data used in this third embodiment. Tables 22 and 23 list a series of surface data. The diameter of the aperture stop is 43. 570 mm.

TABLE 21

Focal

length

of lens/

Absorption

Focal

coefficient

Effective

length

@400

diameter/
Focal
of wide

Lens glass
α = −(1/t)
Effective
Aperture
length
angle

material
*ln(l/10)
diameter
diameter
of lens
end

L1
EF5
0.0044
84.806
1.95
−70.15
2.50

L2
TAF3
0.0030
67.924
1.56
73.09
2.60

L3
KPMK30
0.0005
57.828
1.33
−59.86
2.13

L4
PBH56
0.0039
38.668
0.89
240.97
8.58

L5
PBH56
0.0039
23.060
0.53
−32.59
1.16

L6
LAC14
0.0011
27.124
0.62
57.97
2.06

L7
FCD100
0.0003
34.650
0.80
68.08
2.42

L8
FCD100
0.0003
39.888
0.92
64.10
2.28

L9
PBH56
0.0039
43.010
0.99
−73.84
2.63

L10
FCD1
0.0005
60.544
1.39
158.64
5.65

L11
FDS90SG
0.0192
65.088
1.49
95.28
3.39

L12
PBH56
0.0039
56.170
1.29
106.44
3.79

L13
NBFD15W
0.0059
50.034
1.15
−57.25
2.04

L14
PBH56
0.0039
43.172
0.99
−47.44
1.69

L15
PBH56
0.0039
53.488
1.23
423.30
15.06

L16
FDS90SG
0.0192
64.284
1.48
76.01
2.71

L17
FC5
0.0002
51.956
1.19
163.14
5.81

L18
NBFD15W
0.0059
45.428
1.04
−182.96
6.51

L19
NBFD15W
0.0059
46.192
1.06
−103.90
3.70

L20
FCD100
0.0003
48.506
1.11
86.05
3.06

L21
FCD1
0.0005
48.964
1.12
231.21
8.23

L22
FC5
0.0002
48.242
1.11
360.25
12.82

L23
NBF1
0.0016
43.430
1.00
−152.24
5.42

L24
PBH56
0.0039
45.022
1.03
55.18
1.96

L25
BACD18
0.0013
43.494
1.00
−59.96
2.13

L26
EF2
0.0049
62.506
1.43
−44.34
1.58

L27
FCD100
0.0003
66.422
1.52
105.00
3.74

L28
FCD100
0.0003
77.970
1.79
146.13
5.20

L29
FCD100
0.0003
81.078
1.86
194.35
6.92

P
NBK7
0.0003
73.994
1.70
∞
∞

TABLE 22

Surface data

Effective

Surface number
r
d
nd
vd
radius

Object surface
∞

1
−656.064
5
1.60342
38
42.403

2
45.3758
3.068

34.002

3
46.5425
14.9135
1.8042
46.5
33.962

4
191.6049
0.2

32.662

5
56.5377
4
1.525
70.3
28.914

6*
19.7064
17.2085

22.414

7
49.4787
21
1.84139
24.6
19.334

8
52.7584
10.6396

11.929

9
−22.4814
5.0988
1.84139
24.6
9.521

10
−137.693
0.888

11.53

11
−82.5889
5.6684
1.6968
55.5
11.82

12
−27.8923
0.2

13.562

13
149.0052
8.2639
1.437
95.1
16.319

14
−36.5439
3.5

17.325

15
154.0886
10.8279
1.437
95.1
19.552

16
−33.5046
0.2

19.944

17
−33.8276
3
1.84139
24.6
19.901

18
−77.2754
27.5048

21.505

19
861.9723
8.9991
1.497
81.6
29.78

20
−86.4796
22.7441

30.272

21
67.6685
10.0365
1.84666
23.8
32.544

22
391.3697
0.2

31.909

23
37.4432
10.7465
1.84139
24.6
28.085

24
55.9061
4.1055

25.402

25
126.4832
9.5909
1.8061
33.3
25.017

26
32.6671
21.0051

18.789

27
−37.2255
3.6662
1.84139
24.6
19.101

28
−576.499
10.8649

21.586

29
−36.6964
8.4869
1.84139
24.6
23.23

30
−36.7843
1.2184

26.744

31
−203.449
12.3712
1.84666
23.8
31.221

32
−50.2529
12

32.142

TABLE 23

Surface data (continued)

Effective

Surface number
r
d
nd
vd
radius

Object surface
∞

33
∞
Variable

29.802

34
148.5076
7.2569
1.48749
70.4
25.978

35
−168.485
Variable

25.671

36
−94.9147
3
1.8061
33.3
22.523

37
−270.052
0.7616

22.714

38
−2984.09
3
1.8061
33.3
22.736

39
86.2081
0.2

23.096

40
81.2666
15.0258
1.437
95.1
23.262

41
−66.0493
0.2

24.253

42
154.4512
5.6237
1.497
81.6
24.482

43
−443.437
0.2

24.389

44
107.0246
4.7075
1.48749
70.4
24.121

45
270.0648
Variable

23.745

46(Aperture)
∞
1.1545

21.785

47
−360.513
3
1.7433
49.2
21.715

48
165.5117
25.7366

21.436

49
86.5679
8.4491
1.84139
24.6
22.511

50
−95.6709
0.2

22.258

51
−146.607
3
1.63854
55.4
21.747

52
52.233
11.976

20.344

53
−35.9824
20.0137
1.62004
36.3
20.578

54
141.3419
0.8106

31.253

55
160.2086
15.7633
1.437
95.1
31.801

56
−62.38
0.2

33.211

57
258.7058
15.5491
1.437
95.1
38.335

58
−83.2405
0.2

38.985

59
108.6175
13.0242
1.437
95.1
40.539

60
−375.244
22

40.352

61
∞
153.8
1.5168
64.2
36.997

62
∞
3

23.022

Image surface
∞

TABLE 24

Aspheric data

Sixth surface

K
−9.73E−01

A4
3.64E−06

A6
−2.38E−11

A8
−5.60E−14

A10
−4.24E−16

TABLE 25

Various data when the projecting distance is infinity

Zoom ratio: 1.21915

Wide angle
Intermediate
Telephoto

Focal length
−28.0988
−30.8792
−34.2567

F-number
−2.50496
−2.50462
−2.50739

Angle of view
−38.8107
−36.1987
−33.4064

Image height
22.6
22.6
22.6002

d33
80.9308
68.9152
56.1205

d35
2
8.4566
14.0857

d45
2
7.5589
14.7246

TABLE 26

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
59.1423

2
34
163.14226

3
36
173.85502

4
46
111.97088

TABLE 27

Various data at projection size of 200 inches (145.1 times)

Zoom ratio: 1.21905

Wide angle
Intermediate
Telephoto

Focal length
−28.1488
−30.9255
−34.3149

F-number
−2.50484
−2.50474
−2.50722

Angle of view
−38.7572
−36.161
−33.3605

Image height
22.6
22.6
22.6

Lens total length
700.0066
700.0234
700.0451

BF
0.00648
0.02346
0.04499

d0
4047.138
4450.061
4941.676

d14
3.2421
3.089
3.1792

d18
27.7626
27.9157
27.8256

d30
1.3566
1.3029
1.3263

d33
80.7927
68.8307
56.0126

d35
2
8.4566
14.0857

d45
2
7.5589
14.7246

TABLE 28

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
219.2082

2
15
473.5286

3
19
58.45259

4
31
76.00969

5
34
163.1423

6
36
173.855

7
46
111.9709

TABLE 29

Various data at projection size of 70 inches (50.8 times)

Zoom ratio: 1.21868

Wide angle
Intermediate
Telephoto

Focal length
−28.2429
−31.0236
−34.4191

F-number
−2.50465
−2.50456
−2.50699

Angle of view
−38.6563
−36.0711
−33.2792

Image height
22.6
22.6
22.6

d0
1396.298
1537.34
1709.39

d14
2.6895
2.5629
2.6905

d18
28.3152
28.4418
28.3142

d30
1.6072
1.5305
1.5308

d33
80.5421
68.6031
55.8081

d35
2
8.4566
14.0857

d45
2
7.5589
14.7246

TABLE 30

Zoom lens groups' data

Groups
Start surface
Focal length

1
1
219.2082

2
15
473.5286

3
19
58.45259

4
31
76.00969

5
34
163.1423

6
36
173.855

7
46
111.9709

Table 31 below shows numerical data obtained when each of the conditions (1)-(11) are applied to the lens systems used in the ongoing embodiments. Nevertheless, the numerical data in the rows of conditions (10) and (11) show only the case where the lens having the smallest effective diameter is used. Referring to tables 1-30 will show the lenses having other effective diameters.

TABLE 31

Embodiment 1
Embodiment 2
Embodiment 3

Condition (1)
2.6
2.89
2.61

Condition (2)
0.24
0.69
0.11

Condition (3)
1.07
2.95
0.87

Condition (4)
0
0.13
0.03

Condition (5)
0.01
0.5
0.16

Condition (6)
0.01
0.17
0.12

Condition (7)
6.19
11.06
4.94

Condition (8)
3.95
6.14
3.27

Condition (9)
0.62
0.65
0.63

Condition (10)
0.51
0.46
0.53

Condition (11)
1.44
1.79
1.16

INDUSTRIAL APPLICABILITY

The present disclosure is applicable to image projection apparatus (e.g. projector), and cameras including such as a digital still camera, digital video camera, surveillance camera used in a surveillance system, Web camera, or on-vehicle camera. The present disclosure, in particular, is best-fit for an imaging optical system including such as a projector, digital still camera system, and digital video camera system, viz. the systems requiring quality images.

	Number	Date	Country
Parent	16137637	Sep 2018	US
Child	16806038		US
Parent	PCT/JP2017/017794	May 2017	US
Child	16137637		US

IMAGING OPTICAL SYSTEM AND IMAGE PROJECTION APPARATUS

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

International Classifications

Abstract

Description

Claims

Priority Claims (1)

Continuations (2)