CN100576010C

CN100576010C - Zoom lenses, image pickup devices and personal digital assistants

Info

Publication number: CN100576010C
Application number: CN200710193472A
Authority: CN
Inventors: 大桥和泰
Original assignee: Ricoh Co Ltd
Current assignee: Ricoh Co Ltd
Priority date: 2006-11-27
Filing date: 2007-11-27
Publication date: 2009-12-30
Anticipated expiration: 2027-11-27
Also published as: JP2012185523A; CN101191898A; JP2008158481A; JP5072075B2; JP5516661B2

Abstract

A kind of zoom lens comprises from the order of object space side: has first lens combination of negative refraction power, has second lens combination of positive refracting power, and aperture diaphragm.When zooming to from wide-angle side when taking the photograph far-end, at least the first lens combination and second lens combination move, and the interval of winning between the lens combination and second lens combination can be diminished, second lens combination and can become big as the interval between the plane.Second lens combination has three positive lenss and two negative lenses at least, and one of at least three positive lenss are the aspheric surface positive lenss, the Abbe number ν of glass model _dWith anomalous dispersion Δ θ _{G, F}Meet the following conditions respectively: ν _d＞80.0 (1); Δ θ _{G, F}＞0.025 (2).

Description

Zoom lens, image pick-up device and personal digital assistant

Technical field

The present invention relates to zoom lens, image pick-up device and PDA(Personal Digital Assistant).

Background technology

Image pick-up device such as digital camera is widely used.The higher photographs quality and the littler size of device main body that need image pick-up device.Also need as varifocal mirror first watch of phtographic lens high quality and littler size.

Consider the miniaturization of zoom lens, need be when using zoom lens the total length (lens surface of the most close object space side and the distance that looks like between the plane) of zoom lens shorter.To reduce that total length with camera lens still reduces be very important to each lens group thickness when taking in.Therefore, consider varifocal mirror high performance on first watch, in recent years, need in whole zooming range, provide to be equivalent to the zoom lens of the image-forming component of 8-10 mega pixel at least.There are many user expectation phtographic lenses to have more wide visual field angle.Also there are many user expectation zoom lens preferably to be equal to or greater than 38 degree or to be equal to or greater than 42 degree at the angle of half field-of view of short burnt end (wide-angle side).The field angle of 38 degree and 42 degree respectively equals the silver halide 35mm camera (so-called Lycra (Leica) form) of 28mm and 24mm focal length.

As being suitable for small size and also being suitable for the lens type of the zoom lens of digital camera and reduced size, according to order from the object space side, have zoom lens and aperture diaphragm, zoom lens comprise have negative refraction power (negative refracting power) first lens combination, have second lens combination of positive refracting power (positiverefracting power) and have the 3rd lens combination of positive refracting power, aperture diaphragm is in the object space side of second lens combination, and moves with second lens combination is whole.When this zoom lens zooms to when taking the photograph far-end (telepphoto end) from wide-angle side (wide-angle end), at least the first lens combination and second lens combination move, the interval of winning between the lens combination and second lens combination can be diminished, and the interval between second lens combination and the 3rd lens combination become big.The zoom lens of these types is known by people.Resemble such zoom lens and in second lens combination, have at least three positive lenss and two negative lenses, Abbe number be 80 or bigger low dispersion as the positive lens of second lens combination.According to Japanese patent application publication No. 2004-102211, the lens of these types of 2006-113554 and 2005-24804 are known.

In the zoom lens of Japanese patent application publication No. 2004-102211, Abbe number be 80 or bigger low dispersion as the positive lens of second lens combination.By providing aspheric surface to realize miniaturization.In the zoom lens of Japanese patent application publication No. 2006-113554, three positive lenss and two negative lenses are used for second lens combination, and it reaches the angle of half field-of view that is equal to or greater than 43 degree in wide-angle side.For ratio chromatism, (chromatic aberration of magnification) is proofreaied and correct, Abbe number be 80 or bigger low dispersion as the negative lens of first lens combination.The Abbe number that is used for Japanese patent application publication No. 2004-102211 and 2006-113554 be 80 or bigger low dispersion be called special low dispersion and very expensive, yet it is effective material of proofreading and correct ratio chromatism.Particularly, in order to reach wide field angle in wide-angle side, need reduce the secondary spectrum (secondary spectrum) of the ratio chromatism, that increases corresponding to wide field angle is provided.In this case, it is effective utilizing especial dispersion glass.In the zoom lens according to Japanese patent application publication No. 2004-102211, though especial dispersion glass is used for second lens combination, the angle of half field-of view of wide-angle side is only less than 33 degree in a particular embodiment.The use of especial dispersion glass is not enough for the wide visual field angle role is provided.

Zoom lens according to Japanese patent application publication No. 2006-113554 reaches wide field angle, thereby is equal to or greater than 43 degree at the angle of half field-of view of wide-angle side.Yet expensive especial dispersion glass is used for first lens combination of major diameter lens, because large diameter lens, the cost of zoom lens itself is quite high.In the 4th embodiment of Japanese patent application publication No. 2005-24804, use Abbe number be 80 or higher low dispersion as the positive lens of the 4th lens combination, thereby axial chromatic aberration (axial chromaticaberration) and ratio chromatism, all are corrected.Yet in this example, the angle of half field-of view of wide-angle side is approximately 39 degree equally, does not reach 42 degree.

Summary of the invention

The purpose of this invention is to provide novel zoom lens, utilize the image pick-up device and the personal digital assistant of utilizing this image pick-up device of this novel zoom lens.A kind of zoom lens particularly is provided, this zoom lens provides the resolution that is equivalent to 8-10 ten thousand pixels in whole zooming range, the angle of half field-of view of wide-angle side reaches and is equal to or greater than 42 degree, this angle of half field-of view can obtain with low cost, with the image pick-up device that utilizes this zoom lens, and the personal digital assistant of utilizing this image pick-up device.

A kind of zoom lens, comprise first lens combination with negative refraction power, second lens combination with positive refracting power, second lens combination comprises at least three positive lenss and two negative lenses, wherein one of at least three positive lenss are the aspheric surface positive lenss, with the diaphragm that is arranged on the second lens combination object space side, itself and second lens combination integral body move, first lens combination and second lens combination according to from the object space side to being disposed in order as square side, when carrying out when wide-angle side zooms to the zoom of taking the photograph far-end, at least the first lens combination and second lens combination move, the interval of winning between the lens combination and second lens combination is reduced, interval between second lens combination and the picture plane increases, wherein the Abbe number v of the glass model of the aspheric surface of a slice at least positive lens of three of second lens combination positive lenss _dWith anomalous dispersion Δ θ _{G, F}Meet the following conditions respectively:

v _d＞80.0 (1)

Δθ _g，F＞0.025 (2)

N wherein _gBe the refractive index of g line, n _FBe the refractive index of F line, n _cBe the refractive index of c line, v _dBe Abbe number, Δ θ _{G, F}Be anomalous dispersion, wherein local relatively chromatic dispersion defines with a condition:

θ _g，F＝(n _g-n _F)/(n _F-n _c)

Anomalous dispersion Δ θ wherein _{G, F}Be defined as the deviation with the reference line of two-dimensional coordinate face, wherein the two-dimensional coordinate face is with comprising that the plane of two Z-axises defines, local relatively chromatic dispersion θ _{G, F}Be the longitudinal axis, Abbe number v _dBe transverse axis, wherein the reference line coordinate points (v that connects with reference to glass model K7 _d=60.49, θ _{G, F}=0.5432) with reference to the coordinate points (v of glass model F2 _d=36.26, θ _{G, F}=0.5830) straight line defines.

Preferably, zoom lens, also comprise the 3rd lens combination with positive refracting power, be arranged on picture side's side of second lens combination, wherein when carrying out when wide-angle side zooms to the zoom of taking the photograph far-end, at least the first lens combination and second lens combination move, and the interval of winning between the lens combination and second lens combination is reduced, and the interval between second lens combination and the picture plane increases.

Preferably, the 3rd lens combination comprises a slice positive lens.

Preferably, a slice positive lens of the 3rd lens combination is the aspheric surface positive lens, the Abbe number v of the glass model of the aspheric surface positive lens of a slice positive lens _dWith anomalous dispersion Δ θ _{G, F}Meet the following conditions respectively:

v _d＞80.0 (1)

Δθ _g，F＞0.025 (2)

Preferably, the optical axis distance dS-L the surface from aperture diaphragm to the most approaching picture side of second lens combination side, and the optical axis distance dS-A the aspheric surface from diaphragm to the most approaching picture side of second lens combination side satisfies condition:

0.75＜dS-A/dS-L≤1.0 (3)

Preferably, the aspheric focal distance f A of the focal distance f 2 of second lens combination and the second lens combination picture side side satisfies condition:

0.4＜fA/f2＜1.0 (4)

Preferably, comprise that the aspheric surface positive lens of the glass model of satisfy condition (1) and (2) has resin bed at least one surface of its optical surface, and be hybrid aspherical lens that wherein the air contacting surface of resin bed forms aspherical shape.

Preferably, the center thickness tR of the center thickness tA of whole hybrid aspherical lens and resin bed satisfies condition:

0.01＜tR/tA＜0.1 (5)

Preferably, the aspheric paraxial radius-of-curvature rA of the resin bed air contacting surface of hybrid aspherical lens, the radius-of-curvature rB that forms the sphere of resin bed satisfies condition:

0.5＜rB/rA＜1.4 (6)

Preferably, the aspheric surface positive lens of the glass model of satisfy condition except comprising (1) and (2), second lens combination also comprises a slice non-spherical lens at least.

Preferably, a slice aspheric surface positive lens is arranged on the position of the most approaching picture side of second lens combination side at least, and a slice non-spherical lens is arranged on second lens combination near the position of object space side at least.

Preferably, a slice aspheric surface positive lens is arranged on the position of the most approaching picture side of second lens combination side at least, with negative lens gummed that is arranged on its object space side and is provided with its vicinity.

Preferably, zoom lens has the resolution that is equivalent to 8-10 mega pixel or higher imageing sensor, and wherein the angle of half field-of view of wide-angle side is equal to or greater than 42 degree.

Preferably, a kind of image pick-up device, comprise zoom lens as the photography zoom lens, zoom lens comprises first lens combination with negative refraction power, second lens combination with positive refracting power, second lens combination comprises at least three positive lenss and two negative lenses, wherein one of at least three positive lenss are the aspheric surface positive lenss, be arranged on the diaphragm of the second lens combination object space side, itself and second lens combination integral body move, first lens combination and second lens combination according to from the object space side to being disposed in order as square side, when carrying out when wide-angle side zooms to the zoom of taking the photograph far-end, at least the first lens combination and second lens combination move, the interval of winning between the lens combination and second lens combination is reduced, interval between second lens combination and the picture plane increases, wherein the Abbe number v of the glass model of the aspheric surface of a slice at least positive lens of three of second lens combination positive lenss _dWith anomalous dispersion Δ θ _{G, F}Meet the following conditions respectively:

v _d＞80.0 (1)

Δθ _g，F＞0.025 (2)

θ _g，F＝(n _g-n _F)/(n _F-n _c)

Preferably, color image sensor is as imageing sensor.

Preferably, image pick-up device has the resolution that is equivalent to 8-10 mega pixel or higher imageing sensor, and wherein the angle of half field-of view of wide-angle side is equal to or greater than 42 degree.

Preferably, a kind of personal digital assistant, comprise image pick-up device, image pick-up device comprises the zoom lens as the photography zoom lens, zoom lens has: first lens combination with negative refraction power, second lens combination with positive refracting power, second lens combination comprises at least three positive lenss and two negative lenses, wherein one of at least three positive lenss are the aspheric surface positive lenss, be arranged on the diaphragm of the second lens combination object space side, itself and second lens combination integral body move, first lens combination and second lens combination according to from the object space side to being disposed in order as square side, when carrying out when wide-angle side zooms to the zoom of taking the photograph far-end, at least the first lens combination and second lens combination move, the interval of winning between the lens combination and second lens combination is reduced, and the interval between second lens combination and the picture plane increases, wherein the Abbe number v of the glass model of the aspheric surface of a slice at least positive lens of three of second lens combination positive lenss _dWith anomalous dispersion Δ θ _{G, F}Meet the following conditions respectively:

v _d＞80.0 (1)

Δθ _g，F＞0.025 (2)

θ _g，F＝(n _g-n _F)/(n _F-n _c)

Description of drawings

Displacement when Fig. 1 is expression according to the sectional view of the Zoom lens structure of first embodiment and zoom thereof.

Displacement when Fig. 2 is expression according to the sectional view of the Zoom lens structure of second embodiment and zoom thereof.

Displacement when Fig. 3 is expression according to the sectional view of the Zoom lens structure of the 3rd embodiment and zoom thereof.

Displacement when Fig. 4 is expression according to the sectional view of the Zoom lens structure of the 4th embodiment and zoom thereof.

Displacement when Fig. 5 is expression according to the sectional view of the Zoom lens structure of the 5th embodiment and zoom thereof.

Fig. 6 is according to the aberration figure of first embodiment at short burnt end.

Fig. 7 is according to the aberration figure of first example at middle burnt end.

Fig. 8 is according to the aberration figure of first embodiment at long burnt end.

Fig. 9 is according to the aberration figure of second embodiment at short burnt end.

Figure 10 is according to the aberration figure of second embodiment at middle burnt end.

Figure 11 is according to the aberration figure of second embodiment at long burnt end.

Figure 12 is according to the aberration figure of the 3rd embodiment at short burnt end.

Figure 13 is according to the aberration figure of the 3rd embodiment at middle burnt end.

Figure 14 is according to the aberration figure of the 3rd embodiment at long burnt end.

Figure 15 is according to the aberration figure of the 4th embodiment at short burnt end.

Figure 16 is according to the aberration figure of the 4th embodiment at middle burnt end.

Figure 17 is according to the aberration figure of the 4th embodiment at long burnt end.

Figure 18 is according to the aberration figure of the 5th embodiment at short burnt end.

Figure 19 is according to the aberration figure of the 5th embodiment at middle burnt end.

Figure 20 is according to the aberration figure of the 5th embodiment at long burnt end.

Figure 21 A is the front elevation of the embodiment of personal digital assistant (when shrinking).

Figure 21 B is the front elevation of the embodiment of personal digital assistant (when energising).

Figure 21 C is the rear view of the embodiment of personal digital assistant.

Figure 22 is the diagrammatic sketch of the device of key drawing 21A and 21C.

Embodiment

Hereinafter, explain the description of embodiment.

Zoom lens according to an embodiment, according to order from object space, at least comprise first lens combination with negative refraction power, have second lens combination of just tearing the power of penetrating open and the object space of second lens combination, with whole diaphragm (or the aperture that moves of second lens combination, or aperture diaphragm, or aperture), when zooming to from wide-angle side when taking the photograph far-end, at least the first lens combination and second lens combination move, the interval of winning between the lens combination and second lens combination is diminished, interval between second lens combination and the picture plane becomes big, and has following feature.

Second lens combination has at least three positive lenss and two negative lenses, and one of at least three positive lenss are the aspheric surface positive lenss.In other words, the Abbe number v of the glass model of a slice aspheric surface positive lens at least _dAnomalous dispersion Δ θ with the glass model _{G, F}Satisfy condition:

v _d＞80.0 (1)

Δθ _g，F＞0.025 (2)

Local relatively chromatic dispersion θ _{G, F}Use following expression: θ _{G, F}=(n _g-n _F)/(n _F-n _c) define, each is the g line refractive index n of glass mould number naturally _g, the F line refractive index n of glass model _F, the c line refractive index n of glass model _cThe two-dimensional coordinate face is with comprising that the plane of two Z-axises defines, and they are with local relatively chromatic dispersion θ _{G, F}Be defined as the longitudinal axis, with Abbe number v _dBe defined as transverse axis, reference line is defined as the coordinate points (v of connection with reference to glass model K7 _d=60.49, θ _{G, F}=0.5432) with reference to the coordinate points (v of glass model F2 _d=36.26, θ _{G, F}=0.5830) straight line.The anomalous dispersion Δ θ of glass model _{G, F}Be defined as relative local chromatic dispersion θ with the glass model _{G, F}The deviation of reference line of two-dimensional coordinate face.

Above-mentioned anomalous dispersion Δ θ _{G, F}It is the distance that between the coordinate points of the two-dimensional coordinate face of glass model and reference line, is parallel to y direction.Local relatively chromatic dispersion θ _{G, F}It is physical quantity with the glass model definition.Above-mentioned reference line is with reference to the local relatively chromatic dispersion θ of glass model K7 on the two-dimensional coordinate face _{G, F}(K7:0.5432) and the Abbe number v of K7 _d(K7:60.49) be respectively the coordinate points of ordinate and horizontal ordinate, with the relative local chromatic dispersion θ of reference glass model F2 _{G, F}(F2:0.5830) and the Abbe number v of F2 _d(F2:36.26) be respectively the straight line that the coordinate points of ordinate and horizontal ordinate is connected,

Particularly, for example, be the NSL7 of OHARAINC and be the PBM2 of ONARAINC with reference to the ProductName of glass model: F2 with reference to the ProductName of glass model: K7.

The minimal structure of lens combination might be two lens combination, such as first lens combination and second lens combination.In the picture side of second lens combination,, might also there be the 3rd lens combination and has subsequently lens combination in the 3rd lens combination back such as the 4th lens combination or the like with positive refracting power if the miniaturization of whole lens combination does not stop with positive refracting power.

The preferred embodiment of zoom lens has the 3rd lens combination of positive refracting power in the existence of the picture side of second lens combination with positive refracting power, has this structure, when zooming to from wide-angle side when taking the photograph far-end, at least the first lens combination and second lens combination move, the interval of winning between the lens combination and second lens combination is diminished, and the interval between second lens combination and the 3rd lens combination become big.

Zoom lens might have the 3rd lens combination that comprises a positive lens.In this case, a positive lens of the 3rd lens combination is the aspheric surface positive lens, the Abbe number v of glass model _dAnomalous dispersion Δ θ with the glass model _{G, F}Preferably satisfy condition:

v _d＞80.0 (1)

Δθ _g，F＞0.025 (2)

About zoom lens, the optical axis distance dS-L between the surface of preferred diaphragm and the most approaching picture side of second lens combination side, and the optical axis distance dS-A between the aspheric surface of diaphragm and the most approaching picture side of second lens combination side satisfies condition:

0.75＜dS-A/dS-L≤1.0 (3)

About zoom lens, the focal distance f 2 of second lens combination and preferably satisfy condition: 0.4＜fA/f2＜1.0 (4) at the focal distance f A of the non-spherical lens of the second lens combination picture side side

In this case, if exist in second lens combination more than two non-spherical lenses, focal distance f A is one maximum in those non-spherical lenses.

About zoom lens, in second lens combination or the aspheric surface positive lens in the 3rd lens combination of the glass model that comprises satisfy condition (1) and (2), at least one surface of optical surface, has thin resin layer.The preferred hybrid aspherical lens of aspheric surface positive lens, wherein the air contacting surface of this resin bed is an aspherical shape.

About the hybrid aspherical lens in the zoom lens, the center thickness tA of whole hybrid aspherical lens and the center thickness tR of resin bed preferably satisfy condition: 0.01＜tR/tA＜0.1 (5)

About the hybrid aspherical lens in the zoom lens, the radius-of-curvature rB of the sphere of the aspheric paraxial radius-of-curvature rA of resin bed air contacting surface and formation resin bed preferably satisfies condition:

0.5＜rB/rA＜1.4 (6)

Except the aspheric surface positive lens of the glass model of satisfy condition (1) and (2), zoom lens allows second lens combination to have at least one non-spherical lens.In this case, an aspheric surface positive lens in second lens combination arranges that preferred non-spherical lens is arranged near the object space side of second lens combination near picture side's side of second lens combination.

An aspheric surface positive lens in second lens combination of zoom lens is arranged near picture side's side of second lens combination, and might engage the negative lens of the object space side layout of contiguous aspheric surface positive lens.

This zoom lens might have the angles of half field-of view that are equal to or greater than 42 degree in wide-angle side, has resolution corresponding to 8-10 mega pixel or higher imageing sensor at whole zooming range.

Zoom lens according to the present invention is used for image pick-up device as the photography zoom lens.The imageing sensor of image pick-up device is a color image sensor.

Image pick-up device has the pixel count of the imageing sensor that is equal to or greater than the 8-10 mega pixel.

PDA(Personal Digital Assistant) according to the present invention has the image pick-up device according to zoom lens of the present invention.

For example, in zoom lens according to an embodiment of the invention, such as zoom lens with two lens combination, according to order from the object space side, generally include negative lens group and positive lens groups, when zooming to from wide-angle side when taking the photograph far-end, second lens combination moves on to object space monotonously from picture side, first lens combination moves, and changes to proofread and correct zoom time image planimetric position.For emergent pupil and the distance on picture plane or the distance of back focusing, may increase positive the 3rd lens combination, under the sort of situation, second lens combination realizes main zoom function equally.

In order to realize that more the baby elephant difference changes and more high-resolution zoom lens, the aberration of zoom changes needs to keep very little, especially must be corrected as the aberration in the whole zooming range of second lens combination of main zoom group.Particularly, in order to reach wide field angle at short burnt end (wide-angle side), need reduce the secondary spectrum of the ratio chromatism, that increases along with becoming wide field angle, in order to achieve this end, the structure of second lens combination is also very important.

Usually, carry out the correction of axial chromatic aberration and ratio chromatism,, to use the image space of two wavelength in the wavelength coverage corresponding to usefulness.Still in being clipped in two wavelength coverages between the wavelength, outside the scope of two wavelength, image space is not always corresponding to aberration.Secondary spectrum is remaining aberration (resident chromatic aberration).

The visual sensitivity of human eye is higher to the wavelength of green fields.Therefore, when aberration is very high in the high wavelength coverage of visual sensitivity, since image blurring, visual image resolution step-down.

When photographing with color image sensor, above-mentioned identical situation appears.Usually, have the color image sensor of red, green and blue mosaic optical filter, 50% of whole pixel count has green optical filter, to guarantee resolution.Therefore, the luminance signal that the output of pixel control forms by signal Processing when considering green fields.When aberration is very high in this wavelength coverage, the image resolution ratio step-down of generation.

On the other hand, in most of color image sensors, the photography susceptibility in the short wavelength range is more quite a lot of than human eye and silver-halide color film height.Therefore, because blueness is blured in the image that produces outstanding easily to the color of purple scope aberration.Fuzzy in order to reduce this color, need make blue aberration in the purple scope very little.Yet when attempting to make the very little and insufficient correction secondary spectrum of blue aberration in the purple scope, the aberration in green fields uprises, and it causes that the resolution of the image of above-mentioned generation reduces.

Therefore, the correction of the secondary spectrum of aberration has important effect, to guarantee the resolution of image.

For example, as the structure of second lens combination, usually, it is known being designed to utilize a kind of structure of aspheric surface spherical aberration corrector etc. and being designed to utilize the another kind of structure of low diffusion glass correcting chromatic aberration.One embodiment of the present of invention are characterised in that the structure with second lens combination of aberration correction ability surpasses these conventional examples.In addition, the little a lot of and wideer high-performance variable zoom lens in visual field of fuselage need not raise the cost and realize.

That is to say that in an embodiment of the present invention, the structure of second lens combination comprises at least three positive lenss and two negative lenses.This structure is that of positive lens comprises the aspheric surface positive lens with positive refracting power at least, the glass model of aspheric surface positive lens satisfy condition (1) and (2).

The aspheric surface positive lens that forms with the optical material (glass model) of satisfy condition (1) and (2) is used for second lens combination, thereby each of monochromatic aberration and aberration can reduce with balance mode.

Yet the optical material of satisfy condition (1) and (2) generally is the glass with low especially chromatic dispersion of low refracting power.For aberration correction is good, it is not enough only adopting the aspheric surface positive lens.In an embodiment of the present invention, second lens combination has the structure of three positive lenss and two negative lenses basically, thereby can obtain high chromatic aberration correction ability.

When the angle of half field-of view of wide-angle side is spent above 40, the structure of above-mentioned second lens combination is effective especially, although the generation of monochromatic aberration is limited fully, might proofread and correct ratio chromatism, and colored coma (colorcoma aberration) fairly good, they increase along with broadening of field angle.At this moment, for example,, might need not low especially dispersive glass form wide field angle fully for first lens combination of big lens diameter.

The condition (1) that satisfies in the glass model of the aspheric surface positive lens by being used for second lens combination is as the Abbe number v of the glass model of aspheric surface positive lens _dBe equal to or less than at 80.0 o'clock, the ratio chromatism, undercorrection.The condition (2) that satisfies in the glass model of the aspheric surface positive lens by being used for second lens combination is as anomalous dispersion Δ θ _{G, F}Be equal to or less than at 0.025 o'clock, the secondary spectrum of ratio chromatism, is still quite high, and it is difficult to Show Color and blurs to guarantee resolution.Add positive the 3rd lens combination, negative, positive and three-chip type lens group structure positive lens is possible.Add positive the 3rd lens combination, make the distance of emergent pupil to guarantee easily and the focusing by moving the 3rd lens combination also is possible.

When arranging the 3rd lens combination, the 3rd lens combination comprises towards the positive lens on object space side deep camber surface.The 3rd lens combination preferably has at least one aspheric surface.If the structure of the 3rd lens combination is aforesaid structure, the thickness of the 3rd lens combination is reduced to minimum, and off-axis aberration such as astigmatism etc. is proofreaied and correct better.And when the 3rd lens combination comprised a slice positive lens, the low dispersion model was preferred for the purpose of chromatic aberration correction.The 3rd lens combination can be fixed when zoom, yet the 3rd lens combination is mobile a little, makes the degree of freedom of aberration correction to improve.

As the 3rd lens combination, when the glass model of satisfy condition (1) and (2) comprises a slice positive lens, the most approaching picture of this positive lens plane, the light beam of every field angle be separate and pass through, the optical path change that zoom causes is very little.Therefore, the 3rd lens combination has the chromatic aberration correction different with the aspheric surface positive lens of second lens combination, thereby can improve the effect of chromatic aberration correction in whole zooming range.

Condition (3) is the optimum condition of proofreading and correct from the axle monochromatic aberration, from the axle monochromatic aberration along with field angle broadens, ratio chromatism, and colored coma better and increasing.The aspheric surface positive lens is quite near the position of aperture diaphragm, promptly, when parameter d S-A/dS-L is during in the position that is equal to or less than 0.75, by the insufficient height from the axle chief ray of aspheric surface positive lens, thereby be difficult to and proofread and correct from axle monochromatic aberration such as astigmatism and coma (coma aberration) and aberration such as ratio chromatism, and colored coma.In addition, clearly dS-A/dS-L is no more than 1.0.

When the parameter f A/f2 of condition (4) was equal to or greater than 1.0, the refracting power of aspheric surface positive lens was not enough to reduce secondary spectrum, and was not enough to complete correcting chromatic aberration.On the contrary, when the parameter f A/f2 of condition (4) is equal to or less than 0.4, be difficult to balance chromatic aberration correction and spherical aberration correction.Enough proofreaied and correct with aberration although secondary spectrum enough reduces, for chromatic aberration correction and spherical aberration correction balance is good, preferred parameter fA/f2 satisfies the condition (4A) narrower slightly than condition (4): 0.5＜fA/f2＜0.95.

Abbe number v _dBe 80 or the glass model of the aspheric surface positive lens of higher low especially dispersing lens aspheric surface positive lens that is second lens combination or the 3rd lens combination.For their making, except very little lens, be difficult to use molding process, this technology is when high temperature aspheric die cavity shape to be passed to glass.Have such technology, that is, glass material directly cuts and grinds into aspheric surface, yet, the non-constant of this method productivity, cost height.

For the reason of cost, it is effective being made up of hybrid aspherical lens with the aspheric surface positive lens of the aspheric surface positive lens of second lens combination of the glass model production of satisfy condition (1) and (2) and the 3rd lens combination.Because hybrid aspherical lens is formed by the thin resin layer at least one optical surface of spherical lens, wherein aspheric die cavity transfer of shapes is such as the aspheric surface of mixing.

The optimum condition that satisfies this hybrid aspherical lens is condition (5) and (6).Spherical lens uses inorganic material such as making such as glass easily, and their characteristic variations is subjected to the image of environmental change such as temperature, humidity etc. little.Yet, to compare with glass lens, the characteristic variations (expansion, contraction, change of refractive etc.) that is used for the resin bed of aspheric surface part is subjected to the image of environmental change big.

When the parametric t R/tA of condition (5) was equal to or greater than 0.1, resin bed is thickening unnecessarily, and the change of optical property of zoom lens becomes big owing to environmental change basically, thereby is difficult in the operational phase guaranteed performance.On the contrary, when parameter was equal to or less than 0.01, resin bed was too thin, made the aspheric shape that needs to proofread and correct aberration be difficult to form.

When the parameter rB/rA of condition (6) was equal to or greater than 1.4, in the resin layer thickness attenuation of lens perimeter, the thickness difference of center and peripheral quality inspection was too big, thereby was difficult to form accurately aspheric shape.On the contrary, when parameter was equal to or less than 0.5, at the resin layer thickness thickening of lens perimeter, the thickness difference of center and periphery was big too, is difficult to form accurately aspheric shape.

In zoom lens according to the present invention, except the aspheric surface positive lens, second lens combination preferably has at least one non-spherical lens, makes the correction of spherical aberration correction and astigmatism and coma carry out with high level.Owing to adopt said structure, to a main spherical aberration corrector of aspheric surface, to main correct astigmatism of another aspheric surface and coma.Therefore, the extraordinary performance of zoom lens is possible.In addition, the function of the aberration correction of two non-spherical lenses (aspheric surface positive lens and another non-spherical lens) is separated, thereby the image property that can reduce to be caused by non-spherical lens off-centre descends.

And the aspheric surface positive lens is preferably near picture side's side setting of second lens combination, and other non-spherical lens preferably is provided with near the object space side of second lens combination.In order to improve the effect that ratio chromatism, is proofreaied and correct with low dispersion characteristics, the aspheric surface positive lens should be is rational near picture side's side setting of second lens combination.Simultaneously, aspheric influence may play a major role when proofreading and correct off-axis aberration such as astigmatism, coma etc.Other non-spherical lens is arranged on the position near aperture diaphragm, thereby can realize the main effect of spherical aberration corrector as far as possible effectively.

When the aspheric surface positive lens is provided with near picture side's side of second lens combination, be connected with the negative lens of the setting of contiguous aspheric surface positive lens object space side and use, that is, high chromatic dispersion negative lens is arranged on the object space side of non-women's head-ornaments positive lens, and astigmatism and colored coma can be proofreaied and correct better.These lens are connected to each other, and make the influence of production and composition error to reduce, and more stable performance can be guaranteed.

Hereinafter, assurance zoom lens performance better condition is described.According to the order from the object space side, first lens combination preferably includes three lens, that is, and and negative meniscus lens, negative lens and the positive lens of its concave surface facing picture side side.Two negative lenses are arranged on the object space side of first lens combination, make to have reflecting gradually from the axle luminous flux of big full-shape on whole four surfaces, can reduce the generation of off-axis aberration.

In order to proofread and correct monochromatic aberration better, preferred first lens combination has and equals or more than an aspheric surface.Specifically, be arranged on arbitrary surface that the object space side gets picture side's side of two negative lenses and be preferably aspheric surface.Owing to adopt aspheric surface in this position, especially might be proofreaied and correct effectively at short burnt distortion of holding, astigmatism etc.

Although zoom, the opening diameter of preferred diaphragm is constant, because mechanism is simplified.Yet the opening diameter of long burnt end is greater than the opening diameter of short burnt end, thereby the variation of F number is also very little during zoom.When needs reduced the light quantity that reaches the picture plane, the diameter of diaphragm may be very little.Yet the mode that preferably reduces light quantity is not by changing diaphragm diameter widely, but inserts ND (neutrality) optical filter etc., thereby can prevent because the resolution that refraction effect causes reduces.

Hereinafter, utilize accompanying drawing to explain embodiments of the invention.Fig. 1 represents the embodiment of zoom lens and is first embodiment that describes later.According to order from object space side (left side of accompanying drawing), zoom lens shown in Figure 1 comprises the first lens combination I, the second lens combination II with positive refracting power with negative refraction power, have the 3rd lens combination III of positive refracting power and be arranged on the second lens combination II the object space side and with the whole diaphragm S that changes its position of the second lens combination II.In this zoom lens, when zooming to from wide-angle side when taking the photograph far-end, as shown by arrows, at least the first lens combination I and the second lens combination II move, the interval of winning between the lens combination I and the second lens combination II is reduced, and the interval between the second lens combination II and the 3rd lens combination III increases.As mentioned below, in first embodiment, the glass model of the aspheric surface positive lens that comprises in second lens combination satisfy condition (1) and (2).

Fig. 2 is another embodiment of zoom lens, second embodiment that expression is described later.According to order from object space side (left side of accompanying drawing), zoom lens shown in Figure 2 comprises the first lens combination I, the second lens combination II with positive refracting power with negative refraction power, have the 3rd lens combination III of positive refracting power and be arranged on the second lens combination II the object space side and with the whole diaphragm S that changes its position of the second lens combination II.In this zoom lens, when zooming to from wide-angle side when taking the photograph far-end, as shown by arrows, at least the first lens combination I and the second lens combination II move, the interval of winning between the lens combination I and the second lens combination II is reduced, and the interval between the second lens combination II and the 3rd lens combination III increases.As mentioned below, in a second embodiment, the glass model of the aspheric surface positive lens that comprises in second lens combination satisfy condition (1) and (2).

Fig. 3 is the another embodiment of zoom lens, the 3rd embodiment that expression is described later.According to order from object space side (left side of accompanying drawing), zoom lens shown in Figure 3 comprises the first lens combination I, the second lens combination II with positive refracting power with negative refraction power, have the 3rd lens combination III of positive refracting power and be arranged on the second lens combination II the object space side and with the whole diaphragm S that changes its position of the second lens combination II.In this zoom lens, when zooming to from wide-angle side when taking the photograph far-end, as shown by arrows, at least the first lens combination I and the second lens combination II move, the interval of winning between the lens combination I and the second lens combination II is reduced, and the interval between the second lens combination II and the 3rd lens combination III increases.As mentioned below, in the 3rd embodiment, the glass model of the aspheric surface positive lens that comprises in second lens combination satisfy condition (1) and (2).

Fig. 4 is the another embodiment of zoom lens, the 4th embodiment that expression is described later.According to order from object space side (left side of accompanying drawing), zoom lens shown in Figure 4 comprises the first lens combination I, the second lens combination II with positive refracting power with negative refraction power, have the 3rd lens combination III of positive refracting power and be arranged on the second lens combination II the object space side and with the whole diaphragm S that changes its position of the second lens combination II.In this zoom lens, when zooming to from wide-angle side when taking the photograph far-end, as shown by arrows, at least the first lens combination I and the second lens combination II move, the interval of winning between the lens combination I and the second lens combination II is reduced, and the interval between the second lens combination II and the 3rd lens combination III increases.As mentioned below, in the 4th embodiment, the glass model of the aspheric surface positive lens that comprises in second lens combination satisfy condition (1) and (2).That is, in first to fourth embodiment, each zoom lens comprises three lens combination.

Fig. 5 is the another embodiment of zoom lens, the 5th embodiment that expression is described later.According to order from object space side (left side of accompanying drawing), zoom lens shown in Figure 5 comprises the first lens combination I with negative refraction power, have the second lens combination II of positive refracting power and be arranged on the second lens combination II the object space side and with the whole diaphragm S that changes its position of the second lens combination II.In this zoom lens, when zooming to from wide-angle side when taking the photograph far-end, as shown by arrows, the first lens combination I and the second lens combination II move, the interval of winning between the lens combination I and the second lens combination II is reduced, and the interval between the second lens combination II and the picture plane increases.As mentioned below, in the 5th embodiment, the glass model of the aspheric surface positive lens that comprises in second lens combination satisfy condition (1) and (2).That is, the zoom lens of the 5th embodiment is the example that is made of zoom lens two lens combination.In addition, in Fig. 1-5, describe various optical filters with the flat board that symbol F represents, such as the cover glass (seal glass) of optics low pass filter, cutoff filter etc. and light receiving element such as CCD (charge-coupled device (CCD)) sensor etc., it is single dull and stereotyped.

Before the specific embodiment of describing zoom lens, explain the embodiment of personal digital assistant.Shown in Figure 21 A and 22, personal digital assistant 30 has phtographic lens 31 and as the light receiving element (face sensor) 45 of imageing sensor.Personal digital assistant 30 has such structure, and the subject image of being taken by phtographic lens 31 provides image on light receiving element 45, and imageing sensor 45 can reading images.

Image pick-up device comprises phtographic lens 31 and light receiving element 45.Light receiving element 45 is color image sensors.As phtographic lens 31, specifically, zoom lens according to an embodiment of the invention, for example, use described first to the 5th embodiment in back one.As light receiving element 45, its pixel count is the 8-10 mega pixel, and for example, catercorner length 9.1mm, the pel spacing 2 μ m pixel counts of use optical receiving region are approximately 1,000 ten thousand CCD face sensor etc.

As shown in figure 22, numerical information is handled and converted to the output of light receiving element 45 by the signal processor 42 of CPU (CPU (central processing unit)) 40 controls.After in the image processor 41 of CPU 40 control, carrying out pre-Flame Image Process, by signal processor 42 digitized image information recordings in semiconductor memory 44.LCD (liquid crystal display) device 38 shows the figure of taking, and is also shown in the image of record in the semiconductor memory 44.In addition, the image of record also may utilize communication card 43 grades to send to external device (ED) in semiconductor memory 44.

Shown in Figure 21 A, when carrying device, phtographic lens 31 is at contraction state, and when user's energized switch 36, shown in Figure 21 B, lens barrel stretches out.In this case, every group of zoom lens in lens barrel for example is arranged on short burnt end.Every group layout changes by the operation of zoom lever 34, might zoom to long burnt end like this.Then, view finder 33 is also along with the field angle of phtographic lens 31 changes its change multiplying power of change.

Partly press shutter release button 35 to focus on.When using the zoom lens of first to the 5th embodiment, by the 3rd lens combination move or light receiving element 45 move forward into line focusing.Press shutter release button 35 fully and photograph, then, carry out above-mentioned Image Information Processing.Reference numeral 32 is flashlamp.

By operating operation button 37, can displayed record on the LCD display 38 in semiconductor memory 44 image or utilize communication card 43 etc. to send to external device (ED).Semiconductor memory 44, communication card 43 etc. insert respectively among special-purpose or general the groove 39A and 39B, and use.

When phtographic lens 31 during at contraction state, every group of zoom lens is not always to need to aim at optical axis.For example, if mechanism is three lens combination, the 4th lens combination and the 5th lens combination depart from optical axis, and take in other lens combination is parallel, and personal digital assistant might be thinner.

Hereinafter, description is according to four instantiations of the zoom lens of the embodiment of the invention.In all embodiments, maximum picture height is 4.70mm.In each embodiment, the implication of symbol is described below.

F: the focal length of total system

The F:F number

ω: angle of half field-of view

R: radius-of-curvature

D: between the surface interval

N _d: refractive index

v _d: Abbe number

K: aspheric conic constant

A ₄: fourth stage asphericity coefficient

A ₆: the 6th grade of asphericity coefficient

A ₈: the 8th grade of asphericity coefficient

A ₁₀: the tenth grade of asphericity coefficient

A ₁₂: the tenth secondary asphericity coefficient

A ₁₄: the tenth level Four asphericity coefficient

A ₁₆: the 16 grade of asphericity coefficient

A ₁₈: the 18 grade of asphericity coefficient

If the anti-number of paraxial radius-of-curvature (paraxial curvature) is C, be that H, conic constant are that K, asphericity coefficient are A from the height of optical axis ₄, A ₆, A ₈...,

Aspheric shape provides with following known expression:

X＝CH ²/{1+√(1-(1+K)C ²H ²)}

+A ₄·H ⁴+A ₆·H ⁶+A ₈·H ⁸+A ₁₀·H ¹⁰+A ₁₂·H ¹²+A ₁₄·H ¹⁴+A ₁₆·H ¹⁶+A ₁₈·H ¹⁸

X is to be the length of perpendicular that the aspheric tangent plane to the aspheric surface summit (vertical plane of optical axis) of H is drawn from the height from optical axis.

For example, the product of the product of OHARA company and Sumita optical Glass company is as optical glass.The title of glass model is the name of product of each company.

(first embodiment)

f＝5.204～14.996，F＝2.66～4.67，ω＝43.26～17.51

Surface number

R

D

N _d

V _d

Δθ _g，F

The glass model name

01	24.422	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
01	24.422	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72	02 ^*	9.225	4.11
03	-180.153	1.20	1.77250	49.60	-0.0092	OHARA S-LAH66	02 ^*	9.225	4.11
03	-180.153	1.20	1.77250	49.60	-0.0092	OHARA S-LAH66	04	11.584	4.10
05	20.498	3.55	1.80100	34.97	0.0015	OHARA S-LAM66	04	11.584	4.10
05	20.498	3.55	1.80100	34.97	0.0015	OHARA S-LAM66	06	-34.360	1.00	1.75700	47.82	-0.0076	OHARA S-LAM54
07	232.236	Variable (A)					06	-34.360	1.00	1.75700	47.82	-0.0076	OHARA S-LAM54
07	232.236	Variable (A)					08	Diaphragm	1.00
09 ^*	8.821	1.56	1.77250	49.60	-0.0092	OHARA S-LAH66	08	Diaphragm	1.00
09 ^*	8.821	1.56	1.77250	49.60	-0.0092	OHARA S-LAH66	10	22.899	0.10
11	7.072	1.45	1.80440	39.59	-0.0045	OHARA S-LAH63	10	22.899	0.10
11	7.072	1.45	1.80440	39.59	-0.0045	OHARA S-LAH63	12	11.355	0.70	1.80100	34.97	0.0015	OHARA S-LAM66
13	3.897	2.25	1.48749	70.24	0.0022	OHARA S-FSL5	12	11.355	0.70	1.80100	34.97	0.0015	OHARA S-LAM66
13	3.897	2.25	1.48749	70.24	0.0022	OHARA S-FSL5	14	6.572	0.33
15	11.142	0.60	1.74950	35.28	0.0025	OHARA S-LAM7	14	6.572	0.33
15	11.142	0.60	1.74950	35.28	0.0025	OHARA S-LAM7	16	4.205	2.13	1.49700	81.54	0.0280	OHARA S-FPL51
17 ^*	-100.000	Variable (B)					16	4.205	2.13	1.49700	81.54	0.0280	OHARA S-FPL51

18	12.952	2.50	1.43875	94.94	0.0461	OHARA S-FPL53
18	12.952	2.50	1.43875	94.94	0.0461	OHARA S-FPL53	19 ^*	-153.191	Variable (C)
20	∞	1.24	1.51680	64.20		Various optical filters	19 ^*	-153.191	Variable (C)
20	∞	1.24	1.51680	64.20		Various optical filters	21	∞

(aspheric surface)

" * " number gives aspheric surface.The following example is with top identical.

(the 2nd surface)

K＝0.0，

A ₄＝-1.28414×10 ^-4，A ₆＝-6.57446×10 ^-7，A ₈＝-6.30308×10 ^-9，

A ₁₀＝-1.72874×10 ^-10，A ₁₂＝-2.57252×10 ^-12，A ₁₄＝2.13910×10 ^-14，

A ₁₆＝7.39915×10 ^-16，A ₁₈＝-1.13603×10 ^-17

(the 9th surface)

K＝0.0，

A ₄＝-7.05273×10 ^-5，A ₆＝5.04003×10 ^-7，A ₈＝-6.78678×10 ^-8，

A ₁₀＝1.47308×10 ^-9

(the 17th surface)

K＝0.0，

A ₄＝4.43634×10 ^-5，A ₆＝1.20686×10 ^-5，A ₈＝-4.69301×10 ^-6，

A ₁₀＝1.28473×10 ^-7

(the 19th surface)

K＝0.0，

A ₄＝6.54212×10 ^-5，A ₆＝-8.10291×10 ^-6，A ₈＝1.98320×10 ^-7，

A ₁₀＝-2.19065×10 ^-9

(variable)

	Short burnt end	Middle burnt end	Long burnt end
	Short burnt end	Middle burnt end	Long burnt end	f＝5.20	f＝8.83	f＝15.00
A	21.349	7.868	1.825	f＝5.20	f＝8.83	f＝15.00

B	3.669	7.448	17.837
B	3.669	7.448	17.837	C	4.009	4.883	2.771

(conditional parameter value)

Parameter with above-mentioned data description condition (1) and (2).They are applied to following examples in an identical manner.

dS-A/dS-L＝1.00

fA/f2＝0.555

Hybrid aspherical lens is not used in first embodiment, and therefore, condition (5) and (6) are inapplicable.

(second embodiment)

f＝5.201～14.992，F＝2.61～4.55，ω＝43.30～17.52

Surface number	R	D	N _d	V _d	Δθ _g，F	The glass model name
Surface number	R	D	N _d	V _d	Δθ _g，F	The glass model name	01	24.778	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
02 ^*	9.258	4.13					01	24.778	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
02 ^*	9.258	4.13					03	-135.512	0.90	1.77250	49.60	-0.0092	OHARA S-LAH66
04	11.450	3.68					03	-135.512	0.90	1.77250	49.60	-0.0092	OHARA S-LAH66
04	11.450	3.68					05	20.052	3.62	1.80100	34.97	0.0015	OHARA S-LAM66
06	-31.678	0.80	1.75700	47.82	-0.0076	OHARA S-LAM54	05	20.052	3.62	1.80100	34.97	0.0015	OHARA S-LAM66
06	-31.678	0.80	1.75700	47.82	-0.0076	OHARA S-LAM54	07	575.312	Variable (A)
08	Diaphragm	1.00					07	575.312	Variable (A)
08	Diaphragm	1.00					09 ^*	8.059	1.70	1.77250	49.60	-0.0092	OHARA S-LAH66

10	33.197	0.23
10	33.197	0.23					11	8.347	1.41	1.74320	49.34	-0.0085	OHARA S-LAM60
12	15.124	0.74	1.80100	34.97	0.0015	OHARA S-LAM66	11	8.347	1.41	1.74320	49.34	-0.0085	OHARA S-LAM60
12	15.124	0.74	1.80100	34.97	0.0015	OHARA S-LAM66	13	4.000	1.97	1.48749	70.24	0.0022	OHARA S-FSL5
14	5.836	0.81					13	4.000	1.97	1.48749	70.24	0.0022	OHARA S-FSL5
14	5.836	0.81					15	11.591	0.76	1.69895	30.13	0.0103	OHARA S-TIM35
16	6.099	1.80	1.43875	94.94	0.0461	OHARA S-FPL51	15	11.591	0.76	1.69895	30.13	0.0103	OHARA S-TIM35
16	6.099	1.80	1.43875	94.94	0.0461	OHARA S-FPL51	17	-83.473	0.04	1.52000	52.00		Resin bed
18 ^*	-92.525	Variable (B)					17	-83.473	0.04	1.52000	52.00		Resin bed
18 ^*	-92.525	Variable (B)					19	11.393	2.77	1.43875	94.94	0.0461	OHARA S-FPL53
20 ^*	-173.335	Variable (C)					19	11.393	2.77	1.43875	94.94	0.0461	OHARA S-FPL53
20 ^*	-173.335	Variable (C)					21	∞	1.24	1.51680	64.20		Various optical filters
22	∞						21	∞	1.24	1.51680	64.20		Various optical filters

(aspheric surface)

(the 2nd surface)

K＝0.0，

A ₄＝-1.35880×10 ^-4，A ₆＝-6.92172×10 ^-7，A ₈＝-6.14443×10 ^-9，

A ₁₀＝-1.43503×10 ^-10，

A ₁₂＝-3.48101×10 ^-12，A ₁₄＝2.10140×10 ^-14，A ₁₆＝9.10457×10 ^-16，

A ₁₈＝-1.22550×10 ^-17

(the 9th surface)

K＝0.0，

A ₄＝-1.07511×10 ^-4，A ₆＝-2.17978×10 ^-7，A ₈＝-6.37972×10 ^-8，

A ₁₀＝9.25387×10 ^-10

(the 18th surface)

K＝0.0，

A ₄＝9.82250×10 ^-5，A ₆＝2.14093×10 ^-5，A ₈＝-4.33536×10 ^-6，

A ₁₀＝2.17218×10 ^-7

(the 20th surface)

K＝0.0，

A ₄＝1.17631×10 ^-4，A ₆＝-9.65391×10 ^-6，A ₈＝2.41593×10 ^-7，

A ¹⁰＝-2.63773×10 ^-9

(variable)

	Short burnt end	Middle burnt end	Long burnt end
	Short burnt end	Middle burnt end	Long burnt end		f＝5.20	f＝8.83	f＝14.99
A	21.522	8.000	1.810		f＝5.20	f＝8.83	f＝14.99
A	21.522	8.000	1.810	B	3.665	7.592	17.621
C	3.514	4.348	2.830	B	3.665	7.592	17.621

(conditional parameter value)

dS-A/dS-L＝1.00

fA/f2＝0.884

tR/tA＝0.0217

rB/rA＝0.902

(the 3rd embodiment)

f＝5.204～15.004，F＝2.64～4.66，ω＝43.27～17.52

Surface number

R

D

N _d

V _d

Δθ _g，F

The glass model name

01	25.388	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
01	25.388	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72	02 ^*	9.192	4.03
03	-284.803	0.90	1.77250	49.60	-0.0092	OHARA S-LAH66	02 ^*	9.192	4.03
03	-284.803	0.90	1.77250	49.60	-0.0092	OHARA S-LAH66	04	11.799	4.27
05	20.868	3.43	1.80100	34.97	0.0015	OHARA S-LAM66	04	11.799	4.27
05	20.868	3.43	1.80100	34.97	0.0015	OHARA S-LAM66	06	-34.927	0.80	1.75700	47.82	-0.0076	OHARA S-LAM54
07	206.277	Variable (A)					06	-34.927	0.80	1.75700	47.82	-0.0076	OHARA S-LAM54
07	206.277	Variable (A)					08	Diaphragm	1.00
09 ^*	8.032	1.65	1.79952	42.22	-0.0060	OHARA S-LAH52	08	Diaphragm	1.00
09 ^*	8.032	1.65	1.79952	42.22	-0.0060	OHARA S-LAH52	10	22.923	0.57
11	7.349	1.69	1.78470	26.29	0.0146	OHARA S-TIH23	10	22.923	0.57
11	7.349	1.69	1.78470	26.29	0.0146	OHARA S-TIH23	12	3.790	1.74	1.48749	70.24	0.0022	OHARA S-FSL5
13	6.487	0.44					12	3.790	1.74	1.48749	70.24	0.0022	OHARA S-FSL5
13	6.487	0.44					14	15.189	0.75	1.74950	35.28	0.0025	OHARA S-LAM7
15	6.168	0.16					14	15.189	0.75	1.74950	35.28	0.0025	OHARA S-LAM7
15	6.168	0.16					16 ^*	6.977	0.12	1.52000	52.00		Resin bed
17	6.589	1.50	1.43875	94.94	0.0461	OHARA S-FPL53	16 ^*	6.977	0.12	1.52000	52.00		Resin bed
17	6.589	1.50	1.43875	94.94	0.0461	OHARA S-FPL53	18	-22.660	Variable (B)

19	12.659	2.72	143875	94.94	0.0461	OHARA S-FPL53
19	12.659	2.72	143875	94.94	0.0461	OHARA S-FPL53	20 ^*	-112.732	Variable (C)
21	∞	1.24	1.51680	64.20		Various optical filters	20 ^*	-112.732	Variable (C)
21	∞	1.24	1.51680	64.20		Various optical filters	22	∞

(aspheric surface)

(the 2nd surface)

K＝0.0，

A ₄＝-1.36843×10 ^-4，A ₆＝-6.47708×10 ^-7，A ₈＝-7.35880×10 ^-9，

A ₁₀＝-1.35479×10 ^-10，A ₁₂＝-3.38913×10 ^-12，A ₁₄＝2.21060×10 ^-14，

A ₁₆＝9.07422×10 ^-16，A ₁₈＝-1.29112×10 ^-17

(the 9th surface)

K＝0.0，

A ₄＝-9.88713×10 ^-5，A ₆＝-2.55374×10 ^-7，A ₈＝-7.80472×10 ^-8，

A ₁₀＝1.69652×10 ^-9

(the 16th surface)

K＝0.0，

A ₄＝-4.03962×10 ^-5，A ₆＝5.78224×10 ^-6，A ₈＝1.51452×10 ^-6，

A ₁₀＝-1.25128×10 ^-8

(the 20th surface)

K＝0.0，

A ₄＝3.98967×10 ^-5，A ₆＝-5.16113×10 ^-6，A ₈＝1.10338×10 ^-7，

A ₁₀＝-1.01513×10 ^-9

(variable)

	Short burnt end	Middle burnt end	Long burnt end
	Short burnt end	Middle burnt end	Long burnt end	f＝5.20	f＝8.84	f＝15.00
A	21.350	7.748	1.828	f＝5.20	f＝8.84	f＝15.00

B	4.087	8.347	19.430
B	4.087	8.347	19.430	C	4.321	5.093	2.815

(conditional parameter value)

dS-A/dS-L＝0.832

fA/f2＝0.811

tR/tA＝0.0741

rB/rA＝0.944

(the 4th embodiment)

f＝5.206～15.006，F＝2.58～4.49，ω＝43.27～17.47

Surface number	R	D	N _d	V _d	Δθ _g，F	The glass model name
Surface number	R	D	N _d	V _d	Δθ _g，F	The glass model name	01	24.439	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
02 ^*	9.047	4.04					01	24.439	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
02 ^*	9.047	4.04					03	-208.323	0.90	1.74400	44.79	-0.0035	OHARA S-LAM2
04	12.228	4.35					03	-208.323	0.90	1.74400	44.79	-0.0035	OHARA S-LAM2
04	12.228	4.35					05	22.021	2.42	1.80518	25.42	0.0158	OHARA S-TIH6
06	250.000	Variable (A)					05	22.021	2.42	1.80518	25.42	0.0158	OHARA S-TIH6
06	250.000	Variable (A)					07	Diaphragm	1.00
08 ^*	7.935	1.64	1.79952	42.22	-0.0060	OHARA S-LAH52	07	Diaphragm	1.00
08 ^*	7.935	1.64	1.79952	42.22	-0.0060	OHARA S-LAH52	09	25.546	0.28
10	7.796	1.54	1.80610	40.93	-0.0052	OHARA S-LAH53	09	25.546	0.28

11	-205.340	0.50	1.85000	32.40	0.0039	SUMITA K-LaSFn21
11	-205.340	0.50	1.85000	32.40	0.0039	SUMITA K-LaSFn21	12	4.000	1.95	1.48749	70.24	0.0022	OHARAS- FSL5
13	5.774	0.39					12	4.000	1.95	1.48749	70.24	0.0022	OHARAS- FSL5
13	5.774	0.39					14	10.938	1.17	1.68893	31.07	0.0092	OHARA S-TIM28
15	6.023	1.80	1.43875	94.94	0.0461	OHARA S-FPL53	14	10.938	1.17	1.68893	31.07	0.0092	OHARA S-TIM28
15	6.023	1.80	1.43875	94.94	0.0461	OHARA S-FPL53	16	-56.695	0.08	1.52000	52.00		Resin bed
17 ^*	-59.395	Variable (B)					16	-56.695	0.08	1.52000	52.00		Resin bed
17 ^*	-59.395	Variable (B)					18	11.698	2.64	1.43875	94.94	0.0461	OHARA S-FPL53
19 ^*	-225.859	Variable (C)					18	11.698	2.64	1.43875	94.94	0.0461	OHARA S-FPL53
19 ^*	-225.859	Variable (C)					20	∞	1.24	1.51680	64.20		Various optical filters
21	∞						20	∞	1.24	1.51680	64.20		Various optical filters

(aspheric surface)

(the 2nd surface)

K＝0.0，

A ₄＝-1.30875×10 ^-4，A ₆＝-6.16199×10 ^-7，A ₈＝-9.33434×10 ^-9，

A ₁₀＝-1.13135×10 ^-10，A ₁₂＝-3.64254×10 ^-12，A ₁₄＝2.18018×10 ^-14，

A ₁₆＝9.66843×10 ^-16，A ₁₈＝-1.47933×10 ^-17

(the 8th surface)

K＝0.0，

A ₄＝-9.42018×10 ^-5，A ₆＝1.48563×10 ^-7，A ₈＝-9.08707×10 ^-8，

A ₁₀＝2.14140×10 ^-9

(the 17th surface)

K＝0.0，

A ₄＝1.48391×10 ^-4，A ₆＝2.15451×10 ^-5，A ₈＝-4.41154×10 ^-6，

A ₁₀＝2.28669×10 ^-7

(the 19th surface)

K＝0.0，

A ₄＝1.35253×10 ^-4，A ₆＝-8.89107×10 ^-6，A ₈＝1.65638×10 ^-7，

A ₁₀＝-1.21325×10 ^-9

(variable)

	Short burnt end	Middle burnt end	Long burnt end
	Short burnt end	Middle burnt end	Long burnt end		f＝5.21	f＝8.84	f＝15.01
A	21.161	7.897	1.822		f＝5.21	f＝8.84	f＝15.01
A	21.161	7.897	1.822	B	3.661	7.342	17.177
C	3.498	4.405	2.848	B	3.661	7.342	17.177

(conditional parameter value)

dS-A/dS-L＝1.00

fA/f2＝0.871

tR/tA＝0.0444

rB/rA＝0.955

(the 5th embodiment)

f＝5.200～12.492，F＝2.84～3.96，ω＝43.22～20.63

Surface number	R	D	N _d	V _d	Δθ _g，F	The glass model name
Surface number	R	D	N _d	V _d	Δθ _g，F	The glass model name	01	27.986	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
02 ^*	9.245	2.67					01	27.986	1.60	1.73310	48.89	-0.0093	OHARA L-LAM72
02 ^*	9.245	2.67					03	47.734	0.90	1.77250	49.60	-0.0092	OHARA S-LAH66

04	8.311	3.60
04	8.311	3.60					05	16.509	2.79	1.71736	29.52	0.0110	OHARA S-TIH1
06 ^*	250.000	Variable (A)					05	16.509	2.79	1.71736	29.52	0.0110	OHARA S-TIH1
06 ^*	250.000	Variable (A)					07	Diaphragm	1.00
08 ^*	7.987	1.54	1.79952	42.22	-0.0060	OHARA S-LAH52	07	Diaphragm	1.00
08 ^*	7.987	1.54	1.79952	42.22	-0.0060	OHARA S-LAH52	09	35.368	0.16
10	10.446	1.57	1.77250	49.60	-0.0092	OHARA S-LAH66	09	35.368	0.16
10	10.446	1.57	1.77250	49.60	-0.0092	OHARA S-LAH66	11	-13.557	0.96	1.83400	37.16	-0.0037	OHARA S-LAH60
12	4.260	3.53	1.49700	81.54	0.0280	OHARAS- FSL51	11	-13.557	0.96	1.83400	37.16	-0.0037	OHARA S-LAH60
12	4.260	3.53	1.49700	81.54	0.0280	OHARAS- FSL51	13	7.834	0.59
14	6.809	0.50	1.73400	51.47	-0.0096	OHARA S-LAL59	13	7.834	0.59
14	6.809	0.50	1.73400	51.47	-0.0096	OHARA S-LAL59	15	4.128	3.24	1.43875	94.94	0.0461	OHARA S-FPL53
16	-19.373	0.04	1.52000	52.00		Resin bed	15	4.128	3.24	1.43875	94.94	0.0461	OHARA S-FPL53
16	-19.373	0.04	1.52000	52.00		Resin bed	17 ^*	-19.770	Variable (B)
18	∞	1.24	1.51680	64.20		Various optical filters	17 ^*	-19.770	Variable (B)
18	∞	1.24	1.51680	64.20		Various optical filters	19	∞

(aspheric surface)

(the 2nd surface)

K＝0.0，

A ₄＝-1.23905×10 ^-4，A ₆＝-2.67726×10 ^-6，A ₈＝1.13346×10 ^-8，

A ₁₀＝-7.07042×10 ^-11，A ₁₂＝-4.31642×10 ^-12，A ₁₄＝1.17946×10 ^-14，

A ₁₆＝9.294×10 ^-16，A ₁₈＝-1.19738×10 ^-17

(the 6th surface)

K＝0.0，

A ₄＝-3.05548×10 ^-5，A ₆＝1.71370×10 ^-7，A ₈＝-2.16113×10 ^-8，

A ₁₀＝9.03382×10 ^-11

(the 8th surface)

K＝0.0，

A ₄＝-9.07935×10 ^-5，A ₆＝2.92706×10 ^-7，A ₈＝-1.23507×10 ^-7，

A ¹⁰＝5.11168×10 ^-9

(the 17th surface)

K＝0.0，

A ₄＝2.07163×10 ^-4，A ₆＝4.32738×10 ^-6，A ₈＝-1.9072×10 ^-6，

A ₁₀＝1.13689×10 ^-8

(variable)

	Short burnt end	Middle burnt end	Long burnt end
	Short burnt end	Middle burnt end	Long burnt end		f＝5.20	f＝8.06	f＝12.49
A	21.075	9.408	1.879		f＝5.20	f＝8.06	f＝12.49
A	21.075	9.408	1.879	B	6.431	8.997	12.976

(conditional parameter value)

dS-A/dS-L＝1.00

fA/f2＝0.656

tR/tA＝0.0122

rB/rA＝1.020

Fig. 6-the 8th is about the aberration figure of first embodiment.Fig. 6 is illustrated in the aberration figure of short burnt end (wide-angle side).The aberration figure of burnt end during Fig. 7 is illustrated in, Fig. 8 is illustrated in the aberration figure of long burnt end (taking the photograph far-end).Dotted line in spherical aberration figure is described sine condition.Solid line among the astigmatism figure is described the sagittal image surface, and dotted line is described meridian line image surface.These are applied to the aberration figure of other embodiment in an identical manner.Fig. 9-11 describes the aberration figure of relevant second embodiment.Fig. 9 is illustrated in the aberration figure of short burnt end (wide-angle side).The aberration figure of burnt end during Figure 10 is illustrated in, Figure 11 is illustrated in the aberration figure of long burnt end (taking the photograph far-end).Figure 12-14 describes the aberration figure of relevant the 3rd embodiment.Figure 12 is illustrated in the aberration figure of short burnt end (wide-angle side).The aberration figure of burnt end during Figure 13 is illustrated in, Figure 14 is illustrated in the aberration figure of long burnt end (taking the photograph far-end).Figure 15-17 describes the aberration figure of relevant the 4th embodiment.Figure 15 is illustrated in the aberration figure of short burnt end (wide-angle side).The aberration figure of burnt end during Figure 16 is illustrated in, Figure 17 is illustrated in the aberration figure of long burnt end (taking the photograph far-end).Figure 18-20 describes the aberration figure of relevant the 5th embodiment.Figure 18 is illustrated in the aberration figure of short burnt end (wide-angle side).The aberration figure of burnt end during Figure 19 is illustrated in, Figure 20 is illustrated in the aberration figure of long burnt end (taking the photograph far-end).In each embodiment, aberration is proofreaied and correct fully, and each embodiment can be equivalent to the light receiving element of 8-10 1,000,000 or higher pixel.

According to embodiments of the invention, realize the image pick-up device and the novel personal digital assistant of novel zoom lens, novelty.By the zoom lens according to the embodiment of the invention is provided, as described in embodiment, aberration is corrected, the angle of half field-of view of zoom lens wide-angle side is equal to or greater than 42 degree, also make field angle enough wide, simultaneously, it reaches near 3 times zoom ratio and is equivalent to the 8-10 mega pixel or the resolution of high pixel image processing sensor more.

Although described the present invention according to exemplary embodiment, it is not limited thereto.Should be appreciated that do not break away from the scope of the present invention that following claim limits, those of ordinary skill in the art can make variation to described embodiment.

The application is based on the Japanese patent application No.2006-318743 that submitted on November 27th, 2006 and the Japanese patent application No.2007-109635 that submitted on April 18th, 2007 and the right of priority that requires them, and their full content is incorporated herein by reference in this article.

Claims

1. A zoom lens, comprising:

a first lens group with negative refractive power;

A second lens group having positive refractive power, comprising at least three positive lenses and two negative lenses, wherein at least one of the three positive lenses is an aspheric positive lens; and

a diaphragm provided on the object side of the second lens group, the diaphragm moves integrally with the second lens group,

the first lens group and the second lens group are arranged in order from the object side to the image side, and

When zooming from the wide-angle end to the telephoto end, at least the first lens group and the second lens group move, so that the interval between the first lens group and the second lens group decreases, and the second lens group and the image plane The interval between increases,

Wherein the Abbe number v _d and the abnormal dispersion Δθ _{g, F} of the glass type of at least one aspheric positive lens of the three positive lenses of the second lens group meet the following conditions respectively:

v _d ＞80.0 (1)

_{Δθg, F} >0.025 (2)

where n _g is the refractive index of the g-line, n _F is the refractive index of the F-line, n _c is the refractive index of the c-line, v _d is the Abbe number, Δθ _{g, F} is the anomalous dispersion,

where the relative local dispersion is defined by a condition:

θ _{g, F} = (n _g -n _F )/(n _F -n _c )

Wherein the abnormal dispersion Δθ _{g, F} is defined as the deviation from the reference line of the two-dimensional coordinate plane,

Wherein the two-dimensional coordinate plane is defined by a plane including two vertical axes, the relative local dispersion θ _{g, F} is the vertical axis, and the Abbe number v _d is the horizontal axis,

Wherein the reference line is defined by a straight line connecting the coordinate points of the reference glass type K7 and the coordinate points of the reference glass type F2, wherein the coordinate points of the reference glass type K7 are defined by v _d =60.49, θ _{g, F} =0.5432 defined, and the coordinate point of the reference glass type F2 is defined by v _d =36.26, θ _{g, F} =0.5830.

2. zoom lens as claimed in claim 1, wherein, also comprise:

A third lens group with positive refractive power, the third lens group is arranged on the image side of the second lens group,

Wherein when performing zooming from the wide-angle end to the telephoto end, at least the first lens group and the second lens group move so that the interval between the first lens group and the second lens group decreases, and the second lens group and the second lens group move. The interval between the three lens groups increases.

3. The zoom lens of claim 2, wherein the third lens group comprises a positive lens.

4. zoom lens as claimed in claim 3, wherein, described a piece of positive lens of the 3rd lens group is aspherical positive lens, the Abbe number v _d of the glass type of this aspheric positive lens and abnormal dispersion Δ θ _{g, F} The following conditions are met respectively:

v _d ＞80.0 (1)

Δθg _{, F} > 0.025 (2).

5. The zoom lens as claimed in claim 1, wherein the optical axis distance dS-L from the aperture stop to the surface of the second lens group closest to the image side, and from the stop to the second lens group The optical axis distance dS-A between the aspheric surfaces closest to the image side satisfies the condition:

0.75＜(dS-A)/(dS-L)≤1.0 (3).

6. The zoom lens as claimed in claim 1, wherein the focal length f2 of the second lens group and the focal length fA of the aspheric lens on the image side of the second lens group satisfy the condition:

0.4<fA/f2<1.0 (4).

7. The zoom lens as claimed in claim 1, wherein the aspherical positive lens formed by the glass model satisfying conditions (1) and (2) is a hybrid aspheric lens made of spherical positive lens A thin resin is formed on at least one optical surface, wherein an air-contacting surface of the resin layer is formed in an aspheric shape.

8. The zoom lens according to claim 7, wherein the central thickness tA of the entire hybrid aspheric lens and the central thickness tR of the resin layer satisfy the conditions:

0.01<tR/tA<0.1 (5).

9. The zoom lens as claimed in claim 7, wherein, as the paraxial radius of curvature rA of the aspheric surface of the resin layer air contact surface of the hybrid aspheric lens, and the radius of curvature rB of the spherical surface forming the resin layer satisfy the condition:

0.5<rB/rA<1.4 (6).

10. The zoom lens according to claim 1, wherein the second lens group further includes at least one aspheric lens in addition to the glass-type positive aspheric lens satisfying the conditions (1) and (2).

11. The zoom lens as claimed in claim 10, wherein said at least one aspheric positive lens is arranged at a position closest to the image side in the second lens group, and said at least one aspheric lens is arranged at the second lens group The position closest to the object side in .

12. The zoom lens as claimed in claim 1, wherein said at least one aspherical positive lens is arranged at a position closest to the image side in the second lens group, and is arranged on the object side thereof and adjacent to the negative lens. Lens cemented.

13. The zoom lens of claim 1, wherein, having a resolution equivalent to an image sensor of 8-10 megapixels or more, the half angle of view at the wide-angle end is equal to or greater than 42 degrees.

14. An image pickup device comprising a zoom lens as a photographic zoom lens, the zoom lens comprising:

a first lens group with negative refractive power;

A second lens group having positive refractive power, comprising at least three positive lenses and two negative lenses, wherein at least one of the three positive lenses is an aspherical positive lens; and

When zooming from the wide-angle end to the telephoto end, at least the first lens group and the second lens group move so that the interval between the first lens group and the second lens group decreases, and the second lens group and the image plane The interval between increases,

v _d ＞80.0 (1)

_{Δθg, F} >0.025 (2)

where the relative local dispersion is defined by the following conditions:

θ _{g, F} = (n _g -n _F )/(n _F -n _c )

Wherein the reference line is defined by a straight line connecting the coordinate points of the reference glass type K7 and the coordinate points of the reference glass type F2, wherein the coordinate points of the reference glass type K7 are defined by v _d =60.49, θ _{g, F} =0.5432 , while the coordinate point of the reference glass type F2 is defined by v _d =36.26, θ _{g, F} =0.5830.

15. The image pickup device according to claim 14, wherein a color image sensor is used as the image sensor.

16. The image pickup device according to claim 15, having a resolution equivalent to an image sensor of 8-10 megapixels or higher, and a half angle of view at the wide-angle end is equal to or greater than 42 degrees.

17. A personal digital assistant comprising image pickup means including a zoom lens as a photographic zoom lens, the zoom lens having:

a first lens group with negative refractive power;

v _d ＞80.0 (1)

_{Δθg, F} >0.025 (2)

Wherein the relative local dispersion is defined by the following conditions:

θ _{g, F} = (n _g -n _F )/(n _F -n _c )