TWI509284B - Miniature lens - Google Patents
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本發明係與光學鏡頭有關,更詳而言之是指一種小型化鏡頭。The present invention relates to an optical lens, and more particularly to a miniaturized lens.
近年來,由於行動裝置的蓬勃發展,連帶促進了數位相機模組的市場需求。為了提供行動裝置的方便性與可攜性,市場普遍希望在維持品質的情況下,朝小型化、輕量化發展。In recent years, due to the booming mobile devices, the market demand for digital camera modules has been promoted. In order to provide convenience and portability of mobile devices, the market generally hopes to develop toward miniaturization and light weight while maintaining quality.
目前,一般攝像模組的感光元件,主要可分為感光耦合元件(Charge coupled Device,CCD)與互補性氧化金屬半導體(Complementary Metal Oxide Semiconductor,CMOS),其中因CMOS具備低成本、低耗電性與高整合性,讓CMOS逐漸成為市場上行動裝置感光元件的主流。此外,由於半導體製程技術的進步,使得畫素大小已可大幅降低,此利因可讓感光元件提供更高畫素的影像,但也因縮小畫素面積,使得入光量減少,勢必需要透鏡系統提供更高亮度以降低雜訊影響。At present, the photosensitive elements of the general camera module can be mainly divided into a photosensitive coupled device (CCD) and a complementary metal oxide semiconductor (CMOS), in which CMOS has low cost and low power consumption. With high integration, CMOS has gradually become the mainstream of mobile devices in the market. In addition, due to the advancement of semiconductor process technology, the size of the pixel can be greatly reduced. This factor allows the photosensitive element to provide a higher pixel image, but also reduces the amount of light, so that the amount of light is reduced, and the lens system is inevitable. Provide higher brightness to reduce the effects of noise.
隨著近年來這些影像設備的小型化,上述影像擷取裝置以及應用在上述影像設備上的鏡頭的體積,也被大幅地縮小。另外,由於影像擷取裝置之畫素(pixel)愈來愈高,用以配合這些影像擷取裝置使用的鏡頭,也要能夠具有更高的光學效能,才能使這些影像擷取裝置達成高解析度和高對比之展現。因此,小型化和高光學效能,是影像設備之鏡頭不可缺兩項要件。With the miniaturization of these video devices in recent years, the size of the above-described image capturing device and the lens applied to the above-described image device has also been greatly reduced. In addition, since the pixels of the image capturing device are getting higher and higher, the lens used for the image capturing device can also have higher optical performance, so that the image capturing device can achieve high resolution. Degree and high contrast. Therefore, miniaturization and high optical performance are two essential elements for the lens of imaging equipment.
除此之外,目前影像設備所採用的小型化鏡頭,漸趨往廣角發展,但廣角系統常有畸變及色差問題,而容易影響其影像品質。另外,在降低成本的考量下,市場多以塑膠取代玻璃,但塑膠材質對於溫度變化較為敏感,而使得其成像容易受溫度影響,而有影像品質不穩定之缺點。In addition, the miniaturized lenses used in video equipment are gradually developing towards wide angles, but wide-angle systems often have distortion and chromatic aberration problems, which easily affect their image quality. In addition, under the consideration of cost reduction, the market mostly replaces glass with plastic, but the plastic material is sensitive to temperature changes, which makes its imaging easy to be affected by temperature, and has the disadvantage of unstable image quality.
有鑑於此,本發明之主要目的在於提供一種小型化鏡頭,是由五片透鏡所組成,除可提供小型化與高光量的需求外,亦能有效地改善對廣角系統常有的畸變與色差問題,且在低成本考量下,同時也能降低其溫度之敏感度。In view of this, the main object of the present invention is to provide a miniaturized lens which is composed of five lenses. In addition to providing miniaturization and high light quantity, it can also effectively improve the distortion and chromatic aberration often observed in wide-angle systems. The problem, and at a low cost, can also reduce the sensitivity of its temperature.
緣以達成上述目的,本發明所提供小型化鏡頭包含有由一物側至一成像面且沿一光軸依序排列之一第一鏡片、一第二鏡片、一光圈、一第三鏡片、一第四鏡片以及一第五鏡片。其中,該第一鏡片為具有負屈光力之凸凹透鏡者,且其凸面朝向該物側,而凹面朝向該成像面,且其兩面皆為非球面表面;該第二鏡片具有正屈光力且朝向該物側之表面為凸面,且其兩面皆為非球面表面;該第三鏡片為具有正屈光力之雙凸透鏡者;該第四鏡片為具有正屈光力之雙凸透鏡者;該第五鏡片為具有負屈光力,且朝向該物側之表面為凹面者。In order to achieve the above object, the miniaturized lens provided by the present invention comprises a first lens, a second lens, an aperture, and a third lens arranged from an object side to an imaging surface and sequentially along an optical axis. A fourth lens and a fifth lens. Wherein, the first lens is a convex-concave lens having a negative refractive power, and the convex surface faces the object side, and the concave surface faces the imaging surface, and both sides thereof are aspherical surfaces; the second lens has a positive refractive power and faces the object The surface of the side is convex, and both sides thereof are aspherical surfaces; the third lens is a lenticular lens having positive refractive power; the fourth lens is a lenticular lens having positive refractive power; and the fifth lens has negative refractive power, And the surface facing the object side is concave.
緣以達成上述目的,本發明另提供一小型化鏡頭包含有由一物側至一成像面且沿一光軸依序排列之一第一鏡片、一第二鏡片、一光圈、一第三鏡片、一第四鏡片以及一第五鏡片。其 中,該第一鏡片為具有負屈光力之凸凹透鏡者,且其凸面朝向該物側,而凹面朝向該成像面,且其兩面皆為非球面表面;該第二鏡片朝向該物側之表面為凸面,且其兩面皆為非球面表面;該第三鏡片為具有正屈光力之雙凸透鏡者;該第四鏡片為具有正屈光力之雙凸透鏡者;該第五鏡片為具有負屈光力,且朝向該物側之表面為凹面者;其中,該小型化鏡頭更滿足下列條件:-0.09<f/f2 <0.16;其中,f為該小型化鏡頭之系統焦距,f2 為該第二鏡片之焦距。In order to achieve the above object, the present invention further provides a miniaturized lens comprising a first lens, a second lens, an aperture, and a third lens arranged from an object side to an imaging surface and sequentially along an optical axis. a fourth lens and a fifth lens. Wherein, the first lens is a convex-concave lens having a negative refractive power, and the convex surface faces the object side, and the concave surface faces the imaging surface, and both sides thereof are aspherical surfaces; the surface of the second lens facing the object side is a convex surface, and both surfaces thereof are aspherical surfaces; the third lens is a lenticular lens having a positive refractive power; the fourth lens is a lenticular lens having a positive refractive power; the fifth lens has a negative refractive power and faces the object The surface of the side is concave; wherein the miniaturized lens more satisfies the following condition: -0.09 < f / f 2 <0.16; wherein f is the focal length of the system of the miniaturized lens, and f 2 is the focal length of the second lens.
緣以達成上述目的,本發明另提供一小型化鏡頭包含有由一物側至一成像面且沿一光軸依序排列之一第一鏡片、一第二鏡片、一光圈、一第三鏡片、一第四鏡片以及一第五鏡片。其中,該第一鏡片為具有負屈光力之凸凹透鏡者,且其凸面朝向該物側,而凹面朝向該成像面,且其兩面皆為非球面表面;該第二鏡片朝向該物側之表面為凸面,且其兩面皆為非球面表面;該第三鏡片為具有正屈光力之雙凸透鏡者;該第四鏡片為具有正屈光力之雙凸透鏡者;該第五鏡片為具有負屈光力,且朝向該物側之表面為凹面者;其中,該第三鏡片、第四鏡片及第五鏡片至少其中一者為兩面皆為非球面表面的透鏡。In order to achieve the above object, the present invention further provides a miniaturized lens comprising a first lens, a second lens, an aperture, and a third lens arranged from an object side to an imaging surface and sequentially along an optical axis. a fourth lens and a fifth lens. Wherein, the first lens is a convex-concave lens having a negative refractive power, and the convex surface faces the object side, and the concave surface faces the imaging surface, and both sides thereof are aspherical surfaces; the surface of the second lens facing the object side is a convex surface, and both surfaces thereof are aspherical surfaces; the third lens is a lenticular lens having a positive refractive power; the fourth lens is a lenticular lens having a positive refractive power; the fifth lens has a negative refractive power and faces the object The surface of the side is a concave surface; wherein at least one of the third lens, the fourth lens and the fifth lens is a lens having an aspherical surface on both sides.
藉此,透過上述之光學設計,便可使得該小型化鏡頭具有體積小、有廣角、光學畸變小以及高光學效能之效果。Thereby, through the above optical design, the miniaturized lens can have the effects of small size, wide angle, small optical distortion and high optical performance.
為能更清楚地說明本發明,茲舉較佳實施例並配合圖示詳細說明如後。In order that the present invention may be more clearly described, the preferred embodiments are illustrated in the accompanying drawings.
請參閱圖1,本發明第一較佳實施例之小型化鏡頭1包含有沿一光軸Z且由一物側至一成像面Im依序排列之一第一鏡片L1、一第二鏡片L2、一光圈ST、一第三鏡片L3、一第四鏡片L4以及一第五鏡片L5。另外,依使用上之需求,該第五鏡片L5與該成像面Im之間更可設置有一濾光片(Color Filter)CF,以濾除掉不必要之雜訊光,而可達到提升光學效能之目的。其中:Referring to FIG. 1 , a miniaturized lens 1 according to a first preferred embodiment of the present invention includes a first lens L1 and a second lens L2 arranged along an optical axis Z and sequentially from an object side to an imaging surface Im. An aperture ST, a third lens L3, a fourth lens L4, and a fifth lens L5. In addition, depending on the requirements of use, a color filter CF may be disposed between the fifth lens L5 and the imaging surface Im to filter out unnecessary noise light, thereby improving optical performance. The purpose. among them:
該第一鏡片L1為具有負屈光力且以塑膠材料製成之凸凹透鏡,且其凸面S1朝向該物側,而凹面S2朝向該成像面Im,藉以使該小型化鏡頭1具有廣角之光學特性。另外,該第一鏡片L1之兩面S1、S2皆為非球面表面,而非球面之設計目的,在於可有效地修正該小型化鏡頭1於廣角光學設計時容易出現的畸變問題。The first lens L1 is a convex-concave lens having a negative refractive power and made of a plastic material, and has a convex surface S1 facing the object side, and a concave surface S2 facing the imaging surface Im, whereby the miniaturized lens 1 has a wide-angle optical characteristic. In addition, both sides S1 and S2 of the first lens L1 are aspherical surfaces, and the non-spherical surface is designed to effectively correct the distortion problem that the miniaturized lens 1 is prone to in wide-angle optical design.
該第二鏡片L2為具有正屈光力且以塑膠材料製成之凸凹透鏡,且其凸面S3朝向該物側,而凹面S4朝向該成像面,且其兩面S3、S4皆為非球面表面。上述該第二鏡片L2之結構設計的目的,在於輔助該第一鏡片L1修正該小型化鏡頭1之畸變問題,且同時亦可修正該第一鏡片L1產生之像差。The second lens L2 is a convex-concave lens having a positive refractive power and made of a plastic material, and the convex surface S3 faces the object side, and the concave surface S4 faces the imaging surface, and both surfaces S3 and S4 thereof are aspherical surfaces. The purpose of the structural design of the second lens L2 is to assist the first lens L1 in correcting the distortion problem of the miniaturized lens 1, and at the same time, correct the aberration generated by the first lens L1.
該光圈ST設於該第二鏡片L2與該第三鏡片L3之間的目的在於可有效地減少光線進入該小型化鏡頭1後,投射於該成 像面Im上之角度,而可有效地提升該成像面Im之入光量,藉以縮短該成像面Im與該等鏡片L1~L5之間的距離,進而有效地達到小型化之目的。另外,除上述目的外,該光圈ST設於該第二鏡片L2與該第三鏡片L3之間,亦可使該小型化鏡頭1於該光圈ST前後之鏡片排列呈現較為對稱之設計,而可降低製造時的敏感度。The purpose of the aperture ST between the second lens L2 and the third lens L3 is to effectively reduce the light entering the miniaturized lens 1 and projecting on the lens The angle of the image surface Im can effectively increase the amount of light entering the imaging surface Im, thereby shortening the distance between the imaging surface Im and the lenses L1 to L5, thereby effectively achieving the purpose of miniaturization. In addition, in addition to the above purpose, the aperture ST is disposed between the second lens L2 and the third lens L3, and the lens arrangement of the miniaturized lens 1 before and after the aperture ST can be symmetrically designed. Reduce sensitivity during manufacturing.
該第三鏡片L3為具有正屈光力且以塑膠材料製成之雙凸透鏡,且其兩面S6、S7皆為非球面表面。上述該第三鏡片L3之結構設計的目的,在於提供該小型化鏡頭1的整個光學系統主要的屈光力。The third lens L3 is a lenticular lens having a positive refractive power and made of a plastic material, and both sides S6 and S7 are aspherical surfaces. The purpose of the structural design of the third lens L3 described above is to provide the main refractive power of the entire optical system of the miniaturized lens 1.
該第四鏡片L4為具有正屈光力且以玻璃材料製成之雙凸透鏡,且其兩面S8、S9皆為球面表面。上述該第四鏡片L4之結構設計的目的,在於利用其正屈光力之光學特性與其它鏡片L1~L3、L5搭配,而可有效地縮短該小型化鏡頭1之系統總長,進而達到小型化之目的。The fourth lens L4 is a lenticular lens having a positive refractive power and made of a glass material, and both sides S8 and S9 are spherical surfaces. The purpose of the structural design of the fourth lens L4 is to use the optical characteristics of the positive refractive power to match the other lenses L1 to L3 and L5, thereby effectively shortening the total length of the system of the miniaturized lens 1, thereby achieving miniaturization. .
該第五鏡片L5為具有負屈光力且以玻璃材料製成之雙凹透鏡,且其兩面S10、S11皆為球面表面。另外,該第五鏡片L5朝向該物側之表面S10與該第四鏡片L4朝向該成像面Im之表面S9膠黏,而呈無間隙之設計。上述該第五鏡片L5之結構設計的目的,在於利用其負屈光力之光學特性與該第四鏡片L4之正屈光力的光學特性搭配,而可有效地修正該小型化鏡頭1可能出現的色差問題,進而提升該小型化鏡頭1之光學 效能。The fifth lens L5 is a biconcave lens having a negative refractive power and made of a glass material, and both sides S10 and S11 are spherical surfaces. In addition, the fifth lens L5 is adhered to the surface S10 of the object side and the surface S9 of the fourth lens L4 facing the imaging surface Im, and has a gap-free design. The purpose of the structural design of the fifth lens L5 is to align the optical characteristics of the negative refractive power with the optical characteristics of the positive refractive power of the fourth lens L4, thereby effectively correcting the chromatic aberration problem that may occur in the miniaturized lens 1. Further enhancing the optics of the miniaturized lens 1 efficacy.
另外,除上述該等鏡片L1~L5之結構設計外,該小型化鏡頭1更滿足有下列條件:1.)0.1<f/TTL<0.2;2.)0.5<f/f3 <2;3.)vd4 -vd5 >20;其中,f為該小型化鏡頭1之系統焦距;TTL為該小型化鏡頭1之系統總長;f3 為該第三鏡片L3之焦距;vd4 為該第四鏡片L4之色散係數;vd5 為該第五鏡片L5之色散係數。In addition, in addition to the structural design of the lenses L1 to L5 described above, the miniaturized lens 1 satisfies the following conditions: 1.) 0.1 < f / TTL <0.2; 2.) 0.5 < f / f 3 <2; .) vd 4 -vd 5 >20; wherein f is the focal length of the system of the miniaturized lens 1; TTL is the total length of the system of the miniaturized lens 1; f 3 is the focal length of the third lens L3; vd 4 is the first The dispersion coefficient of the four lenses L4; vd 5 is the dispersion coefficient of the fifth lens L5.
藉此,透過上述第1項之設計,而可使得該小型化鏡頭1能具有廣角且短系統總長之優點。第2項之設計在於透過該第三鏡片L3控制該小型化鏡頭1的整個光學系統主要的屈光力。而第3項之設計在於透過該第四鏡片L4與該第五鏡片L5之色散係數的搭配,而可有效地消除該小型化鏡頭1之像差,進而提升該小型化鏡頭1之成像品質。Thereby, the miniaturized lens 1 can have the advantages of a wide angle and a short total system length by the design of the first item described above. The second item is designed to control the main refractive power of the entire optical system of the miniaturized lens 1 through the third lens L3. The third item is designed to effectively eliminate the aberration of the miniaturized lens 1 by the combination of the fourth lens L4 and the dispersion coefficient of the fifth lens L5, thereby improving the imaging quality of the miniaturized lens 1.
為達上述目的並有效提升該小型化鏡頭1之光學效能,本發明第一較佳實施例之小型化鏡頭1的系統焦距f、系統總長TTL、各個鏡片表面的光軸Z通過處的曲率半徑R、各鏡面與下一鏡面(或成像面Im)於光軸Z上之距離D、各鏡片之折射率Nd、各鏡片之阿貝係數Vd、與各鏡片之焦距f1
~f5
,如表一所示:表一
本實施例的各個透鏡中,該等非球面表面S1、S2、S3、S4、S6、及S7之表面凹陷度z由下列公式所得到:
其中,z:非球面表面之凹陷度;c:曲率半徑之倒數;h:表面之孔徑半徑;k:圓錐係數;α2 ~α8 :表面之孔徑半徑h的各階係數。Where z: the degree of depression of the aspheric surface; c: the reciprocal of the radius of curvature; h: the aperture radius of the surface; k: the conic coefficient; α 2 ~ α 8 : the order factor of the aperture radius h of the surface.
在本實施例中,各個非球面表面的非球面係數k及各階係數α2
~α8
,如表二所示:
藉由上述的鏡片L1~L5及光圈ST配置,使得本實施例之小型化鏡頭1在成像品質上也可達到要求,這可從圖2A至圖2C看出,其中,由圖2A可看出,本實施例之小型化鏡頭1於0℃時的最大場曲不超過-0.16mm及0.02mm,於25℃時的最大場曲不超過-0.12mm及0.06mm,於50℃時的最大場曲不超過-0.06mm及0.16mm;由圖2B可看出,本實施例之小型化鏡頭1的最大畸變量不超過-6%及3%;由圖2C可看出,本實施例之小型化鏡頭1的橫向色差不超過9μm,顯見本實施例之小型化鏡頭1的光學效能是符合標準的。The lens L1 to L5 and the aperture ST are arranged in the above manner, so that the miniaturized lens 1 of the present embodiment can also meet the requirements in image quality, which can be seen from FIG. 2A to FIG. 2C, wherein it can be seen from FIG. 2A. The maximum field curvature of the miniaturized lens 1 of the present embodiment at 0 ° C does not exceed -0.16 mm and 0.02 mm, and the maximum field curvature at 25 ° C does not exceed -0.12 mm and 0.06 mm, and the maximum field at 50 ° C The curvature does not exceed -0.06 mm and 0.16 mm; as can be seen from Fig. 2B, the maximum distortion of the miniaturized lens 1 of the present embodiment does not exceed -6% and 3%; as can be seen from Fig. 2C, the small size of this embodiment The lateral chromatic aberration of the lens 1 is not more than 9 μm, and it is apparent that the optical performance of the miniaturized lens 1 of the present embodiment is in compliance with the standard.
以上所述的,為本發明第一實施例的小型化鏡頭1;依據本發明的技術,以下配合圖3說明本發明第二實施例之小型化鏡頭2。The above-described miniaturized lens 1 according to the first embodiment of the present invention; in accordance with the technology of the present invention, the miniaturized lens 2 of the second embodiment of the present invention will be described below with reference to FIG.
本發明第二較佳實施例之小型化鏡頭2同樣包含有沿一光軸Z且由一物側至一成像面Im依序排列之一第一鏡片L1、一第二鏡片L2、一光圈ST、一第三鏡片L3、一第四鏡片L4、 一第五鏡片L5以及一濾光片CF。其中:The miniaturized lens 2 of the second preferred embodiment of the present invention also includes a first lens L1, a second lens L2, and an aperture ST along an optical axis Z and sequentially arranged from an object side to an imaging surface Im. a third lens L3, a fourth lens L4, A fifth lens L5 and a filter CF. among them:
該第一鏡片L1為具有負屈光力且以塑膠材料製成之凸凹透鏡,且其凸面S1朝向該物側,而凹面S2朝向該成像面Im,且兩面S1、S2皆為非球面表面,藉以使該小型化鏡頭2具有廣角之光學特性,且非球面之設計更可有效地修正該小型化鏡頭2於廣角光學設計時容易出現的畸變問題。The first lens L1 is a convex-concave lens having a negative refractive power and made of a plastic material, and the convex surface S1 faces the object side, and the concave surface S2 faces the imaging surface Im, and both surfaces S1 and S2 are aspherical surfaces, thereby making The miniaturized lens 2 has a wide-angle optical characteristic, and the aspherical design can more effectively correct the distortion problem that the miniaturized lens 2 is prone to in wide-angle optical design.
該第二鏡片L2為具有正屈光力且以塑膠材料製成之凸凹透鏡,且其凸面S3朝向該物側,而凹面S4朝向該成像面Im,且其兩面S3、S4皆為非球面表面。該第二鏡片L2用以輔助該第一鏡片L1修正該小型化鏡頭2之畸變問題,且同時修正該第一鏡片L1產生之像差。The second lens L2 is a convex-concave lens having a positive refractive power and made of a plastic material, and the convex surface S3 faces the object side, and the concave surface S4 faces the imaging surface Im, and both surfaces S3 and S4 thereof are aspherical surfaces. The second lens L2 is used to assist the first lens L1 in correcting the distortion problem of the miniaturized lens 2, and at the same time correcting the aberration generated by the first lens L1.
該光圈ST設於該第二鏡片L2與該第三鏡片L3之間的目的與前一實施例相通,在於可有效地減少光線進投射於該成像面Im上之角度,並可使該小型化鏡頭2於該光圈ST前後之鏡片設計呈現較為對稱之設計,而可有效地提升該成像面Im之入光量、縮短該成像面Im與該等鏡片L1~L5之間的距離、以及降低製造時的敏感度。The purpose of the aperture ST being disposed between the second lens L2 and the third lens L3 is the same as that of the previous embodiment, in that the angle of light incident on the imaging surface Im can be effectively reduced, and the miniaturization can be achieved. The lens 2 has a relatively symmetrical design on the lens before and after the aperture ST, and can effectively increase the amount of light entering the imaging surface Im, shorten the distance between the imaging surface Im and the lenses L1 to L5, and reduce manufacturing time. Sensitivity.
該第三鏡片L3為具有正屈光力且以塑膠材料製成之雙凸透鏡,且其兩面S6、S7皆為非球面表面,用以提供該小型化鏡頭2的整個光學系統主要的屈光力。The third lens L3 is a lenticular lens having a positive refractive power and made of a plastic material, and both sides S6 and S7 are aspherical surfaces for providing the main refractive power of the entire optical system of the miniaturized lens 2.
該第四鏡片L4為具有正屈光力且以塑膠材料製成之雙凸透鏡,且其兩面S8、S9皆為非球面表面,用以利用其正屈光 力之光學特性與其它鏡片L1~L3、L5搭配,而可有效地縮短該小型化鏡頭2之系統總長,進而達到小型化之目的。The fourth lens L4 is a lenticular lens having a positive refractive power and made of a plastic material, and both sides S8 and S9 are aspherical surfaces for utilizing the positive refractive power thereof. The optical characteristics of the force are matched with the other lenses L1 to L3 and L5, and the total length of the system of the miniaturized lens 2 can be effectively shortened, thereby achieving the purpose of miniaturization.
該第五鏡片L5為具有負屈光力且以塑膠材料製成之凸凹透鏡,且其凹面S10朝向該物側,而凸面S11朝向該成像面Im,兩面S10、S11皆為非球面表面,用以利用其負屈光力之光學特性與該第四鏡片L4之正屈光力的光學特性搭配,有效地修正該小型化鏡頭2可能出現的色差問題,進而提升該小型化鏡頭2之光學效能。The fifth lens L5 is a convex-concave lens having a negative refractive power and made of a plastic material, and the concave surface S10 faces the object side, and the convex surface S11 faces the imaging surface Im, and both surfaces S10 and S11 are aspherical surfaces for utilizing The optical characteristic of the negative refractive power is matched with the optical characteristic of the positive refractive power of the fourth lens L4, thereby effectively correcting the chromatic aberration problem that may occur in the miniaturized lens 2, thereby improving the optical performance of the miniaturized lens 2.
另外,除上述該等鏡片L1~L5之結構設計外,第二實施例之該小型化鏡頭2同樣滿足有下列條件,而可使得該小型化鏡頭2能具有廣角、短系統總長、可有效地控制整個光學系統主要的屈光力、以及有效地消除該小型化鏡頭2之像差的效果:1.)0.1<f/TTL<0.2;2.)0.5<f/f3 <2;3.)vd4 -vd5 >20;其中,f為該小型化鏡頭2之系統焦距;TTL為該小型化鏡頭2之系統總長;f3 為該第三鏡片L3之焦距;vd4 為該第四鏡片L4之色散係數;vd5 為該第五鏡片L5之色散係數。In addition, in addition to the structural design of the lenses L1 to L5 described above, the miniaturized lens 2 of the second embodiment also satisfies the following conditions, so that the miniaturized lens 2 can have a wide angle, a short total system length, and can effectively Controls the main refractive power of the entire optical system and effectively eliminates the aberration of the miniaturized lens 2: 1.) 0.1 < f / TTL <0.2; 2.) 0.5 < f / f 3 <2; 3.) vd 4 - vd 5 >20; wherein f is the focal length of the system of the miniaturized lens 2; TTL is the total length of the system of the miniaturized lens 2; f 3 is the focal length of the third lens L3; vd 4 is the fourth lens L4 The dispersion coefficient; vd 5 is the dispersion coefficient of the fifth lens L5.
為達上述目的並有效提升該小型化鏡頭之光學效能,本發明第二較佳實施例之小型化鏡頭2的系統焦距f、系統總長TTL、各個鏡片表面的光軸Z通過處的曲率半徑R、各鏡面與下一鏡面(或成像面Im)於光軸Z上之距離D、各鏡片之折射率
Nd、各鏡片之阿貝係數Vd、與各鏡片之焦距f1
~f5
,如表三所示:
本實施例的各個透鏡中,該等非球面表面S1、S2、S3、S4、S6、S7、S8、S9、S10及S11之表面凹陷度z由下列公式所得到:
其中,z:非球面表面之凹陷度;c:曲率半徑之倒數;h:表面之孔徑半徑; k:圓錐係數;α2 ~α8 :表面之孔徑半徑h的各階係數。Where z: the degree of depression of the aspheric surface; c: the reciprocal of the radius of curvature; h: the aperture radius of the surface; k: the conic coefficient; α 2 ~ α 8 : the order factor of the aperture radius h of the surface.
在本實施例中,各個非球面表面的非球面係數k及各階係數α2
~α8
,如表四所示:
藉由上述的鏡片L1~L5及光圈ST配置,使得本實施例之小型化鏡頭2在成像品質上也可達到要求,這可從圖4A至圖4C看出,其中,由圖4A可看出,本實施例之小型化鏡頭2於0℃時的最大場曲不超過-0.18mm及0.02mm,於25℃時的最大場曲不超過-0.14mm及0.04mm,於50℃時的最大場曲不超過-0.10mm及0.08mm;由圖4B可看出,本實施例之小型化鏡頭2的最大畸變量不超過-8%及3%;由圖4C可看出,本實施例之小型化鏡頭2的橫向色差不超過7.5μm,顯見本實施例之小型化鏡頭2的光學效能是符合標準的。The lens L1 to L5 and the aperture ST are arranged in the above manner, so that the miniaturized lens 2 of the present embodiment can also meet the requirements in image quality, which can be seen from FIG. 4A to FIG. 4C, wherein it can be seen from FIG. 4A. The maximum field curvature of the miniaturized lens 2 of the present embodiment at 0 ° C does not exceed -0.18 mm and 0.02 mm, and the maximum field curvature at 25 ° C does not exceed -0.14 mm and 0.04 mm, and the maximum field at 50 ° C The curvature does not exceed -0.10 mm and 0.08 mm; as can be seen from Fig. 4B, the maximum distortion of the miniaturized lens 2 of the present embodiment does not exceed -8% and 3%; as can be seen from Fig. 4C, the small size of this embodiment The lateral chromatic aberration of the lens 2 is not more than 7.5 μm, and it is apparent that the optical performance of the miniaturized lens 2 of the present embodiment is in compliance with the standard.
另外,除上述第一實施例與第二實施例的小型化鏡頭1、2外,請參閱圖5,本發明第三較佳實施例之小型化鏡頭3同樣包含有沿一光軸Z且由一物側至一成像面Im依序排列之一第一鏡片L1、一第二鏡片L2、一光圈ST、一第三鏡片L3、一第四鏡片L4、一第五鏡片L5以及一濾光片CF。其中:In addition, in addition to the miniaturized lenses 1 and 2 of the first embodiment and the second embodiment, referring to FIG. 5, the miniaturized lens 3 of the third preferred embodiment of the present invention also includes an optical axis Z along and The first lens L1, the second lens L2, the second aperture L1, the third lens L3, the fourth lens L4, the fifth lens L5, and a filter are sequentially arranged from the object side to the image forming surface Im. CF. among them:
該第一鏡片L1為具有負屈光力且以塑膠材料製成之凸凹透鏡,且其凸面S1朝向該物側,而凹面S2朝向該成像面Im,且兩面S1、S2皆為非球面表面,藉以使該小型化鏡頭3具有廣角之光學特性,且非球面之設計更可有效地修正該小型化鏡頭3於廣角光學設計時容易出現的畸變問題。The first lens L1 is a convex-concave lens having a negative refractive power and made of a plastic material, and the convex surface S1 faces the object side, and the concave surface S2 faces the imaging surface Im, and both surfaces S1 and S2 are aspherical surfaces, thereby making The miniaturized lens 3 has wide-angle optical characteristics, and the aspherical design can more effectively correct the distortion problem that the miniaturized lens 3 is prone to in wide-angle optical design.
該第二鏡片L2為具有負屈光力且以塑膠材料製成之凸凹透鏡,且其凸面S3朝向該物側,而凹面S4朝向該成像面Im,且其兩面S3、S4皆為非球面表面。該第二鏡片L2用以輔助該第一鏡片L1修正該小型化鏡頭3之畸變問題,且同時修正該第一鏡片L1產生之像差。The second lens L2 is a convex-concave lens having a negative refractive power and made of a plastic material, and the convex surface S3 faces the object side, and the concave surface S4 faces the imaging surface Im, and both surfaces S3 and S4 thereof are aspherical surfaces. The second lens L2 is used to assist the first lens L1 in correcting the distortion problem of the miniaturized lens 3, and at the same time correcting the aberration generated by the first lens L1.
該光圈ST設於該第二鏡片L2與該第三鏡片L3之間的目的同樣是在於可有效地減少光線投射於該成像面Im上之角度,並可使該小型化鏡頭3於該光圈ST前後之鏡片設計呈現較為對稱之設計,而可有效地提升該成像面Im之入光量、縮短該成像面Im與該等鏡片L1~L5之間的距離、以及降低製造時的敏感度。The purpose of the aperture ST being disposed between the second lens L2 and the third lens L3 is to effectively reduce the angle at which light is projected onto the imaging surface Im, and to enable the miniaturized lens 3 to be in the aperture ST. The front and rear lens designs exhibit a relatively symmetrical design, and can effectively increase the amount of light entering the imaging surface Im, shorten the distance between the imaging surface Im and the lenses L1 to L5, and reduce the sensitivity during manufacturing.
該第三鏡片L3為具有正屈光力且以玻璃材料製成之雙凸 透鏡,且其兩面S6、S7皆為球面表面,用以提供該小型化鏡頭3的整個光學系統主要的屈光力,且透過使用玻璃材料的設計,更可有效地控制該小型化鏡頭3對溫度之敏感度。The third lens L3 is a double convex having a positive refractive power and made of a glass material. The lens, and both sides S6 and S7 are spherical surfaces for providing the main refractive power of the entire optical system of the miniaturized lens 3, and the design of the glass material can more effectively control the temperature of the miniaturized lens 3 Sensitivity.
該第四鏡片L4為具有正屈光力且以塑膠材料製成之雙凸透鏡,且其兩面S8、S9皆為非球面表面,用以利用其正屈光力之光學特性與其它鏡片L1~L3、L5搭配,而可有效地縮短該小型化鏡頭3之系統總長,進而達到小型化之目的。The fourth lens L4 is a lenticular lens having a positive refractive power and made of a plastic material, and both sides S8 and S9 are aspherical surfaces for aligning with other lenses L1~L3 and L5 by utilizing the optical characteristics of the positive refractive power. The system length of the miniaturized lens 3 can be effectively shortened, thereby achieving miniaturization.
該第五鏡片L5為具有負屈光力且以塑膠材料製成之雙凹透鏡,且兩面S10、S11皆為非球面表面,用以利用其負屈光力之光學特性與該第四鏡片L4之正屈光力的光學特性搭配修正該小型化鏡頭3可能出現的色差問題。The fifth lens L5 is a biconcave lens having a negative refractive power and made of a plastic material, and both sides S10 and S11 are aspherical surfaces for utilizing the optical properties of the negative refractive power and the optical power of the positive refractive power of the fourth lens L4. The characteristic match corrects the chromatic aberration problem that may occur in the miniaturized lens 3.
另外,除上述該等鏡片L1~L5之結構設計外,第三實施例之該小型化鏡頭3同樣滿足有下列條件,而可使得該小型化鏡頭能具有廣角、短系統總長、可有效地控制整個光學系統主要的屈光力、以及有效地消除該小型化鏡頭3之像差的效果:1.)0.1<f/TTL<0.2;2.)0.5<f/f3 <2;3.)vd4 -vd5 >20;其中,f為該小型化鏡頭3之系統焦距;TTL為該小型化鏡頭3之系統總長;f3 為該第三鏡片L3之焦距;vd4 為該第四鏡片L4之色散係數;vd5 為該第五鏡片L5之色散係數。In addition, in addition to the structural design of the lenses L1 to L5 described above, the miniaturized lens 3 of the third embodiment also satisfies the following conditions, so that the miniaturized lens can have a wide angle, a short total system length, and can be effectively controlled. The main refractive power of the entire optical system and the effect of effectively eliminating the aberration of the miniaturized lens 3: 1.) 0.1 < f / TTL <0.2; 2.) 0.5 < f / f 3 <2; 3.) vd 4 -vd 5> 20; wherein, f the focal length of the lens system for the miniaturization of 3; the TTL for miniaturization of the lens system 3 of the total length; F for 3 a focal length of the third lens L3; vd 4 for the fourth lens L4 The dispersion coefficient; vd 5 is the dispersion coefficient of the fifth lens L5.
為達上述目的並有效提升該小型化鏡頭3之光學效能,本
發明第三較佳實施例之小型化鏡頭3的系統焦距f、系統總長TTL、各個鏡片表面的光軸Z通過處的曲率半徑R、各鏡面與下一鏡面(或成像面Im)於光軸Z上之距離D、各鏡片之折射率Nd、各鏡片之阿貝係數Vd、與各鏡片之焦距f1
~f5
,如表三所示:
本實施例的各個透鏡中,該等非球面表面S1、S2、S3、S4、S8、S9、S10及S11之表面凹陷度z由下列公式所得到:
其中,z:非球面表面之凹陷度; c:曲率半徑之倒數;h:表面之孔徑半徑;k:圓錐係數;α2 ~α8 :表面之孔徑半徑h的各階係數。Where z: the degree of depression of the aspheric surface; c: the reciprocal of the radius of curvature; h: the aperture radius of the surface; k: the conic coefficient; α 2 ~ α 8 : the order factor of the aperture radius h of the surface.
在本實施例中,各個非球面表面的非球面係數k及各階係數α2
~α8
,如表六所示:
藉由上述的鏡片L1~L5及光圈ST配置,使得本實施例之小型化鏡頭3在成像品質上也可達到要求,這可從圖6A至圖6C看出,其中,由圖6A可看出,本實施例之小型化鏡頭3於0℃時的最大場曲不超過-0.08mm及0.02mm,於25℃時的最大場曲不超過-0.10mm及0.02mm,於50℃時的最大場曲不超過-0.10mm及0.02mm;由圖6B可看出,本實施例之小型化鏡頭3的最大畸變量不超過-2%及1%;由圖6C可看出,本實施例之小型化鏡頭3的橫向色差不超過-1.5μm及4.5μm,顯見本實施例之小型化鏡頭3的光學效能是符合標準的。The lens L1 to L5 and the aperture ST are arranged in the above manner, so that the miniaturized lens 3 of the present embodiment can also meet the requirements in image quality, which can be seen from FIG. 6A to FIG. 6C, wherein it can be seen from FIG. 6A. The maximum field curvature of the miniaturized lens 3 of the present embodiment at 0 ° C does not exceed -0.08 mm and 0.02 mm, and the maximum field curvature at 25 ° C does not exceed -0.10 mm and 0.02 mm, and the maximum field at 50 ° C The curvature does not exceed -0.10 mm and 0.02 mm; as can be seen from Fig. 6B, the maximum distortion of the miniaturized lens 3 of the present embodiment does not exceed -2% and 1%; as can be seen from Fig. 6C, the small size of this embodiment The lateral chromatic aberration of the lens 3 does not exceed -1.5 μm and 4.5 μm, and it is apparent that the optical performance of the miniaturized lens 3 of the present embodiment is in compliance with the standard.
綜合以上所可得知,本發明之小型化鏡頭1~3不僅體積小,更同時具有廣角、光學畸變小、以及高光學效能之效果。另外,以上所述僅為本發明較佳可行實施例而已,舉凡應用本發明說明書及申請專利範圍所為之等效結構變化,理應包含在本發明之專利範圍內。As can be seen from the above, the miniaturized lenses 1 to 3 of the present invention are not only small in size, but also have a wide angle, a small optical distortion, and a high optical performance. In addition, the above description is only a preferred embodiment of the present invention, and equivalent structural changes in the application of the present invention and the scope of the patent application are intended to be included in the scope of the present invention.
1‧‧‧小型化鏡頭1‧‧‧Small lens
L1‧‧‧第一鏡片L1‧‧‧ first lens
L2‧‧‧第二鏡片L2‧‧‧ second lens
L3‧‧‧第三鏡片L3‧‧‧ third lens
L4‧‧‧第四鏡片L4‧‧‧ fourth lens
L5‧‧‧第五鏡片L5‧‧‧ fifth lens
ST‧‧‧光圈ST‧‧‧ aperture
Z‧‧‧光軸Z‧‧‧ optical axis
CF‧‧‧濾光片CF‧‧‧Filter
Im‧‧‧成像面Im‧‧‧ imaging surface
S1~S13‧‧‧面S1~S13‧‧‧
2‧‧‧小型化鏡頭2‧‧‧Small lens
L1‧‧‧第一鏡片L1‧‧‧ first lens
L2‧‧‧第二鏡片L2‧‧‧ second lens
L3‧‧‧第三鏡片L3‧‧‧ third lens
L4‧‧‧第四鏡片L4‧‧‧ fourth lens
L5‧‧‧第五鏡片L5‧‧‧ fifth lens
ST‧‧‧光圈ST‧‧‧ aperture
Z‧‧‧光軸Z‧‧‧ optical axis
CF‧‧‧濾光片CF‧‧‧Filter
Im‧‧‧成像面Im‧‧‧ imaging surface
S1~S13‧‧‧面S1~S13‧‧‧
3‧‧‧小型化鏡頭3‧‧‧Small lens
L1‧‧‧第一鏡片L1‧‧‧ first lens
L2‧‧‧第二鏡片L2‧‧‧ second lens
L3‧‧‧第三鏡片L3‧‧‧ third lens
L4‧‧‧第四鏡片L4‧‧‧ fourth lens
L5‧‧‧第五鏡片L5‧‧‧ fifth lens
ST‧‧‧光圈ST‧‧‧ aperture
Z‧‧‧光軸Z‧‧‧ optical axis
CF‧‧‧濾光片CF‧‧‧Filter
Im‧‧‧成像面Im‧‧‧ imaging surface
S1~S13‧‧‧面S1~S13‧‧‧
圖1為本發明第一較佳實施例之鏡片圖;圖2A為本發明第一較佳實施例之場曲圖;圖2B為本發明第一較佳實施例之畸變圖;圖2C為本發明第一較佳實施例之橫向色差圖;圖3為本發明第二較佳實施例之鏡片圖;圖4A為本發明第二較佳實施例之場曲圖;圖4B為本發明第二較佳實施例之畸變圖;圖4C為本發明第二較佳實施例之橫向色差圖;圖5為本發明第三較佳實施例之鏡片圖;圖6A為本發明第三較佳實施例之場曲圖;圖6B為本發明第三較佳實施例之畸變圖;圖6C為本發明第三較佳實施例之橫向色差圖。1 is a lens diagram of a first preferred embodiment of the present invention; FIG. 2A is a field curvature diagram of a first preferred embodiment of the present invention; FIG. 2B is a distortion diagram of a first preferred embodiment of the present invention; FIG. 3 is a perspective view of a second preferred embodiment of the present invention; FIG. 4B is a second view of the second preferred embodiment of the present invention; FIG. 4C is a cross-sectional chromatic aberration diagram of a second preferred embodiment of the present invention; FIG. 5 is a lens diagram of a third preferred embodiment of the present invention; and FIG. 6A is a third preferred embodiment of the present invention. FIG. 6B is a distortion diagram of a third preferred embodiment of the present invention; and FIG. 6C is a lateral chromatic aberration diagram of the third preferred embodiment of the present invention.
1‧‧‧小型化鏡頭1‧‧‧Small lens
L1‧‧‧第一鏡片L1‧‧‧ first lens
L2‧‧‧第二鏡片L2‧‧‧ second lens
L3‧‧‧第三鏡片L3‧‧‧ third lens
L4‧‧‧第四鏡片L4‧‧‧ fourth lens
L5‧‧‧第五鏡片L5‧‧‧ fifth lens
ST‧‧‧光圈ST‧‧‧ aperture
Z‧‧‧光軸Z‧‧‧ optical axis
CF‧‧‧濾光片CF‧‧‧Filter
Im‧‧‧成像面Im‧‧‧ imaging surface
S1~S13‧‧‧面S1~S13‧‧‧
Claims (20)
Priority Applications (1)
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TW101151106A TWI509284B (en) | 2012-12-28 | 2012-12-28 | Miniature lens |
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TW101151106A TWI509284B (en) | 2012-12-28 | 2012-12-28 | Miniature lens |
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TW201425998A TW201425998A (en) | 2014-07-01 |
TWI509284B true TWI509284B (en) | 2015-11-21 |
Family
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TW101151106A TWI509284B (en) | 2012-12-28 | 2012-12-28 | Miniature lens |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI708963B (en) * | 2020-02-14 | 2020-11-01 | 紘立光電股份有限公司 | Optical imaging lens, imaging device, and electronic device |
Families Citing this family (3)
Publication number | Priority date | Publication date | Assignee | Title |
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TWI710814B (en) * | 2016-03-10 | 2020-11-21 | 先進光電科技股份有限公司 | Optical image capturing system |
TWI710815B (en) | 2016-03-10 | 2020-11-21 | 先進光電科技股份有限公司 | Optical image capturing system |
CN109709658B (en) | 2017-10-25 | 2021-02-05 | 信泰光学(深圳)有限公司 | Camera lens |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201222114Y (en) * | 2007-12-05 | 2009-04-15 | 创研光电股份有限公司 | Five-lens type optical image-fetching lens |
TWM356114U (en) * | 2008-03-11 | 2009-05-01 | Fujinon Corp | Photography lens and photography apparatus using the same |
CN102360114A (en) * | 2011-10-12 | 2012-02-22 | 舜宇光学(中山)有限公司 | Monitoring lens |
-
2012
- 2012-12-28 TW TW101151106A patent/TWI509284B/en not_active IP Right Cessation
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN201222114Y (en) * | 2007-12-05 | 2009-04-15 | 创研光电股份有限公司 | Five-lens type optical image-fetching lens |
TWM356114U (en) * | 2008-03-11 | 2009-05-01 | Fujinon Corp | Photography lens and photography apparatus using the same |
CN102360114A (en) * | 2011-10-12 | 2012-02-22 | 舜宇光学(中山)有限公司 | Monitoring lens |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI708963B (en) * | 2020-02-14 | 2020-11-01 | 紘立光電股份有限公司 | Optical imaging lens, imaging device, and electronic device |
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