光学精密工程2026,Vol.34Issue(2):191-200,10.DOI:10.37188/OPE.20263402.0191
含偶次非球面的手机镜头降敏设计方法
Desensitization design method for mobile phone lens with even aspheric surfaces
摘要
Abstract
In the optical design process,the optimization of optical system performance and tolerance anal-ysis are often treated separately.A system with excellent theoretical performance may have excessively tight tolerance.Therefore,the desensitization of the optical system is crucial during the system design pro-cess.The even aspheric surfaces are commonly used in the mobile phone lens to reduce aberrations and to-tal track length.However,the introduction of high-order terms can lead to significant image quality degra-dation caused by the misalignments.A desensitization design method based on nodal aberration theory was proposed in this paper to desensitize mobile phone lenses with even aspheric surfaces.First,based on nod-al aberration theory,the variations in Zernike coefficients for third-order coma and astigmatism were ana-lyzed for the conic surface base of the misaligned even aspheric surfaces.Then,in order to calculate the variation in wavefront error introduced by the higher-order terms,a transformation of the pupil coordinates was used to obtain the pupil map of the optical surface under misalignments.Based on the coordinate trans-formation in the pupil map,the variation in wavefront error was then calculated.Finally,an as-built per-formance model suitable for optical systems with even aspheric surfaces was established,which was then used to design a 4-element mobile phone lens.The tolerance analysis showed that after 30 minutes of opti-mization and under 5 μm decenter and 5' tilt tolerance,the mean RMS wavefront error of the mobile phone lens was reduced by 33%compared to the default design method,which verifies the effectiveness of the proposed design method in the paper.关键词
节点像差理论/降敏设计/非球面/手机镜头Key words
nodal aberration theory/desensitization design/aspheric surface/mobile phone lens分类
通用工业技术引用本文复制引用
王洋,王楚文,顾志远..含偶次非球面的手机镜头降敏设计方法[J].光学精密工程,2026,34(2):191-200,10.基金项目
吉林省科技厅自然科学基金面上项目(No.20230101217JC) (No.20230101217JC)
