Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo

Wenjun Kang; Masafumi Seigo; Huapan Xiao; Daodang Wang; Rongguang Liang

doi:10.3390/mi13101564

Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo

Wenjun Kang, Masafumi Seigo, Huapan Xiao, Daodang Wang, Rongguang Liang

Optical Sciences

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

On the demand of low-cost, lightweight, miniaturized, and integrated optical systems, precision lenslet arrays are widely used. Diamond turning is often used to fabricate lenslet arrays directly or molds that are used to mold lenslet arrays. In this paper, mainly by real-time monitoring position following error for slow tool servo, different fabrication parameters are quantitatively studied and optimized for actual fabrication, then by actual fabrication validation, uniform and high-fidelity surface topography across the actual whole lenslet array is achieved. The evaluated fabrication parameters include sampling strategy, inverse time feed, arc-length, etc. The study provides a quick, effective, and detailed reference for both convex and concave lenslet array cutting parameter selection. At the end, a smooth zonal machining strategy toolpath is demonstrated for fabricating concave lenslet arrays.

Original language	English (US)
Article number	1564
Journal	Micromachines
Volume	13
Issue number	10
DOIs	https://doi.org/10.3390/mi13101564
State	Published - Oct 2022

Keywords

diamond turning
lenslet array
optics fabrication
position following error
slow tool servo

ASJC Scopus subject areas

Control and Systems Engineering
Mechanical Engineering
Electrical and Electronic Engineering

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10.3390/mi13101564

Cite this

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title = "Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo",

abstract = "On the demand of low-cost, lightweight, miniaturized, and integrated optical systems, precision lenslet arrays are widely used. Diamond turning is often used to fabricate lenslet arrays directly or molds that are used to mold lenslet arrays. In this paper, mainly by real-time monitoring position following error for slow tool servo, different fabrication parameters are quantitatively studied and optimized for actual fabrication, then by actual fabrication validation, uniform and high-fidelity surface topography across the actual whole lenslet array is achieved. The evaluated fabrication parameters include sampling strategy, inverse time feed, arc-length, etc. The study provides a quick, effective, and detailed reference for both convex and concave lenslet array cutting parameter selection. At the end, a smooth zonal machining strategy toolpath is demonstrated for fabricating concave lenslet arrays.",

keywords = "diamond turning, lenslet array, optics fabrication, position following error, slow tool servo",

author = "Wenjun Kang and Masafumi Seigo and Huapan Xiao and Daodang Wang and Rongguang Liang",

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doi = "10.3390/mi13101564",

language = "English (US)",

volume = "13",

journal = "Micromachines",

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publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

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TY - JOUR

T1 - Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo

AU - Kang, Wenjun

AU - Seigo, Masafumi

AU - Xiao, Huapan

AU - Wang, Daodang

AU - Liang, Rongguang

PY - 2022/10

Y1 - 2022/10

N2 - On the demand of low-cost, lightweight, miniaturized, and integrated optical systems, precision lenslet arrays are widely used. Diamond turning is often used to fabricate lenslet arrays directly or molds that are used to mold lenslet arrays. In this paper, mainly by real-time monitoring position following error for slow tool servo, different fabrication parameters are quantitatively studied and optimized for actual fabrication, then by actual fabrication validation, uniform and high-fidelity surface topography across the actual whole lenslet array is achieved. The evaluated fabrication parameters include sampling strategy, inverse time feed, arc-length, etc. The study provides a quick, effective, and detailed reference for both convex and concave lenslet array cutting parameter selection. At the end, a smooth zonal machining strategy toolpath is demonstrated for fabricating concave lenslet arrays.

AB - On the demand of low-cost, lightweight, miniaturized, and integrated optical systems, precision lenslet arrays are widely used. Diamond turning is often used to fabricate lenslet arrays directly or molds that are used to mold lenslet arrays. In this paper, mainly by real-time monitoring position following error for slow tool servo, different fabrication parameters are quantitatively studied and optimized for actual fabrication, then by actual fabrication validation, uniform and high-fidelity surface topography across the actual whole lenslet array is achieved. The evaluated fabrication parameters include sampling strategy, inverse time feed, arc-length, etc. The study provides a quick, effective, and detailed reference for both convex and concave lenslet array cutting parameter selection. At the end, a smooth zonal machining strategy toolpath is demonstrated for fabricating concave lenslet arrays.

KW - diamond turning

KW - lenslet array

KW - optics fabrication

KW - position following error

KW - slow tool servo

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Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo

Abstract

Keywords

ASJC Scopus subject areas

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