221 |
視覚補償デバイスをカスタマイズするためのパラメータの少なくとも1つの値を判定する方法 |
JP2016517657 |
2014-06-03 |
JP6077720B2 |
2017-02-08 |
アフメド ハッダディ; マリー−アンヌ ベルテゼーヌ; イザベル プラン; セシール プティグノー; ロイク ルブロー; セバスチャン ガヤ; ファビアン ディボ; バンジャマン ルッソー |
|
222 |
眼鏡レンズの製造システム、製造装置、製造方法、製造情報管理システム、製造情報管理装置、および製造情報管理方法 |
JP2015502858 |
2014-02-14 |
JP5976918B2 |
2016-08-24 |
鈴江 喬弘; 吉崎 洋 |
|
223 |
眼鏡加工用補助装置および眼鏡レンズの適否判定方法 |
JP2011162844 |
2011-07-26 |
JP5848054B2 |
2016-01-27 |
ペトリ エスコラ |
|
224 |
眼用レンズのベベル形状の決定方法 |
JP2010540131 |
2008-12-23 |
JP5766952B2 |
2015-08-19 |
ダヴィド・フレソン; フレデリク・デュボワ |
|
225 |
基本姿勢を推定するための方法 |
JP2013515853 |
2011-06-21 |
JP5730995B2 |
2015-06-10 |
アンカウア、デイヴィット; トーメ、パスカル |
|
226 |
注文する眼鏡の特徴を取得するための非同期的方法 |
JP2010540134 |
2008-12-23 |
JP5728230B2 |
2015-06-03 |
サワーフィア・サイ; フィリップ・クララ; セバスチャン・セイエ |
|
227 |
リアルタイムで類別を行うシステム及び方法 |
JP2014556095 |
2013-02-11 |
JP2015513689A |
2015-05-14 |
ビョルン・ドローブ; セリーヌ・カリマロ |
汎用眼鏡レンズ設計を更新するシステム及び方法について記述する。本方法は、汎用眼鏡レンズ設計データベースから汎用眼鏡レンズ設計を選択するステップと、データ通信ネットワークを介して、少なくとも1名の個人レンズ着用者に関連付けられたレンズ注文データを受信するステップとを含む。本方法はまた、汎用眼鏡レンズ設計及びレンズ注文データを用いて、少なくとも1名の個人レンズ着用者の各々に向けてカスタマイズされた少なくとも1個の特注眼鏡レンズ設計を生成するステップと、少なくとも1個の特注眼鏡レンズ設計を用いて、汎用眼鏡レンズ設計データベース内の汎用眼鏡レンズ設計を更新するステップとを含む。 |
228 |
フレームに適合する眼鏡レンズを選択するための方法およびコンピュータ手段 |
JP2010540135 |
2008-12-23 |
JP5680419B2 |
2015-03-04 |
サワーフィア・サイ; セバスチャン・セイエ; リュック・マルタン; フレデリック・デュボワ |
|
229 |
所与の眼鏡フレームに応じて光学系を計算する方法 |
JP2010540138 |
2008-12-23 |
JP5670741B2 |
2015-02-18 |
フレデリク・デュボワ; シリル・ギロー; パスカル・アリオネ; セシール・ピエトリ; ダヴィド・フレンソン; クリスティアン・ジョンクール |
|
230 |
眼鏡レンズ上のシグネチャマークを可視化する方法及び装置 |
JP2012256343 |
2012-11-22 |
JP5636413B2 |
2014-12-03 |
ハンセン アダルバート; ホーナー マシアス |
|
231 |
Spectacle lens manufacturing system, manufacturing apparatus, manufacturing method, manufacturing information management system, manufacturing information management device and manufacturing information management method |
JP2013036123 |
2013-02-26 |
JP2014164178A |
2014-09-08 |
SUZUE TAKAHIRO; YOSHIZAKI HIROSHI |
PROBLEM TO BE SOLVED: To provide a system which allows global and speedy manufacturing of spectacle lenses, enabling excellent framing, regardless of a site, a request side or a manufacturing side of spectacle lenses.SOLUTION: A spectacle lens manufacturing system includes: a processing apparatus installed on a manufacture side of spectacle lenses; a processing information acquisition part which acquires processing information calculated by adding a lens shape change amount which is a difference between when spectacle lenses are under environment of an order side and when they are under environment of a manufacture side on the basis of spectacle lens manufacturing request side information including spectacle lens information, frame information, prescription value information and an order side region information, spectacle lens manufacture side information including processing apparatus information, environment information including environment information on the spectacle lens order side and environment information on the spectacle lens manufacture side, and lens shape change information concerning lens shape change depending on an environment. Following the processing information transmitted from the processing information acquisition part to the processing apparatus, the processing apparatus manufactures spectacle lenses so that the lenses are fit to a frame even under the environment of the order side. |
232 |
Method for optimizing the configuration of the system for spectacles |
JP2011525561 |
2009-09-04 |
JP5539987B2 |
2014-07-02 |
フィリップ・クララ |
|
233 |
Eyeglasses frame shape tracing device |
JP2012195457 |
2012-09-05 |
JP2014052222A |
2014-03-20 |
YAMAMOTO TAKAYASU |
PROBLEM TO BE SOLVED: To reduce an assist of an operator as much as possible, and improve tracing efficiency.SOLUTION: An eyeglasses frame shape tracing device comprises: movement means for moving a probe along a bevel groove of a rim; detection means that detects a movement position of the rim; control means that controls the movement means to obtain tracing data on an entire circumference shape; and determination means that, when there is a steep change in the tracing data obtained in a predetermined moving radius range from an initial tracing start point where the probe comes into contact with the rim, determines a tracing error. When it is determined that the tracing is the tracing error, the control means determines whether or not the probe is inserted into the bevel groove on the basis of tracing data obtained when a predetermined operation for inserting the probe into the bevel groove is performed or determines whether or not on the basis of at least one of tracing data obtained when it is determined that the tracing is the tracing error and tracing data obtained thereafter, and obtains tracing data on a rim entire circumference by moving the probe along the bevel groove from a position having the probe inserted into the bevel groove. |
234 |
How to optically design a method and apparatus and correction lens for determining the orientation of the ophthalmic correction lens |
JP2009527911 |
2007-09-10 |
JP5431938B2 |
2014-03-05 |
ショーボー,ジャン−ピエール; リエボワ,ファビアンヌ |
|
235 |
Method and apparatus for visualizing signature mark on spectacle lens |
JP2012256343 |
2012-11-22 |
JP2013137531A |
2013-07-11 |
ADALBERT HANSSEN; MATTHIAS HORNAUER |
PROBLEM TO BE SOLVED: To provide a method and apparatus for visualizing a mark or signature mark on a spectacle lens.SOLUTION: To identify a signature mark 18, an illumination light beam 22 is directed onto the spectacle lens 16. The illumination light beam 22 impinges on the spectacle lens 16, is reflected at a reflector 30 implemented as a retroreflector after impinging on the spectacle lens 16, impinges once again on the spectacle lens 16 as an observation light beam 34, and finally is passed to a camera 36. In this method, a reflection region of the illumination light beam 22 on the reflector 30 is varied by means of a moving first optical element 100. |
236 |
Progressive power lens selector, progressive power lens selection method, and progressive power lens selection program |
JP2011192045 |
2011-09-02 |
JP2013052095A |
2013-03-21 |
KATO KAZUHISA |
PROBLEM TO BE SOLVED: To provide a selection system for a progressive power lens easily selecting a proper progressive power lens by properly determining a visual field in depth.SOLUTION: A progressive power lens selector includes: an accommodation ability acquisition unit 211; a near vision prescription range acquisition unit 212; a lens database 221 storing design parameters of progressive power lenses in response to addition power with respect to each of plural types; an accommodation ability computation unit 231 computing used accommodation ability for near vision; a necessary addition power computation unit 232 computing necessary addition power for near vision; a range computation unit 233 computing the maximum distance ranges and the maximum near ranges when lenses are worn based on the necessary addition power in lenses selected as lenses having design elements of a set condition equal to or more than the necessary addition power of the plural types stored in the lens database 221; and an output control unit 26 allowing a display device 30 to display the maximum distance ranges and the maximum near ranges with respect to the lenses of the design types selected by a selecting unit 24 in juxtaposition. |
237 |
Apparatus and method for determining and measuring brace, the forward tilt of the glasses frame |
JP2007531684 |
2005-09-15 |
JP5094396B2 |
2012-12-12 |
クビッツア,マティアス |
|
238 |
Method for producing a single vision aspheric lens |
JP2010231472 |
2010-10-14 |
JP5031083B2 |
2012-09-19 |
哲馬 山梶; 隆志 畑中 |
The present invention has an object to provide a spectacle lens which has a more optimized prescription surface, taking into consideration individual wearing conditions, and a manufacturing method therefor. Prescription values, comprising data related to a VR value of each spectacles wearer, and other information required in the design and manufacture of a spectacle lens, are sent via a terminal installed at a spectacles store (ordering party) to a host computer installed at a spectacles processing plant (processing party), these data are processed by the host computer, processing conditions are determined by obtaining an optimized lens form based on an optical model of simulated wearing conditions, a spectacle lens is manufactured by numerically-controlled processing machines and an edger, and delivered to an ordering party. |
239 |
眼鏡レンズ発注端末、眼鏡レンズ受注装置、眼鏡レンズ受発注システム及びプログラム |
JP2010520873 |
2009-07-14 |
JPWO2010007997A1 |
2012-01-05 |
重洋 清水 |
眼鏡レンズ発注端末は、眼鏡レンズの光学性能を表わすグラフに対応するグラフデータを含む第1情報を入力する入力手段と、前記グラフを表示する画面を有する表示手段と、前記画面に表示された前記グラフを編集する編集手段と、前記第1情報を受注装置に送信する送信手段と、を有する。 |
240 |
Optic lens manufacturing method |
JP2011158492 |
2011-07-19 |
JP2011227523A |
2011-11-10 |
JAGDISH M JETHMALANI; LAWRENCE WARDEN; XUI TEE LAI; ANDREAS W DREYAR |
PROBLEM TO BE SOLVED: To manufacture easily at low cost optical lenses that correct aberration equal to or higher than three, which could not be corrected with conventional lenses, considering the fact that human cornea and lens can deteriorate optical capability producing impaired vision, and corrections with conventional glasses are limited to correct low-order aberration like defocus and astigmatism.SOLUTION: In manufacturing the lenses which correct high-order aberration, a curable plastic material of a predetermined thickness called spacer is arranged on a first lens, the first lens and a second lens are engaged each other leaving a specific space between them and the curable plastic material is semi-cured to determine a refraction index pattern for correcting high-order aberration, according to the lens definition of desired lenses. Thus, the lenses that correct at the same time various types of aberrations that a patient suffers from, including low-order and high-order aberrations, can be manufactured easily at low cost on a custom-made basis. Lenses capable of precise correction are also provided for specific patients. |