JP3283406B2 - Lens meter - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a lens meter for measuring optical characteristics of a lens.

[0002]

2. Description of the Related Art When a spectacle wearer recreates a spectacle lens due to a mismatched lens, it is necessary to know the optical characteristics of both left and right lenses of the spectacles. In a conventional lens meter, measurement is performed by operating as follows. First, the lens on the side to be measured first is designated by the lens left / right designation switch. The examiner holds the spectacles and places the specified lens on the measurement optical axis. When the alignment is completed, the examiner presses the measurement value reading switch and stores the measurement value. Next, after specifying the other side again with the left / right specification switch, replace the lens on the measurement optical axis, and similarly press the measurement value reading switch when alignment is completed,
Store the measured value. When the measurement of both left and right lenses is completed,
The print result is printed out by pressing the print switch.

[0003]

However, since the examiner holds the spectacle frame by hand and performs alignment, it is not possible to press the other left / right designation switch after the measurement of one lens is completed. Operation is troublesome. In addition, there is a problem that the switch must be pressed many times before obtaining the measurement result, resulting in poor operability. Further, if there are many switches to be selected, smooth measurement may not be performed because the switch to be pressed may be lost, or the switch may be erroneously pressed. Some conventional devices eliminate the need to operate the left / right designation switch by detecting the left / right of the spectacle frame or detecting the left / right of the lens to be inspected using a slider that can move left / right. Although those have been proposed, these detection mechanisms have a drawback that the configuration is complicated.

The present invention has been made in view of the above-mentioned problems of the conventional apparatus,
An object of the present invention is to provide a lens meter with good operability by simplifying switch operation as much as possible without providing a detection mechanism having a complicated configuration.

[0005]

In order to solve the above-mentioned problems, the present invention is characterized by having the following configuration. (1) A lens meter for projecting a measurement light beam to a test lens and measuring the refractive power of the test lens from the position of an image formed on the light receiving element by the measurement light beam transmitted through the test lens,
Designation means for designating left and right of the lens to be measured first;
Storage means for storing the measurement result of the lens to be measured based on the measurement value reading signal; detecting means for detecting whether the lens to be measured is on the measurement optical axis; And right-and-left switching determining means for determining left and right switching of the inspection lens.

(2) The measuring light beam is projected on the lens to be inspected,
Measurement light beam transmitted through the lens to be formed forms on the light receiving element
A lens finder for measuring the refractive power of the test lens from the position of the image
The left and right sides of the lens to be measured first
Specifying means and the lens to be inspected based on the measurement value reading signal
Storage means for storing the measurement result of the
Detecting means for detecting whether or not it is on an axis;
Measurement of the left and right lenses to be inspected is completed based on the detection result.
Measurement end determining means for determining that the measurement has been completed;
Operation of the printing means or output means based on the judgment of the judgment means
Control means for performing printing or output by controlling
And features.

(3 ) The lens meter of (1) or (2)
Has a measuring means for measuring the refractive power of the lens to be inspected,
The detecting means is based on the measurement result of the measuring means.
Means for determining whether the lens is on the measurement optical axis.
It is characterized by that.

(4 ) The lens meter of (1) or (2)
Also determines the alignment of the lens on the measurement optical axis.
Equipped with alignment state judgment means
The signal generation means determines the result of the alignment state determination.
A reading signal is issued based on the result .

(5) The left / right switching determination means of (1)
In addition to the detection result of the detection means,
The determination is based on the presence or absence of a signal.

(6) The measurement end determination means of (2)
The measured value reading signal in addition to the detection result of the detecting means.
Is determined based on the presence or absence of

(7) The measuring light beam is projected on the lens to be inspected,
Measurement light beam transmitted through the lens to be formed forms on the light receiving element
A lens finder for measuring the refractive power of the test lens from the position of the image
The left and right sides of the lens to be measured first
Specifying means and the lens to be inspected based on the measurement value reading signal
Storage means for storing the measurement results of
The input means for inputting whether or not the mode is set, and the measurement mode is a single focus
In the point mode, the signal is read based on the measured value read signal.
Left / right switching determination means for determining left / right switching of the inspection lens
And the following.

[0012]

[0013]

[0014]

An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an external view of a lens meter according to an embodiment. Reference numeral 1 denotes a display such as an LCD, which displays various information such as a target for alignment, measurement information, and a setting screen. Reference numeral 2 denotes a switch group, and a display 1
By pressing the switch corresponding to the switch display 3 displayed at the predetermined position, the apparatus can be started and various items can be set. The switch display 3 in the measurement mode includes a left / right selection switch display, a print switch display, a menu switch display, and the like. When the switch corresponding to the menu switch display is pressed, the contents of the switch display and the graphic display on the display 1 can be switched, and various settings can be made by operating the switch group 2. Reference numeral 4 denotes a READ switch used when reading a measured value by manual operation.

Reference numerals 10 and 11 denote storage sections for a measuring optical system, which will be described later.
A lens 12 is provided to hold the lens to be inspected by lowering the lens holder 13. Reference numeral 14 denotes a lens holder, and the lens holder 14 is held so as to be movable back and forth.
Reference numeral 15 denotes a moving lever of the lens receiving base 14. Reference numeral 34 denotes a printer that prints out the measurement results.

FIG. 2 is a diagram for explaining an optical system and a control system of the lens meter. Reference numeral 20 denotes a measurement light source such as an LED,
Four lenses are arranged near the focal point of the condenser lens 21 at right angles to the optical axis, and are sequentially turned on at the time of measurement under the control of the microcomputer. Numeral 22 denotes a measurement target having orthogonal slits, and includes a condenser lens 21 and a collimator.
It is fixed or movable near the focal point of the focusing lens 23. The nosepiece is arranged near the focal point of the collimating lens 23 and the imaging lens 24. Reference numeral 25 denotes a half prism, and reference numeral 26 denotes two one-dimensional image sensors provided so as to be orthogonal to the optical axis and arranged so that their detection directions are orthogonal to each other. Light from the measurement light source 20 illuminates the measurement target 22 via the condenser lens 21. The light beam having passed through the measurement target 22 passes through the collimating lens 23, the lens L to be measured, and the imaging lens 24, and is orthogonally coupled to two image sensors 26.
Image each on top.

The relationship between the refractive power of the lens to be inspected and the image forming position of the measurement target will be briefly described. Each measurement light source 2
The measurement targets are individually illuminated for the 0 sequential lighting. When there is no lens to be inspected (or when a lens having no refractive power is mounted), all target images formed on the image sensor 26 by turning on the respective measurement light sources overlap. If the test lens has only a spherical refractive power, the position of the target image on the image sensor 26 moves by an amount corresponding to the spherical refractive power. When the test lens has only the columnar refractive power, the light beam incident on the lens has a refractive power in a direction (or the same direction) orthogonal to the main diameter line. Therefore, the spherical power, the astigmatic power, the astigmatic axis angle, and the prism amount can be obtained based on the center coordinates of the target image obtained by turning on each measurement light source 20. This calculation is described in Japanese Patent Application Laid-Open No. 60-17 / 1985 by the same applicant as the present invention.
No. 335 (name of the invention, "Auto Lens Meter"), so reference is made thereto. Output signals from the image sensor 26 are respectively processed by a signal detection processing circuit 30 and input to the microcomputer 31. The microcomputer 31 performs predetermined arithmetic processing to obtain the optical characteristics of the test lens L. Reference numeral 32 denotes a display circuit of the display 1, reference numeral 33 denotes a drive circuit of the measurement light source, and reference numeral 35 denotes a drive circuit of the printer.

In the apparatus configured as described above, the measuring operation of the lens with the spectacle frame, which is a characteristic part of the present invention,
The description will be made based on the flowchart of FIG. The measurement modes of the apparatus include a mode for measuring a single focus lens and a mode for measuring a progressive lens. Here, the measurement mode for a single focus lens will be described as an example (measurement mode). The mode can be selected by operating the switch group 2).
The examiner presses a switch in the switch group 2 meaning left / right selection of the lens, and selects the left / right of the lens to be measured first. For example, start by measuring the right lens. When the switch signal for designating the right lens is input, the apparatus enters the right lens measurement mode. FIG. 4 shows an example of the screen of the display 1 at this time (FIG. 4 omits a part of the screen). 40
Is a reticle for alignment, and 41 and 42 are measurement value display sections for displaying left and right measurement values.
The display of 3 indicates the current mode of the measuring lens.

The examiner holds the spectacle frame by hand and places the selected right lens on the nosepiece 12. When the lens to be measured is placed on the measurement optical axis, the microcomputer 31 calculates the refractive power and obtains measured values of the spherical power, the cylindrical power, the cylindrical axis angle, and the prism amount. Each measurement value of the right lens is displayed on the right measurement value display section 41. The measurement is continuously performed at regular intervals, and the value of the right measured value display section 41 is constantly updated and displayed as the measured value changes.

The microcomputer 31 calculates the amount of deviation from the optical center of the lens to be inspected from the prism value,
A crosshair for alignment is placed at a position corresponding to the deviation.
The get 44 is displayed (see FIG. 5). Inspector is reticle 4
The lens is moved so that the cross target 44 coincides with the center of zero. When the deviation amount falls within a predetermined allowable range, the cross target 44 changes to a large cross to notify the examiner that the alignment has been completed. The apparatus of the present embodiment has a function of issuing a measured value reading signal and automatically storing the measured value in the storage circuit by detecting the completion of alignment and determining whether the obtained measured value is stable. ing. The determination as to whether or not the measured value is stable is made by determining that the fluctuation of each measured value is within a predetermined allowable range (for example, the spherical power and the astigmatic power are within 0.06D for a predetermined time (1 second), The astigmatic axis angle is within 1 degree). Of course, the reading of the measured value can also be performed by pressing the READ switch 4, and either can be selected in advance on the setting screen by operating the menu switch. (Even if the automatic reading is selected, the reading by the READ switch 4 is not performed. Is possible).

When the apparatus has completed reading the measured values,
An unshown sound generator is operated to inform the examiner of the completion of reading, and the measured value display section 41 displays the stored measured values in a hold manner.

After the storage of the measured values of the right lens is completed, the process proceeds to the measurement of the left lens. By moving the measurement lens, the lens that has been measured is removed from the measurement optical axis. Therefore, the microcomputer 31 obtains a measurement value obtained through the measurement optical system of approximately 0 (the test value). Even when there is no lens, there are some errors in the measured values. For example, the calculated equivalent spherical value is less than ± 0.06D, the astigmatic power is less than 0.06D, and the prism amount is less than 0.06 prism.) This is detected depending on whether or not. That is, whether or not the lens has been removed (whether or not the test lens is on the measurement optical axis) is detected based on whether or not the measurement result has changed to substantially zero. When the microcomputer 31 detects that the lens has been removed from the measurement optical axis, the microcomputer 31 further confirms that only the measurement value of one lens is stored in the storage circuit, and the measurement of one lens is performed. Judging that the measurement has been completed (measurement end may be determined based on the fact that the lens has been removed from the measurement optical axis. However, the lens may come off accidentally before reading and storing the measured values. Therefore, it is more preferable to confirm the storage of the measured values.) The microcomputer 31 that has determined that the measurement of one of the lenses is completed,
The lens measurement mode is switched to the other (left) mode. The mark 43 on the display 1 is the left measured value display 4
Move to the second side and inform the examiner that the measurement mode is the left lens measurement mode.

The examiner places the left lens on the nosepiece 12 and changes it. As described above, the examiner moves the lens so that the reticle 40 and the cross target 44 have a predetermined relationship, and performs alignment. When the alignment is completed and the measured value is stabilized, the device automatically issues a measured value reading signal and stores the measured value of the left lens in the storage circuit. The stored measured values are displayed on the left measured value display section 42 in a hold manner. The examiner removes the lens from the nosepiece 12 when the measurement of the left lens is completed. The microcomputer 31 is
As described above, based on the measurement results obtained continuously, it is detected that the lens has been removed from the measurement optical axis, and it is confirmed that both left and right measurement values have been stored in the storage circuit, and that both lenses have been measured. Determine the end of measurement. The microcomputer 31 that has determined that the measurement of both lenses has been completed is sent to the printer drive circuit 35.
Then, an operation signal is issued to operate the printer 34, and both the left and right measurement data stored in the storage circuit are printed out. When connected to an optometer or the like, the measurement data is transferred at the same time.

As described above, the apparatus switches the right / left lens measurement mode, prints out, etc. based on the detection result of whether or not the lens is on the measurement optical axis and the storage result of the measurement value. Activate the operation automatically. Therefore, the troublesome operation of these switches is reduced, and the examiner can perform the measurement smoothly. Further, by automating the reading of the measured values, the examiner is released from the switch operation after starting the measurement, and can concentrate on holding and aligning the lens, thereby enabling efficient measurement.

Each automatic function such as switching of the right / left lens measurement mode and print output can be set independently according to the use condition of the examiner. Of course, even when these automatic functions are set, the command signal from the switch group 2 is effective. For example, after switching from the right lens measurement mode to the left measurement mode, if the right lens designation switch is pressed, the display can be returned to the right lens measurement mode, and even before the apparatus determines that the measurement is completed. Press the print switch to print out.

Although the above description has been made with reference to the measurement of a framed single focus lens as an example, the present invention is more convenient for measuring the addition of a multifocal lens or a progressive lens. That is, if only the measurement of the single focus lens is performed, the end of the measurement may be determined based on the generation of the measurement value reading signal. However, in a lens for measuring the addition power, it is necessary to read and store the measurement value of the distance portion, and then store the measurement and reading of the addition portion. Therefore, by detecting that the lens has been removed from the measurement optical axis, it is possible to determine the end of the measurement in the case of the lens for measuring the addition power, and this detection signal is used as the right / left lens measurement mode. It can be used for automation of switching and print output. Thus, the present invention can be variously modified, and these are included in the present invention as long as the technical ideas are the same.

[0027]

As described above, according to the present invention,
The switch operation can be simplified without complicating the configuration of the device, and a lens meter with extremely high operability can be realized. Thereby, the efficiency of the measurement can be further improved.

[Brief description of the drawings]

FIG. 1 is an external view of a lens meter according to an embodiment.

FIG. 2 is a diagram illustrating an optical system and a control system of a lens meter according to an embodiment.

FIG. 3 is a flow chart for explaining a measuring operation of a lens with a spectacle frame.
It is a figure showing a chart.

FIG. 4 is a diagram showing an example of a screen of a display 1 when starting from measurement of a right lens.

FIG. 5 is a diagram showing an example of a screen of the display 1 during right lens measurement.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Display 2 Switch group 3 Switch display 4 READ switch 20 Measurement light source 26 Image sensor 31 Microcomputer 41 Right measured value display part 42 Left measured value display part 43 Mark

Claims (7)

(57) [Claims] 1. A projecting a measuring light flux on the subject lens, the measurement light beam transmitted through the subject lens to measure the refractive power of the lens from the position of the image to be formed on the light receiving element lens meter - in data, previously A designated hand that specifies the left and right sides of the lens to be measured
A step, storage means for storing a measurement result of the test lens based on the measurement value read signal, detection means for detecting whether the test lens is on the measurement optical axis, and a detection result of the detection means. A left / right switching determining means for determining right / left switching of the test lens based on the detected value. 2. A test light beam is projected onto a lens to be measured,
Position of the image formed on the light receiving element by the measurement light beam transmitted through the lens.
To the lens meter that measures the refractive power of the test lens
To specify the left and right sides of the lens to be measured first.
Step and measurement of the lens under test based on the measured value reading signal
The storage means for storing the result and the test lens are located on the measurement optical axis.
Detecting means for detecting whether or not there is a
Measurement of left and right test lenses based on results
Means for determining the end of measurement,
Controls the operation of the printing means or output means based on the determination of the stage
And a control means for performing printing or output . 3. A lens meter according to claim 1, wherein
Has a measuring means for measuring the refractive power of the lens to be inspected,
The detecting means is based on the measurement result of the measuring means.
Means for determining whether the lens is on the measurement optical axis.
Data - a lens meter which is characterized in Rukoto. 4. A lens meter according to claim 1 or claim 2.
Also determines the alignment of the lens on the measurement optical axis.
Equipped with alignment state judgment means
The signal generation means determines the result of the alignment state determination.
A lens meter for issuing a measurement reading signal based on the result . 5. The left / right switching determining means according to claim 1, wherein:
In addition to the detection result of the detection means,
A lens menu characterized by making a determination based on the presence or absence
Ta. 6. The measurement end determining means according to claim 2, wherein
In addition to the detection result of the
A lens meter characterized by making a determination based on nothing . 7. A measuring beam is projected on a lens to be measured, and
Position of the image formed on the light receiving element by the measurement light beam transmitted through the lens.
To the lens meter that measures the refractive power of the test lens
To specify the left and right sides of the lens to be measured first.
Step and measurement of the lens under test based on the measured value reading signal
The storage means for storing the result, and the measurement mode is a multifocal mode.
Input means for inputting whether or not the measurement mode is a single focus mode
In the case of
Left / right switching determining means for determining the right / left switching of the
A lens meter comprising: