JPH0376406B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a laser spot inspection method suitable for inspecting the brightness distribution of a laser spot in, for example, an optical disk pickup.

The brightness distribution of a laser spot in an optical disk pickup or the like is close to a Gaussian distribution, and evaluation of the distribution curve is one of the important items in the inspection of this type of laser beam. For example, if there are side lobes in the radial direction of the optical disk in the brightness distribution, crosstalk from adjacent tracks will increase, and if there are side lobes in the tangential direction, the eye pattern waveform will deteriorate.

Conventionally, when inspecting this type of laser spot, analog shading correction is applied to the video signal obtained by receiving the brightness distribution of the laser spot with a television camera, and at the same time, an arbitrary line along the vertical direction of the screen is The brightness level at is determined, and this two-dimensional distribution curve is displayed superimposed on an image corresponding to the brightness distribution, and the laser spot is evaluated from these images.

In such conventional inspection methods, the maximum brightness level generally differs depending on the individual pick-up, so when inspecting a laser spot, a brightness distribution curve standardized by the maximum brightness level is required.
We were unable to meet such requests. In addition, as another method for inspecting laser beams, the video signal obtained from the television camera in the conventional method is digitized, stored in a frame memory, etc., and then processed using appropriate software using a minicomputer-level computer. Although it is possible to consider a method of performing desired image processing, it is not practical due to the difficulty of complete real-time processing and the cost.

The present invention has been made in response to the above-mentioned needs, and its purpose is to provide a laser spot inspection method that can standardize the brightness distribution at the maximum brightness level and display the brightness distribution almost in real time. be.

In the laser spot inspection method of the present invention, a television camera receives light from a laser spot whose brightness distribution is to be inspected, converts it into a video signal, detects the maximum brightness level in the brightness distribution in at least one frame period, and detects a plurality of laser spots. By dividing the luminance distribution into luminance levels, comparing the plurality of luminance levels with the video signal, and displaying the output obtained by secondarily differentiating the comparison output at the frame period, the luminance distribution is divided into the plurality of luminance levels. The feature is that the image is converted into a contour line image corresponding to the image and displayed.

The method of the present invention will be explained in detail below with reference to the drawings.

FIG. 1 is a block diagram showing an example of the configuration of a video signal processing circuit, which is a main part of the present invention, in an embodiment of the present invention.

1 is a composite video signal input terminal. This terminal 1
A composite video signal obtained by receiving the luminance distribution of the laser spot to be tested by a well-known television camera (not shown) is added to the signal. The composite video signal is divided into two parts, one of which is first detected by a synchronization separation circuit 2 as a synchronization signal and guided to a vertical synchronization separation circuit 3, where the synchronization signal is integrated and is shown in FIG. 2a. A vertical synchronization signal like this can be obtained. This vertical synchronizing signal is guided to the 1/2 frequency divider shown by 4 as shown in Fig. 2b.
The frame synchronization pulse shown in FIG.
By adding a monostable multivibrator 7 via , we obtain as its output a reset pulse having the timing during the vertical retrace interval shown in FIG. 2d.

On the other hand, the other of the composite video signals applied to the input terminal 1 and divided into two is sent to a television camera (not shown) by a shading correction circuit 9 after the synchronization signal is removed by a luminance signal separation circuit 8. The sensitivity unevenness of the image sensor is corrected. The peak value of the video signal subjected to the shading correction in this manner is stored by the peak value hold circuit 10. This peak value hold circuit 10 is constructed so that the stored peak value can be updated by a reset pulse. That is, as the reset pulse, a sample pulse of one frame period as shown in FIG. At the same time as resetting the stored peak value, a new storage of the peak value during approximately one frame period immediately after the reset is successively repeated for each field cycle.

The output of the peak value hold circuit 10 is led to the next stage sample hold circuit 11, and is formed by a monostable multivibrator 5 as shown in FIG.
Sample and hold is performed using the sample pulse shown in . Since the sample pulse has a timing just before the reset pulse shown in FIG. It is a value. That is, since the video signal is a signal obtained by receiving light from the laser spot to be tested, the peak value corresponds to the highest brightness level in the brightness distribution of the laser spot to be tested.

The output of the sample hold circuit 11 is connected to a resistor.
The maximum brightness level is divided by supplying _it to series resistors consisting of R ₁ , R ₂ ,...R _o , and using the divided voltage obtained by each of these resistors R 1 , R ₂ ,...R _o as the threshold voltage. A plurality of comparators 12-1, 12- provided according to the number of comparators 12-1, 12-
2, . . . 12-n respectively. In addition, these comparators 12-1, 12-2,
...12-n are supplied with video signals branched from the output of the shading correction circuit 9, respectively. By doing this, each threshold value corresponding to a plurality of brightness levels based on the peak value of the video signal in approximately one frame period in the past from the timing of the sample pulse shown in FIG. Signal levels can be compared. Each comparator 12-1, 12-2,...12
-n is followed by second-order differentiators 13-1, 13-2,
. . 13-n are connected, thereby creating positive pulses at the rise and fall of each output of each comparator 12-1, 12-2, . . . 12-n. These pulses are obtained by comparing the video signal obtained by receiving the laser spot with a plurality of threshold values obtained based on the peak value at a frame period. Therefore, these pulses represent a plurality of brightness levels based on the maximum brightness level of the laser spot, and a contour line corresponding to each brightness level of an equivalent laser spot that compares the brightness of each part on the projection plane of the laser spot. becomes.

Each pulse from each second-order differentiator 13-1, 13-2...13-n is converted into a video signal representing contour lines of a plurality of brightness levels via an OR circuit 14, and is led to an adder 15, where it is synchronized. After adding the synchronizing signal from the separation circuit 2, the signal is transmitted through the buffer amplifier 16 and the output terminal 17 to an image display device (not shown), such as a television monitor, for image reproduction, and the resulting image has a luminance distribution cross section as shown in FIG. 3A, for example. The laser spot can be displayed, for example, by contour lines of a plurality of brightness levels, as shown in FIG.

Note that 18 is a contour line output switch, and the output of the OR circuit 14 is guided to the adder 15 via this switch 18. Reference numeral 19 is a switch for guiding the video signal branched from the shading correction circuit to the adder 15. By turning on this switch 19, a laser spot is displayed on an image display device (not shown) by superimposing it on the contour line display. Brightness distribution images can be displayed simultaneously. In this case, if the contour line output switch 18 is turned off, only the optical image of the laser spot will be displayed. Note that 20 is a terminal for measuring the peak value, and by measuring the voltage of this terminal 20, the absolute value of the peak value can be measured.

As is clear from the description of the embodiments above, according to the present invention, the brightness distribution of a laser spot can be displayed and observed using contour lines of brightness levels, and therefore the two-dimensional distribution of brightness can be measured. It becomes easy to evaluate the laser spot to be tested. In addition, the contour lines are formed with the maximum brightness level of the laser spot at its peak, so even if the overall brightness changes,
If the luminance distribution is similar, similar contour lines will be obtained, and therefore the luminance distribution of the laser beam can be observed without being affected by the magnitude of the overall luminance.

Furthermore, according to the configuration of the embodiment shown in FIG. 1, the peak value of the video signal is held and sampled and held, so the absolute peak value is saved during observation. ing. Therefore, the same laser beam can be measured at any time immediately, such as when observing again after a suspension of observation.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an example of the configuration of a video signal processing circuit according to an embodiment of the method of the present invention, FIG. 2 is a waveform diagram for explaining its operation, and FIG.
1 is an example of a luminance distribution displayed in a two-dimensional manner using a conventional method, and FIG. 1...Composite video signal input terminal, 2...Sync separation circuit, 3...Vertical sync separation circuit, 4...1/2 frequency divider, 5, 7...Monostable multivibrator, 6...
... Delay circuit, 8 ... Luminance signal separation circuit, 9 ... Shading correction circuit, 10 ... Peak value hold circuit, 11 ... Sample hold circuit, 12-
1 to 12-n... comparator, 13-1 to 13-n...
...Second order differentiator, 14...OR circuit, 15...Adder, 16...Buffer amplifier, 17...Output terminal, 18...Contour line output switch, 19...Video signal output switch, 20...Peak value Measurement terminals, R ₁ to R _o ...Divider resistor for setting reference voltage.

Claims (1)

[Claims] 1. Receive the laser spot whose brightness distribution is to be inspected with a television camera, convert it into a video signal, detect the maximum brightness level in the brightness distribution in at least one frame period, divide it into a plurality of brightness levels, and converting the brightness distribution into a contour line image corresponding to the plurality of brightness levels by displaying the output obtained by second-order differentiating the comparison output obtained by comparing the brightness level of and the video signal at the frame period; 1. A laser spot inspection method characterized by displaying: