JPS63257975A - Pickup device - Google Patents

Abstract

PURPOSE:To sufficiently secure the following allowance of a pickup with respect to a wide frequency band by weighting and impressing an abutting pressure of a scanner with respect to an information recording disk in accordance with vibration acceleration by means of the transmitting characteristic of a low pass filter. CONSTITUTION:The titled device is provided with means 17 and 18 (sensor, acceleration detecting circuit) detecting the vibrating acceleration of the disk, the low pass filter 19 having the transmission characteristic in which a peak frequency and a peak value coincide with the frequency of the anti-resonance point or the resonance value of a machine impedance in the scanner parts 1 and 3 of a pickup vibrating system, and means 11 (drive circuit) and 8 weighting and impressing the abutting pressure of the scanner 1 with respect to the disk in accordance with the vibration acceleration by the transmission characteristic of the low pass filter 19. Thus, the required abutting pressure is impressed on the scanner 1 in accordance with the machine impedance characteristic of the pickup and the following allowance of the pickup with respect to the wide frequency band can sufficiently be secured.

Description

Detailed Description of the Invention (Industrial Application Field) The present invention applies a scanner to the surface of an information recording disk (hereinafter referred to as a disk) on which information signals are recorded as concentric or spiral recording trajectories. The present invention relates to a pickup device of a reproducing device that sequentially reproduces information signals by bringing the device into contact with the pickup device.

(Prior Art) FIG. 4 shows an example of a conventional pickup device. In the figure, 1 is a scanner (specifically, a reproducing needle, etc.), and 2 is a disk. 3 is a scanning element holder, 4 is a lead wire, 5 is a cantilever, and 6 is a magnet, which are combined into one body to constitute a pickup arm. The vicinity of the magnet 6 of the pickup arm is elastically supported by an elastic support 7 to constitute a vibration system, and an electromagnetic coil 8 is provided above the magnet 6 and spaced apart from it. When a current flows through the electromagnetic coil 8, a rotational force is applied to the pickup arm around the elastic support 7, and the scanning element 1 attached to the tip of the pickup arm is rotated.
A contact pressure against the disk 2 is obtained. Reference numeral 9 denotes a constant contact pressure applying circuit, which is started to operate in response to a switch signal 10 and supplies a constant current to the electromagnetic coil 8 through a drive circuit 11.

Apply a specified contact pressure to the scanning element 1. The lead wire 4 is for transmitting the signal sensed by the scanning element 1 to the signal detector 12. Reference numeral 13 denotes an output drop detection circuit, which detects fluctuations in the reproduced output obtained through the signal detector 12 to detect foreign matter intervening between the scanner 1 and the disk 2. 14 is an adder, which applies a current corresponding to the output decrease level detected by the output decrease detection circuit 13 to the constant contact pressure application circuit 9.
This is added to the specified current from With this configuration, foreign matter that is not removed under the specified contact pressure can be removed, and after removal, when the output is restored, the original specified contact pressure is restored.

(Problem to be solved by the invention) The conventional configuration described above has the following drawbacks.

Disc 2 has surface runout (
There is undulation), and vibrations with various frequency components occur with each rotation. A specified contact pressure is applied to the scanning element 1 to follow this vibration, but there is a difference between the vibration acceleration amplitude A of the disk and the contact pressure W of the scanning element, AQ:ω・W/Zm.
There is a relationship as follows, and as the contact pressure W increases, the disk vibration A that the scanner can follow becomes larger. In the above formula, ω is the angular frequency,
Zm is the mechanical impedance in the disk vibration direction in the scanning element part of the pickup vibration system. However, increasing the contact pressure of the scanner would impair the life of the disk and the scanner, so there was a restriction. Figure 5 shows the relationship between disk vibration and the tracking ability of the pickup (scanner). It is something. In the figure, 15 indicates the vibration level of the disk, and 16 indicates the tracking ability level of the scanning element when a constant contact pressure is applied to the scanning element.The tracking ability level 16 of the scanning element is as shown in the figure. , it decreases by Q2 at the frequency indicated by F2. This is because, due to the configuration of the vibration system of the pickup, the mechanical impedance (Zm) of the scanning element section exhibits a frequency characteristic with a resonance point of resonance value Q1 at frequency F2.1This resonance point is usually called the anti-resonance point. .

In the conventional configuration shown in FIG. 4, the response frequency of the output drop detection circuit 13 is relatively low, and the object to be detected is a foreign object between the scanner 1 and the disk 2, and the detection frequency is extremely low. The time and contact pressure are constant, and as mentioned above, in Fig. 5, the tracking ability level of the scanning element fluctuates as 16, and at low frequencies there is a margin of M machining for the disk vibration level 15. On the other hand, at frequency F2, M
, L/ or you won't be able to afford it. It is important that this tracking margin is maintained uniformly over the entire frequency range, and under the above conditions, an extremely unstable tracking state may occur for a disk with a large vibration component near frequency F2. become. However, as described above, setting the specified contact pressure so as to secure the same follow-up margin as M□ also at frequency F2 is not preferable in terms of disk life and scanner life.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a pickup device that eliminates the conventional drawbacks and has sufficient margin for tracking even a disk having a vibration component near the anti-resonance frequency of the pickup.

(Means for Solving the Problems) The pickup device of the present invention has a pickup arm whose rear end is elastically supported, and a scanner that reads signals by coming into contact with an information recording disk is attached to the tip of the pickup arm. a vibration system, a means for detecting the vibration acceleration of the information recording disk, and a means for detecting the vibration acceleration of the information recording disk, and a means for detecting the vibration acceleration of the information recording disk; The device is equipped with a low-pass filter having a transmission characteristic that roughly matches the value, and means for applying a contact pressure of the scanner to the information recording disk in accordance with the vibration acceleration and weighted according to the transmission characteristic of the low-pass filter.

(Function) According to the present invention, a necessary contact pressure is applied to the scanning element according to the mechanical impedance characteristics of the pickup, and a sufficient follow-up margin of the pickup is ensured over a wide frequency band.

(Example) An example of the present invention will be described based on FIGS. 1 and 3.

FIG. 1 shows a pickup device according to a first embodiment of the present invention. In this figure, the same parts as those in the conventional example shown in FIG. 4 are designated by the same reference numerals, and some explanations thereof will be omitted.

In FIG. 1, 17 is a sensor that senses the vibration of the disk 2, and 18 is an acceleration detection circuit that detects the output from the sensor 17 as acceleration.

Reference numeral 19 denotes a low-pass filter, which has a transfer characteristic as shown in Fig. 2, and the peak frequency F1 and peak value Q1 almost match the anti-resonant frequency F2 and its resonance value Q2 shown in Fig. 5, respectively. .

11 is a drive circuit for driving the electromagnetic coil 8.

The operation of the pickup device configured as described above will be explained based on FIGS. 1 and 5.

The vibration amplitude signal of the disk 2 detected by the sensor 17 is converted into acceleration and detected by the acceleration detection circuit 18, and is then passed through a low-pass filter 19 which outputs a signal corresponding to the vibration level 15 of the disk shown in FIG. The vibration level of the disk 2 is weighted by .

Therefore, it is assumed that the vibration level of the disk has apparently increased by an amount corresponding to the drop in the follow-up ability level of the pickup shown in FIG. The signal level corresponding to the acceleration amplitude of the disk vibration weighted in this way is amplified by the drive circuit 11 and the electromagnetic coil 8
is applied to apply a contact pressure that allows the pickup to have a certain follow-up margin with respect to the acceleration amplitude weighted by 1. 10 is a switch signal that turns on and off a series of operations according to the position of the pickup and other conditions.

As described above, according to this embodiment, the acceleration detection circuit 18
By providing a low-pass filter with a peak characteristic that almost matches the anti-resonance characteristic of the pickup, it is possible to obtain the necessary contact pressure of the scanner according to the vibration level of the disk. It is possible to recover from the problem of decreased tracking ability at the anti-resonance point.

Namely.

In FIG. 5, the tracking ability level of the pickup is improved to approximately the line shown at 16'.

FIG. 3 shows a pickup device according to a second embodiment of the present invention. In the same figure, the difference from FIG. 1 is a comparator 20. Takarajima contact pressure application circuit 9. This is because the adder 14 is provided.

The operation of the pickup device configured as described above will be explained.

In this embodiment, as in the conventional pickup device, a constant contact pressure is always applied to the scanning element by the Takarajima contact pressure applying circuit 9. This constant contact pressure (specified circumferential contact pressure) is determined by the vibration level of the disk at 15
This is a value that ensures the minimum necessary follow-up margin M for the pickup with respect to the expected upper limit level of .

The acceleration amplitude of the disk vibration weighted by the low-pass filter 19 is compared with the acceleration amplitude that the pickup can follow under a specified contact pressure by a comparator 20. That is, an insufficient amount of follow-up margin is detected under the specified contact pressure. Then, the current according to this indefinite amount is
This is added to the specified current from the Takarajima contact pressure applying circuit 9.

As described above, the comparator 20 and the Takarajima contact pressure application circuit 9
By providing the adder 14 and the adder 14, the same effects as in the first embodiment can be obtained.

(Effects of the Invention) According to the present invention, there is provided a means for detecting the vibration acceleration of a disk, and a transmission whose peak frequency and peak value match the frequency and resonance value of the anti-resonance point of the mechanical impedance in the scanning element part of the pickup vibration system. By providing a low-pass filter having specific characteristics and a means for applying the contact pressure of the scanning element to the disk according to the vibration acceleration and weighted according to the transmission characteristics of the low-pass filter, the necessary application can be achieved according to the mechanical impedance characteristics of the pickup. Contact pressure is applied to the scanning element, and a sufficient follow-up margin for the pickup can be ensured over a wide frequency band, which has great practical effects.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a pickup device according to a first embodiment of the present invention, FIG. 2 is a diagram showing the transfer characteristics of a low-pass filter 19, and FIG. 3 is a block diagram of a pickup device according to a second embodiment of the present invention. 4 is a block diagram showing an example of a conventional pickup device, and FIG. 5 is a diagram showing the relationship between disk vibration and tracking ability of the pickup. DESCRIPTION OF SYMBOLS 1... Scanner, 2... Disk, 3... Scanner holder, 4... Lead wire, 5... Cantilever, 6... Magnet, 7... Elastic support, 8 ... Electromagnetic coil, 9... Takarajima contact pressure application circuit, 10... Switch signal, 11... Drive circuit, 12... Signal detector, 13... Output drop detection circuit, 14...・Adder, 15... Vibration level of the disk, 16... Tracking ability level of the scanner,
16'...Following ability level of pickup, 17...
- Sensor, 18... Acceleration detection circuit, 19... Low pass filter, 20... Comparator. Figure 3 1-Scanner 2-1. Task 31. . Scanner holder 4'J-F ¥57. -Creshishiba 5-, Vdene-, h70. Tan sexual intercourse 4η book 8-5. Juusu coil 10 people, 7 chii Ancient and modern Figure 2 Figure 4 Figure 5 Figure 15 - Vibrating bell with Te°l

Claims (1)

[Claims] a vibration system in which a scanner is attached to the tip of a pickup arm whose rear end is elastically supported and reads a signal by contacting the information recording disk; and means for detecting vibration acceleration of the information recording disk. , a low-pass filter having a transmission characteristic whose peak frequency and peak value approximately match the frequency and resonance value of an anti-resonance point of the mechanical impedance in the vibration direction of the information recording disk in the scanning element section of the vibration system; A pickup device comprising means for applying a contact pressure to the information recording disk according to the vibration acceleration and weighted according to the transmission characteristic of the low-pass filter.