Technics-SJMD-100-Service-Manual电路原理图.pdf

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1、WARNING This service information is designed for experienced repair technicians only and is not designed for use by the general public. It does not contain warnings or cautions to advise non-technical individuals of potential dangers in attempting to service a product. Products powered by electricit

2、y should be serviced or repaired only by experienced professional technicians. Any attempt to service or repair the product or products dealt with in this service information by anyone else could result in serious injury or death. 1999 Matsushita Electric Industrial Co., Ltd. All rights reserved. Un

3、authorized copying and distribution is a violation of law. ORDER NO. AD9903069S2 Colour (K) . Black Type Areas (E) . Europe. (EB) . Great Britain. (EG). Germany. SJ-MD100 Minidisc Deck $ This document is supplementary to the following Service Manual: Supplement for technical information about MD. $

4、Contents Area Code (E) (EB) (EG) Order No. MB9902001C2 Model No. SJ-MD100 1. Measuring instruments and special tools $ Purpose O ROMPart No.: RFKV0006 O ROMPart No.: RFKV0014 O Extension Cable Kit Part No.: RFKZJMD100EK O Laser Power MeterModel No.: LE8010 Made by Laser Electric Test Disc Extension

5、Cable Kit Laser Power Meter 2. Basic Knowledge of MD 3. Operating Procedures 4. Troubleshooting Guide for MD Servo Circuit SJ-MD100 2 Construction of magnet optic disc U Construction of an MDY The playback-only MD and the recordable MD are exactly identical in size and shape. Y The figure below is a

6、 cross-sectional diagram of an MD disc. The diameter of an MD disc is 6.4 cm, approximately half that of a CD, and the thickness is 1.2 mm, the same as a CD. Similar to a CD, only one side of an MD disc is used to store data. U Materials used in an MDY The MD disc is made of polycarbonate, the same

7、material that is used for a CD. Polycarbonate is a type of engineering plastic that is highly resistant to temperature and humidity, as well as having excellent wear and impact resistant. Y A clamping plate is mounted in the center of the MD disc, and when the MD is loaded into a player, a magnet in

8、 the player attracts that metal plate to secure the disc in place. If the MD disc were to be secured by clamping it from above and below similar to a CD, it would be necessary to have a hole pass through the center of the MD cartridge, which would reduce the amount of space available for attaching a

9、 label. By using this magnetic method of securing the disc, the entire front side of the MD cartridge can be used as a label area. Y Because of the metal plate mounted at the center of the MD disc, the center of the cartridge is 2 mm thick, slightly thicker than the rest of the cartridge. Y To prote

10、ct the MD disc from dust, fingerprints, and other things that might hinder the reading of the recorded signals, the disc is stored inside a cartridge similar to that of a floppy disc. When the MD is loaded into a player, the shutter on the cartridge is opened and the disc is ready to be played. Y Fo

11、r a recordable MD, because there is no need for a recording head and it is only necessary for a laser beam to be directed at the underside of the disc, the shutter is located only on the back of the cartridge. Y For a playback/record magnet optic disc MD, because it is necessary for the recording he

12、ad and the laser beam to be able to access both sides of the disc, the shutter is located on both sides (upper shell and lower shell) of the cartridge. $ Basic Knowledge of MD T Definition of an MD and the types of MDs Y MD stands for mini disc. Y Similar to a music CD, an MD is also a small disc ca

13、pable of recording and playing back digital sound. Y There are 2 types of MDs, a optical disc for playback-only MD and a magnet optic disc for recordable MD that is capable of both recording and playback. Y A playback-only MD is merely a smaller-diameter version of a CD. Just like a CD, the signals

14、are read by light striking pits on the surface of the disc. Y With a magnet optic disc MD(Recordable MD) that is capable of both recording and playback, recording is per- formed by a vertical magnetization system in which a magnetic thin film on the surface of the disc is heated by a laser beam, and

15、 magnetism is applied in accordance with the data (audio signal) being recorded. Y When a recordable MD is played back, a laser beam weaker than that used during recording strikes the disc and is reflected back, and the reflected light is twisted (polarized) in accordance with whether the magnetized

16、 direction is upward or downward, causing the reflected light to rotate very slightly clockwise or counterclockwise. Those subtle differences in the reflected light are picked up by two light-receiving elements and detected as either a 1 or a 0 by reading whether there is electrical current or no el

17、ectrical current. Y If an MD were recorded in the same way as a CD, it would only have about 15 minutes of recording time. However, by using a new signal compression technology called ATRAC that was specifically developed for MDs, the signals are compressed to approximately one-fifth, making it poss

18、ible to record for an extended time of 74 minutes, the same as with a CD. (Blank MDs are currently marketed in two recording times, 74 minutes and 60 minutes.) Y Although MDs were originally developed for use in recording and playing back music, in July 1993 the MD data standard was established. By

19、using an MD data+music player, MDs can be used as external memory storage media for computers, and a single MD has a storage capacity of 140 MB, equivalent to about 100 floppy discs. U What is an MD? U Two types of MDs U Playback-only MD is same as a CD. U Recordable MD uses magnet optic recording.

20、U Playback of a Recordable MD U 74-minute recording time U Can also be used on a computer. T Construction of an MD MD disc form SJ-MD100 3 D Recording on a magnet optic disc U Can be recorded and played back repeatedly. U Recording principle U Vertical magnetization system U Number of recordings pos

21、sible Y By using a magnet optic disc, digital signals can be recorded and played back over and over again. Y To record on a magnet optic disc, a laser beams momentarily heats pin spots on the magnetic film on the back of the disc and a magnetic field is applied from the other side of the disc. Thus,

22、 both sides of the disc must be accessed in order to record. Y To explain the recording principle, we will assume that the directions of the magnetism on an unrecorded disc are all facing downward (south-north = 0 0 0 0 .). (Actually on an unrecorded disc the directions are random.) Y Thus, to recor

23、d the signals 1 0 1 1 0 1 0, the direction of the magnetism at the locations where 1 is to be recorded must be changed to face upward (north-south). Because the magnetic film is strongly magnetic, once a downward-facing magnetism is recorded, it is not easy to change it to an upward-facing magnetism

24、. Y By directing a laser beam at the magnetic film, the temperature of the location that the laser beam strikes rises to the Curie temperature (recordable MD; about 180pC), eliminating the magnetic force (retention force). (Because the magnetic film is strongly magnetic, similar to a permanent magne

25、t, once it is magnetized it has a strong retention force. In order to eliminate that retention force, it is irradiated with a laser beam so that the temperature rises to the Curie temperature.) Y After the magnetism of the specific location is eliminated, an external magnetic field with an upward di

26、rection (north-south) is applied, thus changing the direction of the magnetism at that location to face upward (north-south). Y Conversely, if a downward-facing (south-north) external magnetic field is applied, the direction of the magnetism at that location is changed to face downward (south-north)

27、. Y Then, when the disc rotates and the location which has been changed to upward-facing magnetism leaves the laser spot, the temperature of the magnetic film drops, and the upward-facing magnetism recorded at that location is retained. Y In this way, digital signals of 1 (upward-facing magnetism) a

28、nd 0 (downward-facing magnetism) are recorded on the tracks on the disc. Y With a conventional magnetic recording tape, the magnetic material is magnetized parallel (horizontal) to the surface of the tape. A magnet optic disc, however, uses a vertical magnetization system in which the magnetic poles

29、 are recorded perpendicular (vertical) to the disc surface. Because the magnetism is recorded vertically rather than horizontally, much more data can be recorded in a smaller area. Y A magnet optic disc can be recorded more than 1 million times, so it can virtually last forever. w w w w w w w w w w

30、w w w w w S i w w w w w w w w w w w w w w w N Only locations struck by a powerful laser beam (reach the Curie temperature) lose their magnetism retention force. B Assuming that the directions of the magnetism on the unrecorded disc are all facing downward (they may also all face upward). A Disk rota

31、tion direction Disk rotation direction Laser spot i w w w q w t w w q q q w w q i w w w w w t w w w w w w w N An external magnetic field is applied to the demagnetized location, creating upword-facing magnetism. C Recorded signals. Directions of magnetism differ according to whether a 1 or a 0 digit

32、al signal is recorded. D Disk rotation direction Disk rotation direction Laser spot S 0 0 0 1 0 1 0 0 1 1 1 0 0 1 BA CD Upword : 1 Downword : 0 Surface of the disk is a magnetic thin film made of terbium-cobalt alloy. Heated External magnetic field is applied. Magnet optic disc recording principle V

33、ertical magnetizationHorizontal magnetization SJ-MD100 4 Y Because the signals on a magnet optic disc are recorded vertically as north-south and south-north magnetism, the north and south magnetic poles appear on the surface of the discs magnetic film. These signals are played back utilizing a pheno

34、menon called the Kerr effect which occurs when a weak laser beam strikes the magnetic poles. Y Light has wave vibration directions called planes of polarization. (Polarization refers to a light wave which vibrates only in a fixed direction.) Y With normal light, because the wave vibration directions

35、 are all mixed, no planes of polarization appear. Y Because a laser beam is artificially generated light, it is possible to align the planes of polarization. Y When a laser beam strikes something that has a magnetic field, the direction of the plane of polarization of the reflected light varies very

36、 slightly in accordance with whether the magnetism is north polarity or south polarity. When playing back a magnet optic disc MD, these slight changes in the direction of the plane of polarization are read. Y To further explain the principle used to read the signals recorded on a magnet optic disc,

37、first a laser beam is directed at the disc. If the direction of the magnetism recorded on the disc is upward (north polarity), the plane of polarization of the light reflected from the disc rotates very slightly clockwise as a result of the Kerr effect. Conversely, if the direction of the magnetism

38、is downward (south polarity), the plane of polarization rotates very slightly counterclockwise. Y When the reflected laser light is passed through a Wollaston prism, the light is distributed to photo detector 1 if the direction of rotation is clockwise or to photo detector 2 if the direction of rota

39、tion is counterclockwise. Y The light striking the two light receiving elements is converted into electrical current and a subtraction is performed. If the result of A-B is plus, a 1 is detected, and if the result of A-B is minus, a 0 is detected. Y An MD player is compatible with both optical recor

40、ding and magnetic recording, changing the reading system in accordance with the type of disc that is loaded. D Playback of a recordable MD U Playback of a recordable MD U Reading of magnetic signals Changes in the polarization axis due to the Kerr effect Playback of recordable MD SJ-MD100 5 Y The si

41、gnals recorded on an MD are rewritten using a new process called “magnetic field modulation overwriting”*. Y In this process, a laser beam spot of about 5 mW is focused on the location on the disc to be rewritten, heating that location to the Curie temperature (180pC) and thus canceling the magnetiz

42、ation. Y At the same time, current flows to the optical pickup and to the magnetic head opposite it, between the two of which the disc is held, thus generating a magnetic field. Y When the disc revolves so the laser spot moves from the location to be rewritten, the temperature drops below the Curie

43、temperature and the magnetic field generated by the magnetic head re-magnetizes that location. Y At this time, if the direction of the current flowing to the magnetic head is reversed in accordance with whether the data being recorded is “1” or “0”, the direction of the magnetic field also changes b

44、etween north and south, and accordingly, the direction of the magnetization of the recording film changes between upward-facing and downward- facing. Thus, it is possible to directly magnetize the recording film on the disc in accordance with the “0” and “1” digital signals. Y Thus, the new recordin

45、g data is overwritten regardless of the direction of the previously recorded magnetization, eliminating the need for an erasing head. Y This process is called “magnetic field modulation overwriting”. Y Because this “magnetic field modulation overwriting” makes it possible to directly overwrite the n

46、ew signals on top of the old signals in a single process, re-recording on a MD is just as easy as with a magnetic tape, making the MD ideally suited for use in personal audio equipment. D Rewriting action of a magnet optic disc U MD rewriting process U No need for a erasing head Magnetic field modul

47、ation overwriting *Overwrite means to write new data while erasing the old data. SJ-MD100 6 Y With a disc, high-speed random access is possible, something which is not possible with a tape. Y The optical pickup moves quickly in the radial direction, thus directly accessing the start of each track. Y

48、 With an optical disc, which is capable of playback only, the addresses in the TOC (table of contents) in the lead-in area are all read beforehand in order to access the start of each track. Y With a recordable MD, which is capable of both recording and playback, blank guide grooves, called “pre-gro

49、oves”, are formed around the entire surface of the disc at the production stage. Y As shown in the illustration below, the pre-grooves wobble very slightly in a regular pattern, and that curve is fine- modulated (at intervals of 13.3 ms) to record beforehand the addresses of the continuous time data. Y Technically speaking, the pre-grooves in the disc is not perfect spiral but is wobble with : a typical amplitude of 30 nm. a spatial period of 54 to 64 m. When this wobble is locked to a frequency of 22.05 kHz, the velocity of the disc should be i