Pioneer-CX916-tape-cdm 电路图 维修手册.pdf

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1、ModelService ManualCD Mechanism ModuleMechanism Unit DEH-P400/X1N/UC DEH-P4000/X1N/UCCRT2308CXK5200CXB3100 DEH-P4050/X1N/ES DEH-P3000R/X1N/EWCRT2309CXK5200CXB3100 DEH-P200/X1N/UC DEH-P300/X1N/UCCRT2310CXK5200CXB3100 DEH-P3000/X1N/UC DEH-P20/X1N/UC DEH-P2000/X1N/UCCRT2311CXK5200CXB3100 DEH-P2050/X1N/

2、ES DEH-2000R/X1N/EW DEH-2020R/X1N/GRCRT2312CXK5200CXB3100 DEH-2030R/X1N/EW DEH-10/X1N/UC DEH-1000/X1N/UCCRT2313CXK5200CXB3100 DEH-1050/X1N/ES PIONEER ELECTRONIC CORPORATION4-1, Meguro 1-Chome, Meguro-ku, Tokyo 153-8654, Japan PIONEER ELECTRONICS SERVICE INC. P.O.Box 1760, Long Beach, CA 90801-1760 U

3、.S.A. PIONEER ELECTRONIC EUROPE N.V. Haven 1087 Keetberglaan 1, 9120 Melsele, Belgium PIONEER ELECTRONICS ASIACENTRE PTE.LTD. 253 Alexandra Road, #04-01, Singapore 159936 C PIONEER ELECTRONIC CORPORATION 1998 K-FZA. DEC. 1998 Printed in Japan ORDER NO. CRT2300 CD MECHANISM MODULE CX-916 - This servi

4、ce manual describes the operation of the CD mechanism incorporated in models listed in the table below. - When performing repairs use this manual together with the specific manual for model under repair. CONTENTS 1. CIRCUIT DESCRIPTIONS.2 2. MECHANISM DESCRIPTIONS.17 3. DISASSEMBLY .18 RadioFans.CN

5、收音机爱 好者资料库 2 CX-916 1. CIRCUIT DESCRIPTIONS The LSI (UPD63710GC) used on this unit comprises five main blocks ; the pre-amp section, servo, signal processor, DAC and CD text decoder (not used on this model). It also equips with nine automatic adjustment functions. 1.1 PRE-AMP SECTION This section pr

6、ocesses the pickup output signals to create the signals for the servo, demodulator and control. The pickup output signals are I-V converted by the pre- amp with the built-in photo-detector in the pickup, then added by the RF amp to obtain RF, FE, TE, TE zero cross and other signals. This pre-amp sec

7、tion is built in the servo LSI UPD63710GC (IC201). The following describes function of each section. Since this system has a single power supply (+5V), the reference voltage for this LSI and pickup are set to REFO (2.5V). The REFO is obtained by passing the REFOUT from the LSI through the buffer amp

8、lifier. The REFO is output from Pin 89 of this LSI. All measurements are done using this REFO as reference. Note : During the measurement, do not try to short the REFO and GND. 1) APC Circuit (Automatic Power Control) When the laser diode is driven with constant current, the optical output has large

9、 negative temperature characteristics. Thus, the current must be controlled from the monitor diode so that the output may be constant. APC circuit is for it. The LD current is obtained by measuring the voltage between LD1 and V+5. The value of this current is about 35mA. 71 72 74 76AGCI 77RFO 75 78

10、79 80 73 91 90 93 92 C-3T FEO FE- TEO TE- 85 86 87E 97PD 99PN F D 82 83 84B C A RF- EQ1 EQ2 AGCO RFI ASY EFM PEAK DET. LPF BOTTOM DET. S/H D/A A/D D/A A/D 94 98 TE2 LD VREG GND APN LDON EFM DEFECT FOK A3T MIRR To the following stage of the LSI Vref Vref Vref Vref Vref Vref Vref Vref Vref Vref Vref V

11、ref Vref Vref Vref Vref(+2.5V) 97 PD 99 PN 98 LD VREG GND AMP_PN (H:Nch L:Pch) LDON (H:LD MOVE L:STOP) Vref Vref(+2.5V) 14 5 R102 10 R101 12 Q101 2SB1132 C102 0.1F C103 100F/6.3V PU UNIT R103 2.2k C105 0.33F +5V 1k 110k 3p 3p 150k 100k 100k 16k 1k Fig.1 : BLOCK DIAGRAM OF BUILT-IN RF AMPLIFIER Fig.2

12、 : APC CIRCUIT RadioFans.CN 收音机爱 好者资料库 CX-916 3 2) RF Amplifier and RFAGC Amplifier The photo-detector outputs (A + C) and (B + D) are added, amplified and equalized on this LSI and then output to the RFI terminal as the RF signal. (The eye pattern can be checked by this signal.) The RFI voltage low

13、 frequency component is : RFI = (A + B + C + D) 3.2 RFI is used on the FOK generator circuit and RF offset adjusting circuit. R214 is an offset resistor for maintaining the bottom reference voltage of the RFI signal at 1.5 VDC. The D/A output used for the RF offset adjustment (to be described later)

14、 is entered via this resistor. After the RFI signal from Pin 77 is externally AC coupled, entered to Pin 76 again, then amplified on the RFAGC amplifier to obtain the RFO signal. The RFAGC adjustment function (to be described later) built-in the LSI is used for switching feedback gain of the RFAGC a

15、mplifier so that the RFO output may go to 1.5 0.3Vpp. The RFO signal is used for the EFM, DFCT, MIRR and RFAGC adjustment circuits. 3) RFOK Circuit This circuit generates the signal that is used for indicating the timing of closing the focus or state of the focus close currently being played. This s

16、ignal is output from Pin 4 as the FOK signal. It goes high when the focus close and in-play. The RFOK signal is generated by holding DC level of the RFI at its peak with the succeeding digital section, then comparing it at a specific threshold level. Thus, the RFOK signal goes high even if the pit i

17、s absent. It indicates that the focus close can take place on the disc mirror surface, too. This signal is also supplied to the micro computer via the low pass filter as the FOK signal and used for the protection and the RF amplifier gain switching. CN101 84 6 13 83 82 10k 10k 85 FOK CIRCUIT A/D 4 A

18、+C 16k B+D 10k 16k 10k R214 12k C209 3pF R212 10k R207 1.8k C206 27pF R213 10k 807974757677 D/A 12k 66 10k RFOAGCIRFI C207 0.22F C206 3900pF FOK TO EFM CIRCUIT Fig.3 : RFAMP, RFAGC AND FOK CIRCUIT RadioFans.CN 收音机爱 好者资料库 4 CX-916 Fig.5 TRACKING ERROR AMPLIFIER AND TRACKING ZERO CROSSING AMPLIFIER 4)

19、 Focus Error Amplifier The photo-detector outputs (A + C) and (B + D) are passed through a differential amplifier and an error amplifier, and then (A + C B D) is output from Pin 91 as the FE signal. The FE voltage low frequency component is : FE = (A + C B D) = (A + C B D) 5 Using REFO as the refere

20、nce, an S-curve of approximately 1.5 Vpp is obtained for the FE output. The final-stage amplifier cutoff frequency is 11.4 kHz. 5) Tracking Error Amplifier The photo-detector outputs E and F are passed through a differential amplifier and an error amplifier, and then (E F) is output from Pin 93 as t

21、he TE signal. The TE voltage low frequency component is : TE = (E F) = (E F) 5.7 (Effective LSI output is 5.0). Using REFO as the reference, the TE waveform of approximately 1.3 Vpp is obtained for the TE output. The final-stage amplifier cutoff frequency is 20 kHz. 6) Tracking Zero Crossing Amplifi

22、er TEC signal (the tracking zero crossing signal) is obtained by multiplying the TE signal four times. It is used for locating the zero crossing points of the tracking error. The zero cross point detection is done for the following two reasons : 1 To count tracks for carriage moves and track jumps.

23、2 To detect the direction in which the lens is moving when the tracking is closed (it is used on the tracking brake circuit to be described later). The TEC signal frequency range is 300 Hz to 20 kHz. TEC voltage = TE level 4 Theoretical TEC level is 5.2V. The signal exceeds D- range of the operation

24、al amplifier and thus is clipped. It, however, can be ignored since this signal is used by the servo LSI only at the zero crossing point. 20k CN101 84 6 13 83 82 10k 20k 85 A+C 16k B+D 48k 16k 10k 9190 D/A 80k 110k FE C210 220pF R200 300k A/D FE OFFSET TO DIG. EQ48k 38k CN101 9 11 86 56k 38k 87 F E

25、F 224k E 48k 224k 56k 9392 D/A 80k 110k TE C211 100pF A/D TE OFFSET TO DIG. EQ 48k R216 27k R215 27k 60k 20k 95 94 TE2 TEC R210 0 C212 6800pF 16k 10k (80k/300k) 20k Fig.4 : FOCUS ERROR AMPLIFIER 224k (56k+27k) 80k 38k CX-916 7) DFCT (Defect) Circuit The DFCT signal is used for detecting defects on t

26、he mirrored disc surface. It allows monitoring from the HOLD pin (Pin 2). It goes high when defects are found on the mirrored surface. The DFCT signal is generated by comparing the RF amplified signal (which is obtained by bottom holding the RFO signal) at a specific threshold level by the succeedin

27、g digital section. Stains or scratches on the disc can constitute the defects on the mirrored disc surface. Thus, as long as the DFCT signal remains high in the LSI, the focus and tracking servo drives are held in the current state so that a better defect prevention may be ensured. 8) 3TOUT Circuit

28、The 3TOUT signal is generated by entering disturbance to the focus servo loop, comparing phase of fluctuations of the RF signal 3T component against that of the FE signal at that time, then converting the signal to DC level. This signal is used for adjusting bias of the FE signal (to be described la

29、ter). This signal is not output from the LSI, thus its monitoring is not available. 9) MIRR (Mirror) Circuit The MIRR signal shows the on track and off track data, and is output from Pin 3. When the laser beam is On track : MIRR = L Off track : MIRR = H This signal is used on the brake circuit (to b

30、e described later) and also as the trigger to turn on track counting when jumping take place. The MIRR signal is supplied to the micro computer, too, for the protection purpose. A/D MIRR CIRCUIT 3T CIRCUIT DFCT CIRCUIT BOTTOM DETECT BOTTOM DETECT PEAK DETECT LPFS/H A/D A/D 76 75 73 3 2 40k 20k 20k 4

31、0k 40k 40k 200k 200k C205 0.1F C3T AGCI RFO 12k 10k 20k 30k MIRR HOLD Fig.6 : DFCT, MIRR AND 3T DETECTION CIRCUIT Fig.7 : HOLD OUTPUT WAVEFORM (When surface defects are present) Fig.8 : MIRR OUTPUT WAVEFORM (When an access is made)5 Surface defects RFI HOLD RFI MIRR OFF TrackON Track 6 CX-916 10) EF

32、M Circuit This circuit is used for converting the RF signal to digital signal consisting of “0” and “1”. The RFO signal from Pin 75 is externally AC coupled, entered to Pin 74, then applied to the EFM circuit. Loss of the RF signal due to scratches or stains on the disc, or vertical asymmetry of the

33、 RF due to variations in the discs manufactured cant be eliminated by AC coupling alone. This circuit, therefore, controls the reference voltage ASY on the EFM comparator by use of the fact that “0” and “1” appear fifty fifty in the EFM signal. By this arrangement, the comparate level is constantly

34、maintained at almost center of the RFO signal level. The reference voltage ASY is generated when the EFM comparator output is passed through the low pass filter. The EFM signal is output from Pin 71. It is a 2.5 Vp-p amplitude signal centering on REFO. 74 RFI 40k 40k C206 3900pF 72 71 ASY EFM 40k 40

35、k15k75k 2k R205 10k R206 39k C203 0.1F C204 3300pF EFM. SIG Fig.9 : EFM CIRCUIT 7 CX-916 1.2 SERVO SECTION (UPD63710GC : IC201) The servo section controls the operations such as error signal equalizing, in focus, track jump and carriage move. The DSP is the signal processing section used for data de

36、coding, error correction and interpolation processing, among others. This circuit implements analog to digital conversion of the FE and TE signals generated on the pre-amplifier, then outputs them through the servo block as the drive signal used on the focus, tracking and carriage system. The EFM si

37、gnal is decoded on the signal processing section and finally output via the D/A converter as the audio signal. The decoding process also generates the spindle servo error signals which is fed to the spindle servo block to generate the spindle drive signal. The focus, tracking, carriage and spindle d

38、rive signals are then amplified on the driver IC BA5985FM (IC301) and fed to respective actuators and motors. 1) Focus Servo System The focus servo main equalizer is consisted of the digital equalizer. Fig.10 shows the focus servo block diagram. When implementing the focus close on the focus servo s

39、ystem, the lens must be brought within the in-focus range. Therefore, the lens is moved up and down according to the triangular focus search voltage to find the focus point. During this time, the spindle motor is kicked and kept rotating as a set speed. The servo LSI monitors the FE and RFOK signals

40、 and automatically carries out the focus close at an appropriate point. The focus closing is carried out when the following three conditions are met : 1 The lens approaches the disc from its current position. 2 RFOK = H 3 The FZC signal is latched at high after it has once crossed the threshold set

41、on the FZD register (Edge of the FZD). As the result, the FE ( = REFO) is forced to low. FE AMP DIG. EQ 82 A+C B+D FD FOP FOM IC301 BA5985FM LENS IC201 UPD63710GC 85 6227 16 15 FOCUS SEARCH TRIANGULAR WAVE GENERATOR DACCONTROL A/D R309 47k Fig.10 : FOCUS SERVO BLOCK DIAGRAM 8 CX-916 When the above c

42、onditions are all met and the focus is closed, the XSI pin goes to low from the current high, then 40 ms later, the microcomputer begins to monitor the RFOK signal after it that has been passed through the low pass filter. When the RFOK signal is recognized as low, the micro computer carries out var

43、ious actions including protection. Fig.11 a series of operations carried out relevant to the focus close (the figure shows the case where focus close is not available). You can check the S-curve, search voltage and actual lens behavior by selecting the Display 01 for the focus mode select in the tes

44、t mode, and then pressing the focus close button. REFO FD LENS POSITION RELATIVE TO DISC NEAR FAR JUST FOCUSED MD REFO Expanding around Just Focused Point REFO RFI FOK FE FZD THRESHOLD LEVEL FZD (INTERNAL SIGNAL) Focus closing would normally take place at these points XSI (IN THE EVENT FOCUS IS CLOS

45、ED) LEVEL Fig.11 : FOCUS CLOSE SEQUENCE 9 CX-916 2) Tracking Servo System The digital equalizer is employed for the main equalizer on the tracking servo. Fig.12 shows the tracking servo block diagram. a) Track jump When the LSI receives the track jump command from the microcomputer, the operation is

46、 carried out automatically by the auto sequence function of the LSI. This system has five types of track jumps used for the search : 1, 4, 10, 32 and 32 3. In the test mode, in addition to three jumps (1, 32 and 32 3), move of the carriage can be check by mode selection. For track jumps, the microco

47、mputer sets almost half of tracks (5 tracks for 10 tracks, for instance) and counts the set number of tracks using the TEC signals. When the microcomputer has counted the set number of tracks, it outputs the brake pulse for a fixed period of time (duration can be specified with the command) to stop

48、the lens. In this way, the tracking is closed and normal play is continued. To improve the servo loop retracting performance just after the track jump, the brake circuit is turned on for 50 ms after the brake pulse has been terminated to increase gain of the tracking servo. Fast forward and reverse

49、operations are realized by through consecutive signal track jumps. The speed is about 10 times as fast as that in the normal mode. TE AMP DIG. EQ 86 F E TD TOP TOM IC301 BA5985FM LENS IC201 UPD63710GC 87 6324 17 18 JUMP PARAMETERS DACCONTROL A/D R310 47k t1 t2 GAIN NORMAL TD KICK BRAKE TEC T. BRAKE EQUALIZER T. SERVO CLOSED OPEN NORMAL GAIN UP OFF ON t1 TD TEC (10 TRACK) EQUALIZER T. BRAKE SERVO SD 2.9mS (4.10 TRACK JUMP) 5.8mS (3