Luminous Audio
Chapter Prcis Integrated A Rebirth of Cool
October 2006 Associated Equipment: Analog Front End
Fanfare FT-1A Digital/Analog FM Monitor

Digital Front End

Marantz SA8260/high frequency digital filter for SACD turned off iRiver iHP-140 (upgraded hard drive from 40 to 60 Gigabytes) Toshiba Gigabeat S60 (WMA Lossless files only)

Amplification

A new Chapter in our lives It just keeps getting better and man, do I love this crazy world of music-playback. Thats what Ive been saying to myself in the afterglow of my experiences with Chapters Prcis Class D integrated Amp. Once again Ive had the pleasure of listening to a piece of equipment that served the music in the way I passionately need and like.
Monolithic Sound PA-1 Line Stage/HC1 Power Supply I had spent several wonderful months more than ever enjoying reproduced music via a pair of Nuforce Reference 8 monoblocks. So Nuforce
Reference 8 paired Monoblocks Nuforce Reference 9 paired Monoblocks

Loudspeakers

you might imagine how distressed I, being challenged-of-wallet, was to receive that inevitable call from Stereo Times editor stating Yo Al, I need the review loaners back. The manufacturer would like to do some upgrades to the units you have Damn Inspect bank account Damn againOh well I performed my usual ritual of procrastination getting the NuForces back since it was the best my system had ever sounded and several of my musician friends could attest to that. Fortunately upon my relinquishing the Reference 8s Perry handed over a Class D integrated amp from a British audio company, Chapter, whom I had never before known. Perry instructed me to give their US distributor a call but I chose not to call them until after finishing this review for fear of tainting my impressions of the review sample. (It may sound silly but Im not found of chatting with a manufacturer or even a distributor during the review process unless I feel a product is damaged or operating in a manner that might need professional repair.) Fit, Finish & Design Elements The chassis is made from bead blasted aluminum alloy that sits upon its own integral base vibration control system. The metalwork is machined by an ISO 9002 quality assured firm local to Chapters offices. On top are 8 wire-mesh covered circular air vents and a single, larger convex circular looking glass which impart an almost art-deco industrial feeling that is striking while at the same time not overwhelming in its design. The looking glass allows a clear and magnified view of the Prcis meticulously placed innards.

Thiel 2.2

Cabling
Straightwire Crescendo Interconnects Straightwire Black Silc Speaker Cables PS Audio Mini Lab Power Cables Analysis Plus Power Oval Cable Soundstring Cable Technologies Power Cable (on each NuForce monoblock)

Power Conditioning

On the front is a wide, clear, and well lit graphical display for device information. Just below the display resides a single rotary knob that PS Audio P300/Multiwave controls all of the Prcis functions. To the left of this knob is 3.5 mm auxiliary input or as Chapter puts it an Ipod input. (Note to Chapter, Upgrade for we dont ALL use only Ipods more on this later.) To the right of the front end knob is the infra-red sensor. components including For the Prcis, Chapter chose to use their very own custom designed preamp volume control potentiometer. PS Audio Ultimate Outlet According to Chapters literature The Chapter Prcis uses a very low (15 Amp Standard) for noise, linear power supply to deliver power to the pre and power sections of the amplifier. Using an 800VA custom made screened Amp only transformer and 300,000uF of capacitance, allows the Prcis to deliver Accessories unmatched deep bass performance, with a deft and delicate touch. Long after it was gone I was taking great pleasure enjoying photos of it

Musicalizer ML 206 Bright Star Big Rock Three under SACD/CD player Room Tunes Junior Justarack main components Lovan Classic HiFi Rack for PS Audio p300 Vibrapods for HC1 power supply only DIY line filters made by a friend placed in 1 empty wall socket next to PS Audio P300 Room Treatments
in my system. (Yes, that might sound pathetic but this is one fascinating piece of equipment!) In some ways it looked even more stunning in my well lit photos than in person. The remote is a very substantial feeling unit apparently built from the same alloy as that of the Prcis chassis. It feels good in the hand and indicates fine quality. Chapter was thoughtful enough to attach 4 translucent rubber or maybe silicone grommets to the underside of the remote as to avoid damaging ones furniture. The manual that accompanied the Prcis was thorough, clear and very informative of not only operating it but also of its features, design elements, and machining. Chapter has put a strong foot forward in its manual that gives the user not only a clear understating of the operation of the Prcis but also a healthy dose of information about the build, and technology of what theyve purchased. For an even more detailed explanation of the Prcis parts build I refer you to its impressive online manual in PDF format here. Setup
Getting the Prcis up and running proved frustratingly difficult in my setup with my Strategically large, unwieldy placed curtains speaker cables. directly behind Unfortunately the system covering power mains input is windows directly to the left of Corner Busters the speaker posts (4) when looking at the rear of the integrated. Subsequently, connecting the power cable required a tiresome amount of gerrymandering. This forced my stiff Straightwire Blac Silc spadeterminated speaker cable to protrude directly from the side of the amp just over the Mains input jack and switch. (This probably would have been a non-issue if I had used the banana pin terminated cables more prevalent with British audiophiles.) I could barely stuff one finger between the positive and negative leads of the speaker cable to turn on the rear AC Mains switch. Granted my speaker cable is bulky but this is a serious design shortcoming that

doesn't maximize the ease of connecting to all speaker cables. Transit had also shown its mark on the Prcis a rear panel Torx head screw was loose, noticeably protruding out from the rear. This was remedied with a Swiss Army Knife Torx wrench. The RCA terminals on input 1 were loose. They twisted when installing and removing the interconnects but tightening up the RCAs securing nuts solved that problem. User interface One of the Prcis most intriguing and pleasing to use design features was its top located, touch sensitive standby mode switch. While the actual power is controlled by a mains switch on the back of the device, switching between on and standby mode is achieved by placing ones hand on a circular touch pad featuring Chapter's logo on top of the device for 2 seconds at which point a halo of blue light around the pad turns to blue, indicating on, or to red indicating the Prcis is in standby mode. When the device is on the front rotary knob is lit blue also. The level of light intensity is selectable and may be turned if preferred. The only drawback was that the 2 second wait was a bit long for my taste. However the tactile involvement with the equipment was satisfying in a nostalgic way while at the same time incorporating modern technology. This is a wonderfully elegant executed design that is commensurate with the price paid for such a high end piece of equipment. A press of the single front knob Sound the beauty is in the details After a long burn in of about a week of random music the Prcis was ready for a thorough inspection. After trying Soundstring and Electraglide power cables for several days I found a simple PS Audio Mini Lab allowed the best performance from the integrated amp. Im saying this up front because the Prcis timing, resolution and perceived levels of distortion were vastly affected by cable choice so
tapping excitement and groove until I put the best matched power cable at my disposal on the integrated. By all means, and if possible be sure to experiment with cables when auditioning this integrated.

Star Sound

The Prcis resolved Wynton Marsalis' Luminous Audio title track "Black Codes" (Columbia CK 40009) with the best inner dynamics Ive ever heard making all the subtleties and technical prowess of Wyntons solo shine more than ever before in my system. All throughout there was an effortless dynamic and harmonic shading that conveyed the little variations of articulation and texture in each soloists story. I heard the most realistic and delicate cymbals ever with gobs of realistic (not euphonic) harmonic bloom. So much so that the cymbals showered the room, - no I stand corrected showered my house with sound without a hint of veil. From his Sabian cymbals to his dark sounding snare down through his fat sounding resonant toms, and down to his meaty rounded bass drum Jeff Tain Watts drum kit had a weight and expansiveness to it on this recording like Ive never before heard in the 20(!) years Ive been listening to this recording. (Im not that old but my god, I just realized Ive been listening to this recording since I was 16!) I suspect the Chapter amps nimble timing aided in rendering such convincing realism. The threshold of volume capabilities before inducing glare and distortion of this amp were fairly astonishing too. At one point on a sunny day I came home and opened the windows and let the system rip on Black Codes. My neighbors across the street, both father and son, have separately remarked weeks later on how beautiful, clean and clear my system sounded. The son even said "I heard you pumping it through the house!" without realizing it was just two speakers. Hearing how this man, who is not an audiophile, spoke of how much he loved the sound and declaring with emphasis it to be "beautiful" was an unbiased testament to how musical and powerful this integrated was. Bass reproduction was considerably more balanced, and nuanced from
dont render the upper bass as convincingly well as this Chapter unit does. The first movement of Mahlers Symphonie #9, conducted by Jess Lpez-Cobas (Telarc 2CD80426l) as played back through the Chapter Prcis was supremely delicate and more harmonically lifelike than any other setup in my system to date. With the volume level set at "00.0" on the Prcis graphical display I missed the slightest bit of the low end bloom and low end extension of the NuForce Reference 8/Channel Islands combo but based on how sensitive this integrated was to my power cable swaps Im confident that this could have been fixed by a higher quality and beefier power cord had I had one available at the time. Still further as I listened to a great many recordings Ive come to the conclusion that the Prcis is more accurate in the bass and the entirety of the musical spectrum than anything I ve ever had in my system and ranks as a first class piece of equipment. The nuances of detail, harmonics, and microdynamics achieved by the Prcis trumped the NuForces sound to no small degree. At the same time, I had to keep in mind I was getting this remarkably wonderful sound with the inexpensive PS Audio Mini Lab power cable. One of the most welcome changes I had with the Prcis was regaining the ability to listen to the radio again. (Yes!) My previous review samples, the NuForce Reference 8s put out so much RFI that my Fanfare FT-1A Digital/Analog FM Monitor was rendered useless. Fortunately for me I was able to once again listen to my favorites of WBGO, WNYC and WQXR broadcast here in the NY City area. I realized how much I was missing by not exploring all the new music or at least music I hadnt heard before on the airwaves at the house. Listening at home and listening in the car are two vastly different experiences and I was once again able to take up the habit of occasionally emailing one of my favorite DJ's, Brian Delp, while he was on air at 2 or 3 AM in celebratory response or just inquiring about music he was playing that I had never heard before. On It's Impossible from Freddie Coles "Merry Go Round" SACD (Telarc-83493-SA) the song reproduction of the instruments was lovingly detailed. The saxophone, sounded natural, full-bodied and rich. The cymbals were appropriately bright. The Prcis effortlessly

conveyed the drummers variety of subtle touch and differentiated the harmonic qualities of his various cymbals to a captivating degree. I could even recognize the engineers mic placement and varied recording techniques without it ever sounding cold, sterile or analytic. The most appreciable aspect was how natural, fleshed-out and rich Freddie Coles voice sounded. It had that right kind of weight without bloat that can be so hard to find in audio. Herbert von Karajans interpretation of the 2nd movement of Beethovens Symphonie no 5 (Deutsche Grammaphon 474 603-2), at the helm of the Berlin Philharmoniker was a display of effortlessly reproduced extremes in dynamics. All the orchestras crescendos and diminuendos were beguilingly conveyed without ever sacrificing truthfulness to the tonal makeup to the orchestra. I never perceived any kind of congestion or distortion of harmonics that would have detracted from my enjoyment of the piece. Set at unity gain, the Prcis drove the Thiels like it owned em and never broke a sweat as it manhandled those 4 ohms speakers. Soundstaging was appropriately layered with excellent Prcis ion of detail both laterally and front to back. Wayne Shorters "Smilin' Through" from Beyond the Sound Barrier (Verve B0004518-02) was the most shockingly dramatic display of the Prcis simultaneously terrific control and seemingly inexhaustible power reserves. John Pattitucis bass was sumptuously portrayed with gobs of texture. Through out the first part of the track Brian Blades colorations with his entire kit were clear crisp and superbly realistic. Cymbal reproduction had Blade's signature warm and earthy sparkle. Ok, I have to really speak as a drummer here the drums sounded RIDICULOUSLY awesome with Blade's dramatic reemergence at 6:28!!!! That first Bass drum hit and the subsequent groove was realized via the Prcis with such authority, weight, and timing that it gave me that goosebump factor that says now this sounds real. At the same time all the complexity of Waynes Quartet being sparked to new levels of interplay was spot-on transparent, engaging and beguiling. The velocity with which the Prcis revealed the musical
intent of that moment was jaw dropping and I literally had to scream and toss up a few expletives. (Sorry mom). No, I didnt have to reach for the volume control even though Im sure the dB levels werent something to wallow in for a long time, but I knew those moments would come and go with out any very long moments so I just sat back and enjoyed the rollercoaster ride. The reproduction of Piano was extremely faithful. At 10:52, the slightest intonations suggested by the sustain pedal and Danilo's damping technique were resoundingly depicted via the Prcis in a way I had never heard before. With the Prcis in place I was able to listen with both my left AND right brain. The dynamics, tonal and harmonic colors being reproduced gave me tons of right brain enjoyment but then at the same time the speed, timing and effortlessness of the amp gave me more than enough information for my left brain to digest. I have to figure the Prcis apparent very low levels of distortion allowed more detail and musical information to make it along those wires to my transducers. This was very, very nearly a real world musical event and Im still basking in the afterglow of it weeks later. Turning to "Bei Mir Bist du Schon" as performed by Regina Carter on I'll be seeing you: a sentimental journey (Verve B0006226-02) with her special guest of Dee Dee bridgewater, I heard a better job of representing Dee Dee's voice than any other amp Ive used with a more faithful midrange and, once again, a truly palpable tonality. Unfortunately the bass was not rendered with as much impact as Im used to hearing so it didn't swing quite as hard as Ive heard before. To my ears the voice stood out more because of the slightly reticent bass. My cymbals on this recording had more distinction between them but not as much euphonic sparkle. For some this might be the exact ticket but for me it didnt invite me into the recording as much as I have with my older amp/preamp combo but then again my perception of my cymbals might be skewed since I spend more time listening to them at a closer range than the mics were placed in the studio. The only real problem was at times I heard the slightest bit of stridency from

Reginas recorded violin sound that I dont recall ever hearing before. Hopefully more Chapters to come The Chapter Prcis offers up a pride of ownership for its physical beauty, exemplary parts build and, most importantly its exceptional sound. It did give me a different perspective of several of my favorite recordings and accordingly I shifted my listening preferences. It seems to favor more modern bass heavier recordings in my system but I must qualify that statement by noting that to get the best tonal balance with it in my system I had to use one of my smaller power cables. At the same time, said power cable is made by one of the most esteemed companies in high end audio power delivery, PS Audio, which more than likely speaks more towards the capabilities of the power cables I had on hand for this review than any kind of shortcoming in the amp. The Prcis does not romanticize while at the same time its clear to my ears that the designers took great care in voicing this integrated amp for maximum musical enjoyment. It relays well recorded music with the least amount of damage Ive ever witnessed in my system. I tried a few pop and R&B recordings from prominent artists and those recordings lack of attention to recording quality shown through loud and clear whereas good recordings sounded good and great ones sounded great. There wasnt any of what I now realized was a slight sonic homogenization I got from my earlier setups. Sadly for me at a price of $6500, this integrated is currently not in my budget. Taking it back to Perry was excruciatingly painful but I will remember my good times with the pages of this Chapter for a very long time to come. Who knows, maybe Ill be able to check a book our two out of the library in the future?

Alvester Garnett

_________________
Specifications: Output Power: 130 Watts into 8 ohms, 260 watts into 4 ohms RMS both channels driven THD + N Less than 0.01% at 1KHz. 22Hz to 22KHz bandwidth IM Distortion Better than -90dB (19+20KHz dual tone test - 1 KHz product at 50W output into 4 ohms Signal to Noise Better than -120dB (22Hz to 22KHz bandwidth). Frequency response DC to 75KHz +0 - 3dB
Cross talk (channel to channel) -100dBv below 50KHz Cross talk (Pre amp stage) -100dB at 1KHz, -90dB at 20KHz, 90dB at 100KHz 1V RMS Input Common mode rejection ratio Less than -90dB (1kHz @ 0dBV) Gain range Minimum to maximum -86dB to +12dB (Pre-amp output) -86dB to +38dB (Amplifier output) Audio inputs Impedance (unbalanced) 47K Ohms Impedance (balanced) 94K Ohms Audio outputs Pre amplifier stage - Balanced Less than 20 Ohms. Power amplifier stage Less than 0.04 ohms. Mechanical Input sockets One pair of XLR for balanced line operation 4 pairs of RCA Phono for single ended operation Output sockets 1 Pair of XLR for Balanced Line operation. 1 pair of RCA for Unbalanced Tape Loop operation. 1 Pair of WBT speaker binding posts per channel Finish Fully bead blasted, anodised aluminium alloy casework. Metalwork machined by a local ISO 9002 quality assured firm. Power on/off Switch and indicator. IEC mains input socket. Weight Approx. 22 Kg Size 437 x100 x300 mm (WxHxD) approx. Price: $6500.00 Importer: Jason Scott Distributing. 8816 Patton Road Wyndmoor, PA 19038 Phone: 800-359-9154 Fax: 215-836-2273 http://www.jasonscottdistributing.com/ Email: sales@jasonscottdistributing.com Manufacturer: Chapter Electronics Ltd 11 Melrose Avenue Kings Hill, West Malling Kent ME19 4SJ United Kingdom Website: www.chapterelectronics.co.uk

Email: info@chapterelectronics.co.uk Telephone: +44 (0)Fax: +44 (0)1392 686795
Don't forget to bookmark us! (CTRL-SHFT-D)

DN02 ID3 DN01 ID3

DN05 ID3

RT01 100

GNDGND

RN03 4.7k

RN07 NC

DN09 NC

QN04 2SA1048

Y.GR DN11

RN04 4.7k

PH26 POWER SW

FOR /F/U/S

LBRN AC12.5V 12 RED AC12.5V 13 ORANGE 2P JH14 YERROW AC3V 15 GREEN 16 BLUE 2 AC9V 18 PURPLE 1 WH1 M-GND GND T1.25A F801 L 250V 1AC8 F822 T800m L 250V A 3AC9 F821 T800m A L 250V 3AC9 F851 T800m L 250V A 8AC12 H1 H2 5AC9 WH02 J801 F852 T800m L 250V A 10AC12 10AC12

RN06 1k

DN08 NC
QN12 2SA1048 Y.GR E3 C 1 QN03 DTC114TS RN11 4.7k 2 MUT1 MUT1
DN12 TMUT2 RN13 100k TMUT2 DIGO
5 CT03 2200p CT04 0.1 GND
GND DN06 4.7V CN02 2.2 50V QN01 DTC114TS 2 RN01 33k 3 1
QN02 2SC2458 C 1 Y,GR 2 B E3 GND

RN12 4.7k

H:MUTE ON L:MUTE OFF
1 GND MUT2 MUT2 RC5S 3 QN11 DTC114TS

RC-5 IN/OUT

GND RC-5 INT/EXT SW
8AC12 H1 H2 5AC9 3AC9 3AC9 DN03 ID3 CN16V DN04 ID3

SF51 GND

RC5F BK5V BK5V RFRFE 4.7k 2 B QFC 2SA1048 CF53 0.1 DF51 RF53 4.7k

AT NO MUTE MUTING ON

74HC04

1A 1Y 2A 2Y 3A 3Y GND

AC9V 4 17

CF54 10/16V

INPUT A H L

OUTPUT Y L H

RF56 4.7k

POWER ON

RF54 10k

AC8V 20 BLUE

0 2SEC

QFC 2SCB 3E

CF52 470p

19 GREEN

RF55 2.2k

CF51 0.1

RF51 22

VCC 6A 6Y 5A 5Y 4A 4Y

JF51 RC-5 IN OUT

TO 4-CHANNEL PCB

COMMAND INTERFACE TO FRONT PCB(PY16)

D806 11EQS10

D853 11EQS10

Q2SK246 V

R853 2.7k

C16V ARA

D807 11EQS10

Q802 BA05T 1 OUT 2 COM

TO FRON T 8AC12

D854 11EQS10

GND +15.5V 2

TO AUDIO

+5F +5F
DAC INTERFACE TO 4-CHANNEL PCB

C612 R680p

FROM X/X PAGE (DAC BUS)
DAPC SYCL DARD DACL DALR RST M41 M3 M2 M0

RR604 1.8k

R613 33
Q601 2SK369 BL D 3 + 1 G C602 330p S 2

3 D - 1 G 2 S

Q604 2SA970 GR,BL 3 E 2 B 1 C
GND Q609 2SK369 BL D3 + 1 G S 2 1C GND Q611 2SC2240 GR,BL 3E 2 B 2 S Q610 2SK369 BL

1CH/2CH

R610 33k

R627 270

R629 33k

Q602 2SK369 BL 1C

C610 560p

C609 1200p

R614 33

R640 33

R643 10k
QD61 CS4397 C601 1800p RST M41 M3 M2 M0 3VDA CD16V RST 1 M4/ADD 2 M3/ADM2/SCM0/SDA 5 DGND 6 CD62 0.1 VD 7 VD 8 DGND 9 SYCL DACL DALR DAPC DARD 384/192fs GND MCLK 10 SCLK 11 CMOD12 SDAT 13 MCD=H 16 GND 28 VREF 27 FILT+ 26 FILT25 CMOUT 24 -LO 23 +LO 5.6VA 22 VA CD16V CD63 0.GND 20 +RD 19 -RD 18 GND 17 MUTEC 16 C/H GND 15 MUTE R651 1.2k GND R652 GND 1.2k R602 1.2k CD16V CD66 0.1 CD10V GND GND CD68 VREF 0.1 CD69 0.1 VREF

DFCT 22 FOK

RFDC CE TE SE

FE VC 38

IGEN 46
HD74LV157A Inputs STB SEL A H X X L L L L L H L H X L H X H : High L : Low X: Output B X X X L H L L H L H SEL 1 1A 2 1B 3 1Y 4 2A 5 2B 6 2Y 7 GND 8 A S G B Y A B A B Y A 16 VCC 15 STB 14 4A 13 4B 12 4Y 11 3A 10 3B 9 3Y
Q101 : CXD1881R Pin Description Power Supply Pins
Name VPA VPB VNA VNB V33 V25 Type Description Power supply pin for the RF block and serial port Power supply pin for the servo block Ground pin for the RF block and serial port Ground pin for the servo block Power supply pin for the output buffers Reference power supply for the servo output

Input Pins

Name DVDRFP, DVDRFN RFSIN AIP, AIN DIP, DIN A, B, C, D A2, B2, C2, D2 CD_A, B, C, D CD_E, F MIN DVDPD CDPD LDON LINK Type I I I I I I I I I I I I I Description RF SIGNAL INPUTS: Differential RF signal attenuator input pins. RF SIGNAL INPUT: Single-ended RF signal attenuator input pin. AGC AMPLIFIER INPUTS: Differential AGC amplier input pins. ANALOG INPUTS FOR RF SINGLE BUFFER: Differential analog inputs to the RF single-end output buffer and full wave rectier. PHOTO DETECTOR INTERFACE INPUTS: Inputs from the main beam photo detector matrix outputs. PHOTO DETECTOR INTERFACE INPUTS: AC coupled inputs for the DPD from the main beam photo detector matrix outputs. CD PHOTO DETECTOR INTERFACE INPUTS: CD_A, B, C, D come from the CD main beam photo detector matrix outputs. CD PHOTO DETECTOR INTERFACE INPUTS: CD side beam photo dector outputs and used for the CD tracking detection. RF SIGNAL INPUT FOR MIRROR: AC coupled inputs for the mirror dection circuit from MEVO. APC INPUT: DVD APC input pin from the monitor photo diode. APC INPUT: CD APC input pin from the monitor photo diode. APC OUTPUT ON/OFF: APC output control pin. A high level activates LD output. (open low) LINKING SIGNAL INPUT PIN: In the linking area, this pin goes high and the Mirror and TE outputs are disabled, when the link signal is enabled. (open low)

Output Pins

Name ATOP, ATON FNP, FNN RFAC RFDC FE TE CE MEVO DFT MIRR PI DVDLD CDLD MNTR Type O O O O O O O O O O O O O O Description DIFFERENTIAL ATTENUATOR OUTPUTS: Attenuator outputs. DIFFERENTIAL NORMAL OUTPUTS: Filter normal outputs. SINGLE-ENDED NORMAL OUTPUT: Single-ended RF output. RF SIGNAL OUTPUT: Single-ended RF summing output reference to VPB-2.4 (V). FOCUSING ERROR SIGNAL OUTPUT: Focus error output reference to V125. TRACKING ERROR SIGNAL OUTPUT: Tracking error output reference to V125. CENTER ERROR SIGNAL OUTPUT: Center error output reference to V125. RFDDC BOTTOM ENVELOPE OUTPUT: Bottom envelope, PI or bottom clamped RF envelope signal output for mirror detection. DEFECT OUTPUT: CMOS output (V33 or VPB). When the PI signal level is below the detection level or when the RF signal level is below the detection level, the DFT output goes high. This output is selected by serial port. MIRROR DETECT OUTPUT: Mirror detect comparator output. CMOS output (V33 or VPB). PULL-IN SIGNAL OUTPUT: The summing signal output of A, B, C, D, or CD_A, B, C, D. Reference to V25/3. APC OUTPUT: DVD APC output pin to control the laser power. APC OUTPUT: CD APC output pin to control the laser power. MONITOR OUTPUT: Monitor output signal is selected by PIOR bit7-5.

4 MSDATI VDC MSDATO MSREADY XMSDOE
9 XRST 60 SMUTE MCKI VSIO EXCKO1 EXCKO2 LRCK FRAME VDIO MNT0 MNT1 MNT2 MNT3 TESTO TESTO TESTO TESTO TCK TDI VSC TDO TMS TRST TEST1 TEST2 TEST3 VDC TESTO XBIT SUPDT0 SUPDT1 SUPDT2 SUPDT3 VSIO SUPDT4 SUPDT5 VDIO SUPDT6 SUPDT7 XSUPAK VSC TESTO TESTI TESTI TESTO VDC TESTO TESTO BCKASL VSDSD BCKAI BCKAO
PHREFI PHREFO ZDFL DSAL ZDFR DSAR VDDSD ZDFC DSAC ZDFLFE
I O O O O O O O O O O O O O O O O O O O O I I O O O I I Ipu O I I I I I I I I I I I I I I I I I I I
71 DSALFE 72 VSDSD 73 ZDFLS 74 DSALS 75 ZDFRS DSARS VDDSD TESTO TESTO VSC TESTO TESTO VDC TESTO TESTO VSIO TESTO TESTI TESTI VDIO TESTO TESTO TESTO VSC TESTI TESTI TESTI TESTO VDC TESTI TESTI TESTI TESTI TESTI TESTI VSIO TESTI TESTI TESTI VDIO WAD0 WAD1 WAD2 WAD3 VSIO VSC WAD4 WAD5 WAD6 WAD7 VDC TESTI WCK WAVDD WAVDD
Phase reference signal input for DSD output phase modulation. Phase reference signal output for DSD output phase modulation. Lch zero data detection ag (when set by the microcomputer). Goes high when silent data continues for 300ms. Lch DSD data output. Rch zero data detection ag (when set by the microcomputer). Goes high when silent data continues for 300ms. Rch DSD data output. Power supply for DSD data output. Supply +3.3V separated from other digital power supplies. Cch zero data detection ag (when set by the microcomputer). Goes high when silent data continues for 300ms. Cch DSD data output. LFEch zero data detection ag (when set by the microcomputer). Goes high when silent data continues for 300ms. LFEch DSD data output. GND for DSD data output. LSch zero data detection ag (when set by the microcomputer). Goes high when silent data continues for 300ms. LSch DSD data output. RSch zero data detection ag (when set by the microcomputer). Goes high when silent data continues for 300ms. RSch DSD data output. Power supply for DSD data output. Supply +3.3V separated from other digital power supplies. Test output. Leave open. Test output. Leave open. Core GND. Test output. Leave open. Test output. Leave open. Core power supply. Supply +2.5V. Test output. Leave open. Test output. Leave open. I/O GND. Test output. Leave open. Test input. Fix to low. Test input. Fix to low. I/O power supply. Supply +3.3V. Test output. Leave open. Test output. Leave open. Test output. Leave open. Core GND. Test input. Fix to high. Test input. Fix to low. Test input. Fix to high. Test output. Leave open. Core power supply. Supply +2.5V. Test input. Fix to low. Test input. Fix to low. Test input. Fix to low. Test input. Fix to low. Test input. Fix to low. Test input. Fix to low. I/O GND. Test input. Fix to low. Test input. Fix to low. Test input. Fix to low. /O power supply. Supply +3.3V. External A/D data input for PSP physical disc mark detection. (LSB) This is used only when not using the internal A/D converter and connecting an external A/D converter. External A/D data input for PSP physical disc mark detection. External A/D data input for PSP physical disc mark detection. External A/D data input for PSP physical disc mark detection. I/O GND. Core GND. External A/D data input for PSP physical disc mark detection. External A/D data input for PSP physical disc mark detection. External A/D data input for PSP physical disc mark detection. External A/D data input for PSP physical disc mark detection. (MSB) Core power supply. Supply +2.5V. Test input. Fix to low. Operating clock for PSP physical disc mark detection. Input the PLL clock corresponding to 1T of RF. A/D power supply for PSP physical disc mark detection. Input +2.5V separated from the digital block. A/D power supply for PSP physical disc mark detection. Input +2.5V separatedfrom the digital block.

126 WARFI 127 WAVRB 176 WAVSS WAVSS VSIO DQ7 DQ6 DQ5 DQ4 VDIO DQ3 DQ2 DQ1 DQ0 VSIO DCLK DCKE XWE XCAS XRAS VDIO TESTO A11 A10 VSC A9 A8 VDC A7 A6 A5 A4 VSIO A3 A2 A1 A0 VDIO XSRQ XSHD SDCK XSAK SDEF SD0 SD1 SD2 SD3 SD4 SD5 SD6 SD7 Ai Analog RF signal input for PSP physical disc mark detection. The full scale is 0.0 to 2.5V. (typ.) Ai A/D bottom reference for PSP physical disc mark detection. The voltage input to this pin is set to bottom level of the A/D converter. A/D GND for PSP physical disc mark detection. A/D GND for PSP physical disc mark detection. I/O GND. I/O SDRAM data I/O. (MSB) I/O SDRAM data I/O. I/O SDRAM data I/O. I/O SDRAM data I/O. I/O power supply. Supply +3.3V. I/O SDRAM data I/O. I/O SDRAM data I/O. I/O SDRAM data I/O. I/O SDRAM data I/O. (LSB) I/O GND. O SDRAM clock output. O SDRAM clock enable output. O SDRAM write enable output. Connect to the XWE pin of the SDRAM. O SDRAM column address strobe output. Connect to the CAS pin of the SDRAM. O SDRAM row address strobe output. Connect to the RAS pin of the SDRAM. I/O power supply. Supply +3.3V. O Test output. Leave open. O SDRAM address output. (MSB) O SDRAM address output. Core GND. O SDRAM address output. O SDRAM address output. Core power supply. Supply +2.5V. O SDRAM address output. O SDRAM address output. O SDRAM address output. O SDRAM address output. I/O GND. O SDRAM address output. O SDRAM address output. O SDRAM address output. O SDRAM address output. (LSB) I/O power supply. Supply +3.3V. O Output for data request to front-end processor. I Input for header ag output from front-end processor. I Input for data transfer clock output from front-end processor. I Input for data valid ag output from front-end processor. I Input for error ag output from front-end processor. I Input for stream data from front-end processor. (LSB) I Input for stream data from front-end processor. I Input for stream data from front-end processor. I Input for stream data from front-end processor. I Input for stream data from front-end processor. I Input for stream data from front-end processor. I Input for stream data from front-end processor. I Input for stream data from front-end processor. (MSB)

Ipu: pulled-up input, Ipd: pulled-down input, Ai: analog input

WARF I WAD [ 7 : 0 ] WCK

A/D DSARS DSAL S DSAL FE DST Decoder

PSP Data Detection

DQ [ 7 : 0 ] A [ 11 : 0 ] DCLK DCKE XWE XCAS XRAS SD [ 7 : 0 ] XSHD XSAK SDEF XSRQ Stream Manager
DSAC DSAR Audio Interface DSAL PHREFO PHREF I BCKAO BCKA I
Supplementary Data Interface Microcomputer Interface C l ock

XSUPAK SUPDT [ 7 : 0 ]

MSDAT I

XMS LAT

EXCKO1

EXCKO2

MSREADY

XMSDOE

Q124 : CXD1882R
Pin Description The pin descriptions by function are given below. 1. Read Channel Block (22 pins) 1-1. PLL (8 pins) (1) PDHVCC (VC input for PD Hi-Z output) Midpoint potential input for RFPLL. If the HPDVC bit (bit 6) of the RFPLL1 register (E0h) is set to 1, the voltage input to this pin is output from the PDO pin when the PDO pin output is other than VCC or GND. This pin sharpens the PDO pin output waveform in order to reduce phase deviation. (2) PDO (phase detector output: output) Phase comparator charge pump output. (3) FDO (frequency detector output: output) Frequency comparator charge pump output. (4) LPF1 (PLL LPF1: input) Inverted input of the operational amplier of the PLL loop lter. (5) LPF2 (PLL LPF2: input) When the LPFTGN bit (bit 0) of the LOOPFCTL register (EAh) is set to 1, this pin is connected to the inverted input of the operational amplier of the PLL loop lter. It is used to switch the PLL loop gain. (6) LPF5 (PLL LPF5: output) Output of the operational amplier of the PLL loop lter. (7) VCOIN (VCO input: input) VCO input. When using the built-in operational amplier, the output of the second operational amplier of the loop lter is connected to this pin. (8) VCOR1 (VCO resistor: input) Connects the VCO oscillation range setting resistor. The setting resistor is connected between his pin and GND. When R2 is increased, the minimum oscillation frequency is reduced. 1-2: RF binary setting (6 pins) (1) RFDCC (RF DC cut control: input) Input for adjusting the RF signal DC cut HPF. A resistor is connected between this pin and the midpoint potential in order to raise the HPF cut-off frequency in areas other than the linking section. (2) ASF[2:1] (asymmetry compensation lter: output) Connects the lter for switching the asymmetry compensation time constant in the linking section. (3) DASYO (data output of asymmetry compensation circuitry: output) RF binary signal output. (4) DASYI (data input of asymmetry compensation circuitry: input) Input for the analog signal obtained by integrating the RF binary signal. (5) RFIN (RF input: input) RF signal input. 1-3. CLV (6 pins) (1) MDSOUT (MDS output: output) Built-in CLV circuit frequency error output. (2) MDPOUT (MDP output: output) Built-in CLV circuit phase error output. (3) MDPIN[2:1] (MDP input: input) MDP inputs. The input from these two pins is switched by the MDPSL bit (bit 0) of the SPDLCTL register (E8h). MDSOUT and MDPOUT are synthesized as analog values and input to one of these pins. A spindle control signal generated by an external spindle control circuit is input to the other pin. (4) SPO (spindle control output: output) Spindle control output. It attenuates and outputs the signal input from MDPIN. (5) CLVS (CLVS control output: output) Control output for switching the spindle control lter constant in CLVS mode. 1-4. Other pins (2 pins) (1) LINK/DEFECT (LINK monitor/DEFECT: input/output) LINK signal monitor output or DEFECT input signal. The signal is switched by the LNDFT bit (bit 7) of the MNTRPIN register ($Efh). For LINK output, this pin is set high in the linking section

5. Host Interface (31 pins) Pin symbols are listed in the order of ATAPI mode, DMA mode and AV mode. Pull up means that the pin should be pulled up by a resistor, 0 means low level output, and nc means No Connect. (1) HCS0 (HOST chip select: input)/nc/nc This pin is pulled up by a resistor. ATAPI: Chip select negative logic input signal from the host. This is connected with the CS1FX pin of the ATAPI interface. DMA/AV: This pin is not used. (2) HCS1 (HOST chip select: input)/nc/nc This pin is pulled up by a resistor. ATAPI: Chip select negative logic input signal from the host. This is connected with the CS3FX pin of the ATAPI interface. DMA/AV: This pin is not used. (3) HA[2:0] (HOST address: input)/pull up/pull up ATAPI: Address input signal for selecting internal registers from the host. DMA/AV: This pin is not used, and should be pulled up by a resistor. (4) XHRD (HOST read: input)/XHRD (HOST read: output)/ XSHDR0 (sector header 0: output) ATAPI: Strobe negative logic input signal for reading data from the host. DMA: Strobe negative logic input signal for reading data to the host. AV: Negative logic output signal indicating the lead byte of the sector. (5) XHWR (HOST write: input)/XHWR (HOST write: output)/DCK (data clock: output) ATAPI: Strobe negative logic input signal for writing data from the host. DMA: Strobe negative logic output signal for writing data to the host. AV: Clock output for data transfer. (6) XHAC (HOST DMA acknowledge: input)/HDRQ (HOST DMA request: input)/REQUEST (request:input) This pin is pulled up by a resistor. ATAPI: DMA acknowledge negative logic input signal from the host. DMA: DMA request input signal from the host. AV: Data transfer request input signal. (7) DASP (drive active/slave present: input/output)/pull up/pull up ATAPI: Negative logic signal indicating that a slave drive is present or a drive is active; open drain signal. DMA/AV: This pin is not used, and should be pulled up by a resistor. (8) HDB[F:0] (HOST data bus: input/output)/HDB[F:0] (HOST data bus: input/output)/7 0, XVFLAG, DATA[7:0] (0, video error ag, data: output) ATAPI/DMA: 16-bit host data bus. AV: Low level is output from the upper 7 bits. The 8th bit from the upper side is an error ag output signal corresponding to the lower 8 bits. The lower 8 bits are video data output signals. (9) HDRQ (HOST DMA request: output)/XHAC (HOST DMA acknowledge: output)/XACK (acknowledge:output) ATAPI: DMA data request positive logic output signal to the host; tri-state signal. DMA: DMA acknowledge negative logic output signal to the host. AV: Data transfer acknowledge negative logic output signal. (10) HINT (HOST interrupt: output)/pull up/pull up ATAPI: Interrupt request positive logic output signal to the host; tri-state signal. DMA/AV: This pin is not used, and should be pulled up by a resistor. (11) XS16 (16-bit data transfer: output)/pull up/pull up ATAPI: Negative logic signal indicating that a 16-bit data port has been selected; open drain signal. This is connected with the IOCS16 pin of the ATAPI interface. DMA/AV: This pin is not used, and should be pulled up by a resistor. (12) REDY (I/O channel ready: output)/pull up/pull up ATAPI: Positive logic signal which is negated when a drive is

not ready to respond to a data transfer request; open drain signal. This is connected with the IORDY pin of the ATAPI interface. DMA/AV: This pin is not used, and should be pulled up by a resistor. (13) XPDI (passed diagnostics: input/output)/pull up/pull up ATAPI: Negative logic signal indicating that diagnostics of the slave drive have been completed; open drain signal. This is connected with the PDIAG pin of the ATAPI interface. DMA/AV: This pin is not used, and should be pulled up by a resistor. (14) XHRS (HOST reset: input)/nc/nc ATAPI: Reset negative logic signal from the host; pulled up by a resistor. DMA/AV: This pin is not used
MA/ mn t 1 MA/ mn t 2 MA9 / mn t 0 MA [ 8 : 0 ] MDB [ F : 0 ] 66 to 69, 71, 73 to 75, 96, 97, 99, 101, 102, 104 to 106

DASY I

114 115

79 , 80 , 82 to 87, 89

RFDCC RF I N PDO PDHVCC FDO LPF 1 LPF 2 VC1 LPF 5 VCOR1 VCO I N MDPOUT MDSOUT CLVS MD I N1 MD I N2 SPO VC2 GFS APEO GSCOR MDAT BCLK LRCK C2PO WFCK SCOR SB I N EXCK XRC I DDAT DLRC DBCK

RF A s ymme t r y

DMA Co n t r o l l e r (Priority resolve & Sequencer) XHRS XPD I
DVD Ma i n Da t a ECC & EDC DMA F I FO SYNC De t e c t

REDY XSH I NT HDRQ

EFM + Demodulator
HOST I /F ATAP I or DMA or V i deo
Se c t o r I D De t e c t
24, 26, 27, 29 to 32, 34, 35, 37, HDB [ F : to 41, 43 to 45
Spindle Control CD - ROM Ma i n Da t a ECC & EDC
DASP XHAC ATAP I Registers 56, 59, 60 HA[2:0] XHWR
167 XTAL 18 XWR 17 XRD 1, 2, 4, 172 to , 7 , 9 t o D[ 7 : 0 ] A[7:0] XCS 20 X I NT X I NT XWA I T DAC I /F Au t h e n t i c a t i o n CPU I / F , DMA Co n t r o l l e r CD ESP CD DSP I /F SYNC Control I n t e r na l C l oc k Su b c o d e Deinterleave & ECC Descramble ATAP I Pa c k e t F I FO

XHRD HCS2 HCSXRST

9 XT L 2

0 XT L 1

Q125 : CXP973064R-1(FLASH) / GXPQ7100(MASK)
Pin No. 65 Pin Name FTMUT SLMUT AMUT SMUT XRST CD/XDVD LOCK MBHLD AMPSDT AMPSCK AMPSEN XDECSEL VSS D0 D1 D2 D3 D4 D5 D6 D7 XDECINT0 XDECINT1 TZC PE3 PE3 SEEK REQST NC DECMNT1 FOK GFSDEC DRVRXD DRVTXD DRVCLK XDRVRDY DRVIRQ XRESET VSS XTAL EXTAL VDD DSPXLAT XMSLAT MSCK MSDTO MSDTI MSREADY DSPDTO DSPSCK SENS SQSO SNSCK SQCK VSS JITIN AMPMNT -ATT P17 PJ0 SCSY GFSDSP C2PO MIRR DECMNT2 I/O O O O O O O I I/O O O O O I/O I/O I/O I/O I/O I/O I/O I/O I I I O O I I I I O I O O I I O O O O O I I O O I I O O I I I O I I I I Description Actuator driver mute signal for foc/track Actuator driver mute signal for spin/sledg Muting on/off "L" : muting on for CXD3068Q Muting on/off signal output to the DSD decoder "H" : muting on System reset signal output (L= reset) CD/DVD(SACD) mode selection signal output (L=CD, H=SACD) GFS is sampled by 460 Hz "H" input when GFS is. "H" NC Serial data transfer DATA signal input,output Serial data transfer clock signal output Serial data transfer enable signal (H=enable) OPU block on/off for modulation circuit (L=on) Ground terminal (digital system) Two-way data bus Two-way data bus Two-way data bus Two-way data bus Two-way data bus Two-way data bus Two-way data bus Two-way data bus Interrupt signal input from CXD1881R Interrupt signal input from CXD1881R Track signal, OPU in case by traversal the disc track line NC NC Display data ready signal output to the feature MPU ("H" : read) Reqest signal CXD1882R Not used (open) RF signal monitor input from CXD1882R Focus on signal Guard frame sync signal input Input signal data from the feature MPU Output signal data for the featur MPU Input signal clock from the featur MPU Output data signal readey for the featur MPU Iutput data signal readey from the featur MPU Power on reset signal input (L=reset) Ground terminal (digital system) System clock input terminal (20 MHz) System clock output terminal (20 MHz) Power supply terminal (+3.3V) (digital system) Serial data latch pulse signal output to the CXD3068Q Serial data latch pulse signal output to the CXD2752R Serial data transfer clock signal output to CXD2752R Serial data output to the DSD CXD2752R Serial data input from the CXD2752R Ready signal input from the CXD2752R "L" : ready Serial data output to the CXD3068Q Serial data clock input from the CXD3068Q Internal status (SENSE) signal input from CXD3068Q Subcode Q data input Serial status data clock output to the CXD3068Q Subcode Q data reading clock signal output Ground terminal (digital system) Jitter signal input terminal Monitor signal from the CXD1881R -12dB atteneation request signal input "L" : attenation on NC NC GRSCOR data sync request signal for CXD3068Q Frequency generator signal input C2 pointer signal input from the CXD3068Q Mirror signal input from CXD3068Q Monitor signal from the CXD1882R

Frequencies

The Left/Right clock determines which channel is currently being input on the serial audio data input, SDATA. The frequency of the Left/Right clock must be at the input sample rate. Audio samples in Left/Right sample pairs will be simultaneously output from the digital-to-analog converter whereas Right/Left pairs will exhibit a one sample period difference. The required relationship between the Left/Right clock, serial clock and serial data is dened by the Mode Control Byte and the options are detailed in Figures 29-33 Serial Audio Data - SDATA Pin 13, Input Function: Serial audio data is input on this pin. The selection of the Digital Interface Format is determined by settings of the Mode select as detailed in Figures 29-33. The data is clocked into SDATA via the serial clock and the channel is determined by the Left/Right clock. The required relationship between the Left/Right clock, serial clock and serial data is dened by the Mode Control Byte and the options are detailed inin Figures 29-33 Soft Mute - MUTE Pin 15, Input Function: The analog outputs will ramp to a muted state when enabled. The ramp requires 1152 left/right clock cycles in Single Speed, 2304 cycles in Double Speed and 4608 cycles in Quad Speed mode. The bias voltage on the outputs will be retained and MUTEC will go active at the completion of the ramp period. The analog outputs will ramp to a normal state when this function transitions from the enabled to disabled state. The ramp requires 1152 left/right clock cycles in Single Speed, 2304 cycles in Double Speed and 4608 cycles in Quad Speed mode. The MUTEC will release immediately on setting MUTE = 1. The converter analog outputs will mute when enabled. The bias voltage on the outputs will be retained and MUTEC will go active during the mute period. Mute DESCRIPTION Enabled Normal operation mode
256x 8.1920 11.2896 12.2880
MCLK (MHz) 384x 512x 12.2880 16.3840 16.9344 22.5792 18.4320 24.5760
768x 24.5760 33.8688 36.8640
Table 4. Single Speed (16 to 50 kHz sample rates) Common Clock
Sample Rate (kHz) 64 88.2 96
128x 8.1920 11.2896 12.2880
MCLK (MHz) 192x 256x 12.2880 16.3840 16.9344 22.5792 18.4320 24.5760
384x 24.5760 33.8688 36.8640
Table 5. Double Speed (50 to 100 kHz sample rates) Common Clock
Sample Rate (kHz) 176.4 192

64x 11.2896 12.2880

MCLK (MHz) 96x 128x 16.9344 22.5792 18.4320 24.5760

192x 33.8688 36.8640

Control Port / Hardware Mode Select - C/H Pin 16, Input Function: Determines if the device will operate in either the Hardware Mode or Control Port Mode. C/H DESCRIPTION Hardware Mode Enabled Control Port Mode Enabled
Table 6. Quad Speed (100 to 200 kHz sample rates) Common Clock
Serial Clock - SCLK Pin 11, Input Function: Clocks individual bits of serial data into the SDATA pin. The required relationship between the Left/Right clock, serial clock and serial data is dened by either the Mode Control Byte in Control Port Mode or the M0 - M4 pins in Hardware Mode. The options are detailed in Figures 29-33 Left/Right Clock - LRCK Pin 12, Input Function:

Mute Control - MUTEC Pin 17, Output Function: The Mute Control pin goes low during power-up initialization, reset, muting, master clock to left/right clock frequency ratio is incorrect or power-down. This pin is intended to be used as a control for an external mute circuit to prevent the clicks and pops that can occur in any single supply system. Use of Mute Control is not mandatory but recommended for designs requiring the absolute minimum in extraneous clicks and pops.
Analog Ground - AGND Pins 18 and 21, Inputs Function: Analog ground reference. Differential Analog Outpus - AOUTR- , AOUTR+ and AOUTL- , AOUTL+ Pins 19, 20, 23 and 24, Outputs Function: The full scale differential analog output level is specied in the Analog Characteristics specications table. Analog Power - VA Pin 22, Input Function: Power for the analog and reference circuits. Typically 5VDC. Common Mode Voltage - CMOUT Pin 25, Output Function: Filter connection for internal bias voltage, typically 50% of VREF. Capacitors must be connected from CMOUT to analog ground, as shown in Figure 6. CMOUT has a typical source impedence of 25 k and any current drawn from this pin will alter device performance Reference Ground - FILTPin 26, Input Function: Ground reference for the internal sampling circuits. Must be connected to analog ground. Reference Filter - FILT+ Pin 27, Output Function: Positive reference for internal sampling circuits. External capacitors are required from FILT+ to analog ground, as shown in Figure 6. FILT+ is not intended to supply external current. Voltage Reference Input- VREF Pin 28, Input Function: Analog voltage reference. Typically 5VDC. HARDWARE MODE Mode Select - M0, M1, M2, M3, M4 Pins 2, 3, 4, 5 and 14, Inputs Function: The Mode Select pins determine the operational mode of the device as detailed in Tables 9-14. The op-tions include; Selection of the Digital Interface Format which determines the required relationship between the Left/Right clock, serial clock and serial data as detailed in Figures 29-33 Selection of the standard 15 s/50 s digital de-emphasis lter response, Figure 28, which requires re-conguration of the digital lter to maintain the proper lter response for 32, 44.1 or 48 kHz sample rates. Selection of the appropriate clocking mode to match the input sample rates. Access to the Direct Stream Digital Mode Access to the 8x Interpolation Input Mode CONTROL PORT MODE Address Bit 0 / Chip Select - AD0 / CS Pin 2, Input Function: In I2C mode, AD0 is a chip address bit. CS is used to enable the control port interface in SPI mode. The device will enter the SPI mode at anytime a high to low transition is detected on this pin. Once the device has entered the SPI mode, it will remain until either the part is reset or undergoes a power-down cycle. Address Bit 1 / Control Data Input - AD1/CDIN Pin 3, Input Function: In I2C mode, AD1 is a chip address bit. CDIN is the control data input line for the control port interface in SPI mode. Serial Control Interface Clock - SCL/CCLK Pin 4, Input Function: In I2C mode, SCL clocks the serial control data into or from SDA/CDOUT. In SPI mode, CCLK clocks the serial data into AD1/CDIN and out of SDA/CDOUT. Serial Control Data I/O - SDA/CDOUT Pin 5, Input/Output Function: In I2C mode, SDA is a data input/output. CDOUT is the control data output for the control port interface in SPI mode. M1 - Mode Select Pin 14, Input Function: This pin is not used in Control Port Mode and must be terminated to ground.

QF01 : MB90F553A

50 MD1 Pin 1 P20/AP21/AP22/AP23/AP24/AP25/AP26/AP27/AP30/ALE 10 P31/RD 11 Vss 12 P32/WRL 13 P33/WRH 14 P34/WRQ 15 P35/HAK 16 P36/RDY 17 P37/CLK 18 P40/SCK 19 P41/SOT 20 P42/SIN 21 P43/SCKP44/SOTVcc 24 P45/SINP46/ADTG 26 P47/SCKC 28 P50/SDA0/SOTP51/SCL0/SINP52/SDAP53/SCLP54/SDAP55/SCLAvcc 35 AVRH 36 AVRL 37 Avss 38 P60/ANP61/ANP62/ANP63/ANVss 43 P64/ANP65/ANP66/ANP67/ANP70/IRQP71/IRQMD0 MODE1 I Mode select Normal=H AVDD AVRef GND AGND ADkey0 ADkey1 ADkey2 ADkey3 Vss EEDAT EECLK O O I I I I 5V 5V GND GND Key input Key input Key input Key input GND EEROM data EEROM clock A/D A/D A/D A/D DRVCLK DRVRX VDD DRVTX CDRST CDCLK Cap. CDIN CDOUT O I I O O O O Front end clock Front end data output 5V Front end data input DAC reset DAC clock 0.1uF DAC data output DAC data input Pulse Pulse active L active L active L FCEN FRES FCLK FDAT O O O O Display driver select Display driver reset Display driver clock Display driver data adrs=L; inst=H active L active L Pulse Vss GND MUT1 MUT2 O O MUTE Front L/R MUTE Surr.L/R, Center, LFE active H active H active H Port Signal M41 M42 M43 I/O O O O Function Description DAC select Front L/R DAC select Surround L/R DAC select center, LFE active H active H active H Active 51 MDHST 53 P72/IRQP73/IRQP74/IRQP75/IRQP76/IRQP77/IRQP80/TINP81/TINP82/TOTP83/TOTP84/INP85/INP86/INP86/INP90/OUTP91/OUTP92/PPGP93/PPGP94/PPGP95/PPGP96/PPGP97/PPGPA0/OUTPA1/OUTRST 78 PAPAPA4/CKOT 81 Vss 82 XXVcc 85 P00/ADP01/ADP02/ADP03/ADP04/ADP05/ADP06/ADP07/ADP10/ADP11/ADP12/ADP13/ADP14/ADP15/ADP16/ADP17/AD15 Multi/2ch I Multi, 2ch select Multi=H; 2ch=L SYCLSW MODE1 STBY O O O Filter control Mode select standby control Custom=L SACD=H;CD=L Standby =L GND X'tal X'tal VDD 8MHz 8MHz 5V Reset Reset active L CD 2ch Multi STBY DISP O O O O O LED CD LED 2ch LED Multi LED standby LED display off active L active L active L active L active L RC-5 RC-5 input active L MODE2 MODE3 HWSTBY SEEK STBSW IR DRV RES DRV RDY DRV RQ O I I Mode select Mode select Hardware standby Search signal Standby on/off key input Standby on/off remote input Front end reset Front end ready Front end request active L active L active L Normal=H Normal=L Normal=H Search=L active H
9. EXPLODED VIEW AND PARTS LIST

32362 DIODE 1SS176 MA165 1SS254 HD20002000 30V 0.1A 32362 DIODE 1SS176 MA165 1SS254 HD20002000 30V 0.1A DIODE SHOTTKY 11EQS10 1A 100V 82421 DIODE 1D3 1A 200V 82421 DIODE 1D3 1A 200V DIODE SHOTTKY 11EQS1 1A 100V 33664 ZENER DIODE HZ6L 3 6.2V 33664 ZENER DIODE HZ6L 3 6.2V 32362 DIODE 1SS176 MA165 1SS254 30V 0.1A HD20055100 HD20002710 HD20002710 HD20055100 HD30021010 HD30021010 HD20002000

OA68801620

POS. NO D859
POS. NO Q652 Q653 Q654 Q655 Q656 Q657 Q658 Q659 Q660
PART NO. (MJI) HF203691B0 HT322402A0 HT109702A0 HT109702A0 HT322402A0 HF201701H0 HF100741H0 HF203691B0 HF203691B0 HT322402A0 HT109702A0 HT109702A0 HT322402A0 HF201701H0 HF100741H0 HT109702A0 HT109702A0 HT109702A0 HT322402A0 HT109702A0 HC36905210 HC36905210 HC38505090 HC38908090 HF202461C0 HT41415100 HT322402A0 HF202461C0 HT21020100 HT109702A0
32362 DIODE 1SS176 MA165 1SS254 HD20002000 30V 0.1A 61189 DIG.TRS. DTC114TS/UN4215 10K 61189 DIG.TRS. DTC114TS/UN4215 10K 42949 TRS. 2SA970 GR OR BL 43818 TRS. 2SC2878 A OR BRANK 41947 TRS. 2SC2458 2SC1740S 2SC3199 ETC. 41947 TRS. 2SC2458 2SC1740S 2SC3199 ETC. 41947 TRS. 2SC2458 2SC1740S 2SC3199 ETC. IC CS4397 DSD/PCD DAC 24BIT 192K 42715 TRS. 2SA1048 2SA933S 2SA1267 ETC. 41947 TRS. 2SC2458 2SC1740S 2SC3199 ETC. 61189 DIG.TRS. DTC114TS/UN4215 10K 41947 TRS. 2SC2458 2SC1740S 2SC3199 ETC. 61189 DIG.TRS. DTC114TS/UN4215 10K 42715 TRS. 2SA1048 2SA933S 2SA1267 ETC. 61189 DIG.TRS. DTC114TS/UN4215 10K 42715 TRS. 2SA1048 2SA933S 2SA1267 ETC. 43818 TRS. 2SC2878 A OR BRANK BA20004000 BA20004000 HT109702A0 HT328782A0 HT30001000 HT30001000 HT30001000 HC10008880 HT10001000 HT30001000 BA20004000 HT30001000 BA20004000 HT10001000 BA20004000 HT10001000
QD21 QD22 QD23 QD24 QD25 QD26 QD27 QD61 QF51 QF52 QN01 QN02 QN03 QN04 QN11 QN12 QN61
Q661 Q662 Q663 Q664 Q665 Q666 Q667 Q668 Q669 Q670 Q673 Q674 Q801 Q802 Q803 Q821 Q851 Q852 Q853 Q855 Q856 Q857
42839 F.E.T. 2SK369 BL VGDS-40V PD0.4W 43233 TRS. 2SC2240 GR OR BL 42949 TRS. 2SA970 GR OR BL 42949 TRS. 2SA970 GR OR BL 43233 TRS. 2SC2240 GR OR BL 41844 F.E.T. 2SK170 V LANK 62649 F.E.T. 2SJ74 V LANK 42839 F.E.T. 2SK369 BL VGDS-40V PD0.4W 42839 F.E.T. 2SK369 BL VGDS-40V PD0.4W 43233 TRS. 2SC2240 GR OR BL 42949 TRS. 2SA970 GR OR BL 42949 TRS. 2SA970 GR OR BL 43233 TRS. 2SC2240 GR OR BL 41844 F.E.T. 2SK170 V LANK 62649 F.E.T. 2SJ74 V LANK 42949 TRS. 2SA970 GR OR BL 42949 TRS. 2SA970 GR OR BL 42949 TRS. 2SA970 GR OR BL 43233 TRS. 2SC2240 GR OR BL
42949 TRS. 2SA970 GR OR BL IC BA05T 5V/1A TO220 IC BA05T 5V/1A TO220 IC NJM78M05F IC NJM7808F F.E.T. 2SK246 GR TRS. 2SD1415A TRS. 2SC2240 GR OR BL F.E.T. 2SK246 GR TRS. 2SB1020A TRS. 2SA970 GR OR BL PP16-MISCELLANEOUS FUSE T1.25A 250V VDE SEMKO FUSE T800MA 250V VDE SEMCO FUSE T800MA 250V VDE SEMKO FUSE T800MA 250V VDE SEMCO FUSE T800MA 250V VDE SEMCO JACK 25 FMN-BTRK 1MM-PITCH TOP JACK 25 FMN-BTRK 1MM-PITCH TOP JACK 21 FMN-BTRK 1MM-PITCH TOP JACK 25 FMN-BTRK 1MM-PITCH TOP TERMINAL 2P CINCH PIN JACK TERMINAL 14X14 RA 1L1P BLK AU FLM-GND OPT. CONNECTOR JFJ300 OPT OUTPUT TERMINAL 1P CINCH YKC21-3725 WHITE L-CH TERMINAL 1P CINCH YKC21-3724 RED R-CH PULSE TRANSF. TPS247MN-0386AN FERRITE BEAD BL02RN2-R62T2

Q119 Q121 Q122 Q123 Q124 Q125
POS. NO Q126 Q127 Q128 Q129 Q132 Q133 Q134 Q135 Q136 Q137 Q138 Q139 Q140 Q141 Q151 Q152 Q153 Q155 Q156 Q157 Q158 Q159 Q160
PART NO. (MJI) HC005805K0 HC10210990 BA10014210 BA20021210 HC006105K0 HC006105K0 BA20021210 HC007905K0 HC010005K0 HC006105K0 BA20021210 HC008405K0 HC009305K0 HC005605K0 HC98A33090 HC98A33090 HC98A26090 HX341162B0 HX409992A0 HX207982A0 HX341162B0 HX409992A0 HX207982A0

130 60856

IC TC74VHC157FT IC M11L16161SA-45T EDO-DRAM 16M DIG.TRS. DTA144EU R DIG.TRS. DTC144EC IC TC74VHC541FT IC TC74VHC541FT DIG.TRS. DTC144EC IC TC7WH74FU D-TYPE FLIP FLOP IC TC7WH08FU 2-INPUT AND GATE IC TC74VHC541FT DIG.TRS. DTC144EC IC TC74VHC86FT IC TC74VHC00FT IC TC74VHC74FT D-FF IC NJM2391DL1-33 1A 3.3V IC NJM2391DL1-33 1A 3.3V IC NJM2391DL1-26 1A 2.6V TRS. CHIP 2SC4116 TRS. CHIP 2SD999 DL DK TRS. CHIP 2SB798 DL DK TRS. CHIP 2SC4116 TRS. CHIP 2SD999 DL DK TRS. CHIP 2SB798 DL DK PV16-MISCELLANEOUS JACK 9610S-25D 25PIN 1MM CONNECTOR JACK S6B-PH-SM3-TB 6P PH SIDE JACK 9610S-09D 9PIN 1MM CONNECTOR JACK 06FFS-SP-TF 6PIN 1.25MM JACK 9610S-25D 25PIN 1MM CONNECTOR JACK 9610S-25D 25PIN 1MM CONNECTOR JACK S4B-PH-SM3-TB PH 4P SMD JACK 9610S-09D 9PIN 1MM CONNECTOR FERRITE CORE FB M J2125HM330-T FERRITE CORE FB M J2125HM330-T CHIP INDUCTER 47UH CHIP INDUCTER 47UH CHIP INDUCTER 47UH FERRITE CORE FB M J2125HM330-T FERRITE CORE FB M J2125HM330-T FERRITE CORE FB M J2125HM330-T
CY01 CY02 CY03 CY04 CY05 CY06

124 21901

PY16-DISPLAY SW CIRCUIT BOARD PY16-CAPACITORS ELECT. 47F 6.3V CER. 0.1F Z 50V CER. 22pF CER. 0.1F Z 50V CER. 0.1F Z 50V ELECT. 47F 6.3V PY16-RESISTORS JUMPER JUMPER PY16-SEMICONDUCTORS
EJ47600610 DA17104110 DA15220110 DA17104110 DA17104110 EJ47600610

R501 R503

DYL.E.D. LT3D8B RED 3O DY04 QY01 QY02 QY06 IC FL DRIVER LC75712NE 61227 DIG.TRS. DTA114ES/UN4111 10K 10K PY16-MISCELLANEOUS JACK 21FMN-BTRK 21P 1MM FFC 14009 PUSH SWITCH SKQNAE H/5MM 160GF DISPLAY UNIT FTD 13-ST-35G FUTABA 11494 PHOTO UNIT RPM6936-V4 IR SENSOR PY26-STANDBY LED CIRCUIT BOARD 80326 L.E.D. LT3D8B RED 3O 14009 PUSH SWITCH SKQNAE H/5MM 160GF HI10062320 HC10416030 BA10001000

JY01 SY01