Sony DVD Player S9000ES User Manual

DVP-S9000ES  
DVD-Video/CD/SACD Player  
Technical Notes  
The standard prices shown in this catalog consumption tax and expenses of transportation, installation, connection and adjustment.  
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For videophiles, equipment reviewers and consumer electronics professionals, the launch  
of a new, top-of-the-line Sony DVD player is always an occasion. In 1997, Sony’s original  
DVP-S7000 was acclaimed as the “Reference Standard.” In 1998, the second-generation  
DVP-S7700 took DVD playback to a new level of accuracy. Now the Sony DVP-  
S9000ES DVD-Video/CD/SACD player redefines the category. The player is a  
comprehensive redesign that represents three significant firsts:  
• The world’s first DVD player with 525P outputs  
based on Fast and Pure Cinema Detection.  
• The world’s first DVD-Video player to incorporate true  
Super Audio Compact Disc playback.  
• The first DVD player to join Sony’s ES Series,  
the Elevated Standard in audio reproduction and now video reproduction.  
In addition, the player represents significant refinements in MPEG image processing,  
optical transport, construction and craftsmanship.  
This booklet serves as an introduction to the technology of the DVP-S9000ES, presenting  
advances that promise to shape the development of DVD players for years to come.  
SACD/DVD Player  
DVP-S9000ES  
INDEX  
Video ....................................  
Audio ...................................  
Construction .........................  
Conveniences .........................  
Specifications ......................  
Page 04  
Page 13  
Page 17  
Page 18  
Page 19  
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second. The “B” field contains the even numbered lines and lasts 1/60  
second. This system can be abbreviated 525/60i or simply 525i  
(when discussing the line rate) or 60i (when discussing the picture  
rate). The 525i solution is a compromise that doubles the picture rate  
but halves the vertical resolution at any given instant. While it is a  
compromise, the 525i system is highly effective, an elegant  
engineering solution that has helped make television an essential part  
of entertainment.  
A Major New Opportunity  
In 1997, Sony’s original DVP-S7000 helped launch the DVD-  
Video format and was quickly acclaimed as the “Reference  
Standard.” In 1998, the second-generation DVP-S7700 took  
DVD playback to a new level of accuracy. Of course, both  
players were designed to maximize performance with the huge  
universe of televisions using 525-line interlace scanning.  
In the mean time, TV stations have launched the era of Digital  
Television (DTV) broadcasting. High Definition satellite  
broadcasting has become a commercial reality. In response,  
Sony and others have introduced a growing population of  
televisions with higher scanning frequencies, capable of better  
than 525-line interlace scanning.  
In the early days of television, when 12-inch diagonal screens were  
commonly used in living rooms, halving the vertical resolution was  
not a practical concern. But in today’s environment of 61-inch  
diagonal projection systems, the illusion of a continuous picture on the  
screen begins to fall apart, especially when you sit close to the screen.  
Individual scanning lines become visible and the compromise in  
vertical resolution becomes an annoyance. That’s why many of  
today’s finest big screen televisions have the ability to input and  
display 525P at 60 frames per second (525/60P). When carefully  
executed, 525/60P can achieve fluid, lifelike fast motion, along with  
breathtaking image detail. The 525/60P system is also superb for  
resolving fine print on the screen — one reason why 525/60P is the  
basis of the popular VGA computer display standard.  
Some of these new televisions offer progressive scan or 525P  
inputs, which can accept 525P output from a DVD player. And  
525P outputs have quickly been promoted as a must-have feature  
in high-end DVD players. They promise reproduction that’s  
even more detailed, more natural, more film-like.  
However, there are important differences in how DVD players  
process the 525P signal. Circuitry varies greatly in sophistica-  
tion and cost. To appreciate the technology behind these  
differences, readers need a firm understanding of progressive  
versus interlace scanning, film versus video origination, 3-2  
pulldown and 3-2 reverse conversion. This section reviews  
these basic issues.  
Film and Video Origination  
Movie film is conventionally shot and displayed at 24 frames per  
second. In the camera, the entire frame of film is exposed at one  
time. In the theater, the entire frame is projected at one time.  
Unfortunately, projecting at the native film rate of 24 frames per  
second creates flicker. That’s why movie projectors use a special  
shutter to display each frame twice, creating the effect of 48  
frames per second.  
Progressive and Interlace Scan  
In video, what appears to be a continuously moving image is  
actually a series of discrete still pictures, called frames. On the  
typical direct-view television, each frame is created on the  
picture tube by an electron beam that moves from the left edge of  
the screen to the right, illuminating one scanning line at a time.  
The American EIA television system uses 525 total scanning lines  
per frame.  
Theatrical release movies aren’t the only programs that are  
originally captured at 24 frames per second on motion picture  
film. The following is a snapshot of common industry practice:  
Genre  
Typical Origination  
24P film  
24P film  
24P film  
24P film  
24P film  
Either  
Fig. 1: Progressive scanning creates  
the picture by illuminating each line  
from top to bottom until all scanning  
lines in the frame are completed.  
Theatrical release movies  
Made for TV movies  
Hour-long primetime dramas  
Music videos  
Due to bandwidth limitations from the early years of television,  
the NTSC system was designed to capture 30 frames per second.  
The natural way to display these images would be to show the  
scanning lines in sequence, an approach called progressive  
scanning. 525-line progressive scanning at 30 frames per  
second is abbreviated 525/30P or simply 525P. Unfortunately,  
525/30P creates flicker: the image visibly darkens between  
frames. In addition, capturing images at 525/30P yields  
unsatisfactory results in fast-paced action like live sports.  
Network commercials  
Sitcoms  
Documentaries  
Either  
Network news magazines  
Live concerts  
Either  
60i video  
60i video  
60i video  
60i video  
60i video  
60i video  
60i video  
60i video  
60i video  
Wildlife/natural history  
Reality-based shows  
Do-it-yourself series  
Soap operas  
For these reasons, the early television engineers developed a  
solution called interlace scanning. Instead of capturing and  
displaying all 525 lines in their numerical sequence, the NTSC  
system divides the image into two fields. The “A” field contains  
the odd-numbered scanning lines (1, 3, 5, etc.) and lasts 1/60  
News  
Fig. 2: Interlace scanning divides the  
frame into two “fields.” The first field  
presents the odd-numbered scanning  
lines (1, 3, 5, etc.). The second field  
presents the even numbered lines.  
Talk shows  
Sports  
Local Commercials  
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Video  
DVD Technical Notes  
Of course, the choice of film or video ultimately depends on  
individual production budgets and artistic intent. And important  
variations occur. A growing number of theatrical releases are  
shot on video. And Sony’s latest HDCAM® high definition video  
equipment can capture images at 24 frames per second  
progressive scan – 24P.  
The 24P encoding of film-originated DVDs means that 3-2  
pulldown must be performed in the DVD player before the  
picture can be displayed on a conventional television. The  
exact pattern of 3-2 pulldown can have a subtle effect on the  
rendering of motion. So it’s important that the DVD reproduce  
the 3-2 pulldown cadence of the original master videotape.  
That’s where the FFRFs come in. They identify each field to be  
repeated as part of a “3.”  
Film-to-Video Transfer and 3-2 Pulldown  
We’ve seen that much of television broadcasting starts out as  
movie film at 24 frames per second. This means not only  
has it been converted from film to video, it’s been converted  
from 24P to 60i. A machine called a telecine performs both  
conversions. Simple arithmetic says that 60÷24 = 2.5. This  
means that each film frame must convert to an average of  
2.5 video fields. A process called 3-2 pulldown performs  
this conversion. The first film frame is converted to three  
video fields. The next film frame is converted to two video  
fields. The next film frame is converted to three video  
fields, and so on. We get a pattern of 3-2-3-2-3-2 etc, from  
which 3-2 pulldown gets its name. This pattern averages out  
to 2.5 video fields for every film frame. The telecine  
converts a film frame to three video fields by repeating the  
first field. For example, the first video field may consist of  
odd scanning lines, the second field consists of even  
scanning lines and the third field consists of the same odd  
scanning lines as the first.  
3-2 Reverse Conversion  
The 525/24P encoding of film-originated material has a special  
property. In conventional 525/60i video, each “B” field repre-  
sents a slice of time 1/60th second after the corresponding “A”  
field. To the extent that objects in the frame are moving, the two  
fields won’t match and aren’t well-suited for direct output in  
progressive scan.  
In contrast, 525/24P film-originated DVD is inherently progres-  
sive and is perfectly suited to progressive scan display. Ironically,  
today’s MPEG decoder chips automatically convert the 525/24P  
progressive DVD into 525/60i interlaced video. There’s no way  
to “tap into” the chips and extract the progressive signal.  
Additional processing is required to convert the 525/60i interlaced  
signal into a 525/60P progressive signal for output to a compa-  
tible television. The required process is called 3-2 reverse  
conversion. Because the process operates on a digital signal in  
the digital domain, it can result in a super high-quality video  
source that promises to be the ideal complement to high-end, big-  
screen televisions with 525P inputs.  
Film and Video on DVD  
In order to fit a feature-length film onto a CD-sized disc, the  
DVD format employs MPEG-2 digital compression. And  
one important trick of this compression is to make an  
important distinction between footage originally shot on  
video and footage originally shot on film. As you would  
expect, DVD stores video footage in its native 60i form.  
But you might be surprised to learn that most DVDs shot  
on film store the images at film’s native rate of 24 frames  
per second!  
Unfortunately, not every DVD player with 525P outputs fully  
delivers on the promise. Concerns such as flicker, motion  
artifacts and 3-2 cadence glitches can visibly degrade the  
viewing experience. As later sections will show, the Sony DVP-  
S9000ES represents a thorough engineering solution — one that  
realizes the full potential of progressive scanning.  
Realizing the Potential of 525P  
Progressive scan 525P outputs have been promoted as a  
must-have feature in high-end DVD players. But not all  
progressive-scan outputs are created equal. Sony, a leader  
in progressive scanning equipment for broadcasting and movie  
production, understands the limitations of conventional  
designs. And Sony engineers were determined to overcome  
those limitations. The result is Sony’s exclusive Precision  
Cinema Detection — the key to even higher performance in  
525P reproduction.  
Like material shot on video, the typical DVD shot on film is  
encoded from 60i videotape. But in the DVD authoring  
process, logic circuits in the majority of high-quality MPEG  
encoders detect the telltale pattern of 3-2-3-2 in the incoming  
video fields, the so-called 3-2 cadence. Since repeated fields  
would waste precious disc space, the DVD eliminates them and  
replaces them with First Field Repeat Flags (FFRFs) to tell  
the player which fields to repeat. The remaining fields are  
reassembled back into their original frames and encoded onto  
the DVD in progressive scan at 525/24P. This system is 20%  
more space-efficient than 60i. It’s an important advantage  
because it enables DVDs to hold films that are 20% longer. Or  
DVDs can encode each frame with a 20% more bits, for even  
better picture quality.  
Sony’s Fast and Pure Cinema Detection.  
A thorough solution to the engineering challenges of  
525P output, Sony’s Fast and Pure Cinema Detection  
incorporates four significant advances:  
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1. High accuracy film detection with FFRF.  
2. Dedicated microprocessor for motion detecting.  
3. Separate 3-2 reverse conversion algorithms for video and film-  
originated DVDs.  
Dedicated Microprocessor with Motion Detection  
The FFRF signal is designed to be present in all film-originated  
DVDs — and absent from all video-originated DVDs. Yet even  
in the most extreme case, where a film-originated DVD contains  
no FFRFs at all, Sony’s dedicated microprocessor with motion  
detection can elicit full performance. The microprocessor can  
judge the correlation between fields very accurately,  
4. Full 3-2 reverse conversion.  
Together, these advances enable the Sony DVP-S9000ES to  
deliver more consistent, more satisfying, more seamless 525P  
output with a wider variety of discs. Flicker, motion artifacts and  
3-2 cadence glitches are controlled. The visibility of scanning  
lines is minimized. Connect the DVP-S9000ES to a 525P-  
compatible television, monitor or projector and prepare to be  
amazed. You’ll approach the full glory of high definition picture  
quality — from today’s standard DVDs!  
supplementing the FFRF detection system. As a result, the Sony  
DVP-S9000ES can read and reproduce even this worst-case disc  
in beautiful, stable 525P.  
Separate Algorithms for Video and Film Originated DVDs  
“A” and “B” fields originated on film represent a single slice of  
time and have no motion between them. “A” and “B” fields  
originated on video represent different slices of time and can  
have significant motion. For this reason, film and video require  
substantially different algorithms in Interlace-to-Progressive  
conversion. Conversion of film-originated DVDs can use  
relatively simple de-interlacing. Conversion of video-originated  
DVDs requires a more complex motion-adaptive algorithm.  
High Accuracy Film Detection with FFRF  
Smooth 525P output depends on proper 3-2 reverse conversion.  
To accomplish this, the player must accurately reconstruct the 3-  
2 cadence of the original master videotape. The key to achieving  
this is the sequence of First Field Repeat Flags (FFRFs) on the  
DVD. Most DVDs contain a complete set of FFRFs. But  
inconsistencies in videotape editing, MPEG encoding and DVD  
authoring can result in irregularity in the FFRF signal. As  
reviewers have already noticed, this can cause even highly  
regarded players to stumble, producing visible motion artifacts.  
The correct application of the video algorithm requires the  
precise identification of motion between pairs of video fields.  
The DVP-S9000ES accomplishes this with the motion detection  
microprocessor. It uses the external graphics memory of the I-to-  
P conversion circuit to read pixel-level motion of each field at  
high speed. Then the microprocessor instantly selects the  
appropriate conversion algorithm for video, for film or for still  
scenes with no motion.  
Sony’s DVP-S9000ES overcomes the problem. The player  
performs high-speed detection of missing flags, with flag look-  
ahead and non-contiguous point detection. The player then  
reconstructs missing flags, for smooth, uninterrupted playback of  
DVD movies.  
Fig. 3: At the top are the original  
film frames, showing a car  
moving down the street. Next  
comes the original 3-2  
3-2 Reverse Conversion  
pulldown. Simple frame  
memory reverse conversion  
results in a motion blur every  
time fields from different film  
frames are combined. (This  
occurs for two out of every five  
frames — or 40% of the time!)  
Sony’s DVP-S9000ES, bottom,  
uses full 3-2 reverse conversion,  
to preserve the integrity of the  
original film frames.  
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Video  
DVD Technical Notes  
devices are not sophisticated enough to detect and maintain this  
High-quality Progressive Output from Film  
integrity. Here again, a well-designed DVD player surpasses  
most outboard devices.  
One potential way to cut corners in 525P output is to adopt  
relatively inexpensive frame memory. However, simple frame  
memory systems can expose the signal to motion blur on two out  
of every five frames. This becomes clear when we review the 3-  
2 pulldown process. In simple frame memory reverse conversion,  
the player combines the present field with the previous one — no  
matter what cinema frame it came from. If the previous field  
came from the same cinema frame, all is well and a good 525P  
picture results. But if the previous field came from the previous  
cinema frame — an event that occurs regularly on two out of  
every five frames — then images that were captured 1/30 second  
apart will be artificially combined on the television screen. The  
result will be a blur of any moving objects in the video picture.  
Such motion artifacts would be completely unacceptable in the  
design program of the DVP-S9000ES. That’s why the player  
undergoes the full 3-2 reverse conversion process.  
High Performance MPEG Image Processor  
Sony’s progressive scanning outputs represent a new benchmark  
in home video perfor-  
mance. But Sony’s design  
goals for the DVP-  
S9000ES required even  
more. Sony built a new  
MPEG Image Processor to  
undertake three crucial  
Photo 1: Sony’s MPEG Image Processor LSI  
functions:  
performs three important functions to optimize  
image quality.  
1. Motion Adaptive Field Noise Reduction.  
2. Block Noise Reduction.  
3. Clear Frame Still Image Performance.  
Achieving 525P: DVD Player vs. Television  
Many televisions capable of 525P have internal line doubling or  
scaling circuitry capable of converting conventional 525i inputs  
into 525P display. Sony’s own such circuits include the Digital  
Reality CreationTM (DRCTM) and DRC Multi-Function (DRC-  
MF) systems. With seemingly similar capabilities in both the  
DVD player and the television, it’s only natural to ask which is  
preferable. In most cases the 525P output of the DVD player  
will provide superior results. There are two reasons.  
Motion Adaptive Field Noise Reproduction  
Data compressed formats such as DVD are susceptible to noise.  
In the video signal, noise appears as tiny flecks or specks of  
unwanted color. Typically, the circuits that reduce noise also  
suppress fine picture detail. Viewers are asked to sacrifice the  
ultimate in resolution for the ultimate in low noise picture clarity.  
Many designs attempt to overcome this limitation by comparing  
the pictures from several video fields at once. Pixels that  
correlate from one field to the next are considered accurate.  
Pixels that vary are  
considered noisy. This  
method performs  
beautifully as long as  
the images are still.  
But because different  
Fig. 4:Allowing the television to transform the signal to 525P (top) exposes the signal to  
the losses entailed in additional D/Aand A/D conversions. Performing the conversion in  
the DVP-S9000ES (bottom) simplifies the signal path for an image with lower noise and  
lower distortion.  
fields can capture the  
image at different  
times, the noise  
reduction system can  
First, only the DVD player can perform the transformation on the  
DVD’s digital signal in the digital domain. The alternative is to  
convert the signal to analog, transfer this analog signal to the  
television, reconvert the signal back to digital and perform 525P  
conversion. This exposes the signal to the losses and distortions  
of an additional analog-to-digital and digital-to-analog  
easily misinterpret  
movement as noise.  
Fig. 5: Conventional digital noise reduction  
assumes that any difference between two fields is  
When this happens, the  
video noise. This effectively reduces the  
noise reduction circuit  
background noise, but can create new problems.  
can create ghost  
In this example, the movement of the car is  
interpreted as noise, resulting in an unwanted ghost  
images, unwanted  
image — a motion artifact behind the car.  
conversion. So the DVD player has a natural advantage.  
motion artifacts that  
may be more annoying than the original noise. In the past, Sony  
has overcome this by exempting areas of screen movement from  
noise reduction. Of course, this allows some video noise to  
reach the television — another compromise.  
Second, when designed properly, DVD player will observe the  
correct 3-2 inverse conversion, respecting the integrity of the  
original film frames. The overwhelming majority of outboard  
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Sony’s Motion Adaptive Field Noise Reduction uses new  
technology to overcome the old compromises. Thanks to the  
new circuit, the DVP-S9000ES can achieve very high signal-to-  
noise ratio, very high resolution and very accurate motion  
— all at the same time!  
differential luminance (Y) signals, is analyzed in blocks one  
pixel high by 8 pixels wide. The Hadamard transform converts  
the noise into an easily processed frequency distribution. To  
reduce errors, eight operations are performed for each pixel. The  
average of the eight values is then used. A limiter is then used to  
extract noise from the converted signals. Than a reverse  
Hadamard transform generates an error-correction signal that is  
added to the video signal to suppress noise.  
In addition, Sony’s Motion Adaptive Field Noise Reduction  
performs the same process for noise in the color difference  
channels, CB and CR. Since luminance and color difference  
signals are separately processed, their noise reduction can be  
individually optimized.  
The mathematics of this noise reduction process may be  
complex, but the results are easy to appreciate. The circuit  
accomplishes three formerly elusive goals simultaneously:  
1. Clean noise-free images on both moving portions and still  
portions of the screen.  
Fig. 6: Sony analyzes the video fields for movement by dividing the fields  
into blocks that are 4 pixels high by 16 pixels wide. When big changes  
are detected between two fields, Sony’s MPEG Image Processor  
determines that there is screen movement. The system attempts to match  
the block across a search window that extends four pixels up, three pixels  
down, eight pixels to the left and seven to the right.  
2. The full resolution of the DVD.  
3. Clear and natural image movement, without ghosting or other  
motion artifacts.  
Block Noise Reduction  
To overcome motion artifacts, the Sony design actively analyzes  
the fields for movement. The system divides the image into  
blocks of 4 pixels high by 16 pixels wide. This specific  
rectangular shape is based on the understanding that most  
movement in video images is horizontal. In blocks where no  
large changes are detected between fields, the system applies  
conventional noise reduction.  
Another characteristic limitation of MPEG-2 compression is  
block noise. This is the tendency for delicately shaded picture  
areas to be rendered as solid rectangles of color. Instead of a  
continuous contour of color on the cheek of an actress, fading  
softly into shadow, you see subtle squares of approximately  
correct color. Block noise is most apparent at the edges where  
squares meet. This effect is also called mosquito wings, because  
it can appear as subtle discoloration in tiny slices of the picture  
and just as quickly disappear.  
When large changes are detected between fields, the system  
automatically searches for block movement. The search  
“window” is 11 pixels high by 31 pixels wide.  
Sony’s MPEG Image Processor mounts a sophisticated, compre-  
hensive attack on block noise. The aim of Sony’s system is to  
identify those areas of subtle gradation of tone — the areas most  
prone to block noise — analyze the gradations and reconstruct  
the abrupt steps of tone as more linear, more gradual slopes.  
By finding matches for blocks that have moved, Sony’s Motion  
Adaptive Field Noise Reduction makes it possible to apply noise  
to areas of screen movement, in addition to the still background.  
The system compares data from the two fields by a mathematical  
method called the Hadamard transform. Noise, in the form of  
The principal challenge here is to distinguish legitimate steps in  
the picture tone (signal) from the unwanted, artificial steps  
(block noise). This separation of wanted and unwanted steps is  
made easier because the block borders area always at the same  
places on the screen. Their location is a fixed attribute of the  
MPEG-2 compression used in the DVD format.  
The DVD format divides the screen into 2,700 blocks (90 hori-  
zontal by 30 vertical). Each block measures 8 pixels horizontal  
by 8 pixels vertical. They’re shown as vertical rectangles because  
of interlace scanning. To judge for block noise, the MPEG Image  
Processor establishes the three pixels to the left and right of the  
Fig. 7: Sony’s Motion Adaptive Field noise reduction identifies and suppresses noise  
across the entire screen area — in moving parts of the picture as well as the motionless  
background. The process uses advanced motion detection and a Hadamard transform to  
suppress noise without sacrificing detail or generating motion artifacts.  
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Video  
DVD Technical Notes  
border as the Vertical Correlation  
Coefficient Area. A larger area,  
extending five pixels to the left and  
right of the border is the Activity  
Calculation Area.  
Small, random-seeming changes at the  
border are determined to be legitimate  
variations in the signal. These are not  
changed. Moderate changes arranged  
in a line along block borders are deter-  
mined to be block noise and are  
corrected. However, when the image  
hardly changes within five pixels of  
the border and undergoes a big change  
right at the border, this is considered  
to be a legitimate edge in the picture,  
and it passes uncorrected.  
Fig. 8: Detection and correction of block noise. On the left is the DVD block structure. In the center, a pair of blocks, showing  
the Activity Calculation Area. Across the bottom are sample readings. The first is a step characteristic of block noise, which  
gets corrected to a gradual slope. In the center are random variations, which are passed uncorrected. On the right is a large step  
characteristic of a legitimate picture edge. This also passes uncorrected.  
After detecting block noise, Sony’s MPEG Image Processor must  
determine the appropriate corrective action. The correction area  
extends four pixels on either side of the border. Correction  
consists of smoothing the step of block noise into a more natural,  
gradual slope.  
Noise Reduction system already knows that it’s a legitimate  
picture edge and will pass it through without correction.  
While we have described Block Noise Reduction for the vertical  
block edges, the system works equally well for horizontal block  
edges. The result is a comprehensive solution to even subtle  
picture errors caused by block noise. Images are clearer and  
more natural. The subtle gradations captured by today’s best  
cinematographers are rendered with a greater precision and care.  
The soft shadows that define a cheekbone, a fold of cloth or a  
footprint in the sand come through with effortless clarity.  
You can match the operation of Block Noise Reduction to the  
condition of each DVD. An on-screen menu offers eight  
settings, ranging from 0 (off) to 7 (maximum).  
Clear Frame Still Image Performance  
The third and final function of Sony’s MPEG Image Processor is  
Clear Frame. As many disappointed VHS users already know,  
when you hit the Pause button on a VCR, you see only the  
information for a single field. Much of the vertical resolution is  
lost. DVD players can perform far better in still mode, because  
DVD can present both fields together to represent the entire  
video frame.  
However, as we discovered in the discussion of 525P outputs, the  
parameters of film-originated DVDs are quite different from  
those of video-originated DVDs.  
Fig. 9: Thanks to motion detection, the Block Noise Reduction circuit “knows” when a  
car is approaching the edge of a block and does not try to correct the picture edge.  
Film-originated DVDs do best with frame pause, because both  
video fields represent the same slice of time. The two fields  
blend together perfectly for a full-resolution still image.  
For even greater sophistication, the Block Noise Reduction  
system takes advantage of the same motion detection engine as  
described above for Field Noise Reduction. In essence, the  
motion detector tells the Block Noise Reduction circuit, “a car is  
approaching the block edge.” When the car arrives, the Block  
Video-originated DVDs capture two fields that represent  
different slices of time, 1/60 second apart. To accommodate  
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this, DVD players have offered a choice between frame pause  
or field pause. Frame pause maximizes vertical resolution, but  
blurs whatever motion may be present in the image. Field  
pause gets rid of motion blur, but sacrifices vertical resolution,  
just like a VCR.  
Horizontal Sharpness  
+/- 20 steps  
+/- 20 steps  
stages 0 to 7  
stages 0 to 7  
Vertical Sharpness  
Block Noise Reduction  
Luminance (Y) Noise Reduction  
Chrominance (CB, CR) Noise Reduction stages 0 to 7  
Chroma Delay  
2 stages  
Now with the Clear Frame system of Sony’s DVP-S9000ES, you  
no longer need to choose. Because the MPEG Image Processor  
already has comprehensive motion detection circuitry, the player  
already “knows” which portions of a video-originated scene have  
motion. So the player applies high-resolution frame pause for all  
“Below Black” Reproduction with  
Graphical Gamma Adjustment  
The DVD format dictates specific quantization for specific bright-  
ness levels. For example, full black corresponds to a quantiza-  
tion of 16 while full white corresponds to 235. However, demand  
has grown for adjustment that matches the DVD player output to  
the characteristics of your display. Direct-view CRTs, plasma  
panels, CRT projectors and LCD projectors each have specific  
needs. For example, LCD projectors are subject to “black float”  
and can benefit from a calibration “below black.” CRT direct  
view televisions tend to loose dark detail when viewed in  
brightly-lit rooms.  
Historically, gamma adjustment has matched the grayscale of a  
video camera to the general transfer characteristics of CRTs.  
Sony’s Graphical Gamma Adjustment matches the grayscale  
performance of the player to the specific transfer characteristics  
of your display. Used with a commercially available calibration  
disc, the Graphical Gamma Adjustment can achieve ideal  
reproduction.  
The system enables you to make adjustments to gamma much  
like a graphic equalizer adjusts audio frequency response. As  
with an audio equalizer, aggressive adjustment can yield  
unnatural results. The controls are best used to make gamma  
curves that are smooth and subtle. Sony’s control offers eight  
points of correction, each with 8-bit precision. And you can  
always return the gamma controls to the industry-standard “flat”  
state by selecting “RESET” on the on-screen display.  
Fig. 10: Sony’s Clear Frame system delivers superior still images of video-originated  
DVDs. Moving areas, like the car are reproduced in motion-stopping field pause. But  
motionless areas, like the stop sign are reproduced in the full resolution of frame pause.  
So you see far higher pause mode resolution!  
the motionless areas of your picture, while it applies motion-  
stopping field pause to areas of movement. Clear Frame is simple,  
automatic and easy to appreciate. It’s a major improvement in  
freeze frame technology.  
High Precision Video Equalizer  
The video equalizer of the DVP-S9000ES enables users to fine-  
tune performance to match their monitors and viewing  
conditions. The equalizer is controlled via on-screen display and  
offers unusually fine adjustment:  
Picture  
+/- 20 steps  
+/- 20 steps  
+/- 20 steps  
+/- 20 steps  
Brightness  
Color Balance  
Hue  
Fig. 11: Graphical Gamma adjustment is like an eight-band graphic equalizer  
for grayscale and black level.  
10  
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Video  
DVD Technical Notes  
more accurate rendition of colors and gray scale from the deepest  
Custom Memory / Playback Memory  
black to the brightest highlights.  
Many of the video equalizer adjustments exist to tailor perform-  
ance for individual DVDs. That’s why the DVP-S9000ES can  
store your favorite settings for instant recall. Custom Memory  
lets you store five standard settings for different movie studios,  
different DVD genres or different types of display. Playback  
Memory stores your fine-tuned adjustments for up to 300 discs.  
Each time you insert one of the 300 discs, the player will  
automatically recall your specific hand-tailored adjustments.  
In addition, the converter employs video oversampling similar to  
the oversampling near universal in audio CD players. To capture  
13.5 MHz signals, the luminance channel uses a 27 MHz  
sampling frequency. The D/A conversion uses 2x oversampling  
system to bring this to 54 MHz. In a similar process, each  
chrominance channel gets 4x oversampling. The CB and CR  
sampling frequency of 13.5 MHz is quadrupled to 54 MHz. As  
in CD players, this method makes quantization noise easier to  
filter out, with more linear amplitude frequency response within  
the passband and superb suppression of noise outside the  
passband. As incorporated in the Analog Devices Super Sub  
Alias FilterTM  
Video Clock and Video Data TBC  
The master clock resides in the Audio section. But instead of  
passively receiving the external clock signal, the video circuit  
regenerates its own 27 MHz reference clock with its own quartz  
crystal. This reference is distributed to every digital video  
circuit. So timing errors and their consequent distortions are  
kept to a bare minimum. Images achieve maximum stability and  
minimum jitter.  
design, this  
achieves better  
signal-to-noise  
ratio and superb  
frequency  
response, taking  
DVD 4:2:2 D/A  
converters into the  
Fig. 13: The Super Sub Sampling Alias Filter (top) controls  
realm of 8:8:8  
the noise of alias signals (bumps on bottom).  
performance.  
Optimized Video Filters  
Separate video filters for progressive and interlaced outputs help  
achieve wide bandwidth, high resolution and minimum out-of-  
band noise.  
Fig.12: A dedicated 27 MHz quartz crystal oscillator regenerates a  
super-clean video-only reference clock.  
High-Speed Video Buffers  
The interlaced output must pass 6.75 MHz, while the progressive  
output must achieve twice that frequency — 13.5 MHz. Since  
bandwidth equates to resolution, the DVP-S9000ES is equipped  
with high-speed video buffer amplifiers that are more than equal  
to the task. These circuits can pass 325 MHz without loss. As  
such, the buffer amps are prepared to drive capacitive cable runs,  
while minimizing such distortions.  
54 MHz Video D/A Converter  
One natural consequence of supplying both progressive and  
interlaced video outputs is the need to provide both progressive  
and interlaced video D/A converters. DVP-S9000ES is equipped  
with both video D/A coverters, one for interlace output and the  
other for progressive output. The DVP-S9000ES progressive  
D/A converter was developed in cooperation with Analog  
Devices Corp., the same company that built the 32-bit SHARC  
processor in Sony’s TA-E9000ES A/V digital preamplifier.  
Output Capacitor-Less (OCL) Coupling  
In typical audio and video design, an output capacitor prevents  
the accidental passing of DC offset voltage from one component  
to the next. However, the mere presence of the output capacitor  
can affect the audio frequency response and literally tinge the  
television picture with unwanted shading. And these effects are  
beyond the adjustment of your television’s video adjustments.  
Sony’s answer is a rigorous design that controls DC offset  
voltages from the start. You get reliable operation without  
performance-robbing output capacitors.  
This is a Large Scale Integrated circuit (LSI) of remarkable  
processing power. Sony’s previous designs converted the DVD’s  
8-bit video samples with 10 bits of precision. This current LSI  
raises the standard of performance with 12-bit conversion for the  
luminance (Y) signal and 11-bit conversion for each of the color  
difference signals (CB and CR). Higher word lengths enable four  
times the fine gradations in the luminance channel, and twice as  
many gradations in each of the color channels. So you get a  
11  
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Video  
DVD Technical Notes  
Carefully Selected Parts  
Wide Pitch Component Output  
More than a labor of technology, the DVP-S9000ES represents  
the enthusiasm that Sony engineers share with high-end  
videophiles. That’s why the player incorporates a variety of  
carefully selected resistors, inductors, semiconductors and  
capacitors. Each plays a specific role in maximizing video  
performance.  
Sony engineers even anticipated the videophile-grade output  
cables likely to be used with the DVP-S9000ES. For this reason,  
the engineers deliberately spaced the Y/CB/CR output jacks  
further apart than common practice, the better to accommodate  
extra-fat cables and plugs!  
Low Distortion Film Capacitors. While electrolytic  
capacitors are suitable to power supply filtering, film  
capacitors are especially proficient for sound and picture.  
Many of these low-distortion capacitors contribute to the  
Many of these low-distortion capacitors contribute to the  
outstanding performance of the DVP-S9000ES.  
Oversized output resistors. Output resistors determine the  
impedance of the analog output circuits. Most designers avoid  
large resistors. But Sony incorporates large resistors of  
uncommonly tight tolerances. This contributes to the high  
slew rates required for wideband audio and video.  
Photo 2: Widely spaced Y/CB/CR output jacks accommodate even extra-fat videophile  
connectors.  
Output Signal Relay. To simplify connections to your  
television, the DVP-S9000ES uses a common set of component  
video terminals for both progressive and interlaced output.  
Naturally, this requires output switching. While common  
designs use semiconductor switches, Sony employs a high-  
quality mechanical relay. It’s a more expensive design that  
delivers more positive connections, lower resistance and lower  
noise across the switch. Progressive and interlaced output can  
be selected via on-screen menus or via back panel switch.  
Fig. 14: Overview of the video processing circuit board.  
12  
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Audio  
DVD Technical Notes  
Laser wavelength  
Lens numerical  
aperture (NA)  
Playback frequency  
range (theoretical)  
Dynamic range  
(theoretical)  
780nm  
0.45  
650nm  
0.60  
A Listening Experience Beyond All Expectations  
The DVP-S9000ES is more than just a cutting edge Sony  
DVD-Video player. It’s a Sony high fidelity component of  
the first order. This is the very first DVD player to be  
part of Sony’s acclaimed ES Series, the Elevated Standard in  
audio/video. It incorporates circuits, topology and  
DC — 20,000 Hz DC — >100,000 Hz  
96 dB (audible More than 120 dB  
range)  
(audible range)  
features carefully designed to maximize DVD-Video sound  
Maximum playback  
time  
Approx. 74 min. Approx. 110 min.  
(stereo)  
(stereo)  
tracks, Compact Discs and Super Audio Compact Discs.  
Approx. 74 min.  
(multi-channel and  
stereo)  
Super Audio Compact Disc:  
Because there’s So Much More to Hear TM  
Additional functions  
Text, graphics Text, graphics,  
video  
The Compact Disc was an important accomplishment in music  
reproduction. But over the years, discerning listeners have  
demanded even more. That’s why Sony and Philips, the  
inventors of CD, have created the new Super Audio Compact  
Disc (SACD). Thanks to a revolutionary technology called  
Direct Stream Digital(tm) (DSD(r)) encoding, this is the highest  
quality stereo sound source available today.  
Security. Pirated copies of discs threaten music companies,  
producers and musicians alike. In addition, consumers need  
protection from fraudulent, unauthorized copies. That’s why  
authorized SACDs are identified by both visible and invisible  
watermarks. The visible watermark is a faint image on the  
signal side of the disc, made possible by Pit Signal Processing  
(PSP) technology. Missing or corrupted watermarks warn  
consumers of unauthorized discs. Invisible watermarks  
authenticate the discs prior to playback. If the SACD player  
cannot read the watermark, the SACD will not play.  
Fidelity. With DSD encoding, SACD can capture more of the  
original sound source. The SACD format offers frequency  
response to 100 kHz and a theoretical dynamic range of 120 dB.  
But specifications alone cannot express the DSD advantage.  
DSD one-bit encoding strips away entire classes of distortion  
that have always characterized PCM. The DSD system  
provides nothing less than a quantum leap in music resolution.  
Compatibility. Music enthusiasts have already made a  
substantial commitment to their CD collections. To protect this  
investment, every SACD player performs superbly with the  
more than 13 billion audio Compact Discs currently in  
existence. And the SACD format also includes a hybrid disc  
option that will play back beautifully in any home, car and  
portable CD player made since 1982.  
Simplicity. To audiophiles, purity has always meant simplicity.  
So with SACD, there’s no option for music to be recorded at  
anything less than the highest possible resolution. There’s also  
no option for lossy compression of any kind. And you’ll never  
experience stereo derived from a computerized fold-down.  
SACD is about music, pure and simple.  
Three types of discs. With the SACD format, music  
companies can offer three different types of discs. The single-  
layer disc can store a full album of high-resolution music. A  
dual-layer disc provides nearly twice the playing time. There’s  
even a hybrid disc that contains both a high density music layer  
and a standard density CD layer for compatibility with over  
700 million CD players, worldwide.  
• Capacity. As a stereo music carrier, the Super Audio Compact  
Disc can hold over six times the data of Compact Disc. Some  
SACDs have enough room for both a two-channel mix and a  
multi-channel version of the same music, not to mention text  
and graphics.  
The Music. SACD has triggered an outpouring of music, both  
reissued and new, from the world’s preeminent artists. Jazz  
greats like Dave Brubeck, Miles Davis, Herbie Hancock, Milt  
Jackson, Wynton Marsalis and Oscar Peterson. Classical  
virtuosos like Emanuel Ax, Glenn Gould, Yo-Yo Ma and Isaac  
Stern. With the world’s finest orchestras under the batons of  
Leonard Bernstein, Eugene Ormandy, Wolfgang Sawallisch  
and Bruno Walter. These performances were singular events.  
Now captured on SACD, these titles gloriously demonstrate  
music the way it should be.  
CD  
SACD (single layer)  
12 cm  
Disc diameter  
Disc thickness  
Playback side  
Coding System  
12 cm  
Fig. 16: 3 Types of Disc  
1.2 mm  
1.2 mm  
Single  
Single  
16-bit linear  
PCM encoding  
44,100 Hz  
680 MB  
1-bit DSD encoding  
Sampling Frequency  
Disc data capacity  
2,822,400 Hz  
4.7 GB  
Disc minimum pit length 0.83 micrometers 0.40 micrometers  
Disc track pitch 1.60 micrometers 0.74 micrometers  
13  
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Direct Stream DigitalTM Encoding:  
The Digital Equivalent of Straight Wire with Gain  
A Foundation for the Future  
The DSD analog-to-digital converter produces a one-bit pulse  
For nearly 30 years, digital audio has been based upon Pulse  
Code Modulation (PCM) technology — and nobody knows PCM  
better than Sony. We’ve used it to develop everything from  
Compact Disc and DAT to professional DASH recorders and  
digital mixing consoles. But to achieve a truly fundamental  
breakthrough in music reproduction, Sony has invented a truly  
amazing audio technology: Direct Stream Digital (DSD)  
encoding. DSD encoding is destined to serve as the foundation  
for digital audio in the future.  
train that appears remarkably analog. In this manner, DSD encoding  
combines the  
advantages of digital  
recording with the  
well-regarded  
characteristics of  
analog sound. For  
recording artists,  
Fig.16: The Direct Stream Digital pulse train  
“looks” remarkably like the analog waveform it  
producers and  
represents. More pulses point up as the wave goes  
engineers, DSD  
positive and down as the wave goes negative.  
technology is a  
Simplifying the Signal Path  
Even the most advanced PCM record/playback systems require  
decimation and interpolation filters that can cause problems,  
including requantization noise, passband ripple and ringing.  
These degradations can smear musical overtones, muddy the  
soundstage and compromise overall transparency. A radically  
simpler approach, Direct Stream Digital processing eliminates  
these problems by eliminating the filters! It enables a 1-bit  
signal to be recorded directly.  
Overview of DSD Circuitry  
priceless new tool. For audiophiles, it’s a major step closer to  
pure music.  
Not surprisingly the DVP-S9000ES audio section makes  
extensive use of technologies originally developed for the world’s  
first SACD player, the Sony SCD-1. Here are the highlights.  
1. RF Processor. For all types of disc, including DVD, this  
circuit performs clock signal extraction, synchronization,  
demodulation and error correction.  
Beyond Comparison  
Direct Stream Digital processing is dramatically different, even  
when compared to the most sophisticated PCM technology. This  
1-bit system encodes music at an astonishing 2,822,400 samples  
per second. The result is more than just superb frequency  
response and dynamic range. You’ll hear the inner detail of  
choral ensembles. The reverberation trailing from a guitar chord.  
And the acoustic space surrounding the instruments. With DSD  
technology, you hear every nuance of sound reproduced with  
incredible ease and clarity.  
2. DSD Decoder. For SACD only. Authenticates the SACD  
invisible watermark, separates text from music and forms the  
left and right DSD pulse trains.  
3. ACP System. For SACD only. Controls the influence of  
switching distortion.  
4. VC24 Plus Digital Filter. For CD only. A supremely  
advanced version of the familiar 8x oversampling digital filter.  
5. Current Pulse D/A Converter. For SACD and CD.  
Supremely accurate conversion from 1-bit digital to analog.  
6. Low Pass Filter. The SACD analog low pass filter helps  
deliver frequency response to 100,000 Hz, unprecedented in a  
home audio source component.  
Fig. 15: In high-end audio, simplest is best. And compared to conventional PCM, the new DSD system is far simpler.  
14  
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Audio  
DVD Technical Notes  
DSD Decorder  
96 kHz / 24-bit capable Current Pulse  
D/A Converter ( for all discs )  
Organizing the data into left and right pulse streams is the job of  
the DSD decoder. A Sony-built LSI, the DSD decoder first reads  
Conventional D/A converters generate pulse height from the voltage  
power supply — a method that can expose the signal to subtle  
power supply voltage fluctuations. The Current Pulse Converter  
overcomes this limitation. The design changes the incoming train of  
voltage pulses to a train of current pulses. Because the circuit  
incorporates an extremely clean “constant current” source, the  
pulses emerge with the desired flat tops, flat bottoms and identical  
height. You get audio output of extraordinarily low distortion. The  
Current Pulse D/A converter operates for SACD, CD and DVD-  
Video sound tracks alike. The system supports the highest sound  
quality in DVD-Video: 96 kHz/24-bit recording.  
the invisible watermark — a key anti-piracy feature — and then  
decodes the incoming data. Data on the disc originate as  
alternating bursts of left-channel and right-channel information.  
Buffer memory and master clock sync enable the bursts to be  
output as two  
continuous,  
simultaneous  
streams. The DSD  
decoder also reads  
sub code data,  
including text and  
Table of Contents  
information such  
VC 24 Plus Digital Filter ( for DVD-Video and CD )  
Photo 3: The heart to SACD reproduction, Sony’s DSD  
as track number  
A conventional digital filter has a fixed filtering coefficient with  
no user controls. Sony’s Variable Coefficient digital filter is a  
dramatic departure. The VC digital filter actually offers different  
settings, representing different filter coefficients, different  
filtering methods and different objectives in reproduced sound.  
decoding LSI.  
and playing time.  
To preserve the maximum accuracy of the DSD pulses, our  
design program identified two basic goals:  
• Amplitude axis precision  
• Time axis precision  
Separate Low-Pass Filters ( for all discs )  
Sony’s Accurate Complementary Pulse Density Modulation (ACP)  
system and Current Pulse D/A Converter meet the first goal.  
Sony’s new pulse generator in VC24 achieve the second goal.  
After current-to-voltage conversion, a simple low-pass filter is  
all that’s required to produce an analog output. Unlike CD, the  
SACD cutoff frequency is largely determined by the characteris-  
tics of the player’s low-pass filter. The DVP-S9000ES low-pass  
filter has aresponse  
curve that slowly  
falls in the vicinity  
of 50 kHz,  
ACP System  
The Megahertz switching speeds of DSD decoding have an  
unfortunate byproduct, switching glitches, rough irregularities in  
the DSD pulse train. Sony’s Accurate Complementary Pulse  
Density Modulation (ACP) overcomes this by converting the  
DSD pulses. Instead of encoding 1 as a pulse and 0 as the  
absence of a pulse, ACP represents each digital 1 as wide 1  
followed by a narrow 0. And ACP represents each digital 0 as a  
narrow 1 followed by a wide 0. In this way, ACP effectively  
converts the data from pulse height (sensitive to glitches) to  
pulse width (insensitive to glitches). So glitches are not passed  
along to subsequent circuitry.  
enabling usable  
response out to  
100 kHz, some  
five times higher  
than previous  
Fig. 18: The Low Pass Filter of the DVP-S9000ES enables  
home audio  
usable frequency response to 100 kHz, some five times higher  
than previous home audio sources.  
sources.  
Two Audio Master Clocks ( for all discs )  
As an audio/video player, the DVP-S9000ES needs to generate  
master clock frequencies for audio and video simultaneously.  
Typical practice deploys a Phase Locked Loop (PLL) circuit to  
subdivide the video master clock for audio use. However, this  
exposes the audio signal to unwanted jitter, which can generate  
audible distortion. That’s why the DVP-S9000ES subdivides  
audio master clock for video use. The SACD and CD master  
clock runs at 44.1 kHz x 1024 = 45 MHz. The DVD-Video sound  
track master clock runs at 48 kHz x 1024 = 49 MHz. And the  
DVD-Video clock for pictures downconverts this via PLL to  
Fig.17: Thanks to Pulse Density Modulation, the ACP system  
disregards amplitude distortions and switching glitches.  
15  
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Audio  
DVD Technical Notes  
27 MHz. For a further reduction in noise, the power supply to  
any unused clocks is automatically turned off.  
purity. A straight path carries the signal directly from the D/A  
converter input to the output terminals on the back panel. As an  
added precaution, extra-thick low-impedance jumper cables  
eliminate patterning between the main ground of the audio board  
and the main ground of the digital block.  
Fig. 19: Contrary to common practice, the DVP-S9000ES subdivides the audio master  
clock for video, not the other way around.  
Photo 4: The front and back of the audio circuit board reveal  
Audio Direct Output ( for all discs )  
One potential concern with so many types of circuitry in one  
chassis is mutual interference. Sony minimizes the possibility of  
radiated interference with Audio Direct output, a front panel  
switch that automatically shuts off all Video and Digital outputs.  
The switch enables the DVP-S9000ES to operate audio-only  
whenever you desire. Three other power configurations are also  
offered:  
Twin R-Core Power Transformers ( for all discs )  
Power transformer cores and windings can vibrate and degrade  
the sound, radiating 60 Hz hum into nearby audio circuits.  
That’s why Sony shields the audio circuit board. And that’s why  
Sony chose twin R-Core power transformers. The R stands for  
round. Not only  
is the core round,  
it has a cylindrical  
cross section,  
Video Off. Shuts down the video and power circuitry to  
eliminate its effect on the audio circuitry.  
Digital Off. Shuts down the signal.  
enabling the  
Display Off. Cuts off power to the fluorescent display panel,  
for a further reduction in noise.  
transformer  
windings to be  
wrapped without  
the voids or gaps  
Jitter-Free 96 kHz / 24-bit Digital Output  
Photo 5: Sony minimizes power transformer hum and  
that permit  
noise by incorporating two carefully made R-core power  
The DVP-S9000ES is capable of sending out DVD-Video sound  
tracks at full 96 kHz/24-bit resolution on discs without copy  
protection. (Discs with copy protection are limited to 48 kHz/  
16-bit digital outputs.) To support full 96 kHz/24-bit digital  
output, the optical output module operates all the way up to 13.2  
Mbps. So you can connect with maximum fidelity.  
vibration. This  
transformers.  
results in far less  
radiation, far less hum. The core itself is formed from long  
narrow magnetic steel plates, rolled into shape without gaps that  
might also generate hum. To further protect the audio stage from  
interference, one transformer handles video, system control  
and servo systems while the other specializes in audio  
alone.  
As an added safeguard to signal integrity, the digital output  
signal is re-synchronized immediately before the coaxial and  
optical digital outputs. The signal is realigned to the highly  
accurate master clock at 49 MHz (for DVD-Audio) and 45 MHz  
(for CD and SACD). This reduces the possibility of distortion-  
inducing jitter at the digital outputs.  
Power Supply Configuration ( for all discs )  
While switching power supplies are common in DVD players,  
Sony demanded more. We use more traditional series power  
supplies with the twin transformers followed by rectifiers.  
Separate power supply secondaries are employed for each stage.  
And the secondaries are located on the circuit boards they serve:  
audio, video, system, motor drive and display. In addition,  
separate regulation is used in the D/A converter, VC 24 Plus,  
master clock oscillator and digital output buffer blocks. This  
minimizes even slight opportunities for mutual interference  
through the power supply.  
Separate Audio Circuit Board ( for all discs )  
As a further defense against radiated noise, the audio circuitry is  
isolated on its own circuit board, shielded by 1.6 mm sheet metal  
and fed by its own, dedicated power supply secondary, located  
on the circuit board itself. The board is laid out in classic dual  
monaural configuration, for enhanced stereo separation and sonic  
16  
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Construction  
DVD Technical Notes  
while the bottom plate is 2 mm thick. The chassis corners  
Audiophile Parts  
benefit from stiffening boards that add strength and diffuse the  
natural resonant frequencies. In this way, materials of different  
shapes and thicknesses combine to suppress vibration. In  
addition, copper plating on the back panel and bottom help  
reduce noise by decreasing the ground potential difference.  
The same insistence on high-performance parts that marks the  
video section of the DVP-S9000ES can be found throughout the  
audio section, as befits a fully qualified member of Sony’s ES  
Series. The parts are selected after undergoing exhaustive  
testing. For example, the audio circuit board is a glass epoxy  
design that steadfastly resists deformation. The copper foil  
traces on the circuit board are twice the normal thickness.  
Principal parts are secured with through-hole connections. The  
digital circuit is intentionally compact with the shortest practical  
leads. High quality electrolytic capacitors are used wherever  
they can impact sound. Even the AC power line uses gold  
plating for the minimum in contact resistance. The result is  
remarkably pure, superbly clean sound.  
Off Center Insulator Feet  
To prevent shelf-borne vibration from entering the chassis, Sony’s  
insulator feet locate the screw hole off center. Varying the radius  
from screw to perimeter tends to vary the resonant frequency  
within the foot — diffusing one potential path for vibration.  
New Fixed Base Unit Mechanism  
The DVP-S9000ES marks the debut of an all-new drive mechanism  
of unusual design. On a conventional DVD drive, the spindle,  
drive motor and optical pickup are mounted on a pivoting base  
unit. The pivot is necessary because the base unit needs to drop  
out of the way when the disc drawer is opening and closing. And  
it needs to swing back up into playing position once a disc has  
been loaded. Unfortunately, this pivoting mechanism is an open  
invitation to vibration and resonance.  
Build Right  
Vibration is the enemy of DVD players for two powerful  
reasons. First, vibration in the disc or optical pickup triggers  
unwanted operation in the tracking servos. This can radiate  
spurious noise throughout the chassis. And this radiation occurs  
in exactly the wrong place — near the sensitive low-level optical  
pickup preamplifier. To make matters worse, vibration can also  
cause subtle distortions in the audio circuitry. Vibration can have  
tiny “microphonic” effects on capacitor values and point-to-point  
wiring. While these distortions are not always apparent to the  
casual listener, Sony’s design program required performance  
without compromise. For all these reasons, the DVP-S9000ES  
takes advantage of Sony’s comprehensive anti-resonant design.  
It’s one more way the player reflects its dual heritage as a top  
Sony DVD machine and proud member of the ES Series.  
Sony engineers  
demanded more.  
And they developed  
the fixed base unit  
mechanism. In the  
new Sony design,  
the spindle, motor  
and optical pickup  
Fig. 20: Conventional DVD players use a pivoting base unit  
base unit is rigidly  
Copper-Plated Frame and Beam Chassis  
(top), prone to vibration. The Sony DVP-S9000ES uses a  
bolted to a sub-  
rigidly fixed base unit (bottom), minimizing vibration and  
The first line of defense against vibration is Sony’s Frame and  
Beam (FB) chassis. In this design, the thick, high-strength  
chassis frame gains additional strength from a horizontal beam.  
The back panel and main parts use 1.6 mm thick sheet metal  
chassis, to reduce  
its consequent distortion.  
any possibility of  
resonance. When you load a disc into the DVP-S9000ES, the  
disc not only moves laterally into the player, it also descends  
onto the spindle. Thanks to Sony’s new design, the disc is  
always read in a silent, extremely stable non-resonant  
environment. Vibration is minimized, along the servo activity  
vibration can cause. The sensitive RF preamplifier is protected  
from servo radiation.  
Hermetic Shutter  
When it carries the disc down to the fixed base unit, the loading  
tray no longer acts like a door to seal the front-panel loading slot.  
Sony engineers addressed this by creating a hermetic shutter. It  
forms an airtight seal to protect the disc and pickup from airborne  
vibration. Even when the speakers in your room are going full  
blast, the disc rotates in peace and quiet.  
Photo 6: Sony’s copper-plated Frame and Beam (FB) is not only strong. Parts of different  
shapes and thicknesses combine to suppress resonance.  
17  
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Construction/  
Conveniences  
DVD Technical Notes  
Performance Meets Refinement  
BMC Mechanical Deck  
The base unit is mounted on a subchassis called the mechanical  
deck. On the DVP-S9000ES, this is a self-contained box formed  
of Sony’s Bulk Molding Compound (BMC). Long a fixture in  
Sony anti-resonant design,  
Thoughtful touches and operating refinements make the  
DVP-S9000ES a pleasure even before playback begins.  
Thick aluminum front panel. The DVP-S9000ES has serious,  
down-to-business styling with a thick, uncluttered aluminum  
front panel. The fluorescent display window is made of high  
hardness acrylic resin, especially formulated to resist scratches.  
Short stroke controls. Front-panel buttons are designed to  
respond to the lightest finger contact. Audio feedback in the  
form of a defeatable beep tone confirms each command.  
LED/fluorescent display dimmer. To minimize distraction  
during movie playback, the front panel fluorescent display can  
be dimmed. When you dim the display, the player  
simultaneously dims the front panel LEDs.  
BMC is carefully  
formulated for high strength  
and high internal loss. Like  
steel, it has the rigidity  
required for its structural  
purpose. But unlike steel,  
BMC steadfastly resists  
vibration and resonance.  
BMC consists of calcium  
carbonate — a principal  
component of marble — glass  
Control Menu. With DVD-Video, SACD and CD playback  
in a single chassis, the DVP-S9000ES is brimming with control  
options and configuration possibilities. Sony organizes all the  
options for maximum clarity and presents them on your  
television screen.  
fiber reinforcement and  
Fig. 21: The mechanical deck is a sealed  
unsaturated polyester. The  
enclosure, shown here with drawer open & closed  
material is subjected to  
thermosetting and is formed into the mechanical deck floor, walls  
and ceiling. Even the disc loading tray is made of non-resonant  
BMC.  
Luminescent remote control. Because owners will be  
enjoying DVDs with the room lights turned down, the remote  
control features glow-in-the-dark keys for Play, Stop, Pause  
and Display.  
Mechanical Deck Insulators  
Sound feedback. Beep tones confirm your selections for both  
front-panel and remote control commands. If you prefer, the  
audio feedback can be deactivated.  
For further protection, the mechanical deck is insulated from the  
DVP-S9000ES main chassis via dedicated supports.  
A new Digital Signal Processor (DSP) handles 40 million  
instructions per second (40 MIPS). The result is highly precise  
control of the optical pickup, for supremely accurate readout of  
the high-density DVD and SACD signal surface. The new DSP  
also helps deliver superb high-speed search and special effects  
playback. And it helps reduce the duration from disc insertion to  
the start of playback.  
Picture Memory. Similar to the customizable desktop picture  
on a PC, the DVP-S9000ES can display different scenes in the  
Stop mode. These can include favorite video scenes stored in  
memory, along with jacket pictures from CD Extra discs as  
well as DVDs.  
Bit Rate Display. Users can track the variable bit rate of  
MPEG-2 compression with on-screen displays of video and  
audio bit rates.  
High-Speed, High-Precision Servo DSP  
Layer and Pickup Display. The DVP-S9000ES can show an  
on-screen graphic representation of your current position on  
the disc, along with your current layer for dual-layer discs.  
Custom Parental Controls. You can password protect the  
viewing of up to 300 DVDs, restricting playback to PG  
versions (on compatible discs) or preventing playback  
altogether.  
This digital controller must speak to such analog devices as the  
disc drive motor, tilt motor, and thread motor. For this purpose,  
the system uses 20 MHz Sigma Delta modulation and a highly  
linear 1-bit D/A converter. The result is 10-bit accuracy in the  
motor control output voltages.  
DVD, SACD and CD TEXTTM display. The DVP-S9000ES  
provides scrolling front panel display for the text functions of  
compatible discs.  
Enviromentally friendly. To conserve energy, power,  
consumption in the Standby mode is less than 1 watt.  
Operation automatically shuts down 30 minutes after Stop.  
To reduce pollution, the printed circuit boards are halogen-free.  
Fig. 22: The drive system uses an uncommonly powerful 40 MIPS DSP,  
combined with an uncommonly accurate Delta Sigma 1-bit D/Aconverter.  
18  
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Specifications  
DVD Technical Notes  
DVP-S9000ES Specifications  
Audio Characteristics  
Frequency Response  
DVD(PCM 96kHz): 2Hz to 44kHz (-2dB; ±1dB at 44kHz)  
CD: 2Hz to 20kHz (±0.5dB)  
SACD: 2Hz to 100kHz (-3dB; ±1dB at50kHz)  
More than 115dB (DVD)  
Signal-to-noise Ratio  
Harmonic Distortion  
DVD: Less than 0.0015%  
CD: Less than 0.002%"  
SACD: Less than 0.0015%  
Dynamic Range  
Wow and Flutter  
More than 103 dB(DVD/SACD)  
More than 99 dB(CD)  
Beneath the limits of measurement (± 0.001% weighted peak)  
General  
Power requirements  
Power Consumption  
Dimensions  
220-240V AC, 50/60Hz  
43W(Standby less than 1W)  
5
17 x 5 x 15 / " (430 x 126 x 398mm)  
8
Weight  
approx 27 lbs., 12 oz. (12.6 kg)  
Photo 8: Remote control  
Photo 7: Front panel  
Photo 9: Rear panel  
19  
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Printed in Singapore  
Specifications, photos and related data are intended for design purposes and may be different from those of the product.  
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