AD9889KSTZ-80 Analog Devices Inc, AD9889KSTZ-80 Datasheet - Page 17
AD9889KSTZ-80
Manufacturer Part Number
AD9889KSTZ-80
Description
TRANSMITTER HDMI/DVI 80-LQFP
Manufacturer
Analog Devices Inc
Type
HDMI, DVI Transmitterr
Datasheet
1.AD9889KSTZ-80.pdf
(48 pages)
Specifications of AD9889KSTZ-80
Applications
Recorders, Set-Top Boxes
Mounting Type
Surface Mount
Package / Case
80-LQFP
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Part Number:
AD9889KSTZ-80
Manufacturer:
ADI/亚德诺
Quantity:
20 000
AUDIO DATA CAPTURE
The AD9889 is capable of receiving audio data in either I
S/PDIF format for packetization and transmission over the
HDMI interface.
I
The AD9889 can accommodate from two to eight channels of I
audio at up to a 192 kHz sampling rate. Selection of I
(vs. S/PDIF) is set with R0x0A[4] = 0. The detected sampling
frequency (from 32 kHz to 192 kHz) can be read in R0x04[7:4].
The output sampling frequency (from 32 kHz to 192 kHz) can be
selected with R0x15[7:4]. The number of channels and the specific
channels can be selected in R0x0C[5:2] and R0x50[7:5]. If all eight
channels (I
1 selects eight channels. If I
selects this. The placement of these packets with respect to their
output can be specified in Register R0x0E to Register R0x11.
Default settings place all channels in their respective position (I
left channel in Channel 0 left position, I
Channel 3 right position), but this mapping is completely
programmable.
The AD9889 supports standard I
justified I
between 16 bits and 24 bits (R0x14[3:0]).
S/PDIF AUDIO
The AD9889 is capable of accepting two channel LPCM and
encoded audio up to a 192 kHz sampling rate via the S/PDIF.
S/PDIF audio input is selected by setting R0x0A[4] = 1. The
AD9889 is capable of accepting S/PDIF with or without an
MCLK input. When no MCLK is present, the AD9889 makes
the determination of the CTS value (N/CTS determines the
MCLK frequency).
CTS GENERATION
Audio data being carried across the HDMI link, which is driven
by a TMDS (video) clock only, does not retain the original
audio sample clock.
2
S AUDIO
2
S formats via R0x0C[1:0] and sample word lengths
2
S0 to I
2
S3) are required, setting all bits or R0x0C[5:2] to
VIDEO CLOCK
128 ×
2
S0 only is needed, setting R0x0C[2] to 1
f
N
S
2
S, left-justified I
1
N AND CTS VALUES ARE TRANSMITTED USING THE “AUDIO CLOCK REGENERATION”
PACKET. VIDEO CLOCK IS TRANSMITTED ON TMDS CLOCK CHANNEL.
2
S3 right channel in
REGISTER
DIVIDE
BY
N
N
SOURCE DEVICE
2
2
S, and right-
S audio mode
Figure 8. Audio Clock Regeneration
COUNTER
CYCLE
2
TIME
S or
2
2
Rev. 0 | Page 17 of 48
S0
S
CLOCK
TMDS
CTS
N
1
The task of recreating this clock at the sink is called audio clock
regeneration. There are a variety of clock regeneration methods
that can be implemented in an HDMI sink, each with a
different set of performance characteristics. The HDMI
specification does not attempt to define exactly how these
mechanisms operate. It does, however, present a possible
configuration and it does define the data items that the HDMI
source supplies to the HDMI sink in order to allow the HDMI
sink to adequately regenerate the audio clock. It also defines
how that data is generated. In many video source devices, the
audio and video clocks are generated from a common clock
(coherent clocks). In this situation, there exists a rational
(integer divided by integer) relationship between these two
clocks. The HDMI clock regeneration architecture can take
advantage of this rational relationship and can also work in an
environment where there is no such relationship between these
two clocks, that is, where the two clocks are truly asynchronous
or where their relationship is unknown.
Figure 8 shows the system architecture model used by HDMI
for audio clock regeneration. The source determines the
fractional relationship between the video clock and an audio
reference clock (128 × audio sample rate) and passes the
numerator and denominator for that fraction to the sink across
the HDMI link. The sink can then recreate the audio clock from
the TMDS clock by using a clock divider and a clock multiplier.
The exact relationship between the two clocks is
The source determines the value of the numerator N as stated in
Section 7.2.1 of the HDMI specification. Typically, this value N
is used in a clock divider to generate an intermediate clock that
is slower than the 128 × fs clock by the factor N. The source
typically determines the value of the denominator cycle time
stamp (CTS) by counting the number of TMDS clocks in each
of the 128 × fs/N clocks.
1
128 × fs = f
DIVIDE
CTS
BY
SINK DEVICE
TMDS
_clock × N/CTS
MULTIPLY
BY
N
128 ×
f
S
AD9889
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