STMICROELECTRONICS STA020_10

STA020
96kHz DIGITAL AUDIO INTERFACE TRANSMITTER
„
„
„
MONOLITHIC DIGITAL AUDIO INTERFACE
TRANSMITTER
3.3V SUPPLY VOLTAGE
SUPPORTS:
– AES/EBU, IEC 958,
– S/PDIF, & EIAJ CP-340
– Professional and Consumer Formats
„
„
SO24
ORDERING NUMBER: STA020D
PARITY BITS AND CRC CODES
GENERATED
TRANSPARENT MODE ALLOWS DIRECT
CONNECTION OF STA020D AND STA120
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DESCRIPTION
The STA020D is a monolithic CMOS device which
encodes and transmits audio data according to the
AES/EBU, IEC 958, S/PDIF, & EIAJ CP-340 interface standards. It supports 96kHz sample rate operation
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The audio serial port is double buffered and capa-
M0
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23
6
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SCK
FSYNC
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SDATA
C
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V
7
8
M1
M2
22
21
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The STA020D accepts audio and digital data
which is then multiplexed, encoded and driven
onto a cable.
BLOCK DIAGRAM
ble of supporting a wide variety of formats.
The STA020D multiplexes the channel, user, and
validity data directly from serial input pins with
dedicated input pins for the most important channel status bits.
VD+
GND
19
18
MCK
5
16
AUDIO
SERIAL PORT
20
MUX
DIFFERENTIAL
9
17
TXP
TXN
REGISTERS
7
15
DEDICATED CHANNEL CBL
STATUS BUS
April 2010
RST
10
11
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24
TRNPT
D97AU599A
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STA020
ABSOLUTE MAXIMUM RATINGS
Symbol
Parameter
Value
Unit
4
V
-0.3 to VD+ 0.3
V
VD+
DC Power Supply
VIND
Digital Input Voltage
Tamb
Ambient Operating Temperature (power applied)
-20 to +85
°C
Tstg
Storage Temperature
-40 to 150
°C
RECOMMENDED OPERATING CONDITIONS (GND = 0V; all voltages with respect to ground)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
VD+
DC Voltage
3
3.3
3.6
V
Tamb
Ambient Operating Temp.
0
25
70
°C
PIN CONNECTIONS (Top view)
C7/C3
1
24
TRNPT/FC1
PRO
2
23
M0
C1/FC0
3
22
M1
C6/C2
4
21
M2
MCK
5
20
TXP
SCK
6
19
VD+
FSYNC
7
18
GND
SDATA
8
17
TXN
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C9/C15
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(s)
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C/SBF
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16
RST
10
15
CBL/SBC
11
14
EM0/C9
12
13
EM1/C8
D97AU608A
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PIN DESCRIPTION
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N°
Pin
Function
Power Supply Connections
18
GND
Ground.
19
VD+
Positive Digital Power. Nominally +3.3V.
Audio Input Interface
6
2/14
SCK
Serial Clock.
Serial clock for SDATA pin which can be configured (via the M0, M1 and M2 pins) as an
input or output and can sample data on the rising or falling edge.As an output, SCK will
contain 32 clocks for every audio sample.
STA020
PIN DESCRIPTION (continued)
N°
Pin
7
FSYNC
Frame Sync.
Delineates the serial data and may indicate the particular channel, left or right and may be
an input or output. The format is based on M0, M1 and M2 pins.
Function
8
SDATA
Serial Data.
Audio data serial input pin.
21,
22,23
M0, M1, M2
Serial Port Mode Select.
Selects the format of FSYNC and the sample edge of SCK with respect to SDATA.
Control Pins
1
C7/C3
2
PRO
3
C1/FC0
Channel Status Bit 7/Channel Status Bit 3
In professional mode, C7 is the inverse of channel status bit 7. In consumer mode, C3 is the
inverse of channel status bit 3, C7/C3 are ignored in Transparent Mode.
Professional/Consumer Select.
Selects between professional mode (PRO low) and consumer mode (PRO high). This pin
defines the functionality of the channel status parallel pins. PRO is ignored in Transparent
Mode.
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Channel Status Bit 1/Frequency Control 0.
In professional mode, C1 is the inverse of channel status bit 1. In consumer mode, FC0 and
FC1 are encoded versions of channel status bits 24 and 25 (bits 0 and 1 of byte 3). When
FC0 and FC1 are both high, CD mode is selected. C1/FC0 are ignored in Transparent
Mode.
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C6/C2
Channel Status Bit 6/Channel Status Bit 2.
In professional mode, C6 is the inverse of channel status bit 6. In consumer mode, C2 is the
inverse of channel status bit 2. C6/C2 are ignored in Transparent Mode
9
V
Validity.
Validity bit serial input port. This bit is defined as per the digital audio standards wherein V =
0 signifies the audio signal is suitable for conversion to analog. V = 1 signifies the audio
signal is not suitable for conversion to analog, i.e. invalid.
10
C/SBF
11
U
12
C9/C15
13
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Channel Status Serial Input/Subcode Frame Clock.
In professional and consumer modes this pin is the channel status serial input port. In CD
mode this pin inputs the CD subcode frame clock.
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User Bit.
User bit serial input port.
Channel Status Bit 9/Channel Status Bit 15.
In professional mode, C9 is the inverse of channel status bit 9 (bit 1 of byte 1). In consumer
mode, C15 is the inverse of channel status bit 15 (bit 7 of byte 1). C9/C15 are ignored in
Transparent Mode.
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EM1/C8
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EM0/C9
15
CBL/SBC
16
RST
Emphasis 1/Channel Status Bit 8.
In professional mode, EM0 and EM1 encode channel status bits 2, 3 and 4. In consumer
mode, C8 is the inverse of channel status bit 8 (bit 0 of byte 1). EM1/C8 are ignored in
Transparent Mode.
Emphasis 0/Channel Status Bit 9.
In professional mode, EM0 and EM1 encode channel status bits 2, 3 and 4. In consumer
mode, C9 is the inverse of channel status bit 9 (bit 1 of byte 1). EM0/C9 are ignored in
Transparent Mode.
Channel Status Block Output/Subcode Bit Clock.
In professional and consumer modes, the channel status block output is high for the first 15
bytes of channel status. In CD mode, this pin outputs the subcode bit clock.
Master Reset.
When low, all internal counters are reset.
3/14
STA020
PIN DESCRIPTION (continued)
N°
Pin
24
Function
TRNPT/FC1 Transparent Mode/Frequency Control 1.
In professional mode, setting TRNPT low selects normal operation & CBL is an output.
Setting TRNPT high, allows the STA020D to be connected directly to an STA120. In
transparent mode, CBL is an input & MCK must be at 256 Fs. In consumer mode, FC0 and
FC1 are encoded versions of channel status bits 24 and 25. When FC0 and FC1 are both
high, CD mode is selected.
Transmitter Interface
5
MCK
20, 17
TXP, TXN
Master Clock. Clock input at 128x the sample frequency which defines the transmit timing.
In trasparent mode MCK must be 256 Fs.
Differential Line Drivers.
DIGITAL CHARACTERISTICS (Tamb = 25°C; VD+ = 3.3V 10%)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
)
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VIH
High-Level Input Voltage
2.0
VDD+0.3
V
VIL
Low-Level Input Voltage
-0.3
+0.8
V
VOH
High-Level Output Voltage
IO = 200µA
VOL
Low-Level Output Voltage
IO = 3.2mA
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VDD-1.0
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Iin
Input Leakage Current
MCK
Master Clock frequency
(Note 1)
Master Clock Duty Cycle
(high time/cycle time)
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1.0
40
0.4
V
10
A
26
MHz
60
%
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Note 1: MCK must be 128x the input word rate, except in Transparent Mode where MCK is 256x the input word rate.
Figure 1. STA020D Professional & Consumer Modes Typical Connection Diagram.
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AUDIO
DATA
PROCESSOR
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EXTERNAL
CLOCK
FSYNC
SCK
SDATA
CBL
C
µCONTROLLER
or
UNUSED
U
V
RST
CHANNEL
STATUS BITS
CONTROL
+3.3V
VD+
MCK
7
19
5
18
24
6
8
23
22
15
10
STA020
21
0.1µF
GND
TRNPT
M0
M1
M2
SERIAL PORT
MODE SELECT
11
9
16
8 DEDICATED C.S. BITS
20
17
TXP
TXN
TRANSMITTER
CIRCUIT
D97AU600A
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STA020
Figure 2. STA020D Typical Connection Diagram.
EXTERNAL
CLOCK
FSYNC
AUDIO
DATA
PROCESSOR
SCK
SDATA
V
SBF
DECODER
SUBCODE
PORT
U
SBC
RST
RESET
CONTROL
+5V
VD+
MCK
7
19
5
6
18
8
9
23
10
22
11
15
STA020
21
20
16
17
CHANNEL
STATUS BITS
CONTROL
0.1µF
GND
M0
M1
M2
SERIAL PORT
MODE SELECT
TXP
TXN
8 DEDICATED C.S. BITS
TRANSMITTER
CIRCUIT
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D99AU989A
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GENERAL DESCRIPTION
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The STA020D is a monolithic CMOS circuit that encodes and transmits audio and digital data according
to the AES/EBU, IEC 958, S/PDIF, and EIAJ CP-340 interface standards. The chip accepts audio and control data separately; multiplex and biphase-mark encode the data internally and drive it, directly or through
a transformer, to a transmission line.
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The STA020D has dedicated pins for the most important control bits and a serial input port for the C, U
and V bits.
Line Drivers
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The differential line drivers for STA020D are low skew, low impedance, differential outputs capable of driving 110Ohm transmission lines. (RS422 line driver compatible).
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They can also be disabled by resetting the device (RST = low).
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STA020D DESCRIPTION
The STA020D accepts 16 to 24-bit audio samples through a serial port configured in one of seven formats;
provides several pins dedicated to particular channel status bits and allows all channel status, user and
validity bits to be serially input through port pins. This data is multiplexed, the parity bit is generated and
the bit stream is biphase-mark encoded and driven through an RS422 line driver.
The STA020D operates as a professional or consumer interface transmitter selectable by pin 2, PRO. As
a professional interface device, the dedicated channel status input pins are defined according to the professional standard, and the CRC code (C.S. byte 23) can be internally generated.
As a consumer device, the dedicated channel status input pins are defined according to the consumer
standard. A submode provided under the consumer mode is compact disk, CD, mode. When transmitting
data from a compact disk, the CD subcode port can accept CD subcode data, extract channel status in5/14
STA020
formation from it, and transmit it as user data.
The master clock , MCK, controls timing for the entire chip and must be 128xFs. As an example, if stereo
data is input to the STA020D at 44.1kHz, MCK input must be 128 times that or 5.6448MHz.
Audio Serial Port
The audio serial port is used to enter audio data and consists of three pins: SCK, SDATA and FSYNC,
SCK clocks in SDATA, which is double buffered, while FSYNC delineates the audio samples and may indicate the particular channel, left or right. To support many different interfaces, M2, M1 and M0 select one
of seven different formats for the serial port. The coding is shown in Table 3 while the formats are shown
in Figure 3.
Format 0 and 1 are designed to interface with Crystal ADCs. Format 2 communicates with Motorola and
TI DSPs. Format 3 is reserved. Format 4 is compatible with the I2S standard. Formats 5 and 6 make the
STA020D look similar to existing 16- and 18-bit DACs and interpolation filters. Format 7 is an MSB-last
format and is conducive to serial arithmetic. SCK and FSYNC are outputs in Format 0 and inputs in all
other formats. In Format 2, the rising edge of FSYNC delineates samples and the falling edge must occur
a minimum of one bit period before or after the rising edge. In all formats except 2, FSYNC contains left/
right information requiring both edges of FSYNC to delineate samples. Formats 5 and 6 require a minimum
of 16- or 18-bit audio words respectively. In all formats other than 5 and 6, the STA020D can accept any
word length from 16 to 24 bits by adding leading zeros in format 7 and trailing zeros in the other formats,
or by restricting the number of SCK periods between active edges of FSYNC to the sample word length.
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FSYNC must be derived from MCK, either through a DSP using the same clock or using counters. If
SFYNC moves (jitters) with respect to MCK by four MCK periods, the internal counters and CBL may be
reset.
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Table 1. Audio Port Modes
M1
M0
0
0
0
0 - FSYNC & SCK Output
0
0
1
1 - Left/Right, 16-24 Bits
0
1
0
0
1
1
0
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2 - Word Sync, 16-24 Bits
3 - Reserved
0
4 - Left/Right, I2S Compatible
1
5 - LSB Justified, 16 Bits
1
0
6 - LSB Justified, 18 Bits
1
1
7 - MSB Last, 16-24 Bits
0
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Format
STA020
Figure 3. Audio Serial Port Formats.
FORMAT 0:
FSYNC(out)
LEFT
RIGHT
SCK(out)
SDATA(in)
MSB
LSB
MSB
LSB
MSB
LSB
MSB
LSB
MSB
FORMAT 1:
FSYNC(in)
LEFT
RIGHT
SCK(in)
SDATA(in)
MSB
LSB
MSB
FORMAT 2:
FSYNC(in)
LEFT
RIGHT
SCK(in)
SDATA(in)
MSB
LSB
MSB
FORMAT 3:
(RESERVED)
FORMAT 4:
FSYNC(in)
LEFT
SCK(in)
SDATA(in)
MSB
LSB
MSB
LSB
FORMAT 5:
FSYNC(in)
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LEFT
RIGHT
SCK(in)
SDATA(in) LSB
FSYNC(in)
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SDATA(in) LSB
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LEFT
SCK(in)
FORMAT 7:
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LSB
MSB
16 Bits
FORMAT 6:
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RIGHT
LSB
MSB
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MSB
MSB
LSB
16 Bits
RIGHT
MSB
18 Bits
LSB
18 Bits
LEFT
RIGHT
SCK(in)
SDATA(in) MSB
LSB
MSB
LSB
MSB
D97AU604
C, U, V Serial Port
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The serial input pins for channel status (C), user (U), and validity (V) are sampled during the first bit period
after the active edge of FSYNC for all formats except Format 4. Format 4 is sampled during the second
bit period (coincident with the MSB). In Figure 3, the arrows on SCK indicate when the C, U, and V bits
are sampled. The C, U, and V bits are transmitted with the audio sample entered before FSYNC edge that
sampled it. The V bit, as defined in the audio standards, is set to zero to indicate the audio data is suitable
for conversion to analog. Therefore, when the audio data is errored, or the data is not audio, the V bit
should be set high. The channel status serial input pin (C) is not available in consumer mode when the
CD subcode port is enabled (FC1 = FC0 = high). Any channel status data entered through the channel
status serial input (C) is logically OR’ed with the data entered through the dedicated pins or internally generated.
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STA020
RST and CBL (TRNPT is low)
When RST goes low, the differential line drivers are set to ground. In order to properly synchronize the
ST020 to the audio serial port, the transmit timing counters, which include CBL, are not enabled after RST
goes high until eight and one half SCK periods after reset is exited) of FSYNC. When FSYNC is configured
as a left/right signal (all defined formats except 2), the counters and CBL are not enabled until the right
sample is being transmitted). This guarantees that channel A is left and channel B is right as per the digital
audio interface specs.
As shown in Figure 4, channel block start output (CBL), can assist in serially inputting the C, U and V bits
as CBL goes high one bit period before the first bit of the preamble of the first sub-frame of the channel
status block is transmitted. This sub-frame contains channel status byte 0, bit 0. CBL returns low one bit
period before the start of the frame that contains bit 0 of channel status byte 16. CBL is not available when
the CD subcode port is enabled.
Figure 4 illustrates timing for stereo data input on the audio port. Notice how CBL rises while the right
channel data (Right 0) is input, but the previous left channel (Left 0) is being transmitted as the first subframe of the channel status block (starting with preamble Z). The C, U, and V input ports only need to be
valid for a short period after FSYNC changes. A sub-frame includes one audio sample while a frame includes a stereo pair. A channel status (C.S.) block contains 24 bytes of channel status and 384 audio samples (or 192 stereo pairs, or frames, of samples). Figure 4 shows the CUV ports as having left and right
bits (e.g. CUV0L, CUV0R). Since the C.S. block is defined as 192 bits, or one bit per frame, there are actually 2 C.S. blocks, one for channel A (left) and one for channel B (right). When inputting stereo audio
data, both blocks normally contain the same information, so C0L and C0R from the input port pin are both
channel status bit 0 of byte 0, which is defined as professional/consumer. These first two bits from the
port, C0L and C0R, are logically OR’ed with the inverse PRO, since PRO is a dedicated channel status
pin defined as C.S. bit 0.
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Also, if in professional mode, C1, C6, C7 and C9 are dedicated C.S. pins. The inverse of C1 is logically
OR’ed with channel status input ports bits C1L and C1R. In similar fashion, C6, C7 and C9 are OR’ed with
their respective input bits. Also, the C bits in CUV128L and CUV128R are both channel status block bit
128, which is bit 0 of channel status byte 16.
Figure 4. CBL and Transmitter Timing.
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TRNPT high
CBL
TRNPT low
SDATA
FSYNC
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TRNPT high
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LEFT 0
RIGHT 0
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LEFT 1
LEFT 128
RIGHT 128
LEFT 0
RIGHT 0
CUV128R
CUV0L
CUV0R
CUV128L
CUV191R
CUV0L
C BITS FROM CPIN
CUV0L
CUV0R
CUV1L
CUV1R
CUV191R
CUV0L
CUV0R
CUV1L
C,U,V
TRNPT low
C BITS OR'ed
w/PRO pin
C BITS OR'ed
w/C1 pin
BITS 0 of C.S.
BLOCK BYTE 16
TXP
RIGHT 191
LEFT 0
RIGHT 0
VUCP0L
Preamble Z
VUCP0R
Preamble Y
LEFT
128
TXN
Preamble Y
VUCP191R
bit
0
3
Preamble Z
4
7
Aux Data
VUCP127R
27 28 29 30 31
Left 0 - Audio Data
SUB-FRAME
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VUCP128L
Preamble X Preamble Y
8
LSB
RIGHT
128
MSB V0 U0 C0 P0
D99AU990
STA020
Transparent Mode
In certain applications it is desirable to receive digital audio data with the STA120 and retransmit it with
the STA020D. In this case, channel status, user and validity information must pass through unaltered. For
studio environments, AES recommends that signal timing synchronization be maintained throughout the
studio. Frame synchronization of digital audio signals input to and output from a piece of equipment must
be within ±5%.
The transparent mode of the STA020D is selected by setting TRNPT, pin 24, high. In this mode, the CBL
pin becomes an input, allowing direct connection of the outputs of the STA120 to the inputs of the
STA020D as shown in Figure 18. The transmitter and receiver are synchronized by the FSYNC signal.
CBL specifies the start of a new channel status block boundry, allowing the transmit block structure to be
slaved to the block structure of the receiver.
In the transparent mode, C, U and V are now transmitted with the current audio sample as shown in Figure
5 (TRNPT high) and the dedicated channel status pins are ignored.
When FSYNC is a word clock (Format 2), CBL is sampled when left C, U, V are sampled. When FSYNC
is Left/Right, CBL is sampled when left C, U, V are sampled. The channel status block boundry is reset
when CBL transitions from low to high (based on two successive samples of CBL). MCK for the STA020D
is normally expected to be 128 times the sample frequency, in the trasparent mode MCK must be 256 Fs.
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Professional Mode
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Setting PRO low places the STA020D in professional mode as shown in Figure 6. In professional mode,
channel status bit 0 is transmitted as a one and bits 1, 2, 3, 4, 6, 7 and 9 can be controlled via dedicated
pins. The pins are actually the inverse of the identified bit.
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For example, tying the C1 pin low places a one in channel status bit 1. As shown in the application Note,
Overview of AES/EBU Digital Audio Interface Data Structures, C1 indicates audio/non-audio; C6 and C7
determine the sample frequency and C9 allows the encoded channel mode to be stereophonic. EM1 and
EM0 determine emphasis and encode C2, C3, C4 as shown in Table 2. The dedicated channel status pins
are read at the appropriate time and are logically OR’ed with data input on the channel status port, C. In
Transparent Mode, these dedicated channel status pins are ignored and channel status bits are input at
the C pin.
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Consumer Mode
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Setting PRO high places the STA020D in consumer mode which redefines the pins as shown in Figure 7.
In consumer mode, channel status bit 0 is transmitted as a zero and channel status bits 2, 3, 8, 9, 15, 24
and 25 are controlled via dedicated pins.
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The pins are actually the inverse of the bit so if pin C2 is tied high, channel status bit 2 will be transmitted
as a zero. Also, FC0 and FC1 are encoded versions of channel status bits 24 and 25, which define the
sample frequency.
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When FC0 and FC1 are both high, the part is placed in a CD submode which activates the CD subcode
port. This submode is described in detail in the next section. Table 3 describes the encoding of C24 and
C25 through the FC1 and FC0 pins. According to AES/EBU standards, C2 is copy prohibit/permit. C3
specifies pre-emphasis, C8 and C9 define the category code and C15 identifies the generation status of
the transmitted material (i.e. first generation, second generation).
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Table 2. Emphasis Encoding
EM1
EM0
C2
C3
C4
0
0
1
1
1
0
1
1
1
0
1
0
1
0
0
1
1
0
0
0
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STA020
Table 3. Sample Frequency Encoding
FC1
FC0
C24
C25
Comments
0
0
0
0
44.1kHz
0
1
0
1
48kHz
1
0
1
1
32kHz
1
1
0
0
44.1kHz, CD Mode
Figure 5. Transparent Mode Interface.
V+
MCK
TRNPT
CBL
C
RXP
TXP
U
V
FSYNC
SCK
RXN
TXN
SDATA
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STA020
STA120
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PROCESSING
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D97AU605
Figure 6. Block Diagram - Professional Mode
M0
23
7
FSYNC
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11
AUDIO
AUX
20
BIPHASE
MARK
ENCODER
MUX
REGISTERS
VALIDITY
TIMING
16
PREAMBLE
2
14
TXN
U Bits
9
PRO
TXP
LINE
DRIVER
17
CRC
MUX
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C Bits
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SERIAL
PORT
LOGIC
6
SCK
U
)
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21
22
8
SDATA
C
M2
M1
)
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13
3
EM0 EM1 C1
PARITY
4
1
C6
24
12
C7
C9
TRNPT
15
CBL
5
MCK
D97AU607B
RST
STA020
Figure 7. Block Diagram - Consumer Mode
M0
23
M2
M1
21
22
8
SDATA
7
FSYNC
AUDIO
SERIAL
PORT
LOGIC
6
SCK
20
AUX
BIPHASE
MARK
ENCODER
C Bits
10
C
U Bits
REGISTERS
16
TIMING
9
V
17
TXN
MUX
11
U
TXP
LINE
DRIVER
RST
VALIDITY
PREAMBLE
MUX
2
PRO
3
24
FC0 FC1
4
1
C2
PARITY
13
C3
14
C8
12
C9
15
C15
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CBL
+3.3V
5
MCK
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D97AU606A
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STA020
mm
inch
OUTLINE AND
MECHANICAL DATA
DIM.
MIN.
TYP.
MAX.
MIN.
TYP.
MAX.
A
2.35
2.65
0.093
0.104
A1
0.10
0.30
0.004
0.012
B
0.33
0.51
0.013
0.200
C
0.23
0.32
0.009
0.013
D (1)
15.20
15.60
0.598
0.614
E
7.40
7.60
0.291
0.299
e
1.27
0.050
H
10.0
10.65
0.394
0.419
h
0.25
0.75
0.010
0.030
L
0.40
1.27
0.016
0.050
k
Weight: 0.60gr
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u
d
0˚ (min.), 8˚ (max.)
ddd
0.10
0.004
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(1) “D” dimension does not include mold flash, protusions or gate
burrs. Mold flash, protusions or gate burrs shall not exceed
0.15mm per side.
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0070769 C
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STA020
REVISION HISTORY
Date
Revision
Changes
14-Oct-2002
5
Technical Migration from ST-PRESS to EDOCS
26-Apr-2010
6
Major revision for revalidation process
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STA020
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