Cirrus CS8416-CZZ 192 khz digital audio interface receiver Datasheet

CS8416
192 kHz Digital Audio Interface Receiver
Features
 32 kHz to 192 kHz Sample Frequency Range
 Complete EIAJ CP1201, IEC-60958, AES3,
 Low-Jitter Clock Recovery
S/PDIF-Compatible Receiver
 Pin and Microcontroller Read Access to
 +3.3 V Analog Supply (VA)
Channel Status and User Data
 +3.3 V Digital Supply (VD)
 SPI™ or I²C® Control Port Software Mode and
Stand-Alone Hardware Mode
 +3.3 V or +5.0 V Digital Interface Supply (VL)
 8:2 S/PDIF Input MUX
 Differential Cable Receiver
 AES/SPDIF Input Pins Selectable in Hardware
 On-Chip Channel Status Data Buffer Memories
Mode
 Three General Purpose Outputs (GPO) Allow
 Auto-Detection of Compressed Audio Input
Streams
Signal Routing
 Selectable Signal Routing to GPO Pins
 Decodes CD Q Sub-Code
 S/PDIF-to-TX Inputs Selectable in Hardware
 OMCK System Clock Mode
 Flexible 3-wire Serial Digital Output Port
See the General Description and Ordering Information
on page 2.
Mode
VA
RXN
RXP0
RXP1
RXP2
RXP3
RXP4
RXP5
RXP6
RXP7
VD
AGND FILT RMCK
Clock &
Data
Recovery
AES3
S/PDIF
Decoder
TX Passthrough
Misc.
Control
RST
http://www.cirrus.com
OMCK
De-emphasis
Filter
Receiver
8:2
MUX
VL DGND
Format
Detect
C & U bit
Data Buffer
Control
Port &
Registers
Serial
Audio
Output
n:3
MUX
OLRCK
OSCLK
SDOUT
GPO0
GPO1
AD2/GPO2
SDA/
SCL/ AD1/ AD0/
CDOUT CCLK CDIN CS
Copyright © Cirrus Logic, Inc. 2007
(All Rights Reserved)
AUGUST '07
DS578F3
CS8416
General Description
The CS8416 is a monolithic CMOS device that receives and decodes one of eight stereo pairs of digital audio data
according to the IEC60958, S/PDIF, EIAJ CP1201, or AES3 interface standards. The CS8416 has a serial digital
audio output port and comprehensive control ability through a selectable control port in Software Mode or through
selectable pins in Hardware Mode. Channel status data are assembled in buffers, making read access easy. GPO
pins may be assigned to route a variety of signals to output pins.
A low-jitter clock recovery mechanism yields a very clean recovered clock from the incoming AES3 stream.
Stand-alone operation allows systems with no microcontroller to operate the CS8416 with dedicated output pins for
channel status data.
The CS8416 is available in 28-pin TSSOP, SOIC, and QFN packages in Commercial grade (-10° to +70° C) and
Automotive grade (-40° to +85° C). The CDB8416 Customer Demonstration board is also available for device evaluation and implementation suggestions. Please refer to “Ordering Information” on page 59 for complete ordering
information.
Target applications include A/V receivers, CD-R, DVD receivers, multimedia speakers, digital mixing consoles, effects processors, set-top boxes, and computer and automotive audio systems.
2
DS578F3
CS8416
TABLE OF CONTENTS
1. CHARACTERISTICS AND SPECIFICATIONS ..................................................................................... 6
SPECIFIED OPERATING CONDITIONS ............................................................................................... 6
ABSOLUTE MAXIMUM RATINGS ......................................................................................................... 6
DC ELECTRICAL CHARACTERISTICS................................................................................................. 7
DIGITAL INPUT CHARACTERISTICS ................................................................................................... 7
DIGITAL INTERFACE SPECIFICATIONS.............................................................................................. 7
SWITCHING CHARACTERISTICS ........................................................................................................ 8
SWITCHING CHARACTERISTICS - SERIAL AUDIO PORTS............................................................... 9
SWITCHING CHARACTERISTICS - CONTROL PORT - SPI MODE .................................................. 10
SWITCHING CHARACTERISTICS - CONTROL PORT- I²C FORMAT ............................................... 11
2. PIN DESCRIPTION - SOFTWARE MODE .......................................................................................... 12
2.1 TSSOP Pin Description ................................................................................................................. 12
2.2 QFN Pin Description ...................................................................................................................... 14
3. PIN DESCRIPTION - HARDWARE MODE ......................................................................................... 16
3.1 TSSOP Pin Description ................................................................................................................. 16
3.2 QFN Pin Description ...................................................................................................................... 18
4. TYPICAL CONNECTION DIAGRAMS ................................................................................................ 20
5. APPLICATIONS .................................................................................................................................. 22
5.1 Reset, Power-Down and Start-Up ................................................................................................. 22
5.2 ID Code and Revision Code .......................................................................................................... 22
5.3 Power Supply, Grounding, and PCB Layout ................................................................................. 22
6. GENERAL DESCRIPTION .................................................................................................................. 23
6.1 AES3 and S/PDIF Standards Documents ..................................................................................... 23
7. SERIAL AUDIO OUTPUT PORT ......................................................................................................... 23
7.1 Slip/Repeat Behavior ..................................................................................................................... 25
7.2 AES11 Behavior ............................................................................................................................ 26
8. S/PDIF RECEIVER .............................................................................................................................. 27
8.1 8:2 S/PDIF Input Multiplexer ......................................................................................................... 27
8.1.1 General ............................................................................................................................... 27
8.1.2 Software Mode ................................................................................................................... 27
8.1.3 Hardware Mode .................................................................................................................. 28
8.2 OMCK System Clock Mode ........................................................................................................... 28
8.3 Clock Recovery and PLL Filter ...................................................................................................... 28
9. GENERAL PURPOSE OUTPUTS ....................................................................................................... 29
10. ERROR AND STATUS REPORTING ................................................................................................ 30
10.1 General ........................................................................................................................................ 30
10.1.1 Software Mode ................................................................................................................. 30
10.1.2 Hardware Mode ................................................................................................................ 30
10.2 Non-Audio Detection ................................................................................................................... 31
10.2.1 Format Detection .............................................................................................................. 31
10.3 Interrupts ..................................................................................................................................... 31
11. CHANNEL STATUS AND USER-DATA HANDLING ....................................................................... 32
11.1 Software Mode ............................................................................................................................ 32
11.2 Hardware Mode ........................................................................................................................... 32
12. CONTROL PORT DESCRIPTION ..................................................................................................... 33
12.1 SPI Mode ..................................................................................................................................... 33
12.2 I²C Mode ...................................................................................................................................... 34
13. CONTROL PORT REGISTER QUICK REFERENCE ....................................................................... 35
14. CONTROL PORT REGISTER DESCRIPTIONS .............................................................................. 36
14.1 Memory Address Pointer (MAP) .................................................................................................. 36
14.2 Control0 (00h) ............................................................................................................................. 36
14.3 Control1 (01h) ............................................................................................................................. 37
DS578F3
3
CS8416
14.4 Control2 (02h) ............................................................................................................................. 38
14.5 Control3 (03h) ............................................................................................................................. 39
14.6 Control4 (04h) ............................................................................................................................. 39
14.7 Serial Audio Data Format (05h) ................................................................................................... 40
14.8 Receiver Error Mask (06h) ......................................................................................................... 41
14.9 Interrupt Mask (07h) .................................................................................................................... 41
14.10 Interrupt Mode MSB (08h) and Interrupt Mode LSB(09h) ......................................................... 41
14.11 Receiver Channel Status (0Ah) ................................................................................................ 42
14.12 Format Detect Status (0Bh) ....................................................................................................... 42
14.13 Receiver Error (0Ch) ................................................................................................................ 43
14.14 Interrupt 1 Status (0Dh) ............................................................................................................ 44
14.15 Q-Channel Subcode (0Eh - 17h) ............................................................................................... 44
14.16 OMCK/RMCK Ratio (18h) ....................................................................................................... 45
14.17 Channel Status Registers (19h - 22h) ....................................................................................... 45
14.18 IEC61937 PC/PD Burst Preamble (23h - 26h) .......................................................................... 45
14.19 CS8416 I.D. and Version Register (7Fh) ................................................................................... 45
15. HARDWARE MODE .......................................................................................................................... 46
15.1 Serial Audio Port Formats ........................................................................................................... 46
15.2 Hardware Mode Function Selection ............................................................................................ 46
15.3 Hardware Mode Equivalent Register Settings ............................................................................. 47
16. EXTERNAL AES3/SPDIF/IEC60958 RECEIVER COMPONENTS ................................................... 49
16.1 AES3 Receiver External Components ........................................................................................ 49
16.2 Isolating Transformer Requirements ........................................................................................... 49
17. CHANNEL STATUS BUFFER MANAGEMENT ............................................................................... 51
17.1 AES3 Channel Status (C) Bit Management ................................................................................ 51
17.2 Accessing the E Buffer ................................................................................................................ 51
17.2.1 Serial Copy Management System (SCMS) ...................................................................... 51
18. PLL FILTER ....................................................................................................................................... 53
18.1 General ........................................................................................................................................ 53
18.2 External Filter Components ......................................................................................................... 53
18.2.1 General ............................................................................................................................. 53
18.2.2 Capacitor Selection .......................................................................................................... 54
18.2.3 Circuit Board Layout ......................................................................................................... 54
18.2.4 Component Value Selection ............................................................................................. 54
18.2.5 Jitter Attenuation ............................................................................................................... 55
19. PACKAGE DIMENSIONS ................................................................................................................. 56
TSSOP THERMAL CHARACTERISTICS............................................................................................. 57
QFN THERMAL CHARACTERISTICS ................................................................................................. 58
20. ORDERING INFORMATION ............................................................................................................. 59
21. REVISION HISTORY ......................................................................................................................... 60
4
DS578F3
CS8416
LIST OF FIGURES
Figure 1. Audio Port Master Mode Timing ................................................................................................... 9
Figure 2. Audio Port Slave Mode and Data Input Timing............................................................................. 9
Figure 3. SPI Mode Timing ........................................................................................................................ 10
Figure 4. I²C Mode Timing ......................................................................................................................... 11
Figure 5. Typical Connection Diagram - Software Mode ........................................................................... 20
Figure 6. Typical Connection Diagram - Hardware Mode .......................................................................... 21
Figure 7. Serial Audio Output Example Formats........................................................................................ 24
Figure 8. AES3 Data Format...................................................................................................................... 25
Figure 9. Receiver Input Structure ............................................................................................................. 27
Figure 10. C/U Data Outputs...................................................................................................................... 32
Figure 11. Control Port Timing in SPI Mode .............................................................................................. 33
Figure 12. Control Port Timing, I²C Slave Mode Write............................................................................... 34
Figure 13. Control Port Timing, I²C Slave Mode Read............................................................................... 34
Figure 14. De-Emphasis Filter Response .................................................................................................. 39
Figure 15. Hardware Mode Data Flow ....................................................................................................... 46
Figure 16. Professional Input Circuit .......................................................................................................... 49
Figure 17. Transformerless Professional Input Circuit ............................................................................... 49
Figure 18. Consumer Input Circuit ............................................................................................................. 50
Figure 19. S/PDIF MUX Input Circuit ......................................................................................................... 50
Figure 20. TTL/CMOS Input Circuit............................................................................................................ 50
Figure 21. Channel Status Data Buffer Structure....................................................................................... 52
Figure 22. Flowchart for Reading the E Buffer........................................................................................... 52
Figure 23. PLL Block Diagram ................................................................................................................... 53
Figure 24. Recommended Layout Example............................................................................................... 54
Figure 25. Jitter Attenuation Characteristics of PLL................................................................................... 55
LIST OF TABLES
Table 1. Typical Delays by Frequency Values ........................................................................................... 26
Table 2. Clock Switching Output Clock Rates............................................................................................ 28
Table 3. GPO Pin Configurations............................................................................................................... 29
Table 4. Hardware Mode Start-Up Pin Conditions ..................................................................................... 47
Table 5. Hardware Mode Serial Audio Format Select................................................................................ 48
Table 6. External PLL Component Values ................................................................................................. 54
DS578F3
5
CS8416
1. CHARACTERISTICS AND SPECIFICATIONS
All Min/Max characteristics and specifications are guaranteed over the Specified Operating Conditions. Typical
performance characteristics and specifications are derived from measurements taken at nominal supply voltages
and TA = 25°C.
SPECIFIED OPERATING CONDITIONS
(AGND, DGND = 0 V, all voltages with respect to 0 V)
Parameter
Power Supply Voltage
Ambient Operating Temperature:
Commercial Grade
Automotive Grade
Symbol
Min
Typ
Max
Units
VA
VD
VL
3.13
3.13
3.13
3.3
3.3
3.3 or 5.0
3.46
3.46
5.25
V
V
V
TA
-10
-40
-
+70
+85
°C
ABSOLUTE MAXIMUM RATINGS
(AGND, DGND = 0 V; all voltages with respect to 0 V. Operation beyond these limits may result in permanent damage to the device. Normal operation is not guaranteed at these extremes.)
Parameter
Power Supply Voltage
Input Current, Any Pin Except Supplies
Input Voltage
Ambient Operating Temperature (power applied)
Storage Temperature
(Note 1)
Symbol
Min
Max
Units
VA, VD,VL
Iin
Vin
TA
Tstg
-0.3
-55
-65
6.0
±10
(VL) + 0.3
125
150
V
mA
V
°C
°C
Notes:
1. Transient currents of up to 100 mA will not cause SCR latch-up.
6
DS578F3
CS8416
DC ELECTRICAL CHARACTERISTICS
(AGND = DGND = 0 V; all voltages with respect to 0 V.)
Parameters
Symbol
Min
Typ
Max
Units
VA
VD
VL = 3.3 V
VL = 5.0 V
IA
ID
IL
IL
-
10
70
10
12
-
μA
μA
μA
μA
VA
VD
VL = 3.3 V
VL = 5.0 V
VA
VD
VL = 3.3 V
VL = 5.0 V
IA
ID
IL
IL
IA
ID
IL
IL
-
5.7
5.9
2.8
4.2
9.4
23
7.8
11.8
-
mA
mA
mA
mA
mA
mA
mA
mA
Power-Down Mode (Notes 2, 4)
Supply Current in power-down
Normal Operation (Notes 3, 4)
Supply Current at 48 kHz frame rate
Supply Current at 192 kHz frame rate
Notes:
2. Power-Down Mode is defined as RST = LO with all clocks and data lines held static.
3. Normal operation is defined as RST = HI.
4. Assumes that no inputs are floating. It is recommended that all inputs be driven high or low at all times.
DIGITAL INPUT CHARACTERISTICS
(AGND = DGND = 0 V; all voltages with respect to 0 V.)
Parameters
Input Leakage Current
Differential Input Sensitivity, RXP[7:0] to RXN
Input Hysteresis
Symbol
Min
Typ
Max
Units
IIN
VTH
VH
0.15
150
-
±0.5
200
1.0
μA
mVpp
V
DIGITAL INTERFACE SPECIFICATIONS
(AGND = DGND = 0 V; all voltages with respect to 0 V.)
Parameters
Symbol
Min
Max
Units
High-Level Output Voltage (IOH = -3.2 mA)
VOH
(VL) - 1.0
-
V
Low-Level Output Voltage (IOL = 3.2 mA)
VOL
-
0.5
V
High-Level Input Voltage, except RXP[7:0], RXN
Low-Level Input Voltage, except RXP[7:0], RXN
VIH
VIL
2.0
-0.3
(VL) + 0.3
0.8
V
V
DS578F3
7
CS8416
SWITCHING CHARACTERISTICS
(Inputs: Logic 0 = 0 V, Logic 1 = VL; CL = 20 pF)
Parameter
Symbol
Min
Typ
Max
Units
RST Pin Low Pulse Width
200
-
-
μS
PLL Clock Recovery Sample Rate Range
30
-
200
kHz
RMCK Output Jitter
(Note 5)
-
200
-
ps RMS
RMCK Output Duty-Cycle
(Note 6)
(Note 7)
45
50
50
55
55
65
%
%
-
-
50
MHz
RMCK/OMCK Maximum Frequency
Notes:
5. Typical RMS cycle-to-cycle jitter.
6. Duty cycle when clock is recovered from biphase encoded input.
7. Duty cycle when OMCK is switched over for output on RMCK.
8
DS578F3
CS8416
SWITCHING CHARACTERISTICS - SERIAL AUDIO PORTS
(Inputs: Logic 0 = 0 V, Logic 1 = VL; CL = 20 pF)
Parameter
Symbol
Min
Typ
Max
Units
OSCLK/OLRCK Active Edge to SDOUT Output Valid
(Note 8)
Master Mode
RMCK to OSCLK active edge delay
(Note 8)
RMCK to OLRCK delay
(Note 9)
OSCLK and OLRCK Duty Cycle
Slave Mode
OSCLK Period
OSCLK Input Low Width
OSCLK Input High Width
OSCLK Active Edge to OLRCK Edge
(Notes 8,9,10)
OSCLK Edge Setup Before OSCLK Active-Edge (Notes 8,9,11)
tdpd
-
-
23
ns
tsmd
tlmd
0
0
-
50
12
12
-
ns
ns
%
tsckw
tsckl
tsckh
tlrckd
tlrcks
36
14
14
10
10
-
-
ns
ns
ns
ns
ns
Notes:
8. In Software Mode the active edges of OSCLK are programmable.
9. In Software Mode the polarity of OLRCK is programmable.
10. This delay is to prevent the previous OSCLK edge from being interpreted as the first one after OLRCK
has changed.
11. This setup time ensures that this OSCLK edge is interpreted as the first one after OLRCK has changed.
O SCLK
(o utp ut)
OLRCK
(input)
t lrckd
OLRCK
(o utp ut)
t sckh
t sckl
OSCLK
(input)
t sm d
t
t sckw
lm d
RMCK
(o utp ut)
Figure 1. Audio Port Master Mode Timing
DS578F3
t lrcks
t dpd
SDOUT
Figure 2. Audio Port Slave Mode and Data Input
9
CS8416
SWITCHING CHARACTERISTICS - CONTROL PORT - SPI MODE
(Inputs: Logic 0 = 0 V, Logic 1 = VL; CL = 20 pF)
Parameter
Symbol
Min
Max
Unit
fsck
0
6.0
MHz
CS High Time Between Transmissions
tcsh
1.0
-
µs
CS Falling to CCLK Edge
CCLK Low Time
CCLK High Time
CDIN to CCLK Rising Setup Time
CCLK Rising to DATA Hold Time
CCLK Falling to CDOUT Stable
Rise Time of CDOUT
Fall Time of CDOUT
Rise Time of CCLK and CDIN
Fall Time of CCLK and CDIN
tcss
tscl
tsch
tdsu
tdh
tpd
tr1
tf1
tr2
tr2
20
66
66
40
15
-
50
25
25
100
100
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
CCLK Clock Frequency
(Note 12)
(Note 13)
(Note 14)
(Note 14)
Notes:
12. If Fs is lower than 46.875 kHz, the maximum CCLK frequency should be less than 128 Fs. This is dictated by the timing requirements necessary to access the Channel Status memory. Access to the control register file can be carried out at the full 6 MHz rate. The minimum allowable input sample rate is
32 kHz, so choosing CCLK to be less than or equal to 4.1 MHz should be safe for all possible conditions.
13. Data must be held for sufficient time to bridge the transition time of CCLK.
14. For fsck <1 MHz.
CS
t scl
t css
t sch
t csh
CCLK
t r2
t f2
CDIN
t dsu
t dh
t pd
CDOUT
Figure 3. SPI Mode Timing
10
DS578F3
CS8416
SWITCHING CHARACTERISTICS - CONTROL PORT- I²C FORMAT
(Inputs: Logic 0 = 0 V, Logic 1 = VL; CL = 20 pF)
Parameter
Symbol
Min
Max
Unit
SCL Clock Frequency
Bus Free Time Between Transmissions
Start Condition Hold Time (prior to first clock pulse)
Clock Low time
Clock High Time
Setup Time for Repeated Start Condition
SDA Hold Time from SCL Falling
(Note 15)
SDA Setup time to SCL Rising
Rise Time of SCL and SDA
Fall Time SCL and SDA
Setup Time for Stop Condition
fscl
tbuf
thdst
tlow
thigh
tsust
thdd
tsud
tr
tf
tsusp
4.7
4.0
4.7
4.0
4.7
10
250
4.7
100
1000
300
-
kHz
µs
µs
µs
µs
µs
ns
ns
ns
ns
µs
Notes:
15. Data must be held for sufficient time to bridge the 300 ns transition time of SCL.
Stop
Repeated
Start
Start
Stop
SDA
t buf
t
t high
t hdst
tf
hdst
t susp
SCL
t
low
t
hdd
t sud
t sust
tr
Figure 4. I²C Mode Timing
DS578F3
11
CS8416
2. PIN DESCRIPTION - SOFTWARE MODE
2.1
12
TSSOP Pin Description
RXP3
1
28
OLRCK
RXP2
2
27
OSCLK
RXP1
3
26
SDOUT
RXP0
4
25
OMCK
RXN
5
24
RMCK
VA
6
23
VD
AGND
7
22
DGND
FILT
8
21
VL
RST
9
20
GPO0
RXP4
10
19
GPO1
RXP5
11
18
AD2 / GPO2
RXP6
12
17
SDA / CDOUT
RXP7
13
16
SCL / CCLK
AD0 / CS
14
15
AD1 / CDIN
Top-Down View
28-pin SOIC/TSSOP
Package
Pin
Name
Pin #
Pin Description
VA
6
Analog Power (Input) - Analog power supply. Nominally +3.3 V. This supply should have as little noise
as possible since noise on this pin will directly affect the jitter performance of the recovered clock
VD
23
Digital Power (Input) – Digital core power supply. Nominally +3.3 V
VL
21
Logic Power (Input) – Input/Output power supply. Nominally +3.3 V or +5.0 V
AGND
7
Analog Ground (Input) - Ground for the analog circuitry in the chip. AGND and DGND should be connected to a common ground area under the chip.
DGND
22
Digital & I/O Ground (Input) - Ground for the I/O and core logic. AGND and DGND should be connected
to a common ground area under the chip.
RST
9
Reset (Input) - When RST is low, the CS8416 enters a low power mode and all internal states are reset.
On initial power up, RST must be held low until the power supply is stable, and all input clocks are stable
in frequency and phase.
FILT
8
PLL Loop Filter (Output) - An RC network should be connected between this pin and analog ground.
For minimum PLL jitter, return the ground end of the filter network directly to AGND. See “PLL Filter” on
page 53 for more information on the PLL and the external components.
RXP0
RXP1
RXP2
RXP3
RXP4
RXP5
RXP6
RXP7
4
3
2
1
10
11
12
13
Positive AES3/SPDIF Input (Input) - Single-ended or differential receiver inputs carrying AES3 or
S/PDIF encoded digital data. The RXP[7:0] inputs comprise the 8:2 S/PDIF Input Multiplexer. The select
line control is accessed using the Control 4 register (04h). Unused multiplexer inputs should be left floating or tied to AGND. See “External AES3/SPDIF/IEC60958 Receiver Components” on page 49 for recommended input circuits.
DS578F3
CS8416
Pin
Name
Pin #
Pin Description
5
Negative AES3/SPDIF Input (Input) - Single-ended or differential receiver input carrying AES3 or
S/PDIF encoded digital data. Used along with RXP[7:0] to form an AES3 differential input. In singleended operation this should be AC coupled to ground through a capacitor. See “External
AES3/SPDIF/IEC60958 Receiver Components” on page 49 for recommended input circuits.
25
System Clock (Input) - When the OMCK System Clock Mode is enabled using the SWCLK bit in the
Control 1 register, the clock signal input on this pin is automatically output through RMCK on PLL unlock.
OMCK serves as the reference signal for OMCK/RMCK ratio expressed in register 18h. “OMCK System
Clock Mode” section on page 28
RMCK
24
Input Section Recovered Master Clock (Output) - Input section recovered master clock output from
the PLL. Frequency defaults to 256x the sample rate (Fs) and may be set to 128x through the RMCKF bit
in the Control 1 register (01h). RMCK may also be set to high impedance by the RXD bit in the Control 4
register (04h).
OSCLK
27
Serial Audio Output Bit Clock (Input/Output) - Serial bit clock for audio data on the SDOUT pin
OLRCK
28
Serial Audio Output Left/Right Clock (Input/Output) - Word rate clock for the audio data on the
SDOUT pin. Frequency will be the output sample rate (Fs)
SDOUT
26
Serial Audio Output Data (Output) - Audio data serial output pin. This pin must be pulled high to VL
through a 47 kΩ resistor to place the part in Software Mode.
SDA /
CDOUT
17
Serial Control Data I/O (I²C) / Data Out (SPI) (Input/Output) - In I²C Mode, SDA is the control I/O data
line. SDA is open drain and requires an external pull-up resistor to VL. In SPI Mode, CDOUT is the output data from the control port interface on the CS8416. See the “Control Port Description” section on
page 33.
SCL /
CCLK
16
Control Port Clock (Input) - Serial control interface clock and is used to clock control data bits into and
out of the CS8416. CCLK is an open drain output and requires an external pull-up resistor to VL. See the
“Control Port Description” section on page 33.
AD0 / CS
14
Address Bit 0 (I²C) / Control Port Chip Select (SPI) (Input) - A falling edge on this pin puts the CS8416
into SPI Control Port Mode. With no falling edge, the CS8416 defaults to I²C Mode. In I²C Mode, AD0 is
a chip address pin. In SPI Mode, CS is used to enable the control port interface on the CS8416. See the
“Control Port Description” section on page 33.
AD1 /
CDIN
15
Address Bit 1 (I²C) / Serial Control Data in (SPI) (Input) - In I²C Mode, AD1 is a chip address pin. In
SPI Mode, CDIN is the input data line for the control port interface. See the “Control Port Description”
section on page 33.
AD2 /
GPO2
18
General Purpose Output 2 (Output) - If using the I²C control port, this pin must be pulled high or low
through a 47 kΩ resistor. See the “Control Port Description” section on page 33 and “General Purpose
Outputs” on page 29 for GPO functions.
RXN
OMCK
GPO1
19
General Purpose Output 1 (Output) - See “General Purpose Outputs” on page 29 for GPO functions.
GPO0
20
General Purpose Output 0 (Output) - See “General Purpose Outputs” on page 29 for GPO functions.
DS578F3
13
CS8416
14
RXP1
RXP2
RXP3
OLRCK
OSCLK
SDOUT
OMCK
QFN Pin Description
28
27
26
25
24
23
22
RXP0
1
21
RMCK
RXN
2
20
VD
VA
3
19
DGND
AGND
4
18
VL
FILT
5
17
GPO0
RST
6
16
GPO1
RXP4
7
15
AD2 / GPO2
Thermal Pad
11
RXP7
AD0 / CS
12
13
14
SDA / CDOUT
10
SCL / CCLK
9
AD1 / CDIN
8
RXP6
Top-Down View
28-pin QFN Package
RXP5
2.2
Pin
Name
Pin #
Pin Description
VA
3
Analog Power (Input) - Analog power supply. Nominally +3.3 V. This supply should have as little noise
as possible since noise on this pin will directly affect the jitter performance of the recovered clock
VD
20
Digital Power (Input) – Digital core power supply. Nominally +3.3 V
VL
18
Logic Power (Input) – Input/Output power supply. Nominally +3.3 V or +5.0 V
AGND
4
Analog Ground (Input) - Ground for the analog circuitry in the chip. AGND and DGND should be connected to a common ground area under the chip.
DGND
19
Digital & I/O Ground (Input) - Ground for the I/O and core logic. AGND and DGND should be connected
to a common ground area under the chip.
RST
6
Reset (Input) - When RST is low, the CS8416 enters a low power mode and all internal states are reset.
On initial power up, RST must be held low until the power supply is stable, and all input clocks are stable
in frequency and phase.
FILT
5
PLL Loop Filter (Output) - An RC network should be connected between this pin and analog ground.
For minimum PLL jitter, return the ground end of the filter network directly to AGND. See “PLL Filter” on
page 53 for more information on the PLL and the external components.
DS578F3
CS8416
Pin
Name
Pin #
Pin Description
RXP0
RXP1
RXP2
RXP3
RXP4
RXP5
RXP6
RXP7
1
28
27
26
7
8
9
10
Positive AES3/SPDIF Input (Input) - Single-ended or differential receiver inputs carrying AES3 or
S/PDIF encoded digital data. The RXP[7:0] inputs comprise the 8:2 S/PDIF Input Multiplexer. The select
line control is accessed using the Control 4 register (04h). Unused multiplexer inputs should be left floating or tied to AGND. See “External AES3/SPDIF/IEC60958 Receiver Components” on page 49 for recommended input circuits.
2
Negative AES3/SPDIF Input (Input) - Single-ended or differential receiver input carrying AES3 or
S/PDIF encoded digital data. Used along with RXP[7:0] to form an AES3 differential input. In singleended operation this should be AC coupled to ground through a capacitor. See “External
AES3/SPDIF/IEC60958 Receiver Components” on page 49 for recommended input circuits.
22
System Clock (Input) - When the OMCK System Clock Mode is enabled using the SWCLK bit in the
Control 1 register, the clock signal input on this pin is automatically output through RMCK on PLL unlock.
OMCK serves as the reference signal for OMCK/RMCK ratio expressed in register 18h. “OMCK System
Clock Mode” section on page 28
RMCK
21
Input Section Recovered Master Clock (Output) - Input section recovered master clock output from
the PLL. Frequency defaults to 256x the sample rate (Fs) and may be set to 128x through the RMCKF bit
in the Control 1 register (01h). RMCK may also be set to high impedance by the RXD bit in the Control 4
register (04h).
OSCLK
24
Serial Audio Output Bit Clock (Input/Output) - Serial bit clock for audio data on the SDOUT pin
OLRCK
25
Serial Audio Output Left/Right Clock (Input/Output) - Word rate clock for the audio data on the
SDOUT pin. Frequency will be the output sample rate (Fs)
SDOUT
23
Serial Audio Output Data (Output) - Audio data serial output pin. This pin must be pulled high to VL
through a 47 kΩ resistor to place the part in Software Mode.
SDA /
CDOUT
14
Serial Control Data I/O (I²C) / Data Out (SPI) (Input/Output) - In I²C Mode, SDA is the control I/O data
line. SDA is open drain and requires an external pull-up resistor to VL. In SPI Mode, CDOUT is the output data from the control port interface on the CS8416. See the “Control Port Description” section on
page 33.
SCL /
CCLK
13
Control Port Clock (Input) - Serial control interface clock and is used to clock control data bits into and
out of the CS8416. CCLK is an open drain output and requires an external pull-up resistor to VL. See the
“Control Port Description” section on page 33.
AD0 / CS
11
Address Bit 0 (I²C) / Control Port Chip Select (SPI) (Input) - A falling edge on this pin puts the CS8416
into SPI Control Port Mode. With no falling edge, the CS8416 defaults to I²C Mode. In I²C Mode, AD0 is
a chip address pin. In SPI Mode, CS is used to enable the control port interface on the CS8416. See the
“Control Port Description” section on page 33.
AD1 /
CDIN
12
Address Bit 1 (I²C) / Serial Control Data in (SPI) (Input) - In I²C Mode, AD1 is a chip address pin. In
SPI Mode, CDIN is the input data line for the control port interface. See the “Control Port Description”
section on page 33.
AD2 /
GPO2
15
General Purpose Output 2 (Output) - If using the I²C control port, this pin must be pulled high or low
through a 47 kΩ resistor. See the “Control Port Description” section on page 33 and “General Purpose
Outputs” on page 29 for GPO functions.
RXN
OMCK
GPO1
16
General Purpose Output 1 (Output) - See “General Purpose Outputs” on page 29 for GPO functions.
GPO0
17
General Purpose Output 0 (Output) - See “General Purpose Outputs” on page 29 for GPO functions.
THERMAL
PAD
-
DS578F3
Thermal Pad - Thermal relief pad for optimized heat dissipation.
15
CS8416
3. PIN DESCRIPTION - HARDWARE MODE
3.1
TSSOP Pin Description
Pin Name
Pin #
VA
6
1
28
OLRCK
RXP2
2
27
OSCLK
RXP1
3
26
SDOUT
RXP0
4
25
OMCK
RXN
5
24
RMCK
VA
6
23
VD
AGND
7
22
DGND
FILT
8
21
VL
RST
9
20
TX
RXSEL1
10
19
C
RXSEL0
11
18
U
TXSEL1
12
17
RCBL
TXSEL0
13
16
96KHZ
NV / RERR
14
15
AUDIO
Top-Down View
28-pin SOIC/TSSOP
Package
Pin Description
Analog Power (Input) - Analog power supply. Nominally +3.3 V. This supply should have as little
noise as possible since noise on this pin will directly affect the jitter performance of the recovered
clock
VD
23
Digital Power (Input) – Digital core power supply. Nominally +3.3 V
VL
21
Logic Power (Input) – Input/Output power supply. Nominally +3.3 V or +5.0 V
AGND
7
Analog Ground (Input) - Ground for the analog circuitry in the chip. AGND and DGND should be
connected to a common ground area under the chip.
DGND
22
Digital & I/O Ground (Input) - Ground for the I/O and core logic. AGND and DGND should be connected to a common ground area under the chip.
RST
9
Reset (Input) - When RST is low, the CS8416 enters a low power mode and all internal states are
reset. On initial power up, RST must be held low until the power supply is stable, and all input clocks
are stable in frequency and phase.
FILT
8
PLL Loop Filter (Output) - An RC network should be connected between this pin and analog
ground.
For minimum PLL jitter, return the ground end of the filter network directly to AGND. See “PLL Filter”
on page 53 for more information on the PLL and the external components.
RXP0
RXP1
RXP2
RXP3
4
3
2
1
Positive AES3/SPDIF Input (Input) - Single-ended or differential receiver inputs carrying AES3 or
S/PDIF encoded digital data. The RXP[3:0] inputs comprise the 4:2 S/PDIF Input Multiplexer. The
select line control is accessed using the RXPSEL[1:0] pins. Unused multiplexer inputs should be left
floating or tied to AGND. See “External AES3/SPDIF/IEC60958 Receiver Components” on page 49
for recommended input circuits.
5
Negative AES3/SPDIF Input (Input) - Single-ended or differential receiver input carrying AES3 or
S/PDIF encoded digital data. Used along with RXP[3:0] to form an AES3 differential input. In singleended operation this should be AC coupled to ground through a capacitor. See “External
AES3/SPDIF/IEC60958 Receiver Components” on page 49 for recommended input circuits.
RXN
16
RXP3
DS578F3
CS8416
Pin Name
Pin #
Pin Description
OMCK
25
System Clock (Input) - OMCK System Clock Mode is enabled by a transition (rising edge active) on
OMCK after reset. When enabled, the clock signal input on this pin is automatically output through
RMCK on PLL unlock. See “OMCK System Clock Mode” on page 28.
RMCK
24
Input Section Recovered Master Clock (Output) - Input section recovered master clock output
from the PLL. Frequency is 256x the sample rate (Fs) when the U pin is pulled down by a 47 kΩ
resistor to DGND. Frequency is 128x the sample rate (Fs) when the U pin is pulled up by a 47 kΩ
resistor to VL.
OSCLK
27
Serial Audio Output Bit Clock (Input/Output) - Serial bit clock for audio data on the SDOUT pin
OLRCK
28
Serial Audio Output Left/Right Clock (Input/Output) - Word rate clock for the audio data on the
SDOUT pin. Frequency will be the output sample rate (Fs)
SDOUT
26
Serial Audio Output Data (Output) - Audio data serial output pin. This pin must be pulled low to
DGND through a 47 kΩ resistor to place the part in Hardware Mode.
RXSEL1
RXSEL0
10
11
Receiver MUX Selector (Input) - Used to select which pin, RXP[3:0], is used for the receiver input.
TXSEL1
TXSEL0
12
13
TX Pin MUX SELECTION (Input) - Used to select which pin, RXP[3:0], is passed to the TX pin output. If TX passthrough is not used, the user should set it to output one of the unused receiver inputs.
TX
20
S/PDIF MUX Passthrough (Output) - Single-ended signal is resolved to full-rail, but is not de-jittered
before it is output. Output is set by TXSEL[1:0]. This pin is also used to select the type of phase
detector (PDUR) at reset. If TX passthrough is not used, the user should set it to output one of the
unused receiver inputs.
NV/RERR
14
Non-Validity Receiver Error/Receiver Error (Output) - Receiver error indicator. NVERR is selected
by a 47 kΩ resistor to DGND. RERR is selected by a 47 kΩ resistor to VL.
AUDIO
15
Audio Channel Status Bit (Output) – When low, a valid linear PCM audio stream is indicated. See
“Non-Audio Detection” on page 31. This pin is also used to select the serial port format (SFSEL1) at
reset.
96KHZ
16
96 kHz Sample Rate Detect (Output) - If the input sample rate is ≤ 48 kHz, outputs a “0”. Outputs a
“1” if the sample rate is ≥ 88.1 kHz. Otherwise the output is indeterminate. Also used to set the
Emphasis Audio Match feature at reset.
RCBL
17
Receiver Channel Status Block (Output) -Indicates the beginning of a received channel status block.
RCBL goes high two frames after the reception of a Z preamble, remains high for 16 frames and then
returns low for the remainder of the block. RCBL changes on rising edges of RMCK. Also used to set
the serial audio port to master or slave at reset.
C
19
Channel Status Data (Output) - Outputs channel status data from the AES3 receiver, clocked by the
rising and falling edges of OLRCK. Also used to select the serial port format (SFSEL0) at reset.
U
18
User Data (Output) - Outputs user data from the AES3 receiver, clocked by the rising and falling
edges of OLRCK. Also used to select the frequency of RMCK to either 256*Fs or 128*Fs at reset.
DS578F3
17
CS8416
RXP1
RXP2
RXP3
OLRCK
OSCLK
SDOUT
OMCK
QFN Pin Description
28
27
26
25
24
23
22
RXP0
1
21
RMCK
RXN
2
20
VD
VA
3
19
DGND
AGND
4
18
VL
FILT
5
17
TX
RST
6
16
C
RXSEL1
7
15
U
Thermal Pad
11
TXSEL0
NV / RERR
12
13
14
RCBL
10
96KHZ
9
AUDIO
8
TXSEL1
Top-Down View
28-pin QFN Package
RXSEL0
3.2
Pin Name
Pin #
VA
3
Analog Power (Input) - Analog power supply. Nominally +3.3 V. This supply should have as little
noise as possible since noise on this pin will directly affect the jitter performance of the recovered
clock
VD
20
Digital Power (Input) – Digital core power supply. Nominally +3.3 V
VL
18
Logic Power (Input) – Input/Output power supply. Nominally +3.3 V or +5.0 V
AGND
4
Analog Ground (Input) - Ground for the analog circuitry in the chip. AGND and DGND should be
connected to a common ground area under the chip.
DGND
19
Digital & I/O Ground (Input) - Ground for the I/O and core logic. AGND and DGND should be connected to a common ground area under the chip.
RST
6
Reset (Input) - When RST is low, the CS8416 enters a low power mode and all internal states are
reset. On initial power up, RST must be held low until the power supply is stable, and all input clocks
are stable in frequency and phase.
FILT
5
PLL Loop Filter (Output) - An RC network should be connected between this pin and analog
ground.
For minimum PLL jitter, return the ground end of the filter network directly to AGND. See “PLL Filter”
on page 53 for more information on the PLL and the external components.
RXP0
RXP1
RXP2
RXP3
1
28
27
26
Positive AES3/SPDIF Input (Input) - Single-ended or differential receiver inputs carrying AES3 or
S/PDIF encoded digital data. The RXP[3:0] inputs comprise the 4:2 S/PDIF Input Multiplexer. The
select line control is accessed using the RXPSEL[1:0] pins. Unused multiplexer inputs should be left
floating or tied to AGND. See “External AES3/SPDIF/IEC60958 Receiver Components” on page 49
for recommended input circuits.
18
Pin Description
DS578F3
CS8416
Pin Name
Pin #
Pin Description
RXN
2
Negative AES3/SPDIF Input (Input) - Single-ended or differential receiver input carrying AES3 or
S/PDIF encoded digital data. Used along with RXP[3:0] to form an AES3 differential input. In singleended operation this should be AC coupled to ground through a capacitor. See “External
AES3/SPDIF/IEC60958 Receiver Components” on page 49 for recommended input circuits.
OMCK
22
System Clock (Input) - OMCK System Clock Mode is enabled by a transition (rising edge active) on
OMCK after reset. When enabled, the clock signal input on this pin is automatically output through
RMCK on PLL unlock. See “OMCK System Clock Mode” on page 28.
RMCK
21
Input Section Recovered Master Clock (Output) - Input section recovered master clock output
from the PLL. Frequency is 256x the sample rate (Fs) when the U pin is pulled down by a 47 kΩ
resistor to DGND. Frequency is 128x the sample rate (Fs) when the U pin is pulled up by a 47 kΩ
resistor to VL.
OSCLK
24
Serial Audio Output Bit Clock (Input/Output) - Serial bit clock for audio data on the SDOUT pin
OLRCK
25
Serial Audio Output Left/Right Clock (Input/Output) - Word rate clock for the audio data on the
SDOUT pin. Frequency will be the output sample rate (Fs)
SDOUT
23
Serial Audio Output Data (Output) - Audio data serial output pin. This pin must be pulled low to
DGND through a 47 kΩ resistor to place the part in Hardware Mode.
RXSEL1
RXSEL0
7
8
Receiver MUX Selector (Input) - Used to select which pin, RXP[3:0], is used for the receiver input.
TXSEL1
TXSEL0
9
10
TX Pin MUX SELECTION (Input) - Used to select which pin, RXP[3:0], is passed to the TX pin output. If TX passthrough is not used, the user should set it to output one of the unused receiver inputs.
TX
17
S/PDIF MUX Passthrough (Output) - Single-ended signal is resolved to full-rail, but is not de-jittered
before it is output. Output is set by TXSEL[1:0]. This pin is also used to select the type of phase
detector (PDUR) at reset. If TX passthrough is not used, the user should set it to output one of the
unused receiver inputs.
NV/RERR
11
Non-Validity Receiver Error/Receiver Error (Output) - Receiver error indicator. NVERR is selected
by a 47 kΩ resistor to DGND. RERR is selected by a 47 kΩ resistor to VL.
AUDIO
12
Audio Channel Status Bit (Output) – When low, a valid linear PCM audio stream is indicated. See
“Non-Audio Detection” on page 31. This pin is also used to select the serial port format (SFSEL1) at
reset.
96KHZ
13
96 kHz Sample Rate Detect (Output) - If the input sample rate is ≤ 48 kHz, outputs a “0”. Outputs a
“1” if the sample rate is ≥ 88.1 kHz. Otherwise the output is indeterminate. Also used to set the
Emphasis Audio Match feature at reset.
RCBL
14
Receiver Channel Status Block (Output) -Indicates the beginning of a received channel status block.
RCBL goes high two frames after the reception of a Z preamble, remains high for 16 frames and then
returns low for the remainder of the block. RCBL changes on rising edges of RMCK. Also used to set
the serial audio port to master or slave at reset.
C
16
Channel Status Data (Output) - Outputs channel status data from the AES3 receiver, clocked by the
rising and falling edges of OLRCK. Also used to select the serial port format (SFSEL0) at reset.
U
15
User Data (Output) - Outputs user data from the AES3 receiver, clocked by the rising and falling
edges of OLRCK. Also used to select the frequency of RMCK to either 256*Fs or 128*Fs at reset.
THERMAL
PAD
-
DS578F3
Thermal Pad - Thermal relief pad for optimized heat dissipation.
19
CS8416
4. TYPICAL CONNECTION DIAGRAMS
+3.3 V
Analog
Supply
Ferrite
Bead
*
+3.3 V
+3.3 V or +5 V
*
10 μ F
0.1μ F
0.1μ F
VA
0.1μ F
VL
VD
47k Ω
VL
RXN
RXP0
RXP1
**
AES3 /
S/PDIF
Sources
RXP2
SDOUT
OLRCK
OSCLK
Serial Audio
Input
Device
RMCK
Clock Control
OMCK
Clock Source
CS8416
RXP3
RXP4
RXP5
RXP6
RXP7
VL
Microcontroller
GPO0
GPO1
AD2/GPO2
AD0 / CS
AD1 / CDIN
SCL / CCLK
SDA / CDOUT
RST
AGND
FILT
External
Interface
DGND
RFLT
CRIP
CFLT
***
* A separate analog supply is only necessary in applications where RMCK is used for a jitter sensitive task. For
applications where RMCK is not used for a jitter sensitive task, connect VA to VD via a ferrite bead. Keep decoupling capacitors between VA and AGND.
** See “S/PDIF Receiver” on page 27 and “External AES3/SPDIF/IEC60958 Receiver Components” on page 49
for typical input configurations and recommended input circuits.
*** For best jitter performance, connect the filter ground directly to the AGND pin. See Table 6 on page 54 for PLL
filter values.
Figure 5. Typical Connection Diagram - Software Mode
20
DS578F3
CS8416
+3.3 V
Analog
Supply
Ferrite **
Bead
+3.3 V
+3.3 V or +5 V
**
10 μ F
0.1μ F
VD
VA
VL
VL
OLRCK
RXN
***
AES3 /
S/PDIF
Sources
0.1μ F
0.1μ F
OSCLK
SDOUT
RXP0
RXP1
CS8416
RXP2
47k Ω
RXP3
VL
Serial Audio
Input Device
RST
RXSEL0
RXSEL1
TXSEL0
Hardware
Control
TXSEL1
NV/RERR *
AUDIO
RMCK
Clock Control
OMCK
Clock Source
*
96KHZ *
TX *
RCBL *
External
Interface
U*
C*
AGND
FILT
DGND
RFLT
CRIP
CFLT
****
* These pins must be pulled high to VL or low to DGND through a 47 kΩ resistor.
** A separate analog supply is only necessary in applications where RMCK is used for a jitter sensitive task. For
applications where RMCK is not used for a jitter sensitive task, connect VA to VD via a ferrite bead. Keep decoupling capacitors between VA and AGND.
*** See “S/PDIF Receiver” on page 27 and “External AES3/SPDIF/IEC60958 Receiver Components” on page 49
for typical input configurations and recommended input circuits.
**** For best jitter performance connect the filter ground directly to the AGND pin. See Table 6 on page 54 for PLL
filter values.
Figure 6. Typical Connection Diagram - Hardware Mode
DS578F3
21
CS8416
5. APPLICATIONS
5.1
Reset, Power-Down and Start-Up
When RST is low, the CS8416 enters a low power mode and all internal states are reset, including the control port and registers, and the outputs are muted. In Software Mode, when RST is high, the control port
becomes operational, and the desired settings should be loaded into the control registers. Writing a 1 to the
RUN bit will then cause the part to leave the low power state and begin operation. After the PLL has settled,
the serial audio outputs will be enabled.
Some options within the CS8416 are controlled by a start-up mechanism. During the reset state, some of
the pins are reconfigured internally to be inputs. Immediately upon exiting the reset state, the level of these
pins is sensed. The pins are then switched to be outputs. This mechanism allows output pins to be used to
set alternative modes in the CS8416 by connecting a 47 kΩ resistor to between the pin and either VL (HI)
or DGND (LO). For each mode, every start-up option select pin MUST have an external pull-up or pull-down
resistor as there are no internal pull-up or pull-down resistors for these startup conditions (except for TX,
which has an internal pull-down). In Software Mode, the only start-up option pins are GPO2, which are used
to set a chip address bit for the control port in I²C Mode, and SDOUT, which selects between Hardware and
Software Modes. The Hardware Mode uses many start-up options, which are detailed in Section 15.2 “Hardware Mode Function Selection” on page 46.
5.2
ID Code and Revision Code
The CS8416 has a register that contains a 4-bit code to indicate that the addressed device is a CS8416.
This is useful when other CS84XX family members are resident in the same system, allowing common software modules.
The CS8416 4-bit revision code is also available. This allows the software driver for the CS8416 to identify
which revision of the device is in a particular system, and modify its behavior accordingly. To allow for future
revisions, it is strongly recommend that the revision code is read into a variable area within the microcontroller, and used wherever appropriate as revision details become known.
5.3
Power Supply, Grounding, and PCB Layout
For most applications, the CS8416 can be operated from a single +3.3 V supply, following normal supply
decoupling practices (See Figures 5 and 6). For applications where the recovered input clock, output on the
RMCK pin, is required to be low jitter, then use a separate, quiet, analog +3.3 V supply for VA, decoupled
to AGND. Make certain that no digital traces are routed near VA, AGND, or FILT as noise may couple and
degrade performance. These pins should be well isolated from switching signals and other noise sources.
VL sets the level for the digital inputs and outputs, as well as the AES/SPDIF receiver inputs.
Extensive use of power and ground planes, ground plane fill in unused areas and surface mount decoupling
capacitors are recommended. Decoupling capacitors should be mounted on the same side of the board as
the CS8416 to minimize inductance effects, and all decoupling capacitors should be as close to the CS8416
as possible. See “PLL Filter” on page 53 for layout recommendations for the PLL.
22
DS578F3
CS8416
6. GENERAL DESCRIPTION
The CS8416 is a monolithic CMOS device that receives and decodes audio data according to the AES3, IEC60958,
S/PDIF, and EIAJ CP1201 interface standards.
The CS8416 provides an 8:2 multiplexer to select between eight inputs for decoding and to allow an input signal to
be routed to an output of the CS8416. Input data can be either differential or single-ended. A low jitter clock is recovered from the incoming data using a PLL. The decoded audio data is output through a configurable, 3-wire serial
audio output port. The channel status and Q-channel subcode portion of the user data are assembled in registers
and may be accessed through an SPI or I²C port.
Three General Purpose Output (GPO) pins are provided to allow a variety of signals to be accessed under software
control. In Hardware Mode, dedicated pins are used to select audio stream inputs for decoding and transmission to
a dedicated TX pin. Hardware Mode also provides channel status and user data output pins.
Figures 5 and 6 show the power supply and external connections to the CS8416 when configured for Software Mode
and Hardware Mode. Please note that all I/O pins, including RXN and RXP[7:0], operate at the VL voltage.
6.1
AES3 and S/PDIF Standards Documents
This document assumes that the user is familiar with the AES3 and S/PDIF data formats. It is advisable to
have current copies of the AES3, IEC60958, and IEC61937 specifications on hand for easy reference.
The latest AES3 standard is available from the Audio Engineering Society or ANSI at www.aes.org or at
www.ansi.org. Obtain a copy of the latest IEC60958/61937 standard from ANSI or from the International
Electrotechnical Commission at www.iec.ch. The latest EIAJ CP-1201 standard is available from the
Japanese Electronics Bureau.
Application Note 22: Overview of Digital Audio Interface Data Structures contains a useful tutorial on digital
audio specifications, but it should not be considered a substitute for the standards.
The paper An Understanding and Implementation of the SCMS Serial Copy Management System for
Digital Audio Transmission, by Clifton Sanchez, is an excellent tutorial on SCMS. It is available from the
AES as reprint 3518.
7. SERIAL AUDIO OUTPUT PORT
A 3-wire serial audio output port is provided. The port can be adjusted to suit the attached device by setting the control registers. The following parameters are adjustable: master or slave, serial clock frequency, audio data resolution, left- or right-justification of the data relative to left/right clock, optional one-bit cell delay of the first data bit, the
polarity of the bit clock, and the polarity of the left/right clock. By setting the appropriate control bits, many formats
are possible.
Figure 7 shows a selection of common output formats, along with the control bit settings. A special AES3 direct output format is included, which allows the serial output port access to the V, U, and C bits embedded in the serial audio
data stream. When using the part in AES3 direct-output format, the de-emphasis filter must be off (see Section 14.4
on page 38). The P bit, which would normally be a parity bit, is replaced by a Z bit, which is used to indicate the start
of each block. The received channel status block start signal is also available as the RCBL pin in Hardware Mode
and through a GPO pin in Software Mode.
In master mode, the left/right clock (OLRCK) and the serial bit clock (OSCLK) are outputs, derived from the recovered RMCK clock. In slave mode, OLRCK and OSCLK are inputs. OLRCK is normally synchronous to the appropriate master clock, but OSCLK can be asynchronous and discontinuous if required. By appropriate phasing of OLRCK
and control of the serial clocks, multiple CS8416’s can share one serial port. OLRCK should be continuous, but the
duty cycle can be less than the specified typical value of 50% if enough serial clocks are present in each phase to
DS578F3
23
CS8416
clock all the data bits. When in slave mode, the serial audio output port cannot be set for right-justified data. The
CS8416 allows immediate mute of the serial audio output port audio data by the MUTESAO bit of Control Register 1.
For more information about serial audio formats, refer to the Cirrus Logic applications note AN282, “The 2-Channel
Serial Audio Interface: A Tutorial”, available at www.cirrus.com.
OLRCK
Left
Justified OSCLK
(Out)
SDOUT
Channel A
LSB
MSB
OLRCK
I²S
(Out)
MSB
LSB
Channel A
MSB
Channel B
OSCLK
SDOUT
LSB
MSB
OLRCK
Right
Justified OSCLK
(Out)
SDOUT
AES3
Direct
(Out)
Channel B
MSB
Channel A
MSB Extended
OLRCK
Channel B
LSB
MSB
MSB Extended
Channel B
Channel A
MSB
LSB
MSB
LSB
Channel A
Channel B
OSCLK
SDOUT
LSB
MSB V U C
LSB
MSB V U C
MSB V U C Z
LSB
MSB V U C Z
Frame 0
Frame 191
Left-Justified
I²S
Right-Justified
AES3 Direct
LSB
SOMS*
SOSF*
X
X
1
X
X
X
X
X
SORES[1:0]* SOJUST*
XX
XX
XX
11
0
0
1
0
SODEL*
0
1
0
0
SOSPOL* SOLRPOL*
0
0
0
0
0
1
0
0
X = don’t care to match format, but does need to be set to the desired setting
* See Serial Output Data Format Register Bit Descriptions for an explanation of the meaning of each bit
Figure 7. Serial Audio Output Example Formats
24
DS578F3
CS8416
7.1
Slip/Repeat Behavior
When using the serial audio output port in slave mode with an OLRCK input that is asynchronous to the
incoming AES3 data, the interrupt bit OSLIP (bit 5 in the Interrupt 1 Status register, 0Dh) is provided to indicate when repeated or dropped samples occur. Refer to Figure 8 for the AES3 data format diagram.
When the serial output port is configured as slave, depending on the relative frequency of OLRCK to the
input AES3 data (Z/X) preamble frequency, the data will be slipped or repeated at the output of the CS8416.
After a fixed delay from the Z/X preamble (a few periods of the internal clock, which is running at 256Fs),
the circuit will look back in time until the previous Z/X preamble and check which of the following conditions
occurred:
1. If during that time, the internal data buffer was not updated, a slip has occurred. Data from the previous
frame will be output and OSLIP will be set to 1. Due to the OSLIP bit being “sticky,” it will remain 1 until
the register is read. It will then be reset until another slip/repeat condition occurs.
2. If during that time the internal data buffer did not update between two positive or negative edges (depending on OLRPOL) of OLRCK, a repeat has occurred. In this case, the buffer data was updated twice,
so the part has lost one frame of data. This event will also trigger OSLIP to be set to 1. Due to the OSLIP
bit being “sticky,” it will remain 1 until the register is read. It will then be reset until another slip/repeat
condition occurs.
3. If during that time, it did see a positive edge on OLRCK (or negative edge if the SOLRPOL is set to 1)
no slip or repeat has happened. Due to the OSLIP bit being “sticky,” it will remain in its previous state
until either the register is read or a slip/repeat condition occurs.
If the user reads OSLIP as soon as the event triggers, over a long period of time the rate of occurring INT
will be equal to the difference in frequency between the input AES data and the slave serial output LRCK.
The CS8416 uses a hysteresis window when a slip/repeat event occurs. The slip/repeat is triggered when
an edge of OLRCK passes a window size from the beginning of the Z/X preamble. Without the hysteresis
window, jitter on OLRCK with a frequency very close to Fs could slip back and forth, causing multiple slip/repeat events. The CS8416 uses a hysteresis window to ensure that only one slip/repeat happens even with
jitter on OLRCK
Frame 191
X
Channel A
Data
Y
Frame 0
Channel B
Data
Z
Channel A
Data
Y
Frame 1
Channel B
Data
X
Channel A
Data
Y
Channel B
Data
Preambles
OLRCK (in slave mode)
Figure 8. AES3 Data Format
DS578F3
25
CS8416
7.2
AES11 Behavior
When OLRCK is configured as a master, the positive or negative edge of OLRCK (depending on the setting
of SOLRPOL in register 05h) will be within -1.0%(1/Fs) to 1.1%(1/Fs) from the start of the preamble X/Z. In
master mode, the latency through the part is dependent on the input sample frequency. The typical delay
through the part from the beginning of the preamble to the active edge of OLRCK for the various sample
frequencies is given in Table 1. In master mode without the de-emphasis filter engaged, the latency of the
audio data will be 3 frames.
Fs (kHz)
Delay (ns)
32
44.1
48
64
96
192
98.0
80.5
78.0
67.0
57.5
47.0
Table 1. Typical Delays by Frequency Values
When OLRCK is configured as a slave, any synchronized input within +/-28%(1/Fs) from the positive or negative edge of OLRCK (depending on the setting of SOLRPOL in register 05h) will be treated as being sampled at the same time. Since the CS8416 has no control of the OLRCK in slave mode, the latency of the
data through the part will be a multiple of 1/Fs plus the delay between OLRCK and the preambles.
Both of these conditions are within the tolerance range set forth in the AES11 standard.
26
DS578F3
CS8416
8. S/PDIF RECEIVER
The CS8416 includes an AES3/SPDIF digital audio receiver. The receiver accepts and decodes bi-phase encoded
audio and digital data according to the AES3, IEC60958 (S/PDIF), and EIAJ CP-1201 interface standards. The receiver consists of an analog differential input stage, driven through analog input pins RXP0 to RXP7 and a common
RXN, a PLL based clock recovery circuit, and a decoder which separates the audio data from the channel status
and user data. External components are used to terminate the incoming data cables and isolate the CS8416. These
components are detailed in “External AES3/SPDIF/IEC60958 Receiver Components” on page 49. Figure 9 shows
the input structure of the receiver.
VL
V L = 5 .0 V : 2 .3 k Ω
V L = 3 .3 V : 3 .0 k Ω
RXN
22 kΩ
(2 2 0 0 0 /N ) Ω
+
R X P [7 :0 ]
V L = 5 .0 V : (1 5 0 0 + 8 0 0 /N ) Ω
V L = 3 .3 V : (1 5 0 0 + 1 5 0 0 /N ) Ω
22 kΩ
(2 2 0 0 0 /N ) Ω
AGND
If RXP[7:0] is selected by either the receiver MUX or the TX passthrough MUX, N=1.
If RXP[7:0] is selected by both the receiver MUX and the TX passthrough MUX, N=2.
If RXP[7:0] is not selected at all, N=0 (i.e. high impedance).
Figure 9. Receiver Input Structure
8.1
8:2 S/PDIF Input Multiplexer
8.1.1
General
The CS8416 employs a 8:2 S/PDIF input multiplexer to accommodate up to eight channels of input digital
audio data. Digital audio data may be single-ended or differential. Differential inputs utilize RXP[7:0] and
a shared RXN. Single ended signals are accommodated by using the RXP[7:0] inputs and AC coupling
RXN to ground.
All active inputs to the CS8416 8:2 input multiplexer should be coupled through a capacitor as these inputs
are biased at VL/2 when selected. These inputs are floating when not selected. Unused multiplexer inputs
should be left floating or tied to AGND. The recommended capacitor value is 0.01 μF to 0.1 μF. The recommended dielectrics for the AC coupling capacitors are C0G or X7R.
The input voltage range for the input multiplexer is set by the I/O power supply pin, VL. The input voltage
of the RXP[7:0] and RXN pins is also set by the level of VL. Input signals with voltage levels above VL or
below DGND may degrade performance or damage the part.
8.1.2
Software Mode
The multiplexer select line control is accessed through bits RXSEL[2:0] in control port register 04h. The
multiplexer defaults to RXP0.
DS578F3
27
CS8416
The second output of the input multiplexer is used to provide the selected input as a source to be output
on a GPO pin. This pass through signal is selected by TXSEL[2:0] in control port register 04h. This singleended signal is resolved to full-rail, but is not de-jittered before it is output.
8.1.3
Hardware Mode
In Hardware Mode the input to the decoder is selected by dedicated pins, RXSEL[1:0].
The pass through signal is selected by dedicated pins, TXSEL[1:0] for output on the dedicated TX pin.
This single-ended signal is resolved to full-rail, but is not de-jittered before it is output.
Selectable inputs are restricted to RXP0 to RXP3 for both the receiver and the TX output pin. These inputs
are selected by RXSEL[1:0] and TXSEL[1:0] respectively.
8.2
OMCK System Clock Mode
A special clock switching mode is available that allows the OMCK clock input to automatically replace
RMCK when the PLL becomes unlocked. This is accomplished without spurious transitions or glitches on
RMCK. In Hardware Mode this feature is enabled by a transition (rising edge active) on the OMCK pin after
reset. Therefore to not enable the clock switching feature in Hardware Mode, OMCK should be tied to DGND
or VL. However, in Hardware Mode, once the clock switching feature has been enabled, it can only be disabled by resetting the part. In Software Mode the automatic clock switching feature is enabled by setting
SWCLK bit in Control1 register to a “1”. Additionally in Software Mode, OMCK can be manually forced to
output on RMCK by using the FSWCLK bit in the Control0 register.
When the clock switching feature is enabled, OSCLK and OLRCK are derived from the OMCK input when
the clock has been switched and the serial port is in master mode. When clock switching is enabled and the
PLL is not locked, OLRCK will be OMCK/256 and OSCLK will be OMCK/4. When the PLL loses lock, the
frequency of the VCO drops to ~750 kHz. When this system clock mode is not enabled, the OSCLK and
OLRCK will be based on the VCO when the PLL is not locked and has reached its steady-state idle frequency. Table 2 shows an example of output clocks based on clock switching being enabled or disabled.
Clock Switching
Enabled/Disabled
PLL
Locked/Unlocked
RMCK Clock
Ratio
RMCK
OSCLK
OLRCK
Disabled
Locked
128*Fs
6.144 MHz
3.072 MHz
48 kHz
Enabled
Locked
128*Fs
6.144 MHz
3.072 MHz
48 kHz
Disabled
Unlocked
128*Fs
~375 kHz
~187.5 kHz
~2.925 kHz
Enabled
Unlocked
128*Fs
11.2896 MHz
2.8224 MHz
44.1 kHz
Disabled
Locked
256*Fs
12.288 MHz
3.072 MHz
48 kHz
Enabled
Locked
256*Fs
12.288 MHz
3.072 MHz
48 kHz
Disabled
Unlocked
256*Fs
~750 kHz
~187.5 kHz
~2.925 kHz
Enabled
Unlocked
256*Fs
11.2896 MHz
2.8224 MHz
44.1 kHz
Example with OMCK = 11.2896 MHz, the receiver input sample rate = 48 kHz,
OSLCK = 64*Fs, and FSWCLK (Software Mode only) = ‘0’.
Table 2. Clock Switching Output Clock Rates
8.3
Clock Recovery and PLL Filter
Please see “PLL Filter” on page 53 for a general description of the PLL, selection of recommended PLL filter
components, and layout considerations. Figures 5 and 6 show the recommended configuration of the two
capacitors and one resistor that comprise the PLL filter.
28
DS578F3
CS8416
9. GENERAL PURPOSE OUTPUTS
Three General Purpose Outputs (GPO) are provided to allow the equipment designer flexibility in configuring the
CS8416. Fourteen signals are available to be routed to any of the GPO pins. The outputs of the GPO pins are set
through the GPOxSEL[3:0] bits in the Control2 (02h) and Control3 (03h) registers. All GPO pins default to GND
after reset.
GPO pins may be configured to provide the following data:
Function
Code
GND
0000
Definition
Fixed low level
EMPH
0001
State of EMPH bit in the incoming data stream.
INT
0010
CS8416 interrupt output
C
0011
Channel status bit
U
0100
User data bit
RERR
0101
Receiver Error
NVERR
0110
Non-Validity Receiver Error
RCBL
0111
Receiver Channel Status Block
96KHZ
1000
If the input sample rate is ≤ 48 kHz, outputs a “0”. Outputs a “1” if the sample rate is ≥ 88.1 kHz.
Otherwise the output is indeterminate.
AUDIO
1001
Non-audio indicator for decoded input stream
VLRCK
1010
Virtual LRCK. Can be used to frame the C and U output data.
TX
1011
Pass through of AES/SPDIF input selected by TXSEL[2:0] in the Control 4 register (04h)
VDD
1100
VDD fixed high level
HRMCK
1101
FS X 512 (Note 1)
Codes 1110 to 1111 - Reserved
Table 3. GPO Pin Configurations
Notes:
1. Frequency = 25 MHz Max, duty cycle not guaranteed, target duty cycle = 50% @ FS = 48 kHz.
DS578F3
29
CS8416
10.ERROR AND STATUS REPORTING
10.1
General
While decoding the incoming bi-phase encoded data stream, the CS8416 has the ability to identify various
error conditions.
10.1.1 Software Mode
Software Mode allows the most flexibility in reading errors. When unmasked, bits in the Receiver Error
register (0Ch) indicate the following errors:
1. QCRC – CRC error in Q subcode data.
2. CCRC – CRC error in channel status data.
3. UNLOCK – PLL is not locked to incoming data stream.
4. V – Data Validity bit is set.
5. CONF – The logical OR of UNLOCK and BIP. The input data stream may be near error condition due
to jitter degradation.
6. BIP – Biphase encoding error.
7. PAR – Parity error in incoming data.
The error bits are “sticky,” meaning that they are set on the first occurrence of the associated error and
will remain set until the user reads the register through the control port. This enables the register to log all
unmasked errors that occurred since the last time the register was read.
As a result of the bits “stickiness,” it is necessary to perform two reads on these registers to see if the error
condition still exists.
The Receiver Error Mask register (06h) allows masking of individual errors. The bits in this register default
to 00h and serve as masks for the corresponding bits of the Receiver Error register. If a mask bit is set to
1, the error is unmasked, which implies the following: its occurrence will be reported in the receiver error
register, induce a pulse on RERR, invoke the occurrence of a RERR interrupt, and affect the current audio
sample according to the status of the HOLD bits. The exceptions are the QCRC and CCRC errors, which
do not affect the current audio sample, even if unmasked.
The HOLD bits allow a choice of:
•
Holding the previous sample
•
Replacing the current sample with zero (mute)
OR
•
Not changing the current audio sample
10.1.2 Hardware Mode
In Hardware Mode, the user may only choose between Non-Validity Receiver Error (NVERR) or Receiver
Error (RERR) by pulling the NV/RERR pin low or high, respectively. The pull-up/pull-down condition will
be sensed on start-up, and the appropriate error reporting will be set.
RERR – The previous audio sample is held and passed to the serial audio output port if the validity bit is
high, or a parity, bi-phase, confidence or PLL lock error occurs during the current sample.
NVERR – The previous audio sample is held and passed to the serial audio output port if a parity, biphase, confidence or PLL lock error occurs during the current sample.
30
DS578F3
CS8416
10.2
Non-Audio Detection
An AES3 data stream may be used to convey non-audio data, thus it is important to know whether the incoming AES3 data stream is digital audio or not. This information is typically conveyed in channel status bit
1, which is extracted automatically by the CS8416. However, certain non-audio sources, such as AC-3™ or
MPEG encoders, may not adhere to this convention, and the bit may not be properly set. The CS8416 AES3
receiver can detect such non-audio data through the use of an autodetect module. The autodetect module
is similar to autodetect software used in Cirrus Logic DSPs.
If the AES3 stream contains sync codes in the proper format for IEC61937 or DTS® data transmission, an
internal AUTODETECT signal will be asserted. If the sync codes no longer appear after a certain amount
of time, autodetection will time-out and AUTODETECT will be de-asserted until another format is detected.
The AUDIO signal is the logical OR of AUTODETECT and the received channel status bit 1 (as decoded
according to the CHS bit in the Control1 register).
In Hardware Mode, AUDIO is output on pin 15. In Software Mode, AUDIO is available through the GPO pins.
If non-audio data is detected, the data is still processed exactly as if it were normal audio. The exception is
the use of de-emphasis auto-select feature which will bypass the de-emphasis filter if the input stream is
detected to be non-audio. It is up to the user to mute the outputs as required.
10.2.1 Format Detection
In Software Mode, the CS8416 can automatically detect various serial audio input formats. The Format
Detect Status register (0Bh) is used to indicate a detected format. The register will indicate if uncompressed PCM data, IEC61937 data, DTS_LD data, DTS_CD data, or digital silence was detected. Additionally, the IEC61937 Pc/Pd burst preambles are available in registers 23h-26h. See the register
descriptions for more information.
10.3
Interrupts
The CS8416 has a comprehensive interrupt capability. The INT signal, available in Software Mode, indicates when an interrupt condition has occurred and may be output on one of the GPOs. It can also be set
through bits INT[1:0] in the Control1 register (01h) to be active low, active high or active low with no active
pull-up transistor. This last mode is used for active low, wired-OR hook- ups, with multiple peripherals connected to the microcontroller interrupt input pin.
Many conditions can cause an interrupt, as listed in the interrupt status register descriptions. Each source
may be masked off through mask register bits. In addition, each source may be set to rising edge, falling
edge, or level sensitive. Combined with the option of level sensitive or edge sensitive modes within the microcontroller, many different configurations are possible, depending on the needs of the equipment designer. Refer to the register descriptions for the Interrupt Mask (07h), Interrupt Mode MSB (08h), Interrupt Mode
LSB (09h), and Interrupt 1 Status (0Dh) registers
DS578F3
31
CS8416
11.CHANNEL STATUS AND USER-DATA HANDLING
“Channel Status Buffer Management” on page 51 describes Channel Status and User data control.
11.1
Software Mode
In Software Mode, several options are available for accessing the Channel Status and User data that is encoded in the received AES3/SPDIF stream.
The first option allows access directly through registers. The first 5 bytes of the Channel Status block are
decoded into the Receiver Channel Status Registers 19h - 22h. Registers 19h - 1Dh contain the A channel
status data. Registers 1Eh - 22h contain the B channel status data.
Received Channel Status (C), User (U), and EMPH bits may also be output to the GPO pins by appropriately
setting the GPOxSEL bits in control port registers 02h and 03h. In serial port master mode, OLRCK and
RCBL can be made available to qualify the U data output. In serial port slave mode, VLRCK and RCBL can
be made available to qualify the U data output. VLRCK is a virtual word clock, equal to the receiver recovered sample rate, that can be used to frame the C/U output. VLRCK and RCBL are available through the
GPO pins. Figure 10 illustrates timing of the C and U data and their related signals.
The user may also access all of the C and U bits directly from the output data stream (SDOUT) by setting
bits SORES[1:0]=11 (AES3 Direct Mode) in the Serial Audio Data Format register (05h). The appropriate
bits can be stripped from the SDOUT signal by external control logic such as a DSP or microcontroller.
If the incoming User data bits have been encoded as Q-channel subcode, the data is decoded, buffered,
and presented in 10 consecutive register locations (0Eh-17h). An interrupt may be enabled to indicate the
decoding of a new Q-channel block, which may be read through the control port.
The encoded Channel Status bits which indicate sample word length are decoded according to AES3-1992
or IEC 60958. The number of auxiliary bits are reported in bits 7 to 4 of the Receiver Channel Status register
(0Ah).
11.2
Hardware Mode
In Hardware Mode, Received Channel Status (C), and User (U) bits are output on pins 19 and 18. In serial
port master mode, OLRCK and RCBL are made available to qualify the C and U data output. Figure 10 illustrates timing of the C and U data and their related signals.
The user may also access all of the C and U bits directly from the output data stream (SDOUT) by pulling
the AUDIO and C pins high through 47 kΩ resistors to VL (AES3 Direct Mode). The appropriate bits can be
stripped from the SDOUT signal by external control logic such as a DSP or microcontroller. Only OLRCK in
master mode is available to qualify the U output. See “Hardware Mode Function Selection” on page 46 and
“Hardware Mode Equivalent Register Settings” on page 47 to configure these pins..
RCBL
(out)
VLRCK
(out)
C/U
(out)
–
–
–
32
RCBL goes high 2 frames after receipt of a Z preamble and is high for 16 frames.
VLRCK is a virtual work clock, available through the GPO pins, that can be used
to frame the C/U output.
VLRCK duty cycle is 50%. VLRCK frequency is always equal to the incoming
Figure 10. C/U Data Outputs
DS578F3
CS8416
12.CONTROL PORT DESCRIPTION
The control port is used to access the registers, allowing the CS8416 to be configured for the desired operational
modes and formats. The operation of the control port may be completely asynchronous with respect to the audio
sample rates. However, to avoid potential interference problems, the control port pins should remain static if no operation is required.
The control port has 2 modes: SPI and I²C, with the CS8416 acting as a slave device. SPI Mode is selected if there
is a high to low transition on the AD0/CS pin, after the RST pin has been brought high. I²C Mode is selected by connecting the AD0/CS pin through a resistor to VL or DGND, thereby permanently selecting the desired AD0 bit address state.
12.1
SPI Mode
In SPI Mode, CS is the CS8416 chip select signal, CCLK is the control port bit clock (input into the CS8416
from the microcontroller), CDIN is the input data line from the microcontroller, CDOUT is the output data line
to the microcontroller. Data is clocked in on the rising edge of CCLK and out on the falling edge.
Figure 11 shows the operation of the control port in SPI Mode. To write to a register, bring CS low. The first
seven bits on CDIN form the chip address and must be 0010000. The eighth bit is a read/write indicator
(R/W), which should be low to write. The next eight bits include the 7-bit Memory Address Pointer (MAP),
which is set to the address of the register that is to be updated. The next eight bits are the data which will
be placed into the register designated by the MAP. During writes, the CDOUT output stays in the Hi-Z state.
It may be externally pulled high or low with a 47 kΩ resistor, if desired.
To read a register, the MAP has to be set to the correct address by executing a partial write cycle which
finishes (CS high) immediately after the MAP byte. To begin a read, bring CS low, send out the chip address
and set the read/write bit (R/W) high. The next falling edge of CCLK will clock out the MSB of the addressed
register (CDOUT will leave the high impedance state). The MAP automatically increments, so data for successive registers will appear consecutively.
CS
CC LK
C H IP
ADDRESS
C D IN
0010000
MAP
MSB
R/W
C H IP
ADDRESS
DATA
b y te 1
High Impedance
CDOUT
LSB
0010000
R/W
b y te n
MSB
LSB MSB
LSB
MAP = Memory Address Pointer, 8 bits, MSB first
Figure 11. Control Port Timing in SPI Mode
DS578F3
33
CS8416
12.2
I²C Mode
In I²C Mode, SDA is a bidirectional data line. Data is clocked into and out of the part by the clock, SCL. There
is no CS pin. Pins AD0 and AD1 form the two least significant bits of the chip address and should be connected through a resistor to VL or DGND as desired. The GPO2 pin is used to set the AD2 bit by connecting
a 47 kΩ resistor from the GPO2 pin to VL or to DGND. The states of the pins are sensed while the CS8416
is being reset.
The signal timings for a read and write cycle are shown in Figures 12 and 13. A Start condition is defined
as a falling transition of SDA while the clock is high. A Stop condition is a rising transition while the clock is
high. All other transitions of SDA occur while the clock is low. The first byte sent to the CS8416 after a Start
condition consists of a 7-bit chip address field and a R/W bit (high for a read, low for a write). The upper 4
bits of the 7-bit address field are fixed at 0010. To communicate with a CS8416, the chip address field, which
is the first byte sent to the CS8416, should match 0010 followed by the settings of the AD2, AD1, and AD0
pins. The eighth bit of the address is the R/W bit. If the operation is a write, the next byte includes the Memory Address Pointer (MAP) which selects the register to be read or written. If the operation is a read, the
contents of the register pointed to by the MAP will be output. The MAP automatically increments, so data
from successive registers will appear consecutively. Each byte is separated by an acknowledge bit (ACK).
The ACK bit is output from the CS8416 after each input byte is read, and is input to the CS8416 from the
microcontroller after each transmitted byte.
Note that the read operation can not set the MAP, so an aborted write operation is used as a preamble. As
shown in Figure 13, the write operation is aborted after the acknowledge for the MAP byte by sending a stop
condition.
0
1
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16 17 18
19
24 25 26 27 28
SCL
CHIP ADDRESS (WRITE)
SDA
MAP BYTE
0 6
0 0 1 0 AD2 AD1 AD0 0
5
4
3
2
1
0
ACK
7
ACK
6
1
DATA +n
DATA +1
DATA
0
7
6
1
0
7
6
1
0
ACK
ACK
STOP
START
Figure 12. Control Port Timing, I²C Slave Mode Write
0
1
2
3
4
5
6
7
8
9
10 11 12 13 14 15 16
17 18
19
20 21 22 23 24 25 26 27 28
SCL
CHIP ADDRESS (WRITE)
SDA
0
0 0 1 0 AD2 AD1 AD0 0
ACK
START
STOP
MAP BYTE
6
5
4
3
2
1
CHIP ADDRESS (READ)
DATA
0 0 1 0 AD2 AD1 AD0 1
0
ACK
7
ACK
START
DATA +1
0
7
ACK
0
DATA + n
7
0
NO
ACK
STOP
Figure 13. Control Port Timing, I²C Slave Mode Read
34
DS578F3
CS8416
13.CONTROL PORT REGISTER QUICK REFERENCE
Addr R/W
(HEX)
00
R/W
Function
7
6
5
4
3
2
1
0
Control0
0
FSWCLK
0
0
PDUR
TRUNC
Reserved
Reserved
MUTSAO
INT1
INT0
HOLD1
HOLD0
RMCKF
CHS
01
R/W
Control1
SWCLK
02
R/W
Control2
DETCI
03
R/W
Control3
EMPH_CN EMPH_CN EMPH_CN GPO0SEL3 GPO0SEL2 GPO0SEL1 GPO0SEL0
TL2
TL1
TL0
GPO1SEL3 GPO1SEL2 GPO1SEL1 GPO1SEL0 GPO2SEL3 GPO2SEL2 GPO2SEL1 GPO2SEL0
04
R/W
Control4
RUN
RXD
RXSEL2
RXSEL1
RXSEL0
TXSEL2
TXSEL1
TXSEL0
05
R/W
Serial Audio Data
Format
SOMS
SOSF
SORES1
SORES0
SOJUST
SODEL
SOSPOL
SOLRPOL
06
R/W
Receiver Error
Mask
0
QCRCM
CCRCM
UNLOCKM
VM
CONFM
BIPM
PARM
07
R/W
Interrupt Mask
0
PCCHM
OSLIPM
DETCM
CCHM
RERRM
QCHM
FCHM
08
R/W
Interrupt Mode
MSB
0
PCCH1
OSLIP1
DETC1
CCH1
RERR1
QCH1
FCH1
09
R/W
Interrupt Mode
LSB
0
PCCH0
OSLIP0
DETC0
CCH0
RERR0
QCH0
FCH0
0A
R
Receiver Channel
Status
AUX3
AUX2
AUX1
AUX0
PRO
COPY
ORIG
EMPH
0B
R
Audio Format
Detect
0
PCM
IEC61937
DTS_LD
DTS_CD
Reserved
DGTL_SIL
96KHZ
0C
R
Receiver Error
0
QCRC
CCRC
UNLOCK
V
CONF
BIP
PAR
0D
R
Interrupt Status
0
PCCH
OSLIP
DETC
CCH
RERR
QCH
FCH
0E
R
Q-Channel
Subcode [0:7]
ADDRESS
ADDRESS
ADDRESS
0F
R
Q-Channel
Subcode [8:15]
TRACK
TRACK
TRACK
TRACK
TRACK
TRACK
TRACK
TRACK
10
R
Q-Channel
Subcode [16:23]
INDEX
INDEX
INDEX
INDEX
INDEX
INDEX
INDEX
INDEX
11
R
Q-Channel
Subcode [24:31]
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
12
R
Q-Channel
Subcode [32:39]
SECOND
SECOND
SECOND
SECOND
SECOND
SECOND
SECOND
SECOND
13
R
Q-Channel
Subcode [40:47]
FRAME
FRAME
FRAME
FRAME
FRAME
FRAME
FRAME
FRAME
14
R
Q-Channel
Subcode [48:55]
ZERO
ZERO
ZERO
ZERO
ZERO
ZERO
ZERO
ZERO
15
R
Q-Channel
Subcode [56:63]
ABS
MINUTE
ABS
MINUTE
ABS
MINUTE
ABS
MINUTE
ABS
MINUTE
ABS
MINUTE
ABS
MINUTE
ABS
MINUTE
16
R
[Q-Channel
Subcode 64:71]
ABS
SECOND
ABS
SECOND
ABS
SECOND
ABS
SECOND
ABS
SECOND
ABS
SECOND
ABS
SECOND
ABS
SECOND
17
R
Q-Channel
Subcode [72:79]
ABS
FRAME
ABS
FRAME
ABS
FRAME
ABS
FRAME
ABS
FRAME
ABS
FRAME
ABS
FRAME
ABS
FRAME
18
R
OMCK_RMCK
Ratio
ORR7
ORR6
ORR5
ORR4
ORR3
ORR2
ORR1
ORR0
CONTROL CONTROL CONTROL CONTROL ADDRESS
19
R
Channel A Status
AC0[7]
AC0[6]
AC0[5]
AC0[4]
AC0[3]
AC0[2]
AC0[1]
AC0[0]
1A
R
Channel A Status
AC1[7]
AC1[6]
AC1[5]
AC1[4]
AC1[3]
AC1[2]
AC1[1]
AC1[0]
1B
R
Channel A Status
AC2[7]
AC2[6]
AC2[5]
AC2[4]
AC2[3]
AC2[2]
AC2[1]
AC2[0]
1C
R
Channel A Status
AC3[7]
AC3[6]
AC3[5]
AC3[4]
AC3[3]
AC3[2]
AC3[1]
AC3[0]
1D
R
Channel A Status
AC4[7]
AC4[6]
AC4[5]
AC4[4]
AC4[3]
AC4[2]
AC4[1]
AC4[0]
DS578F3
35
CS8416
Addr R/W
(HEX)
Function
7
6
5
4
3
2
1
0
1E
R
Channel B Status
BC0[7]
BC0[6]
BC0[5]
BC0[4]
BC0[3]
BC0[2]
BC0[1]
BC0[0]
1F
R
Channel B Status
BC1[7]
BC1[6]
BC1[5]
BC1[4]
BC1[3]
BC1[2]
BC1[1]
BC1[0]
20
R
Channel B Status
BC2[7]
BC2[6]
BC2[5]
BC2[4]
BC2[3]
BC2[2]
BC2[1]
BC2[0]
21
R
Channel B Status
BC3[7]
BC3[6]
BC3[5]
BC3[4]
BC3[3]
BC3[2]
BC3[1]
BC3[0]
22
R
Channel B Status
BC4[7]
BC4[6]
BC4[5]
BC4[4]
BC4[3]
BC4[2]
BC4[1]
BC4[0]
23
R
Burst Preamble PC
Byte 0
PC0[7]
PC0[6]
PC0[5]
PC0[4]
PC0[3]
PC0[2]
PC0[1]
PC0[0]
24
R
Burst Preamble PC
Byte 1
PC1[7]
PC1[6]
PC1[5]
PC1[4]
PC1[3]
PC1[2]
PC1[1]
PC1[0]
25
R
Burst Preamble PD
Byte 0
PD0[7]
PD0[6]
PD0[5]
PD0[4]
PD0[3]
PD0[2]
PD0[1]
PD0[0]
26
R
Burst Preamble PD
Byte 1
PD1[7]
PD1[6]
PD1[5]
PD1[4]
PD1[3]
PD1[2]
PD1[1]
PD1[0]
7F
R
ID & Version
ID3
ID2
ID1
ID0
VER3
VER2
VER1
VER0
14. CONTROL PORT REGISTER DESCRIPTIONS
14.1
Memory Address Pointer (MAP)
Not a register
7
0
6
MAP6
5
MAP5
4
MAP4
3
MAP3
2
MAP2
1
MAP1
0
MAP0
MAP[6:0] - Memory Address Pointer. Will automatically increment after each read or write.
Default = ‘0000000’
14.2
Control0 (00h)
7
0
6
FSWCLK
5
0
4
0
3
PDUR
2
TRUNC
1
Reserved
0
Reserved
FSWCLK – Forces the clock signal on OMCK to be output on RMCK regardless of the SWCLK (Control1
register bit 6) bit functionality or PLL lock.
Default = ‘0’
0 – Clock signal on OMCK is output on RMCK according to the SWCLK bit functionality.
1 – Forces the clock signal on OMCK to be output on RMCK regardless of the SWCLK bit functionality.
PDUR – Changes the type of phase detector used to lock to the active RXP[7:0] input. This bit should only
be set if the sample rate range is between 32 kHz and 108 kHz. If the sample rate is outside of this range
and the PDUR bit is set, loss of lock may occur.
Default = ‘0’
0 – Normal Update Rate Phase Detector - Recovered master clock (RMCK) will have low wide-band jitter,
but increased in-band jitter.
36
DS578F3
CS8416
1 – Higher Update Rate Phase Detector - Recovered master clock (RMCK) will have low in-band jitter, but
increased wide-band jitter. Use this setting for the best performance when the output is connected to a deltasigma digital-to-analog converter (DAC).
TRUNC – Determines if the audio word length is set according to the incoming channel status data as decoded by the AUX[3:0] bits. The resulting word length in bits is 24 minus AUX[3:0].
Default = ‘0’
0 – Incoming data is not truncated.
1 – Incoming data is truncated according to the length specified in the channel status data.
Truncation occurs before the de-emphasis filter. TRUNC has no effect on output data if de-emphasis filter
is not used.
Reserved – These bits may change state depending on the input audio data.
14.3
Control1 (01h)
7
SWCLK
6
MUTESAO
5
INT1
4
INT0
3
HOLD1
2
HOLD0
1
RMCKF
0
CHS
SWCLK - Lets OMCK determine RMCK, OSCLK, OLRCK when PLL loses lock
Default = ‘0’
0 - Disable automatic clock switching. RMCK runs at the VCO frequency (~750 kHz) on PLL Unlock.
1 - Enable automatic clock switching on PLL unlock. OMCK clock input is automatically output on RMCK on
PLL Unlock.
MUTESAO - Mute control for the serial audio output port
Default = ‘0’
0 - SDOUT not muted.
1 – SDOUT muted (set to all zeros).
INT[1:0] - Interrupt output pin (INT) control
Default = ‘00’
00 - Active high; high output indicates interrupt condition has occurred.
01 - Active low, low output indicates an interrupt condition has occurred.
10 - Open drain, active low. Requires an external pull-up resistor on the INT pin. Thus it is not recommended
to multiplex INT onto GPO2 in I²C Control Port Mode since an external resistor is required on GPO2 to specify the AD2 bit of the chip address.
11 – Reserved.
HOLD[1:0] – Determine how received audio sample is affected when a receive error occurs
Default = ‘00’
00 – hold last audio sample.
01 – replace the current audio sample with all zeros (mute).
10- do not change the received audio sample.
11 - reserved
DS578F3
37
CS8416
RMCKF – Recovered Master Clock Frequency
Default = ‘0’
0 – RMCK output frequency is 256*FS.
1 – RMCK output frequency is 128*FS.
CHS – Sets which channel's C data is decoded in the Receiver Channel Status register (0Ah).
Default = ‘0’
0 – A channel.
1 – B channel.
If CHS = 0 and TRUNC = 1, both channels' audio data will be truncated by the AUX[3:0] bits indicated in the
channel A Channel Status data. If CHS = 1 and TRUNC = 1, both channels' audio data will be truncated by
the AUX[3:0] bits indicated in the channel B Channel Status data. This will occur even if the AUX[3:0] bits
indicated in the channel A Channel Status data are not equal to the AUX[3:0] bits indicated in the channel
B Channel Status data.
14.4
Control2 (02h)
7
DETCI
6
5
4
EMPH_CNTL2 EMPH_CNTL1 EMPH_CNTL0
3
GPO0SEL3
2
GPO0SEL2
1
GPO0SEL1
0
GPO0SEL0
DETCI – D to E status transfer inhibit
Default = ‘0’
0 – Allow update.
1 – Inhibit update.
EMPH_CNTL[2:0] – De-emphasis filter control. See Figure 14 for De-emphasis filter response.
Default = ‘000’
000 – If the serial audio output port is using the AES3 direct-output format, the de-emphasis filter must remain off.
001 – 32 kHz setting.
010 – 44.1 kHz setting.
011 – 48 kHz setting.
100 – 50 μs/15 μs de-emphasis filter auto-select on. Coefficients (32, 44.1 or 48 kHz or no de-emphasis filter at all) match the pre-emphasis and sample frequency indicators in the channel status bits of Channel A.
Thus it is impossible to have de-emphasis applied to one channel but not the other. The de-emphasis filter
is turned off if the audio data is detected to be non-audio data.
GPO0SEL[3:0] – GPO0 Source select. See “General Purpose Outputs” on page 29.
Default = ‘0000’
38
DS578F3
CS8416
Gain,
dB
T1 =
50us
0
T2
=15us
-10
F1
3.183
Frequency,
KHz
F2
10.61
Figure 14. De-Emphasis Filter Response
14.5
Control3 (03h)
7
GPO1SEL3
6
GPO1SEL2
5
GPO1SEL1
4
GPO1SEL0
3
GPO2SEL3
2
GPO2SEL2
1
GPO2SEL1
0
GPO2SEL0
GPO1SEL[3:0] – GPO1 Source select. See “General Purpose Outputs” on page 29.
Default = ‘0000’
GPO2SEL[3:0] – GPO2 Source select. See “General Purpose Outputs” on page 29.
Default = ‘0000’
14.6
Control4 (04h)
7
RUN
6
RXD
5
RXSEL2
4
RXSEL1
3
RXSEL0
2
TXSEL2
1
TXSEL1
0
TXSEL0
RUN - Controls the internal clocks, allowing the CS8416 to be placed in a “powered down”, low current consumption state.
Default = ‘0’
0 - Internal clocks are stopped. Internal state machines are reset. The fully static control port is
operational, allowing registers to be read or changed. Power consumption is low.
1 - Normal part operation. This bit must be written to the 1 state to allow the CS8416 to begin operation. All
input clocks should be stable in frequency and phase when RUN is set to 1.
RXD – RMCK Control
Default = ‘0’
0 -RMCK is an output, Clock is derived from input frame rate.
1 – RMCK becomes high impedance. The output of OSCLK, OLRCK, and SDOUT are indeterminate.
RX_SEL[2:0] – Selects RXP0 to RXP7 for input to the receiver
Default =’000’
000 – RXP0
001 – RXP1, etc
DS578F3
39
CS8416
TX_SEL[2:0] – Selects RXP0 to RXP7 as the input for GPO TX source
Default =’001’
000 – RXP0
001 – RXP1, etc
14.7
Serial Audio Data Format (05h)
7
SOMS
6
SOSF
5
SORES1
4
SORES0
3
SOJUST
2
SODEL
1
SOSPOL
0
SOLRPOL
SOMS - Master/Slave Mode Selector
Default = ‘0’
0 - Serial audio output port is in slave mode. OSCLK and OLRCK are inputs.
1 - Serial audio output port is in master mode. OSCLK and OLRCK are outputs.
SOSF - OSCLK frequency (for master mode)
Default = ‘0’
0 - OSCLK output frequency is 64*Fs.
1 - OSCLK output frequency is 128*Fs.
SORES[1:0] - Resolution of the output data on SDOUT
Default = ‘00’
00 - 24-bit resolution.
01 - 20-bit resolution.
10 - 16-bit resolution.
11 - Direct copy of the received NRZ data from the AES3 receiver including C, U, and V bits. The time slot
occupied by the Z bit is used to indicate the location of the block start. This setting forces the SOJUST bit
to be “0”. When using this setting, the de-emphasis filter must be off.
SOJUST - Justification of SDOUT data relative to OLRCK
Default = ‘0’
0 - Left-Justified.
1 - Right-Justified (master mode only and SORES ≠11).
SODEL - Delay of SDOUT data relative to OLRCK, for Left-Justified data formats
(This control is only valid in Left-Justified Mode)
Default = ‘0’
0 - MSB of SDOUT data occurs in the first OSCLK period after the OLRCK edge.
1 - MSB of SDOUT data occurs in the second OSCLK period after the OLRCK edge.
SOSPOL - OSCLK clock polarity
Default = ‘0’
0 - SDOUT is sampled on rising edges of OSCLK.
1 - SDOUT is sampled on falling edges of OSCLK.
40
DS578F3
CS8416
SOLRPOL - OLRCK clock polarity
Default = ‘0’
0 - SDOUT data is valid for the left channel when OLRCK is high.
1 - SDOUT data is valid for the right channel when OLRCK is high.
14.8
Receiver Error Mask (06h)
7
0
6
QCRCM
5
CCRCM
4
UNLOCKM
3
VM
2
CONFM
1
BIPM
0
PARM
The bits in this register serve as masks for the corresponding bits of the Receiver Error Register. If a mask
bit is set to 1, the error is unmasked, meaning that its occurrence will appear in the receiver error register,
will affect RERR, will affect the RERR interrupt, and will affect the current audio sample according to the
status of the HOLD bit. If a mask bit is set to 0, the error is masked, meaning that its occurrence will not
appear in the receiver error register, will not affect the RERR pin, will not affect the RERR interrupt, and will
not affect the current audio sample. The CCRC and QCRC bits behave differently from the other bits: they
do not affect the current audio sample even when unmasked. This register defaults to 00h.
14.9
Interrupt Mask (07h)
7
0
6
PCCHM
5
OSLIPM
4
DETCM
3
CCHM
2
RERRM
1
QCHM
0
FCHM
The bits of this register serve as a mask for the Interrupt Status register. If a mask bit is set to 1, the error
is unmasked, meaning that its occurrence will affect the INT pin and the status register. If a mask bit is set
to 0, the error is masked, meaning that its occurrence will not affect the internal INT signal or the status register. The bit positions align with the corresponding bits in Interrupt Status register. This register defaults to
00h.
The INT signal may be selected to output on the GPO pins. See “General Purpose Outputs” on page 29.
14.10 Interrupt Mode MSB (08h) and Interrupt Mode LSB(09h)
7
0
0
6
PCCH1
PCCH0
5
OSLIP1
OSLIP0
4
DETC1
DETC0
3
CCH1
CCH0
2
RERR1
RERR0
1
QCH1
QCH0
0
FCH1
FCH0
The two Interrupt Mode registers form a 2-bit code for each Interrupt Status register function. There are
three ways to set the INT pin active in accordance with the interrupt condition. In the Rising edge active
mode, the INT pin becomes active on the arrival of the interrupt condition. In the Falling edge active mode,
the INT pin becomes active on the removal of the interrupt condition. In Level active mode, the INT interrupt
pin becomes active during the interrupt condition. Be aware that the active level (Active High or Low) only
depends on the INT[1:0] bits. These registers default to 00h.
00 - Rising edge active
01 - Falling edge active
10 - Level active
11 - Reserved
DS578F3
41
CS8416
14.11 Receiver Channel Status (0Ah)
7
AUX3
6
AUX2
5
AUX1
4
AUX0
3
PRO
2
COPY
1
ORIG
0
EMPH
The bits in this register can be associated with either channel A or B of the received data. The desired channel is selected with the CHS bit of the Control1 register.
AUX3:0 - Incoming auxiliary data field width, as indicated by the incoming channel status bits, decoded according to IEC60958 and AES3.
0000 - Auxiliary data is not present.
0001 - Auxiliary data is 1 bit long.
0010 - Auxiliary data is 2 bits long.
0011 - Auxiliary data is 3 bits long.
0100 - Auxiliary data is 4 bits long.
0101 - Auxiliary data is 5 bits long.
0110 - Auxiliary data is 6 bits long.
0111 - Auxiliary data is 7 bits long.
1000 - Auxiliary data is 8 bits long.
1001 - 1111 Reserved
PRO - Channel status block format indicator
0 - Received channel status block is in the consumer format.
1 - Received channel status block is in the professional format.
COPY - SCMS copyright indicator
0 - Copyright asserted.
1 - Copyright not asserted. If the category code is set to General in the incoming AES3 stream, copyright
will always be indicated by COPY, even when the stream indicates no copyright.
ORIG - SCMS generation indicator, decoded from the category code and the L bit.
0 - Received data is 1st generation or higher.
1 - Received data is original.
Note:
COPY and ORIG will both be set to 1 if incoming data is flagged as professional or if the receiver
is not in use.
EMPH – Indicates whether the input audio data has been pre-emphasized. Also indicates turning on of the
de-emphasis filter during de-emphasis auto-select mode.
0 – 50 μs/15 μs pre-emphasis indicated.
1 – 50 μs/15 μs pre-emphasis not indicated.
14.12 Format Detect Status (0Bh)
7
0
6
PCM
Note:
5
IEC61937
4
DTS_LD
3
DTS_CD
2
Reserved
1
DGTL_SIL
0
96KHZ
PCM, DTS_LD, DTS_CD and IEC61937 are mutually exclusive. A ‘1’ indicated the condition
was detected.
PCM – Uncompressed PCM data was detected.
IEC61937 – IEC61937 data was detected.
DTS_LD – DTS_LD data was detected.
42
DS578F3
CS8416
DTS_CD – DTS_CD data was detected.
Reserved – This bit may change state depending on the input audio data.
DGTL_SIL – Digital Silence was detected: at least 2047 consecutive constant samples of the same 24-bit
audio data on both channels.
96KHZ – If the input sample rate is ≤ 48 kHz, outputs a “0”. Outputs a “1” if the sample rate is ≥ 88.1 kHz.
Otherwise the output is indeterminate.
14.13 Receiver Error (0Ch)
7
0
6
QCRC
5
CCRC
4
UNLOCK
3
V
2
CONF
1
BIP
0
PAR
This register contains the AES3 receiver and PLL status bits. Unmasked bits will go high on occurrence of
the error, and will stay high until the register is read. Reading the register resets all bits to 0, unless the error
source is still true. Bits that are masked off in the receiver error mask register will always be 0 in this register.
QCRC - Q-subcode data CRC error indicator. Updated on Q-subcode block boundaries
0 - No error.
1 - Error.
CCRC - Channel Status Block Cyclic Redundancy Check bit. Updated on CS block boundaries, valid in Pro
mode
0 - No error.
1 - Error.
UNLOCK - PLL lock status bit. Updated on CS block boundaries.
0 - PLL locked.
1 - PLL out of lock.
V - Received AES3 Validity bit status. Updated on sub-frame boundaries.
0 - Data is valid and is normally linear coded PCM audio.
1 - Data is invalid, or may be valid compressed audio.
CONF - Confidence bit. Updated on sub-frame boundaries.
0 - No error.
1 - Confidence error. The logical OR of UNLOCK and BIP. The input data stream may be near error condition due to jitter degradation.
BIP - Bi-phase error bit. Updated on sub-frame boundaries.
0 - No error.
1 - Bi-phase error. This indicates an error in the received bi-phase coding.
PAR - Parity bit. Updated on sub-frame boundaries.
0 - No error.
1 - Parity error.
DS578F3
43
CS8416
14.14 Interrupt 1 Status (0Dh)
7
0
6
PCCH
5
OSLIP
4
DETC
3
CCH
2
RERR
1
QCH
0
FCH
For all bits in this register, a “1” means the associated interrupt condition has occurred at least once since
the register was last read. A “0” means the associated interrupt condition has NOT occurred since the last
reading of the register. Reading the register resets all bits to 0, unless the interrupt mode is set to level and
the interrupt source is still true. Status bits that are masked off in the associated mask register will always
be “0” in this register.
PCCH – PC burst preamble change.
Indicates that the PC byte has changed from its previous value. If the IEC61937 bit in the Format Detect
Status register goes high, it will cause a PCCH interrupt even if the PC byte hasn’t changed since the last
time the IEC61937 bit went high.
OSLIP - Serial audio output port data slip interrupt
When the serial audio output port is in slave mode, and OLRCK is asynchronous to the port data source,
this bit will go high every time a data sample is dropped or repeated. See “Slip/Repeat Behavior” on
page 25 for more information.
DETC - D to E C-buffer transfer interrupt.
Indicates the completion of a D to E C-buffer transfer. See “Channel Status Buffer Management” on
page 51.
C_CHANGE -Indicates that the current 10 bytes of channel status is different from the previous 10 bytes.
(5 bytes per channel)
RERR - A receiver error has occurred.
The Receiver Error register may be read to determine the nature of the error which caused the interrupt.
QCH – A new block of Q-subcode is available for reading. The data must be read within 588 AES3 frames
after the interrupt occurs to avoid corruption of the data by the next block.
FCH – Format Change: Goes high when the PCM, IEC61937, DTS_LD, DTS_CD, or DGTL_SIL bits in the
Format Detect Status register transition from 0 to 1. When these bits in the Format Detect Status register
transition from 1 to 0, an interrupt will not be generated.
14.15 Q-Channel Subcode (0Eh - 17h)
7
6
5
4
3
2
1
0
CONTROL
CONTROL
CONTROL
CONTROL
ADDRESS
ADDRESS
ADDRESS
ADDRESS
TRACK
TRACK
TRACK
TRACK
TRACK
TRACK
TRACK
TRACK
INDEX
INDEX
INDEX
INDEX
INDEX
INDEX
INDEX
INDEX
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
MINUTE
SECOND
SECOND
SECOND
SECOND
SECOND
SECOND
SECOND
SECOND
FRAME
FRAME
FRAME
FRAME
FRAME
FRAME
FRAME
FRAME
ZERO
ZERO
ZERO
ZERO
ZERO
ZERO
ZERO
ZERO
ABS MINUTE ABS MINUTE ABS MINUTE ABS MINUTE ABS MINUTE ABS MINUTE ABS MINUTE ABS MINUTE
ABS SECOND ABS SECOND ABS SECOND ABS SECOND ABS SECOND ABS SECOND ABS SECOND ABS SECOND
ABS FRAME ABS FRAME ABS FRAME ABS FRAME ABS FRAME ABS FRAME ABS FRAME ABS FRAME
Each byte is LSB first with respect to the 80 Q-subcode bits Q[79:0]. Thus, bit 7 of address 0Eh is Q[0] while
bit 0 of address 0Eh is Q[7]. Similarly, bit 0 of address 17h corresponds to Q[79].
44
DS578F3
CS8416
14.16 OMCK/RMCK Ratio (18h)
7
ORR7
6
ORR6
5
ORR5
4
ORR4
3
ORR3
2
ORR2
1
ORR1
0
ORR0
This register allows the calculation of the incoming sample rate by the host microcontroller from the equation
ORR=Fso/Fsi. The Fso is determined by OMCK, whose frequency is assumed to be 256*Fso. ORR is represented as an unsigned 2-bit integer and a 6-bit fractional part. The value is meaningful only after the PLL
has reached lock. For example, if the OMCK is 12.288 MHz, Fso would be 48 kHz (48 kHz =
12.288 MHz/256). Then, if the input sample rate is also 48 kHz, you would get 1.0 from the ORR register
(The value from the ORR register is hexadecimal, so the actual value you will get is 40h).
If FSO/FSI > 3 63/64, ORR will saturate at the value FFh. Also, there is no hysteresis on ORR. Therefore a
small amount of jitter on either clock can cause the LSB ORR[0] to oscillate.
ORR[7:6] - Integer part of the ratio (Integer value=Integer(SRR[7:6])).
ORR[5:0] - Fractional part of the ratio (Fraction value=Integer(SRR[5:0])/64).
14.17 Channel Status Registers (19h - 22h)
19h
Channel A Status Byte 0
AC0[7]
AC0[6]
AC0[5]
AC0[4]
AC0[3]
AC0[2]
AC0[1]
AC0[0]
1Ah
Channel A Status Byte 1
AC1[7]
AC1[6]
AC1[5]
AC1[4]
AC1[3]
AC1[2]
AC1[1]
AC1[0]
1Bh
Channel A Status Byte 2
AC2[7]
AC2[6]
AC2[5]
AC2[4]
AC2[3]
AC2[2]
AC2[1]
AC2[0]
1Ch
Channel A Status Byte 3
AC3[7]
AC3[6]
AC3[5]
AC3[4]
AC3[3]
AC3[2]
AC3[1]
AC3[0]
1Dh
Channel A Status Byte 4
AC4[7]
AC4[6]
AC4[5]
AC4[4]
AC4[3]
AC4[2]
AC4[1]
AC4[0]
1Eh
Channel B Status Byte 0
BC0[7]
BC0[6]
BC0[5]
BC0[4]
BC0[3]
BC0[2]
BC0[1]
BC0[0]
1Fh
Channel B Status Byte 1
BC1[7]
BC1[6]
BC1[5]
BC1[4]
BC1[3]
BC1[2]
BC1[1]
BC1[0]
20h
Channel B Status Byte 2
BC2[7]
BC2[6]
BC2[5]
BC2[4]
BC2[3]
BC2[2]
BC2[1]
BC2[0]
21h
Channel B Status Byte 3
BC3[7]
BC3[6]
BC3[5]
BC3[4]
BC3[3]
BC3[2]
BC3[1]
BC3[0]
22h
Channel B Status Byte 4
BC4[7]
BC4[6]
BC4[5]
BC4[4]
BC4[3]
BC4[2]
BC4[1]
BC4[0]
14.18 IEC61937 PC/PD Burst Preamble (23h - 26h)
23h
Burst Preamble PC Byte 0
PC0[7]
PC0[6]
PC0[5]
PC0[4]
PC0[3]
PC0[2]
PC0[1]
PC0[0]
24h
Burst Preamble PC Byte 1
PC1[7]
PC1[6]
PC1[5]
PC0[4]
PC1[3]
PC1[2]
PC1[1]
PC1[0]
25h
Burst Preamble PD Byte 0
PD0[7]
PD0[6]
PD0[5]
PC0[4]
PD0[3]
PD0[2]
PD0[1]
PD0[0]
26h
Burst Preamble PD Byte 1
PD1[7]
PD1[6]
PD1[5]
PD1[4]
PD1[3]
PD1[2]
PD1[1]
PD1[0]
14.19 CS8416 I.D. and Version Register (7Fh)
7
ID3
6
ID2
5
ID1
4
ID0
3
VER3
2
VER2
1
VER1
0
VER0
ID[3:0] - ID code for the CS8416. Permanently set to 0010
VER[3:0] = 0001 (revision A)
VER[3:0] = 0010 (revision B)
VER[3:0] = 0011 (revision C)
VER[3:0] = 0111 (revision D)
VER[3:0] = 1111 (revision E)
DS578F3
45
CS8416
15.HARDWARE MODE
The CS8416 has a Hardware Mode that allows the device to operate without a microcontroller. Hardware Mode is
selected by connecting the 47 kΩ pull-up/down resistor on the SDOUT pin to ground. Various pins change function
in Hardware Mode, described in Section 15.2 “Hardware Mode Function Selection” on page 46.
Hardware Mode data flow is shown in Figure 15. Audio data is input through the AES3/SPDIF receiver, and routed
to the serial audio output port. The decoded C and U bits are also output, clocked at both edges of OLRCK (master
mode only, see Figure 10).
An error in the incoming audio stream will be indicated on the NV/RERR pin. This pin can be configured in one of
two ways. If RERR is chosen by pulling NV/RERR to VL, the previous audio sample is held and passed to the serial
audio output port if the validity bit is high, or a parity, bi-phase, confidence or PLL lock error occurs during the current
sample. If NVERR is chosen by pulling NV/RERR to DGND, only parity, bi-phase, confidence or PLL lock error
cause the previous audio sample to be held.
15.1
Serial Audio Port Formats
In Hardware Mode, only a limited number of alternative serial audio port formats are available. Table 5 defines the equivalent Software Mode bit settings for each format.
The start-up options, shown in Table 4, allow choice of the serial audio output port as a master or slave, and
the serial audio port format.
RXSEL[1:0] TXSEL[1:0]
TX
RXP0
RXP1
RXP2
RXP3
RXN
OMCK
4:2
MUX
TX Passthrough
AES3 Rx
&
Decoder
Serial
Audio
Output
De-emphasis
Filter
OLRCK
OSCLK
SDOUT
C
U
RMCK NV/RERR 96kHz
AUDIO
RCBL
Power supply pins (VA, VD, and VL), AGND, DGND, the reset pin (RST) and the PLL filter pin (FILT)
are omitted from the diagram. Please refer to the Typical Connection Diagram for connection details.
Figure 15. Hardware Mode Data Flow
15.2
Hardware Mode Function Selection
Hardware Mode and several options for Hardware Mode are selected by pulling CS8416 pins up to VL or
down to DGND through a 47 kΩ resistor. These settings are sensed immediately after RST is released. For
46
DS578F3
CS8416
each mode, every start-up option select pin (except for TX, which has an internal pull-down) MUST have an
external pull-up or pull-down resistor as there are no internal pull-up or pull-down resistors for these startup
conditions (set after reset).
Pin Name
SDOUT
RCBL
AUDIO
C
U
Pull Down to DGND Function
Hardware Mode
Serial Port Slave Mode
Serial Format Select 1 (SFSEL1)=0
Serial Format Select 0 (SFSEL0)=0
RMCK Frequency=256*Fs
Pull Up to VL Function
Software Mode
Serial Port Master Mode
Serial Format Select 1 (SFSEL1)=1
Serial Format Select 0 (SFSEL0)=1
RMCK Frequency=128*Fs
TX
96KHZ
NV/RERR
Normal Phase Detector update rate.
Emphasis Audio Match Off
NVERR Selected
Higher Phase Detector update rate.
Emphasis Audio Match On
RERR Selected
Table 4. Hardware Mode Start-Up Pin Conditions
15.3
Hardware Mode Equivalent Register Settings
Listed below are the equivalent values that the registers are set to in Hardware Mode.
Control0 Register (00h)
FSWCLK = 0
PDUR = Set by TX pin pull-up/down after reset.
TRUNC = 0
Control1 Register (01h)
SWCLK = Set to 1 if there a transition on OMCK after reset. Otherwise set to 0.
MUTSAO = 0
INT[1:0] = N/A.
HOLD[1:0] = 00
RMCKF = Set by U pin pull-up/down after reset.
CHS = 0
Control2 Register (02h)
DETCI = N/A
EMPH_CNTL[2] = set by 96KHZ pull-up/down after reset. See Figure 14 for the de-emphasis filter response.
EMPH_CNTL[1:0] = 00
GPO0SEL[3:0] = N/A
Control3 Register (03h)
GPO1SEL[3:0] = N/A
GPO2SEL[3:0] = N/A
DS578F3
47
CS8416
Control4 Register (04h)
RUN = 1
RXD = 0
RX_SEL[2] = 0
RX_SEL[1:0] = RX_SEL[1:0] pins.
TX_SEL[2] = 0
TX_SEL[1:0] = TX_SEL[1:0] pins.
Serial Audio Data Format Register (05h)
SOMS = set by RCBL pull-up/down after reset.
bits[6:0] = Set by pull-up/down on AUDIO & C after reset. See Table 5 for bit settings.
Serial Format Select [1:0]
00 (Left-Justified 24-bit)
01(I²S 24 bit)
10 (Right-Justified 24-bit)
11 (Direct AES3)
SOSF
SORES[1:0]
SOJUST
SODEL
0
0
0
0
00
00
00
11
0
0
1
0
0
1
0
0
SOSPOL SOLRPOL
0
0
0
0
0
1
0
0
Table 5. Hardware Mode Serial Audio Format Select
Receiver Error Mask register (06h)
QCRCM = 0
CRCM = 0
UNLOCKM = 1
CONFM = 1
BIPM = 1
PARM = 1
VM = set by NV/RERR pull-up/down after reset.
Registers 07h through 7Fh do not have Hardware Mode equivalent settings.
48
DS578F3
CS8416
16.EXTERNAL AES3/SPDIF/IEC60958 RECEIVER COMPONENTS
16.1
AES3 Receiver External Components
The CS8416 AES3 receiver is designed to accept both the professional and consumer interfaces. The digital audio specifications for professional use call for a balanced receiver, using XLR connectors, with
110 Ω ± 20% impedance. The XLR connector on the receiver should have female pins with a male shell.
Since the receiver has a very high input impedance, a 110 Ω resistor should be placed across the receiver
terminals to match the line impedance, as shown in Figures 16 and 17. Although transformers are not required by the AES specification, they are strongly recommended.
If some isolation is desired without the use of transformers, a 0.01 μF capacitor should be placed in series
with each input pin (RXP[7:0] and RXN) as shown in Figure 17. However, if a transformer is not used, high
frequency energy could be coupled into the receiver, causing degradation in analog performance.
Figures 16 and 17 show an optional (recommended) DC blocking capacitor (0.1 μF to 0.47 μF) in series with
the cable input. This improves the robustness of the receiver, preventing the saturation of the transformer,
or any DC current flow, if a DC voltage is present on the cable.
In the case of the consumer interface, the standards call for an unbalanced circuit having a receiver impedance of 75 Ω ±5%. The connector for the consumer interface is an RCA phono socket. The receiver circuit
for the consumer interface is shown in Figure 18. An implementation of the Input S/PDIF Multiplexer using
the consumer interface is shown in Figure 19.
The circuit shown in Figure 20 may be used when external RS422 receivers, optical receivers or other
TTL/CMOS logic outputs drive the CS8416 receiver section.
In the configuration of systems, it is important to avoid ground loops and DC current flowing down the shield
of the cable that could result when boxes with different ground potentials are connected. Generally, it is
good practice to ground the shield to the chassis of the transmitting unit, and connect the shield through a
capacitor to chassis ground at the receiver. However, in some cases it is advantageous to have the ground
of two boxes held to the same potential, and the cable shield might be depended upon to make that electrical
connection. Generally, it is a good idea to provide the option of grounding or capacitively coupling the shield
to the chassis.
16.2
Isolating Transformer Requirements
Please refer to the application note AN134: AES and SPDIF Recommended Transformers for resources on
transformer selection.
XLR
RXP0
110 Ω
110 Ω
Twisted
Pair
CS8416
* See Text
1
RXN
Figure 16. Professional Input Circuit
DS578F3
XLR
* See Text
0.01 μF
RXP0
110 Ω
110 Ω
Twisted
Pair
CS8416
1
0.01 μF
RXN
Figure 17. Transformerless Professional Input Circuit
49
CS8416
.0 1 μ F
RCA Phono
75 Ω
Coax
0.01 μF
75 Ω
Coax
75 Ω
75 Ω
C oax
75 Ω
75 Ω
C oax
75 Ω
.0 1 μ F
CS8416
RXP0
75 Ω
RXN
RXP6
.0 1 μ F
0.01 μF
..
.
RXP0
RXN
.0 1 μ F
Figure 18. Consumer Input Circuit
TTL/CMOS
Gate
C S8416
RXP7
Figure 19. S/PDIF MUX Input Circuit
0.01 μF
CS8416
RXP0
0.01 μF
RXN
Figure 20. TTL/CMOS Input Circuit
50
DS578F3
CS8416
17.CHANNEL STATUS BUFFER MANAGEMENT
17.1
AES3 Channel Status (C) Bit Management
The CS8416 contains sufficient RAM to store the first 5 bytes of C data for both A and B channels
(5 x 2 x 8 = 80 bits). The user may read from this buffer’s RAM through the control port.
The buffering scheme involves two buffers, named D and E, as shown in Figure 21. The MSB of each byte
represents the first bit in the serial C data stream. For example, the MSB of byte 0 (which is at control port
address 19h) is the consumer/professional bit for channel status block A.
The first buffer (D) accepts incoming C data from the AES receiver. The 2nd buffer (E) accepts entire blocks
of data from the D buffer. The E buffer is also accessible from the control port, allowing reading of the first
five bytes of C data.
The complete C data may be obtained through the C pin in Hardware Mode and through one of the GPO
pins in Software Mode. The C data is serially shifted out of the CS8416 clocked by the rising and falling
edges of OLRCK.
17.2
Accessing the E Buffer
The user can monitor the incoming data by reading the E buffer, which is mapped into the register space of
the CS8416, through the control port.
The user can configure the interrupt enable register to cause interrupts to occur whenever D to E buffer
transfers occur. This allows determination of the allowable time periods to interact with the E buffer.
Also provided is a D to E inhibit bit in the Control2 register (02h). This may be used whenever “long” control
port interactions are occurring or for debugging purposes.
A flowchart for reading the E buffer is shown in Figure 22. Since a D to E interrupt occurs just after reading,
there is a substantial time interval until the next D to E transfer (approximately 192 frames worth of time).
This is usually enough time to access the E data without having to inhibit the next transfer.
17.2.1 Serial Copy Management System (SCMS)
In Software Mode, the CS8416 allows read access to all the channel status bits. For consumer mode
SCMS compliance, the host microcontroller needs to read and interpret the Category Code, Copy bit and
L bit appropriately.
In Hardware Mode, the SCMS protocol can be followed by either using the COPY and ORIG output pins,
or by using the C bit serial output pin. These options are documented in Section 15. “Hardware Mode” on
page 46.
DS578F3
51
CS8416
A
8-bits
From
AES3
Receiver
Received
Data
Buffer
B
8-bits
5 words
Control
Port
Registers
19 words
D
E
C Data Serial Output
Figure 21. Channel Status Data Buffer Structure
D to E interrupt occurs
Optionally set D to E inhibit
Read E data
If set, clear D to E inhibit
Return
Figure 22. Flowchart for Reading the E Buffer
52
DS578F3
CS8416
18.PLL FILTER
18.1
General
An on-chip Phase Locked Loop (PLL) is used to recover the clock from the incoming data stream. Figure 23
is a simplified diagram of the PLL. When the PLL is locked to an bi-phase encoded input stream, it is updated at each preamble in the bi-phase encoded stream. This occurs at twice the sampling frequency, FS.
There are some applications where low jitter in the recovered clock, presented on the RMCK pin, is important. For this reason, the PLL has been designed to have good jitter attenuation characteristics, as shown
in Figure 25. In addition, the PLL has been designed to only use the preambles (PDUR=0) of the bi-phase
encoded stream to provide lock update information to the PLL. This results in the PLL being immune to data
dependent jitter affects because the preambles do not vary with the data.
The PLL has the ability to lock onto a wide range of input sample rates with no external component changes.
If the sample rate of the input subsequently changes, for example in a varispeed application, the PLL will
only track up to ±12.5% from the nominal center sample rate. The nominal center sample rate is the sample
rate that the PLL first locks onto upon application of an bi-phase encoded data stream or after enabling the
CS8416 clocks by setting the RUN control bit. If the 12.5% sample rate limit is exceeded, the PLL will return
to its wide lock range mode and re-acquire a new nominal center sample rate.
INPUT
Phase
Comparator
and Charge Pump
VCO
RMCK
RFLT
CFLT
CRIP
÷N
Figure 23. PLL Block Diagram
18.2
External Filter Components
18.2.1 General
The PLL behavior is affected by the external filter component values. Figures 5 and 6 shows the recommended configuration of the two capacitors and one resistor that comprise the PLL filter. In Table 6, the
component values shown have a high corner frequency jitter attenuation curve, take a short time to lock,
and offer good output jitter performance. Lock times are worst case for an Fsi transition of 192 kHz.
It is important to treat the PLL FLT pin as a low-level analog input. It is suggested that the ground end of
the PLL filter be returned directly to the AGND pin independently of the ground plane.
DS578F3
53
CS8416
18.2.2 Capacitor Selection
The type of capacitors used for the PLL filter can have a significant effect on receiver performance. Large
or exotic film capacitors are not necessary as their leads and the required longer circuit board traces add
undesirable inductance to the circuit. Surface mount ceramic capacitors are a good choice because their
own inductance is low, and they can be mounted close to the FILT pin to minimize trace inductance. For
CRIP, a C0G or NPO dielectric is recommended, and for CFLT, an X7R dielectric is preferred. Avoid capacitors with large temperature co-coefficient, or capacitors with high dielectric constants, that are sensitive to shock and vibration. These include the Z5U and Y5V dielectrics.
18.2.3 Circuit Board Layout
CRIP
RFLT
1000
pF
FILT
VA
AGND
Board layout and capacitor choice affect each other and determine the performance of the PLL. Figure 24
contains a suggested layout for the PLL filter components and for bypassing the analog supply voltage.
The 0.1 µF bypass capacitor is in a 1206 form factor. RFLT, CFLT, CRIP, and the 1000 pF decoupling capacitor are in an 0805 form factor. The traces are on the top surface of the board with the IC so that there
is no via inductance. The traces themselves are short to minimize the inductance in the filter path. The
VA and AGND traces extend back to their origin and are shown only in truncated form in the drawing.
.1µF
CFLT
Figure 24. Recommended Layout Example
18.2.4 Component Value Selection
The external PLL component values are listed in Table 6.
Range (kHz)
RFLT
CFLT
CRIP
Settling Time
32 - 192
3 kΩ
22 nF
1 nF
4 ms
Table 6. External PLL Component Values
54
DS578F3
CS8416
18.2.5 Jitter Attenuation
Shown in Figure 25 is the jitter attenuation plot. The AES3 and IEC60958-4 specifications state a maximum of 2 dB jitter gain or peaking.
4
2
external J itter Attenuation (dB )
0
2
4
6
8
10
12
1
10
10
0
10
1
2
10
J itter F requency (Hz)
10
3
10
4
10
5
Figure 25. Jitter Attenuation Characteristics of PLL
DS578F3
55
CS8416
19.PACKAGE DIMENSIONS
28L SOIC (300 MIL BODY) PACKAGE DRAWING
E
H
1
b
c
∝
D
L
SEATING
PLANE
A
e
DIM
A
A1
b
C
D
E
e
H
L
∝
A1
MIN
0.093
0.004
0.013
0.009
0.697
0.291
0.040
0.394
0.016
0°
INCHES
NOM
0.098
0.008
0.017
0.011
0.705
0.295
0.050
0.407
0.026
4°
MAX
0.104
0.012
0.020
0.013
0.713
0.299
0.060
0.419
0.050
8°
MIN
2.35
0.10
0.33
0.23
17.70
7.40
1.02
10.00
0.40
0°
MILLIMETERS
NOM
2.50
0.20
0.42
0.28
17.90
7.50
1.27
10.34
0.65
4°
MAX
2.65
0.30
0.51
0.32
18.10
7.60
1.52
10.65
1.27
8°
JEDEC #: MS-013
Controlling Dimension is Millimeters
56
DS578F3
CS8416
28L TSSOP (4.4 mm BODY) PACKAGE DRAWING
N
D
E11
A2
E
e
b2
SIDE VIEW
A
∝
A1
END VIEW
L
SEATING
PLANE
1 2 3
TOP VIEW
DIM
A
A1
A2
b
D
E
E1
e
L
µ
MIN
-0.002
0.03150
0.00748
0.378 BSC
0.248
0.169
-0.020
0°
INCHES
NOM
-0.004
0.035
0.0096
0.382 BSC
0.2519
0.1732
0.026 BSC
0.024
4°
MAX
0.47
0.006
0.04
0.012
0.386 BSC
0.256
0.177
-0.029
8°
MIN
-0.05
0.80
0.19
9.60 BSC
6.30
4.30
-0.50
0°
MILLIMETERS
NOM
-0.10
0.90
0.245
9.70 BSC
6.40
4.40
0.65 BSC
0.60
4°
NOTE
MAX
1.20
0.15
1.00
0.30
9.80 BSC
6.50
4.50
-0.75
8°
2,3
1
1
JEDEC #: MO-153
Controlling Dimension is Millimeters.
Notes:
1. “D” and “E1” are reference datums and do not include mold flash or protrusions, but do include mold
mismatch and are measured at the parting line, mold flash or protrusions shall not exceed 0.20 mm per
side.
2. Dimension “b” does not include dambar protrusion/intrusion. Allowable dambar protrusion shall be
0.13 mm total in excess of “b” dimension at maximum material condition. Dambar intrusion shall not reduce dimension “b” by more than 0.07 mm at least material condition.
3. These dimensions apply to the flat section of the lead between 0.10 and 0.25 mm from lead tips.
TSSOP THERMAL CHARACTERISTICS
Parameter
Junction to Ambient Thermal Impedance
DS578F3
4 Layer Board
Symbol
Min
θJA
-
Typ
40
Max
Units
-
°C/Watt
57
CS8416
28-PIN QFN (5 × 5 MM BODY) PACKAGE DRAWING
b
D
Pin #1 Corner
e
Pin #1 Corner
E2
E
A1
D2
L
A
Top View
Side View
Bottom View
INCHES
DIM
A
A1
b
D
D2
E
E2
e
L
MIN
-0.0000
0.0071
0.1220
0.1220
0.0197
NOM
--0.0091
0.1969 BSC
0.1240
0.1969 BSC
0.1240
0.0197 BSC
0.0236
MILLIMETERS
MAX
0.0394
0.0020
0.0118
MIN
-0.00
0.18
0.1260
3.10
0.1260
3.10
0.0276
0.50
NOM
--0.23
5.00 BSC
3.15
5.00 BSC
3.15
0.50 BSC
0.60
NOTE
MAX
1.00
0.05
0.30
3.20
3.20
0.70
1
1
1,2
1
1
1
1
1
1
JEDEC #: MO-220
Controlling Dimension is Millimeters.
Notes:
1. Dimensioning and tolerance per ASME Y 14.5M-1995.
2. Dimensioning lead width applies to the plated terminal and is measured between 0.23mm and 0.28mm
from the terminal tip.
QFN THERMAL CHARACTERISTICS
Parameter
Junction to Ambient Thermal Impedance
58
2 Layer Board
4 Layer Board
Symbol
Min
Typ
Max
Units
θJA
-
130
37
-
°C/Watt
°C/Watt
DS578F3
CS8416
20.ORDERING INFORMATION
Product
Description
Pb-Free
Grade
Temp Range
Package
28-SOIC
Commercial
-10° to
+70° C
28-TSSOP
28-QFN
CS8416
192 kHz Digital Audio
Interface Receiver
YES
28-SOIC
Automotive
-40° to
+85° C
28-TSSOP
28-QFN
CDB8416
DS578F3
Evaluation Board for
CS8416
-
-
-
-
Container
Order#
Rail
Tape and
Reel
Rail
Tape and
Reel
Rail
Tape and
Reel
Rail
Tape and
Reel
Rail
Tape and
Reel
Rail
Tape and
Reel
CS8416-CSZ
-
CS8416-CSZR
CS8416-CZZ
CS8416-CZZR
CS8416-CNZ
CS8416-CNZR
CS8416-DSZ
CS8416-DSZR
CS8416-DZZ
CS8416-DZZR
CS8416-DNZ
CS8416-DNZR
CDB8416
59
CS8416
21.REVISION HISTORY
Release
Changes
F1
-Reformatted “Features” on page 1
-Added RMCK/OMCK maximum in“Switching Characteristics” on page 8.
-Corrected AES3 Direct format in “Serial Audio Output Example Formats” on page 24.
-Corrected Table 2 and page 28 text referencing VCO idle frequency.
-Added timing note to Figure 10 on page 32.
-Corrected “Control Port Description” on page 33 to reflect the Auto-Increment function of the MAP.
-Added thermal relief pad label to QFN package in “Pin Description - Software Mode” on page 12 and “Pin
Description - Hardware Mode” on page 16.
-Added “TSSOP Thermal Characteristics” on page 57 and “QFN Thermal Characteristics” on page 58.
F2
Clarified use of de-emphasis filter in AES3 direct-output format.
F3
Updated ordering information to include Automotive grade QFN option.
Contacting Cirrus Logic Support
For all product questions and inquiries, contact a Cirrus Logic Sales Representative.
To find the one nearest you, go to www.cirrus.com.
IMPORTANT NOTICE
Cirrus Logic, Inc. and its subsidiaries ("Cirrus") believe that the information contained in this document is accurate and reliable. However, the information is subject
to change without notice and is provided "AS IS" without warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant
information to verify, before placing orders, that information being relied on is current and complete. All products are sold subject to the terms and conditions of sale
supplied at the time of order acknowledgment, including those pertaining to warranty, indemnification, and limitation of liability. No responsibility is assumed by Cirrus
for the use of this information, including use of this information as the basis for manufacture or sale of any items, or for infringement of patents or other rights of third
parties. This document is the property of Cirrus and by furnishing this information, Cirrus grants no license, express or implied under any patents, mask work rights,
copyrights, trademarks, trade secrets or other intellectual property rights. Cirrus owns the copyrights associated with the information contained herein and gives consent for copies to be made of the information only for use within your organization with respect to Cirrus integrated circuits or other products of Cirrus. This consent
does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale.
CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE (“CRITICAL APPLICATIONS”). CIRRUS PRODUCTS ARE NOT DESIGNED, AUTHORIZED OR WARRANTED FOR USE
IN AIRCRAFT SYSTEMS, MILITARY APPLICATIONS, PRODUCTS SURGICALLY IMPLANTED INTO THE BODY, AUTOMOTIVE SAFETY OR SECURITY DEVICES, LIFE SUPPORT PRODUCTS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF CIRRUS PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE FULLY AT THE CUSTOMER’S RISK AND CIRRUS DISCLAIMS AND MAKES NO WARRANTY, EXPRESS, STATUTORY OR IMPLIED,
INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR PARTICULAR PURPOSE, WITH REGARD TO ANY CIRRUS PRODUCT
THAT IS USED IN SUCH A MANNER. IF THE CUSTOMER OR CUSTOMER’S CUSTOMER USES OR PERMITS THE USE OF CIRRUS PRODUCTS IN CRITICAL
APPLICATIONS, CUSTOMER AGREES, BY SUCH USE, TO FULLY INDEMNIFY CIRRUS, ITS OFFICERS, DIRECTORS, EMPLOYEES, DISTRIBUTORS AND
OTHER AGENTS FROM ANY AND ALL LIABILITY, INCLUDING ATTORNEYS’ FEES AND COSTS, THAT MAY RESULT FROM OR ARISE IN CONNECTION
WITH THESE USES.
Cirrus Logic, Cirrus, and the Cirrus Logic logo designs are trademarks of Cirrus Logic, Inc. All other brand and product names in this document may be trademarks
or service marks of their respective owners.
AC-3 is a registered trademark of Dolby Laboratories, Inc.
DTS is a registered trademark of the Digital Theater Systems, Inc.
I²C is a registered trademark of Philips Semiconductor.
SPI is a trademark of Motorola Inc.
60
DS578F3
Similar pages