CS8427 96 kHz Digital Audio Interface Transceiver Features General Description Complete EIAJ CP1201, IEC-60958, AES3, S/PDIF-compatible Transceiver +5.0 V Analog Supply (VA+) +3.3 V or +5.0 V Digital Interface (VL+) Flexible 3-wire Serial Digital I/O Ports Adjustable Sample Rate up to 96 kHz Low-jitter Clock Recovery Pin and Microcontroller Read/Write Access to Channel Status and User Data Microcontroller and Standalone Modes Differential Cable Driver and Receiver On-chip Channel Status and User Data Buffer Memories Permit Block Reads & Writes OMCK System Clock Mode Decodes Audio CD Q Sub-code The CS8427 is a stereo digital audio transceiver with AES3 and serial digital audio inputs, AES3 and serial digital audio outputs, and includes comprehensive control ability through a 4-wire microcontroller port. Channel status and user data are assembled in block-sized buffers, making read/modify/write cycles easy. A low-jitter clock recovery mechanism yields a very clean recovered clock from the incoming AES3 stream. 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. The CS8427 is available in 28-pin SOIC and TSSOP packages in Commercial (-10°C to +70°C) and Automotive (-40°C to +85°C) grades. The CDB8427 Customer Demonstration Board is also available for device evaluation and implementation suggestions. Please see “Ordering Information” on page 49 for complete details. I VA+ AGND FILT ILRCK ISCLK SDIN Serial Audio Input Serial Audio Output RXP Receiver RXN Misc. Control H/S www.cirrus.com VL+ DGND RERR RMCK RST Clock & Data Recovery AES3 S/PDIF Decoder C & U bit Data Buffer Control Port & Registers EMPH U TCBL SDA/ SCL/ AD1/ AD0/ INT CDOUT CCLK CDIN CS Copyright Cirrus Logic, Inc. 2010 (All Rights Reserved) AES3 S/PDIF Encoder OLRCK OSCLK SDOUT TXP Driver TXN Output Clock Generator OMCK MAY ‘10 DS477F5 1 CS8427 TABLE OF CONTENTS 1. CHARACTERISTICS AND SPECIFICATIONS ......................................................................... 5 SPECIFIED OPERATING CONDITIONS ................................................................................. 5 ABSOLUTE MAXIMUM RATINGS ........................................................................................... 5 DC ELECTRICAL CHARACTERISTICS................................................................................... 6 DIGITAL INPUT CHARACTERISTICS ..................................................................................... 6 DIGITAL INTERFACE SPECIFICATIONS................................................................................ 6 TRANSMITTER CHARACTERISTICS ..................................................................................... 6 SWITCHING CHARACTERISTICS .......................................................................................... 7 SWITCHING CHARACTERISTICS - SERIAL AUDIO PORTS................................................. 8 SWITCHING CHARACTERISTICS - CONTROL PORT - SPI MODE...................................... 9 SWITCHING CHARACTERISTICS - CONTROL PORT - I²C MODE..................................... 10 2. TYPICAL CONNECTION DIAGRAM ...................................................................................... 11 3. GENERAL DESCRIPTION ..................................................................................................... 12 3.1 Audio Input/Output Ports ................................................................................................. 12 3.2 Serial Control Port ............................................................................................................ 12 3.3 Channel Status and User bit Memory .............................................................................. 12 3.4 AES3 and S/PDIF Standards Documents ........................................................................ 13 4. DATA I/O FLOW AND CLOCKING OPTIONS ....................................................................... 13 5. THREE-WIRE SERIAL AUDIO PORTS ................................................................................. 15 6. AES3 RECEIVER .................................................................................................................... 16 6.1 OMCK System Clock Mode ............................................................................................. 16 6.2 PLL, Jitter Attenuation, and Varispeed ............................................................................ 16 6.3 Error Reporting and Hold Function .................................................................................. 16 6.4 Channel Status Data Handling ......................................................................................... 16 6.5 User Data Handling .......................................................................................................... 17 6.6 Non-Audio Auto Detection ............................................................................................... 17 7. AES3 TRANSMITTER ........................................................................................................... 18 7.1 Transmitted Frame and Channel Status Boundary Timing .............................................. 18 7.2 TXN and TXP Drivers ...................................................................................................... 18 8. MONO MODE OPERATION ................................................................................................... 19 8.1 Receiver Mono Mode ....................................................................................................... 19 8.2 Transmitter Mono Mode ................................................................................................... 19 9. CONTROL PORT DESCRIPTION AND TIMING .................................................................... 25 9.1 SPITM Mode .................................................................................................................... 25 9.2 I²C Mode .......................................................................................................................... 25 9.3 Interrupts .......................................................................................................................... 25 10. CONTROL PORT REGISTER SUMMARY ........................................................................... 27 10.1 Memory Address Pointer (MAP) ..................................................................................... 27 11. CONTROL PORT REGISTER BIT DEFINITIONS ................................................................ 28 11.1 Control 1 (01h) ................................................................................................................ 28 11.2 Control 2 (02h) ................................................................................................................ 28 11.3 Data Flow Control (03h).................................................................................................. 29 11.4 Clock Source Control (04h)............................................................................................. 30 11.5 Serial Audio Input Port Data Format (05h)...................................................................... 31 11.6 Serial Audio Output Port Data Format (06h)................................................................... 31 11.7 Interrupt 1 Status (07h) (Read Only)............................................................................... 32 11.8 Interrupt 2 Status (08h) (Read Only)............................................................................... 33 11.9 Interrupt 1 Mask (09h)..................................................................................................... 33 11.10 Interrupt 1 Mode MSB (0Ah) & Interrupt 1 Mode LSB (0Bh)......................................... 33 11.11 Interrupt 2 Mask (0Ch) .................................................................................................. 34 11.12 Interrupt 2 Mode MSB (0Dh) & Interrupt 2 Mode LSB (0Eh) ........................................ 34 11.13 Receiver Channel Status (0Fh) (Read Only) ................................................................ 34 2 DS477F5 CS8427 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. DS477F5 11.14 Receiver Error (10h) (Read Only)................................................................................. 35 11.15 Receiver Error Mask (11h) ........................................................................................... 36 11.16 Channel Status Data Buffer Control (12h).................................................................... 36 11.17 User Data Buffer Control (13h) ..................................................................................... 37 11.18 Q-Channel Subcode Bytes 0 to 9 (14h - 1Dh) (Read Only) ......................................... 37 11.19 OMCK/RMCK Ratio (1Eh) (Read Only)........................................................................ 38 11.20 C-bit or U-bit Data Buffer (20h - 37h) ........................................................................... 38 11.21 CS8427 I.D. and Version Register (7Fh) (Read Only) ................................................. 38 PIN DESCRIPTION - SOFTWARE MODE ........................................................................... 39 HARDWARE MODE DESCRIPTION ................................................................................... 42 13.1 Serial Audio Port Formats ............................................................................................. 42 PIN DESCRIPTION - HARDWARE MODE .......................................................................... 44 APPLICATIONS ................................................................................................................... 46 15.1 Reset, Power Down and Start-up .................................................................................. 46 15.2 ID Code and Revision Code .......................................................................................... 46 15.3 Power Supply, Grounding, and PCB layout ................................................................... 46 15.4 Synchronization of Multiple CS8427s ............................................................................ 46 PACKAGE DIMENSIONS .................................................................................................... 47 ORDERING INFORMATION ............................................................................................... 49 APPENDIX A: EXTERNAL AES3/SPDIF/IEC60958 TRANSMITTER AND RECEIVER COMPONENTS .................................................................................................................................. 50 18.1 AES3 Transmitter External Components ....................................................................... 50 18.2 Isolating Transformer Requirements ............................................................................. 50 18.3 AES3 Receiver External Components ........................................................................... 51 18.4 Isolating Transformer Requirements ............................................................................. 51 APPENDIX B: CHANNEL STATUS AND USER DATA BUFFER MANAGEMENT ........... 52 19.1 AES3 Channel Status(C) Bit Management .................................................................... 52 19.1.1 Manually accessing the E buffer ....................................................................... 52 19.1.2 Reserving the first 5 bytes in the E buffer ......................................................... 53 19.1.3 Serial Copy Management System (SCMS) ....................................................... 53 19.1.4 Channel Status Data E Buffer Access .............................................................. 53 19.2 AES3 User (U) Bit Management .................................................................................... 54 19.2.1 Mode 1: Transmit All Zeros ............................................................................... 54 19.2.2 Mode 2: Block Mode ......................................................................................... 54 APPENDIX C: PLL FILTER .................................................................................................. 55 20.1 General .......................................................................................................................... 55 20.2 External Filter Components ........................................................................................... 56 20.2.1 General ............................................................................................................. 56 20.2.2 Capacitor Selection ........................................................................................... 56 20.2.3 Circuit Board Layout ......................................................................................... 56 20.3 Component Value Selection .......................................................................................... 57 20.3.1 Identifying the Part Revision ............................................................................. 57 20.3.2 Locking to the RXP/RXN Receiver Inputs ......................................................... 57 20.3.3 Locking to the ILRCK Input ............................................................................... 58 20.3.4 Jitter Tolerance ................................................................................................. 58 20.3.5 Jitter Attenuation ............................................................................................... 59 REVISION HISTORY ............................................................................................................ 60 3 CS8427 LIST OF FIGURES Figure 1. Audio Port Master Mode Timing....................................................................................... 8 Figure 2. Audio Port Slave Mode and Data Input Timing ................................................................ 8 Figure 3. SPI Mode timing............................................................................................................... 9 Figure 4. I²C Mode timing.............................................................................................................. 10 Figure 5. Recommended Connection Diagram for Software Mode............................................... 11 Figure 6. CS8427 Internal Block Diagram..................................................................................... 13 Figure 7. Software Mode Audio Data Flow Switching Options...................................................... 19 Figure 8. CS8427 Clock Routing................................................................................................... 20 Figure 9. AES3 Input to Serial Audio Output, Serial Audio Input to AES3 Out ............................. 21 Figure 11. Input Serial Port to AES3 Transmitter without PLL ...................................................... 21 Figure 10. AES3 Input to Serial Audio Output Only ...................................................................... 21 Figure 12. Input Serial Port to AES3 Transmitter with PLL ........................................................... 21 Figure 13. AES3 Receiver Timing for U pin output data ............................................................... 22 Figure 14. AES3 Transmitter Timing for C, U and V pin input data............................................... 22 Figure 15. Serial Audio Input Example Formats............................................................................ 23 Figure 16. Serial Audio Output Example Formats......................................................................... 24 Figure 17. Control Port Timing in SPI Mode.................................................................................. 26 Figure 18. Control Port Timing in I²C Mode................................................................................... 26 Figure 19. Hardware Mode............................................................................................................ 42 Figure 20. Professional Output Circuit .......................................................................................... 50 Figure 21. Consumer Output Circuit.............................................................................................. 50 Figure 22. TTL/CMOS Output Circuit ............................................................................................ 50 Figure 23. Professional Input Circuit ............................................................................................. 51 Figure 24. Transformerless Professional Input Circuit .................................................................. 51 Figure 25. Consumer Input Circuit ................................................................................................ 51 Figure 26. TTL/CMOS Input Circuit............................................................................................... 51 Figure 27. Channel Status Data Buffer Structure.......................................................................... 52 Figure 28. Flowchart for Reading the E Buffer .............................................................................. 53 Figure 29. Flowchart for Writing the E Buffer ................................................................................ 53 Figure 30. PLL Block Diagram ...................................................................................................... 55 Figure 31. Recommended Layout Example .................................................................................. 56 Figure 32. Jitter Tolerance Template ............................................................................................ 58 Figure 33. Revision A .................................................................................................................... 59 Figure 34. Revision A1 .................................................................................................................. 59 Figure 35. Revision A2 using A1 values........................................................................................ 59 Figure 36. Revision A2 using A2* values ...................................................................................... 59 LIST OF TABLES Table 1. Control Register Map Summary ...................................................................................... 27 Table 2. Hardware Mode Start-up Options.................................................................................... 43 Table 3. Serial Audio Output Formats Available in Hardware Mode ............................................. 43 Table 4. Serial Audio Input Formats Available in Hardware Mode................................................ 43 Table 5. Second Line Part Marking ............................................................................................... 57 Table 6. Locking to RXP/RXN - Fs = 8 to 96 kHz ......................................................................... 57 Table 7. Locking to RXP/RXN - Fs = 32 to 96 kHz ....................................................................... 57 Table 8. Locking to the ILRCK Input ............................................................................................. 58 Table 9. Revision History .............................................................................................................. 60 4 DS477F5 CS8427 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 (Note 1) Ambient Operating Temperature: ‘-CS’, ‘CSZ’ & ‘-CZ’ ‘-DS’ & ‘-DZ’ Symbol Min Typ Max Units VA+ VL+ 4.5 2.85 5.0 3.3 or 5.0 5.5 5.5 V V TA -10 -40 - +70 +85 °C Notes: 1. I²C protocol is supported only in VL+ = 5.0 V mode. 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 (Note 2) Symbol Min Max Units VL+,VA+ - 6.0 V Iin - ±10 mA Input Voltage Vin -0.3 (VL+) + 0.3 V Ambient Operating Temperature (power applied) TA -55 125 °C Storage Temperature Tstg -65 150 °C Notes: 2. Transient currents of up to 100 mA will not cause SCR latch-up. DS477F5 5 CS8427 DC ELECTRICAL CHARACTERISTICS AGND = DGND = 0 V; all voltages with respect to 0 V. Parameters Symbol Min Typ Max Units VA+ VL+ = 3.3 V VL+ = 5.0 V - 20 60 60 - μA μA μA Supply Current at 48 kHz frame rate VA+ VL+ = 3.3 V VL+ = 5.0 V - 6.3 30.1 46.5 - mA mA mA Supply Current at 96 kHz frame rate VA+ VL+ = 3.3 V VL+ = 5.0 V - 6.6 44.8 76.6 - mA mA mA Power-down Mode (Note 3) Supply Current in power down Normal Operation (Note 4) Notes: 3. Power Down Mode is defined as RST = LO with all clocks and data lines held static. 4. Normal operation is defined as RST = HI. DIGITAL INPUT CHARACTERISTICS Parameters Input Leakage Current Differential Input Voltage, RXP0 to RXN Symbol Min Typ Max Units Iin - ±1 ±10 μA VTH - 200 - mV 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), except TXP/TXN VOH (VL+) - 1.0 - V Low-Level Output Voltage (IOH = 3.2 mA), except TXP/TXN VOL - 0.4 V High-Level Output Voltage, TXP, TXN (23 mA at VL+ = 5.0 V) (15.2 mA at VL+ = 3.3 V) (VL+) - 0.7 (VL+) - 0.7 - V V Low-Level Output Voltage, TXP, TXN (23 mA at VL+ = 5.0 V) (15.2 mA at VL+ = 3.3 V) - 0.7 0.7 V V VIH 2.0 (VL+) + 0.3 V VIL -0.3 0.4/0.8 V High-Level Input Voltage, except RXP, RXN Low-Level Input Voltage, except RXP, RXN Notes: 5. (Note 5) At 5.0 V mode, VIL = 0.8 V (Max), at 3.3 V mode, VIL =0.4 V (Max). TRANSMITTER CHARACTERISTICS Symbol Min Typ Max Units TXP Output Resistance Parameters VL+ = 5.0 V VL+ = 3.3 V RTXP - 26 40 - Ω Ω TXN Output Resistance VL+ = 5.0 V VL+ = 3.3 V RTXN - 26 40 - Ω Ω 6 DS477F5 CS8427 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 OMCK Frequency for OMCK = 512 * Fso 4.1 - 55.3 MHz OMCK Low and High Width for OMCK = 512 * Fso 7.2 - - ns OMCK Frequency for OMCK = 384 * Fso 3.1 - 41.5 MHz OMCK Low and High Width for OMCK = 384 * Fso 10.8 - - ns OMCK Frequency for OMCK = 256 * Fso 2.0 - 27.7 MHz OMCK Low and High Width for OMCK = 256 * Fso 14.4 - - ns PLL Clock Recovery Sample Rate Range 8.0 - 108.0 kHz RMCK output jitter (Note 6) RMCK output duty cycle - 200 - ps RMS 40 50 60 % RMCK Input Frequency (Note 7) 1.8 - 27.7 MHz RMCK Input Low and High Width (Note 7) 14.4 - - ns - - 1 ns AES3 Transmitter Output Jitter Notes: 6. Cycle-to-cycle locking to RXP/RXN using 32 to 96 kHz external PLL filter components. 7. PLL is bypassed (RXD1:0 bits in the Clock Source Control register set to 10b), clock is input to the RMCK pin. DS477F5 7 CS8427 SWITCHING CHARACTERISTICS - SERIAL AUDIO PORTS Inputs: Logic 0 = 0 V, Logic 1 = VL+; CL = 20 pF. Parameter Symbol Min Typ Max Units OSCLK Active Edge to SDOUT Output Valid (Note 8) tdpd - - 20 ns SDIN Setup Time Before ISCLK Active Edge (Note 8) tds 20 - - ns SDIN Hold Time After ISCLK Active Edge (Note 8) tdh 20 - - ns (Note 8, 9) tsmd 0 - 10 ns (Note 10) tlmd 0 - 10 ns - 50 - % Master Mode O/RMCK to I/OSCLK active edge delay O/RMCK to I/OLRCK delay I/OSCLK and I/OLRCK Duty Cycle Slave Mode tsckw 36 - - ns I/OSCLK Input Low Width I/OSCLK Period (Note 11) tsckl 14 - - ns I/OSCLK Input High Width tsckh 14 - - ns tlrckd 20 - - ns tlrcks 20 - - ns I/OSCLK Active Edge to I/OLRCK Edge (Note 8, 10, 12) I/OLRCK Edge Setup Before I/OSCLK Active Edge (Note 8, 10, 13) Notes: 8. The active edges of ISCLK and OSCLK are programmable. 9. When OSCLK, OLRCK, ISCLK, and ILRCK are derived from OMCK they are clocked from its rising edge. When these signals are derived from RMCK, they are clocked from its falling edge. 10. The polarity of ILRCK and OLRCK is programmable. 11. No more than 128 SCLK per frame. 12. This delay is to prevent the previous I/OSCLK edge from being interpreted as the first one after I/OLRCK has changed. 13. This setup time ensures that this I/OSCLK edge is interpreted as the first one after I/OLRCK has changed. IS C L K O SCLK (o u tp u t) ILRCK OLRCK (input) IL R C K O LRCK (o u tp u t) t sm d t lrckd t lrcks t sckh tsckl ISCLK OSCLK t lm d (input) t sckw RMCK (o u tp u t) H a rd w a re M o d e SDIN RMCK (o u tp u t) tds S o ftw a re M o d e OMCK (in p u t) Figure 1. Audio Port Master Mode Timing 8 tdh tdpd SDOUT Figure 2. Audio Port Slave Mode and Data Input Timing DS477F5 CS8427 SWITCHING CHARACTERISTICS - CONTROL PORT - SPI MODE Inputs: Logic 0 = 0 V, Logic 1 = VL+; CL = 20 pF. Parameter Symbol CCLK Clock Frequency (Note 14) Min Typ Max Units fsck 0 - 6.0 MHz CS High Time Between Transmissions tcsh 1.0 - - μs CS Falling to CCLK Edge tcss 20 - - ns CCLK Low Time tscl 66 - - ns CCLK High Time tsch 66 - - ns CDIN to CCLK Rising Setup Time tdsu 40 - - ns tdh 15 - - ns CCLK Falling to CDOUT Stable tpd - - 50 ns Rise Time of CDOUT tr1 - - 25 ns Fall Time of CDOUT tf1 - - 25 ns CCLK Rising to DATA Hold Time (Note 15) Rise Time of CCLK and CDIN (Note 16) tr2 - - 100 ns Fall Time of CCLK and CDIN (Note 16) tf2 - - 100 ns Notes: 14. If Fso or Fsi is lower than 46.875 kHz, the maximum CCLK frequency should be less than 128 Fso and less than 128 Fsi. This is dictated by the timing requirements necessary to access the Channel Status and User Bit buffer memory. Access to the control register file can be carried out at the full 6 MHz rate. The minimum allowable input sample rate is 8 kHz, so choosing CCLK to be less than or equal to 1.024 MHz should be safe for all possible conditions. 15. Data must be held for sufficient time to bridge the transition time of CCLK. 16. 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 DS477F5 9 CS8427 SWITCHING CHARACTERISTICS - CONTROL PORT - I²C MODE Note 17, Inputs: Logic 0 = 0 V, Logic 1 = VL+; CL = 20 pF. Parameter Symbol Min Typ Max Units SCL Clock Frequency fscl - - 100 kHz Bus Free Time Between Transmissions tbuf 4.7 - - μs Start Condition Hold Time (prior to first clock pulse) thdst 4.0 - - μs Clock Low Time tlow 4.7 - - μs Clock High Time thigh 4.0 - - μs Setup Time for Repeated Start Condition tsust 4.7 - - μs thdd 0 - - μs tsud 250 - - ns Rise Time of Both SDA and SCL Lines tr - - 25 ns Fall Time of Both SDA and SCL Lines tf - - 25 ns tsusp 4.7 - - μs SDA Hold Time from SCL Falling (Note 18) SDA Setup Time to SCL Rising Setup Time for Stop Condition Notes: 17. I²C protocol is supported only in VL+ = 5.0 V mode. 18. Data must be held for sufficient time to bridge the 25 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 10 DS477F5 CS8427 2. TYPICAL CONNECTION DIAGRAM +5.0 V Analog Supply* Ferrite * Bead VA+ AES3/ SPDIF Source Cable Termination +3.3 V or +5.0 V Digital Supply 0.1μF 0.1μF VL+ RXP RXN TXP TXN Cable Interface AES3/ SPDIF Equipment CS8427 3-wire Serial Audio Source ILRCK ISCLK SDIN Clock Source and Control SDA/CDOUT AD0/CS SCL/CCLK AD1/CDIN INT EMPH/AD 2 U RERR RST TCBL H/S AGND FILT DGND Hardware Control To other CS8427's OLRCK OSCLK SDOUT 3-wire Serial Audio Input Device RMCK OMCK Microcontroller RFILT CFILT CRIP * 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 the decoupling capacitor between VA+ and AGND. Figure 5. Recommended Connection Diagram for Software Mode DS477F5 11 CS8427 3. GENERAL DESCRIPTION The CS8427 is an AES3 transceiver intended to be used in digital audio systems. Such systems include digital mixing consoles, effects processors, digital recorders, and computer multimedia systems. 3.1 Audio Input/Output Ports The CS8427 has the following Audio ports: • Serial Audio Input Port • Serial Audio Output Port • AES3 or S/PDIF Receiver • AES3 or S/PDIF Transmitter The Serial Audio ports use a three-wire format. This consists of a serial audio data stream, a leftright clock defining the boundaries of the audio sample frames, and a serial clock signal clocking the data bits. A Serial Audio port may operate in either Master or Slave mode. When a port is a Master, it supplies the left-right clock and the serial clock to the external device that is sending or receiving the serial data. A port in slave mode must have its left-right clock and its serial clock supplied by an external device so that it may send or receive serial audio data. The input sample rate is determined by the stream applied to the Serial Audio Input or to the AES3 Receiver. A phase-locked loop recovers RMCK, the input master clock signal, from the chosen input stream. The output from the device may be through the Serial Audio Output, the AES3 Transmitter, or from both simultaneously. In some configurations, all audio ports of the device may be in use at the same time. 3.2 Serial Control Port Besides the functional blocks already described, the device also has a control port that allows the user to read and write the control registers that configure the part. The control port is capable of operating in either SPI or I²C serial mode. This port also has access to buffer memory that allows the user to control what is transmitted in the Channel Status and User bits of the outgoing AES3 stream. 12 The control port is clocked by the serial clock signal that the user's microcontroller sends it. The MCU can read and write the registers even when the RMCK and OMCK clocks are not running. The Channel Status and User bit buffer memories depend on clocking from RMCK and OMCK. They will not function unless the clocks are running, and the RUN bit in the Clock Source Control register is set. There is also an interrupt signal associated with the Serial Control Port and the internal registers. The format of the interrupt may be chosen by a register setting. There are two interrupt status registers and their associated interrupt mask registers. 3.3 Channel Status and User bit Memory The memory architecture consists of three buffers to handle the Channel Status information, and another three buffers to handle the User bits. The data recovery logic extracts the Channel Status and User bits from the AES3 stream and places them in their respective D buffers. Each buffer contains 384 bits. This is enough memory to hold a complete block of Channel Status bits from both A and B channels and a complete block of User bits. When the D buffers are full, the chip transfers their contents into the E buffers. While in the E buffers the Channel Status and User bits may be read or written through the control port. This allows the user to alter them to suit the needs of the application. The control bit BSEL, in the Channel Status Data Buffer Control register, determines whether the control port has access to the Channel Status bits or the User bits. The AES3 encoder reads the Channel Status and User bits from the F buffers and inserts them into the outgoing AES3 stream. After the F buffers bits are transmitted, the device transfers the current contents of the E buffers into the F buffers. In applications using AES3 in and AES3 out, the CS8427 can automatically transceive user data that conforms to the IEC60958 format. The CS8427 also gives the user access to the bits necessary to comply with the serial copy management system (SCMS). In applications where the user want to read/modify/write the Channel Status information that requires a microcontroller to actively manage the DS477F5 CS8427 SPD1-0 ILRCK ISCLK SDIN Serial Audio Input Serial Audio Output OLRCK OSCLK SDOUT AESBP TXOFF RXN RXP AES3 Receiver TXP AES3 Encoder TXN TXD1-0 Channel Status and User Data Recovery SDA/CDOUT SCL/CCLK AD2/EMPH AD1/CDIN AD0/CS INT Channel Status Bits D E F User Bits D E F Control Port Control Registers Output Clock Generator OMCK Figure 6. CS8427 Internal Block Diagram Channel Status bits. The part also has a feature that allows the first five bytes of Channel Status memory to be configured and transmitted in each channel status block without change. See “Appendix A: External AES3/SPDIF/IEC60958 Transmitter and Receiver Components” on page 50 for a tutorial in Channel Status and User bit management. 3.4 AES3 and S/PDIF Standards Documents This data sheet assumes that the user is familiar with the AES3 and S/PDIF data formats. It is advisable to have current copies of the AES3 and IEC60958 specifications on hand for easy reference. The latest AES3 standard is available from the Audio Engineering Society or ANSI at www.aes.org or www.ansi.org. Obtain the latest IEC60958 standard from ANSI or from the International Electrotechnical Commission at www.iec.ch. The latest DS477F5 EIAJ CP-1201 standard is available from the Japanese Electronics Bureau. Crystal Application Note AN22: 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 preprint 3518. 4. DATA I/O FLOW AND CLOCKING OPTIONS The CS8427 can be configured for several connectivity alternatives, called data flows. Figure 7. “Software Mode Audio Data Flow Switching Options” on page 19 shows the data flow switching, along with the control register bits which control the switches; this drawing only shows the audio data paths for simplicity. This drawing only shows the audio data paths for simplicity. Figure 8 shows the internal 13 CS8427 clock routing and the associated control register bits. The clock routing constraints determine which data routing options are actually usable. Users should note that not all the possible data flow switch setting combinations are valid, because of the clock distribution architecture. The AESBP switch, shown in Figure 7, allows a TTL level bi-phase, mark-encoded data stream connected to RXP to be routed to the TXP and TXN pin drivers. The TXOFF switch causes the TXP and TXN outputs to be driven to ground. There are two possible clock sources. The first, designated the recovered clock, is the output of the PLL, and is output through the RMCK pin. The input to the PLL can be either the incoming AES3 data stream or the ILRCK word rate clock from the serial audio input port. The second clock is input through the OMCK pin and would normally be a crystal derived stable clock. The Clock Source Control Register bits determine which clock is used to operate the CS8427. The CS8427 has another constraint related to the state machine that governs the startup of the part. The startup state machine doesn’t complete its 14 process until the PLL has locked unless one is in the transmitter dataflow (See Figure 10). The consequence of this is that the transmitter will not transmit until the PLL has locked. If you wish to use the part in transceiver mode and this constraint is a problem, there is a work around. Start the part up in its default configuration and allow the PLL to lock to a signal on the ILRCK pin, then without stopping the part, reconfigure it to the transceiver mode. By studying the following drawings and appropriately setting the Data Flow Control and Clock Source Control register bits, the CS8427 can be configured to fit a variety of customer requirements. Please note that applications implementing both the Serial Audio Output Port and the AES3 Transmitter must operate at the same sample rate because they are both controlled by the same clock source. Figure 9 shows the entire data path clocked by the PLL generated recovered clock. Figure 10 illustrates a standard AES3 receiver function. Figure 11 shows a standard AES3 transmitter function without PLL. Figure 12 shows a standard AES3 transmitter function with PLL. DS477F5 CS8427 5. THREE-WIRE SERIAL AUDIO PORTS A 3-wire serial audio input port and a 3-wire serial audio output port is provided. Each 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 1-bit cell delay of the 1st 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 15 shows a selection of common input formats, along with the control bit settings. It should be noted that in right justified mode, the serial audio output data is “MSB extended”. This means that in a sub-frame where the MSB of the data is '1', all bits preceding the MSB in the sub-frame will also be '1'. Conversely, in a sub-frame where the MSB of the data is '0', all bits preceding the MSB in the sub-frame will also be '0'. The clocking of the input section of the CS8427 may be derived from the incoming ILRCK word rate clock, using the on-chip PLL. The PLL operation is described in “AES3 Receiver” on page 16. In the case of use with the serial audio input port, the PLL locks onto the leading edges of the ILRCK clock. DS477F5 Figure 16 shows a selection of common output formats, along with the control bit settings. A special AES3 direct output format is included, which allows serial output port access to the V, U, and C bits embedded in the serial audio data stream. The P bit is replaced by a Z bit that marks the subframe just prior to the start of each block. This format is only available when the serial audio output port is being clocked by the AES3 receiver recovered clock. In master mode, the left/right clock and the serial bit clock are outputs, derived from the appropriate clock domain master clock. In slave mode, the left/right clock and the serial bit clock are inputs. The left/right clock must be synchronous to the appropriate master clock, but the serial bit clock can function in asynchronous burst mode if desired. By appropriate phasing of the left/right clock and control of the serial clocks, CS8427’s can be multiplexed to share one serial port. The left/right clock should be continuous, but the duty cycle does not have to be 50%, provided that enough serial clocks are present in each phase to clock all the data bits. When in slave mode, the serial audio output port must not be set to right justified data. When using the serial audio output port in slave mode with an OLRCK input which is asynchronous to the port’s data source, an interrupt bit (OSLIP) is provided to indicate when repeated or dropped samples occur. 15 CS8427 6. AES3 RECEIVER 6.3 The CS8427 includes an AES3 digital audio receiver and an AES3 digital audio transmitter. A comprehensive buffering scheme provides read/write access to the channel status and user data. This buffering scheme is described in “Appendix B: Channel Status and User Data Buffer Management”. While decoding the incoming AES3 data stream, the CS8427 can identify several kinds of error, indicated in the Receiver Error register. The UNLOCK bit indicates whether the PLL is locked to the incoming AES3 data. The V bit reflects the current validity bit status. The BIP (bi-phase) error bit indicates an error in incoming bi-phase coding. The PAR (parity) bit indicates a received parity error. The AES3 receiver accepts and decodes audio and digital data according to the AES3, IEC60958 (S/PDIF), and EIAJ CP-1201 interface standards. The receiver consists of a differential input stage, accessed through pins RXP and 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 and isolate the incoming data cables from the CS8427. These components are detailed in “Appendix A: External AES3/SPDIF/IEC60958 Transmitter and Receiver Components” on page 50. 6.1 OMCK System Clock Mode A special mode is available that allows the clock that is being input through the OMCK pin to be output through the RMCK pin. This feature is controlled by the SWCLK bit in control register 1. When the PLL loses lock, the frequency of the VCO drops to 300 kHz. The SWCLK function allows the clock from RMCK to be used as a clock in the system without any disruption when input is removed from the Receiver. This clock switching is performed glitch free. None of the internal circuitry that is clocked from the PLL is driven by the OMCK being output from RMCK. This function is available only in software mode. 6.2 PLL, Jitter Attenuation, and Varispeed Please see Appendix C for general description of the PLL, selection of recommended PLL filter components, and layout considerations. Figure 5 shows the recommended configuration of the two capacitors and one resistor that comprise the PLL filter. 16 Error Reporting and Hold Function The error bits are “sticky”: 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. The Receiver Error Mask register allows masking of individual errors. 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, 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 HOLD bits allow a choice of holding the previous sample, replacing the current sample with zero (mute), or not changing the current audio sample. If a mask bit is set to 0, the error is masked, which implies the following: its occurrence will not be reported in the receiver error register, will not induce a pulse on RERR or generate a RERR interrupt, and will not affect the current audio sample. The QCRC and CCRC errors do not affect the current audio sample, even if unmasked 6.4 Channel Status Data Handling The first two bytes of the Channel Status block are decoded into the Receiver Channel Status register. The setting of the CHS bit in the Channel Status Data Buffer Control register determines whether the channel status decodes are from the A channel (CHS = 0) or B channel (CHS = 1). The PRO (professional) bit is extracted directly. For consumer data, the COPY (copyright) bit is extracted, and the category code and L bits are decoded to determine SCMS status, indicated by the ORIG (original) bit. If the category code is set to DS477F5 CS8427 General on the incoming AES3 stream, copyright will always be indicated even when the stream indicates no copyright. Finally, the AUDIO bit is extracted and used to set an AUDIO indicator, as described in the Non-Audio Auto-Detection section below. If the incoming user data bits have been encoded as Q-channel subcode, the data is decoded and presented in ten consecutive register locations. An interrupt may be enabled to indicate the decoding of a new Q-channel block, which may be read through the control port. If 50/15 µs pre-emphasis is detected, the state of the EMPH pin is adjusted accordingly. 6.6 The encoded channel status bits which indicate sample word length are decoded according to AES3-1992 or IEC 60958. Audio data routed to the serial audio output port is unaffected by the word length settings - all 24 bits are passed on as received. “Appendix B: Channel Status and User Data Buffer Management” on page 52 describes the overall handling of Channel Status and User bit data. 6.5 User Data Handling The incoming user data is buffered in a user accessible buffer. Various automatic modes of re-transmitting received User data are provided. The Appendix: Channel Status and User Data Buffer Management describes the overall handling of CS and U data. Received User data may also be output to the U pin, under the control of a control register bit. Depending on the data flow and clocking options selected, there may not be a clock available to qualify the U data output. Figure 13 illustrates the timing. DS477F5 Non-Audio Auto Detection An AES3 data stream may be used to convey nonaudio 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 (AUDIO), which is extracted automatically by the CS8427. However, certain non-audio sources, such as AC3 or MPEG encoders, may not adhere to this convention, and the bit may not be properly set. The CS8427 AES3 receiver can detect such non-audio data. This is accomplished by looking for a 96-bit sync code, consisting of 0x0000, 0x0000, 0x0000, 0x0000, 0xF872, and 0x4E1F. When the sync code is detected, an internal AUTODETECT signal will be asserted. If no additional sync codes are detected within the next 4096 frames, AUTODETECT will be de-asserted until another sync code is detected. The AUDIO bit in the Receiver Channel Status register is the logical OR of AUTODETECT and the received channel status bit 1. If non-audio data is detected, the data is still processed exactly as if it were normal audio. It is up to the user to mute the outputs as required. 17 CS8427 7. AES3 TRANSMITTER The AES3 transmitter encodes and transmits audio and digital data according to the AES3, IEC60958 (S/PDIF), and EIAJ CP-1201 interface standards. Audio and control data are multiplexed together and bi-phase, mark encoded. The resulting bit stream is driven to an output connector either directly or through a transformer. The transmitter clock may be derived from the clock input pin OMCK, or from the incoming data. If OMCK is asynchronous to the data source, an interrupt bit (TSLIP) is provided that will go high every time a data sample is dropped or repeated. Be aware that the pattern of slips does not have hysteresis and so the occurrence of the interrupt condition is not deterministic. The channel status (C) and user channel (U) bits in the transmitted data stream are taken from storage areas within the CS8427. The user can manually access the internal storage or configure the CS8427 to run in one of several automatic modes. The Appendix: Channel Status and User Data Buffer Management provides detailed descriptions of each automatic mode and describes methods of manually accessing the storage areas. The transmitted user data can optionally be input through the U pin, under the control of a control port register bit. Figure 13 shows the timing requirements for clocking U data through the U pin. 7.1 Transmitted Frame and Channel Status Boundary Timing In some applications, it may be necessary to control the precise timing of the transmitted AES3 frame boundaries. This may be achieved in three ways: 1) With TCBL set to input, driving TCBL high for >3 OMCK clocks will cause a frame start, as well as a new channel status block start. 2) If the AES3 output comes from the AES3 input, setting TCBL as output will cause AES3 output frame boundaries to align with AES3 input frame boundaries. 3) If the AES3 output comes from the serial audio input port while the port is in slave mode and TCBL is set to output, the start of the A channel sub-frame will be aligned with the leading edge of IL-CK. 7.2 TXN and TXP Drivers The line drivers are low skew, low impedance, differential outputs capable of driving cables directly. Both drivers are set to ground during reset (RST = low), when no AES3 transmit clock is provided, and optionally under the control of a register bit. The CS8427 also allows immediate mute of the AES3 transmitter audio data through a control register bit. External components are used to terminate and isolate the external cable from the CS8427. These components are detailed in Appendix A: External AES3/SPDIF/IEC60958 Transmitter and Receiver Components. The TCBL pin is used to control or indicate the start of transmitted channel status block boundaries and may be used as an input or output. 18 DS477F5 CS8427 8. MONO MODE OPERATION An AES3 stream may be used in more than one way to transmit 96-kHz sample rate data. One method is to double the frame rate of the current format. This results in a stereo signal with a sample rate of 96 kHz, carried over a single twisted pair cable. An alternate method is implemented using the two sub-frames in a 48-kHz frame rate AES3 signal to carry consecutive samples of a mono signal, resulting in a 96-kHz sample rate stream. This allows older equipment, whose AES3 transmitters and receivers are not rated for 96-kHz frame rate operation, to handle 96-kHz sample rate information. In this “mono mode”, two AES3 cables are needed for stereo data transfer. The CS8427 offers mono mode operation for the AES3 receiver and the AES3 transmitter. The receiver and transmitter sections may be independently set to mono mode through the MMR and MMT control bits. 8.1 Receiver Mono Mode The receiver mono mode effectively doubles the input frame rate, Fsi. The clock output on the RMCK pin tracks Fsi, and thus is doubled in frequency compared to stereo mode. The receiver will run at a frame rate of Fsi/2, and the serial audio output port will run at Fsi. Sub-frame A data will be routed to both the left and right data fields on SD-OUT. Similarly, sub-frame B data will be routed to both the left and right data fields of the next word clock cycle of SDOUT. Using receiver mono mode is only necessary if the serial audio output port must run at 96 kHz. If the CS8427 is kept in normal stereo mode and receives AES3 data arranged in mono mode, the serial audio output port will run at 48 kHz, with left and right data fields representing consecutive audio samples. 8.2 Transmitter Mono Mode In transmitter mono mode, the input port will run at the audio sample rate (Fso), while the AES3 transmitter frame rate will be at Fso/2. Consecutive left or right channel serial audio data samples may be selected for transmission on the A and B subframes, and the channel status block transmitted is also selectable. Using transmitter mono mode is only necessary if the incoming audio sample rate is already at 96 kHz and contains both left and right audio data words. The “mono mode” AES3 output stream may also be achieved by keeping the CS8427 in normal stereo mode and placing consecutive audio samples in the left and right positions of an incoming data stream with a 48-kHz word rate. SPD ILRCK ISCLK SDIN Serial Audio Input Serial Audio Output MUX OLRCK OSCLK SDOUT AESBP TXOFF RXN RXP AES3 Receiver MUX AES3 Encoder TXP TXN TXD Figure 7. Software Mode Audio Data Flow Switching Options DS477F5 19 CS8427 SDIN ISCLK SIMS SERIAL AUDIO INPUT ILRCK RXD0 RMCKF 1 MUX 0 ÷ PLL MUX RXP 0 SDOUT OUTPUT OLRCK OSCLK INC TXN CHANNEL AES3 STATUS TRANSMIT MEMORY 1 SERIAL AUDIO TXP USER 1 0 MUX BIT SWCLK UNLOCK MEMORY 1 0 MUX OUTC 0 MUX RMCK ÷ 1 RXD1 * OMCK CLK[1:0] Note: When SWCLK mode is enabled, signal input on OMCK is only output through RMCK and not routed back through the RXD1 multiplexer; RMCK is not bi-directional in this mode. Figure 8. CS8427 Clock Routing 20 DS477F5 CS8427 SDOUT OSCLK OLRCK SDIN ISCLK ILRCK Serial Serial Audio Audio Output Input AES3 Rx & Decode RXN RXP RXN AES3 Encoder & Driver TXP RXP TXN AES3 Rx & Decode Serial Audio Output OLRCK OSCLK SDOUT PLL PLL RMCK Data Flow Control Bits TXD1-0: 01 SPD1-0: 10 RMCK Clock Source Control Bits OUTC: 1 INC: 0 RXD1-0: 01 Figure 9. AES3 Input to Serial Audio Output, Serial Audio Input to AES3 Out Data Flow Control Bits TXD1-0: 10 SPD1-0: 10 TXOFF : 1 Clock Source Control Bits OUTC: 1 INC: 0 RXD1-0: 01 Figure 10. AES3 Input to Serial Audio Output Only NOTE: Applications implementing both the Serial Audio Output Port and the AES3 Transmitter must operate at the same sample rate because they are both controlled by the same clock source. Serial Audio Input I LRCK I SCLK SD IN AES3 Rx & Decode TXN TXP I LRCK I SCLK SD IN Serial Audio Input AES3 Rx & Decode TXN TXP PLL RMCK OMCK Data Flow Control Bits TXD1-0: 01 SPD1-0: 01 Clock Source Control Bits OUTC: 0 INC: 1 RXD1-0: 00 Figure 11. Input Serial Port to AES3 Transmitter without PLL Data Flow Control Bits TXD1-0: 01 SPD1-0: 01 Clock Source Control Bits OUTC: 1 INC: 0 RXD1-0: 00 Figure 12. Input Serial Port to AES3 Transmitter with PLL NOTE: In this mode, ILRCK and ISCLK are inputs only. DS477F5 21 CS8427 VLRCK U (Out) VLRCK is a virtual word clock, which may not exist, but is used to illustrate the U timing. VLRCK duty cycle is 50%. VLRCK frequency is always equal to the incoming frame rate. If the serial audio output port is in master mode, VLRCK = OLRCK. If the serial audio output port is in slave mode, then VLRCK needs to be externally created, if required. U transitions are aligned within ±1% of VLRCK period to VLRCK edges Figure 13. AES3 Receiver Timing for U pin output data Tth VLRCK Tsetup Thold VCU[0] Data [4] TXP(N) Z Data [0] VCU[1] Data [5] Y Data [1] VCU[2] Data [6] X Data [2] VCU[3] Data [7] Y Data [3] Data [8] X Data [4] Tsetup => 7.5% AES3 frame time Thold = 0 Tth > 3OMCK if TCBL is Input AES3 Transmitter in Stereo Mode TCBL In or Out VCU[4] Tth VLRCK U Input U[0] Data [4] SDIN Input TXP(N) Output TXP(N) Output Z Data [5] Data [0]* U[2] Data [6] Data [7] Data [8] Y Data [2]* X Data [4]* Y Data [3]* X Data [5]* * Assume MMTLR = 0 Z Data [1]* * Assume MMTLR = 1 AES3 Transmitter in Mono Mode Tsetup => 15% AES3 frame time Thold = 0 Tth > 3OMCK if TCBL is Input VLRCK is a virtual word clock, which may not exist, is used to illustrate the CUV timing. VLRCK duty cycle is 50%. In stereo mode, VLRCK frequency = AES3 frame rate. In mono mode, ALRCK frequency = 2xAES3 frame rate. If the serial audio input port is on slave mode and TCBL is an output, then VLRCK=ILRCK if SILRPOL=0 and VLRCK= ILRCK if SILRPOL =1. If the serial audio input port is in master mode and TCBL is an input, then VLRCK=ILRCK if SILRPOL=0 and VLRCK= ILRCK if SILRPOL =1. Figure 14. AES3 Transmitter Timing for C, U and V pin input data 22 DS477F5 CS8427 Left Justified (In) ILRCK Channel A ISCLK SDIN MSB LSB ILRCK I²S (In) Channel B MSB LSB Channel A MSB Channel B ISCLK SDIN Right Justified (In) MSB MSB LSB ILRCK Channel A MSB LSB Channel B ISCLK SDIN MSB LSB MSB LSB SIMS* SISF* SIRES*[1:0] SIJUST* SIDEL* SISPOL* SILRPOL* Left Justified X X 00+ 0 0 0 0 I²S X X 00+ 0 1 0 1 Right Justified X X XX 1 0 0 0 X = don’t care to match format, but does need to be set to the desired setting + I²S can accept an arbitrary number of bits, determined by the number of ISCLK cycles * See Serial Input Port Data Format Register Bit Descriptions for an explanation of the meaning of each bit Figure 15. Serial Audio Input Example Formats DS477F5 23 CS8427 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 Z LSB MSB V U C Z LSB SODEL* SOSPOL* SOLRPOL* MSB V U C Frame 0 Frame 191 SOMS* SOSF* SORES[1:0]* SOJUST* Left Justified X X XX 0 0 0 0 I²S X X XX 0 1 0 1 Right Justified 1 X XX 1 0 0 0 AES3 Direct X X 11 0 0 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 16. Serial Audio Output Example Formats 24 DS477F5 CS8427 9. CONTROL PORT DESCRIPTION AND TIMING The control port is used to access the registers, allowing the CS8427 to be configured for the desired operational modes and formats. In addition, Channel Status and User data may be read and written through the control port. 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 two modes: SPI and I²C, with the CS8427 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 to VL+ or DGND, thereby permanently selecting the desired AD0 bit address state. 9.1 SPITM Mode In SPI mode, CS is the CS8427 chip select signal; CCLK is the control port bit clock (input into the CS8427 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 17 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 0010000b. The eighth bit is a read/write indicator (R/W), which should be low to write. The next eight bits form the 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. There is a MAP auto increment capability, enabled by the INCR bit in the MAP register. If INCR is a zero, the MAP will stay constant for successive read or writes. If INCR is set to a 1, then the MAP will autoincrement after each byte is read or written, allowing block reads or writes of successive registers. DS477F5 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. The MAP auto increment bit (INCR) may be set or not, as desired. 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). If the MAP auto increment bit is set to 1, the data for successive registers will appear consecutively. 9.2 I²C Mode In I²C mode, SDA is a bidirectional data line. Data is clocked into and out of the part by SCL, with the clock to data relationship as shown in Figure 18. There is no CS pin. Each individual CS8427 is given a unique address. Pins AD0 and AD1 form the two least significant bits of the chip address and should be connected to VL+ or DGND as desired. The EMPH pin is used to set the AD2 bit, by connecting a resistor from the EMPH pin to VL+ or to DGND. The state of the pin is sensed while the CS8427 is being reset. The upper four bits of the seven bit address field are fixed at 0010b. To communicate with a CS8427, the chip address field, which is the first byte sent to the CS8427, should be 0010b followed by the settings of the EMPH, AD1, and AD0. The eighth bit of the address is the R/W bit. If the operation is a write, the next byte is 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. Setting the auto increment bit in MAP allows successive reads or writes of consecutive registers. Each byte is separated by an acknowledge bit, ACK, which is output from the CS8427 after each input byte is read. The ACK bit is input to the CS8427 from the microcontroller after each transmitted byte. I²C mode is supported only with VL+ = 5.0 V. 9.3 Interrupts The CS8427 has a comprehensive interrupt capability. The INT output pin is intended to drive the interrupt input pin on the host microcontroller. The INT pin may be set to be active low, active high, or active low with no active pull-up transistor. This last 25 CS8427 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 set-ups are possible depending on the needs of the equipment designer. 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 using mask register CS CC LK C H IP ADDRESS C D IN 0010000 MAP C H IP ADDRESS DATA LSB MSB R/W b y te 1 0010000 R/W b y te n High Impedance LSB MSB MSB CDOUT LSB MAP = Memory Address Pointer, 8 bits, MSB first Figure 17. Control Port Timing in SPI Mode Note 1 0010 SDA AD2-0 R/W Note 2 ACK DATA7-0 ACK Note 3 DATA7-0 ACK SCL Start Stop Note 1: AD2 is derived from a resistor attached to the EMPH pin, AD1 and AD0 are determined by the state of the corresponding pins Note 2: If operation is a write, this byte contains the Memory Address Pointer, MAP Note 3: If operation is a read, the last bit of the read should be a NACK(high) Figure 18. Control Port Timing in I²C Mode 26 DS477F5 CS8427 10. CONTROL PORT REGISTER SUMMARY Addr (HEX) 00 01 02 03 04 05 06 07 08 09 0A 0B 0C 0D 0E 0F 10 11 12 13 14-1D 1E 1F 20-37 7F Function Reserved Control 1 Control 2 Data Flow Control Clock Source Control Serial Input Format Serial Output Format Interrupt 1 Status Interrupt 2 Status Interrupt 1 Mask Interrupt 1 Mode (MSB) Interrupt 1 Mode (LSB) Interrupt 2 Mask Interrupt 2 Mode (MSB) Interrupt 2 Mode (LSB) Receiver CS Data Receiver Errors Receiver Error Mask CS Data Buffer Control U Data Buffer Control Q sub-code Data OMCK/RMCK Ratio Reserved C or U Data Buffer ID and Version 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 0 SWCLK VSET MUTESAO MUTEAES 0 INT1 INT0 TCBLD 0 HOLD1 HOLD0 RMCKF MMR MMT MMTCS MMTLR 0 TXOFF AESBP TXD1 TXD0 SPD1 SPD0 0 0 RUN CLK1 CLK0 OUTC INC RXD1 RXD0 SIMS SISF SIRES1 SIRES0 SIJUST SIDEL SISPOL SILRPOL SOMS SOSF SORES1 SORES0 SOJUST SODEL SOSPOL SOLRPOL TSLIP OSLIP 0 0 0 DETC EFTC RERR 0 0 0 0 EFTU QCH 0 TSLIPM OSLIPM 0 0 0 DETCM EFTCM RERRM TSLIP1 OSLIP1 0 0 0 DETC1 EFTC1 RERR1 TSLIP0 OSLIP0 0 0 0 DETC0 EFTC0 RERR0 0 0 0 0 DETUM EFTUM QCHM 0 0 0 0 0 DETU1 EFTU1 QCH1 0 0 0 0 0 DETU0 EFTU0 QCH0 0 AUX3 AUX2 AUX1 AUX0 PRO AUDIO COPY ORIG 0 QCRC CCRC UNLOCK V CONF BIP PAR 0 QCRCM CCRCM UNLOCKM VM CONFM BIPM PARM 0 0 BSEL CBMR DETCI EFTCI CAM CHS 0 0 0 UD UBM1 UBM0 DETUI EFTUI ORR7 ORR6 ORR5 ORR4 ORR3 ORR2 ORR1 ORR0 ID3 ID2 ID1 ID0 VER3 VER2 VER1 VER0 Table 1. Control Register Map Summary 10.1 Memory Address Pointer (MAP) 7 INCR 6 MAP6 5 MAP5 4 MAP4 3 MAP3 2 MAP2 1 MAP1 0 MAP0 INCR - Auto Increment Address Control Bit Default = ‘0’ 0 - Disable 1 - Enable MAP6:MAP0 - Register address Note: Reserved registers must not be written to during normal operation. Some reserved registers are used for test modes, which can completely alter the normal operation of the CS8427. DS477F5 27 CS8427 11. CONTROL PORT REGISTER BIT DEFINITIONS 11.1 Control 1 (01h) 7 6 5 4 3 2 1 0 SWCLK VSET MUTESAO MUTEAES 0 INT1 INT0 TCBLD SWCLK - Controls output of OMCK on RMCK when PLL loses lock Default = ‘0’ 0 - RMCK default function 1 - OMCK output on RMCK pin VSET - Transmitted Validity bit level Default = ‘0’ 0 - Indicates data is valid, linear PCM audio data 1 - Indicates data is invalid or not linear PCM audio data MUTESAO - Mute control for the serial audio output port Default = ‘0’ 0 - Not Muted 1 - Muted MUTEAES - Mute control for the AES transmitter output Default = ‘0’ 0 - Not Muted 1 - Muted INT1:INT0 - 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. 11 - Reserved TCBLD - Transmit Channel Status Block pin (TCBL) direction specifier Default = ‘0’ 0 - TCBL is an input 1 - TCBL is an output 11.2 Control 2 (02h) 7 6 5 4 3 2 1 0 0 HOLD1 HOLD0 RMCKF MMR MMT MMTCS MMTLR HOLD1:HOLD0 - Determine how received audio sample is affected when a receiver error occurs Default = ‘00’ 00 - Hold the last valid audio sample 01 - Replace the current audio sample with 00 (mute) 10 - Do not change the received audio sample 11 - Reserved RMCKF - Select recovered master clock output pin frequency. Default = ‘0’ 0 - RMCK is equal to 256 * Fsi 1 - RMCK is equal to 128 * Fsi 28 DS477F5 CS8427 MMR - Select AES3 receiver mono or stereo operation Default = ‘0’ 0 - Normal stereo operation 1 - A and B subframes treated as consecutive samples of one channel of data. Data is duplicated to both left and right parallel outputs of the AES receiver block. The input sample rate (Fsi) is doubled compared to MMR=0 MMT - Select AES3 transmitter mono or stereo operation Default = ‘0’ 0 - Normal stereo operation 1 - Output either left or right channel inputs into consecutive subframe outputs (mono mode, left or right is determined by MMTLR bit) MMTCS - Select A or B channel status data to transmit in mono mode Default = ‘0’ 0 - Use channel A CS data for the A subframe and use channel B CS data for the B subframe 1 - Use the same CS data for both the A and B subframe outputs. If MMTLR = 0, use the left channel CS data. If MMTLR = 1, use the right channel CS data. MMTLR - Channel Selection for AES Transmitter mono mode Default = ‘0’ 0 - Use left channel input data for consecutive subframe outputs 1- Use right channel input data for consecutive subframe outputs 11.3 Data Flow Control (03h) 7 6 5 4 3 2 1 0 0 TXOFF AESBP TXD1 TXD0 SPD1 SPD0 0 The Data Flow Control register configures the flow of audio data to/from the following blocks: Serial Audio Input Port, Serial Audio Output Port, AES3 receiver, and AES3 transmitter. In conjunction with the Clock Source Control register, multiple Receiver/Transmitter/Transceiver modes may be selected. The output data should be muted prior to changing bits in this register to avoid transients. TXOFF - AES3 Transmitter Output Driver Control Default = ‘0 0 - AES3 transmitter output pin drivers normal operation 1 - AES3 transmitter output pin drivers drive to 0 V. AESBP - AES3 bypass mode selection Default = ‘0’ 0 - Normal operation 1 - Connect the AES3 transmitter driver input directly to the RXP pin, which becomes a normal TTL threshold digital input. The transmitter clock (selecting using the OUTC bit in the Clock Source Control) must be present for the bypass mode to work. TXD1:TXD0 - AES3 Transmitter Data Source Default = ‘01’ 00 - Reserved 01 - Serial audio input port 10 - AES3 receiver 11 - Reserved DS477F5 29 CS8427 SPD1:SPD0 - Serial Audio Output Port Data Source Default = ‘10’ 00 - Reserved 01 - Serial Audio Input Port 10 - AES3 receiver 11 - Reserved 11.4 Clock Source Control (04h) 7 6 5 4 3 2 1 0 0 RUN CLK1 CLK0 OUTC INC RXD1 RXD0 This register configures the clock sources of various blocks. In conjunction with the Data Flow Control register, various Receiver/Transmitter/Transceiver modes may be selected. RUN - Controls the internal clocks, allowing the CS8427 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. Reading and writing the U and C data buffers is not possible. Power consumption is low. 1 - Normal part operation. This bit must be written to the 1 state to allow the CS8427 to begin operation. All input clocks should be stable in frequency and phase when RUN is set to 1. CLK1:0 - Output side master clock input (OMCK) frequency to output sample rate (Fso) ratio selector. If these bits are changed during normal operation, then always stop the CS8427 first (RUN = 0), write the new value, then start the CS8427 (RUN = 1). Default = ‘00’ 00 - OMCK frequency is 256 * Fso 01 - OMCK frequency is 384 * Fso 10 - OMCK frequency is 512 * Fso 11 - Reserved OUTC - Output Time Base Default = ‘0’ 0 - OMCK input pin, modified by the selected divide ratio bits CLK1:0. 1 - Recovered Input Clock INC - Input Time Base Clock Source Default = ‘0’ 0 - Recovered Input Clock 1 - OMCK input pin, modified by the selected divide ratio bits CLK1:0. RXD1:0 - Recovered Input Clock Source Default = ‘00’ 00 - 256 * Fsi, where Fsi is derived from the ILRCK pin (only possible when the serial audio input port is in slave mode) 01 - 256 * Fsi, where Fsi is derived from the AES3 input frame rate 10 - Bypass the PLL and apply an external 256 * Fsi clock through the RMCK pin. The AES3 receiver is held in synchronous reset. This setting is useful to prevent UNLOCK interrupts when using an external RMCK and inputting data through the serial audio input port. 11 - Reserved. 30 DS477F5 CS8427 11.5 Serial Audio Input Port Data Format (05h) 7 6 5 4 3 2 1 0 SIMS SISF SIRES1 SIRES0 SIJUST SIDEL SISPOL SILRPOL SIMS - Master/Slave Mode Selector Default = ‘0’ 0 - Serial audio input port is in slave mode 1 - Serial audio input port is in master mode SISF - ISCLK frequency (for master mode) Default = ‘0’ 0 - 64 * Fsi 1 - 128 * Fsi SIRES1:0 - Resolution of the input data, for right-justified formats Default = ‘00’ 00 - 24 bit resolution 01 - 20 bit resolution 10 - 16 bit resolution 11 - Reserved SIJUST - Justification of SDIN data relative to ILRCK Default = ‘0’ 0 - Left-justified 1 - Right-justified SIDEL - Delay of SDIN data relative to ILRCK, for left-justified data formats Default = ‘0’ 0 - MSB of SDIN data occurs in the first ISCLK period after the ILRCK edge 1 - MSB of SDIN data occurs in the second ISCLK period after the ILRCK edge SISPOL - ISCLK clock polarity Default = ‘0’ 0 - SDIN sampled on rising edges of ISCLK 1 - SDIN sampled on falling edges of ISCLK SILRPOL - ILRCK clock polarity Default = ‘0’ 0 - SDIN data is for the left channel when ILRCK is high 1 - SDIN data is for the right channel when ILRCK is high 11.6 Serial Audio Output Port Data Format (06h) 7 6 5 4 3 2 1 0 SOMS SOSF SORES1 SORES0 SOJUST SODEL SOSPOL SOLRPOL SOMS - Master/Slave Mode Selector Default = ‘0’ 0 - Serial audio output port is in slave mode 1 - Serial audio output port is in master mode SOSF - OSCLK frequency (for master mode) Default = ‘0’ 0 - 64 * Fso 1 - 128 * Fso DS477F5 31 CS8427 SORES1:0 - Resolution of the output data on SDOUT and on the AES3 output 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 normally occupied by the P bit is used to indicate the location of the block start, SDOUT pin only, serial audio output port clock must be derived from the AES3 receiver recovered clock) SOJUST - Justification of SDOUT data relative to OLRCK Default = ‘0’ 0 - Left-justified 1 - Right-justified (master mode only) SODEL - Delay of SDOUT data relative to OLRCK, for left-justified data formats 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 transitions occur on falling edges of OSCLK 1 - SDOUT transitions occur on rising edges of OSCLK SOLRPOL - OLRCK clock polarity Default = ‘0’ 0 - SDOUT data is for the left channel when OLRCK is high 1 - SDOUT data is for the right channel when OLRCK is high 11.7 Interrupt 1 Status (07h) (Read Only) 7 6 5 4 3 2 1 0 TSLIP OSLIP 0 0 0 DETC EFTC RERR 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. This register defaults to 00h. TSLIP - AES3 transmitter source data slip interrupt. In data flows where OMCK, which clocks the AES3 transmitter, is asynchronous to the data source, this bit will go high every time a data sample is dropped or repeated. When TCBL is an input, this bit will go high on receipt of a new TCBL signal. 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. DETC - D to E C-buffer transfer interrupt. Indicates the completion of a D to E C-buffer transfer. See “Channel Status and User Data Buffer Management” on page 51 for more information. EFTC - E to F C-buffer transfer interrupt. Indicates the completion of a E to F C-buffer transfer. See “Channel Status and User Data Buffer Management” on page 51 for more information. RERR - A receiver error has occurred. The Receiver Error register may be read to determine the nature of the error which caused the interrupt. 32 DS477F5 CS8427 11.8 Interrupt 2 Status (08h) (Read Only) 7 6 5 4 3 2 1 0 0 0 0 0 DETU EFTU QCH 0 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. This register defaults to 00h. DETU - D to E U-buffer transfer interrupt. (Block Mode only) Indicates the completion of a D to E U-buffer transfer. See “Channel Status and User Data Buffer Management” on page 51 for more information. EFTU - E to F U-buffer transfer interrupt. (Block Mode only) Indicates the completion of a E to F U-buffer transfer. See “Channel Status and User Data Buffer Management” on page 51 for more information. QCH - A new block of Q-subcode data is available for reading. The data must be completely read within 588 AES3 frames after the interrupt occurs to avoid corruption of the data by the next block. 11.9 Interrupt 1 Mask (09h) 7 6 5 4 3 2 1 0 TSLIPM OSLIPM 0 0 0 DETCM EFTCM RERRM The bits of this register serve as a mask for the Interrupt 1 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 INT pin or the status register. The bit positions align with the corresponding bits in the Interrupt 1 register. This register defaults to 00h. 11.10 Interrupt 1 Mode MSB (0Ah) & Interrupt 1 Mode LSB (0Bh) 7 6 5 4 3 2 1 0 TSLIP1 TSLIP0 OSLIP1 OSLIP0 0 0 0 0 0 0 DETC1 DETC0 EFTC1 EFTC0 RERR1 RERR0 The two Interrupt Mode registers form a 2-bit code for each Interrupt Register 1 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 00. 00 - Rising edge active 01 - Falling edge active 10 - Level active 11 - Reserved DS477F5 33 CS8427 11.11 Interrupt 2 Mask (0Ch) 7 6 5 4 3 2 1 0 0 0 0 0 DETUM EFTUM QCHM 0 The bits of this register serve as a mask for the Interrupt 2 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 INT pin or the status register. The bit positions align with the corresponding bits in the Interrupt 2 register. This register defaults to 00h. 11.12 Interrupt 2 Mode MSB (0Dh) & Interrupt 2 Mode LSB (0Eh) 7 6 5 4 3 2 1 0 0 0 0 0 0 0 0 0 DETU1 DETU0 EFTU1 EFTU0 QCH1 QCH0 0 0 The two Interrupt Mode registers form a 2-bit code for each Interrupt Register 1 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 00. 00 - Rising edge active 01 - Falling edge active 10 - Level active 11 - Reserved 11.13 Receiver Channel Status (0Fh) (Read Only) 7 6 5 4 3 2 1 0 AUX3 AUX2 AUX1 AUX0 PRO AUDIO COPY ORIG 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 Channel Status Data Buffer Control 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 consumer format 1 - Received channel status block is in professional format 34 DS477F5 CS8427 AUDIO - Audio indicator 0 - Received data is linearly coded PCM audio 1 - Received data is not linearly coded PCM audio 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 the incoming data is flagged as professional, or if the receiver is not in use. 11.14 Receiver Error (10h) (Read Only) 7 6 5 4 3 2 1 0 0 QCRC CCRC UNLOCK V CONF BIP 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. This is the logical OR of BIP and UNLOCK. 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 DS477F5 35 CS8427 11.15 Receiver Error Mask (11h) 7 6 5 4 3 2 1 0 0 QCRCM CCRCM UNLOCKM VM CONFM BIPM 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 the RERR pin, 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. 11.16 Channel Status Data Buffer Control (12h) 7 6 5 4 3 2 1 0 0 0 BSEL CBMR DETCI EFTCI CAM CHS BSEL - Selects the data buffer register addresses to contain User data or Channel Status data Default = ‘0’ 0 - Data buffer address space contains Channel Status data 1 - Data buffer address space contains User data CBMR - Control for the first 5 bytes of channel status “E” buffer Default = ‘0’ 0 - Allow D to E buffer transfers to overwrite the first 5 bytes of channel status data 1 - Prevent D to E buffer transfers from overwriting first 5 bytes of channel status data DETCI - D to E C-data buffer transfer inhibit bit. Default = ‘0’ 0 - Allow C-data D to E buffer transfers 1 - Inhibit C-data D to E buffer transfers EFTCI - E to F C-data buffer transfer inhibit bit. Default = ‘0’ 0 - Allow C-data E to F buffer transfers 1 - Inhibit C-data E to F buffer transfers CAM - C-data buffer control port access mode bit Default = ‘0’ 0 - One byte mode 1 - Two byte mode CHS - Channel select bit Default = ‘0’ 0 - Channel A information is displayed at the EMPH pin and in the receiver channel status register. Channel A information is output during control port reads when CAM is set to 0 (One Byte Mode) 1 - Channel B information is displayed at EMPH pin and in the receiver channel status register. Channel B information is output during control port reads when CAM is set to 0 (One Byte Mode) 36 DS477F5 CS8427 11.17 User Data Buffer Control (13h) 7 6 5 4 3 2 1 0 0 0 0 UD UBM1 UBM0 DETUI EFTUI UD - User data pin (U) direction specifier If this bit is changed during normal operation, then always stop the CS8427 first (RUN = 0), write the new value, then start the CS8427 (RUN = 1). Default = ‘0’ 0 - The U pin is an input. The U data is latched in on both rising and falling edges of OLRCK. This setting also chooses the U pin as the source for transmitted U data. 1 - The U pin is an output. The received U data is clocked out on both rising and falling edges of ILRCK. This setting also chooses the U data buffer as the source of transmitted U data. UBM1:0 - Sets the operating mode of the AES3 U bit manager Default = ‘00’ 00 - Transmit all zeros mode 01 - Block mode 10 - Reserved 11 - Reserved DETUI - D to E U-data buffer transfer inhibit bit (valid in block mode only). Default = ‘0’ 0 - Allow U-data D to E buffer transfers 1 - Inhibit U-data D to E buffer transfers EFTUI - E to F U-data buffer transfer inhibit bit (valid in block mode only). Default = ‘0’ 0 - Allow U-data E to F buffer transfers 1 - Inhibit U-data E to F buffer transfer 11.18 Q-Channel Subcode Bytes 0 to 9 (14h - 1Dh) (Read Only) The following 10 registers contain the decoded Q-channel subcode data 7 6 5 4 3 2 1 0 CONTROL TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME CONTROL TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME CONTROL TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME CONTROL TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME ADDRESS TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME ADDRESS TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME ADDRESS TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME ADDRESS TRACK INDEX MINUTE SECOND FRAME ZERO ABS MINUTE ABS SECOND ABS FRAME Each byte is LSB first with respect to the 80 Q-subcode bits Q[79:0]. Thus bit 7 of address 14h is Q[0] while bit 0 of address 14h is Q[7]. Similarly bit 0 of address 1Dh corresponds to Q[79]. DS477F5 37 CS8427 11.19 OMCK/RMCK Ratio (1Eh) (Read Only) 7 6 5 4 3 2 1 0 ORR7 ORR6 ORR5 ORR4 ORR3 ORR2 ORR1 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 256xFso. 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 > 3.984375, ORR will overflow. Once the register has overflowed, the value shown will be Fso/Fsi modulo 4. For example, if the OMCK is 36.864 MHz, Fso would be 144 kHz (144 kHz = 36.864 MHz/256). Then if the input sample rate is 32 kHz, you would get (144/32) mod 4 = 4.5 mod 4 = 0.5 from the ORR register. (The value from the ORR register is hexadecimal, so the actual value you will get is 20h). 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=ORR[7:6]) ORR[5:0] - Fractional part of the ratio (Fraction value=ORR[5:0]/64) 11.20 C-bit or U-bit Data Buffer (20h - 37h) Either channel status data buffer E or user data buffer E (provided UBM bits are set to block mode) is accessible using these register addresses. 11.21 CS8427 I.D. and Version Register (7Fh) (Read Only) 7 6 5 4 3 2 1 0 ID3 ID2 ID1 ID0 VER3 VER2 VER1 VER0 ID3:0 - ID code for the CS8427. Permanently set to 0111 VER3:0 - CS8427 revision level. Revision A is coded as 0001 38 DS477F5 CS8427 12. PIN DESCRIPTION - SOFTWARE MODE SDA/CDOUT AD0/CS EMPH RXP RXN VA+ AGND FILT RST RMCK RERR ILRCK ISCLK SDIN 1 2 3+ 4* 5* 6* 7* 8* 9* 10* 11* 12* 13* 14* 28 27 *26 *25 *24 *23 *22 21 20 19 *18 *17 *16 *15 SCL/CCLK AD1/CDIN TXP TXN H/S VL + DGND OMCK U INT SDOUT OLRCK OSCLK TCBL * Pins which remain the same function in all modes. + Pins which require a pull up or pull down resistor to select the desired startup option. SDA/CDOUT 1 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 CS8427 AD0/CS 2 Address Bit 0 (I²C) / Control Port Chip Select (SPI) (Input) - A falling edge on this pin puts the CS8427 into SPI control port mode. With no falling edge, the CS8427 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 CS8427 EMPH 3 Pre-Emphasis (Output) - EMPH is low when the incoming Channel Status data indicates 50/15 ms pre-emphasis. EMPH is high when the Channel Status data indicates no preemphasis or indicates pre-emphasis other than 50/15 ms. This is also a start-up option pin, and requires a 47 kΩ resistor to either VL+ or DGND, which determines the AD2 address bit for the control port in I²C mode RXP RXN 4 5 Differential Line Receiver (Input) - Receives differential AES3 data. VA+ 6 Positive Analog Power (Input) - Positive supply for the chip’s analog section. Nominally +5.0 V. This supply should be as quiet as possible since noise on this pin will directly affect the jitter performance of the recovered clock AGND 7 Analog Ground (Input) - Ground for the analog section. AGND should be connected to the same ground as DGND FILT 8 PLL Loop Filter (Output) - An RC network should be connected between this pin and ground. See “Appendix C: PLL Filter” on page 55 for recommended schematic and component values. RST 9 Reset (Input) - When RST is low, the CS8427 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. This is particularly true in hardware mode with multiple CS8427 devices where synchronization between devices is important RMCK 10 Input Section Recovered Master Clock (Input/Output) - Input section recovered master clock output when PLL is used. Frequency defaults to 256x the sample rate (Fs) and may be set to 128x. When the PLL is bypassed by the RXD[1:0] bits in the Clock Source Control register, an external clock of 256 Fs may be applied to this pin DS477F5 39 CS8427 RERR 11 Receiver Error (Output) - When high, indicates an error condition from the AES3 receiver. The status of this pin is updated once per sub-frame of incoming AES3 data. Conditions that can cause RERR to go high are: validity, parity error, bi-phase coding error, confidence, as well as loss of lock by the PLL. Each condition may be optionally masked from affecting the RERR pin using the Receiver Error Mask Register. The RERR pin tracks the status of the unmasked errors: the pin goes high as soon as an unmasked error occurs and goes low immediately when all unmasked errors go away. ILRCK 12 Serial Audio Input Left/Right Clock (Input/Output) - Word rate clock for the audio data on the SDIN pin. ISCLK 13 Serial Audio Bit Clock (Input/Output) - Serial bit clock for audio data on the SDIN pin. SDIN 14 Serial Audio Data Port (Input) - Audio data serial input pin. TCBL 15 Transmit Channel Status Block Start (Input/Output) - When operated as output, TCBL is high during the first sub-frame of a transmitted channel status block, and low at all other times. When operated as input, driving TCBL high for at least three OMCK clocks will cause the next transmitted sub-frame to be the start of a channel status block. OSCLK 16 Serial Audio Output Bit Clock (Input/Output) - Serial bit clock for audio data on the SDOUT pin OLRCK 17 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 18 Serial Audio Output Data (Output) - Audio data serial output pin INT 19 Interrupt (Output) - Indicates errors and key events during the operation of the CS8427. All bits affecting INT may be unmasked through bits in the control registers. The condition(s) that initiated interrupt are readable through a control register. The polarity of the INT output, as well as selection of a standard or open drain output, is set through a control register. Once set true, the INT pin goes false only after the interrupt status registers have been read and the interrupt status bits have returned to zero U 20 User Data (Input/Output) - May optionally be used to input User bit data for transmission by the AES3 transmitter, see Figure 13 on page 22 for timing information. Alternatively, the U pin may be set to output User data from the AES3 receiver, see Figure 13 on page 22 for timing information. If not driven, a 47 kΩ pull-down resistor is recommended for the U pin, since the default state of the UD direction bit sets the U pin as an input. The pull-down resistor ensures that the transmitted user data will be zero. If the U pin is always set to be an output, thereby causing the U bit manager to be the source of the U data, then the resistor is not necessary. The U pin should not be tied directly to ground, in case it is programmed to be an output, and subsequently tries to output a logic high. This situation may affect the long term reliability of the device. If the U pin is driven by a logic level output, then a 100 Ω series resistor is recommended. OMCK 21 System Clock (Input) - When the OMCK System Clock Mode is enabled by the SWCLK bit in the Control 1 register, the clock signal input on this pin is output through RMCK. OMCK serves as reference signal for OMCK/RMCK ratio expressed in register 1Eh. DGND 22 Digital Ground (Input) - Ground for the digital section. DGND should be connected to the same ground as AGND VL+ 23 Positive Digital Power (Input) - Typically +3.3 V or +5.0 V. H/S 24 Hardware/Software Mode Control (Input) - Determines the method of controlling the operation of the CS8427, and the method of accessing CS and U data. In software mode, device control and CS and U data access is primarily through the control port, using a microcontroller. Hardware mode provides an alternate mode of operation and access to the CS and U data through dedicated pins. This pin should be permanently tied to VL+ or DGND 40 DS477F5 CS8427 TXP TXN 25 26 Differential Line Driver (Output) - Drivers transmit AES3 data and are pulled low while the CS8427 is in the reset state. AD1/CDIN 27 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 SCL/CCLK 28 Control Port Clock (Input) - Serial control interface clock and is used to clock control data bits into and out of the CS8427. In I²C mode, SCL requires an external pull-up resistor to VL+ DS477F5 41 CS8427 13. HARDWARE MODE DESCRIPTION Hardware mode is selected by connecting the H/S pin to ‘1’. Hardware Mode data flow is shown in Figure 19. Audio data is input through the AES3 receiver, and routed to the serial audio output port. Different audio data synchronous to RMCK may be input into the serial audio input port, and output through the AES3 transmitter. The channel status data, user data and validity bit information are handled in 2 alternative modes: A and B, determined by a start-up resistor on the COPY pin. In mode A, the received PRO, COPY, ORIG, EMPH, and AUDIO channel status bits are output on pins. The transmitted channel status bits are copied from the received channel status data, and the transmitted U and V bits are 0. In mode B, only the COPY and ORIG pins are output, and reflect the received channel status data. The transmitted channel status bits, user data and validity bits are input serially through the PRO/C, EMPH/U and AUDIO/V pins. Figure 13 on page 22 shows the timing requirements. The APMS pin allows the serial audio input port to be set to master or slave. If a validity, parity, bi-phase or lock receiver error occurs, the current audio sample is passed unmodified to the serial audio output port. Start-up options are shown in Table 2 on page 43, and allow choice of the serial audio output port as a master or slave, whether TCBL is an input or an output, the audio serial ports formats and the source of the transmitted C, U and V data. 13.1 Serial Audio Port Formats In hardware mode, only a limited number of alternative serial audio port formats are available. These formats are described by Table 3 on page 43 and Table 4 on page 43, which define the equivalent software mode bit settings for each format. Timing diagrams are shown in Figure 15 on page 23 and Figure 16 on page 24. VL+ H/S OSCLK ISCLK SDOUT OLRCK ILRCK SDIN Serial Audio Output RXP RXN AES3 Rx & Decoder Serial Audio Input APMS AES3 Encoder & Tx TXP TXN C & U bit Data Buffer RMCK RERR PRO/C COPY ORIG EMPH/U AUDIO/V TCBL Power supply pins (VD+, VA+, DGND, AGND) & the reset pin (RST) and the PLL filter pin (FILT) are omitted from this diagram. Please refer to the Typical Connection Diagram for hook-up details. Figure 19. Hardware Mode 42 DS477F5 CS8427 SDOUT RMCK RERR ORIG COPY LO - - - - Serial Output Port is Slave Function HI - - - - Serial Output Port is Master - - - - LO Mode A: C transmitted data is copied from received data, U and V =0, received PRO, EMPH, AUDIO is visible - - - - HI Mode B: CUV transmitted data is input serially on pins, received PRO, EMPH and AUDIO is not visible - LO LO - - Serial Input & Output Format: Left Justified - LO HI - - Serial Input & Output Format: I²S - HI LO - - Serial Input & Output Format: Right Justified - HI HI - - Serial Input format: Left Justified, Output Format: AES3 Direct - - - LO - TCBL is an input - - - HI - TCBL is an output Table 2. Hardware Mode Start-up Options SOSF SORES1/0 SOJUST SODEL SOSPOL SOLRPOL OF1 - Left Justified 0 00 0 0 0 0 OF2 - I²S 24-bit data 0 00 0 1 0 1 OF3 - Right Justified, master mode only 0 00 1 0 0 0 OF4 - I²S 16 bit data 0 10 0 1 0 1 OF5 - Direct AES3 data 0 11 0 0 0 0 Table 3. Serial Audio Output Formats Available in Hardware Mode SISF SIRES1/0 SIJUST SIDEL SISPOL SILRPOL IF1 - Left Justified 0 00 0 0 0 0 IF2 - I²S 0 00 0 1 0 1 IF3 - Right Justified 24-bit data 0 00 1 0 0 0 IF4 - Right Justified 16-bit data 0 10 1 0 0 0 Table 4. Serial Audio Input Formats Available in Hardware Mode DS477F5 43 CS8427 14. PIN DESCRIPTION - HARDWARE MODE COPY DGND2 EMPH/U RXP RXN VA+ AGND FILT RST RMCK RERR ILRCK ISCLK SDIN 1+ 2 3 4* 5* 6* 7* 8* 9* 10*+ 11*+ 12* 13* 14* +28 27 *26 *25 *24 *23 *22 21 20 19 +*18 *17 *16 *15 ORIG VL 2+ TXP TXN H/S VL + DGND APMS PRO/C AUDIO/V SDOUT OLRCK OSCLK TCBL * Pins which remain the same function in all modes. + Pins which require a pull up or pull down resistor to select the desired startup option. COPY 1 COPY Channel Status Bit (Output) - Reflects the state of the Copyright Channel Status bit in the incoming AES3 data stream. If the category code is set to General, copyright will be indicated whatever the state of the Copyright bit. This is also a start-up option pin, and requires a pull-up or pull-down resistor. DGND2 DGND 2 22 Digital Ground (Input) - Ground for the digital section. DGND should be connected to the same ground as AGND. EMPH/U 3 Pre-Emphasis Indicator / U-bit (Input/Output) - The EMPH/U pin either reflects the state of the EMPH channel status bit in the incoming AES3 data stream, or is the serial U-bit input for the AES3 transmitted data, clocked by OLRCK. If indicating emphasis: EMPH/U is low when the incoming Channel Status data indicates 50/15 ms pre-emphasis. EMPH/U is high when the Channel Status data indicates no pre-emphasis or indicates pre-emphasis other than 50/15 ms. RXP RXN 4 5 Differential Line Receiver (Input) - Receives differential AES3 data. VA+ 6 Positive Analog Power (Input) - Positive supply for the analog section. Nominally +5.0 V. This supply should be as quiet as possible since noise on this pin will directly affect the jitter performance of the recovered clock AGND 7 Analog Ground (Input) - Ground for the analog section. AGND should be connected to the same ground as DGND FILT 8 PLL Loop Filter (Output) - An RC network should be connected between this pin and ground. See “Appendix C: PLL Filter” on page 55 for recommended schematic and component values. RST 9 Reset (Input) - When RST is low, the CS8427 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. This is particularly true in hardware mode with multiple CS8427 devices where synchronization between devices is important RMCK 10 Input Section Recovered Master Clock (Output) - Input section recovered master clock output when PLL is used. Frequency is 256x the sample rate (Fs). RERR 11 Receiver Error (Output) - When high, indicates an error in the operation of the AES3 receiver. The status of this pin is updated once per sub-frame of incoming AES3 data. Conditions that can cause RERR to go high are: parity error, bi-phase coding error, confidence, as well as loss of lock by the PLL. 44 DS477F5 CS8427 ILRCK 12 Serial Audio Input Left/Right Clock (Input/Output) - Word rate clock for the audio data on the SDIN pin. ISCLK 13 Serial Audio Bit Clock (Input/Output) - Serial bit clock for audio data on the SDIN pin. SDIN 14 Serial Audio Data Port (Input) - Audio data serial input pin. TCBL 15 Transmit Channel Status Block Start (Input/Output) - When operated as output, TCBL is high during the first sub-frame of a transmitted channel status block, and low at all other times. When operated as input, driving TCBL high for at least three OMCK clocks will cause the next transmitted sub-frame to be the start of a channel status block. OSCLK 16 Serial Audio Output Bit Clock (Input/Output) - Serial bit clock for audio data on the SDOUT pin OLRCK 17 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 18 Serial Audio Output Data (Output) - Audio data serial output pin AUDIO/V 19 Audio Channel Status Bit / V-Bit (Input/Output) - Reflects either the state of the audio/nonaudio Channel Status bit in the incoming AES3 data stream or is the Validity bit data input for the AES3 transmitted data stream, clocked by OLRCK. PRO/C 20 PRO Channel Status Bit / C-Bit (Input/Output) - Reflects either the state of the Professional/Consumer Channel Status bit in the incoming AES3 data stream or is the serial C-bit input for the AES3 transmitted data, clocked by OLRCK. APMS 21 Serial Audio Input Port Master/Slave Select (Input) - APMS should be connected to VL+ to set serial audio input port as a master, or connected to DGND to set the port as a slave. VL+ VL2+ 23 27 Positive Digital Power (Input) - Typically +3.3 V or +5.0 V. H/S 24 Hardware/Software Mode Control (Input) - Determines the method of controlling the operation of the CS8427, and the method of accessing CS and U data. In software mode, device control and CS and U data access is primarily through the control port, using a microcontroller. Hardware mode provides an alternate mode of operation and access to the CS and U data through dedicated pins. This pin should be permanently tied to VL+ or DGND TXP TXN 25 26 Differential Line Driver (Output) - Drivers transmit AES3 data and are pulled low while the CS8427 is in the reset state. ORIG 28 ORIG Channel Status Bit (Output) - SCMS generation indicator. This is decoded from the incoming category code and the L bit. A low output indicates that the source of the audio data stream is a copy. A high indicates that the source of the audio data stream is an original recording. This is also a start-up option pin, and requires a pull-up or pull-down resistor. DS477F5 45 CS8427 15. APPLICATIONS 15.1 Reset, Power Down and Start-up When RST is low, the CS8427 enters a low power mode and all internal states are reset, including the control port and registers, and the outputs are muted. 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 AES3 and serial audio outputs will be enabled. Some options within the CS8427 are controlled by a start-up mechanism. During the reset state, some of the output 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 CS8427 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. In software mode, the only start-up option pin is EMPH, which is used to set a chip address bit for the control port in I²C mode. Hardware modes use many start-up options, which are detailed in the hardware definition section at the end of this data sheet. 15.2 ID Code and Revision Code The CS8427 has a register that contains a four bit code to indicate that the addressed device is a CS8427. This is useful when other CS84XX family members are resident in the same system, allowing common software modules. The CS8427 four bit revision code is also available. This allows the software driver for the CS8427 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. 46 15.3 Power Supply, Grounding, and PCB layout For most applications, the CS8427 can be operated from a single +5.0 V supply, following normal supply decoupling practices, see Figure 5 on page 11. Note that the I²C protocol is supported only in VL+ = 5.0 V mode. For applications where the recovered input clock, output on the RMCK pin, is required to be low jitter, then use a separate, quiet, analog +5.0 V supply for VA+, decoupled to AGND. In addition, a separate region of analog ground plane around the FILT, AGND, VA+, RXP, and RXN pins is recommended. The VL+ supply should be well decoupled with a 0.1 μF capacitor to DGND to minimize AES3 transmitter induced transients. 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 CS8427 to minimize inductance effects, and all decoupling capacitors should be as close to the CS8427 as possible. 15.4 Synchronization of Multiple CS8427s The serial audio output ports of multiple CS8427s can be synchronized if all devices share the same master clock, OSCLK, OLRCK, and RST line and leave the reset state on the same master clock falling edge. Either all the ports need to be in slave mode, or one can be set as a master. Multiple AES3 transmitters can be synchronized if all devices share the same master clock, TCBL, and RST signals and leave the reset state on the same master clock falling edge. The TCBL pin is used to synchronize multiple CS8427 AES3 transmitters at the channel status block boundaries. One CS8427 must have its TCBL set to master; the others must be set to slave TCBL. Alternatively, TCBL can be derived from external logic, in which case all the CS8427 devices should be set to slave TCBL. DS477F5 CS8427 16. 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 DS477F5 47 CS8427 28L TSSOP (4.4 mm BODY) PACKAGE DRAWING N D E11 A2 E e b2 SIDE VIEW A ∝ A1 L END VIEW SEATING PLANE 1 2 3 TOP VIEW DIM A A1 A2 b D E E1 e L ∝ 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 included 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. 48 DS477F5 CS8427 17. ORDERING INFORMATION Product Description Package Pb-Free 28-pin SOIC CS8427 CDB8427 DS477F5 96 kHz Digital Audio Interface Transceiver 28-pin TSSOP CS8427 Evaluation Board YES - Grade Temp Range Container Order # Rail CS8427-CSZ Tape & Reel CS8427-CSZR Commercial -10 to +70°C Rail CS8427-CZZ Tape & Reel CS8427-CZZR Rail CS8427-DZZ Automotive -40 to +85°C Tape & Reel CS8427-DZZR CDB8427 49 CS8427 18. APPENDIX A: EXTERNAL AES3/SPDIF/IEC60958 TRANSMITTER AND RECEIVER COMPONENTS This section details the external components required to interface the AES3 transmitter and receiver to cables and fiber-optic components. 18.1 AES3 Transmitter External Components The output drivers on the CS8427 are designed to drive both the professional and consumer interfaces. The AES3 specification for professional/broadcast use calls for a 110 Ω source impedance and a balanced drive capability. Since the transmitter output impedance is very low, a 110 Ω resistor should be placed in series with one of the transmit pins. The specifications call for a balanced output drive of 2-7 V peak-to-peak into a 110 Ω load with no cable attached. Using the circuit in Figure 20, the output of the transformer is short-circuit protected, has the proper source impedance, and provides a 5 V peak-to-peak signal into a 110 Ω load. Lastly, the two output pins should be attached to an XLR connector with male pins and a female shell, and with pin 1 of the connector grounded. CS8427 In the case of consumer use, the IEC60958 specifications call for an unbalanced drive circuit with an output impedance of 75 Ω and a output drive level of 0.5 V peak-to-peak ±20% when measured across a 75 Ω load using no cable. The circuit shown in Figure 21 only uses the TXP pin and provides the proper output impedance and drive level using standard 1% resistors. If VL+ is driven from +3.3 V, use resistor values of 243 Ω and 107 Ω. The connector for a consumer application would be an RCA phono socket. This circuit is also short circuit protected. The TXP pin may be used to drive TTL or CMOS gates as shown in Figure 22. This circuit may be used for optical connectors for digital audio since they usually have TTL or CMOS compatible inputs. This circuit is also useful when driving multiple digital audio outputs since RS422 line drivers have TTL compatible inputs. 18.2 Isolating Transformer Requirements Please refer to the application note AN134: AES and SPDIF Recommended Transformers for resources on transformer selection. CS8427 110-(RTXP+RTXN) 374-RTXP TXP TXP 90.9 Ω XLR TXN 1 Figure 20. Professional Output Circuit RCA Phono TXN Figure 21. Consumer Output Circuit CS8427 TXP TTL or CMOS Gate TXN Figure 22. TTL/CMOS Output Circuit 50 DS477F5 CS8427 18.3 AES3 Receiver External Components The CS8427 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 Figure 23. Although transformers are not required by the AES, they are, however, 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 and RXN) as shown in Figure 24. However, if a transformer is not used, high frequency energy could be coupled into the receiver, causing degradation in analog performance. Figure 23 and Figure 24 show an optional 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. XLR * See Text RXP 110 Ω Pair 0.01 μF RXN Figure 23. Professional Input Circuit 75 Ω Coax 0.01 μF The circuit shown in Figure 26 may be used when external RS422 receivers, optical receivers or other TTL/CMOS logic outputs drive the CS8427 receiver section. 18.4 Isolating Transformer Requirements Please refer to the application note AN134: “AES and SPDIF Recommended Transformers” for resources on transformer selection XLR CS8427 0.01 μF * See Text Pair 110 Ω 0.01 μF RXN 1 Figure 24. Transformerless Professional Input Circuit TTL/CMOS Gate 0.01 μF RXP CS8427 RXP 75 Ω RXN 0.01 μF Figure 25. Consumer Input Circuit DS477F5 CS8427 RXP 110 Ω Twisted 1 RCA Phono 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 25. CS8427 0.01 μF 110 Ω Twisted 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 may be a good idea to provide the option of grounding or capacitively coupling the shield to the chassis. 0.01 μF RXN Figure 26. TTL/CMOS Input Circuit 51 CS8427 19. APPENDIX B: CHANNEL STATUS AND USER DATA BUFFER MANAGEMENT The CS8427 has a comprehensive channel status (C) and user (U) data buffering scheme, which allows automatic management of channel status blocks and user data. Alternatively, sufficient control and access is provided to allow the user to completely manage the C and U data through the control port. Be aware that the RUN bit should be set to 1 in order to access the C and U data buffer through the control port. 19.1 AES3 Channel Status(C) Bit Management The CS8427 contains sufficient RAM to store a full block of C data for both A and B channels (192x2 = 384 bits), and also 384 bits of U information. The user may read from or write to these RAMs through the control port. The CS8427 manages the flow of channel status data at the block level, meaning that entire blocks of channel status information are buffered at the input, synchronized to the output timebase, and then transmitted. The buffering scheme involves a cascade of 3 block-sized buffers, named D,E and F, as shown in Figure 27. 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 20h) 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 read A 8-bits From AES3 Receiver D Received Data Buffer and writing of the C data. The 3rd buffer (F) is used as the source of C data for the AES3 transmitter. The F buffer accepts block transfers from the E buffer. 19.1.1 Manually accessing the E buffer The user can monitor the data being transferred by reading the E buffer, which is mapped into the register space of the CS8427, through the control port. The user can modify the data to be transmitted by writing to the E buffer. The user can configure the interrupt enable register to cause interrupts to occur whenever “D to E” or “E to F” buffer transfers occur. This allows determination of the allowable time periods to interact with the E buffer. Also provided are “D to E” and “E to F” inhibit bits. The associated buffer transfer is disabled whenever the user sets these bits. These may be used whenever “long” control port interactions are occurring. They can also be used to align the behavior of the buffers with the selected audio data flow. For example, if the audio data flow is serial port in to AES3 out, then it is necessary to inhibit “D toE” transfers, since these would overwrite the desired transmit C data with invalid data. Flowcharts for reading and writing to the E buffer are shown in Figure 28 and Figure 29. For reading, since a D to E interrupt just occurred, then there a substantial time interval until the next D to E transfer (approximately 24 frames worth of time). This is usually plenty of time to access the E data without having to inhibit the next transfer. B 8-bits E 24 words F To AES3 Transmitter Transmit Data Buffer Control Port Figure 27. Channel Status Data Buffer Structure 52 DS477F5 CS8427 For writing, the sequence starts after a E to F transfer, which is based on the output timebase. Since a D to E transfer could occur at any time (this is based on the input timebase), then it is important to inhibit D to E transfers while writing to the E buffer until all writes are complete. Then wait until the next E to F transfer occurs before enabling D to E transfers. This ensures that the data written to the E buffer actually gets transmitted and not overwritten by a D to E transfer. If the channel status block to transmit indicates PRO mode, then the CRCC byte is automatically calculated by the CS8427, and does not have to be written into the last byte of the block by the host microcontroller. 19.1.2 Reserving the first 5 bytes in the E buffer D to E buffer transfers periodically overwrite the data stored in the E buffer. This can be a problem for users who want to transmit certain channel staD to E interrupt occurs Optionally set D to E inhibit Read E data If set, clear D to E inhibit Return Figure 28. Flowchart for Reading the E Buffer E to F interrupt occurs Optionally set E to F inhibit Set D to E inhibit Write E data If set, clear E to F inhibit Wait for E to F transfer Clear D to E inhibit Return tus settings which are different from the incoming settings. In this case, the user would have to superimpose his settings on the E buffer after every D to E overwrite. To avoid this problem, the CS8427 has the capability of reserving the first 5 bytes of the E buffer for user writes only. When this capability is in use, internal D to E buffer transfers will NOT affect the first 5 bytes of the E buffer. Therefore, the user can set values in these first 5 E bytes once, and the settings will persist until the next user change. This mode is enabled by the Channel Status Data Buffer Control register. 19.1.3 Serial Copy Management System (SCMS) In software mode, the CS8427 allows read/modify/write access to all the channel status bits. For consumer mode SCMS compliance, the host microcontroller needs to read and manipulate 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 input pins, or by using the C bit serial input pin. These options are documented in the hardware mode section of this data sheet. 19.1.4 Channel Status Data E Buffer Access The E buffer is organized as 24 x 16-bit words. For each word the MS Byte is the A channel data, and the LS Byte is the B channel data (see Figure 27). There are two methods of accessing this memory, known as one byte mode and two byte mode. The desired mode is selected through a control register bit. One Byte Mode In many applications, the channel status blocks for the A and B channels will be identical. In this situation, if the user reads a byte from one of the channel's blocks, the corresponding byte for the other channel will be the same. Similarly, if the user wrote a byte to one channel's block, it would be necessary to write the same byte to the other block. One byte mode takes advantage of the often identical nature of A and B channel status data. Figure 29. Flowchart for Writing the E Buffer DS477F5 53 CS8427 When reading data in one byte mode, a single byte is returned, which can be from channel A or B data, depending on a register control bit. If a write is being done, the CS8427 expects a single byte to be input to its control port. This byte will be written to both the A and B locations in the addressed word. One byte mode saves the user substantial control port access time, as it effectively accesses 2 bytes worth of information in 1 byte's worth of access time. If the control port's autoincrement addressing is used in combination with this mode, multi-byte accesses such as full-block reads or writes can be done especially efficiently. Two Byte mode There are those applications in which the A and B channel status blocks will not be the same, and the user is interested in accessing both blocks. In these situations, two byte mode should be used to access the E buffer. In this mode, a read will cause the CS8427 to output two bytes from its control port. The first byte out will represent the A channel status data, and the 2nd byte will represent the B channel status data. Writing is similar, in that two bytes must now be input to the CS8427's control port. The A channel status data is first, B channel status data second. 19.2 AES3 User (U) Bit Management The CS8427 U bit manager has two operating modes: transmit all zeros and block mode. 54 19.2.1 Mode 1: Transmit All Zeros Mode 1 causes only zeros to be transmitted in the output U data, regardless of E buffer contents or U data embedded in an input AES3 data stream. This mode is intended for the user who does not want to transceive U data, and simply wants the output U channel to contain no data. 19.2.2 Mode 2: Block Mode Mode 2 is very similar to the scheme used to control the C bits. Entire blocks of U data are buffered from input to output, using a cascade of 3 blocksized RAMs to perform the buffering. The user has access to the second of these 3 buffers, denoted the E buffer, through the control port. Block mode is designed for use in AES3 in, AES3 out situations in which input U data is decoded using a microcontroller through the control port. It is also the only mode in which the user can merge his own U data into the transmitted AES3 data stream. The U buffer access only operates in two byte mode, since there is no concept of A and B blocks for user data. The arrangement of the data is as follows:Bit15[A7]Bit14[B7]Bit13[A6]Bit12[B6]...Bit1[A 0]Bit0[B0]. The arrangement of the data in the each byte is that the MSB is the first received bit and is the first transmitted bit. The first byte read is the first byte received, and the first byte sent is the first byte transmitted. If you read two bytes from the E buffer, you will get the following arrangement: A[7]B[7]A[6]B[6]....A[0]B[0]. DS477F5 CS8427 20. APPENDIX C: PLL FILTER 20.1 General An on-chip Phase Locked Loop (PLL) is used to recover the clock from the incoming data stream. Figure 30 is a simplified diagram of the PLL in these parts. When the PLL is locked to an AES3 input stream, it is updated at each preamble in the AES3 stream. This occurs at twice the sampling frequency, FS. When the PLL is locked to ILRCK, it is updated at FS so that the duty cycle of the input doesn’t affect jitter. 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 33, Figure 34, Figure 35, and Figure 36. In addition, the PLL has been deINPUT Phase Comparator and Charge Pump signed to only use the preambles of the AES3 stream to provide lock update information to the PLL. This results in the PLL being immune to data dependent jitter affects because the AES3 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 AES3 data stream or after enabling the CS8427 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. VCO RMCK Rfilt Cfilt Crip ÷N Figure 30. PLL Block Diagram DS477F5 55 CS8427 External Filter Components 20.2.1 General The PLL behavior is affected by the external filter component values. Figure 5 on page 11 shows the recommended configuration of the two capacitors and one resistor that comprise the PLL filter. In Table 7 and Table 8, the component values shown for the 32 to 96 kHz range have the highest corner frequency jitter attenuation curve, takes the shortest time to lock, and offers the best output jitter performance. The component values shown in Table 6 and Table 8 for the 8 to 96 kHz range allows the lowest input sample rate to be 8 kHz, and increases the lock time of the PLL. Lock times are worst case for an Fsi transition of 96 kHz. 20.2.2 Capacitor Selection 20.2.3 Circuit Board Layout Board layout and capacitor choice affect each other and determine the performance of the PLL. Figure 31 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. RFILT and the other three capacitors 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. VA+ AGND 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 CFILT, an X7R dielectric is preferred. Avoid capacitors with large temperature coefficients, or capacitors with high dielectric constants, that are sensitive to shock and vibration. These include the Z5U and Y5V dielectrics. Crip Rfilt 1000 pF FILT 20.2 .1µF Cfilt Figure 31. Recommended Layout Example 56 DS477F5 CS8427 20.3 Component Value Selection When transitioning from one revision of the part another, component values may need to be changed. While it is mandatory for customers to change the external PLL component values when transitioning from revision A to revision A1 or from revision A to revision A2, customers do not need to change external PLL component values when transitioning from revision A1 to revision A2, unless the part is used in an application that is required to Pre-October 2002 Revision SOIC & TSSOP (10-Digit) pass the AES3 or IEC60958-4 specification for receiver jitter tolerance (see Table 7). 20.3.1 Identifying the Part Revision The first line of the part marking on the package indicates the part number and package type (CS8427-xx). Table 5 shows a list of part revisions and their corresponding second line part marking, which indicates what revision the part is. New SOIC (12-Digit) New TSSOP (10-Digit) A Zxxxxxxxxx ZFBAAXxxxxxx NAAXxxxxxx A1 Rxxxxxxxxx RFBAA1xxxxxx NAA1xxxxxx A2 N/A RFBAA2xxxxxx NAA2xxxxxx Table 5. Second Line Part Marking 20.3.2 Locking to the RXP/RXN Receiver Inputs CS8427 parts that are configured to lock to only the RXP/RXN receiver inputs should use the external PLL component values listed in Table 6 and Table 7. Values listed for the 32 to 96 kHz Fs range will have the highest corner frequency jitter attenuation curve, take the shortest time to lock, and offer the best output jitter performance. Revision RFILT (kΩ) CFILT (μF) CRIP (nF) PLL Lock Time (ms) A 0.909 1.8 33 56 A1 0.4 0.47 47 60 A2 0.4 0.47 47 60 Table 6. Locking to RXP/RXN - Fs = 8 to 96 kHz Revision RFILT (kΩ) CFILT (μF) CRIP (nF) PLL Lock Time (ms) A* 3.0 0.047 2.2 35 A1* 1.2 0.1 4.7 35 A2 1.2 0.1 4.7 35 A2* 1.6 0.33 4.7 35 Table 7. Locking to RXP/RXN - Fs = 32 to 96 kHz * Parts used in applications that are required to pass the AES3 or IEC60958-4 specification for receiver jitter tolerance should use these component values. Please note that the AES3 and IEC60958 specifications do not have allowances for locking to sample rates less than 32 kHz or for locking to the ILRCK input. Also note that many factors can affect jitter performance in a system. Please follow the circuit and layout recommendations outlined previously. DS477F5 57 CS8427 20.3.3 Locking to the ILRCK Input these values. Values listed for the 32 to 96 kHz Fs range will have the highest corner frequency jitter attenuation curve, take the shortest time to lock, and offer the best output jitter performance. CS8427 parts that are configured to lock to the ILRCK input should use the external PLL component values listed in Table 8. Note that parts that need to lock to both ILRCK and RXP/RXN should use Revision Fs Range (kHz) RFILT (kΩ) CFILT (μF) CRIP (nF) PLL Lock Time (ms) A 8 to 96 1.3 2.7 62 120 A 32-96 5.1 0.15 3.9 70 A1/A2 8 to 96 0.3 1.0 100 120 A1/A2 32-96 0.6 0.22 22 70 Table 8. Locking to the ILRCK Input 20.3.4 Jitter Tolerance Shown in Figure 32 is the Receiver Jitter Tolerance template as illustrated in the AES3 and IEC60958- 4 specification. CS8427 parts used with the appropriate external PLL component values (as noted in Table 7) have been tested to pass this template. Figure 32. Jitter Tolerance Template 58 DS477F5 CS8427 20.3.5 Jitter Attenuation noted in Table 7). The AES3 and IEC60958-4 specifications do not have allowances for locking to sample rates less than 32 kHz or for locking to the ILRCK input. These specifications state a maximum of 2 dB jitter gain or peaking. 5 5 0 0 Jitter Attenuation (dB) Jitter Attenuation (dB) Shown in Figure 33, Figure 34, Figure 35, and Figure 36 are jitter attenuation plots for the various revisions of the CS8427 when used with the appropriate external PLL component values (as −5 −10 −5 −10 −15 −15 −20 −1 10 0 10 1 10 2 10 Jitter Frequency (Hz) 3 10 4 10 −20 −1 10 5 10 0 10 5 5 0 0 −5 −5 −10 −15 −20 −20 0 10 1 10 2 10 Jitter Frequency (Hz) 3 10 4 10 Figure 35. Revision A2 using A1 values DS477F5 3 10 4 10 5 10 −10 −15 −25 −1 10 2 10 Jitter Frequency (Hz) Figure 34. Revision A1 Jitter Attenuation (dB) Jitter Attenuation (dB) Figure 33. Revision A 1 10 5 10 −25 −1 10 0 10 1 10 2 10 Jitter Frequency (Hz) 3 10 4 10 5 10 Figure 36. Revision A2 using A2* values 59 CS8427 21. REVISION HISTORY Release Date Changes PP1 November 1999 1st Preliminary Release PP2 November 2000 2nd Preliminary Release PP3 May 2001 3rd Preliminary Release PP4 February 2003 4th Preliminary Release F1 January 2004 Final Release Updated “Appendix C: PLL Filter” on page 55 to include information from errata ER477E2 F2 July 2004 F3 January 2005 -Changed format of Figures 15 and 16 on page 23 and page 24. -Corrected AES3 Direct format in figure 16 on page 24 and text reference to AES3 Direct format on page 15. -Changed description of DETC, EFTC, DETU, and EFTU bits in “Control Port Register Bit Definitions” on page 32 and page 33. F4 October 2009 Updated and moved “Ordering Information” on page 49 F5 May 2010 Add lead free ordering information Updated description in “OMCK/RMCK Ratio (1Eh) (Read Only)” on page 38 Table 9. Revision History Contacting Cirrus Logic Support For all product questions and inquiries contact a Cirrus Logic Sales Representative. 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All other brand and product names in this document may be trademarks or service marks of their respective owners. SPI is a trademark of Motorola Inc. AC-3 is a registered trademark of Dolby Laboratories Licensing, Inc. 60 DS477F5