® PCM 1601 PCM 160 0 PCM1600 PCM1601 For most current data sheet and other product information, visit www.burr-brown.com 24-Bit, 96kHz Sampling, 6-Channel, Enhanced Multi-Level, Delta-Sigma DIGITAL-TO-ANALOG CONVERTER TM FEATURES APPLICATIONS ● 24-BIT RESOLUTION ● INTEGRATED A/V RECEIVERS ● ANALOG PERFORMANCE: Dynamic Range: 105dB typ SNR: 104dB typ THD+N: 0.0018% typ Full-Scale Output: 3.1Vp-p typ ● DVD MOVIE AND AUDIO PLAYERS ● HDTV RECEIVERS ● CAR AUDIO SYSTEMS ● DVD ADD-ON CARDS FOR HIGH-END PCs ● DIGITAL AUDIO WORKSTATIONS ● 8x OVERSAMPLING INTERPOLATION FILTER: Stopband Attenuation: –82dB Passband Ripple: ±0.002dB ● OTHER MULTI-CHANNEL AUDIO SYSTEMS ● SAMPLING FREQUENCY: 10kHz to 100kHz ● ACCEPTS 16, 18, 20, AND 24-BIT AUDIO DATA ● DATA FORMATS: Standard, I2S, and Left-Justified ● SYSTEM CLOCK: 256fS, 384fS, 512fS, or 768fS ● USER-PROGRAMMABLE FUNCTIONS: Digital Attenuation: 0dB to –63dB, 0.5dB/Step Soft Mute Zero Detect Mute Zero Flags for Each Output Channel Digital De-Emphasis Digital Filter Roll-Off: Sharp or Slow ● DUAL SUPPLY OPERATION: +5V Analog, +3.3V Digital ● 5V TOLERANT DIGITAL LOGIC INPUTS ● PACKAGES(1): LQFP-48 (PCM1600) and MQFP-48 (PCM1601) DESCRIPTION The PCM1600(1) and PCM1601(1) are CMOS monolithic integrated circuits which feature six 24-bit audio digital-to-analog converters and support circuitry in either a LQFP-48 or MQFP-48 package. The digitalto-analog converters utilize Burr-Brown’s enhanced multi-level, delta-sigma architecture, which employ 4th-order noise shaping and 8-level amplitude quantization to achieve excellent signal-to-noise performance and a high tolerance to clock jitter. The PCM1600 and PCM1601 accept industry-standard audio data formats with 16- to 24-bit audio data. Sampling rates up to 100kHz are supported. A full set of user-programmable functions are accessible through a 4-wire serial control port which supports register write and readback functions. NOTE: (1) The PCM1600 and PCM1601 utilize the same die and are electrically the same. All references to the PCM1600 apply equally to the PCM1601. International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 Twx: 910-952-1111 • Internet: http://www.burr-brown.com/ • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132 © 1999 Burr-Brown Corporation SBAS116 PDS-1523C Printed in U.S.A. March, 2000 SPECIFICATIONS All specifications at +25°C, +VCC = +5V, +VDD = +3.3V, system clock = 384fS (fS = 44.1kHz) and 24-bit data, unless otherwise noted. PCM1600Y, PCM1601Y PARAMETER CONDITIONS MIN RESOLUTION TYP MAX 24 DATA FORMAT Audio Data Interface Formats Data Bit Length Audio Data Format Sampling Frequency (fS) System Clock Frequency User Selectable User Selectable DIGITAL INPUT/OUTPUT Logic Family Input Logic Level VIH VIL Input Logic Current IIH(1) IIL(1) IIH(2) IIL(2) Output Logic Level VOH(3) VOL(3) VOH(4) VOL(4) DYNAMIC PERFORMANCE(5) THD+N, VOUT = 0dB VOUT = –60dB Dynamic Range Signal-to-Noise Ratio(6) Channel Separation Level Linearity Error UNITS Bits Standard, I2S, Left-Justified 16, 18, 20, 24-Bit MSB-First, Binary Two’s Complement 10 100 256, 384, 512, 768fS kHz TTL-Compatible 2.0 VIN = VDD VIN = 0V VIN = VDD VIN = 0V 65 IOH = –2mA IOL = +2mA IOH = –4mA IOL = +4mA ANALOG OUTPUT Output Voltage Center Voltage Load Impedance DIGITAL FILTER PERFORMANCE Filter Characteristics 1, Sharp Roll-Off Passband Stopband Passband Ripple Stopband Attenuation Filter Characteristics 2, Slow Roll-Off Passband Stopband Passband Ripple Stopband Attenuation Delay Time De-Emphasis Error ANALOG FILTER PERFORMANCE Frequency Response 0.1 –0.1 100 –0.1 µA µA µA µA 1.0 2.4 1.0 100 98 96 VO = 0.5VCC at Bipolar Zero Full Scale (0dB) AC Load 0.0018 0.0035 0.65 0.75 105 104 104 103 102 101 ±0.5 0.0045 62% of VCC 50% VCC Vp-p V kΩ 0.454fS 0.490fS 0.546fS ±0.002 –75 –82 ±0.002dB –3dB 0.274fS 0.454fS f = 20kHz f = 44kHz 2 Hz Hz Hz dB dB dB 34/fS ±0.1 Hz Hz Hz dB dB sec dB –0.03 –0.20 dB dB 0.732fS Stopband = 0.732fS % % % % dB dB dB dB dB dB dB % of FSR % of FSR mV ±0.002dB –3dB Stopband = 0.546fS Stopband = 0.567fS V V V V ±1.0 ±1.0 ±30 5 ® PCM1600, PCM1601 V V 2.4 fS = 44.1kHz fS = 96kHz fS = 44.1kHz fS = 96kHz EIAJ, A-Weighted, fS =44.1kHz A-Weighted, fS = 96kHz EIAJ, A-Weighted, fS =44.1kHz A-Weighted, fS = 96kHz fS = 44.1kHz fS = 96kHz VOUT = –90dB DC ACCURACY Gain Error Gain Mismatch, Channel-to-Channel Bipolar Zero Error 0.8 ±0.002 –82 SPECIFICATIONS (Cont.) All specifications at +25°C, +VCC = +5V, +VDD = +3.3V, system clock = 384fS (fS = 44.1kHz) and 24-bit data, unless otherwise noted. PCM1600Y, PCM1601Y PARAMETER CONDITIONS POWER SUPPLY REQUIREMENTS Voltage Range, VDD VCC Supply Current, IDD (7) MIN TYP MAX UNITS +3.0 +4.5 +3.3 +5.0 20 42 40 42 266 349 +3.6 +5.5 28 V V mA mA mA mA mW mW fS = 44.1kHz fS = 96kHz fS = 44.1kHz fS = 96kHz fS = 44.1kHz fS = 96kHz ICC Power Dissipation TEMPERATURE RANGE Operation Storage Thermal Resistance, θJA 0 –55 56 409 +70 +125 100 °C °C °C/W NOTES: (1) Pins 38, 40, 41, 45-47 (SCLKI, BCK, LRCK, DATA1, DATA2, DATA3). (2) Pins 34-37 (MDI, MC, ML, RST). (3) Pins 1-6, 48 (ZERO1-6, ZEROA). (4) Pin 39 (SCLKO). (5) Analog performance specifications are tested with Shibasoku #725 THD Meter 400Hz HPF, 30kHz LPF on, average mode with 20kHz bandwidth limiting. The load connected to the analog output is 5kΩ or larger, AC-coupled. (6) SNR is tested with Infinite Zero Detection off. (7) CLKO is disabled. ABSOLUTE MAXIMUM RATINGS ELECTROSTATIC DISCHARGE SENSITIVITY Power Supply Voltage, VDD .............................................................. +4.0V VCC .............................................................. +6.5V +VCC to +VDD Difference ................................................................... ±0.1V Digital Input Voltage ........................................................... –0.2V to +5.5V Digital Output Voltage(1) ........................................... –0.2V to (VDD + 0.2V) Input Current (except power supply) ............................................... ±10mA Power Dissipation .......................................................................... 650mW Operating Temperature Range ............................................. 0°C to +70°C Storage Temperature ...................................................... –55°C to +125°C Lead Temperature (soldering, 5s) ................................................ +260°C Package Temperature (IR reflow, 10s) .......................................... +235°C This integrated circuit can be damaged by ESD. Burr-Brown recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. NOTE: (1) Pin 33 (MDO) when output is disabled. PACKAGE/ORDERING INFORMATION PRODUCT PACKAGE PACKAGE DRAWING NUMBER PCM1600Y 48-Lead LQFP 340 0°C to +70°C PCM1600Y " " " " 48-Lead MQFP 359 0°C to +70°C PCM1601Y " " " " " PCM1601Y " SPECIFIED TEMPERATURE RANGE PACKAGE MARKING ORDERING NUMBER(1) TRANSPORT MEDIA PCM1600Y PCM1600Y/2K PCM1601Y PCM1601Y/1K 250-Piece Tray Tape and Reel 84-Piece Tray Tape and Reel NOTE: (1) Models with a slash (/) are available only in Tape and Reel in the quantities indicated (e.g., /2K indicates 2000 devices per reel). Ordering 2000 pieces of “PCM1600Y/2K” will get a single 2000-piece Tape and Reel. The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant any BURR-BROWN product for use in life support devices and/or systems. ® 3 PCM1600, PCM1601 BLOCK DIAGRAM DAC Output Amp and Low-Pass Filter DAC Output Amp and Low-Pass Filter DAC Output Amp and Low-Pass Filter BCK VOUT1 LRCK DATA1 DATA2 Audio Serial I/F 8x Oversampling Digital Filter with Function Controller DATA3 TEST Enhanced Multi-level Delta-Sigma Modulator VOUT2 VOUT3 VCOM1 VCOM2 Output Amp and Low-Pass Filter DAC VOUT4 RST ML MC Serial Control I/F Output Amp and Low-Pass Filter DAC VOUT5 MDI MDO Output Amp and Low-Pass Filter DAC VOUT6 System Clock VCC1-6 AGND1-6 VCC0 AGND0 VDD DGND ZERO6 ZERO5 ZERO4 ZERO3 ZERO2 ZEROA SCLKO VCC Power Supply Zero Detect AGND System Clock Manager ZERO1 SCLKI PIN CONFIGURATION DATA3 DATA2 DATA1 DGND VDD TEST LRCK BCK SCLKO SCLKI RST LQFP, MQFP ZEROA Top View 48 47 46 45 44 43 42 41 40 39 38 37 ZERO1 1 36 ML ZERO2 2 35 MC ZERO3 3 34 MDI ZERO4 4 33 MDO ZERO5 5 32 NC ZERO6 6 AGND 7 VCC 8 29 AGND0 VOUT6 9 28 VCC1 31 NC PCM1600 PCM1601 30 VCC0 19 20 21 22 23 24 VCC3 18 AGND3 17 VCC4 16 AGND4 15 VCC5 14 AGND5 13 VCC6 25 AGND2 AGND6 VOUT3 12 VCOM1 26 VCC2 VCOM2 VOUT4 11 VOUT1 27 AGND1 VOUT2 VOUT5 10 ® PCM1600, PCM1601 4 PIN ASSIGNMENTS PIN NAME I/O 1 ZERO1 O Zero Data Flag for VOUT1. DESCRIPTION 2 ZERO2 O Zero Data Flag for VOUT2. 3 ZERO3 O Zero Data Flag for VOUT3. 4 ZERO4 O Zero Data Flag for VOUT4. 5 ZERO5 O Zero Data Flag for VOUT5. 6 ZERO6 O Zero Data Flag for VOUT6. 7 AGND — Analog Ground 8 VCC — Analog Power Supply, +5V 9 VOUT6 O Voltage Output of Audio Signal Corresponding to Rch on DATA3. 10 VOUT5 O Voltage Output of Audio Signal Corresponding to Lch on DATA3. 11 VOUT4 O Voltage Output of Audio Signal Corresponding to Rch on DATA2. 12 VOUT3 O Voltage Output of Audio Signal Corresponding to Lch on DATA2. 13 VOUT2 O Voltage Output of Audio Signal Corresponding to Rch on DATA1. 14 VOUT1 O Voltage Output of Audio Signal Corresponding to Lch on DATA1. 15 VCOM2 O Common Voltage Output. This pin should be bypassed with a 10µF capacitor to AGND. 16 VCOM1 O Common Voltage Output. This pin should be bypassed with a 10µF capacitor to AGND. 17 AGND6 — Analog Ground Analog Power Supply, +5V 18 VCC6 — 19 AGND5 — Analog Ground 20 VCC5 — Analog Power Supply, +5V 21 AGND4 — Analog Ground 22 VCC4 — Analog Power Supply, +5V 23 AGND3 — Analog Ground 24 VCC3 — Analog Power Supply, +5V 25 AGND2 — Analog Ground 26 VCC2 — Analog Power Supply, +5V 27 AGND1 — Analog Ground 28 VCC1 — Analog Power Supply, +5V 29 AGND0 — Analog Ground 30 VCC0 — Analog Power Supply, +5V 31 NC — No Connection. Must be open. 32 NC — No Connection. Must be open. 33 MDO O Serial Data Output for Function Register Control Port (3) 34 MDI I Serial Data Input for Function Register Control Port(1) 35 MC I Shift Clock for Function Register Control Port(1) 36 ML I Latch Enable for Function Register Control Port(1) 37 RST I System Reset, Active LOW(1) 38 SCLKI I System Clock In. Input frequency is 256, 384, 512 or 768f S.(2) 39 SCLKO O Buffered Clock Output. Output frequency is 256, 384, 512, or 768fS and one-half of 256, 384, 512, or 768fS. 40 BCK I Shift Clock Input for Serial Audio Data(2) 41 LRCK I 42 TEST — Left and Right Clock Input. This clock is equal to the sampling rate, fS. (2) Test Pin. This pin should be connected to DGND.(1) 43 VDD — Digital Power Supply, +3.3V 44 DGND — Digital Ground for +3.3V 45 DATA1 I Serial Audio Data Input for VOUT1 and VOUT2(2) 46 DATA2 I Serial Audio Data Input for VOUT3 and VOUT4(2) 47 DATA3 I Serial Audio Data Input for VOUT5 and VOUT6(2) 48 ZEROA I Zero Data Flag. Logical “AND” of ZERO1 through ZERO6. NOTES: (1) Schmitt-Trigger input with internal pull-down, 5V tolerant. (2) Schmitt-Trigger input, 5V tolerant. (3) Tri-state output. ® 5 PCM1600, PCM1601 TYPICAL PERFORMANCE CURVES All specifications at +25°C, VCC = 5V, VDD = 3.3V, SYSCLK = 384fS (fS = 44.1kHz), and 24-bit input data, unless otherwise noted. DIGITAL FILTER Digital Filter (De-Emphasis Off, fS = 44.1kHz) FREQUENCY RESPONSE (Sharp Roll-Off) PASSBAND RIPPLE (Sharp Roll-Off) 0.003 0 –20 0.002 Amplitude (dB) Amplitude (dB) –40 –60 –80 –100 0.001 0 –0.001 –120 –0.002 –140 –160 –0.003 0 0.5 1 1.5 2 2.5 3 3.5 4 0 0.1 0.2 0.3 0.4 0.5 Frequency (x fS) Frequency (x fS) FREQUENCY RESPONSE (Slow Roll-Off) TRANSITION CHARACTERISTICS (Slow Roll-Off) 0 0 –2 –20 –4 Amplitude (dB) Amplitude (dB) –40 –60 –80 –100 –6 –8 –10 –12 –14 –16 –120 –18 –140 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 –20 4.0 0 0.1 0.2 Frequency (x fS) DE-EMPHASIS FREQUENCY RESPONSE (fS = 32kHz) Level (dB) Level (dB) De-Emphasis Error 0 –2 –4 –6 –8 –10 0 2 4 6 8 10 12 0 14 Level (dB) Level (dB) 2 4 6 8 10 12 2 4 14 16 18 0 20 Level (dB) Level (dB) 2 4 6 8 10 12 14 6 8 10 12 14 2 4 6 8 10 12 14 16 18 20 20 22 Frequency (kHz) DE-EMPHASIS FREQUENCY RESPONSE (fS = 48kHz) 0 0.6 DE-EMPHASIS ERROR (fS = 44.1kHz) 0.5 0.3 0.1 –0.1 –0.3 –0.5 Frequency (kHz) 0 –2 –4 –6 –8 –10 0.5 Frequency (kHz) DE-EMPHASIS FREQUENCY RESPONSE (fS = 44.1kHz) 0 0.4 DE-EMPHASIS ERROR (fS = 32kHz) 0.5 0.3 0.1 –0.1 –0.3 –0.5 Frequency (kHz) 0 –2 –4 –6 –8 –10 0.3 Frequency (x fS) 16 18 20 0 22 2 4 6 8 10 12 14 Frequency (kHz) Frequency (kHz) ® PCM1600, PCM1601 DE-EMPHASIS ERR0R (fS = 48kHz) 0.5 0.3 0.1 –0.1 –0.3 –0.5 6 16 18 TYPICAL PERFORMANCE CURVES (Cont.) All specifications at +25°C, VCC = 5V, VDD = 3.3V, SYSCLK = 384fS (fS = 44.1kHz), and 24-bit input data, unless otherwise noted. ANALOG DYNAMIC PERFORMANCE Supply Voltage Characteristics TOTAL HARMONIC DISTORTION + NOISE vs VCC (VDD = 3.3V) 10 110 108 THD+N (%) 1 Dynamic Range (dB) 96kHz, 384fS –60dB 44.1kHz, 384fS 0.1 96kHz, 384fS 0.01 DYNAMIC RANGE vs VCC (VDD = 3.3V) 44.1kHz, 384fS 106 104 96kHz, 384fS 102 100 98 0dB 44.1kHz, 384fS 0.001 4.0 110 4.5 96 5.0 5.5 4.0 6.0 5.0 5.5 VCC (V) SIGNAL-TO-NOISE RATIO vs VCC (VDD = 3.3V) CHANNEL SEPARATION vs VCC (VDD = 3.3V) 110 6.0 108 106 Channel Separation (dB) 108 SNR (dB) 4.5 VCC (V) 44.1kHz, 384fS 104 102 96kHz, 384fS 100 106 104 44.1kHz, 384fS 102 100 96kHz, 384fS 98 98 96 96 4.0 4.5 5.0 5.5 4.0 6.0 4.5 5.0 5.5 6.0 VCC (V) VCC (V) ® 7 PCM1600, PCM1601 TYPICAL PERFORMANCE CURVES (Cont.) All specifications at +25°C, VCC = 5V, VDD = 3.3V, SYSCLK = 384fS (fS = 44.1kHz), and 24-bit input data, unless otherwise noted. ANALOG DYNAMIC PERFORMANCE (con.t) Temperature Characteristics TOTAL HARMONIC DISTORTION + NOISE vs TEMPERATURE (VDD = 3.3V) 110 10 108 THD+N (%) Dynamic Range (dB) 96kHz, 384fS 1 –60dB 44.1kHz, 384fS 0.1 96kHz, 384fS 0.01 44.1kHz, 384fS 44.1kHz, 384fS 106 104 102 96kHz, 384fS 100 98 0dB 96 0.001 –25 0 25 50 75 –25 100 0 25 50 75 Temperature (°C) Temperature (°C) SIGNAL-TO-NOISE RATIO vs TEMPERATURE (VDD = 3.3V) CHANNEL SEPARATION vs TEMPERATURE (VDD = 3.3V) 110 108 108 Channel Separation (dB) 110 106 SNR (dB) DYNAMIC RANGE vs TEMPERATURE (VDD = 3.3V) 44.1kHz, 384fS 104 102 96kHz, 384fS 100 100 106 104 44.1kHz, 384fS 102 100 96kHz, 384fS 98 98 96 96 –25 0 25 50 75 –25 100 ® PCM1600, PCM1601 0 25 50 Temperature (°C) Temperature (°C) 8 75 100 SYSTEM CLOCK OUTPUT SYSTEM CLOCK AND RESET FUNCTIONS A buffered version of the system clock input is available at the SCLKO output (pin 39). SCLKO can operate at either full (fSCLKI) or half (fSCLKI/2) rate. The SCLKO output frequency may be programmed using the CLKD bit of Control Register 9. The SCLKO output pin can also be enabled or disabled using the CLKE bit of Control Register 9. The default is SCLKO enabled. SYSTEM CLOCK INPUT The PCM1600 and PCM1601 require a system clock for operating the digital interpolation filters and multi-level delta-sigma modulators. The system clock is applied at the SCLKI input (pin 38). For sampling rates from 10kHz through 64kHz, the system clock frequency may be 256, 384, 512, or 768 times the sampling frequency, fS. For sampling rates above 64kHz, the system clock frequency may be 256, 384, or 512 times the sampling frequency. Table I shows examples of system clock frequencies for common audio sampling rates. POWER-ON AND EXTERNAL RESET FUNCTIONS The PCM1600 includes a power-on reset function. Figure 2 shows the operation of this function. The system clock input at SCLKI should be active for at least one clock period prior to VDD = 2.0V. With the system clock active and VDD > 2.0V, the power-on reset function will be enabled. The initialization sequence requires 1024 system clocks from the time VDD > 2.0V. After the initialization period, the PCM1600 will be set to its reset default state, as described in the Mode Control Register section of this data sheet. Figure 1 shows the timing requirements for the system clock input. For optimal performance, it is important to use a clock source with low phase jitter and noise. Burr-Brown’s PLL1700 multi-clock generator is an excellent choice for providing the PCM1600 system clock source. The PCM1600 also includes an external reset capability using the RST input (pin 37). This allows an external controller or master reset circuit to force the PCM1600 to initialize to its reset default state. For normal operation, RST should be set to a logic ‘1’. SYSTEM CLOCK FREQUENCY (MHz) SCLKI (Pin 38) SAMPLING FREQUENCY (fS) 256fS 384fS 512fS 768fS 22.05kHz 5.6448 8.4670 11.2896 16.9340 24kHz 6.1440 9.2160 12.2880 18.4320 32kHz 8.1920 12.2880 16.3840 24.5760 44.1kHz 11.2896 16.9340 22.5792 33.8688 48kHz 12.2880 18.4320 24.5760 36.8640 64kHz 16.3840 24.5760 32.7680 49.1520 88.2kHz 22.5792 33.8688 45.1584 See Note 1 96kHz 24.5760 36.8640 49.1520 See Note 1 Figure 3 shows the external reset operation and timing. The RST pin is set to logic ‘0’ for a minimum of 20ns. The RST pin is then set to a logic ‘1’ state, which starts the initialization sequence, which lasts for 1024 system clock periods. After the initialization sequence is completed, the PCM1600 will be set to its reset default state, as described in the Mode Control Registers section of this data sheet. NOTE: (1) The 768fS system clock rate is not supported for fS > 64kHz. TABLE I. System Clock Rates for Common Audio Sampling Frequencies. tSCLKIH 2.0V “H” SCLKI 0.8V “L” fSCLKI tSCLKIH System Clock Pulse Width High tSCLKIH System Clock Pulse Width Low tSCLKIL : 7ns min : 7ns min FIGURE 1. System Clock Input Timing. ® 9 PCM1600, PCM1601 2.4V 2.0V 1.6V VCC = VDD Reset Reset Removal Internal Reset 1024 system clocks System Clock (SCLKI) FIGURE 2. Power-On Reset Timing. RST tRST(1) Reset Reset Removal Internal Reset 1024 system clocks System Clock (SCLKI) NOTE: (1) tRST = 20ns min. FIGURE 3. External Reset Timing. default data format is 24-bit Standard. All formats require Binary Two’s Complement, MSB-first audio data. Figure 5 shows a detailed timing diagram for the serial audio interface. The external reset is especially useful in applications where there is a delay between PCM1600 power up and system clock activation. In this case, the RST pin should be held at a logic ‘0’ level until the system clock has been activated. DATA1, DATA2 and DATA3 each carry two audio channels, designated as the Left and Right channels. The Left channel data always precedes the Right channel data in the serial data stream for all data formats. Table II shows the mapping of the digital input data to the analog output pins. AUDIO SERIAL INTERFACE The audio serial interface for the PCM1600 is comprised of a 5-wire synchronous serial port. It includes LRCK (pin 41), BCK (pin 40), DATA1 (pin 45), DATA2 (pin 46) and DATA3 (pin 47). BCK is the serial audio bit clock, and is used to clock the serial data present on DATA1, DATA2 and DATA3 into the audio interface’s serial shift registers. Serial data is clocked into the PCM1600 on the rising edge of BCK. LRCK is the serial audio left/right word clock. It is used to latch serial data into the serial audio interface’s internal registers. CHANNEL DATA1 Left ANALOG OUTPUT VOUT1 DATA1 Right VOUT2 DATA2 Left VOUT3 DATA2 Right VOUT4 DATA3 Left VOUT5 DATA3 Right VOUT6 TABLE II. Audio Input Data to Analog Output Mapping. Both LRCK and BCK must be synchronous to the system clock. Ideally, it is recommended that LRCK and BCK be derived from the system clock input or output, SCLKI or SCLKO. The left/right clock, LRCK, is operated at the sampling frequency (fS). The bit clock, BCK, may be operated at 48 or 64 times the sampling frequency. SERIAL CONTROL INTERFACE The serial control interface is a 4-wire synchronous serial port which operates asynchronously to the serial audio interface. The serial control interface is utilized to program and read the on-chip mode registers. The control interface includes MDO (pin 33), MDI (pin 34), MC (pin 35), and ML (pin 36). MDO is the serial data output, used to read back the values of the mode registers; MDI is the serial data input, used to program the mode registers; MC is the serial bit clock, used to shift data in and out of the control port and ML is the control port latch clock. AUDIO DATA FORMATS AND TIMING The PCM1600 supports industry-standard audio data formats, including Standard, I2S, and Left-Justified. The data formats are shown in Figure 4. Data formats are selected using the format bits, FMT[2:0], in Control Register 9. The ® PCM1600, PCM1601 DATA INPUT 10 11 PCM1600, PCM1601 ® 16 17 18 18 19 20 22 23 24 18-Bit Right-Justified DATA1-DATA3 20-Bit Right-Justified DATA1-DATA3 24-Bit Right-Justified DATA1-DATA3 MSB 1 2 3 4 5 MSB 1 2 3 MSB 1 2 Lch 3 MSB 1 1 2 3 FIGURE 4. Audio Data Input Formats. DATA1-DATA3 BCK (= 48fS or 64fS) LRCK MSB 1 2 3 Lch (3) 24-Bit I2S Data Format; Lch = LOW, Rch = HIGH DATA1-DATA3 BCK (= 48fS or 64fS) LRCK 22 22 Lch LSB 23 24 23 24 (2) 24-Bit Left-Justified Data Format; Lch = HIGH, Rch = LOW 14 15 16 16-Bit Right-Justified DATA1-DATA3 BCK (= 48fS or 64fS) LRCK (1) Standard Data Format; Lch = HIGH, Rch = LOW 2 3 1/fS 2 MSB 1 2 MSB 1 1/fS 3 3 LSB 22 23 24 LSB 18 19 20 LSB 16 17 18 LSB 14 15 16 MSB 1 1/fS Rch 2 3 22 22 Rch 4 LSB 23 24 2 LSB 23 24 5 MSB 1 3 MSB 1 2 Rch 3 MSB 1 1 2 2 3 LSB 22 23 24 LSB 18 19 20 LSB 16 17 18 LSB 14 15 16 LRCK 50% of VDD tBCH tBCL tLB BCK 50% of VDD tBCY tBL 50% of VDD DATA1-DATA3 tDH tDS SYMBOL tBCY tBCH tBCL tBL tLB tDS tDH PARAMETER MIN BCK Pulse Cycle Time BCK High Level Time BCK Low Level Time BCK Rising Edge to LRCK Edge LRCK Falling Edge to BCK Rising Edge DIN Set Up Time DIN Hold Time MAX UNITS 48 or 64fS (1) 50 50 30 30 30 20 ns ns ns ns ns ns NOTE: (1) fS is the sampling frequency (e.g., 44.1kHz, 48kHz, 96kHz, etc.) FIGURE 5. Audio Interface Timing. MSB R/W LSB IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 D7 D6 D5 D4 Register Index (or Address) D3 D2 D5 D4 D3 D2 D1 D0 Register Data Read/Write Operation 0 = Write Operation 1 = Read Operation (register index is ignored) FIGURE 6. Control Data Word Format for MDI. ML MC MDI X 0 IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 D7 D6 D5 D4 D3 D2 D1 D0 X X D15 D14 FIGURE 7. Write Operation Timing. REGISTER WRITE OPERATION SINGLE REGISTER READ OPERATION All Write operations for the serial control port use 16-bit data words. Figure 6 shows the control data word format. The most significant bit is the Read/Write (R/W) bit. When set to ‘0’, this bit indicates a Write operation. There are seven bits, labeled IDX[6:0], that set the register index (or address) for the Write operation. The least significant eight bits, D[7:0], contain the data to be written to the register specified by IDX[6:0]. Read operations utilize the 16-bit control word format shown in Figure 6. For Read operations, the Read/Write (R/W) bit is set to ‘1’. Read operations ignore the index bits, IDX[6:0], of the control data word. Instead, the REG[6:0] bits in Control Register 11 are used to set the index of the register that is to be read during the Read operation. Bits IDX[6:0] should be set to 00H for Read operations. Figure 8 details the Read operation. First, Control Register 11 must be written with the index of the register to be read back. Additionally, the INC bit must be set to logic ‘0’ in order to disable the Auto-Increment Read function. The Read cycle is then initiated by setting ML to logic ‘0’ and setting the R/W bit of the control data word to logic ‘1’, indicating a Read operation. MDO remains at a high-impedance state until the last 8 bits of the 16-bit read cycle, which Figure 7 shows the functional timing diagram for writing the serial control port. ML is held at a logic ‘1’ state until a register needs to be written. To start the register write cycle, ML is set to logic ‘0’. Sixteen clocks are then provided on MC, corresponding to the 16-bits of the control data word on MDI. After the sixteenth clock cycle has completed, ML is set to logic ‘1’ to latch the data into the indexed mode control register. ® PCM1600, PCM1601 12 13 PCM1600, PCM1601 ® I O I O I O I O Write 0 0 X = Don't care 0 0 0 1 1 0 1 0 0 0 0 High Impedance 0 0 0 D7 X D6 X D5 X D3 X INDEX “1” D4 X D2 X FIGURE 9. Read Operation Timing with INC = 1 (Auto-Increment Read). MDO MDI MC ML D1 X High Impedance Read Register Index D0 X X X D7 REG6 REG5 REG4 REG3 REG2 REG1 REG0 Writing Register 11 with INC and REG[6:0] Data 1 FIGURE 8. Read Operation Timing with INC = 0 (Single Register Read). MDO MDI MC ML D6 X X D4 X D3 X Read 0 0 X 0 D2 INDEX “N – 1” D5 X 1 D1 X 0 D0 X 0 0 X D7 X D6 X D7 D5 X X X X X X X D6 D3 X INDEX “N” D4 X D5 D2 X D4 D1 X D3 D0 X D2 D0 High Impedance X D1 Data from Register Indexed by REG[6:0] X Register Read Cycle 0 corresponds to the 8 data bits of the register indexed by the REG[6:0] bits of Control Register 11. The Read cycle is completed when ML is set to ‘1’, immediately after the MC clock cycle for the least significant bit of indexed control register has completed. pin. The Read cycle starts by setting the R/W bit of the control word to ‘1’, and setting all of the IDX[6:0] bits to ‘0.’. All subsequent bits input on the MDI are ignored while ML is set to ‘0.’ For the first 8 clocks of the Read cycle, MDO is set to a high-impedance state. This is followed by a sequence of 8-bit words, each corresponding the data contained in Control Registers 1 through N, where N is defined by the REG[6:0] bits in Control Register 11. The Read cycle is completed when ML is set to ‘1’, immediately after the MC clock cycle for the least significant bit of Control Register N has completed. AUTO-INCREMENT READ OPERATION The Auto-Increment Read function allows for multiple registers to be read sequentially. The Auto-Increment Read function is enabled by setting the INC bit of Control Register 11 to ‘1’. The sequence always starts with Register 1, and ends with the register indexed by the REG[6:0] bits in Control Register 11. CONTROL INTERFACE TIMING REQUIREMENTS Figure 10 shows a detailed timing diagram for the Serial Control interface. Pay special attention to the setup and hold times, as well as tMLS and tMLH, which define minimum delays between edges of the ML and MC clocks. These timing parameters are critical for proper control port operation. Figure 9 shows the timing for the Auto-Increment Read operation. The operation begins by writing Control Register 11, setting INC to ‘1’ and setting REG[6:0] to the last register to be read in the sequence. The actual Read operation starts on the next HIGH to LOW transition of the ML tMHH 50% of VDD ML tMLS tMCH tMCL tMLH 50% of VDD MC tMCY LSB MDI 50% of VDD tMOS tMDS tMCH LSB 50% of VDD MDO SYMBOL tMCY tMCL tMCH tMHH tMLS tMLH tMDI tMDS tMOS PARAMETER MIN MC Pulse Cycle Time MC Low Level Time MC High Level Time ML High Level Time ML Falling Edge to MC Rising Edge ML Hold Time(1) Hold Time MDL Set Up Time MC Falling Edge to MDSO Stable 100 50 50 300 20 20 15 20 NOTE: (1) MC rising edge for LSB to ML rising edge. FIGURE 10. Control Interface Timing. ® PCM1600, PCM1601 14 MAX UNITS 30 ns ns ns ns ns ns ns ns ns MODE CONTROL REGISTERS Register Map User-Programmable Mode Controls The PCM1600 includes a number of user-programmable functions which are accessed via control registers. The registers are programmed using the Serial Control Interface which was previously discussed in this data sheet. Table III lists the available mode control functions, along with their reset default conditions and associated register index. The mode control register map is shown in Table IV. Each register includes a R/W bit, which determines whether a register read (R/W =1) or write (R/W = 0) operation is performed. Each register also includes an index (or address) indicated by the IDX[6:0] bits. FUNCTION Reserved Registers Registers 0 and 12 are reserved for factory use. To ensure proper operation, the user should not write or read these registers. RESET DEFAULT CONTROL REGISTER INDEX, IDX[6:0] Digital Attenuation Control, 0dB to –63dB in 0.5dB Steps 0dB, No Attenuation 1 through 6 01H - 07H Digital Attenuation Load Control Data Load Disabled 7 07H Digital Attenuation Rate Select 2/fS 7 07H Soft Mute Control DAC 1-6 Operation Control Mute Disabled 7 07H DAC 1-6 Enabled 8 08H Infinite Zero Detect Mute Disabled 8 08H 24-Bit Standard Format 9 09H Digital Filter Roll-Off Control Sharp Roll-Off 9 09H SCLKO Frequency Selection Full Rate (= fSCLKI) 9 09H Audio Data Format Control SCLKO Output Enable De-Emphasis Function Control SCLKO Enabled 9 09H De-Emphasis Disabled 10 0AH De-Emphasis Sample Rate Selection 44.1kHz 10 0AH Read Register Index Control REG[6:0] = 01H 11 0BH Read Auto-Increment Control Auto-Increment Disabled 11 0BH TABLE III. User-Programmable Mode Controls. B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 Register 0 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 N/A N/A N/A N/A N/A N/A N/A N/A Register 1 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT17 AT16 AT15 AT14 AT13 AT12 AT11 AT10 Register 2 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT27 AT26 AT25 AT24 AT23 AT22 AT21 AT20 Register 3 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT37 AT36 AT35 AT34 AT33 AT32 AT31 AT30 Register 4 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT47 AT46 AT45 AT44 AT43 AT42 AT41 AT40 Register 5 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT57 AT56 AT55 AT54 AT53 AT52 AT51 AT50 Register 6 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT67 AT66 AT65 AT64 AT63 AT62 AT61 AT60 Register 7 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 ATLD ATTS MUT6 MUT5 MUT4 MUT3 MUT2 MUT1 Register 8 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 res INZD DAC6 DAC5 DAC4 DAC3 DAC2 DAC1 Register 9 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 res res FLT0 CLKD CLKE FMT2 FMT1 FMT0 Register 10 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 res res res DMF1 DMF0 DM56 DM34 DM12 Register 11 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 INC REG6 REG5 REG4 REG3 REG2 REG1 REG0 Register 12 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 N/A N/A N/A N/A N/A N/A N/A N/A TABLE IV. Mode Control Register Map. ® 15 PCM1600, PCM1601 REGISTER DEFINITIONS B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 Register 1 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT17 AT16 AT15 AT14 AT13 AT12 AT11 AT10 Register 2 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT27 AT26 AT25 AT24 AT23 AT22 AT21 AT20 Register 3 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT37 AT36 AT35 AT34 AT33 AT32 AT31 AT30 Register 4 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT47 AT46 AT45 AT44 AT43 AT42 AT41 AT40 Register 5 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT57 AT56 AT55 AT54 AT53 AT52 AT51 AT50 Register 6 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 AT67 AT66 AT65 AT64 AT63 AT62 AT61 AT60 R/W Read/Write Mode Select When R/W = 0, a Write operation is performed. When R/W = 1, a Read operation is performed. Default Value: 0 ATx[7:0] Digital Attenuation Level Setting where x = 1-6, corresponding to the DAC output VOUTx. These bits are Read/Write. Default Value: 1111 1111B Each DAC output, VOUT1 through VOUT6, has a digital attenuator associated with it. The attenuator may be set from 0dB to –63dB, in 0.5dB steps. Alternatively, the attenuator may be set to infinite attenuation (or mute). The attenuation data for each channel can be set individually. However, the data load control (ATLD bit of Control Register 7) is common to all six attenuators. ATLD must be set to ‘1’ in order to change an attenuator’s setting. The attenuation level may be set using the formula below. Attenuation Level (dB) = 0.5 (AT x [7:0]DEC – 255) where: AT x [7:0]DEC = 0 through 255 for: AT x [7:0]DEC = 0 through 128, the attenuator is set to infinite attenuation. The following table shows attenuator levels for various settings. ATx[7:0] Decimal Value Attenuator Level Setting 1111 1111B 1111 1110B 1111 1101B • • • 1000 0010B 1000 0001B 1000 0000B • • • 0000 0000B 255 254 253 • • • 130 129 128 • • • 0 0dB, No Attenuation (default) –0.5dB –1.0dB • • • –62.5dB –63.0dB Mute • • • Mute ® PCM1600, PCM1601 16 Register 7 R/W B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 ATLD ATTS MUT6 MUT5 MUT4 MUT3 MUT2 MUT1 Read/Write Mode Select When R/W = 0, a Write operation is performed. When R/W = 1, a Read operation is performed. Default Value: 0 ATLD Attenuation Control This bit is Read/Write. Default Value: 0 ATLD = 0 ATLD = 1 Attenuation Control Disabled (default) Attenuation Control Enabled The ATLD bit must be set to logic “1” in order for the attenuators to function. Setting ATLD to logic “0” will disable the attenuator function and cause the current attenuator data to be lost. Set ATLD = 1 immediately after reset. ATTS Attenuation Rate Select This bit is Read/Write. Default Value: 0 ATTS = 0 ATTS = 1 Attenuation rate is 2/fS (default) Attenuation rate is 4/fS Changes in attenuator levels are made by incrementing or decrementing the attenuator by one step (0.5dB) for every 2/fS or 4/fS time interval until the programmed attenuator setting is reached. This helps to minimize audible ‘clicking’, or zipper noise, while the attenuator is changing levels. The ATTS bit allows you to select the rate at which the attenuator is decremented/incremented during level transitions. MUTx Soft Mute Control where x = 1-6, corresponding to the DAC output VOUTx. These bits are Read/Write. Default Value: 0 MUTx = 0 MUTx = 1 Mute Disabled (default) Mute Enabled The mute bits, MUT1 through MUT6, are used to enable or disable the Soft Mute function for the corresponding DAC outputs, VOUT1 through VOUT6. The Soft Mute function is incorporated into the digital attenuators. When Mute is disabled (MUTx = 0), the attenuator and DAC operate normally. When Mute is enabled by setting MUTx = 1, the digital attenuator for the corresponding output will be decremented from the current setting to the infinite attenuation setting one attenuator step (0.5dB) at a time, with the rate of change programmed by the ATTS bit. This provides a quiet, ‘pop’ free muting of the DAC output. Upon returning from Soft Mute, by setting MUTx = 0, the attenuator will be incremented one step at a time to the previously programmed attenuator level. ® 17 PCM1600, PCM1601 REGISTER 8 R/W B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 res INZD DAC6 DAC5 DAC4 DAC3 B1 B0 DAC2 DAC1 Read/Write Mode Select When R/W = 0, a Write operation is performed. When R/W = 1, a Read operation is performed. Default Value: 0 INZD Infinite Zero Detect Mute Control This bit is Read/Write. Default Value: 0 INZD = 0 INZD = 1 Infinite Zero Detect Mute Disabled (default) Infinite Zero Detect Mute Enabled The INZD bit is used to enable or disable the Zero Detect Mute function described in the Zero Flag and Infinite Zero Detect Mute section in this data sheet. The Zero Detect Mute function is independent of the Zero Flag output operation, so enabling or disabling the INZD bit has no effect on the Zero Flag outputs (ZERO1-ZERO6, ZEROA). DACx DAC Operation Control where x = 1-6, corresponding to the DAC output VOUTx. These bits are Read/Write. Default Value: 0 DACx = 0 DACx = 1 DAC Operation Enabled (default) DAC Operation Disabled The DAC operation controls are used to enable and disable the DAC outputs, VOUT1 through VOUT6. When DACx = 0, the output amplifier input is connected to the DAC output. When DACx = 1, the output amplifier input is switched to the DC common-mode voltage (VCOM1 or VCOM2), equal to VCC/2. ® PCM1600, PCM1601 18 REGISTER 9 R/W B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 res res FLT0 CLKD CLKE FMT2 FMT1 FMT0 Read/Write Mode Select When R/W = 0, a Write operation is performed. When R/W = 1, a Read operation is performed. Default Value: 0 FLT0 Digital Filter Roll-Off Control These bits are Read/Write. Default Value: 000B FLT0 = 0 FLT0 = 1 Sharp Roll-Off (default) Slow Roll-Off Bit FLT0 allows the user to select the digital filter roll-off that is best suited to their application. Two filter rolloff sections are available: Sharp or Slow. The filter responses for these selections are shown in the Typical Performance Curves section of this data sheet. CLKD SCLKO Frequency Selection This bit is Read/Write. Default Value: 0 CLKD = 0 CLKD = 1 Full Rate, fSCLKO = fSCLKI (default) Half Rate, fSCLKO = fSCLKL/2 The CLKD bit is used to determine the clock frequency at the system clock output pin, SCLKO. CLKE SCLKO Output Enable This bit is Read/Write. Default Value: 0 CLKE = 0 CLKE = 1 SCLKO Enabled (default) SCLKO Disabled The CLKE bit is used to enable or disable the system clock output pin, SCLKO. When SCLKO is enabled, it will output either a full or half rate clock, based upon the setting of the CLKD bit. When SCLKO is disabled, it is set to a high impedance state. FMT[2:0] Audio Interface Data Format These bits are Read/Write. Default Value: 000B FMT[2:0] 000 001 010 011 100 101 110 111 Audio Data Format Selection 24-Bit Standard Format, Right-Justified 20-Bit Standard Format, Right-Justified 18-Bit Standard Format, Right-Justified 16-Bit Standard Format, Right-Justified I2S Format, 16- to 24-bits Left-Justified Format, 16- to 24-Bits Reserved Reserved Data (default) Data Data Data The FMT[2:0] bits are used to select the data format for the serial audio interface. ® 19 PCM1600, PCM1601 REGISTER 10 B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 res res res DMF1 DMF0 DM56 DM34 DM12 R/W Read/Write Mode Select When R/W = 0, a Write operation is performed. When R/W = 1, a Read operation is performed. Default Value: 0 DMF[1:0] Sampling Frequency Selection for the De-Emphasis Function These bits are Read/Write. Default Value: 00B DMF[1:0] 00 01 10 11 De-Emphasis Same Rate Selection 44.1 kHz (default) 48 kHz 32 kHz Reserved The DMF[1:0] bits are used to select the sampling frequency used for the Digital De-Emphasis function when it is enabled. The de-emphasis curves are shown in the Typical Performance Curves section of this data sheet. The table below shows the available sampling frequencies. DM12 Digital De-Emphasis Control for Channels 1 and 2 This bit is Read/Write. Default Value: 0 DM12 = 0 DM12 = 1 De-Emphasis Disabled for Channels 1 and 2 (default) De-Emphasis Enabled for Channels 1 and 2 The DM12 bit is used to enable or disable the De-emphasis function for VOUT1 and VOUT2, which correspond to the Left and Right channels of the DATA1 input. DM34 Digital De-Emphasis Control for Channels 3 and 4 This bit is Read/Write. Default Value: 0 DM34 = 0 DM34 = 1 De-Emphasis Disabled for Channels 3 and 4 (default) De-Emphasis Enabled for Channels 3 and 4 The DM34 bit is used to enable or disable the De-Emphasis function for VOUT3 and VOUT4, which correspond to the Left and Right channels of the DATA2 input. DM56 Digital De-Emphasis Control for Channels 5 and 6 This bit is Read/Write. Default Value: 0 DM56 = 0 DM56 = 1 De-Emphasis Disabled for Channels 5 and 6 (default) De-Emphasis Enabled for Channels 5 and 6 The DM56 bit is used to enable or disable the de-emphasis function for VOUT5 and VOUT6, which correspond to the Left and Right channels of the DATA3 input. ® PCM1600, PCM1601 20 REGISTER 11 R/W B15 B14 B13 B12 B11 B10 B9 B8 B7 B6 B5 B4 B3 B2 B1 B0 R/W IDX6 IDX5 IDX4 IDX3 IDX2 IDX1 IDX0 INC REG6 REG5 REG4 REG3 REG2 REG1 REG0 Read/Write Mode Select When R/W = 0, a Write operation is performed. When R/W = 1, a Read operation is performed. Default Value: 0 INC Auto-Increment Read Control This bit is Read/Write. Default Value: 0 INC = 0 INC = 1 Auto-Increment Read Disabled (default) Auto-Increment Read Enabled The INC bit is used to enable or disable the Auto-Increment Read feature of the Serial Control Interface. Refer to the Serial Control Interface section of this data sheet for details regarding Auto-Increment Read operation. REG[6:0] Read Register Index These bits are Read/Write. Default Value: 01H Bits REG[6:0] are used to set the index of the register to be read when performing a Single Register Read operation. In the case of an Auto-Increment Read operation, bits REG[6:0] indicate the index of the last register to be read in the in the Auto-Increment Read sequence. For example, if Registers 1 through 6 are to be read during an Auto-Increment Read operation, bits REG[6:0] would be set to 06H. Refer to the Serial Control Interface section of this data sheet for details regarding the Single Register and AutoIncrement Read operations. ® 21 PCM1600, PCM1601 ANALOG OUTPUTS ZERO FLAG AND INFINITE ZERO DETECT MUTE FUNCTIONS The PCM1600 includes six independent output channels, VOUT1 through VOUT6. These are unbalanced outputs, each capable of driving 3.1Vp-p typical into a 5kΩ AC load with VCC = +5V. The internal output amplifiers for VOUT1 through VOUT6 are DC biased to the common-mode (or bipolar zero) voltage, equal to VCC/2. The PCM1600 includes circuitry for detecting an all ‘0’ data condition for the data input pins, DATA1 through DATA3. This includes two independent functions: Zero Output Flags and Zero Detect Mute. Although the flag and mute functions are independent of one another, the zero detection mechanism is common to both functions. The output amplifiers include a RC continuous-time filter, which helps to reduce the out-of-band noise energy present at the DAC outputs due to the noise shaping characteristics of the PCM1600’s delta-sigma D/A converters. The frequency response of this filter is shown in Figure 11. By itself, this filter is not enough to attenuate the out-of-band noise to an acceptable level for most applications. An external low-pass filter is required to provide sufficient outof-band noise rejection. Further discussion of DAC postfilter circuits is provided in the Applications Information section of this data sheet. Zero Detect Condition Zero Detection for each output channel is independent from the others. If the data for a given channel remains at a ‘0’ level for 1024 sample periods (or LRCK clock periods), a Zero Detect condition exists for the that channel. Zero Output Flags Given that a Zero Detect condition exists for one or more channels, the Zero flag pins for those channels will be set to a logic ‘1’state. There are Zero Flag pins for each channel, ZERO1 through ZERO6 (pins 1 through 6). In addition, all six Zero Flags are logically ANDed together and the result provided at the ZEROA pin (pin 48), which is set to a logic ‘1’ state when all channels indicate a zero detect condition. The Zero Flag pins can be used to operate external mute circuits, or used as status indicators for a microcontroller, audio signal processor, or other digitally controlled functions. 20 Level (dB) 0 –20 –40 Infinite Zero Detect Mute –60 Infinite Zero Detect Mute is an internal logic function. The Zero Detect Mute can be enabled or disabled using the INZD bit of Control Register 8. The reset default is Zero Detect Mute disabled, INZD = 0. Given that a Zero Detect Condition exists for one or more channels, the zero mute circuitry will immediately force the corresponding DAC output(s) to the bipolar zero level, or VCC/2. This is accomplished by switching the input of the DAC output amplifier from the delta-sigma modulator output to the DC common-mode reference voltage. –80 –100 1 10 100 1k 10k 100k 1M 10M Log Frequency (Hz) FIGURE 11. Output Filter Frequency Response. VCOM1 AND VCOM2 OUTPUTS Two unbuffered common-mode voltage output pins, VCOM1 (pin 16) and VCOM2 (pin 15), are brought out for decoupling purposes. These pins are nominally biased to a DC voltage level equal to VCC/2. If these pins are to be used to bias external circuitry, a voltage follower is required for buffering purposes. Figure 12 shows an example of using the VCOM1 and VCOM2 pins for external biasing applications. PCM1600 PCM1601 APPLICATIONS INFORMATION CONNECTION DIAGRAMS A basic connection diagram is shown in Figure 13, with the necessary power supply bypassing and decoupling components. Burr-Brown recommends using the component values shown in Figure 13 for all designs. A typical application diagram is shown in Figure 14. BurrBrown’s REG1117-3.3 is used to generate +3.3V for VDD from the +5V analog power supply. Burr-Brown’s PLL1700E is used to generate the system clock input at SCLKI, as well as generating the clock for the audio signal processor. 4 1 3 OPA337 16 VCOM1 VBIAS ≈ VCC 2 15 VCOM2 + 10µF The use of series resistors (22Ω to 100Ω) are recommended for SCLKI, LRCK, BCK, DATA1, DATA2, and DATA3. The series resistor combines with the stray PCB and device input capacitance to form a low-pass filter which removes high frequency noise from the digital signal, thus reducing high frequency emission. FIGURE 12. Biasing External Circuits Using the VCOM1 and VCOM2 Pins. ® PCM1600, PCM1601 22 +3.3V Analog +3.3V Regulator To/From Decoder or Microcontroller C12 26 25 37 VCC3 RST 38 AGND3 SCLKI 39 To/From Decoder VCC4 SCLKO 40 AGND4 BCK 41 VCC5 LRCK 42 PCM1600 PCM1601 TEST +3.3V Analog 43 C11 + C10 AGND5 VCC6 VDD 44 DGND AGND6 DATA1 VCOM1 DATA2 VCOM2 DATA3 VOUT1 ZEROA VOUT2 45 46 To/From Decoder 47 2 3 4 5 6 7 8 9 10 11 24 23 22 21 20 19 18 17 + C1 14 + C2 13 + C3 + C4 + C4 + C6 + C7 16 15 VOUT3 VOUT4 VOUT5 VOUT6 VCC AGND ZERO6 ZERO5 ZERO4 ZERO3 ZERO2 ZERO1 48 1 +5V Analog AGND2 VCC0 27 VCC2 28 AGND1 29 VCC1 30 AGND0 31 NC 32 NC MDI 33 MDO 34 MC 35 ML 36 + C13 12 Zero Output Flags Output Low-Pass Filters +5V Analog C9 C8 + NOTE: C1 - C7, C8, C11, C13 = 10µF tantalum or aluminum electrolytic C9, C10, C12 = 0.1µF ceramic FIGURE 13. Basic Connection Diagram. ® 23 PCM1600, PCM1601 24 RS RS RS RS RS RS(3) +3.3V Analog FIGURE 14. Typical Application Diagram. NOTES: (1) Serial Control and Reset functions may be provided by DSP/Decoder GPIO pins. (2) Actual clock output used is determined by the application. (3) RS = 22Ω to 100Ω. (4) See Applications Information section of this data sheet for more information. Audio DSP or Decoder 27MHz Master Clock XT1 SCKO3(2) Buffer C11 + 48 47 46 45 44 43 Zero Flag Outputs for Mute Circuits, microcontroller, or DSP/Decoder. C10 42 41 40 39 38 37 1 ZEROA DATA3 DATA2 DATA1 DGND VDD TEST LRCK BCK SCLKO SCLKI RST 2 3 34 4 33 5 32 31 30 6 7 0.1µF 8 AGND0 9 28 VCC MDO ZERO4 MDI ZERO3 MC ZERO2 ML ZERO1 29 PCM1600 PCM1601 NC ZERO5 PLL1700 35 NC ZERO6 36 27 VCC1 10µF 10 VOUT6 µC/µP(1) AGND1 26 + 11 VOUT5 ANALOG SECTION 25 VCC2 AGND2 VOUT2 VOUT1 VCOM2 VCOM1 AGND6 VCC6 AGND5 VCC5 AGND4 VCC4 AGND3 VCC3 0.1µF +5V Analog 12 VOUT4 DIGITAL SECTION VCC0 AGND PCM1600, PCM1601 VOUT3 ® 13 14 15 16 17 18 19 20 21 22 23 24 10µF 10µF 10µF 10µF + + 10µF 10µF 10µF + + + + + + +5V Analog Output Low-Pass Filters(4) REG1117 +3.3V +3.3V Analog SUB CTR RS LS RF LF POWER SUPPLIES AND GROUNDING Multiple Feedback (MFB) circuit arrangement, which reduces sensitivity to passive component variations over frequency and temperature. For more information regarding MFB active filter design, please refer to Burr-Brown Applications Bulletin AB-034, available from our web site (www.burr-brown.com) or your local Burr-Brown sales office. The PCM1600 requires a +5V analog supply and a +3.3V digital supply. The +5V supply is used to power the DAC analog and output filter circuitry, while the +3.3V supply is used to power the digital filter and serial interface circuitry. For best performance, the +3.3V supply should be derived from the +5V supply using a linear regulator, as shown in Figure 14. Since the overall system performance is defined by the quality of the D/A converters and their associated analog output circuitry, high quality audio op amps are recommended for the active filters. Burr-Brown’s OPA2134 and OPA2353 dual op amps are shown in Figures 15 and 16, and are recommended for use with the PCM1600 and PCM1601. Six capacitors are required for supply bypassing, as shown in Figure 13. These capacitors should be located as close as possible to the PCM1600 or PCM1601 package. The 10µF capacitors should be tantalum or aluminum electrolytic, while the 0.1µF capacitors are ceramic (X7R type is recommended for surface-mount applications). D/A OUTPUT FILTER CIRCUITS Delta-sigma D/A converters utilize noise shaping techniques to improve in-band Signal-to-Noise Ratio (SNR) performance at the expense of generating increased out-of-band noise above the Nyquist Frequency, or fS/2. The out-of-band noise must be low-pass filtered in order to provide the optimal converter performance. This is accomplished by a combination of on-chip and external low-pass filtering. R2 R1 1 AV ≈ – VOUT R2 R1 R2 R1 R3 2 1 C2 3 VCOM1 C2 10µF R4 C1 R1 + 3 OPA2134 FIGURE 15. Dual Supply Filter Circuit. VIN PCM1600 PCM1601 2 C2 R2 VCOM2 R3 VIN Figures 15 and 16 show the recommended external low-pass active filter circuits for dual and single-supply applications. These circuits are 2nd-order Butterworth filters using the AV ≈ – C1 OPA337 R4 OPA2134 VOUT To Additional Low-Pass Filter Circuits FIGURE 16. Single-Supply Filter Circuit. ® 25 PCM1600, PCM1601 PCB LAYOUT GUIDELINES Separate power supplies are recommended for the digital and analog sections of the board. This prevents the switching noise present on the digital supply from contaminating the analog power supply and degrading the dynamic performance of the D/A converters. In cases where a common +5V supply must be used for the analog and digital sections, an inductance (RF choke, ferrite bead) should be placed between the analog and digital +5V supply connections to avoid coupling of the digital switching noise into the analog circuitry. Figure 18 shows the recommended approach for single-supply applications. A typical PCB floor plan for the PCM1600 and PCM1601 is shown in Figure 17. A ground plane is recommended, with the analog and digital sections being isolated from one another using a split or cut in the circuit board. The PCM1600 or PCM1601 should be oriented with the digital I/O pins facing the ground plane split/cut to allow for short, direct connections to the digital audio interface and control signals originating from the digital section of the board. Digital Power +VD Analog Power DGND AGND +5VA +VS –VS REG VCC VDD Digital Logic and Audio Processor DGND PCM1600 PCM1601 Output Circuits Digital Ground AGND DIGITAL SECTION Analog Ground ANALOG SECTION Return Path for Digital Signals FIGURE 17. Recommended PCB Layout. Power Supplies RF Choke or Ferrite Bead +5V AGND +VS –VS REG VCC VDD VDD DGND Output Circuits PCM1600 PCM1601 AGND Common Ground DIGITAL SECTION ANALOG SECTION FIGURE 18. Single-Supply PCB Layout. ® PCM1600, PCM1601 26 THEORY OF OPERATION KEY PERFORMANCE PARAMETERS AND MEASUREMENT The delta-sigma section of PCM1600 is based on a 8-level amplitude quantizer and a 4th-order noise shaper. This section converts the oversampled input data to 8-level deltasigma format. This section provides information on how to measure key dynamic performance parameters for the PCM1600 and PCM1601. In all cases, an Audio Precision System Two Cascade or equivalent audio measurement system is utilized to perform the testing. A block diagram of the 8-level delta-sigma modulator is shown in Figure 19. This 8-level delta-sigma modulator has the advantage of stability and clock jitter sensitivity over the typical one-bit (2 level) delta-sigma modulator. The combined oversampling rate of the delta-sigma modulator and the internal 8x interpolation filter is 64fS for all system clock combinations (256/384/512/768fS). TOTAL HARMONIC DISTORTION + NOISE Total Harmonic Distortion + Noise (THD+N) is a significant figure of merit for audio D/A converters, since it takes into account both harmonic distortion and all noise sources within a specified measurement bandwidth. The true rms value of the distortion and noise is referred to as THD+N. The theoretical quantization noise performance of the 8-level delta-sigma modulator is shown in Figure 20. The enhanced multi-level delta-sigma architecture also has advantages for input clock jitter sensitivity due to the multilevel quantizer, with the simulated jitter sensitivity shown in Figure 21. For the PCM1600 and PCM1601 D/A converters, THD+N is measured with a full scale, 1kHz digital sine wave as the test stimulus at the input of the DAC. The digital generator is set – + 8fS Z–1 + Z–1 + Z–1 + Z–1 + + 8-Level Quantizer 64fS FIGURE 19. Eight-Level Delta-Sigma Modulator. 125 –20 120 –40 115 Dynamic Range (dB) Amplitude (dB) CLOCK JITTER 0 –60 –80 –100 –120 110 105 100 95 –140 90 –160 85 80 –180 0 1 2 3 4 5 6 7 0 8 100 200 300 400 500 600 Jitter (ps) Frequency (fS) FIGURE 20. Quantization Noise Spectrum. FIGURE 21. Jitter Sensitivity. ® 27 PCM1600, PCM1601 The measurement setup for the dynamic range measurement is shown in Figure 23, and is similar to the THD+N test setup discussed previously. The differences include the band limit filter selection, the additional A-Weighting filter, and the –60dBFS input level. to 24-bit audio word length and a sampling frequency of 44.1kHz, or 96kHz. The digital generator output is taken from the unbalanced S/PDIF connector of the measurement system. The S/PDIF data is transmitted via coaxial cable to the digital audio receiver on the DEM-DAI1600 demo board. The receiver is then configured to output 24-bit data in either I2S or left-justified data format. The DAC audio interface format is programmed to match the receiver output format. The analog output is then taken from the DAC post filter and connected to the analog analyzer input of the measurment system. The analog input is band limited using filters resident in the analyzer. The resulting THD+N is measured by the analyzer and displayed by the measurement system. IDLE CHANNEL SIGNAL-TO-NOISE RATIO The SNR test provides a measure of the noise floor of the D/A converter. The input to the D/A is all 0’s data, and the D/A converter’s Infinite Zero Detect Mute function must be disabled (default condition at power up for the PCM1600, PCM1601). This ensures that the delta-sigma modulator output is connected to the output amplifier circuit so that idle tones (if present) can be observed and effect the SNR measurement. The dither function of the digital generator must also be disabled to ensure an all ‘0’s data stream at the input of the D/A converter. DYNAMIC RANGE Dynamic range is specified as A-Weighted, THD+N measured with a –60dBFS, 1kHz digital sine wave stimulus at the input of the D/A converter. This measurment is designed to give a good indicator of how the DAC will perform given a low-level input signal. The measurement setup for SNR is identical to that used for dynamic range, with the exception of the input signal level. (see the notes provided in Figure 23). Evaluation Board DEM-DAI1600 S/PDIF Receiver PCM1600 PCM1601 2nd-Order Low-Pass Filter f–3dB = 54kHz Analyzer and Display Digital Generator S/PDIF Output 100% Full Scale 24-Bit, 1kHz Sine Wave NOTES: (1) There is little difference in measured THD+N when using the various settings for these filters. (2) Required for THD+N test. RMS Mode Band Limit Notch Filter 22Hz(1) HPF = fC = 1kHz LPF = 30kHz(1) Option = 20kHz Apogee Filter(2) FIGURE 22. Test Setup for THD+N Measurements. Evaluation Board DEM-DAI1600 S/PDIF Receiver PCM1600(1) PCM1601 2nd-Order Low-Pass Filter f–3dB = 54kHz S/PDIF Output NOTES: (1) Infinite Zero Detect Mute disabled. (2) Results without A-Weighting will be approximately 3dB worse. Digital Generator 0% Full Scale, Dither Off (SNR) –60dBFS, 1kHz Sine Wave (Dynamic Range) Analyzer and Display A-Weight Filter(1) RMS Mode FIGURE 23. Test Set-Up for Dynamic Range and SNR Meeasurements. ® PCM1600, PCM1601 28 Band Limit HPF = 22Hz LPF = 22kHz Option = A-Weighting(2) Notch Filter fC = 1kHz IMPORTANT NOTICE Texas Instruments and its subsidiaries (TI) reserve the right to make changes to their products or to discontinue any product or service without notice, and advise customers to obtain the latest version of relevant information to verify, before placing orders, that information being relied on is current and complete. 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