WOLFSON WM8771

WM8771
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24-bit, 192kHz 8-Channel Codec
DESCRIPTION
FEATURES
The WM8771 is a high performance, multi-channel audio
codec. The WM8771 is ideal for surround sound processing
applications for home hi-fi, automotive and other audio
visual equipment.
A stereo 24-bit multi-bit sigma delta ADC is used with a
three channel input selector. Each channel has analogue
domain mute and programmable gain control. Digital audio
output word lengths from 16-32 bits and sampling rates
from 8kHz to 96kHz are supported.
Four stereo 24-bit multi-bit sigma delta DACs are used with
oversampling digital interpolation filters. Digital audio input
word lengths from 16-32 bits and sampling rates from 8kHz
to 192kHz are supported. Each DAC channel has
independent digital attenuation and mute control. The audio
data interface supports I2S, left justified, right justified and
DSP digital audio formats.
•
Audio Performance
•
•
•
•
•
−
108dB SNR (‘A’ weighted @ 48kHz) DAC
−
97dB SNR (‘A’ weighted @ 48kHz) ADC
DAC Sampling Frequency: 8kHz – 192kHz
ADC Sampling Frequecncy: 8kHz – 96kHz
3-Wire SPI or CCB MPU Serial Control Interface
Master or Slave Clocking Mode
Programmable Audio Data Interface Modes
•
•
•
•
•
The device is controlled via a 3 wire serial interface. The
interface provides access to all features including channel
selection, volume controls, mutes, de-emphasis and power
management facilities. The device is available in a 64-pin
TQFP package.
−
I2S, Left, Right Justified or DSP
−
16/20/24/32 bit Word Lengths
Four Independent Stereo DAC Audio Outputs
Eight stereo ADC inputs with analogue gain adjust from
+19dB to –12dB in 1dB steps
2.7V to 5.5V Analogue, 2.7V to 3.6V Digital supply
Operation
5V tolerant digital inputs
64-Pin TQFP Package
APPLICATIONS
•
•
Surround Sound Processors
Automotive Audio
AUDIO INTERFACE
STEREO
ADC
AVDD2
VMIDDAC
AGND2
DACREFP2
DACREFP1
DOUT
ADCLRC
BCLK
DACLRC
DIN1
DIN2
DIN3
DIN4
MCLK
ZFLAG1
ZFLAG2
REFADC
AVDD1
VMIDADC
AGND1
AINVGL
DIGITAL
FILTERS
STEREO
DAC
LOW
PASS
FILTERS
VOUT1L
DIGITAL
FILTERS
STEREO
DAC
LOW
PASS
FILTERS
VOUT2L
DIGITAL
FILTERS
STEREO
DAC
LOW
PASS
FILTERS
VOUT3L
DIGITAL
FILTERS
STEREO
DAC
LOW
PASS
FILTERS
VOUT4L
VOUT1R
VOUT2R
&
DIGITAL FILTERS
VOUT3R
VOUT4R
MUTE
CONTROL INTERFACE
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MUTE
WM8771
CCB is a trademark of SANYO ELECTRIC CO., LTD
WOLFSON MICROELECTRONICS LTD
w :: www.wolfsonmicro.com
GR1
GR2
DI
CL
CE
RESETB
DVDD
MUTE
DGND
AINOPL
AINOPR
REC1L
REC1R
REC2L
REC2R
REC3L
REC3R
INPUT SOURCE SELECTOR
AIN1L
AIN1R
AIN2L
AIN2R
AIN3L
AIN3R
AIN4L
AIN4R
AIN5L
AIN5R
AIN6L
AIN6R
AIN7L
AIN7R
AIN8L
AIN8R
AINVGR
BLOCK DIAGRAM
CCB is SANYO’s original bus format and all the bus addresses are controlled by SANYO.
Product Preview, December 2001, Rev 2.0
Copyright 2001 Wolfson Microelectronics Ltd.
WM8771
Product Preview
64-pin TQFP
DVDD
-40 to + 85oC
ZFLAG1
WM8771IFT/V
ZFLAG2
PACKAGE
DOUT
TEMP. RANGE
DIN1
DEVICE
DIN2
DIN3
DIN4
DACLRC
ADCLRC
MCLK
BCLK
ORDERING INFORMATION
CL
DI
CE
RESETB
PIN CONFIGURATION
AIN1L
1
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
48
DGND
AIN1R
2
47
AGND2
AIN2L
3
46
VOUT4R
AIN2R
4
45
VOUT4L
AIN3L
5
44
DACREFP2
AIN3R
6
43
VOUT3R
AIN4L
7
42
GR2
AIN4R
8
41
VOUT3L
AIN5L
9
40
VMIDDAC
AIN5R
10
39
VOUT2R
AIN6L
AIN8R
33
16
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
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AVDD2
REC3R
REC3L
VOUT1L
REC2R
34
NC
15
REC2L
AIN8L
NC
VOUT1R
AVDD1
35
AGND1
14
VMIDADC
AIN7R
REFADC
DACREFP1
RECR
36
RECL
VOUT2L
13
AINOPR
12
AIN7L
AINVGR
GR1
37
AINVGL
38
AINOPL
11
AIN6R
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WM8771
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PIN DESCRIPTION
PIN
NAME
TYPE
1
AIN1L
Analogue Input
Channel 1 left input multiplexor virtual ground
DESCRIPTION
2
AIN1R
Analogue Input
Channel 1 right input multiplexor virtual ground
3
AIN2L
Analogue Input
Channel 2 left input multiplexor virtual ground
4
AIN2R
Analogue Input
Channel 2 right input multiplexor virtual ground
5
AIN3L
Analogue Input
Channel 3 left input multiplexor virtual ground
6
AIN3R
Analogue Input
Channel 3 right input multiplexor virtual ground
7
AIN4L
Analogue Input
Channel 4 left input multiplexor virtual ground
8
AIN4R
Analogue Input
Channel 4 right input multiplexor virtual ground
9
AIN5L
Analogue Input
Channel 5 left input multiplexor virtual ground
10
AIN5R
Analogue Input
Channel 5 right input multiplexor virtual ground
11
AIN6L
Analogue Input
Channel 6 left input multiplexor virtual ground
12
AIN6R
Analogue Input
Channel 6 right input multiplexor virtual ground
13
AIN7L
Analogue Input
Channel 7 left input multiplexor virtual ground
14
AIN7R
Analogue Input
Channel 7 right input multiplexor virtual ground
15
AIN8L
Analogue Input
Channel 8 left input multiplexor virtual ground
16
AIN8R
Analogue Input
Channel 8 right input multiplexor virtual ground
17
AINOPL
Analogue Output
18
AINVGL
Analogue Input
Left channel multiplexor virtual ground
19
AINVGR
Analogue Input
Right channel multiplexor virtual ground
20
AINOPR
Analogue Output
Right channel multiplexor output
21
REC1L
Analogue Output
Left channel input mux select output 1
22
REC1R
Analogue Output
Right channel input mux select output 1
23
REFADC
Analogue Output
ADC reference buffer decoupling pin; 10uF external decoupling
24
VMIDADC
Analogue Output
ADC midrail divider decoupling pin; 10uF external decoupling
25
AGND1
Supply
Analogue negative supply and substrate connection
26
AVDD1
Supply
Analogue positive supply
27
NC
No Connect
Left channel multiplexor output
28
NC
No Connect
29
REC2L
Analogue Output
Left channel input mux select output 2
30
REC2R
Analogue Output
Right channel input mux select output 2
31
REC3L
Analogue Output
Left channel input mux select output 3
32
REC3R
Analogue Output
Right channel input mux select output 3
33
AVDD2
Supply
Analogue positive supply
34
VOUT1L
Analogue output
DAC channel 1 left output
35
VOUT1R
Analogue output
DAC channel 1 right output
36
DACREFP1
Supply
37
VOUT2L
Analogue output
38
GR1
Supply
39
VOUT2R
Analogue output
DAC channel 2 right output
40
VMIDDAC
Analogue output
DAC midrail decoupling pin ; 10uF external decoupling
41
VOUT3L
Analogue output
DAC channel 3 left output
42
GR2
Supply
43
VOUT3R
Analogue output
44
DACREFP2
Supply
45
VOUT4L
Analogue output
DAC channel 4 left output
46
VOUT4R
Analogue output
DAC channel 4 right output
47
AGND2
Supply
Analogue negative supply and substrate connection
48
DGND
Supply
Digital negative supply
49
DVDD
Supply
Digital positive supply
50
ZFLAG1
Digital output
DAC Zero Flag output
51
ZFLAG2
Digital output
DAC Zero Flag output
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DAC positive reference supply
DAC channel 2 left output
DAC ground reference
DAC ground reference
DAC channel 3 right output
DAC positive reference supply
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WM8771
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PIN
NAME
TYPE
52
DOUT
Digital output
ADC data output
DESCRIPTION
53
DIN1
Digital Input
DAC channel 1 data input
54
DIN2
Digital Input
DAC channel 2 data input
55
DIN3
Digital Input
DAC channel 3 data input
56
DIN4
Digital Input
DAC channel 4 data input
57
DACLRC
Digital input/output
DAC left/right word clock
58
ADCLRC
Digital input/output
ADC left/right word clock
59
BCLK
Digital input/output
ADC and DAC audio interface bit clock
60
MCLK
Digital input
Master DAC and ADC clock; 256, 384, 512 or 768fs (fs = word clock
frequency)
61
SCLK
Digital input
Serial interface clock (5V tolerant)
62
SDIN
Digital input
Serial interface data (5V tolerant)
63
LATCH
Digital input
Serial interface Latch signal (5V tolerant)
64
RESETB
Digital input
Device reset input (mutes DAC outputs, resets gain stages to 0dB)
(5V tolerant)
Note: Digital input pins have Schmitt trigger input buffers and are 5V tolerant.
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WM8771
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ABSOLUTE MAXIMUM RATINGS
Absolute Maximum Ratings are stress ratings only. Permanent damage to the device may be caused by continuously operating at
or beyond these limits. Device functional operating limits and guaranteed performance specifications are given under Electrical
Characteristics at the test conditions specified.
ESD Sensitive Device. This device is manufactured on a CMOS process. It is therefore generically susceptible
to damage from excessive static voltages. Proper ESD precautions must be taken during handling and storage
of this device.
MIN
MAX
Digital supply voltage
-0.3V
+3.63V
Analogue supply voltage
-0.3V
+7V
CONDITION
Voltage range digital inputs (DI, CL, CE & RESETB)
DGND -0.3V
+7V
Voltage range digital inputs (MCLK, DIN[3:0], ADCLRC, DACLRC &
BCLK)
DGND -0.3V
DVDD + 0.3V
Voltage range analogue inputs
AGND -0.3V
AVDD +0.3V
Master Clock Frequency
37MHz
Operating temperature range, TA
-40°C
Storage temperature
-65°C
+85°C
+150°C
Package body temperature (soldering 10 seconds)
+240°C
Package body temperature (soldering 2 minutes)
+183°C
Notes:
1.
Analogue and digital grounds must always be within 0.3V of each other.
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WM8771
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RECOMMENDED OPERATING CONDITIONS
PARAMETER
MAX
UNIT
Digital supply range
DVDD
2.7
3.6
V
Analogue supply range
AVDD
2.7
5.5
Ground
SYMBOL
TEST CONDITIONS
MIN
TYP
AGND, DGND
0
Difference DGND to AGND
-0.3
0
V
V
+0.3
V
Note: digital supply DVDD must never be more than 0.3V greater than AVDD.
ELECTRICAL CHARACTERISTICS
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND = 0V, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Digital Logic Levels (TTL Levels)
Input LOW level
VIL
Input HIGH level
VIH
0.8
2.0
Output LOW
VOL
IOL=1mA
Output HIGH
VOH
IOH=1mA
V
V
0.1 x VDD
0.9 x VDD
V
V
Analogue Reference Levels
Reference voltage
VVMID
Potential divider resistance
RVMID
AVDD to VMID and
VMID to AGND
AVDD/2 –
50mV
AVDD/2
AVDD/2 +
50mV
V
40k
50k
60k
Ohms
DAC Performance (Load = 10k ohms, 50pF)
0dBFs Full scale output voltage
SNR (Note 1,2)
A-weighted,
@ fs = 48kHz
SNR (Note 1,2)
A-weighted
@ fs = 96kHz
Dynamic Range (Note 2)
DNR
Total Harmonic Distortion (THD)
A-weighted, -60dB
full scale input
104
104
1kHz, 0dBFs
Vrms
108
dB
108
dB
108
dB
-97
DAC channel separation
Power Supply Rejection Ratio
1.0 x
AVDD/5
-90
100
PSRR
dB
dB
1kHz 100mVpp
50
dB
20Hz to 20kHz
100mVpp
45
dB
ADC Performance
Input Signal Level (0dB)
1.0 x
AVDD/5
SNR (Note 1,2)
A-weighted, 0dB gain
@ fs = 48kHz
SNR (Note 1,2)
Dynamic Range (Note 2)
Total Harmonic Distortion (THD)
ADC Channel Separation
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93
Vrms
97
dB
A-weighted, 0dB gain
@ fs = 96kHz
94
dB
A-weighted, -60dB
full scale input
97
dB
kHz, 0dBFs
-90
-87
dB
1kHz, -3dBFs
-95
-90
dB
1kHz Input
90
dB
PP Rev 2.0 December 2001
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WM8771
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Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND = 0V, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
Programmable Gain Step Size
Programmable Gain Range
1kHz Input
Mute Attenuation
Power Supply Rejection Ratio
MIN
TYP
MAX
UNIT
0.5
1.0
1.5
dB
-12
0
+19
dB
1kHz Input, 0dB gain
PSRR
97
dB
1kHz 100mVpp
50
dB
20Hz to 20kHz
100mVpp
45
dB
AVDD = 5V
100
mA
DVDD = 3.3V
20
mA
Supply Current
Analogue supply current
Digital supply current
Notes:
1.
Ratio of output level with 1kHz full scale input, to the output level with all zeros into the digital input, measured ‘A’
weighted.
2.
All performance measurements done with 20kHz low pass filter, and where noted an A-weight filter. Failure to use
such a filter will result in higher THD+N and lower SNR and Dynamic Range readings than are found in the Electrical
Characteristics. The low pass filter removes out of band noise; although it is not audible it may affect dynamic
specification values.
3.
VMID decoupled with 10uF and 0.1uF capacitors (smaller values may result in reduced performance).
TERMINOLOGY
1.
Signal-to-noise ratio (dB) - SNR is a measure of the difference in level between the full scale output and the output
with no signal applied. (No Auto-zero or Automute function is employed in achieving these results).
2.
Dynamic range (dB) - DNR is a measure of the difference between the highest and lowest portions of a signal.
Normally a THD+N measurement at 60dB below full scale. The measured signal is then corrected by adding the 60dB
to it. (e.g. THD+N @ -60dB= -32dB, DR= 92dB).
3.
THD+N (dB) - THD+N is a ratio, of the rms values, of (Noise + Distortion)/Signal.
4.
Stop band attenuation (dB) - Is the degree to which the frequency spectrum is attenuated (outside audio band).
5.
Channel Separation (dB) - Also known as Cross-Talk. This is a measure of the amount one channel is isolated from
the other. Normally measured by sending a full scale signal down one channel and measuring the other.
6.
Pass-Band Ripple - Any variation of the frequency response in the pass-band region.
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WM8771
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MASTER CLOCK TIMING
tMCLKL
MCLK
tMCLKH
tMCLKY
Figure 1 Master Clock Timing Requirements
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND = 0V, AGND, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
System Clock Timing Information
MCLK System clock pulse width high
tMCLKH
11
ns
MCLK System clock pulse width low
tMCLKL
11
ns
MCLK System clock cycle time
tMCLKY
28
MCLK Duty cycle
40:60
ns
60:40
Table 1 Master Clock Timing Requirements
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WM8771
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DIGITAL AUDIO INTERFACE – MASTER MODE
BCLK
ADCLRC
WM8771
CODEC DACLRC
DSP/
ENCODER/
DECODER
DOUT
DIN1/2/3/4
4
Figure 2 Audio Interface - Master Mode
BCLK
(Output)
tDL
ADCLRC/
DACLRC
(Outputs)
tDDA
DOUT
DIN1/2/3/4
tDST
tDHT
Figure 3 Digital Audio Data Timing – Master Mode
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND, DGND = 0V, TA = +25oC, Master Mode, fs = 48kHz, MCLK = 256fs unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Audio Data Input Timing Information
ADCLRC/DACLRC
propagation delay from
BCLK falling edge
tDL
0
10
ns
DOUT propagation delay
from BCLK falling edge
tDDA
0
10
ns
DIN1/2/3/4 setup time to
BCLCK rising edge
tDST
10
ns
DIN1/2/3/4 hold time from
BCLK rising edge
tDHT
10
ns
Table 2 Digital Audio Data Timing – Master Mode
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WM8771
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DIGITAL AUDIO INTERFACE – SLAVE MODE
BCLK
ADCLRC
WM8771
CODEC DACLRC
DSP
ENCODER/
DECODER
DOUT
DIN1/2/3/4
4
Figure 4 Audio Interface – Slave Mode
tBCH
tBCL
BCLK
tBCY
DACLRC/
ADCLRC
tDS
tLRH
tLRSU
DIN1/2/3/4
tDD
tDH
DOUT
Figure 5 Digital Audio Data Timing – Slave Mode
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND = 0V, DGND = 0V, TA = +25oC, Slave Mode, fs = 48kHz, MCLK = 256fs unless otherwise
stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Audio Data Input Timing Information
BCLK cycle time
tBCY
50
ns
BCLK pulse width high
tBCH
20
ns
BCLK pulse width low
tBCL
20
ns
DACLRC/ADCLRC set-up
time to BCLK rising edge
tLRSU
10
ns
DACLRC/ADCLRC hold
time from BCLK rising edge
tLRH
10
ns
DIN1/2/3/4 set-up time to
BCLK rising edge
tDS
10
ns
DIN1/2/3/4 hold time from
BCLK rising edge
tDH
10
ns
DOUT propagation delay
from BCLK falling edge
tDD
0
10
ns
Table 3 Digital Audio Data Timing – Slave Mode
Note: ADCLRC and DACLRC should be synchronous with MCLK, although the WM8771 interface is tolerant of phase variations or jitter on these signals.
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MPU INTERFACE TIMING
tRCSU
tRCHO
RESETB
tCSL
tCSH
CE
tSCY
tSCH
tCSS
tSCS
tSCL
CL
DI
LSB
tDSU
tDHO
Figure 6 SPI compatible Control Interface Input Timing
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated
SYMBOL
MIN
CE to RESETB hold time
PARAMETER
tRCSU
20
TYP
MAX
UNIT
ns
RESETB to CL setup time
tRCHO
20
ns
CL rising edge to CE rising edge
tSCS
60
ns
CL pulse cycle time
tSCY
80
ns
CL pulse width low
tSCL
30
ns
CL pulse width high
tSCH
30
ns
DI to CL set-up time
tDSU
20
ns
CL to DI hold time
tDHO
20
ns
CE pulse width low
tCSL
20
ns
CE pulse width high
tCSH
20
ns
CE rising to CL rising
tCSS
20
ns
Table 4 3 wire SPI compatible Control Interface Input Timing Information
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tRCES tRCLH
RESETB
tCP tCS
tCH
CE
tSCY
tSCL
tSCH
CL
A7
DI
tDSU
D15
tDHO
Figure 7 3 wire CCB compatible Interface Input Timing Information – CL stopped low
tRCES tRCLH
RESETB
tCH
tCP tCS
CE
tSCY
tSCH
tSCL
CL
DI
A7
tDSU
D15
tDHO
Figure 8 3 wire CCB compatible Interface Input Timing Information – CL stopped high
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated
SYMBOL
MIN
CE to RESETB setup time
PARAMETER
tRCES
20
TYP
MAX
UNIT
ns
RESETB to CL hold time
tRCLH
20
ns
DI to CL setup time
tDSU
20
ns
CL to DI hold time
tDHO
20
ns
CL to CE setup time
tCS
20
ns
CE to CL wait time
tCP
20
ns
CL to CE hold time
tCH
20
ns
CL pulse width high
tSCH
30
ns
CL pulse width low
tSCL
30
ns
CL pulse cycle time
tSCY
80
ns
Table 5 3 wire CCB compatible Interface Input Timing Information
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DEVICE DESCRIPTION
INTRODUCTION
WM8771 is a complete 8-channel DAC, 2-channel ADC audio codec, including digital interpolation
and decimation filters, multi-bit sigma delta stereo ADC, and switched capacitor multi-bit sigma delta
DACs with digital volume controls on each channel and output smoothing filters.
The device is implemented as four separate stereo DACs and a stereo ADC with flexible input
multiplexor, in a single package and controlled by a single interface.
The four stereo channels may either be used to implement a 5.1 channel surround system, with
additional stereo channel for a stereo mix down channel, or for a complete 7.1 channel surround
system.
Each stereo DAC has its own data input DIN1/2/3/4. DAC word clock DACLRC is shared between
them. The stereo ADC has it’s own data output DOUT, and word clock ADCLRC. BITCLK and MCLK
are shared between the ADCs and DACs. The Audio Interface may be configured to operate in either
master or slave mode. In Slave mode ADCLRC, DACLRC and BCLK are all inputs. In Master mode
ADCLRC, DACLRC and BCLK are all outputs.
The input multiplexor to the ADC is configured to allow large signal levels to be input to the ADC,
using external resistors to reduce the amplitude of larger signals to within the normal operating range
of the ADC. The ADC input PGA also allows input signals to be gained up to +19dB and attenuated
down to -12dB. This allows the user maximum flexibility in the use of the ADC.
Three individually selectable stereo record outputs are also provided on REC1/2/3. It is intended that
the REC1/2/3 outputs are only used to drive high impedance buffers.
Each DAC has its own digital volume control. In addition a zero cross detect circuit is provided for
each DAC. The digital volume control detects a transition through the zero point before updating the
volume. This minimises audible clicks and ‘zipper’ noise as the gain values change.
Control of internal functionality of the device is by 3-wire serial control interface. An SPI or CCB type
interface may used, selectable by the state of the CE pin on the rising edge of RESETB. The control
interface may be asynchronous to the audio data interface as control data will be re-synchronised to
the audio processing internally.
Operation using system clock of 128fs, 192fs, 256fs, 384fs, 512fs or 768fs is provided. In Slave
mode selection between clock rates is automatically controlled. In master mode the master clock to
sample rate ratio is set by control bits ADCRATE and DACRATE. ADC and DAC may run at different
rates within the constraint of a common master clock for the ADC and DACs. For example with
master clock at 24.576MHz, a DAC sample rate of 96kHz (256fs mode) and an ADC sample rate of
48kHz (512fs mode) can be accommodated. Master clock sample rates (fs) from less than 8ks/s up
to 192ks/s are allowed, provided the appropriate system clock is input.
The audio data interface supports right, left and I2S interface formats along with a highly flexible DSP
serial port interface.
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AUDIO DATA SAMPLING RATES
In a typical digital audio system there is only one central clock source producing a reference clock to
which all audio data processing is synchronised. This clock is often referred to as the audio system’s
Master Clock. The external master system clock can be applied directly through the MCLK input pin
with no software configuration necessary. In a system where there are a number of possible sources
for the reference clock it is recommended that the clock source with the lowest jitter be used to
optimise the performance of the ADC and DAC.
The master clock for WM8771 supports audio sampling rates from 128fs to 768fs, where fs is the
audio sampling frequency (DACLRC or ADCLRC) typically 32kHz, 44.1kHz, 48kHz, 96kHz or 192kHz
(for DAC operation only). The master clock is used to operate the digital filters and the noise shaping
circuits.
In Slave mode the WM8771 has a master clock detection circuit that automatically determines the
relationship between the system clock frequency and the sampling rate (to within +/- 32 system
clocks). If there is a greater than 32 clocks error the interface is disabled and maintains the output
level at the last sample. The master clock must be synchronised with ADCLRC/DACLRC, although
the WM8771 is tolerant of phase variations or jitter on this clock.
SAMPLING
RATE
(DACLRC/
ADCLRC)
System Clock Frequency (MHz)
128fs
192fs
256fs
384fs
512fs
768fs
32kHz
4.096
6.144
8.192
12.288
16.384
24.576
44.1kHz
5.6448
8.467
11.2896
16.9340
22.5792
33.8688
24.576
36.864
48kHz
6.114
9.216
12.288
18.432
96kHz
12.288
18.432
24.576
36.864
192kHz
24.576
36.864
Unavailable Unavailable
Unavailable Unavailable Unavailable Unavailable
Table 6 System Clock Frequencies Versus Sampling Rate
In Master mode BCLK, DACLRC and ADCLRC are generated by the WM8771. The frequencies of
ADCLRC and DACLRC are set by setting the required ratio of MCLK to DACLRC and ADCLRC using
the DACRATE and ADCRATE control bits (Table 7).
ADCRATE[2:0]/
DACRATE[2:0]
MCLK:ADCLRC/DACLRC
RATIO
000
128fs
001
192fs
010
256fs
011
384fs
100
512fs
101
768fs
Table 7 Master Mode MCLK:ADCLRC/DACLRC ratio select
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SAMPLING
RATE
(DACLRC/
ADCLRC)
System Clock Frequency (MHz)
128fs
192fs
256fs
384fs
512fs
768fs
ADCRATE/
DACRATE
=000
ADCRATE/
DACRATE
=001
ADCRATE/
DACRATE
=010
ADCRATE/
DACRATE
=011
ADCRATE/
DACRATE
=100
ADCRATE/
DACRATE
=101
32kHz
4.096
6.144
8.192
12.288
16.384
24.576
44.1kHz
5.6448
8.467
11.2896
16.9340
22.5792
33.8688
48kHz
6.114
9.216
12.288
18.432
24.576
36.864
96kHz
12.288
18.432
24.576
36.864
192kHz
24.576
36.864
Unavailable Unavailable
Unavailable Unavailable Unavailable Unavailable
Table 8 Master Mode ADC/DACLRC frequency selection
BCLK is also generated by the WM8771. The frequency of BCLK depends on the mode of operation.
In 128/192fs modes (ADCRATE/DACRATE=000 or 001) BCLK = MCLK/2. In 256/384/512fs modes
(ADCRATE/DACRATE=010 or 011 or 100) BCLK = MCLK/4. However if DSP mode is selected as
the audio interface mode then BCLK=MCLK. This is to ensure that there are sufficient BCLKs to
clock in all eight channels. Note that DSP mode cannot be used in 128fs mode for word lengths
greater than 16 bits or in 192fs mode for word lengths greater than 24 bits.
ZERO DETECT
The WM8770 has a zero detect circuit for each DAC channel which detects when 1024 consecutive
zero samples have been input. Two zero flag outputs (ZFLAG1 and ZFLAG2) may be programmed to
output the zero detect signals (see Table 9) which may then be used to control external muting
circuits. A ‘1’ on ZFLAG1 or ZFLAG2 indicates a zero detect. The zero detect may also be used to
automatically enable the PGA mute by setting IZD. The zero flag output may be disabled by setting
DZFM to 0000. The zero flag signal for a DAC channel will only be enabled if that channel is enabled
as an input to the output summing stage.
DZFM[3:0]
ZFLAG1
ZFLAG2
0000
Zero flag disabled
Zero flag disabled
0001
All channels zero
All channels zero
0010
Left channels zero
Right channels zero
0011
Channel 1 zero
Channels 2-4 zero
0100
Channel 1 zero
Channel 2 zero
0101
Channel 1 zero
Channel 3 zero
0110
Channel 1 zero
Channel 4 zero
0111
Channel 2 zero
Channel 3 zero
1000
Channel 2 zero
Channel 4 zero
1001
Channel 3 zero
Channel 4 zero
1010
Channels 1-3 zero
Channel 4 zero
1011
Channel 1 zero
Channels 2 & 3 zero
1100
Channel 1 left zero
Channel 1 right zero
1101
Channel 2 left zero
Channel 2 right zero
1110
Channel 3 left zero
Channel 3 right zero
1111
Channel 4 left zero
Channel 4 right zero
Table 9 Zero Flag Output Select
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POWERDOWN MODES
The WM8771 has powerdown control bits allowing specific parts of the WM8771 to be powered off
when not being used. The 8-channel input source selector and input buffer may be powered down
using control bit AINPD. When AINPD is set all inputs to the source selector (AIN1l/R to AIN8L/R)
are switched to a buffered VMIDADC. Control bit ADCPD powers off the ADC and also the ADC input
PGAs. The four stereo DACs each have a separate powerdown control bit, DACPD[3:0] allowing
individual stereo DACs to be powered off when not in use. The analogue output buffer may also be
powered down by setting OUTPD[3:0]. OUTPD[3:0] also switches the analogue outputs VOUTL/R to
VMIDDAC to maintain a dc level on the output. Setting AINPD, ADCPD, DACPD[3:0] and
OUTPD[3:0] will powerdown everything except the references VMIDADC, ADCREF and VMIDDAC.
These may be powered down by setting PDWN. Setting PDWN will override all other powerdown
control bits. It is recommended that the 8-channel input mux and buffer, ADC, DAC and output
buffers are powered down before setting PDWN. The default is for all powerdown bits to be set
except PDWN.
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DIGITAL AUDIO INTERFACE
MASTER AND SLAVE MODES
The audio interface operates in either Slave or Master mode, selectable using the MS control bit. In
both Master and Slave modes DACDAT is always an input to the WM8771 and ADCDAT is always
an output. The default is Slave mode.
In Slave mode (MS=0) ADCLRC, DACLRC and BCLK are inputs to the WM8771 (Figure 9).
DIN1/2/3/4, ADCLRC and DACLRC are sampled by the WM8771 on the rising edge of BCLK. ADC
data is output on DOUT and changes on the falling edge of BCLK. By setting control bit BCLKINV the
polarity of BCLK may be reversed so that DIN1/2/3/4, ADCLRC and DACLRC are sampled on the
falling edge of BCLK and DOUT changes on the rising edge of BCLK.
BCLK
ADCLRC
WM8771
CODEC DACLRC
DSP
ENCODER/
DECODER
DOUT
DIN1/2/3/4
4
Figure 9 Slave Mode
In Master mode (MS=1) ADCLRC, DACLRC and BCLK are outputs from the WM8771 (Figure 10).
ADCLRC, DACLRC and BITCLK are generated by the WM8771. DIN1/2/3/4 are sampled by the
WM8771 on the rising edge of BCLK so the controller must output DAC data that changes on the
falling edge of BCLK. ADCDAT is output on DOUT and changes on the falling edge of BCLK. By
setting control bit BCLKINV the polarity of BCLK may be reversed so that DIN1/2/3/4 are sampled on
the falling edge of BCLK and DOUT changes on the rising edge of BCLK.
BCLK
ADCLRC
WM8771
CODEC DACLRC
DSP/
ENCODER/
DECODER
DOUT
DIN1/2/3/4
4
Figure 10 Master Mode
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AUDIO INTERFACE FORMATS
Audio data is applied to the internal DAC filters, or output from the ADC filters, via the Digital Audio
Interface. 5 popular interface formats are supported:
•
Left Justified mode
•
Right Justified mode
•
I2S mode
•
DSP Early mode
•
DSP Late mode
All 5 formats send the MSB first and support word lengths of 16, 20, 24 and 32 bits, with the
exception of 32 bit right justified mode, which is not supported.
In left justified, right justified and I2S modes, the digital audio interface receives DAC data on the
DIN1/2/3/4 inputs and outputs ADC data on DOUT. Audio Data for each stereo channel is time
multiplexed with ADCLRC/DACLRC indicating whether the left or right channel is present.
ADCLRC/DACLRC is also used as a timing reference to indicate the beginning or end of the data
words.
In left justified, right justified and I2S modes, the minimum number of BCLKs per DACLRC/ADCLRC
period is 2 times the selected word length. ADCLRC/DACLRC must be high for a minimum of word
length BCLKs and low for a minimum of word length BCLKs. Any mark to space ratio on
ADCLRC/DACLRC is acceptable provided the above requirements are met.
In DSP early or DSP late mode, all 8 DAC channels are time multiplexed onto DIN1. DACLRC is
used as a frame sync signal to identify the MSB of the first word. The minimum number of BCLKs
per DACLRC period is 8 times the selected word length. Any mark to space ratio is acceptable on
DACLRC provided the rising edge is correctly positioned. The ADC data may also be output in DSP
early or late modes, with ADCLRC used as a frame sync to identify the MSB of the first word. The
minimum number of BCLKs per ADCLRC period is 2 times the selected word length
LEFT JUSTIFIED MODE
In left justified mode, the MSB of DIN1/2/3/4 is sampled by the WM8771 on the first rising edge of
BCLK following a DACLRC transition. The MSB of the ADC data is output on DOUT and changes on
the same falling edge of BCLK as ADCLRC and may be sampled on the rising edge of BCLK.
ADCLRC and DACLRC are high during the left samples and low during the right samples (Figure 11).
1/fs
LEFT CHANNEL
RIGHT CHANNEL
DACLRC/
ADCLRC
BCLK
DIN1/2/3/4/
DOUT
1
MSB
2
3
n-2 n-1
n
LSB
1
MSB
2
3
n-2 n-1
n
LSB
Figure 11 Left Justified Mode TIming Diagram
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RIGHT JUSTIFIED MODE
In right justified mode, the LSB of DIN1/2/3/4 is sampled by the WM8771 on the rising edge of BCLK
preceding a DACLRC transition. The LSB of the ADC data is output on DOUT and changes on the
falling edge of BCLK preceding an ADCLRC transition and may be sampled on the rising edge of
BCLK. ADCLRC and DACLRC are high during the left samples and low during the right samples
(Figure 12).
1/fs
LEFT CHANNEL
RIGHT CHANNEL
DACLRC/
ADCLRC
BCLK
DIN1/2/3/4/
DOUT
1
2
3
n-2 n-1
MSB
n
1
LSB
2
3
n-2 n-1
MSB
n
LSB
Figure 12 Right Justified Mode TIming Diagram
I2S MODE
In I2S mode, the MSB of DIN1/2/3/4 is sampled by the WM8771 on the second rising edge of BCLK
following a DACLRC transition. The MSB of the ADC data is output on DOUT and changes on the
first falling edge of BCLK following an ADCLRC transition and may be sampled on the rising edge of
BCLK. ADCLRC and DACLRC are low during the left samples and high during the right samples.
1/fs
LEFT CHANNEL
RIGHT CHANNEL
DACLRC/
ADCLRC
BCLK
1 BCLK
1 BCLK
DIN1/2/3/4/
DOUT
1
2
3
MSB
n-2 n-1
n
LSB
1
MSB
2
3
n-2 n-1
n
LSB
Figure 13 I2S Mode TIming Diagram
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DSP EARLY MODE
In DSP early mode, the MSB of DAC channel 1 left data is sampled by the WM8771 on the second
rising edge on BCLK following a DACLRC rising edge. DAC channel 1 right and DAC channels 2, 3
and 4 data follow DAC channel 1 left data (Figure 14).
1 BCLK
1 BCLK
1/fs
DACLRC
BCK
CHANNEL 1
LEFT
DIN1
1
2
CHANNEL 1
RIGHT
n
n-1
MSB
1
2
n-1
CHANNEL 2
LEFT
n
1
2
CHANNEL 4
RIGHT
n-1
NO VALID DATA
n
LSB
Input Word Length (IWL)
Figure 14 DSP Early Mode Timing Diagram – DAC data input
The MSB of the left channel ADC data is output on DOUT and changes on the first falling edge of
BCLK following a low to high ADCLRC transition and may be sampled on the rising edge of BCLK.
The right channel ADC data is contiguous with the left channel data (Figure 15)
1 BCLK
1 BCLK
1/fs
ADCLRC
BCK
LEFT CHANNEL
DOUT
1
2
MSB
RIGHT CHANNEL
n
n-1
1
2
n-1
NO VALID DATA
n
LSB
Input Word Length (IWL)
Figure 15 DSP Early Mode Timing Diagram – ADC data output
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DSP LATE MODE
In DSP late mode, the MSB of DAC channel 1 left data is sampled by the WM8771 on the first BCLK
rising edge following a DACLRC rising edge. DAC channel 1 right and DAC channels 2, 3 and 4 data
follow DAC channel 1 left data (Figure 16).
1/fs
DACLRC
BCK
CHANNEL 1
LEFT
DIN1
1
2
CHANNEL 1
RIGHT
n
n-1
MSB
1
2
n-1
CHANNEL 2
LEFT
n
1
2
CHANNEL 4
RIGHT
n-1
n
NO VALID DATA
1
LSB
Input Word Length (IWL)
Figure 16 DSP Late Mode Timing Diagram – DAC data input
The MSB of the left channel ADC data is output on DOUT and changes on the same falling edge of
BCLK as the low to high ADCLRC transition and may be sampled on the rising edge of BCLK. The
right channel ADC data is contiguous with the left channel data (Figure 17).
1/fs
ADCLRC
BCK
LEFT CHANNEL
DOUT
1
2
MSB
RIGHT CHANNEL
n
n-1
1
2
n-1
NO VALID DATA
n
1
LSB
Input Word Length (IWL)
Figure 17 DSP Late Mode Timing Diagram – ADC data output
In both early and late DSP modes, DACL1 is always sent first, followed immediately by DACR1 and
the data words for the other 6 channels. No BCLK edges are allowed between the data words. The
word order is DAC1 left, DAC1 right, DAC2 left, DAC2 right, DAC3 left, DAC3 right, DAC4 left, DAC4
right.
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CONTROL INTERFACE OPERATION
The WM8771 is controlled using a 3-wire serial interface in either an SPI compatible configuration or
a CCB (Computer Control Bus) configuration.
The interface configuration is determined by the state of the CE pin on the rising edge of the
RESETB pin. If the CE pin is low on the rising edge of RESETB, CCB configuration is selected. If CE
is high on the rising edge of RESETB, SPI compatible configuration is selected.
The control interface is 5V tolerant, meaning that the control interface input signals CE, CL and DI
may have an input high level of 5V while DVDD is 3V. Input thresholds are determined by DVDD.
RESETB and DACMUTE are also 5V tolerant.
3-WIRE (SPI COMPATIBLE) SERIAL CONTROL MODE
DI is used for the program data, CL is used to clock in the program data and CE is used to latch the
program data. DI is sampled on the rising edge of CL. The 3-wire interface protocol is shown in
Figure 18.
CE
CL
DI
B15
B14
B13
B12
B11
B10
B9
B8
B7
B6
B5
B4
B3
B2
B1
B0
Figure 18 3-wire SPI compatible Interface
1.
B[15:9] are Control Address Bits
2.
B[8:0] are Control Data Bits
3.
CE is edge sensitive – the data is latched on the rising edge of CE.
CCB INTERFACE MODE
CCB Interface mode allows multiple devices to be controlled off a common 3-wire bus. Each device
on the 3-wire bus has its own identifying address. The WM8771 supports write only CCB interface
mode.
DI is used for the device address and program data and CL is used to clock in the address and data
on DI. DI is sampled on the rising edge of CL. CE indicates whether the data on DI is the device
address or program data. The eight clocks before a rising edge on CE will clock in the device
address. The device address is latched on the rising edge of CE. The sixteen clocks before a falling
edge on CE will clock in the program data. The program data is latched on the falling edge of CE.
CE
CL
DI
A0
A1
A2
A3
A4
A5
A6
A7
D0
D1
D2
D3
D14
D15
Figure 19 CCB Interface – CL stopped low
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CE
CL
DI
A0
A1
A2
A3
A4
A5
A6
A7
D0
D1
D2
D3
D14
D15
Figure 20 CCB Interface – CL stopped high
1.
A[7:0] are Device Address bits
2.
D[15:9] are Control Address bits
3.
D[8:0] are Control Data bits
The address A[7:0] for WM8771 is 8Ch (10001100).
CONTROL INTERFACE REGISTERS
DIGITAL AUDIO INTERFACE CONTROL REGISTER
Interface format is selected via the FMT[1:0] register bits:
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10110
Interface Control
1:0
FMT[1:0]
10
DESCRIPTION
Interface format Select
00 : right justified mode
01: left justified mode
10: I2S mode
11: DSP (early or late) mode
In left justified, right justified or I2S modes, the LRP register bit controls the polarity of
ADCLRC/DACLRC. If this bit is set high, the expected polarity of ADCLRC/DACLRC will be the
opposite of that shown Figure 11, Figure 12 and Figure 13. Note that if this feature is used as a
means of swapping the left and right channels, a 1 sample phase difference will be introduced. In
DSP modes, the LRP register bit is used to select between early and late modes.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
10110
Interface Control
2
LRP
0
In left/right/i2s modes:
ADCLRC/DACLRC Polarity (normal)
0 : normal ADCLRC/DACLRC
polarity
1: inverted ADCLRC/DACLRC
polarity
In DSP mode:
0 : Early DSP mode
1: Late DSP mode
By default, ADCLRC/DACLRC and DIN1/2/3/4 are sampled on the rising edge of BCLK and should
ideally change on the falling edge. Data sources that change ADCLRC/DACLRC and DIN1/2/3/4 on
the rising edge of BCLK can be supported by setting the BCP register bit. Setting BCP to 1 inverts
the polarity of BCLK to the inverse of that shown in Figure 11, Figure 12, Figure 13, Figure 14,
Figure 15, Figure 16 and Figure 17.
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
10110
Interface Control
3
BCP
0
DESCRIPTION
BCLK Polarity (DSP modes)
0 : normal BCLK polarity
1: inverted BCLK polarity
The IWL[1:0] bits are used to control the input word length.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10110
Interface Control
5:4
WL[1:0]
10
DESCRIPTION
Input Word Length
00 : 16 bit data
01: 20 bit data
10: 24 bit data
11: 32 bit data
Note: If 32-bit mode is selected in right justified mode, the WM8771 defaults to 24 bits.
In all modes, the data is signed 2's complement. The digital filters always input 24-bit data. If the
DAC is programmed to receive 16 or 20 bit data, the WM8771 pads the unused LSBs with zeros. If
the DAC is programmed into 32 bit mode, the 8 LSBs are ignored.
Note: In 24 bit I2S mode, any width of 24 bits or less is supported provided that ADCLRC/DACLRC
is high for a minimum of 24 BCLKs and low for a minimum of 24 BCLKs.
A number of options are available to control how data from the Digital Audio Interface is applied to
the DAC channels.
Control bit MS selects between audio interface Master and Slave Modes. In Master mode ADCLRC,
DACLRC and BCLK are outputs and are generated by the WM8771. In Slave mode ADCLRC,
DACLRC and BCLK are inputs to WM8771.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
10111
Interface Control
8
MS
0
Audio Interface Master/Slave Mode
select:
0 : Slave Mode
1: Master Mode
MASTER MODE ADCLRC/DACLRC FREQUENCY SELECT
In Master mode the WM8771 generates ADCLRC, DACLRC and BCLK. These clocks are derived
from master clock and the ratio of MCLK to ADCLRC and DACLRC are set by ADCRATE and
DACRATE.
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
10111 ADCLRC and
DACLRC frequency
select
2:0
ADCRATE[2:0]
010
Master Mode MCLK:ADCLRC
ratio select:
000: 128fs
001: 192fs
010: 256fs
011: 384fs
100: 512fs
101: 768fs
6:4
DACRATE[2:0]
010
Master Mode MCLK:DACLRC
ratio select:
000: 128fs
001: 192fs
010: 256fs
011: 384fs
100: 512fs
101: 768fs
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ADC OVERSAMPLING RATE SELECT
For ADC operation at 96kHz it is recommended that the user set the ADCOSR bit. This changes the
ADC signal processing oversample rate to 64fs.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10111
ADC Oversampling Rate
3
ADCOSR
0
DESCRIPTION
ADC oversampling rate select
0: 128x oversampling
1: 64x oversampling
MUTE MODES
The WM8771 has individual mutes for each of the four DAC channels. Setting MUTE for a channel
will apply a ‘soft’ mute to the input of the digital filters of the channel muted. The WM8770 has
individual mutes for each of the four DAC channels. Setting MUTE for a channel will apply a ‘soft’
mute to the input of the digital filters of the channel muted. DMUTE[0] mutes DAC channel 1,
DMUTE[1] mutes DAC channel 2, DMUTE[2] mutes DAC channel 3 & DMUTE[3] mutes DAC
channel 4.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10100
DAC Mute
3:0
DMUTE[3:0]
0
DESCRIPTION
DAC Soft Mute select
0 : Normal Operation
1: Soft mute enabled
Setting the MUTEALL register bit will apply a 'soft' mute to the input of all the DAC digital filters:
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10100
DAC Mute
4
MUTEALL
0
DESCRIPTION
Soft Mute select
0 : Normal Operation
1: Soft mute all channels
1.5
1
0.5
0
-0.5
-1
-1.5
-2
-2.5
0
0.001
0.002
0.003
0.004
0.005
0.006
Time(s)
Figure 21 Application and Release of Soft Mute
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Figure 21 shows the application and release of MUTE whilst a full amplitude sinusoid is being played
at 48kHz sampling rate. When MUTE (lower trace) is asserted, the output (upper trace) begins to
decay exponentially from the DC level of the last input sample. The output will decay towards VMID
with a time constant of approximately 64 input samples. If MUTE is applied to all channels for 1024
or more input samples the outputs will be connected directly to Vmid, if IZD is set. When MUTE is
de-asserted, the output will restart immediately from the current input sample.
Note that all other means of muting the DAC channels: setting the PL[3:0] bits to 0, setting the
PDWN bit or setting attenuation to 0 will cause much more abrupt muting of the output.
Each ADC channel also has an individual mute control bit, which mutes the input to the ADC. In
addition both channels may be muted by setting ADCMUTE.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
11001
ADC Mute
7
ADCMUTE
0
ADC MUTE Left and Right
0 : Normal Operation
1: mute ADC left and ADC right
11001
ADC Mute Left
5
MUTE
0
ADC Mute select
0 : Normal Operation
1: mute ADC left
11010
ADC Mute Right
5
MUTE
0
ADC Mute select
0 : Normal Operation
1: mute ADC right
The Record outputs may be enabled by setting RECEN[2:0], where RECEN[0] mutes the REC1L and
REC1R outputs, RECEN[1] mutes the REC2L and REC2R outputs and RECEN[2] mutes the REC3L
and REC3R outputs.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10100
REC Enable
[7:5]
RECMUTE[2:0]
000
DESCRIPTION
REC Output Enable
0 : REC output disabled
1: REC output enabled
DE-EMPHASIS MODE
A digital De-emphasis filter may be applied to each DAC channel. The De-emphasis filter for each
stereo channel is enabled under the control of DEEMP[3:0]. DEEMP[0] enables the de-emphasis
filter for channel 1, DEEMP[1] enables the de-emphasis filter for channel 2, DEEMP[2] enables the
de-emphasis filter for channel 3 and DEEMP[3] enables the de-emphasis filter for channel 4.
REGISTER ADDRESS
10101
DAC De-emphasis
Control
BIT
LABEL
DEFAULT
[3:0] DEEMPH[3:0]
0000
DESCRIPTION
De-emphasis mode select:
0 : Normal Mode
1: De-emphasis Mode
Refer to Figure 29, Figure 30, Figure 31, Figure 32, Figure 33 and Figure 34 for details of the DeEmphasis modes at different sample rates.
POWERDOWN MODE AND ADC/DAC DISABLE
Setting the PDWN register bit immediately powers down the WM8771. All trace of the previous input
samples are removed, but all control register settings are preserved. When PDWN is cleared the
digital filters will be reinitialised. . It is recommended that the 8-channel input mux and buffer, ADC,
DAC and output buffers are powered down before setting PDWN.
REGISTER ADDRESS
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BIT
LABEL
DEFAULT
DESCRIPTION
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11000
Powerdown Control
0
PDWN
0
Power Down Mode Select:
0 : Normal Mode
1: Power Down Mode
The ADC and DACs may also be powered down by setting the ADCD and DACD disable bits. Setting
ADCD will disable the ADC and select a low power mode. The ADC digital filters will be reset and will
reinitialise when ADCD is reset. Each Stereo DAC channel has a separate disable DACD[3:0].
Setting DACD for a channel will disable the DACs and select a low power mode, also connecting the
DAC outputs to VMID. Resetting DACD will reinitialise the digital filters.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
11000
Powerdown Control
1
ADCD
1
ADC Disable:
0 : Normal Mode
1: Power Down Mode
DESCRIPTION
5:2
DACD[3:0]
1
DAC Disable:
0 : Normal Mode
1: Power Down Mode
ATTENUATOR CONTROL MODE
Setting the ATC register bit causes the left channel attenuation settings to be applied to both left and
right channel DACs from the next audio input sample. No update to the attenuation registers is
required for ATC to take effect.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10011
DAC Channel Control
1
ATC
0
DESCRIPTION
Attenuator Control Mode:
0 : Right channels use Right
attenuations
1: Right Channels use Left
attenuations
INFINITE ZERO DETECT
Setting the IZD register bit will enable the internal infinite zero detect function:
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10011
DAC Channel Control
2
IZD
0
DESCRIPTION
Infinite zero Mute Enable
0 : disable infinite zero mute
1: enable infinite zero Mute
With IZD enabled, applying 1024 consecutive input samples to all 8 DAC channels will cause all
outputs to be muted to VMID. Mute will be removed as soon as any channel receives a non-zero input.
ZERO FLAG OUTPUT
The DZFM control bits allow the selection of the eight DAC channel zero flag bits for output on the
ZFLAG1 and ZFLAG2 pins. A ‘1’ on ZFLAG1 or ZFLAG2 indicates 1024 consecutive zero input
samples to the channels selected.
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
10101
Zero Flag Select
7:4
DZFM[3:0]
0000
DESCRIPTION
Selects the output for ZFLG1 and
ZFLG2 pins (see Table 9). A ‘1’
indicates 1024 consecutive zero
input samples on the channels
selected.
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DAC OUTPUT CONTROL
The DAC output control word determines how the left and right inputs to the audio Interface are
applied to the left and right DACs:
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10011
DAC Control
7:4
PL[3:0]
1001
DESCRIPTION
PL[3:0]
Left
Output
Right
Output
0000
Mute
Mute
0001
Left
Mute
0010
Right
Mute
0011
(L+R)/2
Mute
0100
Mute
Left
0101
Left
Left
0110
Right
Left
0111
(L+R)/2
Left
1000
Mute
Right
1001
Left
Right
1010
Right
Right
1011
(L+R)/2
Right
1100
Mute
(L+R)/2
1101
Left
(L+R)/2
1110
Right
(L+R)/2
1111
(L+R)/2
(L+R)/2
DAC DIGITAL VOLUME CONTROL
The DAC volume may be adjusted in the digital domain using independent digital attenuation control
registers
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
01001
Digital
Attenuation
DACL1
7:0
LDA1[7:0]
11111111
(0dB)
Digital Attenuation data for Left channel DACL1 in 0.5dB steps. See
Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA1 in intermediate latch (no change to output)
1: Store LDA1 and update attenuation on all channels
01010
Digital
Attenuation
DACR1
7:0
RDA1[6:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR1 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA1 in intermediate latch (no change to output)
1: Store RDA1 and update attenuation on all channels.
01011
Digital
Attenuation
DACL2
7:0
LDA2[7:0]
11111111
(0dB)
8
UPDATE
Not latched
w
Digital Attenuation data for Left channel DACL2 in 0.5dB steps. See
Table 10
Controls simultaneous update of all Attenuation Latches
0: Store LDA2 in intermediate latch (no change to output)
1: Store LDA2 and update attenuation on all channels.
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REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
01100
Digital
Attenuation
DACR2
7:0
RDA2[7:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR2 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA2 in intermediate latch (no change to output)
1: Store RDA2 and update attenuation on all channels.
01101
Digital
Attenuation
DACL3
7:0
LDA3[7:0]
11111111
(0dB)
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA3 in intermediate latch (no change to output)
1: Store LDA3 and update attenuation on all channels.
01110
Digital
Attenuation
DACR3
7:0
RDA3[7:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR3 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA3 in intermediate latch (no change to output)
1: Store RDA3 and update attenuation on all channels.
01111
Digital
Attenuation
DACL4
7:0
LDA4[7:0]
11111111
(0dB)
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA4 in intermediate latch (no change to output)
1: Store LDA4 and update attenuation on all channels.
10000
Digital
Attenuation
DACR4
7:0
RDA4[7:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR4 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA4 in intermediate latch (no change to output)
1: Store RDA4 and update attenuation on all channels.
10001
Master
Digital
Attenuation
(all channels)
7:0
MASTDA[7:0]
11111111
(0dB)
Digital Attenuation data for all DAC channels in 0.5dB steps. See
Table 10
8
UPDATE
Not latched
Digital Attenuation data for Left channel DACL3 in 0.5dB steps. See
Table 10
Digital Attenuation data for Left channel DACL4 in 0.5dB steps. See
Table 10
Controls simultaneous update of all Attenuation Latches
0: Store gain in intermediate latch (no change to output)
1: Store gain and update attenuation on all channels.
L/RDAX[7:0]
ATTENUATION LEVEL
00(hex)
-∞ dB (mute)
01(hex)
-127.5dB
:
:
:
:
:
:
FE(hex)
-0.5dB
FF(hex)
0dB
Table 10 Digital Volume Control Attenuation Levels
The Digital volume control also incorporates a zero cross detect circuit which detects a transition
through the zero point before updating the digital volume control with the new volume. This is
enabled by control bit DZCEN.
w
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10011
DAC Control
0
DZCEN
0
DESCRIPTION
DAC Digital Volume Zero Cross
Enable:
0: Zero cross detect disabled
1: Zero cross detect enabled
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DAC OUTPUT PHASE
The DAC Phase control word determines whether the output of each DAC is non-inverted or inverted
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10010
DAC Phase
7:0
PH[7:0]
00000000
DESCRIPTION
Bit
DAC
Phase
0
DAC1L
1 = invert
1
DAC1R
1 = invert
2
DAC2L
1 = invert
3
DAC2R
1 = invert
4
DAC3L
1 = invert
5
DAC3R
1 = invert
6
DAC4L
1 = invert
7
DAC4R
1 = invert
ADC GAIN CONTROL
Control bits LAG[4:0] and RAG[4:0] control the ADC input gain, allowing the user to attenuate the
ADC input signal to match the full-scale range of the ADC. The gain is independently adjustable on
left and right inputs. Left and right inputs may also be independently muted. The LRBOTH control bit
allows the user to write the same attenuation value to both left and right volume control registers. The
ADC volume and mute also applies to the bypass signal path
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
11001
Attenuation
ADCL
4:0
LAG[4:0]
01100
(0dB)
5
MUTE
0
Mute for Left channel ADC:
0: Mute off
1: Mute on
6
LRBOTH
0
Setting LRBOTH will write the same gain value to LAG[4:0] and
RAG[4:0]
4:0
RAG[4:0]
01100
(0dB)
5
MUTE
0
Mute for Right channel ADC:
0: Mute off
]1: Mute on
6
LRBOTH
0
Setting LRBOTH will write the same gain value to RAG[4:0] and
LAG[4:0]
11010
Attenuation
ADCR
w
DESCRIPTION
Attenuation data for Left channel ADC gain in 1dB steps. See Table
11
Attenuation data for right channel ADC gain in 1dB steps. See Table
11
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ADC INPUT GAIN
Registers LAG and RAG control the left and right channel gain into the stereo ADC in 1dB steps from
+19dB to –12dB Table 8 shows how the attenuation levels are selected from the 5-bit words.
L/RAG[6:0]
ATTENUATION LEVEL
0
-12dB
:
:
01100
0dB
:
:
11111
+19dB
Table 11 ADC gain control
ADC HIGHPASS FILTER DISABLE
The ADC digital filters contain a digital highpass filter. This defaults to enabled and can be disabled
using software control bit ADCHPD.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
10110
ADC control
8
ADCHPD
0
DESCRIPTION
ADC Highpass filter disable:
0: Highpass filter enabled
1: Highpass filter disabled
ADC INPUT MUX AND POWERDOWN CONTROL
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
11011
ADC mux and
powerdown
control
2:0
LMX[2:0]
000
ADC left channel input mux control
bits (see Figure 35)
6:4
RMX[2:0]
000
ADC right channel input mux
control bits (see Figure 35)
8
AINPD
1
Input mux and buffer powerdown
0: Input mux and buffer
enabled
1: Input mux and buffer
powered down
Register bits LMX and RMX control the left and right channel inputs into the stereo ADC. The default
is AIN1. However if the analogue input buffer is powered down, by setting AINPD, then all 8-channel
mux inputs are switched to buffered VMIDADC.
LMX[2:0]
LEFT ADC INPUT
RMX[2:0]
RIGHT ADC INPUT
000
AIN1L
000
AIN1L
001
AIN2L
001
AIN2L
010
AIN3L
010
AIN3L
011
AIN4L
011
AIN4L
100
AIN5L
100
AIN5L
101
AIN6L
101
AIN6L
110
AIN7L
110
AIN7R
111
AIN8L
111
AIN8R
Table 12 ADC input mux control
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The DAC output buffers can be powered down under control of OUTPD[3:0]. Each stereo channel
may be powered down separately. Setting OUTPD[3:0] will power off the output buffer and switch the
analogue outputs VOUTL/R to VMIDDAC to maintain a dc level on the output.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
11100
Output
Powerdown
control
8:7
OUTPD[1:0]
11
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
11101
Output
Powerdown
control
8:7
OUTPD[3:2]
11
DESCRIPTION
DAC Output Powerdown select
0: output buffer enabled
1: output buffer powered
down
DESCRIPTION
DAC Output Powerdown select
0: output buffer enabled
1: output buffer powered
down
SOFTWARE REGISTER RESET
Writing to register 11111 will cause a register reset, resetting all register bits to their default
values.
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REGISTER MAP
The complete register map is shown below. The detailed description can be found in the relevant text of the device description.
These can be controlled using the Control Interface. All unused bits should be set to ‘0’.
REGISTER
B15
B14
B13
B12
B11
B10
B9
R9(09h)
0
0
0
1
0
0
1
UPDATE
LDA1[7:0]
X11111111
R10(0Ah)
0
0
0
1
0
1
0
UPDATE
RDA1[7:0]
X11111111
R11(0Bh)
0
0
0
1
0
1
1
UPDATE
LDA2[7:0]
X11111111
R12(0Ch)
0
0
0
1
1
0
0
UPDATE
RDA2[7:0]
X11111111
R13(0Dh)
0
0
0
1
1
0
1
UPDATE
LDA3[7:0]
X11111111
R14(0Eh)
0
0
0
1
1
1
0
UPDATE
RDA3[7:0]
X11111111
R15(0Fh)
0
0
0
1
1
1
1
UPDATE
LDA4[7:0]
X11111111
R16(10h)
0
0
1
0
0
0
0
UPDATE
RDA4[7:0]
X11111111
R17(11h)
0
0
1
0
0
0
1
UPDATE
MASTDA[7:0]
X11111111
R18(12h)
0
0
1
0
0
1
0
0
PHASE[8:0]
000000000
R19(13h)
0
0
1
0
0
1
1
0
R20(14h)
0
0
1
0
1
0
0
0
R21(15h)
0
0
1
0
1
0
1
0
R22(16h)
0
0
1
0
1
1
0
ADCHPD
0
R23(17h)
0
0
1
0
1
1
1
MS
0
R24(18h)
0
0
1
1
0
0
0
0
0
0
R25(19h)
0
0
1
1
0
0
1
0
0
LRBOTH
MUTE
LAG
000001100
R26(1Ah)
0
0
1
1
0
1
0
0
0
LRBOTH
MUTE
RAG
000001100
R27(1Bh)
0
0
1
1
0
1
1
AINPD
0
R28(1Ch)
0
0
1
1
1
0
0
OUTPD[1:0]
0
0
0
0
0
0
0
110000000
R29i1Dh)
0
0
1
1
1
0
1
OUTPD[3:2]
0
0
0
0
0
0
0
110000000
R31(1Fh)
0
0
1
1
1
1
1
ADDRESS
w
B8
B7
B6
B5
B4
B3
PL[3:0]
0
RECMUTE[2:0]
MUTEALL
DZFM[3:0]
0
WL[1:0]
BCP
DACRATE[2:0]
B2
IZD
ATC
B0
DZCEN
DEFAULT
010010000
DMUTE[3:0]
000000000
DEEMP[3:0]
000000000
LRP
000100010
ADCOSR
DACD[3:0]
RMX
B1
0
FMT[1:0]
ADCRATE[2:0]
000010010
ADCD
000111110
PWDN
LMX
100000000
RESET
Not reset
DATA
DEFAULT
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01001
Digital
Attenuation
DACL1
7:0
LDA1[7:0]
11111111
(0dB)
Digital Attenuation data for Left channel DACL1 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA1 in intermediate latch (no change to output)
1: Store LDA1 and update attenuation on all channels
01010
Digital
Attenuation
DACR1
7:0
RDA1[6:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR1 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA1 in intermediate latch (no change to output)
1: Store RDA1 and update attenuation on all channels.
01011
Digital
Attenuation
DACL2
7:0
LDA2[7:0]
11111111
(0dB)
Digital Attenuation data for Left channel DACL2 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA2 in intermediate latch (no change to output)
1: Store LDA2 and update attenuation on all channels.
01100
Digital
Attenuation
DACR2
7:0
RDA2[7:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR2 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA2 in intermediate latch (no change to output)
1: Store RDA2 and update attenuation on all channels.
01101
Digital
Attenuation
DACL3
7:0
LDA3[7:0]
11111111
(0dB)
Digital Attenuation data for Left channel DACL3 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA3 in intermediate latch (no change to output)
1: Store LDA3 and update attenuation on all channels.
01110
Digital
Attenuation
DACR3
7:0
RDA3[7:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR3 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA3 in intermediate latch (no change to output)
1: Store RDA3 and update attenuation on all channels.
01111
Digital
Attenuation
DACL4
7:0
LDA4[7:0]
11111111
(0dB)
Digital Attenuation data for Left channel DACL4 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store LDA4 in intermediate latch (no change to output)
1: Store LDA4 and update attenuation on all channels.
10000
Digital
Attenuation
DACR4
7:0
RDA4[7:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR4 in 0.5dB steps.
See Table 10
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store RDA4 in intermediate latch (no change to output)
1: Store RDA4 and update attenuation on all channels.
10001
Master
Digital
Attenuation
(all channels)
7:0
MASTDA[7:0]
11111111
(0dB)
Digital Attenuation data for all DAC channels in 0.5dB steps. See
Table 10
8
UPDATE
Not latched
w
Controls simultaneous update of all Attenuation Latches
0: Store gain in intermediate latch (no change to output)
1: Store gain and update attenuation on all channels.
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10010
Phase swaps
7:0
PHASE
00000000
Controls phase of DAC outputs
0: Sets non inverted output phase
1: inverts phase of DAC output
10011
DAC Control
0
DZCEN
0
DAC Digital Volume Zero Cross Enable:
0: Zero Cross detect disabled
1: Zero Cross detect enabled
1
ATC
0
Attenuator Control
0: All DACs use attenuations as programmed.
1: Right channel DACs use corresponding left DAC
attenuations
2
IZD
0
Infinite zero detection circuit control and automute control
0: Infinite zero detect disabled
1: Infinite zero detect enabled
7:4
PL[3:0]
1001
DAC Output Control
PL[3:0]
10100
DAC and
REC Mute
10101
DAC Control
Left
Output
Right
Output
PL[3:0]
Left
Output
Right
Output
0000
Mute
Mute
1000
Mute
Right
0001
Left
Mute
1001
Left
Right
0010
Right
Mute
1010
Right
Right
0011
(L+R)/2
Mute
1011
(L+R)/2
Right
0100
Mute
Left
1100
Mute
(L+R)/2
0101
Left
Left
1101
Left
(L+R)/2
0110
Right
Left
1110
Right
(L+R)/2
0111
(L+R)/2
Left
1111
(L+R)/2
(L+R)/2
3:0
DMUTE[3:0]
0000
4
MUTEALL
0
7:5
RECEN[2:0]
000
REC output enable
0 : REC outputs muted
1: REC outputs enabled
7:4
DZFM
0000
Selects the ouput for ZFLG1 and ZFLG2 pins (see Table 9).
1: indicates 1024 consecutive zero input samples on the
channels selected
0: indicates at least one of selected channels has non
zero sample in last 1024 inputs
3:0
DEEMP
0000
De-emphasis mode select:
0 : Normal Mode
1: De-emphasis Mode
1:0
FMT[1:0]
00
w
DAC channel soft mute enables:
0: mute disabled
1: mute enabled
DAC channel master soft mute. Mutes all DAC channels:
0: mute disabled
1: mute enabled
Interface format select
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2
LRP
0
ADCLRC/DACLRC Polarity or DSP Early/Late mode select
Left Justified / Right Justified /
I2S
0: Standard DACLRC Polarity
1: Inverted DACLRC Polarity
10111
Master Mode
control
11000
Powerdown
Control
11001
Attenuation
ADCL
DSP Mode
0: Data in-line with
ADCLRC/DACLRC
1: Data delayed by 1 BCLK
3
BCP
0
BITCLK Polarity
0: Normal - DIN[3:0], DACLRC & ADCLRC sampled on
rising edge of BCLK; DOUT changes on falling edge of
BCLK.
1: Inverted - DIN[3:0], DACLRC & ADCLRC sampled on
falling edge of BCLK; DOUT changes on rising edge of
BCLK.
5:4
WL[1:0]
10
Input Word Length
00: 16-bit Mode
01: 20-bit Mode
10: 24-bit Mode
11: 32-bit Mode (not supported in right justified mode)
8
ADCHPD
0
2:0
ADCRATE[2:0]
010
3
ADCOSR
0
6:4
DACRATE[2:0]
010
8
MS
0
Maser/Slave interface mode select
0: Slave Mode – ADCLRC, DACLRC and BCLK are inputs
1: Master Mode – ADCLRC, DACLRC and BCLK are outputs
0
PWDN
0
Chip Powerdown Control (works in tandem with ADCD and
DACD):
1
ADCD
1
ADC powerdown:
5:2
DACD[3:0]
1111
DAC powerdown
4:0
LAG[4:0]
01100
Attenuation data for left channel ADC gain in 1dB steps
5
MUTE
0
Mute for Left channel ADC:
0: Mute off
1: Mute on
6
LRBOTH
0
Setting LRBOTH will write the same gain value to LAG[4:0 and
RAG[4:0]
w
ADC Highpass Filter Disable:
0: Highpass Filter enabled
1: Highpass Filter disabled
Master Mode MCLK:ADCLRC ratio select:
000: 128fs
001: 192fs
010: 256fs
011: 384fs
100: 512fs
ADC oversample rate select
0: 128x oversampling
1: 64x oversapmling
Master Mode MCLK:DACLRC ratio select:
000: 128fs
001: 192fs
010: 256fs
011: 384fs
100: 512fs
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7
ADCMUTE
0
4:0
RAG[4:0]
01100
(0dB)
5
MUTE
0
Mute for Right channel ADC:
0: Mute off
1: Mute on
6
LRBOTH
0
Setting LRBOTH will write the same gain value to RAG[4:0 and
LAG[4:0]
2:0
LMX[2:0]
000
ADC left channel input mux control bits (see Table 12)
6:4
RMX[2:0]
000
ADC right channel input mux control bits (see Table 12)
8
AINPD
1
Input mux and buffer powerdown
0: Input mux and buffer enabled
1: Input mux and buffer powered down
11100
Output
powerdown
control
8:7
OUTPD[1:0]
11
DAC Output Powerdown select
0: output buffer enabled
1: output buffer powered down
11101
Output
powerdown
control
8:7
OUTPD[3:2]
11
DAC Output Powerdown select
0: output buffer enabled
1: output buffer powered down
11111
Software
reset
[8:0]
RESET
Not reset
11010
Attenuation
ADCR
11011
ADC mux and
powerdown
control
Mute for Left and Right channel ADC:
0: Mute off
1: Mute on
Attenuation data for right channel ADC gain in 1dB steps
Writing to this register will apply a reset to the device registers.
Table 13 Register Map Description
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DIGITAL FILTER CHARACTERISTICS
PARAMETER
TEST CONDITIONS
MIN
±0.01 dB
0
TYP
MAX
UNIT
ADC Filter
Passband
0.4535fs
-6dB
0.5fs
±0.01
Passband ripple
Stopband
dB
0.5465fs
Stopband Attenuation
f > 0.5465fs
-65
dB
Group Delay
22
fs
DAC Filter
±0.05 dB
Passband
0.444fs
-3dB
0.487fs
±0.05
Passband ripple
Stopband
dB
0.555fs
Stopband Attenuation
f > 0.555fs
-60
dB
Group Delay
16
fs
Table 14 Digital Filter Characteristics
DAC FILTER RESPONSES
0.2
0
0.15
-20
-40
Response (dB)
Response (dB)
0.1
-60
0.05
0
-0.05
-80
-0.1
-100
-0.15
-120
-0.2
0
0.5
1
1.5
Frequency (Fs)
2
2.5
3
Figure 22 DAC Digital Filter Frequency Response – 44.1, 48
and 96kHz
0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
Figure 23 DAC Digital Filter Ripple – 44.1, 48 and 96kHz
0.2
0
0
-0.2
Response (dB)
Response (dB)
-20
-40
-0.4
-0.6
-60
-0.8
-80
-1
0
0.2
0.4
0.6
Frequency (Fs)
0.8
1
Figure 24 DAC Digital Filter Frequency Response – 192kHz
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0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
Figure 25 DAC Digital filter Ripple – 192kHz
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ADC FILTER RESPONSES
0.02
0
0.015
0.01
Response (dB)
Response (dB)
-20
-40
0.005
0
-0.005
-60
-0.01
-0.015
-80
-0.02
0
0.5
1
1.5
Frequency (Fs)
2
2.5
3
0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
Figure 27 ADC Digital Filter Ripple
Figure 26 ADC Digital Filter Frequency Response
ADC HIGH PASS FILTER
The WM8771 has a selectable digital highpass filter to remove DC offsets. The filter response is characterised by the
following polynomial.
H(z) =
1 - z-1
1 - 0.9995z-1
Response (dB)
0
-5
-10
-15
0
0.0005
0.001
Frequency (Fs)
0.0015
0.002
Figure 28 ADC Highpass Filter Response
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DIGITAL DE-EMPHASIS CHARACTERISTICS
0
1
0.5
-2
Response (dB)
Response (dB)
0
-4
-6
-0.5
-1
-1.5
-2
-8
-2.5
-10
-3
0
2
4
6
8
10
Frequency (kHz)
12
14
16
Figure 29 De-Emphasis Frequency Response (32kHz)
0
2
4
6
8
10
Frequency (kHz)
12
14
16
Figure 30 De-Emphasis Error (32KHz)
0
0.4
0.3
-2
Response (dB)
Response (dB)
0.2
-4
-6
0.1
0
-0.1
-0.2
-8
-0.3
-10
-0.4
0
5
10
Frequency (kHz)
15
20
Figure 31 De-Emphasis Frequency Response (44.1KHz)
0
5
10
Frequency (kHz)
15
20
Figure 32 De-Emphasis Error (44.1KHz)
0
1
0.8
-2
0.6
Response (dB)
Response (dB)
0.4
-4
-6
0.2
0
-0.2
-0.4
-8
-0.6
-0.8
-10
-1
0
5
10
15
Frequency (kHz)
20
Figure 33 De-Emphasis Frequency Response (48kHz)
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0
5
10
15
Frequency (kHz)
20
Figure 34 De-Emphasis Error (48kHz)
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EXTERNAL CIRCUIT CONFIGURATION
In order to allow the use of 2V rms and larger inputs to the ADC and AUX inputs, a structure is used
that uses external resistors to drop these larger voltages. This also increases the robustness of the
circuit to external abuse such as ESD pulse.
Figure 35 shows the ADC input multiplexor circuit with external components allowing 2Vrms inputs to
be applied.
5K
AINOPL
10uF
10K
10uF
10K
10uF
10K
AINVGL
AIN1L
AIN2L
AIN3L
10uF
10K
10uF
10K
AIN7L
AIN8L
SOURCE
SELECTOR
INPUTS
5K
AINOPR
10uF
10K
10uF
10K
10uF
10K
AINVGR
AIN1R
AIN2R
AIN3R
10uF
10K
10uF
10K
AIN7R
AIN8R
Figure 35 ADC input multiplexor confiuration
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RECOMMENDED EXTERNAL COMPONENTS
It is recommended that a lowpass filter be applied to the output from each DAC channel for Hi-Fi
applications. Typically a second order filter is suitable and provides sufficient attenuation of high
frequency components (the unique low order, high bit count multi-bit sigma delta DAC structure used
in WM8771 produces much less high frequency output noise than competitors devices). This filter is
typically also used to provide the 2x gain needed to provide the standard 2Vrms output level from
most consumer equipment. Figure 24 shows a suitable post DAC filter circuit, with 2x gain.
Alternative inverting filter architectures might also be used with as good results.
1.0nF
10uF
1.8kΩ
Ω
7.5kΩ
Ω
51
VOUT1L
Ω
47kΩ
680pF
4.7kΩ
Ω
4.7kΩ
Ω
OP_FIL
VOUT1R
OP_FIL
VOUT2L
OP_FIL
VOUT2R
OP_FIL
VOUT3L
OP_FIL
VOUT3R
OP_FIL
VOUT4L
OP_FIL
VOUT4R
OP_FIL
Figure 36 Recommended post DAC filter circuit
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PACKAGE DIMENSIONS
FT: 64 PIN TQFP (10 x 10 x 1.0 mm)
DM027.A
b
e
48
33
32
49
E1
E
17
64
Θ
16
1
c
D1
L
D
A
A2
A1
-Cccc
Symbols
A
A1
A2
b
c
D
D1
E
E1
e
L
Θ
ccc
C
SEATING PLANE
Dimensions
(mm)
MIN
NOM
MAX
--------1.20
0.05
----0.15
1.00
1.05
0.95
0.27
0.17
0.22
0.09
----0.20
12.00 BSC
10.00 BSC
12.00 BSC
10.00 BSC
0.50 BSC
0.45
0.60
0.75
o
o
o
0
3.5
7
Tolerances of Form and Position
0.08
REF:
JEDEC.95, MS-026
NOTES:
A. ALL LINEAR DIMENSIONS ARE IN MILLIMETERS.
B. THIS DRAWING IS SUBJECT TO CHANGE WITHOUT NOTICE.
C. BODY DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSION, NOT TO EXCEED 0.25MM.
D. MEETS JEDEC.95 MS-026, VARIATION = ACD. REFER TO THIS SPECIFICATION FOR FURTHER DETAILS.
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IMPORTANT NOTICE
Wolfson Microelectronics Ltd (WM) 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. All products are sold subject to the WM terms and conditions of sale
supplied at the time of order acknowledgement, including those pertaining to warranty, patent infringement, and limitation
of liability.
WM warrants performance of its products to the specifications applicable at the time of sale in accordance with WM’s
standard warranty. Testing and other quality control techniques are utilised to the extent WM deems necessary to support
this warranty. Specific testing of all parameters of each device is not necessarily performed, except those mandated by
government requirements.
In order to minimise risks associated with customer applications, adequate design and operating safeguards must be used
by the customer to minimise inherent or procedural hazards.
WM assumes no liability for applications assistance or customer product design. WM does not warrant or represent that
any license, either express or implied, is granted under any patent right, copyright, mask work right, or other intellectual
property right of WM covering or relating to any combination, machine, or process in which such products or services might
be or are used. WM’s publication of information regarding any third party’s products or services does not constitute WM’s
approval, license, warranty or endorsement thereof.
Reproduction of information from the WM web site or datasheets is permissible only if reproduction is without alteration and
is accompanied by all associated warranties, conditions, limitations and notices. Representation or reproduction of this
information with alteration voids all warranties provided for an associated WM product or service, is an unfair and deceptive
business practice, and WM is not responsible nor liable for any such use.
Resale of WM’s products or services with statements different from or beyond the parameters stated by WM for that
product or service voids all express and any implied warranties for the associated WM product or service, is an unfair and
deceptive business practice, and WM is not responsible nor liable for any such use.
ADDRESS:
Wolfson Microelectronics Ltd
20 Bernard Terrace
Edinburgh
EH8 9NX
United Kingdom
Tel :: +44 (0)131 667 9386
Fax :: +44 (0)131 667 5176
Email :: [email protected]
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