WM8776 Product Datasheet

WM8776
w
24-bit, 192kHz Stereo CODEC with 5 Channel I/P Multiplexer
DESCRIPTION
FEATURES
The WM8776 is a high performance, stereo audio
CODEC with five channel input selector. The WM8776 is
ideal for surround sound processing applications for
home hi-fi, DVD-RW and other audio visual equipment.
•
Audio Performance
•
−
108dB SNR (‘A’ weighted @ 48kHz) DAC
−
102dB SNR (‘A’ weighted @ 48kHz) ADC
DAC Sampling Frequency: 32kHz – 192kHz
A stereo 24-bit multi-bit sigma delta ADC is used with a
five stereo channel input mixer. Each ADC channel has
programmable gain control with automatic level control.
Digital audio output word lengths from 16-32 bits and
sampling rates from 32kHz to 96kHz are supported.
A stereo 24-bit multi-bit sigma delta DAC is used with
digital audio input word lengths from 16-32 bits and
sampling rates from 32kHz to 192kHz. The DAC has an
input mixer allowing an external analogue signal to be
mixed with the DAC signal. There are also Headphone
and line outputs, with volume controls for the
headphones.
The WM8776 supports fully independent sample rates
for the ADC and DAC. The audio data interface supports
I2S, left justified, right justified and DSP formats.
The device is controlled in software via a 2 or 3 wire
serial interface, selected by the MODE pin, which
provides access to all features including channel
selection, volume controls, mutes, and de-emphasis
facilities.
The device is available in a 48-pin TQFP package.
BLOCK DIAGRAM
•
•
•
•
•
•
ADC Sampling Frequency: 32kHz – 96kHz
Five stereo ADC inputs with analogue gain adjust from
+24dB to –21dB in 0.5dB steps
Programmable Limiter or Automatic Level Control (ALC)
Stereo DAC with independent analogue and digital
volume controls
•
•
Stereo Headphone and Line Output
3-Wire SPI Compatible or 2-Wire Software Serial
Control Interface
Master or Slave Clocking Mode
Programmable Audio Data Interface Modes
•
−
I2S, Left, Right Justified or DSP
−
16/20/24/32 bit Word Lengths
Analogue Bypass Path Feature
•
•
Selectable AUX input to the volume controls
2.7V to 5.5V Analogue, 2.7V to 3.6V Digital supply
Operation
APPLICATIONS
•
•
Surround Sound AV Processors and Hi-Fi systems
DVD-RW
WOLFSON MICROELECTRONICS plc
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Production Data, September 2008, Rev 4.1
Copyright ©2008 Wolfson Microelectronics plc
WM8776
Production Data
TABLE OF CONTENTS
DESCRIPTION .......................................................................................................1
FEATURES.............................................................................................................1
APPLICATIONS .....................................................................................................1
BLOCK DIAGRAM .................................................................................................1
TABLE OF CONTENTS .........................................................................................2
PIN CONFIGURATION...........................................................................................3
ORDERING INFORMATION ..................................................................................3
PIN DESCRIPTION ................................................................................................4
ABSOLUTE MAXIMUM RATINGS.........................................................................5
ELECTRICAL CHARACTERISTICS ......................................................................6
TERMINOLOGY ............................................................................................................ 7
MASTER CLOCK TIMING......................................................................................9
DIGITAL AUDIO INTERFACE – MASTER MODE ....................................................... 10
DIGITAL AUDIO INTERFACE – SLAVE MODE .......................................................... 11
3-WIRE MPU INTERFACE TIMING ............................................................................ 12
CONTROL INTERFACE TIMING – 2-WIRE MODE .................................................... 13
INTERNAL POWER ON RESET CIRCUIT ..........................................................14
DEVICE DESCRIPTION.......................................................................................16
INTRODUCTION ......................................................................................................... 16
AUDIO DATA SAMPLING RATES............................................................................... 17
ZERO DETECT ........................................................................................................... 18
POWERDOWN MODES ............................................................................................. 18
DIGITAL AUDIO INTERFACE ..................................................................................... 19
CONTROL INTERFACE OPERATION ........................................................................ 23
CONTROL INTERFACE REGISTERS ........................................................................ 25
LIMITER / AUTOMATIC LEVEL CONTROL (ALC) ...................................................... 34
REGISTER MAP ......................................................................................................... 41
DIGITAL FILTER CHARACTERISTICS ...............................................................49
DAC FILTER RESPONSES......................................................................................... 49
ADC FILTER RESPONSES......................................................................................... 50
ADC HIGH PASS FILTER ........................................................................................... 51
DIGITAL DE-EMPHASIS CHARACTERISTICS........................................................... 52
APPLICATIONS INFORMATION .........................................................................53
EXTERNAL CIRCUIT CONFIGURATION ................................................................... 53
RECOMMENDED EXTERNAL COMPONENTS ..................................................54
PACKAGE DIMENSIONS ....................................................................................56
PACKAGE DIMENSIONS ....................................................................................56
IMPORTANT NOTICE ..........................................................................................57
ADDRESS: .................................................................................................................. 57
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PIN CONFIGURATION
ORDERING INFORMATION
DEVICE
TEMPERATURE
RANGE
PACKAGE
MOISTURE
SENSITIVITY LEVEL
PEAK SOLDERING
TEMPERATURE
WM8776SEFT/V
-25 to +85oC
48-pin TQFP
(Pb-free)
MSL2
(drybagged)
260°C
WM8776SEFT/RV
-25 to +85oC
48-pin TQFP
(Pb-free, tape and reel)
MSL2
(drybagged)
260°C
Note:
Reel quantity = 2,200
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PIN DESCRIPTION
PIN
NAME
TYPE
1
AIN2L
Analogue Input
Channel 2 left input multiplexor virtual ground
DESCRIPTION
2
AIN1R
Analogue Input
Channel 1 right input multiplexor virtual ground
3
AIN1L
Analogue Input
Channel 1 left input multiplexor virtual ground
4
DACBCLK
Digital input/output
5
DACMCLK
Digital input
Master DAC clock; 256, 384, 512 or 768fs (fs = word clock frequency)
6
DIN
Digital Input
DAC data input
7
DACLRC
Digital input/output
DAC left/right word clock
8
ZFLAGR
Open Drain output
DAC Right Zero Flag output (external pull-up resistor required)
9
ZFLAGL
Open Drain output
DAC Left Zero Flag output (external pull-up resistor required)
10
ADCBCLK
Digital input/output
ADC audio interface bit clock
11
ADCMCLK
Digital input
12
DOUT
Digital output
13
ADCLRC
Digital input/output
14
DGND
Supply
Digital negative supply
15
DVDD
Supply
Digital positive supply
16
MODE
Digital input
Control interface mode select
17
CE
Digital input
Serial interface Latch signal
18
DI
Digital input
Serial interface data
19
CL
Digital input
Serial interface clock
20
HPOUTL
Analogue Output
21
HPGND
Supply
Headphone negative supply
22
HPVDD
Supply
Headphone positive supply
23
HPOUTR
Analogue Output
24
NC
Not bonded
DAC audio interface bit clock
ADC audio interface master clock
ADC data output
ADC left/right word clock
Headphone left channel output
Headphone right channel output
25
NC
Not bonded
26
VOUTL
Analogue output
DAC channel left output
27
VOUTR
Analogue output
DAC channel right output
28
VMIDDAC
Analogue output
DAC midrail decoupling pin ; 10uF external decoupling
29
DACREFN
Analogue input
DAC negative reference input
30
DACREFP
Analogue input
DAC positive reference input
31
AUXR
Analogue input
DAC mixer right channel input
32
AUXL
Analogue input
DAC mixer left channel input
33
VMIDADC
Analogue Output
34
ADCREFGND
Supply
35
ADCREFP
Analogue Output
36
AVDD
Supply
Analogue positive supply
37
AGND
Supply
Analogue negative supply and subVstrate connection
38
AINVGR
Analogue Input
39
AINOPR
Analogue Output
40
AINVGL
Analogue Input
41
AINOPL
Analogue Output
42
AIN5R
Analogue Input
Channel 5 right input multiplexor virtual ground
43
AIN5L
Analogue Input
Channel 5 left input multiplexor virtual ground
44
AIN4R
Analogue Input
Channel 4 right input multiplexor virtual ground
45
AIN4L
Analogue Input
Channel 4 left input multiplexor virtual ground
46
AIN3R
Analogue Input
Channel 3 right input multiplexor virtual ground
47
AIN3L
Analogue Input
Channel 3 left input multiplexor virtual ground
48
AIN2R
Analogue Input
Channel 2 right input multiplexor virtual ground
ADC midrail divider decoupling pin; 10uF external decoupling
ADC negative supply and substrate connection
ADC positive reference decoupling pin; 10uF external decoupling
Right channel multiplexor virtual ground
Right channel multiplexor output
Left channel multiplexor virtual ground
Left channel multiplexor output
Note : Digital input pins have Schmitt trigger input buffers.
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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.
Wolfson tests its package types according to IPC/JEDEC J-STD-020B for Moisture Sensitivity to determine acceptable storage
conditions prior to surface mount assembly. These levels are:
MSL1 = unlimited floor life at <30°C / 85% Relative Humidity. Not normally stored in moisture barrier bag.
MSL2 = out of bag storage for 1 year at <30°C / 60% Relative Humidity. Supplied in moisture barrier bag.
MSL3 = out of bag storage for 168 hours at <30°C / 60% Relative Humidity. Supplied in moisture barrier bag.
The Moisture Sensitivity Level for each package type is specified in Ordering Information.
CONDITION
MIN
MAX
Digital supply voltage
-0.3V
+3.63V
Analogue supply voltage
-0.3V
+7V
Voltage range digital inputs (MCLK, DIN, ADCLRC, DACLRC,
ADCBCLK, DACBCLK, DI, CL, CE and MODE)
DGND -0.3V
DVDD + 0.3V
Voltage range analogue inputs
AGND -0.3V
AVDD +0.3V
Master Clock Frequency
37MHz
Operating temperature range, TA
-25°C
+85°C
Storage temperature
-65°C
+150°C
Notes:
1.
Analogue and digital grounds must always be within 0.3V of each other.
RECOMMENDED OPERATING CONDITIONS
PARAMETER
MAX
UNIT
DVDD
2.7
3.6
V
Analogue supply range
AVDD, HPVDD,
DACREFP
2.7
5.5
V
Ground
AGND, DGND,
DACREFN,
ADCREFGND
Digital supply range
SYMBOL
TEST CONDITIONS
Difference DGND to AGND
MIN
TYP
0
-0.3
0
V
+0.3
V
Note: digital supply DVDD must never be more than 0.3V greater than AVDD.
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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 DVDD
0.9 x DVDD
V
V
Analogue Reference Levels
Reference voltage
VVMID
AVDD/2
V
Potential divider resistance
RVMID
50k
Ω
DAC Performance (Load = 10k Ω, 50pF)
0dBFs Full scale output voltage
1.0 x
AVDD/5
Vrms
108
dB
SNR (Note 1,2)
A-weighted,
@ fs = 48kHz
SNR (Note 1,2)
A-weighted
@ fs = 96kHz
108
dB
A-weighted, -60dB
full scale input
108
dB
Dynamic Range (Note 2)
DNR
Total Harmonic Distortion (THD)
102
1kHz, 0dBFs
-97
DAC channel separation
-90
100
Power Supply Rejection Ratio
PSRR
dB
dB
1kHz 100mVpp
50
dB
20Hz to 20kHz
100mVpp
45
dB
Headphone Buffer
Maximum Output voltage
Max Output Power (Note 4)
Po
SNR (Note 1,2)
0.9
Vrms
RL = 32 Ω
25
mW
RL = 16 Ω
50
mW
A-weighted
Headphone analogue Volume
Gain Step Size
85
92
0.5
1
dB
1.5
dB
+6
dB
Headphone analogue Volume
Gain Range
1kHz Input
Headphone analogue Volume
Mute Attenuation
1kHz Input, 0dB gain
100
1kHz, RL = 32Ω @ Po =
10mW rms
-80
0.01
-60
0.1
dB
%
1kHz, RL = 32Ω @ Po =
20mW rms
-77
0.014
-55
1.0
dB
%
20Hz to 20kHz, without
supply decoupling
-40
Total Harmonic Distortion
Power Supply Rejection Ratio
THD
PSRR
-73
dB
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)
A-weighted, 0dB gain
@ fs = 96kHz
64 x OSR
Dynamic Range (note 2)
Total Harmonic Distortion (THD)
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97
Vrms
102
dB
100
dB
A-weighted, -60dB
full scale input
102
dB
1kHz, 0dBFs
-92
dB
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Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND = 0V, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated.
ADC Channel Separation
1kHz, -1dBFs
-95
1kHz Input
90
Programmable Gain Step Size
0.25
-85
dB
dB
0.5
0.75
dB
Programmable Gain Range
(Analogue)
1kHz Input
-21
+24
dB
Programmable Gain Range
(Digital)
1kHz Input
-103
-21.5
dB
Analogue Mute Attenuation
(Note 6)
1kHz Input, 0dB gain
76
dB
1kHz 100mVpp
50
dB
20Hz to 20kHz
100mVpp
45
dB
Power Supply Rejection Ratio
PSRR
Analogue Input (AIN) to Analogue output (VOUT) (Load=10kΩ, 50pF, gain = 0dB) Bypass Mode
0dB Full scale output voltage
SNR (Note 1)
99
THD
Power Supply Rejection Ratio
PSRR
1.0 x
AVDD/5
Vrms
103
dB
1kHz, 0dB
-93
dB
1kHz, -3dB
-95
dB
1kHz 100mVpp
50
dB
20Hz to 20kHz
100mVpp
45
dB
1kHz, 0dB
100
dB
AVDD = 5V
48
mA
DVDD = 3.3V
8
mA
SNR
108
dB
THD
-95
dB
Mute Attenuation
Supply Current
Analogue supply current
Digital supply current
Aux Input (AUX/L/R) to Analogue output (VOUT L/R)( Load=10kΩ, 50pF, gain = 0dB)
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).
4.
Harmonic distortion on the headphone output decreases with output power.
5.
All performance measurement done using certain timings conditions (Please refer to section ‘Digital Audio Interface’).
6.
A full digital MUTE can be achieved if the ADC gain (LAG/RAG) is set to minimum.
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).
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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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MASTER CLOCK TIMING
tMCLKL
MCLK
tMCLKH
tMCLKY
Figure 1 Master Clock Timing Requirements
Test Conditions
o
AVDD = 5V, DVDD = 3.3V, AGND = 0V, AGND, DGND = 0V, TA = +25 C, fs = 48kHz, ADC/DACMCLK = 256fs unless
otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
System Clock Timing Information
ADC/DACMCLK System clock
pulse width high
tMCLKH
11
ns
ADC/DACMCLK System clock
pulse width low
tMCLKL
11
ns
ADC/DACMCLK System clock
cycle time
tMCLKY
28
1000
ADC/DACMCLK Duty cycle
Power-saving mode activated
Normal mode resumed
ns
40:60
60:40
After MCLK stopped
2
10
µs
After MCLK re-started
0.5
1
MCLK
cycle
Table 1 Master Clock Timing Requirements
Note:
If MCLK period is longer than maximum specified above, power-saving mode is entered and DACs are powered down with
internal digital audio filters being reset. In this power-saving mode, all registers will retain their values and can be accessed
in the normal manner through the control interface. Once MCLK is restored, the DACs are automatically powered up, but a
write to the volume update register bit is required to restore the correct volume settings.
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DIGITAL AUDIO INTERFACE – MASTER MODE
DACBCLK
ADCBCLK
ADCLRC
WM8776
CODEC DACLRC
DVD
Controller
DOUT
DIN
Figure 2 Audio Interface - Master Mode
ADCBCLK/
DACBCLK
(Output)
tDL
ADCLRC/
DACLRC
(Outputs)
tDDA
DOUT
DIN
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, ADC/DACMCLK = 256fs unless
otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Audio Data Input Timing Information
ADC/DACLRC propagation
delay from ADC/DACBCLK
falling edge
tDL
0
10
ns
DOUT propagation delay
from ADCBCLK falling edge
tDDA
0
10
ns
DIN setup time to
DACBCLK rising edge
tDST
10
ns
DIN hold time from
DACBCLK rising edge
tDHT
10
ns
Table 2 Digital Audio Data Timing – Master Mode
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DIGITAL AUDIO INTERFACE – SLAVE MODE
DACBCLK
ADCBCLK
WM8776 ADCLRC
CODEC
DACLRC
DVD
Controller
DOUT
DIN
Figure 4 Audio Interface – Slave Mode
tBCH
ADCBCLK/
DACBCLK
tBCL
tBCY
DACLRC/
ADCLRC
tDS
tLRH
tLRSU
DIN
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, ADC/DACMCLK = 256fs unless
otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Audio Data Input Timing Information
ADC/DACBCLK cycle time
tBCY
50
ns
ADC/DACBCLK pulse width
high
tBCH
20
ns
ADC/DACBCLK pulse width
low
tBCL
20
ns
DACLRC/ADCLRC set-up
time to ADC/DACBCLK
rising edge
tLRSU
10
ns
DACLRC/ADCLRC hold
time from ADC/DACBCLK
rising edge
tLRH
10
ns
DIN set-up time to
DACBCLK rising edge
tDS
10
ns
DIN hold time from
DACBCLK rising edge
tDH
10
ns
DOUT propagation delay
from ADCBCLK 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 WM8776 interface is tolerant of phase
variations or jitter on these signals.
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3-WIRE MPU INTERFACE TIMING
tCSL
tCSH
CE
tSCY
tSCH
tCSS
tSCS
tSCL
CL
DI
LSB
tDSU
tDHO
Figure 6 SPI Compatible (3-wire) Control Interface Input Timing (MODE=1)
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated
SYMBOL
MIN
CL rising edge to CE rising edge
PARAMETER
tSCS
60
TYP
MAX
UNIT
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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CONTROL INTERFACE TIMING – 2-WIRE MODE
t3
t3
t5
DI
t6
t4
t2
t8
CL
t1
t9
t7
Figure 7 Control Interface Timing – 2-Wire Serial Control Mode (MODE=0)
Test Conditions
AVDD = 5V, DVDD = 3.3V, AGND, DGND = 0V, TA = +25oC, fs = 48kHz, MCLK = 256fs unless otherwise stated
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
CL Low Pulse-Width
t1
1.3
526
kHz
us
CL High Pulse-Width
t2
600
ns
Hold Time (Start Condition)
t3
600
ns
Setup Time (Start Condition)
t4
600
ns
Data Setup Time
t5
100
DI, CL Rise Time
t6
300
DI, CL Fall Time
t7
300
Setup Time (Stop Condition)
t8
Program Register Input Information
CL Frequency
0
Data Hold Time
t9
Pulse width of spikes that will be suppressed
tps
ns
600
0
ns
ns
ns
900
ns
5
ns
Table 5 2-wire Control Interface Timing Information
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INTERNAL POWER ON RESET CIRCUIT
Figure 8 Internal Power on Reset Circuit Schematic
The WM8776 includes an internal Power on Reset Circuit which is used reset the digital logic into a
default state after power up.
Figure 8 shows a schematic of the internal POR circuit. The POR circuit is powered from AVDD. The
circuit monitors DVDD and VMID and asserts PORB low if DVDD or VMID are below the minimum
threshold Vpor_off.
On power up, the POR circuit requires AVDD to be present to operate. PORB is asserted low until
AVDD and DVDD and VMID are established. When AVDD, DVDD, and VMID have been
established, PORB is released high, all registers are in their default state and writes to the digital
interface may take place.
On power down, PORB is asserted low whenever DVDD or VMID drop below the minimum threshold
Vpor_off.
If AVDD is removed at any time, the internal Power on Reset circuit is powered down and PORB will
follow AVDD.
In most applications the time required for the device to release PORB high will be determined by the
charge time of the VMID node.
Figure 9 Typical Power up Sequence where DVDD is Powered before AVDD
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Figure 10 Typical Power up Sequence where AVDD is Powered before DVDD
Typical POR Operation (typical values, not tested)
SYMBOL
MIN
TYP
MAX
UNIT
Vpora
0.5
0.7
1.0
V
Vporr
0.5
0.7
1.1
V
Vpora_off
1.0
1.4
2.0
V
Vpord_off
0.6
0.8
1.0
V
In a real application the designer is unlikely to have control of the relative power up sequence of
AVDD and DVDD. Using the POR circuit to monitor VMID ensures a reasonable delay between
applying power to the device and Device Ready.
Figure 9 and Figure 10 show typical power up scenarios in a real system. Both AVDD and DVDD
must be established and VMID must have reached the threshold Vporr before the device is ready
and can be written to. Any writes to the device before Device Ready will be ignored.
Figure 9 shows DVDD powering up before AVDD. Figure 10 shows AVDD powering up before
DVDD. In both cases, the time from applying power to Device Ready is dominated by the charge
time of VMID.
A 10uF cap is recommended for decoupling on VMID. The charge time for VMID will dominate the
time required for the device to become ready after power is applied. The time required for VMID to
reach the threshold is a function of the VMID resistor string and the decoupling capacitor. The
Resistor string has an typical equivalent resistance of 50kΩ (+/-20%). Assuming a 10uF capacitor,
the time required for VMID to reach threshold of 1V is approx 110ms.
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DEVICE DESCRIPTION
INTRODUCTION
WM8776 is a complete 2-channel DAC, 2-channel ADC audio CODEC, with flexible input multiplexor
including digital interpolation and decimation filters, multi-bit sigma delta stereo ADC, and switched
capacitor multi-bit sigma delta DACs with analogue volume controls on each channel and output
smoothing filters. It is available in a single package and controlled by either a 3-wire or 2-wire
software interface. The 3-wire interface is compatible with the SPI standard.
An analogue bypass path option is available, to allow stereo analogue signals from any of the 5
stereo inputs to be sent to the stereo outputs via the main volume controls. This allows a purely
analogue input to analogue output high quality signal path to be implemented if required.
The DAC and ADC have separate left/right clocks, bit clocks, master clocks and data I/Os. The
Audio Interface may be configured to operate in either master or slave mode. In Slave mode
ADCLRC, DACLRC, ADCBCLK and DACBCLK are all inputs. In Master mode ADCLRC, DACLRC,
ADCBCLK and DACBCLK are 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 has an analogue input PGA and a digital gain control, accessed by one
register write. The input PGA allows input signals to be gained up to +24dB and attenuated down to
-21dB in 0.5dB steps. The digital gain control allows attenuation from -21.5dB to -103dB in 0.5dB
steps. This allows the user maximum flexibility in the use of the ADC.
The DAC has its own digital volume control, which is adjustable between 0dB and -127.5dB in 0.5dB
steps. There is also an analogue volume control on the headphone outputs, which is adjustable
between +6dB and -73dB in 1dB steps. The analogue and digital volume controls may be operated
independently. In addition a zero cross detect circuit is provided for both analogue and digital volume
controls. When analogue volume zero-cross detection is enabled the attenuation values are only
updated when the input signal to the gain stage is close to the analogue ground level. 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.
The DAC output incorporates an input selector and mixer allowing a signal to be either switched into
the signal path in place of the DAC signal or mixed with the DAC signal before the volume control.
Use of external resistors allows larger input levels to be accepted by the device, giving maximum
user flexibility.
Internal functionality is controlled by CE, CL, DI and MODE input pins. The MODE pin determines
which of the two control interface modes is selected.
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 and have their own bit clocks and master clocks.
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 WM8776 uses separate master clocks for the ADC and DAC. The external master
system clocks can be applied directly through the ADCMCLK and DACMCLK input pins 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 WM8776 supports DAC and ADC audio sampling rates from 256fs to 768fs,
where fs is the audio sampling frequency (DACLRC or ADCLRC) typically 32kHz, 44.1kHz, 48kHz or
96kHz (the DAC also supports operation at 128fs and 192fs and 192kHz sample rate). The master
clock is used to operate the digital filters and the noise shaping circuits.
In Slave mode the WM8776 has a master detection circuit that automatically determines the
relationship between the master 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 should be synchronised with ADCLRC/DACLRC for optical
performance, although the WM8776 is tolerant of phase variations or jitter on this clock. Table 6
shows the typical master clock frequency inputs for the WM8776.
The signal processing for the WM8776 typically operates at an oversampling rate of 128fs for both
ADC and DAC. The exception to this for the DAC is for operation with a 128/192fs system clock, e.g.
for 192kHz operation where the oversampling rate is 64fs. 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.
SAMPLING
RATE
(DACLRC/
ADCLRC)
128fs
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
System Clock Frequency (MHz)
256fs
192fs
384fs
512fs
768fs
DAC ONLY
48kHz
6.144
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 DACBCLK, ADCBCLK, DACLRC and ADCLRC are generated by the WM8776. The
frequencies of ADCLRC and DACLRC are set by setting the required ratio of DACMCLK to DACLRC
and ADCMCLK to ADCLRC using the DACRATE and ADCRATE control bits (Table 7).
ADCRATE[2:0]/
DACRATE[2:0]
ADCMCLK/DACMCLK:
ADCLRC/DACLRC
RATIO
000
128fs (DAC Only)
001
192fs (DAC Only)
010
256fs
011
384fs
100
512fs
101
768fs
Table 7 Master Mode MCLK:ADCLRC/DACLRC Ratio Select
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Table 8 shows the settings for ADCRATE and DACRATE for common sample rates and
ADCMCLK/DACMCLK frequencies.
SAMPLING
RATE
(DACLRC/
ADCLRC)
System Clock Frequency (MHz)
128fs
192fs
256fs
384fs
512fs
768fs
DACRATE
=000
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
24.576
36.864
48kHz
6.144
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 8 Master Mode ADC/DACLRC Frequency Selection
ADCBCLK and DACBCLK are also generated by the WM8776. The frequency of ADCBCLK and
DACBCLK depends on the mode of operation.
In 128/192fs modes (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. 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 WM8776 has a zero detect circuit for each DAC channel, which detects when 1024 consecutive
zero samples have been input. The two zero flag outputs (ZFLAGL and ZFLAGR) may be
programmed to output the zero detect signals (see Table 9) that may then be used to control external
muting circuits. A ‘1’ on ZFLAGL or ZFLAGR 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 00. The zero flag signal for each DAC channel will only be enabled if it is enabled as
an input to the output summing stage.
DZFM[1:0]
ZFLAGL
ZFLAGR
00
Zero flag disabled
Zero flag disabled
01
Left channel zero
Right channel zero
10
Both channel zero
Both channel zero
11
Either channels zero
Either channel zero
Table 9 Zero Flag Output Select
POWERDOWN MODES
The WM8776 has powerdown control bits allowing specific parts of the WM8776 to be powered off
when not being used. The 5-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 AIN5L/R)
are switched to a buffered VMIDADC. Control bit ADCPD powers off the ADC and also the ADC input
PGAs. The stereo DAC has a separate powerdown control bit, DACPD allowing the DAC and
analogue output mixer to be powered off when not in use. This also switches the analogue outputs
VOUTL/R to VMIDDAC to maintain a dc level on the output.
Setting AINPD, ADCPD and DACPD 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 AINPD, HPPD, ADCPD and
DACPD are set before setting PDWN. The default is for all blocks to be enabled other than HPPD.
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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 DIN is always an input to the WM8776 and DOUT is always an output.
The default is Slave mode.
In Slave mode (MS=0) ADCLRC, DACLRC, ADCBCLK and DACBCLK are inputs to the WM8776
(Figure 11). DIN and DACLRC are sampled by the WM8776 on the rising edge of DACBCLK,
ADCLRC is sampled on the rising edge of ADCBCLK. ADC data is output on DOUT and changes on
the falling edge of ADCBCLK. By setting control bit BCLKINV the polarity of ADCBCLK and
DACBCLK may be reversed so that DIN and DACLRC are sampled on the falling edge of DACBCLK,
ADCLRC is sampled on the falling edge of ADCBCLK and DOUT changes on the rising edge of
ADCBCLK.
DACBCLK
ADCBCLK
WM8776 ADCLRC
CODEC
DACLRC
DVD
Controller
DOUT
DIN
Figure 11 Slave Mode
In Master mode (MS=1) ADCLRC, DACLRC, ADCBCLK and DACBCLK are outputs from the
WM8776 (Figure 12). ADCLRC, DACLRC, ADCBCLK and DACBCLK are generated by the WM8776.
DIN is sampled by the WM8776 on the rising edge of DACBCLK so the controller must output DAC
data that changes on the falling edge of DACBCLK. ADC data is output on DOUT and changes on
the falling edge of ADCBCLK. By setting control bit BCLKINV, the polarity of ADCBCLK and
DACBCLK may be reversed so that DIN is sampled on the falling edge of DACBCLK and DOUT
changes on the rising edge of ADCBCLK.
DACBCLK
ADCBCLK
ADCLRC
WM8776
CODEC DACLRC
DVD
Controller
DOUT
DIN
Figure 12 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 mode A
•
DSP mode B
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 DIN
input 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 modes A or B, DACLRC is used as a frame sync signal to identify the MSB of the first word.
The minimum number of DACBCLKs per DACLRC period is 2 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 modes A or B, with ADCLRC used as a frame sync to identify
the MSB of the first word. The minimum number of ADCBCLKs per ADCLRC period is 2 times the
selected word length.
LEFT JUSTIFIED MODE
In left justified mode, the MSB of DIN is sampled by the WM8776 on the first rising edge of
DACBCLK following a DACLRC transition. The MSB of the ADC data is output on DOUT and
changes on the same falling edge of ADCBCLK as ADCLRC and may be sampled on the rising edge
of ADCBCLK. ADCLRC and DACLRC are high during the left samples and low during the right
samples (Figure 13).
1/fs
LEFT CHANNEL
RIGHT CHANNEL
DACLRC/
ADCLRC
DACBCLK/
ADCBCLK
DIN/
DOUT
1
MSB
2
3
n-2 n-1
n
LSB
1
MSB
2
3
n-2 n-1
n
LSB
Figure 13 Left Justified Mode Timing Diagram
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RIGHT JUSTIFIED MODE
In right justified mode, the LSB of DIN is sampled by the WM8776 on the rising edge of DACBCLK
preceding a DACLRC transition. The LSB of the ADC data is output on DOUT and changes on the
falling edge of ADCBCLK preceding a ADCLRC transition and may be sampled on the rising edge of
ADCBCLK. ADCLRC and DACLRC are high during the left samples and low during the right samples
(Figure 14).
1/fs
LEFT CHANNEL
RIGHT CHANNEL
DACLRC/
ADCLRC
DACBCLK/
ADCBCLK
DIN/
DOUT
1
2
3
n-2 n-1
MSB
n
1
LSB
2
3
n-2 n-1
MSB
n
LSB
Figure 14 Right Justified Mode Timing Diagram
2
I S MODE
In I2S mode, the MSB of DIN is sampled by the WM8776 on the second rising edge of DACBCLK
following a DACLRC transition. The MSB of the ADC data is output on DOUT and changes on the
first falling edge of ADCBCLK following an ADCLRC transition and may be sampled on the rising
edge of ADCBCLK. ADCLRC and DACLRC are low during the left samples and high during the right
samples.
1/fs
LEFT CHANNEL
RIGHT CHANNEL
DACLRC/
ADCLRC
DACBCLK/
ADCBCLK
1 BCLK
1 BCLK
DIN/
DOUT
1
2
3
n-2 n-1
MSB
n
LSB
1
MSB
2
3
n-2 n-1
n
LSB
2
Figure 15 I S Mode Timing Diagram
DSP MODES
In DSP/PCM mode, the left channel MSB is available on either the 1st (mode B) or 2nd (mode A)
rising edge of BCLK (selectable by LRP) following a rising edge of LRC. Right channel data
immediately follows left channel data. Depending on word length, BCLK frequency and sample rate,
there may be unused BCLK cycles between the LSB of the right channel data and the next sample.
In device master mode, the LRC output will resemble the frame pulse shown in Figure 16 and Figure
17. In device slave mode, Figure 18 and Figure 19, it is possible to use any length of frame pulse
less than 1/fs, providing the falling edge of the frame pulse occurs greater than one BCLK period
before the rising edge of the next frame pulse.
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Figure 16 DSP/PCM Mode Audio Interface (mode A, LRP=0, Master)
Figure 17 DSP/PCM Mode Audio Interface (mode B, LRP=1, Master)
Figure 18 DSP/PCM Mode Audio Interface (mode A, LRP=0, Slave)
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Figure 19 DSP/PCM Mode Audio Interface (mode B, LRP=0, Slave)
CONTROL INTERFACE OPERATION
The WM8776 is controlled by writing to registers through a serial control interface. A control word
consists of 16 bits. The first 7 bits (B15 to B9) are address bits that select which control register is
accessed. The remaining 9 bits (B8 to B0) are data bits, corresponding to the 9 bits in each control
register. The control interface can operate as either a 3-wire or 2-wire MPU interface. The MODE pin
selects the interface format, as shown in Table 10. .
MODE
Control Mode
0
2 wire interface
1
3 wire interface
Table 10 Control Interface Selection via MODE Pin
3-WIRE (SPI COMPATIBLE) SERIAL CONTROL MODE
In 3-wire mode, every rising edge of CL clocks in one data bit from the DI pin. A rising edge on CE
latches in a complete control word consisting of the last 16 bits. The 3-wire interface protocol is
shown in Figure 20.
latch
CE
CL
DI
B15
B14
B13
B12
B11
B10
B9
control register address
B8
B7
B6
B5
B4
B3
B2
B1
B0
control register data bits
Figure 20 3-wire SPI Compatible Interface
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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.
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2-WIRE SERIAL CONTROL MODE
The WM8776 supports software control via a 2-wire serial bus. Many devices can be controlled by
the same bus, and each device has a unique 7-bit address (this is not the same as the 7-bit address
of each register in the WM8776).
The WM8776 operates as a slave device only. The controller indicates the start of data transfer with
a high to low transition on DI while CL remains high. This indicates that a device address and data
will follow. All devices on the 2-wire bus respond to the start condition and shift in the next eight bits
on DI (7-bit address + Read/Write bit, MSB first). If the device address received matches the address
of the WM8776 and the R/W bit is ‘0’, indicating a write, then the WM8776 responds by pulling DI low
on the next clock pulse (ACK). If the address is not recognised or the R/W bit is ‘1’, the WM8776
returns to the idle condition and wait for a new start condition and valid address.
Once the WM8776 has acknowledged a correct address, the controller sends the first byte of control
data (B15 to B8, i.e. the WM8776 register address plus the first bit of register data). The WM8776
then acknowledges the first data byte by pulling DI low for one clock pulse. The controller then sends
the second byte of control data (B7 to B0, i.e. the remaining 8 bits of register data), and the WM8776
acknowledges again by pulling DI low.
The transfer of data is complete when there is a low to high transition on DI while CL is high. After
receiving a complete address and data sequence the WM8776 returns to the idle state and waits for
another start condition. If a start or stop condition is detected out of sequence at any point during
data transfer (i.e. DI changes while CL is high), the device jumps to the idle condition.
Figure 21 2-wire Serial Interface
1.
B[15:9] are Control Address Bits
2.
B[8:0] are Control Data Bits
The WM8776 has two possible device addresses, which can be selected using the CE pin.
CE STATE
DEVICE ADDRESS
Low
0011010 (0 x 34h)
High
0011011 (0 x 36h)
Table 11 2-Wire MPU Interface Address Selection
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CONTROL INTERFACE REGISTERS
DIGITAL AUDIO INTERFACE CONTROL REGISTER
Interface format is selected via the FMT[1:0] register bits:
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R10 (0Ah)
0001010
DAC Interface Control
1:0
DACFMT
[1:0]
10
R11 (0Bh)
0001011
ADC Interface Control
1:0
ADCFMT
[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 13, Figure 14, etc. 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
R10 (0Ah)
0001010
DAC Interface Control
2
DACLRP
0
R11 (0Bh)
0001011
ADC Interface Control
2
ADCLRP
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 DIN are sampled on the rising edge of ADCBCLK and DACBCLK
and should ideally change on the falling edge. Data sources that change ADCLRC/DACLRC and DIN
on the rising edge of ADCBCLK/DACBCLK 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 13, Figure 14, etc.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R10 (0Ah)
0001010
DAC Interface Control
3
DACBCP
0
R11 (0Bh)
0001011
ADC Interface Control
3
ADCBCP
0
DESCRIPTION
BCLK Polarity (DSP modes)
0 : normal BCLK polarity
1: inverted BCLK polarity
The WL[1:0] bits are used to control the input word length.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R10 (0Ah)
0001010
DAC Interface Control
5:4
DACWL
[1:0]
10
R11 (0Bh)
0001011
ADC Interface Control
5:4
ADCWL
[1:0]
10
DESCRIPTION
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 WM8776 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 WM8776 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.
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When operating the ADC digital interface in slave mode, to optimise the performance of the ADC it is
recommended that the ADCMCLK and ADCBCLK input signals do not have coinciding rising edges.
The ADCMCLK bit provides the option to internally invert the ADCMCLK input signal when the input
signals have coinciding rising edges.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R11(0Bh)
0001011
Interface Control
6
ADCMCLK
0
DESCRIPTION
ADCMCLK Polarity
0 : non-inverted
1: inverted
A number of options are available to control how data from the Digital Audio Interface is applied to
the DAC.
MASTER MODES
Control bit ADCMS selects between audio interface Master and Slave Modes for ADC. In ADC
Master mode ADCLRC and ADCBCLK are outputs and are generated by the WM8776. In Slave
mode ADCLRC and ADCBCLK are inputs to WM8776.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R12 (0Ch)
0001100
Interface Control
9
ADCMS
0
Audio Interface Master/Slave Mode
select for ADC:
0 : Slave Mode
1: Master Mode
Control bit DACMS selects between audio interface Master and Slave Modes for the DAC. In DAC
Master mode DACLRC and DACBCLK are outputs and are generated by the WM8776. In Slave
mode DACLRC and DACBCLK are inputs to WM8776.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R12 (0Ch)
0001100
Interface Control
8
DACMS
0
Audio Interface Master/Slave Mode
select for DAC:
0 : Slave Mode
1: Master Mode
MASTER MODE ADCLRC/DACLRC FREQUENCY SELECT
In ADC Master mode the WM8776 generates ADCLRC and ADCBCLK, in DAC master mode the
WM8776 generates DACLRC and DACBCLK. These clocks are derived from the master clock
(ADCMCLK or DACMCLK). The ratios of ADCMCLK to ADCLRC and DACMCLK to DACLRC are
set by ADCRATE and DACRATE respectively.
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
R12 (0Ch)
0001100
ADCLRC and DACLRC
frequency select
2:0
ADCRATE[2:0]
010
Master Mode MCLK:ADCLRC
ratio select:
010: 256fs
011: 384fs
100: 512fs
101: 768fs
DESCRIPTION
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
DEFAULT
DESCRIPTION
LABEL
R12 (0Ch)
0001100
ADC Oversampling Rate
3
ADCOSR
0
ADC oversampling rate select
0: 128x oversampling
1: 64x oversampling
MUTE MODES
Setting MUTE for the DAC will apply a ‘soft’ mute to the input of the digital filters of the channel
muted.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R8 (08h)
0001000
DAC Mute
0
DMUTE
0
DESCRIPTION
DAC Soft Mute select
0 : Normal Operation
1: Soft mute enabled
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 22 Application and Release of Soft Mute
Figure 22 shows the application and release of DMUTE whilst a full amplitude sinusoid is being
played at 48kHz sampling rate. When DMUTE (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 DMUTE is applied to both
channels for 1024 or more input samples the DAC will be muted if IZD is set. When DMUTE is deasserted, the output will restart immediately from the current input sample.
Note that all other means of muting the DAC: 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.
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ADC MUTE
Each ADC channel also has an individual mute control bit, which mutes the input to the ADC PGA.
By setting the LRBOTH bit (reg22, bit 8) both channels can be muted simultaneously.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R21 (15h)
0010101
ADC Mute Left
7
MUTELA
0
ADC Mute select
0 : Normal Operation
1: mute ADC left
DESCRIPTION
R21 (15h)
0001111
ADC Mute Right
6
MUTERA
0
ADC Mute select
0 : Normal Operation
1: mute ADC right
DE-EMPHASIS MODE
The De-emphasis filter for the DAC is enabled under the control of DEEMP.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R9 (09h)
0001001
DAC De-emphasis
Control
0
DEEMPH
0
DESCRIPTION
De-emphasis mode select:
0 : Normal Mode
1: De-emphasis Mode
Refer to Figure 35, Figure 36, Figure 37, Figure 38, Figure 39 and Figure 40 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 WM8776, including the references,
overriding all other powerdown control bits. All trace of the previous input samples is removed, but all
control register settings are preserved. When PDWN is cleared, the digital filters will be re-initialised.
It is recommended that the 5-channel input mux and buffer, ADC and DAC are powered down before
setting PDWN.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R13 (0Dh)
0001101
Powerdown Control
0
PDWN
0
DESCRIPTION
Power Down Mode Select:
0 : Normal Mode
1: Power Down Mode
The ADC, DAC and HEADPHONE PGA’S 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. The DAC has a separate disable
DACD. Setting DACD will disable the DAC, mixer and output PGAs. Resetting DACD will reinitialise
the digital filters.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R13 (0Dh)
0001101
Powerdown Control
1
ADCPD
0
ADC Powerdown:
0 : Normal Mode
1: Power Down Mode
DESCRIPTION
2
DACPD
0
DAC Powerdown:
0 : Normal Mode
1: Power Down Mode
3
HPPD
1
Headphone output/PGA Power
down :
0 : HP out enabled
1 : HP out disabled
The analogue audio inputs and outputs can also be individually powered down by setting the relevant
bits in the powerdown register.
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
R13 (0Dh)
0001101
Powerdown Control
6
AINPD
0
DESCRIPTION
Analogue input PGA disable:
0 : Normal Mode
1: Power Down Mode
DIGITAL 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
R7 (07h)
0000111
DAC Channel Control
1
ATC
0
DESCRIPTION
Attenuator Control Mode:
0 : Right channel use Right
attenuation
1: Right Channel use Left
Attenuation
INFINITE ZERO DETECT ENABLE
Setting the IZD register bit will enable the internal infinite zero detect function:
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R7 (07h)
0000111
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 zero input samples to the DAC will cause both DAC
outputs to be muted. Mute will be removed as soon as any channel receives a non-zero input.
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:
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
R7 (07h)
0000111
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
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ANALOGUE OUTPUT VOLUME CONTROLS
There are analogue volume controls for the headphone outputs which may be adjusted
independently using separate volume control registers.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R0 (00h)
0000000
Analogue
Attenuation
Headphone
Output Left
6:0
HPLA[6:0]
1111001
(0dB)
7
HPLZCEN
0
8
UPDATE
Not latched
Controls simultaneous update of Headphone Attenuation Latches
0: Store HPLA in intermediate latch (no change to output)
1: Store HPLA and update attenuation on both channels.
R1 (01h)
0000001
Analogue
Attenuation
Headphone
Output Right
6:0
HPLA[6:0]
1111001
(0dB)
Attenuation data for Headphone Right channel in 1dB steps. See
Table 13
7
HPRZCEN
0
8
UPDATE
Not latched
Controls simultaneous update of Headphone Attenuation Latches
0: Store HPRA in intermediate latch (no change to output)
1: Store HPRA and update attenuation on both channels.
R2 (02h)
0000010
Headphone
Master
Analogue
Attenuation
(both channels)
6:0
HPMASTA
[6:0]
1111001
(0dB)
Attenuation data for both Headphone channels in 1dB steps. See
Table 13
7
MZCEN
0
8
UPDATEA
Not latched
R13 (0Dh)
0001101
Power Down
3
HPPD
1
DESCRIPTION
Attenuation data for Headphone Left channel in 1dB steps. See
Table 13
Headphone left zero cross detect enable
0: zero cross disabled
1: zero cross enabled
Headphone right zero cross detect enable
0: zero cross disabled
1: zero cross enabled
Master zero cross detect enable
0: zero cross disabled
1: zero cross enabled
Controls simultaneous update of Attenuation Latches
0: Store gain in intermediate latch (no change to output)
1: Store gain and update attenuation on all channels.
Headphone output/PGA Power Down
0 : HP out enabled
1 : HP out disabled
Table 12 Headphone Attenuation Register Map
Each analogue headphone output channel has a PGA which can be used to attenuate the output
from that channel. The PGA’s can be powered up or down using the HPPD bit. Attenuation is 0dB by
default but can be set between +6dB and –73dB in 1dB steps using the two Attenuation control
words. The attenuation registers are double latched allowing them to be updated in pairs. Setting the
UPDATE bit on an attenuation write to one channel, for example HPOUTL, will cause the pre-latched
value in HPOUTR to be applied to the PGA. A master attenuation register is also included, allowing
both volume levels to be set to the same value in a single write.
Note: The UPDATE bit is not latched. If UPDATE=0, the Attenuation value will be written to the prelatch but not applied to the PGA. If UPDATE=1, pre-latched values will be applied from the next input
sample. Writing to HPMASTA[6:0] overwrites any values previously sent to HPLA[6:0] and
HPRA[6:0].
HEADPHONE OUTPUT PGA ATTENUATION
The analogue output PGAs are controlled by the HPLA and HPRA registers. Register bits MASTA
can be used to control attenuation of both channels.
Table 13 shows how the attenuation levels are selected from the 7-bit words.
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HPLA/ HPRA[6:0]
ATTENUATION LEVEL
00(hex)
-∞dB (mute)
:
:
2F(hex)
-∞dB (mute)
30(hex)
-73dB
:
:
79 (hex)
0dB (default)
:
:
7D(hex)
+4dB
7E(hex)
+5dB
7F(hex)
+6dB
Table 13 Headphone Volume Control Attenuation Levels
In addition a zero cross detect circuit is provided for the output PGA volume under the control of bit 7
(ZCEN) in the each attenuation register. When ZCEN is set the attenuation values are only updated
when the input signal to the gain stage is close to the analogue ground level. This minimises audible
clicks and ‘zipper’ noise as the gain values change. A timeout clock is also provided which will
generate an update after a minimum of 131072 master clocks (= ~10.5ms with a master clock of
12.288MHz). The timeout clock may be disabled by setting TOD.
REGISTER ADDRESS
BIT
R7 (07h)
0000111
Timeout Clock Disable
3
LABEL
TOD
DEFAULT
0
DESCRIPTION
DAC and ADC Analogue Zero
cross detect timeout disable
0 : Timeout enabled
1: Timeout disabled
DAC DIGITAL VOLUME CONTROL
The DAC volume may also be adjusted in the digital domain using independent digital attenuation
control registers
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R3 (03h)
0000011
Digital
Attenuation
DACL
7:0
LDA[7:0]
11111111
(0dB)
8
UPDATED
Not latched
R4 (04h)
0000100
Digital
Attenuation
DACR
7:0
RDA[6:0]
11111111
(0dB)
8
UPDATED
Not latched
R5 (05h)
0000101
Master
Digital
Attenuation
(both channels)
7:0
MASTDA[7:0]
11111111
(0dB)
8
UPDATED
Not latched
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DESCRIPTION
Digital Attenuation data for Left channel DACL in 0.5dB steps. See
Table 14
Controls simultaneous update of Attenuation Latches
0: Store LDA in intermediate latch (no change to output)
1: Store LDA and update attenuation on both channels
Digital Attenuation data for Right channel DACR in 0.5dB steps. See
Table 14
Controls simultaneous update of Attenuation Latches
0: Store RDA in intermediate latch (no change to output)
1: Store RDA and update attenuation on both channels.
Digital Attenuation data for DAC channels in 0.5dB steps. See Table
14
Controls simultaneous update of Attenuation Latches
0: Store gain in intermediate latch (no change to output)
1: Store gain and update attenuation on channels.
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L/RDA[7:0]
ATTENUATION LEVEL
00(hex)
-∞ dB (mute)
01(hex)
-127dB
:
:
:
:
:
:
FE(hex)
-0.5dB
FF(hex)
0dB
Table 14 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.
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R7 (07h)
0000111
DAC Control
0
DZCEN
0
DESCRIPTION
DAC Digital Volume Zero Cross
Enable:
0: Zero cross detect disabled
1: Zero cross detect enabled
DAC OUTPUT PHASE
The DAC Phase control word determines whether the output of the DAC is non-inverted or inverted
REGISTER ADDRESS
BIT
LABEL
DEFAULT
R6 (06h)
0000110
DAC Phase
1:0
PH[1:0]
00
DESCRIPTION
Bit
DAC
Phase
0
DACL
1 = invert
1
DACR
1 = invert
ADC GAIN CONTROL
The ADC has an analogue input PGA and digital gain control for each stereo channel. Both the
analogue and digital gains are adjusted by the same register, LAG for the left and RAG for the right.
The analogue PGA has a range of +24dB to -21dB in 0.5dB steps. The digital gain control allows
further attenuation (after the ADC) from -21.5dB to -103dB in 0.5dB steps. Table 15 shows how the
register maps the analogue and digital gains.
LAG/RAG[7:0]
ATTENUATION
LEVEL (AT
OUTPUT)
ANALOGUE PGA
DIGITAL
ATTENUATION
00(hex)
01(hex)
-∞ dB (mute)
-21dB
Digital mute
-103dB
-21dB
-82dB
:
:
:
:
A4(hex)
-21.5dB
-21dB
-0.5dB
A5(hex)
-21dB
-21dB
0dB
:
:
:
:
CF(hex)
0dB
0dB
0dB
:
:
:
:
FE(hex)
+23.5dB
+23.5dB
0dB
FF(hex)
+24dB
+24dB
0dB
Table 15 Analogue and Digital Gain Mapping for ADC
In addition, a zero cross detect circuit is provided for the input PGA, controlled by bit 8 in each
attenuation register. This minimises audible clicks and ‘zipper’ noise by updating the gain when the
signal crosses the zero level.
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In addition a zero cross detect circuit is provided for the output PGA volume under the control of bit 7
(ZCEN) in the each attenuation register. When ZCEN is set the attenuation values are only updated
when the input signal to the gain stage is close to the analogue ground level. This minimises audible
clicks and ‘zipper’ noise as the gain values change. A timeout clock is also provided which will
generate an update after a minimum of 131072 master clocks (= ~10.5ms with a master clock of
12.288MHz). The timeout clock may be disabled by setting TOD.
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, saving on software
writes. The ADC volume and mute also applies to the bypass signal path.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R14 (0Eh)
0001110
Attenuation
ADCL
7:0
LAG[7:0]
11001111
(0dB)
8
ZCLA
0
R15 (0Fh)
0001111
Attenuation
ADCR
7:0
RAG[7:0]
11001111
(0dB)
8
ZCRA
0
Right channel ADC zero cross enable:
0: Zero cross disabled
1: Zero cross enabled
R21 (15h)
0010101
ADC Input Mux
8
LRBOTH
0
Right channel input PGA controlled by left channel register
0 : Right channel uses RAG.
1 : Right channel uses LAG.
R21 (15h)
0010101
ADC Input Mux
7
MUTELA
0
Mute for left channel ADC
0: Mute Off
1: Mute on
6
MUTERA
0
Mute for right channel ADC
0: Mute Off
1: Mute on
Attenuation data for Left channel ADC gain in 0.5dB steps. See
Table 15.
Left channel ADC zero cross enable:
0: Zero cross disabled
1: Zero cross enabled
Attenuation data for right channel ADC gain in 0.5dB steps. See
Table 15.
ADC HIGHPASS FILTER DISABLE
The ADC digital filters contain a digital high pass filter. This defaults to enabled and can be disabled
using software control bit ADCHPD.
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REGISTER ADDRESS
BIT
LABEL
DEFAULT
R11 (0Bh)
0001011
ADC Control
8
ADCHPD
0
DESCRIPTION
ADC High pass filter disable:
0: High pass filter enabled
1: High pass filter disabled
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LIMITER / AUTOMATIC LEVEL CONTROL (ALC)
The WM8776 has an automatic pga gain control circuit, which can function as a peak limiter or as an
automatic level control (ALC). In peak limiter mode, a digital peak detector detects when the input
signal goes above a predefined level and will ramp the pga gain down to prevent the signal becoming
too large for the input range of the ADC. When the signal returns to a level below the threshold, the
pga gain is slowly returned to its starting level. The peak limiter cannot increase the pga gain above
its static level.
input
signal
PGA
gain
signal
after
PGA
Limiter
threshold
attack
time
decay
time
Figure 23 Limiter Operation
In ALC mode, the circuit aims to keep a constant recording volume irrespective of the input signal
level. This is achieved by continuously adjusting the PGA gain so that the signal level at the ADC
input remains constant. A digital peak detector monitors the ADC output and changes the PGA gain
if necessary.
input
signal
PGA
gain
signal
after
ALC
ALC
target
level
hold
time
decay
time
attack
time
Figure 24 ALC Operation
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The gain control circuit is enabled by setting the LCEN control bit. The user can select between
Limiter mode and three different ALC modes using the LCSEL control bits.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R17 (11h)
0010001
ALC Control 2
8
LCEN
0
Enable the PGA gain control circuit.
0 = Disabled
1 = Enabled
R16 (10h)
0010000
ALC Control 1
8:7
LCSEL
00
LC function select
00 = Limiter
01 = ALC Right channel only
10 = ALC Left channel only
11 = ALC Stereo
The limiter function only operates in stereo, which means that the peak detector takes the maximum
of left and right channel peak values, and any new gain setting is applied to both left and right PGAs,
so that the stereo image is preserved. However, the ALC function can also be enabled on one
channel only. In this case, only one PGA is controlled by the ALC mechanism, while the other
channel runs independently with its PGA gain set through the control register.
When enabled, the threshold for the limiter or target level for the ALC is programmed using the LCT
control bits. This allows the threshold/target level to be programmed between -1dB and -16dB in 1dB
steps.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R16 (10h)
0010000
ALC Control 1
3:0
LCT[3:0]
1011
(-5dB)
DESCRIPTION
Limiter Threshold/ALC target level in
1dB steps.
0000: -16dB FS
0001: -15dB FS
…
1101: -3dB FS
1110: -2dB FS
1111: -1dB FS
ATTACK AND DECAY TIMES
The limiter and ALC have different attack and decay times which determine their operation. However,
the attack and decay times are defined slightly differently for the limiter and for the ALC. DCY and
ATK control the decay and attack times, respectively.
Decay time (Gain Ramp-Up). When in ALC mode, this is defined as the time that it takes for the
PGA gain to ramp up across 90% of its range (e.g. from –21dB up to +20 dB). When in limiter mode,
it is defined as the time it takes for the gain to ramp up by 6dB.
The decay time can be programmed in power-of-two (2n) steps. For the ALC this gives times from
33.6ms, 67.2ms, 134.4ms etc. to 34.41s. For the limiter this gives times from 1.2ms, 2.4ms etc., up
to 1.2288s.
Attack time (Gain Ramp-Down) When in ALC mode, this is defined as the time that it takes for the
PGA gain to ramp down across 90% of its range (e.g. from +20dB down to -21dB gain). When in
limiter mode, it is defined as the time it takes for the gain to ramp down by 6dB.
The attack time can be programmed in power-of-two (2n) steps, from 8.4ms, 16.8ms, 33.6ms etc. to
8.6s for the ALC and from 250us, 500us, etc. up to 256ms.
The time it takes for the recording level to return to its target value or static gain value therefore
depends on both the attack/decay time and on the gain adjustment required. If the gain adjustment is
small, it will be shorter than the attack/decay time.
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REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R18 (12h)
0010010
ALC
Control 3
3:0
ATK[3:0]
0010
DESCRIPTION
LC attack (gain ramp-down) time
ALC mode
0000: 8.4ms
0001: 16.8ms
0010: 33.6ms…
(time doubles with
every step)
1010 or higher:
8.6s
7:4
DCY [3:0]
0011
Limiter Mode
0000: 250us
0001: 500us… 0010:
1ms
(time doubles with
every step)
1010 or higher: 256ms
LC decay (gain ramp-up) time
ALC mode
0000: 33.5ms
0001: 67.2ms
0010: 134.4ms
….(time doubles for
every step)
1010 or higher:
34.3ms
Limiter mode
0000: 1.2ms
0001: 2.4ms
0010: 4.8ms ….(time
doubles for every
step)
1010 or higher:
1.2288s
TRANSIENT WINDOW (LIMITER ONLY)
To prevent the limiter responding to to short duration high ampitude signals (such as hand-claps in a
live performance), the limiter has a programmable transient window preventing it responding to
signals above the threshold until their duration exceeds the window period. The Transient window is
set in register TRANWIN.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R20 (14h)
0010100
Limiter Control
6:4
TRANWIN
[2:0]
010
DESCRIPTION
Length of Transient Window
000: 0us (disabled)
001: 62.5us
010: 125us
…..
111: 4ms
ZERO CROSS
The PGA has a zero cross detector to prevent gain changes introducing noise to the signal. In ALC
mode the register bit ALCZC allows this to be turned off if desired.
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REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R17 (11h)
0010001
ALC Control 2
7
ALCZC
0
(disabled)
DESCRIPTION
PGA zero cross enable
0 : disabled
1: enabled
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MAXIMUM GAIN (ALC ONLY) AND MAXIMUM ATTENUATION
To prevent low level signals being amplified too much by the ALC, the MAXGAIN register sets the
upper limit for the gain. This prevents low level noise being over-amplified. The MAXGAIN register
has no effect on the limiter operation.
The MAXATTEN register has different operation for the limiter and for the ALC. For the limiter it
defines the maximum attenuation below the static (user programmed) gain. For the ALC, it defines
the lower limit for the gain.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R16 (10h)
0010000
ALC Control 1
6:4
MAXGAIN
111
(+24dB)
R20 (14h)
0010100
Limiter Control
3:0
MAXATTEN
0110
DESCRIPTION
Set maximum gain for the PGA (ALC
only)
111 : +24dB
110 : +20dB
…..(-4dB steps)
010 : +4dB
001 : 0dB
000 : 0dB
Maximum attenuation of PGA
Limiter
(attenuation
below static)
0011 or lower:
-3dB
0100: -4dB
…. (-1dB steps)
1100 or higher:
-12dB
ALC (lower PGA
gain limit)
1010 or lower:
-1dB
1011 : -5dB
….. (-4dB steps)
1110 : -17dB
1111 : -21dB
HOLD TIME (ALC ONLY)
The ALC also has a hold time, which is the time delay between the peak level detected being below
target and the PGA gain beginning to ramp up. It can be programmed in power-of-two (2n) steps, e.g.
2.67ms, 5.33ms, 10.67ms etc. up to 43.7ms. Alternatively, the hold time can also be set to zero. The
hold time only applies to gain ramp-up, there is no delay before ramping the gain down when the
signal level is above target.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R17 (11h)
0010001
ALC Control 2
3:0
HLD[3:0]
0000
DESCRIPTION
ALC hold time before gain is
increased.
0000: 0ms
0001: 2.67ms
0010: 5.33ms
… (time doubles with every step)
1111: 43.691s
OVERLOAD DETECTOR (ALC ONLY)
To prevent clipping when a large signal occurs just after a period of quiet, the ALC circuit includes an
overload detector. If the ADC input signal exceeds 87.5% of full scale (–1.16dB), the PGA gain is
ramped down at the maximum attack rate (as when ATK = 0000), until the signal level falls below
87.5% of full scale. This function is automatically enabled whenever the ALC is enabled.
(Note: If ATK = 0000, then the overload detector makes no difference to the operation of the ALC. It
is designed to prevent clipping when long attack times are used).
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NOISE GATE (ALC ONLY)
When the signal is very quiet and consists mainly of noise, the ALC function may cause “noise
pumping”, i.e. loud hissing noise during silence periods. The WM8776 has a noise gate function that
prevents noise pumping by comparing the signal level at the AINL1/2/3/4/5 and/or AINR1/2/3/4/5 pins
against a noise gate threshold, NGTH. The noise gate cuts in when:
•
Signal level at ADC [dB] < NGTH [dB] + PGA gain [dB] + Mic Boost gain [dB]
This is equivalent to:
•
Signal level at input pin [dB] < NGTH [dB]
When the noise gate is triggered, the PGA gain is held constant (preventing it from ramping up as it
would normally when the signal is quiet).
The table below summarises the noise gate control register. The NGTH control bits set the noise
gate threshold with respect to the ADC full-scale range. The threshold is adjusted in 6dB steps.
Levels at the extremes of the range may cause inappropriate operation, so care should be taken with
set–up of the function. Note that the noise gate only works in conjunction with the ALC function, and
always operates on the same channel(s) as the ALC (left, right, both, or none).
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REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R19 (13h)
0010011
Noise Gate
Control
0
NGAT
0
4:2
NGTH[2:0]
000
DESCRIPTION
Noise gate function enable
1 = enable
0 = disable
Noise gate threshold (with respect to
ADC output level)
000: -78dBFS
001: -72dBfs
… 6 dB steps
110: -42dBFS
111: -36dBFS
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ADC INPUT MIXER AND POWERDOWN CONTROL
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R21 (15h)
0010101
ADC Input Mux
4:0
AMX[4:0]
00001
R13 (0Dh)
0001101
Powerdown Control
6
AINPD
0
DESCRIPTION
ADC left channel input mixer
control bits (see Table 16)
Input mux and buffer powerdown
0: Input mux and buffer
enabled
1: Input mux and buffer
powered down
Register bits AMX[4:0] control the left and right channel inputs into the stereo ADC. The default is
AIN1. One bit of AMX is allocated to each stereo input pair to allow the signals to be mixed before
being digitised by the ADC. For example, if AMX[4:0] is 00101, the input signal to the ADC will be
(AIN1L+AIN3L) on the left channel and (AIN1R+AIN3R) on the right channel.
However if the analogue input buffer is powered down, by setting AINPD, then all 5-channel mixer
inputs are switched to buffered VMIDADC.
AMX[4:0]
LEFT ADC INPUT
RIGHT ADC INPUT
00001
AIN1L
AIN1R
00010
AIN2L
AIN2R
00100
AIN3L
AIN3R
01000
AIN4L
AIN4R
10000
AIN5L
AIN5R
Table 16 ADC Input Mixer
AIN1L/R
AMX[0]
AIN2L/R
AMX[1]
AIN3L/R
AMX[2]
AIN4L/R
AMX[3]
AIN5L/R
AMX[4]
Figure 25 ADC Input Mixer
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WM8776
Production Data
OUTPUT SELECT AND ENABLE CONTROL
Register bits MX controls the output selection. The output select block consists of a summing stage
and an input select switch for each input allowing each signal to be output individually or summed
with other signals and output on the analogue output. The default for the output is DAC playback
only. VOUT may be selected to output DAC playback, AUX, analogue bypass or a sum of these
using the output select controls MX[2:0]. For example, to select sum of DAC and AUX, set MX[2:0] to
011.
The output mixer is powered down with DACD.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R22 (16h)
0010110
Output Mux
2:0
MX[2:0]
001
(DAC playback)
DESCRIPTION
VOUT Output select (see Figure 26)
Figure 26 MX[2:0] Output Select
SOFTWARE REGISTER RESET
Writing any value to register 0010111 will cause a register reset, resetting all register bits to
their default values.
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PD, Rev 4.1, September 2008
40
WM8776
Production Data
REGISTER MAP
The complete register map is shown below. The detailed description can be found in the relevant text
of the device description. The WM8776 can be configured using the Control Interface. All unused bits
should be set to ‘0’.
REGISTER B
B
B
15 14 13 12 11 10
B
B
B
B
9
R0 (00h)
0
0
0
0
0
0
0
UPDATE HPLZCEN
R1 (01h)
0
0
0
0
0
0
1
UPDATE HPRZCEN
R2 (02h)
0
0
0
0
0
1
0 UPDATEA HPMZCEN
R3 (03h)
0
0
0
0
0
1
1 UPDATED
R4 (04h)
0
0
0
0
1
0
R5 (05h)
0
0
0
0
1
0
R6 (06h)
0
0
0
0
1
1
0
0
R7 (07h)
0
0
0
0
1
1
1
0
R8 (08h)
0
0
0
1
0
0
0
0
R9 (09h)
0
0
0
1
0
0
1
0
0
0
R10 (0Ah)
0
0
0
1
0
1
0
0
0
0
R11 (0Bh)
0
0
0
1
0
1
1
ADCHPD
0
ADCMCLK
R12 (0Ch)
0
0
0
1
1
0
0
ADCMS
DACMS
R13 (ODh)
0
0
0
1
1
0
1
0
0
R14 (0Eh)
0
0
0
1
1
1
0
ZCLA
LAG[7:0]
0CF
R15 (0Fh)
0
0
0
1
1
1
1
ZCRA
RAG[7:0]
0CF
R16 (10h)
0
0
1
0
0
0
0
R17 (11h)
0
0
1
0
0
0
1
LCEN
R18 (12h)
0
0
1
0
0
1
0
FDECAY
R19 (13h)
0
0
1
0
0
1
1
0
0
R20 (14h)
0
0
1
0
1
0
0
0
1
R21 (15h)
0
0
1
0
1
0
1
LRBOTH
MUTELA
R22 (16h)
0
0
1
0
1
1
0
0
0
R23 (17h)
0
0
1
0
1
1
1
w
B8
B7
B6
B5
B4
B3
B2
B1
B0
DEFAULT
(HEX)
HPLA[6:0]
079
HPRA[6:0]
079
HPMASTA[6:0]
079
LDA[7:0]
0FF
0 UPDATED
RDA[7:0]
0FF
1 UPDATED
MASTDA
0
0
0
0
PL[3:0]
0
0
0
0
0
DACWL[1:0]
ADCWL[1:0]
DACRATE[2:0]
AINPD
LCSEL[1:0]
ALCZC
0
0
0FF
0
0
TOD
IZD
ATC
DZCEN
090
0
0
0
DMUTE
000
0
DACLRP
ADCBCP
ADCLRP
HPPD
MAXGAIN[2:0]
0
0
0
DACPD
0
ADCFMT[1:0]
022
ADCPD
PDWN
SOFTWARE RESET
022
008
07B
HLD[3:0]
000
ATK[3:0]
032
0
MAXATTEN[3:0]
AMX[4:0]
0
000
022
ADCRATE[2:0]
NGTH[2:0]
TRANWIN[2:0]
MUTERA
DEEMPH
000
DACFMT[1:0]
LCT[3:0]
0
DCY[3:0]
0
DZFM [1:0]
DACBCP
ADCOSR
0
PHASE[1:0]
NGAT
000
0A6
001
MX[2:0]
001
not reset
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WM8776
Production Data
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R0 (00h)
0000000
Headphone
Analogue
Attenuation
Headphone
Left
6:0
HPLA[6:0]
1111001
(0dB)
7
HPLZCEN
0
8
UPDATE
Not latched
6:0
HPRA[6:0]
1111001
(0dB)
7
HPRZCEN
0
8
UPDATE
Not latched
Controls simultaneous update of all Attenuation Latches
0: Store HPRA in intermediate latch (no change to output)
1: Store HPRA and update attenuation on all channels.
6:0
HPMASTA[6:0]
1111001
(0dB)
Attenuation data for all ANALOGUE gains (L and R channels) in
1dB steps.
7
MZCEN
0
8
UPDATEA
Not latched
R3 (03h)
0000011
Digital
Attenuation
DACL
7:0
LDA1[7:0]
11111111
(0dB)
8
UPDATED
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
R4 (04h)
0000100
Digital
Attenuation
DACR
7:0
RDA1[6:0]
11111111
(0dB)
Digital Attenuation data for Right channel DACR in 0.5dB steps.
8
UPDATED
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.
R5 (05h)
0000101
Master
Digital
Attenuation
(All Channels
7:0
MASTDA[7:0]
11111111
(0dB)
8
UPDATED
Not latched
R1 (01h)
0000001
Headphone
Analogue
Attenuation
Headphone
Right
R2 (02h)
0000010
Headphone
Master Analogue
Attenuation
(All Channels)
w
DESCRIPTION
Attenuation data for HEADPHONE left channel in 1dB steps.
Left HEADPHONE zero cross detect enable
0: zero cross disabled
1: zero cross enabled
Controls simultaneous update of all Attenuation Latches
0: Store HPLA in intermediate latch (no change to output)
1: Store HPLA and update attenuation on all channels.
Attenuation data for Headphone right channel in 1dB steps.
Right Headphone zero cross detect enable
0: zero cross disabled
1: zero cross enabled
Master zero cross detect enable
0: zero cross disabled
1: zero cross enabled
Controls simultaneous update of all Attenuation Latches
0: Store gains in intermediate latch (no change to output)
1: Store gains and update attenuation on all channels.
Digital Attenuation data for Left channel DACL in 0.5dB steps.
Digital Attenuation data for all DAC channels in 0.5dB steps.
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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WM8776
Production Data
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R6 (06h)
0000110
Phase Swaps
1:0
PHASE
00
Controls phase of DAC outputs (LEFT, RIGHT channel)
0: Sets non inverted output phase
1: inverts phase of DAC output
R7 (07h)
0000111
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 DAC uses left DAC attenuations
2
IZD
0
Infinite zero detection circuit control and automute control
0: Infinite zero detect automute disabled
1: Infinite zero detect automute enabled
3
TOD
0
7:4
PL[3:0]
1001
DAC and ADC Analogue Zero cross detect timeout disable
0 : Timeout enabled
1: Timeout disabled
DAC Output Control
PL[3:0]
Left
Output
Right
Output
PL[3:0]
Left
Output
0000
0001
Mute
Mute
1000
Mute
Right
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
R8 (08h)
0001000
DAC Mute
0
DMUTE
0
DAC channel soft mute enables:
0: mute disabled
1: mute enabled
R9 (09h)
0001001
DAC Control
0
DEEMPH
0
De-emphasis mode select:
0 : Normal Mode
1: De-emphasis Mode
2:1
DZFM
00
DZFM
00
01
10
11
w
ZFLAG1
disabled
left channels zero
both channels zero
either channel zero
Right
Output
ZFLAG2
disabled
right channels zero
both channels zero
either channel zero
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WM8776
Production Data
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R10 (0Ah)
0001010
DAC Interface
Control
1:0
DACFMT[1:0]
10
DAC Interface format select
00: right justified mode
01: left justified mode
10: I2S mode
11: DSP mode
2
DACLRP
0
DACLRC Polarity or DSP Early/Late mode select
Left Justified / Right Justified /
I 2S
0: Standard DACLRC Polarity
1: Inverted DACLRC Polarity
R11 (0Bh)
0001011
ADC Interface
Control
DSP Mode
0: Early Mode
1: Late Mode
3
DACBCP
0
DAC BITCLK Polarity
0: Normal – DIN and DACLRC sampled on rising edge of
DACBCLK.
1: Inverted - DIN and DACLRC sampled on falling edge of
DACBCLK.
5:4
DACWL[1:0]
10
DAC 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)
1:0
ADCFMT[1:0]
10
ADC Interface format select
00: right justified mode
01: left justified mode
10: I2S mode
11: DSP mode
2
ADCLRP
0
ADCLRC Polarity or DSP Early/Late mode select
Left Justified / Right Justified /
I 2S
0: Standard ADCLRC Polarity
1: Inverted ADCLRC Polarity
DSP Mode
0: Early Mode
1: Late Mode
3
ADCBCP
0
ADC BITCLK Polarity
0: Normal - ADCLRC sampled on rising edge of
ADCBCLK; DOUT changes on falling edge of ADCBCLK.
1: Inverted - ADCLRC sampled on falling edge of
ADCBCLK; DOUT changes on rising edge of ADCBCLK.
5:4
ADCWL[1:0]
10
ADC 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)
6
ADCMCLK
0
ADCMCLK Polarity:
0: non-inverted
1: inverted
8
ADCHPD
0
ADC Highpass Filter Disable:
0: Highpass Filter enabled
1: Highpass Filter disabled
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PD, Rev 4.1, September 2008
44
WM8776
Production Data
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R12 (0Ch)
0001100
Master Mode
Control
2:0
ADCRATE[2:0]
010
3
ADCOSR
0
6:4
DACRATE[2:0]
010
7
DACMS
0
DAC Maser/Slave interface mode select
0: Slave Mode – DACLRC and DACBCLK are inputs
1: Master Mode –DACLRC and DACBCLK are outputs
8
ADCMS
0
ADC Maser/Slave interface mode select
0: Slave Mode – ADCLRC and ADCBCLK are inputs
1: Master Mode – ADCLRC and ADCBCLK are outputs
0
PDWN
0
Chip Powerdown Control (works in tandem with ADCD and
DACD):
0: All circuits running, outputs are active
1: All circuits in power save mode, outputs muted
1
ADCPD
0
ADC powerdown:
0: ADC enabled
1: ADC disabled
2
DACPD
0
DAC powerdown
0: DAC enabled
1: DAC disabled
3
HPPD
1
Headphone Output/PGA’s powerdown
0: Headphone out enabled
1: Headphone out disabled
6
AINPD
0
AINPD powerdown
0: ANALOGUE INPUT enabled
1: ANALOGUE INPUT disabled
7:0
LAG[7:0]
11001111
(0dB)
8
ZCLA
0
R13 (0Dh)
0001101
PWR Down
Control
R14 (0Eh)
0001110
Attenuation
ADCL
w
DESCRIPTION
Master Mode ADCMCLK:ADCLRC ratio select:
010: 256fs
011: 384fs
100: 512fs
ADC oversample rate select
0: 128x oversampling
1: 64x oversapmling
Master Mode DACMCLK:DACLRC ratio select:
000: 128fs
001: 192fs
010: 256fs
011: 384fs
100: 512fs
Attenuation data for left channel ADC gain in 0.5dB steps.
00000000 : digital mute
00000001 : -103dB
………..
11001111 : 0dB
…………
11111110 : +23.5dB
11111111 : +24dB
Left ADC zero cross enable:
0: Zero cross disabled
1: Zero cross enabled
PD, Rev 4.1, September 2008
45
WM8776
Production Data
REGISTER
ADDRESS
BIT
R15 (0Fh)
0001111
Attenuation
ADCR
7:0
8
R16 (10h)
0010000
ALC Control 1
RAG[7:0]
DEFAULT
11001111
(0dB)
ZCRA
0
DESCRIPTION
Attenuation data for right channel ADC gain in 0.5dB steps.
00000000 : digital mute
00000001 : -103dB
………..
11001111 : 0dB
…………
11111110 : +23.5dB
11111111 : +24dB
Right ADC zero cross enable:
0: Zero cross disabled
1: Zero cross enabled
3:0
LCT[3:0]
1011
(-5dB)
Limiter threshold/ALC target level in 1dB steps
0000: -16dB FS
0001: -15dB FS
…
1101: -3dB FS
1110: -2dB FS
1111: -1dB FS
6:4
MAXGAIN[2:0]
111
(+24dB)
Set Maximum Gain of PGA
111 : +24dB
110 : +20dB
….(-4dB steps)
010 : +4dB
001 : 0dB
000 : 0dB
LCSEL[1:0]
00
(Limiter)
ALC/Limiter function select
00 = Limiter
01 = ALC Right channel only
10 = ALC Left channel only
11 = ALC Stereo (PGA registers unused)
HLD[3:0]
0000
(OFF)
ALC hold time before gain is increased.
0000: OFF
0001: 2.67ms
0010: 5.33ms
… (time doubles with every step)
1111: 43.691s
7
ALCZC
0 (zero
cross off)
ALC uses zero cross detection circuit.
8
LCEN
0
Enable Gain control circuit.
0 = Disable
1 = Enable
8:7
R17 (11h)
0010001
ALC Control 2
LABEL
3:0
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46
WM8776
Production Data
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
R18 (12h)
0011000
ALC Control 3
3:0
ATK[3:0]
0010
(33ms/1ms)
7:4
R19 (13h)
0010011
Noise Gate
Control
R20 (14h)
0010100
Limiter
Control
R21 (15h)
0010101
ADC Mux
Control
DCY[3:0]
0011
(268ms/
9.6ms)
0
NGAT
0
4:2
NGTH [2:0]
000
3:0
MAXATTEN
[3:0]
0110
6:4
TRANWIN [2:0]
010
4:0
AMX[4:0]
00001
DESCRIPTION
ALC/Limiter attack (gain ramp-down) time
ALC mode
0000: 8.4ms
0001: 16.8ms
0010: 33.6ms…
(time doubles with every step)
1010 or higher: 8.6s
ALC/Limiter decay (gain ramp up) time
ALC mode
0000: 33.5ms
0001: 67.2ms
0010: 134.4ms ….(time
doubles for every step)
1010 or higher: 34.3ms
Limiter mode
0000: 1.2ms
0001: 2.4ms
0010: 4.8ms ….(time doubles
for every step)
1010 or higher: 1.2288s
Noise gate enable (ALC only)
0 : disabled
1 : enabled
Noise gate threshold
000: -78dBFS
001: -72dBfs
… 6 dB steps
110: -42dBFS
111: -36dBFS
Maximum attenuation of PGA
Limiter (attenuation below
static)
0011 or lower: -3dB
0100: -4dB
…. (-1dB steps)
1100 or higher: -12dB
ALC (lower PGA gain limit)
1010 or lower: -1dB
1011 : -5dB
….. (-4dB steps)
1110 : -17dB
1111 : -21dB
Length of Transient Window
000: 0us (disabled)
001: 62.5us
010: 125us
…..
111: 4ms
ADC left channel input mixer control bit
AMX[4:0]
00001
00010
00100
01000
10000
ADC LEFT IN
AIN1L
AIN2L
AIN3L
AIN4L
AIN5L
6
MUTERA
0
Mute for right channel ADC
0: Mute off
1: Mute on
7
MUTELA
0
Mute for left channel ADC
0: Mute off
1: Mute on
w
Limiter Mode
0000: 250us
0001: 500us…
0010: 1ms
(time doubles with every step)
1010 or higher: 256ms
ADC RIGHT IN
AIN1R
AIN2L
AIN3R
AIN4R
AIN5R
PD, Rev 4.1, September 2008
47
WM8776
REGISTER
ADDRESS
Production Data
BIT
LABEL
DEFAULT
8
LRBOTH
0
Right channel input PGA controlled by left channel register
0 : Right channel uses RAG and MUTERA.
1 : Right channel uses LAG and MUTELA.
R22 (16h)
0010110
Output Mux
2:0
MX[2:0]
001
VOUT Output select (Analogue ByPass Enable / Disable)
001: DAC
010: AUX
100: BYPASS
R23 (17h)
0010111
Software
Reset
[8:0]
RESET
Not reset
w
DESCRIPTION
Writing to this register will apply a reset to the device registers.
PD, Rev 4.1, September 2008
48
WM8776
Production Data
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
0.454fs
-3dB
0.4892 fs
±0.05
Passband ripple
Stopband
dB
0.546fs
Stopband Attenuation
f > 0.546fs
-60
dB
Group Delay
19
fs
Table 17 Digital Filter Characteristics
DAC FILTER RESPONSES
10
0
0
-10
Response (dB)
Response (dB)
-20
-40
-60
-80
-20
-30
-40
-50
-60
-100
-70
-80
-120
0
0.5
1
1.5
2
2.5
3
Frequency (Fs)
Figure 27 DAC Digital Filter Frequency Response – 44.1, 48
and 96kHz
w
0.4
0.45
0.5
0.55
0.6
Frequency (Fs)
Figure 28 DAC Digital Filter Transition Band – 44.1, 48 and
96kHz
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WM8776
Production Data
0.2
0
0.15
-20
Response (dB)
Response (dB)
0.1
0.05
0
-0.05
-40
-0.1
-60
-0.15
-0.2
0
0.1
0.2
0.3
0.4
-80
0.5
Frequency (Fs)
0
Figure 29 DAC Digital Filter Ripple – 44.1, 48 and 96kHz
0.2
0.4
0.6
Frequency (Fs)
0.8
1
Figure 30 DAC Digital Filter Frequency Response –
192kHz
0.2
0
Response (dB)
-0.2
-0.4
-0.6
-0.8
-1
0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
Figure 31 DAC Digital filter Ripple - 192kHz
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
Figure 32 ADC Digital Filter Frequency Response
w
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 33 ADC Digital Filter Ripple
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WM8776
Production Data
ADC HIGH PASS FILTER
The WM8776 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 34 ADC Highpass Filter Response
w
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WM8776
Production Data
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 35 De-Emphasis Frequency Response (32kHz)
0
2
4
6
8
10
Frequency (kHz)
12
14
16
Figure 36 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 37 De-Emphasis Frequency Response (44.1KHz)
0
5
10
Frequency (kHz)
15
20
Figure 38 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 39 De-Emphasis Frequency Response (48kHz)
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0
5
10
15
Frequency (kHz)
20
Figure 40 De-Emphasis Error (48kHz)
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Production Data
APPLICATIONS INFORMATION
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 pulses. Figure 41 shows the ADC input multiplexor circuit with
external components allowing 2Vrms inputs to be applied.
5K
AINOPL
10uF
10K
10uF
10K
10uF
10K
10uF
10K
10uF
10K
AINVGL
AIN1L
AIN2L
AIN3L
AIN4L
AIN5L
SOURCE
SELECTOR
INPUTS
5K
AINOPR
10uF
10K
10uF
10K
10uF
10K
10uF
10K
10uF
10K
AINVGR
AIN1R
AIN2R
AIN3R
AIN4R
AIN5R
Figure 41 ADC Input Multiplexor Configuration
10K
MX[0]
10uF
AUX input
DACL/R
10K
AUXL/R
10K
BYPASSL/R
10K
MX[1]
MX[2]
Figure 42 5.1 Channel Input Multiplexor Configuration
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Production Data
RECOMMENDED EXTERNAL COMPONENTS
Figure 43 External Component Diagram
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Production Data
It is recommended that a low pass filter be applied to the output from the DAC 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
WM8776 produces much less high frequency output noise). This filter is typically also used to
provide the 2x gain needed to provide the standard 2Vrms output level from most consumer
equipment. Figure 44 shows a suitable post DAC filter circuit, with 2x gain. Alternative inverting filter
architectures might also be used with as good results.
4.7kΩ
4.7kΩ
+VS
_
51Ω
10uF
+
1.8kΩ
7.5KΩ
+
1.0nF
680pF
-VS
10kΩ
Figure 44 Recommended Post DAC Filter Circuit
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WM8776
Production Data
PACKAGE DIMENSIONS
FT: 48 PIN TQFP (7 x 7 x 1.0 mm)
b
DM004.C
e
36
25
37
24
E1
48
E
13
1
12
Θ
D1
c
D
L
A A2
A1
-Cccc C
Symbols
A
A1
A2
b
c
D
D1
E
E1
e
L
Θ
ccc
REF:
SEATING PLANE
Dimensions
(mm)
MIN
NOM
MAX
--------1.20
0.05
----0.15
0.95
1.00
1.05
0.17
0.22
0.27
0.09
----0.20
9.00 BSC
7.00 BSC
9.00 BSC
7.00 BSC
0.50 BSC
0.45
0.60
0.75
o
o
o
0
3.5
7
Tolerances of Form and Position
0.08
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 = ABC. REFER TO THIS SPECIFICATION FOR FURTHER DETAILS.
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Production Data
WM8776
IMPORTANT NOTICE
Wolfson Microelectronics plc (“Wolfson”) products and services are sold subject to Wolfson’s terms and conditions of sale,
delivery and payment supplied at the time of order acknowledgement.
Wolfson warrants performance of its products to the specifications in effect at the date of shipment. Wolfson reserves the
right to make changes to its products and specifications or to discontinue any product or service without notice. Customers
should therefore obtain the latest version of relevant information from Wolfson to verify that the information is current.
Testing and other quality control techniques are utilised to the extent Wolfson deems necessary to support its warranty.
Specific testing of all parameters of each device is not necessarily performed unless required by law or regulation.
In order to minimise risks associated with customer applications, the customer must use adequate design and operating
safeguards to minimise inherent or procedural hazards. Wolfson is not liable for applications assistance or customer
product design. The customer is solely responsible for its selection and use of Wolfson products. Wolfson is not liable for
such selection or use nor for use of any circuitry other than circuitry entirely embodied in a Wolfson product.
Wolfson’s products are not intended for use in life support systems, appliances, nuclear systems or systems where
malfunction can reasonably be expected to result in personal injury, death or severe property or environmental damage.
Any use of products by the customer for such purposes is at the customer’s own risk.
Wolfson does not grant any licence (express or implied) under any patent right, copyright, mask work right or other
intellectual property right of Wolfson covering or relating to any combination, machine, or process in which its products or
services might be or are used. Any provision or publication of any third party’s products or services does not constitute
Wolfson’s approval, licence, warranty or endorsement thereof. Any third party trade marks contained in this document
belong to the respective third party owner.
Reproduction of information from Wolfson datasheets is permissible only if reproduction is without alteration and is
accompanied by all associated copyright, proprietary and other notices (including this notice) and conditions. Wolfson is
not liable for any unauthorised alteration of such information or for any reliance placed thereon.
Any representations made, warranties given, and/or liabilities accepted by any person which differ from those contained in
this datasheet or in Wolfson’s standard terms and conditions of sale, delivery and payment are made, given and/or
accepted at that person’s own risk. Wolfson is not liable for any such representations, warranties or liabilities or for any
reliance placed thereon by any person.
ADDRESS:
Wolfson Microelectronics plc
Westfield House
26 Westfield Road
Edinburgh
EH11 2QB
United Kingdom
Tel :: +44 (0)131 272 7000
Fax :: +44 (0)131 272 7001
Email :: [email protected]
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