WM8985 Product Datasheet

w
WM8985
Multimedia CODEC with Class D Headphone and Line Out
DESCRIPTION
FEATURES
The WM8985 is a low power, high quality, feature-rich stereo
CODEC designed for portable multimedia applications that
require low power consumption and high quality audio.
Stereo CODEC:

DAC SNR 98dB, THD -84dB (‘A’ weighted @ 48kHz)

ADC SNR 92.5dB, THD -83dB (‘A’ weighted @ 48kHz)

Headphone driver with ‘capless’ option
- 40mW/channel output power into 16 / 3.3V AVDD2
- Class D headphone driver
- Class AB headphone / line Driver
- PSRR 70dB at 217Hz

Stereo, mono or differential line output
The device integrates preamps for stereo differential mics, and
includes class D and class AB drivers for headphone and
differential or stereo line output. External component
requirements are reduced as no separate microphone or
headphone amplifiers are required.
Advanced DSP features include a 5-band equaliser, an
ALC/limiter for the microphone or line input through the ADC
and a digital playback limiter. Additional digital filtering options
are available in the ADC path, to cater for application filtering
such as ‘wind noise reduction’ and a programmable notch filter.
Highly flexible mixers enable many new application features,
with the option to record and playback any combination of voice,
line inputs and digital audio such as FM Radio or MP3.
The WM8985 digital audio interface can operate in master or
slave mode, while an integrated PLL provides flexible clocking
schemes.
The WM8985 operates at analogue supply voltages from 2.5V to
3.3V, although the digital core can operate at voltages down to
1.71V to save power. Additional power management control
enables individual sections of the chip to be powered down
under software control.
Mic Preamps:

Stereo differential or mono microphone interfaces

Programmable preamp gain

Pseudo differential inputs with common mode rejection

Programmable ALC / Noise Gate in ADC path

Low-noise bias supplied for electret microphones
Other Features:

Enhanced 3-D function for improved stereo separation

Digital playback limiter

5-band Equaliser (record or playback)

Programmable ADC High Pass Filter (wind noise reduction)

Programmable ADC Notch Filter

Aux inputs for stereo analog input signals or ‘beep’

PLL supporting various clocks between 8MHz-50MHz

Sample rates supported (kHz): 8, 11.025, 16, 12, 16, 22.05,
24, 32, 44.1, 48

Low power, low voltage

2.5V to 3.6V analogue supplies

1.71V to 3.6V digital supplies

5x5mm 32-lead QFN package
APPLICATIONS


WOLFSON MICROELECTRONICS plc
Portable audio player / FM radio
Multimedia Mobile Handsets
Production Data, February 2013, Rev 4.7
Copyright 2013 Wolfson Microelectronics plc
WM8985
Production Data
BLOCK DIAGRAM
w
PD, Rev 4.7, February 2012
2
WM8985
Production Data
TABLE OF CONTENTS
DESCRIPTION ....................................................................................................... 1 FEATURES ............................................................................................................ 1 APPLICATIONS..................................................................................................... 1 BLOCK DIAGRAM ................................................................................................ 2 TABLE OF CONTENTS ......................................................................................... 3 PIN CONFIGURATION .......................................................................................... 5 ORDERING INFORMATION .................................................................................. 5 PIN DESCRIPTION ................................................................................................ 6 ABSOLUTE MAXIMUM RATINGS ........................................................................ 7 RECOMMENDED OPERATING CONDITIONS ..................................................... 7 ELECTRICAL CHARACTERISTICS ..................................................................... 8 TERMINOLOGY ............................................................................................................ 14 POWER CONSUMPTION .................................................................................... 15 AUDIO PATHS OVERVIEW ................................................................................ 16 SIGNAL TIMING REQUIREMENTS .................................................................... 17 SYSTEM CLOCK TIMING ............................................................................................. 17 AUDIO INTERFACE TIMING – MASTER MODE .......................................................... 17 AUDIO INTERFACE TIMING – SLAVE MODE ............................................................. 18 CONTROL INTERFACE TIMING – 3-WIRE MODE ...................................................... 19 CONTROL INTERFACE TIMING – 2-WIRE MODE ...................................................... 20 INTERNAL POWER ON RESET CIRCUIT .......................................................... 21 RECOMMENDED POWER UP/DOWN SEQUENCE .................................................... 23 DEVICE DESCRIPTION ...................................................................................... 27 INTRODUCTION ........................................................................................................... 27 INPUT SIGNAL PATH ................................................................................................... 28 ANALOGUE TO DIGITAL CONVERTER (ADC) ........................................................... 38 INPUT LIMITER / AUTOMATIC LEVEL CONTROL (ALC)............................................ 43 LIMITER MODE ............................................................................................................. 46 OUTPUT SIGNAL PATH ............................................................................................... 55 3D STEREO ENHANCEMENT ...................................................................................... 62 ANALOGUE OUTPUTS ................................................................................................. 63 DIGITAL AUDIO INTERFACES ..................................................................................... 76 AUDIO SAMPLE RATES ............................................................................................... 81 MASTER CLOCK AND PHASE LOCKED LOOP (PLL) ................................................ 81 COMPANDING .............................................................................................................. 83 GENERAL PURPOSE INPUT/OUTPUT........................................................................ 86 OUTPUT SWITCHING (JACK DETECT)....................................................................... 87 CONTROL INTERFACE ................................................................................................ 88 RESETTING THE CHIP ................................................................................................ 89 POWER SUPPLIES....................................................................................................... 89 POWER MANAGEMENT .............................................................................................. 90 POP MINIMISATION ..................................................................................................... 91 REGISTER MAP .................................................................................................. 92 REGISTER BITS BY ADDRESS ................................................................................... 94 DIGITAL FILTER CHARACTERISTICS ............................................................ 112 TERMINOLOGY .......................................................................................................... 112 DAC FILTER RESPONSES ........................................................................................ 113 ADC FILTER RESPONSES ........................................................................................ 113 HIGHPASS FILTER ..................................................................................................... 114 w
PD, Rev 4.7, February 2012
3
WM8985
Production Data
5-BAND EQUALISER .................................................................................................. 115 APPLICATIONS INFORMATION ...................................................................... 119 RECOMMENDED EXTERNAL COMPONENTS ......................................................... 119 PACKAGE DIAGRAM ....................................................................................... 120 IMPORTANT NOTICE ....................................................................................... 121 ADDRESS: .................................................................................................................. 121 REVISION HISTORY ......................................................................................... 122 w
PD, Rev 4.7, February 2012
4
WM8985
Production Data
PIN CONFIGURATION
ORDERING INFORMATION
ORDER CODE
TEMPERATURE
RANGE
PACKAGE
MOISTURE
SENSITIVITY LEVEL
PEAK SOLDERING
TEMPERATURE
WM8985CGEFL
-40C to +85C
32-lead QFN (5 x 5 mm)
(Pb-free)
MSL1
260 C
WM8985CGEFL/R
-40C to +85C
32-lead QFN (5 x 5 mm)
(Pb-free, tape and reel)
MSL1
260 C
o
o
Note:
Reel quantity = 3,500
w
PD, Rev 4.7, February 2012
5
WM8985
Production Data
PIN DESCRIPTION
PIN
NAME
TYPE
1
LIP
Analogue Input
Left MIC pre-amp positive input
DESCRIPTION
2
LIN
Analogue Input
Left MIC pre-amp negative input
3
L2/GPIO2
Analogue Input
Left channel line input/secondary mic pre-amp positive input/GPIO2 pin
4
RIP
Analogue Input
Right MIC pre-amp positive input
5
RIN
Analogue Input
Right MIC pre-amp negative input
6
R2/GPIO3
Analogue Input
Right channel line input/secondary mic pre-amp positive input/GPIO3 pin
7
LRC
Digital Input / Output
8
BCLK
Digital Input / Output
9
ADCDAT
Digital Output
10
DACDAT
Digital Input
11
MCLK
Digital Input
12
DGND
Supply
Digital ground
13
DCVDD
Supply
Digital core logic supply
Digital buffer (I/O) supply
DAC and ADC sample rate clock
Digital audio bit clock
ADC digital audio data output
DAC digital audio data input
Master clock input
14
DBVDD
Supply
15
CSB/GPIO1
Digital Input / Output
16
SCLK
Digital Input
17
SDIN
Digital Input / Output
18
MODE
Digital Input
19
AUXL
Analogue Input
Left auxiliary input
20
AUXR
Analogue Input
Right auxiliary input
21
OUT4
Analogue Output
Right line output / mono mix output
22
OUT3
Analogue Output
Left line output
23
ROUT2
Analogue Output
24
AGND2
Supply
25
LOUT2
Analogue Output
26
AVDD2
Supply
27
VMID
Reference
28
AGND1
Supply
29
ROUT1
Analogue Output
30
LOUT1
Analogue Output
31
AVDD1
Supply
32
MICBIAS
Analogue Output
3-Wire control interface chip Select / GPIO1 pin
3-Wire control interface clock input / 2-wire control interface clock input
3-Wire control interface data input / 2-Wire control interface data input
Control interface selection
Class D or class AB headphone output right
Analogue ground (ground reference for ROUT2/LOUT2 and OUT3/OUT4)
Class D or class AB headphone output left
Analogue supply (feeds output amplifiers ROUT2/LOUT2 and OUT3/OUT4)
Decoupling for ADC and DAC reference voltage
Analogue ground (ground reference for all input amplifiers, PLL, ADC and
DAC, internal bias circuits, output amplifiers LOUT1, ROUT1)
Class AB headphone or line output right
Class AB headphone or line output left
Analogue supply (feeds all input amplifiers, PLL, ADC and DAC, internal
bias circuits, output amplifiers LOUT1, LOUT2))
Microphone bias
Note:
It is recommended that the QFN ground paddle should be connected to analogue ground on the application PCB. Refer to
the application note WAN_0118 on “Guidelines on How to Use QFN Packages and Create Associated PCB Footprints”.
w
PD, Rev 4.7, February 2012
6
WM8985
Production Data
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-020 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
-0.3V
+4.5V
Voltage range digital inputs
DGND -0.3V
DBVDD +0.3V
Voltage range analogue inputs
AGND1 -0.3V
AVDD1 +0.3V
Operating Temperature Range
-40°C
+85°C
DBVDD, DCVDD, AVDD1, AVDD2 supply voltages
Storage temperature prior to soldering
30C max / 85% RH max
Storage temperature after soldering
-65C
+150C
Notes:
1.
Analogue and digital grounds must always be within 0.3V of each other.
2.
All digital and analogue supplies are internally independent (i.e. not connected).
3.
Analogue supply voltages AVDD1 and AVDD2 should be greater than or equal to the DCVDD digital supply voltage.
4.
DBVDD must be greater than or equal to DCVDD.
RECOMMENDED OPERATING CONDITIONS
PARAMETER
SYMBOL
Digital supply range (Core)
DCVDD
1.71
Digital supply range (Buffer)
DBVDD
1.71
AVDD1, AVDD2
2.5
Analogue supply range
Ground
TEST
CONDITIONS
DGND, AGND1, AGND2
MIN
TYP
MAX
UNIT
1,2
3.6
V
2
3.6
V
1
3.6
0
V
V
Notes:
1.
Analogue supply voltages should not be less than digital supply voltages.
2.
DBVDD must be greater than or equal to DCVDD.
w
PD, Rev 4.7, February 2012
7
WM8985
Production Data
ELECTRICAL CHARACTERISTICS
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Microphone Input PGA Inputs (LIP, LIN, RIP, RIN, L2, R2)
INPPGAVOLL, INPPGAVOLR, PGABOOSTL and PGABOOSTR = 0dB
Full-scale Input Signal Level –
1
Single-ended input via LIN/RIN
AVDD/3.3
Vrms
Full-scale Input Signal Level –
1,2
Pseudo-differential input
AVDD*0.7/
Vrms
Input PGA equivalent input noise
3.3
INPPGAVOLL/R = +35.25dB
150
μV
No input signal
0 to 20kHz
LIN, RIN input resistance
INPPGAVOLL and
INPPGAVOLR = +35.25dB
1.6
k
LIN, RIN input resistance
INPPGAVOLL and
INPPGAVOLR = 0dB
46
k
LIN, RIN input resistance
INPPGAVOLL and
INPPGAVOLR = -12dB
71
k
LIP, RIP input resistance
All gain settings
90
k
L2, R2 input resistance
L2_2INPPGA and
R2_2INPPGA = 1
L2_2BOOSTVOL and
R2_2BOOSTVOL = 000
90
k
L2, R2 input resistance
L2_2INPPGA and
R2_2INPPGA = 0
11
k
22
k
60
k
All analogue input pins
10
pF
Maximum Input PGA Programmable
Gain
Gain adjusted by
INPPGAVOLL and
INPPGAVOLL
+35.25
dB
Minimum Input PGA Programmable
Gain
Gain adjusted by
INPPGAVOLL and
INPPGAVOLL
-12
dB
Guaranteed monotonic
0.75
dB
INPPGAMUTEL and
INPPGAMUTER = 1
100
dB
Input Gain Boost
PGABOOSTL and
PGABOOSTR = 0
0
dB
Input Gain Boost
PGABOOSTL and
PGABOOSTR = 1
+20
dB
L2_2BOOSTVOL and
R2_2BOOSTVOL = +6dB
L2, R2 input resistance
L2_2INPPGA and
R2_2INPPGA = 0
L2_2BOOSTVOL and
R2_2BOOSTVOL = 0dB
L2, R2 input resistance
L2_2INPPGA and
R2_2INPPGA = 0
L2_2BOOSTVOL and
R2_2BOOSTVOL = -12dB
Input Capacitance
Programmable Gain Step Size
Input PGA Mute Attenuation
w
PD, Rev 4.7, February 2012
8
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Auxiliary Analogue Inputs (AUXL, AUXR)
Full-scale Input Signal Level
2
Input Resistance
AVDD/3.3
Vrms
11
k
22
k
60
k
11
k
22
k
60
k
Left Input boost and mixer
enabled, at +6dB
Left Input boost and mixer
enabled, at 0dB gain
Left Input boost and mixer
enabled, at -12dB gain
Right Input boost, mixer
enabled, at +6dB gain
Right Input boost, mixer
enabled, at 0dB gain
Right Input boost, mixer
enabled, at -12dB gain
Input Capacitance
Maximum Gain from AUXL and
AUXR input to left and right input
PGA mixers
All analogue Inputs
10
pF
Gain adjusted by
+6
dB
-12
dB
Guaranteed monotonic
3
dB
Gain adjusted by
+6
dB
-12
dB
AUXL2BOOSTVOL and
AUXR2BOOSTVOL
Minimum Gain from AUXL and
AUXR input to left and right input
PGA mixers
Gain adjusted by
AUXL2BOOSTVOL and
AUXR2BOOSTVOL
AUXLBOOSTVOL and
AUXRBOOSTVOL step size
L2, R2 Line Input Programmable Gain
Maximum Gain from L2/R2 input to
left and right input PGA mixers
L2_2BOOSTVOL and
R2_2BOOSTVOL
Minimum Gain from L2/R2 input to
left and right input PGA mixers
Gain adjusted by
L2_2BOOSTVOL and
R2_2BOOSTVOL
L2/R2_2BOOSTVOL step size
Guaranteed monotonic
L2/R2_2BOOSTVOL mute
attenuation
3
dB
100
dB
OUT4 to left or right input boost record path
Maximum Gain into left and right
input PGA mixers
Gain adjusted by
OUT4_2ADCVOL
+12
dB
Minimum Gain into left and right
input PGA mixers
Gain adjusted by
OUT4_2ADCVOL
-6
dB
OUT4_2ADCVOL gain step size
Guaranteed monotonic
3
dB
100
dB
OUT4_2ADCVOL mute attenuation
Analogue to Digital Converter (ADC) - Input from LIN/P and RIN/P in differential configuration to input PGA
INPPGAVOLL, INPPGAVOLR, PGABOOSTL, PGABOOSTR, ADCLVOL and ADCRVOL = 0dB
Signal to Noise Ratio
3
SNR
A-weighted
92.5
dB
91.5
dB
90
dB
90
dB
AVDD1=AVDD2=3.3V
A-weighted
AVDD1=AVDD2=2.5V
22Hz to 20kHz
AVDD1=AVDD2=3.3V
22Hz to 20kHz
AVDD1=AVDD2=2.5V
w
PD, Rev 4.7, February 2012
9
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
Total Harmonic Distortion
4
SYMBOL
TEST CONDITIONS
THD
-7dBV Input
MIN
TYP
MAX
UNIT
-75
-70
dB
AVDD1=AVDD2=3.3V
-7dBV Input
-75
dB
AVDD1=AVDD2=2.5V
Total Harmonic Distortion + Noise
5
THD+N
-7dBV Input
-72
-68
dB
AVDD1=AVDD2=3.3V
-7dBV Input
-72
dB
100
dB
AVDD1=AVDD2=2.5V
Channel Separation
6
1kHz full scale input signal
Analogue to Digital Converter (ADC) - Input from L2, R2 into left and right PGA mixer. INPPGAVOLL, INPPGAVOLR,
L2_2BOOSTVOL, R2_2BOOSTVOL, ADCLVOL and ADCRVOL = 0dB
Signal to Noise Ratio
3
SNR
A-weighted
85
92.5
dB
92.5
dB
90
dB
90
dB
AVDD1=AVDD2=3.3V
A-weighted
AVDD1=AVDD2=2.5V
22Hz to 20kHz
AVDD1=AVDD2=3.3V
22Hz to 20kHz
AVDD1=AVDD2=2.5V
Total Harmonic Distortion
4
THD
-1dBV Input
-83
-78
dB
AVDD1=AVDD2=3.3V
-1dBV Input
-66
dB
AVDD1=AVDD2=2.5V
Total Harmonic Distortion + Noise
5
THD+N
-1dBV Input
-81
-70
dB
AVDD1=AVDD2=3.3V
-1dBV Input
-65
dB
100
dB
AVDD1/3.3
Vrms
98
dB
96
dB
95.5
dB
93.5
dB
AVDD1=AVDD2=2.5V
Channel Separation
6
1kHz input signal
DAC to left and right mixers into 10k / 50pF load on LOUT1 and ROUT1
LOUT1VOL, ROUT1VOL, DACLVOL and DACRVOL = 0dB
Full-scale output
1
LOUT1VOL and
ROUTVOL = 0dB
Signal to Noise Ratio
3
SNR
A-weighted
92
AVDD1=AVDD2=3.3V
A-weighted
AVDD1=AVDD2=2.5V
22Hz to 20kHz
AVDD1=AVDD2=3.3V
22Hz to 20kHz
AVDD1=AVDD2=2.5V
Total Harmonic Distortion
4
THD
0dBFS input
-84
-80
dBFS
AVDD1=AVDD2=3.3V
Total Harmonic Distortion + Noise
Channel Separation
6
w
5
THD+N
0dBFS input
AVDD1=AVDD2=2.5V
-84
dBFS
0dBFS input
AVDD1=AVDD2=3.3V
-82
0dBFS input
AVDD1=AVDD2=2.5V
-82
dBFS
1kHz signal
100
dB
-78
dBFS
PD, Rev 4.7, February 2012
10
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DAC to L/R mixer into 10k / 50pF load on L/ROUT2, class AB mode
LOUT2VOL, ROUT2VOL, DACLVOL and DACRVOL = 0dB
Full-scale output
1
LOUT2VOL and
AVDD1/3.3
Vrms
100
dB
96
dB
95.5
dB
93.5
dB
0dBFS input
AVDD1=AVDD2=3.3V
-84
dBFS
0dBFS input
AVDD1=AVDD2=2.5V
-82
dBFS
0dBFS input
AVDD1=AVDD2=3.3V
-82
dBFS
0dBFS input
AVDD1=AVDD2=2.5V
-80
dBFS
1kHz input signal
100
dB
ROUT2VOL = 0dB
Signal to Noise Ratio
3
SNR
A-weighted
AVDD1=AVDD2=3.3V
A-weighted
AVDD1=AVDD2=2.5V
22Hz to 20kHz
AVDD1=AVDD2=3.3V
22Hz to 20kHz
AVDD1=AVDD2=2.5V
Total Harmonic Distortion
4
Total Harmonic Distortion + Noise
Channel Separation
THD
5
THD+N
6
DAC to OUT3 and OUT4 mixers into OUT3/OUT4 outputs into (10k / 50pF load. DACVOLL and DACVOLR = 0dB)
Full-scale output voltage
Signal to Noise Ratio
3
SNR
A-weighted
AVDD2/3.3
Vrms
98
dB
-84
dBFS
-82
dBFS
100
dB
AVDD1/3.3
Vrms
100
dB
95.5
dB
AVDD1=AVDD2=3.3V
Total Harmonic Distortion
4
THD
full-scale signal
AVDD1=AVDD2=3.3V
Total Harmonic Distortion + Noise
5
THD+N
full-scale signal
AVDD1=AVDD2=3.3V
Channel Separation
6
1kHz signal
DAC to left and right mixer into headphone 16Ω load on LOUT1 and ROUT1
LOUT1VOL, ROUT1VOL, DACLVOL and DACRVOL = 0dB
Full-scale output
Signal to Noise Ratio
3
SNR
A-weighted
AVDD1=AVDD2=3.3V
22Hz to 20kHz
AVDD1=AVDD2=3.3V
Total Harmonic Distortion
4
Total Harmonic Distortion + Noise
Channel Separation
6
w
5
THD
Po = 20mW, RL=16Ω
-79
dB
THD+N
Po = 20mW, RL=16Ω
-75
dB
1kHz signal
100
dB
PD, Rev 4.7, February 2012
11
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
DAC to left and right mixer into headphone 16Ω load on LOUT2 and ROUT2, Class AB mode
LOUT2VOL, ROUT2VOL, DACLVOL and DACRVOL = 0dB
Full-scale output
Signal to Noise Ratio
3
SNR
A-weighted
90
AVDD1/3.3
Vrms
97
dB
95.5
dB
AVDD1=AVDD2=3.3V
22Hz to 20kHz
AVDD1=AVDD2=3.3V
Total Harmonic Distortion
4
Total Harmonic Distortion + Noise
Channel Separation
5
THD
Po = 20mW, RL=16Ω
-80
-75
dB
THD+N
Po = 20mW, RL=16Ω
-77
-70
dB
1kHz signal
100
6
dB
DAC to left and right mixer into headphone 16Ω load on LOUT2 and ROUT2, Class D mode, Lfilter = 33uH Cfilter = 220nf
LOUT2VOL, ROUT2VOL, DACLVOL and DACRVOL = 0Db
Full-scale output
Signal to Noise Ratio
3
SNR
A-weighted
90
AVDD1/3.3
Vrms
97
dB
AVDD1=AVDD2=3.3V
Total Harmonic Distortion
Channel Separation
4
THD
6
Po = 20mW, RL=16Ω
-79
1kHz signal
-75
dB
100
dB
PWM Rise Time
1.5
ns
PWM Fall Time
1.5
ns
DCLKDIV = 1000
1.4
MHz
RL = 16Ω, tPW = 20ns,
72
%
100mVpp ripple @217Hz
injected on AVDD2
70
dB
No analogue output signal
0.5
mA
PWM Switching Frequency
Efficiency
PO = 20mW
Power Supply Rejection
Idle Current
PSRR
on either channel
Bypass paths to left and right output mixers. BYPL2LMIX = 1 and BYPR2RMIX = 1
Maximum PGA gain into mixer
Gain adjusted by
BYPLMIXVOL and
BYPRMIXVOL
+6
dB
Minimum PGA gain into mixer
Gain adjusted by
BYPLMIXVOL and
BYPRMIXVOL
-15
dB
Guaranteed monotonic
3
dB
BYPL2LMIX = 0 BYPR2RMIX
=0
100
dB
BYPLMIXVOL and BYPRMIXVOL
gain step into mixer
Mute attenuation
Analogue outputs (LOUT1, ROUT1, LOUT2, ROUT2)
Maximum Programmable Gain
Gain adjusted by
L/ROUT1VOL and
L/ROUT2VOL
+6
dB
Minimum Programmable Gain
Gain adjusted by
L/ROUT1VOL and
L/ROUT2VOL
-57
dB
Programmable Gain step size
Guaranteed monotonic
1
dB
Mute attenuation
1kHz, full scale signal
85
dB
L/ROUT1MUTE = 1
L/ROUT2MUTE = 1
w
PD, Rev 4.7, February 2012
12
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LIN and RIN input PGA to input boost stage into 10k / 50pF load on OUT3/OUT4 outputs
INPPGAVOLL, INPPGAVOLR, PGABOOSTL and PGABOOSTR = 0dB
Full-scale output voltage, 0dB gain
Signal to Noise Ratio
3
SNR
A-weighted
90
AVDD2/3.3
Vrms
98
dB
96
dB
95.5
dB
93.5
dB
-84
dBFS
-82
dBFS
-82
dBFS
-80
dBFS
100
dB
AVDD1/3.3
Vrms
100
dB
96
dB
95.5
dB
93.5
dB
AVDD1=AVDD2=3.3V
A-weighted
AVDD1=AVDD2=2.5V
22Hz to 22kHz
AVDD1=AVDD2=3.3V
22Hz to 22kHz
AVDD1=AVDD2=2.5V
Total Harmonic Distortion
4
THD
full-scale signal
AVDD1=AVDD2=3.3V
full-scale signal
AVDD1=AVDD2=2.5V
Total Harmonic Distortion + Noise
5
THD+N
full-scale signal
AVDD1=AVDD2=3.3V
full-scale signal
AVDD1=AVDD2=2.5V
6
Channel Separation
LIN and RIN into input PGA Bypass to LOUT1 and ROUT1 into 16 / 50pF loads
BYPLMIXVOL, BYPRMIXVOL, LOUT1VOL and ROUT1VOL = 0dB
Full-scale output voltage, 0dB gain
Signal to Noise Ratio
3
SNR
A-weighted
90
AVDD1=AVDD2=3.3V
A-weighted
AVDD1=AVDD2=2.5V
22Hz to 22kHz
AVDD1=AVDD2=3.3V
22Hz to 22kHz
AVDD1=AVDD2=2.5V
Total Harmonic Distortion
4
THD
full-scale signal
-87
-75
dBFS
AVDD1=AVDD2=3.3V
full-scale signal
-69
dBFS
AVDD1=AVDD2=2.5V
Total Harmonic Distortion + Noise
5
THD+N
full-scale signal
-85
-73
dBFS
AVDD1=AVDD2=3.3V
full-scale signal
-68
dBFS
1kHz full scale signal
100
dB
MBVSEL=0
0.9*AVDD1
V
MBVSEL=1
0.65*AVDD1
AVDD1=AVDD2=2.5V
Channel separation
6
Microphone Bias
Bias Voltage
Bias Current Source
for VMICBIAS within +/-3%
Output Noise Voltage
1kHz to 20kHz
w
V
3
15
mA
nV/Hz
PD, Rev 4.7, February 2012
13
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, AVDD1=AVDD2=DBVDD=3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Digital Input / Output
Input HIGH Level
Input LOW Level
VIL
Output HIGH Level
VOH
Output LOW Level
VOL
Input Capacitance
Input leakage
0.7DBV
DD
VIH
V
0.3DBVDD
IOL=1mA
0.9DBV
DD
V
IOH-1mA
All digital pins
V
0.1xDBVDD
V
10
pF
50
pA
TERMINOLOGY
1.
Full-scale input and output levels scale in relation to AVDD1 or AVDD2 depending upon the input or output used. For
example, when AVDD1 = 3.3V, 0dBFS = 1Vrms (0dBV). When AVDD < 3.3V the absolute level of 0dBFS will decrease
with a linear relationship to AVDD.
2.
Input level to RIP and LIP in differential configurations is limited to a maximum of -3dB or performance will be reduced.
3.
Signal-to-noise ratio (dBFS) – SNR is the difference in level between a reference full scale output signal and the
device output with no signal applied. This ratio is also called idle channel noise. (No Auto-zero or Automute function is
employed in achieving these results).
4.
Total Harmonic Distortion (dB) – THD is the difference in level between a reference output signal and the first seven
harmonics of the output signal. To calculate the ratio, the fundamental frequency of the output signal is notched out
and an RMS value of the next seven harmonics is calculated.
5.
Total Harmonic Distortion plus Noise (dB) – THD+N is the difference in level between a reference output signal and
the sum of the harmonics, wide-band noise and interference on the output signal. To calculate the ratio, the
fundamental frequency of the output signal is notched out and an RMS value of the total harmonics, wide-band noise
and interference is calculated.
6.
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.
w
PD, Rev 4.7, February 2012
14
WM8985
Production Data
POWER CONSUMPTION
Typical power consumption for various scenarios is shown below.
DBVDD(V)
DBVDD(mA)
AVDD1(V)
AVDD1(mA)
AVDD2(V)
AVDD2(mA)
Total (mW)
1.8 0.0002
1.8 0.0002
1.8 0.0002
3.3 0.006
3.6 0.008
1.8
3.3
3.3
3.3
3.6
0
0
0
0
0
2.5
3
3.3
3.3
3.6
0.01
0.011
0.012
0.011
0.012
2.5
3
3.3
3.3
3.6
0
0
0
0
0
0.03
0.03
0.04
0.06
0.07
Standby mode (Lowest Power)
1.8
1.8
1.8
3.3
3.6
0.002
0.002
0.002
0.006
0.008
1.8
3.3
3.3
3.3
3.6
0
0
0
0
0
2.5
3
3.3
3.3
3.6
0.117
0.138
0.149
0.149
0.157
2.5
3
3.3
3.3
3.6
0
0
0
0
0
0.30
0.42
0.50
0.51
0.59
DAC Playback 32Ω load
L/ROUT2 - Class AB Mode
fs=44.1kHz
1.8
1.8
3.3
3.6
3.336
3.336
7.182
8.098
1.8 0.003
3.3 0.0021
3.3 0.0021
3.6 0.025
2.5
3
3.3
3.6
2.238
2.728
3.025
3.325
2.5
3
3.3
3.6
0.28
0.35
0.39
0.44
12.31
15.24
34.98
42.80
ADC Stereo Line Record
fs=44.1kHz
1.8
1.8
3.3
3.6
3.57
3.57
7.603
8.529
1.8
3.3
3.3
3.6
2.5
2.7
3
3.3
4.76
4.967
5.272
5.578
2.5
3
3.3
3.6
0
0
0
0
18.35
19.88
40.99
49.21
Description
Off (Default Settings)
DCVDD(V)
DCVDD(mA)
All measurements are made with quiescent signal.
0.013
0.013
0.026
0.027
Table 1 Power Consumption
Contact Wolfson for more information on device power consumption.
w
PD, Rev 4.7, February 2012
15
WM8985
Production Data
AUDIO PATHS OVERVIEW
Figure 1 Audio Paths Overview
w
PD, Rev 4.7, February 2012
16
WM8985
Production Data
SIGNAL TIMING REQUIREMENTS
SYSTEM CLOCK TIMING
tMCLKL
MCLK
tMCLKH
tMCLKY
Figure 2 System Clock Timing Requirements
Test Conditions
o
DCVDD=1.8V, DBVDD=AVDD1=AVDD2=3.3V, DGND=AGND1=AGND2=0V, TA = +25 C, Slave Mode
PARAMETER
SYMBOL
CONDITIONS
MIN
TMCLKY
MCLK=SYSCLK (=256fs)
TYP
MAX
UNIT
System Clock Timing Information
MCLK cycle time
MCLK duty cycle
MCLK input to PLL
TMCLKDS
Note 1
81.38
ns
20
ns
60:40
40:60
Note:
1.
PLL pre-scaling and PLL N and K values should be set appropriately so that SYSCLK is no greater than 12.288MHz.
AUDIO INTERFACE TIMING – MASTER MODE
Figure 3 Digital Audio Data Timing – Master Mode (see Control Interface)
w
PD, Rev 4.7, February 2012
17
WM8985
Production Data
Test Conditions
o
DCVDD=1.8V, DBVDD=AVDD1=AVDD2=3.3V, DGND=AGND1=AGND2=0V, TA=+25 C, Master Mode, fs=48kHz, MCLK=256fs,
24-bit data, unless otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
Audio Data Input Timing Information
LRC propagation delay from BCLK falling edge
tDL
10
ns
ADCDAT propagation delay from BCLK falling edge
tDDA
15
ns
DACDAT setup time to BCLK rising edge
tDST
10
ns
DACDAT hold time from BCLK rising edge
tDHT
10
ns
AUDIO INTERFACE TIMING – SLAVE MODE
Figure 4 Digital Audio Data Timing – Slave Mode
Test Conditions
o
DCVDD=1.8V, DBVDD=AVDD1=AVDD2=3.3V, DGND=AGND1=AGND2=0V, TA=+25 C, Slave Mode, fs=48kHz,
MCLK= 256fs, 24-bit data, unless otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
Audio Data Input Timing Information
BCLK cycle time
tBCY
50
ns
BCLK pulse width high
tBCH
20
ns
BCLK pulse width low
tBCL
20
ns
LRC set-up time to BCLK rising edge
tLRSU
10
ns
LRC hold time from BCLK rising edge
tLRH
10
ns
DACDAT hold time from BCLK rising edge
tDH
10
ns
DACDAT set-up time to BCLK rising edge
tDs
10
ADCDAT propagation delay from BCLK falling edge
tDD
ns
15
ns
Note:
BCLK period should always be greater than or equal to MCLK period.
w
PD, Rev 4.7, February 2012
18
WM8985
Production Data
CONTROL INTERFACE TIMING – 3-WIRE MODE
3-wire mode is selected by connecting the MODE pin high.
Figure 5 Control Interface Timing – 3-Wire Serial Control Mode
Test Conditions
o
DCVDD = 1.8V, DBVDD = AVDD1 = AVDD2 = 3.3V, DGND = AGND1 = AGND2 = 0V, TA=+25 C, Slave Mode, fs=48kHz, MCLK
= 256fs, 24-bit data, unless otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
Program Register Input Information
SCLK rising edge to CSB rising edge
tSCS
80
SCLK pulse cycle time
tSCY
200
ns
SCLK pulse width low
tSCL
80
ns
SCLK pulse width high
tSCH
80
ns
SDIN to SCLK set-up time
tDSU
40
ns
SCLK to SDIN hold time
tDHO
40
ns
CSB pulse width low
tCSL
40
ns
CSB pulse width high
tCSH
40
ns
CSB rising to SCLK rising
tCSS
40
ns
tps
0
Pulse width of spikes that will be suppressed
w
ns
5
ns
PD, Rev 4.7, February 2012
19
WM8985
Production Data
CONTROL INTERFACE TIMING – 2-WIRE MODE
2-wire mode is selected by connecting the MODE pin low.
t3
t3
t5
SDIN
t4
t6
t2
t8
SCLK
t1
t9
t7
Figure 6 Control Interface Timing – 2-Wire Serial Control Mode
Test Conditions
o
DCVDD=1.8V, DBVDD=AVDD1=AVDD2=3.3V, DGND=AGND1=AGND2=0V,
MCLK = 256fs, 24-bit data, unless otherwise stated.
TA=+25 C,
Slave
PARAMETER
SYMBOL
MIN
SCLK Low Pulse-Width
t1
1.3
us
SCLK 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
SDIN, SCLK Rise Time
t6
300
ns
SDIN, SCLK Fall Time
t7
300
ns
Setup Time (Stop Condition)
t8
Data Hold Time
t9
900
ns
Pulse width of spikes that will be suppressed
tps
5
ns
TYP
Mode,
fs=48kHz,
MAX
UNIT
526
kHz
Program Register Input Information
SCLK Frequency
w
0
ns
600
0
ns
PD, Rev 4.7, February 2012
20
WM8985
Production Data
INTERNAL POWER ON RESET CIRCUIT
Figure 7 Internal Power on Reset Circuit Schematic
The WM8985 includes an internal Power-On-Reset Circuit, as shown in Figure 7, which is used to
reset the digital logic into a default state after power up. The POR circuit is powered from AVDD1 and
monitors DCVDD. It asserts PORB low if AVDD1 or DCVDD is below a minimum threshold.
Figure 8 Typical Power up Sequence where AVDD1 is Powered before DCVDD
Figure 8 shows a typical power-up sequence where AVDD1 comes up first. When AVDD1 goes
above the minimum threshold, Vpora, there is enough voltage for the circuit to guarantee PORB is
asserted low and the chip is held in reset. In this condition, all writes to the control interface are
ignored. Now AVDD1 is at full supply level. Next DCVDD rises to Vpord_on and PORB is released high
and all registers are in their default state and writes to the control interface may take place.
On power down, where AVDD1 falls first, PORB is asserted low whenever AVDD1 drops below the
minimum threshold Vpora_off.
w
PD, Rev 4.7, February 2012
21
WM8985
Production Data
Figure 9 Typical Power up Sequence where DCVDD is Powered before AVDD1
Figure 9 shows a typical power-up sequence where DCVDD comes up first. First it is assumed that
DCVDD is already up to specified operating voltage. When AVDD1 goes above the minimum
threshold, Vpora, there is enough voltage for the circuit to guarantee PORB is asserted low and the
chip is held in reset. In this condition, all writes to the control interface are ignored. When AVDD1
rises to Vpora_on, PORB is released high and all registers are in their default state and writes to the
control interface may take place.
On power down, where DCVDD falls first, PORB is asserted low whenever DCVDD drops below the
minimum threshold Vpord_off.
SYMBOL
MIN
TYP
MAX
UNIT
Vpora
0.4
0.6
0.8
V
Vpora_on
0.9
1.2
1.6
V
Vpora_off
0.4
0.6
0.8
V
Vpord_on
0.5
0.7
0.9
V
Vpord_off
0.4
0.6
0.8
V
Table 2 Typical POR Operation (Typical Simulated Values)
Notes:
w
1.
If AVDD1 and DCVDD suffer a brown-out (i.e. drop below the minimum recommended operating
level but do not go below Vpora_off or Vpord_off) then the chip will not reset and will resume normal
operation when the voltage is back to the recommended level again.
2.
The chip will enter reset at power down when AVDD1 or DCVDD falls below Vpora_off or Vpord_off.
This may be important if the supply is turned on and off frequently by a power management
system.
3.
The minimum tpor period is maintained even if DCVDD and AVDD1 have zero rise time. This
specification is guaranteed by design rather than test.
PD, Rev 4.7, February 2012
22
WM8985
Production Data
RECOMMENDED POWER UP/DOWN SEQUENCE
In order to minimise output pop and click noise, it is recommended that the WM8985 device is
powered up and down under control using the following sequences:
Power Up:
1.
Turn on external power supplies. Wait for supply voltage to settle.
2.
Set low analogue bias mode, BIASCUT = 1
3.
Enable thermal shutdown TSDEN = TSOPCTRL = 1
4.
Enable Internal bias BIASEN = 1.
5.
Mute all outputs and set PGAs to minimum gain, R52 to R57 = 0x140h.
6.
Enable VMID independent current bias, POBCTRL = 1.
7.
Enable required outputs, DACs and mixers.
8.
Enable VMID with required charge time e.g. VMIDSEL=01.
9.
Wait 500ms
1
10. Setup digital interface, input amplifiers, PLL, ADCs and DACs for desired operation.
11. Disable VMID independent current bias, POBCTRL = 0.
12. Unmute L/ROUT1 and set desired volume, e.g. for 0dB R52 and R53 = 0x139h.
13. Unmute L/ROUT2 and set desired volume, e.g. for 0dB R54 and R55 = 0x139h.
2
Power Down :
1.
Disable Thermal shutdown, TSDEN = TSOPCTRL = 0
2.
Disable VMIDSEL=00 and BIASEN=0
3.
Wait for VMID to discharge
4.
Power off registers R1, R2, R3 = 0x000h
5.
Remove external power supplies
3
Notes:
w
1.
Charging time constant is determined by impedance selected by VMIDSEL and the value of
decoupling capacitor connected to VMID pin.
2.
It is possible to interrupt the power down sequence and power up to VMID before the allocated
VMID discharge time. This is done by following the power-up sequence omitting steps 4 to 8.
3.
Discharge time constant is determined by the values of analogue output capacitors.
PD, Rev 4.7, February 2012
23
WM8985
Production Data
Figure 10 ADC Power Up and Down Sequence (not to scale)
SYMBOL
MIN
TYPICAL
MAX
UNIT
tmidrail_on
300
tmidrail_off
>6
ms
s
tadcint
2/fs
n/fs
ADC Group Delay
29/fs
n/fs
Table 3 Typical POR Operation (Typical Simulated Values)
w
PD, Rev 4.7, February 2012
24
WM8985
Production Data
Notes:
1.
The analogue input pin charge time, tmidrail_on, is determined by the VMID pin charge time. This
time is dependent upon the value of VMID decoupling capacitor and VMID pin input resistance
and AVDD1 power supply rise time.
2.
The analogue input pin discharge time, tmidrail_off, is determined by the analogue input coupling
capacitor discharge time. The time, tmidrail_off, is measured using a 1μF capacitor on the analogue
input but will vary dependent upon the value of input coupling capacitor.
3.
While the ADC is enabled there will be LSB data bit activity on the ADCDAT pin due to system
noise but no significant digital output will be present.
4.
The VMIDSEL and BIASEN bits must be set to enable analogue input midrail voltage and for
normal ADC operation.
5.
ADCDAT data output delay from power up - with power supplies starting from 0V - is determined
primarily by the VMID charge time. ADC initialisation and power management bits may be set
immediately after POR is released; VMID charge time will be significantly longer and will dictate
when the device is stabilised for analogue input.
6.
ADCDAT data output delay at power up from device standby (power supplies already applied) is
determined by ADC initialisation time, 2/fs.
Figure 11 DAC Power Up and Down Sequence (not to scale)
w
PD, Rev 4.7, February 2012
25
WM8985
Production Data
SYMBOL
MIN
TYPICAL
MAX
UNIT
tline_midrail_on
300
ms
tline_midrail_off
>6
s
ms
thp_midrail_on
300
thp__midrail_off
>6
s
tdacint
2/fs
n/fs
DAC Group Delay
29/fs
n/fs
Table 4 Typical POR Operation (Typical Simulated Values)
Notes:
w
1.
The lineout charge time, tline_midrail_on, is determined by the VMID pin charge time. This time is
dependent upon the value of VMID decoupling capacitor and VMID pin input resistance and
AVDD1 power supply rise time. The values above were measured using a 4.7μF capacitor.
2.
It is not advisable to allow DACDAT data input during initialisation of the DAC. If the DAC data
value is not zero at point of initialisation, then this is likely to cause a pop noise on the analogue
outputs. The same is also true if the DACDAT is removed at a non-zero value, and no mute
function has been applied to the signal beforehand.
3.
The lineout discharge time, tline_midrail_off, is determined by the VMID pin discharge time. This time
is dependent upon the value of VMID decoupling capacitor and VMID pin input resistance. The
values above were measured using a 4.7μF capacitor.
4.
The headphone charge time, thp_midrail_on, is dependent upon the value of VMID decoupling
capacitor and VMID pin input resistance and AVDD1 power supply rise time. The values above
were measured using a 4.7μF VMID decoupling capacitor.
5.
The headphone discharge time, thp_midrail_off, is dependent upon the value of VMID decoupling
capacitor and VMID pin input resistance. The values above were measured using a 4.7μF VMID
decoupling capacitor.
6.
The VMIDSEL and BIASEN bits must be set to enable analogue output midrail voltage and for
normal DAC operation.
PD, Rev 4.7, February 2012
26
WM8985
Production Data
DEVICE DESCRIPTION
INTRODUCTION
The WM8985 is a low power audio CODEC combining a high quality stereo audio DAC and ADC, with
flexible line and microphone input and output processing.
FEATURES
The chip offers great flexibility in use, and so can support many different modes of operation as
follows:
MICROPHONE INPUTS
Two pairs of stereo microphone inputs are provided, allowing a pair of stereo microphones to be
pseudo-differentially connected, with user defined gain. The provision of the common mode input pin
for each stereo input allows for rejection of common mode noise on the microphone inputs (level
depends on gain setting chosen). A microphone bias is output from the chip which can be used to
bias both microphones. The signal routing can be configured to allow manual adjustment of mic
levels, or to allow the ALC loop to control the level of mic signal that is transmitted.
Total gain through the microphone paths of up to +55.25dB can be selected.
PGA AND ALC OPERATION
A programmable gain amplifier is provided in the input path to the ADC. This may be used manually
or in conjunction with a mixed analogue/digital automatic level control (ALC) which keeps the
recording volume constant.
AUXILIARY ANALOG LINE INPUTS (AUXL, AUXR)
The inputs, AUXL and AUXR, can be used as a stereo line input or as an input for warning tones (or
‘beeps’) etc. These inputs can be summed into the record paths, along with the microphone preamp
outputs, so allowing for mixing of audio with ‘backing music’ etc as required.
Additional stereo analogue signals might be connected to the Line inputs of WM8985 (e.g. melody
chip or FM radio), and the stereo signal listened to via headphones, or recorded, simultaneously if
required.
ADC
The stereo ADC uses a 24-bit high-order over sampling architecture to deliver optimum performance
with low power consumption.
HI-FI DAC
The hi-fi DAC provides high quality audio playback suitable for all portable audio hi-fi type
applications, including MP3 players and portable disc players of all types.
OUTPUT MIXERS
Flexible mixing is provided on the outputs of the device. A stereo mixer is provided for the stereo
headphone or line outputs, LOUT1/ROUT1, and additional summers on the OUT3/OUT4 outputs
allow for an optional differential or stereo line output on these pins. Gain adjustment PGAs are
provided for the LOUT1/ROUT1 and LOUT2/ROUT2 outputs, and signal switching is provided to allow
for all possible signal combinations.
w
PD, Rev 4.7, February 2012
27
WM8985
Production Data
OUT3 and OUT4 can be configured to provide an additional stereo or mono differential lineout from
the output of the DACs, the mixers or the input microphone boost stages. They can also provide a
midrail reference for pseudo differential inputs to external amplifiers.
AUDIO INTERFACES
The WM8985 has a standard audio interface, to support the transmission of stereo data to and from
the chip. This interface is a 3 wire standard audio interface which supports a number of audio data
formats including:
2

IS

DSP/PCM Mode (a burst mode in which LRC sync plus 2 data packed words are
transmitted)

MSB-First, left justified

MSB-First, right justified
The interface can operate in master or slave modes.
CONTROL INTERFACES
To allow full software control over all features, the WM8985 offers a choice of 2 or 3 wire control
interface. It is fully compatible and an ideal partner for a wide range of industry standard
microprocessors, controllers and DSPs.
Selection of the mode is via the MODE pin. In 2 wire mode, the address of the device is fixed as
0011010.
CLOCKING SCHEMES
WM8985 offers the normal audio DAC clocking scheme operation, where 256fs MCLK is provided to
the DAC and ADC. A flexible clock divider allows the 256fs DAC clock to be generated from a range
of input clock frequencies, for example, 256fs, 384fs, 512fs and 768fs.
A PLL is included which may be used to generate these clocks in the event that they are not available
from the system controller. This PLL can accept a range of common input clock frequencies between
8MHz and 50MHz to generate high quality audio clocks. If this PLL is not required for generation of
these clocks, it can be reconfigured to generate alternative clocks which may then be output on the
GPIO1 pin and used elsewhere in the system; available in 2-wire control mode only.
POWER CONTROL
The design of the WM8985 has given much attention to power consumption without compromising
performance. The WM8985 operates at low analogue and digital supply voltages, and includes the
ability to power off any unused parts of the circuitry under software control. It also includes standby
and power off modes.
INPUT SIGNAL PATH
The WM8985 has a number of flexible analogue inputs. There are two input channels, Left and
Right, each of which consists of an input PGA stage followed by a boost/mix stage which drives into
the hi-fi ADC. Each input path has three input pins which can be configured in a variety of ways to
accommodate single-ended, pseudo-differential or dual differential microphones. There are two
auxiliary input pins which can be fed into to the input boost/mix stage as well as driving into the
output path. A bypass path exists from the output of the boost/mix stage into the output left/right
mixers.
MICROPHONE INPUTS
The WM8985 can accommodate a variety of microphone configurations including single ended and
pseudo-differential inputs. The inputs to the left differential input PGA are LIN, LIP and L2. The
inputs to the right differential input PGA are RIN, RIP and R2.
In single-ended microphone input configuration the microphone signal should be input to LIN or RIN
and the non-inverting input of the input PGA clamped to VMID.
w
PD, Rev 4.7, February 2012
28
WM8985
Production Data
Figure 12 Microphone Input PGA Circuit
The input PGAs are enabled by the INPPGAENL and INPPGAENR register bits.
REGISTER
ADDRESS
R2 (02h)
Power
Management
2
BIT
2
LABEL
INPPGAENL
DEFAULT
0
DESCRIPTION
Left channel input PGA enable
0 = disabled
1 = enabled
3
INPPGAENR
0
Right channel input PGA enable
0 = disabled
1 = enabled
Table 5 Input PGA Enable Register Settings
w
PD, Rev 4.7, February 2012
29
WM8985
Production Data
REGISTER
ADDRESS
BIT
R44 (2Ch)
0
LABEL
LIP2INPPGA
DEFAULT
1
Input
Control
DESCRIPTION
Connect LIP pin to left channel input PGA
amplifier positive terminal.
0 = LIP not connected to input PGA
1 = input PGA amplifier positive terminal
connected to LIP (constant input
impedance)
1
LIN2INPPGA
1
Connect LIN pin to left channel input PGA
negative terminal.
0 = LIN not connected to input PGA
1 = LIN connected to input PGA amplifier
negative terminal.
2
L2_2INPPGA
0
Connect L2 pin to left channel input PGA
positive terminal.
0 = L2 not connected to input PGA
1 = L2 connected to input PGA amplifier
positive terminal (constant input
impedance).
4
RIP2INPPGA
1
Connect RIP pin to right channel input
PGA amplifier positive terminal.
0 = RIP not connected to input PGA
1 = right channel input PGA amplifier
positive terminal connected to RIP
(constant input impedance)
5
RIN2INPPGA
1
Connect RIN pin to right channel input
PGA negative terminal.
0 = RIN not connected to input PGA
1 = RIN connected to right channel input
PGA amplifier negative terminal.
6
R2_2INPPGA
0
Connect R2 pin to right channel input PGA
positive terminal.
0 = R2 not connected to input PGA
1 = R2 connected to input PGA amplifier
positive terminal (constant input
impedance).
Table 6 Input PGA Control
INPUT PGA VOLUME CONTROLS
The input microphone PGAs have a gain range from -12dB to +35.25dB in 0.75dB steps. The gain
from the LIN/RIN input to the PGA output and from the L2/R2 amplifier to the PGA output are always
common and controlled by the register bits INPPGAVOLL[5:0] and INPPGABVOLR[5:0]. These
register bits also affect the LIP pin when LIP2INPPGA=1, the L2 pin when L2_2INPPGA=1, the RIP
pin when RIP2INPPGA=1 and the L2 pin when L2_2INPPGA=1.
When the Automatic Level Control (ALC) is enabled the input PGA gains are controlled automatically
and the INPPGAVOLL and INPPGAVOLR bits should not be used.
w
PD, Rev 4.7, February 2012
30
WM8985
Production Data
REGISTER
ADDRESS
BIT
R45 (20h)
5:0
LABEL
INPPGAVOLL
Left channel
input PGA
volume
control
DEFAULT
DESCRIPTION
010000
Left channel input PGA volume
(0dB)
000000 = -12dB
000001 = -11.25db
.
010000 = 0dB
.
111111 = +35.25dB
6
INPPGAMUTEL
0
Mute control for left channel input PGA:
0 = Input PGA not muted, normal
operation
1 = Input PGA muted (and disconnected
from the following input BOOST stage).
7
INPPGAZCL
0
Left channel input PGA zero cross
enable:
0 = Update gain when gain register
changes
st
1 = Update gain on 1 zero cross after
gain register write.
8
INPPGAVU
Not
latched
INPPGA left and INPPGA right volume
do not update until a 1 is written to
INPPGAVU (in reg 45 or 46)
5:0
INPPGAVOLR
010000
Right channel input PGA volume
(0dB)
000000 = -12dB
(See "Volume Updates" below)
R46 (2Eh)
Right
channel
input PGA
volume
control
000001 = -11.25db
.
010000 = 0dB
.
111111 = +35.25dB
6
INPPGAMUTER
0
Mute control for right channel input PGA:
0 = Input PGA not muted, normal
operation
1 = Input PGA muted (and disconnected
from the following input BOOST stage).
7
INPPGAZCR
0
Right channel input PGA zero cross
enable:
0 = Update gain when gain register
changes
st
1 = Update gain on 1 zero cross after
gain register write.
8
INPPGAVU
Not
latched
8:7
ALCSEL
00
INPPGA left and INPPGA right volume
do not update until a 1 is written to
INPPGAVU (in reg 45 or 46)
(See "Volume Updates" below)
R32 (20h)
ALC control
1
ALC function select:
00 = ALC off
01 = ALC right only
10 = ALC left only
11 = ALC both on
Table 7 Input PGA Volume Control
w
PD, Rev 4.7, February 2012
31
WM8985
Production Data
VOLUME UPDATES
Volume settings will not be applied to the PGAs until a '1' is written to one of the INPPGAVU bits.
This is to allow left and right channels to be updated at the same time, as shown in Figure 13.
Figure 13 Simultaneous Left and Right Volume Updates
If the volume is adjusted while the signal is a non-zero value, an audible click can occur as shown in
Figure 14.
Figure 14 Click Noise during Volume Update
In order to prevent this click noise, a zero cross function is provided. When enabled, this will cause
the PGA volume to update only when a zero crossing occurs, minimising click noise as shown in
Figure 15.
w
PD, Rev 4.7, February 2012
32
WM8985
Production Data
Figure 15 Volume Update using Zero Cross Detection
If there is a long period where no zero-crossing occurs, a timeout circuit in the WM8985 will
automatically update the volume. The volume updates will occur between one and two timeout
periods, depending on when the INPPGAVU bit is set as shown in Figure 16.
Figure 16 Volume Update after Timeout
w
PD, Rev 4.7, February 2012
33
WM8985
Production Data
AUXILLIARY INPUTS
There are two auxiliary inputs, AUXL and AUXR which can be used for a variety of purposes such as
stereo line inputs or as a ‘beep’ input signal to be mixed with the outputs.
The AUXL/R inputs can be used as a line input to the input BOOST stage which has adjustable gain
of -12dB to +6dB in 3dB steps, with an additional "off" state (i.e. not connected to ADC input). See
the INPUT BOOST section for further details.
The AUXL/R inputs can also be mixed into the output channel mixers, with a gain of -15dB to +6dB
plus off.
INPUT BOOST
Each of the stereo input PGA stages is followed by an input BOOST circuit. The input BOOST circuit
has 3 selectable inputs: the input microphone PGA output, the AUX amplifier output and the L2/R2
input pin (can be used as a line input, bypassing the input PGA). These three inputs can be mixed
together and have individual gain boost/adjust as shown in Figure 17.
Figure 17 Input Boost Stage
w
PD, Rev 4.7, February 2012
34
WM8985
Production Data
The input PGA paths can have a +20dB boost (PGABOOSTL/R=1), a 0dB pass through
(PGABOOSTL/R=0) or be completely isolated from the input boost circuit (INPPGAMUTEL/R=1).
REGISTER
ADDRESS
R47 (2Fh)
BIT
8
LABEL
PGABOOSTL
DEFAULT
1
Left Input
BOOST
control
DESCRIPTION
Boost enable for left channel input
PGA:
0 = PGA output has +0dB gain through
input BOOST stage.
1 = PGA output has +20dB gain
through input BOOST stage.
R48 (30h)
8
PGABOOSTR
Right Input
BOOST
control
1
Boost enable for right channel input
PGA:
0 = PGA output has +0dB gain through
input BOOST stage.
1 = PGA output has +20dB gain
through input BOOST stage.
Table 8 Input BOOST Stage Control
The Auxiliary amplifier path to the BOOST stages is controlled by the AUXL2BOOSTVOL[2:0] and
AUXR2BOOSTVOL[2:0] register bits. When AUXL2BOOSTVOL/AUXR2BOOSTVOL=000 this path
is completely disconnected from the BOOST stage. Settings 001 through to 111 control the gain in
3dB steps from -12dB to +6dB.
The L2/R2 path to the BOOST stage is controlled by the LIP2BOOSTVOL[2:0] and the
RIP2BOOSTVOL[2:0] register bits. When L2_2BOOSTVOL[6:4] and R2_2BOOSTVOL[6:4]=000 the
L2/R2 input pin is completely disconnected from the BOOST stage. Settings 001 through to 111
control the gain in 3dB steps from -12dB to +6dB.
w
PD, Rev 4.7, February 2012
35
WM8985
Production Data
REGISTER
ADDRESS
R42 (2Ah)
BIT
8:6
LABEL
OUT4_2ADCVOL
DEFAULT
000
OUT4 to ADC
DESCRIPTION
Controls the OUT4 to ADC input
boost stage:
000 = Path disabled
(disconnected)
001 = -12dB gain
010 = -9dB gain
011 = -6dB gain
100 = -3dB gain
101 = +0dB gain
110 = +3dB gain
111 = +6dB gain
5
OUT4_2LNR
0
OUT4 to L or R ADC input
0 = Right ADC input
1 = Left ADC input
R47 (2Fh)
2:0
AUXL2BOOSTVOL
000
Left channel
Input BOOST
control
Controls the auxiliary amplifier to
the left channel input boost stage:
000 = Path disabled
(disconnected)
001 = -12dB gain
010 = -9dB gain
011 = -6dB gain
100 = -3dB gain
101 = +0dB gain
110 = +3dB gain
111 = +6dB gain
6:4
L2_2BOOSTVOL
000
Controls the L2 pin to the left
channel input boost stage:
000 = Path disabled
(disconnected)
001 = -12dB gain
010 = -9dB gain
011 = -6dB gain
100 = -3dB gain
101 = +0dB gain
110 = +3dB gain
111 = +6dB gain
R48 (30h)
Right channel
Input BOOST
control
2:0
AUXR2BOOSTVOL
000
Controls the auxiliary amplifier to
the right channel input boost
stage:
000 = Path disabled
(disconnected)
001 = -12dB gain
010 = -9dB gain
011 = -6dB gain
100 = -3dB gain
101 = +0dB gain
110 = +3dB gain
111 = +6dB gain
w
PD, Rev 4.7, February 2012
36
WM8985
Production Data
REGISTER
ADDRESS
BIT
LABEL
6:4
DEFAULT
R2_2BOOSTVOL
000
DESCRIPTION
Controls the R2 pin to the right
channel input boost stage:
000 = Path disabled
(disconnected)
001 = -12dB
010 = -9dB gain
011 = -6dB gain
100 = -3dB gain
101 = +0dB gain
110 = +3dB gain
111 = +6dB gain
Table 9 Input BOOST Stage Control
The BOOST stage is enabled under control of the BOOSTEN register bit.
REGISTER
ADDRESS
R2 (02h)
Power
management
2
BIT
LABEL
4
DEFAULT
BOOSTENL
0
DESCRIPTION
Left channel Input BOOST enable
0 = Boost stage OFF
1 = Boost stage ON
5
BOOSTENR
0
Right channel Input BOOST enable
0 = Boost stage OFF
1 = Boost stage ON
Table 10 Input BOOST Enable Control
MICROPHONE BIASING CIRCUIT
The MICBIAS output provides a low noise reference voltage suitable for biasing electret type
microphones and the associated external resistor biasing network. Refer to the Applications
Information section for recommended external components. The MICBIAS voltage can be altered via
the MBVSEL register bit. When MBVSEL=0, MICBIAS=0.9*AVDD1 and when MBVSEL=1,
MICBIAS=0.65*AVDD1. The output can be enabled or disabled using the MICBEN control bit.
REGISTER
ADDRESS
BIT
R1 (01h)
4
LABEL
MICBEN
DEFAULT
0
Power
management 1
DESCRIPTION
Microphone Bias Enable
0 = OFF (high impedance output)
1 = ON
Table 11 Microphone Bias Enable Control
REGISTER
ADDRESS
R44 (2Ch)
BIT
8
LABEL
MBVSEL
DEFAULT
0
Input control
DESCRIPTION
Microphone Bias Voltage Control
0 = 0.9 * AVDD1
1 = 0.65 * AVDD1
Table 12 Microphone Bias Voltage Control
The internal MICBIAS circuitry is shown in Figure 18. Note that the maximum source current
capability for MICBIAS is 3mA. The external biasing resistors therefore must be large enough to limit
the MICBIAS current to 3mA.
w
PD, Rev 4.7, February 2012
37
WM8985
Production Data
Figure 18 Microphone Bias Schematic
ANALOGUE TO DIGITAL CONVERTER (ADC)
The WM8985 uses stereo multi-bit, oversampled sigma-delta ADCs. The use of multi-bit feedback
and high oversampling rates reduces the effects of jitter and high frequency noise. The ADC Full
Scale input level is proportional to AVDD1. With a 3.3V supply voltage, the full scale level is 1.0Vrms.
Any voltage greater than full scale may overload the ADC and cause distortion.
ADC DIGITAL FILTERS
The ADC filters perform true 24 bit signal processing to convert the raw multi-bit oversampled data
from the ADC to the correct sampling frequency to be output on the digital audio interface. The digital
filter path for each ADC channel is illustrated in Figure 19.
Figure 19 ADC Digital Filter Path
The ADCs are enabled by the ADCENL/R register bit.
REGISTER
ADDRESS
R2 (02h)
BIT
0
LABEL
ADCENL
DEFAULT
0
Power
management 2
DESCRIPTION
Enable ADC left channel:
0 = ADC disabled
1 = ADC enabled
1
ADCENR
0
Enable ADC right channel:
0 = ADC disabled
1 = ADC enabled
Table 13 ADC Enable Control
w
PD, Rev 4.7, February 2012
38
WM8985
Production Data
The polarity of the output signal can also be changed under software control using the
ADCLPOL/ADCRPOL register bit. The oversampling rate of the ADC can be adjusted using the
ADCOSR128 register bit. With ADCOSR=0 the oversample rate is 64x which gives lowest power
operation and when ADCOSR=1 the oversample rate is 128x which gives best performance.
REGISTER
ADDRESS
BIT
R14 (0Eh)
0
LABEL
DEFAULT
ADCLPOL
0
ADC Control
DESCRIPTION
ADC left channel polarity adjust:
0 = normal
1 = inverted
1
ADCRPOL
0
ADC right channel polarity adjust:
0 = normal
1 = inverted
3
ADCOSR128
0
ADC oversample rate select:
0 = 64x (lower power)
1 = 128x (best performance)
Table 14 ADC Control
SELECTABLE HIGH PASS FILTER
A selectable high pass filter is provided and enabled as default. To disable this filter set HPFEN=0.
The filter has two modes controlled by HPFAPP. In Audio Mode (HPFAPP=0) the filter is first order,
with a cut-off frequency of 3.7Hz. In Application Mode (HPFAPP=1) the filter is second order, with a
cut-off frequency selectable via the HPFCUT register. The cut-off frequencies when HPFAPP=1 are
shown in Table 16.
REGISTER
ADDRESS
R14 (0Eh)
BIT
6:4
LABEL
HPFCUT
DEFAULT
000
DESCRIPTION
Application mode cut-off frequency
See Table 16 for details.
ADC Control
PLL Output Clock Division Ratio
00 = divide by 1
01 = divide by 2
10 = divide by 3
11 = divide by 4
Note: HPCUT and OPCLKDIV cannot be
set independently
7
HPFAPP
0
Select audio mode or application mode
st
0 = Audio mode (1 order, fc = ~3.7Hz)
nd
1 = Application mode (2 order, fc =
HPFCUT)
8
HPFEN
1
High Pass Filter Enable
0 = disabled
1 = enabled
Table 15 ADC Enable Control
w
PD, Rev 4.7, February 2012
39
WM8985
Production Data
HPFCUT
SR=101/100
SR=011/010
[2:0]
SR=001/000
fs (kHz)
8
11.025
12
16
22.05
24
32
44.1
48
000
82
113
122
82
113
122
82
113
122
001
102
141
153
102
141
153
102
141
153
010
131
180
196
131
180
196
131
180
196
011
163
225
245
163
225
245
163
225
245
100
204
281
306
204
281
306
204
281
306
101
261
360
392
261
360
392
261
360
392
110
327
450
490
327
450
490
327
450
490
111
408
563
612
408
563
612
408
563
612
Table 16 High Pass Filter Cut-off Frequencies (HPFAPP=1)
Note that the High Pass filter values (when HPFAPP=1) are calculated on the assumption that the
SR register bits are set correctly for the actual sample rate as shown in Table 16. Sampling rate (SR)
is enabled by register bits R7[1:3].
Register 14(0Eh) bits [5:4] (HPFCUT) are used to control the high pass filter cut-off in applications
mode and also the PLL output clock division ratio (OPCLKDIV).
w
PD, Rev 4.7, February 2012
40
WM8985
Production Data
PROGRAMMABLE NOTCH FILTER
A programmable notch filter is provided. This filter has a variable centre frequency and bandwidth,
programmable via two coefficients, a0 and a1. These coefficients should be converted to 2’s
complement numbers to determine the register values. A0 and a1 are represented by the register bits
NFA0[13:0] and NFA1[13:0]. Because these coefficient values require four register writes to setup
there is an NFU (Notch Filter Update) flag which should be set only when all four registers are setup.
REGISTER
ADDRESS
R27 (1Bh)
Notch Filter 1
BIT
6:0
7
LABEL
DEFAULT
DESCRIPTION
NFA0[13:7]
0
Notch Filter a0 coefficient, bits [13:7]
NFEN
0
Notch filter enable:
0 = Disabled
1 = Enabled
8
NFU
0
Notch filter update. The notch filter
values used internally only update
when one of the NFU bits is set high.
R28 (1Ch)
6:0
NFA0[6:0]
0
Notch Filter a0 coefficient, bits [6:0]
Notch Filter 2
8
NFU
0
Notch filter update. The notch filter
values used internally only update
when one of the NFU bits is set high.
R29 (1Dh)
6:0
NFA1[13:7]
0
Notch Filter a1 coefficient, bits [13:7]
Notch Filter 3
8
NFU
0
Notch filter update. The notch filter
values used internally only update
when one of the NFU bits is set high.
R30 (1Eh)
Notch Filter 4
0-6
8
NFA1[6:0]
0
Notch Filter a1 coefficient, bits [6:0]
NFU
0
Notch filter update. The notch filter
values used internally only update
when one of the NFU bits is set high.
Table 17 Notch Filter Function
The coefficients are calculated as follows:
a0 
1  tan( w b / 2)
1  tan( w b / 2)
a1  (1  a0 ) cos( w 0 )
Where:
w 0  2fc / fs
w b  2fb / fs
fc = centre frequency in Hz, fb = -3dB bandwidth in Hz, fs = sample frequency in Hz
The coefficients are calculated as follows:
13
NFA0 = -a0 x 2
12
NFA1 = -a1 x 2
These values are then converted to 2’s complement notation to determine the register values.
w
PD, Rev 4.7, February 2012
41
WM8985
Production Data
NOTCH FILTER WORKED EXAMPLE
The following example illustrates how to calculate the a0 and a1 coefficients for a desired centre
frequency and -3dB bandwidth.
Fc = 1000 Hz
fb = 100 Hz
fs = 48000 Hz
w 0  2fc / fs = 2 x (1000 / 48000) = 0.1308996939 rads
w b  2fb / fs = 2 x (100 / 48000) = 0.01308996939 rads
a0 
1  tan( w b / 2)
1  tan(0.0130899693 9 / 2)
= 0.9869949627
=
1  tan( w b / 2)
1  tan(0.0130899693 9 / 2)
a1  (1  a0 ) cos( w 0 ) = (1  0.9869949627 ) cos(0.1308996939 ) = -1.969995945
13
NFA0 = -a0 x 2 = -8085 (rounded to nearest whole number)
12
NFA1 = -a1 x 2 = 8069 (rounded to nearest whole number)
These values are then converted to 2’s complement:
NFA0 = 14’h206B = 14’b10000001101011
NFA1 = 14’h1F85 = 14’b 01111110000101
DIGITAL ADC VOLUME CONTROL
The output of the ADCs can be digitally attenuated over a range from –127dB to 0dB in 0.5dB steps.
The gain for a given eight-bit code X is given by:
0.5  (G-255) dB for 1  G  255;
REGISTER
ADDRESS
R15 (0Fh)
BIT
7:0
Left channel
ADC Digital
Volume
LABEL
MUTE for G = 0
DEFAULT
DESCRIPTION
ADCLVOL
11111111
Left ADC Digital Volume Control
[7:0]
( 0dB )
0000 0000 = Digital Mute
0000 0001 = -127dB
0000 0010 = -126.5dB
… 0.5dB steps up to
1111 1111 = 0dB
R16 (10h)
8
ADCVU
Not
latched
ADC left and ADC right volume do not
update until a 1 is written to ADCVU (in
reg 15 or 16)
7:0
ADCRVOL
11111111
Right ADC Digital Volume Control
[7:0]
( 0dB )
0000 0000 = Digital Mute
Right channel
ADC Digital
Volume
0000 0001 = -127dB
0000 0010 = -126.5dB
... 0.5dB steps up to
1111 1111 = 0dB
8
ADCVU
Not
latched
ADC left and ADC right volume do not
update until a 1 is written to ADCVU (in
reg 15 or 16)
Table 18 ADC Digital Volume Control
w
PD, Rev 4.7, February 2012
42
WM8985
Production Data
INPUT LIMITER / AUTOMATIC LEVEL CONTROL (ALC)
The WM8985 has an automatic PGA gain control circuit, which can function as an input peak limiter
or as an automatic level control (ALC).
The Automatic Level Control (ALC) provides continuous adjustment of the input PGA in response to
the amplitude of the input signal. A digital peak detector monitors the input signal amplitude and
compares it to a register defined threshold level (ALCLVL).
If the signal is below the threshold, the ALC will increase the gain of the PGA at a rate set by
ALCDCY. If the signal is above the threshold, the ALC will reduce the gain of the PGA at a rate set
by ALCATK.
The ALC has two modes selected by the ALCMODE register: normal mode and peak limiter mode.
The ALC/limiter function is enabled by settings the register bits R32[8:7] ALCSEL.
REGISTER
ADDRESS
R32 (20h)
BIT
2:0
ALC Control
1
LABEL
ALCMIN
DEFAULT
000 (-12dB)
[2:0]
DESCRIPTION
Set minimum gain of PGA
000 = -12dB
001 = -6dB
010 = 0dB
011 = +6dB
100 = +12dB
101 = +18dB
110 = +24dB
111 = +30dB
5:3
ALCMAX
[2:0]
111
(+35.25dB)
Set Maximum Gain of PGA
111 = +35.25dB
110 = +29.25dB
101 = +23.25dB
100 = +17.25dB
011 = +11.25dB
010 = +5.25dB
001 = -0.75dB
000 = -6.75dB
8:7
ALCSEL
00
ALC function select
00 = ALC disabled
01 = Right channel ALC enabled
10 = Left channel ALC enabled
11 = Both channels ALC enabled
R33 (21h)
ALC Control
2
3:0
ALCLVL
1011
[3:0]
(-6dB)
ALC target – sets signal level at ADC
input
1111 = -1.5dBFS
1110 = -1.5dBFS
1101 = -3dBFS
1100 = -4.5dBFS
1011 = -6dBFS
1010 = -7.5dBFS
1001 = -9dBFS
1000 = -10.5dBFS
0111 = -12dBFS
0110 = -13.5dBFS
0101 = -15dBFS
0100 = -16.5dBFS
0011 = -18dBFS
0010 = -19.5dBFS
0001 = -21dBFS
0000 = -22.5dBFS
w
PD, Rev 4.7, February 2012
43
WM8985
Production Data
REGISTER
ADDRESS
BIT
7:4
LABEL
DEFAULT
ALCHLD
0000
[3:0]
(0ms)
DESCRIPTION
ALC hold time before gain is
increased.
0000 = 0ms
0001 = 2.67ms
0010 = 5.33ms
0011 = 10.66ms
0100 = 21.32ms
0101 = 42.64ms
0110 = 85.28ms
0111 = 0.17s
1000 = 0.34s
1001 = 0.68s
1010 or higher = 1.36s
R34 (22h)
8
ALCMODE
0
ALC Control
3
Determines the ALC mode of
operation:
0 = ALC mode (Normal Operation)
1 = Limiter mode.
7:4
ALCDCY
0011
Decay (gain ramp-up) time
[3:0]
(13ms/6dB)
(ALCMODE ==0)
Per
step
Per
6dB
90% of
range
0000
410us
3.3ms
24ms
0001
820us
6.6ms
48ms
0010
1.64ms
13.1ms
192ms
… (time doubles with every step)
1010
or
higher
420ms
3.36s
0011
Decay (gain ramp-up) time
(2.9ms/6dB)
(ALCMODE ==1)
Per
step
24.576s
Per
6dB
90% of
range
0000
90.8us
726.4us
5.26ms
0001
181.6us
1.453ms
10.53m
s
0010
363.2us
2.905ms
21.06m
s
… (time doubles with every step)
1010
3:0
93ms
744ms
5.39s
ALCATK
0010
ALC attack (gain ramp-down) time
[3:0]
(832us/6dB)
(ALCMODE == 0)
Per
step
Per
6dB
90% of
range
0000
104us
832us
6ms
0001
208us
1.66ms
12ms
0010
416us
3.32ms
24.1ms
… (time doubles with every step)
1010
or
higher
852ms
6.18s
0010
ALC attack (gain ramp-down) time
(182us/6dB)
(ALCMODE == 1)
0000
w
106ms
Per
step
Per
6dB
90% of
range
22.7us
182.4us
1.31ms
PD, Rev 4.7, February 2012
44
WM8985
Production Data
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
0001
45.4us
363.2us
2.62ms
0010
90.8us
726.4us
5.26ms
… (time doubles with every step)
1010
23.2ms
186ms
1.348s
Table 20 ALC Control Registers
When the ALC is disabled, the input PGA remains at the last controlled value of the ALC. An input
gain update must be made by writing to the INPPGAVOLL/R register bits.
NORMAL MODE
In normal mode, the ALC will attempt to maintain a constant signal level by increasing or decreasing
the gain of the PGA. The following diagram shows an example of this.
Figure 21 ALC Normal Mode Operation
w
PD, Rev 4.7, February 2012
45
WM8985
Production Data
LIMITER MODE
In limiter mode, the ALC will reduce peaks that go above the threshold level, but will not increase the
PGA gain beyond the starting level. The starting level is the PGA gain setting when the ALC is
enabled in limiter mode. If the ALC is started in limiter mode, this is the gain setting of the PGA at
startup. If the ALC is switched into limiter mode after running in ALC mode, the starting gain will be
the gain at switchover. The diagram below shows an example of limiter mode.
Figure 20 ALC Limiter Mode Operation
ATTACK AND DECAY TIMES
The attack and decay times set the update times for the PGA gain. The attack time is the time
constant used when the gain is reducing. The decay time is the time constant used when the gain is
increasing. In limiter mode, the time constants are faster than in ALC mode. The time constants are
shown below in terms of a single gain step, a change of 6dB and a change of 90% of the PGAs gain
range.
Note that, these times will vary slightly depending on the sample rate used (specified by the SR
register).
w
PD, Rev 4.7, February 2012
46
WM8985
Production Data
NORMAL MODE
ALCMODE = 0 (Normal Mode)
ALCATK
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
tATK
104µs
208µs
416µs
832µs
1.66ms
3.33ms
6.66ms
13.3ms
26.6ms
53.2ms
106ms
Attack Time (s)
tATK6dB
tATK90%
832µs
6ms
1.66ms
12ms
3.33ms
24ms
6.66ms
48ms
13.3ms
96ms
26.6ms
192ms
53.2ms
384ms
106ms
767ms
213.2ms
1.53s
426ms
3.07s
852ms
6.13s
ALCMODE = 0 (Normal Mode)
ALCDCY
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
tDCY
410µs
820µs
1.64ms
3.28ms
6.56ms
13.1ms
26.2ms
52.5ms
105ms
210ms
420ms
Decay Time (s)
tDCY6dB
tDCY90%
3.28ms
23.6ms
6.56ms
47.2ms
13.1ms
94.5ms
26.2ms
189ms
52.5ms
378ms
105ms
756ms
210ms
1.51s
420ms
3.02s
840ms
6.05s
1.68s
12.1s
3.36s
24.2s
Table 19 ALC Normal Mode (Attack and Decay times)
w
PD, Rev 4.7, February 2012
47
WM8985
Production Data
LIMITER MODE
ALCMODE = 1 (Limiter Mode)
ALCATK
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
tATKLIM
22.7µs
45.4µS
90.8µS
182µS
363µS
726µS
1.45ms
2.9ms
5.81ms
11.6ms
23.2ms
Attack Time (s)
tATKLIM6dB
tATKLIM90%
182µs
1.31ms
363µs
2.62ms
726µs
5.23ms
1.45ms
10.5ms
2.91ms
20.9ms
5.81ms
41.8ms
11.6ms
83.7ms
23.2ms
167ms
46.5ms
335ms
93ms
669ms
186ms
1.34s
ALCMODE = 1 (Limiter Mode)
ALCDCY
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
tDCYLIM
90.8µs
182µS
363µS
726µS
1.45ms
2.91ms
5.81ms
11.6ms
23.2ms
46.5ms
93ms
Attack Time (s)
tDCYLIM6dB
tDCYLIM90%
726µs
5.23ms
1.45ms
10.5ms
2.91ms
20.9ms
5.81ms
41.8ms
11.6ms
83.7ms
23.2ms
167ms
46.5ms
335ms
93ms
669ms
186ms
1.34s
372ms
2.68s
744ms
5.36s
Table 20 ALC Limiter Mode (Attack and Decay times)
w
PD, Rev 4.7, February 2012
48
WM8985
Production Data
MINIMUM AND MAXIMUM GAIN
The ALCMIN and ALCMAX register bits set the minimum/maximum gain value that the PGA can be
set to whilst under the control of the ALC. This has no effect on the PGA when ALC is not enabled.
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R32
5:3
ALCMAX
111
Set Maximum Gain of PGA
ALC Control
1
2:0
ALCMIN
000
Set minimum gain of PGA
Table 23 ALC Max/Min Gain
In normal mode, ALCMAX sets the maximum boost which can be applied to the signal. In limiter
mode, ALCMAX will normally have no effect (assuming the starting gain value is less than the
maximum gain specified by ALCMAX) because the maximum gain is set at the starting gain level.
ALCMIN sets the minimum gain value which can be applied to the signal.
Figure 23 ALC Min/Max Gain
ALCMAX
111
110
101
100
011
010
001
000
Maximum Gain (dB)
35.25
29.25
23.25
17.25
11.25
5.25
-0.75
-6.75
Table 24 ALC Max Gain Values
w
PD, Rev 4.7, February 2012
49
WM8985
Production Data
ALCMIN
000
001
010
011
100
101
110
111
Minimum Gain (dB)
-12
-6
0
6
12
18
24
30
Table 25 ALC Min Gain Values
Note that if the ALC gain setting strays outside the ALC operating range, either by starting the ALC
outside of the range or changing the ALCMAX or ALCMIN settings during operation, the ALC will
immediately adjust the gain to return to the ALC operating range. It is recommended that the ALC
starting gain is set between the ALCMAX and ALCMIN limits.
ALC HOLD TIME (NORMAL MODE ONLY)
In Normal mode, the ALC has an adjustable hold time which sets a time delay before the ALC begins
it’s decay phase (gain increasing). The hold time is set by the ALCHLD register.
REGISTER
ADDRESS
R33
BIT
7:4
LABEL
ALCHLD
DEFAULT
0000
DESCRIPTION
ALC hold time before gain is increased.
ALC Control
2
Table 26 ALC Hold Time
If the hold time is exceeded this indicates that the signal has reached a new average level and the
ALC will increase the gain to adjust for that new average level. If the signal goes above the threshold
during the hold period, the hold phase is abandoned and the ALC returns to normal operation.
w
PD, Rev 4.7, February 2012
50
Production Data
WM8985
Figure 24 ALCLVL
w
PD, Rev 4.7, February 2012
51
WM8985
Production Data
Figure 25 ALC Hold Time
ALCHLD
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
tHOLD (s)
0
2.67ms
5.34ms
10.7ms
21.4ms
42.7ms
85.4ms
171ms
342ms
684ms
1.37s
Table 27 ALC Hold Time Values
w
PD, Rev 4.7, February 2012
52
WM8985
Production Data
PEAK LIMITER
To prevent clipping when a large signal occurs just after a period of quiet, the ALC circuit includes a
limiter function. 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 ALCATK = 0000), until the signal level falls below
87.5% of full scale. This function is automatically enabled whenever the ALC is enabled.
Note: If ALCATK = 0000, then the limiter makes no difference to the operation of the ALC. It is
designed to prevent clipping when long attack times are used.
NOISE GATE (NORMAL MODE 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 WM8985 has a noise gate function that
prevents noise pumping by comparing the signal level at the input pins against a noise gate
threshold, NGTH. The noise gate cuts in when:
Signal level at ADC [dBFS] < NGTH [dBFS] + PGA gain [dB] + Mic Boost gain [dB]
This is equivalent to:
Signal level at input pin [dBFS] < NGTH [dBFS]
The PGA gain is then held constant (preventing it from ramping up as it normally would 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. The noise gate only operates in conjunction with the ALC and cannot be used
in limiter mode.
REGISTER
ADDRESS
R35 (23h)
BIT
2:0
LABEL
NGTH
DEFAULT
000
DESCRIPTION
Noise gate threshold:
ALC Noise Gate
000 = -39dB
Control
001 = -45dB
010 = -51db
011 = -57dB
100 = -63dB
101 = -70dB
110 = -76dB
111 = -81dB
3
NGATEN
0
Noise gate function enable
1 = enable
0 = disable
Table 28 ALC Noise Gate Control
The diagrams below show the response of the system to the same signal with and without noise
gate.
w
PD, Rev 4.7, February 2012
53
WM8985
Production Data
Figure 21 ALC Operation Above Noise Gate Threshold
w
PD, Rev 4.7, February 2012
54
WM8985
Production Data
Figure 22 Noise Gate Operation
OUTPUT SIGNAL PATH
The WM8985 output signal paths consist of digital application filters, up-sampling filters, stereo Hi-Fi
DACs, analogue mixers, stereo headphone and stereo line/mono/midrail output drivers. The digital
filters and DAC are enabled by register bits DACENL and DACENR. The mixers and output drivers
can be separately enabled by individual control bits (see Analogue Outputs). Thus it is possible to
utilise the analogue mixing and amplification provided by the WM8985, irrespective of whether the
DACs are running or not.
The WM8985 DACs receive digital input data on the DACDAT pin. The digital filter block processes
the data to provide the following functions:

Digital volume control

Graphic equaliser

A digital peak limiter

Sigma-Delta Modulation
High performance sigma-delta audio DAC converts the digital data into an analogue signal.
w
PD, Rev 4.7, February 2012
55
WM8985
Production Data
Figure 23 DAC Digital Filter Path
The analogue outputs from the DACs can then be mixed with the aux analogue inputs and the ADC
analogue inputs. The mix is fed to the output drivers for headphone (LOUT1/ROUT1,
LOUT2/ROUT2) or line (OUT3/OUT4). OUT3 and OUT4 have additional mixers which allow them to
output different signals to the line outputs or back into the record path.
DIGITAL PLAYBACK (DAC) PATH
Digital data is passed to the WM8985 via the flexible audio interface and is then passed through a
variety of advanced digital filters as shown in Figure 23 to the hi-fi DACs. The DACs are enabled by
the DACENL/R register bits.
REGISTER
ADDRESS
R3 (03h)
BIT
0
LABEL
DACENL
DEFAULT
0
Power
Management 3
DESCRIPTION
Left channel DAC enable
0 = DAC disabled
1 = DAC enabled
1
DACENR
0
Right channel DAC enable
0 = DAC disabled
1 = DAC enabled
Table 21 DAC Enable Control
The WM8985 also has a Soft Mute function, which when enabled, gradually attenuates the volume of
the digital signal to zero. When disabled, the gain will ramp back up to the digital gain setting. This
function is enabled by default. To play back an audio signal, it must first be disabled by setting the
SOFTMUTE bit to zero.
REGISTER
ADDRESS
R10 (0Ah)
BIT
0
LABEL
DACPOL
DEFAULT
0
DAC Control
DESCRIPTION
Left DAC output polarity:
0 = non-inverted
1 = inverted (180 degrees phase shift)
1
DACRPOL
0
Right DAC output polarity:
0 = non-inverted
1 = inverted (180 degrees phase shift)
2
AMUTE
0
Automute enable
0 = Amute disabled
1 = Amute enabled
3
DACOSR128
0
DAC oversampling rate:
0 = 64x (lowest power)
1 = 128x (best performance)
6
SOFTMUTE
0
Softmute enable:
0 = Enabled
1 = Disabled
Table 22 DAC Control Register
w
PD, Rev 4.7, February 2012
56
WM8985
Production Data
The digital audio data is converted to oversampled bit streams in the on-chip, true 24-bit digital
interpolation filters. The bitstream data enters the multi-bit, sigma-delta DACs, which convert it to a
high quality analogue audio signal. The multi-bit DAC architecture reduces high frequency noise and
sensitivity to clock jitter. It also uses a Dynamic Element Matching technique for high linearity and low
distortion.
The DAC output phase defaults to non-inverted. Setting DACLPOL will invert the DAC output phase
on the left channel and DACRPOL inverts the phase on the right channel.
AUTO-MUTE
The DAC has an auto-mute function which applies an analogue mute when 1024 consecutive zeros
are detected. The mute is released as soon as a non-zero sample is detected. Auto-mute can be
disabled using the AMUTE control bit.
DIGITAL HI-FI DAC VOLUME (GAIN) CONTROL
The signal volume from each hi-fi DAC can be controlled digitally. The gain range is –127dB to 0dB
in 0.5dB steps. The level of attenuation for an eight-bit code X is given by:
0.5  (X-255) dB for 1  X  255;
REGISTER
ADDRESS
R11 (0Bh)
BIT
7:0
Left DAC
Digital Volume
LABEL
MUTE for X = 0
DEFAULT
DESCRIPTION
DACLVOL
11111111
Left DAC Digital Volume Control
[7:0]
( 0dB )
0000 0000 = Digital Mute
0000 0001 = -127dB
0000 0010 = -126.5dB
... 0.5dB steps up to
1111 1111 = 0dB
R12 (0Ch)
8
DACVU
Not
latched
DAC left and DAC right volume do
not update until a 1 is written to
DACVU (in reg 11 or 12)
7:0
DACRVOL
11111111
Right DAC Digital Volume Control
[7:0]
( 0dB )
0000 0000 = Digital Mute
Right DAC
Digital Volume
0000 0001 = -127dB
0000 0010 = -126.5dB
... 0.5dB steps up to
1111 1111 = 0dB
8
DACVU
Not
latched
DAC left and DAC right volume do
not update until a 1 is written to
DACVU (in reg 11 or 12)
Table 23 DAC Digital Volume Control
Note: An additional gain of up to 12dB can be added using the gain block embedded in the
digital peak limiter circuit (see DAC OUTPUT LIMITER section).
5-BAND EQUALISER
A 5-band graphic equaliser function which can be used to change the output frequency levels to suit
the environment. This can be applied to the ADC or DAC path and is described in the 5-BAND
EQUALISER section for further details on this feature.
3-D ENHANCEMENT
The WM8985 has an advanced digital 3-D enhancement feature which can be used to vary the
perceived stereo separation of the left and right channels. Like the 5-band equaliser this feature can
be applied to either the ADC record path or the DAC playback path but not both simultaneously.
Refer to the 3-D STEREO ENHANCEMENT section for further details on this feature.
DAC DIGITAL OUTPUT LIMITER
The WM8985 has a digital output limiter function. The operation of this is shown in Figure 24. In this
diagram the upper graph shows the envelope of the input/output signals and the lower graph shows
the gain characteristic.
w
PD, Rev 4.7, February 2012
57
WM8985
Production Data
Figure 24 DAC Digital Limiter Operation
The limiter has a programmable upper threshold which is close to 0dB. Referring to Figure 24, in
normal operation (LIMBOOST=000 => limit only) signals below this threshold are unaffected by the
limiter. Signals above the upper threshold are attenuated at a specific attack rate (set by the LIMATK
register bits) until the signal falls below the threshold. The limiter also has a lower threshold 1dB
below the upper threshold. When the signal falls below the lower threshold the signal is amplified at
a specific decay rate (controlled by LIMDCY register bits) until a gain of 0dB is reached. Both
threshold levels are controlled by the LIMLVL register bits. The upper threshold is 0.5dB above the
value programmed by LIMLVL and the lower threshold is 0.5dB below the LIMLVL value.
VOLUME BOOST
The limiter has programmable upper gain which boosts signals below the threshold to compress the
dynamic range of the signal and increase its perceived loudness. This operates as an ALC function
with limited boost capability. The volume boost is from 0dB to +12dB in 1dB steps, controlled by the
LIMBOOST register bits.
The output limiter volume boost can also be used as a stand alone digital gain boost when the limiter
is disabled.
w
PD, Rev 4.7, February 2012
58
WM8985
Production Data
REGISTER
ADDRESS
R24 (18h)
BIT
3:0
LABEL
LIMATK
DEFAULT
0010
DAC digital
limiter control
1
DESCRIPTION
Limiter Attack time (per 6dB gain
change) for 44.1kHz sampling. Note
that these are proportionally related to
sample rate.
0000 = 94us
0001 = 188s
0010 = 375us
0011 = 750us
0100 = 1.5ms
0101 = 3ms
0110 = 6ms
0111 = 12ms
1000 = 24ms
1001 = 48ms
1010 = 96ms
1011 to 1111 = 192ms
7:4
LIMDCY
0011
Limiter Decay time (per 6dB gain
change) for 44.1kHz sampling. Note
that these are proportionally related to
sample rate:
0000 = 750us
0001 = 1.5ms
0010 = 3ms
0011 = 6ms
0100 = 12ms
0101 = 24ms
0110 = 48ms
0111 = 96ms
1000 = 192ms
1001 = 384ms
1010 = 768ms
1011 to 1111 = 1.536s
R25 (19h)
DAC digital
limiter control
2
w
8
LIMEN
0
Enable the DAC digital limiter:
0=disabled
1=enabled
3:0
LIMBOOST
0000
Limiter volume boost (can be used as a
stand alone volume boost when
LIMEN=0):
0000 = 0dB
0001 = +1dB
0010 = +2dB
0011 = +3dB
0100 = +4dB
0101 = +5dB
0110 = +6dB
0111 = +7dB
1000 = +8dB
1001 = +9dB
1010 = +10dB
1011 = +11dB
1100 = +12dB
1101 to 1111 = reserved
PD, Rev 4.7, February 2012
59
WM8985
Production Data
REGISTER
ADDRESS
BIT
6:4
LABEL
LIMLVL
DEFAULT
000
DESCRIPTION
Programmable signal threshold level
(determines level at which the limiter
starts to operate)
000 = -1dB
001 = -2dB
010 = -3dB
011 = -4dB
100 = -5dB
101 to 111 = -6dB
Table 24 DAC Digital Limiter Control
5-BAND GRAPHIC EQUALISER
A 5-band graphic equaliser is provided, which can be applied to the ADC or DAC path, together with
3D enhancement, under control of the EQ3DMODE register bit.
REGISTER
ADDRESS
R18 (12h)
BIT
8
LABEL
EQ3DMODE
DEFAULT
1
EQ Control 1
DESCRIPTION
0 = Equaliser and 3D Enhancement
applied to ADC path
1 = Equaliser and 3D Enhancement
applied to DAC path
Table 25 EQ and 3D Enhancement DAC or ADC Path Select
Note: The ADCs and DACs must be disabled before changing the EQ3DMODE bit.
The equaliser consists of low and high frequency shelving filters (Band 1 and 5) and three peak filters
for the centre bands. Each has adjustable cut-off or centre frequency, and selectable boost (+/- 12dB
in 1dB steps). The peak filters have selectable bandwidth.
To enable the use of the 5-band equaliser the device must be in 128fs mode by setting M128ENB to
1 in register R7 bit 8. Refer to the Low Power section under Power Management below for more
details.
REGISTER
ADDRESS
R18 (12h)
BIT
4:0
LABEL
EQ1G
EQ Band 1
Control
6:5
EQ1C
DEFAULT
01100
DESCRIPTION
(0dB)
Band 1 Gain Control. See Table 31 for
details.
01
Band 1 Cut-off Frequency:
00 = 80Hz
01 = 105Hz
10 = 135Hz
11 = 175Hz
Table 26 EQ Band 1 Control
w
PD, Rev 4.7, February 2012
60
WM8985
Production Data
REGISTER
ADDRESS
R19 (13h)
BIT
4:0
LABEL
EQ2G
EQ Band 2
Control
6:5
EQ2C
DEFAULT
01100
DESCRIPTION
(0dB)
Band 2 Gain Control. See Table 31 for
details.
01
Band 2 Centre Frequency:
00 = 230Hz
01 = 300Hz
10 = 385Hz
8
EQ2BW
0
11 = 500Hz
Band 2 Bandwidth Control
0 = narrow bandwidth
1 = wide bandwidth
Table 27 EQ Band 2 Control
REGISTER
ADDRESS
R20 (14h)
BIT
4:0
LABEL
EQ3G
EQ Band 3
Control
6:5
EQ3C
DEFAULT
01100
DESCRIPTION
(0dB)
Band 3 Gain Control. See Table 31 for
details.
01
Band 3 Centre Frequency:
00 = 650Hz
01 = 850Hz
8
EQ3BW
0
10 = 1.1kHz
11 = 1.4kHz
Band 3 Bandwidth Control
0 = narrow bandwidth
1 = wide bandwidth
Table 28 EQ Band 3 Control
REGISTER
ADDRESS
R21 (15h)
BIT
4:0
LABEL
EQ4G
EQ Band 4
Control
6:5
8
EQ4C
EQ4BW
DEFAULT
01100
DESCRIPTION
(0dB)
Band 4 Gain Control. See Table 31 for
details
01
Band 4 Centre Frequency:
0
00 = 1.8kHz
01 = 2.4kHz
10 = 3.2kHz
11 = 4.1kHz
Band 4 Bandwidth Control
0 = narrow bandwidth
1 = wide bandwidth
Table 29 EQ Band 4 Control
w
PD, Rev 4.7, February 2012
61
WM8985
Production Data
REGISTER
ADDRESS
R22 (16h)
BIT
4:0
LABEL
EQ5G
EQ Band 5
Gain Control
6:5
EQ5C
DEFAULT
01100
DESCRIPTION
(0dB)
Band 5 Gain Control. See Table 31 for
details.
01
Band 5 Cut-off Frequency:
00 = 5.3kHz
01 = 6.9kHz
10 = 9kHz
11 = 11.7kHz
Table 30 EQ Band 5 Control
GAIN REGISTER
GAIN
00000
+12dB
00001
+11dB
00010
+10dB
…. (1dB steps)
01100
0dB
01101
-1dB
11000
-12dB
11001 to 11111
Reserved
Table 31 Gain Register Table
See also Figure 47 to Figure 64 for equaliser and high pass filter responses.
3D STEREO ENHANCEMENT
The WM8985 has a digital 3D enhancement option to increase the perceived separation between the
left and right channels. Selection of 3D for record or playback is controlled by register bit
EQ3DMODE. Switching this bit from record to playback or from playback to record may only be done
when both ADCs and both DACs are disabled.
To enable the 3D Stereo Enhancement in the ADC path the device must be in 128fs mode by setting
M128ENB to 1 in register R7 bit 8. Refer to the Low Power section under Power Management below
for more details.
The DEPTH3D setting controls the degree of stereo expansion.
w
PD, Rev 4.7, February 2012
62
WM8985
Production Data
REGISTER
ADDRESS
R41 (29h)
BIT
3:0
LABEL
DEPTH3D
DEFAULT
0000
3D Control
DESCRIPTION
Stereo depth
0000 = Disabled
0001 = 6.67%
0010 = 13.3%
0011 = 20%
0100 = 26.7%
0101 = 33.3%
0110 = 40%
0111 = 46.6%
1000 = 53.3%
1001 = 60%
1010 = 66.7%
1011 = 73.3%
1100 = 80%
1101 = 86.7%
1110 = 93.3%
1111 = 100% (maximum 3D effect)
Table 32 3D Stereo Enhancement Function
Note: When 3D enhancement is used, it may be necessary to attenuate the signal by 6dB to avoid
limiting.
ANALOGUE OUTPUTS
The WM8985 has three sets of stereo analogue outputs. These are:



LOUT1 and ROUT1 which are normally used to drive a headphone load.
LOUT2 and ROUT2 – which can be used as class D or class AB headphone
drivers.
OUT3 and OUT4 – can be configured as a stereo line out (OUT3 is left output and
OUT4 is right output) or a differential output. OUT4 can also be used to provide a
mono mix of left and right channels.
The outputs LOUT2 and ROUT2 are powered from AVDD2 and are capable of driving a 1V rms
signal (AVDD1/3.3).
LOUT1, ROUT1, OUT3 and OUT4 are powered from AVDD1
LOUT1, ROUT1, LOUT2 and ROUT2 have individual analogue volume PGAs with -57dB to +6dB
gain ranges.
There are four output mixers in the output signal path, the left and right channel mixers which control
the signals to headphone (and optionally the line outputs) and also dedicated OUT3 and OUT4
mixers.
w
PD, Rev 4.7, February 2012
63
WM8985
Production Data
LEFT AND RIGHT OUTPUT CHANNEL MIXERS
The left and right output channel mixers are shown in Figure 25. These mixers allow the AUX inputs,
the ADC bypass and the DAC left and right channels to be combined as desired. This allows a mono
mix of the DAC channels to be performed as well as mixing in external line-in from the AUX or
speech from the input bypass path.
The AUX and bypass inputs have individual volume control from -15dB to +6dB and the DAC volume
can be adjusted in the digital domain if required. The output of these mixers is connected to both the
headphone (LOUT1 and ROUT1) and class D headphone (LOUT2 and ROUT2) and can optionally
be connected to the OUT3 and OUT4 mixers.
Figure 25 Left/Right Output Channel Mixers
w
PD, Rev 4.7, February 2012
64
WM8985
Production Data
REGISTER
ADDRESS
R43 (2Bh)
BIT
8
LABEL
BYPL2RMIX
DEFAULT
0
Output mixer
control
DESCRIPTION
Left bypass path (from the Left
channel input PGA stage) to right
output mixer
0 = not selected
1 = selected
R43 (2Bh)
7
BYPR2LMIX
0
Output mixer
control
Right bypass path (from the right
channel input PGA stage) to Left
output mixer
0 = not selected
1 = selected
R49 (31h)
5
DACR2LMIX
0
Output mixer
control
Right DAC output to left output mixer
0 = not selected
1 = selected
6
DACL2RMIX
0
Left DAC output to right output mixer
0 = not selected
1 = selected
R50 (32h)
Left channel
output mixer
control
0
DACL2LMIX
1
Left DAC output to left output mixer
0 = not selected
1 = selected
1
BYPL2LMIX
0
Left bypass path (from the left
channel input PGA stage) to left
output mixer
0 = not selected
1 = selected
4:2
BYPLMIXVOL
000
Left bypass volume control to output
channel mixer:
000 = -15dB
001 = -12dB
010 = -9dB
011 = -6dB
100 = -3dB
101 = 0dB
110 = +3dB
111 = +6dB
5
AUXL2LMIX
0
Left Auxiliary input to left channel
output mixer:
0 = not selected
1 = selected
8:6
AUXLMIXVOL
000
Aux left channel input to left mixer
volume control:
000 = -15dB
001 = -12dB
010 = -9dB
011 = -6dB
100 = -3dB
101 = 0dB
110 = +3dB
111 = +6dB
w
PD, Rev 4.7, February 2012
65
WM8985
Production Data
R51 (33h)
0
DACR2RMIX
1
Right channel
output mixer
control
Right DAC output to right output
mixer
0 = not selected
1 = selected
1
BYPR2RMIX
0
Right bypass path (from the right
channel input PGA stage) to right
output mixer
0 = not selected
1 = selected
4:2
BYPRMIXVOL
000
Right bypass volume control to
output channel mixer:
000 = -15dB
001 = -12dB
010 = -9dB
011 = -6dB
100 = -3dB
101 = 0dB
110 = +3dB
111 = +6dB
5
AUXR2RMIX
0
Right Auxiliary input to right channel
output mixer:
0 = not selected
1 = selected
8:6
AUXRMIXVOL
000
Aux right channel input to right mixer
volume control:
000 = -15dB
001 = -12dB
010 = -9dB
011 = -6dB
100 = -3dB
101 = 0dB
110 = +3dB
111 = +6dB
R3 (03h)
Power
management
3
2
LMIXEN
0
Left output channel mixer enable:
0 = disabled
1= enabled
3
RMIXEN
0
Right output channel mixer enable:
0 = disabled
1 = enabled
Table 33 Left and Right Output Mixer Control
HEADPHONE OUTPUTS (LOUT1 AND ROUT1)
The headphone outputs LOUT1 and ROUT1 can drive a 16 or 32 headphone load, either through
DC blocking capacitors, or DC-coupled to a buffered midrail reference (LOUT2 or ROUT2), saving a
capacitor (capless mode). When using capless mode AVDD1 and AVDD2 should use the same
supply to maximise supply rejection. OUT3 and OUT4 should not be used as a buffered midrail
reference in capless mode.
w
PD, Rev 4.7, February 2012
66
WM8985
Production Data
Headphone Output using DC Blocking Capacitors
DC Coupled Headphone Output
Figure 26 Recommended Headphone Output Configurations
When DC blocking capacitors are used, their capacitance and the load resistance together determine
the lower cut-off frequency of the output signal, fc. Increasing the capacitance lowers fc, improving the
bass response. Smaller capacitance values will diminish the bass response. Assuming a 16 load
and C1, C2 = 220F:
fc = 1 / 2 RLC1 = 1 / (2 x 16 x 220F) = 45 Hz
In the DC coupled configuration, the headphone pseudo-ground is connected to the buffered midrail
reference pin (LOUT2 or ROUT2). The L/ROUT2 pins can be configured as a DC output driver by
setting the LOUT2MUTE and ROUT2MUTE register bits. The DC voltage on VMID in this
configuration is equal to the DC offset on the LOUT1 and ROUT1 pins therefore no DC blocking
capacitors are required. This saves space and material cost in portable applications.
It is not recommended to use DC-coupling to line inputs of another device. Although the built-in short
circuit protection on the headphone outputs would be tolerant of shorts to ground, such a connection
could be noisy, and may not function properly if the other device is grounded. DC-coupled
configurations should only be used with headphones.
w
PD, Rev 4.7, February 2012
67
WM8985
Production Data
REGISTER
ADDRESS
R52 (34h)
BIT
5:0
LABEL
LOUT1VOL
LOUT1
DEFAULT
111001
(0dB)
Volume
control
DESCRIPTION
Left headphone output volume:
(1dB steps)
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
6
LOUT1MUTE
0
Left headphone output mute:
0 = Normal operation
1 = Mute
7
LOUT1ZC
0
Headphone volume zero cross
enable:
1 = Change gain on zero cross only
0 = Change gain immediately
R53
8
HPVU
5:0
ROUT1VOL
ROUT1
Volume
control
Not latched
111001
(0dB)
LOUT1 and ROUT1 volumes do not
update until a 1 is written to HPVU
(in reg 52 or 53)
Right headphone output volume:
(1dB steps)
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
6
ROUT1MUTE
0
Right headphone output mute:
0 = Normal operation
1 = Mute
7
ROUT1ZC
0
Headphone volume zero cross
enable:
1 = Change gain on zero cross only
0 = Change gain immediately
8
HPVU
Not latched
LOUT1 and ROUT1 volumes do not
update until a 1 is written to HPVU
(in reg 52 or 53)
Table 34 OUT1 Volume Control
w
PD, Rev 4.7, February 2012
68
WM8985
Production Data
CLASS D / CLASS AB HEADPHONE OUTPUTS (LOUT2 AND ROUT2)
The outputs LOUT2 and ROUT2 are designed to drive two headphone loads of 16 or 32 or line
outputs (See Headphone Output and Line Output sections, respectively). Each output has an
individual volume control PGA, a mute and an enable control bit as shown in Figure 27. LOUT2 and
ROUT2 output the left and right channel mixer outputs respectively.
REGISTER
ADDRESS
R7 (07h)
BIT
7:4
LABEL
DCLKDIV
DEFAULT
1000
DESCRIPTION
Controls clock division from
SYSCLK to generate suitable class
D clock.
Recommended class D clock
frequency = 1.4MHz.
0000 = divide by 1
0010 = divide by 2
0011 = divide by 3
0100 = divide by 4
0101 = divide by 5.5
0110 = divide by 6
1000 = divide by 8
1001 = divide by 12
1010 = divide by 16
R23 (17h)
8
CLASSDEN
0
Enable signal for class D mode on
LOUT2 and ROUT2
0 = Class AB mode
1 = Class D mode
Table 35 Class D Control Registers
When driving headphones using class D outputs it is necessary to use appropriate filtering, placed
close to the device, to minimise EMI emissions from the headphone cable (Refer to "Applications
Information" for more information). This filtering does not prevent class AB mode operation.
Figure 27 LOUT2 and ROUT2 Class D Headphone Configuration
w
PD, Rev 4.7, February 2012
69
WM8985
Production Data
Figure 28 LOUT2 and ROUT2 Class AB Headphone Configuration
The output configurations shown in figures 29 and 30 are both suitable for class AB operation.
The signal output on LOUT2/ROUT2 comes from the Left/Right Mixer circuits and can be any
combination of the DAC output, the bypass path (output of the input boost stage) and the AUX input.
The LOUT2/ROUT2 volume is controlled by the LOUT2VOL/ ROUT2VOL register bits. Gains over
0dB may cause clipping if the input signal is too high. The LOUT2MUTE/ ROUT2MUTE register bits
cause these outputs to be muted (the output DC level is driven out). The output pins remain at the
same DC level, so that no click noise is produced when muting or un-muting.
w
PD, Rev 4.7, February 2012
70
WM8985
Production Data
REGISTER
ADDRESS
R54 (36h)
BIT
5:0
LABEL
DEFAULT
LOUT2VOL
111001
LOUT2
Volume
control
DESCRIPTION
Left output volume:
(1dB steps)
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
6
LOUT2MUTE
0
Left output mute:
0 = Normal operation
1 = Mute
7
LOUT2ZC
0
LOUT2 volume zero cross enable:
1 = Change gain on zero cross only
0 = Change gain immediately
R55 (37h)
8
OUT2VU
5:0
ROUT2VOL
Not latched
111001
ROUT2
Volume
control
LOUT2 and ROUT2 volumes do not
update until a 1 is written to SPKVU
(in reg 54 or 55)
Right output volume:
(1dB steps)
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
6
ROUT2MUTE
0
Right output mute:
0 = Normal operation
1 = Mute
7
ROUT2ZC
0
ROUT2 volume zero cross enable:
1 = Change gain on zero cross only
0 = Change gain immediately
8
OUT2VU
Not latched
LOUT2 and ROUT2 volumes do not
update until a 1 is written to SPKVU
(in reg 54 or 55)
Table 36 OUT2 Volume Control
ZERO CROSS TIMEOUT
A zero-cross timeout function is provided so that if zero cross is enabled on the input or output PGAs
the gain will automatically update after a timeout period if a zero cross has not occurred. This is
enabled by setting SLOWCLKEN. The timeout period is dependent on the clock input to the digital
21
and is equal to 2 * SYSCLK period.
REGISTER
ADDRESS
R7 (07h)
BIT
0
LABEL
SLOWCLKEN
Additional
Control
DEFAULT
0
DESCRIPTION
Slow clock enable
0 = slow clock disabled
1 = slow clock enabled
Table 37 Timeout Clock Enable Control
Note: SLOWCLKEN is also used for the jack insert detect debounce circuit
w
PD, Rev 4.7, February 2012
71
WM8985
Production Data
OUT3/OUT4 MIXERS AND OUTPUT STAGES
The OUT3/OUT4 pins provide an additional stereo line output, a mono output, or a differential output.
There is a dedicated analogue mixer for OUT3 and one for OUT4 as shown in Figure 29.
The OUT3 and OUT4 output stages are powered from AVDD1 and AGND1.
Figure 29 OUT3 and OUT4 Mixers
OUT3 can provide a left line output, or a mono mix line output.
OUT4 can provide a right line output, or a mono mix line output.
A 6dB attenuation function is provided for OUT4, to prevent clipping during mixing of left and right
signals. This function is enabled by the OUT4ATTN register bit.
w
PD, Rev 4.7, February 2012
72
WM8985
Production Data
REGISTER
ADDRESS
R56 (38h)
OUT3 mixer
control
BIT
6
LABEL
OUT3MUTE
DEFAULT
0
DESCRIPTION
0 = Output stage outputs OUT3 mixer
1 = Output stage muted
3
OUT4_2OUT3
0
OUT4 mixer output to OUT3
0 = disabled
1 = enabled
2
BYPL2OUT3
0
Left ADC input to OUT3
0 = disabled
1 = enabled
1
LMIX2OUT3
0
Left DAC mixer to OUT3
0 = disabled
1 = enabled
0
LDAC2OUT3
1
Left DAC output to OUT3
0 = disabled
1 = enabled
R57 (39h)
7
OUT3_2OUT4
0
OUT4 mixer
control
OUT3 mixer output to OUT4
0 = disabled
1 = enabled
6
OUT4MUTE
0
0 = Output stage outputs OUT4 mixer
1 = Output stage muted
5
OUT4ATTN
0
0 = OUT4 normal output
1 = OUT4 attenuated by 6dB
4
LMIX2OUT4
0
Left DAC mixer to OUT4
0 = disabled
1 = enabled
3
LDAC2OUT4
0
Left DAC to OUT4
0 = disabled
1 = enabled
2
BYPR2OUT4
0
Right ADC input to OUT4
0 = disabled
1 = enabled
1
RMIX2OUT4
0
Right DAC mixer to OUT4
0 = disabled
1 = enabled
0
RDAC2OUT4
1
Right DAC output to OUT4
0 = disabled
1 = enabled
Table 38 OUT3/OUT4 Mixer Registers
w
PD, Rev 4.7, February 2012
73
WM8985
Production Data
ENABLING THE OUTPUTS
Each analogue output of the WM8985 can be independently enabled or disabled. The analogue
mixer associated with each output has a separate enable bit. All outputs are disabled by default. To
save power, unused parts of the WM8985 should remain disabled.
Outputs can be enabled at any time, but it is not recommended to do so when BUFIO is disabled
(BUFIOEN=0), as this may cause pop noise (see “Power Management” and “Applications
Information” sections).
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R1 (01h)
2
BUFIOEN
0
Unused input/output bias buffer enable
Power
Management
1
6
OUT3MIXEN
0
OUT3 mixer enable
7
OUT4MIXEN
0
OUT4 mixer enable
R2 (02h)
8
ROUT1EN
0
ROUT1 output enable
Power
Management
2
7
LOUT1EN
0
LOUT1 output enable
6
SLEEP
0
0 = Normal device operation
R3 (03h)
2
Power
Management
3
1 = Supply current reduced in device
standby mode when clock supplied (see
note)
LMIXEN
0
Left mixer enable
3
RMIXEN
0
Right mixer enable
5
LOUT2EN
0
LOUT2 output enable
6
ROUT2EN
0
ROUT2 output enable
7
OUT3EN
0
OUT3 enable
8
OUT4EN
0
OUT4 enable
Note: All “Enable” bits are 1 = ON, 0 = OFF
Table 39 Output Stages Power Management Control
Note: The SLEEP bit R2[6] should only be used when the device is already Standby mode. The
SLEEP bit prevents the MCLK from propagating round the device when the external MCLK signal
cannot be removed.
THERMAL SHUTDOWN
To protect the WM8985 from becoming too hot, a thermal sensor has been built in. If the device
junction temperature reaches approximately 125C and the TSDEN and TSOPCTRL bit are set, then
all outputs will be disabled to avoid further increase of the chip temperature.
Additionally, when the device is too hot and TSDEN is set, then the WM8985 de-asserts GPIO bit 11,
a virtual GPIO that can be set up to generate an interrupt to the CPU (see “GPIO and Interrupt
Control” section).
REGISTER
ADDRESS
R49 (31h)
BIT
1
LABEL
TSDEN
DEFAULT
0
Output Control
DESCRIPTION
Thermal Sensor Enable
0 = disabled
1 = enabled
2
TSOPCTRL
0
Thermal Shutdown Output enable
0 = Disabled
1 = Enabled, i.e. all outputs will be
disabled if TI set and the device junction
temperature is more than 125ºC.
Table 40 Thermal Shutdown
w
PD, Rev 4.7, February 2012
74
WM8985
Production Data
UNUSED ANALOGUE INPUTS/OUTPUTS
Whenever an analogue input/output is disabled, it remains connected to a voltage source (AVDD1/2)
through a resistor. This helps to prevent pop noise when the output is re-enabled. The resistance
between the voltage buffer and the output pins can be controlled using the VROI control bit. The
default impedance is low, so that any capacitors on the outputs can charge up quickly at start-up. If a
high impedance is desired for disabled outputs, VROI can then be set to 1, increasing the resistance
to about 30k.
REGISTER
ADDRESS
BIT
R49 (31h)
0
LABEL
DEFAULT
VROI
0
DESCRIPTION
VREF (AVDD1/2) to analogue output
resistance
0 = approx 1k
1 = approx 30 k
Table 41 Disabled Outputs to VREF Resistance
A dedicated buffer is available for biasing unused analogue I/O pins as shown in Figure 30. This
buffer can be enabled using the BUFIOEN register bit.
Figure 30 summarises the bias options for the output pins.
Analogue inputs
1k
1k
1k
1k
LOUT1
30k
VROI
R49[0]
1k
ROUT1
30k
AVDD/2
+
AVDD/2
BUFIOEN
R1[2]
Used to tie off all unused
inputs and outputs
VROI
R49[0]
1k
OUT4
30k
VROI
R49[0]
1k
OUT3
30k
VROI
R49[0]
1k
LOUT2
30k
VROI
R49[0]
1k
ROUT2
30k
VROI
R49[0]
Figure 30 Unused Input/Output Pin Tie-off Buffers
w
PD, Rev 4.7, February 2012
75
WM8985
Production Data
L/ROUT2EN/
VROI
OUTPUT CONFIGURATION
OUT3/4EN
0
1kΩ to AVDD1/2
0
1
30kΩ to AVDD1/2
1
X
Output enabled (DC level=AVDD1/2)
0
Table 42 Unused Output Pin Bias Options
DIGITAL AUDIO INTERFACES
The audio interface has four pins:

ADCDAT: ADC data output

DACDAT: DAC data input

LRC: Data Left/Right alignment clock

BCLK: Bit clock, for synchronisation
The clock signals BCLK, and LRC can be outputs when the WM8985 operates as a master, or inputs
when it is a slave (see Master and Slave Mode Operation, below).
Five different audio data formats are supported:

Left justified

Right justified

IS

DSP mode A

DSP mode B
2
All of these modes are MSB first. They are described in Audio Data Formats, below. Refer to the
Electrical Characteristic section for timing information.
MASTER AND SLAVE MODE OPERATION
The WM8985 audio interface may be configured as either master or slave. As a master interface
device the WM8985 generates BCLK and LRC and thus controls sequencing of the data transfer on
ADCDAT and DACDAT. To set the device to master mode register bit MS should be set high. In
slave mode (MS=0), the WM8985 responds with data to clocks it receives over the digital audio
interfaces.
AUDIO DATA FORMATS
In Left Justified mode, the MSB is available on the first rising edge of BCLK following an LRC
transition. The other bits up to the LSB are then transmitted in order. Depending on word length,
BCLK frequency and sample rate, there may be unused BCLK cycles before each LRC transition.
Figure 31 Left Justified Audio Interface (assuming n-bit word length)
In Right Justified mode, the LSB is available on the last rising edge of BCLK before a LRC transition.
All other bits are transmitted before (MSB first). Depending on word length, BCLK frequency and
sample rate, there may be unused BCLK cycles after each LRC transition.
w
PD, Rev 4.7, February 2012
76
WM8985
Production Data
Figure 32 Right Justified Audio Interface (assuming n-bit word length)
2
In I S mode, the MSB is available on the second rising edge of BCLK following a LRC transition. The
other bits up to the LSB are then transmitted in order. Depending on word length, BCLK frequency
and sample rate, there may be unused BCLK cycles between the LSB of one sample and the MSB of
the next.
2
Figure 33 I S Audio Interface (assuming n-bit word length)
st
nd
In DSP/PCM mode, the left channel MSB is available on either the 1 (mode B) or 2 (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 LRC pulse shown in Figure 34 and Figure
35. In device slave mode, Figure 36 and Figure 37, it is possible to use any length of LRC pulse less
than 1/fs, providing the falling edge of the LRC pulse occurs greater than one BCLK period before the
rising edge of the next LRC pulse.
Figure 34 DSP/PCM Mode Audio Interface (mode A, LRP=0, Master)
w
PD, Rev 4.7, February 2012
77
WM8985
Production Data
Figure 35 DSP/PCM Mode Audio Interface (mode B, LRP=1, Master)
Figure 36 DSP/PCM Mode Audio Interface (mode A, LRP=0, Slave)
Figure 37 DSP/PCM Mode Audio Interface (mode B, LRP=0, Slave)
w
PD, Rev 4.7, February 2012
78
WM8985
Production Data
REGISTER
ADDRESS
R4 (04h)
BIT
0
LABEL
MONO
DEFAULT
0
Audio
Interface
Control
DESCRIPTION
Selects between stereo and mono
device operation:
0 = Stereo device operation
1 = Mono device operation. Data
appears in ‘left’ phase of LRC only.
1
ALRSWAP
0
Controls whether ADC data appears in
‘right’ or ‘left’ phases of LRC clock:
0 = ADC left data appear in ‘left’ phase
of LRC and right data in ‘right’ phase
1 = ADC left data appear in ‘right’ phase
of LRC and right data in ‘left’ phase
2
DLRSWAP
0
Controls whether DAC data appears in
‘right’ or ‘left’ phases of LRC clock:
0 = DAC left data appear in ‘left’ phase
of LRC and right data in ‘right’ phase
1 = DAC left data appear in ‘right’ phase
of LRC and right data in ‘left’ phase
4:3
FMT
10
Audio interface Data Format Select:
00 = Right Justified
01 = Left Justified
2
10 = I S format
11 = DSP/PCM mode
6:5
WL
10
Word length
00 = 16-bits
01 = 20-bits
10 = 24-bits
11 = 32-bits (see note)
7
LRP
0
LRC clock polarity
0 = normal
1 =inverted
DSP Mode – mode A/B select
nd
0 = MSB is available on 2 BCLK rising
edge after LRC rising edge (mode A)
st
1 = MSB is available on 1 BCLK rising
edge after LRC rising edge (mode B)
8
BCP
0
BCLK polarity
0 = normal
1 = inverted
R5
0
LOOPBACK
0
Digital loopback function
0 = No loopback
1 = Loopback enabled, ADC data output
is fed directly into DAC data input.
Table 43 Audio Interface Control
Note: Right Justified Mode will only operate with a maximum of 24 bits. If 32-bit mode is selected the
device will operate in 24-bit mode.
AUDIO INTERFACE CONTROL
The register bits controlling audio format, word length and master / slave mode are summarised
below.
Register bit MS selects audio interface operation in master or slave mode. In Master mode BCLK,
and LRC are outputs. The frequency of BCLK in master mode can be controlled with BCLKDIV. The
frequencies of BCLK and LRC are also controlled by MCLKDIV. The LRC sample rate is set to the
required values by MCLKDIV and the BCLK rate will be set accordingly to provide sufficient BCLKs
for that chosen sample rate. These clocks are divided down versions of master clock.
w
PD, Rev 4.7, February 2012
79
WM8985
Production Data
REGISTER
ADDRESS
R6 (06h)
BIT
0
LABEL
MS
DEFAULT
0
Clock
Generation
Control
DESCRIPTION
Sets the chip to be master over LRC and
BCLK
0 = BCLK and LRC clock are inputs
1 = BCLK and LRC clock are outputs
generated by the WM8985 (MASTER)
4:2
BCLKDIV
000
Configures the BCLK output frequency,
for use when the chip is master over
BCLK.
000 = divide by 1 (BCLK=SYSCLK)
001 = divide by 2 (BCLK=SYSCLK/2)
010 = divide by 4 (BCLK=SYSCLK/4)
011 = divide by 8 (BCLK=SYSCLK/8)
100 = divide by 16 (BCLK=SYSCLK/16)
101 = divide by 32 (BCLK=SYSCLK/32)
110 = reserved
111 = reserved
7:5
MCLKDIV
010
Sets the scaling for SYSCLK clock
output (under control of CLKSEL)
000 = divide by 1 (LRC=SYSCLK/128)
001 = divide by 1.5 (LRC=SYSCLK/192)
010 = divide by 2 (LRC=SYSCLK/256)
011 = divide by 3 (LRC=SYSCLK/384)
100 = divide by 4 (LRC=SYSCLK/512)
101 = divide by 6 (LRC=SYSCLK/768)
110 = divide by 8 (LRC=SYSCLK/1024)
111 = divide by 12 (LRC=SYSCLK/1536)
8
CLKSEL
1
Controls the source of the clock for all
internal operation:
0 = MCLK
1 = PLL output
Table 44 Clock Control
The CLKSEL bit selects the internal source of the Master clock from the PLL (CLKSEL=1) or from
MCLK (CLKSEL=0). When the internal clock is switched from one source to another using the
CLKSEL bit, the clock originally selected must generate at least one falling edge after CLKSEL has
changed for the switching of clocks to be successful.
EXAMPLE:
If the PLL is the current source of the internal clock (CLKSEL=1) and it is required to switch to the
MCLK, change CLKSEL to select MCLK (CLKSEL=0) and then disable PLL (PLLEN=0).
w
PD, Rev 4.7, February 2012
80
WM8985
Production Data
AUDIO SAMPLE RATES
The WM8985 ADC high pass filter, ALC and DAC limiter characteristics are sample rate dependent.
SR should be set to the correct sample rate or the closest value if the actual sample rate is not
available.
If a sample rate that is not explicitly supported by the SR register settings is required then the closest
SR value to that sample rate should be chosen. The filter characteristics and the ALC attack decay
and hold times will scale appropriately.
REGISTER
ADDRESS
R7 (07h)
BIT
LABEL
3:1
SR
DEFAULT
000
Additional
Control
DESCRIPTION
Approximate sample rate (configures the
coefficients for the internal digital filters):
000 = 48kHz
001 = 32kHz
010 = 24kHz
011 = 16kHz
100 = 12kHz
101 = 8kHz
110-111 = reserved
Table 45 Sample Rate Control
MASTER CLOCK AND PHASE LOCKED LOOP (PLL)
The WM8985 has an on-chip phase-locked loop (PLL) circuit that can be used to:
Generate master clocks for the WM8985 audio functions from another external clock, e.g. in
telecoms applications.
Generate and output (on pin CSB/GPIO1) a clock for another part of the system that is derived from
an existing audio master clock.
Figure 38 shows the PLL and internal clocking on the WM8985.
The PLL can be enabled or disabled by the PLLEN register bit.
REGISTER
ADDRESS
R1 (01h)
BIT
5
Power
management 1
LABEL
PLLEN
DEFAULT
0
DESCRIPTION
PLL enable
0 = PLL off
1 = PLL on
Table 46 PLLEN Control Bit
w
PD, Rev 4.7, February 2012
81
WM8985
Production Data
Figure 38 PLL and Clock Select Circuit
The PLL frequency ratio R = f2/f1 (see Figure 38) can be set using the register bits PLLK and PLLN:
PLLN = int R
24
PLLK = int (2 (R-PLLN))
EXAMPLE:
MCLK=12MHz, required clock = 12.288MHz.
R should be chosen to ensure 5 < PLLN < 13. There is a fixed divide by 4 in the PLL and a selectable
divide by N after the PLL which should be set to divide by 2 to meet this requirement.
Enabling the divide by 2 sets the required f2 = 4 x 2 x 12.288MHz = 98.304MHz.
R = 98.304 / 12 = 8.192
PLLN = int R = 8
24
k = int ( 2 x (8.192 – 8)) = 3221225 = 3126E9h
REGISTER
ADDRESS
R36 (24h)
BIT
4
LABEL
PLLPRESCALE
DEFAULT
0
PLL N value
R37 (25h)
0 = MCLK input not divided (default)
1 = Divide MCLK by 2 before input to
PLL
3:0
PLLN
1000
Integer (N) part of PLL input/output
frequency ratio. Use values greater
than 5 and less than 13.
5:0
PLLK [23:18]
0Ch
Fractional (K) part of PLL1
input/output frequency ratio (treat as
one 24-digit binary number).
8:0
PLLK [17:9]
093h
8:0
PLLK [8:0]
0E9h
PLL K value
1
R38 (26h)
DESCRIPTION
PLL K Value
2
R39 (27h)
PLL K Value
3
Table 47 PLL Frequency Ratio Control
The PLL performs best when f2 is around 90MHz. Its stability peaks at N=8. Some example settings
are shown in 48.
w
PD, Rev 4.7, February 2012
82
WM8985
Production Data
f2
(MHz)
(MHz)
R
N
K
N
K REGISTERS
REGISTER
MCLKDIV
(f1)
DESIRED
OUTPUT
(SYSCLK)
PLLPRESCALE
MCLK
(MHz)
R37
R36[3:0]
R38
R39
12
11.29
90.3168
1
2
7.5264
7h
86C226h
XX7h
021h
161h
026h
12
12.288
98.304
1
2
8.192
8h
3126E8h
XX8h
00Ch
093h
0E8h
13
11.29
90.3168
1
2
6.947446
6h
F28BD4h
XX6h
03Ch
145h
1D4h
13
12.288
98.304
1
2
7.561846
7h
8FD525h
XX7h
023h
1Eah
125h
14.4
11.29
90.3168
1
2
6.272
6h
45A1Cah
XX6h
011h
0D0h
1Cah
14.4
12.288
98.304
1
2
6.826667
6h
D3A06Eh
XX6h
034h
1D0h
06Eh
19.2
11.29
90.3168
2
2
9.408
9h
6872Afh
XX9h
01Ah
039h
0Afh
19.2
12.288
98.304
2
2
10.24
Ah
3D70A3h
XXAh
00Fh
0B8h
0A3h
19.68
11.29
90.3168
2
2
9.178537
9h
2DB492h
XX9h
00Bh
0Dah
092h
19.68
12.288
98.304
2
2
9.990243
9h
FD809Fh
XX9h
03Fh
0C0h
09Fh
19.8
11.29
90.3168
2
2
9.122909
9h
1F76F7h
XX9h
007h
1BBh
0F7h
19.8
12.288
98.304
2
2
9.929697
9h
EE009Eh
XX9h
03Bh
100h
09Eh
24
11.29
90.3168
2
2
7.5264
7h
86C226h
XX7h
021h
161h
026h
24
12.288
98.304
2
2
8.192
8h
3126E8h
XX8h
00Ch
093h
0E8h
26
11.29
90.3168
2
2
6.947446
6h
F28BD4h
XX6h
03Ch
145h
1D4h
26
12.288
98.304
2
2
7.561846
7h
8FD525h
XX7h
023h
1Eah
125h
27
11.29
90.3168
2
2
6.690133
6h
B0AC93h
XX6h
02Ch
056h
093h
27
12.288
98.304
2
2
7.281778
7h
482296h
XX7h
012h
011h
096h
Table 48 PLL Frequency Examples
LOOPBACK
Setting the LOOPBACK register bit enables digital loopback. When this bit is set the output data
from the ADC audio interface is fed directly into the DAC data input.
COMPANDING
The WM8985 supports A-law and -law companding on both transmit (ADC) and receive (DAC)
sides. Companding can be enabled on the DAC or ADC audio interfaces by writing the appropriate
value to the DAC_COMP or ADC_COMP register bits respectively.
REGISTER
ADDRESS
R5 (05h)
BIT
2:1
LABEL
ADC_COMP
DEFAULT
0
Companding
Control
DESCRIPTION
ADC companding
00 = off
01 = reserved
10 = µ-law
11 = A-law
4:3
DAC_COMP
0
DAC companding
00 = off
01 = reserved
10 = µ-law
11 = A-law
5
WL8
0
0 = off
1 = device operates in 8-bit mode.
Table 49 Companding Control
w
PD, Rev 4.7, February 2012
83
WM8985
Production Data
Companding involves using a piecewise linear approximation of the following equations (as set out
by ITU-T G.711 standard) for data compression:
-law (where =255 for the U.S. and Japan):
F(x) = ln( 1 + |x|) / ln( 1 + )
-1 ≤ x ≤ 1
A law (where A=87.6 for Europe):
F(x) = A|x| / ( 1 + lnA)
 for x ≤ 1/A
F(x) = ( 1 + lnA|x|) / (1 + lnA)
 for 1/A ≤ x ≤ 1
The companded data is also inverted as recommended by the G.711 standard (all 8 bits are inverted
for -law, all even data bits are inverted for A-law). The data will be transmitted as the first 8 MSB’s
of data.
Companding converts 13 bits (-law) or 12 bits (A-law) to 8 bits using non-linear quantization. The
input data range is separated into 8 levels, allowing low amplitude signals better precision than that
of high amplitude signals. This is to exploit the operation of the human auditory system, where louder
sounds do not require as much resolution as quieter sounds. The companded signal is an 8-bit word
containing sign (1-bit), exponent (3-bits) and mantissa (4-bits).
Setting the WL8 register bit allows the device to operate with 8-bit data. In this mode it is possible to
use 8 BCLK’s per LRC frame. When using DSP mode B, this allows 8-bit data words to be output
consecutively every 8 BCLK’s and can be used with 8-bit data words using the A-law and u-law
companding functions.
BIT7
BIT[6:4]
BIT[3:0]
SIGN
EXPONENT
MANTISSA
Table 50 8-bit Companded Word Composition
u-law Companding
1
120
0.9
Companded Output
0.7
80
0.6
0.5
60
0.4
40
0.3
Normalised Output
0.8
100
0.2
20
0.1
0
0
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Normalised Input
Figure 39 µ-Law Companding
w
PD, Rev 4.7, February 2012
84
WM8985
Production Data
A-law Companding
1
120
0.9
Companded Output
0.7
80
0.6
0.5
60
0.4
40
0.3
Normalised Output
0.8
100
0.2
20
0.1
0
0
0
0.2
0.4
0.6
0.8
1
Normalised Input
Figure 40 A-Law Companding
w
PD, Rev 4.7, February 2012
85
WM8985
Production Data
GENERAL PURPOSE INPUT/OUTPUT
The WM8985 has three dual purpose input/output pins.

CSB/GPIO1: CSB / GPIO1 pin

L2/GPIO2: Left channel line input / headphone detection input

R2/GPIO3: Right channel line input / headphone detection input
The GPIO2 and GPIO3 functions are provided for use as jack detection inputs.
The GPIO1 function is provided for use as jack detection input or general purpose output.
The default configuration for the CSB/GPIO1 is to be an input.
When setup as an input, the CSB/GPIO1 pin can either be used as CSB or for jack detection,
depending on how the MODE pin is set.
Table 45 illustrates the functionality of the GPIO1 pin when used as a general purpose output.
REGISTER
ADDRESS
R8 (08h)
BIT
2:0
LABEL
GPIO1SEL
DEFAULT
000
GPIO
DESCRIPTION
CSB/GPIO1 pin function select:
000 = input (CSB / Jack detection:
depending on MODE setting)
Control
001 = reserved
010 = Temp ok
011 = Amute active
100 = PLL clk output
101 = PLL lock
110 = logic 0
111 = logic 1
3
GPIO1POL
0
GPIO1 Polarity invert
0 = Non inverted
1 = Inverted
6
GPIO1GPD
0
GPIO1 Internal pull-down enable:
0 = Internal pull-down disabled
1 = Internal pull-down enabled
7
GPIO1GPU
0
GPIO1 Internal pull-up enable:
0 = Internal pull-up disabled
1 = Internal pull-up enabled
8
GPIO1GP
0
GPIO1 Open drain enable
0 = Open drain disabled
1 = Open drain enabled
R14(0Eh)
5:4
OPCLKDIV
00
PLL Output clock division ratio
00 = divide by 1
01 = divide by 2
10 = divide by 3
11 = divide by 4
Table 45 CSB/GPIO Control
Note:
If MODE is set to 3 wire mode, CSB/GPIO1 is used as CSB input irrespective of the GPIO1SEL[2:0]
bits.
Register R14(0Eh) bits [5:4] (OPCLKDIV) are used to control the PLL output clock division ratio and
also the highpass filter cut-off in applications mode (HPFCUT). OPCLKDIV and HPFCUT cannot be
set independently.
w
PD, Rev 4.7, February 2012
86
WM8985
Production Data
For further details of the jack detect operation see the OUTPUT SWITCHING section.
OUTPUT SWITCHING (JACK DETECT)
When the device is operated using a 2-wire interface the CSB/GPIO1 pin can be used as a switch
control input to automatically disable one set of outputs and enable another; the most common use
for this functionality is as jack detect circuitry. The L2/GPIO2 and R2/GPIO3 pins can also be used
for this purpose.
The GPIO pins have an internal de-bounce circuit when in this mode in order to prevent the output
enables from toggling multiple times due to input glitches. This de-bounce circuit is clocked from a
21
slow clock with period 2 x MCLK and is enabled by the SLOWCLKEN bit.
Notes:
1.
The SLOWCLKEN bit must be enabled for the jack detect circuitry to operate.
2.
The GPIOPOL bit is not relevant for jack detection, it is the signal detected at the pin which is
used
Switching on/off of the outputs is fully configurable by the user. Each output, OUT1, OUT2, OUT3
and OUT4 has 2 associated enables. OUT1_EN_0, OUT2_EN_0, OUT3_EN_0 and OUT4_EN_0 are
the output enable signals which are used if the selected jack detection pin is at logic 0 (after debounce). OUT1_EN_1, OUT2_EN_1, OUT3_EN_1 and OUT4_EN_1 are the output enable signals
which are used if the selected jack detection pin is at logic 1 (after de-bounce).
The jack detection enables operate as follows:
All OUT_EN signals have an AND function performed with their normal enable signals (in Table 39).
When an output is normally enabled as per Table 39, the selected jack detection enable (controlled
by selected jack detection pin polarity) is set 0; it will turn the output off. If the normal enable signal is
already OFF (0), the jack detection signal will have no effect due to the AND function.
During jack detection if the user desires an output to be un-changed whether the jack is in or not,
both the JD_EN settings, i.e. JD_EN0 and JD_EN1, should be set to 0000.
If jack detection is not enabled (JD_EN=0), the output enables default to all 1’s, allowing the outputs
to be controlled as normal via the normal output enables found in Table 39.
w
PD, Rev 4.7, February 2012
87
WM8985
Production Data
BIT
LABEL
DEFAULT
DESCRIPTION
REGISTER
ADDRESS
R9 (09h)
5:4
JD_SEL
00
GPIO control
Pin selected as jack detection input
00 = GPIO1
01 = GPIO2
10 = GPIO3
11 = Reserved
6
JD_EN
0
Jack Detection Enable
0 = disabled
1 = enabled
R13 (00h)
3:0
JD_EN0
0000
Output enables when selected jack
detection input is logic 0.
[0]= OUT1_EN_0
[1]= OUT2_EN_0
[2]= OUT3_EN_0
[3]= OUT4_EN_0
7:4
JD_EN1
0000
Output enables when selected jack
detection input is logic 1
[4]= OUT1_EN_1
[5]= OUT2_EN_1
[6]= OUT3_EN_1
[7]= OUT4_EN_1
Table 46 Jack Detect Register Control Bits
CONTROL INTERFACE
SELECTION OF CONTROL MODE AND 2-WIRE MODE ADDRESS
The control interface can operate as either a 3-wire or 2-wire control interface. The MODE pin
determines the 2 or 3 wire mode as shown in Table 47.
The WM8985 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 register address bits that select which control
register is accessed. The remaining 9 bits (B8 to B0) are data bits, corresponding to the 9 data bits in
each control register.
MODE
INTERFACE FORMAT
Low
2 wire
High
3 wire
Table 47 Control Interface Mode Selection
3-WIRE SERIAL CONTROL MODE
In 3-wire mode, every rising edge of SCLK clocks in one data bit from the SDIN pin. A rising edge on
CSB/GPIO latches in a complete control word consisting of the last 16 bits.
Figure 39 3-Wire Serial Control Interface
w
PD, Rev 4.7, February 2012
88
WM8985
Production Data
2-WIRE SERIAL CONTROL MODE
The WM8985 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 device address (this is not the same as the 7-bit
address of each register in the WM8985).
The WM8985 operates as a slave device only. The controller indicates the start of data transfer with
a high to low transition on SDIN while SCLK 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 SDIN (7-bit address + Read/Write bit, MSB first). If the device address received matches the
address of the WM8985, the WM8985 responds by pulling SDIN low on the next clock pulse (ACK). If
the address is not recognised or the R/W bit is ‘1’ when operating in write only mode, the WM8985
returns to the idle condition and waits for a new start condition and valid address.
During a write, once the WM8985 has acknowledged a correct address, the controller sends the first
byte of control data (B15 to B8, i.e. the WM8985 register address plus the first bit of register data).
The WM8985 then acknowledges the first data byte by driving SDIN low for one clock cycle. The
controller then sends the second byte of control data (B7 to B0, i.e. the remaining 8 bits of register
data), and the WM8985 acknowledges again by pulling SDIN low.
Transfer is complete when there is a low to high transition on SDIN while SCLK is high. After a
complete sequence the WM8985 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. SDIN
changes while SCLK is high), the control interface returns to the idle condition.
DEVICE ADDRESS
(7 BITS)
SDIN
RD / WR
BIT
ACK
(LOW)
CONTROL BYTE 1
(BITS 15 TO 8)
ACK
(LOW)
CONTROL BYTE 1
(BITS 7 TO 0)
ACK
(LOW)
SCLK
START
register address and
1st register data bit
remaining 8 bits of
register data
STOP
Figure 40 2-Wire Serial Control Interface
In 2-wire mode the WM8985 has a fixed device address, 0011010.
RESETTING THE CHIP
The WM8985 can be reset by performing a write of any value to the software reset register (address
0h). This will cause all register values to be reset to their default values. In addition to this there is a
Power-On Reset (POR) circuit which ensures that the registers are initially set to default when the
device is powered up.
POWER SUPPLIES
The WM8985 requires four separate power supplies:
AVDD1 and AGND1: Analogue supply, powers all internal analogue functions and output drivers
LOUT1, ROUT1, OUT3 and OUT4. AVDD1 must be between 2.5V and 3.6V and has the most
significant impact on overall power consumption (except for power consumed in the headphones).
Higher AVDD1 will improve audio quality.
AVDD2 and AGND2: Output driver supplies, power LOUT2 and ROUT2. AVDD2 must be between
2.5V and 3.6V. AVDD2 can be tied to AVDD1, but it requires separate layout and decoupling
capacitors to curb harmonic distortion.
DCVDD: Digital core supply, powers all digital functions except the audio and control interface pads.
DCVDD must be between 1.71V and 3.6V, and has no effect on audio quality. The return path for
DCVDD is DGND, which is shared with DBVDD.
DBVDD must be between 1.71V and 3.6V. DBVDD return path is through DGND.
It is possible to use the same supply voltage for all four supplies. However, digital and analogue
supplies should be routed and decoupled separately on the PCB to keep digital switching noise out of
the analogue signal paths.
w
PD, Rev 4.7, February 2012
89
WM8985
Production Data
POWER MANAGEMENT
SAVING POWER BY REDUCING OVERSAMPLING RATE
The default mode of operation of the ADC and DAC digital filters is in 64x oversampling mode. Under
the control of ADCOSR128 and DACOSR128 the oversampling rate may be doubled. 64x
oversampling results in a slight decrease in noise performance compared to 128x but lowers the
power consumption of the device.
REGISTER
ADDRESS
R10 (0Ah)
BIT
3
LABEL
DEFAULT
DACOSR128
0
DESCRIPTION
DAC oversample rate select
DAC control
0 = 64x (lowest power)
1 = 128x (best SNR)
R14 (0Eh)
3
ADCOSR128
0
ADC oversample rate select
ADC control
0 = 64x (lowest power)
1 = 128x (best SNR)
Table 48 ADC and DAC Oversampling Rate Selection
LOW POWER MODE
If only DAC or ADC functionality is required, the WM8985 can be put into a low power mode. In this
mode, the DSP core runs at half of the normal rate, reducing digital power consumption of the core
by half. For DAC low power only, 3D enhancement with 2-Band equaliser functionality is permitted,
where only Band 1 (low shelf) and Band 5 (high shelf) can be used. For ADC low power, the
equaliser and 3D cannot be used.
REGISTER
ADDRESS
R7 (07h)
BIT
8
LABEL
M128ENB
DEFAULT
0
Additional Ctrl
DESCRIPTION
0 = low power mode enabled
1 = low power mode disabled
Table 49 DSP Core Low Power Mode Control
There are 3 modes of low power operation, as detailed below. The device will not enter low power
unless in one of these register configurations, regardless of M128ENB.
For pop-free operation of the device it is recommended to change the M128ENB low power
functionality only when both the DACs and ADCs are disabled, i.e. when DACENL=0, DACENR=0,
ADCENL=0 and ADCENR=0.
FUNCTION
ADC low power
DAC low power
REGISTER BITS
SETTING
M128ENB
0
ADCENL
1
ADCENR
1
DACENL
0
DACENR
0
EQ3DMODE
1 (DAC path)
M128ENB
0
ADCENL
0
ADCENR
0
DACENL
1
DACENR
1
DESCRIPTION
Either or both of ADCENL and
ADCENR must be set (mono or
stereo mode)
Either or both of DACENL and
DACENR must be set (mono or
stereo mode)
EQ3DMODE = 0: EQ in ADC path
EQ3DMODE = 1: EQ in DAC path
Table 50 DSP Core Low Power Modes for ADC Only and DAC Only Modes
w
PD, Rev 4.7, February 2012
90
WM8985
Production Data
VMID
The analogue circuitry will not operate unless VMID is enabled. The impedance of the VMID resistor
string, together with the decoupling capacitor on the VMID pin will determine the start-up time of the
VMID circuit.
REGISTER
ADDRESS
R1 (01h)
BIT
1:0
LABEL
DEFAULT
VMIDSEL
00
Power
management 1
DESCRIPTION
Reference string impedance to VMID pin
00 = off (250kΩ VMID to AGND1)
01=75kΩ
10=300kΩ
11=5kΩ
Table 51 VMID Impedance Control
BIASEN
The analogue amplifiers will not operate unless BIASEN is enabled.
REGISTER
ADDRESS
R1 (01h)
BIT
3
LABEL
BIASEN
DEFAULT
0
Power
management 1
DESCRIPTION
Analogue amplifier bias control
0 = disabled
1 = enabled
Table 52 Analogue Bias Control
POP MINIMISATION
POBCTRL
WM8985 has two bias generators. A noisy bias derived from AVDD and a low noise bias derived from
VMID. POBCTRL is use to switch between the two bias generators. During power up, the AVDD
derived bias is available as soon as AVDD is applied; the VMID derived bias is available once the
VMID node has charged up.
REGISTER
ADDRESS
R42
OUT4 to ADC
BIT
2
LABEL
POB
CTRL
DEFAULT
0
DESCRIPTION
VMID independent current bias control
0 = Disable VMID independent current
bias
1 = Enable VMID independent current bias
Note: POBCTRL should be asserted during power up to minimize pops and then de-asserted
at the end of the power up sequence to give best performance. Refer to Recommended
Power Up/Down
w
PD, Rev 4.7, February 2012
91
WM8985
Production Data
REGISTER MAP
ADDR
B[15:9]
REGISTER
NAME
B8
B7
B6
B5
B4
B3
B2
B1
B0
VAL
DEC HEX
(HEX)
0
00
Software Reset
1
01
Power manage’t 1
2
02
Power manage’t 2
03
Power manage’t 3
4
04
Audio Interface
5
05
Companding ctrl
3
DEF’T
Software reset
0
ROUT1EN
OUT4MIX
OUT3MIX
EN
EN
LOUT1EN
SLEEP
PLLEN
MICBEN
BIASEN
BUFIOEN
BOOST
BOOST
INPGA
INPPGA
ENR
ENL
ENR
ENL
OUT4EN
OUT3EN
ROUT2EN LOUT2EN
BCP
LRP
WL
0
0
WL8
RMIXEN
VMIDSEL[1:0]
LMIXEN
000
ADCENR
ADCENL
000
DACENR
DACENL
000
FMT
DLRSWAP ALRSWAP
MONO
050
DAC_COMP[1:0]
ADC_COMP[1:0]
LOOP
000
BACK
6
06
Clock Gen ctrl
CLKSEL
7
07
Additional ctrl
M128ENB
MCLKDIV[2:0]
BCLKDIV[2:0]
0
DCLKDIV[3:0]
SR[2:0]
MS
140
SLOWCLK
080
EN
8
08
GPIO Stuff
9
09
Jack detect control
GPIO1GP
0
GPIO1GPU GPIO1GPD
0
JD_EN
10
0A
DAC Control
0
0
SOFT
0
0
JD_SEL
0
0
MUTE
11
0B
Left DAC digital Vol
DACVU
12
0C
Right DAC dig’l Vol
DACVU
13
0D
Jack Detect Control
0
14
0E
ADC Control
GPIO1POL
GPIO1SEL[2:0]
0
0
DACOSR
AMUTE
000
0
DACRPOL DACLPOL
DACLVOL[7:0]
HPFCUT[2:0]
0
000
0FF
DACRVOL[7:0]
HPFAPP
000
128
0FF
JD_EN1[3:0]
HPFEN
0
ADCOSR
OPCLKDIV[1:0]
JD_EN0[3:0]
000
0
100
ADCRPOL ADCLPOL
128
15
0F
Left ADC Digital Vol
ADCVU
ADCLVOL[7:0]
0FF
16
10
Right ADC Digital
Vol
ADCVU
ADCRVOL[7:0]
0FF
18
12
EQ1 – low shelf
EQ3DMODE
0
EQ1C[1:0]
EQ1G[4:0]
12C
19
13
EQ2 – peak 1
EQ2BW
0
EQ2C[1:0]
EQ2G[4:0]
02C
20
14
EQ3 – peak 2
EQ3BW
0
EQ3C[1:0]
EQ3G[4:0]
02C
21
15
EQ4 – peak 3
EQ4BW
0
EQ4C[1:0]
EQ4G[4:0]
02C
22
16
EQ5 – high shelf
0
0
EQ5C[1:0]
EQ5G[4:0]
02C
23
17
Class D Control
CLASSDEN
0
24
18
DAC Limiter 1
LIMEN
25
19
DAC Limiter 2
0
0
27
1B
Notch Filter 1
NFU
NFEN
NFA0[13:7]
000
28
1C
Notch Filter 2
NFU
0
NFA0[6:0]
000
29
1D
Notch Filter 3
NFU
0
NFA1[13:7]
000
30
1E
Notch Filter 4
NFU
0
NFA1[6:0]
000
32
20
ALC control 1
ALCSEL[1:0]
0
33
21
ALC control 2
0
ALCHLD[3:0]
34
22
ALC control 3
ALCMODE
35
23
Noise Gate
0
0
0
0
0
36
24
PLL N
0
0
0
0
PLLPRE
0
0
0
10
0
LIMDCY[3:0]
LIMLVL[2:0]
0
032
LIMBOOST[3:0]
000
ALCMAX[2:0]
ALCMIN[2:0]
ALCDCY[3:0]
008
LIMATK[3:0]
038
ALCLVL[3:0]
00B
ALCATK[3:0]
032
NGEN
NGTH[2:0]
000
PLLN[3:0]
008
SCALE
37
25
PLL K 1
38
26
PLL K 2
0
0
0
PLLK[17:9]
PLLK[23:18]
39
27
PLL K 3
PLLK[8:0]
41
29
3D control
42
2A
OUT4 to ADC
00C
093
0E9
DEPTH3D[3:0]
OUT4_2ADCVOL[2:0]
OUT4_2
000
0
0
POBCTRL
0
0
000
0
0
0
0
0
000
LNR
43
2B
Beep control
w
BYPL2
BYPR2
0
0
PD, Rev 4.7, February 2012
92
WM8985
Production Data
ADDR
B[15:9]
REGISTER
NAME
B8
B7
B6
B5
B4
B3
B2
B1
B0
VAL
DEC HEX
44
45
46
47
2C
2D
2E
2F
DEF’T
(HEX)
Input ctrl
RMIX
LMIX
MBVSEL
0
Left INP PGA gain
ctrl
INPGAVU
Right INP PGA gain
ctrl
INPGAVU
Left ADC Boost ctrl
PGA
R2_2
RIN2
RIP2
INPPGA
INPPGA
INPPGA
INPPGA
INPPGA
ZCL
MUTEL
INPPGA
INPPGA
ZCR
MUTER
0
L2_2
LIN2
LIP2
INPPGA
INPPGA
INPPGA
003
INPPGAVOLL[5:0]
010
INPPGAVOLR[5:0]
010
0
L2_2BOOSTVOL[2:0]
0
AUXL2BOOSTVOL[2:0]
100
0
R2_2BOOSTVOL[2:0]
0
AUXR2BOOSTVOL[2:0]
100
BOOSTL
48
30
Right ADC Boost ctrl
PGA
BOOSTR
49
50
31
32
Output ctrl
0
Left mixer ctrl
0
DACL2
DACR2
RMIX
LMIX
AUXLMIXVOL[2:0]
0
0
TSOP
AUXL2
BYPLMIXVOL[2:0]
LMIX
51
33
Right mixer ctrl
AUXRMIXVOL[2:0]
AUXR2
BYPRMIXVOL[2:0]
RMIX
52
53
54
55
56
34
35
36
37
38
LOUT1 (HP) volume
ctrl
OUT1VU
ROUT1 (HP) volume
ctrl
OUT1VU
LOUT2 (SPK)
volume ctrl
OUT2VU
ROUT2 (SPK)
volume ctrl
OUT2VU
OUT3 mixer ctrl
0
LOUT1ZC
LOUT1
39
OUT4 (MONO)
mixer ctrl
61
3D
Bias Control
VROI
002
BYPL2
DACL2
001
LMIX
LMIX
BYPR2
DACR2
RMIX
RMIX
001
LOUT1VOL[5:0]
039
ROUT1VOL[5:0]
039
LOUT2VOL[5:0]
039
ROUT2VOL[5:0]
039
MUTE
ROUT1ZC
ROUT1
MUTE
LOUT2ZC
LOUT2
MUTE
ROUT2ZC
ROUT2
MUTE
0
OUT3
0
0
MUTE
57
TSDEN
CTRL
0
BIASCUT
OUT
OUT4
OUT4
LMIX2
3_2OUT4
MUTE
ATTN
OUT4
0
0
0
00
OUT4_
BYPL2
LMIX2
LDAC2
2OUT3
OUT3
OUT3
OUT3
LDAC2
BYPR2
RMIX2
RDAC2
OUT4
OUT4
OUT4
OUT4
00
0
001
001
000
Table 53 WM8985 Register Map
w
PD, Rev 4.7, February 2012
93
WM8985
Production Data
REGISTER BITS BY ADDRESS
Notes:
1. Default values of N/A indicate non-latched data bits (e.g. software reset or volume update bits).
2. Register bits marked as “Reserved” should not be changed from the default.
REGISTER
ADDRESS
0 (00h)
1 (01h)
BIT
[8:0]
LABEL
DESCRIPTION
RESET
N/A
0
Reserved. Initialise to 0
OUT4MIXEN
0
OUT4 mixer enable
8
7
DEFAULT
REFER TO
Software reset
Resetting the
Chip
Power
Management
0=disabled
1=enabled
6
OUT3MIXEN
0
OUT3 mixer enable
Power
Management
0=disabled
1=enabled
5
PLLEN
0
PLL enable
Master Clock
and Phase
Locked Loop
(PLL)
0=PLL off
1=PLL on
4
MICBEN
0
Microphone Bias Enable
Input Signal
Path
0 = OFF (high impedance output)
1 = ON
3
BIASEN
0
Analogue amplifier bias control
Power
Management
0=disabled
1=enabled
2
BUFIOEN
0
Unused input/output tie off buffer enable
0=disabled
Power
Management
1=enabled
1:0
VMIDSEL[1:0]
00
Reference string impedance to VMID pin
00 = off (250kΩ VMID to AGND1)
Power
Management
01=75kΩ
10=300kΩ
11=5kΩ
2 (02h)
8
ROUT1EN
0
ROUT1 output enable
Power
Management
0=disabled
1=enabled
7
LOUT1EN
0
LOUT1 output enable
Power
Management
0=disabled
1=enabled
6
SLEEP
0
0 = normal device operation
1 = residual current reduced in device standby
mode
5
BOOSTENR
0
Right channel Input BOOST enable
0 = Boost stage OFF
Power
Management
Power
Management
1 = Boost stage ON
4
BOOSTENL
0
Left channel Input BOOST enable
0 = Boost stage OFF
Power
Management
1 = Boost stage ON
3
INPPGAENR
0
Right channel input PGA enable
0 = disabled
Power
Management
1 = enabled
2
INPPGAENL
0
Left channel input PGA enable
0 = disabled
Power
Management
1 = enabled
w
PD, Rev 4.7, February 2012
94
WM8985
Production Data
REGISTER
ADDRESS
BIT
1
LABEL
ADCENR
DEFAULT
0
DESCRIPTION
Enable ADC right channel:
0 = ADC disabled
1 = ADC enabled
0
ADCENL
0
Enable ADC left channel:
0 = ADC disabled
1 = ADC enabled
3 (03h)
8
OUT4EN
0
OUT4 enable
0 = disabled
REFER TO
Analogue to
Digital
Converter
(ADC)
Analogue to
Digital
Converter
(ADC)
Power
Management
1 = enabled
7
OUT3EN
0
OUT3 enable
0 = disabled
Power
Management
1 = enabled
6
ROUT2EN
0
ROUT2 enable
0 = disabled
Power
Management
1 = enabled
5
LOUT2EN
0
LOUT2 enable
0 = disabled
Power
Management
1 = enabled
4
3
RMIXEN
0
Reserved. Initialise to 0
0
Right output channel mixer enable:
0 = disabled
Analogue
Outputs
1 = enabled
2
LMIXEN
0
Left output channel mixer enable:
0 = disabled
Analogue
Outputs
1 = enabled
1
DACENR
0
Right channel DAC enable
0 = DAC disabled
Analogue
Outputs
1 = DAC enabled
0
DACENL
0
Left channel DAC enable
0 = DAC disabled
Analogue
Outputs
1 = DAC enabled
4 (04h)
8
BCP
0
BCLK polarity
0=normal
Digital Audio
Interfaces
1=inverted
7
LRP
0
LRC clock polarity
0=normal
Digital Audio
Interfaces
1=inverted
6:5
WL
10
Word length
00=16 bits
Digital Audio
Interfaces
01=20 bits
10=24 bits
11=32 bits
4:3
FMT
10
Audio interface Data Format Select:
00=Right Justified
Digital Audio
Interfaces
01=Left Justified
2
10=I S format
11= DSP/PCM mode
w
PD, Rev 4.7, February 2012
95
WM8985
REGISTER
ADDRESS
Production Data
BIT
2
LABEL
DLRSWAP
DEFAULT
0
DESCRIPTION
REFER TO
Controls whether DAC data appears in ‘right’ or
Digital Audio
‘left’ phases of LRC clock:
Interfaces
0=DAC data appear in ‘left’ phase of LRC
1=DAC data appears in ‘right’ phase of LRC
1
ALRSWAP
0
Controls whether ADC data appears in ‘right’ or
‘left’ phases of LRC clock:
Digital Audio
Interfaces
0=ADC data appear in ‘left’ phase of LRC
1=ADC data appears in ‘right’ phase of LRC
0
MONO
0
Selects between stereo and mono device
operation:
Digital Audio
Interfaces
0=Stereo device operation
1=Mono device operation. Data appears in ‘left’
phase of LRC
5 (05h)
8:6
5
WL8
000
Reserved. Initialise to 0
0
Companding Control 8-bit mode
Digital Audio
Interfaces
0=off
1=device operates in 8-bit mode
4:3
DAC_COMP
00
Digital Audio
Interfaces
DAC companding
00=off (linear mode)
01=reserved
10=µ-law
11=A-law
2:1
ADC_COMP
00
Digital Audio
Interfaces
ADC companding
00=off (linear mode)
01=reserved
10=µ-law
11=A-law
0
LOOPBACK
0
Digital loopback function
Digital Audio
Interfaces
0=No loopback
1=Loopback enabled, ADC data output is fed
directly into DAC data input.
6 (06h)
8
CLKSEL
1
Controls the source of the clock for all internal
operation:
Digital Audio
Interfaces
0=MCLK
1=PLL output
7:5
MCLKDIV
010
Sets the scaling for either the MCLK or PLL
clock output (under control of CLKSEL)
Digital Audio
Interfaces
000=divide by 1
001=divide by 1.5
010=divide by 2
011=divide by 3
100=divide by 4
101=divide by 6
110=divide by 8
111=divide by 12
w
PD, Rev 4.7, February 2012
96
WM8985
Production Data
REGISTER
ADDRESS
BIT
4:2
LABEL
BCLKDIV
DEFAULT
000
DESCRIPTION
REFER TO
Configures the BCLK output frequency, for use
Digital Audio
when the chip is master over BCLK.
Interfaces
000=divide by 1 (BCLK=MCLK)
001=divide by 2 (BCLK=MCLK/2)
010=divide by 4
011=divide by 8
100=divide by 16
101=divide by 32
110=reserved
111=reserved
1
0
MS
0
Reserved. Initialise to 0
0
Sets the chip to be master over LRC and BCLK
0=BCLK and LRC clock are inputs
Digital Audio
Interfaces
1=BCLK and LRC clock are outputs generated
by the WM8985 (MASTER)
7 (07h)
8
M128ENB
0
0 = low power mode enabled
Additional
Control
1 = low power mode disabled
7:4
DCLKDIV
1000
Controls clock division from SYSCLK to
generate suitable class D clock.
Recommended class D clock frequency =
1.4MHz.
Class A / D
Headphone
Outputs
0000 = divide by 1
0010 = divide by 2
0011 = divide by 3
0100 = divide by 4
0101 = divide by 5.5
0110 = divide by 6
1000 = divide by 8
1001 = divide by 12
1010 = divide by 16
3:1
SR
000
Approximate sample rate (configures the
coefficients for the internal digital filters):
Audio Sample
Rates
000=48kHz
001=32kHz
010=24kHz
011=16kHz
100=12kHz
101=8kHz
110-111=reserved
0
SLOWCLKEN
0
Slow clock enable. Used for both the jack insert
detect debounce circuit and the zero cross
timeout.
Analogue
Outputs
0 = slow clock disabled
1 = slow clock enabled
8 (08h)
8
GPIO1GP
0
GPIO1 Open drain enable
0 = Open drain disabled
1 = Open drain enabled
7
GPIO1GPU
0
GPIO1 Internal pull-up enable:
0 = Internal pull-up disabled
1 = Internal pull-up enabled
w
General
Purpose
Input/Output
(GPIO)
General
Purpose
Input/Output
(GPIO)
PD, Rev 4.7, February 2012
97
WM8985
REGISTER
ADDRESS
Production Data
BIT
6
LABEL
GPIO1GPD
DEFAULT
0
DESCRIPTION
REFER TO
GPIO1 Internal pull-down enable:
General
Purpose
Input/Output
(GPIO)
0 = Internal pull-down disabled
1 = Internal pull-down enabled
3
GPIO1POL
0
GPIO1 Polarity invert
General
Purpose
Input/Output
(GPIO)
0=Non inverted
1=Inverted
2:0
GPIO1SEL
000
[2:0]
CSB/GPIO1 pin function select:
000= input (CSB/jack detection: depending on
MODE setting)
001= reserved
General
Purpose
Input/Output
(GPIO)
010=Temp ok
011=Amute active
100=PLL clk o/p
101=PLL lock
110=logic 1
111=logic 0
9 (09h)
8:7
6
00
JD_EN
0
Reserved. Initialise to 00
Jack Detection Enable
Output
Switching
(Jack Detect)
0=disabled
1=enabled
5:4
JD_SEL
00
Output
Switching
(Jack Detect)
Pin selected as jack detection input
00 = GPIO1
01 = GPIO2
10 = GPIO3
11 = Reserved
10 (0Ah)
3:0
0
Reserved. Initialise to 0
8:7
00
Reserved. Initialise to 0
6
SOFTMUTE
0
Softmute enable:
Output Signal
Path
0=Disabled
1=Enabled
5:4
3
00
DACOSR128
0
Reserved. Initialise to 0
DAC oversample rate select
Power
Management
0 = 64x (lowest power)
1 = 128x (best SNR)
2
AMUTE
0
Automute enable
Output Signal
Path
0 = Amute disabled
1 = Amute enabled
1
DACPOLR
0
Right DAC output polarity:
Output Signal
Path
0 = non-inverted
1 = inverted (180 degrees phase shift)
0
DACPOLL
0
Left DAC output polarity:
Output Signal
Path
0 = non-inverted
1 = inverted (180 degrees phase shift)
11 (0Bh)
8
DACVU
w
N/A
DAC left and DAC right volume do not update
until a 1 is written to DACVU (in reg 11 or 12)
Digital to
Analogue
Converter
(DAC)
PD, Rev 4.7, February 2012
98
WM8985
Production Data
REGISTER
ADDRESS
BIT
7:0
LABEL
DACVOLL
DEFAULT
11111111
DESCRIPTION
REFER TO
Digital to
Analogue
Converter
(DAC)
Left DAC Digital Volume Control
0000 0000 = Digital Mute
0000 0001 = -127dB
0000 0010 = -126.5dB
… 0.5dB steps up to
1111 1111 = 0dB
12 (0Ch)
8
DACVU
N/A
7:0
DACVOLR
11111111
DAC left and DAC right volume do not update
until a 1 is written to DACVU (in reg 11 or 12)
Output Signal
Path
Right DAC Digital Volume Control
Output Signal
Path
0000 0000 = Digital Mute
0000 0001 = -127dB
0000 0010 = -126.5dB
... 0.5dB steps up to
1111 1111 = 0dB
13 (0Dh)
8
7:4
JD_EN1
0
Reserved. Initialise to 0
0000
Output enabled when selected jack detection
input is logic 1
[4]= OUT1_EN_1
Output
Switching
(Jack Detect)
[5]= OUT2_EN_1
[6]= OUT3_EN_1
[7]= OUT4_EN_1
3:0
JD_EN0
0000
Output enabled when selected jack detection
input is logic 0.
[0]= OUT1_EN_0
Output
Switching
(Jack Detect)
[1]= OUT2_EN_0
[2]= OUT3_EN_0
[3]= OUT4_EN_0
14 (0Eh)
8
HPFEN
1
7
HPFAPP
0
High Pass Filter Enable
0=disabled
1=enabled
Analogue to
Digital
Converter
(ADC)
Select audio mode or application mode
Analogue to
Digital
Converter
(ADC)
st
0=Audio mode (1 order, fc = ~3.7Hz)
nd
1=Application mode (2 order, fc = HPFCUT)
6:4
HPFCUT /
OPCLKDIV
000
Application mode cut-off frequency
Analogue to
Digital
Converter
(ADC)
See Table 16 for details.
General
Purpose
Input/Output
(GPIO)
PLL Output Clock Division Ratio
00 = divide by 1
01 = divide by 2
10 = divide by 3
11 = divide by 4
Note: HPCUT and OPCLKDIV cannot be set
independently
3
ADCOSR
0
128
ADC oversample rate select
0 = 64x (lowest power)
Power
Management
1 = 128x (best SNR)
2
1
0
ADCRPOL
0
Reserved. Initialise to 0
ADC right channel polarity adjust:
0=normal
1=inverted
w
Analogue to
Digital
Converter
(ADC)
PD, Rev 4.7, February 2012
99
WM8985
REGISTER
ADDRESS
Production Data
BIT
0
LABEL
ADCLPOL
DEFAULT
0
DESCRIPTION
REFER TO
ADC left channel polarity adjust:
Analogue to
Digital
Converter
(ADC)
0=normal
1=inverted
15 (0Fh)
8
ADCVU
N/A
7:0
ADCVOLL
11111111
ADC left and ADC right volume do not update
until a 1 is written to ADCVU (in reg 16 or 17)
Analogue to
Digital
Converter
(ADC)
Left ADC Digital Volume Control
Analogue to
Digital
Converter
(ADC)
0000 0000 = Digital Mute
0000 0001 = -127dB
0000 0010 = -126.5dB
... 0.5dB steps up to
1111 1111 = 0dB
16 (10h)
8
ADCVU
N/A
7:0
ADCVOLR
11111111
ADC left and ADC right volume do not update
until a 1 is written to ADCVU (in reg 16 or 17)
Analogue to
Digital
Converter
(ADC)
Right ADC Digital Volume Control
Analogue to
Digital
Converter
(ADC)
0000 0000 = Digital Mute
0000 0001 = -127dB
0000 0010 = -126.5dB
... 0.5dB steps up to
1111 1111 = 0dB
18 (12h)
8
EQ3DMODE
1
0 = Equaliser and 3D Enhancement applied to
ADC path
Output Signal
Path
1 = Equaliser and 3D Enhancement applied to
DAC path
7
6:5
EQ1C
0
Reserved. Initialise to 0
01
EQ Band 1 Cut-off Frequency:
Output Signal
Path
00=80Hz
01=105Hz
10=135Hz
11=175Hz
19 (13h)
4:0
EQ1G
01100
8
EQ2BW
0
EQ Band 1 Gain Control. See Table 31 for
details.
Output Signal
Path
EQ Band 2 Bandwidth Control
Output Signal
Path
0=narrow bandwidth
1=wide bandwidth
7
6:5
0
EQ2C
01
Reserved. Initialise to 0
Output Signal
Path
EQ Band 2 Centre Frequency:
00=230Hz
01=300Hz
10=385Hz
11=500Hz
20 (14h)
4:0
EQ2G
01100
8
EQ3BW
0
EQ Band 2 Gain Control. See Table 31 for
details.
Output Signal
Path
EQ Band 3 Bandwidth Control
Output Signal
Path
0=narrow bandwidth
1=wide bandwidth
7
w
0
Reserved. Initialise to 0
PD, Rev 4.7, February 2012
100
WM8985
Production Data
REGISTER
ADDRESS
BIT
6:5
LABEL
EQ3C
DEFAULT
01
DESCRIPTION
REFER TO
Output Signal
Path
EQ Band 3 Centre Frequency:
00=650Hz
01=850Hz
10=1.1kHz
11=1.4kHz
21 (15h)
4:0
EQ3G
01100
8
EQ4BW
0
EQ Band 3 Gain Control. See Table 31 for
details.
Output Signal
Path
EQ Band 4 Bandwidth Control
Output Signal
Path
0=narrow bandwidth
1=wide bandwidth
7
6:5
EQ4C
0
Reserved. Initialise to 0
01
EQ Band 4 Centre Frequency:
Output Signal
Path
00=1.8kHz
01=2.4kHz
10=3.2kHz
11=4.1kHz
4:0
22 (16h)
EQ4G
8:7
6:5
EQ5C
01100
EQ Band 4 Gain Control. See Table 31 for
details.
Output Signal
Path
0
Reserved. Initialise to 0
Output Signal
Path
01
EQ Band 5 Cut-off Frequency:
Output Signal
Path
00=5.3kHz
01=6.9kHz
10=9kHz
11=11.7kHz
23 (17h)
4:0
EQ5G
01100
EQ Band 5 Gain Control. See Table 31 for
details.
Output Signal
Path
8
CLASSDEN
0
Enable signal for class D mode on LOUT2 and
ROUT2
Class D
Control
0 = Class AB mode
1 = Class D mode
7:0
24 (18h)
000 1000
Reserved.
8
LIMEN
0
Enable the DAC digital limiter:
0=disabled
1=enabled
Output Signal
Path
7:4
LIMDCY
0011
DAC Limiter Decay time (per 6dB gain change)
for 44.1kHz sampling. Note that these will scale
Output Signal
Path
with sample rate:
0000=750us
0001=1.5ms
0010=3ms
0011=6ms
0100=12ms
0101=24ms
0110=48ms
0111=96ms
1000=192ms
1001=384ms
1010=768ms
w
PD, Rev 4.7, February 2012
101
WM8985
REGISTER
ADDRESS
Production Data
BIT
3:0
LABEL
LIMATK
DEFAULT
0010
DESCRIPTION
REFER TO
DAC Limiter Attack time (per 6dB gain change)
for 44.1kHz sampling. Note that these will scale
with sample rate.
Output Signal
Path
0000=94us
0001=188s
0010=375us
0011=750us
0100=1.5ms
0101=3ms
0110=6ms
0111=12ms
1000=24ms
1001=48ms
1010=96ms
1011 to 1111=192ms
25 (19h)
8:7
6:4
LIMLVL
00
Reserved. Initialise to 0
000
Programmable signal threshold level
(determines level at which the DAC limiter starts
Output Signal
Path
to operate)
000=-1dB
001=-2dB
010=-3dB
011=-4dB
100=-5dB
101 to 111=-6dB
3:0
LIMBOOST
0000
DAC Limiter volume boost (can be used as a
stand alone volume boost when LIMEN=0):
Output Signal
Path
0000=0dB
0001=+1dB
0010=+2dB
… (1dB steps)
1011=+11dB
1100=+12dB
1101 to 1111=reserved
27 (1Bh)
28 (1Ch)
8
NFU
0
Notch filter update. The notch filter values used
internally only update when one of the NFU bits
is set high.
Analogue to
Digital
Converter
(ADC)
7
NFEN
0
Notch filter enable:
0=Disabled
1=Enabled
Analogue to
Digital
Converter
(ADC)
6:0
NFA0[13:7]
0000000
Notch Filter a0 coefficient, bits [13:7]
Analogue to
Digital
Converter
(ADC)
8
NFU
0
Notch filter update. The notch filter values used
internally only update when one of the NFU bits
is set high.
Analogue to
Digital
Converter
(ADC)
0
Reserved. Initialise to 0
0000000
Notch Filter a0 coefficient, bits [6:0]
7
6:0
NFA0[6:0]
w
Analogue to
Digital
Converter
(ADC)
PD, Rev 4.7, February 2012
102
WM8985
Production Data
REGISTER
ADDRESS
29 (1Dh)
BIT
8
LABEL
NFU
7
30 (1Eh)
DESCRIPTION
REFER TO
0
Notch filter update. The notch filter values used
internally only update when one of the NFU bits
is set high.
0
Reserved. Initialise to 0
Analogue to
Digital
Converter
(ADC)
6:0
NFA1[13:7]
0000000
Notch Filter a1 coefficient, bits [13:7]
Analogue to
Digital
Converter
(ADC)
8
NFU
0
Notch filter update. The notch filter values used
internally only update when one of the NFU bits
is set high.
Analogue to
Digital
Converter
(ADC)
7
32 (20h)
DEFAULT
0
Reserved. Initialise to 0
6:0
NFA1[6:0]
0000000
Notch Filter a1 coefficient, bits [6:0]
Analogue to
Digital
Converter
(ADC)
8:7
ALCSEL
00
ALC function select:
Input Limiter/
Automatic
Level Control
(ALC)
00=ALC off
01=ALC right only
10=ALC left only
11=ALC both on
6
5:3
ALCMAXGAIN
0
Reserved. Initialise to 0
111
Set Maximum Gain of PGA
Input Limiter/
Automatic
Level Control
(ALC)
111=+35.25dB
110=+29.25dB
101=+23.25dB
100=+17.25dB
011=+11.25dB
010=+5.25dB
001=-0.75dB
000=-6.75dB
2:0
ALCMINGAIN
000
Input Limiter/
Automatic
Level Control
(ALC)
Set minimum gain of PGA
000=-12dB
001=-6dB
010=0dB
011=+6dB
100=+12dB
101=+18dB
110=+24dB
111=+30dB
33 (21h)
7:4
ALCHLD
0000
Input Limiter/
Automatic
Level Control
(ALC)
ALC hold time before gain is increased.
0000 = 0ms
0001 = 2.67ms
0010 = 5.33ms
… (time doubles with every step)
1111 = 43.691s
3:0
ALCLVL
1011
ALC target – sets signal level at ADC input
1111 : -1.5dBFS
1110 : -1.5dBFS
1101 : -3dBFS
1100 : -4.5I...... (-1.5dB steps)
0001 : -21dBFS
Input Limiter/
Automatic
Level Control
(ALC)
0000 : -22.5dBFS
w
PD, Rev 4.7, February 2012
103
WM8985
REGISTER
ADDRESS
34 (22h)
Production Data
BIT
8
LABEL
ALCMODE
DEFAULT
0
DESCRIPTION
REFER TO
Determines the ALC mode of operation:
Input Limiter/
Automatic
Level Control
(ALC)
0=ALC mode
1=Limiter mode
7:4
ALCDCY
0011
[3:0]
Decay (gain ramp-up) time
(ALCMODE ==0)
Per step
Per 6dB
90% of range
0000
410us
3.3ms
24ms
0001
820us
6.6ms
48ms
0010
1.64ms
13.1ms
192ms
Input Limiter/
Automatic
Level Control
(ALC)
… (time doubles with every step)
1010
or
higher
0011
420ms
3.36s
24.576s
Decay (gain ramp-up) time
(ALCMODE ==1)
Per step
Per 6dB
90% of range
0000
90.8us
726.4us
5.26ms
0001
181.6us
1.453ms
10.53ms
0010
363.2us
2.905ms
21.06ms
… (time doubles with every step)
1010
3:0
ALCATK
0010
93ms
744ms
5.39s
ALC attack (gain ramp-down) time
(ALCMODE == 0)
Per step
Per 6dB
90% of range
0000
104us
832us
6ms
0001
208us
1.664ms
12ms
0010
416us
3.328ms
24.1ms
Input Limiter/
Automatic
Level Control
(ALC)
… (time doubles with every step)
1010
or
higher
0010
106ms
852ms
6.18s
ALC attack (gain ramp-down) time
(ALCMODE == 1)
Per step
Per 6dB
90% of range
0000
22.7us
182.4us
1.31ms
0001
45.4us
363.2us
2.62ms
0010
90.8us
726.4us
5.26ms
… (time doubles with every step)
1010
35 (23h)
8:4
3
00000
NGEN
0
23.2ms
186ms
ALC Noise gate function enable
1 = enable
0 = disable
2:0
NGTH
000
1.348s
Reserved. Initialise to 0
ALC Noise gate threshold:
000=-39dB
001=-45dB
010=-51db
Input Limiter/
Automatic
Level Control
(ALC)
Input Limiter/
Automatic
Level Control
(ALC)
… (6dB steps)
111=-81dB
36 (24h)
8:5
w
0000
Reserved. Initialise to 0
PD, Rev 4.7, February 2012
104
WM8985
Production Data
REGISTER
ADDRESS
BIT
4
LABEL
PLLPRESCALE
DEFAULT
0
DESCRIPTION
REFER TO
0 = MCLK input not divided (default)
1 = Divide MCLK by 2 before input to PLL
3:0
PLLN[3:0]
1000
000
Reserved. Initialise to 0
5:0
PLLK[23:18]
01100
Fractional (K) part of PLL1 input/output
frequency ratio (treat as one 24-digit binary
number).
Master Clock
and Phase
Locked Loop
(PLL)
38 (26h)
8:0
PLLK[17:9]
010010011
Fractional (K) part of PLL1 input/output
frequency ratio (treat as one 24-digit binary
number).
Master Clock
and Phase
Locked Loop
(PLL)
39 (27h)
8:0
PLLK[8:0]
011101001
Fractional (K) part of PLL1 input/output
frequency ratio (treat as one 24-digit binary
number).
Master Clock
and Phase
Locked Loop
(PLL)
00000
Reserved. Initialise to 0
DEPTH3D
0000
Stereo depth
37 (25h)
41 (29h)
8:6
8:4
3:0
Integer (N) part of PLL input/output frequency
ratio. Use values greater than 5 and less than
13.
Master Clock
and Phase
Locked Loop
(PLL)
Master Clock
and Phase
Locked Loop
(PLL)
3D Stereo
Enhancement
0000: 0% (minimum 3D effect)
0001: 6.67%
....
1110: 93.3%
1111: 100% (maximum 3D effect)
42 (2Ah)
8:6
OUT4_2ADCVOL
000
Controls the OUT4 to ADC input boost stage:
000 = Path disabled (disconnected)
Analogue
Outputs
001 = -12dB gain
010 = -9dB gain
011 = -6dB gain
100 = -3dB gain
101 = +0dB gain
110 = +3dB gain
111 = +6dB gain
5
OUT4_2LNR
0
OUT4 to L or R ADC input
0 = Right ADC input
1 = Left ADC input
4:3
2
00
POBCTRL
0
Reserved. Initialise to 0
VMID independent current bias control
0 = Disable VMID independent current bias
1 = Enable VMID independent current bias
1:0
43 (2Bh)
8
BYPL2RMIX
00
Reserved. Initialise to 0
0
Left bypass path (from the Left channel input
PGA stage) to right output mixer
Analogue
Outputs
0 = not selected
1 = selected
7
BYPR2LMIX
0
Right bypass path (from the right channel input
PGA stage) to Left output mixer
Analogue
Outputs
0 = not selected
1 = selected
6
0
Reserved. Initialise to 0
5
0
Reserved. Initialise to 0
4
0
Reserved. Initialise to 0
w
PD, Rev 4.7, February 2012
105
WM8985
REGISTER
ADDRESS
44 (2Ch)
Production Data
BIT
LABEL
DEFAULT
DESCRIPTION
3:1
000
Reserved. Initialise to 000
0
0
Reserved. Initialise to 0
8
MBVSEL
0
REFER TO
Microphone Bias Voltage Control
Input Signal
Path
0 = 0.9 * AVDD
1 = 0.65 * AVDD
7
6
R2_2INPPGA
0
Reserved. Initialise to 0
0
Connect R2 pin to right channel input PGA
positive terminal.
Input Signal
Path
0=R2 not connected to input PGA
1=R2 connected to input PGA amplifier positive
terminal (constant input impedance).
5
RIN2INPPGA
1
Connect RIN pin to right channel input PGA
negative terminal.
Input Signal
Path
0=RIN not connected to input PGA
1=RIN connected to right channel input PGA
amplifier negative terminal.
4
RIP2INPPGA
1
Connect RIP pin to right channel input PGA
amplifier positive terminal.
Input Signal
Path
0 = RIP not connected to input PGA
1 = right channel input PGA amplifier positive
terminal connected to RIP (constant input
impedance)
3
2
L2_2INPPGA
0
Reserved. Initialise to 0
0
Connect L2 pin to left channel input PGA
positive terminal.
Input Signal
Path
0=L2 not connected to input PGA
1=L2 connected to input PGA amplifier positive
terminal (constant input impedance).
1
LIN2INPPGA
1
Connect LIN pin to left channel input PGA
negative terminal.
Input Signal
Path
0=LIN not connected to input PGA
1=LIN connected to input PGA amplifier negative
terminal.
0
LIP2INPPGA
1
Connect LIP pin to left channel input PGA
amplifier positive terminal.
Input Signal
Path
0 = LIP not connected to input PGA
1 = input PGA amplifier positive terminal
connected to LIP (constant input impedance)
45 (2Dh)
8
INPPGAU
N/A
7
INPPGAZCL
0
INPPGAVOLL and INPPGAVOLR volume do not
update until a 1 is written to INPPGAUPDATE (in
reg 45 or 46)
Input Signal
Path
Left channel input PGA zero cross enable:
Input Signal
Path
0=Update gain when gain register changes
st
1=Update gain on 1 zero cross after gain
register write.
6
INPPGAMUTEL
0
Mute control for left channel input PGA:
0=Input PGA not muted, normal operation
Input Signal
Path
1=Input PGA muted (and disconnected from the
following input BOOST stage).
5:0
INPPGAVOLL
010000
Left channel input PGA volume
000000 = -12dB
Input Signal
Path
000001 = -11.25db
.
010000 = 0dB
.
111111 = 35.25dB
w
PD, Rev 4.7, February 2012
106
WM8985
Production Data
REGISTER
ADDRESS
46 (2Eh)
BIT
LABEL
DEFAULT
8
INPPGAU
N/A
7
INPPGAZCR
0
DESCRIPTION
REFER TO
INPPGAVOLL and INPPGAVOLR volume do not
update until a 1 is written to INPPGAUPDATE (in
reg 45 or 46)
Input Signal
Path
Right channel input PGA zero cross enable:
Input Signal
Path
0=Update gain when gain register changes
st
1=Update gain on 1 zero cross after gain
register write.
6
INPPGAMUTER
0
Mute control for right channel input PGA:
0=Input PGA not muted, normal operation
Input Signal
Path
1=Input PGA muted (and disconnected from the
following input BOOST stage).
5:0
INPPGAVOLR
010000
Input Signal
Path
Right channel input PGA volume
000000 = -12dB
000001 = -11.25db
.
010000 = 0dB
.
111111 = +35.25dB
47 (2Fh)
8
PGABOOSTL
1
Boost enable for left channel input PGA:
0 = PGA output has +0dB gain through input
BOOST stage.
Input Signal
Path
1 = PGA output has +20dB gain through input
BOOST stage.
7
6:4
L2_2BOOSTVOL
0
Reserved. Initialise to 0
000
Controls the L2 pin to the left channel input
boost stage:
Input Signal
Path
000=Path disabled (disconnected)
001=-12dB gain through boost stage
010=-9dB gain through boost stage
…
111=+6dB gain through boost stage
3
2:0
AUXL2BOOSTVOL
0
Reserved. Initialise to 0
000
Controls the auxiliary amplifier to the left channel
input boost stage:
Input Signal
Path
000=Path disabled (disconnected)
001=-12dB gain through boost stage
010=-9dB gain through boost stage
…
111=+6dB gain through boost stage
48 (30h)
8
PGABOOSTR
1
Boost enable for right channel input PGA:
0 = PGA output has +0dB gain through input
BOOST stage.
Input Signal
Path
1 = PGA output has +20dB gain through input
BOOST stage.
7
6:4
R2_2BOOSTVOL
0
Reserved. Initialise to 0
000
Controls the R2 pin to the right channel input
boost stage:
Input Signal
Path
000=Path disabled (disconnected)
001=-12dB gain through boost stage
010=-9dB gain through boost stage
…
111=+6dB gain through boost stage
3
w
0
Reserved. Initialise to 0
PD, Rev 4.7, February 2012
107
WM8985
REGISTER
ADDRESS
Production Data
BIT
2:0
LABEL
AUXR2BOOSTVOL
DEFAULT
000
DESCRIPTION
REFER TO
Controls auxiliary amplifier to the right channel
input boost stage:
Input Signal
Path
000=Path disabled (disconnected)
001=-12dB gain through boost stage
010=-9dB gain through boost stage
…
111=+6dB gain through boost stage
49 (31h)
8:7
6
00
DACL2RMIX
0
Reserved. Initialise to 0
Left DAC output to right output mixer
Analogue
Outputs
0 = not selected
1 = selected
5
DACR2LMIX
0
Right DAC output to left output mixer
Analogue
Outputs
0 = not selected
1 = selected
4:3
2
00
TSOPCTRL
0
Reserved. Initialise to 0
Analogue
Outputs
Thermal Shutdown Output enable
0 = Disabled
1 = Enabled, i.e. all outputs will be disabled if TI
set and the device junction temperature is more
than 125ºC.
1
TSDEN
1
Analogue
Outputs
Thermal Shutdown Enable
0 : thermal shutdown disabled
1 : thermal shutdown enabled
0
VROI
0
VREF (AVDD/2 or 1.5xAVDD/2) to analogue
output resistance
Analogue
Outputs
0: approx 1k
1: approx 30 k
50 (32h)
8:6
AUXLMIXVOL
000
Aux left channel input to left mixer volume
control:
Analogue
Outputs
000 = -15dB
001 = -12dB
…
101 = 0dB
110 = +3dB
111 = +6dB
5
AUXL2LMIX
0
Left auxiliary input to left channel output mixer:
0 = not selected
Analogue
Outputs
1 = selected
4:2
BYPLMIXVOL
000
Left bypass volume control to output channel
mixer:
Analogue
Outputs
000 = -15dB
001 = -12dB
…
101 = 0dB
110 = +3dB
111 = +6dB
1
BYPL2L
0
MIX
Left bypass path (from the left channel input
boost output) to left output mixer
Analogue
Outputs
0 = not selected
1 = selected
0
DACL2L
MIX
1
Left DAC output to left output mixer
0 = not selected
Analogue
Outputs
1 = selected
w
PD, Rev 4.7, February 2012
108
WM8985
Production Data
REGISTER
ADDRESS
51 (33h)
BIT
8:6
LABEL
AUXRMIXVOL
DEFAULT
000
DESCRIPTION
REFER TO
Aux right channel input to right mixer volume
control:
Analogue
Outputs
000 = -15dB
001 = -12dB
…
101 = 0dB
110 = +3dB
111 = +6dB
5
AUXR2RMIX
0
Right Auxiliary input to right channel output
mixer:
Analogue
Outputs
0 = not selected
1 = selected
4:2
BYPRMIXVOL
000
Right bypass volume control to output channel
mixer:
Analogue
Outputs
000 = -15dB
001 = -12dB
…
101 = 0dB
110 = +3dB
111 = +6dB
1
BYPR2RMIX
0
Right bypass path (from the right channel input
boost output) to right output mixer
Analogue
Outputs
0 = not selected
1 = selected
0
DACR2RMIX
1
Right DAC output to right output mixer
Analogue
Outputs
0 = not selected
1 = selected
52 (34h)
8
OUT1VU
N/A
7
LOUT1ZC
0
LOUT1 and ROUT1 volumes do not update until
a 1 is written to OUT1VU (in reg 52 or 53)
Analogue
Outputs
Headphone volume zero cross enable:
Analogue
Outputs
1 = Change gain on zero cross only
0 = Change gain immediately
6
LOUT1MUTE
0
Left headphone output mute:
Analogue
Outputs
0 = Normal operation
1 = Mute
5:0
LOUT1VOL
111001
Analogue
Outputs
Left headphone output volume:
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
53 (35h)
8
OUT1VU
N/A
7
ROUT1ZC
0
LOUT1 and ROUT1 volumes do not update until
a 1 is written to OUT1VU (in reg 52 or 53)
Analogue
Outputs
Headphone volume zero cross enable:
Analogue
Outputs
1 = Change gain on zero cross only
0 = Change gain immediately
6
ROUT1MUTE
0
Right headphone output mute:
0 = Normal operation
Analogue
Outputs
1 = Mute
w
PD, Rev 4.7, February 2012
109
WM8985
REGISTER
ADDRESS
Production Data
BIT
5:0
LABEL
ROUT1VOL
DEFAULT
111001
DESCRIPTION
REFER TO
Analogue
Outputs
Right headphone output volume:
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
54 (36h)
8
OUT2VU
N/A
7
LOUT2ZC
0
LOUT2 and ROUT2 volumes do not update until
a 1 is written to OUT2VU (in reg 54 or 55)
Analogue
Outputs
Speaker volume zero cross enable:
Analogue
Outputs
1 = Change gain on zero cross only
0 = Change gain immediately
6
LOUT2MUTE
0
Left speaker output mute:
Analogue
Outputs
0 = Normal operation
1 = Mute
5:0
LOUT2VOL
111001
Analogue
Outputs
Left speaker output volume:
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
55 (37h)
8
OUT2VU
N/A
7
ROUT2ZC
0
LOUT2 and ROUT2 volumes do not update until
a 1 is written to OUT2VU (in reg 54 or 55)
Analogue
Outputs
Speaker volume zero cross enable:
Analogue
Outputs
1 = Change gain on zero cross only
0 = Change gain immediately
6
ROUT2MUTE
0
Right speaker output mute:
Analogue
Outputs
0 = Normal operation
1 = Mute
5:0
ROUT2VOL
111001
Analogue
Outputs
Right speaker output volume:
000000 = -57dB
...
111001 = 0dB
...
111111 = +6dB
56 (38h)
8:7
6
00
OUT3MUTE
0
Reserved
0 = Output stage outputs OUT3 mixer
1 = Output stage muted – drives out VMID. Can
be used as VMID buffer in this mode. (Not to be
used for Capless HP pseudo GND)
5:4
3
00
OUT4_2OUT3
0
Analogue
Outputs
Reserved. Initialise to 0
OUT4 mixer output to OUT3
0 = disabled
Analogue
Outputs
1= enabled
2
BYPL2OUT3
0
Left ADC input to OUT3
0 = disabled
Analogue
Outputs
1= enabled
1
LMIX2OUT3
0
Left DAC mixer to OUT3
0 = disabled
Analogue
Outputs
1= enabled
0
LDAC2OUT3
1
Left DAC output to OUT3
0 = disabled
Analogue
Outputs
1= enabled
57 (39h)
8
w
0
Reserved. Initialise to 0
PD, Rev 4.7, February 2012
110
WM8985
Production Data
REGISTER
ADDRESS
BIT
7
LABEL
OUT3_2OUT4
DEFAULT
0
DESCRIPTION
REFER TO
OUT3 mixer output to OUT4
Analogue
Outputs
0 = disabled
1 = enabled
6
OUT4MUTE
0
0 = Output stage outputs OUT4 mixer
1 = Output stage muted – drives out VMID. Can
be used as VMID buffer in this mode. (Not to be
used for Capless HP pseudo GND)
5
HALFSIG
0
0=OUT4 normal output
1=OUT4 attenuated by 6dB
4
LMIX2OUT4
0
Left DAC mixer to OUT4
0 = disabled
Analogue
Outputs
Analogue
Outputs
Analogue
Outputs
1= enabled
3
LDAC2OUT4
0
Left DAC to OUT4
0 = disabled
Analogue
Outputs
1= enabled
2
BYPR2OUT4
0
Right ADC input to OUT4
0 = disabled
Analogue
Outputs
1= enabled
1
RMIX2OUT4
0
Right DAC mixer to OUT4
0 = disabled
Analogue
Outputs
1= enabled
0
RDAC2OUT4
1
Right DAC output to OUT4
0 = disabled
Analogue
Outputs
1= enabled
61 (3Dh)
8
0
Global bias control
Bias Control
0 = normal
1 = 0.5x
7:0
w
000 0000
Reserved. Initialise to 0
PD, Rev 4.7, February 2012
111
WM8985
Production Data
DIGITAL FILTER CHARACTERISTICS
PARAMETER
TEST CONDITIONS
MIN
+/- 0.025dB
0
TYP
MAX
UNIT
ADC Filter
Passband
-6dB
0.454fs
0.5fs
Passband Ripple
+/- 0.025
Stopband
Stopband Attenuation
dB
0.546fs
f > 0.546fs
-60
Group Delay
dB
21/fs
ADC High Pass Filter
High Pass Filter Corner
Frequency
-3dB
3.7
-0.5dB
10.4
-0.1dB
21.6
Hz
DAC Filter
Passband
+/- 0.035dB
0
-6dB
0.454fs
0.5fs
Passband Ripple
+/-0.035
Stopband
Stopband Attenuation
Group Delay
dB
0.546fs
f > 0.546fs
-55
dB
29/fs
Table 54 Digital Filter Characteristics
TERMINOLOGY
1.
Stop Band Attenuation (dB) – the degree to which the frequency spectrum is attenuated (outside audio band)
2.
Pass-band Ripple – any variation of the frequency response in the pass-band region
w
PD, Rev 4.7, February 2012
112
WM8985
Production Data
DAC FILTER RESPONSES
3.05
0
3
-20
2.95
-40
Response (dB)
Response (dB)
20
-60
-80
-100
2.9
2.85
2.8
2.75
-120
2.7
-140
2.65
2.6
-160
0
0.5
1
1.5
2
0
2.5
0.05
0.1
0.15
Figure 41 DAC Digital Filter Frequency Response
(128xOSR)
0.25
0.3
0.35
0.4
0.45
0.5
0.45
0.5
Figure 42 DAC Digital Filter Ripple (128xOSR)
3.05
20
0
3
-20
2.95
-40
Response (dB)
Response (dB)
0.2
Frequency (fs)
Frequency (fs)
-60
-80
-100
2.9
2.85
2.8
2.75
-120
2.7
-140
2.65
2.6
-160
0
0.5
1
1.5
2
0
2.5
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
Frequency (fs)
Frequency (fs)
Figure 43 DAC Digital Filter Frequency Response (64xOSR)
Figure 44 DAC Digital Filter Ripple (64xOSR)
ADC FILTER RESPONSES
0.2
0
0.15
0.1
Response (dB)
Response (dB)
-20
-40
-60
-80
0.05
0
-0.05
-0.1
-100
-0.15
-0.2
-120
0
0.5
1
1.5
2
Frequency (Fs)
Figure 45 ADC Digital Filter Frequency Response
w
2.5
3
0
0.1
0.2
0.3
0.4
0.5
Frequency (Fs)
Figure 46 ADC Digital Filter Ripple
PD, Rev 4.7, February 2012
113
WM8985
Production Data
HIGHPASS FILTER
The WM8985 has a selectable digital highpass filter in the ADC filter path. This filter has two modes,
st
audio and applications. In audio mode the filter is a 1 order IIR with a cut-off of around 3.7Hz. In
nd
applications mode the filter is a 2 order high pass filter with a selectable cut-off frequency.
5
0
-5
Response (dB)
-10
-15
-20
-25
-30
-35
-40
0
5
10
15
20
25
30
35
40
45
Frequency (Hz)
Figure 47 ADC Highpass Filter Response, HPFAPP=0
10
10
0
0
-10
-20
Response (dB)
Response (dB)
-10
-20
-30
-30
-40
-50
-40
-60
-50
-70
-80
-60
0
200
400
600
800
1000
1200
0
200
400
600
800
1000
1200
Frequency (Hz)
Frequency (Hz)
Figure 48 ADC Highpass Filter Responses (48kHz),
Figure 49 ADC Highpass Filter Responses (24kHz),
HPFAPP=1, all cut-off settings shown
HPFAPP=1, all cut-off settings shown
10
0
-10
Response (dB)
-20
-30
-40
-50
-60
-70
-80
-90
0
200
400
600
800
1000
1200
Frequency (Hz)
Figure 50 ADC Highpass Filter Responses (12kHz),
HPFAPP=1, all cut-off settings shown
w
PD, Rev 4.7, February 2012
114
WM8985
Production Data
5-BAND EQUALISER
15
15
10
10
5
5
Magnitude (dB)
Magnitude (dB)
The WM8985 has a 5-band equaliser which can be applied to either the ADC path or the DAC path.
The plots from Figure 51 to Figure 64 show the frequency responses of each filter with a sampling
frequency of 48kHz, firstly showing the different cut-off/centre frequencies with a gain of 12dB, and
secondly a sweep of the gain from -12dB to +12dB for the lowest cut-off/centre frequency of each
filter.
0
-5
-5
-10
-10
-15
-1
10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
-15
-1
10
5
Figure 51 EQ Band 1 Low Frequency Shelf Filter Cut-offs
15
15
10
10
5
5
0
-5
-10
-10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
Figure 53 EQ Band 2 – Peak Filter Centre Frequencies,
EQ2BW=0
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
0
-5
-15
-1
10
10
Figure 52 EQ Band 1 Gains for Lowest Cut-off Frequency
Magnitude (dB)
Magnitude (dB)
0
-15
-1
10
Figure 54
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
EQ Band 2 – Peak Filter Gains for Lowest Cut-off
Frequency, EQ2BW=0
15
10
Magnitude (dB)
5
0
-5
-10
-15
-2
10
10
-1
10
0
1
10
Frequency (Hz)
10
2
10
3
10
4
Figure 55 EQ Band 2 – EQ2BW=0, EQ2BW=1
w
PD, Rev 4.7, February 2012
115
Production Data
15
15
10
10
5
5
Magnitude (dB)
Magnitude (dB)
WM8985
0
0
-5
-5
-10
-10
-15
-1
10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
-15
-1
10
Figure 56 EQ Band 3 – Peak Filter Centre Frequencies, EQ3B Figure 57
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
EQ Band 3 – Peak Filter Gains for Lowest Cut-off
Frequency, EQ3BW=0
15
10
Magnitude (dB)
5
0
-5
-10
-15
-2
10
10
-1
10
0
1
10
Frequency (Hz)
10
2
10
3
10
4
Figure 58 EQ Band 3 – EQ3BW=0, EQ3BW=1
w
PD, Rev 4.7, February 2012
116
WM8985
15
15
10
10
5
5
Magnitude (dB)
Magnitude (dB)
Production Data
0
0
-5
-5
-10
-10
-15
-1
10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
-15
-1
10
5
Figure 59 EQ Band 4 – Peak Filter Centre Frequencies,
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
Figure 60 EQ Band 4 – Peak Filter Gains for Lowest Cut-off
EQ3BW=0
Frequency, EQ4BW=0
15
10
Magnitude (dB)
5
0
-5
-10
-15
-2
10
10
-1
10
0
1
10
Frequency (Hz)
10
2
10
3
10
4
15
15
10
10
5
5
Magnitude (dB)
Magnitude (dB)
Figure 61 EQ Band 4 – EQ3BW=0, EQ3BW=1
0
0
-5
-5
-10
-10
-15
-1
10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
Figure 62 EQ Band 5 High Frequency Shelf Filter Cut-offs
w
-15
-1
10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
Figure 63 EQ Band 5 Gains for Lowest Cut-off Frequency
PD, Rev 4.7, February 2012
117
WM8985
Production Data
Figure 64 shows the result of having the gain set on more than one channel simultaneously. The
blue traces show each band (lowest cut-off/centre frequency) with 12dB gain. The red traces show
the cumulative effect of all bands with +12dB gain and all bands -12dB gain, with EqxBW=0 for the
peak filters.
20
15
Magnitude (dB)
10
5
0
-5
-10
-15
-1
10
10
0
10
1
2
10
Frequency (Hz)
10
3
10
4
10
5
Figure 64 Cumulative Frequency Boost/Cut
w
PD, Rev 4.7, February 2012
118
Production Data
WM8985
APPLICATIONS INFORMATION
RECOMMENDED EXTERNAL COMPONENTS
Figure 65 External Component Diagram
1.
When operating LOUT2 and ROUT2 in class D mode, it is recommended that LC filtering is placed as close to the
2.
LOUT2 and ROUT2 pins as possible. Low ESR components should be used for maximum efficiency. It is
recommended that a filter, consisting of a 33μH inductor and a 220nF capacitor, is used for optimal performance.
The addition of ferrite beads to the outputs of LOUT2 and ROUT2 will suppress any potential interference noise
produced by the class D switching clocks.
w
PD, Rev 4.7, February 2012
119
WM8985
Production Data
PACKAGE DIAGRAM
FL: 32 PIN QFN PLASTIC PACKAGE 5 X 5 X 0.9 mm BODY, 0.50 mm LEAD PITCH
DM101.A
D
DETAIL 1
D2
32
25
L
1
24
4
EXPOSED
GROUND 6
PADDLE
INDEX AREA
(D/2 X E/2)
E2
17
E
8
16
2X
15
9
b
B
e
1
bbb M C A B
2X
aaa C
aaa C
TOP VIEW
BOTTOM VIEW
ccc C
A3
A
5
0.08 C
C
A1
SIDE VIEW
SEATING PLANE
M
M
45°
DETAIL 2
0.30
EXPOSED
GROUND
PADDLE
DETAIL 1
W
Exposed lead
T
A3
G
H
b
Half etch tie bar
DETAIL 2
Symbols
A
A1
A3
b
D
D2
E
E2
e
G
H
L
T
W
MIN
0.80
0
0.18
3.30
3.30
0.30
Dimensions (mm)
NOM
MAX
NOTE
0.90
1.00
0.02
0.05
0.203 REF
1
0.25
0.30
5.00 BSC
3.45
5.00 BSC
3.45
0.50 BSC
0.20
0.1
0.40
0.103
3.60
2
3.60
2
0.50
0.15
Tolerances of Form and Position
aaa
bbb
ccc
REF:
0.15
0.10
0.10
JEDEC, MO-220, VARIATION VHHD-5.
NOTES:
1. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.15 mm AND 0.30 mm FROM TERMINAL TIP.
2. FALLS WITHIN JEDEC, MO-220, VARIATION VHHD-5.
3. ALL DIMENSIONS ARE IN MILLIMETRES.
4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL CONFORM TO JEDEC 95-1 SPP-002.
5. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.
6. REFER TO APPLICATION NOTE WAN_0118 FOR FURTHER INFORMATION REGARDING PCB FOOTPRINTS AND QFN PACKAGE SOLDERING.
7. THIS DRAWING IS SUBJECT TO CHANGE WITHOUT NOTICE.
w
PD, Rev 4.7, February 2012
120
Production Data
WM8985
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]
w
PD, Rev 4.7, February 2012
121
WM8985
Production Data
REVISION HISTORY
DATE
REV
ORIGINATOR
CHANGES
23/07/12
4.7
JMacD
Order codes changed from WM8985GEFL and WM8985GEFL/R to
WM8985CGEFL and WM8985CGEFL/R to reflect change to copper wire
bonding.
23/07/12
4.7
JMacD
Package diagram changed to DM101.A
w
PD, Rev 4.7, February 2012
122