WOLFSON WM8750JL

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WM8750JL
Stereo CODEC for Portable Audio Applications
DESCRIPTION
FEATURES
The WM8750JL is a low power, high quality stereo CODEC
designed for portable digital audio applications.

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The device integrates complete interfaces to stereo or mono
microphones and a stereo headphone. External component
requirements are drastically reduced as no separate
microphone or headphone amplifiers are required.
Advanced on-chip digital signal processing performs graphic
equaliser, 3-D sound enhancement and automatic level
control for the microphone or line input.
The WM8750JL can operate as a master or a slave, with
various master clock frequencies including 12 or 24MHz for
USB devices, or standard 256fs rates like 12.288MHz and
24.576MHz. Different audio sample rates such as 96kHz,
48kHz, 44.1kHz are generated directly from the master
clock without the need for an external PLL.
The WM8750JL operates at supply voltages down to 1.8V,
although the digital core can operate at voltages down to
1.42V to save power, and the maximum for all supplies is
3.6 Volts. Different sections of the chip can also be powered
down under software control.
The WM8750JL is supplied in a very small and thin 5x5mm
QFN package, ideal for use in hand-held and portable
systems.



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

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
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DAC SNR 97dB (‘A’ weighted), THD -85dB at 48kHz, 3.3V
ADC SNR 88dB (‘A’ weighted), THD -80dB at 48kHz, 3.3V
Complete Stereo / Mono Microphone Interface
- Programmable ALC (timed out) / Noise Gate
On-chip 400mW BTL Speaker Driver (mono)
On-chip Headphone Driver
- >40mW output power on 16 / 3.3V
- THD –73dB at 5mW, SNR 98dB with 16 load
- No DC blocking capacitors required (capless mode)
Separately mixed mono output
Digital Graphic Equaliser
Low Power
- 6 mW stereo playback (1.8V / 1.5V supplies)
- 13 mW record & playback (1.8V / 1.5V supplies)
Low Supply Voltages
- Analogue 1.8V to 3.6V
- Digital core: 1.42V to 3.6V
- Digital I/O: 1.8V to 3.6V
256fs / 384fs or USB master clock rates: 12MHz, 24MHz
Audio sample rates: 8, 11.025, 16, 22.05, 24, 32, 44.1, 48,
88.2, 96kHz generated internally from master clock
5x5x0.9mm QFN package
APPLICATIONS



Portable Media Player
Mobile phone handsets
Mobile gaming
BLOCK DIAGRAM
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Production Data, April 2012, Rev 4.1
Copyright 2012 Wolfson Microelectronics plc
WM8750JL
Production Data
TABLE OF CONTENTS
DESCRIPTION ................................................................................................................... 1 FEATURES ......................................................................................................................... 1 APPLICATIONS ................................................................................................................. 1 BLOCK DIAGRAM ............................................................................................................. 1 TABLE OF CONTENTS ..................................................................................................... 2 PIN CONFIGURATION ....................................................................................................... 3 ORDERING INFORMATION .............................................................................................. 3 PIN DESCRIPTION ............................................................................................................ 4 ABSOLUTE MAXIMUM RATINGS..................................................................................... 5 RECOMMENDED OPERATION CONDITIONS ................................................................. 5 ELECTRICAL CHARACTERISTICS .................................................................................. 6 TYPICAL PERFORMANCE................................................................................................ 8 POWER CONSUMPTION............................................................................................................... 8 OUTPUT DRIVERS ........................................................................................................................ 9 OUTPUT PGA’S LINEARITY ........................................................................................................ 10 SIGNAL TIMING REQUIREMENTS ................................................................................. 11 SYSTEM CLOCK TIMING ............................................................................................................ 11 AUDIO INTERFACE TIMING – MASTER MODE ......................................................................... 11 AUDIO INTERFACE TIMING – SLAVE MODE ............................................................................ 12 CONTROL INTERFACE TIMING – 3-WIRE MODE ..................................................................... 13 CONTROL INTERFACE TIMING – 2-WIRE MODE ..................................................................... 14 INTERNAL POWER ON RESET CIRCUIT ...................................................................... 15 DEVICE DESCRIPTION ................................................................................................... 16 INTRODUCTION ........................................................................................................................... 16 INPUT SIGNAL PATH ................................................................................................................... 16 AUTOMATIC LEVEL CONTROL (ALC)........................................................................................ 23 OUTPUT SIGNAL PATH............................................................................................................... 27 ANALOGUE OUTPUTS ................................................................................................................ 32 ENABLING THE OUTPUTS.......................................................................................................... 34 HEADPHONE SWITCH ................................................................................................................ 34 THERMAL SHUTDOWN ............................................................................................................... 36 HEADPHONE OUTPUT................................................................................................................ 36 DIGITAL AUDIO INTERFACE ...................................................................................................... 37 AUDIO INTERFACE CONTROL ................................................................................................... 42 CLOCKING AND SAMPLE RATES .............................................................................................. 44 CONTROL INTERFACE ............................................................................................................... 46 POWER SUPPLIES ...................................................................................................................... 47 POWER MANAGEMENT .............................................................................................................. 47 REGISTER MAP ............................................................................................................... 50 DIGITAL FILTER CHARACTERISTICS ........................................................................... 51 TERMINOLOGY ............................................................................................................................ 51 DAC FILTER RESPONSES .......................................................................................................... 52 ADC FILTER RESPONSES .......................................................................................................... 53 DE-EMPHASIS FILTER RESPONSES ........................................................................................ 54 HIGHPASS FILTER ...................................................................................................................... 55 APPLICATIONS INFORMATION ..................................................................................... 56 RECOMMENDED EXTERNAL COMPONENTS .......................................................................... 56 LINE INPUT CONFIGURATION ................................................................................................... 57 MICROPHONE INPUT CONFIGURATION .................................................................................. 57 MINIMISING POP NOISE AT THE ANALOGUE OUTPUTS ........................................................ 57 POWER MANAGEMENT EXAMPLES ......................................................................................... 58 IMPORTANT NOTICE ...................................................................................................... 60 ADDRESS ..................................................................................................................................... 60 REVISION HISTORY ........................................................................................................ 61 w
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PIN CONFIGURATION
ORDERING INFORMATION
ORDER CODE
TEMPERATURE
RANGE
PACKAGE
MOISTURE
SENSITIVITY LEVEL
PEAK SOLDERING
TEMPERATURE
WM8750CJLGEFL
-25C to +85C
32-lead QFN (5x5x0.9mm)
(Pb-free)
MSL1
260 C
WM8750CJLGEFL/R
-25C to +85C
32-lead QFN (5x5x0.9mm)
(Pb-free, tape and reel)
MSL1
260 C
o
o
Note:
Reel quantity = 3500
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PIN DESCRIPTION
PIN NO
NAME
1
MCLK
2
TYPE
DESCRIPTION
Digital Input
Master Clock
DCVDD
Supply
Digital Core Supply
3
DBVDD
Supply
Digital Buffer (I/O) Supply
4
DGND
Supply
Digital Ground (return path for both DCVDD and DBVDD)
5
BCLK
Digital Input / Output
Audio Interface Bit Clock
6
DACDAT
Digital Input
DAC Digital Audio Data
7
DACLRC
Digital Input / Output
Audio Interface Left / Right Clock/Clock Out
8
ADCDAT
Digital Output
ADC Digital Audio Data
9
ADCLRC
Digital Input / Output
Audio Interface Left / Right Clock
10
MONOOUT
Analogue Output
Mono Output
11
OUT3
Analogue Output
Analogue Output 3 (can be used as Headphone Pseudo Ground)
12
ROUT1
Analogue Output
Right Output 1 (Line or Headphone)
13
LOUT1
Analogue Output
Left Output 1 (Line or Headphone)
14
HPGND
Supply
Supply for Analogue Output Drivers (LOUT1/2, ROUT1/2)
15
ROUT2
Analogue Output
Right Output 1 (Line or Headphone or Speaker)
16
LOUT2
Analogue Output
Left Output 1 (Line or Headphone or Speaker)
HPVDD
Supply
Supply for Analogue Output Drivers (LOUT1/2, ROUT1/2, MONOUT)
18
AVDD
Supply
Analogue Supply
19
AGND
Supply
Analogue Ground (return path for AVDD)
20
VREF
Analogue Output
Reference Voltage Decoupling Capacitor
21
VMID
Analogue Output
Midrail Voltage Decoupling Capacitor
22
MICBIAS
Analogue Output
Microphone Bias
23
RINPUT3 /
HPDETECT
Analogue Input
Right Channel Input 3 or Headphone Plug-in Detection
24
LINPUT3
Analogue Input
Left Channel Input 3
25
RINPUT2
Analogue Input
Right Channel Input 2
26
LINPUT2
Analogue Input
Left Channel Input 2
27
RINPUT1
Analogue Input
Right Channel Input 1
28
LINPUT1
Analogue Input
Left Channel Input 1
29
MODE
Digital Input
Control Interface Selection
30
CSB
Digital Input
Chip Select / Device Address Selection
31
32
SDIN
SCLK
Digital Input/Output
Digital Input
Control Interface Data Input / 2-wire Acknowledge output
Control Interface Clock Input
17
Note:
It is recommended that the QFN ground paddle should be connected to analogue ground on the application PCB.
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ABSOLUTE MAXIMUM RATINGS
Absolute Maximum Ratings are stress ratings only. Permanent damage to the device may be caused by continuously
operating at or beyond these limits. Device functional operating limits and guaranteed performance specifications are given
under Electrical Characteristics at the test conditions specified.
ESD Sensitive Device. This device is manufactured on a CMOS process. It is therefore generically susceptible
to damage from excessive static voltages. Proper ESD precautions must be taken during handling and storage
of this device.
Wolfson tests its package types according to IPC/JEDEC J-STD-020B for Moisture Sensitivity to determine acceptable storage
conditions prior to surface mount assembly. These levels are:
MSL1 = unlimited floor life at <30C / 85% Relative Humidity. Not normally stored in moisture barrier bag.
MSL2 = out of bag storage for 1 year at <30C / 60% Relative Humidity. Supplied in moisture barrier bag.
MSL3 = out of bag storage for 168 hours at <30C / 60% Relative Humidity. Supplied in moisture barrier bag.
The Moisture Sensitivity Level for each package type is specified in Ordering Information.
CONDITION
MIN
MAX
-0.3V
+3.63V
Voltage range digital inputs
DGND -0.3V
DBVDD +0.3V
Voltage range analogue inputs
AGND -0.3V
AVDD +0.3V
Operating temperature range, TA
-25C
+85C
Storage temperature after soldering
-65C
+150C
Supply voltages
Notes
1.
Analogue and digital grounds must always be within 0.3V of each other.
2.
All digital and analogue supplies are independent of each other.
3.
DCVDD must be less than or equal to AVDD and DBVDD.
RECOMMENDED OPERATION CONDITIONS
PARAMETER
SYMBOL
MIN
MAX
UNIT
Digital supply range (Core)
DCVDD
1.42
3.6
V
DBVDD
1.7
3.6
V
AVDD, HPVDD
1.8
3.6
V
Digital supply range (Buffer)
Analogue supplies range
Ground
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DGND,AGND, HPGND
TYP
0
V
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ELECTRICAL CHARACTERISTICS
Test Conditions
o
DCVDD = 1.5V, DBVDD = 3.3V, AVDD = HPVDD = 3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, ADCOSR=1, DACOSR=1,
PGA gain = 0dB, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Analogue Inputs (LINPUT1, RINPUT1, LINPUT2, RINPUT2, LINPUT3, RINPUT3) to ADC out
Full Scale Input Signal Level
AVDD/3.3
V rms
PGA gain=0dB into ADC
22
k
PGA gain=+30dB into
ADC
1.5
DC Measurement from
L/RINPUT1
16
input pin unused
17
VINFS
(for ADC 0dB Input at 0dB Gain)
Input Resistance
Pins LINPUT1/2/3, RINPUT1/2/3
Input Capacitance
Signal to Noise Ratio
SNR
AVDD = 3.3V
(A-weighted)
80
10
pF
88
dB
ADCOSR=1
AVDD = 3.3V
95
ADCOSR=0
AVDD = 1.8V
85
ADCOSR=1
AVDD = 1.8V
90
ADCOSR=0
Total Harmonic Distortion
THD
-1dBFs input,
-80
dB
AVDD = 3.3V
0.01
%
-1dBFs input,
-74
AVDD = 1.8V
0.02
ADC Channel Separation
1kHz signal
Channel Matching
1kHz signal
85
-0.5
dB
0.5
dB
Analogue Outputs (LOUT1/2, ROUT1/2, MONOOUT)
0dB Full scale output voltage
AVDD/3.3
Mute attenuation
Vrms
1kHz, full scale signal
90
MONOOUT pin
81
analogue in
85
dB
97
dB
Channel Separation
dB
to analogue out
DAC to Line-Out (L/ROUT2 with 10k / 50pF load)
Signal to Noise Ratio
SNR
(A-weighted)
Total Harmonic Distortion
THD
Channel Separation
AVDD=3.3V
90
AVDD=1.8V
94
AVDD=3.3V
-85
AVDD=1.8V
-79
1kHz signal
100
dB
dB
Headphone Output (LOUT1/ROUT1, using capacitors)
Output Power per channel
Total Harmonic Distortion plus
Noise
Signal to Noise Ratio
(A-weighted)
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PO
THD+N
SNR
Output power is very closely correlated with THD; see below.
HPVDD=1.8V, RL=32
0.02
%
PO=5mW
-73
dB
HPVDD=1.8V, RL=16
0.03
PO=5mW
-70
HPVDD=3.3V, RL=32,
PO=5mW
0.015
HPVDD=3.3V, RL=16,
PO=5mW
0.02
HPVDD = 3.3V
HPVDD = 1.8V
-76
-73
90
98
dB
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WM8750JL
Production Data
Test Conditions
o
DCVDD = 1.5V, DBVDD = 3.3V, AVDD = HPVDD = 3.3V, TA = +25 C, 1kHz signal, fs = 48kHz, ADCOSR=1, DACOSR=1,
PGA gain = 0dB, 24-bit audio data unless otherwise stated.
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Speaker Output (LOUT2/ROUT2 with 8 bridge tied load, ROUT2INV=1)
Output Power at 1% THD
Maximum Achievable Output
Power
Total Harmonic Distortion
Signal to Noise Ratio
PO
THD = 1%
330
mW (rms)
POmax
AVDD=HPVDD=3.3V,
RL=8
400
mW (rms)
THD
Po=200mW, RL=8,
HPVDD=3.3V
-60
dB
0.1
%
HPVDD=3.3V, RL=8
95
dB
SNR
(A-weighted)
Analogue Reference Levels
Midrail Reference Voltage
VMID
–3%
AVDD/2
+3%
V
Buffered Reference Voltage
VREF
–3%
AVDD/2
+3%
V
–5%
0.9AVDD
+ 5%
V
3
mA
Microphone Bias
Bias Voltage
VMICBIAS
Bias Current Source
IMICBIAS
Output Noise Voltage
Vn
3mA load current
1K to 20kHz
15
nV/Hz
Digital Input / Output
Input HIGH Level
VIH
Input LOW Level
VIL
Output HIGH Level
VOH
IOH = +1mA
Output LOW Level
VOL
IOL = -1mA
0.7DBVDD
V
0.3DBVDD
V
0.1DBVDD
V
0.3AVDD
V
0.9DBVDD
V
HPDETECT (pin 23)
Input HIGH Level
VIH
Input LOW Level
VIL
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0.7AVDD
V
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Production Data
TYPICAL PERFORMANCE
POWER CONSUMPTION
The power consumption of the WM8750JL depends on the following factors.

Supply voltages: Reducing the supply voltages also reduces supply currents, and therefore results in significant power
savings, especially in the digital sections of the WM8750JL.

Oversampling rate: Significant power savings can be achieved by running the DAC and ADC at the lower over-sampling
rate of 64 (this is achieved by setting ADCOSR and DACOSR to ‘1’ in R24). Note all figures quoted here assume
ADCOSR=DACOSR=1.

Operating mode: Disabling parts of the WM8750JL that are not currently in use (e.g. mic pre-amps, unused outputs,
DAC, ADC, etc.) also saves power.
OFF
Standby
(500 KOhm VMID string)
Playback to Line-out
Playback to 32 Ohm Headphone
Playback to 32 Ohm Headphone
0.1mW / channel into load
(JEITA CP-2905B)
Playback to 32 Ohm Headphone
5mW / channel into load
Playback to 32 Ohm Headphone
(capless mode using OUT3)
Playback to 8 Ohm BTL Speaker
Headphone Amp
(line-in to 32 Ohm headphone)
Speaker Amp
(line-in to 8 Ohm speaker)
Record from Line-in
Record from mono microphone
Record from mono microphone
(differential)
Stereo Record & Playback
R24 R23
VSEL
VMIDSEL
Bit
R26 (1Ah)
VREF
AINL
AINR
ADCL
ADCR
MICB
DACL
DACR
LOUT1
ROUT1
LOUT2
ROUT2
MONO
OUT3
ADCOSR
DACOSR
R25 (19h)
Control Register
Other settings
AVDD
V
00 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 11
Clocks stopped
3.3
01
2.5
00
1.8
10 1 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 11
Interface Stopped
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 11
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 11
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 11
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 1 1 1 1 0 0 0 0 1 1 11
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 1 1 1 1 0 0 0 1 1 1 11 R24, OUT3SW=00
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 1 1 0 0 1 1 0 0 1 1 11 R24, ROUT2INV=1 3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 0 0 1 1 0 0 0 0 1 1 11
Clocks Stopped
3.3
01
2.5
00
1.8
01 1 0 0 0 0 0 0 0 0 0 1 1 0 0 1 1 11
Clocks Stopped
3.3
01 R24, ROUT2INV=1 2.5
00
1.8
01 1 1 1 1 1 0 0 0 0 0 0 0 0 0 1 1 11
3.3
01
2.5
00
1.8
01 1 1 0 1 0 1 0 0 0 0 0 0 0 0 1 1 11 R32, LMICBOOST=11; 3.3
01
R23, DATSEL=01
2.5
00
1.8
01 1 1 0 1 0 1 0 0 0 0 0 0 0 0 1 1 11 R32, LMICBOOST=11; 3.3
01
R23, DATSEL=01;
2.5
00
R32, LINSEL=11
1.8
01 1 1 1 1 1 1 1 1 0 0 1 1 0 0 1 1 11
3.3
01
2.5
00
1.8
I (mA)
0.000
0.000
0.000
0.360
0.268
0.183
2.457
1.814
1.606
2.456
1.814
1.606
2.456
1.814
1.607
2.470
1.833
1.635
2.426
1.788
1.244
2.652
1.950
1.694
1.107
0.812
0.559
1.305
0.948
0.649
4.631
3.892
3.239
2.829
2.330
1.892
3.197
2.593
2.067
6.670
5.389
4.281
DCVDD
V
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
3.3
2.5
1.5
I (mA)
0.010
0.008
0.007
0.011
0.009
0.007
4.687
2.779
1.483
4.649
2.758
1.483
5.454
3.354
1.831
5.469
3.408
1.862
3.969
2.705
1.481
4.655
2.761
1.482
0.624
0.090
0.007
0.565
0.092
0.007
5.010
3.237
1.649
4.996
3.208
1.632
4.993
3.208
1.636
8.014
5.326
2.851
DBVDD
V
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
3.3
2.5
1.8
I (mA)
0.000
0.000
0.000
0.000
0.000
0.000
0.250
0.178
0.122
0.250
0.178
0.122
0.250
0.178
0.122
0.250
0.178
0.122
0.251
0.179
0.122
0.250
0.178
0.122
0.000
0.000
0.000
0.000
0.000
0.000
0.273
0.196
0.135
0.273
0.194
0.134
0.273
0.194
0.134
0.272
0.196
0.135
HPVDD
Tot. Power
V I (mA)
3.3 0.000
2.5 0.000
1.8 0.000
3.3 0.000
2.5 0.000
1.8 0.000
3.3 0.683
2.5 0.670
1.8 0.406
3.3 0.709
2.5 0.682
1.8 0.410
3.3 1.929
2.5 1.927
1.8 1.793
3.3 11.248
2.5 11.283
1.8 10.974
3.3 1.010
2.5 0.980
1.8 0.670
3.3 1.256
2.5 1.095
1.8 0.773
3.3 0.685
2.5 0.672
1.8 0.407
3.3 0.691
2.5 0.679
1.8 0.455
3.3 0.000
2.5 0.000
1.8 0.000
3.3 0.000
2.5 0.000
1.8 0.000
3.3 0.000
2.5 0.000
1.8 0.000
3.3 0.805
2.5 0.613
1.8 0.329
mW
0.0330
0.0200
0.0105
1.2243
0.6925
0.3399
26.6541
13.6025
6.0657
26.6112
13.5800
6.0729
33.2937
18.1825
9.0861
64.1421
41.7550
25.7088
25.2648
14.1300
5.8863
29.0829
14.9600
6.8832
7.9728
3.9350
1.7493
8.4513
4.2975
1.9977
32.7162
18.3125
8.5467
26.7234
14.3300
6.0948
27.9279
14.9875
6.4158
52.0113
28.8100
12.8175
Table 1 Supply Current Consumption
Notes:
o
1.
All figures are at TA = +25 C, Slave Mode, fs = 48kHz, MCLK = 12.288 MHz (256fs), ADCOSR=DACOSR=1.
2.
Unless otherwise noted, these measurements are quiescent (i.e. signal amplitude is zero).
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Production Data
OUTPUT DRIVERS
Headphone Output Power vs THD+N
10
1
THD+N [%]
AVDD=3.3V, 32 Ohm load
AVDD=3.3V, 16 Ohm load
AVDD=1.8V, 32 Ohm load
AVDD=1.8V, 16 Ohm load
0.1
0.01
0.1
1
10
100
Power per channel [mW]
Speaker Output Power vs THD+N
10
THD+N [%]
1
AVDD=3.3V, 8 Ohm load
AVDD=1.8V, 8 Ohm load
0.1
0.01
1
10
100
1000
Power [mW]
Notes:
1. These graphs show THD+N relative to the signal amplitude at each point (not relative to full scale).
2. Signal frequency = 1kHz
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OUTPUT PGA’S LINEARITY
10.000
0.000
Output PGA Gains
Measured Gain [dB]
-10.000
-20.000
-30.000
LOUT1
-40.000
ROUT1
LOUT2
-50.000
ROUT2
MONOOUT
-60.000
-70.000
40
50
60
70
80
90
100
110
120
130
XXXVOL Register Setting (binary)
2.000
1.750
Output PGA Gain Step Size
Step Size [dB]
1.500
1.250
1.000
0.750
LOUT1
ROUT1
0.500
LOUT2
ROUT2
0.250
MONOOUT
0.000
40
50
60
70
80
90
100
110
120
130
XXXVOL Register Setting (binary)
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SIGNAL TIMING REQUIREMENTS
SYSTEM CLOCK TIMING
tMCLKL
MCLK
tMCLKH
tMCLKY
Figure 1 System Clock Timing Requirements
Test Conditions
o
CLKDIV2=0, DCVDD = 1.42V, DBVDD = 3.3V, DGND = 0V, TA = +25 C, Slave Mode fs = 48kHz, MCLK = 384fs, 24-bit data,
unless otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
MCLK System clock pulse width high
TMCLKL
21
MCLK System clock pulse width low
TMCLKH
21
ns
MCLK System clock cycle time
TMCLKY
54
ns
MCLK duty cycle
TMCLKDS
60:40
System Clock Timing Information
ns
40:60
Test Conditions
o
CLKDIV2=1, DCVDD = 1.42V, DBVDD = 3.3V, DGND = 0V, TA = +25 C, Slave Mode fs = 48kHz, MCLK = 384fs, 24-bit data,
unless otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
MCLK System clock pulse width high
TMCLKL
10
ns
MCLK System clock pulse width low
TMCLKH
10
ns
MCLK System clock cycle time
TMCLKY
27
ns
System Clock Timing Information
AUDIO INTERFACE TIMING – MASTER MODE
BCLK
(Output)
tDL
ADCLRC/
DACLRC
(Outputs)
tDDA
ADCDAT
DACDAT
tDST
tDHT
Figure 2 Digital Audio Data Timing – Master Mode (see Control Interface)
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Test Conditions
o
DCVDD = 1.42V, DBVDD = 3.3V, DGND = 0V, TA = +25 C, Master Mode, fs = 48kHz, MCLK = 256fs, 24-bit data, unless
otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
3
ns
3
ns
Bit Clock Timing Information
BCLK rise time (10pF load)
tBCLKR
BCLK fall time (10pF load)
tBCLKF
BCLK duty cycle (normal mode, BCLK = MCLK/n)
tBCLKDS
50:50
BCLK duty cycle (USB mode, BCLK = MCLK)
tBCLKDS
TMCLKDS
Audio Data Input Timing Information
ADCLRC/DACLRC propagation delay from BCLK falling edge
tDL
10
ns
ADCDAT propagation delay from BCLK falling edge
tDDA
40
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
tBCH
tBCL
BCLK
tBCY
DACLRC/
ADCLRC
tDS
tLRH
tLRSU
DACDAT
tDD
tDH
ADCDAT
Figure 3 Digital Audio Data Timing – Slave Mode
Test Conditions
o
DCVDD = 1.42V, DBVDD = 3.3V, DGND = 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
ADCLRC/DACLRC set-up time to BCLK rising edge
tLRSU
10
ns
ADCLRC/DACLRC hold time from BCLK rising edge
tLRH
10
ns
DACDAT hold time from BCLK rising edge
tDH
10
ADCDAT propagation delay from BCLK falling edge
tDD
ns
10
ns
Note:
BCLK period should always be greater than or equal to MCLK period.
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CONTROL INTERFACE TIMING – 3-WIRE MODE
tCSL
tCSH
CSB
tCSS
tSCY
tSCH
tSCS
tSCL
SCLK
LSB
SDIN
tDSU
tDHO
Figure 4 Control Interface Timing – 3-Wire Serial Control Mode
Test Conditions
o
DCVDD = 1.42V, DBVDD = 3.3V, DGND = 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
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CONTROL INTERFACE TIMING – 2-WIRE MODE
t3
t3
t5
SDIN
t4
t6
t2
t8
SCLK
t1
t9
t7
Figure 5 Control Interface Timing – 2-Wire Serial Control Mode
Test Conditions
o
DCVDD = 1.42V, DBVDD = 3.3V, DGND = 0V, TA = +25 C, Slave Mode, fs = 48kHz, MCLK = 256fs, 24-bit data, unless
otherwise stated.
PARAMETER
SYMBOL
MIN
TYP
MAX
UNIT
SCLK Low Pulse-Width
t1
1.3
526
kHz
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
Program Register Input Information
SCLK Frequency
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0
ns
600
0
ns
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INTERNAL POWER ON RESET CIRCUIT
DCVDD
AVDD
VDD
T1
Power on Reset
Circuit
Internal PORB
GND
DGND
Figure 6 Internal Power on Reset Circuit Schematic
The WM8750JL includes an internal Power-On-Reset Circuit, as shown in Figure 6, which is used to
reset the digital logic into a default state after power up. The power on reset circuit is powered from
DCVDD and monitors DCVDD and AVDD. It asserts PORB low if DCVDD or AVDD are below a
minimum threshold.
Figure 7 Typical Power-Up Sequence
Figure 7 shows a typical power-up sequence. When DCVDD and AVDD rise above the minimum
thresholds, Vpord_dcvdd and Vpord_avdd, there is enough voltage for the circuit to guarantee the
Power on Reset is asserted low and the chip is held in reset. In this condition, all writes to the control
interface are ignored. When DCVDD rises to Vpor_dcvdd_on and AVDD rises to Vpor_avdd_on,
PORB is released high and all registers are in their default state and writes to the control interface
may take place. If DCVDD and AVDD rise at different rates then PORB will only be released when
DCVDD and AVDD have both exceeded the Vpor_dcvdd_on and Vpor_avdd_on thresholds.
On power down, PORB is asserted low whenever DCVDD drops below the minimum threshold
Vpor_dcvdd_off or AVDD drops below the minimum threshold Vpor_avdd_off.
SYMBOL
MIN
TYP
MAX
UNIT
Vpord_dcvdd
0.4
0.6
0.8
V
Vpor_dcvdd_on
0.9
1.26
1.6
V
Vpor_avdd_on
0.5
0.7
0.9
V
Vpor_avdd_off
0.4
0.6
0.8
V
Table 2 Typical POR Operation (typical values, not tested)
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DEVICE DESCRIPTION
INTRODUCTION
The WM8750JL is a low power audio codec offering a combination of high quality audio, advanced
features, low power and small size. These characteristics make it ideal for portable digital audio
applications such as MP3 and minidisk player / recorders. Stereo 24-bit multi-bit delta sigma ADCs
and DACs are used with oversampling digital interpolation and decimation filters.
The device includes three stereo analogue inputs that can be switched internally. Each can be used
as either a line level input or microphone input and LINPUT1/RINPUT1 and LINPUT2/RINPUT2 can
be configured as mono differential inputs. A programmable gain amplifier with automatic level control
(ALC) keeps the recording volume constant. The on-chip stereo ADC and DAC are of a high quality
using a multi-bit, low-order oversampling architecture to deliver optimum performance with low power
consumption.
The DAC output signal first enters an analogue mixer where an analogue input and/or the post-ALC
signal can be added to it. This mix is available on line and headphone outputs.
The WM8750JL has a configurable digital audio interface where ADC data can be read and digital
2
audio playback data fed to the DAC. It supports a number of audio data formats including I S, DSP
Mode (a burst mode in which frame sync plus 2 data packed words are transmitted), and MSB-First,
left justified, and can operate in master or slave modes.
The WM8750JL uses a unique clocking scheme that can generate many commonly used audio
sample rates from either a 12.00MHz USB clock or an industry standard 256/384 fs clock. This feature
eliminates the common requirement for an external phase-locked loop (PLL) in applications where the
master clock is not an integer multiple of the sample rate. Sample rates of 8kHz, 11.025kHz, 12kHz,
16kHz, 22.05kHz, 24kHz, 32kHz, 44.1kHz, 48kHz, 88.2kHz and 96kHz can be generated. The digital
filters used for recording and playback are optimised for each sampling rate used.
To allow full software control over all its features, the WM8750JL offers a choice of 2 or 3 wire MPU
control interface. It is fully compatible and an ideal partner for a wide range of industry standard
microprocessors, controllers and DSPs.
The design of the WM8750JL has given much attention to power consumption without compromising
performance. It operates at very low voltages, and includes the ability to power off parts of the
circuitry under software control, including standby and power off modes.
INPUT SIGNAL PATH
The input signal path for each channel consists of a switch to select between three analogue inputs,
followed by a PGA (programmable gain amplifier) and an optional microphone gain boost. A
differential input of either (LINPUT1 – RINPUT1) or (LINPUT2 – RINPUT2) may also be selected. The
gain of the PGA can be controlled either by the user or by the on-chip ALC function (see Automatic
Level Control).
The signal then enters an ADC where it is digitised. Alternatively, the two channels can also be mixed
in the analogue domain and digitised in one ADC while the other ADC is switched off. The mono-mix
signal appears on both digital output channels.
SIGNAL INPUTS
The WM8750JL has three sets of high impedance, low capacitance AC coupled analogue inputs,
LINPUT1/RINPUT1, LINPUT2/RINPUT2 and LINPUT3/RINPUT3. Inputs can be configured as
microphone or line level by enabling or disabling the microphone gain boost.
LINSEL and RINSEL control bits (see Table 3) are used to select independently between external
inputs and internally generated differential products (LINPUT1-RINPUT1 or LINPUT2-RINPUT2). The
choice of differential signal, LINPUT1-RINPUT1 or LINPUT2-RINPUT2 is made using DS (refer to
Table 5).
As an example, the WM8750JL can be set up to convert one differential and one single ended mono
signal by applying the differential signal to LINPUT1/RINPUT1 and the single ended signal to
RINPUT2. By setting LINSEL to L-R Differential (see Table 3), DS to LINPUT1 – RINPUT1 (see Table
5) and RINSEL to RINPUT2, each mono signal can then be routed to a separate ADC or Bypass
path.
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The signal inputs are biased internally to the reference voltage VREF. Whenever the line inputs are
muted or the device placed into standby mode, the inputs are kept biased to VREF using special antithump circuitry. This reduces any audible clicks that may otherwise be heard when changing inputs.
DC MEASUREMENT
For DC measurements (for example, battery voltage monitoring), the input signal at the LINPUT1
and/or RINPUT1 pins can be taken directly into the respective ADC, bypassing both PGA and
microphone boost. The ADC output then becomes unsigned relative to AVDD, instead of being a
signed (two’s complement) number relative to VREF. Setting L/RDCM will override L/RINSEL. The
input range for dc measurement is AGND to AVDD.
REGISTER
ADDRESS
R32 (20h)
BIT
7:6
LABEL
LINSEL
DEFAULT
00
DESCRIPTION
Left Channel Input Select
00 = LINPUT1
ADC Signal
Path Control
(Left)
01 = LINPUT2
10 = LINPUT3
11 = L-R Differential (either LINPUT1RINPUT1 or LINPUT2-RINPUT2,
selected by DS)
5:4
LMICBOOST
00
Left Channel Microphone Gain Boost
00 = Boost off (bypassed)
01 = 13dB boost
10 = 20dB boost
11 = 29dB boost
R33 (21h)
7:6
RINSEL
00
Right Channel Input Select
00 = RINPUT1
ADC Signal
Path Control
(Right)
01 = RINPUT2
10 = RINPUT3
11 = L-R Differential (either LINPUT1RINPUT1 or LINPUT2-RINPUT2,
selected by DS)
5:4
RMICBOOST
00
Right Channel Microphone Gain Boost
00 = Boost off (bypassed)
01 = 13dB boost
10 = 20dB boost
11 = 29dB boost
Table 3 Input Software Control
REGISTER
ADDRESS
R31 (1Fh)
BIT
5
LABEL
RDCM
DEFAULT
0
ADC input Mode
DESCRIPTION
Right Channel DC Measurement
0 = Normal Operation, PGA Enabled
1 = Measure DC level on RINPUT1
4
LDCM
0
Left Channel DC Measurement
0 = Normal Operation, PGA Enabled
1 = Measure DC level on LINPUT1
Table 4 DC Measurement Select
REGISTER
ADDRESS
R31 (1Fh)
BIT
8
LABEL
DS
ADC Input Mode
DEFAULT
0
DESCRIPTION
Differential input select
0: LINPUT1 – RINPUT1
1: LINPUT2 – RINPUT2
Table 5 Differential Input Select
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MONO MIXING
The stereo ADC can operate as a stereo or mono device, or the two channels can be mixed to mono
in the analogue domain (i.e. before the ADC). MONOMIX selects the mode of operation; either the left
or right channel ADC can be used, allowing the unused ADC to be powered off or used for a DC
measurement conversion. The user also has the flexibility to select the data output from the audio
interface using DATSEL. The default is for left and right channel ADC data to be output, but the
interface may also be configured so that e.g. left channel ADC data is output as both left and right
data for when mono mixing is selected.
Note:
If DC measurement is selected this overrides the MONOMIX selection.
REGISTER
ADDRESS
BIT
R31 (1Fh)
7:6
LABEL
DEFAULT
MONOMIX
00
00: Stereo
[1:0]
ADC input
Mode
DESCRIPTION
01: Analogue Mono Mix (using left ADC)
10: Analogue Mono Mix (using right ADC)
11: Reserved
Table 6 Mono Mixing
REGISTER
ADDRESS
R23 (17h)
BIT
LABEL
3:2
DATSEL
DEFAULT
00
00: left data=left ADC; right data =right ADC
[1:0]
Additional
Control (1)
DESCRIPTION
01: left data =left ADC; right data = left ADC
10: left data = right ADC; right data =right ADC
11: left data = right ADC; right data = left ADC
Table 7 ADC Data Output Configuration
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 output can be enabled or disables
using the MICB control bit (see also the “Power Management” section).
REGISTER
ADDRESS
R25 (19h)
BIT
1
LABEL
MICB
DEFAULT
0
Power
Management (1)
DESCRIPTION
Microphone Bias Enable
0 = OFF (high impedance output)
1 = ON
Table 8 Microphone Bias Control
The internal MICBIAS circuitry is shown below. Note that the is a maximum source current capability
for MICBIAS is 3mA. The external biasing resistors therefore must be large enough to limit the
MICBIAS current to 3mA.
VMID
MICB
internal
resistor
MICBIAS
= 1.8 x VMID
= 0.9 X AVDD
internal
resistor
AGND
Figure 8 Microphone Bias Schematic
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PGA CONTROL
The PGA matches the input signal level to the ADC input range. The PGA gain is logarithmically
adjustable from +30dB to –17.25dB in 0.75dB steps. Each PGA can be controlled either by the user
or by the ALC function (see Automatic Level Control). When ALC is enabled for one or both channels,
then writing to the corresponding PGA control register has no effect.
The gain is independently adjustable on both Right and Left Line Inputs. Additionally, by controlling
the register bits LIVU and RIVU, the left and right gain settings can be simultaneously updated.
Setting the LZCEN and RZCEN bits enables a zero-cross detector which ensures that PGA gain
changes only occur when the signal is at zero, eliminating any zipper noise. If zero cross is enabled a
timeout is also available to update the gain if a zero cross does not occur. This function may be
enabled by setting TOEN in register R23 (17h).
The inputs can also be muted in the analogue domain under software control. The software control
registers are shown in Table 9. If zero crossing is enabled, it is necessary to enable zero cross
timeout to un-mute the input PGAs. This is because their outputs will not cross zero when muted.
Alternatively, zero cross can be disabled before sending the un-mute command.
REGISTER
ADDRESS
R0 (00h)
BIT
8
LABEL
LIVU
DEFAULT
0
Left Channel
DESCRIPTION
Left Volume Update
0 = Store LINVOL in intermediate
latch (no gain change)
PGA
1 = Update left and right channel
gains (left = LINVOL, right =
intermediate latch)
7
LINMUTE
1
Left Channel Input Analogue Mute
1 = Enable Mute
0 = Disable Mute
Note: LIVU must be set to un-mute.
6
LZCEN
0
Left Channel Zero Cross Detector
1 = Change gain on zero cross only
0 = Change gain immediately
5:0
LINVOL
010111
Left Channel Input Volume Control
[5:0]
( 0dB )
111111 = +30dB
111110 = +29.25dB
. . 0.75dB steps down to
000000 = -17.25dB
R1 (01h)
8
RIVU
0
Right Channel
Right Volume Update
0 = Store RINVOL in intermediate
latch (no gain change)
PGA
1 = Update left and right channel
gains (right = RINVOL, left =
intermediate latch)
7
RINMUTE
1
Right Channel Input Analogue Mute
1 = Enable Mute
0 = Disable Mute
Note: RIVU must be set to un-mute.
6
RZCEN
0
Right Channel Zero Cross Detector
1 = Change gain on zero cross only
0 = Change gain immediately
5:0
RINVOL
010111
Right Channel Input Volume Control
[5:0]
( 0dB )
111111 = +30dB
111110 = +29.25dB
. . 0.75dB steps down to
000000 = -17.25dB
R23 (17h)
0
TOEN
Additional
Control (1)
0
Timeout Enable
0 : Timeout Disabled
1 : Timeout Enabled
Table 9 Input PGA Software Control
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ANALOGUE TO DIGITAL CONVERTER (ADC)
The WM8750JL uses a multi-bit, oversampled sigma-delta ADC for each channel. 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 AVDD. With a 3.3V supply voltage, the full scale level is 1.0
Volts r.m.s. Any voltage greater than full scale may overload the ADC and cause distortion.
ADC DIGITAL FILTER
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 is illustrated in Figure 9.
FROM ADC
DIGITAL
DECIMATOR
DIGITAL
FILTER
DIGITAL
HPF
TO DIGITAL
AUDIO
INTERFACE
ADCHPD
Figure 9 ADC Digital Filter
The ADC digital filters contain a digital high pass filter, selectable via software control. The high-pass
filter response is detailed in the Digital Filter Characteristics section. When the high-pass filter is
enabled the dc offset is continuously calculated and subtracted from the input signal. By setting
HPOR, the last calculated dc offset value is stored when the high-pass filter is disabled and will
continue to be subtracted from the input signal. If the DC offset is changed, the stored and subtracted
value will not change unless the high-pass filter is enabled. This feature can be used for calibration
purposes. In addition the highpass filter may be enabled separately on the left and right channels
(see Table 11).
The output data format can be programmed by the user to accommodate stereo or monophonic
recording on both inputs. The polarity of the output signal can also be changed under software
control. The software control is shown in Table 10.
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REGISTER
ADDRESS
R5 (05h)
BIT
6:5
ADC and DAC
Control
LABEL
ADCPOL
DEFAULT
00
[1:0]
DESCRIPTION
00 = Polarity not inverted
01 = L polarity invert
10 = R polarity invert
11 = L and R polarity invert
4
HPOR
0
Store dc offset when high-pass
filter disabled
1 = store offset
0 = clear offset
0
ADCHPD
0
ADC high-pass filter enable
(Digital)
HPFLREN = 0
1 = Disable high-pass filter on left
and right channels
0 = Enable high-pass filter on left
and right channels
HPFLREN = 1
0 = High-pass enabled on left,
disabled on right
1 = High-pass enabled on right,
disabled on left
R27 (1Bh)
5
HPFLREN
0
ADC high-pass filter left or right
enable
0 = High-pass filter enable/disable
on left and right channels
controlled by ADCHPD
1 = High-pass filter enabled on left
or right channel, as selected by
ADCHPD
Table 10 ADC Signal Path Control
HPFLREN
ADCHPD
0
0
High-pass filter enabled on left and right
channels
HIGH PASS MODE
0
1
High-pass filter disabled on left and right
channels
1
0
High-pass filter enabled on left channel,
disabled on right channel
1
1
High-pass filter disabled on left channel,
enabled on right channel
Table 11 ADC High Pass Filter Enable Modes
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DIGITAL ADC VOLUME CONTROL
The output of the ADCs can be digitally amplified or attenuated over a range from –97dB to +30dB in
0.5dB steps. The volume of each channel can be controlled separately. The gain for a given eight-bit
code X is given by:
0.5  (X-195) dB for 1  X  255;
MUTE for X = 0
The LAVU and RAVU control bits control the loading of digital volume control data. When LAVU or
RAVU are set to 0, the LADCVOL or RADCVOL control data will be loaded into the respective control
register, but will not actually change the digital gain setting. Both left and right gain settings are
updated when either LAVU or RAVU are set to 1. This makes it possible to update the gain of both
channels simultaneously.
REGISTER
ADDRESS
R21 (15h)
BIT
7:0
Left ADC
Digital Volume
LABEL
DEFAULT
DESCRIPTION
LADCVOL
11000011
Left ADC Digital Volume Control
[7:0]
( 0dB )
0000 0000 = Digital Mute
0000 0001 = -97dB
0000 0010 = -96.5dB
... 0.5dB steps up to
1111 1111 = +30dB
8
LAVU
0
Left ADC Volume Update
0 = Store LADCVOL in intermediate
latch (no gain change)
1 = Update left and right channel
gains (left = LADCVOL, right =
intermediate latch)
R22 (16h)
7:0
Right ADC
Digital Volume
RADCVOL
11000011
Right ADC Digital Volume Control
[7:0]
( 0dB )
0000 0000 = Digital Mute
0000 0001 = -97dB
0000 0010 = -96.5dB
... 0.5dB steps up to
1111 1111 = +30dB
8
RAVU
0
Right ADC Volume Update
0 = Store RADCVOL in intermediate
latch (no gain change)
1 = Update left and right channel
gains (left = intermediate latch, right
= RADCVOL)
Table 12 ADC Digital Volume Control
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AUTOMATIC LEVEL CONTROL (ALC)
The WM8750JL has an automatic level control that aims to keep a constant recording volume
irrespective of the input signal level. This is achieved by continuously adjusting the PGA gain so that
the signal level at the ADC input remains constant. A digital peak detector monitors the ADC output
and changes the PGA gain if necessary. Note that when the ALC function is enabled, the settings of
registers 0 and 1 (LINVOL, LIVU, LIZC, LINMUTE, RINVOL, RIVU, RIZC and RINMUTE) are ignored.
A selectable Zero-Cross function ensures that the ALC volume updates will be timed to coincide with
a zero-crossing of the audio signal.
input
signal
PGA
gain
ALC
target
level
signal
after
ALC
hold
time
decay
time
attack
time
Figure 10 ALC Operation
The ALC function is enabled using the ALCSEL control bits. When enabled, the recording volume can
be programmed between –6dB and –28.5dB (relative to ADC full scale) using the ALCL register bits.
An upper limit for the PGA gain can be imposed by setting the MAXGAIN control bits.
HLD, DCY and ATK control the hold, decay and attack times, respectively:
Hold time is the time delay between the peak level detected being below target and the PGA gain
n
beginning to ramp up. It can be programmed in power-of-two (2 ) steps, e.g. 2.67ms, 5.33ms,
10.67ms etc. up to 43.7s. Alternatively, the hold time can also be set to zero. The hold time only
applies to gain ramp-up, there is no delay before ramping the gain down when the signal level is
above target.
Decay (Gain Ramp-Up) Time is the time that it takes for the PGA gain to ramp up across 90% of its
range (e.g. from –15B up to 27.75dB). The time it takes for the recording level to return to its target
value therefore depends on both the decay time and on the gain adjustment required. If the gain
adjustment is small, it will be shorter than the decay time. The decay time can be programmed in
n
power-of-two (2 ) steps, from 24ms, 48ms, 96ms, etc. to 24.58s.
Attack (Gain Ramp-Down) Time is the time that it takes for the PGA gain to ramp down across 90%
of its range (e.g. from 27.75dB down to -15B gain). The time it takes for the recording level to return to
its target value therefore depends on both the attack time and on the gain adjustment required. If the
gain adjustment is small, it will be shorter than the attack time. The attack time can be programmed in
n
power-of-two (2 ) steps, from 6ms, 12ms, 24ms, etc. to 6.14s.
When operating in stereo, the peak detector takes the maximum of left and right channel peak values,
and any new gain setting is applied to both left and right PGAs, so that the stereo image is preserved.
However, the ALC function can also be enabled on one channel only. In this case, only one PGA is
controlled by the ALC mechanism, while the other channel runs independently with its PGA gain set
through the control register.
When one ADC channel is unused or used for DC measurement, the peak detector disregards that
channel. The ALC function can also operate when the two ADC outputs are mixed to mono in the
digital domain, but not if they are mixed to mono in the analogue domain, before entering the ADCs.
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REGISTER
ADDRESS
R17 (11h)
BIT
8:7
ALC Control 1
LABEL
DEFAULT
DESCRIPTION
ALCSEL
00
ALC function select
[1:0]
(OFF)
00 = ALC off (PGA gain set by register)
01 = Right channel only
10 = Left channel only
11 = Stereo (PGA registers unused)
Note: ensure that LINVOL and
RINVOL settings (reg. 0 and 1) are
the same before entering this mode.
6:4
MAXGAIN
[2:0]
111
(+30dB)
Set Maximum Gain of PGA
111 : +30dB
110 : +24dB
….(-6dB steps)
001 : -6dB
000 : -12dB
3:0
ALCL
1011
[3:0]
(-12dB)
ALC target – sets signal level at ADC
input
0000 = -28.5dB FS
0001 = -27.0dB FS
… (1.5dB steps)
1110 = -7.5dB FS
1111 = -6dB FS
R18 (12h)
7
0 (zero
cross
off)
ALC Zero Cross detect
HLD
0000
ALC hold time before gain is increased.
[3:0]
(0ms)
0000 = 0ms
ALCZC
ALC Control 2
3:0
0 = Change gain immediately
1 = Change gain on zero cross only
0001 = 2.67ms
0010 = 5.33ms
… (time doubles with every step)
1111 = 43.691s
R19 (13h)
7:4
ALC Control 3
DCY
0011
ALC decay (gain ramp-up) time
[3:0]
(192ms)
0000 = 24ms
0001 = 48ms
0010 = 96ms
… (time doubles with every step)
1010 or higher = 24.58s
3:0
ATK
0010
ALC attack (gain ramp-down) time
[3:0]
(24ms)
0000 = 6ms
0001 = 12ms
0010 = 24ms
… (time doubles with every step)
1010 or higher = 6.14s
Table 13 ALC Control
Note: For correct ALC operation in differential input mode it is recommended that the ALC is not used
with a combined signal gain (mic boost and PGA) greater than 30dB.
ALC ZERO CROSS
The ALC Zero Cross function can be used to ensure that the ALC volume updates will be timed to
coincide with a suitable zero-crossing of the audio signal. This avoids audible ‘zipper noise’ effects of
instantaneous volume changes. The ALC Zero Cross function includes a timeout to ensure that the
gain is updated even if a zero cross does not occur. If the signal level is small, it is possible that a
zero cross does not occur, due to DC offset within the signal path. In this case, the timeout will ensure
that the ALC volume change is still executed.
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Note that the PGA Control Zero Cross function described earlier (see “Input Signal Path”) also has a
timeout function. Because the ALC function applies volume changes via a series of small changes,
the ALC Zero Cross timeout needs to be many times faster than the normal, register-controlled PGA
volume control. This improves the ALC response, in particular when handling small signals, where the
zero-cross function may be less effective.
The ALC zero-cross timeout is duration is fixed in relation to MCLK. The maximum ALC zero-cross
timeout period is given by the equation below. In the case of a 12.288MHz MCLK, the maximum
timeout duration is approximately 21ms.
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 ATK = 0000), until the signal level falls below
87.5% of full scale. This function is automatically enabled whenever the ALC is enabled.
Note:
If ATK = 0000, then the limiter makes no difference to the operation of the ALC. It is designed to
prevent clipping when long attack times are used.
NOISE GATE
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 WM8750JL has a noise gate function
that prevents noise pumping by comparing the signal level at the LINPUT1/2/3 and/or RINPUT1/2/3
pins against a noise gate threshold, NGTH. The noise gate cuts in when:

Signal level at ADC [dB] < NGTH [dB] + PGA gain [dB] + Mic Boost gain [dB]
This is equivalent to:

Signal level at input pin [dB] < NGTH [dB]
The ADC output can then either be muted or alternatively, the PGA gain can be 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 1.5dB steps. Levels
at the extremes of the range may cause inappropriate operation, so care should be taken with set–up
of the function. Note that the noise gate only works in conjunction with the ALC function, and always
operates on the same channel(s) as the ALC (left, right, both, or none).
REGISTER
ADDRESS
R20 (14h)
BIT
7:3
Noise Gate
LABEL
NGTH
DEFAULT
00000
[4:0]
Control
DESCRIPTION
Noise gate threshold
17
-76.5dBfs
17
-75dBfs
… 1.5 dB steps
2:1
NGG
00
[1:0]
11110
-31.5dBfs
11111
-30dBfs
Noise gate type
X0 = PGA gain held constant
01 = mute ADC output
11 = reserved (do not use this setting)
0
NGAT
0
Noise gate function enable
1 = enable
0 = disable
Table 14 Noise Gate Control
Note:
The performance of the ADC may degrade at high input signal levels if the monitor bypass mux is
selected with MIC boost and ALC enabled.
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3D STEREO ENHANCEMENT
The WM8750JL has a digital 3D enhancement option to artificially increase the separation between
the left and right channels. This effect can be used for recording or playback, but not for both
simultaneously. Selection of 3D for record or playback is controlled by register bit MODE3D.
Important:
Switching the 3D filter from record to playback or from playback to record may only be done
when ADC and DAC are disabled. The WM8750JL control interface will only allow MODE3D to
be changed when ADC and DAC are disabled (i.e. bits ADCL, ADCR, DACL and DACR in reg. 26
/ 1Ah are all zero).
The 3D enhancement function is activated by the 3DEN bit, and has two programmable parameters.
The 3DDEPTH setting controls the degree of stereo expansion. Additionally, one of four filter
characteristics can be selected for the 3D processing, using the 3DVC and 3DLC control bits.
REGISTER
ADDRESS
R16 (10h)
BIT
7
LABEL
DEFAULT
MODE3D
0
3D enhance
DESCRIPTION
Playback/Record 3D select
0 = 3D selected for Record
1 = 3D selected for Playback
6
3DUC
0
Upper Cut-off frequency
0 = High (2.2kHz at 48kHz sampling)
1 = Low (1.5kHz at 48kHz sampling)
5
3DLC
0
Lower Cut-off frequency
0 = Low (200Hz at 48kHz sampling)
1 = High (500Hz at 48kHz sampling)
4:1
3DDEPTH
0000
[3:0]
Stereo depth
0000: 0% (minimum 3D effect)
0001: 6.67%
....
1110: 93.3%
1111: 100% (maximum 3D effect)
0
3DEN
0
3D function enable
1: enabled
0: disabled
Table 15 3D Stereo Enhancement Function
When 3D enhancement is enabled (and/or the graphic equaliser for playback) it may be necessary to
attenuate the signal by 6dB to avoid limiting. This is a user selectable function, enabled by setting
ADCDIV2 for the record path and DACDIV2 for the playback path.
REGISTER
ADDRESS
R5 (05h)
BIT
8
LABEL
ADCDIV2
DEFAULT
0
ADC and DAC
control
DESCRIPTION
ADC 6dB attenuate enable
0 = disabled (0dB)
1 = -6dB enabled
7
DACDIV2
0
DAC 6dB attenuate enable
0 = disabled (0dB)
1 = -6dB enabled
Table 16 ADC and DAC 6dB Attenuation Select
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OUTPUT SIGNAL PATH
The WM8750JL output signal paths consist of digital filters, DACs, analogue mixers and output
drivers. The digital filters and DACs are enabled when the WM8750JL is in ‘playback only’ or ‘record
and playback’ mode. 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 WM8750JL, irrespective of whether the DACs are running or not.
The WM8750JL receives digital input data on the DACDAT pin. The digital filter block processes the
data to provide the following functions:

Digital volume control

Graphic equaliser and Dynamic Bass Boost

Sigma-Delta Modulation
Two high performance sigma-delta audio DACs convert the digital data into two analogue signals (left
and right). These can then be mixed with analogue signals from the LINPUT1/2/3 and RINPUT1/2/3
pins, and the mix is fed to the output drivers, LOUT1/ROUT1, LOUT2/ROUT2, OUT3 and
MONOOUT.

LOUT1/ROUT1/OUT3: can drive a 16 or 32 stereo headphone or stereo line output.

LOUT2/ROUT2: can drive a 16 or 32 stereo headphone or stereo line output, or an
8 mono speaker.

MONOOUT: can drive a mono line output or other load down to 10k
DIGITAL DAC VOLUME CONTROL
The signal volume from each DAC can be controlled digitally, in the same way as the ADC volume
(see Digital ADC Volume Control). The gain and attenuation 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;
MUTE for X = 0
The LDVU and RDVU control bits control the loading of digital volume control data. When LDVU or
RDVU are set to 0, the LDACVOL or RDACVOL control data is loaded into an intermediate register,
but the actual gain does not change. Both left and right gain settings are updated simultaneously
when either LDVU or RDVU are set to 1.
REGISTER
ADDRESS
R10 (0Ah)
BIT
8
LABEL
LDVU
DEFAULT
0
Left Channel
Digital Volume
DESCRIPTION
Left DAC Volume Update
0 = Store LDACVOL in intermediate
latch (no gain change)
1 = Update left and right channel
gains (left = LDACVOL, right =
intermediate latch)
7:0
LDACVOL
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
R11 (0Bh)
8
RDVU
0
Right Channel
Digital Volume
Right DAC Volume Update
0 = Store RDACVOL in intermediate
latch (no gain change)
1 = Update left and right channel
gains (left = intermediate latch, right
= RDACVOL)
7:0
RDACVOL
11111111
Right DAC Digital Volume Control
[7:0]
( 0dB )
similar to LDACVOL
Table 17 Digital Volume Control
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GRAPHIC EQUALISER
The WM8750JL has a digital graphic equaliser and adaptive bass boost function. This function
operates on digital audio data before it is passed to the audio DACs. Bass enhancement can take two
different forms:

Linear bass control: bass signals are amplified or attenuated by a user programmable
gain. This is independent of signal volume, and very high bass gains on loud signals may
lead to signal clipping.

Adaptive bass boost: The bass volume is amplified by a variable gain. When the bass
volume is low, it is boosted more than when the bass volume is high. This method is
recommended because it prevents clipping, and usually sounds more pleasant to the
human ear.
Treble control applies a user programmable gain, without any adaptive boost function. Bass and
treble control are completely independent with separately programmable gains and filter
characteristics.
REGISTER
ADDRESS
R12 (0Ch)
BIT
7
LABEL
BB
DEFAULT
0
Bass Control
DESCRIPTION
Bass Boost
0 = Linear bass control
1 = Adaptive bass boost
6
BC
0
Bass Filter Characteristic
0 = Low Cutoff (130Hz at 48kHz sampling)
1 = High Cutoff (200Hz at 48kHz sampling)
3:0
BASS
[3:0]
R13 (0Dh)
6
TC
1111
(Disabled)
0
Treble Control
Bass Intensity
Code
BB=0
BB=1
0000
+9dB
15 (max)
0001
+9dB
14
0010
+7.5dB
13
0011
+6dB
12
0100
+4.5dB
11
0101
+3dB
10
0110
+1.5dB
9
0111
0dB
8
1000
-1.5dB
7
1001
-3dB
6
1010
-4.5dB
5
1011
-6dB
4
1100
-6dB
3
1101
-6dB
2
1110
-6dB
1
1111
Bypass (OFF)
Treble Filter Characteristic
0 = High Cutoff (8kHz at 48kHz sampling)
1 = Low Cutoff (4kHz at 48kHz sampling)
3:0
TRBL
[3:0]
1111
(Disabled)
Treble Intensity
0000 or 0001 = +9dB
0010 = +7.5dB
… (1.5dB steps)
1011 to 1110 = -6dB
1111 = Disable
Table 18 Graphic Equaliser
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DIGITAL TO ANALOGUE CONVERTER (DAC)
After passing through the graphic equaliser filters, digital ‘de-emphasis’ can be applied to the audio
data if necessary (e.g. when the data comes from a CD with pre-emphasis used in the recording). Deemphasis filtering is available for sample rates of 48kHz, 44.1kHz and 32kHz.
The WM8750JL also has a Soft Mute function, which gradually attenuates the volume of the digital
signal to zero. When removed, the gain will return to the original setting. This function is enabled by
default. To play back an audio signal, it must first be disabled by setting the DACMU bit to zero.
REGISTER
ADDRESS
R5 (05h)
BIT
2:1
ADC and DAC
Control
LABEL
DEEMP
DEFAULT
00
DESCRIPTION
De-emphasis Control
[1:0]
11 = 48kHz sample rate
10 = 44.1kHz sample rate
01 = 32kHz sample rate
00 = No De-emphasis
3
DACMU
1
Digital Soft Mute
1 = mute
0 = no mute (signal active)
Table 19 DAC Control
The digital audio data is converted to oversampled bit streams in the on-chip, true 24-bit digital
interpolation filters. The bitstream data enters two multi-bit, sigma-delta DACs, which convert them to
high quality analogue audio signals. 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.
In normal operation, the left and right channel digital audio data is converted to analogue in two
separate DACs. However, it is also possible to disable one channel, so that the same signal (left or
right) appears on both analogue output channels. Additionally, there is a mono-mix mode where the
two audio channels are mixed together digitally and then converted to analogue using only one DAC,
while the other DAC is switched off. The mono-mix signal can be selected to appear on both
analogue output channels.
The DAC output defaults to non-inverted. Setting DACINV will invert the DAC output phase on both
left and right channels.
REGISTER
ADDRESS
R23 (17h)
BIT
5:4
LABEL
DMONOMIX
DEFAULT
00
[1:0]
Additional
Control (1)
DESCRIPTION
DAC mono mix
00: stereo
01: mono ((L+R)/2) into DACL, ‘0’ into
DACR
10: mono ((L+R)/2) into DACR, ‘0’ into
DACL
11: mono ((L+R)/2) into DACL and
DACR
1
DACINV
0
DAC phase invert
0 : non-inverted
1 : inverted
Table 20 DAC Mono Mix and Phase Invert Select
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OUTPUT MIXERS
The WM8750JL provides the option to mix the DAC output signal with analogue line-in signals from
the LINPUT1/2/3, RINPUT1/2/3 pins or a mono differential input (LINPUT1 – RINPUT1) or (LINPUT2
– RINPUT2), selected by DS (see Table 5) . The level of the mixed-in signals can be controlled with
PGAs (Programmable Gain Amplifiers).
The mono mixer is designed to allow a number of signal combinations to be mixed, including the
possibility of mixing both the right and left channels together to produce a mono output. To prevent
overloading of the mixer when full-scale DAC left and right signals are input, the mixer inputs from the
DAC outputs each have a fixed gain of -6dB. The bypass path inputs to the mono mixer have variable
gain as determined by R38/R39 bits [6:4].
REGISTER
ADDRESS
R34 (22h)
BIT
2:0
LABEL
LMIXSEL
DEFAULT
000
Left Mixer (1)
DESCRIPTION
Left Input Selection for Output Mix
000 = LINPUT1
001 = LINPUT2
010 = LINPUT3
011 = Left ADC Input (after PGA /
MICBOOST)
100 = Differential input
R36 (24h)
2:0
RMIXSEL
000
Right Mixer
(1)
Right Input Selection for Output Mix
000 = RINPUT1
001 = RINPUT2
010 = RINPUT3
011 = Right ADC Input (after PGA /
MICBOOST)
100 = Differential input
Table 21 Output Mixer Signal Selection
REGISTER
ADDRESS
R34 (22h)
BIT
8
LABEL
LD2LO
DEFAULT
0
Left Mixer
Control (1)
DESCRIPTION
Left DAC to Left Mixer
0 = Disable (Mute)
1 = Enable Path
7
LI2LO
0
LMIXSEL Signal to Left Mixer
0 = Disable (Mute)
1 = Enable Path
6:4
LI2LOVOL
[2:0]
101
LMIXSEL Signal to Left Mixer Volume
(-9dB)
000 = +6dB
… (3dB steps)
111 = -15dB
R35 (23h)
8
RD2LO
0
Left Mixer
Control (2)
Right DAC to Left Mixer
0 = Disable (Mute)
1 = Enable Path
7
RI2LO
0
RMIXSEL Signal to Left Mixer
0 = Disable (Mute)
1 = Enable Path
6:4
RI2LOVOL
[2:0]
101
RMIXSEL Signal to Left Mixer Volume
(-9dB)
000 = +6dB
… (3dB steps)
111 = -15dB
Table 22 Left Output Mixer Control
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REGISTER
ADDRESS
R36 (24h)
BIT
8
LABEL
LD2RO
DEFAULT
0
DESCRIPTION
Left DAC to Right Mixer
Right Mixer
Control (1)
0 = Disable (Mute)
1 = Enable Path
7
LI2RO
0
LMIXSEL Signal to Right Mixer
0 = Disable (Mute)
1 = Enable Path
6:4
LI2ROVOL
[2:0]
101
LMIXSEL Signal to Right Mixer Volume
(-9dB)
000 = +6dB
… (3dB steps)
111 = -15dB
R37 (25h)
8
RD2RO
0
Right DAC to Right Mixer
Right Mixer
Control (2)
0 = Disable (Mute)
1 = Enable Path
7
RI2RO
0
RMIXSEL Signal to Right Mixer
0 = Disable (Mute)
1 = Enable Path
6:4
RI2ROVOL
[2:0]
101
RMIXSEL Signal to Right Mixer Volume
(-9dB)
000 = +6dB
… (3dB steps)
111 = -15dB
Table 23 Right Output Mixer Control
REGISTER
ADDRESS
R38 (26h)
BIT
8
LABEL
LD2MO
DEFAULT
0
Mono Mixer
Control (1)
DESCRIPTION
Left DAC to Mono Mixer
0 = Disable (Mute)
1 = Enable Path
7
LI2MO
0
LMIXSEL Signal to Mono Mixer
0 = Disable (Mute)
1 = Enable Path
6:4
LI2MOVOL
101
[2:0]
(-9dB)
LMIXSEL Signal to Mono Mixer
Volume
000 = +6dB
… (3dB steps)
111 = -15dB
R39 (27h)
8
RD2MO
0
Mono Mixer
Control (2)
Right DAC to Mono Mixer
0 = Disable (Mute)
1 = Enable Path
7
RI2MO
0
RMIXSEL Signal to Mono Mixer
0 = Disable (Mute)
1 = Enable Path
6:4
RI2MOVOL
101
[2:0]
(-9dB)
RMIXSEL Signal to Mono Mixer
Volume
000 = +6dB
… (3dB steps)
111 = -15dB
Table 24 Mono Output Mixer Control
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ANALOGUE OUTPUTS
LOUT1/ROUT1 OUTPUTS
The LOUT1 and ROUT1 pins can drive a 16 or 32 headphone or a line output (see Headphone
Output and Line Output sections, respectively). The signal volume on LOUT1 and ROUT1 can be
independently adjusted under software control by writing to LOUT1VOL and ROUT1VOL,
respectively. Note that gains over 0dB may cause clipping if the signal is large. Any gain setting below
0101111 (minimum) mutes the output driver. The corresponding output pin remains at the same DC
level (the reference voltage on the VREF pin), so that no click noise is produced when muting or unmuting.
A zero cross detect on the analogue output may also be enabled when changing the gain setting to
minimize audible clicks and zipper noise as the gain updates. If zero cross is enabled a timeout is
also available to update the gain if a zero cross does not occur. This function may be enabled by
setting TOEN in register R23 (17h).
REGISTER
ADDRESS
R2 (02h)
BIT
8
LABEL
LO1VU
DEFAULT
0
LOUT1
DESCRIPTION
Left Volume Update
0 = Store LOUT1VOL in intermediate
latch (no gain change)
Volume
1 = Update left and right channel gains
(left = LOUT1VOL, right = intermediate
latch)
7
LO1ZC
0
Left zero cross enable
1 = Change gain on zero cross only
0 = Change gain immediately
6:0
LOUT1VOL
1111001
LOUT1 Volume
[6:0]
(0dB)
1111111 = +6dB
… (80 steps)
0110000 = -67dB
0101111 to 0000000 = Analogue
MUTE
R3 (03h)
8
RO1VU
0
ROUT1
Right Volume Update
0 = Store ROUT1VOL in intermediate
latch (no gain change)
Volume
1 = Update left and right channel gains
(left = intermediate latch, right =
ROUT1VOL)
7
RO1ZC
0
Right zero cross enable
1 = Change gain on zero cross only
0 = Change gain immediately
6:0
ROUT1VOL
[6:0]
1111001
ROUT1 Volume
1111111 = +6dB
… (80 steps)
0110000 = -67dB
0101111 to 0000000 = Analogue
MUTE
Table 25 LOUT1/ROUT1 Volume Control
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LOUT2/ROUT2 OUTPUTS
The LOUT2 and ROUT2 output pins are essentially similar to LOUT1 and ROUT1, but they are
independently controlled and can also drive an 8 mono speaker (see Speaker Output section). For
speaker drive, the ROUT2 signal must be inverted (ROUT2INV = 1), so that the left and right channel
are mixed to mono in the speaker [L–(-R) = L+R].
REGISTER
ADDRESS
R40 (28h)
BIT
6:0
LOUT2
LABEL
DEFAULT
DESCRIPTION
LOUT2VOL
1111001
LOUT2 Volume
[6:0]
(0dB)
1111111 = +6dB
Volume
… (80 steps)
0110000 = -67dB
0101111 to 0000000 = Analogue MUTE
7
LO2ZC
0
Left zero cross enable
1 = Change gain on zero cross only
0 = Change gain immediately
8
LO2VU
0
Left Volume Update
0 = Store LOUT2VOL in intermediate
latch (no gain change)
1 = Update left and right channel gains
(left = LOUT2VOL, right = intermediate
latch)
R41 (29h)
6:0
ROUT2
ROUT2VOL
1111001
ROUT2 Volume
[6:0]
(0dB)
1111111 = +6dB
Volume
… (80 steps)
0110000 = -67dB
0101111 to 0000000 = Analogue MUTE
7
RO2ZC
0
Right zero cross enable
1 = Change gain on zero cross only
0 = Change gain immediately
8
RO2VU
0
Right Volume Update
0 = Store ROUT1VOL in intermediate
latch (no gain change)
1 = Update left and right channel gains
(left = ROUT1VOL, right = intermediate
latch)
R24 (18h)
4
ROUT2INV
0
ROUT2 Invert
Additional
Control (2)
0 = No Inversion (0 phase shift)
1 = Signal inverted (180 phase shift)
Table 26 LOUT2/ROUT2 Volume Control
MONO OUTPUT
The MONOOUT pin can drive a mono line output. The signal volume on MONOOUT can be adjusted
under software control by writing to MONOOUTVOL.
REGISTER
ADDRESS
R42 (2Ah)
BIT
6:0
MONOOUT
LABEL
DEFAULT
DESCRIPTION
MONOOUT
1111001
MONOOUT Volume
VOL [6:0]
(0dB)
1111111 = +6dB
Volume
… (80 steps)
0110000 = -67dB
0101111 to 0000000 = Analogue MUTE
7
MOZC
0
MONOOUT zero cross enable
1 = Change gain on zero cross only
0 = Change gain immediately
Table 27 MONOOUT Volume Control
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OUT3 OUTPUT
The OUT3 pin can drive a 16 or 32 headphone or a line output or be used as a DC reference for a
headphone output (see Headphone Output section). It can be selected to either drive out an inverted
ROUT1 or inverted MONOOUT for e.g. an earpiece drive between OUT3 and LOUT1 or differential
output between OUT3 and MONOOUT. OUT3 can also drive an un-inverted ROUT1 signal, which
originates at the right mixer output before the output PGA.
OUT3SW selects the mode of operation required.
REGISTER
ADDRESS
R24 (18h)
BIT
8:7
Additional
Control (2)
LABEL
OUT3SW
DEFAULT
00
[1:0]
DESCRIPTION
OUT3 select
00 : VREF
01 : ROUT1 signal (volume controlled by
ROUT1VOL)
10 : MONOOUT
11 : right mixer output (no volume
control through ROUT1VOL)
Table 28 OUT3 Select
ENABLING THE OUTPUTS
Each analogue output of the WM8750JL can be separately enabled or disabled. The analogue mixer
associated with each output is powered on or off along with the output pin. All outputs are disabled by
default. To save power, unused outputs should remain disabled.
Outputs can be enabled at any time, except when VREF is disabled (VR=0), as this may cause pop
noise (see “Power Management” and “Applications Information” sections)
REGISTER
ADDRESS
BIT
LABEL
DEFAULT
DESCRIPTION
R26 (1Ah)
6
LOUT1
0
LOUT1 Enable
Power
Management
(2)
5
ROUT1
0
ROUT1 Enable
4
LOUT2
0
LOUT2 Enable
3
ROUT2
0
ROUT2 Enable
2
MONO
0
MONOOUT Enable
1
OUT3
0
OUT3 Enable
Note: All “Enable” bits are 1 = ON, 0 = OFF
Table 29 Analogue Output Control
Whenever an analogue output is disabled, it remains connected to VREF (pin 20) through a resistor.
This helps to prevent pop noise when the output is re-enabled. The resistance between VREF and
each output can be controlled using the VROI bit in register 27. The default is low (1.5k), 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 40k.
REGISTER
ADDRESS
R27 (1Bh)
BIT
6
LABEL
VROI
DEFAULT
0
Additional (1)
DESCRIPTION
VREF to analogue output resistance
0: 1.5 k
1: 40 k
Table 30 Disabled Outputs to VREF Resistance
HEADPHONE SWITCH
The RINPUT3/HPDETECT pin can be used as a headphone switch control input to automatically
disable the speaker output and enable the headphone output e.g. when a headphone is plugged into
a jack socket. In this mode, enabled by setting HPSWEN, HPDETECT switches between headphone
and speaker outputs (e.g. when the pin is connected to a mechanical switch in the headphone socket
to detect plug-in). The HPSWPOL bit reverses the pin’s polarity. Note that the LOUT1, ROUT1,
LOUT2 and ROUT2 bits in register 26 must also be set for headphone and speaker output (see Table
31 and Table 32).
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Note:
When RINPUT3/HPDETECT is used as the HPDETECT input, the thresholds become CMOS levels
(0.3 AVDD / 0.7 AVDD).
HPSWEN
HPSWPOL HPDETECT L/ROUT1
(PIN23)
(REG. 26)
(REG. 26)
L/ROUT2
HEADPHONE
ENABLED
SPEAKER
ENABLED
0
X
X
0
0
no
no
0
X
X
0
1
no
yes
0
X
X
1
0
yes
no
0
X
X
1
1
yes
yes
1
0
0
X
0
no
no
1
0
0
X
1
no
yes
1
0
1
0
X
no
no
1
0
1
1
X
yes
no
1
1
0
0
X
no
no
no
1
1
0
1
X
yes
1
1
1
X
0
no
no
1
1
1
X
1
no
yes
Table 31 Headphone Switch Operation
REGISTER
ADDRESS
R24 (18h)
BIT
6
LABEL
HPSWEN
DEFAULT
0
Additional
Control (2)
DESCRIPTION
Headphone Switch Enable
0 : Headphone switch disabled
1 : Headphone switch enabled
5
HPSWPOL
0
Headphone Switch Polarity
0 : HPDETECT high = headphone
1 : HPDETECT high = speaker
Table 32 Headphone Switch
Figure 11 Example Headset Detection Circuit Using Normally-Open Switch
Figure 12 Example Headset Detection Circuit Using Normally-Closed Switch
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THERMAL SHUTDOWN
The speaker and headphone outputs can drive very large currents. To protect the WM8750JL from
overheating a thermal shutdown circuit is included. If the device temperature reaches approximately
150°C and the thermal shutdown circuit is enabled (TSDEN = 1 ) then the speaker and headphone
amplifiers (outputs OUT1L/R, OUT2L/R and OUT3) will be disabled.
REGISTER
ADDRESS
R23 (17h)
BIT
8
LABEL
DEFAULT
TSDEN
0
Additional
Control (1)
DESCRIPTION
Thermal Shutdown Enable
0 : thermal shutdown disabled
1 : thermal shutdown enabled
Table 33 Thermal Shutdown
HEADPHONE OUTPUT
Analogue outputs LOUT1/ROUT1, LOUT2/ROUT2, and OUT3, can drive a 16 or 32 headphone
load, either through DC blocking capacitors, or DC coupled without any capacitor.
Headphone Output using DC blocking
capacitors
DC Coupled Headphone Output
(OUT3SW = 00)
Figure 13 Recommended Headphone Output Configurations
When DC blocking capacitors are used, then their capacitance and the load resistance together
determine the lower cut-off frequency, fc. Increasing the capacitance lowers fc, improving the bass
response. Smaller capacitance values will diminish the bass response. Assuming a 16 Ohm 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 “ground” is connected to the OUT3 pin, which must
be enabled by setting OUT3 = 1 and OUT3SW = 00. As the OUT3 pin produces a DC voltage of
AVDD/2 (=VREF), there is no DC offset between LOUT1/ROUT1 and OUT3, and therefore no DC
blocking capacitors are required. This saves space and material cost in portable applications.
It is recommended to connect the DC coupled headphone outputs only to headphones, and not to the
line input of another device. Although the built-in thermal shutdown circuit will prevent any damage to
the headphone outputs if overloaded, such a connection may be noisy, and may not function properly
if the other device is grounded.
SPEAKER OUTPUT
LOUT2 and ROUT2 can differentially drive a mono 8 speaker as shown below.
LEFT
MIXER
LOUT2
LOUT2VOL
ROUT2INV = 1
VSPKR = L-(-R) = L+R
-1
RIGHT
MIXER
ROUT2VOL
ROUT2
Figure 14 Speaker Output Connection
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The right channel is inverted by setting the ROUT2INV bit, so that the signal across the loudspeaker
is the sum of left and right channels.
LINE OUTPUT
The analogue outputs, LOUT1/ROUT1 and LOUT2/ROUT2, can be used as line outputs. Additionally,
OUT3 and MONOOUT can be used as a stereo line-out by setting OUT3SW=11 (reg. 24) and
ensuring the contents of registers 38 and 39 (mono-out mix) are the same as reg. 34 and 35 (left out
mix). Recommended external components are shown below.
Figure 15 Recommended Circuit for Line Output
The DC blocking capacitors and the load resistance together determine the lower cut-off frequency, fc.
Assuming a 10 kOhm load and C1, C2 = 1F:
fc = 1 / 2 (RL+R1) C1 = 1 / (2 x 10.1k x 1F) = 16 Hz
Increasing the capacitance lowers fc, improving the bass response. Smaller values of C1 and C2 will
diminish the bass response. The function of R1 and R2 is to protect the line outputs from damage
when used improperly.
DIGITAL AUDIO INTERFACE
The digital audio interface is used for inputting DAC data into the WM8750JL and outputting ADC
data from it. It uses five pins:

ADCDAT: ADC data output

ADCLRC: ADC data alignment clock

DACDAT: DAC data input

DACLRC: DAC data alignment clock

BCLK: Bit clock, for synchronisation
The clock signals BCLK, ADCLRC and DACLRC can be outputs when the WM8750JL operates as a
master, or inputs when it is a slave (see Master and Slave Mode Operation, below).
Four different audio data formats are supported:

Left justified

IS

DSP mode
2
All four 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 WM8750JL can be configured as either a master or slave mode device. As a master device the
WM8750JL generates BCLK, ADCLRC and DACLRC and thus controls sequencing of the data
transfer on ADCDAT and DACDAT. In slave mode, the WM8750JL responds with data to clocks it
receives over the digital audio interface. The mode can be selected by writing to the MS bit (see
Table 23). Master and slave modes are illustrated below.
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BCLK
ADCLRC
WM8750JL
CODEC
DACLRC
ADCDAT
DSP
ENCODER/
DECODER
DACDAT
Note: The ADC and DAC can run at different sample rates
Figure 16 Master Mode
Figure 17 Slave Mode
Note: For optimum ADC audio performance in slave mode, the BCLK input signal should be
configured to transition at the same time as the falling edge of MCLK.
The ADCDAT digital data output is buffered inside the CODEC using a digital logic buffering block.
However, the ADCDAT buffering block is not reset by the power-on reset circuit and hence the
ADCDAT pin stage (logic high or logic low) is undefined at power up until data is clocked out from the
ADC. Implementation of either of these workarounds will ensure correct operation:

Ensure that any external connection to the ADCDAT pin is made with the understanding
that ADCDAT pin may be driven high or low by the CODEC until ADC data is clocked out.

Tri-state the ADCDACDAT output pin by setting the TRI bit in R24 (Additional Control 2
register). Setting this bit will also configure ADCLRC, DACLRC and BCLK as inputs and (as
the CODEC has no internal pull-up/down resistors) the input voltage level must be set on
these pins by an external source (either the device connected to the digital audio interface
or pull-up/down resistors) to prevent excess current consumption.
AUDIO DATA FORMATS
2
In I S mode, the MSB is available on the second rising edge of BCLK following a LRCLK 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 18 I S Audio Interface Format (assuming n-bit word length)
In Left Justified mode, the MSB is available on the first rising edge of BCLK following a LRCLK
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 LRCLK transition.
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Figure 19 Left Justified Audio Interface (assuming n-bit word length)
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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 frame pulse shown in Figure 20 and Figure
21. In device slave mode, Figure 22 and Figure 23, it is possible to use any length of frame pulse less
than 1/fs, providing the falling edge of the frame pulse occurs greater than one BCLK period before
the rising edge of the next frame pulse.
Figure 20 DSP/PCM Mode Audio Interface (mode A, LRP=0, Master)
Figure 21 DSP/PCM Mode Audio Interface (mode B, LRP=1, Master)
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Figure 22 DSP/PCM Mode Audio Interface (mode A, LRP=0, Slave)
Figure 23 DSP/PCM Mode Audio Interface (mode B, LRP=0, Slave)
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AUDIO INTERFACE CONTROL
The register bits controlling audio format, word length and master / slave mode are summarised in
Table 34. MS selects audio interface operation in master or slave mode. In Master mode BCLK,
ADCLRC and DACLRC are outputs. The frequency of ADCLRC and DACLRC is set by the sample
rate control bits SR[4:0] and USB. In Slave mode BCLK, ADCLRC and DACLRC are inputs.
REGISTER
ADDRESS
R7 (07h)
BIT
7
LABEL
DEFAULT
BCLKINV
0
Digital Audio
Interface
Format
DESCRIPTION
BCLK invert bit (for master and slave
modes)
0 = BCLK not inverted
1 = BCLK inverted
6
MS
0
Master / Slave Mode Control
1 = Enable Master Mode
0 = Enable Slave Mode
5
LRSWAP
0
Left/Right channel swap
1 = swap left and right DAC data in
audio interface
0 = output left and right data as normal
4
LRP
0
right, left and i2s modes – LRCLK
polarity
1 = invert LRCLK polarity
0 = normal LRCLK polarity
DSP Mode – mode A/B select
st
1 = MSB is available on 1 BCLK rising
edge after LRC rising edge (mode B)
nd
0 = MSB is available on 2 BCLK rising
edge after LRC rising edge (mode A)
3:2
WL[1:0]
10
Audio Data Word Length
11 = 32 bits (see Note)
10 = 24 bits
01 = 20 bits
00 = 16 bits
1:0
FORMAT[1:0]
10
Audio Data Format Select
11 = DSP Mode
2
10 = I S Format
01 = Left justified
00 = Reserved
Table 34 Audio Data Format Control
AUDIO INTERFACE OUTPUT TRISTATE
Register bit TRI, register 24(18h) bit[3] can be used to tristate the ADCDAT pin and switch ADCLRC,
DACLRC and BCLK to inputs. In Slave mode (MASTER=0) ADCLRC, DACLRC and BCLK are by
default configured as inputs and only ADCDAT will be tri-stated, (see Table 35).
REGISTER
ADDRESS
R24(18h)
Additional
Control (2)
BIT
LABEL
DEFAULT
3
TRI
0
DESCRIPTION
Tristates ADCDAT and switches ADCLRC,
DACLRC and BCLK to inputs.
0 = ADCDAT is an output, ADCLRC, DACLRC
and BCLK are inputs (slave mode) or outputs
(master mode)
1 = ADCDAT is tristated, ADCLRC, DACLRC
and BCLK are inputs
Table 35 Tri-stating the Audio Interface
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MASTER MODE ADCLRC AND DACLRC ENABLE
In Master mode, by default ADCLRC is disabled when the ADC is disabled and DACLRC is disabled
when the DAC is disabled. Register bit LRCM, register 24(18h) bit[2] changes the control so that the
ADCLRC and DACLRC are disabled only when ADC and DAC are disabled. This enables the user to
use e.g. ADCLRC for both ADC and DAC LRCLK and disable the ADC when DAC only operation is
required, (see Table 36).
REGISTER
ADDRESS
R24(18h)
Additional
Control (2)
BIT
LABEL
DEFAULT
2
LRCM
0
DESCRIPTION
Selects disable mode for ADCLRC and
DACLRC
0 = ADCLRC disabled when ADC (Left and
Right) disabled, DACLRC disabled when
DAC (Left and Right) disabled.
1 = ADCLRC and DACLRC disabled only when
ADC (Left and Right) and DAC (Left and
Right) are disabled.
Table 36 ADCLRC/DACLRC Enable
BIT CLOCK MODE
The default master mode bit clock generator produces a bit clock frequency based on the sample rate
and input MCLK frequency as shown in Table 40. When enabled by setting the appropriate BCM[1:0]
bits, the bit clock mode (BCM) function overrides the default master mode bit clock generator to
produce the bit clock frequency shown in the table below:
REGISTER
ADDRESS
R8 (08h)
BIT
LABEL
DEFAULT
8:7
BCM[1:0]
00
Clocking and
Sample Rate
Control
DESCRIPTION
BCLK Frequency
00 = BCM function disabled
01 = MCLK/4
10 = MCLK/8
11 = MCLK/16
Table 37 Master Mode BCLK Frequency Control
The BCM mode bit clock generator produces 16 or 24 bit clock cycles per sample. The number of bit
clock cycles per sample in this mode is determined by the word length bits (WL[1:0]) in the Digital
Audio Interface Format register (R7). When these bits are set to 00, there will be 16 bit clock cycles
per sample. When these bits are set to 01, 10 or 11, there will be 24 bit clock cycles per sample.
Please refer to Figure 24.
The BCM generator uses the ADCLRC signal, hence the ADCLRC signal must be enabled when
using bit clock mode. To enable the ADCLRC signal, either the ADC must be powered up or, if the
ADC is not in use, the LRCM bit must be set to enable both the ADCLRC and DACLRC signals when
either the ADC or the DAC is enabled.
When the BCM function is enabled, the following restrictions apply:
1. The bit clock invert (BCLKINV) function is not available.
2. The DAC and ADC must be operated at the same sample rate.
3. DSP late digital audio interface mode is not available and must not be enabled.
Figure 24 Bit Clock Mode
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Note: The shaded bit clock cycles are present only when 24-bit mode is selected. Please refer to the
“Bit Clock Mode” description for details.
CLOCK OUTPUT
By default ADCLRC (pin 9) is the ADC word clock input/output. Under the control of ADCLRM[1:0],
register 27(1Bh) bits [8:7] the ADCLRC pin may be configured as a clock output. If ADCLRM is 01, 10
or 11 then ADCLRC pin is always an output even in slave mode or when TRI = ‘1’, (see Table 38).
The ADC then uses the DACLRC pin as its LRCLK in both master and slave modes.
REGISTER
ADDRESS
R27(1Bh)
Additional
Control (3)
BIT
LABEL
DEFAULT
[8:7] ADCLRM
00
DESCRIPTION
Configures ADCLRC pin
00 = ADCLRC is ADC word clock input (slave
mode) or ADCLRC output (master mode)
[1:0]
01 = ADCLRC pin is MCLK output
10 = ADCLRC pin is MCLK / 5.5 output
11 = ADCLRC pin is MCLK / 6 output
Table 38 ADCLRC Clock Output
CLOCKING AND SAMPLE RATES
The WM8750JL supports a wide range of master clock frequencies on the MCLK pin, and can
generate many commonly used audio sample rates directly from the master clock. The ADC and DAC
do not need to run at the same sample rate; several different combinations are possible.
There are two clocking modes:

‘Normal’ mode supports master clocks of 128fs, 192fs, 256fs, 384fs, and their multiples
(Note: fs refers to the ADC or DAC sample rate, whichever is faster)

USB mode supports 12MHz or 24MHz master clocks. This mode is intended for use in
systems with a USB interface, and eliminates the need for an external PLL to generate
another clock frequency for the audio codec.
REGISTER
ADDRESS
R8 (08h)
Clocking and
Sample Rate
Control
BIT
6
LABEL
CLKDIV2
DEFAULT
0
DESCRIPTION
Master Clock Divide by 2
1 = MCLK is divided by 2
0 = MCLK is not divided
5:1
SR [4:0]
00000
Sample Rate Control
0
USB
0
Clocking Mode Select
1 = USB Mode
0 = ‘Normal’ Mode
Table 39 Clocking and Sample Rate Control
The clocking of the WM8750JL is controlled using the CLKDIV2, USB, and SR control bits. Setting
the CLKDIV2 bit divides MCLK by two internally. The USB bit selects between ‘Normal’ and USB
mode. Each value of SR[4:0] selects one combination of MCLK division ratios and hence one
combination of sample rates (see next page). Since all sample rates are generated by dividing MCLK,
their accuracy depends on the accuracy of MCLK. If MCLK changes, the sample rates change
proportionately.
Note that some sample rates (e.g. 44.1kHz in USB mode) are approximated, i.e. they differ from their
target value by a very small amount. This is not audible, as the maximum deviation is only 0.27%
(8.0214kHz instead of 8kHz in USB mode). By comparison, a half-tone step corresponds to a 5.9%
change in pitch.
The SR[4:0] bits must be set to configure the appropriate ADC and DAC sample rates in both master
and slave mode.
Note: When the ADC is configured at a sample rate of 88.2, 88.235 or 96kHZ (SR[4:0]), the ADC right
channel data output will be delayed by one sample relative to the left channel data.
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MCLK
MCLK
ADC SAMPLE RATE
DAC SAMPLE RATE
CLKDIV2=0
CLKDIV2=1
(ADCLRC)
(DACLRC)
‘Normal’ Clock Mode (‘*’ indicates backward compatibility with WM8731)
8 kHz (MCLK/1536)
8 kHz (MCLK/1536)
24.576 MHz
8 kHz (MCLK/1536)
48 kHz (MCLK/256)
12 kHz (MCLK/1024)
12 kHz (MCLK/1024)
16 kHz (MCLK/768)
16 kHz (MCLK/768)
24 kHz (MCLK/512)
24 kHz (MCLK/512)
32 kHz (MCLK/384)
32 kHz (MCLK/384)
48 kHz (MCLK/256)
8 kHz (MCLK/1536)
48 kHz (MCLK/256)
48 kHz (MCLK/256)
96 kHz (MCLK/128)
96 kHz (MCLK/128)
8.0182 kHz (MCLK/1408)
8.0182 kHz (MCLK/1408)
11.2896MHz 22.5792MHz
8.0182 kHz (MCLK/1408)
44.1 kHz (MCLK/256)
11.025 kHz (MCLK/1024)
11.025 kHz (MCLK/1024)
22.05 kHz (MCLK/512)
22.05 kHz (MCLK/512)
44.1 kHz (MCLK/256)
8.0182 kHz (MCLK/1408)
44.1 kHz (MCLK/256)
44.1 kHz (MCLK/256)
88.2 kHz (MCLK/128)
88.2 kHz (MCLK/128)
8 kHz (MCLK/2304)
8 kHz (MCLK/2304)
18.432MHz 36.864MHz
8 kHz (MCLK/2304)
48 kHz (MCLK/384)
12 kHz (MCLK/1536)
12 kHz (MCLK/1536)
16kHz (MCLK/1152)
16 kHz (MCLK/1152)
24kHz (MCLK/768)
24 kHz (MCLK/768)
32 kHz (MCLK/576)
32 kHz (MCLK/576)
48 kHz (MCLK/384)
48 kHz (MCLK/384)
48 kHz (MCLK/384)
8 kHz (MCLK/2304)
96 kHz (MCLK/192)
96 kHz (MCLK/192)
8.0182 kHz (MCLK/2112)
8.0182 kHz (MCLK/2112)
16.9344MHz 33.8688MHz
8.0182 kHz (MCLK/2112)
44.1 kHz (MCLK/384)
11.025 kHz (MCLK/1536)
11.025 kHz (MCLK/1536)
22.05 kHz (MCLK/768)
22.05 kHz (MCLK/768)
44.1 kHz (MCLK/384)
8.0182 kHz (MCLK/2112)
44.1 kHz (MCLK/384)
44.1 kHz (MCLK/384)
88.2 kHz (MCLK/192)
88.2 kHz (MCLK/192)
USB Mode (‘*’ indicates backward compatibility with WM8731)
8 kHz (MCLK/1500)
8 kHz (MCLK/1500)
12.000MHz 24.000MHz
8 kHz (MCLK/1500)
48 kHz (MCLK/250)
8.0214 kHz (MCLK/1496)
8.0214kHz (MCLK/1496)
8.0214 kHz (MCLK/1496)
44.118 kHz (MCLK/272)
11.0259 kHz (MCLK/1088)
11.0259kHz (MCLK/1088)
12 kHz (MCLK/1000)
12 kHz (MCLK/1000)
16kHz (MCLK/750)
16kHz (MCLK/750)
22.0588kHz (MCLK/544)
22.0588kHz (MCLK/544)
24kHz (MCLK/500)
24kHz (MCLK/500)
32 kHz (MCLK/375)
32 kHz (MCLK/375)
44.118 kHz (MCLK/272)
8.0214kHz (MCLK/1496)
44.118 kHz (MCLK/272)
44.118 kHz (MCLK/272)
48 kHz (MCLK/250)
8 kHz (MCLK/1500)
48 kHz (MCLK/250)
48 kHz (MCLK/250)
88.235kHz (MCLK/136)
88.235kHz (MCLK/136)
96 kHz (MCLK/125)
96 kHz (MCLK/125)
12.288 MHz
USB
SR [4:0]
FILTER
BCLK
TYPE
(MS=1)
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
00110 *
00100 *
01000
01010
11100
01100 *
00010 *
00000 *
01110 *
10110 *
10100 *
11000
11010
10010 *
10000 *
11110 *
00111 *
00101 *
01001
01011
11101
01101 *
00001 *
00011 *
01111 *
10111 *
10101 *
11001
11011
10011 *
10001 *
11111 *
1
1
1
1
1
1
1
1
3
1
1
1
1
1
1
3
1
1
1
1
1
1
1
1
3
1
1
1
1
1
1
3
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/2
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/4
MCLK/2
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/3
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/6
MCLK/3
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
00110 *
00100 *
10111 *
10101 *
11001
01000
01010
11011
11100
01100 *
10011 *
10001 *
00010 *
00000 *
11111 *
01110 *
0
0
1
1
1
0
0
1
0
0
1
1
0
0
3
2
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
MCLK
Table 40 Master Clock and Sample Rates
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CONTROL INTERFACE
SELECTION OF CONTROL MODE
The WM8750JL is controlled by writing to registers through a serial control interface. A control word
consists of 16 bits. The first 7 bits (B15 to B9) are address bits that select which control register is
accessed. The remaining 9 bits (B8 to B0) are data bits, corresponding to the 9 bits in each control
register. The control interface can operate as either a 3-wire or 2-wire MPU interface. The MODE pin
selects the interface format.
MODE
INTERFACE FORMAT
Low
2 wire
High
3 wire
Table 41 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 latches in a complete control word consisting of the last 16 bits.
latch
CSB
SCLK
SDIN
B15
B14
B13
B12
B11
B10
B9
B8
B7
B6
control register address
B5
B4
B3
B2
B1
B0
control register data bits
Figure 25 3-Wire Serial Control Interface
2-WIRE SERIAL CONTROL MODE
The WM8750JL supports software control via a 2-wire serial bus. Many devices can be controlled by
the same bus, and each device has a unique 7-bit address (this is not the same as the 7-bit address
of each register in the WM8750JL).
The WM8750JL 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 WM8750JL and the R/W bit is ‘0’, indicating a write, then the WM8750JL responds
by pulling SDIN low on the next clock pulse (ACK). If the address is not recognised or the R/W bit is
‘1’, the WM8750JL returns to the idle condition and wait for a new start condition and valid address.
Once the WM8750JL has acknowledged a correct address, the controller sends the first byte of
control data (B15 to B8, i.e. the WM8750JL register address plus the first bit of register data). The
WM8750JL then acknowledges the first data byte by pulling SDIN low for one clock pulse. The
controller then sends the second byte of control data (B7 to B0, i.e. the remaining 8 bits of register
data), and the WM8750JL acknowledges again by pulling SDIN low.
The transfer of data is complete when there is a low to high transition on SDIN while SCLK is high.
After receiving a complete address and data sequence the WM8750JL 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 device jumps 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 2
(BITS 7 TO 0)
ACK
(LOW)
SCLK
START
register address and
1st register data bit
remaining 8 bits of
register data
STOP
Figure 26 2-Wire Serial Control Interface
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The WM8750JL has two possible device addresses, which can be selected using the CSB pin.
CSB STATE
DEVICE ADDRESS
Low
0011010 (0 x 34h)
High
0011011 (0 x 36h)
Table 42 2-Wire MPU Interface Address Selection
POWER SUPPLIES
The WM8750JL can use up to four separate power supplies:

AVDD / AGND: Analogue supply, powers all analogue functions except the headphone drivers.
AVDD can range from 1.8V to 3.6V and has the most significant impact on overall power
consumption (except for power consumed in the headphone). A large AVDD slightly improves
audio quality.

HPVDD / HPGND: Headphone supply, powers the headphone drivers. HPVDD is normally tied
to AVDD, but it requires separate layout and decoupling capacitors to curb harmonic distortion.
If HPVDD is lower than AVDD, the output signal may be clipped.

DCVDD: Digital core supply, powers all digital functions except the audio and control interfaces.
DCVDD can range from 1.42V to 3.6V, and has no effect on audio quality. The return path for
DCVDD is DGND, which is shared with DBVDD.

DBVDD: Digital buffer supply, powers the audio and control interface buffers. This makes it
possible to run the digital core at very low voltages, saving power, while interfacing to other
digital devices using a higher voltage. DBVDD draws much less power than DCVDD, and has
no effect on audio quality. DBVDD can range from 1.8V to 3.6V. The return path for DBVDD is
DGND, which is shared with DCVDD.
It is possible to use the same supply voltage on all four. However, digital and analogue supplies
should be routed and decoupled separately to keep digital switching noise out of the analogue signal
paths.
POWER MANAGEMENT
The WM8750JL has two control registers that allow users to select which functions are active. For
minimum power consumption, unused functions should be disabled. To avoid any pop or click noise,
it is important to enable or disable functions in the correct order (see Applications Information).
VMIDSEL is the enable for the Vmid reference, which defaults to disabled and can be enabled as a
50k potential divider or, for low power maintenance of Vref when all other blocks are disabled, as a
500k potential divider.
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REGISTER
ADDRESS
R25 (19h)
BIT
8:7
LABEL
VMIDSEL
DEFAULT
00
DESCRIPTION
Vmid divider enable and select
00 – Vmid disabled (for OFF mode)
Power
Management
(1)
01 – 50k divider enabled (for
playback/record)
10 – 500k divider enabled (for low-power
standby)
11 – 5k divider enabled (for fast start-up)
6
VREF
0
VREF (necessary for all other functions)
0 = Power down
1 = Power up
5
AINL
0
Analogue in PGA Left
0 = Power down
1 = Power up
4
AINR
0
Analogue in PGA Right
0 = Power down
1 = Power up
3
ADCL
0
ADC Left
0 = Power down
1 = Power up
2
ADCR
0
ADC Right
0 = Power down
1 = Power up
1
MICB
0
MICBIAS
0 = Power down
1 = Power up
R26 (1Ah)
Power
Management
(2)
8
DACL
0
DAC Left
0 = Power down
1 = Power up
7
DACR
0
DAC Right
0 = Power down
1 = Power up
6
LOUT1
0
LOUT1 Output Buffer*
0 = Power down
1 = Power up
5
ROUT1
0
ROUT1 Output Buffer*
0 = Power down
1 = Power up
4
LOUT2
0
LOUT2 Output Buffer*
0 = Power down
1 = Power up
3
ROUT2
0
ROUT2 Output Buffer*
0 = Power down
1 = Power up
2
MONO
0
MONOOUT Output Buffer and Mono Mixer
0 = Power down
1 = Power up
1
OUT3
0
OUT3 Output Buffer
0 = Power down
1 = Power up
* The left mixer is enabled when LOUT1=1 or LOUT2=1. The right mixer is enabled when
ROUT1=1 or ROUT2=1.
Table 43 Power Management
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STOPPING THE MASTER CLOCK
In order to minimise power consumed in the digital core of the WM8750JL, the master clock may be
stopped in Standby and OFF modes. If this cannot be done externally at the clock source, the
DIGENB bit (R25, bit 0) can be set to stop the MCLK signal from propagating into the device core. In
Standby mode, setting DIGENB will typically provide an additional power saving on DCVDD of 20uA.
However, since setting DIGENB has no effect on the power consumption of other system components
external to the WM8750JL, it is preferable to disable the master clock at its source wherever possible.
REGISTER
ADDRESS
BIT
R25 (19h)
0
LABEL
DIGENB
DEFAULT
0
DESCRIPTION
Master clock disable
Additional Control
(1)
0: master clock enabled
1: master clock disabled
Table 44 ADC and DAC Oversampling Rate Selection
NOTE: Before DIGENB can be set, the control bits ADCL, ADCR, DACL and DACR must be set
to zero and a waiting time of 1ms must be observed. Any failure to follow this procedure may
prevent DACs and ADCs from re-starting correctly.
SAVING POWER BY REDUCING OVERSAMPLING RATE
The default mode of operation of the ADC and DAC digital filters is in 128x oversampling mode.
Under the control of ADCOSR and DACOSR the oversampling rate may be halved. This will result in
a slight decrease in noise performance but will also reduce the power consumption of the device. In
USB mode ADCOSR must be set to 0, i.e. 128x oversampling.
REGISTER
ADDRESS
BIT
R24 (18h)
1
LABEL
ADCOSR
DEFAULT
0
Additional Control
(2)
DESCRIPTION
ADC oversample rate select
1 = 64x (lowest power)
0 = 128x (best SNR)
0
DACOSR
0
DAC oversample rate select
1 = 64x (lowest power)
0 = 128x (best SNR)
Table 45 ADC and DAC Oversampling Rate Selection
ADCOSR set to ‘1’, 64x oversample mode, is not supported in USB mode (USB=1).
SAVING POWER AT HIGHER SUPPLY VOLTAGES
The analogue supplies to the WM8750JL can run from 1.8V to 3.6V. By default, all analogue circuitry
on the device is optimized to run at 3.3V. This set-up is also good for all other supply voltages down
to 1.8V. At lower voltages, performance can be improved by increasing the bias current. If low power
operation is preferred the bias current can be left at the default setting. This is controlled as shown
below.
REGISTER
ADDRESS
BIT
LABEL
R23 (17h)
7:6
VSEL
[1:0]
Additional
Control(1)
DEFAULT
11
DESCRIPTION
Analogue Bias optimization
00: Highest bias current, optimized for AVDD=1.8V
01: Bias current optimized for AVDD=2.5V
1X: Lowest bias current, optimized for AVDD=3.3V
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REGISTER MAP
ADDRESS
REGISTER
remarks
Bit[8]
Bit[7]
Bit[6]
Bit[5]
Bit[4]
Bit[3]
Bit[2]
Bit[1]
Bit[0]
default
page ref
(Bit 15 – 9)
R0 (00h)
0000000
Left Input volume
LIVU
LINMUTE
LIZC
LINVOL
010010111
19
R1 (01h)
0000001
Right Input volume
RIVU
RINMUTE
RIZC
RINVOL
010010111
19
R2 (02h)
0000010
LOUT1 volume
LO1VU
LO1ZC
LOUT1VOL[6:0]
001111001
32
R3 (03h)
0000011
ROUT1 volume
RO1VU
RO1ZC
ROUT1VOL[6:0]
001111001
32
R4 (04h)
0000100
Reserved
0
0
000000000
-
R5 (05h)
0000101
ADC & DAC Control
ADCHPD
000001000
21, 26,29
R6 (06h)
0000110
Reserved
0
0
0
0
0
000000000
-
R7 (07h)
0000111
Audio Interface
0
BCLKINV
MS
LRSWAP
LRP
FORMAT[1:0]
000001010
42
R8 (08h)
0001000
Sample rate
USB
000000000
43, 44
R9 (09h)
0001001
Reserved
0
0
0
0
000000000
-
R10 (0Ah)
0001010
Left DAC volume
LDVU
011111111
27
0
ADCDIV2 DACDIV2
BCM[1:0]
0
ADCPOL[1:0]
0
0
HPOR
DACMU
0
0
0
DEEMPH[1:0]
0
0
0
WL[1:0]
CLKDIV2
0
0
SR[4:0]
0
0
0
0
LDACVOL[7:0]
R11 (0Bh)
0001011
Right DAC volume
RDVU
011111111
27
R12 (0Ch)
0001100
Bass control
0
BB
BC
0
0
BASS[3:0]
000001111
28
R13 (0Dh)
0001101
Treble control
0
0
TC
0
0
TRBL[3:0]
000001111
28
R15 (0Fh)
0001111
Reset
R16 (10h)
0010000
3D control
0
MODE3D
R17 (11h)
0010001
ALC1
RDACVOL[7:0]
not reset
-
000000000
26
ALCL[3:0]
001111011
24
HLD[3:0]
000000000
24
ATK[3:0]
000110010
24
000000000
25
22
writing to this register resets all registers to their default state
3DUC
ALCSEL[1:0]
ALCZC
3DLC
3DDEPTH[3:0]
MAXGAIN[2:0]
0
0
0
3DEN
R18 (12h)
0010010
ALC2
0
R19 (13h)
0010011
ALC3
0
R20 (14h)
0010100
Noise Gate
0
R21 (15h)
0010101
Left ADC volume
LAVU
LADCVOL[7:0]
011000011
R22 (16h)
0010110
Right ADC volume
RAVU
RADCVOL[7:0]
011000011
DCY[3:0]
NGTH[4:0]
NGG[1:0]
NGAT
22
18, 19, 29,
R23 (17h)
0010111
Additional control(1)
TSDEN
VSEL[1:0]
DMONOMIX[1:0]
DATSEL[1:0]
DACINV
TOEN
011000000
36
33, 34, 35,
R24 (18h)
0011000
Additional control(2)
OUT3SW[1:0]
R25 (19h)
0011001
Pwr Mgmt (1)
VMIDSEL[1:0]
HPSWEN HPSWPOL ROUT2INV
TRI
LRCM
ADCOSR
DACOSR
000000000
DIGENB
000000000
42, 43, 49
DACL
DACR
VREF
48
AINL
AINR
ADCL
ADCR
MICB
LOUT1
ROUT1
LOUT2
ROUT2
MONO
OUT3
0
000000000
48
VROI
HPFLREN
0
0
0
0
0
000000000
21, 34, 44
RDCM
LDCM
0
0
0
0
000000000
17
R26 (1Ah)
0011010
Pwr Mgmt (2)
R27 (1Bh)
0011011
Additional Control (3)
R31 (1Fh)
0011111
ADC input mode
DS
R32 (20h)
0100000
ADCL signal path
0
LINSEL[1:0]
LMICBOOST[1:0]
0
0
0
0
000000000
17
R33 (21h)
0100001
ADCR signal path
0
RINSEL[1:0]
RMICBOOST[1:0]
0
0
0
0
000000000
17
R34 (22h)
0100010
Left out Mix (1)
LD2LO
001010000
30
ADCLRM[1:0]
MONOMIX[1:0]
LI2LO
LI2LOVOL[2:0]
0
LMIXSEL[2:0]
001010000
30
001010000
31
0
001010000
31
0
0
001010000
31
0
0
001010000
31
001111001
33
ROUT2VOL[6:0]
001111001
33
MOUTVOL[6:0]
001111001
33
R35 (23h)
0100011
Left out Mix (2)
RD2LO
RI2LO
RI2LOVOL[2:0]
0
R36 (24h)
0100100
Right out Mix (1)
LD2RO
LI2RO
LI2ROVOL[2:0]
0
R37 (25h)
0100101
Right out Mix (2)
RD2RO
RI2RO
RI2ROVOL[2:0]
0
0
0
R38 (26h)
0100110
Mono out Mix (1)
LD2MO
LI2MO
LI2MOVOL[2:0]
0
0
R39 (27h)
0100111
Mono out Mix (2)
RD2MO
RI2MO
RI2MOVOL[2:0]
0
0
R40 (28h)
0101000
LOUT2 volume
LO2VU
LO2ZC
LOUT2VOL[6:0]
R41 (29h)
0101001
ROUT2 volume
RO2VU
RO2ZC
R42 (2Ah)
0101010
MONOOUT volume
0
MOZC
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0
0
0
RMIXSEL[2:0]
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DIGITAL FILTER CHARACTERISTICS
The ADC and DAC employ different digital filters. There are 4 types of digital filter, called Type 0, 1, 2
and 3. The performance of Types 0 and 1 is listed in the table below, the responses of all filters is
shown in the proceeding pages.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ADC Filter Type 0 (USB Mode, 250fs operation)
Passband
+/- 0.05dB
0
-6dB
0.416fs
0.5fs
Passband Ripple
+/- 0.05
Stopband
dB
0.584fs
Stopband Attenuation
f > 0.584fs
-60
dB
ADC Filter Type 1 (USB mode, 272fs or Normal mode operation)
Passband
+/- 0.05dB
0
-6dB
0.4535fs
0.5fs
Passband Ripple
+/- 0.05
Stopband
dB
0.5465fs
Stopband Attenuation
f > 0.5465fs
High Pass Filter Corner
Frequency
-60
dB
-3dB
3.7
-0.5dB
10.4
-0.1dB
21.6
Hz
DAC Filter Type 0 (USB mode, 250fs operation)
Passband
+/- 0.03dB
0
-6dB
0.416fs
0.5fs
Passband Ripple
+/-0.03
Stopband
dB
0.584fs
Stopband Attenuation
f > 0.584fs
-50
dB
DAC Filter Type 1 (USB mode, 272fs or Normal mode operation)
Passband
+/- 0.03dB
0
-6dB
0.4535fs
0.5fs
Passband Ripple
+/- 0.03
Stopband
dB
0.5465fs
Stopband Attenuation
f > 0.5465fs
-50
dB
Table 46 Digital Filter Characteristics
DAC FILTERS
ADC FILTERS
Mode
Group Delay
Mode
Group Delay
0 (250 USB)
11/FS
0 (250 USB)
13/FS
1 (256/272)
16/FS
1 (256/272)
23/FS
2 (250 USB, 96k mode)
4/FS
2 (250 USB, 96k mode)
4/FS
3 (256/272, 88.2/96k mode)
3/FS
3 (256/272, 88.2/96k mode)
5/FS
Table 47 ADC/DAC Digital Filters Group Delay
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
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DAC FILTER RESPONSES
0.02
0
0.01
0
Response (dB)
Response (dB)
-20
-40
-60
-0.01
-0.02
-0.03
-0.04
-80
-0.05
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
3
-0.06
0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
0.4
0.45
0.5
Figure 27 DAC Digital Filter Frequency Response – Type 0 Figure 28 DAC Digital Filter Ripple – Type 0
0.02
0
0.01
0
Response (dB)
Response (dB)
-20
-40
-60
-0.01
-0.02
-0.03
-0.04
-80
-0.05
-0.06
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
0
3
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
Figure 29 DAC Digital Filter Frequency Response – Type 1 Figure 30 DAC Digital Filter Ripple – Type 1
0.02
0
0.01
0
Response (dB)
Response (dB)
-20
-40
-60
-0.01
-0.02
-0.03
-0.04
-80
-0.05
-0.06
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
3
0
0.05
0.1
0.15
Frequency (Fs)
0.2
0.25
Figure 31 DAC Digital Filter Frequency Response – Type 2 Figure 32 DAC Digital Filter Ripple – Type 2
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0.25
0
0.2
0.15
-20
Response (dB)
Response (dB)
0.1
-40
-60
0.05
0
-0.05
-0.1
-0.15
-80
-0.2
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
-0.25
3
0
0.05
0.1
0.15
Frequency (Fs)
0.2
0.25
Figure 33 DAC Digital Filter Frequency Response – Type 3 Figure 34 DAC Digital Filter Ripple – Type 3
ADC FILTER RESPONSES
0.04
0
0.03
0.02
Response (dB)
Response (dB)
-20
-40
-60
0.01
0
-0.01
-0.02
-80
-0.03
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
-0.04
3
0
Figure 35 ADC Digital Filter Frequency Response – Type 0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
Figure 36 ADC Digital Filter Ripple – Type 0
0.02
0
0.01
0
Response (dB)
Response (dB)
-20
-40
-60
-0.01
-0.02
-0.03
-0.04
-80
-0.05
-0.06
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
Figure 37 ADC Digital Filter Frequency Response – Type 1
w
3
0
0.05
0.1
0.15
0.2
0.25
0.3
Frequency (Fs)
0.35
0.4
0.45
0.5
Figure 38 ADC Digital Filter Ripple – Type 1
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0.25
0
0.2
0.15
-20
Response (dB)
Response (dB)
0.1
-40
-60
0.05
0
-0.05
-0.1
-0.15
-80
-0.2
-100
0
0.5
1
1.5
Frequency (Fs)
2
2.5
-0.25
3
0
Figure 39 ADC Digital Filter Frequency Response – Type 2
0.05
0.1
0.15
Frequency (Fs)
0.2
0.25
Figure 40 ADC Digital Filter Ripple – Type 2
0.25
0
0.2
0.15
-20
Response (dB)
Response (dB)
0.1
-40
-60
0.05
0
-0.05
-0.1
-80
-0.15
-100
-0.25
-0.2
0
0.5
1
1.5
Frequency (Fs)
2
2.5
0
3
Figure 41 ADC Digital Filter Frequency Response – Type 2
0.05
0.1
0.15
Frequency (Fs)
0.2
0.25
Figure 42 ADC Digital Filter Ripple – Type 3
DE-EMPHASIS FILTER RESPONSES
0.4
0
0.3
-2
Response (dB)
Response (dB)
0.2
-4
-6
0.1
0
-0.1
-0.2
-8
-0.3
-0.4
-10
0
2000
4000
6000
8000
10000
Frequency (Fs)
12000
14000
Figure 43 De-emphasis Frequency Response (32kHz)
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16000
0
2000
4000
6000
8000
10000
Frequency (Fs)
12000
14000
16000
Figure 44 De-emphasis Error (32kHz)
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0.4
0
0.3
-2
Response (dB)
Response (dB)
0.2
-4
-6
0.1
0
-0.1
-0.2
-8
-0.3
-0.4
-10
0
5000
10000
Frequency (Fs)
15000
0
20000
Figure 45 De-emphasis Frequency Response (44.1kHz)
5000
10000
Frequency (Fs)
15000
20000
15000
20000
Figure 46 De-emphasis Error (44.1kHz)
0.4
0
0.3
-2
Response (dB)
Response (dB)
0.2
-4
-6
0.1
0
-0.1
-0.2
-8
-0.3
-0.4
-10
0
5000
10000
Frequency (Fs)
15000
0
20000
Figure 47 De-emphasis Frequency Response (48kHz)
5000
10000
Frequency (Fs)
Figure 48 De-emphasis Error (48kHz)
HIGHPASS FILTER
The WM8750JL has a selectable digital highpass filter in the ADC filter path to remove DC offsets. The filter response is
characterised by the following polynomial:
H(z) =
1 - z-1
1 - 0.9995z-1
Figure 49 ADC Highpass Filter Response
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APPLICATIONS INFORMATION
RECOMMENDED EXTERNAL COMPONENTS
DVDD
AVDD
DGND
3
2
18
17
100nF
C1 C2
100nF
HPGND
AGND
DGND
14
19
AVDD
HPVDD
AGND
C4
C3
100nF
DGND
DBVDD
DCVDD
4
100nF
LOUT2
AGND
AUDIO
INTERFACE
(I2S/LJ/RJ/DSP)
1
MCLK
5
9
7
6
8
BCLK
ADCLRC
DACLRC
DACDAT
ADCDAT
ROUT2
MONOOUT
16
+
8 OHM
LOUDSPEAKER
15
10
+ C13
1uF
OUT3
11
32 OHM EAR
SPEAKER
220uF
HIGH for 3-wire
LOW for 2-wire
29
LOUT1
MODE
ROUT1
13
+ C14
12
+ C15
220uF
30
31
32
CONTROL
INTERFACE
(2 OR 3-WIRE)
AVDD
+ C5
10uF
AGND
DVDD
C7
1uF 28
C8
1uF 27
C9
1uF 26
C10
1uF 25
C11
1uF 24
WM8750JL
LINPUT1
MICBIAS
RINPUT1
VREF
LINPUT2
VMID
16 OR 32 OHM
HEADPHONES
22
20
C18
+ C6
10uF
DGND
CSB
SDIN
SCLK
C12
1uF 23
21
C16
100nF
RINPUT2
+ C17
100nF
+ C19
10uF
C20
+ C21
100nF 10uF
10uF
AGND
LINPUT3
RINPUT3 /
HPDETECT
GND_PADDLE
33
AGND
AGND
Layout Notes:
1. C1 to C4, C16, C18 and C20 should be as close to the relative WM8750JL connecting pin as possible.
2. AGND and DGND should be joined as close to the WM8750JL as possible.
3. C20 and C21 are only needed if MICBIAS is used externally.
4. For capacitors C5, C6, C17, C19 and C21 it is recommended that low ESR components are used.
5. For added strength and heat dissipation, it is recommended that the GND_PADDLE (Pin 33) is connected to AGND
Figure 50 Recommended External Components Diagram
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LINE INPUT CONFIGURATION
When LINPUT1/RINPUT1 or LINPUT2/RINPUT2 are used as line inputs, the microphone boost and
ALC functions should normally be disabled.
In order to avoid clipping, the user must ensure that the input signal does not exceed AVDD. This
may require a potential divider circuit in some applications. It is also recommended to remove RF
interference picked up on any cables using a simple first-order RC filter, as high-frequency
components in the input signal may otherwise cause aliasing distortion in the audio band. AC signals
with no DC bias should be fed to the WM8750JL through a DC blocking capacitor, e.g. 1F.
MICROPHONE INPUT CONFIGURATION
MICBIAS
R1
680 Ohm to 2.2kOhm
check microphone's specification
FROM
MICROPHONE
C2
1uF
LINPUT1/2/3
RINPUT1/2/3
AGND
R2
47kOhm
AGND
C1
220pF
AGND
Figure 51 Recommended Circuit for Line Input
For interfacing to a microphone, the ALC function should be enabled and the microphone boost
switched on. Microphones held close to a speaker’s mouth would normally use the 13dB gain setting,
while tabletop or room microphones would need a 29dB boost.
The recommended application circuit is shown above. R1 and R2 form part of the biasing network
(refer to Microphone Bias section). R1 connected to MICBIAS is necessary only for electret type
microphones that require a voltage bias. R2 should always be present to prevent the microphone
input from charging to a high voltage which may damage the microphone on connection. R1 and R2
should be large so as not to attenuate the signal from the microphone, which can have source
impedance greater than 2kOhm. C1 together with the source impedance of the microphone and the
WM8750JL input impedance forms an RF filter. C2 is a DC blocking capacitor to allow the
microphone to be biased at a different DC voltage to the MICIN signal.
MINIMISING POP NOISE AT THE ANALOGUE OUTPUTS
To minimise any pop or click noise when the system is powered up or down, the following procedures
are recommended.
POWER UP

Switch on power supplies. By default the WM8750JL is in Standby Mode, the DAC is
digitally muted and the Audio Interface, Line outputs and Headphone outputs are all OFF
(DACMU = 1 Power Management registers 1 and 2 are all zeros).

Enable Vmid and VREF.

Enable DACs as required

Enable line and / or headphone output buffers as required.

Set DACMU = 0 to soft-un-mute the audio DACs.
POWER DOWN
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
Set DACMU = 1 to soft-mute the audio DACs.

Disable all output buffers.

Switch off the power supplies.
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POWER MANAGEMENT EXAMPLES
AINL/R
POWER MANAGEMENT (1)
VREF
OPERATION MODE
PGAs
POWER MANAGEMENT (2)
ADCs
PGL PGR ADL ADR
DACs
MBI
DAL DAR
Output Buffers
LO1
RO1
LO2
RO2
MO
HPD
Stereo Headphone Playback
1
0
0
0
0
0
0
1
1
1
1
0
0
0
x
Stereo Line-in Record
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
Stereo Microphone Record
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
Mono Microphone Record
1
1
1
0
1
0
1
0
0
0
0
0
0
0
0
Stereo Line-in to Headphone Out
1
1
0
0
0
0
0
0
0
1
1
0
0
0
x
Phone Call
1
1
1
0
0
0
1
0
0
1
1
0
0
1
x
Speaker Phone Call [ROUT2INV = 1]
1
1
1
0
0
0
1
0
0
0
0
1
1
1
0
Record Phone Call [L channel = mic with
boost, R channel = RX, enable mono mix]
1
1
1
1
1
1
1
0
0
1
1
0
0
1
x
Table 48 Register Settings for Power Management
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PACKAGE DIMENSIONS
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
2X
16
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
0.30
0.25
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.
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IMPORTANT NOTICE
Wolfson Microelectronics plc (“Wolfson”) products and services are sold subject to Wolfson’s terms and conditions of sale,
delivery and payment supplied at the time of order acknowledgement.
Wolfson warrants performance of its products to the specifications in effect at the date of shipment. Wolfson reserves the
right to make changes to its products and specifications or to discontinue any product or service without notice. Customers
should therefore obtain the latest version of relevant information from Wolfson to verify that the information is current.
Testing and other quality control techniques are utilised to the extent Wolfson deems necessary to support its warranty.
Specific testing of all parameters of each device is not necessarily performed unless required by law or regulation.
In order to minimise risks associated with customer applications, the customer must use adequate design and operating
safeguards to minimise inherent or procedural hazards. Wolfson is not liable for applications assistance or customer
product design. The customer is solely responsible for its selection and use of Wolfson products. Wolfson is not liable for
such selection or use nor for use of any circuitry other than circuitry entirely embodied in a Wolfson product.
Wolfson’s products are not intended for use in life support systems, appliances, nuclear systems or systems where
malfunction can reasonably be expected to result in personal injury, death or severe property or environmental damage.
Any use of products by the customer for such purposes is at the customer’s own risk.
Wolfson does not grant any licence (express or implied) under any patent right, copyright, mask work right or other
intellectual property right of Wolfson covering or relating to any combination, machine, or process in which its products or
services might be or are used. Any provision or publication of any third party’s products or services does not constitute
Wolfson’s approval, licence, warranty or endorsement thereof. Any third party trade marks contained in this document
belong to the respective third party owner.
Reproduction of information from Wolfson datasheets is permissible only if reproduction is without alteration and is
accompanied by all associated copyright, proprietary and other notices (including this notice) and conditions.
Wolfson is
not liable for any unauthorised alteration of such information or for any reliance placed thereon.
Any representations made, warranties given, and/or liabilities accepted by any person which differ from those contained in
this datasheet or in Wolfson’s standard terms and conditions of sale, delivery and payment are made, given and/or
accepted at that person’s own risk. Wolfson is not liable for any such representations, warranties or liabilities or for any
reliance placed thereon by any person.
ADDRESS
Wolfson Microelectronics plc
Westfield House
26 Westfield Road
Edinburgh
EH11 2QB
United Kingdom
Tel :: +44 (0)131 272 7000
Fax :: +44 (0)131 272 7001
Email :: [email protected]
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REVISION HISTORY
DATE
REV
ORIGINATOR
CHANGES
16/01/12
4.1
JMacD
Order codes updated from WM8750JLGEFL and WM8750JLGEFL/R to
WM8750CJLGEFL and WM8750CJLGEFL/R to reflect change to copper wire
bonding.
16/01/12
4.1
w
JMacD
Package diagram changed to DM101.A
PD, April 2012, Rev 4.1
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