ams AS3430 Low power ambient noise-cancelling speaker driver Datasheet

AS3400 AS3410 AS3430
L o w P o w e r A m b i e n t N o i s e - C an c e l l i n g S p e a k e r D r i v e r
1 General Description
Line Input
Volume control via serial interface or volume pin
The AS3400/10/30 are speaker driver with Ambient Noise Cancelling
function for handsets, headphones or ear pieces. It is intended to
improve quality of e.g. music listening, a phone conversation etc. by
reducing background ambient noise.
The fully analog implementation allows the lowest power
consumption, lowest system BOM cost and most natural received
voice enhancement otherwise difficult to achieve with DSP
implementations. The device is designed to be easily applied to
existing architectures.
64 steps @ 0.75dB and MUTE, pop-free gain setting
Single ended stereo or mono differential mode
ANC processing
Feed-forward cancellation
Feed-back cancellation with filter loop transfer function
definable via simple RC components
Simple in production SW calibration
An internal OTP-ROM can be optionally used to store the
microphones gain calibration settings.
12-30dB noise reduction (headset dependent)
10-2000Hz wide frequency active noise attenuation (headset
dependent)
The AS3400/10/30 can be used in different configurations for best
trade-off of noise cancellation, required filtering functions and
mechanical designs.
The simpler feed-forward topology is used to effectively reduce low
frequency background noise. The feed-back topology with either 1 or
2 filtering stages can be used to reduce noise for a larger frequency
range, and to even implement transfer functions like speaker
equalization, Baxandall equalization, high/low shelving filter and to
set a predefined loop bandwidth.
The filter loop is optimized by the user for specific handset electrical
and mechanical designs by dimensioning simple R, C components.
Most handset implementations will make use of a single noise
detecting microphone. Two microphones could be used to allow for
increased flexibility of their location in the handset mechanical
design. Using the bridged mode allows to even drive high impedance
headsets.
Monitor Function
For assisted hearing, i.e. to monitor announcements
Fixed (OTP prog.) ambient sound amplification to compensate
headphone passive attenuation
Volume controlled ambient sound amplification mixed with fixed
(OTP prog.) attenuation of LineIn
Incremental Functions
ANC with or without music on the receiving path
Improved dynamic range playback
OTP ROM for automatic trimming during production (4 times
programbable)
Performance Parameter
2 Key Features
Microphone Input
128 gain steps @ 0.375dB and MUTE with AGC
Differential, low noise microphone amplifier
Single ended or differential mode
Improved supply for electret microphone
MIC gain OTP programmable
High Efficiency Headphone Amplifier
2x34mW, 0.1% THD @ 16Ω, 1.5V supply,
100dB SNR
Bridged mode for e.g. 300Ω loads
Click and pop less start-up and mode switching
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5/3.8mA @ 1.5V stereo/mono ANC; <1µA quiescent
Extended PSRR for 217Hz
Interfaces
2-wire serial control mode & volume inputs
Calibration via Line-In or 2-wire serial interface (patent pending)
Single cell or fixed 1.0-1.8V supply with internal CP
Package
AS3400, AS3410 QFN24 [4x4mm] 0.5mm pitch
AS3430 QFN32 [5.x5mm] 0.5mm pitch
3 Applications
The devices are ideal for Ear pieces, Headsets, Hands-Free Kits,
Mobile Phones, and Voice Communicating Devices.
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n s
Figure 1. AS3410 Feed Forward ANC Block Diagram
Figure 2. AS3430 Feed-Back Block Diagram
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Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n s
Figure 3. AS3400 Feed-Back Block Diagram
Figure 4. AS3400 Feed Forward Block Diagram
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AS3400 AS3410 AS3430 1v0
Data Sheet - C o n t e n t s
Contents
1 General Description ..................................................................................................................................................................
1
2 Key Features.............................................................................................................................................................................
1
3 Applications...............................................................................................................................................................................
1
4 Pin Assignments .......................................................................................................................................................................
4
4.1 Pin Descriptions....................................................................................................................................................................................
5
5 Absolute Maximum Ratings ......................................................................................................................................................
7
6 Electrical Characteristics...........................................................................................................................................................
8
7 Typical Operating Characteristics .............................................................................................................................................
9
8 Detailed Description................................................................................................................................................................
12
8.1 Audio Line Input..................................................................................................................................................................................
12
8.1.1 Gain Stage................................................................................................................................................................................. 12
8.1.2 Parameter .................................................................................................................................................................................. 12
8.2 Microphone Input................................................................................................................................................................................
13
8.2.1 Gain Stage & Limiter.................................................................................................................................................................. 13
8.2.2 Supply........................................................................................................................................................................................ 13
8.2.3 Parameter .................................................................................................................................................................................. 14
8.3 Headphone Output .............................................................................................................................................................................
8.3.1
8.3.2
8.3.3
8.3.4
8.3.5
Input Multiplexer ........................................................................................................................................................................
No-Pop Function........................................................................................................................................................................
No-Clip Function ........................................................................................................................................................................
Over-Current Protection.............................................................................................................................................................
Parameter ..................................................................................................................................................................................
8.4 Operational Amplifier ..........................................................................................................................................................................
15
15
15
15
15
16
16
8.4.1 Parameter .................................................................................................................................................................................. 16
8.5 SYSTEM.............................................................................................................................................................................................
8.5.1
8.5.2
8.5.3
8.5.4
Power Up/Down Conditions.......................................................................................................................................................
Start-up Sequence.....................................................................................................................................................................
Mode Switching .........................................................................................................................................................................
Status Indication ........................................................................................................................................................................
8.6 VNEG Charge Pump ..........................................................................................................................................................................
17
17
17
18
19
19
8.6.1 Parameter .................................................................................................................................................................................. 19
8.7 OTP Memory & Internal Registers......................................................................................................................................................
19
8.7.1 Register & OTP Memory Configuration ..................................................................................................................................... 19
8.7.2 OTP Fuse Burning ..................................................................................................................................................................... 20
8.8 2-Wire-Serial Control Interface ...........................................................................................................................................................
21
8.8.1 Protocol...................................................................................................................................................................................... 21
8.8.2 Parameter .................................................................................................................................................................................. 24
9 Register Description................................................................................................................................................................
25
10 Application Information .........................................................................................................................................................
38
11 Package Drawings and Markings..........................................................................................................................................
43
12 Ordering Information.............................................................................................................................................................
47
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AS3400 AS3410 AS3430 1v0
Data Sheet - P i n A s s i g n m e n t s
4 Pin Assignments
Note: Pin assignment may change in preliminary data sheets.
19 CPP
20 GND
17 HPR
AGND 2
17 HPVDD
AS3400
16 HPL
LINL 3
AS3410
16 HPR
QFN 24pin
15 VSS
LINR 4
QFN 24pin
15 HPL
14 QOP2R
24 VBAT
QLINL 2
23 HPVDD
QMICL 3
22 HPR
AS3430
LINL 5
IOP1R 12
QMICR 11
MICR 10
25 n.c.
26 CPP
27 GND
28 CPN
29 VNEG
30 QOP2L
31 IOP2L
MICL 7
13 QOP1R
IOP1L 1
AGND 4
14 VSS
25 VNEG or open
MODE_CSCL 6
QOP1R 12
32 QOP1L
IOP1R 11
QLINR 10
QMICR 9
13 IOP2R
MICR 8
MICL 6
VOL_CSDA 5
MICS 9
25 VNEG or open
MICS 7
21 CPN
18 VBAT
VOL_CSDA 4
21 HPVSS
20 HPL
QFN 32pin
LINR 6
19 VSS
33 Exposed Pad: VNEG
or open
VOL_CSDA 7
18 QOP2R
Revision 1.02
QOP1R 16
IOP1R 15
QLINR 14
QMICR 13
MICR 12
MICS 11
ILED 10
17 IOP2R
MICL 9
MODE_CSCL 8
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22 VNEG
QMICL 1
LINL 2
MODE_CSCL 5
23 QOP1L
18 HPVDD
ILED 8
AGND 1
LINR 3
24 IOP1L
19 VBAT
20 CPP
21 GND
22 CPN
23 VNEG
24 QMICL
Figure 5. Pin Assignments (Top View)
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AS3400 AS3410 AS3430 1v0
Data Sheet - P i n A s s i g n m e n t s
4.1 Pin Descriptions
Note: Pin description may change in preliminary data sheets.
Table 1. Pin Description for AS3400 AS3410 AS3430
Pin Name
Pin Number
Type
Description
AS3400
AS3410
AS3430
IOP1L
-
24
1
ANA IN
QLINL
-
-
2
ANA OUT
Line In GainStage Output Left Channel
QMICL
24
1
3
ANA OUT
MIC GainStage Output Right Channel
AGND
1
2
4
ANA IN
Analog Reference
Filter OpAmp1 Input Left Channel
LINL
2
3
5
ANA IN
DIG IN
Line In Left Channel
During Appl Trim Mode Write – CSDA
During Appl Trim Mode Burn – VNEG
LINR
3
4
6
ANA IN
DIG IO
LineIn Right Channel
During Appl Trim Mode Write – CSCL
During Appl Trim Mode Burn – Clock
VOL_CSDA
4
5
7
MIXED IO
Serial Interface Data
ADC Input for volume regulation
MODE_CSCL
5
6
8
DIG IN
Mode Pin (PowerUp/Dn, Monitor)
Serial Interface Clock
MICL
6
7
9
ANA IN
Microphone In Left Channel
ILED
-
8
10
ANA OUT
Current Output for on-indication LED
MICS
7
9
11
ANA OUT
Microphone Supply
MICR
8
10
12
ANA IN
QMICR
9
11
13
ANA OUT
MIC GainStage Output Right Channel
QLINR
10
-
14
ANA OUT
Line In GainStage Output Right Channel
IOP1R
11
12
15
ANA IN
FilterOpAmp1 Input Right Channel
QOP1R
12
13
16
ANA IN
Filter OpAmp1 Output Right Channel
IOP2R
13
-
17
ANA IN
Filter OpAmp2 Input Right Channel
QOP2R
14
-
18
ANA OUT
VSS
15
14
19
SUP IN
HPL
16
15
20
ANA OUT
HPVSS
-
-
21
SUP IN
HPR
17
16
22
ANA OUT
HPVDD
18
17
23
SUP IN
Headphone VDD Supply
VBAT
19
18
24
SUP IN
VNEG ChargePump Positive Supply
n.c.
-
-
25
-
CPP
20
19
26
ANA OUT
GND
21
20
27
GND
CPN
22
21
28
ANA OUT
VNEG
23
22
29
SUP IO
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Revision 1.02
Microphone Input Right Channel
Filter OpAmp2 Output Right Channel
Core and Periphery Circuit VSS Supply
Headphone Output Left Channel
Headphone VSS Supply
Headphone Output Right Channel
VNEG ChargePump Flying Capacitor Positive Terminal
VNEG ChargePump Negative Supply
VNEG ChargePump Flying Capacitor Negative Terminal
VNEG ChargePump Output
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AS3400 AS3410 AS3430 1v0
Data Sheet - P i n A s s i g n m e n t s
Table 1. Pin Description for AS3400 AS3410 AS3430
Pin Name
Pin Number
Type
AS3400
AS3410
AS3430
QOP2L
-
-
30
ANA OUT
IOP2L
-
-
31
ANA IN
QOP1L
-
23
32
ANA OUT
25
25
33
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Description
Filter OpAmp2 Output Left Channel
Filter OpAmp2 Input Left Channel
Filter OpAmp1 Output Right Channel
Exposed Pad: connect to VNEG or leave it unconnected
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AS3400 AS3410 AS3430 1v0
Data Sheet - A b s o l u t e M a x i m u m R a t i n g s
5 Absolute Maximum Ratings
Stresses beyond those listed in Table 2 may cause permanent damage to the device. These are stress ratings only, and functional operation of
the device at these or any other conditions beyond those indicated in Electrical Characteristics on page 9 is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability. The device should be operated under recommended operating
conditions.
Table 2. Absolute Maximum Ratings
Parameter
Min
Max
Units
Comments
Reference Ground
Defined as in GND
Supply terminals
-0.5
2.0
V
Applicable for pin VBAT, HPVDD
Ground terminals
-0.5
0.5
V
Applicable for pins AGND
Negative terminals
-2.0
0.5
V
Applicable for pins VNEG, VSS, HPVSS
Voltage difference at VSS terminals
-0.5
0.5
V
Applicable for pins VSS, HPVSS
Pins with protection to VBAT
VNEG
-0.5
5.0
VBAT+0.5
V
Applicable for pins CPP, CPN
Pins with protection to HPVDD
VSS
-0.5
5.0
HPVDD+0.5
V
Applicable for pins LINL/R, MICL/R, ILED, HPR,
HPL, QMICL/R, QLINL/R, IOPx, QOPx
other pins
VSS
-0.5
5
Input Current (latch-up immunity)
-100
100
mA
Norm: JEDEC 17
-
200
mW
PT for QFN16/24/32 package
+/-2
kV
Norm: JEDEC JESD22-A114C
Applicable for pins MICS, VOL_CSDA,
MODE_CSCL
Continuous Power Dissipation (TA = +70ºC)
Continuous Power Dissipation
1
Electrostatic Discharge
Electrostatic Discharge HBM
Temperature Ranges and Storage Conditions
Junction Temperature
+110
ºC
Storage Temperature Range
-55
+125
ºC
Humidity non-condensing
5
85
%
Moisture Sensitive Level
Package Body Temperature
3
Represents a max. floor life time of 168h
260
ºC
The reflow peak soldering temperature (body
temperature) specified is in accordance with IPC/
JEDEC J-STD-020“Moisture/Reflow Sensitivity
Classification for Non-Hermetic Solid State
Surface Mount Devices”.
1. Depending on actual PCB layout and PCB used
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Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - E l e c t r i c a l C h a r a c t e r i s t i c s
6 Electrical Characteristics
VBAT = 1.0V to 1.8V, TA = -20ºC to +85ºC. Typical values are at VBAT = 1.5V, TA = +25ºC, unless otherwise specified.
Table 3. Electrical Characteristics
Symbol
Parameter
TA
Condition
Min
Max
Unit
Ambient Temperature Range
-20
+85
°C
GND
Reference Ground
0
0
V
VBAT,
HPVDD
Battery Supply Voltage
normal operation with MODE pin high
1.0
1.8
V
Two wire interface operation
1.4
1.8
V
VNEG
ChargePump Voltage
-1.8
-0.7
V
VSS
Analog neg. Supply Voltages
HPVSS, VSS, VNEG
-1.8
-0.7
V
VDELTA-
Difference of Ground Supplies
GND, AGND
To achieve good performance, the negative
supply terminals should be connected to low
impedance ground plane.
-0.1
0.1
V
VDELTA--
Difference of Negative Supplies
VSS, VNEG, HPVSS
Charge pump output or external supply
-0.1
0.1
V
VDELTA+
Difference of Positive Supplies
VBAT-HPVDD
-0.25
0.25
V
VMICS
Microphone Supply Voltage
MICS
0
3.6
V
VHPVDD
Pins with diode to HPVDD
MICL/R, ILED, HPR, HPL, QMICL/R, QLINL/
R, IOPx, QOPx
VSS
3.6
V
VVBAT
Pins with diode to VBAT
CPP, CPN
VNEG
VBAT
V
VCONTROL
Control Pins
VSS
3.7
V
VTRIM
Line Input & Application Trim Pins
LINL, LINR
VNEG -0.5
or -1.8
HPVDD +0.5
or 1.8
V
Symbol
Parameter
Condition
Ileak
Leakage current
Supply Voltages
Other pins
MODE_CSCL, VOL_CSDA
Min
Typ
Max
Unit
VBAT<0.8V
20
µA
VBAT<0.6V
10
µA
Block Power Requirements @ 1.5V VBAT
ISYS
Reference supply current
Bias generation, oscillator, ILED current sink,
ADC6
0.25
mA
ILIN
LineIn gain stage current
no signal, stereo
0.64
mA
IMIC
Mic gain stage current
no signal, stereo
2.10
mA
IHP
Headphone stage current
no signal
1.70
mA
IVNEG
VNEG charge pump current
no load
0.25
mA
IMICS
MICS charge pump current
no load
0.06
mA
IMIN
Minimal supply current
Sum of all above blocks
5.00
mA
IOP1
OP1 supply current
no load
0.64
mA
IOP2
OP2 supply current
no load
0.64
mA
IILED
ILED current sink current
100% duty cycle
2.50
mA
IMICB
Microphone bias current
200µA per microphone via charge pump
1.30
mA
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AS3400 AS3410 AS3430 1v0
Data Sheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
7 Typical Operating Characteristics
VBAT = +1.5V, TA = +25ºC, unless otherwise specified.
Figure 6. LIN to HPH: THD+N vs. Output Power
THD+N vs POUT - 16Ω - single ended stereo
THD+N vs POUT - 32Ω - stereo single ended
1
1
VBAT=1.8V
VBAT=1.5V
VBAT=1.0V
THD+N [%]
THD+N [%]
VBAT=1.8V
VBAT=1.5V
VBAT=1.0V
0,1
0,1
0,01
0,01
0
10
20
30
40
50
0
60
5
10
15
THD+N vs POUT - 32Ω - bridged-tied load
25
30
35
40
THD+N vs POUT - 64Ω - bridged-tied load
1
1
VBAT=1.8V
VBAT=1.8V
VBAT=1.5V
VBAT=1.5V
VBAT=1.0V
VABT=1.0V
THD+N [%]
THD+N [%]
20
Pout [mW]
Pout [mW]
0,1
0,1
0,01
0,01
0
10
20
30
40
50
60
70
80
90
100
110
120
0
130
10
20
30
40
50
60
70
80
90
Pout [mW]
Pout [mW]
Figure 7. VNEG Charge Pump
VNEG CP Voltage vs Load Current
VNEG CP Efficiency
0,0
100
-0,2
95
VBAT=1.0V
-0,4
90
VBAT=1.5V
VBAT=1.8V
85
80
-0,8
Eff [%]
V_VNEG [V]
-0,6
-1,0
75
70
-1,2
65
-1,4
VBAT=1.0V
VBAT=1.5V
60
-1,6
VBAT=1.8V
55
-1,8
50
0
50
100
150
200
I_VNEG [mA]
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0
20
40
60
80
100
120
140
160
180
200
I_VNEG [mA]
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
Figure 8. Microphone Supply Generation
I_MICS vs dI_VBAT
7000
3
6000
2,5
5000
dI_VBAT [uA]
V_MICS [V]
MICS Charge Pump
3,5
2
1,5
VBAT=1.8V
VBAT=1.5V
VABT=1.0V
1
4000
VBAT=1.8V
VBAT=1.5V
VBAT=1.0V
3000
2000
1000
0,5
0
0
0
500
1000
1500
0
2000
500
1000
V_MICS vs V_VBAT
140
3,3
130
R_MICS_Switch [Ω]
V_MICS [V]
120
I_MCS = 0.0uA
I_MICS = 600uA
2,9
2000
R_MICS_Switch vs V_VBAT
3,5
3,1
1500
I_MICS [uA]
I_MICS [uA]
2,7
2,5
2,3
2,1
110
100
90
80
70
1,9
60
1,7
50
40
1,5
0,9
1,0
1,1
1,2
1,3
1,4
1,5
1,6
1,7
0,9
1,8
1,0
1,1
1,2
VBAT [V]
1,3
1,4
1,5
1,6
1,7
1,8
VBAT [V]
Figure 9. ILED Current Sink (100% PWM setting)
ILED Current
ILED Current
120,0
120,0
100,0
100,0
ILED (Vbat=1.5V)
ILED (Vbat=1.0V)
60,0
ILED (Vbat=1.8V)
80,0
ILED (Vbat=1.8V)
I (ILED) [%]
I (ILED) [%]
80,0
ILED (Vbat=1.5V)
ILED (Vbat=1.0V)
60,0
40,0
40,0
20,0
20,0
0,0
0,0
0,0
0,1
0,2
0,3
0,4
0,5
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0,0
0,5
1,0
1,5
2,0
2,5
3,0
V (ILED-VNEG) [V]
V (ILED-VNEG) [V]
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - Ty p i c a l O p e r a t i n g C h a r a c t e r i s t i c s
Figure 10. THD vs. Frequency @ 1.5V, 16Ω, 25mW
Figure 11. Typical Performance Data, FF Configuration
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AS3400 AS3410 AS3430 1v0
Data Sheet - D e t a i l e d D e s c r i p t i o n
8 Detailed Description
This section provides a detailed description of the device related components.
8.1 Audio Line Input
The chip features one line input. The blocks can work in mono differential or in stereo single ended mode.
In addition to the 12.5-25kΩ input impedance, LineIn has a termination resistor of 10kΩ which is also effective during MUTE to charge
eventually given input capacitors.
8.1.1
Gain Stage
The Line In gain stage is designed to have 63 gain steps of 0.75dB with a max gain of 0dB plus MUTE.
In default, the gain will be ramped up from MUTE to 0dB during startup. There is a possibility to make the playback volume user controlled by the
VOL pin with an ADC converted VOL voltage or UP/DN buttons.
In monitor mode, the gain stage can be set to an fixed default attenuation level for reducing the loudness of the music.
Figure 12. Line Inputs
12.5k
LINR
k
12.5k
LINR
mute
QLINR
10k
mute
QLINR
10k
AGND
AGND
10k
10k
QLINL
mute
QLINL
mute
LINL
LINL
12.5k
k
AGND
12.5k
stereo mode
8.1.2
k
k
mono differential mode
Parameter
VBAT=1.5V, TA= 25ºC, unless otherwise specified.
Table 4. Line Input Parameter
Symbol
Parameter
VLIN
Input Signal Level
Condition
Min
Typ
Max
Unit
0.6*
VBAT
VBAT
VPEAK
0dB gain (12.5k // 10k)
5.6
kΩ
-46.5dB gain (25k // 10k)
7.2
kΩ
MUTE
RLIN
Input Impedance
10
kΩ
ΔRLIN
Input Impedance Tolerance
±30
%
CLIN
Input Capacitance
5
pF
ALIN
Programmable Gain
Gain Steps
ALINMUTE
-46.5
dB
0.75
dB
Gain Step Accuracy
0.5
dB
Mute Attenuation
100
dB
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Discrete logarithmic gain steps
+0
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - D e t a i l e d D e s c r i p t i o n
Table 4. Line Input Parameter (Continued)
Symbol
ΔALIN
Parameter
Condition
Gain Ramp Rate
Min
Typ
PotiMode, Tinit=100ms
20
ButtonMode, Tinit=400ms
80
MonitorMode
8
VATTACK
Limiter Activation Level
HPL/R start of neg. clipping
VDECAY
Limiter Release Level
HPL/R
tATTACK
tDECAY
Max
Unit
ms/step
VPEAK
VNEG
+0.3
VPEAK
Limiter Attack Time
4
µs
Limiter Decay Time
8
ms
8.2 Microphone Input
The AFE offers two microphone inputs and one low noise microphone voltage supply (microphone bias). The inputs can be switched to single
ended or differential mode.
Figure 13. Microphone Input
MICR
MICR
QMICR
AGND
QMICR
AGND
QMICL
MICL
QMICL
MICL
AGND
stereo mode
8.2.1
mono differential mode
Gain Stage & Limiter
The Mic GainStage has programmable Gain within -6dB…+41.625dB in 128 steps of 0.375dB.
As soft-start function is implemented for an automatic gain ramping implemented with steps of 4ms to fade in the audio at the end of the start-up
sequence.
A limiter automatically attenuates high input signals. The AGC has 127 steps with 0.375dB with a dynamic range of the full gain stage.
In monitor mode, the gain stage can be set to an fixed (normally higher) gain level or be controlled by the VOL pin.
8.2.2
Supply
The MICS charge pump is providing a proper microphone supply voltage for the AAA supply. Since AAA batteries are operating down to 1.0V,
the direct battery voltage cannot be used for mic-supply. There are 2 modes.
The first mode SWITCH-MODE for 1.8V supply is to have just a switch from VBAT to MICS. With this switch, the microphone current is switched
off in idle mode.
The second mode CHAREGPUMP_MODE for AAA batteries is the real charge pump mode, in this mode a positive voltage is generated of about
2* VBAT.
It is also possible to switch off the microphone supply if not needed (e.g. playback without ANC)
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Data Sheet - D e t a i l e d D e s c r i p t i o n
8.2.3
Parameter
VBAT=1.5V, TA= 25ºC unless otherwise specified.
Table 5. Microphone Input Parameter
Symbol
Parameter
Condition
VMICIN0
Input Signal Level
AMIC = 30dB
Min
Typ
Max
20
mVP
Unit
VMICIN1
AMIC = 36dB
10
mVP
VMICIN2
AMIC = 42dB
5
mVP
MICP to AGND
7.5
kΩ
RMICIN
Input Impedance
ΔMICIN
Input Impedance Tolerance
-7
+33
%
CMICIN
Input Capacitance
5
pF
AMIC
Programmable Gain
Gain Steps
-6
Discrete logarithmic gain steps
Gain Step Precision
+41.6
dB
0.375
dB
0.15
dB
4
ms/step
0.67
1
0.4
1
41.625
dB
ΔAMIC
Gain Ramp Rate
VATTACK
Limiter Activation Level
VDECAY
Limiter Release Level
AMICLIMIT
Limiter Gain Overdrive
tATTACK
Limiter Attack Time
5
µs/step
tDECAY-DEB
Limiter Decay Debouncing Time
64
ms
tDECAY
Limiter Decay Time
4
ms/step
VMICS
Microphone Supply Voltage
VBAT*2240mV
V
IMICSMIN
Min. Microphone Supply Current
650
µA
ROUT_CP
CP Output Resistance
1300
Ω
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Tinit=64ms
VPEAK related to VBAT or VNEG
127 @ 0.375dB
VBAT=+1.0V
VNEG=-0.7V
MICS=+1.75V
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8.3 Headphone Output
The headphone output is a true ground output using VNEG as negative supply, designed to provide the audio signal with 2x12mW @ 16Ω-64Ω,
which are typical values for headphones. It is also capable to operate in bridged mode for higher impedance (e.g. 300Ω) headphone. In this
mode the left output is carrying the inverted signal of the right output shown in Figure 15.
Figure 14. Headphone Output Single Ended Mode
HPVDD
MUX
QMicR
QOP1R
QOP2R
open
LineInR
HPR
AGND
HPL
LineInL
MUX
open
QOP2L
QOP1L
QMicL
Pop
Click
Control
LineIn
gain stage
HPVSS
Figure 15. Headphone Output Differential Mode
8.3.1
Input Multiplexer
The signal from the line-input gain stage gets summed at the input of the headphone stage with the microphone gain stage output, the first filter
opamp output or the second filter opamp output. The microphone gain stage output is used per default. It is also possible to playback without
ANC by only using the line-input gain stage with no other signal on the multiplexer.
For the monitor mode, the setting of this input multiplexer can be changed to another source, normally to the microphone.
8.3.2
No-Pop Function
The No-Pop startup of the headphone stage takes 60ms to 120ms dependent on the supply voltage.
8.3.3
No-Clip Function
The headphone output stage gets monitored by comparator stages which detect if the output signal starts to clip.
This signal is used to reduce the LineIn gain to avoid distortion of the output signal. A hystereses avoids jumping between 2 gain steps for a
signal with constant amplitude.
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8.3.4
Over-Current Protection
The over-current protection has a threshold of 150-200mA and a debouncing time of 8µs. The stage is forced to OFF mode in an over-current
situation. After this, the headphone stage tries to power up again every 8ms as long as the over-current situation still exists or the stage is turned
off manually.
8.3.5
Parameter
VBAT=1.5V, TA= 25ºC, unless otherwise specified.
Table 6. Headphone Output Parameter
Symbol
Parameter
Condition
Min
RL_HP
Load Impedance
Stereo mode
16
CL_HP
Load Capacitance
Stereo mode
PHP
Nominal Output Power
PSRRHP
Power Supply Rejection Ratio
Typ
Max
Unit
Ω
100
pF
RL=64Ω
12
mW
RL=32Ω
24
mW
RL=16Ω
34
mW
200Hz-20kHz, 720mVpp, RL=16Ω
90
dB
8.4 Operational Amplifier
While AS3410 offers only one operational amplifier for feed-forward ANC, AS3400 and AS3430 feature an additional second operational
amplifier stage to perform feed-back ANC or any other additional needed filtering.
Both operational amplifiers stages can be activated and used individually. While OP1 stage is always configured as inverting amplifier, OP2
stage can be also switched to a non-inverting mode with an adjustable gain of 0...+10.5dB.
Figure 16. Operational Amplifiers
0..10.5dB
IOP1R
IOP2R
QOP1R
AGND
QOP2R
AGND
QOP2R
IOP2R
AGND
QOP1L
IOP1L
QOP2L
IOP2L
QOP2L
IOP2L
AGND
OP1
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OP2 inverting mode
Revision 1.02
0..10.5dB
OP2 non-inverting mode
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Data Sheet - D e t a i l e d D e s c r i p t i o n
8.4.1
Parameter
VBAT=1.5V, TA= 25ºC, unless otherwise specified.
Table 7. Headphone Output Parameter
Symbol
Parameter
Condition
Min
RL_OP
Load Impedance
Single ended
1
CL_OP
Load Capacitance
Single ended
GBWOP
Gain Band Width
VOS_OP
Offset Voltage
VEIN_HP
Equivalent Input Noise
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Typ
Max
kΩ
100
4.3
Revision 1.02
2.6
pF
MHz
6
200Hz-20kHz
Unit
mV
µV
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Data Sheet - D e t a i l e d D e s c r i p t i o n
8.5 SYSTEM
The system block handles the power up and power down sequencing, as well as, the mode switching.
8.5.1
Power Up/Down Conditions
The chip powers up when one of the following conditions is true:
Table 8. Power UP Conditions
#
Source
1
MODE pin
2
I2C start
Description
In stand-alone mode, MODE pin has to be driven high to turn on the device
In I2C mode, a I2C start condition turns on the device
The chip automatically shuts off if one of the following conditions arises:
Table 9. Power DOWN Conditions
#
Source
1
MODE pin
2
SERIF
3
Low Battery
4
VNEG CP OVC
8.5.2
Description
Power down by driving MODE pin to low
Power down by SERIF writing 0h to register 20h bit <0>
Power down if VBAT is lower than the supervisor off-threshold
Power down if VNEG is higher than the VNEG off-threshold
Start-up Sequence
The start-up sequence depends on the used mode.
In stand-alone mode the sequence runs automatically, in I2C mode the sequence runs till a defined state and waits then for an I2C command.
Either the automatic sequence is started by setting the CONT_PWRUP bit in addition to the PWR_HOLD bit. If only the PWR_HOLD is set all
enable bits for headphone, microphone, etc have to be set manually.
Figure 17. Stand-Alone Mode Start-Up Sequence
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Data Sheet - D e t a i l e d D e s c r i p t i o n
Figure 18. I2C Mode Start-Up Sequence
The total start-up time (inlcuding fade-in of the gain stages) can be reduced from 900ms to 600ms by OTP setting.
8.5.3
Mode Switching
When the chip is in stand-alone mode (no I2C control), the mode can be switched with different levels on the MODE pin.
Table 10. Operation Modes
MODE
MODE pin
OFF
LOW (VSS)
ANC
HIGH (VBAT)
MONITOR
VBAT/2
Description
Chip is turned off
Chip is turned on and active noise cancellation is active
Chip is turned on and monitor mode is active
In Monitor mode, a different (normally higher) microphone preamplifier gain can be chosen to get
an amplification of the surrounding noise. This volume can be either fixed or be controlled by the
VOL input.
To get rid of the low pass filtering needed for the noise cancellation, the headphone input
multiplexer can be set to a different (normally to MIC) source.
In addition, the LineIn gain can be lowered to reduce the loudness of the music currently played
back.
In I2C mode, the monitor mode can be activated be setting the corresponding bit in the system register.
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Data Sheet - D e t a i l e d D e s c r i p t i o n
8.5.4
Status Indication
AS3410and AS3430 features a on-status information via the current output pin ILED. The current can be controlled in 3 steps and be switched
off, by setting the PWM to 0%, 25%, 50% or 100% duty cycle of a 50kHz signal.
If LOW_BAT is active, ILED switches to blinking with 1Hz, 50% duty cycle and 50% current setting.
8.6 VNEG Charge Pump
The VNEG charge pump uses one external 1uF capacitor to generate a negative supply voltage out of the battery input voltage to supply all
audio related blocks. This allows a true-ground headphone output with no more need of external dc-decoupling capacitors.
8.6.1
Parameter
VBAT=1.5V, TA= 25ºC, unless otherwise specified.
Table 11. Headphone Output Parameter
Symbol
Parameter
Condition
Min
Typ
Max
Unit
VIN
Input voltage
VBAT
1.0
1.5
1.8
V
VOUT
Output voltage
VNEG
-0.7
-1.5
-1.8
V
CEXT
External flying capacitor
1
µF
8.7 OTP Memory & Internal Registers
The OTP memory consists of OTP register and the OTP fuses.The OTP register can be written as often as wanted but will lose the content on
power off. The OTP fuses are intended to store basic chip configurations as well as the microphone gain settings to optimize the ANC
performance and get rid of sensitivity variations of different microphones. Burning the fuses can only be done once and is a permanent change,
which means the fuses keep the content even if the chip is powered down. This AS3400/10/30 offers 4 register set for storing the microphone
gain making it possible to change the gain 3 times for re-calibration or other purposes.
When the chip is controlled by a microcontroller via I2C, the OTP memory don’t has to be used.
8.7.1
Register & OTP Memory Configuration
Figure 19 is showing the principal register interaction.
Figure 19. Register Access
OTP WRITE
BURN
OTP Register
I2C IF
OTP READ
normal I2C write
normal I2C read
10h...16h; 30h...35h
LOAD
OTP
Fuses
Register
Register
0x8,0x9,0xA
8h...21h
0xB, 0xC, 0x21
OTP path is default
but can be switched
by register setting
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Data Sheet - D e t a i l e d D e s c r i p t i o n
Registers 0x8, 0x9, 0xA, 0xB, 0xC and 0x21 have only effect when the corresponding “REG_ON” bit is set, otherwise the chip operates with the
OTP Register settings which are loaded from the OTP fuses at every start-up.
All registers settings can be changed several times, but will loose the content on power off. When using the I2C mode, the chip configuration has
to be loaded from the microcontroller after every start-up. In stand alone mode the OTP fuses have to be programmed for a permanent change
of the chip configuration.
A single OTP cell can be programmed only once. Per default, the cell is “0”; a programmed cell will contain a “1”. While it is not possible to reset
a programmed bit from “1” to “0”, multiple OTP writes are possible, but only additional unprogrammed “0”-bits can be programmed to “1”.
Independent of the OTP programming, it is possible to overwrite the OTP register temporarily with an OTP write command at any time. This
setting will be cleared and overwritten with the hard programmed OTP settings at each power-up sequence or by a LOAD operation.
The OTP memory can be accessed in the following ways:
LOAD Operation. The LOAD operation reads the OTP fuses and loads the contents into the OTP register. A LOAD operation is automatically
executed after each power-on-reset.
WRITE Operation. The WRITE operation allows a temporary modification of the OTP register. It does not program the OTP. This operation
can be invoked multiple times and will remain set while the chip is supplied with power and while the OTP register is not modified with another
WRITE or LOAD operation.
READ Operation. The READ operation reads the contents of the OTP register, for example to verify a WRITE command or to read the OTP
memory after a LOAD command.
BURN Operation. The BURN operation programs the contents of the OTP register permanently into the OTP fuses. Don’t use old or nearly
empty batteries for burning the fuses.
Attention: If you once burn the OTP_LOCK bit, no further programming, e.g. setting additional “0” to “1”, of the OTP can be done.
For production, the OTP_LOCK bit must be set to avoid an unwanted change of the OTP content during the livetime of the product.
8.7.2
OTP Fuse Burning
In most stand alone applications, the I2C pins are not accessible. Burning the fuses can be done by switching the line inputs into a special mode
to access the chip by I2C over the line input connections. This allows trimming of the microphone gain with no openings in the final housing and
so no influence to the acoustic of the headset.
This mode is called “Application Trimm” mode, or short “APT”. (Patent Pending)
During the application trimm mode LINR has to provide the clock, while LINL has to provide the data for the I2C communication.
Please note that the OTP register cannot be accessed directly but have to be enabled before a read or write access. This is independent whether
you access the OTP register via the normal I2C pins or in application trimm mode via LINL and LINR. Please refer to the detailed register
description to get more information on how the registers can be accessed.
To achieve a proper burning of the fuses, the negative supply has to be buffered by applying an external negative supply during burning. This
voltage can also be applied to the LINL terminal. An internal switch is connecting LINL and VNEG during the fuse burning. LINR has to provide
the clock for burning the fuses.
The below flow chart shows the principle steps of the OTP burning process. The application trimm mode can only be entered at a specific timing
during the start-up sequence.
The device offers the possibility to change microphone gain settings 3 times by using alternative registers. The selection which register set is
being used to set the microphone gain is done by the “lock” bits of the corresponding registers.
A more detailed description of the individual steps is available in an application note.
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Data Sheet - D e t a i l e d D e s c r i p t i o n
Figure 20. OTP Burning Process
enter
“Application Trimm”
mode
ANC pre burning
measurements
MAIN_LOCK
set?
Y
Y
ALT1_LOCK
set?
N
N
write, burn OTP fuses
30-35h, 16-17h
Set MAIN_LOCK and
SEQ_LOCK
Y
ALT2_LOCK
set?
N
MIC trimm #2
write, burn OTP fuses
10-11h
Set ALT1_LOCK
ALT3_LOCK
set?
Y
N
MIC trimm #3
write, burn OTP fuses
12-13h
Set ALT2_LOCK
MIC trimm #4
write, burn OTP fuses
14-15h
Set ALT3_LOCK
leave
“Application Trimm”
mode
No further MIC
trimming possible
trimm verification
verification
OK?
N
leave
“Application Trimm”
mode
N
Device trimming
failed
Y
leave
“Application Trim”
mode
ANC post burning
measurements
verification
OK?
Y
Device trimming
succeeded
8.8 2-Wire-Serial Control Interface
There is an I2C slave block implemented to have access to 64 byte of setting information.
The I2C address is: Adr_Group8 - audio processors
8Eh_write
8Fh_read
8.8.1
Protocol
Table 12. 2-Wire Serial Symbol Definition
Symbol
Definition
RW
Note
S
Start condition after stop
R
1 bit
Sr
Repeated start
R
1 bit
DW
Device address for write
R
1000 1110b (8Eh)
DR
Device address for read
R
1000 1111b (8Fh)
WA
Word address
R
8 bit
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Data Sheet - D e t a i l e d D e s c r i p t i o n
Table 12. 2-Wire Serial Symbol Definition
Symbol
Definition
RW
Note
A
Acknowledge
W
1 bit
N
No Acknowledge
R
1 bit
reg_data
Register data/write
R
8 bit
data (n)
Register data/read
W
8 bit
P
Stop condition
R
1 bit
WA++
Increment word address internally
R
during acknowledge
AS3400 AS3410 AS3430 (=slave) receives data
AS3400 AS3410 AS3430 (=slave) transmits data
Figure 21. Byte Write
S
DW
A
WA
A
reg_data
A P
write register
WA++
Figure 22. Page Write
S
DW
A
WA
A
reg_data 1
A
reg_data 2
write register
WA++
A
write register
WA++
...
reg_data n
A
P
write register
WA++
Byte Write and Page Write formats are used to write data to the slave.
The transmission begins with the START condition, which is generated by the master when the bus is in IDLE state (the bus is free). The devicewrite address is followed by the word address. After the word address any number of data bytes can be sent to the slave. The word address is
incremented internally, in order to write subsequent data bytes on subsequent address locations.
For reading data from the slave device, the master has to change the transfer direction. This can be done either with a repeated START condition
followed by the device-read address, or simply with a new transmission START followed by the device-read address, when the bus is in IDLE
state. The device-read address is always followed by the 1st register byte transmitted from the slave. In Read Mode any number of subsequent
register bytes can be read from the slave. The word address is incremented internally.
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Data Sheet - D e t a i l e d D e s c r i p t i o n
Figure 23. Random Read
S
DW
A
WA
A Sr
DR
A
data
N P
read register
WA++
Random Read and Sequential Read are combined formats. The repeated START condition is used to change the direction after the data transfer
from the master.
The word address transfer is initiated with a START condition issued by the master while the bus is idle. The START condition is followed by the
device-write address and the word address.
In order to change the data direction a repeated START condition is issued on the 1st SCL pulse after the acknowledge bit of the word address
transfer. After the reception of the device-read address, the slave becomes the transmitter. In this state the slave transmits register data located
by the previous received word address vector. The master responds to the data byte with a not-acknowledge, and issues a STOP condition on
the bus.
Figure 24. Sequential Read
S
DW
A
WA
A Sr
DR
A
data
read register
WA++
A
reg_data 2
read register
WA++
A
...
reg_data n
N P
read register
WA++
Sequential Read is the extended form of Random Read, as more than one register-data bytes are transferred subsequently. In difference to the
Random Read, for a sequential read the transferred register-data bytes are responded by an acknowledge from the master. The number of data
bytes transferred in one sequence is unlimited (consider the behavior of the word-address counter). To terminate the transmission the master
has to send a not-acknowledge following the last data byte and generate the STOP condition subsequently.
Figure 25. Current Address Read
S
DR
A
read register
WA++
data
A
reg_data 2
read register
WA++
A
...
reg_data n
N P
read register
WA++
To keep the access time as small as possible, this format allows a read access without the word address transfer in advance to the data transfer.
The bus is idle and the master issues a START condition followed by the Device-Read address. Analogous to Random Read, a single byte
transfer is terminated with a not-acknowledge after the 1st register byte. Analogous to Sequential Read an unlimited number of data bytes can
be transferred, where the data bytes has to be responded with an acknowledge from the master. For termination of the transmission the master
sends a not-acknowledge following the last data byte and a subsequent STOP condition.
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Data Sheet - D e t a i l e d D e s c r i p t i o n
8.8.2
Parameter
Figure 26. 2-Wire Serial Timing
TS
TSU
TH
THD
TL
TPD
CSDA
CSCL
1-7
Start
Address
Condition
8
9
1-7
R/W
ACK
8
Data
9
ACK
1-7
8
9
Data
ACK
Stop
Condition
1
VBAT >=1.4V , TA=25ºC, unless otherwise specified.
Table 13. 2-Wire Serial Parameter
Symbol
Parameter
Condition
Min
Typ
Max
Unit
VCSL
CSCL, CSDA Low Input Level
(max 30%DVDD)
0
-
0.87
V
VCSH
CSCL, CSDA High Input Level
CSCL, CSDA (min 70%DVDD)
2.03
-
5.5
V
HYST
CSCL, CSDA Input Hysteresis
200
450
800
mV
VOL
CSDA Low Output Level
-
-
0.4
V
Tsp
Spike insensitivity
50
100
-
ns
TH
Clock high time
TL
Clock low time
at 3mA
max. 400kHz clock speed
500
ns
ns
max. 400kHz clock speed
500
TSU
CSDA has to change Tsetup before rising edge
of CSCL
250
-
-
ns
THD
No hold time needed for CSDA relative to rising
edge of CSCL
0
-
-
ns
TS
CSDA H hold time relative to CSDA edge for
start/stop/rep_start
200
-
-
ns
TPD
CSDA prop delay relative to lowgoing edge of
CSCL
50
ns
1. Serial interface operates down to VBAT = 1.0V but with 100kHz clock speed and degraded parameters.
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Addr
Name
b7
b6
b5
b4
b3
b2
08h
MIC_L
09h
MIC_R
0Ah
LINE_IN
0Bh
GP_OP_L
0Ch
GP_OP_R
0Dh-0Fh
18h-1Fh
reserved
reserved
MIC_MODE
0: StereoSingleEnd
1: MonoDiff
MIC_REG_ON
0: use reg 30h & 31h
1: use reg 08h & 09h
LIN_REG_ON
Revision 1.02
b1
b0
OP2L_ON
OP1L_ON
OP2R_ON
OP1R_ON
Audio Registers
00-07h
reserved
System Register
20h
SYSTEM
21h
PWR_SET
0: use reg 33h and VOL
pin
1: use reg 0Ah
MICL_VOL<6:0>
Gain from MICL to QMICL or Mixer = -6dB...+41.6dB; 127 steps of 0.375dB
MICR_VOL<6:0>
Gain from MICR to QMICR or Mixer = -6dB...+41.6dB; 127 steps of 0.375dB
LIN_MODE
LIN_VOL<5:0>
0: StereoSingleEnd
1: MonoDiff
0: MUTE;
0x01..0x3F: Gain from LINR/L to QLINR/L or Mixer = -46.5dB...+0dB; 63 steps of 0.75dB
HP_MUX<1:0>
OP2L<3:0>
0: MIC; 1: OP1;
2: OP2; 3: open
0: OP2L inverting mode;
0x1..0xF: OP2L non inverting mode gain = 0...10.5dB; 15 steps of 0.75dB
OP_REG_ON
HP_MODE
OP2R<3:0>
0: use reg 34h
1: use reg 0Bh & 0Ch
0: StereoSingleEnd
1: MonoDiff
0: OP2R inverting mode;
0x1..0xF: OP2R non inverting mode gain = 0...10.5dB; 15 steps of 0.75dB
Design_Version<3:0> 0100
ILED<1:0>
PWR_REG_ON
0: 1: use reg 21h
LOW_BAT
22h-2Fh
reserved
HP_ON
0: OFF; 1: 25%;
2: 50%; 3: 100%
PWRUP_
COMPLETE
REG3F_ON
MONITOR_ON
CONT_PWRUP
PWR_HOLD
MIC_ON
LIN_ON
MICS_CP_ON
MICS_ON
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 14. I2C Register Overview
AS3400 AS3410 AS3430 1v0
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9 Register Description
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Name
b7
b6
b5
b4
b3
b2
b1
b0
Revision 1.02
10h
ANC_L2
TEST_BIT_5
11h
ANC_R2
ALT1_LOCK
12h
ANC_L3
TEST_BIT_6
13h
ANC_R3
ALT2_LOCK
14h
ANC_L4
TEST_BIT_7
15h
ANC_R4
ALT3_LOCK
16h
MICS_CNTR
17h
PWRUP
SEQ_LOCK
30h
ANC_L
TEST_BIT_1
31h
ANC_R
TEST_BIT_2
32h
MIC_MON
33h
AUDIO_SET
34h
GP_OP
35h
OTP_SYS
3Eh
CONFIG_1
3Fh
CONFIG_2
MON_MODE
0: fixed volume
1: adj. volume
VOL_PIN_OFF
MICL_VOL_OTP2<6:0>
Gain from MICL to QMICL or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MICR_VOL_OTP2<6:0>
Gain from MICR to QMICR or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MICL_VOL_OTP3<6:0>
Gain from MICL to QMICL or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MICR_VOL_OTP3<6:0>
Gain from MICR to QMICR or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MICL_VOL_OTP4<6:0>
Gain from MICL to QMICL or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MICR_VOL_OTP4<6:0>
Gain from MICR to QMICR or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
LowBat + 100mV
FAST_START<4:0>
0: ~900ms; 0Eh: ~600ms
0: potentiometer
1: up/down button
0: StereoSingleEnd
1: MonoDiff
0: StereoSingleEnd
1: MonoDiff
0: StereoSingleEnd
1: MonoDiff
OP2_OTP<3:0>
0: MIC; 1: OP1;
2: OP2; 3: -
0: OP2 inverting mode;
0x1..0xF: OP2 non inverting mode gain = 0...10.5dB; 15 steps of 0.75dB
0: write reg 30h.. 35h
1: lock reg 30h..35h
MIC_AGC_OFF
MICL_VOL_OTP<6:0>
Gain from MICL to QMICL or Mixer = MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MICR_VOL_OTP<6:0>
Gain from MICR to QMICR or Mixer =MUTE, -5.625dB...+41.6dB; 127 steps of 0.375dB
MIC_MON_OTP<6:0>
Gain from MICl/R to QMICL/R or Mixer = MUTE, -5.625dB...+41.6dB; 0.375dB steps, if MON_MODE is set to 0
Gain from MICl/R to QMICL/R or Mixer = MUTE, -5.625dB...+41.6dB; 0.375dB steps, adjustable by VOL pin if MON_MODE is set to 1
VOL_PIN_
LIN_MODE_
MIC_MODE_
HP_MODE_
LIN_MON_ATTEN<2:0>
MODE
OTP
OTP
OTP
0: no attenuation;
HP_MUX_OTP<1:0>
MAIN_LOCK
LIN_AGC_OFF
TEST_BIT_3
MON_HP_MUX<1:0>
ILED_OTP<1:0>
0: MIC; 1: OP1;
2: OP2; 3: -
0: OFF; 1: 25%;
2: 50%; 3: 100%
1..6: LIN_VOL<6:0> shift by -6dB...-36dB
7: MUTE
OP2_ON_OTP
OP1_ON_OTP
MICS_CP_OFF
I2C_MODE
EXTBURNCLK
TM34
BURNSW
TM_REG34-35
TM_REG30-33
OTP_MODE<1:0>
28 - 51
0: READ; 1: LOAD;
2: WRITE; 3: BURN
Data Sheet - R e g i s t e r D e s c r i p t i o n
Addr
OTP Register
AS3400 AS3410 AS3430 1v0
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Table 14. I2C Register Overview
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 15. MIC_L Register
Name
Base
Default
MIC_L
2-wire serial
00h
Left Microphone Input Register
Offset: 08h
Configures the gain for the left microphone input and defines the microphone operation mode. This
register is reset at POR.
Bit
Bit Name
Default
Access
Bit Description
7
MIC_MODE
0
R/W
Selects the microphone input mode
0: single ended stereo mode
1: mono differential mode
6:0
MICL_VOL<6:0>
000 0000
R/W
Volume settings for left microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 16. MIC_R Register
Name
Base
Default
MIC_R
2-wire serial
00h
Right Microphone Input Register
Offset: 09h
Configures the gain for the right microphone input and enables register 08h & 09h. This register is reset at
POR.
Bit
Bit Name
Default
Access
7
MIC_REG_ON
0
R/W
Defines which registers are used for the microphone settings.
0: settings of register 30h and 31h are used
1: settings of register 08h and 09h are used
6:0
MICR_VOL<6:0>
000 0000
R/W
Volume settings for right microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
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Bit Description
Revision 1.02
29 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 17. LINE_IN Register
Name
Base
Default
LINE_IN
2-wire serial
00h
Line Input Register
Offset: 0Ah
Configures the attenuation for the line input, defines the line input operation mode and enables register
0Ah. This register is reset at POR.
Bit
Bit Name
Default
Access
Bit Description
7
LIN_REG_ON
0
R/W
Defines which source is used for the line input settings.
0: settings of register 33h and VOL pin are used
1: register 0Ah is used
6
LIN_MODE
0
R/W
Selects the line input mode
0: single ended stereo mode
1: mono differential mode
5:0
LIN_VOL<5:0>
00 0000
R/W
Volume settings for line input, adjustable in 63 steps of 0.75dB
00 0000: MUTE
00 0001:-46.5dB gain
00 0010:-45.75dB gain
..
11 1110:-0.75dB gain
11 1111:.0 dB gain
Table 18. GP_OP_L Register
Name
Base
Default
GP_OP_L
2-wire serial
00h
Left General Purpose Operational Amplifier Register
Offset: 0Bh
Enables the left opamp stages, defines opamp 2 mode and gain and sets the HP input multiplexer. This
register is reset at POR.
Bit
Bit Name
Default
Access
7:6
HP_MUX<1:0>
00
R/W
Multiplexes the analog audio signal to HP amp
00: MIC: selects QMICL/R output
01: OP1: selects QOP1L/R outputs
10:OP2: selects QOP2L/R output
11: open: no signal mixed together with the line input signal
5:2
OP2L<3:0>
0000
R/W
Mode and volume settings for left OP2, adjustable in 15 steps of 0.75dB
0000: OP2L in inverting mode
0001: 0 dB gain, OP2L in non inverting mode
0001: 0.75 dB gain, non inverting
..,
1110: 9.75dB gain, non inverting
1111:.10.5 dB gain, non inverting
1
OP2L_ON
0
R/W
Enables left OP 2
0: left OP2 is switched off
1: left OP2 is enabled
0
OP1L_ON
0
R/W
Enables left OP 1
0: left OP1 is switched off
1: left OP1 is enabled
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Bit Description
Revision 1.02
30 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 19. GP_OP_R Register
Name
Base
Default
GP_OP_R
2-wire serial
00h
Right General Purpose Operational Amplifier Register
Offset: 0Ch
Enables the right opamp stages, defines opamp 2 mode and gain and sets the HP mode. This register is
reset at POR.
Bit
Bit Name
Default
Access
7
OP_REG_ON
0
R/W
Defines which register is used for the opamp and HP settings.
0: settings of register 33h and 34h are used
1: register 0B and 0Ch are used
Bit Description
6
HP_MODE
0
R/W
Selects the line input mode
0: single ended stereo mode
1: mono differential mode
5:2
OP2R<3:0>
0000
R/W
Mode and volume settings for right OP2, adjustable in 15 steps of 0.75dB
0000: OP2R in inverting mode
0001: 0 dB gain, OP2R in non inverting mode
0001: 0.75 dB gain, non inverting
..,
1110: 9.75dB gain, non inverting
1111:.10.5 dB gain, non inverting
1
OP2R_ON
0
R/W
Enables right OP 2
0: right OP2 is switched off
1: right OP2 is enabled
0
OP1R_ON
0
R/W
Enables right OP 1
0: right OP1 is switched off
1: right OP1 is enabled
Table 20. SYSTEM Register
Name
Base
Default
SYSTEM
2-wire serial
31h
Offset: 20h
SYSTEM Register
This register is reset at a POR.
Bit
Bit Name
Default
Access
7:4
Design_Version<3:0>
0100
R
3
TESTREG_ON
0
R/W
0: normal operation
1: enables writing to test register 3Eh & 3Fh to configure the OTP and set
the access mode.
2
MONITOR_ON
0
R/W
Enables the monitor mode
0: normal operation
1: monitor mode enabled
1
CONT_PWRUP
0
R/W
Continues the automatic power-up sequence when using the I2C mode
0: chip stops the power-up sequence after the supplies are stable,
switching on individual blocks has to be done via I2C commands
1: automatic power-up sequence is continued
0
PWR_HOLD
1
R/W
0: power up hold is cleared and AFE will power down
1: is automatically set to on after power on
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Bit Description
AFE number to identify the design version
0100: for chip version 1v0
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 21. PWR_SET Register
Name
PWR_SET
Base
Default
2-wire serial
0x11 1111b (stand alone mode)
0x00 0000b (I2C mode)
Power Setting Register
Offset: 21h
Please be aware that writing to this register will enable/disable the corresponding blocks,
while reading gets the actual status. It is not possible to read back e.g ILED settings. This
register is reset at POR.
Bit
Bit Name
Default
Access
7
PWR_REG_ON
0
R/W
6:5
ILED<1:0>
00
W
Sets the current sunk into ILED
00: current sink switched OFF
01: 25%
10: 50%
11: 100%
6
LOW_BAT
x
R
VBAT supervisor status
0: VBAT is above brown out level
1: BVDD has reached brown out level
5
PWRUP_COMPLETE
x
R
Power-Up sequencer status
0: power-up sequence incomplete
1: power-up sequence completed
4
HP_ON
0
W
0: switches HP stage off
1: switches HP stage on
x
R
0: HP stage not powered
1: normal operation
0
W
0: switches microphone stage off
1: switches microphone stage on
x
R
0: microphone stage not powered
1: normal operation
0
W
0: switches line input stage off
1: switches line input stage on
x
R
0: line input stage not powered
1: normal operation
0
W
0: switches microphone supply charge pump off
1: switches microphone supply charge pump on
x
R
0: microphone supply charge pump not powered
1: normal operation
0
W
0: switches microphone supply off
1: switches microphone supply on
x
R
0: microphone supply not enabled
1: normal operation
3
2
1
0
MIC_ON
LIN_ON
MICS_CP_ON
MICS_ON
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Bit Description
Defines which register is used for the power settings.
0: all blocks stay on as defined in the start-up sequence
1: register 21h is used
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 22. ANC_L2 Register
Name
ANC_L2
Base
Default
2-wire serial
80h (OTP)
Left OTP Microphone Input Register (2nd OTP option)
Offset: 10h
Bit
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit Name
Default
Access
7
TEST_BIT_5
1
R
6:0
MICL_VOL_OTP2
<6:0>
000 0000
R/W
Bit Description
for testing purpose only
Volume settings for left microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 23. ANC_R2 Register
Name
Base
Default
ANC_R2
2-wire serial
00h (OTP)
Right OTP Microphone Input Register (2nd OTP option)
Offset: 11h
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7
ALT1_LOCK
0
R/W
0: additional bits can be fused inside register 10h & 11h
1: OTP fusing for register 10h & 11h gets locked, no more changes can be
done.
6:0
MICR_VOL_OTP2
<6:0>
000 0000
R/W
Volume settings for right microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
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Bit Description
Revision 1.02
33 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 24. ANC_L3 Register
Name
Base
Default
ANC_L3
2-wire serial
80h (OTP)
Left OTP Microphone Input Register (3rd OTP option)
Offset: 12h
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7
TEST_BIT_6
1
R
6:0
MICL_VOL_OTP3
<6:0>
000 0000
R/W
Bit Description
for testing purpose only
Volume settings for left microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 25. ANC_R3 Register
Name
Base
Default
ANC_R3
2-wire serial
00h (OTP)
Right OTP Microphone Input Register (3rd OTP option)
Offset: 13h
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
Bit Description
7
ALT2_LOCK
0
R/W
0: additional bits can be fused inside register 12h & 13h
1: OTP fusing for register 12h & 13h gets locked, no more changes can be
done.
6:0
MICR_VOL_OTP3
<6:0>
000 0000
R/W
Volume settings for right microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
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Revision 1.02
34 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 26. ANC_L4 Register
Name
Base
Default
ANC_L4
2-wire serial
80h (OTP)
Left OTP Microphone Input Register (4th OTP option)
Offset: 14h
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7
TEST_BIT_7
1
R
6:0
MICL_VOL_OTP4
<6:0>
000 0000
R/W
Bit Description
for testing purpose only
Volume settings for left microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 27. ANC_R4 Register
Name
ANC_R4
Base
Default
2-wire serial
00h (OTP)
Right OTP Microphone Input Register (4th OTP option)
Offset: 15h
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
Bit Description
7
ALT3_LOCK
0
R/W
0: additional bits can be fused inside register 14h & 15h
1: OTP fusing for register 14h & 15h gets locked, no more changes can be
done.
6:0
MICR_VOL_OTP4
<6:0>
000 0000
R/W
Volume settings for right microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 28. MICS_CNTR Register
Name
Base
Default
MICS_CNTR
2-wire serial
00h (OTP)
Offset: 16h
Microphone Supply Regsiter
Configures the low battery trehshold value
Bit
Bit Name
Default
Access
3
LowBat
0
R/W
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Bit Description
0: default LowBat value
1: 100mV increase of LowBat threshold
Revision 1.02
35 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 29. PWRUP_CNTR Register
Name
Base
Default
PWRUP_CNTR
2-wire serial
00h (OTP)
PowerUp Control Register
Offset: 17h
Configures chip start-up speed. This is a special register, writing needs to be enabled by writing 10b to
Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7
SEQ_LOCK
0
R/W
0: additional bits can be fused inside register 16h & 17h
1: OTP fusing for register 16h & 17h gets locked, no more changes can be
done.
6:2
FAST_START
<4:0>
0 0000
R/W
0h: ~900ms start-up time
0Eh: ~600ms start-up time
1
LIN_AGC_OFF
0
R/W
0: Line Input AGC enabled
1: Line Input AGC switched off
0
MIC_AGC_OFF
0
R/W
0:Microphone Input AGC enabled
1: Microphone Input AGC switched off
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Bit Description
Revision 1.02
36 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 30. ANC_L Register
Name
Base
Default
ANC_L
2-wire serial
80h (OTP)
Left OTP Microphone Input Register
Offset: 30h
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7
TEST_BIT_1
1
R
6:0
MICL_VOL_OTP
<6:0>
000 0000
R/W
Bit Description
for testing purpose only
Volume settings for left microphone input, adjustable in 127 steps of 0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 31. ANC_R Register
Name
Base
Default
ANC_R
2-wire serial
80h (OTP)
Right OTP Microphone Input Register
Offset: 31h
Bit
Bit Name
Configures the gain for the left microphone input. This is a special register, writing needs to be enabled by
writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Default
Access
7
TEST_BIT_2
1
R
6:0
MICR_VOL_OTP
<6:0>
000 0000
R/W
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Bit Description
for testing purpose only
Volume settings for right microphone input, adjustable in 127 steps of
0.375dB
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
vvvvvvvvvv
Table 32. MIC_MON Register
Name
Base
Default
MIC_MON
2-wire serial
00h (OTP)
OPT Microphone Monitor Mode Register
Configures the gain for the microphone input in monitor mode. This is a special register, writing needs to
be enabled by writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP
fuse contents.
Offset: 32h
Bit
Bit Name
Default
Access
Bit Description
7
MON_MODE
0
R/W
0: monitor mode is working with fixed microphone gain
1: monitor mode uses adjustable gain via the VOL pin
6:0
MIC_MON_OTP
<6:0>
000 0000
R/W
Volume settings for microphone input during monitor mode, adjustable in
127 steps of 0.375dB. If MON_MODE bit is set to 1 the gain can be further
adjusted via the VOL pin.
00 0000: MUTE
00 0001: -5.625dB gain
00 0010: -5.25 dB gain
..
11 1110: 41.250dB gain
11 1111: 41.625 dB gain
Table 33. AUDIO_SET Register
Name
Base
Default
AUDIO_SET
2-wire serial
00h (OTP)
OPT Audio Setting Register
Offset: 33h
Configures the audio settings. This is a special register, writing needs to be enabled by writing 10b to Reg
3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
Bit Description
7
VOL_PIN_OFF
0
R/W
0: VOL pin is enabled
1: line in volume settings can only be done via I2C. VOL_PIN_MODE has to
be set to 1 in this mode.
6
VOL_PIN_MODE
0
R/W
0: VOL pin is in potentiometer mode
1: VOL pin is in up/down button mode
5
LIN_MODE_OTP
0
R/W
0: line input stage operating in single ended mode
1: line input operating in mono balanced
4
MIC_MODE_OTP
0
R/W
0: microphone input stage operating in single ended mode
1: normal operating in mono balanced
3
HP_MODE_OTP
0
R/W
0: headphone stage operating in single ended mode
1: normal operating in mono balanced
2:0
LIN_MON_ATTEN
<6:0>
000
R/W
Volume settings for line input during monitor mode, adjustable in 7 steps of
6dB and mute.
000: 0dB gain
001: -6dB gain
..
110: -36dB gain
111: MUTE
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Revision 1.02
38 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 34. GP_OP Register
Name
Base
Default
GP_OP
2-wire serial
00h (OTP)
OTP General Purpose Operational Amplifier Register
Enables the opamp stages, defines opamp 2 mode and gain and sets the HP input multiplexer. This is
a special register, writing needs to be enabled by writing 10b to Reg 3Fh first. This register is reset at
POR and gets loaded with the OTP fuse contents.
Offset: 34h
Bit
Bit Name
Default
Access
Bit Description
7:6
HP_MUX_OTP<1:0>
00
R/W
Multiplexes the analog audio signal to HP amp
00: MIC: selects QMICL/R output
01:OP1: selects QOP1L/R outputs
10:OP2: selects QOP2L/R output
11: open: no signal mixed together with the line input signal
5:2
OP2_OTP<3:0>
0000
R/W
Mode and volume settings for OP2, adjustable in 15 steps of 0.75dB
0000: OP2L in inverting mode
0001: 0 dB gain, OP2L in non inverting mode
0001: 0.75 dB gain, non inverting
..,
1110: 9.75dB gain, non inverting
1111:.10.5 dB gain, non inverting
1
OP2_ON
0
R/W
0: OP2 is switched off
1: left OP2 is enabled
0
OPL_ON
0
R/W
0: OP1 is switched off
1: OP1 is enabled
Table 35. OTP_SYS Register
Name
Base
Default
OTP_SYS
2-wire serial
40h (OTP)
OTP System Settings Register
Offset: 35h
Defines several system settings for OTP operation. This is a special register, writing needs to be enabled
by writing 10b to Reg 3Fh first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7
MAIN_LOCK
0
R/W
6
TEST_BIT_3
1
R
5:4
MON_HP_MUX
<1:0>
00
R/W
3:2
ILED_OTP<1:0>
00
W
1
MICS_CP_OFF
0
R/W
0: MICS charge pump is enabled
1: MICS charge pump is switched off
0
I2C
0
R/W
0: I2C and stand alone mode start-up possible
1: chip starts-up in I2C mode only
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Bit Description
0: additional bits can be fused inside the OTP
1: OTP fusing gets locked, no more changes can be done
for testing purpose only
Multiplexes the analog audio signal to HP amp in monitor mode
00: MIC: selects QMICL/R output
01: OP1: selects QOP1L/R outputs
10:OP2: selects QOP2L/R output
11: open: no signal mixed together with the line input signal
Sets the current sunk into ILED
00: current sink switched OFF
01: 25%
10: 50%
11: 100%
Revision 1.02
39 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e g i s t e r D e s c r i p t i o n
Table 36. CONFIG_1 Register
Name
Base
Default
CONFIG_1
2-wire serial
00h
OTP Configuration Register
Offset: 3Eh
Controls the clock configuration. This is a special register, writing needs to be enabled by writing 9h to
Reg 20h first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit
Bit Name
Default
Access
7:4
-
0000
n/a
3
EXTBURNCLK
0
n/a
2:0
-
000
n/a
Bit Description
0: ext. clock for OTP burning disabled
1: ext. clock for OTP burning enabled
Table 37. CONFIG_2 Register
Name
Base
Default
CONFIG_2
2-wire serial
00h
OTP Access Configuration Register
Offset: 3Fh
Bit
Controls the OTP access. This is a special register, writing needs to be enabled by writing 9h to Reg 20h
first. This register is reset at POR and gets loaded with the OTP fuse contents.
Bit Name
Default
Access
7:6
-
000
n/a
5
TM34
0
n/a
This Register defines the Register bank selection for Register
TM_REG34-35 and TMREG30-33. Depending on TM34 you can select
either between Register bank 14h-17h and 10h-13h enabled or 30h-33h and
34h-37h enabled.
0: test mode Registers 14h-17h and 10h-13h disabled
test mode Registers 30h-33h and 34h-37h enabled
1: test mode Registers 14h-17h and 10h-13h enabled
test mode Registers 30h-33h and 34h-37h disabled
4
BURNSW
0
n/a
0: BURN switch from LINL to VNEG is disabled
1: BURN switch from LINL to VNEG is enabled
3
TM_REG34-35
0
n/a
0: test mode for Register 34h-35h disabled
test mode for Register 14h-17h disabled
1: test mode for Register 34h-35h enabled
test mode for Register 14h-17h enabled
2
TM_REG30-33
0
n/a
0: test mode for Register 30h-33h disabled
test mode for Register 10h-13h disabled
1: test mode for Register 30h-33h enabled
test mode for Register 10h-13h enabled
1:0
OTP_MODE<1:0>
00
R/W
Controls the OTP access
00: READ
01: LOAD
10: WRITE
11: BURN
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Bit Description
Revision 1.02
40 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n I n f o r m a t i o n
10 Application Information
Figure 27. AS3410 High Performance Application in Bridged Mode for High Impedance Headsets
For high impedance headphones two AS3410 can be used in a bridged mode each one driving one side of the headphone load as differential
output to get 24mW output power per channel. Also the microphone inputs can be used in differential mode to reduce the noise level.
Figure 28. AS3400 Feed-Forward ANC Block Diagram
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Revision 1.02
41 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n I n f o r m a t i o n
Figure 29. AS3430 on Music Player with ANC
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Revision 1.02
42 - 51
D
C
B
1
R
GND
2
1
50k
P1A
MICS
Volume Control
Vpos
AAA Batterie
U3
Battery Socket
R18
10k
Monitor Button
2
R17
10k
R20
150R
Vpos
R19
150R
Vneg
2
3
ON/OFF Bypass slider
3
1
3
Alternative Volume Control
MICS
Line Input
4
3
1
2
4.7uF
C15
MICS
C3
10u
Values dep. on
headphone
characteristics, also
other topologies
possible
1
L
3
U2
1
Revision 1.02
2
2
2
Vneg
LED
220R
3
2
1
C6
2
QOP1R
VSS
HPL
HPR
C?
13
14
15
16
17
18
GND
22nF
GND
22nF
Mic LPF cap dep.
on headphone
characteristics
2
1
C8
R?
con_mic
-
+
J4
10u
C10
-
+
Right Speaker
J?
HEADPHONE
for open loop noise cancelation
-
R?
VBAT
HVDD
U?
AS3410
Vpos
C13 Values dep. on
2.2uF headphone
characteristics, also
other topologies
possible
1
C7
Left Speaker
-
+
J?
con_mic
+
C12
2.2uF
C1
2.2uF
J1
R13
2k2
20
AS3410
MODE_CSCL
VOL_CSDA
LINR
LINL
AGND
QMICL
C?
R1
R14
2k2
VCC
6
5
4
3
2
1
R?
R?
3
23
QOP1L
24
IOP1L
MICL
7
MICS
9
ILED
8
22
VNEG
21 1uF
CPN
MICR
10
19
CPP
IOP1R
GND
QMICR
11
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12
A
1
2
1
Vneg
4
4
D
C
B
A
AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n I n f o r m a t i o n
Figure 30. AS3410 Feed-Forward Application Example
43 - 51
D
C
B
1
Line Input
U2
2
1
3
Vpos
2
Battery Socket
AAA Batterie
U3
R19
150R
R20
150R
50k
P1A
MICS
3
Monitor Button
Volume Control
Alternative Volume Control
MICS
R
GND
L
4
3
1
2
10k
R18
R17
10k
4
D1
LED
8
7
6
5
4
3
2
1
Vpos
R14
2k2
220R
ON/OFF Bypass slider
R13
2k2
MODE/CSCL
VOL/CSDA
LINR
LINL
AGND
QMICL
QLINL
IOP1L
U1
AS3430
R25
Vpos
R3
R2
R1
Mic Supply
resistors depend
on Mic Spec
C15
4.7uF
MICS
Power Led
R6
R5
R4
C5
C4
C2
C20
2.2uF
5
1u
C6
C1
3
LPF and NOTCH-Filter to
avoid oscillation by acustic
(Headphone-Speaker <=> Mic)
1
MICL
9
C3
10u
AS3430
2.2u
1
C12
3
4
3
C9
30
2
3
2
32
QOP1L
31
IOP2L
ILED
10
QOP2L
1
MICR
12
2.2u
C13
5
Vneg
R15
C7
Mic LPF
cap dep. on
Headphone
Characteris
tics
QMICR
13
MICS
11
29
VNEG
28
CPN
27
GND
QLINR
14
R9
25
VSS
HPL
HVSS
HPR
HVDD
VBAT
R16
3
4
5
2
IOP2R
QOP2R
NC
26
CPP
IOP1R
15
QOP1R
16
2
2
Revision 1.02
C17
R11
10u
C10
6
C14
R12
Vneg
-
+
6
-
+
HEADPHONE
for closed loop noise cancelation
LPF and NOTCH-Filter to avoid oscillation by
acustic (Headphone-Speaker <=> Mic)
R10
C11
Vpos
C16
17
18
19
20
21
22
23
24
LINE
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LINE
A
1
3
4
5
2
C18
C8
7
7
Mic LPF cap dep.
on Headphone
Characteristics
8
8
D
C
B
A
AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n I n f o r m a t i o n
Figure 31. AS3430 Feed-back Application Example
44 - 51
Revision 1.02
D
C
B
A
1
CPU for I2C control
e.g. bluetooth, audio codec
differential audio output
R?
2k2
Vpos
C?
C?
R?
2k2
Vpos
470nF
470nF
Vneg
220
R3
MICL
2
AGND
4.7uF
C6
MICS_F
AGND
PGND
6
5
4
3
2
1
Vneg
2.2uF
C7
MICS
MICL
MODE/CSCL
VOL/CSDA
LINR
LINL
AGND
PGND
10uF
100nF
PGND
C3
C2
MICS
7
1uF
C1
CPP
20
2
24
QMICL
23
VNEG
CPN
22
AS3400
CPN
QMICR
9
MICR
8
MICR
21
GND
QLINR
10
Vpos
19
13
14
15
16
HPL
HPR
Vpos
Vneg
U1
AS3400
3
3
RC filter network
IOP2R
QOP2R
VSS
HPL
HPR
17
18
PGND
HPVDD
VBAT
QOP1R
CPP
IOP1R
11
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12
1
PGND
10uF
100nF
PGND
C5
C4
Vpos
2.2uF
C?
2.2uF
C?
Mic LPF cap dep.
on Headphone
Characteristics
2
1
R?
2k2
AGND
AGND
C?
2
1
R4
2k2
MICS_F
1V - 1.8V
4
T-a
m1
-
+
-
+
s1
PGND
supply from power management unit
4
D
C
B
A
AS3400 AS3410 AS3430 1v0
Data Sheet - A p p l i c a t i o n I n f o r m a t i o n
Figure 32. AS3400 Mode Differential Feed Forward Application Example
45 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - P a c k a g e D r a w i n g s a n d M a r k i n g
11 Package Drawings and Marking
Figure 33. QFN Marking
Table 38. Package Code AYWWZZZ
YY
WW
I
ZZ
last two digits of the year
manufacturing week
plant identifier
free choice / traceability code
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Revision 1.02
46 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - P a c k a g e D r a w i n g s a n d M a r k i n g
Figure 34. AS3400, AS3410, 24-pin QFN 0.5mm Pitch
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Revision 1.02
47 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - P a c k a g e D r a w i n g s a n d M a r k i n g
Figure 35. AS3430 32-pin QFN 0.5mm Pitch
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Revision 1.02
48 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - R e v i s i o n H i s t o r y
Revision History
Revision
Date
Owner
Description
0.1
19.1.2010
pkm
initial release
0.2
29.1.2010
pkm
updated block diagrams and application schematics
1.0
27.10.2010
hgt
update to new datasheet template
1.01
11.11.2010
hgt
updated package drawings, QFN markings and operating temperature range
1.02
24.11.2010
hgt
inserted register description for MIC_R and updated register table overview
Note: Typos may not be explicitly mentioned under revision history.
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Revision 1.02
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AS3400 AS3410 AS3430 1v0
Data Sheet - O r d e r i n g I n f o r m a t i o n
12 Ordering Information
The devices are available as the standard products shown in Table 39.
Table 39. Ordering Information
Ordering Code
Description
Delivery Form
Package
AS3400-EQFP
Low Power Ambient Noise-Cancelling Speaker Driver
Tape & Reel
dry pack
QFN 24 [4.0x4.0x0.85mm] 0.5mm
pitch
AS3410-EQFP
Low Power Ambient Noise-Cancelling Speaker Driver
Tape & Reel
dry pack
QFN 24 [4.0x4.0x0.85mm] 0.5mm
pitch
AS3430-EQFP
Low Power Ambient Noise-Cancelling Speaker Driver
Tape & Reel
dry pack
QFN 32 [5.0x5.0x0.85mm] 0.5mm
pitch
Note: All products are RoHS compliant and austriamicrosystems green.
Buy our products or get free samples online at ICdirect: http://www.austriamicrosystems.com/ICdirect
For further information and requests, please contact us mailto:[email protected]
or find your local distributor at http://www.austriamicrosystems.com/distributor
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Revision 1.02
50 - 51
AS3400 AS3410 AS3430 1v0
Data Sheet - C o p y r i g h t s
Copyrights
Copyright © 1997-2010, austriamicrosystems AG, Tobelbaderstrasse 30, 8141 Unterpremstaetten, Austria-Europe. Trademarks Registered ®.
All rights reserved. The material herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of
the copyright owner.
All products and companies mentioned are trademarks or registered trademarks of their respective companies.
Disclaimer
Devices sold by austriamicrosystems AG are covered by the warranty and patent indemnification provisions appearing in its Term of Sale.
austriamicrosystems AG makes no warranty, express, statutory, implied, or by description regarding the information set forth herein or regarding
the freedom of the described devices from patent infringement. austriamicrosystems AG reserves the right to change specifications and prices at
any time and without notice. Therefore, prior to designing this product into a system, it is necessary to check with austriamicrosystems AG for
current information. This product is intended for use in normal commercial applications. Applications requiring extended temperature range,
unusual environmental requirements, or high reliability applications, such as military, medical life-support or life-sustaining equipment are
specifically not recommended without additional processing by austriamicrosystems AG for each application. For shipments of less than 100
parts the manufacturing flow might show deviations from the standard production flow, such as test flow or test location.
The information furnished here by austriamicrosystems AG is believed to be correct and accurate. However, austriamicrosystems AG shall not
be liable to recipient or any third party for any damages, including but not limited to personal injury, property damage, loss of profits, loss of use,
interruption of business or indirect, special, incidental or consequential damages, of any kind, in connection with or arising out of the furnishing,
performance or use of the technical data herein. No obligation or liability to recipient or any third party shall arise or flow out of
austriamicrosystems AG rendering of technical or other services.
Contact Information
Headquarters
austriamicrosystems AG
Tobelbaderstrasse 30
A-8141 Unterpremstaetten, Austria
Tel: +43 (0) 3136 500 0
Fax: +43 (0) 3136 525 01
For Sales Offices, Distributors and Representatives, please visit:
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Revision 1.02
51 - 51
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