NSC LM49101TM

March 23, 2009
Mono Class AB Audio Subsystem with a True Ground
Headphone Amplifier and Earpiece Switch
General Description
■ Output Power
The LM49101 is a fully integrated audio subsystem with a
mono power amplifier capable of delivering 540mW of continuous average power into an 8Ω BTL speaker load with 1%
THD+N using a 3.3V supply. The LM49101 includes a separate stereo headphone amplifier that can deliver 44mW per
channel into 32Ω loads using a 2.75V supply.
The LM49101 has four input channels. A pair of single-ended
inputs and a fully differential input channel with volume control
and amplification stages. Additionally, a bypass differential
input is available that connects directly to the mono speaker
outputs through an analog switch without any amplification or
volume control stages. The LM49101 features a 32–step digital volume control on the input stage and an 8–step digital
volume control on the headphone output stage.
The digital volume control and output modes, programmed
through a two-wire I2C compatible interface, allows flexibility
in routing and mixing audio channels.
The LM49101 is designed for cellular phones, PDAs, and
other portable handheld applications. The high level of integration minimizes external components. The True Ground
headphone amplifier eliminates the physically large DC blocking output capacitors reducing required board space and
reducing cost.
VDDLS = 3.3V, VDDHP = 2.75V
1% THD+N
Key Specifications
■ Supply Voltage (VDDLS)
2.7V ≤ VDDLS ≤ 5.5V
■ Supply Voltage (VDDHP)
1.8V ≤ VDDHP ≤ 2.9V
■ 1.7V ≤ I2CVDD ≤ 5.5V
I2C
Supply Voltage
■ Output power
RL = 8Ω speaker
540W (typ)
RL = 32Ω headphone
40mW (typ)
■ PSRR:
VDD = 3.3V, 217Hz ripple, Mono In
■ Shutdown power supply current
90dB (typ)
0.01μA (typ)
Features
■
■
■
■
■
■
■
■
■
■
■
■
■
■
■
Differential mono input and stereo single-ended input
Separate earpiece (receiver) differential input
Analog switch for a separate earpiece path
32-step digital volume control (-80 to +18dB)
Three independent volume channels (Left, Right, Mono)
Separate headphone volume control
Flexible output for speaker and headphone output
True Ground headphone amplifier eliminates large DC
blocking capacitors reducing PCB space and cost.
Hardware reset function
RF immunity topology
“Click and Pop” suppression circuitry
Thermal shutdown protection
Micro-power shutdown
I2C control interface
Available in space-saving microSMD package
Applications
VDDLS = 5V, VDDHP = 2.75V
1% THD+N
RL = 8Ω speaker
1.3W (typ)
RL = 32Ω headphone
45mW (typ)
■ Portable electronic devices
■ Mobile Phones
■ PDAs
Boomer® is a registered trademark of National Semiconductor Corporation.
© 2009 National Semiconductor Corporation
300862
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LM49101Mono Class AB Audio Subsystem with a True Ground Headphone Amplifier and
Earpiece Switch
LM49101
LM49101
Typical Application
30086203
FIGURE 1. Typical Audio Application Circuit
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2
LM49101
Connection Diagrams
25 Bump micro SMD Package
micro SMD Markings
30086204
Top View
XY - Date Code
TT - Die Traceability
G- Boomer Family
L4 - LM49101TM
30086202
Top View
(Bump Side Down)
Order Number LM49101TM, LM49101TMX
See NS Package Number TMD25BCA
Ordering Information
Order
Number
Package
Package DWG
#
Transport Media
MSL Level
Green Status
LM49101TM
25 Bump micro
SMD
TMD25BCA
250 units on tape and reel
1
RoHS and no Sb/Br
LM49101TMX
25 Bump micro
SMD
TMD25BCA
3000 units on tape and reel
1
RoHS and no Sb/Br
3
Features
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LM49101
Bump Descriptions
Bump
Name
A1
CPGND
Charge pump ground terminal
A2
VSSCP
Negative charge pump power supply
Power Output
A3
HPR
Right headphone output
Analog Output
A4
VDDHP
Headphone amplifier power supply
Power Input
A5
MIN+
Positive input pin for the mono, differential input
Analog Input
B1
C1N
Negative terminal of the charge pump flying capacitor
Analog Output
B2
C1P
Positive terminal of the charge pump flying capacitor
Analog Output
B3
HPL
Left headphone output
Analog Output
B4
HPGND
B5
MIN-
C1
VDDCP
C2
SDA
C3
GND
Ground
C4
RIN
Single-ended input for the right channel
Analog Input
C5
LIN
Single-ended input for the left channel
Analog Input
D1
BYPASS_IN-
Earpiece negative input, bypass volume control and amplifier
Analog Input
D2
I2CVDD
I2C power supply
Power Input
I2C clock
Digital Input
Hardware reset function, active low. When pin is low (<0.6V) the
LM49101 goes into shutdown mode and will remain in shutdown
mode until pin goes to logic high (>1.6V) and is activated by I2C
control. When reset all registers are set to the default value of 0.
Digital Input
D3
D4
D5
SCL
HW RESET
MONO+
E2
VDDLS
E3
GND
E4
MONO-
E5
BIAS
Type
Ground
Headphone signal ground
Ground
Negative input pin for the mono, differential input
Analog Input
Charge pump power supply
Power Input
I2C data
Digital Input
Ground
BYPASS_IN+ Earpiece positive input, bypass volume control and amplifier
E1
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Pin Function
Positive loudspeaker output
Analog Input
Analog Output
Main power supply
Power Input
Ground
Ground
Negative loudspeaker output
Analog Output
Half-supply bias, capacitor bypassed
Analog Output
4
LM49101
See AN-1112 “Micro SMD Wafer Level Chip Scale
Package”
Thermal Resistance
Absolute Maximum Ratings (Notes 1, 2)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
θJA (Note 8)
Supply Voltage (Loudspeaker,
VDDLS)
6.0V
Supply Voltage (Headphone, VDDHP)
3.0V
Storage Temperature
−65°C to +150°C
Voltage at Any Input Pin
GND − 0.3 to VDD LS + 0.3
Power Dissipation (Note 3)
Internally Limited
ESD Rating (Note 4)
2000V
ESD Rating (Note 5)
200V
Junction Temperature (TJMAX)
150°C
Soldering Information
Vapor Phase (60sec.)
215°C
Infrared (15sec.)
220°C
51°C/W
Operating Ratings
Temperature Range
TMIN ≤ TA ≤ TMAX
Supply Voltage (VDDLS)
−40°C ≤ TA ≤ 85°C
2.7V ≤ VDDLS ≤ 5.5V
1.8V ≤ VDDHP ≤ 2.9V
VDDHP ≤ VDDLS
VDDCP = VDD HP
Supply Voltage (VDDHP)
Supply Voltage (VDDCP)
Supply Voltage (I2CVDD)
1.7V ≤ I2CVDD ≤ 5.5V
I2CVDD ≤ VDDLS
Electrical Characteristics VDDLS = 3.3V, VDDHP = 2.75V
(Notes 1, 2)
The following specifications apply for VDDLS = 3.3V, VDDHP = 2.75V, TA = 25°C, all volume controls set to 0dB, unless otherwise
specified. LS = Loudspeaker, HP = Headphone, EP = Earpiece.
LM49101
Symbol
Parameter
Conditions
Units
(Limits)
Typical
(Note 6)
Limits
(Note 7)
0.03
0.045
mA (max)
LS only (Mode 1), GAMP_SD = 0
VDDLS
VDDHP
2.5
0
4.2
mA (max)
mA
LS only (Mode 1), GAMP_SD = 1
VDDLS
VDDHP
2
0
VIN = 0, No Load
EP Receiver
(Output Mode Bit EP Bypass = 1)
IDD
Quiescent Power Supply Current
HP only (Mode 8), GAMP_SD = 0
VDDLS
VDDHP
VDDLS +VDDHP
HP only (Mode 8), GAMP_SD = 1
VDDLS
VDDHP
ISD
Shutdown Current
VOS
Output Offset Voltage
1.6
3.1
mA
mA
2.0
4.5
6.45
2.8
3.3
mA (max)
mA (max)
mA (max)
mA
mA
LS+HP (Mode 10), GAMP_SD = 0
VDDLS
VDDHP
VDDLS +VDDHP
2.8
3.1
3.8
4.5
8
mA (max)
mA (max)
mA (max)
Power_On = 0
0.01
2
µA (max)
2.5
0.5
22
5
mV (max)
mV (max)
LS output, Mode 1, RL = 8Ω BTL
THD+N = 1%, f = 1kHz, LS_Gain = 6dB
540
480
mW (min)
HP output, Mode 8, RL = 32Ω SE
THD+N = 1%, f = 1kHz
44
40
mW (min)
VIN = 0V, Mode 10
LS output, RL = 8Ω BTL
HP output, RL = 32Ω SE
PO
Output Power
5
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LM49101
LM49101
Symbol
THD+N
SNR
Parameter
Total Harmonic Distortion + Noise
Signal-to-Noise Ratio
Conditions
Typical
(Note 6)
Limits
(Note 7)
Units
(Limits)
LS output, f = 1kHz, RL = 8Ω BTL
PO = 250mW, Mode 1, LS_Gain = 6dB
0.065
%
HP output, f = 1kHz, RL = 32Ω SE
PO = 20mW, Mode 8
0.015
%
LS output, f = 1kHz, Mode 1
VREF = VOUT (1%THD+N)
Vol. Gain & LS_GAIN = 0dB
A-Wtg, LIN & RIN AC terminated
105
dB
HP output, f = 1kHz, Mode 8
VREF = VOUT (1%THD+N)
Vol. Gain = 0dB, A-weighted
LIN & RIN AC terminated
100
dB
VRIPPLE on VDDLS = 200mVPP, fRIPPLE = 217Hz, CB = 2.2μF
All inputs AC terminated to GND, output referred
PSRR
Power Supply Rejection Ratio
LS: Mode 1, 5, 9, 13, RL = 8Ω BTL
90
dB (max)
LS: Mode 2, 6, 10 ,14, RL = 8Ω BTL
75
dB (max)
HP: Mode 4, 5, 6, 7, RL = 32Ω SE
85
dB (max)
HP: Mode 8, 9, 10, 11, RL = 32Ω SE
81
dB (max)
60
60
dB
dB
72
dB
f = 217Hz, VCM = 1VP-P
CMRR
Common-Mode Rejection Ratio
LS: RL = 8Ω BTL, Mode 1
HP: RL = 32Ω SE, Mode 4
XTALK
Crosstalk
HP PO = 20mW
f = 1kHz, Mode 8
Maximum Gain setting
12.5
10
15
KΩ (min)
KΩ (max)
Maximum Attenuation setting
110
90
130
KΩ (min)
KΩ (max)
On Resistance
Analog Switch On
3.4
Ω
VOL
Digital Volume Control Range
Maximum Gain
Maximum Attenuation
18
–80
dB
dB
VOL
Volume Control Step Size Error
ZIN
RON
TWU
MIN, LIN, and RIN Input Impedance
Wake-Up Time from Shutdown
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±0.02
dB
CB = 2.2μF, HP, Normal Turn-On Mode
30
ms
CB = 2.2μF, HP, Fast Turn-On Mode
15
ms
6
(Notes 1, 2)
The following specifications apply for VDDLS = 5.0V, VDDHP = 2.75V, TA = 25°C, all volume controls set to 0dB, unless otherwise
specified. LS = Loudspeaker, HP = Headphone, EP = Earpiece.
LM49101
Symbol
Parameter
Conditions
Units
(Limits)
Typical
(Note 6)
Limits
(Note 7)
0.05
0.07
mA (max)
LS only (Mode 1), GAMP_SD = 0
VDDLS
VDDHP
2.9
0
4.4
mA (max)
mA
LS only (Mode 1), GAMP_SD = 1
VDDLS
VDDHP
2.1
0
VIN = 0, No Load
EP Receiver
(Output Mode Bit EP Bypass = 1)
IDD
Quiescent Power Supply Current
HP only (Mode 8), GAMP_SD = 0
VDDLS
VDDHP
VDDLS+VDDHP
HP only (Mode 8), GAMP_SD = 1
VDDLS
VDDHP
ISD
Shutdown Current
1.8
3.1
mA
mA
2.15
4.5
6.6
1.3
3.1
mA (max)
mA (max)
mA (max)
mA
mA
LS+HP only (Mode 10), GAMP_SD = 0
VDDLS
VDDHP
VDDLS+VDDHP
3
3.1
4.1
4.5
8.35
mA (max)
mA (max)
mA (max)
Power_On = 0
0.01
2
µA (max)
2.5
0.5
22
5
mV (max)
mV (max)
VIN = 0V, Mode 10
VOS
Output Offset Voltage
LS output, RL = 8Ω BTL
HP output, RL = 32Ω SE
PO
THD+N
SNR
Output Power
Total Harmonic Distortion + Noise
Signal-to-Noise Ratio
LS output, Mode 1, RL = 8Ω BTL
THD+N = 1%, f = 1kHz, LS_Gain = 6dB
1.3
W
HP output, Mode 8, RL = 32Ω SE
THD+N = 1%, f = 1kHz
45
mW
LS output, f = 1kHz, RL = 8Ω BTL
PO = 600mW, Mode 1, LS_Gain = 6dB
0.055
%
HP output, f = 1kHz, RL = 32Ω SE
PO = 20mW, Mode 8
0.015
%
LS output, f = 1kHz, Mode 1
VREF = VOUT (1%THD+N)
Vol. Gain & LS_GAIN = 0dB
A-Wtg, LIN & RIN AC terminated
108
dB
HP output, f = 1kHz, Mode 8
VREF = VOUT (1%THD+N)
Vol. Gain = 0dB, A-weighted
LIN & RIN AC terminated
100
dB
VRIPPLE on VDDLS = 200mVPP, fRIPPLE = 217Hz, CB = 2.2μF
All inputs AC terminated to GND, output referred
PSRR
Power Supply Rejection Ratio
LS: Mode 1, 5, 9, 13, RL = 8Ω BTL
90
dB
LS: Mode 2, 6, 10, 14, RL = 8Ω BTL
74
dB
HP: Mode 4, 5, 6, 7, RL = 32Ω SE
84
dB
HP: Mode 8, 9, 10, 11, RL = 32Ω SE
79
dB
7
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LM49101
Electrical Characteristics VDDLS = 5.0V, VDDHP = 2.75V
LM49101
LM49101
Symbol
Parameter
Conditions
Typical
(Note 6)
Limits
(Note 7)
Units
(Limits)
f = 217Hz, VCM = 1VP-P
CMRR
Common-Mode Rejection Ratio
LS: RL = 8Ω BTL, Mode 1
HP: RL = 32Ω SE, Mode 4
XTALK
ZIN
RON
Crosstalk
HP PO = 20mW
f = 1kHz, Mode 8
60
60
dB
dB
72
dB
Maximum Gain setting
12.5
10
15
KΩ (min)
KΩ (max)
Maximum Attenuation setting
110
90
130
KΩ (min)
KΩ (max)
MIN, LIN, and RIN Input Impedance
2
Ω
18
–80
dB
dB
±0.02
dB
CB = 2.2μF, HP, Normal Turn-On Mode
30
ms
CB = 2.2μF, HP, Fast Turn-On Mode
15
ms
On Resistance
Analog Switch On
VOL
Digital Volume Control Range
Maximum Gain
Maximum Attenuation
VOL
Volume Control Step Size Error
TWU
Wake-Up Time from Shutdown
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8
(Notes 1, 2)
The following specifications apply for VDDLS = 5.0V and 3.3V, 2.2V ≤ I2C_VDD ≤ 5.5V, TA = 25°C, unless otherwise specified.
LM49101
Symbol
Parameter
Conditions
Typical
(Note 4)
Units
(Limits)
Limits
(Notes 7, 9)
t1
I2C Clock Period
2.5
µs (min)
t2
I2C Data Setup Time
100
ns (min)
t3
I2C
0
ns (min)
t4
Start Condition Time
100
ns (min)
t5
Stop Condition Time
100
ns (min)
t6
I2C Data Hold Time
100
ns (min)
Data Stable Time
VIH
I2C
VIL
I2C Input Voltage Low
Input Voltage High
I2C Interface 1.7V ≤ I2C_VDD ≤ 2.2V,
0.7xI2CV
DD
V (min)
0.3xI2CVDD
V (max)
(Notes 1, 2)
The following specifications apply for VDDLS = 5.0V and 3.3V, TA = 25°C, 1.7V ≤ I2C_VDD ≤ 2.2V, unless otherwise specified.
LM49101
Symbol
Parameter
Conditions
Typical
(Note 6)
Units
(Limits)
Limits
(Notes 7, 9)
t1
I2C Clock Period
2.5
µs (min)
t2
I2C Data Setup Time
250
ns (min)
t3
I2C
0
ns (min)
t4
Start Condition Time
250
ns (min)
t5
Stop Condition Time
250
ns (min)
t6
I2C Data Hold Time
250
ns (min)
Data Stable Time
VIH
I2C
VIL
I2C Input Voltage Low
0.7xI2CV
Input Voltage High
DD
V (min)
0.3xI2CVDD
V (max)
Note 1: “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur, including inoperability and degradation of device reliability
and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or other conditions beyond those indicated in
the Recommended Operating Conditions is not implied. The Recommended Operating Conditions indicate conditions at which the device is functional and the
device should not be operated beyond such conditions. All voltages are measured with respect to the ground pin, unless otherwise specified
Note 2: The Electrical Characteristics tables list guaranteed specifications under the listed Recommended Operating Conditions except as otherwise modified
or specified by the Electrical Characteristics Conditions and/or Notes. Typical specifications are estimations only and are not guaranteed.
Note 3: The maximum power dissipation must be derated at elevated temperatures and is dictated by TJMAX, θJA, and the ambient temperature, TA. The maximum
allowable power dissipation is PDMAX = (TJMAX - TA) / θJA or the number given in Absolute Maximum Ratings, whichever
Note 4: Human body model, applicable std. JESD22-A114C.
Note 5: Machine model, applicable std. JESD22-A115-A.
Note 6: Typical values represent most likely parametric norms at TA = +25°C, and at the Recommended Operation Conditions at the time of product
characterization and are not guaranteed.
Note 7: Datasheet min/max specification limits are guaranteed by test or statistical analysis.
Note 8: The given θJA is for an LM49101 mounted on a demonstration board.
Note 9: Refer to the I2C timing diagram, Figure 2.
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LM49101
I2C Interface 2.2V ≤ I2C_VDD ≤ 5.5V,
LM49101
Typical Performance Characteristics
THD+N vs Frequency
VDDLS = 3.3V, RL = 8Ω BTL, PO = 250mW
Mode 1 (Mono), 80kHz BW
THD+N vs Frequency
VDDLS = 3.3V, RL = 8Ω BTL, PO = 250mW
Mode 2 (Left + Right), 80kHz BW
30086219
30086220
THD+N vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, RL = 32Ω SE,
PO = 5mW/Ch, Mode 4 (Mono), 80kHz BW
THD+N vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, RL = 32Ω SE,
PO = 5mW/Ch, Mode 8 (Left/Right ), 80kHz BW
30086221
30086222
THD+N vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, RL = 8Ω BTL, RL = 32Ω SE,
PO = 250mW BTL, PO = 5mW/Ch SE, Mode 5 (Mono)
LS (EP Mode) = 0, 80kHz BW
THD+N vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, RL = 8Ω BTL, RL = 32Ω SE,
PO = 250mW BTL, PO = 5mW/Ch SE, Mode 10 (L/R)
LS (EP Mode) = 0, 80kHz BW
30086226
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30086229
10
THD+N vs Frequency
VDDLS = 5V, RL = 8Ω BTL, PO = 600mW,
Mode 2 (Let + Right), 80kHz BW
30086223
30086224
THD+N vs Frequency
VDDLS = 5V, VDDHP = 2.75V, RL = 32Ω SE,
PO = 20mW/Ch, Mode 4 (Mono), 80kHz BW
THD+N vs Frequency
VDDLS = 5V, VDDHP = 2.75V, RL = 32Ω SE,
PO = 20mW/Ch, Mode 8 (Left/Right), 80kHz BW
30086225
30086228
THD+N vs Frequency
VDDLS = 5V, VDDHP = 2.75V, RL = 8Ω BTL, RL = 32Ω SE,
PO = 600mW BTL, PO = 20mW/Ch SE, Mode 5 (Mono)
LS (EP Mode) = 0, 80kHz BW
THD+N vs Frequency
VDDLS = 5V, VDDHP = 2.75V, RL = 8Ω BTL, RL = 32Ω SE,
PO = 600mW BTL, PO = 20mW/Ch SE, Mode 10 (L/R)
LS (EP Mode) = 0, 80kHz BW
30086227
30086230
11
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LM49101
THD+N vs Frequency
VDDLS = 5V, RL = 8Ω BTL, PO = 600mW,
Mode 1 (Mono), 80kHz BW
LM49101
THD+N vs Output Power
VDDLS = 3.3V & 5V, f = 1kHz, RL = 8Ω BTL
Mode 1 (Mono), 80kHz BW
THD+N vs Output Power
VDDLS = 3.3V & 5V, f = 1kHz, RL = 8Ω BTL
Mode 2 (Left + Right), 80kHz BW
30086243
30086244
THD+N vs Output Power
VDDLS = 3.3V, VDDHP = 1.8V & 2.75V, f = 1kHz,
RL = 32Ω SE, Mode 4 (Mono), 80kHz BW
THD+N vs Output Power
VDDLS = 3.3V, VDDHP = 1.8V & 2.75V, f = 1kHz,
RL = 32Ω SE, Mode 8 (Left/Right), 80kHz BW
30086245
30086246
THD+N vs Output Power
VDDLS = 3.3V & 5V, VDDHP = 2.75V, f = 1kHz,
RL = 8Ω BTL, Mode 5 (Mono), 80kHz BW
THD+N vs Output Power
VDDLS = 3.3V, VDDHP = 1.8V & 2.75V, f = 1kHz,
RL = 32Ω SE, Mode 10 (Left/Right), 80kHz BW
30086242
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30086247
12
PSRR vs Frequency
VDDLS = 3.3V, VRIPPLELS = 200mVPP, RL = 8Ω BTL,
Mode 2 (Left + Right), 80kHz BW
30086211
30086213
PSRR vs Frequency
VDDLS = 5V, VRIPPLELS = 200mVPP, RL = 8Ω BTL,
Mode 1 (Mono), 80kHz BW
PSRR vs Frequency
VDDLS = 5V, VRIPPLELS = 200mVPP, RL = 8Ω BTL,
Mode 2 (Left + Right), 80kHz BW
30086212
30086214
PSRR vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, VRIPPLEHP = 200mVPP,
RL = 32Ω SE, Mode 8 (Left/Right), 80kHz BW
PSRR vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, VRIPPLEHP = 200mVPP,
RL = 32Ω SE, Mode 4 (Mono), 80kHz BW
30086215
30086217
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LM49101
PSRR vs Frequency
VDDLS = 3.3V, VRIPPLELS = 200mVPP, RL = 8Ω BTL,
Mode 1 (Mono), 80kHz BW
LM49101
PSRR vs Frequency
VDDLS = 3.3V, VDDHP = 2.75V, VRIPPLEHP = 200mVPP,
RL = 32Ω SE, Mode 4 (Mono), 80kHz BW
PSRR vs Frequency
VDDLS = 3.3V, VDDHP = 2.75V, VRIPPLEHP = 200mVPP,
RL = 32Ω SE, Mode 8 (Left/Right), 80kHz BW
30086248
30086249
Power Dissipation vs Output Power
VDDLS = 3.3V & 5V, VDDHP = 2.75V, RL = 8Ω BTL,
Mode 3 (Mono + Left + Right), 80kHz BW
Power Dissipation vs Output Power
VDDLS = 5V, VDDHP = 1.8V & 2.75V, RL = 32Ω SE,
Mode 12 (Mono + Left/ Right), 80kHz BW
30086236
30086235
Crosstalk vs Frequency
VDDLS = 3.3V, VDDHP = 1.8V, VIN = 1VPP,
RL = 32Ω SE, Mode 8 (Left/Right), 80kHz BW
Crosstalk vs Frequency
VDDLS = 3.3V, VDDHP = 2.75V, VIN = 1VPP,
RL = 32Ω SE, Mode 8 (Left/Right), 80kHz BW
30086231
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30086232
14
Supply Current vs Supply Voltage (VDDLS)
VDDHP = 2.75V, No Load, Gain_SD = 0 & 1
LS (EP_Mode) = 0 & 1, Mode 2
30086237
30086239
Supply Current vs Supply Voltage (VDDHP)
VDDLS = 3.3V, No Load, Gain_SD = 0 or 1
HPR_SD = 0 & 1, Modes 4, 8, 15
Supply Current vs Supply Voltage (VDDLS)
VDDHP = 2.75V, No Load, Gain_SD = 0 or 1
LS (EP_Mode) = 0 & 1, Mode 15
30086238
30086240
Output Power vs Supply Voltage (VDDLS)
VDDHP = 2.75V, RL = 8Ω BTL,
Mode 1
Output Power vs Supply Voltage (VDDHP)
VDDLS = 3.3V, RL = 32Ω SE,
Mode 4
30086234
30086233
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LM49101
Supply Current vs Supply Voltage (VDDLS)
VDDHP = 2.75V, No Load, Gain_SD = 0 & 1
LS (EP_Mode) = 0 & 1, Mode 1
LM49101
Application Information
I2C BUS FORMAT
The I2C bus format is shown in Figure 4. The START signal,
the transition of SDA from HIGH to LOW while SCL is HIGH,
is generated, alerting all devices on the bus that a device address is being written to the bus.
The 7-bit device address is written to the bus, most significant
bit (MSB) first, followed by the R/W bit. R/W = 0 indicates the
master is writing to the slave device, R/W = 1 indicates the
master wants to read data from the slave device. Set R/W =
0; the LM49101 is a WRITE-ONLY device and will not respond to the R/W = 1. The data is latched in on the rising edge
of the clock. Each address bit must be stable while SCL is
HIGH. After the last address bit is transmitted, the master device releases SDA, during which time, an acknowledge clock
pulse is generated by the slave device. If the LM49101 receives the correct address, the device pulls the SDA line low,
generating an acknowledge bit (ACK).
Once the master device registers the ACK bit, the 8-bit register data word is sent. Each data bit should be stable while
SCL is HIGH. After the 8-bit register data word is sent, the
LM49101 sends another ACK bit. Following the acknowledgement of the register data word, the master issues a
STOP bit, allowing SDA to go high while SCL is high.
I2C COMPATIBLE INTERFACE
The LM49101 is controlled through an I2C compatible serial
interface that consists of a serial data line (SDA) and a serial
clock (SCL). The clock line is uni-directional. The data line is
bi-directional (open drain). The LM49101 and the master can
communicate at clock rates up to 400kHz. Figure 2 shows the
I2C interface timing diagram. Data on the SDA line must be
stable during the HIGH period of SCL. The LM49101 is a
transmit/receive slave-only device, reliant upon the master to
generate the SCL signal. Each transmission sequence is
framed by a START condition and a STOP condition (Figure
3). Each data word, device address and data, transmitted
over the bus is 8 bits long and is always followed by an acknowledge pulse (Figure 4). The LM49101 device address is
11111000.
I2C INTERFACE POWER SUPPLY PIN (I2CVDD)
The LM49101's I2C interface is powered up through the
I2CVDD pin. The LM49101's I2C interface operates at a voltage level set by the I2CVDD pin which can be set independent
to that of the main power supply pin VDDLS. This is ideal
whenever logic levels for the I2C interface are dictated by a
microcontroller or microprocessor that is operating at a lower
supply voltage than the VDDLS voltage.
300862s0
FIGURE 2. I2C Timing Diagram
300862s1
FIGURE 3. Start and Stop Diagram
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16
LM49101
300862s2
FIGURE 4. Start and Stop Diagram
TABLE 1. Chip Address
A7
A6
A5
A4
A3
A2
A1
A0
1
1
1
1
1
0
0
0
Chip
Address
TABLE 2. Control Registers
Register
D7
D6
D5
D4
D3
LS
(EP_Mode) (2)
General Control
0
0
1
GAMP_SD (1)
Output Mode Control
0
1
EP
Bypass (5)
HPR_SD (6)
Output Gain Control
1
0
0
Input_Mute (8)
Mono Input Volume
Control
1
0
1
Left Input Volume
Control
1
1
0
Right Input Volume
Control
1
1
1
D2
D1
D0
0
Turn_On
_Time (3)
Power_On (4)
Mode_ Control (7)
LS_Gain (9)
HP_Gain (10)
Mono_Vol (11)
Left_Vol (11)
Right_Vol (11)
Notes: All registers default to 0 on initial power-up.
1. GAMP_SD: Is used to shut down gain amplifiers not in use
and reduce current consumption. See Table 3.
2. LS (EP_Mode): Loudspeaker power amplifier bias current
reduction. See Table 3.
3. Turn_On_Time: Reduces the turn on time for faster activation. See Table 3.
4. Power_On: Master Power on bit. See Table 3.
5. EP Bypass: Earpiece bypass mode to allow BYPASS inputs to drive speaker outputs. See Table 4
6. HPR_SD: Will shutdown one channel of the headphone
amplifier. See Table 4.
7. Mode_Control: Sets the output mode. See Table 4.
8. Input Mute: Controls muting of the inputs except the BYPASS inputs. See Table 5.
9. LS_Gain: Sets the gain of the loudspeaker amplifier to 0dB
or 6dB. See Table 5.
10. HP_Gain: Sets the headphone amplifier output gain. See
Table 5.
11. Mono_Vol/Left_Vol/Right_Vol: Sets the input volume for
Mono, Left and Right inputs. See Table 6.
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LM49101
TABLE 3. General Control Register
Bit
Name
Value
Description
This bit is a master shutdown control bit and sets the device to be on or off.
0
Power_On
Value
Status
0
Master power off, device disable.
1
Master power on, device enable.
This bit sets the turn on time of the device.
1
Turn_On_Time
Value
Status
0
Normal Turn-on time
1
Fast Turn-on time
This bit enables EP Mode reducing loudspeaker output stage bias current by 500μA.
Value
3
LS (EP Mode)
Status
0
Normal loudspeaker power amplifier operation.
1
Enables EP Mode reducing loudspeaker output stage bias current
by 500μA.
This bit is used to reduce IDD by shutting down gain amplifiers not in use.
4
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0
Normal operation of all gain amplifiers.
1
Disables the input gain amplifiers that are not in use to reduce
current from VDDLS. Recommended for Output Modes 1, 2, 4, 5,
8, 10.
GAMP_SD
18
LM49101
TABLE 4. Output Mode Control Register (see key below table)
Bits
3:0
Field
Description
Mode_Control These bits determine how the input signals are mixed and routed to the outputs.
D3
D2
D1
D0
Headphone
Loudspeaker
D3D2D1D0
Mode
Left
Headphone
Right
Headphone
0000
0
SD
SD
SD
0001
1
SD
SD
GM x M
0010
2
SD
SD
2 x (GL x L + GR x R)
0011
3
SD
SD
2 x (GL x L + GR x R)
+ GM x M
0100
4
GM x M/2
GM x M/2
SD
0101
5
GM x M/2
GM x M/2
GM x M
0110
6
GM x M/2
GM x M/2
2 x (GL x L + GR x R)
0111
7
GM x M/2
GM x M/2
2 x (GL x L + GR x R)
+ GM x M
1000
8
GL x L
GR x R
SD
1001
9
GL x L
GR x R
GM x M
1010
10
GL x L
GR x R
2 x (GL x L + GR x R)
1011
11
GL x L
GR x R
2 x (GL x L + GR x R)
+ GM x M
1100
12
GL x L + GM x
M/2
GR x R + GM x
M/2
SD
1101
13
GL x L + GM x
M/2
GR x R + GM x
M/2
GM x M
1110
14
GL x L + GM x
M/2
GR x R + GM x
M/2
2 x (GL x L + GR x R)
1111
15
GL x L + GM x
M/2
GR x R + GM x
M/2
2 x (GL x L + GR x R)
+ GM x M
This bit sets the headphone amplifiers to normal mode or mono mode.
4
HPR_SD
Value
Status
0
Normal stereo headphone operation.
1
Disable right headphone output.
This bit is used to control the analog switch to have the BYPASS inputs drive the loudspeaker outputs.
Value
5
EP Bypass
Status
0
Normal output mode operation with analog switch off.
1
Loudspeaker and headphone amplifiers go into shutdown mode and Bypass (Receiver) path
enable with the analog switch on.
M : MIN, Mono differential input
L : LIN, Left single-ended input
R : RIN, Right single-ended input
SD : Shutdown
GM : Mono_Vol setting determined by the Mono Input Volume Control register, See Table 6.
GL : Left_Vol setting determined by the Left Input Volume Control register, See Table 6.
GR : Right_Vol setting determined by the Right Input Volume Control register, See Table 6.
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LM49101
TABLE 5. Output Gain Control Register
Bits
Field
Description
These bits set the gain of the headphone output amplifiers.
2:0
HP_GAIN
Value
Gain (dB)
000
0
001
–1.2
010
–2.5
011
–4.0
100
–6.0
101
–8.5
110
–12
111
–18
This bit sets the loudspeaker output amplifier gain.
3
LS_GAIN
Value
Status
0
Loudspeaker output amplifier gain is set to 0dB.
1
Loudspeaker output amplifier gain is set to 6dB.
This bit will set all the inputs except the BYPASS inputs to be in Mute mode.
Value
4
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Status
0
Normal operation of all inputs.
1
Mutes all inputs except BYPASS with over 80dB of attenuation
with out adjusting the volume settings. This bit can be used to
mute the inputs to eliminate noise or transients from other
systems and ICs. See the section Input Mute Bit in the
Application Information section for a detailed explanation.
INPUT MUTE
20
LM49101
TABLE 6. Input Volume Control Registers
Bits
Fields
4:0
Mono_Vol
Right_Vol
Left_Vol
Description
These bits set the input volume for each input volume register listed.
Volume Step
Value
Gain (dB)
1
00000
–80.0
2
00001
–46.5
3
00010
–40.5
4
00011
–34.5
5
00100
–30.0
6
00101
–27.0
7
00110
–24.0
8
00111
–21.0
9
01000
–18.0
10
01001
–15.0
11
01010
–13.5
12
01011
–12.0
13
01100
–10.5
14
01101
–9.0
15
01110
–7.5
16
01111
–6.0
17
10000
–4.5
18
10001
–3.0
19
10010
–1.5
20
10011
0.0
21
10100
1.5
22
10101
3.0
23
10110
4.5
24
10111
6.0
25
11000
7.5
26
11001
9.0
27
11010
10.5
28
11011
12.0
29
11100
13.5
30
11101
15.0
31
11110
16.5
32
11111
18.0
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LM49101
the rest of the IC blocks except for the I2C circuitry will go into
shutdown for minimal current consumption.
HW RESET FUNCTION
The LM49101 can be globally reset without using the I2C controls. When the HW RESET pin is set to a logic low the
LM49101 will enter into shutdown, the mode control bits of the
Output Mode Control register, volume control registers and
Power_On bits will be set to the default value of zero. The
other bits will retain their values. The LM49101 cannot be activated until the HW RESET pin is set to a logic high voltage.
When the HW RESET is set to a logic high then the I2C controls can activate and set the register control bits.
HPR_SD BIT
The HPR_SD bit will deactivate the right headphone output
amplifier. This bit is provided to reduce power consumption
when only one headphone output is needed.
MODE_CONTROL BITS
The LM49101 includes a comprehensive mixer multiplexer
controlled through the I2C interface. The mixer/multiplexer allows any input combination to appear on any output of
LM49101. Multiple input paths can be selected simultaneously. Under these conditions, the selected inputs are mixed
together and output on the selected channel. Table 4 shows
how the input signals are mixed together for each possible
input selection.
GAMP_SD BIT
The GAMP_SD bit allows for reduced power consumption.
When set to '1' the gain amplifiers on unused inputs will be
shutdown saving approximately 0.4mA per input in shutdown.
For example, in Mode 1 only the mono inputs are in use. Setting GAMP_SD to '1' will shut down the gain amplifiers for the
left and right inputs reducing current draw from the VDDLS
supply by approximately 0.8mA. The GAMP_SD bit does not
need to be set each time when changing modes as the
LM49101 will automatically activate and deactivate the needed inputs based on the mode selected.
When operating with GAMP_SD set to '1', a transient may be
observed on the outputs when changing modes. During power up, the LM49101 uses a start up sequence to eliminate any
pops and clicks on the outputs. The volume control circuitry
is powered up first followed by the other internal circuitry with
the output amplifiers being powered up last. If a mode change
requires a gain amplifier to turn on then a potential transient
may be created that is amplified on the already active outputs.
To eliminate unwanted noise on the outputs the Power_On
bit should be used to turn off the LM49101 before changing
modes, perform a mode change, then turn the LM49101 back
on. This procedure will cause the LM49101 to follow the start
up sequence.
INPUT MUTE BIT
The Input Mute bit will mute all inputs except the Bypass inputs when set to a '1'. This allows complete and quick mute
of the Mono, Left, and Right inputs without changing the Volume Control registers or HP_Gain bits. The volume and
HP_Gain bits retain their values when the Input Mute is enabled or disabled.
The Input Mute bit can be used to mute all the inputs when
other chips in a system, such as the baseband IC, create
transients causing unwanted noise on the outputs of the
LM49101. This added feature eliminates the need for power
cycling the LM49101.
LS_GAIN BIT
The loudspeaker amplifier can have an additional gain of 0dB
or 6dB by using the LS_Gain bit. The Mono input has 6dB of
attenuation before the volume control (see Figure 1) while the
Left and Right inputs do not. The LS_Gain bit is used to account for the different attenuation levels for each input and to
achieve maximum output power. To obtain maximum output
power on the loudspeaker outputs, the LS_Gain bit should be
se to '1' for Modes 1, 5, 9, 13.
LS (EP_MODE) BIT
The LS (EP_Mode) bit selects the amount of bias current in
the loudspeaker amplifier. Setting the LS (EP_Mode) bit to a
'1' will reduce the amount of current from the VDDLS supply
by approximately 0.5mA. The THD performance of the loudspeaker amplifier will be reduced as a result of lower bias
current. See the performance graphs in the Typical Performance Characteristics section above.
HP_GAIN BITS
The headphone outputs have an additional, single volume
control set by the three HP_Gain bits in the Output Gain Control register. The HP_Gain volume setting controls the output
level for both the left and the right headphone outputs.
TURN_ON_TIME BIT
The Turn_On_Time bit determines the delay time from the
Power_On bit set to '1' and the internal circuits ready. For
input capacitor values up to 0.47μF the Turn_On_Time bit can
be set to fast mode by setting the bit to a '1'. When the input
capacitor values are larger than 0.47μF then the
Turn_On_Time bit should be set to '0' for normal turn-on time
and higher delay. This allows sufficient time to charge the input capacitors to the ½ VDDLS bias voltage.
VOLUME CONTROL BITS
The LM49101 has three independent 32-step volume controls, one for each of the inputs. The five bits of the Volume
Control registers sets the volume for the specified input channel.
SHUTDOWN FUNCTION
The LM49101 features the following shutdown controls.
Bit D4 (GAMP_SD) of the GENERAL CONTROL register
controls the gain amplifiers. When GAMP_SD = 1, it disables
the gain amplifiers that are not in use. For example, in Modes
1, 4 and 5, the Mono inputs are in use, so the Left and Right
input gain amplifiers are disabled, causing the IDD to be minimized.
Bit D0 (Power_On) of the GENERAL CONTROL register is
the global shutdown control for the entire device. Set
Power_On = 0 for normal operation. Power_On = 1 overrides
any other shutdown control bit.
POWER_ON BIT
The Power_On bit is the master control bit to activate or deactivate the LM49101. All registers can be loaded independent of the Power_On bit setting as long as the IC is powered
correctly. Cycling the Power_On bit does not change the values of any registers nor return all bits to the default power on
value of zero. The Power_On bit only determines whether the
IC is on or off.
EP BYPASS BIT
The EP Bypass bit is used to set the LM49101 to earpiece
mode. When this bit is set the analog switch is activated and
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POWER SUPPLY BYPASSING
As with any amplifier, proper supply bypassing is critical for
low noise performance and high power supply rejection. The
capacitor location on both the bypass and power supply pins
should be as close to the device as possible. Typical applications employ a 5V regulator with 10µF tantalum or electrolytic capacitor and a ceramic bypass capacitor which aid in
supply stability. This does not eliminate the need for bypassing the supply nodes of the LM49101. The selection of a
bypass capacitor, especially CB, is dependent upon PSRR
requirements, click and pop performance, system cost, and
size constraints.
BRIDGE CONFIGURATION EXPLAINED
By driving the load differentially through the MONO outputs,
an amplifier configuration commonly referred to as “bridged
mode” is established. Bridged mode operation is different
from the classical single-ended amplifier configuration where
one side of the load is connected to ground.
A bridge amplifier design has a few distinct advantages over
the single-ended configuration, as it provides differential drive
to the load, thus doubling output swing for a specified supply
voltage. Four times the output power is possible as compared
to a single-ended amplifier under the same conditions. This
increase in attainable output power assumes that the amplifier is not current limited or clipped.
A bridge configuration, such as the one used in LM49101,
also creates a second advantage over single-ended amplifiers. Since the differential outputs are biased at half-supply,
no net DC voltage exists across the load. This eliminates the
need for an output coupling capacitor which is required in a
single supply, single-ended amplifier configuration. Without
an output coupling capacitor, the half-supply bias across the
load would result in both increased internal IC power dissipation and also possible loudspeaker damage.
GROUND REFERENCED HEADPHONE AMPLIFIER
The LM49101 features a low noise inverting charge pump that
generates an internal negative supply voltage. This allows the
headphone outputs to be biased about GND instead of a
nominal DC voltage, like traditional headphone amplifiers.
Because there is no DC component, the large DC blocking
capacitors (typically 220μF) are not necessary. The coupling
capacitors are replaced by two small ceramic charge pump
capacitors, saving board space and cost. Eliminating the output coupling capacitors also improves low frequency response. In traditional headphone amplifiers, the headphone
impedance and the output capacitor from a high-pass filter
that not only blocks the DC component of the output, but also
attenuates low frequencies, impacting the bass response.
Because the LM49101 does not require the output coupling
capacitors, the low frequency response of the device is not
degraded by external components. In addition to eliminating
the output coupling capacitors, the ground referenced output
nearly doubles the available dynamic range of the LM49101
headphone amplifiers when compared to a traditional headphone amplifier operating from the same supply voltage.
POWER DISSIPATION
Power dissipation is a major concern when designing a successful amplifier, whether the amplifier is bridged or singleended. A direct consequence of the increased power
delivered to the load by a bridge amplifier is an increase in
internal power dissipation. The power dissipation of the
LM49101 varies with the mode selected. The maximum power dissipation occurs in modes where all inputs and outputs
are active (Modes 6, 7, 8, 9, 10, 11, 13, 14, 15). The power
dissipation is dominated by the Class AB amplifier. The maximum power dissipation for a given application can be derived
from the power dissipation graphs or from Equation 1.
PDMAX = 4*(VDD)2/(2π2RL)
HEADPHONE & CHARGE PUMP SUPPLY VOLTAGE
(VDDHP & VDDCP)
The headphone outputs are centered at ground by using dual
supply voltages for the headphone amplifier. The positive
power supply is set by the voltage on the VDDHP pin while the
negative supply is created with an internal charge pump. The
negative supply voltage is equal in magnitude but opposite in
voltage to the voltage on the VDDCP pin.
INPUT CAPACITOR SELECTION
Input capacitors may be required for some applications, or
when the audio source is single-ended. Input capacitors block
the DC component of the audio signal, eliminating any conflict
between the DC component of the audio source and the bias
voltage of the LM49101. The input capacitors create a highpass filter with the input resistors RIN. The -3dB point of the
high-pass filter is found using Equation (2) below.
(1)
It is critical that the maximum junction temperature (TJMAX) of
150°C is not exceeded. TJMAX can be determined from the
power derating curves by using PDMAX and the PC board foil
area. By adding additional copper foil, the thermal resistance
of the application can be reduced from the free air value, resulting in higher PDMAX. Additional copper foil can be added
to any of the leads connected to the LM49101. It is especially
effective when connected to VDD, GND, and the output pins.
Refer to the application information on the LM49101 reference design board for an example of good heat sinking. If
TJMAX still exceeds 150°C, then additional changes must be
made. These changes can include reduced supply voltage,
higher load impedance, or reduced ambient temperature. Internal power dissipation is a function of output power. Refer
to the Typical Performance Characteristics curves for
f = 1 / 2πRINCIN (Hz)
(2)
Where the value of RIN is given in the Electrical Characteristics Table as ZIN.
When the LM49101 is using a single-ended source, power
supply noise on the ground is seen as an input signal. Setting
the high-pass filter point above the power supply noise frequencies, 217Hz in a GSM phone, for example, filters out the
noise such that it is not amplified and heard on the output.
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LM49101
power dissipation information for different output powers and
output loading.
DIFFERENTIAL AMPLIFIER EXPLANATION
The LM49101 features a differential input stage, which offers
improved noise rejection compared to a single-ended input
amplifier. Because a differential input amplifier amplifies the
difference between the two input signals, any component
common to both signals is cancelled. An additional benefit of
the differential input structure is the possible elimination of the
DC input blocking capacitors. Since the DC component is
common to both inputs, and thus cancelled by the amplifier,
the LM49101 can be used without input coupling capacitors
when configured with a differential input signal.
LM49101
Capacitors with a tolerance of 10% or better are recommended for impedance matching and improved CMRR and PSRR.
drop and reduced power to the load on the loudspeaker outputs.
The current through the FET switch should not exceed 500mA
or die heating may cause thermal shut down activation and
potential IC damage.
CHARGE PUMP FLYING CAPACITOR (C1)
The flying capacitor (C1), see Figure 1, affects the load regulation and output impedance of the charge pump. A C1 value
that is too low results in a loss of current drive, leading to a
loss of amplifier headroom. A higher valued C1 improves load
regulation and lowers charge pump output impedance to an
extent. Above 2.2μF, the RDS(ON) of the charge pump switches
and the ESR of C1 and Cs3 dominate the output impedance.
A lower value capacitor can be used in systems with low maximum output power requirements.
MINIMUM POWER OPERATION
The LM49101 has several options to reduce power consumption and is designed to conserve power when possible. When
a speaker only mode is selected the headphone sections are
shutdown and the current drawn from the VDDHP/VDDCP
power supply will be zero. When a headphone mode is selected the current drawn from the VDDLS supply is also reduced by shutting down unused circuitry. See the various
Supply Current vs Supply Voltage graphs in the Typical Performance Characteristics section.
To reduce power consumption further, the additional control
bits GAMP_SD, LS (EP Mode), and HPR_SD are provided.
When low power consumption is more important than the
THD performance of the loudspeaker the LS (EP_mode) bit
should be set to '1' saving approximately 0.5mA from the
VDDLS supply. The GAMP_SD bit should be set on to save
approximately 0.4mA for each input shut down. For modes
where only the mono input is used, up to 0.8mA can be saved
from the VDDLS supply. Also, the HPR_SD bit can be used to
shut down the right headphone channel reducing power consumption when only one amplifier headphone output is needed.
Additionally, the supply voltages for the different VDD pins
(VDDLS, VDDHP, and VDDCP) can be set to the minimum
needed values to obtain the output power levels required by
the design. By reducing the supply voltage the total power
consumption will be reduced.
For best system efficiency, a DC-DC converter (buck) can be
used to power the VDDHP and VDDCP voltages from the
VDDLS supply instead of a linear regulator. DC-DC converters
achieve much higher efficiency (> 90%) than even a low
dropout regulator (LDO).
CHARGE PUMP HOLD CAPACITOR (CS3)
The value and ESR of the hold capacitor Cs3 directly affects
the ripple on VSSCP. Increasing the value of Cs3 reduces output ripple. Decreasing the ESR of Cs3 reduces both output
ripple and charge pump output impedance. A lower value capacitor can be used in systems with low maximum output
power requirements.
SELECTION OF INPUT RESISTORS
The Bypass_In inputs connect to the loudspeaker output
through an FET switch when EP Bypass is active (see Figure
5). Because THD through this path is mainly dominated by
the switch impedance variation, adding input resistors (R3 and
R4 in Figure 5) will help reduce impedance effects resulting in
improved THD. For example, a change in the switch
impedance from 2Ω to 3Ω is a 67% change in impedance. If
10Ω input resistors are used then the impedance change is
from 12Ω to 13Ω, only 7.7% impedance variation. The analog
switch impedance is typically 2Ω to 3.4Ω. The switch
impedance change is a result of heating and the increase in
RDS(ON) of the FETs.
The value of the input resistors must be balanced against the
amount of output current and the load impedance on the loudspeaker outputs. A higher value input resistor reduces the
effects of switch impedance variation but also causes voltage
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LM49101
Demo Board Circuit
30086201
FIGURE 5. Demo Board Circuit
it. When powered from the USB bus the I2CVDD will be set to
3.3V and the VDDLS will be set to 5V. Jumper headers J13 and
J12 must be set accordingly. If a single power supply for
I2CVDD and VDDLS is desired then header J5 should be used
with a jumper added to header J11 to connect I2CVDD to the
external supply voltage connected to J5 (see Figure 5).
Connection headers J1 and J2 are provided along with the
stereo headphone jack J4 for easily connection and monitoring of the headphone outputs.
Demonstration Board
The demonstration board (see Figure 5) has connection and
jumper options to be powered partially from the USB bus or
from external power supplies. Additional options are to power
the I2C logic and loudspeaker amplifier (VDDLS) from a single
power supply or separate power supplies. The headphone
amplifier and charge pump can also be powered from the
same supply as long as the voltage limits for each power supply are not exceeded, although the option is not built into the
board. See theOperating Ratings for each supply's range lim-
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LM49101
LM49101 microSMD Demo Board Views
30086209
30086205
Composite View
Silk Screen
30086206
30086208
Top Layer
Internal Layer 1
30086207
30086210
Internal Layer 2
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Bottom Layer
26
LM49101
LM49101 Reference Demo Board Bill Of Materials
TABLE 7. Bill Of Materials
Designator
Vlaue
Tolerance
Part Description
R1, R2
5.1kΩ
5%
1/10W, 0603 Resistors
R3, R4
10Ω
1%
1/10W, 0603 Resistors
R5
100kΩ
5%
1/10W, 0805 Resistor
CIN1, CIN2
CIN3, CIN4
1μF
10%
1206, X7R Ceramic Capacitor
CS1, CS4
CS5, CB
2.2μF
10%
Size A, Tantalum Capacitor
CS2
0.1μF
10%
0805, 16V, X7R Ceramic Capacitor
CS3, C1
2.2μF
10%
0603, 10V, X7R Ceramic Capacitor
Comment
U1
LM49101TM
J1, J2, J3
J5, J7, J8
J9, J10, J14
0.100" 1x2 header, vertical mount
Input, Output, VDD, GND
J11, J12, J13
0.100" 1x3 header, vertical mount
VDD Selects, VDD, I2CVDD,
GND
J6
16 pin header
I2C Connector
J4
Headphone Jack
SW1
Momentary Push Switch
RESET function
log and digital sections. It is further recommended to put
digital and analog power traces over the corresponding digital
and analog ground traces to minimize noise coupling.
PCB Layout Guidelines
This section provides practical guidelines for mixed signal
PCB layout that involves various digital/analog power and
ground traces. Designers should note that these are only
"rule-of-thumb" recommendations and the actual results will
depend heavily on the final layout.
PLACEMENT OF DIGITAL AND ANALOG COMPONENTS
All digital components and high-speed digital signals traces
should be located as far away as possible from analog components and circuit traces.
General Mixed Signal Layout
Recommendations
AVOIDING TYPICAL DESIGN AND LAYOUT PROBLEMS
Avoid ground loops or running digital and analog traces parallel to each other (side-by-side) on the same PCB layer.
When traces must cross over each other do it at 90 degrees.
Running digital and analog traces at 90 degrees to each other
from the top to the bottom side as much as possible will minimize capacitive noise coupling and cross talk.
SINGLE-POINT POWER AND GROUND CONNECTIONS
The analog power traces should be connected to the digital
traces through a single point (link). A "Pi-filter" can be helpful
in minimizing high frequency noise coupling between the ana-
27
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LM49101
Revision History
Rev
Date
0.01
10/18/08
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Description
Initial released.
28
LM49101
Physical Dimensions inches (millimeters) unless otherwise noted
25 Bump micro SMD Package
NS Package Number TMD25BCA
X1 = 2.040±0.030mm X2 = 2.066±0.030mm, X3 = 0.600±0.075mm
29
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LM49101Mono Class AB Audio Subsystem with a True Ground Headphone Amplifier and
Earpiece Switch
Notes
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