TI TPA3110D2PWP

TPA3110D2
www.ti.com................................................................................................................................................. SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009
15-W FILTER-FREE STEREO CLASS-D AUDIO POWER AMPLIFIER with
SPEAKERGUARD™
Check for Samples :TPA3110D2
FEATURES
APPLICATIONS
•
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1
2
•
•
•
•
•
•
•
•
•
•
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15-W/ch into an 8-Ω Loads at 10% THD+N
From a 16-V Supply
10-W/ch into 8-Ω Loads at 10% THD+N From a
13-V Supply
30-W into a 4-Ω Mono Load at 10% THD+N
From a 16-V Supply
90% Efficient Class-D Operation Eliminates
Need for Heat Sinks
Wide Supply Voltage Range Allows Operation
from 8 V to 26 V
Filter-Free Operation
SpeakerGuard™ Speaker Protection Includes
Adjustable Power Limiter plus DC Protection
Flow Through Pin Out Facilitates Easy Board
Layout
Robust Pin-to-Pin Short Circuit Protection and
Thermal Protection with Auto Recovery Option
Excellent THD+N / Pop-Free Performance
Four Selectable, Fixed Gain Settings
Differential Inputs
Televisions
Consumer Audio Equipment
DESCRIPTION
The TPA3110D2 is a 15-W (per channel) efficient,
Class-D audio power amplifier for driving bridged-tied
stereo speakers. Advanced EMI Suppression
Technology enables the use of inexpensive ferrite
bead filters at the outputs while meeting EMC
requirements. SpeakerGuard™ speaker protection
circuitry includes an adjustable power limiter and a
DC detection circuit. The adjustable power limiter
allows the user to set a "virtual" voltage rail lower
than the chip supply to limit the amount of current
through the speaker. The DC detect circuit measures
the frequency and amplitude of the PWM signal and
shuts off the output stage if the input capacitors are
damaged or shorts exist on the inputs.
The TPA3110D2 can drive stereo speakers as low as
4 Ω. The high efficiency of the TPA3110D2, 90%,
eliminates the need for an external heat sink when
playing music.
The outputs are also fully protected against shorts to
GND, VCC, and output-to-output. The short-circuit
protection and thermal protection includes an
auto-recovery feature.
1mF
Audio
Source
OUTL+
LINP
OUTL-
LINN
OUTR+
RINP
OUTR-
RINN
TPA3110D2
OUTPL
OUTNL
FERRITE
BEAD
FILTER
15W
8W
FERRITE
BEAD
FILTER
15W
8W
GAIN0
GAIN1
OUTPR
OUTNR
PLIMIT
PBTL
Fault
SD
PVCC
8 to 26V
Figure 1. TPA3110D2 Simplified Application Schematic
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
SpeakerGuard, PowerPad are trademarks of Texas Instruments.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009, Texas Instruments Incorporated
TPA3110D2
SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009................................................................................................................................................. www.ti.com
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted) (1)
UNIT
VCC
Supply voltage
VI
Interface pin voltage
AVCC, PVCC
–0.3 V to 30 V
SD, GAIN0, GAIN1, PBTL, FAULT
–0.3 V to VCC + 0.3 V
PLIMIT
–0.3 V to GVDD + 0.3 V
RINN, RINP, LINN, LINP
–0.3 V to 6.3 V
Continuous total power dissipation
See Dissipation Rating Table
TA
Operating free-air temperature range
–40°C to 85°C
TJ
Operating junction temperature range (2)
–40°C to 150°C
Tstg
Storage temperature range
–65°C to 150°C
RL
Minimum Load Resistance
BTL: PVCC > 15 V
4.8
BTL: PVCC ≤ 15 V
3.2
PBTL
ESD
(1)
3.2
Human body model
Electrostatic discharge
(3)
Charged-device model
(all pins)
(4)
±2 kV
(all pins)
±500 V
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings
only, and functional operations of the device at these or any other conditions beyond those indicated under recommended operating
conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
The TPA3110D2 incorporates an exposed thermal pad on the underside of the chip. This acts as a heatsink, and it must be connected
to a thermally dissipating plane for proper power dissipation. Failure to do so may result in the device going into thermal protection
shutdown. See TI Technical Briefs SLMA002 for more information about using the TSSOP thermal pad.
In accordance with JEDEC Standard 22, Test Method A114-B.
In accordance with JEDEC Standard 22, Test Method C101-A
(2)
(3)
(4)
DISSIPATION RATINGS
PACKAGE
(1)
28 pin TSSOP (PWP)
(1)
TA ≤ 25°C
DERATING FACTOR (θJA)
TA = 85°C
θJP
ΨJT
4.48 W
27.87 °C/W
2.33 W
0.72 °C/W
0.45 °C/W
For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI
website at www.ti.com.
RECOMMENDED OPERATING CONDITIONS
over operating free-air temperature range (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
MAX
26
UNIT
VCC
Supply voltage
PVCC, AVCC
8
VIH
High-level input voltage
SD, GAIN0, GAIN1, PBTL
2
VIL
Low-level input voltage
SD, GAIN0, GAIN1, PBTL
0.8
V
VOL
Low-level output voltage
FAULT, RPULL-UP=100k, VCC=26V
0.8
V
IIH
High-level input current
SD, GAIN0, GAIN1, PBTL, VI = 2V, VCC = 18 V
50
µA
IIL
Low-level input current
SD, GAIN0, GAIN1, PBTL, VI = 0.8 V, VCC = 18 V
5
µA
TA
Operating free-air temperature
–40
85
°C
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V
TPA3110D2
www.ti.com................................................................................................................................................. SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009
DC CHARACTERISTICS
TA = 25°C, VCC = 24 V, RL = 8 Ω (unless otherwise noted)
PARAMETER
TEST CONDITIONS
| VOS |
Class-D output offset voltage (measured
differentially)
VI = 0 V, Gain = 36 dB
ICC
Quiescent supply current
SD = 2 V, no load, PVCC = 24V
ICC(SD)
Quiescent supply current in shutdown mode
SD = 0.8 V, no load, PVCC = 24V
rDS(on)
VCC = 12 V, IO = 500 mA,
TJ = 25°C
Drain-source on-state resistance
GAIN1 = 0.8 V
G
Gain
GAIN1 = 2 V
ton
Turn-on time
SD = 2 V
tOFF
Turn-off time
SD = 0.8 V
GVDD
Gate Drive Supply
IGVDD = 100μA
tDCDET
DC Detect time
V(RINN) = 6V, VRINP = 0V
MIN
TYP MAX
1.5
15
mV
32
50
mA
250
400
µA
High Side
240
Low side
240
mΩ
GAIN0 = 0.8 V
19
20
21
GAIN0 = 2 V
25
26
27
GAIN0 = 0.8 V
31
32
33
GAIN0 = 2 V
35
36
37
6.4
UNIT
dB
dB
14
ms
2
μs
6.9
7.4
420
V
ms
DC CHARACTERISTICS
TA = 25°C, VCC = 12 V, RL = 8 Ω (unless otherwise noted)
PARAMETER
TEST CONDITIONS
| VOS |
Class-D output offset voltage (measured
differentially)
VI = 0 V, Gain = 36 dB
ICC
Quiescent supply current
SD = 2 V, no load, PVCC = 12V
ICC(SD)
Quiescent supply current in shutdown mode
SD = 0.8 V, no load, PVCC = 12V
rDS(on)
Drain-source on-state resistance
VCC = 12 V, IO = 500 mA,
TJ = 25°C
GAIN1 = 0.8 V
G
Gain
GAIN1 = 2 V
tON
Turn-on time
SD = 2 V
tOFF
Turn-off time
SD = 0.8 V
GVDD
Gate Drive Supply
IGVDD = 2mA
VO
Output Voltage maximum under PLIMIT
control
V(PLIMIT) = 2 V; VI = 1V rms
MIN
TYP MAX
1.5
15
mV
20
35
mA
200
High Side
240
Low side
240
µA
mΩ
GAIN0 = 0.8 V
19
20
21
GAIN0 = 2 V
25
26
27
GAIN0 = 0.8 V
31
32
33
GAIN0 = 2 V
35
36
37
14
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dB
dB
ms
μs
2
6.4
6.9
7.4
V
6.75
7.90
8.75
V
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UNIT
3
TPA3110D2
SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009................................................................................................................................................. www.ti.com
AC CHARACTERISTICS
TA = 25°C, VCC = 24 V, RL = 8 Ω (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
KSVR
Power Supply ripple rejection
200 mVPP ripple at 1 kHz,
Gain = 20 dB, Inputs ac-coupled to AGND
PO
Continuous output power
THD+N
Total harmonic distortion + noise
Vn
TYP
MAX
UNIT
–70
dB
THD+N = 10%, f = 1 kHz, VCC = 16 V
15
W
VCC = 16 V, f = 1 kHz, PO = 7.5 W (half-power)
0.1
%
65
µV
Output integrated noise
20 Hz to 22 kHz, A-weighted filter, Gain = 20 dB
Crosstalk
VO = 1 Vrms, Gain = 20 dB, f = 1 kHz
SNR
Signal-to-noise ratio
Maximum output at THD+N < 1%, f = 1 kHz,
Gain = 20 dB, A-weighted
fOSC
Oscillator frequency
250
Thermal trip point
Thermal hysteresis
–80
dBV
–100
dB
102
dB
310
350
kHz
150
°C
15
°C
AC CHARACTERISTICS
TA = 25°C, VCC = 12 V, RL = 8 Ω (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
KSVR
Supply ripple rejection
200 mVPP ripple from 20 Hz–1 kHz,
Gain = 20 dB, Inputs ac-coupled to AGND
PO
Continuous output power
THD+N = 10%, f = 1 kHz; VCC = 13 V
THD+N
Total harmonic distortion + noise
RL = 8 Ω, f = 1 kHz, PO = 5 W (half-power)
Vn
Output integrated noise
20 Hz to 22 kHz, A-weighted filter, Gain = 20 dB
Crosstalk
Po = 1 W, Gain = 20 dB, f = 1 kHz
SNR
Signal-to-noise ratio
Maximum output at THD+N < 1%, f = 1 kHz,
Gain = 20 dB, A-weighted
fOSC
Oscillator frequency
250
Thermal trip point
Thermal hysteresis
TYP
MAX
UNIT
–70
dB
10
W
0.06
%
65
µV
–80
dBV
–100
dB
102
dB
310
350
kHz
150
°C
15
°C
PWP (TSSOP) PACKAGE
(TOP VIEW)
SD
FAULT
1
28
2
27
LINP
LINN
GAIN0
GAIN1
3
26
4
25
AVCC
AGND
GVDD
PLIMIT
RINN
RINP
NC
PBTL
4
5
24
6
23
7
22
8
21
9
20
10
19
11
18
12
17
13
16
14
15
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PVCCL
PVCCL
BSPL
OUTPL
PGND
OUTNL
BSNL
BSNR
OUTNR
PGND
OUTPR
BSPR
PVCCR
PVCCR
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PIN FUNCTIONS
PIN
Pin
Number
I/O/P
SD
1
I
Shutdown logic input for audio amp (LOW = outputs Hi-Z, HIGH = outputs
enabled). TTL logic levels with compliance to AVCC.
FAULT
2
O
Open drain output used to display short circuit or dc detect fault status. Voltage
compliant to AVCC. Short circuit faults can be set to auto-recovery by connecting
FAULT pin to SD pin. Otherwise, both short circuit faults and dc detect faults must
be reset by cycling PVCC.
LINP
3
I
Positive audio input for left channel. Biased at 3V.
LINN
4
I
Negative audio input for left channel. Biased at 3V.
GAIN0
5
I
Gain select least significant bit. TTL logic levels with compliance to AVCC.
GAIN1
6
I
Gain select most significant bit. TTL logic levels with compliance to AVCC.
AVCC
7
P
Analog supply
AGND
8
GVDD
9
O
High-side FET gate drive supply. Nominal voltage is 7V. Also should be used as
supply for PLIMIT function
PLIMIT
10
I
Power limit level adjust. Connect a resistor divider from GVDD to GND to set
power limit. Connect directly to GVDD for no power limit.
RINN
11
I
Negative audio input for right channel. Biased at 3V.
RINP
12
I
Positive audio input for right channel. Biased at 3V.
NC
13
PBTL
14
I
Parallel BTL mode switch
PVCCR
15
P
Power supply for right channel H-bridge. Right channel and left channel power
supply inputs are connect internally.
PVCCR
16
P
Power supply for right channel H-bridge. Right channel and left channel power
supply inputs are connect internally.
BSPR
17
I
Bootstrap I/O for right channel, positive high-side FET.
OUTPR
18
O
Class-D H-bridge positive output for right channel.
PGND
19
OUTNR
20
O
Class-D H-bridge negative output for right channel.
BSNR
21
I
Bootstrap I/O for right channel, negative high-side FET.
BSNL
22
I
Bootstrap I/O for left channel, negative high-side FET.
OUTNL
23
O
Class-D H-bridge negative output for left channel.
PGND
24
OUTPL
25
O
Class-D H-bridge positive output for left channel.
BSPL
26
I
Bootstrap I/O for left channel, positive high-side FET.
PVCCL
27
P
Power supply for left channel H-bridge. Right channel and left channel power
supply inputs are connect internally.
PVCCL
28
P
Power supply for left channel H-bridge. Right channel and left channel power
supply inputs are connect internally.
NAME
DESCRIPTION
Analog signal ground. Connect to the thermal pad.
Not connected
Power ground for the H-bridges.
Power ground for the H-bridges.
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TPA3110D2
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FUNCTIONAL BLOCK DIAGRAM
GVDD
PVCCL
BSPL
PVCCL
PBTL Select
OUTPL FB
Gate
Drive
OUTPL
OUTPL FB
LINP
Gain
Control
PGND
PWM
Logic
PLIMIT
GVDD
LINN
PVCCL
BSNL
PVCCL
OUTNL FB
OUTNL FB
FAULT
Gate
Drive
OUTNL
SD
GAIN0
TTL
Buffer
SC Detect
Gain
Control
GAIN1
Ramp
Generator
Biases and
References
Startup Protection
Logic
PLIMIT
Reference
PLIMIT
PGND
DC Detect
Thermal
Detect
UVLO/OVLO
GVDD
AVDD
AVCC
PVCCL
BSNR
PVCCL
LDO
Regulator
GVDD
Gate
Drive
GVDD
OUTNR
OUTNN FB
OUTNR FB
RINN
Gain
Control
PLIMIT
PGND
PWM
Logic
GVDD
RINP
PVCCL
BSPR
PVCCL
OUTNP FB
Gate
Drive
PBTL
TTL
Buffer
PBTL
Select
OUTPR
PBTL Select
OUTPR FB
AGND
PGND
6
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TPA3110D2
www.ti.com................................................................................................................................................. SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009
TYPICAL CHARACTERISTICS
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (BTL)
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (BTL)
10
Gain = 20 dB
VCC = 12 V
ZL = 8 Ω + 66 µH
THD − Total Harmonic Distortion − %
THD − Total Harmonic Distortion − %
10
1
0.1
PO = 5 W
PO = 0.5 W
0.01
Gain = 20 dB
VCC = 18 V
ZL = 8 Ω + 66 µH
1
0.1
PO = 10 W
PO = 1 W
0.01
PO = 5 W
PO = 2.5 W
0.001
20
100
1k
10k
0.001
20
20k
100
f − Frequency − Hz
1k
10k
G001
G002
Figure 2.
Figure 3.
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (BTL)
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (BTL)
10
Gain = 20 dB
VCC = 24 V
ZL = 8 Ω + 66 µH
THD − Total Harmonic Distortion − %
THD − Total Harmonic Distortion − %
10
1
0.1
20k
f − Frequency − Hz
PO = 10 W
PO = 1 W
0.01
Gain = 20 dB
VCC = 12 V
ZL = 6 Ω + 47 µH
1
0.1
PO = 5 W
PO = 0.5 W
0.01
PO = 2.5 W
PO = 5 W
0.001
20
100
1k
10k
20k
0.001
20
f − Frequency − Hz
100
1k
10k
20k
f − Frequency − Hz
G003
Figure 4.
G004
Figure 5.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (BTL)
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (BTL)
10
Gain = 20 dB
VCC = 18 V
ZL = 6 Ω + 47 µH
THD − Total Harmonic Distortion − %
THD − Total Harmonic Distortion − %
10
1
PO = 10 W
0.1
0.01
PO = 1 W
Gain = 20 dB
VCC = 12 V
ZL = 4 Ω + 33 µH
1
0.1
PO = 10 W
PO = 1 W
0.01
PO = 5 W
PO = 5 W
0.001
20
100
1k
10k
0.001
20
20k
100
1k
f − Frequency − Hz
10k
G005
G006
Figure 6.
Figure 7.
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (BTL)
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (BTL)
10
Gain = 20 dB
VCC = 12 V
ZL = 8 Ω + 66 µH
THD+N − Total Harmonic Distortion + Noise − %
THD+N − Total Harmonic Distortion + Noise − %
10
1
f = 20 Hz
0.1
f = 1 kHz
0.01
f = 10 kHz
0.001
0.01
0.1
1
PO − Output Power − W
10
50
Gain = 20 dB
VCC = 18 V
ZL = 8 Ω + 66 µH
1
f = 1 kHz
f = 20 Hz
0.1
0.01
f = 10 kHz
0.001
0.01
G007
Figure 8.
8
20k
f − Frequency − Hz
0.1
1
PO − Output Power − W
10
50
G008
Figure 9.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (BTL)
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (BTL)
10
Gain = 20 dB
VCC = 24 V
ZL = 8 Ω + 66 µH
THD+N − Total Harmonic Distortion + Noise − %
THD+N − Total Harmonic Distortion + Noise − %
10
1
f = 1 kHz
0.1
0.01
f = 20 Hz
f = 10 kHz
0.001
0.01
0.1
1
10
PO − Output Power − W
1
f = 1 kHz
f = 20 Hz
0.1
0.01
f = 10 kHz
0.001
0.01
50
0.1
1
10
PO − Output Power − W
G009
Figure 11.
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (BTL)
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (BTL)
10
THD+N − Total Harmonic Distortion + Noise − %
Gain = 20 dB
VCC = 18 V
ZL = 6 Ω + 47 µH
1
f = 1 kHz
f = 20 Hz
0.1
0.01
f = 10 kHz
0.001
0.01
50
G010
Figure 10.
10
THD+N − Total Harmonic Distortion + Noise − %
Gain = 20 dB
VCC = 12 V
ZL = 6 Ω + 47 µH
0.1
1
PO − Output Power − W
10
50
Gain = 20 dB
VCC = 12 V
ZL = 4 Ω + 33 µH
1
f = 1 kHz
0.1
0.01
f = 20 Hz
f = 10 kHz
0.001
0.01
G011
Figure 12.
0.1
1
10
PO − Output Power − W
50
G012
Figure 13.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
MAXIMUM OUTPUT POWER
vs
PLIMIT VOLTAGE (BTL)
OUTPUT POWER
vs
PLIMIT VOLTAGE (BTL)
35
14
Gain = 20 dB
VCC = 24 V
ZL = 8 Ω + 66 µH
Gain = 20 dB
VCC = 12 V
ZL = 4 Ω + 33 µH
30
12
PO − Output Power − W
PO(Max) − Maximum Output Power − W
16
10
8
6
25
20
15
10
4
5
2
0
0.0
0
0.5
1.0
1.5
2.0
2.5
0
3.0
1
2
3
4
5
6
VPLIMIT − PLIMIT Voltage − V
VPLIMIT − PLIMIT Voltage − V
G014
G013
Note: Dashed Lines represent thermally limited regions.
Figure 14.
Figure 15.
GAIN/PHASE
vs
FREQUENCY (BTL)
OUTPUT POWER
vs
SUPPLY VOLTAGE (BTL)
40
100
35
50
30
Gain = 20 dB
ZL = 8 Ω + 66 µH
25
25
−50
Gain
20
15
10
5
0
20
−100
−150
CI = 1 µF
Gain = 20 dB
Filter = Audio Precision AUX-0025
VCC = 12 V
VI = 0.1 Vrms
ZL = 8 Ω + 66 µH
100
1k
−200
−250
10k
PO − Output Power − W
0
Phase − °
Gain − dB
Phase
30
20
THD = 10%
15
THD = 1%
10
5
−300
100k
0
f − Frequency − Hz
G015
6
8
10
12
14
16
18
20
22
24
VCC − Supply Voltage − V
26
G016
Note: Dashed Lines represent thermally limited regions.
Figure 16.
10
Figure 17.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
OUTPUT POWER
vs
SUPPLY VOLTAGE (BTL)
EFFICIENCY
vs
OUTPUT POWER (BTL)
25
100
Gain = 20 dB
ZL = 4 Ω + 33 µH
20
VCC = 18 V
70
THD = 10%
15
THD = 1%
10
60
50
40
30
5
20
Gain = 20 dB
ZL = 8 Ω + 66 µH
10
0
0
6
8
10
12
14
16
18
VCC − Supply Voltage − V
0
5
10
15
20
25
30
35
PO − Output Power − W
G017
Note: Dashed Lines represent thermally limited regions.
40
G018
Note: Dashed Lines represent thermally limited regions.
Figure 18.
Figure 19.
EFFICIENCY
vs
OUTPUT POWER (BTL with LC FILTER)
EFFICIENCY
vs
OUTPUT POWER (BTL)
100
100
VCC = 12 V
90
VCC = 18 V
90
80
VCC = 12 V
VCC = 18 V
80
VCC = 24 V
70
η − Efficiency − %
70
η − Efficiency − %
VCC = 24 V
80
η − Efficiency − %
PO − Output Power − W
VCC = 12 V
90
60
50
40
30
60
50
40
30
20
20
Gain = 20 dB
LC Filter = 22 µH + 0.68 µF
RL = 8 Ω
10
Gain = 20 dB
ZL = 6 Ω + 47 µH
10
0
0
0
5
10
15
PO − Output Power − W
20
25
0
5
10
15
20
PO − Output Power − W
G032
25
G019
Note: Dashed Lines represent thermally limited regions.
Figure 20.
Figure 21.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
EFFICIENCY
vs
OUTPUT POWER (BTL with LC FILTER)
EFFICIENCY
vs
OUTPUT POWER (BTL)
100
100
90
90
VCC = 12 V
VCC = 12 V
80
80
VCC = 18 V
70
η − Efficiency − %
η − Efficiency − %
70
60
50
40
30
50
40
30
20
20
Gain = 20 dB
LC Filter = 22 µH + 0.68 µF
RL = 6 Ω
10
Gain = 20 dB
ZL = 4 Ω + 33 µH
10
0
0
0
5
10
15
20
PO − Output Power − W
25
0
3
6
9
12
15
PO − Output Power − W
G033
18
G020
Figure 22.
Figure 23.
EFFICIENCY
vs
OUTPUT POWER (BTL with LC FILTER)
SUPPLY CURRENT
vs
TOTAL OUTPUT POWER (BTL)
2.6
100
2.4
90
VCC = 18 V
2.2
VCC = 12 V
80
ICC − Supply Current − A
2.0
70
η − Efficiency − %
60
60
50
40
30
1.8
1.6
VCC = 12 V
1.4
1.2
VCC = 24 V
1.0
0.8
0.6
20
Gain = 20 dB
LC Filter = 22 µH + 0.68 µF
RL = 4 Ω
10
0.4
Gain = 20 dB
ZL = 8 Ω + 66 µH
0.2
0.0
0
0
5
10
15
PO − Output Power − W
20
25
0
5
10
15
20
25
30
35
PO(Tot) − Total Output Power − W
G034
40
G021
Note: Dashed Lines represent thermally limited regions.
Figure 24.
12
Figure 25.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
SUPPLY CURRENT
vs
TOTAL OUTPUT POWER (BTL)
CROSSTALK
vs
FREQUENCY (BTL)
3.2
−20
Gain = 20 dB
ZL = 4 Ω + 33 µH
2.8
−30
−40
−50
2.0
Crosstalk − dB
ICC − Supply Current − A
2.4
Gain = 20 dB
VCC = 12 V
VO = 1 Vrms
ZL = 8 Ω + 66 µH
VCC = 12 V
1.6
1.2
−60
−70
−80
Right to Left
−90
−100
0.8
Left to Right
−110
0.4
−120
0.0
0
5
10
15
20
25
−130
20
30
PO(Tot) − Total Output Power − W
100
1k
10k
20k
f − Frequency − Hz
G022
G023
Note: Dashed Lines represent thermally limited regions.
Figure 26.
Figure 27.
SUPPLY RIPPLE REJECTION RATIO
vs
FREQUENCY (BTL)
TOTAL HARMONIC DISTORTION
vs
FREQUENCY (PBTL)
−20
10
Gain = 20 dB
Vripple = 200 mVpp
ZL = 8 Ω + 66 µH
THD − Total Harmonic Distortion − %
KSVR − Supply Ripple Rejection Ratio − dB
0
−40
−60
VCC = 12 V
−80
−100
−120
20
100
1k
10k
20k
Gain = 20 dB
VCC = 24 V
ZL = 4 Ω + 33 µH
1
PO = 5 W
0.1
PO = 0.5 W
0.01
PO = 2.5 W
0.001
20
f − Frequency − Hz
G024
Figure 28.
100
1k
10k
20k
f − Frequency − Hz
G025
Figure 29.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
TOTAL HARMONIC DISTORTION + NOISE
vs
OUTPUT POWER (PBTL)
GAIN/PHASE
vs
FREQUENCY (PBTL)
100
40
Gain = 20 dB
VCC = 24 V
ZL = 4 Ω + 33 µH
35
50
1
f = 1 kHz
0.1
30
0
25
−50
Gain
20
−100
15
0.01
5
f = 20 Hz
0.001
0.01
0.1
1
10
PO − Output Power − W
−150
CI = 1 µF
Gain = 20 dB
Filter = Audio Precision AUX-0025
VCC = 24 V
VI = 0.1 Vrms
ZL = 8 Ω + 66 µH
10
0
20
f = 10 kHz
Phase − °
Phase
Gain − dB
THD+N − Total Harmonic Distortion + Noise − %
10
100
−200
−250
−300
100k
10k
1k
f − Frequency − Hz
50
G027
G026
Figure 30.
Figure 31.
OUTPUT POWER
vs
SUPPLY VOLTAGE (PBTL)
EFFICIENCY
vs
OUTPUT POWER (PBTL)
100
40
Gain = 20 dB
ZL = 4 Ω + 33 µH
35
90
80
VCC = 18 V
70
η − Efficiency − %
PO − Output Power − W
30
25
THD = 10%
20
THD = 1%
15
VCC = 12 V
60
50
40
30
10
20
5
Gain = 20 dB
ZL = 4 Ω + 33 µH
10
0
0
6
8
10
12
14
16
18
VCC − Supply Voltage − V
20
0
5
G028
10
15
20
25
30
PO − Output Power − W
35
40
45
G029
Note: Dashed Lines represent thermally limited regions.
Figure 32.
14
Figure 33.
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TYPICAL CHARACTERISTICS (continued)
(All Measurements taken at 1 kHz, unless otherwise noted. Measurements were made using the TPA3110D2 EVM which is
available at ti.com.)
SUPPLY CURRENT
vs
OUTPUT POWER (PBTL)
SUPPLY RIPPLE REJECTION RATIO
vs
FREQUENCY (PBTL)
2.8
0
2.4
KSVR − Supply Ripple Rejection Ratio − dB
Gain = 20 dB
ZL = 4 Ω + 33 µH
2.6
ICC − Supply Current − A
2.2
2.0
1.8
VCC = 12 V
1.6
1.4
VCC = 18 V
1.2
1.0
0.8
0.6
0.4
−20
Gain = 20 dB
Vripple = 200 mVpp
ZL = 8 Ω + 66 µH
−40
−60
VCC = 12 V
−80
−100
0.2
0.0
0
5
10
15
20
25
30
PO − Output Power − W
35
40
45
−120
20
G030
Figure 34.
100
1k
10k
20k
f − Frequency − Hz
G031
Figure 35.
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DEVICE INFORMATION
Gain setting via GAIN0 and GAIN1 inputs
The gain of the TPA3110D2 is set by two input terminals, GAIN0 and GAIN1.
The gains listed in Table 1 are realized by changing the taps on the input resistors and feedback resistors inside
the amplifier. This causes the input impedance (ZI) to be dependent on the gain setting. The actual gain settings
are controlled by ratios of resistors, so the gain variation from part-to-part is small. However, the input impedance
from part-to-part at the same gain may shift by ±20% due to shifts in the actual resistance of the input resistors.
For design purposes, the input network (discussed in the next section) should be designed assuming an input
impedance of 7.2 kΩ, which is the absolute minimum input impedance of the TPA3110D2. At the lower gain
settings, the input impedance could increase as high as 72 kΩ
Table 1. Gain Setting
AMPLIFIER GAIN (dB)
INPUT IMPEDANCE
(kΩ)
TYP
TYP
20
60
1
26
30
1
0
32
15
1
1
36
9
GAIN1
GAIN0
0
0
0
SD OPERATION
The TPA3110D2 employs a shutdown mode of operation designed to reduce supply current (ICC) to the absolute
minimum level during periods of nonuse for power conservation. The SD input terminal should be held high (see
specification table for trip point) during normal operation when the amplifier is in use. Pulling SD low causes the
outputs to mute and the amplifier to enter a low-current state. Never leave SD unconnected, because amplifier
operation would be unpredictable.
For the best power-off pop performance, place the amplifier in the shutdown mode prior to removing the power
supply voltage.
PLIMIT
The voltage at pin 10 can used to limit the power to levels below that which is possible based on the supply rail.
Add a resistor divider from GVDD to ground to set the voltage at the PLIMIT pin. An external reference may also
be used if tighter tolerance is required. Also add a 1μF capacitor from pin 10 to ground.
Vinput
PLIMIT = 6.96V Pout = 11.8W
PLIMIT = 3V Pout = 10W
PLIMIT = 1.8V Pout = 5W
TPA3110D2 Power Limit Function
Vin=1.13VPP Freq=1kHz RLoad=8W
Figure 36. PLIMIT Circuit Operation
16
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The PLIMIT circuit sets a limit on the output peak-to-peak voltage. The limiting is done by limiting the duty cycle
to fixed maximum value. This limit can be thought of as a "virtual" voltage rail which is lower than the supply
connected to PVCC. This "virtual" rail is 4 times the voltage at the PLIMIT pin. This output voltage can be used to
calculate the maximum output power for a given maximum input voltage and speaker impedance.
POUT
ææ
ö
ö
RL
çç ç
÷ x VP ÷÷
è RL + 2 x RS ø
ø
= è
2 x RL
2
for unclipped power
(1)
Where:
RS is the total series resistance including RDS(on), and any resistance in the output filter.
RL is the load resistance.
VP is the peak amplitude of the output possible within the supply rail.
VP = 4 × PLIMIT voltage if PLIMIT < 4 × VP
POUT (10%THD) = 1.25 × POUT (unclipped)
Table 2. PLIMIT Typical Operation
Test Conditions ()
PLIMIT Voltage
Output Power (W)
Output Voltage
Amplitude (VP-P)
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=26dB
6.97
36.1 (thermally limited)
43
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=26dB
2.94
15
25.2
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=26dB
2.34
10
20
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=26dB
1.62
5
14
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=20dB
6.97
12.1
27.7
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=20dB
3.00
10
23
PVCC=24V, Vin=1Vrms,
RL=8Ω, Gain=20dB
1.86
5
14.8
PVCC=12V, Vin=1Vrms,
RL=8Ω, Gain=20dB
6.97
10.55
23.5
PVCC=12V, Vin=1Vrms,
RL=8Ω, Gain=20dB
1.76
5
15
GVDD Supply
The GVDD Supply is used to power the gates of the output full bridge transistors. It can also be used to supply
the PLIMIT voltage divider circuit. Add a 1μF capacitor to ground at this pin.
DC Detect
TPA3110D2 has circuitry which will protect the speakers from DC current which might occur due to defective
capacitors on the input or shorts on the printed circuit board at the inputs. A DC detect fault will be reported on
the FAULT pin as a low state. The DC Detect fault will also cause the amplifier to shutdown by changing the
state of the outputs to Hi-Z. To clear the DC Detect it is necessary to cycle the PVCC supply. Cycling S D will
NOT clear a DC detect fault.
A DC Detect Fault is issued when the output differential duty-cycle of either channel exceeds 14% (for example,
+57%, -43%) for more than 420 msec at the same polarity. This feature protects the speaker from large DC
currents or AC currents less than 2Hz. To avoid nuisance faults due to the DC detect circuit, hold the SD pin low
at power-up until the signals at the inputs are stable. Also, take care to match the impedance seen at the positive
and negative inputs to avoid nuisance DC detect faults.
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The minimum differential input voltages required to trigger the DC detect are show in table 2. The inputs must
remain at or above the voltage listed in the table for more than 420 msec to trigger the DC detect.
Table 3. DC Detect Threshold
AV(dB)
Vin (mV, differential)
20
112
26
56
32
28
36
17
PBTL Select
TPA3110D2 offers the feature of parallel BTL operation with two outputs of each channel connected directly. If
the PBTL pin (pin 14) is tied high, the positive and negative outputs of each channel (left and right) are
synchronized and in phase. To operate in this PBTL (mono) mode, apply the input signal to the RIGHT input and
place the speaker between the LEFT and RIGHT outputs. Connect the positive and negative output together for
best efficiency. For an example of the PBTL connection, see the schematic in the APPLICATION INFORMATION
section.
For normal BTL operation, connect the PBTL pin to local ground.
SHORT-CIRCUIT PROTECTION AND AUTOMATIC RECOVERY FEATURE
TPA3110D2 has protection from overcurrent conditions caused by a short circuit on the output stage. The short
circuit protection fault is reported on the FAULT pin as a low state. The amplifier outputs are switched to a Hi-Z
state when the short circuit protection latch is engaged. The latch can be cleared by cycling the SD pin through
the low state.
If automatic recovery from the short circuit protection latch is desired, connect the FAULT pin directly to the SD
pin. This allows the FAULT pin function to automatically drive the SD pin low which clears the short-circuit
protection latch.
THERMAL PROTECTION
Thermal protection on the TPA3110D2 prevents damage to the device when the internal die temperature
exceeds 150°C. There is a ±15°C tolerance on this trip point from device to device. Once the die temperature
exceeds the thermal set point, the device enters into the shutdown state and the outputs are disabled. This is not
a latched fault. The thermal fault is cleared once the temperature of the die is reduced by 15°C. The device
begins normal operation at this point with no external system interaction.
Thermal protection faults are NOT reported on the FAULT terminal.
18
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APPLICATION INFORMATION
PVCC
100 μF
0.1 μF
1000 pF
100 kΩ
Control
System
1
SD
PVCCL
FAULT
PVCCL
28
1 kΩ
2
1 mF
3
1 mF
4
5
6
PVCC
10 Ω
7
1 mF
8
1 mF
9
BSPL
LINP
OUTPL
LINN
GAIN0
PGND
GAIN1
OUTNL
BSNL
AVCC
TPA3110D2
AGND
BSNR
GVDD
OUTNR
PLIMIT
PGND
27
26
0.22 μF
FB
25
1000 pF
24
23
1000 pF
22
0.22 μF
0.22 μF
21
FB
FB
20
1000 pF
1 mF
10 kΩ
10
19
10 kΩ
1 mF
Audio
Source
11
12
1 mF
13
14
RINN
OUTPR
RINP
BSPR
NC
PBTL
PVCCR
PVCCR
18
1000 pF
17
FB
0.22 μF
16
100 μF
15
0.1 μF
1000 pF
GND
29
PowerPAD
PVCC
Figure 37. Stereo Class-D Amplifier with BTL Output and Single-Ended Inputs
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PVCC
100 μF
0.1 μF
1000 pF
100 kΩ
Control
System
1
SD
PVCCL
FAULT
PVCCL
28
1 kΩ
2
3
4
5
6
PVCC
7
LINP
LINN
8
9
1 mF
10
1 mF
Audio
Source
11
12
1 mF
13
OUTPL
GAIN0
PGND
GAIN1
OUTNL
AVCC
BSNL
10 Ω
1 mF
BSPL
TPA3110D2
AGND
BSNR
GVDD
OUTNR
PLIMIT
PGND
RINN
OUTPR
RINP
BSPR
NC
PVCCR
PBTL
PVCCR
27
26
0.47 μF
25
24
FB
23
1000 pF
22
21
1000 pF
20
FB
19
0.47 μF
18
17
16
100 μF
AVCC
14
0.1 μF
1000 pF
15
GND
29
PowerPAD
PVCC
Figure 38. Stereo Class-D Amplifier with PBTL Output and Single-Ended Input
20
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TPA3110D2 Modulation Scheme
The TPA3110D2 uses a modulation scheme that allows operation without the classic LC reconstruction filter
when the amp is driving an inductive load. Each output is switching from 0 volts to the supply voltage. The OUTP
and OUTN are in phase with each other with no input so that there is little or no current in the speaker. The duty
cycle of OUTP is greater than 50% and OUTN is less than 50% for positive output voltages. The duty cycle of
OUTP is less than 50% and OUTN is greater than 50% for negative output voltages. The voltage across the load
sits at 0V throughout most of the switching period, reducing the switching current, which reduces any I2R losses
in the load.
OUTP
OUTN
OUTP
OUTP-OUTN
No Output
0V
Speaker
Current
OUTP
OUTN
Positive Output
PVCC
OUTP-OUTN 0V
Speaker
Current
0A
OUTP
Negative Output
OUTN
OUTP-OUTN
0V
-PVCC
Speaker 0A
Current
Figure 39. The TPA3110D2 Output Voltage and Current Waveforms Into an Inductive Load
Ferrite Bead Filter Considerations
Using the Advanced Emissions Suppression Technology in the TPA3110D2 amplifier it is possible to design a
high efficiency Class-D audio amplifier while minimizing interference to surrounding circuits. It is also possible to
accomplish this with only a low-cost ferrite bead filter. In this case it is necessary to carefully select the ferrite
bead used in the filter.
One important aspect of the ferrite bead selection is the type of material used in the ferrite bead. Not all ferrite
material is alike, so it is important to select a material that is effective in the 10 to 100 MHz range which is key to
the operation of the Class D amplifier. Many of the specifications regulating consumer electronics have
emissions limits as low as 30 MHz. It is important to use the ferrite bead filter to block radiation in the 30 MHz
and above range from appearing on the speaker wires and the power supply lines which are good antennas for
these signals. The impedance of the ferrite bead can be used along with a small capacitor with a value in the
range of 1000 pF to reduce the frequency spectrum of the signal to an acceptable level. For best performance,
the resonant frequency of the ferrite bead/ capacitor filter should be less than 10 MHz.
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Also, it is important that the ferrite bead is large enough to maintain its impedance at the peak currents expected
for the amplifier. Some ferrite bead manufacturers specify the bead impedance at a variety of current levels. In
this case it is possible to make sure the ferrite bead maintains an adequate amount of impedance at the peak
current the amplifier will see. If these specifications are not available, it is also possible to estimate the bead
current handling capability by measuring the resonant frequency of the filter output at low power and at maximum
power. A change of resonant frequency of less than fifty percent under this condition is desirable. Examples of
ferrite beads which have been tested and work well with the TPA3110D2 include 28L0138-80R-10 and
HI1812V101R-10 from Steward and the 742792510 from Wurth Electronics.
A high quality ceramic capacitor is also needed for the ferrite bead filter. A low ESR capacitor with good
temperature and voltage characteristics will work best.
Additional EMC improvements may be obtained by adding snubber networks from each of the class D outputs to
ground. Suggested values for a simple RC series snubber network would be 10 Ω in series with a 330 pF
capacitor although design of the snubber network is specific to every application and must be designed taking
into account the parasitic reactance of the printed circuit board as well as the audio amp. Take care to evaluate
the stress on the component in the snubber network especially if the amp is running at high PVCC. Also, make
sure the layout of the snubber network is tight and returns directly to the PGND or the PowerPad™ beneath the
chip.
70
FCC Class B
Limit Level - dBmV/m
60
50
40
30
20
10
0
30M
230M
430M
630M
830M
f - Frequency - Hz
Figure 40. TPA3110D2 EMC spectrum with FCC Class B Limits
Efficiency: LC Filter Required With the Traditional Class-D Modulation Scheme
The main reason that the traditional class-D amplifier needs an output filter is that the switching waveform results
in maximum current flow. This causes more loss in the load, which causes lower efficiency. The ripple current is
large for the traditional modulation scheme, because the ripple current is proportional to voltage multiplied by the
time at that voltage. The differential voltage swing is 2 × VCC, and the time at each voltage is half the period for
the traditional modulation scheme. An ideal LC filter is needed to store the ripple current from each half cycle for
the next half cycle, while any resistance causes power dissipation. The speaker is both resistive and reactive,
whereas an LC filter is almost purely reactive.
The TPA3110D2 modulation scheme has little loss in the load without a filter because the pulses are short and
the change in voltage is VCC instead of 2 × VCC. As the output power increases, the pulses widen, making the
ripple current larger. Ripple current could be filtered with an LC filter for increased efficiency, but for most
applications the filter is not needed.
An LC filter with a cutoff frequency less than the class-D switching frequency allows the switching current to flow
through the filter instead of the load. The filter has less resistance but higher impedance at the switching
frequency than the speaker, which results in less power dissipation, therefore increasing efficiency.
22
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TPA3110D2
www.ti.com................................................................................................................................................. SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009
When to Use an Output Filter for EMI Suppression
The TPA3110D2 has been tested with a simple ferrite bead filter for a variety of applications including long
speaker wires up to 125 cm and high power. The TPA3110D2 EVM passes FCC Class B specifications under
these conditions using twisted speaker wires. The size and type of ferrite bead can be selected to meet
application requirements. Also, the filter capacitor can be increased if necessary with some impact on efficiency.
There may be a few circuit instances where it is necessary to add a complete LC reconstruction filter. These
circumstances might occur if there are nearby circuits which are sensitive to noise. In these cases a classic
second order Butterworth filter similar to those shown in the figures below can be used.
Some systems have little power supply decoupling from the AC line but are also subject to line conducted
interference (LCI) regulations. These include systems powered by "wall warts" and "power bricks." In these
cases, it LC reconstruction filters can be the lowest cost means to pass LCI tests. Common mode chokes using
low frequency ferrite material can also be effective at preventing line conducted interference.
33 mH
OUTP
L1
C2
1 mF
33 mH
OUTN
L2
C3
1 mF
Figure 41. Typical LC Output Filter, Cutoff Frequency of 27 kHz, Speaker Impedance = 8 Ω
15 mH
OUTP
L1
C2
2.2 mF
15 mH
OUTN
L2
C3
2.2 mF
Figure 42. Typical LC Output Filter, Cutoff Frequency of 27 kHz, Speaker Impedance = 4 Ω
Ferrite
Chip Bead
OUTP
1 nF
Ferrite
Chip Bead
OUTN
1 nF
Figure 43. Typical Ferrite Chip Bead Filter (Chip Bead Example: )
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23
TPA3110D2
SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009................................................................................................................................................. www.ti.com
INPUT RESISTANCE
Changing the gain setting can vary the input resistance of the amplifier from its smallest value, 9 kΩ ±20%, to the
largest value, 60 kΩ ±20%. As a result, if a single capacitor is used in the input high-pass filter, the -3 dB or
cutoff frequency may change when changing gain steps.
Zf
Ci
IN
Input
Signal
Zi
The -3-dB frequency can be calculated using Equation 2. Use the ZI values given in Table 1.
f =
1
2p Zi Ci
(2)
INPUT CAPACITOR, CI
In the typical application, an input capacitor (CI) is required to allow the amplifier to bias the input signal to the
proper dc level for optimum operation. In this case, CI and the input impedance of the amplifier (ZI) form a
high-pass filter with the corner frequency determined in Equation 3.
-3 dB
fc =
1
2p Zi Ci
fc
(3)
The value of CI is important, as it directly affects the bass (low-frequency) performance of the circuit. Consider
the example where ZI is 60 kΩ and the specification calls for a flat bass response down to 20 Hz. Equation 3 is
reconfigured as Equation 4.
Ci =
1
2p Zi fc
(4)
In this example, CI is 0.13 µF; so, one would likely choose a value of 0.15 μF as this value is commonly used. If
the gain is known and is constant, use ZI from Table 1 to calculate CI. A further consideration for this capacitor is
the leakage path from the input source through the input network (CI) and the feedback network to the load. This
leakage current creates a dc offset voltage at the input to the amplifier that reduces useful headroom, especially
in high gain applications. For this reason, a low-leakage tantalum or ceramic capacitor is the best choice. When
polarized capacitors are used, the positive side of the capacitor should face the amplifier input in most
applications as the dc level there is held at 3 V, which is likely higher than the source dc level. Note that it is
important to confirm the capacitor polarity in the application. Additionally, lead-free solder can create dc offset
voltages and it is important to ensure that boards are cleaned properly.
24
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TPA3110D2
www.ti.com................................................................................................................................................. SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009
POWER SUPPLY DECOUPLING, CS
The TPA3110D2 is a high-performance CMOS audio amplifier that requires adequate power supply decoupling
to ensure that the output total harmonic distortion (THD) is as low as possible. Power supply decoupling also
prevents oscillations for long lead lengths between the amplifier and the speaker. Optimum decoupling is
achieved by using a network of capacitors of different types that target specific types of noise on the power
supply leads. For higher frequency transients due to parasitic circuit elements such as bond wire and copper
trace inductances as well as lead frame capacitance, a good quality low equivalent-series-resistance (ESR)
ceramic capacitor of value between 220 pF and 1000 pF works well. This capacitor should be placed as close to
the device PVCC pins and system ground (either PGND pins or PowerPad) as possible. For mid-frequency noise
due to filter resonances or PWM switching transients as well as digital hash on the line, another good quality
capacitor typically 0.1 μF to 1 µF placed as close as possible to the device PVCC leads works best For filtering
lower frequency noise signals, a larger aluminum electrolytic capacitor of 220 μF or greater placed near the
audio power amplifier is recommended. The 220 μF capacitor also serves as a local storage capacitor for
supplying current during large signal transients on the amplifier outputs. The PVCC terminals provide the power
to the output transistors, so a 220 µF or larger capacitor should be placed on each PVCC terminal. A 10 µF
capacitor on the AVCC terminal is adequate. Also, a small decoupling resistor between AVCC and PVCC can be
used to keep high frequency class D noise from entering the linear input amplifiers.
BSN and BSP CAPACITORS
The full H-bridge output stages use only NMOS transistors. Therefore, they require bootstrap capacitors for the
high side of each output to turn on correctly. A 0.22 μF ceramic capacitor, rated for at least 25 V, must be
connected from each output to its corresponding bootstrap input. Specifically, one 0.22 μF capacitor must be
connected from OUTPx to BSPx, and one 0.22 μF capacitor must be connected from OUTNx to BSNx. (See the
application circuit diagram in Figure 1.)
The bootstrap capacitors connected between the BSxx pins and corresponding output function as a floating
power supply for the high-side N-channel power MOSFET gate drive circuitry. During each high-side switching
cycle, the bootstrap capacitors hold the gate-to-source voltage high enough to keep the high-side MOSFETs
turned on.
DIFFERENTIAL INPUTS
The differential input stage of the amplifier cancels any noise that appears on both input lines of the channel. To
use the TPA3110D2 with a differential source, connect the positive lead of the audio source to the INP input and
the negative lead from the audio source to the INN input. To use the TPA3110D2 with a single-ended source, ac
ground the INP or INN input through a capacitor equal in value to the input capacitor on INN or INP and apply
the audio source to either input. In a single-ended input application, the unused input should be ac grounded at
the audio source instead of at the device input for best noise performance. For good transient performance, the
impedance seen at each of the two differential inputs should be the same.
The impedance seen at the inputs should be limited to an RC time constant of 1 ms or less if possible. This is to
allow the input dc blocking capacitors to become completely charged during the 14 ms power-up time. If the input
capacitors are not allowed to completely charge, there will be some additional sensitivity to component matching
which can result in pop if the input components are not well matched.
USING LOW-ESR CAPACITORS
Low-ESR capacitors are recommended throughout this application section. A real (as opposed to ideal) capacitor
can be modeled simply as a resistor in series with an ideal capacitor. The voltage drop across this resistor
minimizes the beneficial effects of the capacitor in the circuit. The lower the equivalent value of this resistance,
the more the real capacitor behaves like an ideal capacitor.
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25
TPA3110D2
SLOS528A – JULY 2009 – REVISED SEPTEMBER 2009................................................................................................................................................. www.ti.com
PRINTED-CIRCUIT BOARD (PCB) LAYOUT
The TPA3110D2 can be used with a small, inexpensive ferrite bead output filter for most applications. However,
since the Class-D switching edges are fast, it is necessary to take care when planning the layout of the printed
circuit board. The following suggestions will help to meet EMC requirements.
• Decoupling capacitors—The high-frequency decoupling capacitors should be placed as close to the PVCC
and AVCC terminals as possible. Large (220 µF or greater) bulk power supply decoupling capacitors should
be placed near the TPA3110D2 on the PVCCL and PVCCR supplies. Local, high-frequency bypass
capacitors should be placed as close to the PVCC pins as possible. These caps can be connected to the
thermal pad directly for an excellent ground connection. Consider adding a small, good quality low ESR
ceramic capacitor between 220 pF and 1000 pF and a larger mid-frequency cap of value between 0.1μF and
1μF also of good quality to the PVCC connections at each end of the chip.
• Keep the current loop from each of the outputs through the ferrite bead and the small filter cap and back to
PGND as small and tight as possible. The size of this current loop determines its effectiveness as an
antenna.
• Grounding—The AVCC (pin 7) decoupling capacitor should be grounded to analog ground (AGND). The
PVCC decoupling capacitors should connect to PGND. Analog ground and power ground should be
connected at the thermal pad, which should be used as a central ground connection or star ground for the
TPA3110D2.
• Output filter—The ferrite EMI filter (Figure 43) should be placed as close to the output terminals as possible
for the best EMI performance. The LC filter (Figure 41 and Figure 42) should be placed close to the outputs.
The capacitors used in both the ferrite and LC filters should be grounded to power ground.
• Thermal Pad—The thermal pad must be soldered to the PCB for proper thermal performance and optimal
reliability. The dimensions of the thermal pad and thermal land should be 6.46 mm by 2.35mm. Seven rows of
solid vias (three vias per row, 0,3302 mm or 13 mils diameter) should be equally spaced underneath the
thermal land. The vias should connect to a solid copper plane, either on an internal layer or on the bottom
layer of the PCB. The vias must be solid vias, not thermal relief or webbed vias. See the TI Application
Report SLMA002 for more information about using the TSSOP thermal pad. For recommended PCB
footprints, see figures at the end of this data sheet.
For an example layout, see the TPA3110D2 Evaluation Module (TPA3110D2EVM) User Manual. Both the EVM
user manual and the thermal pad application report are available on the TI Web site at http://www.ti.com.
REVISION HISTORY
Changes from Original (July 2009) to Revision A ........................................................................................................... Page
•
Changed Changed the Stereo Class-D Amplifier with BTL Output and Single-Ended Input illustration Figure 37 Corrected the pin names. ................................................................................................................................................... 19
•
Changed Changed the Stereo Class-D Amplifier with PBTL Output and Single-Ended Input illustration Figure 38 Corrected the pin names. ................................................................................................................................................... 20
26
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PACKAGE OPTION ADDENDUM
www.ti.com
31-Aug-2009
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
TPA3110D2PWP
ACTIVE
HTSSOP
PWP
28
TPA3110D2PWPR
ACTIVE
HTSSOP
PWP
28
50
Lead/Ball Finish
MSL Peak Temp (3)
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
31-Aug-2009
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
TPA3110D2PWPR
Package Package Pins
Type Drawing
SPQ
HTSSOP
2000
PWP
28
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
330.0
16.4
Pack Materials-Page 1
6.9
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
10.2
1.8
12.0
16.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
31-Aug-2009
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
TPA3110D2PWPR
HTSSOP
PWP
28
2000
346.0
346.0
33.0
Pack Materials-Page 2
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