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TAS5342LA
SLAS624A – NOVEMBER 2008 – REVISED NOVEMBER 2016
TAS5342LA 100-W Stereo Digital Amplifier Power Stage
1 Features
3 Description
•
The TAS5342LA is a high-performance, integrated
stereo digital amplifier power stage designed to drive
a 4-Ω bridge-tied load (BTL) at up to 100 W per
channel with low-harmonic distortion, low-integrated
noise, and low-idle current.
•
•
•
•
•
•
•
•
•
•
•
•
•
Total Power Output (Bridge Tied Load)
– 2 × 100 W at 10% THD+N Into 4 Ω
– 2 × 80 W at 10% THD+N Into 6 Ω
– 2 × 65 W at 10% THD+N Into 8 Ω
Total Power Output (Single Ended)
– 4 × 40 W at 10% THD+N Into 3 Ω
– 4 × 30 W at 10% THD+N Into 4 Ω
Total Power Output (Parallel Mode)
– 1 × 200 W at 10% THD+N Into 2 Ω
– 1 × 160 W at 10% THD+N Into 3 Ω
>110 dB SNR (A-Weighted With TAS5518
Modulator)
90%) With 110-mΩ
Output MOSFETs
Thermally Enhanced Package 44-Pin HTSSOP
(DDV)
Error Reporting, 3.3-V and 5-V Compliant
EMI Compliant When Used With Recommended
System Design
2 Applications
•
•
•
Mini/Micro Audio System
DVD Receiver
Home Theater
The TAS5342LA has a complete protection system
integrated on-chip, safeguarding the device against a
wide range of fault conditions that could damage the
system. These protection features are short-circuit
protection, over-current protection, under voltage
protection, over temperature protection, and a loss of
PWM signal (PWM activity detector).
A power-on-reset (POR) circuit is used to eliminate
power-supply sequencing that is required for most
power-stage designs.
Device Information(1)
PART NUMBER
PACKAGE
BODY SIZE (NOM)
TAS5342LA
HTSSOP (44)
14.00 mm × 6.10 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
BTL Output Power vs Supply Voltage
120
110
TC = 75°C,
THD+N @ 10%
100
90
PO - Output Power - W
1
4W
80
6W
70
60
50
8W
40
30
20
10
0
0 2
4 6 8 10 12 14 16 18 20 22 24 26 28 30 32
PVDD - Supply Voltage - Vrms
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
TAS5342LA
SLAS624A – NOVEMBER 2008 – REVISED NOVEMBER 2016
www.ti.com
Table of Contents
1
2
3
4
5
6
7
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Pin Configuration and Functions .........................
Specifications.........................................................
1
1
1
2
3
4
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
6.9
4
5
5
5
6
7
7
8
8
Absolute Maximum Ratings ......................................
ESD Ratings ............................................................
Recommended Operating Conditions.......................
Thermal Information ..................................................
Electrical Characteristics..........................................
Audio Specifications (BTL).......................................
Audio Specifications (Single-Ended Output)............
Audio Specifications (PBTL) ....................................
Typical Characteristics .............................................
Detailed Description ............................................ 12
7.1 Overview ................................................................. 12
7.2 Functional Block Diagram ....................................... 12
7.3 Feature Description................................................. 13
7.4 Device Functional Modes........................................ 17
8
Application and Implementation ........................ 18
8.1 Application Information............................................ 18
8.2 Typical Applications ................................................ 18
8.3 Systems Examples.................................................. 28
9 Power Supply Recommendations...................... 29
10 Layout................................................................... 30
10.1 Layout Guidelines ................................................. 30
10.2 Layout Example .................................................... 31
11 Device and Documentation Support ................. 32
11.1
11.2
11.3
11.4
11.5
11.6
Documentation Support ........................................
Receiving Notification of Documentation Updates
Community Resources..........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
32
32
32
32
32
32
12 Mechanical, Packaging, and Orderable
Information ........................................................... 32
4 Revision History
Changes from Original (November 2008) to Revision A
Page
•
Added Pin Configuration and Functions, ESD Ratings table, Feature Description section, Device Functional Modes,
Application and Implementation section, Power Supply Recommendations section, Layout section, Device and
Documentation Support section, and Mechanical, Packaging, and Orderable Information section....................................... 1
•
Deleted the Ordering Information table; see the POA at the end of the datasheet. ............................................................. 5
•
Added the Thermal Information table ..................................................................................................................................... 5
2
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SLAS624A – NOVEMBER 2008 – REVISED NOVEMBER 2016
5 Pin Configuration and Functions
DDV Package
44-Pin HTTSOP
Top View
Pin Functions
PIN
I/O
DESCRIPTION
11
P
Analog ground
BST_A
43
P
Bootstrap pin, A-Side
BST_B
34
P
Bootstrap pin, B-Side
BST_C
33
P
Bootstrap pin, C-Side
BST_D
24
P
Bootstrap pin, D-Side
GND
10
P
Ground
GND_A
38
P
Power ground for half-bridge A
GND_B
37
P
Power ground for half-bridge B
GND_C
30
P
Power ground for half-bridge C
GND_D
29
P
Power ground for half-bridge D
GVDD_A
44
P
Gate-drive voltage supply; A-Side
NAME
NO.
AGND
GVDD_B
1
P
Gate-drive voltage supply; B-Side
GVDD_C
22
P
Gate-drive voltage supply; C-Side
GVDD_D
23
P
Gate-drive voltage supply; D-Side
M1
15
I
Mode selection pin (LSB)
M2
14
I
Mode selection pin
M3
13
I
Mode selection pin (MSB)
NC
3, 4, 19, 20,
25, 42
–
No connect. Pins may be grounded.
OC_ADJ
9
O
Analog overcurrent programming pin
OTW
2
O
Overtemperature warning signal, open-drain, active-low
OUT_A
39
O
Output, half-bridge A
OUT_B
36
O
Output, half-bridge B
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Pin Functions (continued)
PIN
I/O
DESCRIPTION
31
O
Output, half-bridge C
28
O
Output, half-bridge D
PVDD_A
40, 41
P
Power supply input for half-bridge A
NAME
NO.
OUT_C
OUT_D
PVDD_B
35
P
Power supply input for half-bridge B
PVDD_C
32
P
Power supply input for half-bridge C
PVDD_D
26, 27
P
Power supply input for half-bridge D
PWM_A
6
I
PWM Input signal for half-bridge A
PWM_B
8
I
PWM Input signal for half-bridge B
PWM_C
16
I
PWM Input signal for half-bridge C
PWM_D
18
I
PWM Input signal for half-bridge D
RESET_AB
7
I
Reset signal for half-bridge A and half-bridge B, active-low
RESET_CD
17
I
Reset signal for half-bridge C and half-bridge D, active-low
SD
5
O
Shutdown signal, open-drain, active-low
VDD
21
P
Input power supply
VREG
12
P
Internal voltage regulator
6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)
(1)
MIN
MAX
UNIT
VDD to AGND
–0.3
13.2
V
GVDD_X to AGND
–0.3
13.2
V
–0.3
46
V
PVDD_X to GND_X
(2)
OUT_X to GND_X
(2)
–0.3
46
V
BST_X to GND_X
(2)
–0.3
59.2
V
–0.3
46
V
VREG to AGND
–0.3
4.2
V
GND_X to GND
–0.3
0.3
V
GND_X to AGND
–0.3
0.3
V
GND to AGND
–0.3
0.3
V
PWM_X, OC_ADJ, M1, M2, M3 to AGND
–0.3
4.2
V
RESET_X, SD, OTW to AGND
–0.3
7
V
9
mA
BST_X to GVDD_X
(2)
Maximum continuous sink current (SD, OTW)
Minimum pulse duration, low
Maximum operating junction temperature range, TJ
Storage temperature, Tstg
(1)
(2)
4
30
ns
0
125
°C
–40
125
°C
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
These voltages represent the DC voltage and peak AC waveform measured at the terminal of the device in all conditions.
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SLAS624A – NOVEMBER 2008 – REVISED NOVEMBER 2016
6.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±2500
Charged-device model (CDM), per JEDEC specification JESD22C101 (2)
±750
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
TYP
MAX
0
32
34
V
GVDD_X
Supply voltage for logic regulators and gate-drive
circuitry
10.8
12
13.2
V
VDD
Digital regulator supply voltage
10.8
12
13.2
V
3
4
2.25
3
PVDD_X
Half-bridge supply voltage
RL (BTL)
RL (SE)
Resistive load impedance (no Cycle-by-Cycle current
control), recommended demodulation filter
RL (PBTL)
LOutput (BTL)
LOutput (SE)
Minimum output inductance under
short-circuit condition
Output-filter inductance
LOutput (PBTL)
1.5
2
5
10
5
10
5
10
192
384
UNIT
Ω
μH
fS
PWM frame rate
tLOW
Minimum low-state pulse duration per PWM Frame,
noise shaper enabled
432
kHz
CPVDD
PVDD close decoupling capacitors
0.1
μF
CBST
Bootstrap capacitor, selected value supports PWM
frame rates from 192 kHz to 432 kHz
33
nF
ROC
Over-current programming resistor
REXT-PULLUP
External pullup resistor to 3.3 V to 5.0 V for SD or OTW
TJ
Junction temperature
30
Resistor tolerance = 5%
nS
22
22
3.3
4.7
0
47
kΩ
kΩ
125
°C
6.4 Thermal Information
TAS5342LA
THERMAL METRIC
(1)
DDV (HTSSOP)
UNIT
44 PINS
RθJA
Junction-to-ambient thermal resistance
41.1
°C/W
RθJC(top)
RθJB
Junction-to-case (top) thermal resistance
0.7
°C/W
Junction-to-board thermal resistance
18.0
°C/W
ψJT
Junction-to-top characterization parameter
0.7
°C/W
ψJB
Junction-to-board characterization parameter
17.9
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
(1)
For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application
report.
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6.5
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Electrical Characteristics
PVDD_x = 32 V, GVDD_X = 12 V, VDD = 12 V, TC (Case temperature) = 25°C, fS = 384 kHz, unless otherwise specified.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
3
3.3
3.6
Operating, 50% duty cycle
7.1
17
Idle, reset mode
5.6
11
50% duty cycle
5.9
12
1
1.8
UNIT
INTERNAL VOLTAGE REGULATOR AND CURRENT CONSUMPTION
VREG
Voltage regulator, only used as a reference
node
IVDD
VDD supply current
IGVDD_X
Gate supply current per half-bridge
IPVDD_X
Half-bridge idle current
VDD = 12 V
Reset mode
V
mA
mA
50% duty cycle, without output filter or load
10.5
20
mA
Reset mode, no switching
594
713
μA
110
125
mΩ
110
125
mΩ
OUTPUT STAGE MOSFETs
RDSon,LS
Drain-to-source resistance, Low Side
RDSon,HS
Drain-to-source resistance, High Side
TJ = 25°C, excludes metallization resistance
I/O PROTECTION
Vuvp,G
Undervoltage protection limit, GVDD_X
9.5
V
Undervoltage protection limit, GVDD_X
250
mV
BSTuvpF
Puts device into RESET when BST voltage falls
below limit
6.11
V
BSTuvpR
Brings device out of RESET when BST voltage
rises above limit
7.25
V
Vuvp,hyst
(1)
OTW (1)
Overtemperature warning
OTWHYST
OTE
(1)
(1)
115
Temperature drop needed below OTW temp.
for OTW to be inactive after the OTW event
Overtemperature error threshold
145
(1)
OTE - OTW differential, temperature delta
between OTW and OTE
OLPC
Overload protection counter
fS = 384 kHz
IOC
Overcurrent limit protection
Resistor—programmable, high-end,
ROC = 22 kΩ with 1 ms pulse, TC= 75°C
IOCT
Overcurrent response time
tACTIVITY
Time for PWM activity detector to activate when
no PWM is present
Lack of transistion of any PWM input
Output pulldown current of each half-bridge
Connected when RESET is active to provide
bootstrap capacitor charge. Not used in SE
mode.
IPD
135
25
OTE-OTWdifferential
DETECTOR
125
7.9
155
°C
°C
165
°C
30
°C
1.25
ms
8.4
A
150
ns
13.2
μS
3
mA
STATIC DIGITAL SPECIFICATIONS
VIH
High-level input voltage
VIL
Low-level input voltage
ILeakage
Input leakage current
PWM_A, PWM_B, PWM_C, PWM_D, M1, M2,
M3, RESET_AB, RESET_CD
2
V
0.8
V
100
μA
kΩ
OTW/SHUTDOWN (SD)
RINT_PU
Internal pullup resistance, OTW to VREG, SD to
VREG
VOH
High-level output voltage
VOL
Low-level output voltage
IO = 4 mA
0.2
FANOUT
Device fanout OTW, SD
No external pullup
30
(1)
6
Internal pullup resistor
External pullup of 4.7 kΩ to 5 V
20
26
32
3
3.3
3.6
4.5
5
0.4
V
V
Devices
Specified by design
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6.6
SLAS624A – NOVEMBER 2008 – REVISED NOVEMBER 2016
Audio Specifications (BTL)
Audio performance is recorded as a chipset consisting of a TAS5518 pwm processor (modulation index limited to 97.7%) and
a TAS5342LA power stage. PCB and system configuration are in accordance with recommended guidelines. Audio frequency
= 1 kHz, PVDD_x = 32 V, GVDD_x = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 22 kΩ, TC = 75°C, Output Filter: LDEM = 10 μH,
CDEM = 470 nF, unless otherwise noted.
PARAMETER
POMAX
TEST CONDITIONS
Maximum Power Output
PO
Unclipped Power Output
MIN
TYP
RL = 4 Ω, 10% THD+N, clipped input signal
100
RL = 6 Ω, 10% THD+N, clipped input signal
80
RL = 8 Ω, 10% THD+N, clipped input signal
65
RL = 4 Ω, 0 dBFS, unclipped input signal
80
RL = 6 Ω, 0 dBFS, unclipped input signal
64
RL = 8 Ω, 0 dBFS, unclipped input signal
50
0 dBFS; AES17 filter
MAX
UNIT
W
W
0.4%
THD+N
Total harmonic distortion + noise
Vn
Output integrated noise
A-weighted, AES17 filter, Auto mute disabled
55
μV
SNR
Signal-to-noise ratio
(1)
A-weighted, AES17 filter, Auto mute disabled
110
dB
DNR
Dynamic range
A-weighted, input level = –60 dBFS, AES17
filter
110
dB
DC Offset
Output offset voltage
±15
mV
3
W
Power dissipation due to idle losses
(IPVDD_X)
Pidle
(1)
(2)
1 W; AES17 filter
0.09%
PO = 0 W, all halfbridges switching
(2)
SNR is calculated relative to 0-dBFS input level.
Actual system idle losses are affected by core losses of output inductors.
6.7
Audio Specifications (Single-Ended Output)
Audio performance is recorded as a chipset consisting of a TAS5086 pwm processor (modulation index limited to 97.7%) and
a TAS5342LA power stage. PCB and system configuration are in accordance with recommended guidelines. Audio frequency
= 1 kHz, PVDD_x = 32 V, GVDD_x = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 22 kΩ, TC = 75°C, Output Filter: LDEM = 20 μH,
CDEM = 1 μF, unless otherwise noted.
PARAMETER
POMAX
TEST CONDITIONS
Maximum Power Output
MIN
TYP
RL = 3 Ω, 10% THD+N, clipped input signal
40
RL = 4 Ω, 10% THD+N, clipped input signal
30
RL = 3 Ω, 0 dBFS, unclipped input signal
30
RL = 4 Ω, 0 dBFS, unclipped input signal
25
MAX
UNIT
W
PO
Unclipped Power Output
THD+N
Total harmonic distortion + noise
Vn
Output integrated noise
A-weighted, AES17 filter, Auto mute
disabled
35
μV
SNR
Signal-to-noise ratio (1)
A-weighted, AES17 filter, Auto mute
disabled
109
dB
DNR
Dynamic range
A-weighted, input level = –60 dBFS AES17
filter
109
dB
Pidle
Power dissipation due to idle losses
(IPVDD_X)
PO = 0 W, all half bridges switching (2)
3
W
(1)
(2)
0 dBFS; AES17 filter
0.4%
1 W; AES17 filter
0.09%
SNR is calculated relative to 0-dBFS input level.
Actual system idle losses are affected by core losses of output inductors.
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6.8
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Audio Specifications (PBTL)
Audio performance is recorded as a chipset consisting of a TAS5518 pwm processor (modulation index limited to 97.7%) and
a TAS5342LA power stage. PCB and system configuration are in accordance with recommended guidelines. Audio frequency
= 1 kHz, PVDD_x = 32 V, GVDD_x = 12 V, RL = 3 Ω, fS = 384 kHz, ROC = 22 kΩ, TC = 75°C, Output Filter: LDEM = 10 μH,
CDEM = 1 uF, unless otherwise noted.
PARAMETER
POMAX
TEST CONDITIONS
Maximum Power Output
PO
Unclipped Power Output
THD+N
Total harmonic distortion + noise
Vn
MIN
TYP
RL = 2 Ω, 10% THD+N, clipped input
signal
200
RL = 3 Ω, 10% THD+N, clipped input
signal
160
RL = 2 Ω, 0 dBFS, unclipped input signal
150
RL = 3 Ω, 0 dBFS, unclipped input signal
120
MAX
UNIT
W
0 dBFS; AES17 filter
W
0.4%
1 W; AES17 filter
0.09%
Output integrated noise
A-weighted, AES17 filter, Auto mute
disabled
45
μV
SNR
Signal-to-noise ratio (1)
A-weighted, AES17 filter, Auto mute
disabled
110
dB
DNR
Dynamic range
A-weighted, input level = –60 dBFS
AES17 filter
110
dB
DC Offset
Outuput offset voltage
±15
mV
Pidle
Power dissipation due to idle losses (IPVDD_X)
3
W
(1)
(2)
PO = 0 W, all half bridges switching (2)
SNR is calculated relative to 0-dBFS input level.
Actual system idle losses are affected by core losses of output inductors.
6.9 Typical Characteristics
6.9.1 BTL Configuration
120
5
TC = 75°C,
THD+N @ 10%
110
8W
90
6W
1
0.5
4W
0.2
0.1
0.05
4W
80
6W
70
60
50
8W
40
30
0.02
20
0.01
10
0.005
20m
100m 200m
1 2
10 20
PO - Output Power - W
100 200
0
0 2
4 6 8 10 12 14 16 18 20 22 24 26 28 30 32
PVDD - Supply Voltage - Vrms
Figure 1. Total Harmonic Distortion + Noise vs Output
Power
8
TC = 75°C,
THD+N @ 10%
100
2
PO - Output Power - W
THD+N - Total Harmonic Distortion - %
10
Figure 2. Output Power vs Supply Voltage
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BTL Configuration (continued)
100
100
8W
TC = 75°C
90
90
80
4W
70
60
6W
50
8W
40
4W
60
50
40
30
30
20
20
10
10
0
0
0 2 4
6W
70
Efficiency - %
PO - Output Power - W
80
6 8 10 12 14 16 18 20 22 24 26 28 30 32
PVDD - Supply Voltage - Vrms
Figure 3. Unclipped Output Power vs Supply Voltage
TC = 25°C,
THD+N @ 10%
0
20
40 60 80 100 120 140 160 180 200 220
2 Channels Output Power - W
Figure 4. System Efficiency vs Output Power
130
40
TC = 25°C,
THD+N @ 10%
36
THD+N @ 10%
120
110
32
PO - Output Power - W
28
Power Loss - W
4W
100
4W
24
20
16
6W
12
90
80
6W
70
8W
60
50
40
30
8
20
8W
4
10
0
0
20
0
10
40 60 80 100 120 140 160 180 200 220
2 Channels Output Power - W
Figure 5. System Power Loss vs Output Power
+0
-10
-20
40 50 60 70 80 90 100 110 120
TC - Case Temperature - °C
Figure 6. System Output Power vs Case Temperature
TC = 75°C,
VREF = 18.69 V,
Sample Rate = 48 kHz,
FFT Size = 16384
-30
Noise Amplitude - V
20 30
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
-140
-150
-160
0
2
4
6
8 10 12 14 16 18
f - Frequency - kHz
20
22
Figure 7. Noise Amplitude vs Frequency
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6.9.2 SE Configuration
10
48
TC = 75°C,
THD+N @ 10%
44
36
1
0.5
0.2
0.1
3W
0.05
0.02
4W
32
28
3W
24
20
4W
16
12
8
0.01
0.005
20m
TC = 75°C,
THD+N @ 10%
40
2
PO - Output Power - W
THD+N - Total Harmonic Distortion - %
5
4
0
100m 200m
1
2
10
PO - Output Power - W
20
0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32
PVDD - Supply Voltage - Vrms
50
Figure 9. Output Power vs Supply Voltage
Figure 8. Total Harmonic Distortion + Noise vs Output
Power
48
THD+N @ 10%
44
3W
PO - Output Power - W
40
36
4W
32
28
24
20
16
12
8
4
0
10
20
30
40 50 60 70 80 90 100 110 120
TC - Case Temperature - °C
Figure 10. Output Power vs Case Temperature
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6.9.3 PBTL Configuration
5
240
TC = 75°C,
THD+N @ 10%
220
8W
TC = 75°C,
THD+N @ 10%
200
2
4W
PO - Output Power - W
THD+N - Total Harmonic Distortion - %
10
1
3W
0.5
0.2
2W
0.1
0.05
180
2W
160
3W
140
120
4W
100
8W
80
60
0.02
40
0.01
20
0.005
20m 100m200m
1 2
10 20
PO - Output Power - W
100 200 400
0
0
2
4
6 8 10 12 14 16 18 20 22 24 26 28 30 32
PVDD - Supply Voltage - Vrms
Figure 12. Output Power vs Supply Voltage
Figure 11. Total Harmonic Distortion + Noise vs Output
Power
260
240
2W
THD+N @ 10%
220
PO - Output Power - W
200
180
3W
160
140
4W
120
100
80
8W
60
40
20
0
10 20
30 40 50 60 70 80 90 100 110 120
TC - Case Temperature - °C
Figure 13. System Output Power vs Case Temperature
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7 Detailed Description
7.1 Overview
TAS5342LA is a PWM input, Class-D audio amplifier. The output of the TAS5342LA can be configured for singleended, bridge-tied load (BTL) or parallel BTL (PBTL) output. Independent supply rails provide improved audio
performance, one for audio power output (PVDD) and the other for gate drive and analog control (GVDD and
VDD).
The TAS5342LA contains a protection system that safeguards the device against short circuits, overload, overtemperature, and under-voltage conditions. An error reporting system provides feedback under fault conditions.
Figure 14 shows typical connections for BTL outputs. A detailed schematic can be viewed in
(TAS5342LDDV6EVM User Guide).
7.2 Functional Block Diagram
VDD
4
Undervoltage
Protection
OTW
Internal Pullup
Resistors to VREG
SD
M1
Protection
and
I/O Logic
M2
M3
4
VREG
VREG
Power
On
Reset
AGND
Temp.
Sense
GND
RESET_AB
Overload
Protection
RESET_CD
Isense
OC_ADJ
GVDD_D
BST_D
PVDD_D
PWM_D
PWM
Rcv.
Ctrl.
Timing
Gate
Drive
OUT_D
BTL/PBTL−Configuration
Pulldown Resistor
GND_D
GVDD_C
BST_C
PVDD_C
PWM_C
PWM
Rcv.
Ctrl.
Timing
Gate
Drive
OUT_C
BTL/PBTL−Configuration
Pulldown Resistor
GND_C
GVDD_B
BST_B
PVDD_B
PWM_B
PWM
Rcv.
Ctrl.
Timing
Gate
Drive
OUT_B
BTL/PBTL−Configuration
Pulldown Resistor
GND_B
GVDD_A
BST_A
PVDD_A
PWM_A
PWM
Rcv.
Ctrl.
Timing
Gate
Drive
OUT_A
BTL/PBTL−Configuration
Pulldown Resistor
GND_A
B0034-03
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7.3 Feature Description
7.3.1 Mid Z Sequence Compatibility
The TAS5342LA is compatable with the Mid Z sequence of the TAS5086 Modulator. The Mid Z Sequence is a
series of pulses that is generated by the modulator. This sequence causes the power stage to slowly enable its
outputs as it begins to switch.
By slowly starting the PWM switching, the impulse response created by the onset of switching is reduced. This
impulse response is the acoustic artifact that is heard in the output transducers (loudspeakers) and is commonly
termed "click" or "pop".
The low acoustic artifact noise of the TAS5342LA will be further decreased when used in conjunction with the
TAS5086 modulator with the Mid Z Sequence enabled.
The Mid Z sequence is primarily used for the single-ended output configuration. It facilitates a "softer" PWM
output start after the split cap output configuration is charged.
7.3.2 Device Protection System
The TAS5342LA contains advanced protection circuitry carefully designed to facilitate system integration and
ease of use, as well as to safeguard the device from permanent failure due to a wide range of fault conditions
such as short circuits, overload, overtemperature, and undervoltage. The TAS5342LA responds to a fault by
immediately setting the power stage in a high-impedance (Hi-Z) state and asserting the SD pin low. In situations
other than overload and over-temperature error (OTE), the device automatically recovers when the fault condition
has been removed, that is, the supply voltage has increased.
The device will function on errors, as shown in Table 1.
Table 1. Device Protection
BTL MODE
Local Error In
A
B
C
D
PBTL MODE
Turns Off
Local Error In
A+B
C+D
Turns Off
SE MODE
Local Error In
A
A
B
B
C
A+B+C+D
D
C
D
Turns Off
A+B
C+D
Bootstrap UVP does not shutdown according to the table, it shutsdown the respective halfbridge.
7.3.3 Use Of TAS5342LA In High-Modulation-Index Capable Systems
This device requires at least 30 ns of low time on the output per 384-kHz PWM frame rate in order to keep the
bootstrap capacitors charged. As an example, if the modulation index is set to 99.2% in the TAS5508, this setting
allows PWM pulse durations down to 10 ns. This signal, which does not meet the 30-ns requirement, is sent to
the PWM_X pin and this low-state pulse time does not allow the bootstrap capacitor to stay charged. The
TAS5342LA device requires limiting the TAS5508 modulation index to 97.7% to keep the bootstrap capacitor
charged under all signals and loads.
The TAS5342LA contains a bootstrap capacitor under voltage protection circuit (BST_UVP) that monitors the
voltage on the bootstrap capacitors. When the voltage on the bootstrap capacitors is less than required for
proper control of the High-Side MOSFETs, the device will initiate bootstrap capacitor recharge sequences until
the bootstrap capacitors are properly charged for robust operation. This function may be activated with PWM
pulses less than 30 nS.
Therefore, TI strongly recommends using a TI PWM processor, such as TAS5518, TAS5086 or TAS5508, with
the modulation index set at 97.7% to interface with TAS5342LA.
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Feature Description (continued)
7.3.4 Overcurrent (OC) Protection With Current Limiting and Overload Detection
The device has independent, fast-reacting current detectors with programmable trip threshold (OC threshold) on
all high-side and low-side power-stage FETs. See the following table for OC-adjust resistor values. The detector
outputs are closely monitored by two protection systems. The first protection system controls the power stage in
order to prevent the output current from further increasing, that is, it performs a current-limiting function rather
than prematurely shutting down during combinations of high-level music transients and extreme speaker load
impedance drops. If the high-current situation persists, that is, the power stage is being overloaded, a second
protection system triggers a latching shutdown, resulting in the power stage being set in the high-impedance (HiZ) state. Current limiting and overload protection are independent for half-bridges A and B and, respectively, C
and D. That is, if the bridge-tied load between half-bridges A and B causes an overload fault, only half-bridges A
and B are shut down.
• For the lowest-cost bill of materials in terms of component selection, the OC threshold measure should be
limited, considering the power output requirement and minimum load impedance. Higher-impedance loads
require a lower OC threshold.
• The demodulation-filter inductor must retain at least 5 μH of inductance at twice the OC threshold setting.
Unfortunately, most inductors have decreasing inductance with increasing temperature and increasing current
(saturation). To some degree, an increase in temperature naturally occurs when operating at high output
currents, due to core losses and the dc resistance of the inductor copper winding. A thorough analysis of inductor
saturation and thermal properties is strongly recommended.
Setting the OC threshold too low might cause issues such as lack of enough output power and/or unexpected
shutdowns due to too-sensitive overload detection.
TI recommends following the external component selection and PCB layout as given in the Application and
Implementation section.
For added flexibility, the OC threshold is programmable within a limited range using a single external resistor
connected between the OC_ADJ pin and AGND. (See the Electrical Characteristics section of this data sheet for
information on the correlation between programming-resistor value and the OC threshold.) It should be noted that
a properly functioning overcurrent detector assumes the presence of a properly designed demodulation filter at
the power-stage output. Short-circuit protection is not provided directly at the output pins of the power stage but
only on the speaker terminals (after the demodulation filter). It is required to follow certain guidelines when
selecting the OC threshold and an appropriate demodulation inductor:
Table 2. Overcurrent Resistor Selection
OC-Adjust Resistor Values (kΩ)
Max. Current Before OC Occurs (A), TC=75°C
22
8.4 A
33
6.8 A
47
5.3 A
The reported maximum peak current in the table above is measured with continuous current in 1 Ω, one channel
active and the other one muted.
7.3.5 Pin-To-Pin Short Circuit Protection System (PPSC)
The PPSC detection system protects the device from permanent damage in the case that a power output pin
(OUT_X) is shorted to GND_X or PVDD_X. For comparison the OC protection system detects an over current
after the demodulation filter where PPSC detects shorts directly at the pin before the filter. PPSC detection is
performed at startup, that is, when VDD is supplied, consequently a short to either GND_X or PVDD_X after
system startup will not activate the PPSC detection system. When PPSC detection is activated by a short on the
output, all half bridges are kept in a Hi-Z state until the short is removed, the device then continues the startup
sequence and starts switching. The detection is controlled globally by a two step sequence. The first step
ensures that there are no shorts from OUT_X to GND_X, the second step tests that there are no shorts from
OUT_X to PVDD_X. The total duration of this process is roughly proportional to the capacitance of the output LC
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Feature Description (continued)
filter. The typical duration is < 15 ms/μF. While the PPSC detection is in progress, SD is kept low, and the device
will not react to changes applied to the RESET pins. If no shorts are present the PPSC detection passes, and SD
is released. A device reset will not start a new PPSC detection. PPSC detection is enabled in BTL and PBTL
output configurations, the detection is not performed in SE mode. To make sure not to trip the PPSC detection
system it is recommended not to insert resistive load to GND_X or PVDD_X.
7.3.6 Overtemperature Protection
The TAS5342LA has a two-level temperature-protection system that asserts an active-low warning signal (OTW)
when the device junction temperature exceeds 125°C (nominal) and, if the device junction temperature exceeds
155°C (nominal), the device is put into thermal shutdown, resulting in all half-bridge outputs being set in the highimpedance (Hi-Z) state and SD being asserted low. OTE is latched in this case. To clear the OTE latch, either
RESET_AB or RESET_CD must be asserted. Thereafter, the device resumes normal operation.
7.3.7 Undervoltage Protection (UVP) and Power-On Reset (POR)
The UVP and POR circuits of the TAS5342LA fully protect the device in any power-up or down and brownout
situation. While powering up, the POR circuit resets the overload circuit (OLP) and ensures that all circuits are
fully operational when the GVDD_X and VDD supply voltages reach stated in the Electrical Characteristics table.
Although GVDD_X and VDD are independently monitored, a supply voltage drop below the UVP threshold on
any VDD or GVDD_X pin results in all half-bridge outputs immediately being set in the high-impedance (Hi-Z)
state and SD being asserted low. The device automatically resumes operation when all supply voltages have
increased above the UVP threshold.
7.3.8 Error Reporting
The SD and OTW pins are both active-low, open-drain outputs. Their function is for protection-mode signaling to
a PWM controller or other system-control device.
Any fault resulting in device shutdown is signaled by the SD pin going low. Likewise, OTW goes low when the
device junction temperature exceeds 125°C (see Table 3).
Table 3. Error Reporting
SD
OTW
0
0
Overtemperature (OTE) or overload (OLP) or undervoltage (UVP)
DESCRIPTION
0
1
Overload (OLP) or undervoltage (UVP)
1
0
Junction temperature higher than 125°C (overtemperature warning)
1
1
Junction temperature lower than 125°C and no OLP or UVP faults (normal operation)
Note that asserting either RESET_AB or RESET_CD low forces the SD signal high, independent of faults being
present. TI recommends monitoring the OTW signal using the system microcontroller and responding to an
overtemperature warning signal by, for example, turning down the volume to prevent further heating of the device
resulting in device shutdown (OTE).
To reduce external component count, an internal pullup resistor to 3.3 V is provided on both SD and OTW
outputs. Level compliance for 5-V logic can be obtained by adding external pullup resistors to 5 V (see the
Electrical Characteristics section of this data sheet for further specifications).
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Feature Description (continued)
7.3.9 Device Reset
Two reset pins are provided for independent control of half-bridges A/B and C/D. When RESET_AB is asserted
low, all four power-stage FETs in half-bridges A and B are forced into a high-impedance (Hi-Z) state. Likewise,
asserting RESET_CD low forces all four power-stage FETs in half-bridges C and D into a high-impedance state.
Thus, both reset pins are well suited for hard-muting the power stage if needed.
In BTL modes, to accommodate bootstrap charging prior to switching start, asserting the reset inputs low enables
weak pulldown of the half-bridge outputs. In the SE mode, the weak pulldowns are not enabled, and it is
therefore recommended to ensure bootstrap capacitor charging by providing a low pulse on the PWM inputs
when reset is asserted high.
Asserting either reset input low removes any fault information to be signalled on the SD output, that is, SD is
forced high.
A rising-edge transition on either reset input allows the device to resume operation after an overload fault. To
ensure thermal reliability, the rising edge of reset must occur no sooner than 4 ms after the falling edge of SD.
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7.4 Device Functional Modes
Protection modes are selected by shorting M1, M2, and M3 to VREG or GND.
Table 4. Protection Mode Selection Pins
MODE PINS
(1)
(2)
(3)
MODE NAME
PWM INPUT
(1)
DESCRIPTION
M3
M2
M1
0
0
0
BTL mode 1
2N
All protection systems enabled
0
0
1
BTL mode 2
2N
Latching shutdown on, PWM activity detector and
OLP disabled
0
1
0
BTL mode 3
1N
1N / 2N
All protection systems enabled
(2)
0
1
1
PBTL mode
1
0
0
SE mode 1
1N
All protection systems enabled
All protection systems enabled
1
0
1
SE mode 2
1N
Latching shutdown on, PWM activity detector and
OLP disabled (3)
1
1
0
1
1
1
(3)
Reserved
The 1N and 2N naming convention is used to indicate the number of PWM lines to the power stage per channel in a specific mode.
PWM_D is used to select between the 1N and 2N interface in PBTL mode (Low = 1N; High = 2N). PWM_D is internally pulled low in
PBTL mode. PWM_A is used as the PWM input in 1N mode and PWM_A and PWM_B are used as inputs for the 2N mode
PPSC detection system disabled.
7.4.1 System Power-Up/Power-Down Sequence
7.4.1.1 Powering Up
The TAS5342LA does not require a power-up sequence. The outputs of the H-bridges remain in a highimpedance state until the gate-drive supply voltage (GVDD_X) and VDD voltage are above the undervoltage
protection (UVP) voltage threshold (see the Electrical Characteristics section of this data sheet). Although not
specifically required, it is recommended to hold RESET_AB and RESET_CD in a low state while powering up the
device. This allows an internal circuit to charge the external bootstrap capacitors by enabling a weak pulldown of
the half-bridge output.
When the TAS5342LA is being used with TI PWM modulators such as the TAS5518, no special attention to the
state of RESET_AB and RESET_CD is required, provided that the chipset is configured as recommended.
7.4.1.2 Powering Down
The TAS5342LA does not require a power-down sequence. The device remains fully operational as long as the
gate-drive supply (GVDD_X) voltage and VDD voltage are above the undervoltage protection (UVP) voltage
threshold (see the Electrical Characteristics section of this data sheet). Although not specifically required, it is a
good practice to hold RESET_AB and RESET_CD low during power down, thus preventing audible artifacts
including pops or clicks.
When the TAS5342LA is being used with TI PWM modulators such as the TAS5518, no special attention to the
state of RESET_AB and RESET_CD is required, provided that the chipset is configured as recommended.
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8 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
8.1 Application Information
TAS5342LA can be configured either in stereo BTL mode, 4 channel SE mode, or mono PBTL mode, depending
on output power conditions and system design.
8.2 Typical Applications
8.2.1 Typical Differential (2N) BTL Application
The following schematics and PCB layouts illustrate "best practices" in the use of the TAS5342LA.
GVDD (+12 V)
10 W
PVDD
10 W
100 nF
3.3 W
470 µF
50 V
100 nF
10 nF
50 V
TAS5342LDDV
GND
Microcontroller
1
2
3
4
I2C
GND
PWM1_P
VALID
PWM1_M
27 k
GND
100 nF
PWM2_P
PWM2_M
TAS5508/18
0W
GND
100 nF
5
GVDD_B
GVDD_A
BST_A
OTW
NC
NC
NC
PVDD_A
SD
PVDD_A
6
PWM_A
7
RESET_AB
8
PWM_B
9
OC_ADJ
10
GND
11
AGND
12
VREG
13
M3
14
M2
15
M1
16
PWM_C
17
RESET_CD
18
PWM_D
19
NC
20
NC
21
VDD
22
GVDD_C
OUT_A
GND_A
GND_B
OUT_B
PVDD_B
BST_B
BST_C
44
GND
10 µH
43
42 33 nF 25 V
41
GND
GND
40
39
100 nF
50 V
38
37
36
100 nF
50 V
GND
100 nF
50 V
100 nF
50 V
GND
1 nF
50 V
GND
33 nF 25 V
10 nF
50 V
3.3 W
10 µH
33
32 33 nF 25V
PVDD_C
31
OUT_C
30
GND
GND_C
29
GND_D
28
OUT_D
27
PVDD_D
26
PVDD_D
25
GND
NC
24
BST_D
23
GVDD_D
33 nF 25 V
10 µH
3.3 W
1 nF
50 V
100 nF
50 V
10 nF
50 V
100 nF
50 V
470 nF
100 nF
50 V
GND
100 nF
50 V
1 nF
50 V
GND
10 nF
50 V
3.3 W
10 µH
PVDD
3.3 W
GND
470 µF
50 V
100 nF
100 nF
10 W
10 nF
50 V
10 W
GND
GND
VDD (+12 V)
10 nF
50 V
470 nF
35
34
3.3 W
1 nF
50 V
GND
GVDD (+12 V)
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Figure 14. Typical Differential (2N) BTL Application With AD Modulation Filters
8.2.1.1 Design Requirements
For this design example, use the parameters listed in Table 5 as the input parameters.
Table 5. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
Low Power (pull-up) supply
3.3 V
Mid Power Supply (GVDD, VDD)
12 V
High Power Supply (PVDD)
12 V – 36 V
INPUT A = 0 – 3.3 V PWM
INPUT_B = 0 – 3.3 V PWM
PWM Inputs
INPUT_C = 0 – 3.3 V PWM
INPUT_D = 0 – 3.3 V PWM
Speaker Impedance
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8.2.1.2 Detailed Design Procedure
8.2.1.2.1 PCB Material Recommendation
FR-4 Glass Epoxy material with 2 oz. (70 μm) is recommended for use with the TAS5342LA. The use of this
material can provide for higher power output, improved thermal performance, and better EMI margin (due to
lower PCB trace inductance.
8.2.1.2.2 PVDD Capacitor Recommendation
The large capacitors used in conjunction with each full-birdge, are referred to as the PVDD Capacitors. These
capacitors should be selected for proper voltage margin and adequate capacitance to support the power
requirements. In practice, with a well designed system power supply, 1000 μF, 50-V supports more applications.
The PVDD capacitors should be low ESR type because they are used in a circuit associated with high-speed
switching.
8.2.1.2.3 Decoupling Capacitor Recommendations
In order to design an amplifier that has robust performance, passes regulatory requirements, and exhibits good
audio performance, good quality decoupling capacitors should be used. In practice, X7R should be used in this
application.
The voltage of the decoupling capacitors should be selected in accordance with good design practices.
Temperature, ripple current, and voltage overshoot must be considered. This fact is particularly true in the
selection of the 0.1 μF that is placed on the power supply to each half-bridge. It must withstand the voltage
overshoot of the PWM switching, the heat generated by the amplifier during high power output, and the ripple
current created by high power output. A minimum voltage rating of 50-V is required for use with a 32 V power
supply.
8.2.1.3 Application Curves
Relevant performance plots for TAS5342LA are shown in the BTL Configuration.
Table 6. Performance Plots, Typical BTL Configurations
PLOT TITLE
FIGURE NUMBER
Total Harmonic Distortion + Noise vs. Output power
Figure 1
Output Power vs. Supply Voltage
Figure 2
Unclipped Output Power vs. Supply Voltage
Figure 3
System Efficiency vs. Output Power
Figure 4
System Power Loss vs. Output Power
Figure 5
System Output Power vs. Case Temperature
Figure 6
Noise Amplitude vs. Frequency
Figure 7
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8.2.2 Typical Non-Differential (1N) BTL
Design Requirements Typical Non-Differential BTL.
GVDD (+12 V)
10 W
PVDD
10 W
100 nF
3.3 W
470 µF
50 V
100 nF
10 nF
50 V
TAS5342LDDV
GND
Microcontroller
I2C
GND
PWM1_P
VALID
27 k
GND
100 nF
PWM2_P
TAS5508/18
0W
GND
100 nF
1
GVDD_A
GVDD_B
2
OTW
3
NC
4
NC
5
SD
6
PWM_A
7
RESET_AB
8
PWM_B
9
OC_ADJ
10
GND
11
AGND
12
VREG
13
M3
14
M2
15
M1
16
PWM_C
17
RESET_CD
18
PWM_D
19
NC
20
NC
21
VDD
22
GVDD_C
44
GND
43
42 33 nF 25 V
NC
GND
41
PVDD_A
40
PVDD_A
39
OUT_A
38
GND_A
37
GND
GND_B
36
OUT_B
35
PVDD_B
34 33 nF 25 V
BST_B
33
BST_C
3233 nF 25V
PVDD_C
31
OUT_C
30
GND
GND_C
29
GND_D
28
OUT_D
27
PVDD_D
26
PVDD_D
25
GND
NC
24
BST_D
23
GVDD_D
33 nF 25 V
10 µH
GND
BST_A
100 nF
50 V
100 nF
50 V
10 nF
50 V
470 nF
100 nF
50 V
100 nF
50 V
GND
1 nF
50 V
GND
10 nF
50 V
3.3 W
10 µH
10 µH
3.3 W
1 nF
50 V
100 nF
50 V
10 nF
50 V
100 nF
50 V
470 nF
100 nF
50 V
100 nF
50 V
GND
1 nF
50 V
GND
10 nF
50 V
3.3 W
10 µH
PVDD
3.3 W
GND
470 µF
50 V
100 nF
100 nF
10 W
VDD (+12 V)
3.3 W
1 nF
50 V
10 nF
50 V
10 W
GND
GND
GND
GVDD (+12 V)
Copyright © 2016, Texas Instruments Incorporated
Figure 15. Typical Non-Differential (1N) BTL Application With AD Modulation Filters
8.2.2.1 Design Requirements
For this design example, use the parameters listed in Table 7 as the input parameters.
Table 7. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
Low Power (pull-up) supply
3.3 V
Mid Power Supply (GVDD, VDD)
12 V
High Power Supply (PVDD)
12 V – 36 V
INPUT A = 0 – 3.3 V PWM
INPUT_B = N/C
PWM Inputs
INPUT_C = 0 – 3.3 V PWM
INPUT_D = N/C
Speaker Impedance
20
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8.2.2.2 Application Curves
Relevant performance plots for TAS5342LA are shown in the BTL Configuration.
Table 8. Performance Plots, Typical BTL Configurations
PLOT TITLE
FIGURE NUMBER
Total Harmonic Distortion + Noise vs. Output power
Figure 1
Output Power vs. Supply Voltage
Figure 2
Unclipped Output Power vs. Supply Voltage
Figure 3
System Efficiency vs. Output Power
Figure 4
System Power Loss vs. Output Power
Figure 5
System Output Power vs. Case Temperature
Figure 6
Noise Amplitude vs. Frequency
Figure 7
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8.2.3 Typical SE Application
Design Requirements Typical SE
2
2
GVDD (+12V)
PVDD
2
6
VALID
7
8
PWM2_P
2
9
10
GND
1
11
2
12
100nF
13
14
15
16
PWM3_P
17
18
PWM4_P
19
TAS5508/18
20
GND
0R
2
21
1
1
22
100nF
PVDD_A
SD
PVDD_A
PWM_A
OUT_A
RESET_AB
GND_A
PWM_B
GND_B
OC_ADJ
OUT_B
GND
PVDD_B
AGND
BST_B
VREG
BST_C
M3
PVDD_C
M2
OUT_C
M1
GND_C
PWM_C
GND_D
RESET_CD
OUT_D
PWM_D
PVDD_D
NC
PVDD_D
NC
NC
VDD
BST_D
GVDD_C
GVDD_D
2
33nF
42
1
GND
2
A
2
B
2
C
2
D
25V
GND
41
1
NC
20uH
1
40
100nF
50V
39
2
PWM1_P
NC
43
38
GND
37
1
5
NC
GND
44
100nF
50V
36
2
4
GND
BST_A
35
34
33nF
1
33
1
25V
2
1
2
1
20uH
20uH
33nF
32
25V
1
I2C
GVDD_A
OTW
31
30
100nF
50V
GND
2
3
GVDD_B
29
1
2
28
100nF
50V
27
2
1
Microcontroller
2
TAS5342ADDV
GND
22k
10nF
50V
2
2
100nF
2
1
470uF
50V
100nF
1
3.3R
1
1
1
1
2.2R
1
1
2.2R
26
25
GND
24
1
20uH
2
33nF
23
1
25V
1
1
2
PVDD
3.3R
1
2
10nF
50V
2
2
100nF
2
2.2R
1
2
2.2R
1
GND
470uF
50V
1
2
100nF
2
1
GND
GND
GND
VDD (+12V)
GVDD (+12V)
10nF
50V
1
2
1
2
1
1
10nF
50V
GND
GND
2
3.3R
2
3.3R
1
2
2
1
1 2
1
2
2
1
3.3R
2
2
GND
10k
1%
2
3.3R
1
GND
100nF
50V
1
2
10k
1%
2
1
470uF
50V
1
2
470uF
50V
1
1 2
10k
1%
470uF
50V
GND
2
1
2
100nF
50V
100nF
50V
1uF
10k
PVDD
1
2
1
2
1
2
1
10k
1%
470uF
50V
2
1
100nF
50V
1uF
10k
PVDD
1
B
1
A
2
50V
10nF
1
GND
10nF
50V
GND
10nF
50V
1
2
1
2
1
1
2
50V
10nF
GND
GND
GND
2
3.3R
2
3.3R
1
2
2
1 2
1
2
1
2
GND
3.3R
2
50V
10nF
100nF
50V
2
2
1
1
1
2
1 2
2
2
1
10k
1%
470uF
50V
3.3R
2
GND
10k
1%
470uF
50V
1
2
PVDD
GND
1
10k
1%
470uF
50V
100nF
50V
100nF
50V
1uF
10k
1
1
2
1
2
2
1
2
10k
1%
470uF
50V
1
2
1
PVDD
100nF
50V
1uF
10k
1
D
1
C
GND
1
2
50V
10nF
GND
GND
Copyright © 2016, Texas Instruments Incorporated
Figure 16. Typical SE Application
22
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8.2.3.1 Design Requirements
For this design example, use the parameters listed in Table 9 as the input parameters.
Table 9. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
Low Power (pull-up) supply
3.3 V
Mid Power Supply (GVDD, VDD)
12 V
High Power Supply (PVDD)
12 V – 36 V
INPUT A = 0 – 3.3 V PWM
NPUT B = 0 – 3.3 V PWM
PWM Inputs
INPUT_C = 0 – 3.3 V PWM
NPUT D = 0 – 3.3 V PWM
Speaker Impedance
3Ω–4Ω
8.2.3.2 Application Curves
Relevant performance plots for TAS5342LA are shown in the SE Configuration.
Table 10. Performance Plots, Typical SE Configurations
PLOT TITLE
FIGURE NUMBER
Total Harmonic Distortion + Noise vs. Output power
Figure 8
Output Power vs. Supply Voltage
Figure 9
Power Output vs. Case Temperature
Figure 10
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8.2.4 Typical Differential (2N) PBTL Application
Design Requirements Typical Differential PBTL
GVDD (+12 V)
10 W
PVDD
10 W
100 nF
3.3 W
470 µF
50 V
100 nF
10 nF
50 V
TAS5342LDDV
GND
Microcontroller
I2C
GND
PWM1_P
VALID
PWM1_M
27 k
0W
GND
100 nF
TAS5508/18
0W
GND
100 nF
1
GVDD_B
2
OTW
3
NC
4
NC
5
SD
6
PWM_A
7
RESET_AB
8
PWM_B
9
OC_ADJ
10
GND
11
AGND
12
VREG
13
M3
14
M2
15
M1
16
PWM_C
17
RESET_CD
18
PWM_D
19
NC
20
NC
21
VDD
22
GVDD_C
GVDD_A
44
GND
43
42 33 nF 25 V
NC
41
GND
PVDD_A
40
PVDD_A
39
OUT_A
38
GND_A
37
GND
GND_B
36
OUT_B
35
PVDD_B
34 33 nF 25 V
BST_B
33
BST_C
3233 nF 25V
PVDD_C
31
OUT_C
30
GND
GND_C
29
GND_D
28
OUT_D
27
PVDD_D
26
PVDD_D
25
GND
NC
24
BST_D
23
GVDD_D
33 nF 25 V
10 µH
GND
BST_A
100 nF
100 nF
50 V
100 nF
50 V
10 µH
10 nF
50 V
1 µF
100 nF
50 V
10 µH
1 nF
50 V
100 nF
50 V
GND
10 nF
50 V
3.3 W
100 nF
50 V
10 µH
PVDD
3.3 W
GND
470 µF
50 V
100 nF
100 nF
10 W
VDD (+12 V)
3.3 W
1 nF
50 V
10 nF
50 V
10 W
GND
GND
GND
GVDD (+12 V)
Copyright © 2016, Texas Instruments Incorporated
Figure 17. Typical Differential (2N) PBTL Application With AD Modulation Filters
8.2.4.1 Design Requirements
For this design example, use the parameters listed in Table 11 as the input parameters.
Table 11. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
Low Power (pull-up) supply
3.3 V
Mid Power Supply (GVDD, VDD)
12 V
High Power Supply (PVDD)
12 V – 36 V
INPUT A = 0 – 3.3 V PWM
INPUT_B = N/C
PWM Inputs
INPUT_C = N/C
INPUT_D = GND
Speaker Impedance
24
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8.2.4.2 Application Curves
Relevant performance plots for TAS5342LA are shown in the PBTL Configuration.
Table 12. Performance Plots, Typical PBTL Configurations
PLOT TITLE
FIGURE NUMBER
Total Harmonic Distortion + Noise vs. Output power
Figure 11
Output Power vs. Supply Voltage
Figure 12
Power Output vs. Case Temperature
Figure 13
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8.2.5 Typical Non-Differential (1N) PBTL
Design Requirements Typical Non-Differential PBTL.
GVDD (+12 V)
10 W
PVDD
10 W
100 nF
3.3 W
470 µF
50 V
100 nF
10 nF
50 V
TAS5342LDDV
GND
Microcontroller
I2C
GND
PWM1_P
VALID
PWM1_M
27 k
0W
GND
100 nF
TAS5508/18
0W
GND
100 nF
1
GVDD_B
2
OTW
3
NC
4
NC
5
SD
6
PWM_A
7
RESET_AB
8
PWM_B
9
OC_ADJ
10
GND
11
AGND
12
VREG
13
M3
14
M2
15
M1
16
PWM_C
17
RESET_CD
18
PWM_D
19
NC
20
NC
21
VDD
22
GVDD_C
GVDD_A
44
GND
43
42 33 nF 25 V
NC
41
GND
PVDD_A
40
PVDD_A
39
OUT_A
38
GND_A
37
GND
GND_B
36
OUT_B
35
PVDD_B
34 33 nF 25 V
BST_B
33
BST_C
3233 nF 25V
PVDD_C
31
OUT_C
30
GND
GND_C
29
GND_D
28
OUT_D
27
PVDD_D
26
PVDD_D
25
GND
NC
24
BST_D
23
GVDD_D
33 nF 25 V
10 µH
GND
BST_A
100 nF
50 V
100 nF
50 V
100 nF
50 V
10 µH
10 nF
50 V
1 µF
100 nF
50 V
10 µH
1 nF
50 V
100 nF
50 V
GND
10 nF
50 V
3.3 W
100 nF
50 V
10 µH
PVDD
3.3 W
GND
470 µF
50 V
100 nF
100 nF
10 W
VDD (+12 V)
3.3 W
1 nF
50 V
10 nF
50 V
10 W
GND
GND
GND
GVDD (+12 V)
Copyright © 2016, Texas Instruments Incorporated
Figure 18. Typical Non-Differential (1N) PBTL Application
8.2.5.1 Design Requirements
For this design example, use the parameters listed in Table 13 as the input parameters.
Table 13. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUE
Low Power (pull-up) supply
3.3 V
Mid Power Supply (GVDD, VDD)
12 V
High Power Supply (PVDD)
12 V – 36 V
INPUT A = 0 – 3.3 V PWM
INPUT_B = N/C
PWM Inputs
INPUT_C = N/C
INPUT_D = GND
Speaker Impedance
26
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8.2.5.2 Application Curves
Relevant performance plots for TAS5342LA are shown in the PBTL Configuration.
Table 14. Performance Plots, Typical PBTL Configurations
PLOT TITLE
FIGURE NUMBER
Total Harmonic Distortion + Noise vs. Output power
Figure 11
Output Power vs. Supply Voltage
Figure 12
Power Output vs. Case Temperature
Figure 13
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8.3 Systems Examples
A block diagram for a typical audio system using the TAS5342LA is shown in Figure 19. The TAS5518 is an
8 channel digital audio PWM processor.
OTW
System
Microcontroller
SD
SD
OTW
I2C
TAS5518
BST_A
BST_B
RESET_AB
RESET_CD
VALID
PWM_A
LeftChannel
Output
OUT_A
Output
H-Bridge 1
Input
H-Bridge 1
PWM_B
OUT_B
Bootstrap
Capacitors
2nd-Order L-C
Output Filter
for Each
Half-Bridge
2-Channel
H-Bridge
BTL Mode
OUT_C
PWM_C
4
32.0 V
PVDD
System
Power
Supply
GND
12 V
4
PVDD
Power
Supply
Decoupling
2nd-Order L-C
Output Filter
for Each
Half-Bridge
OC_ADJ
AGND
VDD
BST_C
VREG
GVDD_A, B, C, D
M3
OUT_D
GND
M2
GND_A, B, C, D
M1
Hardwire
Mode
Control
Output
H-Bridge 2
Input
H-Bridge 2
PWM_D
PVDD_A, B, C, D
RightChannel
Output
BST_D
Bootstrap
Capacitors
4
GVDD
VDD
VREG
Power Supply
Decoupling
Hardwire
OC Limit
GND
GVDD (12 V)/VDD (12 V)
VAC
B0047-02
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Figure 19. Typical Audio System
28
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9 Power Supply Recommendations
To facilitate system design, the TAS5342LA needs only a 12-V supply in addition to the (typical) 32-V powerstage supply. An internal voltage regulator provides suitable voltage levels for the digital and low-voltage analog
circuitry. Additionally, all circuitry requiring a floating voltage supply, for example, the high-side gate drive, is
accommodated by built-in bootstrap circuitry requiring only an external capacitor for each half-bridge.
In order to provide outstanding electrical and acoustical characteristics, the PWM signal path including gate drive
and output stage is designed as identical, independent half-bridges. For this reason, each half-bridge has
separate gate drive supply (GVDD_X), bootstrap pins (BST_X), and power-stage supply pins (PVDD_X).
Furthermore, an additional pin (VDD) is provided as supply for all common circuits. Although supplied from the
same 12-V source, it is highly recommended to separate GVDD_A, GVDD_B, GVDD_C, GVDD_D, and VDD on
the printed-circuit board (PCB) by RC filters (see application diagram for details). These RC filters provide the
recommended high-frequency isolation. Special attention should be paid to placing all decoupling capacitors as
close to their associated pins as possible. In general, inductance between the power supply pins and decoupling
capacitors must be avoided. (See reference board documentation for additional information.)
For a properly functioning bootstrap circuit, a small ceramic capacitor must be connected from each bootstrap pin
(BST_X) to the power-stage output pin (OUT_X). When the power-stage output is low, the bootstrap capacitor is
charged through an internal diode connected between the gate-drive power-supply pin (GVDD_X) and the
bootstrap pin. When the power-stage output is high, the bootstrap capacitor potential is shifted above the output
potential and thus provides a suitable voltage supply for the high-side gate driver. In an application with PWM
switching frequencies in the range from 352 kHz to 384 kHz, it is recommended to use 33-nF ceramic capacitors,
size 0603 or 0805, for the bootstrap supply. These 33-nF capacitors ensure sufficient energy storage, even
during minimal PWM duty cycles, to keep the high-side power stage FET (LDMOS) fully turned on during the
remaining part of the PWM cycle. In an application running at a reduced switching frequency, generally 192 kHz,
the bootstrap capacitor might need to be increased in value.
Special attention should be paid to the power-stage power supply; this includes component selection, PCB
placement, and routing. As indicated, each half-bridge has independent power-stage supply pins (PVDD_X). For
optimal electrical performance, EMI compliance, and system reliability, it is important that each PVDD_X pin is
decoupled with a 100-nF ceramic capacitor placed as close as possible to each supply pin. It is recommended to
follow the PCB layout of the TAS5342LA reference design. For additional information on recommended power
supply and required components, see the application diagrams given previously in this data sheet.
The 12-V supply should be from a low-noise, low-output-impedance voltage regulator. Likewise, the 32-V powerstage supply is assumed to have low output impedance and low noise. The power-supply sequence is not critical
as facilitated by the internal power-on-reset circuit. Moreover, the TAS5342LA is fully protected against
erroneous power-stage turnon due to parasitic gate charging. Thus, voltage-supply ramp rates (dV/dt) are noncritical within the specified range (see the Recommended Operating Conditions section of this data sheet).
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10 Layout
10.1 Layout Guidelines
•
•
•
•
•
•
•
•
•
30
Use an unbroken ground plane to have good low impedance and inductance return path to the power supply
for power and audio signals.
Maintain a contiguous ground plane from the ground pins to the PCB area surrounding the device for as
many of the ground pins as possible, since the ground pins are the best conductors of heat in the package.
PCB layout, audio performance and EMI are linked closely together.
Routing the audio input should be kept short and together with the accompanied audio source ground.
The small bypass capacitors on the PVDD lines of the DUT be placed as close the PVDD pins as possible.
A local ground area underneath the device is important to keep solid to minimize ground bounce.
Orient the passive component so that the narrow end of the passive component is facing the TAS5342LA
device, unless the area between two pads of a passive component is large enough to allow copper to flow
between the two pads.
Avoid placing other heat producing components or structures near the TAS5342LA device.
Avoid cutting off the flow of heat from the TAS5342lA device to the surrounding ground areas with traces or
via strings, especially on output side of device.
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10.2 Layout Example
1
44
2
43
3
42
4
41
5
40
6
39
7
38
8
37
9
36
10
35
11
34
12
33
13
32
14
31
15
30
16
29
17
28
18
27
19
26
20
25
21
24
22
23
System Processor
Bottom Layer Signal Traces
Pad to top layer ground pour
Top Layer Signal Traces
Bottom to top layer connection via
Figure 20. Example Layout
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11 Device and Documentation Support
11.1 Documentation Support
11.1.1 Related Documentation
For related documentation see the following:
• TAS5342LDDV6EVM User Guide (SLAU243)
11.2 Receiving Notification of Documentation Updates
To receive notification of documentation updates, navigate to the device product folder on ti.com. In the upper
right corner, click on Alert me to register and receive a weekly digest of any product information that has
changed. For change details, review the revision history included in any revised document.
11.3 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
11.4 Trademarks
E2E is a trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
11.5 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
11.6 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
12 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
32
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PACKAGE OPTION ADDENDUM
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10-Dec-2020
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
(2)
Lead finish/
Ball material
MSL Peak Temp
Op Temp (°C)
Device Marking
(3)
(4/5)
(6)
TAS5342LADDV
ACTIVE
HTSSOP
DDV
44
35
RoHS & Green
NIPDAU
Level-3-260C-168 HR
0 to 70
TAS5342LA
TAS5342LADDVR
ACTIVE
HTSSOP
DDV
44
2000
RoHS & Green
NIPDAU
Level-3-260C-168 HR
0 to 70
TAS5342LA
(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)
RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance
do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may
reference these types of products as "Pb-Free".
RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.
Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of