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TAS5612LA
SLAS847A – MAY 2012 – REVISED MARCH 2015
TAS5612LA 125-W Stereo and 250-W Mono PurePath™ HD Digital-Input Class-D Power
Stage
1 Features
3 Description
•
The TAS5612LA is a feature optimized class-D power
amplifier based on the TAS5612A.
1
•
•
•
•
•
•
•
•
PurePath™ HD Integrated Feedback Provides:
– 0.05% THD at 1 W Into 4 Ω
– > 65-dB PSRR (No Input Signal)
– > 105-dB (A Weighted) SNR
Preclipping Output for Control of a Class-G Power
Supply
Reduced Heat Sink Size Due to Use of 60-mΩ
Output MOSFET With > 90% Efficiency at Full
Output Power
Output Power at 10% THD+N
– 125-W and 4-Ω BTL Stereo Configuration
– 250-W and 2-Ω in PBTL Mono Configuration
Output Power at 1% THD+N
– 105-W and 4-Ω BTL Stereo Configuration
– 55-W and 8-Ω BTL Stereo Configuration
Click- and Pop-Free Start-up
Error Reporting Self-Protected Design With UVP,
Overtemperature, and Short-Circuit Protection
EMI Compliant When Used With Recommended
System Design
44-Pin HTSSOP (DDV) Package for Reduced
Board Size
The unique preclipping output signal can be used to
control a class-G power supply. This combined with
the low idle loss and high power efficiency of the
TAS5612LA leads to industry-leading levels of
efficiency ensuring a super “green” system.
The TAS5612LA uses constant voltage gain. The
internally matched gain resistors ensure a high Power
Supply Rejection Ratio giving an output voltage only
dependent on the audio input voltage and free from
any power supply artifacts.
The high integration of the TAS5612LA makes the
amplifier easy to use; and, using TI’s reference
schematics and PCB layouts leads to fast design in
time. The TAS5612LA is available in the spacesaving, surface-mount, 44-pin HTSSOP package.
Device Information(1)
PART NUMBER
TAS5612LA
PACKAGE
BODY SIZE (NOM)
HTSSOP (44)
14.00 mm × 6.10 mm
(1) For all available packages, see the orderable addendum at
the end of the data sheet.
2 Applications
•
•
•
•
The TAS5612LA uses large MOSFETs for improved
power efficiency and a novel gate drive scheme for
reduced losses in idle and at low output signals
leading to reduced heat sink size.
Blu-ray™ and DVD Receivers
High-Power Sound Bars
Powered Subwoofer and Active Speakers
Mini Combo Systems
Typical TAS5612LA Application Block Diagram
PurePath HDTM
TAS
5630
TAS5612LA
TASxxxx
DIGITAL
AUDIO
INPUT
Digital Audio
Processor
+12V
18V-32.5V
PurePath HDTM
Class G Power Supply
Ref design
+3.3V
REG.
105VAC
→ 240VAC
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.
TAS5612LA
SLAS847A – MAY 2012 – REVISED MARCH 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
Features ..................................................................
Applications ...........................................................
Description .............................................................
Revision History.....................................................
Pin Configuration and Functions .........................
Specifications.........................................................
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
6.9
7
1
1
1
2
3
5
Absolute Maximum Ratings ...................................... 5
ESD Ratings.............................................................. 5
Recommended Operating Conditions....................... 5
Thermal Information .................................................. 6
Electrical Characteristics........................................... 7
Audio Specification Stereo (BTL).............................. 8
Audio Specification 4 Channels (SE) ........................ 8
Audio Specification Mono (PBTL) ............................ 9
Typical Characteristics ............................................ 10
Detailed Description ............................................ 12
7.1
7.2
7.3
7.4
8
Overview .................................................................
Functional Block Diagrams .....................................
Feature Description.................................................
Device Functional Modes........................................
12
13
15
19
Application and Implementation ........................ 20
8.1 Application Information............................................ 20
8.2 Typical Applications ................................................ 21
9 Power Supply Recommendations...................... 30
10 Layout................................................................... 30
10.1 Layout Guidelines ................................................. 30
10.2 Layout Example .................................................... 32
11 Device and Documentation Support ................. 34
11.1 Trademarks ........................................................... 34
11.2 Electrostatic Discharge Caution ............................ 34
11.3 Glossary ................................................................ 34
12 Mechanical, Packaging, and Orderable
Information ........................................................... 34
4 Revision History
Changes from Original (May 2012) to Revision A
•
2
Page
Added Pin Configuration and Functions section, 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
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SLAS847A – MAY 2012 – REVISED MARCH 2015
5 Pin Configuration and Functions
DDV Package
44-Pin HTSSOP
Top View
GVDD_AB
VDD
OC_ADJ
RESET
INPUT_A
INPUT_B
C_START
DVDD
GND
BST_A
BST_B
GND
GND
OUT_A
OUT_A
PVDD_AB
PVDD_AB
PVDD_AB
OUT_B
GND
GND
GND
AVDD
INPUT_C
INPUT_D
FAULT
OTW
CLIP
M1
GND
GND
OUT_C
PVDD_CD
PVDD_CD
PVDD_CD
OUT_D
OUT_D
GND
GND
BST_C
BST_D
M2
M3
GVDD_CD
Pin Functions
PIN
I/O/P (1)
DESCRIPTION
NAME
NO.
AVDD
13
P
Internal voltage regulator, analog section
BST_A
44
P
Bootstrap pin, A-side
BST_B
43
P
Bootstrap pin, B-side
BST_C
24
P
Bootstrap pin, C-side
BST_D
23
P
Bootstrap pin, D-side
CLIP
18
O
Clipping warning, open drain, active low
C_START
7
O
Start-up ramp
DVDD
8
P
Internal voltage regulator, digital section
FAULT
16
O
Shutdown signal, open drain, active low
9, 10, 11, 12, 25, 26,
33, 34, 41, 42
P
Ground
GVDD_AB
1
P
Gate-drive voltage supply; AB-side
GVDD_CD
22
P
Gate-drive voltage supply; CD-side
INPUT_A
5
I
PWM input signal for half-bridge A
INPUT_B
6
I
PWM input signal for half-bridge B
INPUT_C
14
I
PWM input signal for half-bridge C
INPUT_D
15
I
PWM input signal for half-bridge D
M1
19
I
Mode selection 1 (LSB)
M2
20
I
Mode selection 2
M3
21
I
Mode selection 3 (MSB)
OC_ADJ
3
O
Overcurrent threshold programming pin
GND
(1)
I = Input, O = Output, P = Power
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Pin Functions (continued)
PIN
NAME
I/O/P (1)
NO.
OTW
DESCRIPTION
17
O
Overtemperature warning, open drain, active low
OUT_A
39, 40
O
Output, half-bridge A
OUT_B
35
O
Output, half-bridge B
OUT_C
32
O
Output, half-bridge C
OUT_D
27, 28
O
Output, half-bridge D
PVDD_AB
36, 37, 38
P
PVDD supply for half-bridge A and B
PVDD_CD
29, 30, 31
P
PVDD supply for half-bridge C and D
RESET
4
I
Device reset Input; active low
VDD
2
P
Input power supply
PowerPAD™
–
P
Ground, connect to grounded heat sink
Mode Selection Pins
MODE PINS
(1)
(2)
(3)
4
PWM
Input (1)
OUTPUT
CONFIGURATION
INPUT A
0
2N + 1
2 x BTL
1
1N + 1 (2)
2 x BTL
0
2N + 1
M3
M2
M1
0
0
0
0
0
1
1N + 1
(2)
INPUT B
INPUT C
INPUT D
MODE
PWMa
PWMb
PWMa
Unused
PWMc
PWMd
AD mode
PWMc
Unused
2 x BTL
PWMa
AD mode
PWMb
PWMc
PWMd
BD mode
0
1
1
1 x BTL + 2 x SE
PWMa
Unused
PWMc
PWMd
AD mode
1
0
0
2N + 1
1 x PBTL
PWMa
PWMb
0
0
AD mode
1
0
0
1N + 1 (2)
1 x PBTL
PWMa
Unused
0
1
AD mode
1
0
0
2N + 1
1 x PBTL
PWMa
PWMb
1
0
BD mode
1
0
1
1N + 1
4 x SE (3)
PWMa
PWMb
PWMc
PWMd
AD mode
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.
Using 1N interface in BTL and PBTL mode results in increased DC offset on the output terminals.
The 4xSE mode can be used as 1xBTL + 2xSE configuration by feeding a 2N PWM signal to either INPUT_AB or INPUT_CD for
improved DC offset accuracy
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SLAS847A – MAY 2012 – REVISED MARCH 2015
6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range unless otherwise noted (1)
VDD to GND, GVDD_X (2) to GND
PVDD_X
(2)
to GND
(3)
(3)
, OUT_X to GND , BST_X to GVDD_X
(2) (3)
MIN
MAX
UNIT
–0.3
13.2
V
–0.3
50
V
BST_X to GND (3) (4)
–0.3
62.5
V
DVDD to GND
–0.3
4.2
V
AVDD to GND
–0.3
8.5
V
OC_ADJ, M1, M2, M3, C_START, INPUT_X to GND
–0.3
4.2
V
RESET, FAULT, OTW, CLIP, to GND
–0.3
4.2
V
Maximum continuous sink current (FAULT, OTW, CLIP)
9
Maximum operating junction temperature, TJ
0
mA
150
Lead temperature
260
Storage temperature, Tstg
–40
(1)
(2)
(3)
(4)
°C
°C
150
°C
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating
Conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
GVDD_X and PVDD_X represents a full bridge gate drive or power supply. GVDD_X is GVDD_AB or GVDD_CD, PVDD_X is
PVDD_AB or PVDD_CD
These voltages represents the dc voltage + peak ac waveform measured at the terminal of the device in all conditions.
Maximum BST_X to GND voltage is the sum of maximum PVDD to GND and GVDD to GND voltages minus a diode drop.
6.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic
discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±2000
Charged-device model (CDM), per JEDEC specification JESD22-C101 (2)
±500
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
MIN
NOM
MAX
PVDD_X
Full-bridge supply
DC supply voltage
12
32.5
34
V
GVDD_X
Supply for logic regulators and
gate-drive circuitry
DC supply voltage
10.8
12
13.2
V
VDD
Digital regulator supply voltage DC supply voltage
10.8
12
13.2
V
3.0
4.0
RL
Load impedance
1.5
3.0
1.5
2.0
BTL
SE
PBTL
Output filter: L = 10 µH, 1 µF
Output AD modulation,
switching frequency > 350 kHz.
Minimum inductance at overcurrent
limit, including inductor tolerance,
temperature and possible inductor
saturation
UNIT
Ω
μH
LOUTPUT
Output filter inductance
5
FPWM
PWM frame rate
352
384
CPVDD
PVDD close decoupling
capacitors
0.44
1
μF
C_START
Start-up ramp capacitor
100
nF
1
μF
ROC
Overcurrent programming
resistor
Resistor tolerance = 5%
24
ROC_LATCHED
Overcurrent programming
resistor
Resistor tolerance = 5%
47
TJ
Junction temperature
BTL and PBTL configuration
SE and 1xBTL+2xSE configuration
0
62
500
33
kΩ
68
kΩ
125
°C
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6.4 Thermal Information
THERMAL METRIC
(1)
TAS5612L
A
DDV
UNIT
44 PINS
RθJH
Junction-to-heatsink thermal resistance
2.3
RθJC(top)
Junction-to-case (top) thermal resistance
0.8
RθJB
Junction-to-board thermal resistance
2.1
ψJT
Junction-to-top characterization parameter
0.8
ψJB
Junction-to-board characterization parameter
2.1
RθJC(bot)
Junction-to-case (bottom) thermal resistance
n/a
(1)
6
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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6.5 Electrical Characteristics
PVDD_X = 32.5 V, GVDD_X = 12 V, VDD = 12 V, TC (Case temperature) = 75°C, fS = 384 kHz, unless otherwise specified.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
3.0
3.3
3.6
UNIT
INTERNAL VOLTAGE REGULATOR AND CURRENT CONSUMPTION
DVDD
Voltage regulator, only used as a
reference node
VDD = 12 V
AVDD
Voltage regulator, only used as a
reference node
VDD = 12 V
7.8
IVDD
VDD supply current
Operating, 50% duty cycle
20
Idle, reset mode
20
IGVDD_X
Gate-supply current per full-bridge
50% duty cycle
9
Reset mode
2
IPVDD_X
Full-bridge idle current
50% duty cycle without load
18
RESET low
1.7
VDD and GVDD_X at 0mV
V
V
mA
mA
mA
0.35
OUTPUT-STAGE MOSFETs
RDS(on), LS
Drain-to-source resistance, low side
(LS)
RDS(on), HS
Drain-to-source resistance, high side
(HS)
TJ = 25°C, excludes metalization
resistance,
GVDD = 12 V
60
100
mΩ
60
100
mΩ
I/O PROTECTION
Vuvp,GVDD
Vuvp,GVDD,
hyst
(1)
Vuvp,VDD
Vuvp,VDD,
hyst
(1)
Vuvp,PVDD
Vuvp,PVDD,hyst (1)
OTW (1)
OTWhyst
OTE
Undervoltage protection limit, GVDD_X
Undervoltage protection limit, VDD
Undervoltage protection limit, PVDD_X
(1)
115
Temperature drop needed below OTW temperature for OTW to be inactive
after OTW event.
Overtemperature error
OTE-OTWdifferential (1)
V
0.7
V
8.5
V
0.7
V
8.5
V
0.7
Overtemperature warning
(1)
8.5
125
V
135
°C
25
145
155
°C
165
°C
OTE-OTW differential
30
A device reset is needed to clear FAULT after an OTE event
25
°C
OLPC
Overload protection counter
fPWM = 384 kHz
2.6
ms
IOC
Overcurrent limit protection
Resistor – programmable, nominal
peak current in 1-Ω load, ROC = 24
kΩ
15
A
IOC_LATCHED
Overcurrent limit protection, latched
Resistor – programmable, nominal
peak current in 1-Ω load, ROC = 62
kΩ
15
A
IOCT
Overcurrent response time
Time from application of short
condition to Hi-Z of affected halfbridge
150
ns
IPD
Internal pulldown resistor at output of
each half bridge
Connected when RESET is active to
provide bootstrap charge. Not used in
SE mode.
3
mA
OTEHYST
(1)
°C
STATIC DIGITAL SPECIFICATIONS
VIH
High level input voltage
VIL
Low level input voltage
LEAKAGE
Input leakage current
INPUT_X, M1, M2, M3, RESET
1.9
V
0.8
V
100
μA
kΩ
OTW / SHUTDOWN (FAULT)
RINT_PU
Internal pullup resistance, OTW, CLIP, FAULT to DVDD
VOH
High level output voltage
Internal pullup resistor
VOL
Low level output voltage
IO = 4 mA
FANOUT
Device fanout OTW, FAULT, CLIP
No external pullup
(1)
20
26
33
3
3.3
3.6
V
200
500
mV
30
devices
Specified by design.
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6.6 Audio Specification Stereo (BTL)
Audio performance is recorded as a chipset consisting of a TASxxxx PWM Processor (modulation index limited to 97.7%) and
a TAS5612LA power stage with PCB and system configurations in accordance with recommended guidelines. Audio
frequency = 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C, Output Filter: LDEM
= 10 μH, CDEM = 1 µF, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
RL = 4 Ω, 10% THD+N
125
RL = 4 Ω, 1% THD+N
105
MAX
UNIT
PO
Power output per channel
THD+N
Total harmonic distortion + noise
1-W, 1-kHz signal
Vn
Output integrated noise
A-weighted, AES17 measuring filter
VOS
Output offset voltage
No signal
SNR
Signal-to-noise ratio (1)
A-weighted, AES17 measuring filter
105
dB
DNR
Dynamic range
A-weighted, –60 dBFS (rel 1% THD+N)
105
dB
Pidle
Power dissipation due to idle losses
(IPVDD_X)
1.2
W
(1)
(2)
PO = 0, channel switching
W
0.05%
μV
180
10
(2)
20
mV
SNR is calculated relative to 1% THD-N output level.
Actual system idle losses also are affected by core losses of output inductors.
6.7 Audio Specification 4 Channels (SE)
Audio performance is recorded as a chipset consisting of a TASxxxx PWM Processor (modulation index limited to 97.7%) and
a TAS5612LA power stage with PCB and system configurations in accordance with recommended guidelines. Audio
frequency = 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C, Output Filter: LDEM
= 10 μH, CDEM = 1 µF, CDCB = 470 µF, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
RL = 3 Ω, 10% THD+N
43
RL = 3 Ω, 1% THD+N
35
MAX
UNIT
PO
Power output per channel
THD+N
Total harmonic distortion + noise
1-W, 1-kHz signal
Vn
Output integrated noise
A-weighted, AES17 measuring filter
180
μV
SNR
Signal-to-noise ratio
A-weighted, AES17 measuring filter
102
dB
DNR
Dynamic range
A-weighted, –60 dBFS (rel 1%
THD+N)
102
dB
Pidle
Power dissipation due to Idle losses
(IPVDD_X)
PO = 0, channels switching (1)
1.2
W
(1)
8
W
0.04%
Actual system idle losses also are affected by core losses of output inductors.
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6.8 Audio Specification Mono (PBTL)
Audio performance is recorded as a chipset consisting of a TASxxxx PWM Processor (modulation index limited to 97.7%) and
a TAS5612LA power stage with PCB and system configurations in accordance with recommended guidelines. Audio
frequency = 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C, Output Filter: LDEM
= 10 μH, CDEM = 1 μF, unless otherwise noted.
PARAMETER
PO
Power output per channel
TEST CONDITIONS
MIN
TYP
RL = 2 Ω, 10%, THD+N
250
RL = 3 Ω, 10% THD+N
165
RL = 4 Ω, 10% THD+N
130
RL = 2 Ω, 1% THD+N
210
RL = 3 Ω, 1% THD+N
135
RL = 4 Ω, 1% THD+N
105
MAX
UNIT
W
THD+N
Total harmonic distortion + noise
1-W, 1-kHz signal
Vn
Output integrated noise
A-weighted, AES17 measuring filter
VOS
Output offset voltage
No signal
SNR
Signal to noise ratio (1)
A-weighted, AES17 measuring filter
105
dB
DNR
Dynamic range
A-weighted, –60 dBFS (rel 1% THD)
105
dB
Pidle
Power dissipation due to idle losses
(IPVDD_X)
1.2
W
(1)
(2)
PO = 0, All channels switching
0.025%
10
(2)
μV
180
20
mV
SNR is calculated relative to 1% THD-N output level.
Actual system idle losses are affected by core losses of output inductors.
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6.9 Typical Characteristics
6.9.1 Typical Characteristics, BTL Configuration
Measurement conditions are: 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C,
Output Filter: LDEM = 10 μH, CDEM = 1 µF, 20-Hz to 20-kHz bandwidth (AES17 low-pass filter), unless otherwise noted.
200
3Ω
4Ω
8Ω
3Ω
4Ω
8Ω
180
160
1
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
0.1
140
120
100
80
60
40
20
0.01
TC = 75°C
THD+N at 10%
TC = 75°C
0.005
0.02
0.1
1
10
0
100 200
PO − Output Power − W
Figure 1. Total Harmonic + Noise vs Output Power, 1 kHz
15
20
25
PVDD − Supply Voltage − V
30
35
G003
Figure 2. Output Power vs Supply Voltage vs Distortion +
Noise = 10%
10
160
1W
10 W
80 W
3Ω
4Ω
8Ω
140
1
120
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
G001
0.1
100
0.01
80
60
40
20
TC = 75°C
0.001
20
100
1k
Frequency − Hz
10k
TC = 75°C
0
20k
10
15
20
25
PVDD − Supply Voltage − V
30
35
G002
100
95
90
85
80
75
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
G004
Figure 4. Output Power vs Supply Voltage, vs Distortion +
Noise = 1%
60
50
45
40
35
30
25
20
15
10
3Ω
4Ω
8Ω
0
5
TC = 75°C
100
200
300
Total Output Power − W
TC = 75°C
0
400
G005
Figure 5. System Efficiency vs Output Power
10
3Ω
4Ω
8Ω
55
Power Loss − W
Efficiency − %
Figure 3. Total Harmonic Distortion + Noise vs Frequency,
4Ω
0
100
200
300
Total Output Power − W
400
G006
Figure 6. System Power Loss vs Output Power
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Typical Characteristics, BTL Configuration (continued)
Measurement conditions are: 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C,
Output Filter: LDEM = 10 μH, CDEM = 1 µF, 20-Hz to 20-kHz bandwidth (AES17 low-pass filter), unless otherwise noted.
200
180
140
Noise Amplitude − dB
PO − Output Power − W
160
120
100
80
60
40
3Ω
4Ω
8Ω
20
0
−10
0
10
THD+N at 10%
20
30
40
50
60
70
80
90 100 110
TC − Case Temperature − °C
0
−10
−20
−30
−40
−50
−60
−70
−80
−90
−100
−110
−120
−130
−140
−150
−160
−170
−180
−190
−200
TC = 75°C
VREF = 20.5 V
Sample Rate = 48kHz
FFT Size = 16384
0
2k
4k
6k
4Ω
8k 10k 12k 14k 16k 18k 20k 22k 24k
f − Frequency − Hz
G007
Figure 7. Output Power vs Temperature
G008
Figure 8. Noise Amplitude vs Frequency
6.9.2 Typical Characteristics, SE Configuration
Measurement conditions are: 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C,
Output Filter: LDEM = 10 μH, CDEM = 1 µF, CDCB = 470 µF, 20-Hz to 20-kHz BW (AES17 low-pass filter), unless otherwise
noted.
80
2Ω
3Ω
4Ω
2Ω
3Ω
4Ω
60
1
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
0.1
40
20
TC = 75°C
THD+N at 10%
0.01
TC = 75°C
0.005
0.02
0.1
1
10
0
100
PO − Output Power − W
10
15
20
25
PVDD − Supply Voltage − V
30
35
G009
Figure 9. Total Harmonic Distortion + Noise vs Output
Power
G010
Figure 10. Output Power vs Supply Voltage
6.9.3 Typical Characteristics, PBTL Configuration
Measurement conditions are: 1 kHz, PVDD_X = 32.5 V, GVDD_X = 12 V, RL = 4 Ω, fS = 384 kHz, ROC = 24 kΩ, TC = 75°C,
Output Filter: LDEM = 10 μH, CDEM = 1 µF, 20-Hz to 20-kHz BW (AES17 low-pass filter), unless otherwise noted.
320
2Ω
3Ω
4Ω
2Ω
3Ω
4Ω
300
280
260
240
1
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
0.1
220
200
180
160
140
120
100
80
60
40
0.01
0.1
1
10
100
PO − Output Power − W
TC = 75°C
THD+N at 10%
20
TC = 75°C
0.005
0.02
0
400
G011
Figure 11. Total Harmonic Distortion + Noise vs Output
Power
10
15
20
25
PVDD − Supply Voltage − V
30
35
G012
Figure 12. Output Power vs Supply Voltage
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7 Detailed Description
7.1 Overview
TAS5612LA is a PWM input, audio PWM (class-D) amplifier. The output of the TAS5612LA can be configured for
single-ended, BTL (Bridge-Tied Load) or parallel BTL (PBTL) output. It requires two rails for power supply, PVDD
and 12 V (GVDD and VDD).
The following block diagram shows typical connections for BTL outputs. Detailed schematic can be viewed in
TAS5612LA EVM User's Guide (SLAU375)
12
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7.2 Functional Block Diagrams
Capacitors for
External
Filtering
&
Startup/Stop
System
microcontroller
/AMP RESET
C_START
/CLIP
*NOTE1
/OTW
TASxxxx
PWM Modulator
/FAULT
I2C
/RESET
VALID
BST_A
BST_B
LeftChannel
Output
PWM_A
INPUT_A
PWM_B
INPUT_B
OUT_A
Input
H-Bridge 1
Output
H-Bridge 1
OUT_B
Bootstrap
Capacitors
nd
2 Order
L-C Output
Filter for
each
H-Bridge
2-CHANNEL
H-BRIDGE
BTL MODE
nd
PWM_C
INPUT_C
PWM_D
INPUT_D
32.5V
PVDD
12V
Output
H-Bridge 2
OUT_D
PVDD
OC_ADJ
DVDD
AVDD
VDD
M3
2 Order
L-C Output
Filter for
each
H-Bridge
BST_C
GND
M2
GVDD_AB, CD
M1
Power Supply
Decoupling
SYSTEM
Power
Supplies
GND
Input
H-Bridge 2
GND
Hardwire
Mode
Control
OUT_C
PVDD_AB, CD
RightChannel
Output
GVDD, VDD,
& VREG
Power Supply
Decoupling
BST_D
Bootstrap
Capacitors
Hardwire
OverCurrent
Limit
GND
GVDD (12V)/VDD (12V)
VAC
(1) Logic AND is inside or outside the microprocessor.
Figure 13. Typical System Block Diagram
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Functional Block Diagrams (continued)
/CLIP
/OTW
/FAULT
UVP
BST_X
GVDD_X
AVDD
DVDD
/RESET
PROTECTION & I/O LOGIC
MODE1-3
AVDD
AVDD
VDD
DVDD
DVDD
POWER-UP
RESET
TEMP
SENSE
CB3C OVERLOAD
PROTECTION
STARTUP
CONTROL
C_START
BST_A
PVDD_AB
INPUT_A
PWM
RECEIVER
ANALOG
LOOP FILTER
+
-
PWM &
TIMING
CONTROL
GATE-DRIVE
OUT_A
GND
GVDD_AB
BST_B
PVDD_AB
INPUT_B
PWM
RECEIVER
ANALOG
LOOP FILTER
+
-
PWM &
TIMING
CONTROL
GATE-DRIVE
OUT_B
GND
BST_C
PVDD_CD
INPUT_C
PWM
RECEIVER
ANALOG
LOOP FILTER
+
-
PWM &
TIMING
CONTROL
GATE-DRIVE
OUT_C
GND
GVDD_CD
BST_D
PVDD_CD
INPUT_D
PWM
RECEIVER
ANALOG
LOOP FILTER
+
-
PWM &
TIMING
CONTROL
GATE-DRIVE
OUT_D
GND
Figure 14. Functional Block Diagram
14
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7.3 Feature Description
7.3.1 Power Supplies
To facilitate system design, the TAS5612LA needs only a 12-V supply in addition to the (typical) 32.5-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.
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
bootstrap pins (BST_X) and each full-bridge has separate power stage supply (PVDD_X) and gate supply
(GVDD_X) pins. 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_AB, GVDD_CD, 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.)
Special attention should be paid to the power-stage power supply; this includes component selection, PCB
placement, and routing. As indicated, each full-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
connection is decoupled with minimum 2 × 220-nF ceramic capacitors placed as close as possible to each
supply pin. TI recommends following the PCB layout of the TAS5612LA reference design. For additional
information on recommended power supply and required components, see the application diagrams in this data
sheet.
The 12-V supply should be from a low-noise, low-output-impedance voltage regulator. Likewise, the 32.5-V
power-stage 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 TAS5612LA is fully protected against
erroneous power-stage turn on due to parasitic gate charging when power supplies are applied. Thus, voltagesupply ramp rates (dV/dt) are non-critical within the specified range (see Recommended Operating Conditions).
7.3.1.1
Boot Strap Supply
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 300 kHz to 400 kHz, TI recommends using 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.
7.3.2 System Power-Up and Power-Down Sequence
7.3.2.1 Powering Up
The TAS5612LA 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 Electrical Characteristics). Although not specifically required, TI
recommends to hold RESET 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.
7.3.2.2 Powering Down
The TAS5612LA 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 Electrical Characteristics). Although not specifically required, it is a good practice to hold RESET
low during power down, thus preventing audible artifacts including pops or clicks.
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Feature Description (continued)
7.3.3 Start-up and Shutdown Ramp Sequence
The integrated start-up and stop sequence ensures a click and pop free start-up and shutdown sequence of the
amplifier. The start-up sequence uses a voltage ramp with a duration set by the CSTART capacitor. The
sequence uses the input PWM signals to generate output PWM signals, hence input idle PWM should be present
during both start-up and shut down ramping sequences.
VDD, GVDD_X and PVDD_X power supplies must be turned on and with settled outputs before starting the startup ramp by setting RESET high.
During start-up and shutdown ramp the input PWM signals should be in muted condition with the PWM processor
noise shaper activity turned off (50% duty cycle).
The duration of the start-up and shutdown ramp is 100 ms + X ms, where X is the CSTART capacitor value in
nF.
TI recommends to use 100-nF CSTART in BTL and PBTL mode and 1 µF in SE mode configuration. This results
in ramp times of 200 ms and 1.1 s, respectively. The longer ramp time in SE configuration allows charge and
discharge of the output ac coupling capacitor without audible artifacts.
Ramp Start
Ramp End
Ramp Start
Ramp End
3.3V
/RESET
0V
INPUT_X
OUT_X
INPUT_X IS SWITCHING (MUTE)
NOISE SHAPER OFF
(UNMUTED)
INPUT_X IS SWITCHING (MUTE)
NOISE SHAPER OFF
OUT_X IS SWITCHING (MUTE)
(UNMUTED)
OUT_X IS SWITCHING (MUTE)
3.3V
Hi-Z
0V
PVDD_X
Hi-Z
0V
VI_CM
DC_RAMP
0V
50%
PVDD_X/2
SPEAKER OUT_X
0V
tStartup Ramp
tStartup Ramp
INPUT_X IS SWITCHING (MUTE)
NOISE SHAPER ON
Figure 15. Start-up/Shutdown Ramp
7.3.4 Unused Output Channels
If all available output channels are not used, TI recommends disabling switching of unused output nodes to
reduce power consumption. Furthermore by disabling unused output channels the cost of unused output LC
demodulation filters can be avoided.
Disabling a channel is done by leave the bootstrap capacitor (BST) unstuffed and connecting the respective input
to GND. The unused output pin(s) can be left floating. The PVDD decoupling capacitors still must be mounted.
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Feature Description (continued)
Table 1. Unused Output Channels
OPERATING
MODE
PWM
INPUT
000
2N + 1
001
1N + 1
010
2N + 1
101
1N + 1
OUTPUT
CONFIGURATION
UNUSED
CHANNEL
INPUT_A
INPUT_B
INPUT_C
INPUT_D
UNSTUFFED
COMPONENT
2 x BTL
AB
CD
GND
PWMa
GND
PWMb
PWMc
GND
PWMd
GND
BST_A and BST_B
capacitors
BST_C and BST_D
capacitors
A
GND
PWMb
PWMc
PWMd
BST_A capacitor
B
PWMa
GND
PWMc
PWMd
BST_B capacitor
C
PWMa
PWMb
GND
PWMd
BST_C capacitor
D
PWMa
PWMb
PWMc
GND
BST_D capacitor
4 x SE
7.3.5 Device Protection System
The TAS5612LA 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 TAS5612LA responds to a fault by
immediately setting the power stage in a high-impedance (Hi-Z) state and asserting the FAULT pin low. In
situations other than overload and overtemperature 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 2.
Table 2. Device Protection
BTL MODE
PBTL MODE
SE MODE
CHANNEL FAULT
TURNS OFF
CHANNEL FAULT
TURNS OFF
CHANNEL FAULT
TURNS OFF
A
A+B
A
A+B+C+D
A
A+B
B
C
C+D
D
B
B
C
C
D
D
C+D
Bootstrap UVP does not shutdown according to the table, it shuts down the respective high-side FET.
spacer
7.3.6 Pin-to-Pin Short-Circuit Protection (PPSC)
The PPSC detection system protects the device from permanent damage if a power output pin (OUT_X) is
shorted to GND 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
start-up, that is, when VDD is supplied, consequently a short to either GND or PVDD_X after system start-up will
not activate the PPSC detection system. When PPSC detection is activated by a short on the output, all halfbridges are kept in a Hi-Z state until the short is removed, the device then continues the start-up 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, 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 filter. The typical duration
is 2.6 ms)
OC shutdown
Channel
FAULT Pin
Latched
Toggle RESET
Hi-Z
Latched OC (ROC > 47k)
OC shutdown
Channel
FAULT Pin
Latched
Toggle RESET
Hi-Z
Flip state, cycle by
cycle at fs/2
FAULT or EVENT
PVDD_X UVP
VDD UVP
GVDD_X UVP
AVDD UVP
CBC (24k < ROC < 33k)
OC Limiting
Channel
None
Self Clearing
reduce signal level or
remove short
No PWM
Channel
None
Self Clearing
resume PWM
Hi-Z
No PWM
Global
None
Self Clearing
resume PWM
Hi-Z
(1)
Stuck at Fault (1 to 3
channels)
(1)
Stuck at Fault (All
channels)
(1)
Stuck at Fault occurs when input PWM drops below minimum PWM frame rate given in Recommended Operating Conditions.
7.3.12 Device Reset
When RESET is asserted low, all power-stage FETs in the four half-bridges are forced into a high-impedance
(Hi-Z) state.
In BTL modes, to accommodate bootstrap charging prior to switching start, asserting the reset input low enables
weak pulldown of the half-bridge outputs. In the SE mode, the output is forced into a high-impedance state when
asserting the reset input low. Asserting reset input low removes any fault information to be signaled on the
FAULT output, that is, FAULT is forced high. A rising-edge transition on 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 FAULT.
7.3.13 System Design Consideration
A rising-edge transition on reset input allows the device to execute the start-up sequence and starts switching.
Apply audio only according to the timing information for start-up and shutdown sequence. That will start and stop
the amplifier without audible artifacts in the output transducers.
The CLIP signal indicates that the output is approaching clipping (when output PWM starts skipping pulses due
to loop filter saturation). The signal can be used to initiate an audio volume decrease or to adjust the power
supply rail.
The device inverts the audio signal from input to output.
The DVDD and AVDD pins are not recommended to be used as a voltage source for external circuitry.
7.4 Device Functional Modes
As mentioned above, there are three main output modes that the user can configure the device as per
application requirement. In addition there are two PWM modulation modes, AD and BD.
AD modulation can have single-ended (SE) or differential analog inputs. AD modulation can also be configured to
have SE, BTL, BTL+SE, or PBTL outputs. BD modulation requires differential analog inputs.
BD modulation can only be configured in BTL or PTBL mode.
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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
The following sections discuss in detail three typical audio PWM (class-D) configurations:
• Differential input, stereo BTL outputs
• Differential input, mono PBTL output
• Single ended inputs, quad single-ended outputs.
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8.2 Typical Applications
8.2.1 Typical BTL Application
3.3R
+12V
GND
10uF
100 nF
100 nF
33nF
BST_A 44
1 GVDD_AB
BST_B 43
2 VDD
33nF
ROC-ADJUST
_ DJ
3 OC A
GND 42
/RESET
4 /RESET
GND 41
PWM_A
5 INPUT_A
PWM_B
6 INPUT_B
OUT_A 39
7 C_START
PVDD_AB 38
8 DVDD
PVDD_AB 37
10 µH
100 nF
OUT_A 40
220 nF
100 nF
9 GND
10 GND
11 GND
1uF
12 GND
13 AVDD
14 INPUT_C
PWM_C
3R3
470 nF
220 nF
470 uF
3R3
100 nF
1 nF
TAS5612LA
1uF
10nF
1nF
PVDD_AB 36
10nF
OUT_B 35
10 µH
PVDD
GND
GND 34
GND 33
OUT_C 32
10 µH
10nF
PVDD_CD 31
1nF
PWM_D
/FAULT
15 INPUT_D
PVDD_CD 30
16 /FAULT
PVDD_CD 29
/OTW
17 /OTW
OUT_D 28
/CLIP
18 /CLIP
OUT_D 27
19 M1
GND 26
20 M2
GND 25
100 nF
220 nF 220 nF
21 M3
BST_C 24
22 GVDD_CD
BST_D 23
470 nF
3R3
100 nF
1nF
10nF
33nF
100 nF
3R3
470 uF
10 µH
33nF
3.3R
Figure 16. Typical Differential (2N) BTL Application With AD Modulation Filters
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8.2.1.1 Design Requirements
See Figure 16 for application schematic. In this application, differential PWM inputs are used with AD modulation
from the PWM modulator (TAS5558). AD modulation scheme is defined as PWM(+) is opposite polarity from
PWM(-).
8.2.1.2 Detailed Design Procedure
• Pin 1 - GVDD_AB is the gate drive voltage for half-bridges A and B. This pin needs a 3.3-Ω isolation resistor
and a 0.1-µF decoupling capacitor.
• Pin 2 - VDD is the supply for internal voltage regulators AVDD and DVDD. This pin needs a 10-uF bulk
capacitor and a 0.1-µF decoupling capacitor.
• Pin 3 - Roc adjust is the overcurrent programming resistor. Depending on the application, this resistor can be
between 24 kΩ to 68 kΩ.
• Pin 4 - RESET pin when asserted, this pin keeps outputs Hi-Z and no PWM switching. This pin can be
controlled by a microprocessor.
• Pins 5 and 6 - These are PWM (+) and PWM (–) pins with signals provided by a PWM modulator such as
TAS5558. These are PWM differential pair.
• Pin 7 - Start up ramp capacitor should be 0.1 µF for BTL configuration.
• Pin 8 - Digital output supply pin is connected to 1-µF decoupling capacitor.
• Pins 9-12 - Ground pins are connected to board ground.
• Pin 13 - Analog output supply pin is connected to 1-µF decoupling capacitor.
• Pins 14 and 15 - These are PWM (+) and PWM (–) pins with signals provided by a PWM modulator such as
TAS5558. These are PWM differential pair.
• Pin 16 - Fault pin can be monitored by a microcontroller through GPIO pin. System can decide to assert reset
or shutdown.
• Pin 17 - Overtemperature warning pin can be monitored by a microcontroller through a GPIO pin. System can
decide to turn on fan or lower output power.
• Pin 18 - Output clip indicator can be monitored by a microcontroller through a GPIO pin. System can decide
to lower the volume.
• Pins 19-21 - Mode pins set the input and output configurations. For this configuration M1-M3 are grounded.
These mode pins must be hardware configured, such as, not through GPIO pins from a microcontroller.
• Pin 22 - GVDD_CD is the gate drive voltage for half-bridges C and D. It needs a 3.3-Ω isolation resistor and a
0.1-µF decoupling capacitor.
• Pins 23, 24, 43, 44 - Bootstrap pins for half-bridges A, B, C, and D. Connect 33 nF from this pin to
corresponding output pins.
• Pins 25, 26, 33, 34, 41, 42 - These ground pins should be used to ground decoupling capacitors from
PVDD_X.
• Pins 27, 28, 32, 35, 39, 40 - Output pins from half-bridges A, B, C, and D. Connect appropriate bootstrap
capacitors and differential LC filter as shown in Figure 16.
• Pins 29, 30, 31, 36, 37, 38 - Power supply pins to half-bridges A, B, C, and D. A and B form a full-bridge and
C and D form another full-bridge. A 470-uF bulk capacitor is recommended for each full-bridge power pins.
Two 0.22-µF decoupling capacitors are placed on each full-bridge power pins. See Figure 16 for details.
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8.2.1.3 Application Curves
200
3Ω
4Ω
8Ω
3Ω
4Ω
8Ω
180
160
1
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
0.1
140
120
100
80
60
40
20
0.01
TC = 75°C
THD+N at 10%
TC = 75°C
0.005
0.02
0.1
1
10
PO − Output Power − W
0
100 200
G001
Figure 17. Total Harmonic + Noise vs Output Power, 1 kHz
10
15
20
25
PVDD − Supply Voltage − V
30
35
G003
Figure 18. Output Power vs Supply Voltage vs Distortion +
Noise = 10%
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8.2.2 Typical PBTL Configuration
3.3R
+12V
GND
10uF
100 nF
100 nF
1
GVDD_AB
33 nF
BST_A 44
BST_B 43
2
VDD
3
OC_ADJ
GND 42
4
/RESET
GND 41
33 nF
R OC-ADJUST
/RESET
PWM_A
5
INPUT_A
OUT_A 40
PWM_B
6
INPUT_B
OUT_A 39
7
C_START
PVDD_AB 38
8
DVDD
PVDD_AB 37
9
GND
PVDD_AB 36
10µH
220 nF
100nF
220 nF
470 uF
10nF
10 GND
11 GND
12 GND
1uF
13 AVDD
14 INPUT_C
TAS5612LA
1uF
1 nF
100 nF
OUT_B 35
3R 3
10 µH
PVDD
GND
GND 34
GND 33
OUT_C 32
470 nF
3R 3
100 nF
10 µH
1 nF
PVDD_CD 31
10nF
/FAULT
/OTW
/CLIP
100 nF
15 INPUT_D
PVDD_CD 30
16 /FAULT
PVDD_CD 29
17 /OTW
OUT_D 28
18 /CLIP
OUT_D 27
19 M1
GND 26
20 M2
GND 25
21 M3
BST_C 24
22 GVDD_CD
BST_D 23
470 uF
220 nF 220 nF
33nF
10 µH
33nF
3.3R
Figure 19. Typical Differential (2N) PBTL Application With AD Modulation Filter
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8.2.2.1 Design Requirements
See Figure 19 for application schematic. In this application, one differential PWM input is used with AD
modulation from the PWM modulator such as the TAS5558. AD modulation scheme is defined as PWM(+) is
opposite polarity from PWM(-). The output PBTL configuration is often used to drive lower impedance load such
as a subwoofer.
8.2.2.2 Detailed Design Procedure
• Pin 1 - GVDD_AB is the gate drive voltage for half-bridges A and B. This pin needs a 3.3-Ω isolation resistor
and a 0.1-µF decoupling capacitor.
• Pin 2 - VDD is the supply for internal voltage regulators AVDD and DVDD. This pin needs a 10-µF bulk
capacitor and a 0.1-µF decoupling capacitor.
• Pin 3 - Roc adjust is the overcurrent programming resistor. Depending on the application, this resistor can be
between 24 kΩ to 68 kΩ.
• Pin 4 - RESET pin when asserted, this pin keeps outputs Hi-Z and no PWM switching. This pin can be
controlled by a microprocessor.
• Pins 5 and 6 - These are PWM (+) and PWM (–) pins with signals provided by a PWM modulator such as
TAS5558. These are PWM differential pair.
• Pin 7 - Start up ramp capacitor should be 0.1 µF for PBTL configuration.
• Pin 8 - Digital output supply pin is connected to 1-µF decoupling capacitor.
• Pins 9-12 - Ground pins are connected to board ground.
• Pin 13 - Analog output supply pin is connected to 1-uF decoupling capacitor.
• Pins 14 and 15 - These are PWM (+) and PWM (–) pins with signals provided by a PWM modulator such as
TAS5558. These are PWM differential pair.
• Pin 16 - Fault pin can be monitored by a microcontroller through GPIO pin. System can decide to assert reset
or shutdown.
• Pin 17 - Overtemperature warning pin can be monitored by a microcontroller through a GPIO pin. System can
decide to turn on fan or lower output power.
• Pin 18 - Output clip indicator can be monitored by a microcontroller through a GPIO pin. System can decide
to lower the volume.
• Pins 19-21 - Mode pins set the input and output configurations. For this configuration M1-M3 are grounded.
These mode pins must be hardware configured, such as, not through GPIO pins from a microcontroller.
• Pin 22 - GVDD_CD is the gate drive voltage for half-bridges C and D. This pin needs a 3.3-Ω isolation
resistor and a 0.1-µF decoupling capacitor.
• Pins 23, 24, 43, 44 - Bootstrap pins for half-bridges A, B, C, and D. Connect 33 nF from this pin to
corresponding output pins.
• Pins 25, 26, 33, 34, 41, 42 - These ground pins should be used to ground decoupling capacitors from
PVDD_X.
• Pins 27, 28, 32, 35, 39, 40 - Output pins from half-bridges A, B, C, and D. Connect appropriate bootstrap
capacitors and differential LC filter as shown in Figure 19.
• Pins 29, 30, 31, 36, 37, 38 - Power supply pins to half-bridges A, B, C, and D. A and B form a full-bridge and
C and D form another full-bridge. A 470-uF bulk capacitor is recommended for each full-bridge power pins.
Two 0.22-µF decoupling capacitors are placed on each full-bridge power pins. See Figure 19 for details.
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8.2.2.3 Application Curves
320
2Ω
3Ω
4Ω
280
260
240
1
0.1
220
200
180
160
140
120
100
80
60
40
0.01
0.005
0.02
0.1
1
10
PO − Output Power − W
100
TC = 75°C
THD+N at 10%
20
TC = 75°C
0
400
G011
Figure 20. Total Harmonic Distortion + Noise vs Output
Power
26
2Ω
3Ω
4Ω
300
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
10
15
20
25
PVDD − Supply Voltage − V
30
35
G012
Figure 21. Output Power vs Supply Voltage
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8.2.3 Typical SE Configuration
3 .3R
+12V
GND
10uF
100nF
100 nF
1
GVDD_ AB
BST_ A 44
2
VDD
BST_ B 43
33nF
* 85°C, Low ESR
33nF
ROC -ADJUST
3
OC_ ADJ
GND 42
/RESET
4
/RESET
GND 41
PWM_ A
5
INPUT_ A
OUT_ A 40
PWM _B
6
INPUT_ B
OUT_ A 39
7
C_START
PVDD_AB 38
8
DVDD
PVDD_AB 37
1 0uH
10nF
470 uF
1nF
1 µF
3R3
220 nF 220nF
1µF
9
GND
10 GND
11 GND
1 uF
12 GND
13 AVDD
14 INPUT_ C
PWM_C
3R3
1 µF
1nF
TAS5612LA
1 uF
470uF
PVDD_AB 36
470uF
OUT_ B 35
1 0uH
GND 34
10nF
* 85°C, Low ESR
PVDD
GND
* 85°C, Low ESR
GND 33
OUT_C 32
10 uH
10nF
470uF
PVDD_CD 31
1nF
PWM_ D
15 INPUT_ D
PVDD_CD 30
/FAULT
16 /FAULT
PVDD_CD 29
1µF
3R3
470uF
220 nF 220nF
/OTW
17 /OTW
OUT_D 28
/CLIP
18 /CLIP
OUT_D 27
100 nF
19 M 1
GND 26
20 M 2
GND 25
21 M 3
BST _C 24
22 GVDD_ CD
BST _D 23
3R3
1µF
1nF
470uF
33nF
10nF
10 uH
* 85°C, Low ESR
33nF
3 .3R
Figure 22. Typical (1N) SE Application
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8.2.3.1 Design Requirements
See Figure 22 for application schematic. In this application, four single-ended PWM inputs are used with AD
modulation from the PWM modulator such as the TAS5558. AD modulation scheme is defined as PWM(+) is
opposite polarity from PWM(-). The single-ended (SE) output configuration is often used to drive 4 independent
channels in one TAS5612LA device.
8.2.3.2 Detailed Design Procedure
• Pin 1 - GVDD_AB is the gate drive voltage for half-bridges A and B. This pin needs a 3.3-Ω isolation resistor
and a 0.1-uF decoupling capacitor.
• Pin 2 - VDD is the supply for internal voltage regulators AVDD and DVDD. This pin needs a 10-uF bulk
capacitor and a 0.1-uF decoupling capacitor.
• Pin 3 - Roc adjust is the overcurrent programming resistor. Depending on the application, this resistor can be
between 24 kΩ to 68 kΩ.
• Pin 4 - RESET pin when asserted, this pin keeps outputs Hi-Z and no PWM switching. This pin can be
controlled by a microprocessor.
• Pins 5 and 6 - These are PWM (+) and PWM (–) pins with signals provided by a PWM modulator such as
TAS5558. These are PWM differential pair.
• Pin 7 - Start up ramp capacitor should be 1 uF for SE configuration.
• Pin 8 - Digital output supply pin is connected to 1-uF decoupling capacitor.
• Pins 9-12 - Ground pins are connected to board ground.
• Pin 13 - Analog output supply pin is connected to 1-uF decoupling capacitor.
• Pins 14 and 15 - These are PWM (+) and PWM (–) pins with signals provided by a PWM modulator such as
TAS5558. These are PWM differential pair.
• Pin 16 - Fault pin can be monitored by a microcontroller through GPIO pin. System can decide to assert reset
or shutdown.
• Pin 17 - Overtemperature warning pin can be monitored by a microcontroller through a GPIO pin. System can
decide to turn on fan or lower output power.
• Pin 18 - Output clip indicator can be monitored by a microcontroller through a GPIO pin. System can decide
to lower the volume.
• Pins 19-21 - Mode pins set the input and output configurations. For this configuration M1-M3 are grounded.
These mode pins must be hardware configured, such as, not through GPIO pins from a microcontroller.
• Pin 22 - GVDD_CD is the gate drive voltage for half-bridges C and D. This pin needs a 3.3-Ω isolation
resistor and a 0.1-uF decoupling capacitor.
• Pins 23, 24, 43, 44 - Bootstrap pins for half-bridges A, B, C, and D. Connect 33 nF from this pin to
corresponding output pins.
• Pins 25, 26, 33, 34, 41, 42 - These ground pins should be used to ground decoupling capacitors from
PVDD_X.
• Pins 27, 28, 32, 35, 39, 40 - Output pins from half-bridges A, B, C, and D. Connect appropriate bootstrap
capacitors and differential LC filter as shown in Figure 22.
• Pins 29, 30, 31, 36, 37, 38 - Power supply pins to half-bridges A, B, C, and D. A and B form a full-bridge and
C and D form another full-bridge. A 470-uF bulk capacitor is recommended for each full-bridge power pins.
Two 0.22-µF decoupling capacitors are placed on each full-bridge power pins. See Figure 22 for details.
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8.2.3.3 Application Curves
80
2Ω
3Ω
4Ω
2Ω
3Ω
4Ω
60
1
PO − Output Power − W
THD+N − Total Harmonic Distortion + Noise − %
10
0.1
40
20
TC = 75°C
THD+N at 10%
0.01
TC = 75°C
0.005
0.02
0.1
1
10
PO − Output Power − W
0
100
G009
Figure 23. Total Harmonic Distortion + Noise vs Output
Power
10
15
20
25
PVDD − Supply Voltage − V
30
35
G010
Figure 24. Output Power vs Supply Voltage
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9 Power Supply Recommendations
The most important parameters are the absolute maximum rating on PVDD pins, bootstrap pins, and output pins.
Over stress the device with higher that maximum voltage rating may shorten device lifetime operation and even
cause device damage. Be sure that the specifications in Specifications are observed.
For best audio performance, low ESR bulk capacitors are recommended. Depending on the application 470-uF
capacitor or higher should be used. As always, decoupling capacitors must be placed no more than 1 mm from
the power supply pins. If PCB space is not allowed for close decoupling capacitor placement, the decoupling
capacitors can be placed on the back side of the device with vias. However, the device must be directly below
the pins.
10 Layout
10.1 Layout Guidelines
10.1.1 PCB Material Recommendation
FR-4 Glass Epoxy material with 1 oz. (35 μm) is recommended for use with the TAS5612LA. The use of this
material can provide for higher power output, improved thermal performance, and better EMI margin (due to
lower PCB trace inductance.
10.1.2 PVDD Capacitor Recommendation
The large capacitors used in conjunction with each full-bridge, 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 should support most
applications. The PVDD capacitors should be low ESR type because they are used in a circuit associated with
high-speed switching.
10.1.3 Decoupling Capacitor Recommendation
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, X5R or better 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 close decoupling capacitor 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 32.5-V power supply.
See to the TAS5614LADDVEVM User's Guide, SLAU375, for more details including layout and Bill of Materials.
10.1.4 Circuit Component and Printed-Circuit Board Recommendation
These requirements must be followed to achieve best performance and reliability and minimum ground bounce at
rated output power of TAS5612LA.
10.1.4.1 Circuit Component Requirements
A number of circuit components are critical to performance and reliability. They include LC filter inductors and
capacitors, decoupling capacitors and the heatsink. The best detailed reference for these is the TAS5612LA
EVM BOM in the users guide, which includes components that meet all the following requirements.
• High-frequency decoupling capacitors: small high frequency decoupling capacitors are placed next to the IC
to control switching spikes and keep high-frequency currents in a tight loop to achieve best performance and
reliability and EMC. They must be high quality ceramic parts with material like X7R or X5R and voltage
ratings at least 30% greater than PVDD, to minimize loss of capacitance caused by applied dc voltage.
(capacitors made of materials like Y5V or Z5U should never be used in decoupling circuits or audio circuits
because their capacitance falls dramatically with applied dc and ac voltage, often to 20% of rated value or
less.)
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Layout Guidelines (continued)
•
•
•
•
Bulk decoupling capacitors: large bulk decoupling capacitors are placed as close as possible to the IC to
stabilize the power supply at lower frequencies. They must be high quality aluminum parts with low ESR and
ESL and voltage ratings at least 25% more than PVDD to handle power supply ripple currents and voltages.
LC filter inductors: to maintain high efficiency, short-circuit protection and low distortion, LC filter inductors
must be linear to at least the OCP limit and must have low dc resistance and core losses. For SCP, minimum
working inductance, including all variations of tolerance, temperature and current level, must be 5 µH.
Inductance variation of more than 1% over the output current range can cause increased distortion.
LC filter capacitors: to maintain low distortion and reliable operation, LC filter capacitors must be linear to
twice the peak output voltage. For reliability, capacitors must be rated to handle the audio current generated
in them by the maximum expected audio output voltage at the highest audio frequency.
Heatsink: The heatsink must be fabricated with the PowerPAD contact area spaced 1.0 mm ±0.01 mm above
mounting areas that contact the PCB surface. It must be supported mechanically at each end of the IC. This
mounting ensures the correct pressure to provide good mechanical, thermal and electrical contact with
TAS5612LA PowerPAD. The PowerPAD contact area must be bare and must be interfaced to the PowerPAD
with a thin layer (about 1 mil) of a thermal compound with high thermal conductivity.
10.1.4.2 Printed Circuit Board Requirements
PCB layout, audio performance, EMC and reliability are linked closely together, and solid grounding improves
results in all these areas. The circuit produces high, fast-switching currents, and care must be taken to control
current flow and minimize voltage spikes and ground bounce at IC ground pins. Critical components must be
placed for best performance and PCB traces must be sized for the high audio currents that the IC circuit
produces.
Grounding: ground planes must be used to provide the lowest impedance and inductance for power and audio
signal currents between the IC and its decoupling capacitors, LC filters and power supply connection. The area
directly under the IC should be treated as central ground area for the device, and all IC grounds must be
connected directly to that area. A matrix of vias must be used to connect that area to the ground plane. Ground
planes can be interrupted by radial traces (traces pointing away from the IC), but they must never be interrupted
by circular traces, which disconnect copper outside the circular trace from copper between it and the IC. Top and
bottom areas that do not contain any power or signal traces should be flooded and connected with vias to the
ground plane.
Decoupling capacitors: high frequency decoupling capacitors must be located within 2mm of the IC and
connected directly to PVDD and GND pins with solid traces. Vias must not be used to complete these
connections, but several vias must be used at each capacitor location to connect top ground directly to the
ground plane. Placement of bulk decoupling capacitors is less critical, but they still must be placed as close as
possible to the IC with strong ground return paths. Typically the heatsink sets the distance.
LC filters: LC filters must be placed as close as possible to the IC after the decoupling capacitors. The capacitors
must have strong ground returns to the IC through top and bottom grounds for effective operation.
PCB copper must be at least 1 ounce thickness. PVDD and output traces must be wide enough to carry
expected average currents without excessive temperature rise. PWM input traces must be kept short and close
together on the input side of the IC and must be shielded with ground flood to avoid interference from high power
switching signals.
The heatsink must be grounded well to the PCB near the IC, and a thin layer of highly conductive thermal
compound (about 1mil) must be used to connect the heatsink to the PowerPAD.
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10.2 Layout Example
T5
T1
T2
T4
T3
T5
T6
Note T1: Bottom and top layer ground plane areas are used to provide strong ground connections. The area under
the IC must be treated as central ground, with IC grounds connected there and a strong via matrix connecting the
area to bottom ground plane. The ground path from the IC to the power supply ground through top and bottom layers
must be strong to provide very low impedance to high power and audio currents.
Note T2: Low impedance X7R or X5R ceramic high frequency decoupling capacitors must be placed within 2 mm of
PVDD and GND pins and connected directly to them and to top ground plane to provide good decoupling of high
frequency currents for best performance and reliability. Their dc voltage rating must be 2 × PVDD.
Note T3: Low impedance electrolytic bulk decoupling capacitors must be placed as close as possible to the IC.
Typically the heat sink sets the distance. Wide PVDD traces are routed on the top layer with direct connections to the
pins, without going through vias.
Note T4: LC filter inductors and capacitors must be placed as close as possible to the IC after decoupling capacitors.
Inductors must have low dc resistance and switching losses and must be linear to at least the OCP (over current
protection) limit. capacitors must be linear to at least twice the maximum output voltage and must be capacitorable of
conducting currents generated by the maximum expected high frequency output.
Note T5: Bulk decoupling capacitors and LC filter capacitors must have strong ground return paths through ground
plane to the central ground area under the IC.
Note T6: The heat sink must have a good thermal and electrical connection to PCB ground and to the IC PowerPAD.
It must be connected to the PowerPAD through a thin layer, about 1 mil, of highly conductive thermal compound.
Figure 25. Printed Circuit Board - Top Layer
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Layout Example (continued)
B1
B2
B1
Note B1: A wide PVDD bus and a wide ground path must be used to provide very low impedance to high power and
audio currents to the power supply. Top and bottom ground planes must be connected with vias at many points to
reinforce the ground connections.
Note B2: Wide output traces can be routed on the bottom layer and connected to output pins with strong via arrays.
Figure 26. Printed Circuit Board - Bottom Layer
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11 Device and Documentation Support
11.1 Trademarks
PurePath, PowerPAD are trademarks of Texas Instruments.
Blu-ray is a trademark of Blu-ray Disk Association (BDA).
All other trademarks are the property of their respective owners.
11.2 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.
11.3 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.
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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)
TAS5612LADDV
ACTIVE
HTSSOP
DDV
44
35
RoHS & Green
NIPDAU
Level-3-260C-168 HR
0 to 125
TAS5612LA
TAS5612LADDVR
ACTIVE
HTSSOP
DDV
44
2000
RoHS & Green
NIPDAU
Level-3-260C-168 HR
0 to 125
TAS5612LA
(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