TI TWL6040A2ZQZR

TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
8-CHANNEL HIGH_QUALITY LOW-POWER AUDIO CODEC
FOR PORTABLE APPLICATIONS
Check for Samples: TWL6040
FEATURES
1
•
•
2
•
•
•
•
•
•
•
•
•
•
Four audio digital-to-analog (DAC) channels
Stereo capless headphone drivers:
– Up to 104-dB DR
– Power tune for performance/power
consumption tradeoff
Stereo 8 Ω, 1.5 W per channel speaker drivers
Differential earpiece driver
Stereo line-out
Two audio analog-to-digital (ADC) channels:
– 96-dBA SNR
Four audio inputs:
– Three differential microphone inputs
– Stereo line-in/FM input
Two vibrator/haptics feedback channels:
– Differential H-bridge drivers
Two low-noise analog microphone bias
outputs
Two digital microphone bias outputs
Analog low-power loop from line-in to
headphone/speaker outputs
Dual phase-locked loops (PLLs) for flexible
clock support:
– 32-kHz sleep clock input for system
low-power playback mode
•
•
•
•
•
•
– 12-/19.2-/26-/38.4-MHz system clock input
Accessory plug/unplug detection, accessory
button press detection
Integrated power supplies:
– Negative charge pump for capless
headphone driver
– Two low dropout voltage regulators (LDOs)
for high power supply rejection ratio
(PSRR)
2
I C control
Thermal protection:
– Host interrupt
Power supplies:
– Analog: 2.1 V
– Digital I/O: 1.8 V
– Battery 2.3 to 5.5 V
Package 6-mm × 6-mm 120-pin PBGA
APPLICATIONS
•
•
•
Mobile and smart phones
MP3 players
Handheld devices
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
OMAP4 is a trademark of Texas Instruments.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
DESCRIPTION
The TWL6040 device is an audio coder/decoder (codec) with a high level of integration providing analog audio
codec functions for portable applications, as shown in Figure 1. It contains multiple audio analog inputs and
outputs, as well as microphone biases and accessory detection. It is connected to the OMAP4™ host processor
through a proprietary PDM interface for audio data communication enabling partitioning with optimized power
consumption and performance. Multichannel audio data is multiplexed to a single wire for downlink (PDML) and
uplink (PDMUL).
The OMAP4 device provides the TWL6040 device with five PDM audio-input channels (DL0–DL4). Channels
DL0–DL3 are connected to four parallel DAC channels multiplexed to stereo headphone (HSL, HSR), stereo
speaker (HFL, HFR), and earpiece (EAR) or stereo line outputs (AUXL, AUXR).
The stereo headphone path has a low-power (LP) mode operating from a 32-kHz sleep clock to enable more
than 100 hours of MP3 playback time. Very-high dynamic range of 104 dBA is achieved when using the system
clock input and DAC path high-performance (HP) mode. Class-AB headphone drivers provide a 1-Vrms output
and are ground centered for capless connection to headphone, thus enabling system size and cost reduction.
The earpiece driver is a differential class-AB driver with 2 Vrms capability to a typical 32-Ω load or 1.4 Vrms to a
typical 16-Ω load.
Stereo speaker path has filterless class-D outputs with 1.5-W capability per channel. For output power
maximization supply connection to an external boost is supported. Speaker drivers also support also hearing aid
coil loads. For vibrator and haptic feedback support, the TWL6040 has two PWM channels with independent
input signals from DL4 or inter-integrated circuit (I2C™).
Vibrator drivers are differential H-bridge outputs, enabling fast acceleration and deceleration of vibrator motor. An
external driver for a hearing aid coil or a piezo speaker requiring high voltage can be connected to line outputs.
The TWL6040 supports three differential microphone inputs (MMIC, HMIC, SMIC) and a stereo line-input (AFML,
AFMR) multiplexed to two parallel ADCs. The PDM output from the ADCs is transmitted to the OMAP4 processor
through UL0 and UL1. AFML, AFMR inputs can also be looped to analog outputs (LB0, LB1).
Two LDOs provide a voltage of 2.1 V to bias analog microphones (MBIAS and HBIAS). The maximum output
current is 2 mA for each analog bias, allowing up to two microphones on one bias. Two LDOs provide a voltage
of 1.8 V/1.85 V to bias digital microphones (DBIAS1 and DBIAS2). One bias generator can bias up several digital
microphones at the same time, with a total maximum output current of 10 mA.
The TWL6040 has an integrated negative charge pump (NCP) and two LDOs (HS LDO and LS LDO) for high
PSRR. The only external supply needed is 2.1 V, which is available from the 2.1-V DC-DC of the TWL6030
power management IC (PMIC) in the OMAP4 system. By powering audio from low-noise 2.1-V DC-DC of low
power consumption, high dynamic range and high output swing at headset output are achieved. All other supply
inputs can be directly connected to battery or system 1.8-V I/O.
Two integrated PLLs enable operatation from a 12/19.2/26/38.4-MHz system clock (MCLK) or, in LP playback
mode, from a 32-kHz sleep clock (CLK32K). The frequency plan is based on a 48-kS/s audio data rate for all
channels, and host processor uses sample-rate converters to interface with different sample rates (for example,
44.1 kHz). In the specific case of low-power audio playback, the 44.1-kS/s and 48-kS/s rates are supported by
the TWL6040. Transitions between sample rates or input clocks are seamless.
Accessory plug and unplug detections are
submitting send/end signal to the terminal
periodic accessory button press detection
properties can be programmed according to
supported (PLUGDET). Some headsets have a manual switch for
through the microphone input pin. This feature is supported by a
to minimize current consumption in sleep mode. Detection cycle
system requirements.
Figure 1 shows a simplified block diagram of the device.
Table 1. ORDERING INFORMATION
PART NUMBER
PACKAGE
ORDERING
MEDIUM
TWL6040
6-mm × 6-mm PBGA
TWL6040A2ZQZ/R
Reel
2
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
AAFL
VDDAMBIAS
HBIAS
HMBIAS
MBIAS
HMICP
HMICN
0:30 dB
MMBIAS
VDDUL
Uplink
VDDDMBIAS
DBIAS1
MMICN
ADCL
1
GNDAMIC
MMICP
MicAmpL
VSSUL
AAFR
DMBIAS1
GNDDMIC
MicAmpR
ADCR
1
SMICP
SMICN
DBIAS2
DMBIAS2
0:30 dB
LineInAmpR
UL0
UL1
DL0
PDMDN
PDMUP
PDMCLK
PDM
interface
PDMCLKLB
SDA
SCL
AFMR
LineInAmpL
DL1
DL2
LB0
AFML
DL3
–18:24 dB
DL4
PDMFRAME
GPO1(2,3)
LB1
EarDrv
GNDVCM
VDDEAR
EARP
Interface
EARN
–24:6 dB
HSLDrv
2
I C
registers
VSSEAR
HSL
PBKG
1
HSDACL
–30:0 dB
VDDV2V1
VDDLDO
HSRDrv
HSR
LS LDO
1
HSDACR
VDDDL
–30:0 dB
GNDLDO
AUXLN
CFLYP
CFLYN
Negative
charge
pump
AUXRP
Downlink
AUXRN
PGAL
NCPOUT
HFLDrv
NCPFB
VDDHFL
HFLP
Power
REF
REFP
REFN
VSSDL
AUXLP
VDDREGNCP
GNDNCP
VSSHS
GNDHS
HS LDO
VSSLDOIN
VSSLDO
VDDHS
1
Reference
temp
sense
HFLN
HFDACL
GNDHFL
–52:6 dB
PGAR
GNDREF
HFRDrv
VDDHFR
HFRP
PLUGDET
ACCONN
VDDVIO
Accessory
connector
detection
1
PDM
to
1 PCM
VDDPLL
MCLK
HFRN
HFDACR
8
8
HP PLL
PCM
to
PWM
8
CLK32K
VSSPLL
GNDHFR
–52:6 dB
VIBLDrv
VDDVIBL
VIBLP
1
VIBLN
1
GNDVIBL
LP PLL
Clock system
8
8
Osc
8
PCM
to
PWM
VIBRDrv
VDDVIBR
VIBRP
1
1
VIBRN
GNDVIBR
SWCS044-001
Figure 1. Simplified Block Diagram
Copyright © 2009–2011, Texas Instruments Incorporated
3
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
Table 2. Terminal Functions
NAME
BALL
TYPE
I/O (1)
MCLK
K7
Digital
I
System clock
CLK32K
H7
Digital
I
Real-time clock (RTC)
AUDPWRON
D8
Digital
I
Power-up signal
NRESPWRON
J9
Digital
I
Power-up reset
NAUDINT
E8
Digital
O
Interrupt
SDA
H6
Digital
I/O
I2C serial interface data
SCL
G6
Digital
I
I2C serial interface clock
PDMCLKLB
K8
Digital
I
PDM loopback clock
PDMCLK
L10
Digital
O
PDM reference clock
PDMFRAME
H8
Digital
I/O
PDM frame
PDMDN
K9
Digital
I
PDM downlink audio data
PDMUP
L8
Digital
O
PDM uplink audio data
HBIAS
J3
Power
O
Headset microphone bias supply
MBIAS
K3
Power
O
Main analog microphone bias supply
DBIAS1
J5
Power
O
Digital microphone 1st bias supply
DBIAS2
L4
Power
O
Digital microphone 2nd bias supply
MMICP
K1
Analog
I
Main microphone (+)
MMICN
J2
Analog
I
Main microphone (–)
SMICP
J4
Analog
I
Submicrophone (+)
SMICN
H4
Analog
I
Submicrophone (–)
HMICP
H1
Analog
I
Headset microphone (+)
HMICN
H2
Analog
I
Headset microphone (–)
AFML
F1
Analog
I
Auxiliary or FM radio left input
AFMR
F2
Analog
I
Auxiliary or FM radio right input
EARP
B10
Analog
O
Earphone output (+)
EARN
C11
Analog
O
Earphone output (–)
HSL
J11
Analog
O
Headset left output
HSR
K11
Analog
O
Headset right output
AUXLP
G3
Analog
O
Auxiliary predriver left output (+)
AUXLN
F3
Analog
O
Auxiliary predriver left output (–)
AUXRP
G4
Analog
O
Auxiliary predriver right output (+)
AUXRN
F4
Analog
O
Auxiliary predriver right output (–)
HFLP1
A4
Analog
O
Hands-free left output (+)
HFLP2
B4
Analog
O
Hands-free left output (+)
HFLN1
A5
Analog
O
Hands-free left output (–)
HFLN2
B5
Analog
O
Hands-free left output (–)
HFRP1
B9
Analog
O
Hands-free right output (+)
HFRP2
A9
Analog
O
Hands-free right output (+)
HFRN1
B8
Analog
O
Hands-free right output (–)
HFRN2
A8
Analog
O
Hands-free right output (–)
VIBLP
C1
Analog
O
Vibrator left output (+)
VIBLN
D3
Analog
O
Vibrator left output (–)
VIBRP
A2
Analog
O
Vibrator right output (+)
VIBRN
B1
Analog
O
Vibrator right output (–)
DESCRIPTION
Uplink Channel
Downlink Channel
(1)
4
I = Input; O = Output
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
Table 2. Terminal Functions (continued)
NAME
I/O (1)
BALL
TYPE
DESCRIPTION
VDDVREF
H5
Power
I
Reference system supply
VDDLDO
D1
Power
O
High-side LDO output
VDDEAR
B11
Power
I
Earphone positive supply
VDDHS
J10
Power
I
Headset positive supply
VDDUL
G2
Power
I
Uplink codec positive supply
VDDDL
E9
Power
I
Downlink codec positive supply
VDDPLL
J7
Power
I
PLL positive supply
VDDHFL1
A3
Power
I
Hands-free left positive supply
VDDHFL2
A6
Power
I
Hands-free left positive supply
VDDHFR1
A7
Power
I
Hands-free right positive supply
VDDHFR2
A10
Power
I
Hands-free right positive supply
VDDVIBL
C2
Power
I
Vibrator positive supply
VDDVIBR
B2
Power
I
Vibrator positive supply
VDDAMBIAS
L2
Power
I
Analog microphone bias supply
VDDDMBIAS
K4
Power
I
Digital microphone bias supply
VDDREGNCP
H11
Power
I
Negative charge pump positive
supply
VDDV2V1
E2
Power
I
Preregulated main positive supply
VDDVIO
L9
Power
I
Interface I/O supply
CFLYN
F11
Power
O
Flying capacitor negative terminal
CFLYP
G11
Power
O
Flying capacitor positive terminal
NCPOUT1
E10
Power
O
Negative charge pump output
NCPOUT2
E11
Power
O
Negative charge pump output
NCPFB
G9
Power
I
Negative SMPS feedback
VSSLDOIN
D11
Power
I
Low-side LDO input supply
VSSLDO
D10
Power
O
Low-side LDO output
VSSEAR
C10
Power
I
Earphone negative supply
VSSHS
H10
Power
I
Headset negative supply
VSSUL
G1
Power
I
Uplink negative supply
VSSDL
F9
Power
I
Downlink negative supply
VSSPLL
L7
Power
I
PLL negative supply
GN DREF
K5
Ground
I
Bandgap reference ground
GNDHS
H9
Ground
I
Headset sense input
GNDAMIC
H3
Ground
I
Analog microphone ground
GNDDMIC
L3
Ground
I
Digital microphone and accessory
ground
GNDLDO1
E3
Ground
I
HS and LS LDO ground
GNDLDO2
D9
Ground
I
HS and LS LDO ground
GNDVCM
J1
Ground
I
Codec ground
GNDNCP1
F10
Ground
I
Negative charge pump ground
GNDNCP2
G10
Ground
I
Negative charge pump ground
GNDHFL1
C5
Ground
I
Hands-free left driver ground
GNDHFL2
C4
Ground
I
Hands-free left driver ground
GNDHFL3
C6
Ground
I
Hands-free left driver ground
GNDHFR1
C7
Ground
I
Hands-free right driver ground
Positive Supplies
Negative Supplies
Ground
Copyright © 2009–2011, Texas Instruments Incorporated
5
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
Table 2. Terminal Functions (continued)
BALL
TYPE
I/O (1)
GNDHFR2
C8
Ground
I
Hands-free right driver ground
GNDHFR3
C9
Ground
I
Hands-free right driver ground
GNDDIG
J6
Ground
I
Digital ground
GNDVIBR
B3
Ground
I
Vibrator driver ground
GNDVIBL
D2
Ground
I
Vibrator driver ground
GNDIO
J8
Ground
I
General-purpose I/O ground
PBKG1
F5
Ground
I
Substrate package ground
PBKG2
F6
Ground
I
Substrate package ground
PBKG3
F7
Ground
I
Substrate package ground
PBKG4
E4
Ground
I
Substrate package ground
PBKG5
K10
Ground
I
Substrate package ground
REF
L5
Analog
I/O
Bandgap reference
REFP
K6
Analog
I/O
Positive converter reference
REFN
L6
Analog
I/O
Negative converter reference
ATEST
K2
Analog
O
Analog test pin
GPO1
D4
Digital
O
General-purpose output 1
GPO2
B6
Digital
O
General-purpose output 2
GPO3
B7
Digital
O
General-purpose output 3
DTEST1
A1
Digital
I
Digital test pin 1
DTEST2
L1
Digital
I
Digital test pin 2
DTEST3
A11
Digital
I
Digital test pin 3
PROG
L11
Digital
I
EEPROM programming pin
ACCONN
E1
Analog
I/O
PLUGDET
G5
Analog
I
NAME
DESCRIPTION
Miscallaneous
6
Accessory connector pin
Accessory plug detection pin
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
1
2
3
4
5
6
7
8
9
10
11
A
DTEST1
VIB
RP
VDD
HFL
HFLP
HFLN
VDD
HFL
VDD
HFR
HFRN
HFRP
VDD
HFR
DTEST3
B
VIB
RN
VDD
VIBR
GND
VIBR
HFLP
HFLN
GPO2
GPO3
HFRN
HFRP
EARP
VDD
EAR
C
VIB
LP
VDD
VIBL
GND
HFL
GND
HFL
GND
HFL
GND
HFR
GND
HFR
GND
HFR
VSS
EAR
EARN
D
VDD
LDO
GND
VIBL
VIB
LN
GPO1
AUDP
WRON
GND
LDO2
VSS
LDO
VSS
LDOIN
E
ACC
ONN
VDD
V2V1
GND
LDO1
PBKG
NAUD
INT
VDD
DL
NCP
OUT
NCP
OUT
F
AFML
AFMR
AUX
LN
AUX
RN
PBKG
PBKG
VSS
DL
GND
NCP
CFLYN
G
VSS
UL
VDD
UL
AUX
LP
AUX
RP
PLUG
DET
SCL
NCP
FB
GND
NCP
CFLYP
GND
AMIC
SMICN
VDD
VREF
SDA
CLK
32K
PDM
FRAME
GND
HS
VSS
HS
VDD
REG
NCP
GND
DIG
VDD
PLL
GND
IO
NRES
PWR
ON
VDD
HS
HSL
H
J
HMICP HMICN
GND
VCM
MMICN HBIAS
SMICP DBIAS1
PBKG
K
MMICP ATEST
MBIAS
VDD
DM
BIAS
GND
REF
REFP
MCLK
PDM
CLKLB
PDM
DN
PBKG
HSR
L
VDDA
DTEST2 MBIAS
GND
DMIC
DBIAS2
REF
REFN
VSS
PLL
PDM
UP
VDD
VIO
PDM
CLK
PROG
SWCS044-002
Figure 2. Pin Assignment (Top View)
Copyright © 2009–2011, Texas Instruments Incorporated
7
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
ABSOLUTE MAXIMUM RATINGS
Over operating free-air temperature range (unless otherwise noted)
Stresses beyond those listed below 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 below are not implied. Exposure to
absolute-maximum-rated conditions for extended periods may affect device reliability.
PARAMETER
TEST CONDITIONS
Supply voltage
MIN
TYP
MAX
UNIT
DC
–0.3
5.5
V
AC, 1000 spikes of
10 ms
–0.3
6
V
duration over 7 years
Ambient operating temperature
–30
85
°C
Storage temperature
–55
150
°C
Electrostatic discharge protection (HBM)
2
kV
Electrostatic discharge protection (CDM)
500
V
THERMAL CHARACTERISTICS (1)
Over operating free-air temperature range (unless otherwise noted)
PACKAGE
POWER (W)
RΘJA (°C/W)
RΘJB (°C/W)
RΘJC (°C/W)
BOARD TYPE
PBGA, 6mm x 6mm
0.4
34
22
8
2S2P
(1)
NOTE: The maximum power, 0.4 W, is at 85°C ambient temperature.
(a) RθJA (Theta-JA) = Thermal Resistance Junction-to-Ambient, °C/W
(b) RθJB (Theta-JB) = Thermal Resistance Junction-to-Board, °C/W
(c) RθJC (Theta-JC) = Thermal Resistance Junction-to-Case, °C/W
RECOMMENDED OPERATING CONDITIONS
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
MIN
NOM
MAX
UNIT
Supply voltage
VBAT
2.3
3.7
5.5
V2V1
2.039
2.127
2.205
VIO
1.747
1.823
1.89
Operating junction temperature range
–30
125
Operating ambient temperature range
–30
85
V
°C
CURRENT CONSUMPTION
Over operating free-air temperature range (unless otherwise noted)
PARAMETER
NOM
MAX
0.54
4.4
Deep-sleep mode: 1.8 V I/O present, other regulated supplies pulled down, plug
detection enabled, other modules disabled. From VBAT (3.8 V)
1.4
15.3
Sleep mode: all supplies present. No accessory connected, plug detection enabled,
other modules disabled. From VBAT (3.6 V)
2.4
17.6
15.2
40.5
Power-off mode: only battery supply present, other supplies pulled down. From VBAT
(2.3–5.5 V)
Sleep mode: all supplies present. Accessory connected, accessory unplug and button
press detections enabled, other modules disabled. From VBAT (3.6 V)
8
MIN
UNIT
µA
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
UPLINK MICROPHONE CHANNEL
Over operating free-air temperature range (unless otherwise noted)
UPLINK MICROPHONE CHANNEL
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
Single-ended or differential input swing 0 dBFs (THD > 40 dB)
2
Vpp
Single-ended or differential input slew rate
1
V/µs
0
dB
30
dB
–6
Programmable preattenuation
Programmable preamplifier gain
6
Programmable preamplifier gain step size
6
dB
Absolute gain accuracy
Gain = Min
–0.5
0.5
dB
Relative gain accuracy
Gain = Min to Max referenced to
gain = Min
–0.5
0.5
dB
Gain step size accuracy
Referenced to step = Typ
–0.25
0.25
dB
Gain variation with frequency
f = 20–20 kHz,
relative to f = 1 kHz
without external capacitor
–0.5
0.5
dB
200
240
kΩ
0 dBFs
–42
–40
–10 dBFs
–72
–70
–67
–65
–47
–45
Single-ended input resistance
160
Total harmonic distortion in 20–20 kHz bandwidth
–20 dBFs
Gain = Min, f = 1 kHz
–40 dBFs
Input referred idle channel noise (including
microphone bias and typical microphone biasing
circuitry)
–60 dBFs
–27
–25
20 Hz to 8 kHz, gain = 6 dB
10.9
14.8
20 Hz to 8 kHz, gain = 24 dB
2.5
3.3
20 Hz to 20 kHz, gain = 6 dB
13.6
18.6
20 Hz to 20 kHz, gain = 12 dB
6.7
9.6
20 Hz to 20 kHz, gain = 18 dB
4.1
5.6
3
4
20 Hz to 20 kHz, gain = 24 or 30 dB
Signal-to-noise ratio
Power supply rejection from VBAT
Antialias attenuation at Fs
Interchannel crosstalk and separation
20 Hz to 8 kHz, gain = 6 dB
92
98
20 Hz to 8 kHz, gain = 24 dB
86
92
20 Hz to 20 kHz, gain = 6 dB
90
96
20 Hz to 20 kHz, gain = 24 or 30 dB
84
90
dB(A)
µVrms(A)
dB(A)
Gain = Min
VBAT > 2.3 V, f < 1 kHz
74
VBAT > 2.3 V, f < 8 kHz
56
VBAT > 2.3 V, f < 20 kHz
48
VBAT > 2.5 V, f < 1 kHz
80
VBAT > 2.5 V, f < 8 kHz
62
VBAT > 2.5 V, f < 20 kHz
54
6-dB gain
15
22
24-dB gain
30
40
dB(A)
Input at 1 kHz and –20 dBFs
dB
60
dB
–80
–74
dB
60
45
dB
4
µs
Preamplifier Gain = 18 dB
Input-to-output leakage
Input at 1 kHz and 0 dBFs
Common mode rejection
20 Hz to 20 kHz
Delay
MicAmp input to McPDM output
Total uplink current from VBAT = 3.6 V
Mono
(with analog microphone load)
Stereo
Copyright © 2009–2011, Texas Instruments Incorporated
3
4.6
5.9
7.8
mA
9
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
ANALOG MICROPHONE BIAS
Over operating free-air temperature range (unless otherwise noted)
ANALOG MICROPHONE BIAS
PARAMETER
TEST CONDITIONS
Positive supply voltage (VDDAMBIAS)
At the pad
Negative supply voltage (GNDAMIC)
At the pad
Output voltage (VOUT)
Normal mode
2.06
2.1
2.14
Sleep mode
2.06
2.1
2.2
Normal mode
0
0.6
Sleep mode
0
Output current (IL)
Integrated noise
MIN
TYP
MAX
2.3
3.6
5
0
V
V
V
2
mA
0.2
mA
f = 20 Hz to 8 kHz
1.65
2.3 µVrms (P)
f = 20 Hz to 8 kHz
3
4 µVrms (A)
3.5
5 µVrms (A)
f = 20 Hz to 20 kHz
Power supply rejection from VDDAMBIAS
UNIT
IL = 0 to Max, Cf = Min to Max
VDDAMBIAS > 2.3 V, f < 1 kHz
74
VDDAMBIAS > 2.3 V, f < 8 kHz
56
VDDAMBIAS > 2.3 V, f < 20 kHz
48
VDDAMBIAS > 2.5 V, f < 1 kHz
80
100
VDDAMBIAS > 2.5 V, f < 8 kHz
62
80
VDDAMBIAS > 2.5 V, f < 20 kHz
54
Load transient
80% IL Max in 1 µs
Startup time
VOUT at 90%
Short-circuit current limit
Output shorted to ground
3
Output impedance in power-down mode
dc, with respect to GND
3
dB(A)
30
6
mV
200
µs
10
mA
VOUT from 0 to 2.1 V
MΩ
V2V1 enabled
Pulldown
DC, with respect to GND
Quiescent current
Normal mode, IL = 0–Max
200
Sleep mode, IL = 0–Max/10
200
300
10
20
Parasitic board capacitor Cp
200
External filter resistor value Rf
External filter capacitor value Cf
Ceramic capacitor
External capacitor ESR
f = 100 kHz
Biasing resistance Rb
Microphone equivalent resistance Rm
10
Ω
µA
pF
185
200
215
Ω
0
220
250
nF
6
Ω
2.09
2.2
2.31
kΩ
1
3
6
kΩ
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
DIGITAL MICROPHONE BIAS
Over operating free-air temperature range (unless otherwise noted)
DIGITAL MICROPHONE BIAS
PARAMETER
TEST CONDITIONS
Positive supply voltage (VDDDMBIAS)
At the pad
Negative supply voltage (GNDDMIC)
At the pad
Output dc voltage (VOUT)
Normal mode, IL = 0 to Max
Sleep mode, IL = 0 to Max/10
Output current (IL)
Power supply rejection from VDDDMBIAS
MIN
TYP
MAX
2.3
3.6
5
0
1.8
1.85
1.8
1.85
1.9
10
IL = 200 µA to Max, normal mode
VOUT = 1.8 V, f < 20 kHz
80% IL Max in 1 µs
Output impedance in power-down mode
DC, with respect to GND
1
Short-circuit current limit
Output shorted to ground
20
Quiescent current
Normal mode
30
External capacitor value
External capacitor ESR
0.9
mA
mV
MΩ
600
µs
30
40
mA
20
30
7
10
2.2
3.3
µF
0.6
Ω
0.02
Ω
MAX
UNIT
Startup time
Sleep mode
V
dB(A)
40
Load transient
V
V
1.75
0
UNIT
f < 100 kHz
1 MHz < f < 10 MHz
µA
ANALOG LOOP, LINE-IN TO HEADPHONE OUTPUT
Over operating free-air temperature range (unless otherwise noted)
ANALOG LOOP, LINE-IN TO HEADPHONE OUTPUT
PARAMETER
TEST CONDITIONS
MIN
Programmable gain range in line-in amplifier
42
–18
Programmable gain in line-in amplifier
Programmable gain step size
dB
24
dB
60
kΩ
6
Single-ended input resistance
40
Maximum input voltage (0 dBFs)
For single-ended input
Total analog loop SNR output
Gain = 0 dB, 0.5 Vrms signal
Total analog loop THDN at FS
Total stereo analog loop path quiescent current
85% DC 3.8-V Vbat
Copyright © 2009–2011, Texas Instruments Incorporated
TYP
50
dB
2
Vpp
90
dB(A)
LineG = 6 dB, HSDrvG = 0 dB,
output = 1 Vrms
–66
dB
From VBAT = 3.8 V
2.5
3.5
mA
11
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
DOWNLINK (DAC) CHANNEL TO HEADPHONE OUTPUT
Over operating free-air temperature range (unless otherwise noted)
DOWNLINK (DAC) CHANNEL TO HEADPHONE OUTPUT
PARAMETER
TEST CONDITIONS
Speaker load resistance (RL)
Single-ended output swing 0 dBFs (THD > 40
dB, –4 dB analog gain in HP mode and –2-dB
gain in LP mode)
at the ball RL + Rf = 32 + 15 = 47 Ω
at the load RL + Rf = 32 + 15 = 47 Ω
MIN
TYP
16
32
UNIT
Ω
1
Vrms
0.7
–30
Programmable gain range
MAX
Programmable gain step size
0
2
dB
dB
Absolute gain accuracy
Gain = Max
–0.5
0.5
dB
Relative gain accuracy
Relative to gain = Max
–0.5
0.5
dB
–0.25
0.25
dB
–0.85
–0.6
dB
Gain step size accuracy
Gain variation with frequency
f = 20 Hz to 20 kHz, gain = Min to
Max
–1.1
relative to 1 kHz at the ball
Idle channel noise
LP mode, at the ball
10
14
Gain = Max
HP mode, at the ball
6
9
Dynamic range
HP mode
104
µVrms(A)
dB(A)
–60-dBFs output with –4-dB analog gain
Dynamic range
LP mode
100
103
–60-dBFs output with –30-dB analog gain
HP mode
105
108
Signal-to-noise ratio
–1-dBFs output, LP mode
94
97
–1-dBFs output, HP mode
98
101
–10-dBFs output, LP mode
86
89
–10-dBFs output, HP mode
90
93
.
dB(A)
dB(A)
–40
Total harmonic distortion in 20 Hz–20 kHz
bandwidth
0 dBFs
–10 dBFs
–70
(sine-wave @1 kHz, gain = Max)
–20 dBFs
–56
–40 dBFs
–36
–60 dBFs
–16
THD+N
RL = 32 Ω, Pload = 20 mW (–2.5
dBFS)
Power supply rejection from VBAT
Gain = Max, 217 Hz TDMA pulse
noise
80
HS reference GNDHS noise rejection
f = 1 kHz, 10 mVrms amplitude
40
0.012
100
Group delay
Offset
0.1
After system compensation
%
dB(A)
7.1
From stand-alone IC
dB(A)
–16
16
–2
2
µs
mV
L/R gain mismatch
at 0 dBFs, 1 kHz
–0.5
0.5
dB
L/R phase mismatch
at 0 dBFs, 1 kHz
–10
10
degrees
L/R cross-talk
at 0 dBFs, 1 kHz
Output impedance
Driver and pulldown disabled
Average playback current from VBAT
LP mode
5.3
7
HP mode
7.4
9.23
12
–60
1
dB
MΩ
mA
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
EARPHONE PATH SPECIFICATION
Over operating free-air temperature range (unless otherwise noted)
EARPHONE PATH SPECIFICATION
PARAMETER
TEST CONDITIONS
Speaker load resistance (RL)
Output differential swing 0 dBFs (THD > 40 dB)
at 6-dB analog gain
MIN
TYP
MAX
16
32
100
Ω
RL = Typ
2
Vrms
RL = Min
1.42
Vrms
–24
Programmable gain range
Programmable gain step size
Absolute gain accuracy
UNIT
6
2
Gain = Max
–0.5
dB
dB
0.5
dB
Relative gain accuracy
–0.5
0.5
dB
Gain step size accuracy
–0.25
0.25
dB
–0.55
0.3
dB
32
45
µVrms(A)
Gain variation with frequency
f = 20 Hz to 20 kHz, relative to 1
kHz
Idle channel noise
f = 20 Hz to 20 kHz
Dynamic range, –60-dBFs output with –24-dB
analog gain
–0.8
87
87
97
dB(A)
SNR, 0-dBFs output
f = 20 Hz to 20 kHz
Total harmonic distortion
0 dBFs
–60
97
–40
dB(A)
(sine wave @1 kHz, gain = Max)
–10 dBFs
–70
–60
–20 dBFs
–70
–60
–40 dBFs
–50
–40
–60 dBFs
–30
–20
THD+N
RL = TYP, 0 dBFS output
0.02
0.1
THD+N
RL = TYP, –6 dBFS output
0.015
0.1
–25
Differential offset
Power supply rejection from VBAT
Group delay
Average current from VBAT
Copyright © 2009–2011, Texas Instruments Incorporated
Gain = Max
80
25
100
SINC filter
3.7
%
mV
dB(A)
4.125
FIR filter
dB(A)
µs
1
µs
4.8
mA
13
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
AUX-OUTPUT PATH SPECIFICATION
Over operating free-air temperature range (unless otherwise noted)
AUX-OUTPUT PATH SPECIFICATION
PARAMETER
TEST CONDITIONS
Load resistance (RL)
Output differential swing 0 dBFs (THD > 40 dB)
RL = Typ
MIN
TYP
10
150
dB
2
dB
–1.0
1.0
dB
–0.25
0.25
dB
Gain = –40 to –50 dB
–0.5
0.5
dB
Gain = 6 to –40 dB
–0.5
0.5
dB
Gain = –40 to –50 dB
–1.0
1.0
dB
f= 20 Hz to 20 kHz relative to 1 kHz
–0.5
0.5
dB
Absolute gain accuracy
Gain = 0 dB
Gain step size accuracy
Gain = 6 to –40 dB
Gain variation with frequency
Vrms
58
Programmable gain step size
UNITS
kΩ
1.7
Programmable gain range
Relative gain accuracy
MAX
Gain = 0 dB
Dynamic range, –60-dBFs output with –24-dB
analog gain
SNR, 0-dBFs output
87
90
dB(A)
80
90
dB(A)
10-kΩ load, HFPGA = 0 dB, 1-kHz
signal
THD+N
Idle channel noise
14
1-Vpp single-ended output
0.07
2-Vpp single-ended output
0.4
1-Vpp differential output
0.07
2-Vpp differential output
0.4
40
%
50
µVrms(A)
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
HANDS-FREE PATH SPECIFICATION
Over operating free-air temperature range (unless otherwise noted)
HANDS-FREE PATH SPECIFICATION
PARAMETER
TEST CONDITIONS
Input supply
Battery
MIN
TYP
2.3
5
SMPS boost
Maximum output power (PGA = 0 dB)
5.5
VDDHF = 5.5 V (THD > 40 dB)
1.3
VDDHF = 4.5 V (THD > 40 dB)
0.9
1
VDDHF = 3.6 V (THD > 40 dB)
0.55
0.6
VDDHF = 2.8 V (THD > 40 dB)
0.24
0.28
VDDHF = 2.3 V (THD > 30 dB)
0.15
0.2
Gain = 0 dB
Relative gain accuracy
Gain = 6 to –40 dB
Gain = –40 to –50 dB
Gain = 6 to –40 dB
Gain = –40 to –50 dB
f = 20 kHz relative to 1 kHz
Dynamic range, –60-dBFs output with –24-dB
HFPGA gain
Idle channel noise
Gain = –24 dB
Total harmonic distortion in f = 20 Hz to 20 kHz
RL = 8 Ω, VDDHF > 3.6 V
(sine wave @ 1 kHz, 0-dB PGA gain setting)
Carrier frequencey
Average quiescent current from VBAT
Copyright © 2009–2011, Texas Instruments Incorporated
W
6
2
Absolute gain accuracy
Power supply rejection from VBAT
V
1.5
–52
Programmable gain step size (PGA)
Gain variation with frequency
UNIT
RL = 8 Ω
Programmable gain range (PGA)
Gain step size accuracy
MAX
dB
–1
1
–0.5
0.5
–1
1
–0.25
0.25
–0.5
0.5
–1.25
–1
85
93
dB
–0.75
dB
dB
dB
dB
dB(A)
65
170
µVrms(A)
25 mW < POUT < 0.5 W
–55
–50
dB(A)
1 mW < POUT < 25 mW
–45
–40
Gain = 0 dB
Idle channel
55
Intermodulation
70
dB(A)
65
80
dBc
19.6 MHz PDM clock
384
kHz
17.64 MHz PDM clock
353
Mono
2
kHz
3
mA
15
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
VIBRA DRIVER PATHS
Over operating free-air temperature range (unless otherwise noted)
VIBRA DRIVER PATHS
PARAMETER
TEST CONDITIONS
Input supply VDD
Battery or SMPS boost
DC output voltage
Left channel, RL = 16 Ω
MIN
TYP
2.3
MAX
5.5
VDDVIB = 4.8 V
3.3
3.6
VDDVIB = 3.8 V
2.6
2.9
VDDVIB = 2.5 V
1.6
1.7
VDDVIB = 4.8 V
3.6
3.9
VDDVIB = 3.8 V
2.7
3
VDDVIB = 2.3 V
1.6
1.8
UNIT
V
V
Right channel, RL = 8 Ω
–0.5
Absolute gain accuracy
Voltage step
V
0.5
50
–0.5
Gain variation with frequency
f = 250 Hz to 8 kHz relative to 1 kHz
Total harmonic distortion in f = 20 Hz to 8 kHz
RL = 8 Ω, VDD > 3.6 V, –1 dBVrms
Latency
PDM input
20.8
PCM input
10.4
Load resistance RL
Average quiescent current from VBAT
8
Mono
dB
mV
0
0.5
dB
–35
–30
dB(A)
µs
Ω
16
1
1.5
TYP
mA
INPUT CLOCK PARAMETERS
Over operating free-air temperature range (unless otherwise noted)
SYSTEM CLOCK
PARAMETER
TEST CONDITIONS
Input frequency accuracy
Square wave
Input swing
Input SSB phase noise @ 1 kHz
Sine wave, input common mode 0.5
to 0.7 V
MAX
UNIT
–100
MIN
100
ppm
1.65
1.89
V
0.4
1
Vpp
12 MHz
–89
–86
19.2 MHz
–86
–83
26 MHz
–83
–80
38.4 MHz
–80
–77
TYP
MAX
UNIT
1000
ppm
dBc/Hz
SLEEP CLOCK
Over operating free-air temperature range (unless otherwise noted)
SLEEP CLOCK
PARAMETER
TEST CONDITIONS
MIN
Input frequency
32,768
–1000
Input frequency accuracy
Input duty cycle
Input SSB phase noise
Input integrated jitter
16
40
Hz
60
@ 100Hz
–108
–105
@ 1 kHz
–128
–125
20 Hz to 20 kHz flat
0.61
0.86
80 Hz to 20 kHz flat
0.31
0.43
%
dBc/Hz
nsrms
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
APPLICATION INFORMATION
UPLINK PATH DESCRIPTION
The voice uplink path includes two low-noise input amplifier stages (MicAmpL and MicAmpR) and two ADCs
dedicated to the three microphone inputs and stereo auxiliary/FM inputs. Two low-power input amplifiers
(LineInAmpL and LineInAmpR) enable stereo analog loops (LB0, LB1) to the downlink section, independent and
concurrent with stereo microphone uplink to OMAP4. The auxiliary/FM radio left and right channels can be
connected to the microphone preamplifiers for recording, or to a line-in amplifier for direct analog loop to
downlink drivers, or simultaneously to both.
Analog microphone bias outputs, MBIAS and HBIAS, have a dedicated supply pin (VDDABIAS), which can be
connected to the battery or to an external boost. If full PSR performance is required in a system with minimum
battery level below 2.5 V, the latter connection is recommended.
Microphone bias blocks can be set to sleep mode for low quiescent current consumption. In sleep mode, only the
output voltage specification is ensured with the specified sleep mode load current.
Mapping of analog inputs to uplink data channels UL0 and UL1 connected to the OMAP4 is indicated in the
following table:
UL0
Main microphone, MMIC
UL1
LB0
LB1
X
SubMicrophone, SMIC
X
Headset microphone, HSMIC
X
Left auxiliary/FM radio
X
X
X
Right auxiliary/FM radio
X
X
For microphone bias connection, if the negative terminal of the microphone is available, which is usually the case
for device internal microphones, the board schematic for a fully differential input shown in Figure 3 is proposed.
This approach minimizes differential coupling but provides almost no rejection from bias noise voltage (MBIAS).
200 W
220 nF
50 W
1 kW
100 nF
MBIAS
MMICP
SMICP
1 nF
50 W
1 nF
100 nF
1 kW
Reference
point
MMICN
SMICN
GNDAMIC
SWCS044-004
Figure 3. Board With Available Negative Terminal
If the negative terminal of the microphone is not available (that is, it is directly connected to ground), which is
usually the case for accessory microphones, the board schematic for a pseudodifferential input shown in Figure 4
is suggested. This approach can suffer from differential coupling, but provides good rejection from bias noise
voltage (HBIAS).
Copyright © 2009–2011, Texas Instruments Incorporated
17
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
200 W
HBIAS
100 nF
220 nF
HMICP
50 W
2.2 kW
HMICN
1 nF
100 nF
Reference
point
GNDAMIC
SWCS044-005
Figure 4. Board With Unavailable Negative Terminal
In all board layouts, the star connection of all the ground lines to a single via to the ground plane (reference
point) is highly recommended to minimize degradation from unequal potential grounds.
The schematics and component values in Figure 3 and Figure 4 are general proposals and may not be the
optimal choice for specific user applications.
Two LDOs provide an external voltage of 1.8/1.85 V to bias digital microphones (DBIAS1 and DBIAS2). One bias
generator can bias several digital microphones at the same time, with a total maximum output current of 10 mA.
Digital microphone inputs and clocks are supported by OMAP.
DOWNLINK PATH DESCRIPTION
Mapping of audio data inputs from the OMAP4 to audio driver outputs is shown in the following table.
DL0
Earphone
DL1
DL2
DL3
DL4
I2C or Frame (1)
Left headset
X
Right headset
X
Left hands-free
Right hands-free
LB1
X
X
X
X
X
Left auxiliary
X (3)
Right auxiliary
X (3)
X
X
X
X
X (3)
X
Right vibrator
X
X
Left vibrator
X
X
(1)
(2)
(3)
LB0
X (2)
The frame line can be used for register write (for example, vibrator data registers) in command mode.
This path cannot be concurrent with L/R headset paths.
These paths can be concurrent, but not independent of L/R hands-free paths.
Headphone/Headset Paths
For music playback, the analog headset path can be configured in two different modes:
• Low-power mode (LP)
• High-performance mode (HP)
The LP mode system is designed to maximize playback time while maintaining better audio performance than
provided by current compression algorithms. The only input clock required in this mode is the RTC at 32,768 Hz.
The HP mode improves the dynamic range (DR) performance by 5 dB with tradeoff of increased current
consumption compared to LP mode. A high-quality clock (that is, generated by VTCXO) is required in this mode.
The headset path modules (DAC and HS driver) can be individually set in LP and HP modes.
18
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
www.ti.com
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
The DAC is followed by a class AB single-ended HS driver, to provide a signal up to 1 Vrms at the ball.
Programmable analog attenuation is available in the HS driver. The overall gain of the system is segmented
between this analog gain and the digital gain of the application processor, with a minimum step of 0.1 dB. The
HS path can drive headphone or line-out loads. Optional EMC or ESD protection circuitry can be inserted
between the stereo HS driver and the load connector, without performance degradation at the ball. A single
ground feedback is brought star connected from the connector ground to the stereo HS driver feedback.
Hands-Free/Speaker Paths
Hands-free/speaker drivers can be connected to a battery or to an external boost. To reach 1-W output power
from a mono speaker, a boosted supply equal to or greater than 4.5 V is recommended.
The board can be designed without an output filter if the traces from the TWL6040 to hands-free (HF) speakers
are short. A ferrite bead filter can be used if the board design is failing radiated emission. In both cases, the
audio performance is maintained.
There is a short-circuit protection for HF amplifiers to limit power dissipation. A short circuit can exist between
output terminals, output and ground, or output and battery.
Short circuit detection in at least one of the two drivers automatically disables both HF drivers and generates an
interrupt.
Vibra Paths
Two high-efficiency differential drivers, capable of driving rotational, linear multifunction vibrator devices, are
provided. Each vibrator can be independently supplied by an external power source. The left vibrator driver
RDSON is optimized for a 16-Ω equivalent load, whereas the right vibrator driver RDSON is optimized for an 8-Ω
equivalent load (higher current). Loads with higher equivalent resistance value than stated above are also
supported.
Each of the vibrators can be driven through PDM or PCM data. The PDM data comes from the 5th downlink
channel. The PCM data can be sent through the PDM interface command mode at a maximum rate of 48 kS/s,
or through the I2C interface for near DC signal. Better than 8-bit resolution on lower bandwidth can be achieved
through the PCM signal by averaging the data.
There is no analog or digital gain in the TWL6040 vibrator paths; that is, the signal amplitude is entirely set in the
digital companion IC.
Similar to the hands-free drivers, there is a short-circuit protection for vibrator drivers to limit power dissipation if
the current exceeds 500 mA in any of the output transistors. Short-circuit detection in at least one of the two
drivers automatically disables both vibrator drivers and generates an interrupt.
External Boost
An external boost can be used to supply the following functions:
• Hands-free stereo drivers
• Left and right vibrator drivers
• Main and headset microphone biasing LDOs
Any of the corresponding modules in the TWL6040 device can be independently powered by the battery or by
the output of this external boost.
The external boost should provide a minimum output voltage of 4.5 V to allow each HF driver to deliver a typical
2-W peak power into an 8-Ω load. Larger output voltage values enable more output power in the HF loads, but it
must not exceed 5.5 V dc for reliability reasons.
By default, the two HF drivers work in phase quadrature (90-degree phase shift) to reduce the rms load current.
Figure 5 shows the stereo HF load current waveforms for worst-case (close to 100% modulation or 4-W stereo
output power) and typical (less than 50% modulation or 1-W stereo output). Figure 5 also indicates the driver
sinking the current (left or right).
Copyright © 2009–2011, Texas Instruments Incorporated
19
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
I(A)
1.0
A)
L/R
0.5
L/R
2.6 ms
L/R
L/R
L/R
0.0
T(s)
I(A)
2.6 ms
B)
0.2
L
R
L
R
L
R
0.0
T(s)
SWCS044-006
Figure 5. Current Load Waveforms, Worst-Case A) and Typical B)
The following table shows the external boost SMPS recommendations.
Parameter
Test Conditions
Input voltage
at the ball
Min
Typ
2.3
Output voltage
4.5
Output current
0.003
Output peak power
Stereo HF
Strereo HF + mono Vibra
Output average power
(1)
Stereo HF
Strereo HF + mono Vibra
Efficiency
IL=3 mA to 1.3 A
80
f = 217 Hz
Output current limit for short-circuit detection
(1)
20
20
Units
5.0
V
5
V
1.25
A
4.5
W
5.625
W
0.31
W
0.4
W
4
ms
90
Start-up time
Power supply rejection from VBAT
Max
%
30
dB
1.6
A
The Max/Typ ratio is based on 12-dB crest factor audio signal.
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
ACCESSORY DETECTIONS
The standard connector is shown in Figure 6, and has the following terminals:
1. Left headset speaker input
2. Right headset speaker input
3. Microphone input
4. Ground return for speakers and microphone
5. Open/ground switch input
4
2
1
3
5
SWCS044-007
Figure 6. Standard Connector
The TWL6040 is compatible with a system supporting the standard 2.5-mm and 3.5-mm audio-jack connector
shown in Figure 7:
Jack
No Mic
L
R G
With Mic
L R M G
Stereo
SWCS044-008
Figure 7. Standard 2.5-mm and 3.5-mm Audio-Jack
With proper board wiring TWL6040 is compatible also with L-R-G-M -jack.
The TWL6040 is not compatible with the 2.5-mm and 3.5-mm audio-jack connectors shown in Figure 8. If this
type of connector is inserted, the system performances and/or functionality are not assured, but the TWL6040 is
not damaged.
¼-Inch Jack
No Mic
L
G
With Mic
LM
G
Mono
SWCS044-009
Figure 8. Incompatible 2.5-mm and 3.5-mm Connectors
Plug Detection
The TWL6040 supports plug detection through a mechanical switch closing to ground when a connector is
inserted. The plug detection is implemented as a simple comparator with a pullup resistance. The comparator
output is debounced to avoid false detection due to perturbation, such as ESD events. When a plug or unplug
event is detected, interrupt signal PLUGINT is generated. The maximum value of the plug resistance Rp is 10 Ω.
Figure 9 shows the plug-detection circuit.
Copyright © 2009–2011, Texas Instruments Incorporated
21
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
VDDVIO
5
Ru
Rp
PLUGDET
SWCS044-010
Figure 9. Plug Detection Circuit
Send/End Button Detection
Some headsets have a manual switch for submitting send/end signals to the terminal through the microphone
input pin. The two possible configurations are:
• The button switch is parallel to the microphone (most common).
• The button switch is in series with the microphone.
The two configurations are shown in Figure 10.
Case
Case
Rm
Rs
Button
Rs
Rm
Button
1-parallel configuration
2-serial configuration
SWCS044-011
Figure 10. Manual Switch Configuration
In both configurations, the detection is based on an impedance detection involving the microphone. The
detection is assured for a maximum Rs of 100 Ω and a microphone having a current-to-voltage transfer function
within the mask described in Figure 11.
I
600 mA
100 mA
0.6 V
V
SWCS044-012
Figure 11. Microphone Current-to-Voltage Transfer Function
22
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
Two detection mechanisms are implemented on the TWL6040 to address the parallel and serial hook
configurations. By default, these detections are concurrent, but they can be independently disabled by the
HKPARADIS bit in register HKCTL1 and the HKSERDIS bit defined in register HKCTL2.
In the parallel configuration for send-event detection, the VDDV2V1 supply pulls up the bias resistance Rb to 2.1
V, while the microphone bias amplifier is in high-impedance output mode. It also provides a threshold Vth1 for the
hook comparator COMP1 through a resistor divider. This comparator is used to detect the short of the
microphone bias. The detection analog block diagram is described in Figure 12, and the entire system is
powered from the VDDV2V1 supply. During settling and comparison, switch Ri is closed and as much as 600 µA
can flow from VDDV2V1 to the microphone, and up to 1.1 mA if the button is pressed.
The same mechanism is used for end-event detection, except that the LDO HBIAS is already biasing the
microphone, and VDDV2V1 is used only as a supply for the comparator.
VDDV2V1
Ri
HKUPEN
Cf
HBIAS
Rf
HBIAS
HMICP
HKSEREN
Vth2
EN
COMPOUT
–
+
HKCOMP2
HKCOMP1
EN
+
–
Rb
3
HMICN
Vth1
HKPARAEN
ACCONN
GNDAMIC
SWCS044-013
Figure 12. Parallel/Serial Configuration Detection
The detection is performed with a duty cycle compatible with system quiescent-current requirements and timing
of the mechanical short. The sequence is programmed by setting three parameters based on the RTC clock:
• Interval period between detection trials
• Settling time (dependent on external RC filter)
• Debounce time for comparison
The minimum recommended duration consists of eight clock cycles for settling and eight clock cycles to
debounce the output of the comparator. With one detection every 100 ms, this on-duration allows a duty cycle
smaller than 1/500 and a minimum sleep current. Figure 13 shows the timing diagram.
Copyright © 2009–2011, Texas Instruments Incorporated
23
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
HKRATE
periods
HKSET
periods
HKSET
periods
HKDBNC
periods
HKDBNC
periods
CLK
HKEN
ACONN
COMPOUT
COMPINT
1 1 1 1 1 1 1 1
1 1 1 1 0
HOOKINT
SWCS044-016
Figure 13. Detection Timing
In end event mode detection, when the HMBIAS module is enabled, the duty cycle is disabled and the analog
module detection is always on to avoid transient perturbations coupling to the uplink channel. The duty cycle in
this mode can be restored by setting HKSWEN high.
The same detection scheme can be used for serial configuration. The comparator HKCOMP2 can work
synchronously with HKCOMP1 and their output can be combined before the debounce function.
When a send event is detected, an interrupt signal is generated and the switch between VDDV2V1 and
PAD_MBIAS is disabled. For end event detection, an interrupt signal is generated.
CLOCK SYSTEM
The frequency plan is based on a 48 kS/s audio data rate for all channels. The data converters use a fixed
oversampling ratio (OSR) equal to 80 (3.84 MHz). The audio data PDM interface runs at five times the OSR rate,
using a clock equal to 19.2 MHz. The application companion uses sample rate converters to interface with other
sample rates (for example, 44.1 kHz).
In the specific case of low-power audio playback (LP mode), where only the headphone path is active, the
TWL6040 supports the 44.1 kS/s and 48 kS/s rates. The ratio between audio sample rate, data converter clock,
and PDM clock remains the same.
The high-quality input clock MCLK from the system can have the following values: 12, 19.2, 26, or 38.4 MHz.
The input waveform can be a sine wave or a square wave. If the clock frequency is equal to 19.2 or 38.4 MHz,
the clock can be directly divided and level-shifted. If MCLK is 12 MHz or 26 MHz, the high frequency input PLL
(HF PLL) generates a 19.2 MHz signal from the MCLK, compatible with the requirement for HS quality in high
performance (HP) mode. A clock slicer is inserted between the MCLK input pad and the HF PLL.
The low frequency input PLL (LF PLL) generates a 17.64 MHz or 19.2 MHz signal from the RTC at 32,768 Hz
(CLK32K), compatible with the requirement for MP3 playback in low power (LP) mode. In all cases, the input
reference clock must meet the phase-noise performance described in INPUT CLOCK PARAMETERS.
Figure 14 shows the clock-system block diagram.
24
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
Digital
ADC
ADC
HPLLSEL
LP PLL
PAD_CLK32K_1P8V
0
RC
osc
HPLLSQR
0
0
PAD_MCLK_1P8V
Clock
slicer
1
1
HP PLL
1
HPLLENA
PAD_PDMCLK_1P8V
McPDM
DAC
NCP
SWCS044-017
Figure 14. Clock System
POWER MANAGEMENT
The TWL6030 PMIC provides a +2.1-V preregulated supply VDDV2V1 to the TWL6040. The digital I/O buffers
and other digital functions are directly powered by the VDDVIO supply for a maximum 5-mA average load
current. The TWL6040 has an internal reference system powered from VBAT.
A high-side LDO postregulates VDDV2V1 to VDDLDO supply of +1.6 V for a maximum load of 150 mA. The
preamplifiers, PGA, ADCs, DAC, PLL, headset drivers, earpiece driver, auxiliary drivers, and other analog
functions use the VDDLDO supply.
An integrated negative charge pump generates a –1.9-V preregulated supply NCPOUT. A low-side LDO
postregulates NCPOUT to a VSSLDO supply of –1.6 V for a maximum load of 150 mA, providing the negative
supply for the analog functions powered by VDDLDO formerly described.
Figure 15 shows the power-management diagram.
Copyright © 2009–2011, Texas Instruments Incorporated
25
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
VBAT
TWL6030
SMPS
VR_V2V1
SMPS
VIO_V1V8
Band gap
VDDLDO
I/O
digital,
5 mA
HS-LDO
150 mA
GNDREF
REF
VDDHFL
VDDHFR
VDDVIBL
VDDVIBR
VDDVIO
VDDV2V1
Boost
Band gap
Optional
VDDVREF
GNDLDO1
VDDEAR, VDDHS,
VDDUL, VDDDL,
VDDPLL
VSSEAR, VSSHS,
VSSUL, VSSDL,
VSSPLL
VDDABIAS
PreAmp, ADC, DAC, PGA, PLL,
Earpiece, HS, AUX drivers
110 mA
IHF drivers
vibrator
1A
Analog bias
2 x 2 mA
GNDAMIC
GNDLDO2
VSSLDO
VDDBIAS
LS-LDO
150 mA
Digital bias
2 x 10 mA
VSSLDOIN
NCPFB
NCPOUT
CFLYN
GNDDMIC
NCP
150 mA
Audio
ref
TWL6040
GNDHFL
GNDHFR
GNDVIBL
GNDVIBR
REFN
REFP
GNDNCP
VDDREGNCP
CFLYP
SWCS044-018
Figure 15. Power-Management Diagram
26
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
THERMAL PROTECTION
If the temperature in the TWL6040 increases above a thermal threshold at which damage can occur, a thermal
interrupt THINT is generated. Also, immediate action is automatically taken to reduce the amount of power drawn
from the device.
Figure 16 shows a timing sequence showing a thermal event.
TWL6040
Application
processor
AUDPWRON_SYS
AUDPWRON
VIO
TWL6030
V1V8_FDBK
V1V8_SW
VDDVIO
V2V1_FDBK
V2V1_SW
VDDV2V1
NRESPWRON
NRESPWRON
SWCS044-019
Figure 16. Thermal-Event Timing
PARAMETER
Thermal interrupt threshold
TEST CONDITIONS
MIN
TYP
MAX
UNITS
Positive
142
152
162
°C
Negative
132
142
152
°C
The TWL6040 initiates a power-down sequence (except for the reference system and temperature sensor) when
the junction temperature goes above the positive threshold (TSHUTCOMP equals 1). The must to pull the
AUDPWRON line down when the thermal-interrupt information is received. In this particular case, pulling
AUDPWRON down does not disable the reference system and temperature sensor. The host should only bring
the TWL6040 to POWER-ON state (by pulling the AUDPWRON high) when another thermal interrupt is received.
Copyright © 2009–2011, Texas Instruments Incorporated
27
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
INTERFACES
The TWL6040 has three digital interfaces:
1. I2C interface for information with noncritical latency
2. PDM interface for the audio signal and the register associated with audio path (gain, control)
3. GPO for audio IC interacting with TWL6040 (drivers, power provider)
Some dual-access registers (addresses 0x0A to 0x1B) can be accessed by the I2C and PDM interfaces. The
concurrent access is disabled by default, and only the PDM interface can write to these registers. The R/W
access can be switched to I2C-only by setting the I2CSEL bit. A concurrent access by the I2C and PDM
interfaces is also possible by setting the PDMI2CSEL bit. In this case, the TWL6040 does not provide arbitration
of simultaneous accesses and the functionality of the system cannot be assured. In this mode, software must
ensure that access by one interface is complete before using the other one, to avoid collisions.
I2C
The TWL6040 device provides one I2C interface. This allows read/write access to the configuration registers of
all resources of the system. Table 3 describes the I2C interface.
Table 3. I2C Interface
SUPPORTED
NOT SUPPORTED
Compliant to Philips I C spec Rev 3.0
General call, bus clear, device ID, CBUS compatibility, SMBus,
time-out feature, PMBus, IPMI, ATCA
Slave only (receiver and transmitter)
Master mode (bus arbitration and clock generation)
2
Standard mode (up to 100 kbits/s)
Fast mode (up to 400 kbit/s)
Fast-mode plus (up to 1 Mbit/s)
High-speed mode (up to 3.4 Mbit/s)
Four I2C slave address decoding features
7-bit device addressing mode
10-bit device-addressing mode
Clock stretching
The TWL6040 I2C embeds a single slave address hard coded to 0x4B to address a single register address
space of 256 bytes.
PDM Interface
The PDM interface is the oversampled serial interface used for communication between TWL6040 audio and the
application processor companion chip. PDM_CLK is 19.2 or 17.64 MHz, and the data rate represented by
PDM_FRAME is 1.92 or 1.764 MHz. Words of data can be transmitted from OMAP to the TWL6040 chip using
the PDM_DN line (downlink path), but words of data can also be transmitted from the TWL6040 chip to OMAP
using the PDM_UP line (uplink path). Both chips are synchronized through the PDM_FRAME line. The OMAP
device owns PDM_FRAME by default.
The PDM interface has three modes: normal, command, and test. The normal and command modes are
intended for use with OMAP McPDM. The test mode is designed for evaluation and production test.
Figure 17 shows the PDM interface.
28
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
TWL6040
OMAP
PDM_FRAME
PDMFRAME
PDMUL
PDM_UP
PDMDL
PDM_DN
PDM_CLK
PDMCLK
PDM_CLK_LB
PDMCLKLB
SWCS044-020
Figure 17. PDM Interface
PDM_CLK is used to generate all internal clocks in the OMAP McPDM interface. The clock-tree architecture in
the OMAP may produce multiclock cycle delays under the worst-case conditions. To assure the uplink/downlink
data handshake between the TWL6040 and OMAP, the TWL6040 PDM interface uses PDM_CLK_LB, which is
the clock reproduced in OMAP. This prevents any critical timing issues.
In normal mode, the ratio between PDM_FRAME and PDM_CLOCK_LB is 10. This ratio is static and the
PDM_FRAME low-pulse width is one clock period long. In this mode, the PDM_FRAME signal is driven by
OMAP (through its McPDM module) to TWL6040. The OMAP drives the PDM_FRAME line low during one clock
cycle, and then drives it high during one clock cycle before releasing the PDM_FRAME driver in Hi-Z state.
TWl6040 connects PDM_FRAME to the I/O supply with a pullup resistor to keep it high.
In normal mode, a maximum of 2 × 5 downlink samples can be received during a frame period. As data samples
are generated at 3.84 MHz, this mean that two words of five samples can be transmitted during one frame cycle.
The receive channels can be enabled through I2C register bits. A maximum of 2 × 2 uplink samples can be
transmitted during a frame. The transmit channels can be enabled by I2C register bits.
Figure 18 shows the timing in normal mode with two downlink and two uplink channels enabled.
PDM_FRAME_OUT
PDM_CLK_LB
PDM_DN
U
Rx0
Rx1
Rx0
Rx1
Rx0
Rx1
Rx0
Rx1
PDM_UP
U
Tx0
Tx1
Tx0
Tx1
Tx0
Tx1
Tx0
Tx1
SWCS044-021
Figure 18. Normal Mode With Two Downlink and Two Uplink Channels Enabled
OMAP starts to send downlink packet on the first rising edge of PDM_CLK_LB, after PDM_CLK_LB goes from
high to low while PDM_FRAM_OUT is low. This is the start downlink condition. The uplink path has the same
timing as its downlink path.
Figure 19 shows the timing in normal mode with five downlink and two uplink channels enabled.
Copyright © 2009–2011, Texas Instruments Incorporated
29
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
PDM_FRAME_OUT
PDM_CLK_LB
PDM_DN
U
Rx0 Rx1 Rx2 Rx3 Rx4 Rx0 Rx1 Rx2 Rx3 Rx4 Rx0 Rx1 Rx2 Rx3 Rx4 Rx0 Rx1 Rx2 Rx3 Rx4
PDM_UP
U
Tx0 Tx1
Tx0 Tx1
Tx0 Tx1
Tx0 Tx1
SWCS044-022
Figure 19. Normal Mode With Five Downlink and Two Uplink Channels Enabled
In command mode, register data can be sent from the OMAP to the TWL6040 using the PDM_FRAME line. This
can be the case when OMAP attempts to change the audio gain value on the fly without using the I2C interfaces,
which may be busy, and add a timing mismatch between signal and gain correction. The command mode is
available by default, but can be disabled by register.
General-Purpose Interface
The TWL6040 audio provides three general-purpose digital output buffers accessible through the I2C interface.
The goal is to make provisions for the interface of external audio devices or power providers, such as HAC
drivers, high-voltage drivers for piezo-electric loads, or external boost supplies for internal HF drivers. The default
value of these buffers is low and they have pulldown resistors.
POWER-UP AND POWER-DOWN SEQUENCES
Figure 20 shows the schematic diagram for the power-up and power-down sequences.
TWL6040
Application
processor
AUDPWRON_SYS
AUDPWRON
VIO
TWL6030
V1V8_FDBK
V1V8_SW
VDDVIO
V2V1_FDBK
V2V1_SW
NRESPWRON
VDDV2V1
NRESPWRON
SWCS044-024
Figure 20. Power-Up and Power-Down Sequences
The NRESPWRON input signal is an active-low reset signal (NRESPWRON) delivered by the TWL6030 at the
30
Copyright © 2009–2011, Texas Instruments Incorporated
TWL6040
www.ti.com
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
end of its own power-on sequence, it is released when all the supply voltage (core and I/Os) are correctly set up.
TWL6030 has a VRTC domain powered pulldown on the NRESPWRON signal, ensuring a low-impedance path
to ground, even when the VIO supply is off. The TWL6040 uses this signal to reset the register and
state-machine running from the I/O supplies, as well as disable the modules directly powered by the VBAT
supply.
AUDPWRON is an active-high input signal generated by a GPIO on the application processor side. It triggers the
internal power-on and power-off sequences of the TWL6040. The AUDPWRON signal is internally debounced.
Power-Up Sequence
The VIO domain logic and registers are in reset when VIO is high and NRESPWRON is low.
After NRESPWRON goes high, I2C on the VIO domain, plug detect, and GPO functions are available
(deep-sleep mode).
After V2V1 goes high, the hook-detect function is available by I2C programming (sleep mode).
The power-up sequence is initiated by a low-to-high transition on the AUDPWRON signal. VBAT, VIO, and V2V1
must be within their specified limits when the AUDPWRON transition occurs. The power-up sequence is
internally generated by the TWL6040 state-machine and completion of sequence is signaled by the READYINT
active-high output-interrupt signal. READYINT signals the application processor that the TWL6040 has
completed its power-up sequence and is ready to communicate with the application processor through the I2C or
PDM interface.
Power-Down Sequence
The power-down sequence is initiated by a high-to-low transition of the AUDPWRON signal. The power-down
sequence is internally generated by the TWL6040 state-machine.
INTERRUPTS
The TWL6040 drives the NAUDINT line low when an interrupt is internally detected and the host must be
notified.
The possible events are:
• THINT: Die temperature overlimit detection
• PLUGINT: Plug insertion detection
• UNPLUGINT: Plug removal detection
• HOOKINT: Hook send/end detection
• HFINT: Left or right hands-free driver overcurrent detection
• VIBINT: Left or right vibrator driver overcurrent detection
• READYINT: Completion of power-up sequence
For each interrupt, an optional mask bit can be set.
Copyright © 2009–2011, Texas Instruments Incorporated
31
TWL6040
SWCS044H – NOVEMBER 2009 – REVISED JULY 2011
www.ti.com
PACKAGE CHARACTERISTICS
The package is a ZQZ lead-free 6 × 6 mm2 MicroStar Junior plastic ball grid array (PBGA) 120ZQZ
(PTWL6040A2ZQZ/R) 0.5 mm with 120 physical balls, of which 119 are routable. The mechanical data is shown
below.
SWCS044-026
Figure 21. TWL6040 Mechanical Package
32
Copyright © 2009–2011, Texas Instruments Incorporated
PACKAGE OPTION ADDENDUM
www.ti.com
9-Aug-2011
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package
Drawing
Pins
Package Qty
Eco Plan
(2)
Lead/
Ball Finish
MSL Peak Temp
(3)
Samples
(Requires Login)
TWL6040A2ZQZ
ACTIVE
BGA
MICROSTAR
JUNIOR
ZQZ
120
250
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
TWL6040A2ZQZR
ACTIVE
BGA
MICROSTAR
JUNIOR
ZQZ
120
2500
Green (RoHS
& no Sb/Br)
SNAGCU
Level-3-260C-168 HR
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
3-Aug-2011
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
TWL6040A2ZQZR
Package Package Pins
Type Drawing
BGA MI
CROSTA
R JUNI
OR
ZQZ
120
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
2500
330.0
16.4
Pack Materials-Page 1
6.3
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
6.3
1.5
12.0
16.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
3-Aug-2011
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
TWL6040A2ZQZR
BGA MICROSTAR
JUNIOR
ZQZ
120
2500
333.2
345.9
31.8
Pack Materials-Page 2
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Following are URLs where you can obtain information on other Texas Instruments products and application solutions:
Products
Applications
Audio
www.ti.com/audio
Communications and Telecom www.ti.com/communications
Amplifiers
amplifier.ti.com
Computers and Peripherals
www.ti.com/computers
Data Converters
dataconverter.ti.com
Consumer Electronics
www.ti.com/consumer-apps
DLP® Products
www.dlp.com
Energy and Lighting
www.ti.com/energy
DSP
dsp.ti.com
Industrial
www.ti.com/industrial
Clocks and Timers
www.ti.com/clocks
Medical
www.ti.com/medical
Interface
interface.ti.com
Security
www.ti.com/security
Logic
logic.ti.com
Space, Avionics and Defense
www.ti.com/space-avionics-defense
Power Mgmt
power.ti.com
Transportation and
Automotive
www.ti.com/automotive
Microcontrollers
microcontroller.ti.com
Video and Imaging
www.ti.com/video
RFID
www.ti-rfid.com
Wireless
www.ti.com/wireless-apps
RF/IF and ZigBee® Solutions
www.ti.com/lprf
TI E2E Community Home Page
e2e.ti.com
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