TI TPS61106PW

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TPS61100, TPS61103
TPS61106, TPS61107
SLVS411B – JUNE 2002 – REVISED APRIL 2004
DUAL-OUTPUT, SINGLE-CELL BOOST CONVERTER
•
FEATURES
•
•
•
•
•
•
•
•
•
•
Synchronous 95% Efficient Boost Converter
Integrated 120 mA LDO for Second Output
Voltage
TSSOP-20 and QFN-24 Package
65 µA (Typ) Total Device Quiescent Current
0.8 V to 3.3 V Input Voltage Range
Adjustable Output Voltage up to 5.5 V and
Fixed Output Voltage Options
Power-Save Mode for Improved Efficiency at
Low Output Power
Battery Supervision
Power Good Output
Pushbutton Function for Start-Up
•
•
•
•
Low EMI-Converter (Integrated Antiringing
Switch)
Load Disconnect During Shutdown
Auto Discharge Allows the Device to
Discharge Output Capacitor During Shutdown
Overtemperature Protection
EVM Available (TPS6110XEVM-216)
APPLICATIONS
•
•
All Single or Dual Cell Battery Operated
Products Which Use Two System Voltages
Like DSP C5X Applications
Internet Audio Player, PDAs, Digital Still
Cameras and Other Portable Equipment
TYPICAL APPLICATION
SWN
VBAT
Battery
VOUT
LBI
VCC1
TPS61100
FB
Control
Inputs
OFF
ON
OFF
ON
OFF
OFF
ON
OFF
ON
ON
SKIPEN
ADEN
EN
ENPB
LDOEN
GND
PGOOD
LBO1
LBO2
Control
Outputs
LDOIN
LDOOUT
VCC2
PGND LDOSENSE
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.
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 © 2002–2004, Texas Instruments Incorporated
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
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.
DESCRIPTION
The TPS6110x devices provide a complete power supply solution for products powered by either one or two
Alkaline, NiCd, or NiMH battery cells. The converter generates two stable output voltages that are either adjusted
by an external resistor divider or fixed internally on the chip. It stays in operation with supply voltages down to
0.8 V. The implemented boost converter is based on a fixed frequency, pulse-width-modulation (PWM) controller
using a synchronous rectifier to obtain maximum efficiency.
The maximum peak current in the boost switch is limited to a value of 1800 mA.
The converter can be disabled to minimize battery drain. During shutdown, the load is completely disconnected
from the battery. An auto discharge function allows discharging the output capacitors during shutdown mode.
This is especially useful in microcontroller applications where the microcontroller or microprocessor should not
remain active due to the stored voltage on the output capacitors. Programming the ADEN-pin disables this
feature. A low-EMI mode is implemented to reduce ringing and in effect lower radiated electromagnetic energy
when the converter enters the discontinuous conduction mode. A power good output at the boost stage provides
additional control of cascaded power supply components.
The built-in LDO can be used for a second output voltage derived either from the boost output or directly from
the battery. The output voltage of this LDO can be programmed by an external resistor divider or is fixed
internally on the chip. The LDO can be enabled separately i.e., using the power good of the boost stage.
The device is packaged in a 20-pin TSSOP (20 PW) package or in a 24-pin QFN (24 RGE) package.
AVAILABLE PACKAGE OPTIONS
PACKAGE
CODE
20-Pin TSSOP
PW
24-Pin QFN
RGE
AVAILABLE OUTPUT VOLTAGE OPTIONS
TA
40°C to 85°C
(1)
2
OUTPUT
VOLTAGE
DC/DC
OUTPUT
VOLTAGE
LDO
PART NUMBER (1)
PART NUMBER (1)
Adjustable
Adjustable
TPS61100PW
TPS61100RGE
3.3 V
Adjustable
TPS61103PW
TPS61103RGE
3.3 V
1.5 V
TPS61106PW
TPS61106RGE
3.3 V
1.8 V
TPS61107PW
TPS61107RGE
The PW package is available taped and reeled. Add R suffix to device type (e.g., TPS61100PWR) to
order quantities of 2000 devices per reel. The RGE package is only available in reels. Add R suffix to
device type (e.g. TPS61100RGER) to order quantities of 3000 devices per reel.
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
FUNCTIONAL BLOCK DIAGRAM
SWN
VOUT
VBAT
AntiRinging
Auto
Discharge
PGND
Gate
CONTROL
PGND
PGND
Regulator
Error
Amplifier
FB
Vref
Control Logic
Oscillator
EN
ENPB
PGOOD
LDOEN
SKIPEN
ADEN
Temperature
Control
GND
Low Dropout
Regulator
LBI
LBO1
LBO2
LDOIN
LDOOUT
Auto
Discharge
Low Battery
Comparator
LDOSENSE
GND
3
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
Terminal Functions
TERMINAL
NAME
NO.
I/O
DESCRIPTION
PW
RGE
ADEN
5
3
I
Auto discharge enable (1/VBAT enabled, 0/GND disabled)
EN
4
2
I
Boost-enable input. (1/VBAT enabled, 0/GND disabled)
ENPB
3
24
I
Boost-enable input (pushbutton). (0/GND enabled. 1/VBAT disabled)
FB
20
21
I
Boost-voltage feedback of adjustable versions
GND
10
8
I/O
LBI
2
23
I
Low battery comparator input (comparator enabled with EN)
LBO1
12
11
O
Low battery comparator output 1 (open drain)
LBO2
13
12
O
Low battery comparator output 2 (open drain)
LDOEN
7
5
I
LDO-enable input (1/VBAT enabled, 0/GND disabled)
LDOOUT
9
7
O
LDO output
LDOIN
8
6
I
LDO input
LDOSENSE
6
4
I
LDO feedback for voltage adjustment, must be connected to LDOOUT at fixed output voltage
versions
NC
17
1
PGND
11
9, 10
I/O
Power ground
PGOOD
15
15
O
Boost output power good (1 : good, 0 : failure) (open drain)
SKIPEN
18
18
I
Enable/disable Power save mode (1: VBAT enabled, 0: GND disabled)
14, 16
13, 14,
16, 17
I
Boost switch input
No connection
VBAT
1
22
I
Supply pin
VOUT
19
19, 20
O
Boost output
PW PACKAGE
(TOP VIEW)
1
2
3
4
5
6
7
8
9
10
NC – No internal connection
4
20
19
18
17
16
15
14
13
12
11
FB
VOUT
SKIPEN
NC
SWN
PGOOD
SWN
LBO2
LBO1
PGND
ENPB
LBI
VBAT
FB
VOUT
VOUT
VBAT
LBI
ENPB
EN
ADEN
LDOSENSE
LDOEN
LDOIN
LDOOUT
GND
RGE PACKAGE
(TOP VIEW)
NC
EN
ADEN
LDOSENSE
LDOEN
LDOIN
TPS6110X
LDOOUT
GND
PGND
PGND
LBO1
LBO2
SWN
Control/logic ground
SKIPEN
SWN
SWN
PGOOD
SWN
SWN
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
DETAILED DESCRIPTION
SYNCHRONOUS RECTIFIER
The device integrates an N-channel and a P-channel MOSFET transistor to realize a synchronous rectifier.
Because the commonly used discrete Schottky rectifier is replaced with a low RDS(ON) PMOS switch, the power
conversion efficiency reaches 95%. To avoid ground shift due to the high currents in the NMOS switch, two
separate ground pins are used. The reference for all control functions is the GND pin. The source of the NMOS
switch is connected to PGND. Both grounds must be connected on the PCB at only one point close to the GND
pin. A special circuit is applied to disconnect the load from the input during shutdown of the converter. In
conventional synchronous rectifier circuits, the backgate diode of the high-side PMOS is forward biased in
shutdown and allows current flowing from the battery to the output. This device however uses a special circuit
which takes the cathode of the backgate diode of the high-side PMOS and disconnects it from the source when
the regulator is not enabled (EN = low).
The benefit of this feature for the system design engineer is that the battery is not depleted during shutdown of
the converter. No additional components have to be added to the design to make sure that the battery is
disconnected from the output of the converter.
CONTROLLER CIRCUIT
The controller circuit of the device is based on a fixed frequency multiple feedforward controller topology. Input
voltage, output voltage, and voltage drop on the NMOS switch are monitored and forwarded to the regulator. So
changes in the operating conditions of the converter directly affect the duty cycle and must not take the indirect
and slow way through the control loop and the error amplifier. The control loop, determined by the error amplifier,
only has to handle small signal errors. The input for it is the feedback voltage on the FB pin or, at fixed output
voltage versions, the voltage on the internal resistor divider. It is compared with the internal reference voltage to
generate an accurate and stable output voltage.
The peak current of the NMOS switch is also sensed to limit the maximum current flowing through the switch and
the inductor. The nominal peak current limit is set to 1500 mA.
An internal temperature sensor prevents the device from getting overheated in case of excessive power
dissipation.
DEVICE ENABLE
The device is put into operation when EN is set high. It is put into a shutdown mode when EN is set to GND. It
also can be enabled with a low signal on ENPB. This forces the converter to start up as long as the low signal is
applied. During this time EN must be set high to prevent the converter from going down into shutdown mode
again. If EN is high, a negative signal on ENPB is ignored.
In shutdown mode, the regulator stops switching, all internal control circuitry including the low-battery comparator
is switched off, and the load is isolated from the input (as described in the synchronous rectifier section). This
also means that the output voltage can drop below the input voltage during shutdown. During start-up of the
converter, the duty cycle and the peak current are limited in order to avoid high peak currents drawn from the
battery.
An undervoltage lockout function prevents device start-up if the supply voltage on VBAT is lower than
approximately 0.7 V. When in operation and the battery is being discharged, the device automatically enters the
shutdown mode if the voltage on VBAT drops below approximately 0.7 V. This undervoltage lockout function is
implemented in order to prevent the malfunctioning of the converter.
LDO ENABLE
When the voltage is applied at VBAT, the LDO can be separately enabled and disabled by using the LDOEN pin
in the same way as the EN pin at the dc/dc converter stage described above.
POWER GOOD
The PGOOD pin stays high impedance when the dc/dc converter delivers an output voltage within a defined
voltage window. So it can be used to enable the converter after pushbutton start-up, or to enable any connected
circuitry such as cascaded converters (LDO) or processor circuits.
5
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
DETAILED DESCRIPTION (continued)
POWER SAVE MODE
The SKIPEN pin can be used to select different operation modes. To enable power save, SKIPEN must be set
high. Power save mode is used to improve efficiency at light load. In power save mode the converter only
operates when the output voltage trips below a set threshold voltage. It ramps up the output voltage with one or
several pulses and goes again into power save mode once the output voltage exceeds the set threshold voltage.
This power save mode can be disabled by setting the SKIPEN to GND.
AUTO DISCHARGE
The auto discharge function is needed in applications where the supply voltage of a microcontroller,
microprocessor or memory has to be removed during shutdown in order to make sure that the system quickly
goes in a defined state. The auto discharge function is enabled when the ADEN is set high. It is disabled when
the ADEN is set to GND. When the auto discharge function is enabled, the output capacitor is discharged after
the device is programmed in the shutdown mode. The output capacitor is discharged by an integrated switch of
400 Ω, hence the discharge time depends on the size of the output capacitor.
LOW BATTERY DETECTOR CIRCUIT—LBI/LBO
The low-battery detector circuit is typically used to supervise the battery voltage and to generate an error flag
when the battery voltage drops below a user-set threshold voltage. The function is active only when the device is
enabled. When the device is disabled, both LBO-pin are high-impedance. There are three programmed
thresholds, 400 mV, 450 mV, and 500 mV. The outputs on LBO1 and LBO2 are shown as follows:
LBI INPUT
(mV)
LBO1
LBO2
0-400
0
0
400-450
1
0
450-500
0
1
500-VBAT
1
1
1 means that the output stays at high-impedance and 0 means that the output goes active low. If there is only
one LBO output needed, both outputs can be tied together. Then the switching threshold is at 500 mV at LBI.
The battery voltage, at which the detection circuit switches, can be programmed with a resistive divider
connected to the LBI-pin. The resistive divider scales down the battery voltage to a voltage level of 400 mV
(450 mV, 500 mV), which is then compared to the LBI threshold voltage. The LBI-pin has a built-in hysteresis of
10 mV. See the application section for more details about the programming of the LBI-threshold. If the
low-battery detection circuit is not used, the LBI-pin should be connected to GND (or to VBAT) and the LBO-pin
can be left unconnected. Do not let the LBI-pin float.
LOW-EMI SWITCH
The device integrates a circuit that removes the ringing that typically appears on the SW-node when the
converter enters discontinuous current mode. In this case, the current through the inductor ramps to zero and the
rectifying PMOS switch is turned off to prevent a reverse current flowing from the output capacitors back to the
battery. Due to the remaining energy that is stored in parasitic components of the semiconductor and the
inductor, a ringing on the SW-pin is induced. The integrated antiringing switch clamps this voltage to VBAT and
therefore dampens ringing.
LDO
The built-in LDO can be used to generate a second output voltage derived from the dc/dc converter output, from
the battery, or from another power source like an ac adapter or a USB power rail. The LDOSENSE input must be
connected to LDOOUT at fixed output voltage versions.
6
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TPS61100, TPS61103
TPS61106, TPS61107
SLVS411B – JUNE 2002 – REVISED APRIL 2004
ABSOLUTE MAXIMUM RATINGS (1)
over operating free-air temperature range (unless otherwise noted)
UNIT
Input voltage range on VBAT, LBI, SKIPEN, EN, ENPB, ADEN, FB, LDOEN
-0.3 V to 3.6 V
Input voltage range on SWN, VOUT, LDOIN, LDOOUT, LDOSENSE, PGOOD, LBO1, LBO2
-0.3 V to 7 V
Operating free air temperature range, TA
-40°C to 85°C
Maximum junction temperature, TJ
Storage temperature range, Tstg
150°C
-65°C to 150°C
Lead temperature 1,6 mm (1/16 inch) from case for 10s
(1)
260°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.
RECOMMENDED OPERATING CONDITIONS
MIN NOM
VI
Supply voltage at VBAT
0.8
L
Boost—inductor
4.7
Ci
Boost—input capacitor
Co
Boost—output capacitor
Ci
LDO—input capacitor
Co
LDO—output capacitor
TJ
Operating virtual junction temperature
22
1
-40
MAX
3.3
UNIT
V
10
µH
10
µF
100
µF
1
µF
2.2
µF
125
°C
7
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
ELECTRICAL CHARACTERISTICS
over recommended free-air temperature range and over recommended input voltage range (typical at an ambient temperature
range of 25°C) (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP MAX
UNIT
BOOST STAGE
VI(b)
Vo(b)
RL > = 66 Ω at Vo = 3.3 V
Input voltage for start-up
Input voltage once started
Output voltage
1.5
PW package, VBAT ≥ 1.5 V
Minimum possible output power
Vref
Reference voltage
f
Oscillator frequency
0.85
0.8
Switch current limit
Vo = 3.3 V
V
3.3
V
5.5
600
500
515
mV
320
500
800
kHz
1200 1500 1800
mA
610
Boost switch on resistance
Vo = 3.3 V
Sync switch on resistance
Vo = 3.3 V
Total accuracy
V
mW
485
Startup current limit
mA
180
300
mΩ
180
300
mΩ
-3%
Auto discharge switch resistance
Boost quiescent current
1.1
3%
Ω
400
VBAT
IO = 0 mA, VEN = VBAT = 3.3 V, Vo = 3.3 V, ENLDO = 0
25
40
µA
VOUT
IO = 0 mA, VEN = VBAT = 3.3 V, Vo = 3.3 V, ENLDO = 0
12
20
µA
VEN = 0 V
0.5
5
µA
Boost shutdown current
LDO STAGE
VI(LDO)
Input voltage range
1.5
7
V
Vo(LDO)
Output voltage
0.9
3.6
V
Io(LDO)
Output current
VI ≥ 1.8 V
120
VI < 1.8 V
80
270
LDO short circuit current limit
500
mA
300
mV
Minimum voltage drop
VI ≥ 1.8 V, Io(LDO) = 120 mA
Total accuracy
Io ≥ 1 mA
±3%
Line regulation
LDOIN change form 1.8 V to 2.6 V at 100 mA
0.6%
Load regulation
Load change from 10% to 90%
0.6%
Auto discharge switch resistance
LDO quiescent current
LDO shutdown current
8
mA
Ω
400
LDOIN
VBAT
LDOIN = 7 V, VBAT = 1.2 V, EN = 0
27
40
27
40
0.01
1
µA
µA
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
ELECTRICAL CHARACTERISTICS (CONTINUED)
over recommended free-air temperature range and over recommended input voltage range (typical at an ambient temperature
range of 25°C) (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
CONTROL STAGE
VIL
LBI1 voltage threshold
VLBI voltage decreasing
390
400
410
mV
LBI2 voltage threshold
VLBI voltage decreasing
440
450
460
mV
LBI3 voltage threshold
VLBI voltage decreasing
490
500
510
mV
LBI input hysteresis
10
mV
LBI input current
EN = Vbat or GND
0.01
0.1
LBO1 output low voltage
Vo = 3.3 V, IOL = 10 µA
0.04
0.4
LBO1 output low current
10
µA
V
µA
LBO1 output leakage current
VLBO = 3.3 V
0.01
0.1
µA
LBO2 output low voltage
Vo = 3.3 V, IOL = 10 µA
0.04
0.4
V
VLBO = 3.3 V
0.01
LBO2 output low current
10
LBO2 output leakage current
VIL
EN, ENPB, LDOEN, SKIPEN and ADEN input
low voltage
VIH
EN, ENPB, LDOEN, SKIPEN and ADEN input
high voltage
µA
0.1
0.2 × VBAT
0.8 × VBAT
EN, ENPB, LDOEN, SKIPEN and ADEN input
current
Clamped on GND or VBAT
Powergood threshold
Vo = 3.3 V
0.9xVo
0.01
0.1
0.92xVo
0.95xVo
Powergood delay
30
Powergood output low voltage
µA
Vo = 3.3 V, IOL = 10 µA
µs
0.04
Powergood output low current
µA
0.4
10
V
µA
Powergood output leakage current
0.01
0.1
µA
Overtemperature protection
140
°C
Overtemperature hysteresis
20
°C
PARAMETER MEASUREMENT INFORMATION
U1
L1
10 µH
SWN
VBAT
Power
Supply
C3
10 µF
List of Components:
U1 = TPS6110x
L1 = SUMIDA CDRH74–100
C3, C5, C6 = X7R/X5R Ceramic
C4 = Low ESR Tantalum
R3
C6
2.2 µF
FB
LBI
R2
LDOIN
SKIPEN
LDOOUT
ADEN
LDOSENSE
EN
ENPB
LDOEN
GND
VCC1
Boost Output
VOUT
R1
LBO1
LBO2
PGOOD
PGND
C4
100 µF
R6
VCC2
LDO Output
R5
C5
R4
R7
R8
R9
Control
Outputs
TPS6110x
9
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS
Table of Graphs
BOOST CONVERTER
Maximum output current
Efficiency
Figure
vs Input voltage for VOUT = 3.3 V, 5.0 V
1
vs Input voltage for VOUT = 1.8 V, 2.5 V
2
vs Output current for VIN = 1.2 V, VOUT = 1.5 V
3
vs Output current for VIN = 1.2 V, VOUT = 2.5 V
4
vs Output current for VIN = 1.2 V, VOUT = 3.3 V
5
vs Output current for VIN = 1.8 V, VOUT = 2.5 V
6
vs Output current for VIN = 2.4 V, VOUT = 3.3 V
7
vs Output current for VIN = 2.4 V, VOUT = 5.0 V
8
vs Input voltage for Iout = 10 mA/100 mA/200 mA, VOUT = 3.3 V
9
Output voltage
vs Output current TPS61103/6
10
Minimum start-up supply voltage
vs Load resistance
11
No-load supply current into VBAT
vs Input voltage
12
No-load supply current into VOUT
vs Input voltage
13
Output voltage (ripple) in continuous modeInductor current
14
Output voltage (ripple) in power save modeInductor current
15
Load transient response for output current step of 40 mA to 120 mA
16
Line transient response for supply voltage step from 1 V to 1.5 V at Iout = 100 mA
17
Boost converter start-up after enable
18
vs Input voltage for VOUT = 2.5 V, 3.3 V
19
Waveforms
LDO
Maximum output current
vs Input voltage for VOUT = 1.5 V, 1.8 V
20
Output voltage
vs Output current TPS61106
21
Dropout voltage
vs Output current TPS61100 at 3.3 V TPS61106
22
No-load supply current into LDOIN
vs Input voltage
23
PSRR
vs Frequency
24
Load transient response for output current step of 20 mA to 100 mA
25
Line transient response for supply voltage step from 1.8 V to 2.4 V at Iout = 100 mA
26
LDO start-up after enable
27
Waveforms
10
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
MAXIMUM OUTPUT CURRENT
vs
INPUT VOLTAGE
MAXIMUM OUTPUT CURRENT
vs
INPUT VOLTAGE
1.2
1.4
TPS61100
1.2
1
Maximum Output Current - A
Maximum Output Current - A
TPS61100
0.8
VO = 3.3 V
0.6
VO = 5 V
0.4
0.2
0.8
VO = 1.8 V
0.6
VO = 2.5 V
0.4
0.2
0
0.8
1 1.2 1.4 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2
VI - Input Voltage - V
1
1.2
1.4 1.6 1.8
2
VI - Input Voltage - V
Figure 1.
Figure 2.
EFFICIENCY
vs
OUTPUT CURRENT
EFFICIENCY
vs
OUTPUT CURRENT
100
100
90
90
80
80
70
70
Efficiency - %
Efficiency - %
0
0.8
1
60
50
40
30
2.2
2.4
60
50
40
30
20
20
TPS61100
VO = 1.5 V,
VBAT = 1.2 V
10
0
0.1
1
10
100
IO - Output Current - mA
Figure 3.
TPS61100
VO = 2.5 V,
VBAT = 1.2 V
10
1000
0
0.1
1
10
100
IO - Output Current - mA
1000
Figure 4.
11
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TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS (continued)
EFFICIENCY
vs
OUTPUT CURRENT
100
100
90
90
80
80
70
70
Efficiency - %
Efficiency - %
EFFICIENCY
vs
OUTPUT CURRENT
60
50
40
30
40
20
TPS61106
VBAT = 1.2 V
10
0
0.1
1
10
100
IO - Output Current - mA
TPS61100
VO = 2.5 V,
VBAT = 1.8 V
10
0
1000
0.1
1
10
100
IO - Output Current - mA
Figure 5.
Figure 6.
EFFICIENCY
vs
OUTPUT CURRENT
EFFICIENCY
vs
OUTPUT CURRENT
100
100
90
90
80
80
70
70
Efficiency - %
Efficiency - %
50
30
20
60
50
40
1000
60
50
40
30
30
20
20
TPS61106
VBAT = 2.4 V
10
TPS61100
VO = 5 V,
VBAT = 2.4 V
10
0
0
0.1
1
10
100
IO - Output Current - mA
Figure 7.
12
60
1000
0.1
1
10
IO - Output Current - mA
Figure 8.
100
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS (continued)
EFFICIENCY
vs
INPUT VOLTAGE
OUTPUT VOLTAGE
vs
OUTPUT CURRENT
100
3.34
90
3.32
TPS61103/6
80
3.3
IO = 10 mA
VO - Output Voltage - V
70
Efficiency - %
VBAT = 1.2 V
IO = 100 mA
IO = 250 mA
60
50
40
30
3.28
3.26
3.24
3.22
20
10
3.2
TPS61106
0
0.8 1
1.2 1.4 1.6 1.8 2
2.2 2.4 2.6 2.8
3.18
0.1
3 3.2
Figure 9.
Figure 10.
MINIMUM START-UP SUPPLY VOLTAGE
vs
LOAD RESISTANCE
NO-LOAD SUPPLY CURRENT INTO VBAT
vs
INPUT VOLTAGE
1000
30
1
85°C
µA
TPS61106
0.95
25
No-Load Supply Current Into VBAT -
Minimum Startup Supply Voltage - V
100
10
IO - Output Current - mA
VI - Input Voltage - V
0.9
0.85
0.8
0.75
0.7
10
1
100
1k
25°C
-40°C
20
15
10
5
0
0.8 1 1.2 1.4 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6
Load Resistance - Ω
VI - Input Voltage - V
Figure 11.
Figure 12.
13
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS (continued)
NO-LOAD SUPPLY CURRENT INTO VOUT
vs
INPUT VOLTAGE
OUTPUT VOLTAGE IN CONTINUOUS MODE
N0-Load Supply Current Into - VOUT -
µA
16
TPS61106
Output Voltage
20 mV/Div, AC
85°C
14
12
25°C
-40°C
10
Inductor Current
200 mA/Div, DC
8
6
4
2
0
0.8 1 1.2 1.4 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6
Timebase - 1 µs/Div
VI - Input Voltage - V
Figure 13.
Figure 14.
OUTPUT VOLTAGE IN POWER SAVE MODE
LOAD TRANSIENT RESPONSE
Output Voltage
50 mV/Div, AC
Inductor Current
200 mA/Div, DC
Timebase - 500 µs/Div
Figure 15.
14
Output Current
50 mA/Div, DC
Output Voltage
20 mV/Div, AC
Timebase - 500 µs/Div
Figure 16.
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS (continued)
LINE TRANSIENT RESPONSE
BOOST-CONVERTER START-UP AFTER ENABLE
Input Voltage
500 mV/Div, DC
Enable
2 V/Div, DC
Output Voltage
2 V/Div, DC
Voltage at SW
2 V/Div, DC
Output Voltage
50 mV/Div, AC
Input Current
500 mA/Div, DC
Timebase - 400 µs/Div
Timebase - 2 ms/Div
Figure 17.
Figure 18.
MAXIMUM LDO OUTPUT CURRENT
vs
LDO INPUT VOLTAGE
MAXIMUM LDO OUTPUT CURRENT
vs
LDO INPUT VOLTAGE
0.35
Maximum LDO Output Current - A
Maximum LDO Output Current - A
0.35
VO = 2.5 V
0.3
0.25
VO = 3.3 V
0.2
0.15
0.1
0.3
VO = 1.5 V
0.25
VO = 1.8 V
0.2
0.15
0.1
2.5
3
3.5
4
4.5
5
5.5
LDO Input Voltage - V
Figure 19.
6
6.5
7
1.5
2
2.5
3
3.5 4
4.5
LDO Input Voltage - V
5
5.5
6
Figure 20.
15
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TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS (continued)
LDO OUTPUT VOLTAGE
vs
LDO OUTPUT CURRENT
LDO DROPOUT VOLTAGE
vs
LDO OUTPUT CURRENT
1.51
3.5
TPS61106
LDOIN = 1.8 V
3
LDO Dropout Voltage - V
LDO Output Voltage - V
1.5
1.49
1.48
1.47
1.46
0
50
100
150
TPS61106
(LDO OUTPUT
VOLTAGE 1.5 V)
1.5
1
TPS61100
(LDO OUTPUT
VOLTAGE 3.3 V)
0
200
0
100
200
300
400
LDO Output Current - mA
LDO Output Current - mA
Figure 21.
Figure 22.
SUPPLY CURRENT INTO LDOIN
vs
LDOIN INPUT VOLTAGE
PSRR
vs
FREQUENCY
35
500
80
85°C
LDO Output Current 10 mA
70
30
25°C
60
25
-40°C
20
15
PSRR - dB
Supply Current Into LDOIN - µ A
2
0.5
1.45
50
40
LDO Output Current 100 mA
30
10
20
5
0
16
2.5
TPS61106
LDOIN = 3.3 V
10
0.8 1 1.2 1.4 1.6 1.8 2 2.2 2.4 2.6 2.8 3 3.2 3.4 3.6
0
1k
LDOIN Input Voltage - V
100k
f - Frequency - Hz
Figure 23.
Figure 24.
10k
1M
10M
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
TYPICAL CHARACTERISTICS (continued)
LDO LOAD TRANSIENT RESPONSE
LDO LINE TRANSIENT RESPONSE
Output Current
50 mA/Div, DC
Input Voltage
1 V/Div, DC
Output Voltage
10 mV/Div, AC
Output Voltage
20 mV/Div, AC
Timebase - 2 ms/Div
Timebase - 1 ms/Div
Figure 25.
Figure 26.
LDO START-UP AFTER ENABLE
LDO-Enable
2 V/Div, DC
LDO-Output Voltage
1 V/Div, DC
Input Current
50 mA/Div, DC
Timebase - 50 µs/Div
Figure 27.
17
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TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
APPLICATION INFORMATION
DESIGN PROCEDURE
The TPS6110x boost converters are intended for systems powered by a single-cell NiCd or NiMH battery with a
typical terminal voltage between 0.9 V and 1.6 V. They can also be used in systems powered by two-cell NiCd or
NiMH batteries with a typical stack voltage between 1.8 V and 3.2 V. Additionally, single- or dual-cell, primary
and secondary alkaline battery cells can be the power source in systems where the TPS6110x is used.
Programming the Output Voltage
Boost Converter
The output voltage of the TPS61100 boost converter section can be adjusted with an external resistor divider.
The typical value of the voltage on the FB pin is 500 mV. The maximum allowed value for the output voltage is
5.5 V. The current through the resistive divider should be about 100 times greater than the current into the FB
pin. The typical current into the FB pin is 0.01 µA and the voltage across R6 is typically 500 mV. Based on those
two values, the recommended value for R6 should be lower than 500 kΩ, in order to set the divider current at 1
µA or higher. Because of internal compensation circuitry the value for this resistor should be in the range of 200
kΩ. From that, the value of resistor R3, depending on the needed output voltage (VO), can be calculated using
Equation 1:
V
V
O –1 180 k O –1
R3 R6 V
500 mV
FB
(1)
If as an example, an output voltage of 3.3 V is needed, a 1-MΩ resistor should be chosen for R3.
U1
L1
10 µH
SWN
VBAT
Power
Supply
C3
10 µF
R3
C6
2.2 µF
FB
LBI
R2
LDOIN
SKIPEN
LDOOUT
ADEN
LDOSENSE
EN
ENPB
LDOEN
GND
VCC1
Boost Output
VOUT
R1
LBO1
LBO2
PGOOD
PGND
C4
100 µF
R6
VCC2
LDO Output
R5
C5
R4
R7
R8
R9
Control
Outputs
TPS61100
Figure 28. Typical Application Circuit for Adjustable Output Voltage Option
LDO
Programming the output voltage at the LDO follows almost the same rules as at the boost converter section. The
maximum programmable output voltage at the LDO is 3.3 V. Since reference and internal feedback circuitry are
similar, as they are at the boost converter section, R4 also should be in the 200-kΩ range. The calculation of the
value of R5 can be done using the following Equation 2:
V
V
O –1 180 k O –1
R5 R4 V
500 mV
FB
(2)
If as an example, an output voltage of 1.5 V is needed, a 360 kΩ-resistor should be chosen for R5.
18
TPS61100, TPS61103
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
APPLICATION INFORMATION (continued)
Programming the LBI/LBO Threshold Voltage
The current through the resistive divider should be about 100 times greater than the current into the LBI pin. The
typical current into the LBI pin is 0.01 µA, and the voltage across R2 is equal to the LBI voltage threshold that is
generated on-chip, which has a value of 400 mV, 450 mV or 500 mV. The recommended value for R2is therefore
in the range of 500 kΩ. From that, the value of resistor R1, depending on the desired minimum battery voltage
VBAT, can be calculated using Equation 3.
R1 R2 V
V
BAT
–1
LBI-threshold
390 k V
BAT –1
450 mV
(3)
For example, if the low-battery detection circuit should flag an error condition for the 450 mV threshold on the
LBO outputs at a battery voltage of 1.23 V, a 680-kΩ resistor should be chosen for R1. The resulting battery
voltages of the other thresholds can be calculated using Equation 4:
V
V
R1 1 500 mV 680 k 1
BAT
LBI-threshold
R2
390 k
(4)
The result for the 500-mV threshold in our example is 1.37 V and for the 400-mV threshold 1.1 V. This results in
the following truth table for the battery supervisor outputs:
VBAT [V]
LBO1
LBO2
0-1.1
0
0
1.1-1.23
1
0
1.23-1.37
0
1
1.37-VBAT max
1
1
If the application requires only a simple LBI/LBO function both LBO outputs can be connected together. The LBI
threshold then is 500 mV.
The outputs of the low battery supervisor are simple open-drain outputs that go active low if the dedicated battery
voltage drops below the programmed threshold voltage on LBI. The output requires a pullup resistor with a
recommended value of 1 MΩ. The maximum voltage which is used to pull up the LBO outputs should not exceed
the output voltage of the boost converter. If not used, the LBO pin can be left floating or tied to GND.
Inductor Selection
A boost converter normally requires two main passive components for storing energy during the conversion. A
boost inductor and a storage capacitor at the output are required. To select the boost inductor, it is
recommended to keep the possible peak inductor current below the current limit threshold of the power switch in
the chosen configuration. For example, the current limit threshold of the TPS6110x's switch is 1200 mA at an
output voltage of 3.3 V. The highest peak current through the inductor and the switch depends on the output
load, the input (VBAT), and the output voltage (VOUT). Estimation of the maximum average inductor current can be
done using Equation 5:
V
OUT
I I
L
OUT V
0.8
BAT
(5)
For example, for an output current of 100 mA at 3.3 V, at least 515 mA of current flows through the inductor at a
minimum input voltage of 0.8 V.
19
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
The second parameter for choosing the inductor is the desired current ripple in the inductor. Normally, it is
advisable to work with a ripple of less than 20% of the average inductor current. A smaller ripple reduces the
magnetic hysteresis losses in the inductor, as well as output voltage ripple and EMI. But in the same way,
regulation time at load changes rises. In addition, a larger inductor increases the total system costs. With those
parameters, it is possible to calculate the value for the inductor by using Equation 6:
V
L
V
–V
BAT
OUT BAT
I ƒ V
L
OUT
(6)
Parameter 0 is the switching frequency and∆ IL is the ripple current in the inductor, i.e., 20% × IL. In this example,
the desired inductor has the value of 12 µH. With this calculated value and the calculated currents, it is possible
to choose a suitable inductor. Care has to be taken that load transients and losses in the circuit can lead to
higher currents as estimated in Equation 5. Also, the losses in the inductor caused by magnetic hysteresis losses
and copper losses are a major parameter for total circuit efficiency.
Table 1. Inductors
VENDOR
RECOMMENDED INDUCTOR SERIES
CDRH73
CDRH74
Sumida
CDRH5D18
CDRH6D38
DR73
Coiltronics
DR74
LQS66C
Murata
LQN6C
SLF 7045
TDK
SLF 7032
Wurth Electronic
WE-PD Type M
WE-PD Type S
CAPACITOR SELECTION
Input Capacitor
At least a 10-µF input capacitor is recommended to improve transient behavior of the regulator and EMI behavior
of the total power supply circuit. A ceramic capacitor or a tantalum capacitor with a 100-nF ceramic capacitor in
parallel, placed close to the IC, is recommended.
Output Capacitor Boost Converter
The major parameter necessary to define the output capacitor is the maximum allowed output voltage ripple of
the converter. This ripple is determined by two parameters of the capacitor, the capacitance and the ESR. It is
possible to calculate the minimum capacitance needed for the defined ripple, supposing that the ESR is zero, by
using Equation 7:
I
C
min
V
V
OUT
OUT
BAT
ƒ V V
OUT
Parameter f is the switching frequency and ∆V is the maximum allowed ripple.
20
(7)
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
With a chosen ripple voltage of 15 mV, a minimum capacitance of 10 µF is needed. The total ripple is larger due
to the ESR of the output capacitor. This additional component of the ripple can be calculated using Equation 8:
V
I
R
ESR
OUT
ESR
(8)
An additional ripple of 10 mV is the result of using a tantalum capacitor with a low ESR of 100 mΩ. The total
ripple is the sum of the ripple caused by the capacitance and the ripple caused by the ESR of the capacitor. In
this example, the total ripple is 25 mV. It is possible to improve the design by enlarging the capacitor or using
smaller capacitors in parallel to reduce the ESR or by using better capacitors with lower ESR, like ceramics. So,
trade-offs have to be made between performance and costs of the converter circuit.
Output Capacitor LDO
To ensure stable output regulation, it is required to use an output capacitor at the LDO output. We recommend
using ceramic capacitors in the range from 1 µF up to 4.7 µF. At 4.7 µF and above it is recommended to use
standard ESR tantalum. There is no maximum capacitance value.
LAYOUT CONSIDERATIONS
As for all switching power supplies, the layout is an important step in the design, especially at high peak currents
and high switching frequencies. If the layout is not carefully done, the regulator could show stability problems as
well as EMI problems. Therefore, use wide and short traces for the main current path and for the power ground
tracks. The input capacitor, output capacitor, and the inductor should be placed as close as possible to the IC.
Use a common ground node for power ground and a different one for control ground to minimize the effects of
ground noise. Connect these ground nodes at any place close to one of the ground pins of the IC.
The feedback divider should be placed as close as possible to the control ground pin of the IC. To lay out the
control ground, it is recommended to use short traces as well, separated from the power ground traces. This
avoids ground shift problems, which can occur due to superimposition of power ground current and control
ground current.
APPLICATION EXAMPLES
U1
L1
10 µH
SWN
VBAT
VOUT
C6
2.2 µF
R1
C3
10 µF
LBI
R2
List of Components:
U1 = TPS61106
L1 = SUMIDA CDRH74–100
C3, C5, C6 = X7R/X5R Ceramic
C4 = Low ESR Tantalum
LDOIN
SKIPEN
LDOOUT
ADEN
LDOSENSE
EN
ENPB
LDOEN
GND
C4
100 µF
C5
2.2 µF
R7
R8
LBO1
LBO2
PGOOD
PGND
3.3 V,
>250 mA
1.5 V,
>120 mA
R9
LBO1
LBO2
PGOOD
TPS61106
Figure 29. Solution for Maximum Output Power
21
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
U1
L1
SWN
10 µH
VBAT
3.3 V
VOUT
C6
2.2 µF
R1
C3
10 µF
LBI
R2
C4
100 µF
LDOIN
SKIPEN
LDOOUT
ADEN
LDOSENSE
EN
1.5 V
C5
2.2 µF
R7
ENPB
List of Components:
U1 = TPS61106
L1 = SUMIDA 5D18–100
C3, C5, C6 = X7R/X5R Ceramic
C4 = Low ESR, Low Profile Tantalum
LDOEN
R8
R9
LBO1
LBO2
PGOOD
PGND
GND
LBO1
LBO2
PGOOD
TPS61106
Figure 30. Low Profile Solution, Maximum Height 1,8 mm
6V
C7
U1
0.1 µF
L1
10 µH
VOUT
3.3 V
C6
2.2 µF
R1
LBI
R2
List of Components:
U1 = TPS61106
L1 = SUMIDA CDRH74–100
C3, C5, C6,
C7, C8 = X7R/X5R Ceramic
C4 = Low ESR Tantalum
DS1 = BAT54S
C8
1 µF
SWN
VBAT
C3
10 µF
DS1
LDOIN
SKIPEN
LDOOUT
ADEN
LDOSENSE
EN
LDOEN
GND
1.5 V
C5
2.2 µF
R7
ENPB
C4
100 µF
R8
R9
LBO1
LBO2
PGOOD
PGND
TPS61106
Figure 31. Dual Power Supply With Auxiliary Positive Output Voltage
22
LBO1
LBO2
PGOOD
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
–3 V
C7
U1
C8
1 µF
0.1 µF
L1
10 µH
DS1
SWN
VBAT
VOUT
3.3 V
C6
2.2 µF
R1
C3
10 µF
LBI
R2
C4
100 µF
LDOIN
1.5 V
SKIPEN
LDOOUT
ADEN
LDOSENSE
EN
C5
2.2 µF
R7
ENPB
List of Components:
U1 = TPS61106
L1 = SUMIDA CDRH74–100
C3, C5, C6,
C7, C8 = X7R/X5R Ceramic
C4 = Low ESR Tantalum
DS1 = BAT54S
LDOEN
R8
R9
LBO1
LBO2
LBO1
LBO2
PGOOD
PGND
GND
PGOOD
TPS61106
Figure 32. Dual Power Supply With Auxiliary Negative Output Voltage
U1
L1
10 µH
SWN
VBAT
C3
10 µF
VOUT
R3
R1
C6
22 µF
FB
LBI
R6
R2
LDOIN
LDOOUT
SKIPEN
ADEN
LDOSENSE
EN
ENPB
List of Components:
U1 = TPS61100
L1 = SUMIDA CDRH74–100
C3, C5 = X7R/X5R Ceramic
C6 = X7R/X5R Ceramic or Low
ESR Tantalum
LDOEN
GND
3.3 V
R5
C5
2.2 µF
R4
LBO1
LBO2
PGOOD
PGND
R7
R8
R9
LBO1
LBO2
PGOOD
TPS61100
Figure 33. Single Output Using LDO as Filter
23
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
U1
L1
SWN
10 µH
VBAT
3.3 V
VOUT
C6
2.2 µF
R1
C3
10 µF
LBI
R2
C4
100 µF
LDOIN
1.5 V
LDOOUT
C5
2.2 µF
SKIPEN
LDOSENSE
ADEN
EN
R10
ENPB
LDOEN
List of Components:
U1 = TPS61106
L1 = SUMIDA 5D18–100
C3, C5, C6 = X7R/X5R Ceramic
C4 = Low ESR Tantalum
GND
R7
R8
R9
LBO1
LBO2
PGOOD
PGND
LBO1
LBO2
TPS61106
Figure 34. Simple Solution Using a Pushbutton for Start-Up
D1
USB-Input
4.2 V – 5.5 V
List of Components:
U1 = TPS61100
L1 = SUMIDA CDRH73–100
C3, C6 = X7R/X5R Ceramic
C4 = Low ESR Tantalum
D1 = ON-Semiconductor MBR0520
D2
R12
180 kΩ
U1
L1
10 µH
SWN
VBAT
VOUT
R1
C3
10 µF
R3 1 MΩ
LBI
R2
R10
680 kΩ
LDOIN
SYNC
ADEN
EN
GND
R6
180 kΩ
R5 1.022 MΩ
LDOSENSE
ENPB
R11
1 MΩ
C4
100 µF
LDOOUT
LDOEN
LBO1
LBO2
PGOOD
PGND
R4
180 kΩ
TPS61100
Figure 35. Dual Input Power Supply
24
C6
2.2 µF
FB
VCC
3.3 V System
Supply
R7
R8
R9
Control
Outputs
TPS61100, TPS61103
TPS61106, TPS61107
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SLVS411B – JUNE 2002 – REVISED APRIL 2004
U1
L1
10 µH
SWN
VBAT
INPUT
C3
10 µF
VOUT
OUTPUT
R3
R1
LBI
FB
C6
2.2 µF
C4
100 µF
R11
R6
R2
R10
LDOIN
LDOOUT
LDOOUT
SKIPEN
SKIPEN
ADEN
LDOSENSE
EN
ADEN
C5
2.2 µF
R5
R4
ENPB
R7
R8
R9
LDOEN
EN
GND
ENPB
LBO1
LBO2
PGOOD
PGND
LBO1
LBO2
PGOOD
TPS6110XRGE
LDOEN
Figure 36. TPS6110x EVM Circuit Diagram
THERMAL INFORMATION
Implementation of integrated circuits in low-profile and fine-pitch surface-mount packages typically requires
special attention to power dissipation. Many system-dependent issues such as thermal coupling, airflow, added
heat sinks and convection surfaces, and the presence of other heat-generating components affect the
power-dissipation limits of a given component.
Three basic approaches for enhancing thermal performance are listed below.
• Improving the power dissipation capability of the PCB design.
• Improving the thermal coupling of the component to the PCB.
• Introducing airflow in the system.
The maximum junction temperature (TJ) of the TPS6110x devices is 150°C. The thermal resistance of the 20-pin
TSSOP package (PW) isRΘJA = 155 K/W (QFN package, RGE, 161 K/W). Specified regulator operation is
assured to a maximum ambient temperature TA of 85°C. Therefore, the maximum power dissipation is about 420
mW. More power can be dissipated if the maximum ambient temperature of the application is lower.
T
T
J(MAX)
A
P
150°C 85°C 420 mW
D(MAX)
R
155 kW
JA
(9)
25
MECHANICAL DATA
MTSS001C – JANUARY 1995 – REVISED FEBRUARY 1999
PW (R-PDSO-G**)
PLASTIC SMALL-OUTLINE PACKAGE
14 PINS SHOWN
0,30
0,19
0,65
14
0,10 M
8
0,15 NOM
4,50
4,30
6,60
6,20
Gage Plane
0,25
1
7
0°– 8°
A
0,75
0,50
Seating Plane
0,15
0,05
1,20 MAX
PINS **
0,10
8
14
16
20
24
28
A MAX
3,10
5,10
5,10
6,60
7,90
9,80
A MIN
2,90
4,90
4,90
6,40
7,70
9,60
DIM
4040064/F 01/97
NOTES: A.
B.
C.
D.
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Body dimensions do not include mold flash or protrusion not to exceed 0,15.
Falls within JEDEC MO-153
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