TPS61040/61041
FEATURES
DESCRIPTION
•
•
•
The TPS61040/41 is a high-frequency boost
converter dedicated for small to medium LCD bias
supply and white LED backlight supplies. The device
is ideal to generate output voltages up to 28 V from a
dual cell NiMH/NiCd or a single cell Li-Ion battery.
The part can also be used to generate standard
3.3-V/5-V to 12-V power conversions.
1
•
•
•
•
•
1.8-V to 6-V Input Voltage Range
Adjustable Output Voltage Range up to 28 V
400-mA (TPS61040) and 250-mA (TPS61041)
Internal Switch Current
Up to 1-MHz Switching Frequency
28-mA Typical No-Load Quiescent Current
1-mA Typical Shutdown Current
Internal Soft Start
Available in SOT23-5, Packages
The TPS61040/41 operates with a switching
frequency up to 1 MHz. This allows the use of small
external components using ceramic as well as
tantalum output capacitors. Together with the thin
SON package, the TPS61040/41 gives a very small
overall solution size. The TPS61040 has an internal
400 mA switch current limit, while the TPS61041 has
a 250-mA switch current limit, offering lower output
voltage ripple and allows the use of a smaller form
factor inductor for lower power applications. The low
quiescent current (typically 28 mA) together with an
optimized control scheme, allows device operation at
very high efficiencies over the entire load current
range.
APPLICATIONS
•
•
•
•
•
•
•
LCD Bias Supply
White-LED Supply for LCD Backlights
Digital Still Camera
PDAs, Organizers, and Handheld PCs
Cellular Phones
Internet Audio Player
Standard 3.3-V/5-V to 12-V Conversion
ORDERING INFORMATION
DEVICE
Package Type
MARKING
Packing
Packing Qty
TPS61040M5/TR
SOT23-5
PHOI
REEL
3000pcs/reel
TPS61041M5/TR
SOT23-5
PHPI
REEL
3000pcs/reel
TYPICAL APPLICATION
EFFICIENCY
vs
OUTPUT CURRENT
5 V
IN
SW
FB
D1
R1
1
VI = 5 V
86
84
CFF
CO
1 µF
3
VO = 18 V
88
VOUT
VIN to 28 V
Efficiency − %
VIN
1.8 V to 6 V
CIN
4.7 µF
90
L1
10 µH
VI = 3.6 V
82
80
VI = 2.4 V
78
76
4
EN
GND
2
74
R2
72
70
0.1
http://www.hgsemi.com.cn
1
1
10
IO − Output Current − mA
100
2022 JAN
TPS61040/61041
SOT23 5 PACKAGE
(Top View)
SW
1
GND
2
FB
3
5
VIN
4
EN
Table 2. Terminal Functions
TERMINAL
NAME
I/O
DESCRIPTION
DBV NO.
EN
4
I
This is the enable pin of the device. Pulling this pin to ground forces the device into shutdown
mode reducing the supply current to less than 1 mA. This pin should not be left floating and needs
to be terminated.
FB
3
I
This is the feedback pin of the device. Connect this pin to the external voltage divider to program
the desired output voltage.
GND
2
–
Ground
SW
1
I
Connect the inductor and the Schottky diode to this pin. This is the switch pin and is connected to
the drain of the internal power MOSFET.
VIN
5
I
Supply voltage pin
FUNCTIONAL BLOCK DIAGRAM
SW
Under Voltage
Lockout
Bias Supply
VIN
400 ns Min
Off Time
Error Comparator
-
FB
S
+
RS Latch
Logic
Gate
Driver
Power MOSFET
N-Channel
VREF = 1.233 V
R
Current Limit
EN
6 µs Max
On Time
+
_
RSENSE
Soft
Start
GND
http://www.hgsemi.com.cn
2
2022 JAN
TPS61040/61041
DETAILED DESCRIPTION
OPERATION
The TPS61040/41 operates with an input voltage range of 1.8 V to 6 V and can generate output voltages up to
28 V. The device operates in a pulse-frequency-modulation (PFM) scheme with constant peak current control.
This control scheme maintains high efficiency over the entire load current range, and with a switching frequency
up to 1 MHz, the device enables the use of very small external components.
The converter monitors the output voltage, and as soon as the feedback voltage falls below the reference voltage
of typically 1.233 V, the internal switch turns on and the current ramps up. The switch turns off as soon as the
inductor current reaches the internally set peak current of typically 400 mA (TPS61040) or 250 mA (TPS61041).
See the Peak Current Control section for more information. The second criteria that turns off the switch is the
maximum on-time of 6 ms (typical). This is just to limit the maximum on-time of the converter to cover for extreme
conditions. As the switch is turned off the external Schottky diode is forward biased delivering the current to the
output. The switch remains off for a minimum of 400 ns (typical), or until the feedback voltage drops below the
reference voltage again. Using this PFM peak current control scheme the converter operates in discontinuous
conduction mode (DCM) where the switching frequency depends on the output current, which results in very high
efficiency over the entire load current range. This regulation scheme is inherently stable, allowing a wider
selection range for the inductor and output capacitor.
PEAK CURRENT CONTROL
The internal switch turns on until the inductor current reaches the typical dc current limit (ILIM) of 400 mA
(TPS61040) or 250 mA (TPS61041). Due to the internal propagation delay of typical 100 ns, the actual current
exceeds the dc current limit threshold by a small amount. The typical peak current limit can be calculated:
V
I
+I
) IN
100 ns
peak(typ)
LIM
L
V
100 ns for the TPS61040
I
+ 400 mA ) IN
peak(typ)
L
V
I
+ 250 mA ) IN
100 ns for the TPS61041
peak(typ)
L
(1)
The higher the input voltage and the lower the inductor value, the greater the peak.
By selecting the TPS61040 or TPS61041, it is possible to tailor the design to the specific application current limit
requirements. A lower current limit supports applications requiring lower output power and allows the use of an
inductor with a lower current rating and a smaller form factor. A lower current limit usually has a lower output
voltage ripple as well.
http://www.hgsemi.com.cn
3
2022 JAN
TPS61040/61041
SOFT START
All inductive step-up converters exhibit high inrush current during start-up if no special precaution is made. This
can cause voltage drops at the input rail during start up and may result in an unwanted or early system shut
down.
I LIM
The TPS61040/41 limits this inrush current by increasing the current limit in two steps starting from
4
for 256
I LIM
cycles to
2
for the next 256 cycles, and then full current limit (see Figure 14).
ENABLE
Pulling the enable (EN) to ground shuts down the device reducing the shutdown current to 1 mA (typical).
Because there is a conductive path from the input to the output through the inductor and Schottky diode, the
output voltage is equal to the input voltage during shutdown. The enable pin needs to be terminated and should
not be left floating. Using a small external transistor disconnects the input from the output during shutdown as
shown in Figure 18.
UNDERVOLTAGE LOCKOUT
An undervoltage lockout prevents misoperation of the device at input voltages below typical 1.5 V. When the
input voltage is below the undervoltage threshold, the main switch is turned off.
THERMAL SHUTDOWN
An internal thermal shutdown is implemented and turns off the internal MOSFETs when the typical junction
temperature of 168°C is exceeded. The thermal shutdown has a hysteresis of typically 25°C. This data is based
on statistical means and is not tested during the regular mass production of the IC.
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature (unless otherwise noted)
(1)
UNIT
Supply voltages on pin VIN
Voltages on pins EN, FB
(2)
–0.3 V to 7 V
(2)
Switch voltage on pin SW
–0.3 V to VIN + 0.3 V
(2)
30 V
Continuous power dissipation
See Dissipation Rating Table
TJ
Operating junction temperature
–40°C to 150°C
Tstg
Storage temperature
–65°C to 150°C
(1)
(2)
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.
All voltage values are with respect to network ground terminal.
http://www.hgsemi.com.cn
4
2022 JAN
TPS61040/61041
RECOMMENDED OPERATING CONDITIONS
MIN
VIN
Input voltage range
VOUT
Output voltage range
L
Inductor (1)
f
Switching frequency (1)
TYP
6
28
2.2
10
CIN
Input capacitor
Output capacitor
4.7
(1)
UNIT
V
V
mH
1
(1)
COUT
MAX
1.8
MHz
mF
1
mF
TA
Operating ambient temperature
–40
85
°C
TJ
Operating junction temperature
–40
125
°C
TYP
MAX
UNIT
(1)
See application section for further information.
ELECTRICAL CHARACTERISTICS
VIN = 2.4 V, EN = VIN, TA = –40°C to 85°C, typical values are at TA = 25°C (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
SUPPLY CURRENT
VIN
Input voltage range
6
V
IQ
Operating quiescent current
IOUT = 0 mA, not switching, VFB = 1.3 V
1.8
28
50
mA
ISD
Shutdown current
EN = GND
0.1
1
mA
VUVLO
Under-voltage lockout threshold
1.5
1.7
V
ENABLE
VIH
EN high level input voltage
VIL
EN low level input voltage
II
EN input leakage current
1.3
EN = GND or VIN
V
0.4
V
1
mA
30
V
0.1
POWER SWITCH AND CURRENT LIMIT
Vsw
Maximum switch voltage
toff
Minimum off time
250
400
550
ns
ton
Maximum on time
4
6
7.5
ms
RDS(on)
MOSFET on-resistance
VIN = 2.4 V; ISW = 200 mA; TPS61040
600
1000
mΩ
750
1250
mΩ
1
10
mA
RDS(on)
MOSFET on-resistance
VIN = 2.4 V; ISW = 200 mA; TPS61041
MOSFET leakage current
VSW = 28 V
ILIM
MOSFET current limit
TPS61040
350
400
450
mA
ILIM
MOSFET current limit
TPS61041
215
250
285
mA
28
V
OUTPUT
VOUT
Adjustable output voltage range
Vref
Internal voltage reference
VIN
1.233
IFB
Feedback input bias current
VFB = 1.3 V
VFB
Feedback trip point voltage
1.8 V ≤ VIN ≤ 6 V
Line regulation
(1)
Load regulation (1)
(1)
1.208
1.233
V
1
mA
1.258
V
1.8 V ≤ VIN ≤ 6 V; VOUT = 18 V; Iload = 10 mA;
CFF = not connected
0.05
%/V
VIN = 2.4 V; VOUT = 18 V; 0 mA ≤ IOUT ≤ 30 mA
0.15
%/mA
The line and load regulation depend on the external component selection. See the application section for further information.
http://www.hgsemi.com.cn
5
2022 JAN
TPS61040/61041
TYPICAL CHARACTERISTICS
Table 3. Table of Graphs
FIGURE
vs Load current
1, 2, 3
h
Efficiency
vs Input voltage
4
IQ
Quiescent current
vs Input voltage and temperature
5
VFB
Feedback voltage
vs Temperature
6
ISW
Switch current limit
ICL
Switch current limit
RDS(on)
RDS(on)
vs Temperature
7
vs Supply voltage, TPS61041
8
vs Supply voltage, TPS61040
9
vs Temperature
10
vs Supply voltage
11
Line transient response
12
Load transient response
13
Start-up behavior
14
EFFICIENCY
vs
OUTPUT CURRENT
EFFICIENCY
vs
LOAD CURRENT
90
90
VO = 18 V
88
88
VI = 5 V
86
86
82
80
VI = 2.4 V
78
82
78
76
74
74
72
72
1
10
IO − Output Current − mA
70
0.1
100
Figure 1.
http://www.hgsemi.com.cn
TPS61041
80
76
70
0.1
TPS61040
84
VI = 3.6 V
Efficiency − %
Efficiency − %
84
L = 10 µH
VO = 18 V
1
10
IL − Load Current − mA
100
Figure 2.
6
2022 JAN
TPS61040/61041
EFFICIENCY
vs
LOAD CURRENT
EFFICIENCY
vs
INPUT VOLTAGE
90
88
90
VO = 18 V
86
IO = 10 mA
86
L = 10 µH
84
IO = 5 mA
84
L = 3.3 µH
82
Efficiency − %
Efficiency − %
L = 10 µH
VO = 18 V
88
80
78
82
80
78
76
76
74
74
72
72
70
70
0.1
1
10
IL − Load Current − mA
1
100
2
3
4
5
6
VI − Input Voltage − V
Figure 3.
Figure 4.
TPS61040
QUIESCENT CURRENT
vs
INPUT VOLTAGE
FEEDBACK VOLTAGE
vs
FREE-AIR TEMPERATURE
40
1.24
TA = 85°C
35
VFB − Feedback Voltage − V
Quiescent Current − µA
1.238
30
TA = 27°C
25
TA = −40°C
20
15
10
1.236
VCC = 2.4 V
1.234
1.232
5
0
1.8
2.4
3
3.6
4.2
4.8
5.4
1.23
−40
6
VI − Input Voltage − V
Figure 5.
http://www.hgsemi.com.cn
−20
0
20
40
60
80
TA − Temperature − °C
100
120
Figure 6.
7
2022 JAN
TPS61040/61041
TPS61040/41
SWITCH CURRENT LIMIT
vs
FREE-AIR TEMPERATURE
TPS61041
CURRENT LIMIT
vs
SUPPLY VOLTAGE
260
430
TPS61040
258
390
256
I(CL) − Current Limit − mA
I(SW) − Switch Current Limit − mA
410
370
350
330
310
290
254
TA = 27°C
252
250
248
246
244
270
TPS61041
250
242
230
−40 −30 −20 −10 0 10 20 30 40 50 60 70 80 90
TA − Temperature − °C
240
1.8
TPS61040
CURRENT LIMIT
vs
SUPPLY VOLTAGE
TPS61040/41
STATIC DRAIN-SOURCE ON-STATE RESISTANCE
vs
FREE-AIR TEMPERATURE
rDS(on) − Static Drain-Source On-State Resistance − mΩ
I(CL) − Current Limit − mA
5.4
Figure 8.
415
410
405
TA = 27°C
400
395
390
385
2.4
3
3.6
4.2
4.8
VCC − Supply Voltage − V
Figure 7.
420
380
1.8
2.4
3
3.6
4.2
4.8
5.4
6
VCC − Supply Voltage − V
Figure 9.
http://www.hgsemi.com.cn
6
1200
1000
TPS61041
800
TPS61040
600
400
200
0
−40 −30 −20 −10 0 10 20 30 40 50 60 70 80 90
TA − Temperature − °C
Figure 10.
8
2022 JAN
TPS61040/61041
rDS(on) − Static Drain-Source On-State Resistance − mΩ
TPS61040/41
STATIC DRAIN-SOURCE ON-STATE RESISTANCE
vs
SUPPLY VOLTAGE
1000
VO = 18 V
900
VI
2.4 V to 3.4 V
800
TPS61041
700
600
TPS61040
500
400
VO
100 mV/div
300
200
100
0
1.8
2.4
3
3.6
4.2
4.8
5.4
200 µS/div
6
VCC − Supply Voltage − V
Figure 11.
Figure 12. Line Transient Response
VO = 18 V
VO = 18 V
VO
100 mA/div
VO
5 V/div
EN
1 V/div
VO
1 mA to 10 mA
II
50 mA/div
200 µS/div
Figure 13. Load Transient Response
http://www.hgsemi.com.cn
Figure 14. Start-Up Behavior
9
2022 JAN
TPS61040/61041
APPLICATION INFORMATION
INDUCTOR SELECTION, MAXIMUM LOAD CURRENT
Because the PFM peak current control scheme is inherently stable, the inductor value does not affect the stability
of the regulator. The selection of the inductor together with the nominal load current, input and output voltage of
the application determines the switching frequency of the converter. Depending on the application, inductor
values between 2.2 mH and 47 mH are recommended. The maximum inductor value is determined by the
maximum on time of the switch, typically 6 ms. The peak current limit of 400 mA/250 mA (typically) should be
reached within this 6-ms period for proper operation.
The inductor value determines the maximum switching frequency of the converter. Therefore, select the inductor
value that ensures the maximum switching frequency at the converter maximum load current is not exceeded.
The maximum switching frequency is calculated by the following formula:
V
(V
*V
IN(min)
OUT
IN)
fS max +
I
L V
P
OUT
Where:
IP = Peak current as described in the Peak Current Control section
L = Selected inductor value
VIN(min) = The highest switching frequency occurs at the minimum input voltage
(2)
If the selected inductor value does not exceed the maximum switching frequency of the converter, the next step
is to calculate the switching frequency at the nominal load current using the following formula:
2 I
(V
* V ) Vd)
load
OUT
IN
fS I
+
2
load
L
I
P
ǒ
Ǔ
Where:
IP = Peak current as described in the Peak Current Control section
L = Selected inductor value
Iload = Nominal load current
Vd = Rectifier diode forward voltage (typically 0.3V)
(3)
A smaller inductor value gives a higher converter switching frequency, but lowers the efficiency.
The inductor value has less effect on the maximum available load current and is only of secondary order. The
best way to calculate the maximum available load current under certain operating conditions is to estimate the
expected converter efficiency at the maximum load current. This number can be taken out of the efficiency
graphs shown in Figure 1 through Figure 4. The maximum load current can then be estimated as follows:
I 2 L fS max
I
+h P
load max
2 (V
*V
OUT
IN)
Where:
IP = Peak current as described in the Peak Current Control section
L = Selected inductor value
fSmax = Maximum switching frequency as calculated previously
h = Expected converter efficiency. Typically 70% to 85%
http://www.hgsemi.com.cn
10
(4)
2022 JAN
TPS61040/61041
The maximum load current of the converter is the current at the operation point where the converter starts to
enter the continuous conduction mode. Usually the converter should always operate in discontinuous conduction
mode.
Last, the selected inductor should have a saturation current that meets the maximum peak current of the
converter (as calculated in the Peak Current Control section). Use the maximum value for ILIM for this calculation.
Another important inductor parameter is the dc resistance. The lower the dc resistance, the higher the efficiency
of the converter. See Table 4 and the typical applications for the inductor selection.
Table 4. Recommended Inductor for Typical LCD Bias Supply (see Figure 15)
DEVICE
INDUCTOR VALUE
COMPONENT SUPPLIER
COMMENTS
10 mH
Sumida CR32-100
High efficiency
10 mH
Sumida CDRH3D16-100
High efficiency
10 mH
Murata LQH4C100K04
High efficiency
4.7 mH
Sumida CDRH3D16-4R7
Small solution size
4.7 mH
Murata LQH3C4R7M24
Small solution size
10 mH
Murata LQH3C100K24
High efficiency
Small solution size
TPS61040
TPS61041
SETTING THE OUTPUT VOLTAGE
The output voltage is calculated as:
V
OUT
+ 1.233 V
ǒ1 ) R1
Ǔ
R2
(5)
For battery-powered applications, a high-impedance voltage divider should be used with a typical value for R2 of
≤200 kΩ and a maximum value for R1 of 2.2 MΩ. Smaller values might be used to reduce the noise sensitivity of
the feedback pin.
A feedforward capacitor across the upper feedback resistor R1 is required to provide sufficient overdrive for the
error comparator. Without a feedforward capacitor, or one whose value is too small, the TPS61040/41 shows
double pulses or a pulse burst instead of single pulses at the switch node (SW), causing higher output voltage
ripple. If this higher output voltage ripple is acceptable, the feedforward capacitor can be left out.
The lower the switching frequency of the converter, the larger the feedforward capacitor value required. A good
starting point is to use a 10-pF feedforward capacitor. As a first estimation, the required value for the feedforward
capacitor at the operation point can also be calculated using the following formula:
1
C
+
FF
fS
2 p
R1
20
Where:
R1 = Upper resistor of voltage divider
fS = Switching frequency of the converter at the nominal load current (See the Inductor Selection, Maximum
Load Current section for calculating the switching frequency)
CFF = Choose a value that comes closest to the result of the calculation
http://www.hgsemi.com.cn
11
(6)
2022 JAN
TPS61040/61041
The larger the feedforward capacitor the worse the line regulation of the device. Therefore, when concern for line
regulation is paramount, the selected feedforward capacitor should be as small as possible. See the following
section for more information about line and load regulation.
LINE AND LOAD REGULATION
The line regulation of the TPS61040/41 depends on the voltage ripple on the feedback pin. Usually a 50 mV
peak-to-peak voltage ripple on the feedback pin FB gives good results.
Some applications require a very tight line regulation and can only allow a small change in output voltage over a
certain input voltage range. If no feedforward capacitor CFF is used across the upper resistor of the voltage
feedback divider, the device has the best line regulation. Without the feedforward capacitor the output voltage
ripple is higher because the TPS61040/41 shows output voltage bursts instead of single pulses on the switch pin
(SW), increasing the output voltage ripple. Increasing the output capacitor value reduces the output voltage
ripple.
If a larger output capacitor value is not an option, a feedforward capacitor CFF can be used as described in the
previous section. The use of a feedforward capacitor increases the amount of voltage ripple present on the
feedback pin (FB). The greater the voltage ripple on the feedback pin (≥50 mV), the worse the line regulation.
There are two ways to improve the line regulation further:
1. Use a smaller inductor value to increase the switching frequency which will lower the output voltage ripple,
as well as the voltage ripple on the feedback pin.
2. Add a small capacitor from the feedback pin (FB) to ground to reduce the voltage ripple on the feedback pin
down to 50 mV again. As a starting point, the same capacitor value as selected for the feedforward capacitor
CFF can be used.
OUTPUT CAPACITOR SELECTION
For best output voltage filtering, a low ESR output capacitor is recommended. Ceramic capacitors have a low
ESR value but tantalum capacitors can be used as well, depending on the application.
Assuming the converter does not show double pulses or pulse bursts on the switch node (SW), the output
voltage ripple can be calculated as:
I
DV out + out
Cout
Ǔ
ǒ
I
L
P
1
–
fS(Iout) Vout ) Vd–Vin
)I
P
ESR
where:
IP = Peak current as described in the Peak Current Control section
L = Selected inductor value
Iout = Nominal load current
fS (Iout) = Switching frequency at the nominal load current as calculated previously
Vd = Rectifier diode forward voltage (typically 0.3 V)
Cout = Selected output capacitor
ESR = Output capacitor ESR value
(7)
See Table 5 and the typical applications section for choosing the output capacitor.
Table 5. Recommended Input and Output Capacitors
DEVICE
TPS61040/41
CAPACITOR
VOLTAGE RATING
COMPONENT SUPPLIER
COMMENTS
4.7 mF/X5R/0805
6.3 V
Tayo Yuden JMK212BY475MG
CIN/COUT
10 mF/X5R/0805
6.3 V
Tayo Yuden JMK212BJ106MG
CIN/COUT
1 mF/X7R/1206
25 V
Tayo Yuden TMK316BJ105KL
COUT
1 mF/X5R/1206
35 V
Tayo Yuden GMK316BJ105KL
COUT
4.7 mF/X5R/1210
25 V
Tayo Yuden TMK325BJ475MG
COUT
http://www.hgsemi.com.cn
12
2022 JAN
TPS61040/61041
INPUT CAPACITOR SELECTION
For good input voltage filtering, low ESR ceramic capacitors are recommended. A 4.7 mF ceramic input capacitor
is sufficient for most of the applications. For better input voltage filtering this value can be increased. See Table 5
and typical applications for input capacitor recommendations.
DIODE SELECTION
To achieve high efficiency a Schottky diode should be used. The current rating of the diode should meet the
peak current rating of the converter as it is calculated in the Peak Current Control section. Use the maximum
value for ILIM for this calculation. See Table 6 and the typical applications for the selection of the Schottky diode.
Table 6. Recommended Schottky Diode for Typical LCD Bias Supply (see Figure 15)
DEVICE
REVERSE VOLTAGE
COMPONENT SUPPLIER
30 V
ON Semiconductor MBR0530
TPS61040/41
20 V
ON Semiconductor MBR0520
20 V
ON Semiconductor MBRM120L
30 V
Toshiba CRS02
COMMENTS
High efficiency
LAYOUT CONSIDERATIONS
Typical for all switching power supplies, the layout is an important step in the design; especially at high peak
currents and switching frequencies. If the layout is not carefully done, the regulator might show noise problems
and duty cycle jitter.
The input capacitor should be placed as close as possible to the input pin for good input voltage filtering. The
inductor and diode should be placed as close as possible to the switch pin to minimize the noise coupling into
other circuits. Because the feedback pin and network is a high-impedance circuit, the feedback network should
be routed away from the inductor. The feedback pin and feedback network should be shielded with a ground
plane or trace to minimize noise coupling into this circuit.
Wide traces should be used for connections in bold as shown in Figure 15. A star ground connection or ground
plane minimizes ground shifts and noise.
D1
L1
VO
VIN
VIN
CFF
R1
SW
CO
FB
CIN
EN
R2
GND
Figure 15. Layout Diagram
http://www.hgsemi.com.cn
13
2022 JAN
TPS61040/61041
L1
10 µH
VIN
1.8 V to 6 V
D1
VOUT
18 V
TPS61040
VIN
CFF
22 pF
R1
2.2 MW
SW
C2
1 µF
FB
C1
4.7 µF
EN
GND
L1:
D1:
C1:
C2:
R2
160 kW
Sumida CR32-100
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Tayo Yuden TMK316BJ105KL
Figure 16. LCD Bias Supply
L1
10 µH
D1
VO
18 V
TPS61040
VIN
1.8 V to 6 V
VIN
CFF
22 pF
R1
2.2 MW
SW
C2
1 µF
FB
C1
4.7 µF
EN
GND
DAC or Analog Voltage
0 V = 25 V
1.233 V = 18 V
R2
160 kW
L1:
D1:
C1:
C2:
Sumida CR32-100
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Tayo Yuden GMK316BJ105KL
Figure 17. LCD Bias Supply With Adjustable Output Voltage
R3
200 kW
VIN
1.8 V to 6 V
L1
10 µH
TPS61040
VIN
C1
4.7 µF
SW
FB
EN
GND
BC857C
D1
VOUT
18 V / 10 mA
R1
2.2 MW
C2
1 µF
CFF
22 pF
C3
0.1 µF
(Optional)
R2
160 kW
L1:
D1:
C1:
C2:
Sumida CR32-100
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Tayo Yuden TMK316BJ105KL
Figure 18. LCD Bias Supply With Load Disconnect
http://www.hgsemi.com.cn
14
2022 JAN
TPS61040/61041
D3
V2 = –10 V/15 mA
D2
L1
6.8 µH
C4
4.7 µF
C3
1 µF
D1
V1 = 10 V/15 mA
TPS61040
VIN
VIN = 2.7 V to 5 V
SW
CFF
22 pF
R1
1.5 MW
C2
1 µF
FB
C1
4.7 µF
EN
GND
L1:
D1, D2, D3:
C1:
C2, C3, C4:
R2
210 kW
Murata LQH4C6R8M04
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Tayo Yuden EMK316BJ105KF
Figure 19. Positive and Negative Output LCD Bias Supply
L1
6.8 µH
D1
VO = 12 V/35 mA
TPS61040
VIN 3.3 V
C1
10 µF
VIN
SW
R1
1.8 MW
CFF
4.7 pF
C2
4.7 µF
FB
EN
GND
L1:
D1:
C1:
C2:
R2
205 kW
Murata LQH4C6R8M04
Motorola MBR0530
Tayo Yuden JMK212BJ106MG
Tayo Yuden EMK316BJ475ML
Figure 20. Standard 3.3-V to 12-V Supply
D1
3.3 µH
5 V/45 mA
TPS61040
VIN
1.8 V to 4 V
SW
CFF
3.3 pF
R1
620 kW
C2
4.7 µF
FB
C1
4.7 µF
EN
GND
R2
200 kW
L1:
D1:
C1, C2:
Murata LQH4C3R3M04
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Figure 21. Dual Battery Cell to 5-V/50-mA Conversion
Efficiency Approx. Equals 84% at VIN = 2.4 V to Vo = 5 V/45 mA
http://www.hgsemi.com.cn
15
2022 JAN
TPS61040/61041
L1
10 µH
VCC = 2.7 V to 6 V
VIN
SW
C1
4.7 µF
D1
D2
24 V
(Optional)
FB
EN
PWM
100 Hz to 500 Hz
C2
1 µF
GND
RS
82 Ω
L1:
D1:
C1:
C2:
Murata LQH4C100K04
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Tayo Yuden TMK316BJ105KL
Figure 22. White LED Supply With Adjustable Brightness Control
Using a PWM Signal on the Enable Pin, Efficiency Approx. Equals 86% at VIN = 3 V, ILED = 15 mA
L1
10 µH
VCC = 2.7 V to 6 V
C1
4.7 µF
VIN
SW
D2
24 V
(Optional)
FB
EN
C2
100 nF
(See
Note A)
R1
120 kΩ
GND
Analog Brightness Control
3.3 V ≅ Led Off
0 V ≅ Iled = 20 mA
A.
D1
MBRM120L
R2
160 kΩ
RS
110 Ω
L1:
D1:
C1:
C2:
Murata LQH4C3R3M04
Motorola MBR0530
Tayo Yuden JMK212BY475MG
Standard Ceramic Capacitor
A smaller output capacitor value for C2 causes a larger LED ripple.
Figure 23. White LED Supply With Adjustable Brightness Control
Using an Analog Signal on the Feedback Pin
http://www.hgsemi.com.cn
16
2022 JAN
TPS61040/61041
PACKAGE
SOT23-5
Dimensions In Millimeters
http://www.hgsemi.com.cn
17
Symbol
Min
Max
Symbol
Min
Max
A
1.050
1.150
D
0.300
0.600
A1
0.000
0.100
Q
0.400
B
2.820
3.020
a
C
2.650
2.950
b
0.950
C1
1.500
1.700
e
1.900
2022 JAN
TPS61040/61041
Important statement:
Huaguan Semiconductor Co,Ltd. reserves the right to change
the products and services provided without notice. Customers
should obtain the latest relevant information before ordering,
and verify the timeliness and accuracy of this information.
Customers are responsible for complying with safety
standards and taking safety measures when using our
products for system design and machine manufacturing to
avoid potential risks that may result in personal injury or
property damage.
Our products are not licensed for applications in life support,
military, aerospace, etc., so we do not bear the consequences
of the application of these products in these fields.
Our documentation is only permitted to be copied without
any tampering with the content, so we do not accept any
responsibility or liability for the altered documents.
http://www.hgsemi.com.cn
18
2022 JAN