TI TPS65105PWP

TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
TRIPLE OUTPUT LCD SUPPLY WITH LINEAR REGULATOR AND VCOM BUFFER
FEATURES
•
•
•
•
•
•
•
•
•
•
•
•
•
DESCRIPTION
2.7-V to 5.8-V Input Voltage Range
1.6-MHz Fixed Switching Frequency
3 Independent Adjustable Outputs
Main Output of up to 15 V With < 1% Output
Voltage Accuracy
Negative Output Voltage Down to -12 V/20 mA
Positive Output Voltage up to 30 V/20 mA
Integrated VCOM Buffer
Auxiliary 3.3-V Linear Regulator Controller
Internal Soft Start
Internal Power-On Sequencing
Fault Detection of all Outputs
Thermal Shutdown
Available in TSSOP-24 and QFN-24
PowerPAD™ Packages
APPLICATIONS
•
•
•
•
•
•
TFT LCD Displays for Notebooks
TFT LCD Displays for Monitors
Portable DVD Players
Tablet PCs
Car Navigation Systems
Industrial Displays
The TPS65100/05 offers a compact and small power
supply solution that provides all three voltages
required by thin film transistor (TFT) LCD displays.
The auxiliary linear regulator controller can be used
to generate a 3.3-V logic power rail for systems
powered by a 5-V supply rail only.
The main output, Vo1, is a 1.6-MHz, fixed-frequency
PWM boost converter providing the source drive
voltage for the LCD display. The device is available in
two versions with different internal switch current
limits to allow the use of a smaller external inductor
when lower output power is required. The TPS65100
has a typical switch current limit of 2.3 A, and the
TPS65105 has a typical switch current limit of 1.37 A.
A fully integrated adjustable charge pump
doubler/tripler provides the positive LCD gate drive
voltage. An externally adjustable negative charge
pump provides the negative gate drive voltage. Due
to the high 1.6-MHz switching frequency of the
charge pumps, inexpensive and small 220-nF capacitors can be used.
The TPS65100/05 has an integrated VCOM buffer to
power the LCD backplane. For LCD panels powered
by 5 V only, the TPS65100/05 has a linear regulator
controller using an external transistor to provide a
regulated 3.3-V output for the digital circuits. For
maximum safety, the entire device goes into shutdown as soon as one of the outputs is out of
regulation. The device can be enabled again by
toggling the input or the enable (EN) pin to GND.
TPS65100/05
Vin
2.7 V to 5.8 V
Boost
Converter
Positive Charge
Pump
Vo1
Up to 15 V / 400 mA
Vo3
Up to 30 V / 20 mA
Negative
Charge Pump
Vo2
Up to −12 V / 20 mA
Vcom Buffer
Vcom
Linear Regulator
Controller
Vo4
3.3 V
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.
PowerPAD 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 © 2003–2004, Texas Instruments Incorporated
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 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.
TYPICAL APPLICATION CIRCUIT
L1
4.7 µH
VI
2.7 to 5.8 V
C3
22 µF
TPS65100
VIN
COMP
R7
C1
0.22 µF
R8
VO2
Up to 12 V/20 mA
D2
C12
C4
22 µF
0.22 µF
SW
SW
VCOMIN
FB1
EN
SUP
C2
ENR
D3
R3
C6
0.22 µF
C5
R1
C11
10 nF
VO1
VO1
Up to 15 V/350 mA
D1
C2+
C2−/MODE
C1+
C1−
0.22 µF
R2
Vo3
up to 30 V/20 mA
OUT3
DRV
FB3
FB2
VCOM
REF
FB4
PGND
R5
PGND
BASE
C7
0.22 µF
GND
R4
R6
C11
220 nF
Q1
BCP68
VI
C9
1 µF
VO4
3.3 V
Vcom
C8
1 µF
C10
4.7 µF
ORDERING INFORMATION
TA
-40°C to
85°C
(1)
2
PACKAGE (1)
LINEAR REGULATOR
OUTPUT VOLTAGE
MINIMUM SWITCH
CURRENT LIMIT
TSSOP
QFN
PACKAGE
MARKING
3.3 V
1.6 A
TPS65100PWP
TPS65100RGE
TPS65100
3.3 V
0.96 A
TPS65105PWP
TPS65105RGE
TPS65105
The PWP and RGE packages are available taped and reeled. Add an R suffix to the device type (TPS65100PWPR) to order the device
taped and reeled. The PWPR package has quantities of 2000 devices per reel, and the the RGER package has 3000 devices per reel.
Without suffix the PWP package only, is shipped in tubes with 60 devices per tube.
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted) (1)
UNIT
Voltages on pin VIN (2)
-0.3 V to 6.0 V
Voltages on pin Vo1, SUP, PG
(2)
-0.3 V to 15.5 V
Voltages on pin EN, MODE, ENR (2)
-0.3 V to VI + 0.3 V
Voltage on VCOMIN
14 V
Voltage on pin SW (2)
20 V
Continuous power dissipation
See Dissipation Rating Table
Operating junction temperature range
-40°C to 150°C
Storage temperature range
-65°C to 150°C
Lead temperature (soldering, 10 sec)
(1)
(2)
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.
All voltage values are with respect to network ground terminal.
DISSIPATION RATINGS
PACKAGE
RΘJA
TA≤25°C
POWER RATING
TA = 70°C
POWER RATING
TA = 85°C
POWER RATING
24-Pin TSSOP
30.13 C°/W (PWP soldered)
3.3 W
1.83 W
1.32 W
24-Pin QFN
30.0 C°/W
3.3 W
1.8 W
1.3 W
RECOMMENDED OPERATING CONDITIONS
MIN
TYP
MAX
2.7
UNIT
VIN
Input voltage range
5.8
L
Inductor (1)
V
TA
Operating free-air temperature
-40
85
°C
TJ
Operating junction temperature
-40
125
°C
(1)
Refer to the application section for further information.
4.7
µH
ELECTRICAL CHARACTERISTICS
Vin = 3.3 V, EN = VIN, Vo1 = 10 V, TA = -40°C to 85°C, typical values are at TA = 25°C (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SUPPLY CURRENT
Vin
Input voltage range
2.7
IQIN
Quiescent current into VIN
IQCharge
Charge pump quiescent current into SUP
IQVCOM
VCOM quiescent current into
SUP
IQEN
LDO controller quiescent cur- ENR = VIN, EN = GND
rent into VIN
ISD
Shutdown current into VIN
EN = ENR = GND
VUVLO
Undervoltage lockout
threshold
VIN falling
Thermal shutdown
Temperature rising
160
5.8
V
mA
ENR = VCOMIN = GND, Vo3 = 2 ×Vo1,
Boost converter not switching
0.7
0.9
Vo1 = SUP = 10 V, Vo3 = 2 × Vo1
1.7
2.7
Vo1 = SUP = 10 V, Vo3 = 3× Vo1
3.9
6
ENR = GND, Vo1 = SUP = 10 V
750
1300
µA
300
800
µA
1
10
µA
2.2
2.4
V
mA
°C
LOGIC SIGNALS EN, ENR
VIH
High-level input voltage
1.5
V
3
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
ELECTRICAL CHARACTERISTICS (continued)
Vin = 3.3 V, EN = VIN, Vo1 = 10 V, TA = -40°C to 85°C, typical values are at TA = 25°C (unless otherwise noted)
PARAMETER
VIL
Low-level input voltage
IIleak
Input leakage current
TEST CONDITIONS
MIN
EN = GND or VIN
TYP
0.01
MAX
UNIT
0.4
V
0.1
µA
15
V
MAIN BOOST CONVERTER
Vo1
Output voltage range
5
VO1 - VI
Minimum input to output voltage difference
1
VREF
Reference voltage
1.205
1.213
1.219
V
VFB
Feedback regulation voltage
1.136
1.146
1.154
V
IFB
Feedback input bias current
nA
V
10
100
195
290
Vo1 = 5.0 V, Isw = 500 mA
285
420
rDS(ON)
N-MOSFET on-resistance
(Q1)
Vo1 = 10.0 V, Isw = 500 mA
ILIM
N-MOSFET switch current
limit (Q1)
TPS65100
1.6
2.3
2.6
A
TPS65105
0.96
1.37
1.56
A
rDS(ON)
P-MOSFET on-resistance
(Q2)
Vo1 = 10.0 V, Isw = 100 mA
9
15
Vo1 = 5.0 V, Isw = 100 mA
14
22
IMAX
Maximum P-MOSFET peak
switch current
Ileak
Switch leakage current
fSW
Oscillator frequency
1
Vsw = 15 V
1
10
Vsw = 0 V
1
10
0°C ≤ TA≤ 85°C
1.295
1.6
2.1
-40°C ≤ TA≤ 85°C
1.191
1.6
2.1
Line regulation
2.7 V ≤ VI≤ 5.7 V, Iload = 100 mA
Load regulation
0 mA ≤ IO≤ 300 mA
mΩ
Ω
A
µA
MHz
0.012
%/V
0.2
%/A
NEGATIVE CHARGE PUMP Vo2
Vo2
Output voltage range
Vref
Reference voltage
VFB
Feedback regulation voltage
IFB
Feedback input bias current
rDS(ON)
IO
Q8 P-Channel switch RDSon
Q9 N-Channel switch RDSon
-2
1.213
1.219
-36
0
36
mV
10
100
nA
IO = 20 mA
Minimum output current
V
1.205
4.3
8
2.9
4.4
20
Line regulation
7 V ≤ Vo1 ≤ 15 V, Iload = 10 mA, Vo2 = -5.0 V
Load regulation
1 mA ≤ IO≤ 20 mA, Vo2 = -5.0 V
V
Ω
mA
0.09
%/V
0.126
%/mA
POSITIVE CHARGE PUMP Vo3
Vo3
Output voltage range
30
V
Vref
Reference voltage
1.205
1.213
1.219
V
VFB
Feedback regulation voltage
1.187
1.214
1.238
V
IFB
Feedback input bias current
10
100
nA
Q3 P-Channel switch RDSon
9.9
15.5
Q4 N-Channel switch RDSon
1.1
1.8
4.6
8.5
1.2
2.2
610
720
rDS(ON)
Q5 P-Channel switch RDSon
IO = 20 mA
Q6 N-Channel switch RDSon
Vd
D1 – D4 Shottky diode forward voltage
IO
Minimum output current
4
ID1-D4 = 40 mA
20
Ω
mV
mA
Line regulation
10 V ≤ Vo1 ≤ 15 V, Iload = 10 mA, Vo3 = 27 V
0.56
%/V
Load regulation
1 mA ≤ IO≤ 20 mA, Vo3 = 27 V
0.05
%/mA
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
ELECTRICAL CHARACTERISTICS (continued)
Vin = 3.3 V, EN = VIN, Vo1 = 10 V, TA = -40°C to 85°C, typical values are at TA = 25°C (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
3.4
UNIT
LINEAR REGULATOR CONTROLLER Vo4
Vo4
4.5 V ≤ VI≤ 5.5V, 10 mA ≤ IO≤ 500 mA
Output voltage
IBASE
Maximum base drive current
VI - Vo4 - VBE≥ 0.5 V
(1)
VI - Vo4 - VBE≥ 0.75 V
3.2
3.3
13.5
19
20
27
(1)
Line regulation
4.75 V ≤ VI≤ 5.5 V, Iload = 500 mA
0.186
Load regulation
1 mA ≤ IO≤ 500 mA, VI = 5.0 V
0.064
Start up current
Vo4 ≤ 0.8 V
11
20
V
mA
%/V
%/A
25
mA
VCOM BUFFER
Vcm
Common mode input range
Vos
Input offset voltage
DC Load regulation
IB
2.25
(Vo1)-2
Io = 0 mA
-25
+25
Io = ±25 mA
-30
37
Io = ±50 mA
-45
55
Io = ±100 mA
-72
85
Io = ±150 mA
-97
110
VCOMIN Input bias current
Ipeak
Peak output current
-300
-30
300
V
mV
mV
nA
Vo1 = 15 V
1.2
A
Vo1 = 10 V
0.65
A
Vo1 = 5 V
0.15
A
Vo1 Rising
-12
-8.75%
Vo1
-6
V
Vo2 Rising
-13
-9% Vo2
-5
V
Vo3 Rising
-11
-8% Vo3
-5
V
FAULT PROTECTION THRESHOLDS
V(th, VO1)
V(th, VO2)
Shutdown threshold
V(th, VO3)
With Vin = supply voltage of the TPS65100/05, Vo4 = output voltage of the regulator, VBE = basis emitter voltage of external transistor
DEVICE INFORMATION
8
18
17
9
16
10
15
11
14
12
13
C1+
1
24 23 22 21 20 19
18
ENR
2
17
C2+
EN
3
16
OUT3
FB1
4
15
FB3
FB4
5
14
VCOMIN
BASE
6
Exposed
Thermal Die*
7
8
9 10 11 1213
C2−/MODE
VCOM
SUP
7
DRV
20
19
C1−
5
6
COMP
PGND
21
GND
22
4
PGND
3
EN
ENR
COMP
FB2
REF
GND
DRV
C1−
C1+
C2−/MODE
C2+
OUT3
REF
23
SW
24
2
SW
1
VIN
FB1
FB4
BASE
VIN
SW
SW
PGND
PGND
SUP
VCOM
VCOMIN
FB3
RGE PACKAGE
TOP VIEW
FB2
PWP PACKAGE
TOP VIEW
Thermal PAD*
(1)
5
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
DEVICE INFORMATION (continued)
Terminal Functions
TERMINAL
NO.
(PWP)
NO.
(RGE)
I/O
VIN
4
7
I
Input voltage pin of the device
EN
24
3
I
Enable pin of the device. This pin should be terminated and not be left floating. A logic
high enables the device and a logic low shuts down the device.
COMP
22
1
VCOMIN
11
14
I
Positive input terminal of the VCOM buffer. When the VCOM buffer is not used, this
terminal can be connected to GND to reduce the overall quiescent current of the IC.
ENR
23
2
I
Enable pin of the linear regulator controller. This pin should be terminated and not be
left floating. Logic high enables the regulator and a logic low puts the regulator in
shutdown.
C1+
16
19
C1-
17
20
DRV
18
21
O
External charge pump driver
FB2
21
24
I
Feedback pin of negative charge pump
REF
20
23
O
Internal reference output typically 1.23 V
FB4
2
5
I
Feedback pin of the linear regulator controller. The linear regulator controller is set to a
fixed output voltage of 3.3 V or 3.0 V depending on the version.
O
Base drive output for the external transistor
NAME
BASE
3
6
GND
19
22
PGND
7, 8
10, 11
VCOM
10
13
FB3
12
OUT3
13
DESCRIPTION
Compensation pin for the main boost converter. A small capacitor is connected to this
pin.
Positive terminal of the charge pump flying capacitor
Negative terminal of the charge pump flying capacitor
Ground
Power ground
O
VCOM buffer output
15
I
Feedback pin of positive charge pump
16
O
Positive charge pump output
C2-/MODE
15
18
Negative terminal of the charge pump flying capacitor and charge pump MODE pin. If
the flying capacitor is connected to this pin, the converter operates in a voltage tripler
mode. If the charge pump needs to operate in a voltage doubler mode, the flying
capacitor is removed and the C2-/MODE pin should be connected to GND.
C2+
14
17
Positive terminal for the charge pump flying capacitor. If the device runs in voltage
doubler mode, this pin should be left open.
SUP
9
12
I
Supply pin of the positive, negative charge pump, boost converter gate drive circuit,
and VCOM buffer. This pin should be connected to the output of the main boost
converter and cannot be connected to any other voltage source. For performance
reasons, it is not recommended for a bypass capacitor to be connected directly to this
pin.
FB1
1
4
I
Feedback pin of the boost converter
SW
5, 6
8, 9
I
Switch pin of the boost converter
PowerPAD™/
Thermal Die
6
The PowerPad or exposed thermal die needs to be connected to the power ground
pins (PGND)
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
FUNCTIONAL BLOCK DIAGRAM
VIN
SW
SW
Q2
FB1
FB2
FB3
Bias Vref = 1.213 V
Thermal Shutdown
Start-Up Sequencing
Undervoltage Detection
Short-Circuit Protection
S
D
Main boost
converter
EN
Current Limit
and
Soft Start
1.6-MHz
Oscillator
SUP
Control Logic
Gate Drive Circuit
D
Q1
S
COMP
GM Amplifier
Comparator
Sawtooth
Generator
FB1
VFB
1.146 V
SUP
SUP
(VO)
FB3
Positive
Charge Pump
GM Amplifier
Low Gain
VFB
1.146 V
Vref
1.214 V
Negative
Charge Pump
SUP
Q8
D
Q3
S
Current
Control
C1−
Gain Select
(Doubler or
Tripple Mode)
D
Q4
S
SUP
Soft Start
D
C1+
Current
Control
Soft Start
S
DRV
D
Q7
S
D
Q9
SUP
SUP
S
Vo3
D1
D2
D Q5
D4
S
C2+
FB2
D
Vref
0V
S
D3
Q6
C2−
Reference
Output
REF
Vref
1.213 V
SUP
Vin
Soft Start
Iref = 20 mA
Soft Start
Short Circuit
Detect
D
Q11
S
~1 V
FB4
VCOM
D
Linear
Regulator
Controller
S
Vref
1.213 V
D
Q12
S
Q10
Disable
VCOM
Buffer
ENR
BASE
VCOMIN
GND
PGND
PGND
7
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
TYPICAL CHARACTERISTICS
Table of Graphs
FIGURE
Main Boost Converter
Efficiency, main boost converter Vo1
vs Load current
1
Efficiency, main boost converter Vo1
vs Load current
2
Efficiency
vs Input voltage
3
fsw
Switching frequency
vs Free-air temperature
4
rDS(on)
rDS(on) N-Channel main switch Q1
vs Free-air temperature
5
η
PWM operation, continuous mode
6
PWM operation at light load
7
Load transient response, Cout = 22 µF
8
Load transient response, Cout = 2*22 µF
9
Power-up sequencing
10
Soft start Vo1
11
Negative Charge Pump
Imax
Vo2 Maximum load current
vs Output voltage Vo1
12
Positive Charge Pump
Imax
Vo3 Maximum load current
vs Output voltage Vo1 (doubler mode)
13
Imax
Vo3 Maximum load current
vs Output voltage Vo1 (tripler mode)
14
EFFICIENCY
vs
LOAD CURRENT
100
100
90
90
Vo1 = 15 V
40
30
70
Vo1 = 10 V
60
50
Vo1 = 15 V
40
Vo1 = 6 V
90
Vo2 = 10 V
85
Vo3 = 15 V
80
30
VI = 3.3 V
Vo2, Vo3 = No Load, Switching
20
10
10
100
IL − Load Current − mA
Figure 1.
1k
75
VI = 5 V
Vo2, Vo3 = No Load, Switching
20
10
1
8
ILoad at Vo1 = 100 mA
Vo2, Vo3 = No Load, Switching
Efficiency − %
Efficiency − %
60
50
100
80
Vo1 = 10 V
70
EFFICIENCY
vs
INPUT VOLTAGE
95
Vo1 = 6 V
80
Efficiency − %
EFFICIENCY
vs
LOAD CURRENT
1
10
100
IL − Load Current − mA
Figure 2.
1k
70
2.5
3
3.5
4
4.5
5
VI − Input Voltage − V
Figure 3.
5.5
6
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
TYPICAL CHARACTERISTICS (continued)
SWITCHING FREQUENCY
vs
FREE-AIR TEMPERATURE
rDS(on) N-CHANNEL MAIN SWITCH
vs
FREE-AIR TEMPERATURE
350
r
− N−Channel Main Switch − mΩ
DS(on)
Switching Frequency − MHz
1.9
1.8
VI = 2.7 V
1.7
VI = 3.3 V
1.6
VI = 5.8 V
1.5
1.4
1.3
−40
PWM OPERATION CONTINUOUS
MODE
−20
0
20
40
60
80
100
VSW
10 V/div
300
Vo1 = 5 V
250
VO
50 mV/div
200
Vo1 = 10 V
150
IL
1 A/div
Vo1 = 15 V
100
−40
−20
0
20
40
60
80
VI = 3.3 V
VO = 10 V/300 mA
100
250 ns/div
TA − Free-Air Temperature − °C
TA − Free-Air Temperature − °C
Figure 4.
Figure 5.
Figure 6.
PWM OPERATION AT LIGHT LOAD
LOAD TRANSIENT RESPONSE
LOAD TRANSIENT RESPONSE
VI = 3.3 V
Vo1 = 10 V, CO= 2*22 µF
Vo1
200 mV/div
VSW
10 V/div
Vo1
100 mV/div
VO
50 mV/div
VI = 3.3 V
VO = 10 V/10 mA
IO
50 mA to 250 mA
IL
500 mA/div
VI = 3.3 V
Vo1 = 10 V, CO= 22 µF
IO
50 mA to 250 mA
100 µs/div
100 µs/div
250 ns/div
Figure 7.
Figure 8.
POWER-UP SEQUENCING
SOFT START Vo1
Figure 9.
Vo2 MAXIMUM LOAD CURRENT
0.20
VI = 3.3 V
VO = 10 V,
IO = 300 mA
Vo2 = −8 V
0.18
I O − Output Current − A
Vo1
5 V/div
Vo1
5 V/div
Vo2
5 V/div
Vo3
10 V/div
VCOM
2 V/div
VI = 3.3 V
VO = 10 V,
VCOM CI = 1 nF
500 µs/div
TA = −40°C
0.16
II
500
mA/div
0.14
TA = 85°C
0.12
0.10
TA = 25°C
0.08
0.06
0.04
0.02
500 µs/div
0
8.8
9.8
10.8
11.8
12.8
13.8
14.8
Vo1 − Output Voltage − V
Figure 10.
Figure 11.
Figure 12.
9
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
TYPICAL CHARACTERISTICS (continued)
Vo3 MAXIMUM LOAD CURRENT
Vo3 MAXIMUM LOAD CURRENT
0.14
0.12
TA = −40°C
Vo3 = 18 V (Doubler Mode)
0.10
TA = −40°C
I O − Output Current − A
I O − Output Current − A
0.12
TA = 85°C
0.10
TA = 25°C
0.08
0.06
0.04
TA = 25°C
0.08
TA = 85°C
0.06
0.04
0.02
0.02
Vo3 = 28 V (Tripler Mode)
0
9
10
11
12
13
14
Vo1 − Output Voltage − V
15
0
9
10
11
12
13
14
15
Vo1 − Output Voltage − V
Figure 13.
Figure 14.
DETAILED DESCRIPTION
The TPS65100/05 consists of a main boost converter operating with a fixed switching frequency of 1.6 MHz to
allow for small external components. The boost converter output voltage Vo1 is also the input voltage, connected
via the pin SUP, for the positive and negative charge pumps and the bias supply for the VCOM buffer. The linear
regulator controller is independent from this system with its own enable pin. This allows the linear regulator
controller to continue to operate while the other supply rails are disabled or in shutdown due to a fault condition
on one of their outputs. See the functional block diagram for more information.
Main Boost Converter
The main boost converter operates with PWM and a fixed switching frequency of 1.6 MHz. The converter uses a
unique fast response, voltage mode controller scheme with input voltage feedforward. This achieves excellent
line and load regulation (0.2% A load regulation typical) and allows the use of small external components. To add
higher flexibility to the selection of external component values the device uses external loop compensation.
Although the boost converter looks like a nonsynchronous boost converter topology operating in discontinuous
mode at light load, the TPS65100/05 maintains continuous conduction even at light load currents.
This is achieved with a unique architecture using an external Schottky diode and an integrated MOSFET in
parallel connected between SW and SUP (see the functional block diagram). The integrated MOSFET Q2 allows
the inductor current to become negative at light load conditions. For this purpose, a small integrated P-channel
MOSFET with typically 10 Ω rDSon is sufficient. When the inductor current is positive, the external Schottky diode
with the lower forward voltage conducts the current. This causes the converter to operate with a fixed frequency
in continuous conduction mode over the entire load current range. This avoids the ringing on the switch pin as
seen with a standard nonsynchronous boost converter and allows a simpler compensation for the boost
converter.
VCOM Buffer
VCOMIN is the input of the VCOM buffer. If the VCOM buffer is not required for certain applications, it is possible
to shut down the VCOM buffer by statically connecting VCOMIN to ground, reducing the overall quiescent
current. The VCOM buffer features soft start avoiding a large voltage drop at Vo1 during start-up. The VCOMIN
cannot be pulled dynamically to ground during operation.
Enable and Power On Sequencing (EN, ENR)
The device has two enable pins. These pins should be terminated and not left floating to prevent unpredictable
operation. Pulling the enable pin (EN) high enables the device and starts the power on sequencing with the main
boost converter Vo1 coming up first then the negative and positive charge pumps and the VCOM buffer. If the
VCOMIN pin is held low, the VCOM buffer remains disabled. The linear regulator has an independent enable pin
(ENR). Pulling this pin low disables the regulator, and pulling this pin high enables this regulator.
10
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TPS65100
TPS65105
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
DETAILED DESCRIPTION (continued)
If the enable pin EN is pulled high, the device starts its power on sequencing. The main boost converter starts up
first with its soft start. If the output voltage has reached 91.25% of its output voltage, the negative charge pump
comes up next. The negative charge pump starts with a soft start and when the output voltage has reached 91%
of the nominal value, the positive charge pump comes up with a soft start. The VCOM buffer is enabled as soon
as the positive charge pump has reached its nominal value and VCOMIN is greater than typically 1.0 V.
Pulling the enable pin low shuts down the device. Depended on load current and output capacitance, each of the
outputs goes down.
Positive Charge Pump
The TPS65100/05 has a fully regulated integrated positive charge pump generating Vo3. The input voltage for
the charge pump is applied to the SUP pin that is equal to the output of the main boost converter Vo1. The
charge pump is capable of supplying a minimum load current of 20 mA. Depending on the voltage difference
between Vo1 and Vo3 higher load currents are possible. See Figure 13 and Figure 14.
Negative Charge Pump
The TPS65100/05 has a regulated negative charge pump using two external Schottky diodes. The input voltage
for the charge pump is applied to the SUP pin that is connected to the output of the main boost converter Vo1.
The charge pump inverts the main boost converter output voltage and is capable of supplying a minimum load
current of 20 mA. Depending on the voltage difference between Vo1 and Vo2, higher load currents are possible.
See Figure 12.
Linear Regulator Controller
The TPS65100/05 includes a linear regulator controller to generate a 3.3-V rail which is useful when the system
is powered from a 5-V supply. The regulator is independent from the other voltage rails of the device and has its
own enable (ENR).
Soft Start
The main boost converter as well as the charge pumps, linear regulator, and VCOM buffer have an internal soft
start. This avoids heavy voltage drops at the input voltage rail or at the output of the main boost converter Vo1
during start-up caused by high inrush currents. See Figure 10 and Figure 11.
Fault Protection
All the outputs of the TPS65100/05 have short circuit detection and cause the device to go into shutdown. The
main boost converter has overvoltage and undervoltage protection. If the output voltage Vo1 rises above the
overvoltage protection threshold of typically 5% of Vo1, then the device stops switching but remains operational.
When the output voltage falls below this threshold again, then the converter continues operation. When the
output voltage falls below the undervoltage protection threshold of typically 8.75% of Vo1, in case of a short
circuit condition, then the TPS65100/05 goes into shutdown. Because there is a direct pass from the input to the
output through the diode, the short circuit condition remains. If this condition needs to be avoided, a fuse at the
input or an output disconnect using a single transistor and resistor is required. The negative and positive charge
pumps have an undervoltage lockout to protect the LCD panel of possible latch-up conditions in case of a short
circuit condition or faulty operation. When the negative output voltage is typically above 9.5% of its output voltage
(closer to ground), then the device enters shutdown. When the positive charge pump output voltage Vo3 is below
8% typ of its output voltage, then the device goes into shutdown as well. See the electrical characteristics table
under fault protection thresholds. The device can be enabled again by toggling the enable pin (EN) below 0.4 V
or by cycling the input voltage below the UVLO of 1.7 V. The linear regulator reduces the output current to typical
20 mA under a short circuit condition when the output voltage is typically < 1 V. See the functional block diagram.
The linear regulator does not go into shutdown under a short-circuit condition.
11
TPS65100
TPS65105
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
www.ti.com
DETAILED DESCRIPTION (continued)
Thermal Shutdown
A thermal shutdown is implemented to prevent damage due to excessive heat and power dissipation. Typically,
the thermal shutdown threshold is 160°C. If this temperature is reached, the device goes into shutdown. The
device can be enabled by toggling the enable pin to low and back to high or by cycling the input voltage to GND
and back to VI again.
12
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
APPLICATION INFORMATION
BOOST CONVERTER DESIGN PROCEDURE
The first step in the design procedure is to calculate the maximum possible output current of the main boost
converter under certain input and output voltage conditions. The following example is for a 3.3-V to 10-V
conversion:
Vin = 3.3 V, Vout = 10 V, Switch voltage drop Vsw = 0.5 V, Schottky diode forward voltage VD = 0.8 V
1. Duty cycle:
Vout V V
D
in 10 V 0.8 V 3.3 V 0.73
D
V out V V sw
10 V 0.8 V 0.5 V
D
2. Average inductor current:
I
I out 300 mA 1.11 A
L
1 0.73
1D
3. Inductor peak-to-peak ripple current:
i L
Vin Vsw D
fs L
(3.3 V 0.5 V) 0.73
304 mA
1.6 MHz 4.2 H
4. Peak switch current:
i
I
I L 1.11 A 304 mA 1.26 A
swpeak
L
2
2
. The integrated switch, the inductor, and the external Schottky diode must be able to handle the peak switch
current. The calculated peak switch current has to be equal to or lower than the minimum N-MOSFET switch
current limit as specified in the electrical characteristics table (1.6 A for the TPS65100 and 0.96 A for the
TPS65105). If the peak switch current is higher, then the converter cannot support the required load current. This
calculation must be done for the minimum input voltage where the peak switch current is highest. The calculation
includes conduction losses like switch rDSon (0.5 V) and diode forward drop voltage losses (0.8 V). Additional
switching losses, inductor core and winding losses, etc., require a slightly higher peak switch current in the actual
application. The above calculation still allows a for good design and component selection.
Inductor Selection
Several inductors work with the TPS65100/05. Especially with the external compensation, the performance can
be adjusted to the specific application requirements. The main parameter for inductor selection is the saturation
current of the inductor which should be higher than the peak switch current as calculated above with additional
margin to cover for heavy load transients and extreme start-up conditions. Another method is to choose the
inductor with a saturation current at least as high as the minimum switch current limit of 1.6 A for the TPS65100
and 0.96 A for the TPS65105. The different switch current limits allow selection of a physically smaller inductor
when less output current is required. The second important parameter is inductor dc resistance. Usually, the
lower the dc resistance, the higher the efficiency. However, inductor dc resistance, is not the only parameter
determining the efficiency. Especially for a boost converter where the inductor is the energy storage elemen,t the
type and material of the inductor influences the efficiency as well. Especially at the high switching frequency of
1.6 MHz, inductor core losses, proximity effects, and skin effects become more important. Usually, an inductor
with a larger form factor yields higher efficiency. The efficiency difference between different inductors can vary
between 2% to 10%. For the TPS65100/05, inductor values between 3.3 µH and 6.8 µH are a good choice but
other values can be used as well. Possible inductors are shown in Table 1.
13
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
APPLICATION INFORMATION (continued)
Table 1. Inductor Selection
DEVICE
TPS65100
TPS65105
INDUCTOR VALUE
COMPONENT SUPPLIER
DIMENSIONS
ISAT/DCR
4.7 µH
Coilcraft DO1813P-472HC
8.89*6.1*5.0
2.6 A/54 mΩ
4.2 µH
Sumida CDRH5D28 4R2
5.7*5.7*3
2.2 A/23 mΩ
4.7 µH
Sumida CDC5D23 4R7
6*6*2.5
1.6 A/48 mΩ
3.3 µH
Wuerth Elektronik 744042003
4.8*4.8*2.0
1.8 A/65 mΩ
4.2 µH
Sumida CDRH6D12 4R2
6.5*6.5*1.5
1.8 A/60 mΩ
3.3 µH
Sumida CDRH6D12 3R3
6.5*6.5*1.5
1.9 A/50 mΩ
3.3 µH
Sumida CDPH4D19 3R3
5.1*5.1*2.0
1.5 A/26 mΩ
3.3 µH
Coilcraft DO1606T-332
6.5*5.2*2.0
1.4 A/120 mΩ
3.3 µH
Sumida CDRH2D18/HP 3R3
3.2*3.2*2.0
1.45 A/69 mΩ
4.7 µH
Wuerth Elektronik 744010004
5.5*3.5*1.0
1.0 A/260 mΩ
3.3 µH
Coilcraft LPO6610-332M
6.6*5.5*1.0
1.3 A/160 mΩ
Output Capacitor Selection
For the best output voltage filtering, a low ESR output capacitor is recommended. Ceramic capacitors have a low
ESR value, but depending on the application, tantalum capacitors can be used as well. A 22-µF ceramic output
capacitor works for most of the applications. Higher capacitor values can be used to improve the load transient
regulation. See Table 2 for selection of the output capacitor. The output voltage ripple can be calculated as:
Ip L
I
V out out 1 I p ESR
Cout
f s Vout V V
d
in
with:
Ip = Peak current as described in the previous section peak current control
L = Selected inductor value
Iout = Nominal load current
fs = Switching frequency
Vd = Rectifier diode forward voltage (typically 0.3 V)
Cout = Selected output capacitor
ESR = Output capacitor ESR value
Input Capacitor Selection
For good input voltage filtering, low ESR ceramic capacitors are recommended. A 22-µF ceramic input capacitor
is sufficient for most of the applications. For better input voltage filtering, this value can be increased. See
Table 2 and the typical applications for input capacitor recommendations.
Table 2. Input and Output Capacitors Selection
CAPACITOR
VOLTAGE RATING
COMPONENT SUPPLIER
COMMENTS
22 µF/1210
16 V
Taiyo Yuden EMK325BY226MM
Cout
22 µF/1206
6.3 V
Taiyo Yuden JMK316BJ226
Cin
Rectifier Diode Selection
To achieve high efficiency, a Schottky diode should be used. The voltage rating should be higher than the
maximum output voltage of the converter. The average forward current should be equal to the average inductor
current of the converter. The main parameter influencing the efficiency of the converter is the forward voltage and
the reverse leakage current of the diode; both should be as low as possible. Possible diodes are: On
Semiconductor MBRM120L, Microsemi UPS120E, and Fairchild Semiconductor MBRS130L.
14
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
Converter Loop Design and Stability
The TPS65100/05 converter loop can be externally compensated and allows access to the internal
transconductance error amplifier output at the COMP pin. A small feedforward capacitor across the upper
feedback resistor divider speeds up the circuit as well. To test the converter stability and load transient
performance of the converter, a load step from 50 mA to 250 mA is applied, and the output voltage of the
converter is monitored. Applying load steps to the converter output is a good tool to judge the stability of such a
boost converter.
Design Procedure Quick Steps
1. Select the feedback resistor divider to set the output voltage.
2. Select the feedforward capacitor to place a zero at 50 kHz.
3. Select the compensation capacitor on pin COMP. The smaller the value, the higher the low frequency gain.
4. Use a 50-kΩ potentiometer in series to Cc and monitor Vout during load transients. Fine tune the load
transient by adjusting the potentiometer. Select a resistor value that comes closest to the potentiometer
resistor value. This needs to be done at the highest Vin and highest load current since the stability is most
critical at these conditions.
Setting the Output Voltage and Selecting the Feedforward Capacitor
The output voltage is set by the external resistor divider and is calculated as:
V out 1.146 V 1 R1
R2
Across the upper resistor a bypass capacitor is required to speed up the circuit during load transients as shown
in Figure 15.
VO1
Up to 10 V/150 mA
D1
C8
6.8 pF
SW
SW
R1
430 kΩ
C4
22 µF
FB1
SUP
C2+
C2−/MODE
C2
0.22 µF
R2
56 kΩ
Figure 15. Feedforward Capacitor
Together with R1 the bypass capacitor C8 sets a zero in the control loop at approximately 50 kHz:
1
ƒz 2 C8 R1
A value closest to the calculated value should be used. Larger feedforward capacitor values reduce the load
regulation of the converter and cause load steps as shown in Figure 16.
15
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
Load Step
Figure 16. Load Step Caused By A Too Large Feedforward Capacitor Value
Compensation
The regulator loop can be compensated by adjusting the external components connected to the COMP pin. The
COMP pin is connected to the output of the internal transconductance error amplifier. A typical compensation
scheme is shown in Figure 17.
RC
15 kΩ
CC
VIN
COMP
1 nF
Figure 17. Compensation Network
The compensation capacitor Cc adjusts the low frequency gain and the resistor value adjusts the high frequency
gain. The formula below calculates at what frequency the resistor increases the high frequency gain.
1
fz 2 Cc Rc
Lower input voltages require a higher gain and therefore a lower compensation capacitor value. A good start is
Cc = 1 nF for a 3.3-V input and Cc = 2.2 nF for a 5-V input. If the device operates over the entire input voltage
range from 2.7 V to 5.8 V, a large compensation capacitor up to 10 nF is recommended. Figure 18 shows the
load transient with a larger compensation capacitor, and Figure 19 shows a smaller compensation capacitor.
Figure 18. Cc = 4.7 nF
16
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
Figure 19. Cc = 1 nF
Lastly, Rc needs to be selected. A good practice is to use a 50-kΩ potentiometer and adjust the potentiometer for
best load transient where no oscillations should occur. These tests have to be done at the highest Vin and
highest load current because converter stability is most critical under these conditions. Figure 20, Figure 21, and
Figure 22 show the fine tuning of the loop with Rc.
Figure 20. Overcompensated (Damped Oscillation), Rc Is Too Large
Figure 21. Undercompensated (Loop Is Too Slow), Rc Is Too Small
17
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
Figure 22. Optimum, Rc Is Ideal
Negative Charge Pump
The negative charge pump provides a regulated output voltage by inverting the main output voltage Vo1. The
negative charge pump output voltage is set with external feedback resistors.
The maximum load current of the negative charge pump depends on the voltage drop across the external
Schottky diodes, the internal on resistance of the charge pump MOSFETS Q8 and Q9, and the impedance of the
flying capacitor C12. When the voltage drop across these components is larger than the voltage difference from
Vo1 to Vo2, the charge pump is in dropout, providing the maximum possible output current. Therefore, the higher
the voltage difference between Vo1 and Vo2, the higher the possible load current. See Figure 12 for the possible
output current versus boost converter voltage Vo1.
Voutmin = -(Vo1 - 2 VD - Io (2 × rDS(on)Q8 + 2 × rDS(on)Q9 + Xcfly))
Setting the output voltage:
V out V
REF
1 R3 V
1.213 V 1 R3 1.213 V
REF
R4
R4
Vout VREF 1 R4 Vout 1.213 1
1.213
VREF
R3 R4 The lower feedback resistor value R4 should be in a range between 40 kΩ to 120 kΩ or the overall feedback
resistance should be within 500 kΩ to 1 MΩ. Smaller values load the reference too heavily and larger values may
cause stability problems. The negative charge pump requires two external Schottky diodes. The peak current
rating of the Schottky diode has to be twice the load current of the output. For a 20-mA output current, the dual
Schottky diode BAT54 or similar is a good choice.
Positive Charge Pump
The positive charge pump can be operated in a voltage doubler mode or a voltage tripler mode depending on the
configuration of the C2+ and C2-/MODE pins. Leaving the C2+ pin open and connecting C2-/MODE to GND
forces the positive charge pump to operate in a voltage doubler mode. If higher output voltages are required, the
positive charge pump can be operated as a voltage tripler. To operate the charge pump in the voltage tripler
mode, a flying capacitor needs to be connected to C2+ and C2-/MODE.
The maximum load current of the positive charge pump depends on the voltage drop across the internal Schottky
diodes, the internal on resistance of the charge pump MOSFETS, and the impedance of the flying capacitor.
When the voltage drop across these components is larger than the voltage difference Vo1 × 2 to Vo3 (doubler
mode) or Vo1 × 3 to Vo3 (tripler mode), then the charge pump is in dropout, providing the maximum possible
output current. Therefore, the higher the voltage difference between Vo1 × 2 (doubler) or Vo1 × 3 (tripler) to Vo3,
the higher the possible load current. See Figure 13 and Figure 14 for the output current versus boost converter
voltage Vo1 and the following calculations.
Voltage doubler:
Vo3max = 2 × Vo1 - (2 VD + 2× Io × (2 × rDS(on)Q5 + rDS(on)Q3 + rDS(on)Q4 + XC1))
18
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
Voltage tripler:
Vo3max = 3 × Vo1 - (3 × VD + 2 × Io × (3 × rDS(on)Q5 + rDS(on)Q3 + rDS(on)Q4 + XC1 + XC2))
The output voltage is set by the external resistor divider and is calculated as:
V out 1.214 1 R5
R6
R5 R6 Vout
V
FB
1
R6 V out
1.214
1
VCOM Buffer
The VCOM buffer is typically used to drive the backplane of a TFT panel. The VCOM output voltage is typically
set to half of the main output voltage Vo1 plus a small shift to implement the specific compensation voltage. The
TFT video signal gets coupled through the TFT storage capacitor plus the LCD cell capacitance to the output of
the VCOM buffer. Because of these, short current pulses in the positive and negative direction appear at the
output of the VCOM buffer. To minimize the output voltage ripple caused by the current pulses, a
transconductance amplifier having a current source output and an output capacitor is used. The output capacitor
supports the high frequency part of the current pulses drawn from the LCD panel. The VCOM buffer only needs
to handle the low frequency portion of the current pulses. A 1-µF ceramic output capacitor is sufficient for most of
the applications. When using other output capacitor values it is important to keep in mind that the output
capacitor is part of the VCOM buffer loop stabilization.
The VCOM buffer has an integrated soft start to avoid voltage drops on Vo1 during start-up. The soft start is
implemented as such that the VCOMIN is held low until the VCOM buffer is fully biased and the common mode
range is reached. Then the positive input is released and the VCOM buffer output slowly comes up. Usually a
1-nF capacitor on VCOMIN to GND is used to filter high frequency noise coupled in from Vo1. The size of this
capacitor together with the upper feedback resistor value determines the start-up time. The larger the capacitor
from VCOMIN to GND, the slower the soft start.
Linear Regulator Controller
The TPS65100/05 includes a linear regulator controller to generate a 3.3-V rail when the system is powered from
a 5-V supply. Because an external npn transistor is required, the input voltage of the TPS65100/05 applied to
VIN needs to be higher than the output voltage of the regulator. To provide a minimum base drive current of 13.5
mA, a minimum internal voltage drop of 500 mV from Vin to Vbase is required. This can be translated into a
minimum input voltage on VIN for a certain output voltage as the following calculation shows:
VINmin= Vo4 + VBE + 0.5 V
The base drive current together with the hFE of the external transistor determines the possible output current.
Using a standard npn transistor like the BCP68 allows an output current of 1 A and using the BCP54 allows a
load current of 337 mA for an input voltage of 5 V. Other transistors can be used as well depending on the
required output current, power dissipation, and PCB space. The device is stable with a 4.7-µF ceramic output
capacitor. Larger output capacitor values can be used to improve the load transient response when higher load
currents are required.
Layout Considerations
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 designed, the regulator might show stability and EMI
problems. Therefore, the traces carrying high-switching currents should be routed first using wide and short
traces. The input filter capacitor should be placed as close as possible to the input pin VIN of the IC. See the
evaluation module (EVM) for a layout example.
19
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
Thermal Information
An influential component of thermal performance of a package is board design. To take full advantage of the
heat dissipation abilities of the PowerPAD or QFN package with exposed thermal die, a board that acts similar to
a heat sink and allows the use of an exposed (and solderable) deep downset pad should be used. For further
information, see the Texas Instrumens application notes (SLMA002) PowerPAD Thermally Enhanced Package,
and (SLMA004) PowerPAD Made Easy. For the QFN package, see the application report (SLUA271) QFN/SON
PCB Attachement.
VI
3.3 V
L1
3.3 µH
C3
22 µF
Vo1
R9
15 kΩ
R7
500 kΩ
C14
1 nF
C5
0.22 µF
VIN
COMP
R8
500 kΩ
D2
VO2
−5 V/20 mA
R3
620 kΩ
C8
6.8 pF
TPS65100
C9
1 nF
C1
0.22 µF
C12
0.22 µF
D3
SW
SW
VCOMIN
FB1
EN
SUP
ENR
C1+
C1−
C2+
C2−/MODE
C2
0.22 µF
R1
430 kΩ
FB3
FB2
VCOM
REF
FB4
PGND
PGND
C4
22 µF
R2
56 kΩ
OUT3
DRV
BASE
VO1
10 V/300 mA
D1
VO3
23 V/20 mA
R5
1M
C6
0.22 µF
GND
R3
150 kΩ
R6
56 kΩ
C11
220 nF
Vcom
5V
C7
1 µF
Figure 23. Typical Application, Notebook supply
20
TPS65100
TPS65105
www.ti.com
SLVS496B – SEPTEMBER 2003 – REVISED MARCH 2004
L1
4.7 µH
CDRH5D18−4R1
Vin
5V
C3
22 µF
R9
4.3 kΩ
R7
500 kΩ
VO1
VIN
COMP
VCOMIN
C14
1 nF
VO2
−7 V/20 mA
R8
500 kΩ
C1
0.22 µF
C12
0.22 µF
D2
C6
0.22 µF
C5
3.3 pF
TPS65100
C9
2.2 nF
R3
750 kΩ
D3
EN
ENR
C1+
C1−
DRV
FB2
REF
FB4
BASE
VO1
13.5 V/400 mA
D1
SW
SW
FB1
SUP
R2
75 kΩ
C2+
C2−/MODE
VO3
23 V/20 mA
OUT3
FB3
VCOM
PGND
PGND
GND
C7
0.22 µF
R5
1 MΩ
R4
130 kΩ
C11
220 nF
C4
22 µF
R1
820 kΩ
R6
56 kΩ
Q1
BCP68
Vin
C12
1 µF
VO4
3.3 V/500 mA
C10
4.7 µF
Vcom
7V
C8
1 µF
Figure 24. Typical Application, Monitor Supply
21
THERMAL PAD MECHANICAL DATA
PowerPAD™ PLASTIC SMALL-OUTLINE
PWP (R-PDSO-G24)
www.ti.com
MECHANICAL DATA
MPQF124A – FEBRUARY 2002 – REVISED DECEMBER 2002
RGE (S-PQFP-N24)
PLASTIC QUAD FLATPACK
4,15
3,85
4,15
3,85
Pin 1 Index Area
Top and Bottom
1,00
0,80
0,20 REF.
Seating Plane
0,05
0,08
0,00
2,55 MAX SQ.
0,50
24X
0,30
1
6
0,50
24
7
19
12
18
2,50
13
Exposed Thermal Die Pad
(See Note D)
0,30
24X
0,18
0,10
4204104/B 11/02
NOTES: A.
B.
C.
D.
E.
All linear dimensions are in millimeters.
This drawing is subject to change without notice.
Quad Flatpack, No-leads, (QFN) package configuration.
The package thermal performance may be enhanced by bonding the thermal die pad to an external thermal plane.
Falls within JEDEC M0-220.
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