MAXIM MAX1779

19-1795; Rev 0; 11/00
Low-Power Triple-Output TFT LCD DC-DC
Converter
The MAX1779 triple-output DC-DC converter provides
highly efficient regulated voltages required by small
active matrix, thin-film transistor (TFT) liquid-crystal displays (LCDs). One high-power DC-DC converter and
two low-power charge pumps convert the +2.7V to
+5.5V input supply voltage into three independent output voltages.
The primary high-power DC-DC converter generates a
boosted output voltage (VMAIN) up to 13V that is regulated within ±1%. The low-power BiCMOS control circuitry and the low on-resistance (1Ω) of the integrated
power MOSFET allows efficiency up to 91%. The
250kHz current-mode pulse-width modulation (PWM)
architecture provides fast transient response and
allows the use of ultra-small inductors and ceramic
capacitors.
The dual charge pumps independently regulate one
positive output (VPOS) and one negative output (VNEG).
These low-power outputs use external diode and
capacitor stages (as many stages as required) to regulate output voltages up to +40V and down to -40V. A
proprietary regulation algorithm minimizes output ripple, as well as capacitor sizes for both charge pumps.
The MAX1779 is available in the ultra-thin TSSOP package (1.1mm max height).
Features
♦ Three Integrated DC-DC Converters
♦ 250kHz Current-Mode PWM Boost Regulator
Up to +13V Main High-Power Output
±1% Accuracy
High Efficiency (91%)
♦ Dual Charge-Pump Outputs
Up to +40V Positive Charge-Pump Output
Down to -40V Negative Charge-Pump Output
♦ Internal Supply Sequencing
♦ Internal Power MOSFETs
♦ +2.7V to +5.5V Input Supply
♦ 0.1µA Shutdown Current
♦ 0.5mA Quiescent Current
♦ Internal Soft-Start
♦ Power-Ready Output
♦ Ultra-Small External Components
♦ Thin TSSOP Package (1.1mm max)
Ordering Information
PART
MAX1779EUE
TEMP. RANGE
PIN-PACKAGE
-40°C to +85°C
16 TSSOP
Pin Configuration
________________________Applications
TFT Active-Matrix LCD Displays
Passive-Matrix LCD Displays
TOP VIEW
16 TGND
RDY 1
FB 2
PDAs
Digital-Still Cameras
INTG 3
IN 4
Camcorders
15 LX
14 PGND
MAX1779
13 SUPP
GND 5
12 DRVP
REF 6
11 SUPN
FBP 7
10 DRVN
FBN 8
9
SHDN
TSSOP
Typical Operating Circuit appears at end of data sheet.
________________________________________________________________ Maxim Integrated Products
1
For price, delivery, and to place orders, please contact Maxim Distribution at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX1779
General Description
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
ABSOLUTE MAXIMUM RATINGS
IN, SHDN, TGND to GND .........................................-0.3V to +6V
DRVN to GND .........................................-0.3V to (VSUPN + 0.3V)
DRVP to GND..........................................-0.3V to (VSUPP + 0.3V)
PGND to GND.....................................................................±0.3V
RDY to GND ...........................................................-0.3V to +14V
LX, SUPP, SUPN to PGND .....................................-0.3V to +14V
INTG, REF, FB, FBN, FBP to GND ...............-0.3V to (VIN + 0.3V)
Continuous Power Dissipation (TA = +70°C)
16-Pin TSSOP (derate 9.4mW/°C above +70°C) ..........755mW
Operating Temperature Range
MAX1779EUE ..................................................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°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 in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = +3.0V, SHDN = IN, VSUPP = VSUPN = +10V, TGND = PGND = GND, CREF = 0.22µF, CINTG = 2200pF, TA = 0°C to +85°C,
unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
Input Supply Range
SYMBOL
CONDITIONS
VIN
Input Undervoltage Threshold
VUVLO
IN Quiescent Supply Current
IIN
MIN
TYP
2.7
VIN rising, 40mV hysteresis (typ)
2.2
MAX
UNITS
5.5
V
2.4
2.6
V
VFB = VFBP = +1.5V, VFBN = -0.2V
0.5
1
mA
SUPP Quiescent Current
ISUPP
VFBP = +1.5V
0.25
0.55
mA
SUPN Quiescent Current
ISUPN
VFBN = -0.1V
0.25
0.55
mA
V SHDN = 0, VIN = +5V
0.1
10
µA
IN Shutdown Current
SUPP Shutdown Current
V SHDN = 0, VSUPP = +13V
0.1
10
µA
SUPN Shutdown Current
V SHDN = 0, VSUPN = +13V
0.1
10
µA
13
V
1.248
1.261
V
50
nA
212
250
288
kHz
79
85
92
%
MAIN BOOST CONVERTER
Output Voltage Range
VMAIN
VIN
FB Regulation Voltage
VFB
1.235
FB Input Bias Current
IFB
Operating Frequency
fOSC
VFB = +1.25V, INTG = GND
Oscillator Maximum Duty Cycle
Load Regulation
-50
0.1
%
Line Regulation
IMAIN = 0 to 50mA, VMAIN = +5V
0.1
%/V
Integrator Gm
320
µs
RLX(ON)
ILX = 100mA
1.0
2.0
Ω
LX Leakage Current
ILX
VLX = +13V
0.01
20
µA
LX Current Limit
ILIM
450
650
mA
LX Switch On-Resistance
350
Maximum RMS LX Current
250
FB Fault Trip Level
POSITIVE CHARGE PUMP
VSUPP Input Supply Range
2
Falling edge
VSUPP
1.07
1.1
2.7
_______________________________________________________________________________________
mA
1.14
V
13
V
Low-Power Triple-Output TFT LCD DC-DC
Converter
(VIN = +3.0V, SHDN = IN, VSUPP = VSUPN = +10V, TGND = PGND = GND, CREF = 0.22µF, CINTG = 2200pF, TA = 0°C to +85°C,
unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
MAX
0.5 ×
fOSC
Operating Frequency
FBP Regulation Voltage
FBP Input Bias Current
DRVP PCH On-Resistance
TYP
VFBP
IFBP
VFBP = +1.5V
1.20
-50
VFBP = +1.200V
DRVP NCH On-Resistance
VFBP = +1.300V
FBP Power-Ready Trip Level
Rising edge
FBP Fault Trip Level
Falling edge
Hz
1.25
1.30
50
V
nA
3
10
Ω
1.5
5
20
1.09
Maximum RMS DRVP Current
UNITS
Ω
kΩ
1.13
1.16
V
1.11
V
0.1
A
NEGATIVE CHARGE PUMP
VSUPN Input Supply Range
VSUPN
2.7
Operating Frequency
FBN Regulation Voltage
FBN Input Bias Current
DRVN PCH On-Resistance
13
0.5 ×
fOSC
VFBN
IFBN
VFBN = -0.05V
-50
-50
DRVN NCH On-Resistance
VFBN = +0.050V
VFBN = -0.050V
20
FBN Power-Ready Trip Level
Falling edge
80
FBN Fault Trip Level
Rising edge
Maximum RMS DRVN Current
V
Hz
0
50
50
mV
nA
3
1.5
10
5
Ω
Ω
kΩ
120
165
mV
140
mV
0.1
A
REFERENCE
Reference Voltage
VREF
Reference Undervoltage
Threshold
LOGIC SIGNALS
-2µA < IREF < 50µA
VREF rising
SHDN Input Low Voltage
1.25
1.269
V
0.9
1.05
1.2
V
0.25V hysteresis (typ)
SHDN Input High Voltage
SHDN Input Current
1.231
0.9
2.1
I SHDN
V
V
µA
0.01
1
RDY Output Low Voltage
ISINK = 2mA
0.25
0.5
V
RDY Output High Voltage
V RDY = +13V
0.01
1
µA
_______________________________________________________________________________________
3
MAX1779
ELECTRICAL CHARACTERISTICS (continued)
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
ELECTRICAL CHARACTERISTICS
(VIN = +3.0V, SHDN = IN, VSUPP = VSUPN = +10V, TGND = PGND = GND, CREF = 0.22µF, CINTG = 2200pF, TA = -40°C to +85°C,
unless otherwise noted.) (Note 1)
PARAMETER
Input Supply Range
SYMBOL
CONDITIONS
MIN
MAX
UNITS
2.7
5.5
V
2.2
2.6
V
1
mA
VFBP = +1.5V
0.55
mA
VFBN = -0.1V
0.55
mA
VIN
Input Undervoltage Threshold
VUVLO
IN Quiescent Supply Current
IIN
SUPP Quiescent Current
ISUPP
SUPN Quiescent Current
ISUPN
VIN rising, 40mV hysteresis (typ)
VFB = VFBP = +1.5V, VFBN = -0.2V
IN Shutdown Current
V SHDN = 0, VIN = +5V
10
µA
SUPP Shutdown Current
V SHDN = 0, VSUPP = +13V
10
µA
SUPN Shutdown Current
V SHDN = 0, VSUPN = +13V
10
µA
VIN
13
V
1.225
1.271
V
-50
50
nA
195
305
kHz
79
92
%
MAIN BOOST CONVERTER
Output Voltage Range
VMAIN
FB Regulation Voltage
VFB
FB Input Bias Current
IFB
Operating Frequency
fOSC
VFB = +1.25V, INTG = GND
Oscillator Maximum Duty Cycle
LX Switch On-Resistance
LX Leakage Current
LX Current Limit
RLX(ON)
ILX
ILX = 100mA
2.0
Ω
VLX = +13V
20
µA
350
700
mA
1.07
1.14
V
2.7
13
V
1.20
1.30
V
-50
50
nA
10
Ω
ILIM
FB Fault Trip Level
Falling edge
POSITIVE CHARGE PUMP
SUPP Input Supply Range
VSUPP
FBP Regulation Voltage
VFBP
FBP Input Bias Current
IFBP
VFBP = +1.5V
DRVP PCH On-Resistance
VFBP = +1.200V
DRVP NCH On-Resistance
VFBP = +1.300V
FBP Power-Ready Trip Level
Rising edge
5
20
Ω
kΩ
1.09
1.16
V
NEGATIVE CHARGE PUMP
SUPN Input Supply Range
VSUPN
2.7
13
V
FBN Regulation Voltage
VFBN
-50
50
mV
FBN Input Bias Current
DRVN PCH On-Resistance
IFBN
50
nA
VFBN = -0.05V
-50
VFBN = +0.050V
DRVN NCH On-Resistance
FBN Power-Ready Trip Level
10
Ω
5
Ω
VFBN = -0.050V
20
Falling edge
80
165
mV
1.223
1.269
V
0.9
1.2
V
kΩ
REFERENCE
Reference Voltage
Reference Undervoltage
4
VREF
-2µA < IREF < 50µA
VREF rising
_______________________________________________________________________________________
Low-Power Triple-Output TFT LCD DC-DC
Converter
(VIN = +3.0V, SHDN = IN, VSUPP = VSUPN = +10V, TGND = PGND = GND, CREF = 0.22µF, CINTG = 2200pF, TA = -40°C to +85°C,
unless otherwise noted.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
MAX
UNITS
0.9
V
1
µA
LOGIC SIGNALS
SHDN Input Low Voltage
0.25V hysteresis (typ)
SHDN Input High Voltage
2.1
SHDN Input Current
V
I SHDN
RDY Output Low Voltage
ISINK = 2mA
0.5
V
RDY Output High Leakage
V RDY = +13V
1
µA
Note 1: Specifications to -40°C are guaranteed by design, not production tested.
Typical Operating Characteristics
(Circuit of Figure 5, VIN = +3.3V, TA = +25°C, unless otherwise noted.)
MAIN STEP-UP CONVERTER EFFICIENCY
vs. LOAD CURRENT
(L = 10µH, 5V OUTPUT)
5.01
VIN = +4.2V
5.00
4.99
VIN = +3.0V
VIN = +3.0V
80
VMAIN (V)
EFFICIENCY (%)
VIN = +3.0V
70
FIGURE 6
4.98
50
100
150
200
FIGURE 5
4.98
0
50
100
150
200
0
50
100
150
200
250
300
IMAIN (mA)
IMAIN (mA)
IMAIN (mA)
MAIN STEP-UP CONVERTER EFFICIENCY
vs. LOAD CURRENT
(L = 33µH, 5V OUTPUT)
MAIN OUTPUT VOLTAGE vs. LOAD CURRENT
(L = 33µH, 10V OUTPUT)
MAIN STEP-UP CONVERTER EFFICIENCY
vs. LOAD CURRENT
(L = 33µH, 10V OUTPUT)
10.02
80
VMAIN (V)
VIN = +3.0V
VIN = +3.3V
VIN = +5.0V
10.00
70
9.98
FIGURE 5
0
50
100
150
IMAIN (mA)
200
250
300
MAX1779-06
VIN = +5.5V
90
VIN = +3.3V
80
70
60
60
50
100
MAX1779-05
VIN = +4.2V
90
10.04
MAX1779-04
100
EFFICIENCY (%)
FIGURE 6
50
0
VIN = +4.2V
5.00
4.99
60
EFFICIENCY (%)
VMAIN (V)
VIN = +4.2V
90
5.01
5.02
MAX1779-02
100
MAX1779-01
5.02
MAIN OUTPUT VOLTAGE vs. LOAD CURRENT
(L = 33µH, 5V OUTPUT)
MAX1779-03
MAIN OUTPUT VOLTAGE vs. LOAD CURRENT
(L = 10µH, 5V OUTPUT)
FIGURE 5
9.96
0
50
100
IMAIN (mA)
150
FIGURE 5
50
0
50
100
150
IMAIN (mA)
_______________________________________________________________________________________
5
MAX1779
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics (continued)
(Circuit of Figure 5, VIN = +3.3V, TA = +25°C, unless otherwise noted.)
EFFICIENCY vs. LOAD CURRENT
(BOOST CONVERTER AND CHARGE PUMPS)
-7.88
-7.92
-7.96
VSUPN = +7V
60
50
100
150
200
40
-8.08
30
VNEG = -8V
0
250
5
10
POSITIVE CHARGE-PUMP OUTPUT VOLTAGE
vs. LOAD CURRENT
15
20
INEG (mA)
10
INEG (mA)
POSITIVE CHARGE-PUMP EFFICIENCY
vs. LOAD CURRENT
SWITCHING FREQUENCY
vs. INPUT VOLTAGE
IMAIN (mA)
0
90
12.12
VSUPP = +5V
12.00
VPOS (V)
VPOS (V)
80
VSUPP = +7V
11.88
70
VSUPP = +6V
60
VSUPP = +7V
50
11.76
VSUPP = +6V
VSUPP = +5V
VPOS = +12V
30
5
10
15
20
25
15
280
260
240
220
0
30
5
10
15
20
25
200
2.5
30
3.0
3.5
4.0
4.5
IPOS (mA)
IPOS (mA)
INPUT VOLTAGE (V)
REFERENCE VOLTAGE
vs. REFERENCE LOAD CURRENT
RIPPLE WAVEFORMS
LOAD TRANSIENT
(L = 10µH, 500µs PULSE)
MAX1779-14
1.254
5V
A
5.0V
-8V
B
4.9V
5.0
MAX1779-15
5.1V
MAX1779-13
1.256
20
40
11.64
0
5
300
MAX1779-11
100
MAX1779-10
12.24
VSUPN = +7V
MAX1779-12
0
VSUPN = +6V
60
-8.04
SWITCHING FREQUENCY (kHz)
50
70
50
-8.00
VNEG = -8V, INEG = 1mA
VPOS = +12V, IPOS = 1mA
VSUPN = +5V
80
EFFICIENCY (%)
VMAIN = +10V
SINGLE-STAGE
CHARGE PUMPS
70
90
-7.84
VSUPN = +6V
80
100
MAX1779-09
VSUPN = +5V
-7.80
VNEG (V)
EFFICIENCY (%)
90
-7.76
MAX1779-08
VMAIN = +5V
TWO-STAGE
CHARGE PUMPS
NEGATIVE CHARGE-PUMP EFFICIENCY
vs. LOAD CURRENT
NEGATIVE CHARGE-PUMP OUTPUT VOLTAGE
vs. LOAD CURRENT
MAX1779-07
100
A
1.252
VREF (V)
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
1.250
50mA
1.248
C
12V
1.246
B
0
1.244
0
10
20
30
IREF (µA)
6
40
50
4.0µs/div
A. VMAIN = 5V, IMAIN = 100mA, 10mV/div
B. VNEG = -8V, INEG = 1mA, 5mV/div
C. VPOS = 12V, IPOS = 1mA, 5mV/div, FIGURE 5
100µs/div
A. VMAIN = 5V, 50mV/div
B. VMAIN = 5mA to 50mA, 25mA/div
FIGURE 6
_______________________________________________________________________________________
Low-Power Triple-Output TFT LCD DC-DC
Converter
LOAD TRANSIENT WITHOUT INTEGRATOR
(L = 10µH, 5µs PULSE)
LOAD TRANSIENT WITHOUT INTEGRATOR
(L = 10µH, 500µs PULSE)
LOAD TRANSIENT
(L = 33µH, 500µs PULSE)
MAX1779-17
MAX1779-16
5.0V
5.0V
A
5V
A
A
400mA
4.9V
200mA
B
0
50mA
B
4.9V
100mA
100mA
B
C
0
0
0
10µs/div
A. VMAIN = 5V, 100mV/div
B. IL, 200mA/div
C. IMAIN = 10mA to 100mA, 100mA/div
INTG = REF, FIGURE 6
100µs/div
A. VMAIN = 5V, 50mV/div
B. VMAIN = 5mA to 50mA, 25mA/div
INTG = REF, FIGURE 6
100µs/div
A. VMAIN = 5V, 50mV/div
B. IMAIN = 10mA to 100mA, 50mA/div
FIGURE 5
LOAD TRANSIENT
(L = 33µH, 5µs PULSE)
LOAD TRANSIENT WITHOUT INTEGRATOR
(L = 33µH, 500µs PULSE)
5.1V
MAX1779-18
5.1V
MAX1779-19
5.1V
STARTUP WAVEFORM
(L = 10µH)
MAX1779-20
MAX1779-21
2V
5.0V
A
5.0V
A
A
0
5V
4.9V
4.9V
100mA
200mA
B
3V
B
B
0
0
100µs/div
A. VMAIN = 5V, 50mV/div
B. IMAIN = 10mA to 100mA, 50mA/div
INTG = REF, FIGURE 5
500mA
C
0
10µs/div
A. VMAIN = 5V, 50mV/div
B. IMAIN = 20mA to 200mA, 100mA/div
FIGURE 5
200µs/div
A. VSHDN = 0 to 2V, 2V/div
B. VMAIN = 5V, 1V/div
C. IL, 500 mA/div
FIGURE 6, RMAIN = 100Ω
_______________________________________________________________________________________
7
MAX1779
Typical Operating Characteristics (continued)
(Circuit of Figure 5, VIN = +3.3V, TA = +25°C, unless otherwise noted.)
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
Typical Operating Characteristics (continued)
(Circuit of Figure 5, VIN = +3.3V, TA = +25°C, unless otherwise noted.)
STARTUP WAVEFORM
(L = 33µH)
POWER-UP SEQUENCING
MAX1779-23
MAX1779-22
2V
A
2V
A
0
0
5V
5V
B
B
3V
0
500mA
-10V
C
0
C
10V
D
0
200µs/div
A. VSHDN = 0 to 2V, 2V/div
B. VMAIN = 5V, 1V/div
C. IL, 500mA/div
RMAIN = 50Ω
4ms/div
A. VSHDN = 0 to 2V, 2V/div
B. VMAIN = 5V, RMAIN = 50Ω, 2.5V/div
C. VNEG = -8V, RNEG = 8kΩ, 10V/div
D. VPOS = +12V, RPOS = 12kΩ, 10V/div
Pin Description
8
PIN
NAME
FUNCTION
1
RDY
Active-Low Open-Drain Output. Indicates all outputs are ready. The on-resistance is 125Ω (typ).
2
FB
Main Boost Regulator Feedback Input. Regulates to 1.25V nominal. Connect feedback resistive
divider to analog ground (GND).
3
INTG
4
IN
5
GND
Analog Ground. Connect to power ground (PGND) underneath the IC.
6
REF
Internal Reference Bypass Terminal. Connect a 0.22µF capacitor from this terminal to analog ground
(GND). External load capability to 50µA.
7
FBP
Positive Charge-Pump Regulator Feedback Input. Regulates to 1.25V nominal. Connect feedback
resistive divider to analog ground (GND).
8
FBN
Negative Charge-Pump Regulator Feedback Input. Regulates to 0V nominal.
9
SHDN
Main Boost Integrator Output. If used, connect 2200pF to analog ground (GND). To disable
integrator, connect to REF.
Supply Input. +2.7V to +5.5V input range. Bypass with a 0.1µF capacitor between IN and GND, as
close to the pins as possible.
Active-Low Logic-Level Shutdown Input. Connect SHDN to IN for normal operation.
_______________________________________________________________________________________
Low-Power Triple-Output TFT LCD DC-DC
Converter
PIN
NAME
FUNCTION
10
DRVN
Negative Charge-Pump Driver Output. Output high level is VSUPN, and low level is PGND.
11
SUPN
Negative Charge-Pump Driver Supply Voltage. Bypass to PGND with a 0.1µF capacitor.
12
DRVP
Positive Charge-Pump Driver Output. Output high level is VSUPP, and low level is PGND.
13
SUPP
Positive Charge-Pump Driver Supply Voltage. Bypass to PGND with a 0.1µF capacitor.
14
PGND
Power Ground. Connect to GND underneath the IC.
15
LX
16
TGND
Main Boost Regulator Power MOSFET N-Channel Drain. Connect output diode and output capacitor
as close to PGND as possible.
Must be connected to ground.
Detailed Description
The MAX1779 is a highly efficient triple-output power
supply for TFT LCD applications. The device contains
one high-power step-up converter and two low-power
charge pumps. The primary boost converter uses an
internal N-channel MOSFET to provide maximum efficiency and to minimize the number of external components. The output voltage of the main boost converter
(VMAIN) can be set from VIN to 13V with external resistors.
The dual charge pumps independently regulate a positive output (VPOS) and a negative output (VNEG). These
low-power outputs use external diode and capacitor
stages (as many stages as required) to regulate output
voltages up to +40V and down to -40V. A proprietary
regulation algorithm minimizes output ripple as well as
capacitor sizes for both charge pumps.
Also included in the MAX1779 are a precision 1.25V
reference that sources up to 50µA, logic shutdown,
soft-start, power-up sequencing, fault detection, and an
active-low open-drain ready output.
Main Boost Converter
The MAX1779 main step-up converter switches at a
constant 250kHz internal oscillator frequency to allow
the use of small inductors and output capacitors. The
MOSFET switch pulse width is modulated to control the
power transferred on each switching cycle and to regulate the output voltage.
During PWM operation, the internal clock’s rising edge
sets a flip-flop, which turns on the N-channel MOSFET
(Figure 1). The switch turns off when the voltage-error,
slope-compensation, and current-feedback signals trip
the comparators and reset the flip-flop. The switch
remains off for the rest of the clock cycle. Changes in
the output voltage error signal shift the switch current
trip level, consequently modulating the MOSFET duty
cycle.
Dual Charge-Pump Regulator
The MAX1779 contains two individual low-power charge
pumps. One charge pump inverts the supply voltage
(SUPN) and provides a regulated negative output voltage.
The second charge pump doubles the supply voltage
(SUPP) and provides a regulated positive output voltage.
The MAX1779 contains internal P-channel and N-channel
MOSFETs to control the power transfer. The internal
MOSFETs switch at a constant 125kHz (0.5 ✕ fOSC).
Negative Charge Pump
During the first half-cycle, the P-channel MOSFET turns
on and the flying capacitor C5 charges to VSUPN minus
a diode drop (Figure 2). During the second half-cycle,
the P-channel MOSFET turns off, and the N-channel
MOSFET turns on, level shifting C5. This connects C5 in
parallel with the reservoir capacitor C6. If the voltage
across C6 minus a diode drop is lower than the voltage
across C5, charge flows from C5 to C6 until the diode
(D5) turns off. The amount of charge transferred to the
output is controlled by the variable N-channel on-resistance.
Positive Charge Pump
During the first half-cycle, the N-channel MOSFET turns
on and charges the flying capacitor C3 (Figure 3). This
initial charge is controlled by the variable N-channel
on-resistance. During the second half-cycle, the Nchannel MOSFET turns off and the P-channel MOSFET
turns on, level shifting C3 by VSUPP volts. This connects
C3 in parallel with the reservoir capacitor C4. If the voltage across C4 plus a diode drop (VPOS + VDIODE) is
smaller than the level-shifted flying capacitor voltage
_______________________________________________________________________________________
9
MAX1779
Pin Description (continued)
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
L1
VOUT = [1 + (R1 / R2)] x VREF
VREF = 1.25V
VIN = 2.7V TO 5.5V
IN
OSC
LX
S
R
VMAIN
(UP TO 13V)
D1
Q
R1
+
+
+
-
PGND
C1
ILIM
Σ
-
SLOPE
COMP
+
RCOMP
FB
+
+
Gm
INTG
CINTG
REF
+ MAX1779
GND
R2
C2
CCOMP
1.25V
Figure 1. PWM Boost Converter Block Diagram
(VC3 + VSUPP), charge flows from C3 to C4 until the
diode (D3) turns off.
Soft-Start
The main boost regulator does not have soft-start.
For the charge pumps, soft-start is achieved by controlling the rise rate of the output voltage. The output voltage regulates within 16ms, regardless of output
capacitance and load, limited only by the regulator’s
output impedance (see the Startup Waveforms in the
Typical Operating Characteristics).
Shutdown
A logic-low level on SHDN disables all three MAX1779
converters and the reference. When shut down, the
supply current drops to 0.1µA to maximize battery life
and the reference is pulled to ground. The output
10
capacitance and load current determine the rate at
which each output voltage will decay. A logic-level high
on SHDN activates the MAX1779 (see Power-Up
Sequencing). Do not leave SHDN floating. If unused,
connect SHDN to IN.
Power-Up Sequencing
Upon power-up or exiting shutdown, the MAX1779
starts a power-up sequence. First, the reference powers up. Then the main DC-DC step-up converter powers up. Once the main boost converter reaches
regulation, the negative charge pump turns on. When
the negative output voltage reaches approximately 90%
of its nominal value (V FBN < 120mV), the positive
charge pump starts up. Finally, when the positive output voltage reaches 90% of its nominal value (VFBP >
______________________________________________________________________________________
Low-Power Triple-Output TFT LCD DC-DC
Converter
MAX1779
VSUPN = 2.7V TO 13V
SUPN
OSC
D4
C5
DRVN
D5
R5
FBN
+
VNEG
C6
+
R6
VREF
1.25V
REF
MAX1779
CREF
0.22µF
PGND
GND
( )
VNEG = - R5 VREF
R6
VREF = 1.25V
Figure 2. Negative Charge-Pump Block Diagram
VSUPP = 2.7V TO 13V
SUPP
OSC
D2
C3
DRVP
D3
R3
FBP
+
VPOS
C4
+
-
R4
VREF
1.25V
MAX1779
GND
PGND
( )V
VPOS = 1 + R3
R4
VREF = 1.25V
REF
Figure 3. Positive Charge-Pump Block Diagram
______________________________________________________________________________________
11
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
1.125V), the active-low ready signal (RDY) is pulled low
(see Power Ready section).
Power Ready
Power ready is an open-drain output. When the powerup sequence is properly completed, the MOSFET turns
on and pulls RDY low with a typical 125Ω on-resistance. If a fault is detected, the internal open-drain
MOSFET appears as a high impedance. Connect a
100kΩ pullup resistor between RDY and IN for a logiclevel output.
output voltage. With high inductor values, the MAX1779
sources higher output currents, has less output ripple,
and enters continuous-conduction operation with lighter
loads; however, the circuit’s transient response time is
slower. On the other hand, low-value inductors respond
faster to transients, remain in discontinuous-conduction
operation, and typically offer smaller physical size. The
maximum output current an inductor value will support
may be calculated by the following equations:
A. Continuous-conduction: if
Fault Detection
Once RDY is low, if any output falls below its faultdetection threshold, then RDY becomes high impedance.
For the reference, the fault threshold is 1.05V. For the
main boost converter, the fault threshold is 88% of its
nominal value (VFB < 1.1V). For the negative charge
pump, the fault threshold is approximately 88% of its
nominal value (VFBN < 140mV). For the positive charge
pump, the fault threshold is 88% of its nominal value
(VFBP < 1.11V).
Once an output faults, all outputs later in the power
sequence shut down until the faulted output rises
above its power-up threshold. For example, if the negative charge-pump output voltage falls below the fault
detection threshold, the main boost converter remains
active while the positive charge pump stops switching
and its output voltage decays, depending on output
capacitance and load. The positive charge-pump output will not power up until the negative charge-pump
output voltage rises above its power-up threshold (see
the Power-Up Sequencing section).
Voltage Reference
The voltage at REF is nominally 1.25V. The reference
can source up to 50µA with good load regulation (see
Typical Operating Characteristics). Connect a 0.22µF
bypass capacitor between REF and GND.
Design Procedure
Main Boost Converter
Inductor Selection
Inductor selection depends upon the minimum required
inductance value, saturation rating, series resistance,
and size. These factors influence the converter’s efficiency, maximum output load capability, transient
response time, and output voltage ripple. For most
applications, values between 10µH and 33µH work
best with the controller’s switching frequency.
The inductor value depends on the maximum output
load the application must support, input voltage, and
12
IMAIN(MAX) ≥
1  VIN(MIN) 
ILIM(MIN)
2  VMAIN 
then






VMAIN - VIN(MIN)
2

V



1  1  IN(MIN)
   VIN(MIN) 

L≥   
I
-I
2  ƒ   VMAIN     VMAIN  LIM(MIN)  MAIN(MAX) 


B. Discontinuous-conduction: if
IMAIN(MAX) <
1  VIN(MIN) 
ILIM(MIN)
2  VMAIN 
then
(
 1   IMAIN(MAX) VMAIN - VIN(MIN)
L ≥ 2  
ILIM(MIN)2
 ƒ 

) 


where I LIM(MIN) = 350mA and ƒ = 250kHz (see the
Electrical Characteristics).
The inductor’s saturation current rating should exceed
peak inductor current throughout the normal operating
range. Under fault conditions, the inductor current may
reach up to 600mA (I LIM(MAX) , see the Electrical
Characteristics). However, the MAX1779’s fast currentlimit circuitry allows the use of soft-saturation inductors
while still protecting the IC.
The inductor’s DC resistance significantly affects efficiency due to the power loss in the inductor. The power
loss due to the inductor’s series resistance (PLR) may
be approximated by the following equation:
2
I
× VMAIN 
PLR ≅  MAIN
 × RL
VIN


______________________________________________________________________________________
Low-Power Triple-Output TFT LCD DC-DC
Converter
Output Capacitor
The output capacitor selection depends on circuit stability and output voltage ripple. In order to deliver the
maximum output current capability of the MAX1779, the
inductor must run in continuous-conduction mode (see
Inductor Selection). The minimum recommended output
capacitance is:
COUT >
60 × L × IMAIN(MAX)
VMAIN × VIN(MIN)
For configurations that need less output current, the
MAX1779 allows lower output capacitance when operating in discontinuous-conduction mode throughout the
load range. Under these conditions, at least 10µF is
recommended, as shown in Figure 6. In both discontinuous and continuous operation, additional feedback
compensation is required (see the Feedback
Compensation section) to increase the margin for stability by reducing the bandwidth further. In cases where
the output capacitance is sufficiently large, additional
feedback compensation will not be necessary.
However, in certain applications that require benign
load transients and constantly operate in discontinuous-conduction mode, output capacitance less than
10µF may be used.
Output voltage ripple has two components: variations in
the charge stored in the output capacitor with each LX
pulse, and the voltage drop across the capacitor’s
equivalent series resistance (ESR) caused by the current into and out of the capacitor:
VRIPPLE = VRIPPLE(C) + VRIPPLE(ESR)
For low-value ceramic capacitors, the output voltage
ripple is dominated by VRIPPLE(C).
Integrator Capacitor
The MAX1779 contains an internal current integrator
that improves the DC load regulation but increases the
peak-to-peak transient voltage (see the Load Transient
Waveforms in the Typical Operating Characteristics).
For highly accurate DC load regulation, enable the integrator by connecting a capacitor to INTG. The minimum
capacitor value should be COUT/10k or 1nF, whichever
is greater. Alternatively, to minimize the peak-to-peak
transient voltage at the expense of DC load regulation,
disable the integrator by connecting INTG to REF and
adding a 100kΩ resistor to GND.
Feedback Compensation
Compensation on the feedback node is required to
have enough margin for stability. Add a pole-zero pair
from FB to GND in the form of a compensation resistor
(RCOMP in Figures 5 and 6) in series with a compensation capacitor (CCOMP in Figures 5 and 6). For continuous conduction operation, select RCOMP to be 1/2 the
value of R2, the low-side feedback resistor. For discontinuous-conduction operation, select RCOMP to be 1/5th
the value of R2.
Start with a compensation capacitor value of (220pF ✕
RCOMP)/10kΩ. Increase this value to improve the DC
stability as necessary. Larger compensation values
slow down the converter’s response time. Check the
startup waveform for excessive overshoot each time the
compensation capacitor value is increased.
Charge Pump
Efficiency Considerations
The efficiency characteristics of the MAX1779 regulated
charge pumps are similar to a linear regulator. They are
dominated by quiescent current at low output currents
and by the input voltage at higher output currents (see
Typical Operating Characteristics). So the maximum
efficiency may be approximated by:
Efficiency ≅ IVNEGI / [VIN ✕ N];
for the negative charge pump
Efficiency ≅ VPOS / [VIN ✕ (N + 1)];
for the positive charge pump
where N is the number of charge-pump stages.
Output Voltage Selection
Adjust the positive output voltage by connecting a voltage-divider from the output (VPOS) to FBP to GND (see
Typical Operating Circuit). Adjust the negative output
voltage by connecting a voltage-divider from the output
(VNEG) to FBN to REF. Select R4 and R6 in the 50kΩ to
100kΩ range. Higher resistor values improve efficiency
at low output current but increase output voltage error
due to the feedback input bias current. Calculate the
remaining resistors with the following equations:
R3 = R4 [(VPOS / VREF) - 1]
R5 = R6 (IVNEG / VREFI)
where VREF = 1.25V. VPOS may range from VSUPP to
+40V, and VNEG may range from 0 to -40V.
Flying Capacitor
Increasing the flying capacitor’s value increases the
output current capability. Above a certain point,
increasing the capacitance has a negligible effect
because the output current capability becomes domi-
______________________________________________________________________________________
13
MAX1779
where RL is the inductor’s series resistance. For best
performance, select inductors with resistance less than
the internal N-channel MOSFET on-resistance (1Ω typ).
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
nated by the internal switch resistance and the diode
impedance. Start with 0.1µF ceramic capacitors.
Smaller values may be used for low-current applications.
Charge-Pump Output Capacitor
Increasing the output capacitance or decreasing the
ESR reduces the output ripple voltage and the peak-topeak transient voltage. Use the following equation to
approximate the required capacitor value:
CPUMP ≥ [IPUMP / (125kHz ✕ VRIPPLE)]
Charge-Pump Input Capacitor
Use a bypass capacitor with a value equal to or greater
than the flying capacitor. Place the capacitor as close
to the IC as possible. Connect directly to PGND.
Rectifier Diode
Use Schottky diodes with a current rating equal to or
greater than 4 times the average output current, and a
voltage rating at least 1.5 times VSUPP for the positive
charge pump and VSUPN for the negative charge pump.
PC Board Layout and Grounding
Carefully printed circuit layout is extremely important to
minimize ground bounce and noise. First, place the
main boost converter output diode and output capacitor
less than 0.2in (5mm) from the LX and PGND pins with
wide traces and no vias. Then place 0.1µF ceramic
bypass capacitors near the charge-pump input pins
(SUPP and SUPN) to the PGND pin. Keep the chargepump circuitry as close to the IC as possible, using
wide traces and avoiding vias when possible. Locate
all feedback resistive dividers as close to their respective feedback pins as possible. The PC board should
feature separate GND and PGND areas connected at
only one point under the IC. To maximize output power
and efficiency and to minimize output power ripple voltage, use extra wide power ground traces and solder
the IC’s power ground pin directly to it. Avoid having
sensitive traces near the switching nodes and high-current lines.
mum load current that the LX charge pump can provide
and is limited by the following formula:
ILXPUMP = ((N + 1) ✕ IPOS) + (M + INEG) ≤ 5mA
where N is the number of stages in the positive lowpower charge pump, and M is the number of stages in
the negative charge pump. Applications requiring more
output current should not use the LX charge pump, so
they will require extra stages on both low-power charge
pumps. The output capacitor of this unregulated
charge pump needs to be stacked on top of the main
output in order to keep the main regulator stable.
Increasing the integrator capacitor may also be
required to compensate for the additional charge-pump
capacitance on the main regulator loop.
The output capacitor of this unregulated charge pump
needs to be stacked on top of the main output in order
to keep the main regulator stable. Increasing the integrator capacitor may also be required to compensate
for the additional charge-pump capacitance on the
main regulator loop.
Table 1. Component Suppliers
SUPPLIER
INDUCTORS
PHONE
FAX
Coilcraft
847-639-6400
847-639-1469
Coiltronics
561-241-7876
561-241-9339
Sumida USA
847-956-0666
847-956-0702
Toko
847-297-0070
847-699-1194
CAPACITORS
AVX
803-946-0690
803-626-3123
Kemet
408-986-0424
408-986-1442
Sanyo
619-661-6835
619-661-1055
Taiyo Yuden
408-573-4150
408-573-4159
Central
Semiconductor
516-435-1110
516-435-1824
International
Rectifier
310-322-3331
310-322-3332
Motorola
602-303-5454
602-994-6430
LX Charge Pump
Nihon
847-843-7500
847-843-2798
Some applications require multiple charge-pump
stages due to low supply voltages. In order to reduce
the circuit’s size and component count, an unregulated
charge pump may be added onto the LX switching
node. The configuration shown in Figure 4 works well
for most applications. The maximum output current of
the low-power charge pumps depends on the maxi-
Zetex
516-543-7100
516-864-7630
Refer to the MAX1779 evaluation kit for an example of
proper board layout.
Applications Information
14
DIODES
Chip Information
TRANSISTOR COUNT: 2846
______________________________________________________________________________________
______________________________________________________________________________________
1.0µF
(2) 4.7µF
VNEG = -8V, 1mA
VIN = +3.0V
CINTG
3300pF
100k
R5
320k
CREF
0.22µF
R6
49.9k
0.1µF
0.1µF
GND
TGND
INTG
REF
FBN
DRVN
RDY
SHDN
IN
MAX1779
10µH
PGND
FBP
DRVP
SUPP
SUPN
FB
LX
RCOMP
10k
R4
49.9k
0.1µF
R2
50k
R1
150k
R3
549k
CCOMP
220pF
COUT
(2) 4.7µF
VMAIN = +5V
1.0µF
1.0µF
VPOS = +15V, 1mA
MAX1779
0.47µF
Low-Power Triple-Output TFT LCD DC-DC
Converter
Figure 4. Minimizing the Number of Charge-Pump Stages
15
16
VNEG
-8V, 5mA
C6
0.47µF
C10
2.2µF
CIN
10µF
VIN = +3.3V
CREF
0.22µF
R5
320k
R6
49.9k
C9
0.22µF
CINTG
2200pF
C11
0.1µF
C5
0.1µF
RRDY
100k
PGND
REF
FBN
DRVN
INTG
RDY
SHDN
IN
MAX1779
33µH
GND
TGND
FBP
DRVP
SUPP
SUPN
FB
LX
C7
0.22µF
C3
0.1µF
R2
50k
R1
150k
CCOMP
470pF
RCOMP
24k
R4
49.9k
C8
430k
C3
0.47µF
C8
2.2µF
VPOS
+12V, 5mA
COUT
22µF
VMAIN = +5.0V
MAX1779
Low-Power Triple-Output TFT LCD DC-DC
Converter
Figure 5. Typical Operating Circuit (L = 33µH)
______________________________________________________________________________________
______________________________________________________________________________________
VNEG
-8V, 5mA
C6
0.47µF
CIN
(2) 4.7µF
CREF
0.22µF
C10
2.2µF
R5
320k
R6
49.9k
C9
0.22µF
CINTG
2200pF
C11
0.1µF
C5
0.1µF
RRDY
100k
PGND
REF
FBN
DRVN
INTG
RDY
SHDN
IN
MAX1779
10µH
GND
TGND
FBP
DRVP
SUPP
SUPN
FB
LX
C7
0.22µF
C3
0.1µF
R2
50k
R1
150k
CCOMP
220pF
RCOMP
10k
R4
49.9k
R3
430k
C4
0.47µF
C8
2.2µF
VPOS
+12V, 5mA
COUT
(2) 4.7µF
VMAIN = +5.0V
MAX1779
VIN = +3.3V
Low-Power Triple-Output TFT LCD DC-DC
Converter
Figure 6. Typical Operating Circuit (L = 10µH)
17
Low-Power Triple-Output TFT LCD DC-DC
Converter
TSSOP.EPS
MAX1779
Package Information
Note: The MAX1779 16-pin TSSOP package does not have an exposed pad.
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
18 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2000 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.