MAXIM MAX1800EHJ

19-1833; Rev 0; 10/00
KIT
ATION
EVALU
E
L
B
AVAILA
Digital Camera Step-Up
Power Supply
Features
♦ +0.7V to +5.5V Input Voltage Range
♦ Main DC-DC Converter
95% Efficiency
+2.7V to +5.5V Adjustable Output Voltage
1.5A Load Current
♦ Uncommitted Gain Block for Linear Regulator
♦ Three Independent Auxiliary Step-Up Controllers
Adjustable Maximum Duty Cycle
♦ Oscillator and Reference Outputs to Drive External
Slave Controllers (MAX1801)
♦ Power-Ready Output
♦ Up to 1MHz Switching Frequency
♦ 1µA Supply Current in Shutdown Mode
♦ Internal Soft-Start Control
♦ Overload Protection for all DC-DC Converters
♦ Compact 32-Pin TQFP Package (5mm x 5mm body)
The auxiliary step-up controllers can be used to power a
digital camera’s CCD, LCD, and backlight. The MAX1800
also features expandability by supplying power, oscillator
signal, and reference to the MAX1801, a low-cost slave
DC-DC controller that supports step-up, SEPIC, and flyback configurations.
The MAX1800 is available in a space-saving 32-pin TQFP
package (5mm x 5mm body), and the MAX1801 is available in an 8-pin SOT package. An evaluation kit
(MAX1800EVKIT) featuring both devices is available to
expedite designs.
________________________Applications
Digital Still Cameras
PDAs
Digital Video Cameras
DVD Players
Ordering Information
PART
MAX1800EHJ
TEMP. RANGE
PIN-PACKAGE
-40°C to +85°C
32 TQFP
Pin Configuration
Hand-Held Devices
ON3
FB3
COMP3
DCON3
ONA
AO
AI
32
31
30
29
28
27
26
25
PGND
1
24 ONM
DL1
2
23 RDYM
CCD
ON1
3
22 POUT
TFT
FB1
4
Typical Operating Circuit
21 LX
MAX1800
MAX1800
CCFL
COMP1
5
MASTER
CORE
DCON1
6
19 PGND
MAIN
POUT
7
18 COMPM
DL2
8
17 FBM
20 LX
12 13
14
15
16
GND
OSC
11
OUT
MOTOR
10
REF
SLAVE
9
DCON2
MAX1801
COMP2
REF
FB2
OSC
ON2
INPUT
0.7V TO 5.5V
DL3
TOP VIEW
Internet Access Tablets
TQFP
________________________________________________________________ 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.
MAX1800
General Description
The MAX1800 provides a complete power-supply solution for digital still cameras and video cameras. The
device integrates a high-efficiency main step-up DC-DC
converter, three auxiliary step-up controllers, and an
uncommitted gain block that drives an external P-channel
MOSFET for a linear regulator. The MAX1800 is targeted
for applications that use either two or three primary cells
or a single lithium-ion (Li+) battery.
The main DC-DC converter accepts inputs from +0.7V to
+5.5V and regulates a resistor-adjustable output from
2.7V to 5.5V. It uses an internal synchronous rectifier to
regulate the output with 95% efficiency. An adjustable
operating frequency facilitates designs for optimum size,
cost, and efficiency.
MAX1800
Digital Camera Step-Up
Power Supply
ABSOLUTE MAXIMUM RATINGS
OUT, POUT, ON_, DCON_, FB_, RDYM to GND .....-0.3V to +6.0V
PGND to GND ......................................................-0.3V to +0.3V
OUT to POUT_ ......................................................-0.3V to +0.3V
LX, DL_, AO to PGND .............................-0.3V to (POUT + 0.3V)
REF, OSC, AI, COMP_ to GND..................-0.3V to (OUT + 0.3V)
Continuous Power Dissipation (TA = +70°C)
32-Pin TQFP (derate 11mW/°C above +70°C) ............880mW
Operating Temperature Range
MAX1800EHJ.................................................. -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
(Circuit of Figure 1, VOUT = VPOUT = 3.3V, PGND = GND, VONM = 3.3V, VON1 = VON2 = VON3 = VONA = 0, TA = -40°C to +85°C,
unless otherwise noted. Typical values are at TA = +25°C.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
GENERAL
Input Voltage Range (Note 2)
Minimum Startup Voltage
VIN
VSTART
Frequency in Startup Mode
0.7
ILOAD < 1mA, TA = +25oC
VOUT = 1.5V
40
5.5
V
0.9
1.1
V
150
300
kHz
0.002
5
µA
SUPPLY CURRENT
Shutdown Supply Current
VONM = 0
Main DC/DC Converter Supply
Current
VFBM = 1.2V, VOSC = 0
250
400
µA
Main + Auxiliary 1 Supply
Current
VON1 = 3.3V, VFBM = 1.2V, VFB1 = 1.2V,
VOSC = 0
375
600
µA
Main + Auxiliary 2 Supply
Current
VON2 = 3.3V, VFBM = 1.2V, VFB2 = 1.2V,
VOSC = 0
375
600
µA
Main + Auxiliary 3 Supply
Current
VON3 = 3.3V, VFBM = 1.2V, VFB3 = 1.2V,
VOSC = 0
375
600
µA
Analog Gain Block Supply
Current
VONA = 3.3V, VFBM = 1.2V, AI = REF,
AO open, VOSC = 0
375
600
µA
1.250
1.27
V
REFERENCE
Reference Output Voltage
VREF
IREF = 20µA
REF Load Regulation
10µA < IREF < 200µA
REF Line Rejection
2.7V < VOUT < 5.5V
1.23
10
mV
0.2
5
mV
1.250
1.275
V
0.01
100
nA
37
75
OSCILLATOR
OSC Discharge Trip Level
Rising edge
OSC Input Bias Current
VOSC = 1.1V
OSC Discharge Resistance
VOSC = 1.5V, IOSC = 3mA
OSC Discharge Pulse Width
2
1.225
100
_______________________________________________________________________________________
Ω
ns
Digital Camera Step-Up
Power Supply
(Circuit of Figure 1, VOUT = VPOUT = 3.3V, PGND = GND, VONM = 3.3V, VON1 = VON2 = VON3 = VONA = 0, TA = -40°C to +85°C,
unless otherwise noted. Typical values are at TA = +25°C.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
LOGIC INPUTS (ONM, ON1, ON2, ON3, ONA)
Input Low Level
VIL
Input High Level
VIH
1.1V < VOUT < 1.8V (ONM only)
0.2
1.8V < VOUT < 5.5V
0.4
1.1V < VOUT < 1.8V (ONM only)
1.8V < VOUT < 5.5V
Input Leakage Current
VOUT 0.2
V
V
1.6
VIN = 0 or VIN = VOUT = 5.5V
0.01
1
µA
5.5
V
MAIN DC/DC CONVERTER
Main Output Voltage Adjust
Range
VOUT
2.7
Main Undervoltage Lockout
Threshold (Note 3)
Rising edge
2.2
2.35
2.6
V
Main Output Maximum Duty
Cycle
Measured at LX output, VFBM = 1V
80
85
88
%
Idle-Mode™ Threshold
VOSC = 0.625V
0.3
A
ERROR AMPLIFIER
FBM Regulation Voltage
Unity gain configuration, FBM = COMPM
1.23
1.250
1.27
V
FBM to COMPM
Transconductance
Unity gain configuration, FBM = COMPM,
-5µA < ILOAD < +5µA
60
100
140
µS
FBM to COMPM Maximum
Voltage Gain
2000
FBM Input Leakage Current
VFBM = 1.35V
0.01
COMPM Minimum Output
Voltage
VFBM = 1.35V, COMPM open
0.1
COMPM Maximum Output
Voltage
VFBM = 1.15V, COMPM open
2.00
V/V
100
nA
V
2.15
2.30
V
POWER SWITCHES
POUT Leakage Current
VLX = 0, VPOUT = 5.5V
0.1
20
µA
LX Leakage Current
VLX = VOUT = 5.5V
0.1
20
µA
N-channel
100
180
P-channel
200
350
Switch On- Resistance
RON
N-Channel Current Limit
2
P-Channel Turn-Off Current
mΩ
A
40
120
190
mA
1.09
1.125
1.16
V
1
µA
0.4
V
POWER READY
RDYM Trip Level
VFBM rising edge, 1% typical hysteresis
RDYM Output High Leakage
VRDYM = 5.5V
RDYM Output Voltage Low
ISINK = 1mA
0.01
Idle Mode is a trademark of Maxim Integrated Products.
_______________________________________________________________________________________
3
MAX1800
ELECTRICAL CHARACTERISTICS (continued)
MAX1800
Digital Camera Step-Up
Power Supply
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VOUT = VPOUT = 3.3V, PGND = GND, VONM = 3.3V, VON1 = VON2 = VON3 = VONA = 0, TA = -40°C to +85°C,
unless otherwise noted. Typical values are at TA = +25°C.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
1.23
1.25
1.27
V
ANALOG GAIN BLOCK
AI Feedback Regulation Voltage
VAO = VOUT - 1.25V
AI Input Common-Mode Range
-0.1
AI Input Current
VAI = 1.35V
AI to AO Voltage Gain
70
100
AO Output Sink Current
VAI = 1V, VAO = 2V
0.5
2.5
AO Output Source Current
VAI = 1.5V, VAO = 2V
0.5
2.5
AO Output Low Voltage
VAI = 1V, ISINK = 25µA
AO Output High Voltage
VAI = 1.5V or VONA = 0, ISOURCE = 25µA
1.3
V
100
nA
140
V/V
mA
mA
0.5
V
VPOUT
- 0.5
AI to AO -3dB Bandwidth
V
5
MHz
AUXILIARY DC/DC CONTROLLERS 1, 2, 3
INTERNAL CLOCK
OSC Clock Low Trip Level
Falling edge
OSC Clock High Trip Level
0.2
0.25
0.3
VDCON = 0.625V
0.575
0.625
0.675
VDCON = VOUT
1.00
1.05
1.10
Maximum Duty-Cycle
Adjustment Range
40
V
V
%
90
Maximum Duty Cycle
VDCON_ = 0.625V
50
%
Default Maximum Duty Cycle
VDCON_ = 1.25V
84
%
ERROR AMPLIFIER
FB_ Regulation Voltage
FB_ = COMP_
FB_ to COMP_
Transconductance
FB_ = COMP_, -5µA < ILOAD < +5µA
FB_ to COMP_ Maximum
Voltage Gain
1.23
1.25
1.27
V
60
100
140
µS
2000
FB_ Input Leakage Current
VFB_ = 1.35V
V/V
100
nA
6
Ω
DRIVERS (DL1, DL2, DL3)
DL_ Driver Resistance
DL_ Drive Current
RON
Output high or low
Sourcing or sinking, VDL _ = VOUT/2
2
0.5
A
1024
OSC
cycles
1024
OSC
cycles
SOFT-START
Soft-Start Interval
SHORT-CIRCUIT PROTECTION
Fault Interval
Note 1: Specifications to -40°C are guaranteed by design and not production tested.
Note 2: Operating voltage. Since the regulator is bootstrapped to the output, once started it will operate down to +0.7V input.
Note 3: The regulator is in startup mode until the voltage is reached.
4
_______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
MAIN OUTPUT
EFFICIENCY vs. LOAD CURRENT
MAIN OUTPUT
EFFICIENCY vs. LOAD CURRENT
VIN = 2.0V
70
VIN = 1.5V
60
50
40
80
VIN = 1.5V
40
30
20
10
VOUT = 2.7V
VOUT = 3.3V
0
1
10
100
10
100
1000
LOAD CURRENT (mA)
MAIN OUTPUT
EFFICIENCY vs. LOAD CURRENT
MINIMUM STARTUP CURRENT
vs. INPUT VOLTAGE
VIN = 2.5V
70
VIN = 2.0V
60
VIN = 1.5V
50
500
STARTUP CURRENT (mA)
80
40
30
MAX1800 toc04
600
MAX1800 toc03
VIN = 3.0V
90
1
1000
LOAD CURRENT (mA)
100
20
400
300
200
100
10
VOUT = 5V
0
0
1
10
100
0
1000
0.5
1.0
1.5
2.0
LOAD CURRENT (mA)
INPUT VOLTAGE (V)
REFERENCE VOLTAGE vs.
TEMPERATURE
REFERENCE VOLTAGE
vs. REFERENCE CURRENT
1.253
MAX1800 toc05
1.260
1.252
REFERENCE VOLTAGE (V)
1.255
1.250
1.245
2.5
MAX1800 toc06
EFFICIENCY (%)
VIN = 2.0V
50
20
0
REFERENCE VOLTAGE (V)
VIN = 2.5V
70
60
30
10
VIN = 3.0V
90
EFFICIENCY (%)
EFFICIENCY (%)
80
MAX1800 toc02
VIN = 2.5V
90
100
MAX1800 toc01
100
1.251
1.250
1.249
1.248
1.247
1.240
-40
-20
0
20
40
TEMPERATURE (°C)
60
80
0
50
100
150
200
250
REFERENCE CURRENT (µA)
_______________________________________________________________________________________
5
MAX1800
Typical Operating Characteristics
(Circuit of Figure 1, VINPUT = 2.4V, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(Circuit of Figure 1, VINPUT = 2.4V, TA = +25°C, unless otherwise noted.)
AUXILIARY CONTROLLER
MAXIMUM DUTY CYCLE vs. VDCON_
FB_ TO COMP_ SMALL-SIGNAL OPEN-LOOP
FREQUENCY RESPONSE
60
40
20
MAX1800 toc08
50
40
30
20
10
0
0
0.4
0.5
0.6
0.7
0.8
0.9
1.0
1.1
1.2
1
VDCON_ (V)
100
1000
OSCILLATOR FREQUENCY vs. ROSC
80
COSC = 470pF
40
20
0
1000
COSC = 470pF
OSCILLATOR FREQUENCY (kHz)
MAX1800 toc09
100
800
COSC = 220pF
COSC = 100pF
600
COSC = 47pF
400
200
0
0
200
400
600
800
1000
1
10
FREQUENCY (kHz)
100
1000
ROSC (kΩ)
MAIN OUTPUT STARTUP RESPONSE
LDO STARTUP RESPONSE
MAX1800 toc11
MAX1800 toc12
VONM
2V/div
0V
VONA
2V/div
0V
MAIN
OUTPUT
VOLTAGE
2V/div
0V
INPUT
CURRENT
1A/div
0A
LDO
OUTPUT
VOLTAGE
2V/div
0V
INPUT
CURRENT
500mA/div
0A
1.00 ms/div
MAIN LOAD = 24Ω
6
10,000
FREQUENCY (kHz)
AUXILIARY CONTROLLER DEFAULT
MAXIMUM DUTY CYCLE vs. FREQUENCY
60
10
MAX1800 toc10
MAXIMUM CYCLE (%)
80
60
SMALL-SIGNAL RESPONSE (dB)
MAX1800 toc07
100
DEFAULT MAXIMUM DUTY CYCLE (%)
MAX1800
Digital Camera Step-Up
Power Supply
1.00 ms/div
MAIN LOAD = 24Ω
LDO LOAD = 8Ω
_______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
AUXILIARY CONTROLLER STARTUP
RESPONSE
STARTUP SEQUENCE
MAX1800 toc14
MAX1800 toc13
3.3V
VON_
5V/div
0V
VONM
5V/div
0V
MAIN
OUTPUT
VOLTAGE
2V/div
VOUT
2V/div
0V
0V
IIN
0.5A/div
LDO
OUTPUT
VOLTAGE
2V/div
0V
AUXILIARY
OUTPUT
VOLTAGE
2V/div
0A
0V
1.00ms/div
MAIN LOAD = 24Ω
LDO LOAD = 8Ω
AUXILIARY LOAD = 10Ω
AUXILIARY OUTPUT VOLTAGE = 5V
1ms/div
VOUT = 5V
LOAD = 10Ω
LDO OUTPUT LOAD TRANSIENT
RESPONSE
MAIN OUTPUT LOAD-TRANSIENT
RESPONSE
MAX1800 toc16
MAX1800 toc15
LDO
OUTPUT
VOLTAGE
20mV/div
AC COUPLED
VPOUT
AC COUPLED
100mV/div
IOUT
200mA/div
LDO
LOAD
CURRENT
100mA/div
0A
0A
COUT = 100µF
400 us/div
VOUT = 5V
LOAD = 10Ω
100µs/div
AUXILIARY CONTROLLER OUTPUT
LOAD-TRANSIENT RESPONSE
MAIN OUTPUT RESPONSE DUE
TO LDO TRANSIENT
MAX1800 toc17
MAX1800 toc18
VPOUT
AC COUPLED
100mV/div
MAIN
OUTPUT
VOLTAGE
20mV/div
AC COUPLED
IOUT
200mA/div
LDO
LOAD
CURRENT
100mA/div
0A
200 µs/div
400 us/div
VOUT = 5V
MAIN LOAD = 24Ω
_______________________________________________________________________________________
7
MAX1800
Typical Operating Characteristics (continued)
(Circuit of Figure 1, VINPUT = 2.4V, TA = +25°C, unless otherwise noted.)
Digital Camera Step-Up
Power Supply
MAX1800
Pin Description
PIN
NAME
1, 19
PGND
2
DL1
External MOSFET Gate Drive Output for Auxiliary Controller 1. DL1 swings between POUT and GND with
typical 500mA drive current. Connect DL1 to the gate of the external switching N-channel MOSFET for
auxiliary controller 1.
3
ON1
Enable Input for Auxiliary Controller 1. Connect ON1 to POUT to automatically start auxiliary controller 1.
4
FB1
Feedback Input for Auxiliary Controller 1. Connect a feedback resistive voltage-divider from the output to FB1
to set the output voltage. Regulation voltage is VREF (1.25V).
5
COMP1
Compensation for Auxiliary Controller 1. Output of transconductance error amplifier. Connect a series resistor
and capacitor to GND to compensate the control loop. See Compensation Design.
6
DCON1
Maximum Duty-Cycle Control Input for Auxiliary Controller 1. Connect to POUT to set the default maximum
duty cycle. Connect a resistive voltage-divider from REF to DCON1 to set the maximum duty cycle between
40% and 90%. Pull DCON1 below 400mV to turn the controller off.
7, 22
8
POUT
FUNCTION
Power Ground. Sources of internal N-channel MOSFET power switches. Connect both PGND pins to GND as
close to the IC as possible.
Main Power Output. Source of P-channel MOSFET synchronous rectifier switch. Connect both POUT pins
together as close to the IC as possible.
8
DL2
External MOSFET Gate Drive Output for Auxiliary Controller 2. DL2 swings between POUT and GND with
typical 500mA drive current. Connect DL2 to the gate of the external switching N-channel MOSFET for
auxiliary controller 2.
9
ON2
Enable Input for Auxiliary Controller 2. Connect ON2 to POUT to automatically start auxiliary controller 2.
10
FB2
Feedback Input for Auxiliary Controller 2. Connect a feedback resistive voltage-divider from the output to FB2
to set the output voltage. Regulation voltage is VREF (1.25V).
11
COMP2
Compensation for Auxiliary Controller 2. Output of transconductance error amplifier. Connect a series resistor
and capacitor to GND to compensate the control loop. See Compensation Design.
12
DCON2
Maximum Duty-Cycle Control Input for Auxiliary Controller 2. Connect to POUT to set the default maximum
duty cycle. Connect a resistive voltage-divider from REF to DCON2 to set the maximum duty cycle between
40% and 90%. Pull DCON2 below 400mV to turn the controller off.
13
OUT
Internal Bias Supply Input. Connect to POUT through a resistor, and bypass OUT to GND with a capacitor.
See Compensation Design.
14
REF
1.250V Reference Output. Bypass REF to GND with a 0.1µF or greater ceramic capacitor.
15
GND
Analog Ground. Connect GND to PGND at a single point near the IC.
16
OSC
Oscillator Control. Connect a timing capacitor from OSC to GND and a timing resistor from OSC to POUT to
set the switching frequency between 100kHz and 1MHz. See Setting the Switching Frequency.
17
FBM
Main DC/DC Converter Feedback Input. Connect a feedback resistive voltage-divider from POUT to FBM to
set the output voltage. Regulation voltage is VREF (1.25V).
18
COMPM
Compensation for Main Controller. Output of transconductance error amplifier. Connect a series resistor and
capacitor to GND to compensate the control loop. See Compensation Design.
20,
21
LX
Main Power Switching Node. Drains of the internal P-channel and N-channel MOSFET switches. Connect the
LX pins together as close to the IC as possible.
23
RDYM
Main Converter Ready Output. An open-drain output sinks current when VFBM < 1.125V, indicating that the
main output is more than 10% out of regulation.
_______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
PIN
NAME
FUNCTION
24
ONM
Main Converter Enable Input. High level turns the main converter on. Connect ONM to POUT to automatically
start the main converter. When the main converter is off, all other outputs are disabled.
25
AI
Analog Gain Block Input. AI is the positive input to the gain block. The negative input is internally connected
to the 1.25V reference.
26
AO
Analog Gain Block Output. AO is a push-pull output driven between GND and POUT. The voltage gain of the
block is approximately 100.
27
ONA
Analog Gain Block Enable Input. Connect ONA to POUT to enable the gain block. When ONA is low, the AO
output is driven to POUT.
28
DCON3
Maximum Duty-Cycle Control Input for Auxiliary Controller 3. Connect to POUT to set the default maximum
duty cycle. Connect a resistive voltage-divider from REF to DCON3 to set the maximum duty cycle between
40% and 90%. Pull DCON3 below 400mV to turn the controller off.
29
COMP3
Compensation for Auxiliary Controller 3. Output of transconductance error amplifier. Connect a series resistor
and capacitor to GND to compensate the control loop. See Compensation Design.
30
FB3
Feedback Input for Auxiliary Controller 3. Connect a feedback resistive voltage-divider from the output to FB3
to set the output voltage. Regulation voltage is VREF (1.25V).
31
ON3
Enable Input for Auxiliary Controller 3. Connect ON2 to POUT to automatically start auxiliary controller 3.
32
DL3
External MOSFET Gate Drive Output for Auxiliary Controller 3. DL3 swings between POUT and GND with
typical 500mA drive current. Connect DL3 to the gate of the external switching N-channel MOSFET for
auxiliary controller 3.
Detailed Description
The MAX1800 typical application circuit is shown in
Figure 1. It features a main step-up DC-DC converter,
three auxiliary step-up DC-DC controllers, an uncommitted gain block, a power-ready comparator, and control capability for multiple external MAX1801 slave
DC-DC controllers. The uncommitted gain block can be
used with an external P-Channel MOSFET to make a
linear regulator. The linear regulator can be used with
the main output for step-up/step-down functionality or
to make a separate stand-alone output voltage.
Together, these provide a complete high-efficiency
power-supply solution for digital still cameras. Figure 2
shows the MAX1800 functional diagram.
Master-Slave Configuration
The MAX1800 supports MAX1801 “slave” controllers
that obtain input power, a voltage reference, and an
oscillator signal directly from the MAX1800 “master”
DC-DC converter. The master-slave configuration
reduces system cost by eliminating redundant circuitry
and controlling the harmonic content of noise with synchronized converter switching.
Main DC-DC Converter
The MAX1800 main step-up DC-DC switching converter generates a 2.7V to 5.5V output voltage from a +0.7V
to +5.5V battery input voltage. An internal switch and
synchronous rectifier allow conversion efficiencies as
high as 95% while reducing both circuit size and the
number of external components. The converter operates in a low-noise, constant-frequency PWM mode to
regulate the voltage across the load. Switching harmonics generated by fixed-frequency operation are
consistent and easily filtered.
The internal N-channel MOSFET switch turns on during
the first part of each cycle, allowing current to ramp up
in the inductor and store energy in a magnetic field.
During the second part of each cycle, the MOSFET
turns off and the voltage across the inductor reverses,
forcing current through the internal P-channel synchronous rectifier to the output filter capacitor and load. As
the energy stored in the inductor is depleted, the current ramps down. The synchronous rectifier turns off
when the inductor current approaches zero or at the
beginning of a cycle.
The current-mode PWM controller uses the voltage at
COMPM to program the inductor current and regulate
_______________________________________________________________________________________
9
MAX1800
Pin Description (continued)
MAX1800
Digital Camera Step-Up
Power Supply
INPUT
0.7V TO 5.5V
+15V
POUT
4
DCON
+5V
8
6
5
DL
POUT
7
IN
OSC
MAXIM
MAX 1801
CCD BIAS
LX
ROSC
1
16
OSC
DL1
MAX1800
REF
-7.5V
2
COSC
FB
COMP
20,
21
14
3
0.1µF
GND
2
6
12
28
FB1
4
REF
+18V
LCD BIAS
DCON1
+12V
DCON2
DCON3
+7V
32
30
DL2
DL3
FB3
FB2
RCM
RC1
RC2
RC3
18
COMPM
5 COMP1
11
COMP2
COMP3
29
AO
8
10
26
LDO
1.8V
AI
25
INPUT
CCM
CC1
ON
CC3
7, 22
24
OFF
27
3
POUT
MAIN
3.3V
POUT
CC2
9
31
ONM
COUT
ONA
ON1
OUT
13
ON2
FBM
ON3
RDYM
GND PGND
15
17
23
1, 19
Figure 1. Typical Application Circuit
10
______________________________________________________________________________________
MAIN POWER OK
Digital Camera Step-Up
Power Supply
MAX1800
UNDERVOLTAGE LOCKOUT
OUT
MAX1800
IC POWER
2.35V
EN
EN
STARTUP
OSCILLATOR
POUT
POUT
MAIN PWM
CONTROLLER
Q
Q1
D
P
LX
ONM
REF
GND
OSC
1.25V
EN
RDY
ON
REFERENCE
REF
EN
OSCILLATOR
FBM
LX
OSC
FB
Q2
N
PGND
PGND
COMP
COMPM
FB1
COMP1
DCON1
AUX1
EN
OSC
Q
FB
COMP
DUTY
DL1
FB2
COMP2
DCON2
AUX2
EN
OSC
Q
FB
COMP
DUTY
DL2
FB3
COMP3
DCON3
AUX3
EN
OSC
Q
FB
COMP
DUTY
DL3
AI
GAIN
BLOCK
ON1
ON2
VREF
AO
EN
RDYM
N
ON3
ONA
0.9VREF
Figure 2. Simplified Functional Diagram
the output voltage. The controller forces the inductor current to rise above the 300mA Idle Mode threshold to
ensure pulse skipping and improved efficiency at light
loads.
Auxiliary DC-DC Controllers
The MAX1800 auxiliary controllers operate in a low-noise,
fixed-frequency, PWM mode, with output power limited by
the external components. The controllers regulate their output voltages by modulating the pulse width of the drive signal for an external N-channel MOSFET switch. The auxiliary
controllers are inactive until the main output has started.
Figure 3 shows a block diagram for a MAX1800 auxiliary PWM controller. A sawtooth oscillator signal at OSC
governs the internal timing. At the beginning of each
cycle, DL_ goes high to turn on the external MOSFET
switch. The MOSFET switch turns off when the internally
level-shifted sawtooth rises above COMP_ or when the
maximum duty cycle is exceeded. The switch remains
off until the beginning of the next cycle. An internal
transconductance amplifier establishes an integrated
error voltage at COMP_, thereby increasing the loop
gain for improved regulation accuracy.
______________________________________________________________________________________
11
MAX1800
Digital Camera Step-Up
Power Supply
FB
COMP
R
Q
DL_
LEVEL
SHIFT
REFI
SOFTSTART*
REF
S
DCON
CLK
OSC
*SOFT-START RAMPS REFI FROM 0V TO VREF IN 1024 CLK CYCLES.
FAULT
PROTECTION
ENABLE
Figure 3. PWM Auxiliary Controller Block Diagram
Analog Gain Block
The MAX1800 analog gain block is a voltage amplifier
with a gain of 100 and a push-pull output stage with
2.5mA drive capability. The analog gain block can be
used with an external P-channel MOSFET pass transistor to build a low-dropout linear regulator or can function as a comparator.
Reference
The MAX1800 has an internal 1.250V, 1.6% bandgap
reference. Connect a 0.1µF bypass capacitor from REF
to GND within 0.2in (5mm) of the REF pin. REF can
source up to 200µA of external load current, and it is
enabled whenever ONM is high and VOUT is above the
main undervoltage lockout threshold. The internal analog gain block, auxiliary controllers, and MAX1801
slave controllers each sink up to 30µA REF current during startup. If multiple MAX1801 slave controllers are
turned on simultaneously, ensure that the master voltage reference can provide sufficient current or buffer
the reference with an appropriate unity-gain amplifier.
Oscillator
The oscillator uses a comparator, a 100ns one-shot,
and an internal N-channel MOSFET switch in conjunction with an external timing resistor and capacitor to
generate the oscillator signal at OSC (Figure 4). The
capacitor voltage exponentially approaches the main
12
output voltage from zero with a time constant given by
the ROSCCOSC product when the switch is open, and
the comparator output becomes high when the capacitor voltage reaches VREF (1.25V). In turn, the one-shot
activates the internal MOSFET switch to discharge the
capacitor within a 100ns interval, and the cycle
repeats. Note that the oscillation frequency changes as
the main output voltage ramps upward following startup. The oscillation frequency is constant while the main
output is in regulation.
Low-Voltage Startup Oscillator
The MAX1800 internal control and reference-voltage
circuitry receive power from the main output and do not
function when the main output voltage is less than the
main undervoltage lockout threshold. The MAX1800
main controller uses a low-voltage startup oscillator,
allowing it to start from an input voltage as low as 0.9V.
At startup, the low-voltage oscillator switches the internal LX-connected N-channel MOSFET until the output
voltage rises to the main undervoltage lockout threshold. Above this level, the normal boost converter control
circuitry takes over.
Once in regulation, the MAX1800 operates with inputs
as low as 0.7V since internal power for the IC is bootstrapped from the output through OUT. At low input
voltages, the MAX1800 may have difficulty starting into
______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
Ready-Main (RDYM) Output
ROSC
The MAX1800 power-ready RDYM comparator opendrain output sinks up to 1mA if the main output drops
10% below its regulation voltage. When FBM exceeds
the RDYM trip level, the RDYM output becomes high
impedance to indicate that the main output is within the
limits of regulation. The RDYM comparator has 1% hysteresis to prevent oscillations near the trip threshold.
Connect RDYM to POUT with a 1MΩ pullup resistor.
OSC
COSC
VREF
(1.25V)
100ns
ONE-SHOT
MAX1800
Shutdown
Figure 4. Master Oscillator
heavy loads (see the Startup Current vs. Input Voltage
graph in the Typical Operating Characteristics).
Maximum Duty Cycle
The MAX1800 auxiliary controllers use the sawtooth
oscillator signal generated at OSC, the voltage at
DCON_, and an internal comparator to limit their maximum duty cycles (see Setting the Maximum Duty
Cycle). Limiting the duty cycle can prevent saturation in
some magnetic components. A low maximum duty
cycle can also force the converter to operate in discontinuous current mode, simplifying design stability at the
cost of a slight reduction in efficiency.
Soft-Start
The MAX1800 gain block and auxiliary controllers feature a soft-start function that limits inrush current and
prevents excessive battery loading at startup by ramping the output voltage to the regulation voltage. This is
achieved by increasing the internal reference inputs to
the controller transconductance amplifiers from 0 to the
1.25V reference voltage over 1024 oscillator cycles
when initial power is applied or when the controller is
enabled.
Overload Protection
The MAX1800 auxiliary controllers have a fault protection that prevents damage to transformer-coupled or
single-ended primary inductance converter (SEPIC) circuits due to an output overload. When the output voltage drops out of regulation for 1024 oscillator clock
periods, the auxiliary controller is disabled to prevent
excessive output current. Restart the controller by
cycling the voltage at ON_ or DCON_ to GND and back
to the on state. For a step-up application, short-circuit
current is not limited, due to the DC current path
through the inductor and output rectifier to the short-circuit. If short-circuit protection is required in a step-up
The main DC-DC converter shuts down with a low input
at ONM. Auxiliary DC-DC converters 1, 2, and 3, and the
uncommitted gain block shut down with low inputs at
ON1, ON2, ON3, and ONA, respectively. The auxiliary
converters and the gain block cannot be activated until
the MAIN output reaches the RDYM trip threshold.
Typical shutdown supply current is 2nA. For automatic
startup, connect ON_ to POUT. When ONA is low to disable the gain block, AO is driven to POUT.
Design Procedure
Setting the Switching Frequency
Choose a switching frequency to optimize external component size or circuit efficiency for the particular
MAX1800 application. Typically, switching frequencies
between 400kHz and 500kHz offer a good balance
between component size and circuit efficiency—higher
frequencies generally allow smaller components, and
lower frequencies give better conversion efficiency.
The switching frequency is set with an external timing
resistor (ROSC) and capacitor (COSC). At the beginning
of a cycle, the timing capacitor charges through the
resistor until it reaches VREF. The charge time t1 is:


V
t1 = − ROSCCOSC ln 1 − REF 
 VPOUT 
and it decays to zero over time t2 = 100ns. The oscillator frequency is fOSC = 1 / (t1 + t2). Choose fOSC in the
range 100kHz < fOSC < 1MHz. Choose COSC between
22pF and 470pF. Determine ROSC from the relation:
100ns −
ROSC =
1
fOSC

1.25 
COSC ln 1−

 VPOUT 
See the Typical Operating Characteristics for fOSC versus ROSC using different values of COSC.
______________________________________________________________________________________
13
MAX1800
configuration, a protection device such as a fuse must
be used to limit short-circuit current.
VPOUT
MAX1800
Digital Camera Step-Up
Power Supply
Setting the Output Voltages
Set the MAX1800 output voltages by connecting a
resistive voltage-divider from the output voltage to the
corresponding FB_ input. The FB_ input bias current is
less than 100nA, so choose RL1 (the low-side FB_-toGND resistor) to be 100kΩ. Choose RH1 (the high-side
output-to-FB_ resistor) according to the relation:
V

RH1 = RL1  OUT − 1
 1.25

Setting the Maximum Duty Cycle
The master oscillator signal at OSC and the voltage at
DCON_ are used to generate the internal clock signals
for the MAX1800 auxiliary controllers (CLK in Figure 3).
The internal clock’s falling edge occurs when VOSC
exceeds VDCON_ (set by a resistive divider). The internal clock’s rising edge occurs when VOSC falls below
0.25V (Figure 5).
The adjustable maximum duty-cycle range is 40% to
90% (see the Maximum Duty Cycle vs. VDCON_ graph
in the Typical Operating Characteristics.) The maximum
duty cycle defaults to 84% at 100kHz if VDCON_ is at or
above the voltage at V REF (1.25V) (see the Default
Maximum Duty Cycle vs. Frequency graph in the
Typical Operating Characteristics). The controller shuts
down if VDCON_ is less than 0.3V.
Inductor Selection
Select the inductor for either continuous or discontinuous current. Continuous conduction generally offers the
best efficiency. Use discontinuous current if the stepup ratio (VOUT / VIN ) is greater than 1 / ( 1 - DMAX).
Continuous Inductor Current
A reasonable inductor value (LIDEAL) can be derived
from the following equation, which sets continuous
peak-to-peak inductor current at one-third the DC
inductor current:
LIDEAL =
3 (VIN(MAX) − VSW ) D (1 − D)
IOUT fOSC
tent peak-to-peak inductor current is 0.33 IOUT / (1 - D).
The maximum inductor current is 1.17 IOUT / (1 - D).
Inductance values smaller than LIDEAL can be used;
however, the maximum inductor current will rise as L is
reduced, and a larger output capacitance will be
required to maintain output ripple.
The inductor current will become discontinuous if IOUT
decreases by more than a factor of six from the value
used to determine LIDEAL.
Discontinuous Inductor Current
In the discontinuous mode of operation, the MAX1800
controller regulates the output voltage by adjusting the
duty cycle to allow adequate power transfer to the load.
To ensure regulation under worst-case load conditions
(maximum IOUT), choose
V
D
L = OUT MAX
2 IOUT fOSC
The peak inductor current is VIN DMAX / (L fOSC).
The inductor’s saturation current rating should meet or
exceed the calculated peak inductor current.
Input and Output Filter Capacitors
The input capacitor (CIN) in step-up designs reduces
the current peaks drawn from the battery or input
power source and reduces switching noise in the controller. The impedance of the input capacitor at the
switching frequency should be less than that of the
VOSC (V)
DMAX =
tH
tL + tH
1.25
VDCON_
0.25
0
where D, the duty cycle, is given by:
D ≈ 1−
VIN
VOUT + VD
In these equations, VSW is the voltage drop across the
N-channel MOSFET switch, and VD is the forward voltage drop across the rectifier. Given LIDEAL, the consis-
CLK
tL
tH
Figure 5. Auxiliary Controller Internal Clock Signal Generation
14
______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
VRIPPLE ≈ IL(PEAK) ✕ ESR
where IL(PEAK) is the peak inductor current.
Ceramic capacitors typically have lower ESR than tantalum capacitors, but with relatively small capacitance
that dominates the impedance at the switching frequency. In turn, the output ripple is approximately:
VRIPPLE ≈ IL(PEAK) ✕ ZC
where IL(PEAK) is the peak inductor current, and ZC ≈
1 / (2 π fOSC COUT ).
See the Compensation Design section for a discussion
of the influence of output capacitance and ESR on regulation control loop stability.
The capacitor voltage rating must exceed the maximum
applied capacitor voltage. For most tantalum capacitors, manufacturers suggest derating the capacitor by
applying no more than 70% of the rated voltage to the
capacitor. Ceramic capacitors are typically used up to
the voltage rating of the capacitor. Consult the manufacturer’s specifications for proper capacitor derating.
MOSFET Selection
The MAX1800 auxiliary controllers drive an external
logic-level N-channel MOSFET as the circuit switch element. The key selection parameters are:
• On-resistance (RDS(ON))
• Maximum drain-to-source voltage (VDS(MAX))
• Total gate charge (Qg)
• Reverse transfer capacitance (CRSS)
Since the external gate drive swings between POUT
and GND, use a MOSFET whose “on” resistance is
specified at or below the main output voltage. The gate
charge, Qg, includes all capacitance associated with
gate charging and helps to predict the transition time
required to drive the MOSFET between on and off
states. The power dissipated in the MOSFET is due to
on-resistance and transition losses. The on-resistance
loss is:
P1 ≈ D IL2 RDS(ON)
where D is the duty cycle, IL is the average inductor
current, and RDS(ON) is the on-resistance of the MOSFET. The transition loss is approximately:
V
I f
t
P2 ≈ OUT L OSC T
3
where VOUT is the output voltage, IL is the average
inductor current, fOSC is the converter switching frequency, and tT is the transition time. The transition time
is approximately Qg / IG , where Qg is the total gate
charge, and IG is the gate drive current (typically 0.5A).
The total power dissipation in the MOSFET is:
PMOSFET = P1 + P2
Diode Selection
For low-output-voltage applications, use a Schottky
diode to rectify the output voltage because of the
diode’s low forward voltage and fast recovery time.
Schottky diodes exhibit significant leakage current at
high reverse voltages and high temperatures. Thus, for
high-voltage, high-temperature applications, use ultrafast junction rectifiers.
Compensation Design
Each DC/DC converter has an internal transconductance error amplifier whose output is used to compensate the control loop. Typically, a series resistor and
capacitor are inserted from COMP_ to GND to form a
pole-zero pair. The external inductor, the output capacitor, the compensation resistor and capacitor, and the
POUT-to-OUT RC filter govern control-loop stability.
The inductor and output capacitor are usually chosen
in consideration of performance, size, and cost, but the
compensation resistor and capacitor and the POUT-toOUT RC filter are chosen to optimize control-loop stability. The component values in the circuit of Figure 1
yield stable operation over a broad range of input/output voltages and converter switching frequencies.
Follow the procedures below for optimal compensation.
Main Controller
The main converter uses current mode to regulate the
main output voltage, thereby simplifying the controlloop compensation. When the converter operates with
continuous inductor current, a right-half-plane zero
appears in the loop-gain frequency response. To
ensure stability, the control loop must cross over (drop
below unity gain) at a frequency much less than that of
the right-half-plane zero.
______________________________________________________________________________________
15
MAX1800
input source so that high-frequency switching currents
do not pass through the input source.
The output capacitor is required to keep the output voltage ripple small and to ensure stability of the regulation
control loop. The output capacitor must have low
impedance at the switching frequency. Tantalum and
ceramic capacitors are good choices. Tantalum capacitors typically have high capacitance and medium-tolow equivalent series resistance (ESR) so that ESR
dominates the impedance at the switching frequency.
In turn, the output ripple is approximately:
MAX1800
Digital Camera Step-Up
Power Supply
To determine the compensation components:
1) Find the frequency of the right-half-plane zero:
V
(1 − DM )2
fRHPZ = POUT
2π ILOAD(MAX) L
where VPOUT is the output voltage, ILOAD(MAX) is the
maximum load current, L is the inductor value, and
D M is the duty-cycle under maximum load,
specifically:
DM =
[
]
VPOUT − VIN + ILIM (RPCH + ESRL )
VPOUT + ILIM (RPCH + RNCH )
where I LIM is the average inductor current under
maximum load, ESRL is the equivalent series resistance of the inductor, RPCH and RNCH are the onstate drain-source resistance of the P-channel switch
(200mΩ typ) and N-channel switch (100mΩ typ),
respectively.
2) Specify the control-loop crossover frequency (the
frequency at which the loop gain drops to unity) at
one-fifth the frequency of the right-half-plane zero:
fCROSS = fRHPZ / 5
3) Find the DC open-loop voltage gain:
V
(1 − DM )A VCOMP
A VLOOP = REF
A VCS ILOAD
where VREF is the 1.25V reference voltage, AVCOMP
is the DC voltage gain of the internal error amplifier
(2000), A VCS is the transresistance gain of the
internal current-sense amplifier (0.375), and DM is
the maximum duty cycle determined in step 1 above.
With these parameter values, the open-loop voltage
gain is:
A VLOOP =
6666 (1 − DM )
ILOAD
4) Set the dominant pole so that the loop crossover
occurs at the frequency specified in step 2 above:
f
GM
fDOM = CROSS =
A VLOOP (2πA VCOMP CC )
where GM is the transconductance of the error amplifier (typically 100µS), and CC is the compensation
capacitor. Subject to this condition, the compensation capacitor is:
16
CC =
50 x 10−9 A VLOOP
2π fCROSS
5) Determine the pole due to the output capacitor
(fOUT), and set the compensation zero (fCOMPZ) at
the same frequency. The pole occurs at:
ILOAD(MAX)
fOUT =
2π COUT VPOUT
where COUT is the total output capacitance at POUT,
and the zero occurs at:
fCOMPZ =
1
2πRCCC
Thus, setting fOUT to fCOMZ:
ILOAD(MAX)
COUT VPOUT
=
1
RC C C
The compensation resistor RC (positioned in series
with the compensation capacitor) is:
RC =
COUT VPOUT
CC ILOAD(MAX)
6) Find the frequency of the zero (fESRZ) due to the output capacitance equivalent series resistance (ESR),
and set the POUT-to-OUT RC filter pole (fFILTER) at
the same frequency. The zero occurs at:
fESRZ =
1
2π COUT ESR
and the pole occurs at:
fFILTER =
1
2π RF CF
where RF and CF are the filter resistor and capacitor,
respectively. Thus:
COUT ESR = RF CF
To ensure that noise is reduced at OUT, choose CF ≥
1µF. Then determine RF:
RF =
COUTESR
CF
______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
Discontinuous Inductor Current
For discontinuous inductor current, the PWM converter
has a single pole. The pole frequency and DC gain of
the PWM controller are dependent on the operating
duty cycle, which is:
1
GEA
=
4000 π CC 4 × 107 π CC
PC =
ZC =
The equivalent series resistance (ESR) of the output filter capacitor causes a zero in the loop response at the
frequency (in Hz):
1
 2Lf
2
D =  OSC 
 RE 
where RE is the equivalent load resistance, or:
RE =
VIN2 RLOAD
VOUT (VOUT − VIN )
The frequency of the single pole due to the PWM converter is:
PO =
(2 VOUT − VIN )
2π (VOUT − VIN ) RLOAD COUT
The DC gain of the PWM controller is:
AVO =
2VOUT (VOUT − VIN )
2π( VOUT − VIN ) RLOAD COUT
ZO =
1
2 π COUT ESR
The DC gain, and the poles and zeros are shown in the
Bode plot of Figure 6.
To achieve a stable circuit with the Bode plot of Figure
6, perform the following procedure:
1) Choose the compensation resistor RC that is equivalent to the inverse of the transconductance of the
error amplifier, 1/ RC = GEA = 100µS, or RC = 10kΩ.
This sets the high-frequency voltage gain of the
error amplifier to 0dB.
2) Determine the maximum output pole frequency:
PO(MAX) =
2(VOUT - VIN)
2π(VOUT - VIN ) RLOAD(MIN) COUT
where:
Note that the pole frequency decreases and the DC
gain increases proportionally as the load resistance
(RLOAD) is increased. Since the crossover frequency is
the product of the pole frequency and the DC gain, it
remains independent of the load.
RLOAD(MIN) =
VOUT
IOUT(MAX)
180°
80
The gain through the voltage-divider is:
V
A VDV = REF
VOUT
1
2 π RC CC
AVDC
60
PC
PHASE
90°
40
The DC gain of the error amplifier is AVEA = 2000V/V.
Thus, the DC loop gain is:
ZC = PO
GAIN
(dB)
GAIN
AVDC = AVDV AVEA AVO
The compensation resistor-capacitor pair at COMP
cause a pole and zero at frequencies (in Hz):
PHASE
20
0°
O
ZO
-20
FREQUENCY
Figure 6. MAX1800 Discontinuous-Current, Voltage-Mode,
Step-Up Converter Bode Plot
______________________________________________________________________________________
17
MAX1800
Auxiliary Controllers
The auxiliary controllers use voltage mode to regulate
their output voltages, so the control-loop compensation
is slightly more complex than that for the main converter. Use one of the two following procedures:
MAX1800
Digital Camera Step-Up
Power Supply
4) Place the compensation zero at the same frequency
as the maximum output pole frequency (in Hz):
ZC =
1
2π RCCC
=
2(VOUT - VIN)
2π(VOUT - VIN ) RLOAD(MIN) COUT
Solving for CC:


VOUT - VIN
CC = COUT VOUT 

 RC IOUT(MAX) 2(VOUT - VIN ) 
Use values of CC less than 10nF. If the above calculation determines that the capacitor should be greater
than 10nF, use CC = 10nF, skip step 4 , and proceed to
step 5.
4) Determine the crossover frequency (in Hz):
fC =
The response of the control loop includes a right-halfplane zero and a complex pole pair due to the inductor
and output capacitor. For stable operation, the controller loop gain must drop below unity (0dB) at a much
lower frequency than the right-half-plane zero frequency. The zero arising from the ESR of the output capacitor is typically used to compensate the control circuit
by increasing the phase near the crossover frequency,
increasing the phase margin. If a low-value, low-ESR
output capacitor (such as a ceramic capacitor) is used,
the ESR-related zero occurs at too high a frequency
and does not increase the phase margin. In this case,
use a lower value inductor so that it operates with discontinuous current (see the Discontinuous Inductor
Current section).
For continuous inductor current, the gain of the voltage
divider is AVDV = VREF / VOUT, and the DC gain of the
error amplifier is AVEA = 2000. The gain through the
PWM controller in continuous current is:
VREF
π D COUT
To maintain at least a 10dB gain margin, make sure
that the crossover frequency is less than or equal to
1/3 of the output capacitor ESR zero frequency, or:
3fC ≤ ZO
A VO =
Thus, the total DC loop gain is:
A VDC =
or:
ESR ≤ D
D
6 VERF
If this is not the case, go to step 5 to reduce the error
amplifier high-frequency gain to decrease the
crossover frequency.
5) The high-frequency gain may be reduced, thus
reducing the crossover frequency, as long as the
zero due to the compensation network remains at
or below the crossover frequency. In this case:
ESR ≤
D
GEA RC 6 VERF
and:
V
G R
1
fC = REF EA C ≥ 1
π D COUT
2π RC CC
Choose COUT, RC, and CC to simultaneously satisfy
both equations.
Continuous Inductor Current
For continuous inductor current, there are two conditions that change, requiring different compensation.
18
VOUT 2
VIN VREF
2000 VOUT
VIN
The complex pole pair due to the inductor and output
capacitor occurs at the frequency (in Hz):
PO =
VOUT
2π VIN LCOUT
The pole and zero due to the compensation network at
COMP occur at the frequencies (in Hz):
PC =
1
GEA
=
7
4000 π CC 4 × 10 π CC
ZC =
1
2 π RC CC
The frequency (in Hz) of the zero due to the ESR of the
output capacitor is:
ZO =
1
2 π COUT ESR
The right-half-plane zero frequency (in Hz) is:
ZRHP =
(1 - D)2 RLOAD
2πL
______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
MAIN
GAIN
AVDC
MAX1800
180°
PC
INPUT
1-CELL
LITHIUM-ION
L1
L2
PHASE
ZC=PO
90°
GAIN
(dB)
IN
DCON
PHASE
O dB
C2
DL
Q1
PART OF
MAX1800
PHASE
MARGIN
ZO
GAIN
MARGIN
OUTPUT
3.3V
D1
R1
FB
0°
COMP
ZrRHP
R2
FREQUENCY
RC
Figure 7. MAX1800 Continuous-Current, Voltage-Mode,
Step-Up Converter Bode Plot
The Bode plot of the loop gain of this control circuit is
shown in Figure 7.
To configure the compensation network for a stable
control loop, set the crossover frequency at that of the
zero due to the output capacitor ESR. Use the following
procedure:
1) Determine the frequency of the right-half-plane
zero:
CC
Figure 8. Auxiliary SEPIC Configuration
5) Determine the desired compensation pole. Since
the response between the compensation pole and
the complex pole pair is 1st order (-20dB per
decade), the ratio of the frequencies is equal to the
ratio of the amplitudes at those frequencies. Thus:
PO
A
= DC
PC A(PO )
2
ZRHP =
(1 - D) RLOAD
2πL
Solving this equation for CC:
2) Find the DC loop gain:
3
CC =
AVDC = 2000 VOUT VIN
3) Determine the frequency of the complex pole pair
due to the inductor and output capacitor:
fO =
VOUT
2π VIN LCOUT
( )
2
20MΩ VIN (L)
1
2
6) Determine that the compensation resistor, RC for
the compensation zero frequency, is equal to the
complex pole-pair frequency:
ZC = PO
4) Since response is 2nd order (-40dB per decade)
between the complex pole pair and the ESR zero,
determine the desired amplitude at the complex
pole pair to force the crossover frequency equal to
the ESR zero frequency. Thus:
Z 
A PO =  O 
 PO 
VOUT (COUT ) 2 ESR2
Solving for RC:
RC =
VIN LCOUT
VOUT CC
2
=
LVIN
COUT ESR2 VOUT
2
______________________________________________________________________________________
19
MAX1800
Digital Camera Step-Up
Power Supply
Applications Information
Using the MAX1801 with the MAX1800
Step-Up Master
The MAX1801 is a slave DC-DC controller that can be
used with the MAX1800 to generate additional output
voltages. It does not generate its own reference or
oscillator. Instead, it uses the reference and oscillator
of the MAX1800 step-up master converter controller
(Figure 1). The MAX1801 controller operation and
design are similar to that for the MAX1800 auxiliary
controllers. For more details, consult the MAX1801 data
sheet.
Using an Auxiliary Controller
in a SEPIC Configuration
Where the battery voltage may be above or below the
required output voltage, a step-up converter or stepdown converter will not be suitable; use a step-up
/step-down converter. One type of step-up/step-down
converter is the single-ended primary inductance converter (or SEPIC) shown in Figure 8. Inductors L1 and
L2 can be separate inductors or can be wound on a
single core and coupled like a transformer. Typically,
using a coupled inductor will improve efficiency since
some power is transferred through the coupling so that
less power passes through coupling capacitor C2.
Likewise, C2 should be a low-ESR type capacitor to
improve efficiency. The ripple current rating must be
greater than the larger of the input and output currents.
The MOSFET (Q1) drain-source voltage rating and the
rectifier (D1) reverse voltage rating must exceed the
sum of the input and output voltages. Other types of
step-up/step-down circuits are a flyback converter and
a step-up converter followed by a linear regulator.
Using an Auxiliary Controller
for a Multi-Output Flyback Circuit
Some applications require multiple voltages from a single converter that features a flyback transformer. Figure
9 shows a MAX1800 auxiliary controller in a two-output
flyback configuration. The controller drives an external
MOSFET that switches the transformer primary, and the
two secondaries generate the output voltages. Only a
single positive output voltage can be regulated using
the feedback resistive voltage-divider, so the other voltages are set by the turns ratio of the transformer secondaries. The regulation of the other secondary voltages
degrades due to transformer leakage inductance and
winding resistance. Voltage regulation is best when the
load current is limited to a small range. Consult the
transformer manufacturer for the proper design for a
given application.
20
+ OUTPUT
INPUT
1-CELL
LITHIUM-ION
MAIN
- OUTPUT
IN
DCON
DL
Q1
PART OF
MAX1800
R1
FB
COMP
R2
RC
CC
Figure 9. Auxiliary Flyback Configuration
Using a Charge Pump For
Negative Output Voltages
Negative output voltages can be produced without a
transformer, using a charge-pump circuit with an auxiliary controller as shown in Figure 10. When MOSFET
Q1 turns off, the voltage at its drain rises to supply current to VOUT+. At the same time, C1 charges to the voltage at VOUT+ through D1. When the MOSFET turns on,
C1 discharges through D3, thereby charging C3 to
VOUT- minus the drop across D3 to create roughly the
same voltage as V OUT+ at V OUT- but with inverted
polarity. If different magnitudes are required for the
positive and negative voltages, a linear regulator can
be used at one of the outputs to achieve the desired
voltages.
Using the Gain Block
as a Linear Regulator
The gain block at AO can be used with an external Pchannel MOSFET to make a low-dropout linear regulator. The gain block output has push-pull drive, which
makes it suitable to drive a MOSFET gate. The circuit
for this application is shown in Figure 11.
The output voltage is set by the resistive voltage-divider
of R1 and R2. Use 100kΩ for R2. R1 is:
______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
MAX1800
D3
INPUT VOLTAGE
(FROM MAIN
OUTPUT)
VOUTC3
INPUT
1-CELL
LITHIUM-ION
D1
MAIN
PART OF MAX 1800
C1
L
Q1
D2
IN
AI
VOUT+
DCON
DL
COUT
C2
Q1
PART OF
MAX1800
R1
R1
LOAD
RESISTOR
(RL)
AI
FB
VREF
COMP
R2
R2
ONA
ON
OFF
RC
CC
Figure 11. Linear Regulator
Figure 10. Auxiliary Charge-Pump Configuration
V

R1 = R2  OUT − 1
V
 REF

Choose the MOSFET for low dropout. The maximum
acceptable on-resistance of the MOSFET is determined
by the maximum load current to achieve the required
dropout voltage (minimum input voltage minus output
voltage):
RDS − ON ≤
VDROPOUT
ILOAD(MAX)
Determine the minimum output capacitance as follows.
The output capacitor and load resistance set the dominant pole (fP1):
fP1 =
1
2πRLOAD COUT
The second pole (fP2) occurs due to the AO output
resistance and the gate capacitance of the external
MOSFET:
fP2 =
1
2πRAO C(GATE − Q1)
where RAO is the output resistance of the gain block at
AO, and C(GATE-Q1) is the total gate capacitance of the
MOSFET, Q1. The control loop DC gain is:
V

A VLOOP =  REF  A (V −GB)G(FS−Q1)RLOAD
 VOUT 
where AV-GB is the voltage gain from AI to AO (typically
100), and G(FS-Q1) is the forward transconductance
gain of Q1. Choose the output capacitance so that the
second pole occurs at or above the loop-gain crossover
frequency:
V

COUT ≥  REF  A (V −GB)G(FS−Q1)RAOC(GATE−Q1)
V
 OUT 
Since VREF is 1.25V, A(V-GB) is typically 100, and RAO
is typically 800Ω, then:
 12,500G(FS−Q1)C(GATE−Q1) 
COUT ≥ 

VOUT


Using the Linear Regulator to Make a
Step-Up/Step-Down Circuit
Some applications have a battery voltage that can be
either greater than or less than the desired output voltage. In this case, a step-up or step-down converter will
not be able to generate the required output voltage
under all conditions. To avoid this limitation, use a step-
______________________________________________________________________________________
21
MAX1800
Digital Camera Step-Up
Power Supply
up/step-down DC/DC converter. One way of making
such a circuit is to add a low-dropout linear regulator
after a step-up converter. When the battery voltage is
below the output voltage, the step-up converter generates the higher voltage, and the LDO regulator is in
dropout. When the battery voltage is greater than the
output voltage, the LDO drops the voltage to the
required output voltage.
Designing a PC Board
A good PC board layout is important to achieve optimal
performance from the MAX1800. Poor design can
cause excessive conducted and/or radiated noise,
both of which are undesirable.
Conductors carrying discontinuous currents should be
kept as short as possible. Conductors carrying high
currents should be made as wide as possible. A separate low-noise ground plane containing the reference
and signal grounds should only connect to the power-
22
ground plane at one point to minimize the effects of
power-ground currents.
Keep the voltage feedback network very close to the
IC, preferably within 0.2in (5mm) of the FB_ pin. Nodes
with high dV/dt (switching nodes) should be kept as
small as possible and should stay away from highimpedance nodes such as FB_.
Consult the MAX1800EVKIT evaluation kit data sheet
for a full PC board example.
Chip Information
TRANSISTOR COUNT: 5641
______________________________________________________________________________________
Digital Camera Step-Up
Power Supply
32L TQFP, 5x5x01.0.EPS
______________________________________________________________________________________
23
MAX1800
Package Information
Digital Camera Step-Up
Power Supply
MAX1800
Package Information (continued)
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.
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© 2000 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.