MAXIM MAX1566|MAX1567

19-2882; Rev 0; 5/03
KIT
ATION
EVALU
E
L
B
AVAILA
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
The MAX1566/MAX1567 include six high-efficiency DCto-DC conversion channels:
Features
♦ 95% Efficient Step-Up DC-to-DC Converter
♦ 0.7V Minimum Input Voltage
♦ Main DC-to-DC Configurable as Either Step-Up or
Step-Down
♦ Combine Step-Up and Step-Down for 90%
Efficient Boost-Buck
♦ 95% Efficient Step-Down for DSP Core
♦ Regulate LED Current for Four, Six, or More LEDs
♦ Open LED Overvoltage Protection
• Step-up DC-to-DC converter with on-chip power FETs
♦ Transformerless Inverting Controller (MAX1567)
• Main DC-to-DC converter with on-chip FETs, configurable to step either up or down
♦ Three Extra PWM Controllers (Two on the
MAX1567)
• Step-down core DC-to-DC converter with on-chip
FETs
♦ Up to 1MHz Operating Frequency
• DC-to-DC controller for white LEDs or other output
♦ Soft-Start and Overload Protection
♦ Compact 40-Pin 6mm x 6mm Thin QFN Package
Ordering Information
• Transformerless inverting DC-to-DC controller (typically for negative CCD bias) on the MAX1567
PART
TEMP RANGE PIN-PACKAGE
40 Thin QFN
6mm x 6mm
Step-up
controller
MAX1567ETL -40°C to +85°C
40 Thin QFN
6mm x 6mm
Inverting
controller
Applications
Typical Operating Circuit
Li+ OR 2AA
BATTERY INPUT
MAX1567
STEP-UP
SYSTEM 5V
STEP-DN
ONSU
ONM
AUX1
1.8V CORE
CCD/LCD + 15V
FB2
INDL2
GND
DL2
30 CC2
CC1 2
29 ON2
FB1 3
28 PVM
ON1 4
27 LXM
26 PGM
MAX1566/MAX1567
25 PVSU
LXSD 6
AUX3
ONSD
ON3(LED)
LEDS
PVSD 7
24 LXSU
ONSD 8
23 PGSU
FBSD 9
22 OSC
CCSD 10
21 SDOK
AUX1OK
SCF
ONSU
FBSU
REF
CCSU
ONM
CCD - 7.5V
FBM
AUX2
CCM
11 12 13 14 15 16 17 18 19 20
SUSD
ON1
ON2
3.3V LOGIC
CC3
40 39 38 37 36 35 34 33 32 31
FB3H 1
PGSD 5
MAIN DC-TO-DC
PV
TOP VIEW
PDAs
FB3L
Pin Configuration
ON3
Digital Cameras
AUX2
FUNCTION
MAX1566ETL -40°C to +85°C
DL3
All DC-to-DC channels operate at one fixed frequency
settable from 100kHz to 1MHz to optimize size, cost, and
efficiency. Other features include soft-start, power-OK
outputs, and overload protection. The MAX1566/
MAX1567 are available in space-saving 40-pin thin QFN
packages. An evaluation kit is available to expedite
designs.
DL1
• Extra DC-to-DC controller (typically for LCD); two
extra controllers on the MAX1566
♦ 1µA Shutdown Mode
6mm x 6mm
THIN QFN
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at
1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.
1
MAX1566/MAX1567
General Description
The MAX1566/MAX1567 provide a complete powersupply solution for digital cameras. They improve performance, component count, and size compared to conventional multichannel controllers in 2-cell AA,
1-cell lithium-ion (Li+), and dual-battery designs. On-chip
MOSFETs provide up to 95% efficiency for critical power
supplies, while additional channels operate with external
FETs for optimum design flexibility. This optimizes overall
efficiency and cost, while also reducing board space.
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
ABSOLUTE MAXIMUM RATINGS
PV, PVSU, SDOK, AUX1OK, SCF, ON_, FB_,
SUSD to GND ....................................................... -0.3V to +6V
PG_ to GND...........................................................-0.3V to +0.3V
DL1, DL3, INDL2, PVM, PVSD to GND …-0.3V to (PVSU + 0.3V)
DL2 to GND ............................................-0.3V to (INDL2 + 0.3V)
LXSU Current (Note 1) ..........................................................3.6A
LXM Current (Note 1) ............................................................3.6A
LXSD Current (Note 1) ........................................................2.25A
REF, OSC, CC_ to GND...........................-0.3V to (PVSU + 0.3V)
Continuous Power Dissipation (TA = +70°C)
40-Pin Thin QFN (derate 26.3mW/°C above +70°C) .2105mW
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Note 1: LXSU has internal clamp diodes to PVSU and PGSU, LXM has internal clamp diodes to PVM and PGM, and LXSD has internal clamp diodes to PVSD and PGSD. Applications that forward bias these diodes should take care not to exceed the
devices’ power dissipation limits.
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
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
5.5
V
GENERAL
Input Voltage Range
(Note 2)
Step-Up Minimum Startup
Voltage (Note 2)
ILOAD < 1mA, TA = +25°C; startup voltage tempco is
-2300ppm/°C (typ) (Note 3)
0.7
0.9
1.1
V
Shutdown Supply Current into PV
PV = 3.6V
0.1
10
µA
Supply Current into PV with StepUp Enabled
ONSU = 3.6V, FBSU = 1.5V
(does not include switching losses)
300
450
µA
Supply Current into PV with StepUp and Step-Down Enabled
ONSU = ONSD = 3.6V, FBSU = 1.5V, FBSD = 1.5V
(does not include switching losses)
450
700
µA
Supply Current into PV with StepUp and Main Enabled
ONSU = ONM = 3.6V, FBSU = 1.5V, FBSD = 1.5V
(does not include switching losses)
450
700
µA
Total Supply Current from PV and
PVSU with Step-Up and One
AUX Enabled
ONSU = ON1 = 3.6V, FBSU = 1.5V, FB2 = 1.5V
(does not include switching losses)
400
650
µA
REFERENCE
Reference Output Voltage
IREF = 20µA
1.25
1.27
V
Reference Load Regulation
10µA < IREF < 200µA
1.23
4.5
10
mV
Reference Line Regulation
2.7 < PVSU < 5.5V
1.3
5
mV
1.25
1.275
V
52
80
OSCILLATOR
OSC Discharge Trip Level
Rising edge
OSC Discharge Resistance
OSC = 1.5V, IOSC = 3mA
OSC Discharge Pulse Width
OSC Frequency
2
ROSC = 47kΩ, COSC = 100pF
1.225
Ω
150
ns
500
kHz
_______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Rising edge or falling edge (Note 4)
2.30
2.5
2.65
V
STEP-UP DC-TO-DC
Step-Up Startup-to-Normal
Operating Threshold
Step-Up Startup-to-Normal
Operating Threshold Hysteresis
80
Step-Up Voltage Adjust Range
3.0
Start Delay of ONSD, ONM,
ON1, ON2, and ON3 after
SU in Regulation
mV
5.5
OSC
cycles
1024
FBSU Regulation Voltage
V
1.231
1.25
1.269
V
FBSU to CCSU Transconductance
FBSU = CCSU
80
135
185
µS
FBSU Input Leakage Current
FBSU = 1.25V
-100
0.01
+100
Idle ModeTM Trip Level
Current-Sense Amplifier
Transresistance
mA
0.275
V/A
Step-Up Maximum Duty Cycle
FBSU = 1V
85
90
%
PVSU Leakage Current
VLX = 0V, PVSU = 3.6V
0.1
5
µA
LXSU Leakage Current
VLX = VOUT = 3.6V
0.1
5
µA
N channel
95
150
P channel
150
250
2.1
2.4
Switch On-Resistance
N-Channel Current Limit
80
nA
150
1.8
P-Channel Turn-Off Current
mΩ
A
20
mA
mA
Startup Current Limit
PVSU = 1.8V (Note 5)
450
Startup tOFF
PVSU = 1.8V
700
ns
Startup Frequency
PVSU = 1.8V
200
kHz
MAIN DC-TO-DC CONVERTER
Main Step-Up Voltage
Adjust Range
SUSD = PVSU
Main Step-Down Voltage
Adjust Range
PVM Undervoltage Lockout in
Step-Down Mode
3
5.5
V
SUSD = GND, PVM must be greater than output (Note 6)
2.45
5.00
V
SUSD = GND (Note 6)
2.45
2.5
2.55
V
1.231
1.25
1.269
V
Regulation Voltage
FBM to CCM Transconductance
FBM = CCM
80
135
185
µS
FBM Input Leakage Current
FBM = 1.25V
-100
0.01
+100
nA
Idle Mode Trip Level
Current-Sense Amplifier
Transresistance
Step-up mode (SUSD = PVSU)
150
Step-down mode (SUSD = GND)
100
Step-up mode (SUSD = PVSU)
0.25
Step-down mode (SUSD = GND)
0.5
mA
V/A
Idle Mode is a trademark of Maxim Integrated Products, Inc.
_______________________________________________________________________________________
3
MAX1566/MAX1567
ELECTRICAL CHARACTERISTICS (continued)
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
Maximum Duty Cycle (Note 6)
LXM Leakage Current
Switch On-Resistance
Main Switch Current Limit
Synchronous Rectifier
Turn-Off Current
CONDITIONS
Step-up mode (SUSD = PVSU)
MIN
TYP
MAX
80
85
90
Step-down mode (SUSD = GND)
95
VLXM = 0 to 3.6V, PVSU = 3.6V
0.1
5
N channel
95
150
P channel
150
250
Step-up mode (SUSD = PVSU)
1.8
2.1
2.4
Step-down mode (SUSD = GND)
0.70
0.8
0.95
Step-up mode (SUSD = PVSU)
20
Step-down mode (SUSD = GND)
20
Soft-Start Interval
UNITS
%
µA
mΩ
A
mA
OSC
cycles
4096
STEP-DOWN DC-TO-DC CONVERTER
Step-Down Output-Voltage Adjust
PVSD must be greater than output (Note 7)
Range
1.25
FBSD Regulation Voltage
1.231
FBSD to CCSD
Transconductance
FBSD = CCSD
80
FBSD Input Leakage Current
FBSD = 1.25V
-100
5.00
V
1.25
1.269
V
135
185
µS
0.1
+100
nA
Idle Mode Trip Level
100
mA
Current-Sense Amplifier
Transresistance
0.5
V/A
LXSD Leakage Current
Switch On-Resistance
VLXSD = 0 to 3.6V, PVSU = 3.6V
0.1
5
N channel
95
150
P channel
150
250
0.77
0.90
P-Channel Current Limit
0.65
N-Channel Turn-Off Current
Soft-Start Interval
µA
mΩ
A
20
mA
2048
OSC
cycles
SDOK Output Low Voltage
0.1mA into SDOK
0.01
0.1
V
SDOK Leakage Current
ONSU = GND
0.01
1
µA
2.45
2.5
2.55
V
80
85
90
%
FB1, FB2 (MAX1566), FB3H
Regulation Voltage
1.231
1.25
1.269
V
FB2 (MAX1567) Inverter
Regulation Voltage
-0.01
0
+0.01
V
AUX1, 2, 3 DC-TO-DC CONTROLLERS
INDL2 Undervoltage
Lockout
Maximum Duty Cycle
4
FB_ = 1V
_______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
FB3L Regulation Voltage
MIN
TYP
MAX
UNITS
0.19
0.2
0.21
V
AUX1, AUX2 FB to CC
Transconductance
80
135
185
µS
AUX3 FBL or FBH to CC
Transconductance
50
100
150
µS
-100
FB_ Input Leakage Current
0.1
+100
nA
DL_ Driver Resistance
Output high or low
2.5
7
Ω
DL_ Drive Current
Sourcing or sinking
0.5
A
4096
OSC
cycles
Soft-Start Interval
AUX1OK Output Low Voltage
0.1mA into AUX1OK
0.01
0.1
V
AUX1OK Leakage Current
ONSU = GND
0.01
1
µA
OVERLOAD PROTECTION
Overload Protection Fault Delay
OSC
cycles
100,000
SCF Leakage Current
ONSU = PVSU, FBSU = 1.5V
0.1
1
µA
SCF Output Low Voltage
0.1mA into SCF
0.01
0.1
V
THERMAL-LIMIT PROTECTION
Thermal Shutdown
160
°C
Thermal Hysteresis
20
°C
LOGIC INPUTS (ON_, SUSD)
ONSU Input Low Level
1.1V < PVSU < 1.8V
0.2
1.8V < PVSU < 5.5V
0.4
1.1V < PVSU < 1.8V
(PVSU
- 0.2)
1.8V < PVSU < 5.5V
1.6
ONSU Input High Level
ONM, ONSD, ON1, ON2, ON3,
SUSD Input Low Level
2.7V < PVSU < 5.5V (Note 8)
ONM, ONSD, ON1, ON2, ON3,
SUSD Input High Level
2.7V < PVSU < 5.5V (Note 8)
V
V
0.4
1.6
V
V
SUSD Input Leakage
0.1
ON_ Impedance to GND
330
1
µA
kΩ
_______________________________________________________________________________________
5
MAX1566/MAX1567
ELECTRICAL CHARACTERISTICS (continued)
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
ELECTRICAL CHARACTERISTICS
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = -40°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
MAX
UNITS
0.7
GENERAL
Input Voltage Range
(Note 2)
5.5
V
Step-Up Minimum Startup
Voltage (Note 2)
ILOAD < 1mA, TA = +25°C; startup voltage tempco is
-2300ppm/°C (typ) (Note 3)
1.1
V
Shutdown Supply Current into PV
PV = 3.6V
10
µA
Supply Current into PV with StepUp Enabled
ONSU = 3.6V, FBSU = 1.5V
(does not include switching losses)
400
µA
Supply Current into PV with StepUp and Step-Down Enabled
ONSU = ONSD = 3.6V, FBSU = 1.5V, FBSD = 1.5V
(does not include switching losses)
600
µA
Supply Current into PV with StepUp and Main Enabled
ONSU = ONM = 3.6V, FBSU = 1.5V, FBSD = 1.5V
(does not include switching losses)
600
µA
Total Supply Current from PV and
PVSU with Step-Up and One
AUX Enabled
ONSU = ON1 = 3.6V, FBSU = 1.5V, FB2 = 1.5V
(does not include switching losses)
550
µA
REFERENCE
Reference Output Voltage
IREF = 20µA
1.27
V
Reference Load Regulation
10µA < IREF < 200µA
1.23
10
mV
Reference Line Regulation
2.7V < PVSU < 5.5V
5
mV
1.275
V
80
Ω
2.65
V
OSCILLATOR
OSC Discharge Trip Level
Rising edge
OSC Discharge Resistance
OSC = 1.5V, IOSC = 3mA
1.225
STEP-UP DC-TO-DC CONVERTER
Step-Up Startup-to-Normal
Operating Threshold
Rising edge or falling edge (Note 4)
Step-Up Voltage Adjust Range
FBSU Regulation Voltage
2.30
3.0
5.5
V
1.231
1.269
V
FBSU to CCSU
Transconductance
FBSU = CCSU
80
185
µS
FBSU Input Leakage Current
FBSU = 1.25V
-100
+100
nA
Step-Up Maximum Duty Cycle
FBSU = 1V
80
90
%
PVSU Leakage Current
VLX = 0V, PVSU = 3.6V
5
µA
LXSU Leakage Current
VLX = VOUT = 3.6V
5
µA
Switch On-Resistance
N channel
150
P channel
250
N-Channel Current Limit
mΩ
1.8
2.4
A
3.0
5.5
V
MAIN DC-TO-DC CONVERTER
Main Step-Up Voltage
Adjust Range
6
SUSD = PVSU
_______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAX1566/MAX1567
ELECTRICAL CHARACTERISTICS (continued)
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = -40°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
MAX
UNITS
Main Step-Down Voltage
Adjust Range
SUSD = GND, PVM must be greater than output (Note 6)
2.45
5.00
V
PVM Undervoltage Lockout in
Step-Down Mode
SUSD = GND (Note 6)
2.45
2.55
V
1.225
1.275
V
Regulation Voltage
FBM to CCM Transconductance
FBM = CCM
80
185
µS
FBM Input Leakage Current
FBM = 1.25V
-100
+100
nA
Maximum Duty Cycle
Step-up mode (SUSD = PVSU),
step-down mode (SUSD = GND) (Note 6)
80
90
%
LXM Leakage Current
VLXM = 0 to 3.6V, PVSU = 3.6V
5
µA
Switch On-Resistance
Main Switch Current Limit
N channel
150
P channel
250
mΩ
Step-up mode (SUSD = PVSU)
1.8
2.4
Step-down mode (SUSD = GND)
0.70
0.95
1.25
5.00
V
1.225
1.275
V
A
STEP-DOWN DC-TO-DC CONVERTER
Step-Down Output Voltage
Adjust Range
PVSD must be greater than output (Note 7)
FBSD Regulation Voltage
FBSD to CCSD
Transconductance
FBSD = CCSD
80
185
µS
FBSD Input Leakage Current
FBSD = 1.25V
-100
+100
nA
LXSD Leakage Current
VLXSD = 0 to 3.6V, PVSU = 3.6V
5
µA
Switch On-Resistance
N channel
150
P channel
250
P-Channel Current Limit
0.65
SDOK Output Low Voltage
0.1mA into SDOK
SDOK Leakage Current
ONSU = GND
mΩ
0.90
A
0.1
V
1
µA
AUX1, 2, 3 DC-TO-DC CONTROLLERS
INDL2 Undervoltage Lockout
2.45
2.55
V
80
90
%
FB1, FB2 (MAX1566), FB3H
Regulation Voltage
1.225
1.275
V
FB2 (MAX1567) Inverter
Regulation Voltage
-0.01
+0.01
V
FB3L Regulation Voltage
0.19
0.21
V
80
185
µS
Maximum Duty Cycle
AUX1, AUX2 FB to CC
Transconductance
FB_ = 1V
_______________________________________________________________________________________
7
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
ELECTRICAL CHARACTERISTICS (continued)
(VPVSU = VPV = VPVM = VPVSD = VINDL2 = 3.6V, TA = -40°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
AUX3 FBL or FBH to CC
Transconductance
FB_ Input Leakage Current
DL_ Driver Resistance
Output high or low
AUX1OK Output Low
0.1mA into AUX1OK
AUX1OK Leakage Current
ONSU = GND
MIN
MAX
UNITS
35
150
µS
-100
+100
nA
7
Ω
0.1
V
1
µA
OVERLOAD PROTECTION
SCF Leakage Current
ONSU = PVSU, FBSU = 1.5V
1
µA
SCF Output Low Voltage
0.1mA into SCF
0.1
V
1.1V < PVSU < 1.8V
0.2
1.8V < PVSU < 5.5V
0.4
LOGIC INPUTS (ON_, SUSD)
ONSU Input Low Level
1.1V < PVSU < 1.8V
(PVSU
- 0.2)
1.8V < PVSU < 5.5V
1.6
ONSU Input High Level
ONM, ONSD, ON1, ON2, ON3,
SUSD Input Low Level
2.7V < PVSU < 5.5V (Note 8)
ONM, ONSD, ON1, ON2, ON3,
SUSD Input High Level
2.7V < PVSU < 5.5V (Note 8)
V
0.4
1.6
SUSD Input Leakage
v
V
V
1
µA
Note 2: The MAX1566/MAX1567 are powered from the step-up output (PVSU). An internal low-voltage startup oscillator drives the
step-up starting at approximately 0.9V until PVSU reaches approximately 2.5V. When PVSU reaches 2.5V, the main control
circuitry takes over. Once the step-up is up and running, it can maintain operation with very low input voltages; however,
output current is limited.
Note 3: Since the device is powered from PVSU, a Schottky rectifier, connected from the battery to PVSU, is required for low-voltage
startup.
Note 4: The step-up regulator is in startup mode until this voltage is reached. Do not apply full load current during startup. A powerOK output can be used with an external PFET to gate the load until the step-up is in regulation. See the AUX1OK, SDOK,
and SCF Connections section.
Note 5: The step-up current limit in startup refers to the LXSU switch current limit, not the output current limit.
Note 6: If the main converter is configured as a step-up (SUSD = PVSU), the P-channel synchronous rectifier is disabled until the
2.5V normal operation threshold has been exceeded. If the main converter is configured as a step-down (SUSD = GND), all
step-down operation is locked out until the normal operation threshold has been exceeded. When the main is configured as
a step-down, operation in dropout (100% duty cycle) can only be maintained for 100,000 OSC cycles before the output is
considered faulted, triggering global shutdown.
Note 7: Operation in dropout (100% duty cycle) can only be maintained for 100,000 OSC cycles before the output is considered
faulted, triggering global shutdown.
Note 8: ONM, ONSD, ON1, ON2, and ON3 are disabled until 1024 OSC cycles after PVSU reaches 2.7V.
8
_______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAIN (STEP-UP) EFFICIENCY
vs. LOAD CURRENT
90
80
EFFICIENCY (%)
40
40
40
30
20
20
20
10
10
VSU = 5V
10
100
0
0
1
1000
10
100
1000
LOAD CURRENT (mA)
OUTPUT CURRENT (mA)
STEP-DOWN EFFICIENCY
vs. LOAD CURRENT
BOOST-BUCK EFFICIENCY (SU + SD)
vs. LOAD CURRENT
80
60
50
80
40
30
SD = 1.8V
SD INPUT
CONNECTED
TO BATT
20
10
70
VIN = 3.2V
VIN = 2.5V
VIN = 2.0V
VIN = 1.5V
60
50
40
20
100
1000
VM = 3.3V
IOUTVM = 200mA
90
SU = 5V, IOUTSU = 500mA
85
AUX2 = 8V, IOUT2 = 100mA
80
SU + SD, IOUT3 = 350mA
70
1
10
100
1000
1.5
2.5
3.5
LOAD CURRENT (mA)
LOAD CURRENT (mA)
INPUT VOLTAGE (V)
AUX EFFICIENCY vs. LOAD CURRENT
AUX EFFICIENCY vs. LOAD CURRENT
MAX1567 AUX2 EFFICIENCY
vs. LOAD CURRENT
100
MAX1566/67 toc07
90
80
70
30
80
70
VIN = 4.5V
VIN = 3.8V
VIN = 3.0V
VIN = 2.0V
VIN = 1.5V
70
60
20
VOUT_AUX = 5V
0
100
LOAD CURRENT (mA)
1000
50
40
20
40
10
VIN = 2.5V
VIN = 3.0V
VIN = 3.8V
VIN = 4.5V
60
30
50
10
90
EFFICIENCY (%)
40
EFFICIENCY (%)
50
90
4.5
100
80
VIN = 4.5V
VIN = 3.8V
VIN = 3.0V
VIN = 2.0V
VIN = 1.5V
60
1
95
75
VSU = 3.3V
SD = 1.8V
10
10
1000
30
0
1
100
EFFICIENCY vs. INPUT VOLTAGE
90
EFFICIENCY (%)
VIN = 2.5V
VIN = 3.0V
VIN = 3.8V
VIN = 4.5V
70
10
100
EFFICIENCY (%)
90
1
OUTPUT CURRENT (mA)
100
MAX1566/67 toc04
100
VM = 3.3V
VSU = 5V
10
VM = 3.3V
MAX1566/67 toc05
1
VIN = 4.5V
VIN = 3.8V
VIN = 3.2V
VIN = 2.5V
50
30
0
EFFICIENCY (%)
50
70
60
MAX1566/67 toc09
50
60
80
MAX1566/67 toc08
EFFICIENCY (%)
VIN = 4.5V
VIN = 3.8V
VIN = 3.2V
VIN = 2.5V
VIN = 2.0V
VIN = 1.5V
60
30
EFFICIENCY (%)
VIN = 3.2V
VIN = 2.5V
VIN = 2.0V
VIN = 1.5V
70
70
90
MAX1566/67 toc06
80
EFFICIENCY (%)
90
100
MAX1566/67 toc02
100
MAX1566/67 toc01
100
BOOST-BUCK EFFICIENCY
(SU + MAIN AS STEP-DOWN) vs. LOAD CURRENT
MAX1566/67 toc03
STEP-UP EFFICIENCY vs. LOAD CURRENT
VOUT_AUX = 15V
30
10
VAUX2 = -7.5V
0
1
10
LOAD CURRENT (mA)
100
1
10
100
1000
LOAD CURRENT (mA)
_______________________________________________________________________________________
9
MAX1566/MAX1567
Typical Operating Characteristics
(TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(TA = +25°C, unless otherwise noted.)
MINIMUM STARTUP VOLTAGE
vs. LOAD CURRENT (OUTSU)
VSU = 5.0V
+ VSD = 1.8V
1.5
1.0
VSU = 5.0V ONLY
2.0
1.5
1.0
0.5
2
3
4
200
400
600
800
1000
LOAD CURRENT (mA)
REFERENCE VOLTAGE
vs. REFERENCE LOAD CURRENT
OSCILLATOR FREQUENCY vs. ROSC
MAX1566/67 toc13
1.249
1.248
1.247
1.246
1.245
OSCILLATOR FREQUENCY (kHz)
INPUT VOLTAGE (V)
1.250
800
0
50
100
150
200
250
400
200
1
10
AUX_ MAXIMUM DUTY CYCLE
vs. FREQUENCY
100
1000
-50
STEP-UP STARTUP WAVEFORMS
87
86
MAX1566/67 toc16
WHEN THIS DUTY CYCLE IS
EXCEEDED FOR 100,000 CLOCK CYCLES,
THE MAX1566/MAX1567 SHUT DOWN
85
84
COSC = 100pF
83
75
100
-25
0
25
50
75
100
STEP-UP STARTUP WAVEFORMS
MAX1566/67 toc18
ONSU
2V/div
ONSU
2V/div
0V
0V
VSU = 3.3V
5V/div
0V
0V
0A
IOUT_SU
100mA/div
0A
0A
IIN
1A/div
0A
VSU = 5V
5V/div
IOUT_SU
100mA/div
82
81
IIN
1A/div
VIN = 2V, VSU = 3.3V
80
0
200
400
600
800
1000
1200
100µs/div
VIN = 3.0V, VSU = 5V
100µs/div
FREQUENCY (kHz)
10
50
TEMPERATURE (°C)
MAX1566/67 toc17
88
25
315
314
313
312
311
310
309
308
307
306
305
304
303
302
301
300
ROSC (kΩ)
REFERENCE LOAD CURRENT (µA)
0
SWITCHING FREQUENCY vs. TEMPERATURE
600
300
-25
TEMPERATURE (°C)
COSC = 470pF
COSC = 330pF
COSC = 220pF
COSC = 100pF
COSC = 47pF
1000
-50
0
1.244
1.246
1.243
0
5
1.248
SWITCHING FREQUENCY (kHz)
1
MAX1566/7 toc14
0
1.251
WITH NO SCHOTTKY RECTIFER
FROM BATT TO PVSU
0.0
0.5
REFERENCE VOLTAGE (V)
2.5
MAX1566/67 toc15
2.0
3.0
REFERENCE VOLTAGE (V)
VSU = 5.0V
+ VM = 3.3V
1.254
MAX1566/67 toc11
MINIMUM STARTUP VOLTAGE (V)
INPUT CURRENT (mA)
2.5
REFERENCE VOLTAGE vs. TEMPERATURE
3.5
MAX1566/67 toc10
3.0
MAX1566/67 toc12
NO-LOAD INPUT CURRENT
vs. INPUT VOLTAGE (SWITCHING)
MAXIMUM DUTY CYCLE (%)
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAIN (STEP-DOWN MODE) AND STEP-DOWN
STARTUP WAVEFORMS
MAIN (STEP-UP MODE) AND STEP-DOWN
STARTUP WAVEFORMS
MAX1566/67 toc20
MAX1566/67 toc19
ONSU =
ONSD =
ONM
2V/div
0V
VSU
5V/div
VSD
1V/div
0V
VM (MAIN
AS BOOST)
2V/div
0V
0V
ONSU =
ONM =
ONSD
2V/div
VSU
2V/div
0V
0V
VSD
2V/div
0V
VM
2V/div
0V
(MAIN AS STEP-DOWN)
VIN = 3.0V
2ms/div
2ms/div
STEP-UP LOAD TRANSIENT RESPONSE
MAIN (STEP-UP MODE)
LOAD TRANSIENT RESPONSE
MAX1566/67 toc22
MAX1566/67 toc21
0V
VSU
AC-COUPLED
100mV/div
0A
VIN = 3.0V, VSU = 5V
ISU
200mA/div
0V
0A
(MAIN AS STEP-UP)
VIN = 3.0V, VM = 3.3V
IM
100mA/div
1ms/div
1ms/div
MAIN (STEP-DOWN MODE)
LOAD TRANSIENT RESPONSE
STEP-DOWN TRANSIENT RESPONSE
MAX1566/67 toc23
MAX1566/67 toc24
VM
AC-COUPLED
200mV/div
0V
IM
200mA/div
0A
(MAIN AS STEP-DOWN FROM SU)
VIN = 3.0V, VM = 3.3V
1ms/div
VM
AC-COUPLED
100mV/div
VSD
AC-COUPLED
20mV/div
0V
ISD
100mA/div
0A
VIN = 3.0V, VSD = 1.8V
1ms/div
______________________________________________________________________________________
11
MAX1566/MAX1567
Typical Operating Characteristics (continued)
(TA = +25°C, unless otherwise noted.)
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAX1566/MAX1567
Pin Description
PIN
FUNCTION
1
FB3H
AUX3 Controller Voltage Feedback Input. Connect a resistive voltage-divider from the step-up
converter output to FBH to set the output voltage. The feedback threshold is 1.25V. This pin is high
impedance in shutdown. FB3H can provide conventional voltage feedback (with FB3L grounded) or
open-LED protection in white LED drive circuits.
2
CC1
AUX1 Controller Compensation Node. Connect a series resistor-capacitor from this pin to GND to
compensate the converter control loop. This pin is actively driven to GND in shutdown, overload, and
thermal limit. See the AUX Compensation section.
3
FB1
AUX1 Controller Feedback Input. The feedback threshold is 1.25V. This pin is high impedance in
shutdown.
4
ON1
AUX1 Controller On/Off Input. Logic high = on; however, turn-on is locked out until 1024 OSC cycles
after the step-up has reached regulation. This pin has an internal 330kΩ pulldown resistance to GND.
5
PGSD
Power Ground. Connect all PG_ pins to GND with short wide traces as close to the IC as possible.
6
LXSD
Step-Down Converter Switching Node. Connect to the inductor of the step-down converter. LXSD is
high impedance in shutdown.
7
PVSD
Step-Down Converter Input. Bypass to GND with a 1µF ceramic capacitor. The step-down efficiency
is measured from this input.
8
ONSD
Step-Down Converter On/Off Control Input. Logic high = on; however, turn-on is locked out until 1024
OSC cycles after the step-up has reached regulation. This pin has an internal 330kΩ pulldown
resistance to GND.
9
FBSD
Step-Down Converter Feedback Input. The feedback threshold is 1.25V. This pin is high impedance
in shutdown.
10
CCSD
Step-Down Converter Compensation Node. Connect a series resistor-capacitor from this pin to GND
for compensating the converter control loop. This pin is actively driven to GND in shutdown, overload,
and thermal limit. See the Step-Down Compensation section.
SUSD
Configures the Main Converter as a Step-Up or a Step-Down. This function must be hardwired. Onthe-fly changes are not allowed. With SUSD connected to PV, the main is configured as a step-up
and PVM is the converter output. With SUSD connected to GND, the main is configured as a stepdown and PVM is the power input.
12
CCM
Main Converter Compensation Node. Connect a series resistor-capacitor from this pin to GND for
compensating the converter control loop. This pin is actively driven to GND in shutdown, overload,
and thermal limit. See the Step-Up Compensation section when the main is used in step-up mode
and the Step-Down Compensation section when the main is used in step-down mode.
13
FBM
Main Converter Feedback Input. The feedback threshold is 1.25V. This pin is high impedance in
shutdown. The main output voltage must not be set higher than the step-up output.
14
ONM
On/Off Control for the Main DC-to-DC Converter. Logic high = on; however, turn-on is locked out until
1024 OSC cycles after the step-up has reached regulation. This pin has an internal 330kΩ pulldown
resistance to GND. SUSD pin configures the main converter as a step-up or step-down.
15
REF
Reference Output. Bypass REF to GND with a 0.1µF or greater capacitor. The maximum-allowed REF
load is 200µA. REF is actively pulled to GND when the step-up is shut down (all converters turn off).
11
12
NAME
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
PIN
NAME
FUNCTION
16
CCSU
Step-Up Converter Compensation Node. Connect a series resistor-capacitor from this pin to GND for
compensating the converter control loop. This pin is actively driven to GND in shutdown, overload,
and thermal limit. See the Step-Up Compensation section.
17
FBSU
Step-Up Converter Feedback Input. The feedback threshold is 1.25V. This pin is high impedance in
shutdown.
18
ONSU
Step-Up Converter On/Off Control. Logic high = on. All other ON_ pins are locked out until 1024 OSC
cycles after the step-up DC-to-DC converter output has reached its final value. This pin has an
internal 330kΩ pulldown resistance to GND.
19
SCF
Open-Drain, Active-Low, Short-Circuit Flag Output. SCF goes open when overload protection occurs
and during startup. SCF can drive high-side PFET switches connected to one or more outputs to
completely disconnect the load when the channel turns off in response to a logic command or an
overload. See the Status Outputs (SDOK, AUX1OK, SCF) section.
20
AUX1OK
21
SDOK
22
OSC
Oscillator Control. Connect a timing capacitor from OSC to GND and a timing resistor from OSC to
PVSU (or other DC voltage) to set the oscillator frequency between 100kHz and 1MHz. See the
Setting the Switching Frequency section. This pin is high impedance in shutdown.
23
PGSU
Power Ground. Connect all PG_ pins to GND with short wide traces as close to the IC as possible.
24
LXSU
Step-Up Converter Switching Node. Connect to the inductor of the step-up converter. LXSU is high
impedance in shutdown.
25
PVSU
Power Output of the Step-Up DC-to-DC Converter. PVSU can also power other converter channels.
Connect PVSU and PV together.
26
PGM
Power Ground. Connect all PG_ pins to GND with short wide traces as close to the IC as possible.
27
LXM
Main Converter Switching Node. Connect to the inductor of the main converter (can be configured as
a step-up or step-down by SUSD). LXM is high impedance in shutdown.
28
PVM
When SUSD = PVSU, the main converter is configured as a step-up and PVM is the main output.
When SUSD = GND, the main is configured as a step-down and PVM is the power input.
29
ON2
AUX2 Controller On/Off Input. Logic high = on; however, turn-on is locked out until 1024 OSC cycles
after the step-up has reached regulation. This pin has an internal 330kΩ pulldown resistance to GND.
30
CC2
AUX2 Controller Compensation Node. Connect a series resistor-capacitor from this pin to GND to
compensate the converter control loop. This pin is actively driven to GND in shutdown, overload, and
thermal limit. See the AUX Compensation section.
Open-Drain, Active-Low, Power-OK Signal for AUX1 Controller. AUX1OK goes low when the AUX1
controller has successfully completed soft-start. AUX1OK goes high impedance in shutdown,
overload, and thermal limit.
Open-Drain, Active-Low, Power-OK Signal for Step-Down Converter. SDOK goes low when the stepdown has successfully completed soft-start. SDOK goes high impedance in shutdown, overload, and
thermal limit.
______________________________________________________________________________________
13
MAX1566/MAX1567
Pin Description (continued)
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAX1566/MAX1567
Pin Description (continued)
PIN
31
FB2
FUNCTION
AUX2 Controller
Feedback Input. This
pin is high impedance
in shutdown.
MAX1566 (AUX2 is configured as a boost): FB2 feedback threshold is
1.25V.
MAX1567 (AUX2 is configured as an inverter): FB2 feedback threshold is
0V.
MAX1566 (AUX2 is configured as a boost): connect INDL2 to PVSU for
Voltage Input for AUX2
optimum N-channel gate drive.
Gate Driver. The voltage
MAX1567 (AUX2 is configured as an inverter): connect INDL2 to the
at INDL2 sets the high
external P-channel MOSFET source to ensure the P channel is completely
gate-drive voltage.
off when DL2 swings high.
32
INDL2
33
GND
Analog Ground. Connect to all PG_ pins as close to the IC as possible.
DL2
AUX2 Controller GateDrive Output. DL2
drives between INDL2
and GND.
34
The MAX1566 configures DL2 to drive an N-channel FET in a boost
configuration. DL2 is driven low in shutdown, overload, and thermal limit.
The MAX1567 configures DL2 to drive a PFET in an inverter configuration.
DL2 is driven high in shutdown, overload, and thermal limit.
35
DL3
AUX3 Controller Gate-Drive Output. Connect to the gate of an N-channel MOSFET. DL3 drives
between GND and PVSU and supplies up to 500mA. This pin is actively driven to GND in shutdown,
overload, and thermal limit.
36
DL1
AUX1 Controller Gate-Drive Output. Connect to the gate of an N-channel MOSFET. DL1 drives
between GND and PVSU and supplies up to 500mA. This pin is actively driven to GND in shutdown,
overload, and thermal limit.
37
PV
38
CC3
AUX3 Controller Compensation Node. Connect a series resistor-capacitor from this pin to GND for
compensating the converter control loop. This pin is actively driven to GND in shutdown, overload,
and thermal limit. See the AUX Compensation section.
39
FB3L
AUX3 Controller Current-Feedback Input. Connect a resistor from FB3L to GND to set LED current in
LED boost-drive circuits. The feedback threshold is 0.2V. Connect this pin to GND if using only the
FB3H feedback. This pin is high impedance in shutdown.
40
ON3
AUX3 Controller On/Off Input. Logic high = on; however, turn-on is locked out until 1024 OSC cycles
after the step-up has reached regulation. This pin has an internal 330kΩ pulldown resistance to GND.
EP
Exposed Metal Pad. This pad is connected to ground. Note this internal connection is a soft-connect,
meaning there is no internal metal or bond wire physically connecting the exposed pad to the GND
pin. The connection is through the silicon substrate of the die and then through a conductive epoxy.
Connecting the exposed pad to ground does not remove the requirement for a good ground
connection to the appropriate pins.
Pad
14
NAME
IC Power Input. Connect PVSU and PV together.
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
The MAX1566/MAX1567 include the following blocks to
build a multiple-output digital camera power-supply
system. Both devices can accept inputs from a variety
of sources including 1-cell Li+ batteries, 2-cell alkaline
or NiMH batteries, and even systems designed to
accept both battery types. The MAX1566/
MAX1567 include six DC-to-DC converter channels to
generate all required voltages:
• Step-up DC-to-DC converter (_SU pins) with on-chip
power FETS
• Main DC-to-DC converter (_M pins) with on-chip
power FETS that can be configured as either a stepup or step-down DC-to-DC converter
• Step-down core DC-to-DC converter with on-chip
MOSFETs (_SD pins)
• AUX1 DC-to-DC controller for boost and flyback
converters
• AUX2 DC-to-DC controller for boost and flyback
converters (MAX1566)
• AUX2 DC-to-DC controller for inverting DC-to-DC
converters (MAX1567)
• AUX3 DC-to-DC controller for white LED as well as
conventional boost applications; includes open LED
overvoltage protection
Step-Up DC-to-DC Converter
The step-up DC-to-DC switching converter typically is
used to generate a 5V output voltage from a 1.5V to
4.5V battery input, but any voltage from VIN to 5V can
be set. An internal NFET switch and external synchronous rectifier allow conversion efficiencies as high as
95%. Under moderate to heavy loading, the converter
operates in a low-noise PWM mode with constant
frequency and modulated pulse width. Switching
harmonics generated by fixed-frequency operation are
consistent and easily filtered. Efficiency is enhanced
under light (<75mA typ) loading by an Idle Mode that
switches the step-up only as needed to service the
load. In this mode, the maximum inductor current is
150mA for each pulse.
Main DC-to-DC Converter (Step-Up or
Step-Down)
The main converter can be configured as a step-up
(Figure 2) or a step-down converter (Figure 1) with the
SUSD pin. The main DC-to-DC converter is typically
used to generate 3.3V, but any voltage from 2.7V to 5V
can be set; however, the main output must not be set
higher than the step-up output (PVSU).
An internal MOSFET switch and synchronous rectifier
allow conversion efficiencies as high as 95%. Under
moderate to heavy loading, the converter operates in a
low-noise PWM mode with constant frequency and
modulated pulse width. Switching harmonics generated
by fixed-frequency operation are consistent and easily
filtered. Efficiency is enhanced under light loading
(<150mA typical for step-up mode, <100mA typical for
step-down mode) by assuming an Idle Mode during
which the converter switches only as needed to service
the load.
Step-down operation can be direct from a Li+ cell if the
minimum input voltage exceeds the desired output by
approximately 200mV. Note that if the main DC-to-DC,
operating as a step-down, operates in dropout, the
overload protection circuit senses an out-of-regulation
condition and turns off all channels.
Li+ to 3.3V Boost-Buck Operation
When generating 3.3V from an Li+ cell, boost-buck
operation may be needed so a regulated output can be
maintained for input voltages above and below 3.3V. In
that case, it may be best to configure the main converter as a step-down (SUSD = GND) and to connect its
input, PVM, to the step-up output (PVSU), set to a voltage at or above 4.2V (Figures 1 and 3). The compound
efficiency with this connection is typically up to 90%.
This connection is also suitable for designs that must
operate from both 1-cell Li+ and 2 AA cells.
Note that the step-up output supplies both the step-up
load and the main step-down input current when the
main is powered from the step-up. The main input current reduces the available step-up output current for
other loads.
2 AA to 3.3V Operation
In designs that operate only from 2 AA cells, the main
DC-to-DC can be configured as a boost converter (SUSD
= PVM) to maximize the 3.3V efficiency (Figure 2).
______________________________________________________________________________________
15
MAX1566/MAX1567
Detailed Description
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
VBATT
C16
10µF
C15
10µF
1 Li+
2.8V TO
4.2V
AUX1
PWM
L1
1.4µH
C1
1µF
D1
L2
1.2µH
OUTSU
MAX1567
D6
R11
1MΩ
N2
FB1
DL3
R1
1MΩ
INDL2
DL2
D2–D5
LEDS
C2
0.1µF
R3
10Ω
VSU
D7
AUX3
PWM
AUX2
INVERTING
PWM
FB3L
R12
90.9kΩ
TO VBATT
L3
22µH
P1
FB3H
R2
90.9kΩ
15V
20mA
DL1
OUTSU
N1
C18
1µF
R13
549kΩ
FB2
TO REF
R14
90.9kΩ
AUX1OK
TO
VBATT
REF
PV
R4
47kΩ
-7.5V
40mA
C17
1µF
C10
47µF
PVSU
OSC
C3
100pF
ONSU
ONM
D8
CURRENTMODE
STEP-UP
PWM
LXSU
ON3 (LED)
R16
90.9kΩ
FBSU
ON1
ON2
SUSD
R15
274kΩ
L4
10µH
PGSU
ONSD
VSU
+5V
500mA
SCF
OK
PWR ON
OR FAULT
PVM
CCSU
R5
CCSD
R6
CCM
C4
R7
CURRENTMODE UP
OR DOWN
PWM
LXM
CC3
PGM
C5
R8
CC1
C11
10µF
C12
22µF
R17
150kΩ
VM
+3.3V
200mA
R18
90.9kΩ
FBM
C6
R9
L5
10µH
CC2
C7
PVSD
R10
C8
C9
GND
CURRENTMODE
STEPDOWN
PWM
LXSD
L6
5.6µH
TO
C13 BATT
10µF
C14
22µF
R19
40.2kΩ
VSD
+1.8V
350mA
FBSD
SDOK
PGSD
R20
90.9kΩ
Figure 1. Typical 1-Cell Li+ Powered System (3.3V logic is stepped down from +5V, and 1.8V core is stepped down directly from the
battery. Alternate connections are shown in the following figures.)
16
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
C16
10µF
C15
10µF
2 AA
1.5V TO
3.4V
L2
1.2µH
AUX1
PWM
L1
1.4µH
D1
D6
R11
1MΩ
N2
INDL2
TO VSU
L3
22µH
P1
DL2
FB3H
D2–D5
LEDS
VSU
AUX2
INVERTING
PWM
FB3L
C2
0.1µF
R3
10Ω
D7
AUX3
PWM
R2
90.9kΩ
R12
90.9kΩ
FB1
DL3
R1
1MΩ
15V
20mA
DL1
OUTSU
N1
C18
1µF
OUTSU
MAX1567
C1
1µF
FB2
TO REF
R14
90.9kΩ
AUX1OK
TO
VBATT
REF
R4
47kΩ
-7.5V
40mA
C17
1µF
R13
549kΩ
PV
C10
47µF
PVSU
OSC
C3
100pF
ONSU
ONM
D8
CURRENTMODE
STEP-UP
PWM
LXSU
ON3 (LED)
R16
90.9kΩ
FBSU
ON1
ON2
SUSD
SCF
OK
TO
VBATT
PWR ON
OR FAULT
PVM
CCSU
R5
CCSD
R6
CCM
C4
R7
CURRENTMODE UP
OR DOWN
PWM
LXM
CC3
PGM
CC1
C21
47µF
VM
+3.3V
500mA
R17
150kΩ
R18
90.9kΩ
FBM
C6
R9
L5
3.3µH
C11
10µF
C12
10µF
C5
R8
VSU
+5V
350mA
R15
274kΩ
L4
4.7µH
PGSU
ONSD
TO VSU
MAX1566/MAX1567
VBATT
CC2
C7
PVSD
R10
C8
C9
GND
CURRENTMODE
STEPDOWN
PWM
LXSD
L6
10µH
TO
C13 VM
10µF
C14
47µF
R19
40.2kΩ
VSD
+1.8V
250mA
FBSD
SDOK
PGSD
R20
90.9kΩ
Figure 2. Typical 2-Cell AA-Powered System (3.3V is boosted from the battery and 1.8V is stepped down from VM (3.3V).)
______________________________________________________________________________________
17
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
VBATT
C16
10µF
C15
10µF
2 AA OR Li+
1.5V TO
4.2V
L2
1.2µH
AUX1
PWM
L1
1.4µH
C1
1µF
D1
D6
R11
1MΩ
N2
FB1
DL3
R1
1MΩ
INDL2
DL2
D2–D5
LEDS
C2
0.1µF
R3
10Ω
VSU
D7
AUX3
PWM
AUX2
INVERTING
PWM
FB3L
R12
90.9kΩ
TO VSU
L3
22µH
P1
FB3H
R2
90.9kΩ
15V
20mA
DL1
OUTSU
N1
C18
1µF
OUTSU
MAX1567
R13
549kΩ
FB2
TO REF
R14
90.9kΩ
AUX1OK
TO
VBATT
REF
PV
R4
47kΩ
-7.5V
40mA
C17
1µF
C10
47µF
PVSU
OSC
C3
100pF
ONSU
ONM
D8
CURRENTMODE
STEP-UP
PWM
LXSU
ON3 (LED)
R16
90.9kΩ
FBSU
ON1
ON2
SUSD
R15
274kΩ
L4
4.7µH
PGSU
ONSD
VSU
+5V
100mA
SCF
OK
PWR ON
OR FAULT
PVM
CCSU
R5
CCSD
R6
CCM
C4
R7
CURRENTMODE UP
OR DOWN
PWM
LXM
CC3
PGM
C5
R8
CC1
C11
10µF
C12
22µF
R17
150kΩ
VM
+3.3V
200mA
R18
90.9kΩ
FBM
C6
R9
L5
10µH
CC2
C7
PVSD
R10
C8
C9
GND
CURRENTMODE
STEPDOWN
PWM
LXSD
L6
10µH
TO
C13 BATT
10µF
C14
22µF
R19
40.2kΩ
VSD
+1.8V
200mA
FBSD
SDOK
PGSD
R20
90.9kΩ
Figure 3. Li+ or Multibattery Input (This power supply accepts inputs from 1.5V to 4.2V, so it can operate from either 2 AA cells or 1
Li+ cell. The 3.3V logic supply and the 1.8V core supply are both stepped down from 5V for true boost-buck operation.)
18
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAX1566/MAX1567
INTERNAL
POWEROK
VSU
NORMAL
MODE
STARTUP
OSCILLATOR
2.35V
ONSU
VREF
REFOK
DIE OVER
TEMP
1V
MAX1566
ONSU
FLTALL
100,000CLOCK-CYCLE
FAULT TIMER
FAULT
IN
TO INTERNAL
POWER
CLK
PV
OSC
REF
1.25V
REFERENCE
REF
300ns
ONE-SHOT
GND
CCSU
PVSU
FBSU
FAULT
STEP-UP
SOFT-START TIMER
DONE
(SUSSD)
SOFT-START
RAMP
GENERATOR
CURRENTMODE
DC-TO-DC
STEP-UP
LXSU
TO
VREF
PGSU
ONSU
FLTALL
CCSD
PVSD
FBSD
FAULT
SOFT-START
RAMP
GENERATOR
ONSD
CURRENTMODE
DC-TO-DC
STEP-DOWN
LXSD
TO
VREF
PGND
SUSSD
FLTALL
SUSD
SDOK
PVM
CC_
FAULT
CURRENTMODE
DC-TO-DC
STEP-DOWN
OR
STEP-UP
FB_
SOFT-START
RAMP
GENERATOR
TO
VREF
FAULT
1 OF 3
VOLTAGE-MODE
DC-TO-DC
CONTROLLERS
AUX_
FLTALL
SUSSD
LXM
PGM
FBM
ON_
SUSSD
FLTALL
DL_
TO VREF
CLK
SOFT-START
RAMP
GENERATOR
ONM
AUX1OK
Figure 4. MAX1566 Functional Diagram
______________________________________________________________________________________
19
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
Core Step-Down DC-to-DC Converter
The step-down DC-to-DC is optimized for generating low
output voltages (down to 1.25V) at high efficiency. The
step-down runs from the voltage at PVSD. This pin can
be connected directly to the battery if sufficient headroom exists to avoid dropout; otherwise, PVSD can be
powered from the output of another converter. The stepdown can also operate with the step-up, or the main converter in step-up mode, for boost-buck operation.
Under moderate to heavy loading, the converter operates in a low-noise PWM mode with constant frequency
and modulated pulse width. Efficiency is enhanced
under light (<75mA typ) loading by assuming an Idle
Mode during which the step-down switches only as
needed to service the load. In this mode, the maximum
inductor current is 100mA for each pulse. The stepdown DC-to-DC is inactive until the step-up DC-to-DC
is in regulation.
The step-down also features an open-drain SDOK output that goes low when the step-down output is in regulation. SDOK can be used to drive an external MOSFET
switch that gates 3.3V power to the processor after the
core voltage is in regulation. This connection is shown
in Figure 15.
AUX1, AUX2, and AUX3 DC-to-DC
Controllers
The three auxiliary controllers operate as fixed-frequency voltage-mode PWM controllers. They do not have
internal MOSFETs, so output power is determined by
external components. The controllers regulate output
voltage by modulating the pulse width of the DL_ drive
signal to an external MOSFET switch.
On the MAX1566, AUX1 and AUX2 are boost/flyback
PWM controllers. On the MAX1567, AUX1 is a boost/flyback PWM controller, but AUX2 is an inverting PWM
controller. On both devices, AUX3 is a boost/flyback
controller that can be connected to regulate output voltage and/or current (for white-LED drive).
Figure 5 shows a functional diagram of an AUX boost
controller channel. A sawtooth oscillator signal at OSC
governs timing. At the start of each cycle, DL_ goes high,
turning on the external NFET switch. The switch then
turns off when the internally level-shifted sawtooth rises
above CC_ or when the maximum duty cycle is exceeded. The switch remains off until the start of the next cycle.
A transconductance error amplifier forms an integrator at
CC_ to maintain high DC loop gain and accuracy.
20
The auxiliary controllers do not start until 1024 OSC
cycles after the step-up DC-to-DC output is in regulation. If the auxiliary controller remains faulted for
100,000 OSC cycles (200ms at 500kHz), then all
MAX1566/MAX1567 channels latch off.
Maximum Duty Cycle
The AUX PWM controllers have a guaranteed maximum
duty cycle of 80%: all controllers can achieve at least
80% and typically reach 85%. In boost designs that
employ continuous current, the maximum duty cycle
limits the boost ratio so:
1 - VIN / VOUT < 80%
With discontinuous inductor current, no such limit exists
for the input/output ratio since the inductor has time to
fully discharge before the next cycle begins.
AUX1
AUX1 can be used for conventional DC-to-DC boost
and flyback designs (Figures 8 and 9). Its output (DL1)
is designed to drive an N-channel MOSFET. Its feedback (FB1) threshold is 1.25V.
AUX2
In the MAX1566, AUX2 is identical to AUX1. In the
MAX1567, AUX2 is an inverting controller that generates a regulated negative output voltage, typically for
CCD and LCD bias. This is useful in height-limited
designs where transformers may not be desired.
The AUX2 MOSFET driver (DL2) in the MAX1567 is
designed to drive P-channel MOSFETs. INDL2 biases
the driver so VINDL2 is the high output level of DL2.
INDL2 should be connected to the P-channel MOSFET
source to ensure the MOSFET turns completely off when
DL2 is high. See Figure 10 for a typical inverter circuit.
AUX3 DC-to-DC Controller, LED Driver
The AUX3 step-up DC-to-DC controller has two feedback inputs, FB3L and FB3H, with feedback thresholds
of 0.2V (FB3L) and 1.25V (FB3H). If used as a conventional voltage-output step-up, FB3L is grounded and
FB3H is used as the feedback input. In that case, AUX3
behaves exactly like AUX1.
If AUX3 is used as a switch-mode boost current source
for white LEDs, FB3L provides current-sensing feedback, while FB3H provides (optional) open-LED overvoltage protection (Figure 7).
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAX1566/MAX1567
FB2
CC2
R
Q
DL_
LEVEL SHIFT
S
REFI
SOFT-START
REF
0.85 REF
MAX1567
AUX2 INVERTER
CLK
OSC
FAULT PROTECTION
ENABLE
FB
CC
R
Q
DL_
LEVEL SHIFT
S
REFI
SOFT-START
REF
0.85 REF
MAX1566/MAX1567
AUX_ BOOST
CLK
OSC
FAULT PROTECTION
ENABLE
IN 1024 CLOCK CYCLES, SOFT-START
RAMPS UP REFI FROM 0V TO VREF IN
MAX1566/MAX1567 AUX_ BOOST
CONTROLLERS AND RAMPS DOWN
REFI FROM VREF TO 0V IN
MAX1567 AUX2 INVERTER.
Figure 5. AUX Controller Functional Diagram
______________________________________________________________________________________
21
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
VSU
MAX1566
MAX1567
(PARTIAL)
ROSC
TO
VBATT
AUX
PWM
OSC
VREF
(1.25V)
COSC
PVSU
Q1
+15V
50mA
LCD
D6
DL_
150ns
ONE-SHOT
FB_
MAX1566
MAX1567
Figure 6. Oscillator Functional Diagram
TO
VBATT
Figure 8. +15V LCD Bias with Basic Boost Topology
MAX1566
MAX1567
(PARTIAL)
PVSU
DL3
FB3H
(1.25V)
AUX3
PWM
D2–D5
LEDS
TO
VBATT
+15V
50mA
CCD+
MAX1566
MAX1567
(PARTIAL)
AUX
PWM
R1
R2
NOTE: THIS CIRCUIT CAN OPERATE WITH AUX1, AUX2,
OR AUX3 ON THE MAX1566, AND WITH AUX1 OR AUX3 ON
THE MAX1567. TO USE AUX3, FB3L = GND, AND
FB3H IS USED FOR FEEDBACK.
FB3L
(0.2V)
PVSU
Q1
D2
DL_
-7.5V
30mA
CCD-
FB_
R3
NOTE: IF OPEN LED PROTECTION IS NOT
REQUIRED, REMOVE R2 AND R3 AND GROUND FB3H.
Figure 7. LED drive with open LED overvoltage protection is
provided by the additional feedback input to AUX3, FB3H.
Master-Slave Configurations
The MAX1566/MAX1567 support MAX1801 slave PWM
controllers that obtain input power, a voltage reference,
and an oscillator signal directly from the MAX1566/
MAX1567 master. The master-slave configuration allows
channels to be easily added and minimizes system cost
by eliminating redundant circuitry. The slaves also control the harmonic content of noise because their operating frequency is synchronized to that of the MAX1566/
22
NOTE: THIS CIRCUIT CAN OPERATE WITH AUX1, AUX2,
OR AUX3 ON THE MAX1566, AND WITH AUX1 OR AUX3 ON
THE MAX1567. TO USE AUX3, FB3L = GND, AND
FB3H IS USED FOR FEEDBACK.
Figure 9. +15V and -7.5V CCD Bias with Transformer
MAX1567 master converter. A MAX1801 connection to
the MAX1566/MAX1567 is shown in Figure 14.
Status Outputs (SDOK, AUX1OK, SCF)
The MAX1566/MAX1567 include three versatile status
outputs that can provide information to the system. All
are open-drain outputs and can directly drive MOSFET
switches to facilitate sequencing, disconnect loads
during overloads, or perform other hardware-based
functions.
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
+15V
20mA
TO VBATT
TO VBATT
INDL2
DL2
FB_
AUX_
PWM
-7.5V
100mA
AUX2
INVERTING
PWM
PVSU
RTOP
-7.5V
20mA
DL_
FB2
RREF
REF
MAX1566/MAX1567
(PARTIAL)
Figure 10. Regulated -7.5V Negative CCD (Bias is provided by
conventional inverter (works only with the MAX1567).)
IN
SHDN
GND
L1
10µH
D2
TO VBATT
VOUT+
+15V
20mA
C2
1µF
1µF
OUT
R1
1MΩ
FB_
FB_
AUX_
PWM
+1.25V
PVSU
Q1
DL_
C1
1µF
D1
R2
90.9kΩ
D3
VOUT-15V
C3 10mA
1µF
MAX1616
NOTE: THIS CIRCUIT CAN OPERATE WITH AUX1, AUX2, OR AUX3 ON THE MAX1566,
AND WITH AUX1 OR AUX3 ON THE MAX1567. TO USE AUX3, FB3L = GND,
AND FB3H IS USED FOR FEEDBACK.
MAX1566
MAX1567
(PARTIAL)
Figure 11. ±15V Output Using an AUX-Driven Boost with
Charge-Pump Inversion
SDOK pulls low when the step-down has successfully
completed soft-start. SDOK goes high impedance in
shutdown, overload, and thermal limit. A typical use for
SDOK is to drive a P-channel MOSFET that connects
3.3V power to the CPU I/O after the CPU core is powered up (Figure 15), thus providing safe sequencing in
hardware without system intervention.
AUX1OK pulls low when the AUX1 controller has successfully completed soft-start. AUX1OK goes high
impedance in shutdown, overload, and thermal limit. A
typical use for AUX1OK is to drive a P-channel MOSFET
Figure 12. +15V and -7.5V CCD Bias Without Transformer
Using Boost with a Diode-Capacitor Charge Pump (A positiveoutput linear regulator (MAX1616) can be used to regulate the
negative output of the charge pump.)
that connects 5V power to the CCD after the 15V CCD
bias (generated by AUX1) is powered up (Figure 16).
SCF goes high (high impedance, open drain) when
overload protection occurs. Under normal operation,
SCF pulls low. SCF can drive a high-side P-channel
MOSFET switch that can disconnect a load during
power-up or when a channel turns off in response to a
logic command or an overload. Several connections
are possible for SCF. One is shown in Figure 17 where
SCF provides load disconnect for the step-up on fault
and power-up.
______________________________________________________________________________________
23
MAX1566/MAX1567
MAX1567
(PARTIAL)
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
INPUT
1-CELL
Li+
TO BATT
VSU
L2
L1
PVSU
VOUT
D1
PV
DL_
PART OF
MAX1566
MAX1567
(PARTIAL)
DL
OUTPUT
3.3V
PVSU
MAX1801 OSC
C2
Q1
IN
OSC
MAX1566
MAX1567
(PARTIAL)
FB
R1
COMP
REF
GND
REF
DCON
FB_
R2
Figure 14. Adding a PWM Channel with an External MAX1801
Slave Controller
Figure 13. SEPIC Converter Additional Boost-Buck Channel
MAX1566
MAX1567
(PARTIAL)
SUSD
PVM
CURRENTMODE UP
OR DOWN
PWM
LXM
L3
VM
+3.3V
3.3V
TO
CPU
PGM
FBM
SDOK
PVSD
CURRENTMODE
STEPDOWN
PWM
LXSD
TO
VBATT
L4
VSD
+1.8V
350mA
FBSD
PGSD
Figure 15. Using SDOK to Drive External PFET that Gates 3.3V Power to CPU After 1.8V Core Voltage Is in Regulation
24
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
MAX1566/MAX1567
TO
VBATT
MAX1566
MAX1567
(PARTIAL)
PVSU
AUX1
PWM
DL1
D6
15V
100mA
FB1
AUX1OK
PV
PVSU
TO
VBATT
CURRENTMODE
STEP-UP
PWM
LXSU
GATED +5V
TO CCD
VSU
+5V
L2
PGSU
FBSU
Figure 16. AUX1OK Drives an External PFET that Gates 5V Supply to the CCD After the +15V CCD Bias Supply Is Up
Soft-Start
The MAX1566/MAX1567 channels feature a soft-start
function that limits inrush current and prevents excessive battery loading at startup by ramping the output
voltage of each channel up to the regulation voltage.
This is accomplished by ramping the internal reference
inputs to each channel error amplifier from 0V to the
1.25V reference voltage over a period of 4096 oscillator
cycles (16ms at 500kHz) when initial power is applied
or when a channel is enabled.
The step-down soft-start ramp takes half the time (2048
clock cycles) of the other channel ramps. This allows
the step-down and main outputs to track each other
and rise at nearly the same dV/dt rate on power-up.
Once the step-down output reaches its regulation point
(1.5V or 1.8V typ), the main output (3.3V typ) continues
to rise at the same ramp rate. See the Typical
Operating Characteristics Main and Step-Down Startup
Waveforms graphs.
Soft-start is not included in the step-up converter to
avoid limiting startup capability with loading.
Fault Protection
The MAX1566/MAX1567 have robust fault and overload
protection. After power-up, the device is set to detect
an out-of-regulation state that could be caused by an
overload or short. If any DC-to-DC converter channel
(step-up, main, step-down, or any of the auxiliary controllers) remains faulted for 100,000 clock cycles
(200ms at 500kHz), then all outputs latch off until the
step-up DC-to-DC converter is reinitialized by the
ONSU pin or by cycling the input power. The faultdetection circuitry for any channel is disabled during its
initial turn-on soft-start sequence.
An exception to the standard fault behavior is that there
is no 100,000 clock cycle delay in entering the fault
state if the step-up output (PVSU) is dragged below its
2.5V UVLO threshold or is shorted. In this case, the
______________________________________________________________________________________
25
MAX1566/MAX1567
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
step-up UVLO immediately triggers and shuts down all
channels. The step-up then continues to attempt starting. If the step-up output short remains, these attempts
cannot succeed since PVSU remains near ground.
If a soft-short or overload remains on PVSU, the startup
oscillator switches the internal N-channel MOSFET, but
fault is retriggered if regulation is not achieved by the
end of the soft-start interval. If PVSU is dragged below
the input, the overload is supplied by the body diode of
the internal synchronous rectifier, or by a Schottky
diode connected from the battery to PVSU. If desired,
this overload current can be interrupted by a P-channel
MOSFET controlled by SCF, as shown in Figure 17.
MAX1566
MAX1567
(PARTIAL)
PV
PVSU
VSU
+5V
TO
VBATT
CURRENT-MODE
STEP-UP
PWM
L2
LXSU
PGSU
FBSD
SCF
Reference
The MAX1566/MAX1567 has a precise 1.250V reference. Connect a 0.1µF ceramic bypass capacitor from
REF to GND within 0.2in (5mm) of the REF pin. REF can
source up to 200µA and is enabled whenever ONSU is
high and PVSU is above 2.5V. The auxiliary controllers
and MAX1801 slave controllers (if connected) each sink
up to 30µA REF current during startup. In addition, the
feedback network for the AUX2 inverter (MAX1567) also
draws current from REF. If the 200µA REF load limit
must be exceeded, buffer REF with an external op amp.
Oscillator
All DC-to-DC converter channels employ fixed-frequency
PWM operation. The operating frequency is set by an RC
network at the OSC pin. The range of usable settings is
100kHz to 1MHz. When MAX1801 slave controllers are
added, they operate at the frequency set by OSC.
The oscillator uses a comparator, a 150ns one-shot, and
an internal NFET switch in conjunction with an external
timing resistor and capacitor (Figure 6). When the switch
is open, the capacitor voltage exponentially approaches
the step-up output voltage from zero with a time constant
given by the product of ROSC and COSC. The comparator output switches high when the capacitor voltage
reaches VREF (1.25V). In turn, the one-shot activates the
internal MOSFET switch to discharge the capacitor for
150ns, and the cycle repeats. The oscillation frequency
changes as the main output voltage ramps upward following startup. The oscillation frequency is then constant
once the main output is in regulation.
Low-Voltage Startup Oscillator
The MAX1566/MAX1567 internal control and referencevoltage circuitry receive power from PVSU and do not
function when PVSU is less than 2.5V. To ensure lowvoltage startup, the step-up employs a low-voltage
startup oscillator that activates at 0.9V if a Schottky rectifier is connected from VBATT to PVSU (1.1V with no
26
OK
PWR ON
OR FAULT
Figure 17. SCF Drives PFET Load Switch on 5V to Disconnect
Load on Fault and Allow Full-Load Startup
VSU
3.3V
PVSU
PV
MAX1566
MAX1567
(PARTIAL)
PVSD
10µF
LXSD
CURRENT-MODE
STEP-DOWN
4.7µH
VSD
0.8V
22µF
PGSD
FBSD
R3
100kΩ
VFBSD
1.25V
R1
56kΩ
R2
100kΩ
Figure 18. Setting PVSD for Outputs Below 1.25V
Schottky rectifier). The startup oscillator drives the internal N-channel MOSFET at LXSU until PVSU reaches
2.5V, at which point voltage control is passed to the
current-mode PWM circuitry.
Once in regulation, the MAX1566/MAX1567 operate
with inputs as low as 0.7V since internal power for the
IC is supplied by PVSU. At low input voltages, the step-
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
Shutdown
The step-up converter is activated with a high input at
ONSU. The main converter (step-up or step-down) is activated by a high input on ONM. The step-down and auxiliary DC-to-DC converters 1, 2, and 3 activate with high
inputs at ONSD, ON1, ON2, and ON3, respectively. The
step-down, main, and AUX_ converters cannot be activated until PVSU is in regulation. For automatic startup, connect ON_ to PVSU or a logic level greater than 1.6V.
Design Procedure
Setting the Switching Frequency
Choose a switching frequency to optimize external
component size or circuit efficiency for the particular
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 as follows:
t1 = -ROSC x COSC x In(1 - 1.25 / VPVSU)
The capacitor voltage then decays to zero over time, t2
= 150ns. The oscillator frequency is as follows:
fOSC = 1 / (t1 + t2)
fOSC can be set from 100kHz to 1MHz. Choose COSC
between 22pF and 470pF. Determine ROSC:
ROSC = (150ns - 1 / fOSC) / (COSC ln[1 - 1.25 / VPVSU])
See the Typical Operating Characteristics for fOSC vs.
ROSC using different values of COSC.
Setting Output Voltages
All MAX1566/MAX1567 output voltages are resistor set.
The FB_ threshold is 1.25V for all channels except for
FB3L (0.2V) on both devices and FB2 (inverter) on the
MAX1567. When setting the voltage for any channel
except the MAX1567 AUX2, connect a resistive voltage-divider from the channel output to the corresponding FB_ input and then to GND. The FB_ input bias
current is less than 100nA, so choose the bottom-side
(FB_-to-GND) resistor to be 100kΩ or less. Then calculate the top-side (output-to-FB_) resistor:
RTOP = RBOTTOM[(VOUT / 1.25) - 1]
When using AUX3 to drive white LEDs (Figure 7), select
the LED current-setting resistor (R3, Figure 7) using the
following formula:
R3 = 0.2V / ILED
The FB2 threshold on the MAX1567 is 0V. To set the
AUX2 negative output voltage, connect a resistive voltage-divider from the negative output to the FB2 input,
and then to REF. The FB2 input bias current is less than
100nA, so choose the REF-side (FB2-to-REF) resistor
(RREF) to be 100kΩ or less. Then calculate the top-side
(output-to-FB2) resistor:
RTOP = RREF(-VOUT(AUX2) / 1.25)
General Filter Capacitor Selection
The input capacitor in a DC-to-DC converter reduces
current peaks drawn from the battery or other 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
input source so high-frequency switching currents do
not pass through the input source.
The output capacitor keeps output ripple small and
ensures control-loop stability. The output capacitor must
also have low impedance at the switching frequency.
Ceramic, polymer, and tantalum capacitors are suitable,
with ceramic exhibiting the lowest ESR and high-frequency impedance.
Output ripple with a ceramic output capacitor is
approximately as follows:
VRIPPLE = IL(PEAK)[1 / (2π x fOSC x COUT)]
If the capacitor has significant ESR, the output ripple
component due to capacitor ESR is as follows:
VRIPPLE(ESR) = IL(PEAK) x ESR
Output capacitor specifics are also discussed in each
converter’s Compensation section.
Step-Up Component Selection
This section describes component selection for the
step-up, as well as for the main, if SUSD = PV.
The external components required for the step-up are
an inductor, an input and output filter capacitor, and a
compensation RC.
The inductor is typically selected to operate with continuous current for best efficiency. An exception might be
if the step-up ratio, (VOUT / VIN), is greater than 1 / (1 DMAX), where DMAX is the maximum PWM duty factor
of 80%.
When using the step-up channel to boost from a low
input voltage, loaded startup is aided by connecting a
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27
MAX1566/MAX1567
up may have difficulty starting into heavy loads (see the
Minimum Startup Voltage vs. Load Current (OUTSU)
graph in the Typical Operating Characteristics); however,
this can be remedied by connecting an external Pchannel load switch driven by SCF so the load is not
connected until the PVSU is in regulation (Figure 17).
MAX1566/MAX1567
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Schottky diode from the battery to PVSU. See the
Minimum Startup Voltage vs. Load Current graph in the
Typical Operating Characteristics.
Step-Up Inductor
In most step-up designs, a reasonable inductor value
(LIDEAL) can be derived from the following equation,
which sets continuous peak-to-peak inductor current at
1/2 the DC inductor current:
LIDEAL = [2VIN(MAX) x D(1 - D)] / (IOUT x fOSC)
where D is the duty factor given by:
D = 1 - (VIN / VOUT)
Given LIDEAL, the consistent peak-to-peak inductor current is 0.5 IOUT / (1 - D). The peak inductor current,
IIND(PK) = 1.25 IOUT / (1 - D).
Inductance values smaller than LIDEAL can be used to
reduce inductor size; however, if much smaller values
are used, inductor current rises and a larger output
capacitance may be required to suppress output ripple.
2) Select RC based on the allowed load-step transient.
RC sets a voltage delta on the CC pin that corresponds to load-current step.
3) Calculate the output-filter capacitor (COUT) required
to allow the RC and CC selected.
4) Determine if C P is required (if calculated to be
>10pF).
For continuous conduction, the right-half-plane zero frequency (fRHPZ) is given by the following:
fRHPZ = VOUT(1 - D)2 / (2π x L x ILOAD)
where D = the duty cycle = 1 - (VIN / VOUT), L is the
inductor value, and ILOAD is the maximum output current. Typically target crossover (fC) for 1/6 of the RHPZ.
For example, if we assume fOSC = 500kHz, VIN = 2.5V,
VOUT = 5V, and IOUT = 0.5A, then RLOAD = 10Ω. If we
select L = 4.7µH, then:
fRHPZ = 5 (2.5 / 5)2 / (2π x 4.7 x 10-6 x 0.5) = 84.65kHz
Choose fC = 14kHz. Calculate CC:
Step-Up Compensation
The inductor and output capacitor are usually chosen
first in consideration of performance, size, and cost. The
compensation resistor and capacitor are then chosen to
optimize control-loop stability. In some cases, it may
help to readjust the inductor or output-capacitor value to
get optimum results. For typical designs, the component
values in the circuit of Figure 1 yield good results.
The step-up converter employs current-mode control,
thereby simplifying the control-loop compensation.
When the converter operates with continuous inductor
current (typically the case), a right-half-plane zero
appears in the loop-gain frequency response. To
ensure stability, the control-loop gain should cross over
(drop below unity gain) at a frequency (fC) much less
than that of the right-half-plane zero.
CC = (VFB / VOUT)(RLOAD / RCS)(gm / 2π x fC)(1 - D)
= (1.25 / 5)(10 / 0.3) x [135µS / (6.28 x 14kHz)] (2/5)
= 6.4nF
Choose 6.8nF.
The relevant characteristics for step-up channel compensation are as follows:
So, for a 500mA output load step with VIN = 2.5V and
VOUT = 5V:
RC = [1.25(0.3 x 0.5 x 5) / 2)] / 6.75µA = 69.4kΩ
Note that the inductor does not limit the response in this
case since it can ramp at 2.5V / 4.7µH, or 530mA/µs.
The output filter capacitor is then chosen so the COUT
RLOAD pole cancels the RC CC zero:
COUT x RLOAD = RC x CC
For the example:
COUT = 68kΩ x 6.8nF / 10Ω = 46µF
Choose 47µF for COUT. If the available COUT is substantially different from the calculated value, insert the
available C OUT value into the above equation and
• Transconductance (from FB to CC), gmEA (135µS)
• Current-sense amplifier transresistance, R CS
(0.3V/A)
• Feedback regulation voltage, VFB (1.25V)
• Step-up output voltage, VSU, in V
• Output load equivalent resistance, RLOAD, in Ω =
VOUT / ILOAD
The key steps for step-up compensation are as follows:
1) Place fC sufficiently below the right-half-plane zero
(RHPZ) and calculate CC.
28
Now select R C so transient-droop requirements are
met. As an example, if 4% transient droop is allowed,
the input to the error amplifier moves 0.04 x 1.25V, or
50mV. The error-amp output drives 50mV x 135µS, or
6.75µA, across RC to provide transient gain. Since the
current-sense transresistance is 0.3V/A, the value of RC
that allows the required load-step swing is as follows:
RC = 0.3 IIND(PK) / 6.75µA
In a step-up DC-to-DC converter, if LIDEAL is used, output current relates to inductor current by:
IIND(PK) = 1.25 IOUT / (1 - D) = 1.25 IOUT x VOUT / VIN
______________________________________________________________________________________
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If CP is calculated to be <10pF, it can be omitted.
Step-Down Component Selection
This section describes component selection for the
step-down converter, and for the main converter if used
in step-down mode (SUSD = GND).
Step-Down Inductor
The external components required for the step-down
are an inductor, input and output filter capacitors, and
compensation RC network.
The MAX1566/MAX1567 step-down converter provides
best efficiency with continuous inductor current. A reasonable inductor value (LIDEAL) can be derived from
the following:
LIDEAL = [2(VIN) x D(1 - D)] / IOUT x fOSC
This sets the peak-to-peak inductor current at 1/2 the
DC inductor current. D is the duty cycle:
D = VOUT / VIN
Given LIDEAL, the peak-to-peak inductor current is 0.5
IOUT. The absolute-peak inductor current is 1.25 IOUT.
Inductance values smaller than LIDEAL can be used to
reduce inductor size; however, if much smaller values are
used, inductor current rises, and a larger output capacitance may be required to suppress output ripple. Larger
values than LIDEAL can be used to obtain higher output
current, but typically with larger inductor size.
Step-Down Compensation
The relevant characteristics for step-down compensation are as follows:
• Transconductance (from FB to CC), gmEA (135µS)
• Step-down slope-compensation pole, PSLOPE = VIN /
(πL)
• Current-sense amplifier transresistance, R CS
(0.6V/A)
• Feedback-regulation voltage, VFB (1.25V)
• Output-load equivalent resistance, RLOAD, in Ω =
VOUT / ILOAD
The key steps for step-down compensation are
as follows:
1) Set the compensation RC to zero to cancel the
RLOAD COUT pole.
2) Set the loop crossover below the lower of 1/5 the
slope compensation pole or 1/5 the switching
frequency.
If we assume VIN = 2.5V, VOUT = 1.8V, and IOUT =
350mA, then RLOAD = 5.14Ω.
If we select fOSC = 500kHz and L = 5.6µH.
PSLOPE = VIN / (πL) = 142kHz, so choose fC = 24kHz
and calculate CC:
CC = (VFB / VOUT)(RLOAD / RCS)(gm / 2π x fC)
= (1.25 / 1.8)(5.14 / 0.6) x [135µS / (6.28 x 24kHz)]
= 6.4nF
Choose 6.8nF.
Now select R C so transient-droop requirements are
met. As an example, if 4% transient droop is allowed,
the input to the error amplifier moves 0.04 x 1.25V, or
50mV. The error-amp output drives 50mV x 135µS, or
6.75µA across RC to provide transient gain. Since the
current-sense transresistance is 0.6V/A, the value of RC
that allows the required load-step swing is as follows:
RC = 0.6 IIND(PK) / 6.75µA
In a step-down DC-to-DC converter, if LIDEAL is used,
output current relates to inductor current by the following:
IIND(PK) = 1.25 IOUT
So for a 250mA output load step with VIN = 2.5V and
VOUT = 1.8V:
RC = (1.25 x 0.6 x 0.25) / 6.75µA = 27.8kΩ
Choose 27kΩ.
Note that the inductor does somewhat limit the response
in this case since it ramps at (VIN - VOUT) / 5.6µH, or
(2.5 - 1.8) / 5.6µH = 125mA/µs.
The output filter capacitor is then chosen so the COUT
RLOAD pole cancels the RC CC zero:
COUT x RLOAD = RC x CC
For the example:
COUT = 27kΩ x 6.8nF / 5.14Ω = 35.7µF
Since ceramic capacitors are common in either 22µF or
47µF values, 22µF is within a factor of two of the ideal value
and still provides adequate phase margin for stability.
• Step-down output voltage, VSD, in V
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29
MAX1566/MAX1567
recalculate RC. Higher substituted COUT values allow a
higher RC, which provides higher transient gain and
consequently less transient droop.
If the output filter capacitor has significant ESR, a zero
occurs at the following:
ZESR = 1 / (2π x COUT x RESR)
If ZESR > fC, it can be ignored, as is typically the case
with ceramic output capacitors. If ZESR is less than fC,
it should be cancelled with a pole set by capacitor CP
connected from CC to GND:
CP = COUT x RESR / RC
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If the output filter capacitor has significant ESR, a zero
occurs at the following:
ZESR = 1 / (2π x COUT x RESR)
If ZESR > fC, it can be ignored, as is typically the case
with ceramic output capacitors. If ZESR < fC, it should
be cancelled with a pole set by capacitor CP connected from CC to GND:
CP = COUT x RESR / RC
Diode
For most AUX applications, a Schottky diode rectifies
the output voltage. Schottky low forward voltage and
fast recovery time provide the best performance in
most applications. Silicon signal diodes (such as
1N4148) are sometimes adequate in low-current
(<10mA), high-voltage (>10V) output circuits where the
output voltage is large compared to the diode forward
voltage.
If CP is calculated to be <10pF, it can be omitted.
AUX Compensation
The auxiliary controllers employ voltage-mode control
to regulate their output voltage. Optimum compensation depends on whether the design uses continuous or
discontinuous inductor current.
AUX Controller Component Selection
External MOSFET
All MAX1566/MAX1567 AUX controllers drive external
logic-level MOSFETs. Significant MOSFET selection
parameters are as follows:
• On-resistance (RDS(ON))
• Maximum drain-to-source voltage (VDS(MAX))
• Total gate charge (QG)
• Reverse transfer capacitance (CRSS)
On the MAX1566, all AUX drivers are designed for Nchannel MOSFETs. On the MAX1567, AUX2 is a DC-toDC inverter, so DL2 is designed to drive a P-channel
MOSFET. In both devices, the driver outputs DL1 and
DL3 swing between PVSU and GND. MOSFET driver
DL2 swings between INDL2 and GND.
Use a MOSFET with on-resistance specified with gate
drive at or below the main output voltage. The gate
charge, QG, includes all capacitance associated with
charging the gate and helps to predict MOSFET transition time between on and off states. MOSFET power
dissipation is a combination of on-resistance and transition losses. The on-resistance loss is as follows:
PRDSON = D x IL2 x RDS(ON)
where D is the duty cycle, IL is the average inductor
current, and RDS(ON) is MOSFET on-resistance. The
transition loss is approximately as follows:
PTRANS = (VOUT x IL x fOSC x tT) / 3
where VOUT is the output voltage, IL is the average
inductor current, fOSC is the 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 (0.5A typ). The total power
dissipation in the MOSFET is as follows:
PMOSFET = PRDSON + PTRANS
30
AUX Step-Up, Discontinuous Inductor Current
When the inductor current falls to zero on each switching cycle, it is described as discontinuous. The inductor
is not utilized as efficiently as with continuous current,
but in light-load applications this often has little negative
impact since the coil losses may already be low compared to other losses. A benefit of discontinuous inductor current is more flexible loop compensation, and no
maximum duty-cycle restriction on boost ratio.
To ensure discontinuous operation, the inductor must
have a sufficiently low inductance to fully discharge on
each cycle. This occurs when:
L < [VIN2 (VOUT - VIN) / VOUT3] [RLOAD / (2fOSC)]
A discontinuous current boost has a single pole at the
following:
fP = (2VOUT - VIN) / (2π x RLOAD x COUT x VOUT)
Choose the integrator cap so the unity-gain crossover,
fC, occurs at fOSC / 10 or lower. Note that for many AUX
circuits, such as those powering motors, LEDs, or other
loads that do not require fast transient response, it is
often acceptable to overcompensate by setting fC at
fOSC / 20 or lower.
CC is then determined by the following:
CC = [2VOUT x VIN / ((2VOUT - VIN) x VRAMP)] [VOUT /
(K(VOUT - VIN))]1/2 [(VFB / VOUT)(gM / (2π x fC))]
where:
K = 2L x fOSC / RLOAD
and VRAMP is the internal slope-compensation voltage
ramp of 1.25V.
______________________________________________________________________________________
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AUX Step-Up, Continuous Inductor Current
Continuous inductor current can sometimes improve
boost efficiency by lowering the ratio between peak
inductor current and output current. It does this at the
expense of a larger inductance value that requires larger
size for a given current rating. With continuous inductorcurrent boost operation, there is a right-half-plane zero,
ZRHP, at the following:
ZRHP = (1 - D)2 x RLOAD / (2π x L)
where (1 - D) = VIN / VOUT (in a boost converter).
There is a complex pole pair at the following:
f0 = VOUT / [2π x VIN (L x COUT)1/2]
If the zero due to the output capacitance and ESR is
less than 1/10 the right-half-plane zero:
ZCOUT = 1 / (2π x COUT x RESR) < ZRHP / 10
Then choose CC so the crossover frequency fC occurs
at ZCOUT. The ESR zero provides a phase boost at
crossover:
CC = (VIN / VRAMP) (VFB / VOUT) [gM / (2π x ZCOUT)]
Choose RC to place the integrator zero, 1 / (2π x RC x
CC), at f0 to cancel one of the pole pairs:
RC = VIN(L x COUT)1/2 / (VOUT x CC)
If ZCOUT is not less than ZRHP / 10 (as is typical with
ceramic output capacitors) and continuous conduction
is required, then cross the loop over before ZRHP and f0:
fC < f0 / 10, and fC < ZRHP / 10
In that case:
CC = (VIN / VRAMP) (VFB / VOUT) (gM / (2π x fC))
Place:
1 / (2π x RC x CC) = 1 / (2π x RLOAD x COUT), so that
RC = RLOAD x COUT / CC
Or, reduce the inductor value for discontinuous operation.
MAX1567 AUX2 Inverter Compensation,
Discontinuous Inductor Current
If the load current is very low (≤40mA), discontinuous
current is preferred for simple loop compensation and
freedom from duty-cycle restrictions on the inverter
input-output ratio. To ensure discontinuous operation,
the inductor must have a sufficiently low inductance to
fully discharge on each cycle. This occurs when:
L < [VIN / (|VOUT| + VIN)]2 RLOAD / (2fOSC)
A discontinuous current inverter has a single pole at the
following:
fP = 2 / (2π x RLOAD x COUT)
Choose the integrator cap so the unity-gain crossover,
fC, occurs at fOSC / 10 or lower. Note that for many AUX
circuits that do not require fast transient response, it is
often acceptable to overcompensate by setting fC at
fOSC / 20 or lower.
CC is then determined by the following:
CC = [VIN / (K1/2 x VRAMP] [VREF / (VOUT + VREF)] [gM /
(2π x fC)]
where K = 2L x fOSC / RLOAD, and VRAMP is the internal
slope-compensation voltage ramp of 1.25V.
The CC RC zero is then used to cancel the fP pole, so:
RC = (RLOAD x COUT) / (2CC)
MAX1567 AUX2 Inverter Compensation,
Continuous Inductor Current
Continuous inductor current may be more suitable for
larger load currents (50mA or more). It improves efficiency by lowering the ratio between peak inductor current and output current. It does this at the expense of a
larger inductance value that requires larger size for a
given current rating. With continuous inductor-current
inverter operation, there is a right-half-plane zero,
ZRHP, at:
ZRHP = [(1 - D)2 / D] x RLOAD / (2π x L)
where D = |VOUT| / (|VOUT| + VIN) (in an inverter).
There is a complex pole pair at:
f0 = (1 - D) / (2π(L x C)1/2)
If the zero due to the output-capacitor capacitance and
ESR is less than 1/10 the right-half-plane zero:
ZCOUT = 1 / (2π x COUT x RESR) < ZRHP / 10
Then choose CC such that the crossover frequency fC
occurs at ZCOUT. The ESR zero provides a phase boost
at crossover:
CC = (VIN / VRAMP) [VREF / (VREF + |VOUT|)] [gM /
(2π x ZCOUT)]
Choose RC to place the integrator zero, 1 / (2π x RC x
CC), at f0 to cancel one of the pole pairs:
RC = (L x COUT)1/2 / [(1 - D) x CC]
If ZCOUT is not less than ZRHP / 10 (as is typical with
ceramic output capacitors) and continuous conduction
is required, then cross the loop over before ZRHP and f0:
fC < f0 /10, and fC < ZRHP / 10
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31
MAX1566/MAX1567
The CC RC zero is then used to cancel the fP pole, so:
RC = RLOAD x COUT x VOUT / [(2VOUT - VIN) x CC]
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In that case:
CC = (VIN / VRAMP) [VREF /
(VREF + |VOUT|)] [gM / (2π x fC)]
Place:
1 / (2π x RC x CC) = 1 / (2π x RLOAD x COUT), so that
RC = RLOAD x COUT / CC
Or, reduce the inductor value for discontinuous operation.
Applications Information
Typical Operating Circuits
Figures 1, 2, and 3 show connections for AA and Li+
battery arrangements. Figures 7–13 show various connections for the AUX1, 2, and 3 controllers. Figures 15,
16, and 17 show various connections for the SDOK,
AUX1OK, and SCF outputs.
Figure 1. Typical Operating Circuit for One Li+ Cell
In this connection, the main converter is operated as a
step-down (SUSD = GND) and is powered from PVSU.
This provides boost-buck operation for the main 3.3V
output so a regulated output is maintained over the Li+
2.7V to 4.2V cell voltage range. The compound efficiency from the battery to the 3.3V output reaches 90%.
The step-down 1.8V (core) output is powered directly
from VBATT.
The CCD and LCD voltages are generated with a transformerless design. AUX1 generates +15V for CCD positive and LCD bias. The MAX1567 AUX2 inverter
generates -7.5V for negative CCD bias. The AUX3 controller generates a regulated current for a series network of four white LEDs that backlight the LCD.
Figure 2. Typical Operating Circuit for 2 AA Cells
Figure 2 is optimized for 2-cell AA inputs (1.5V to 3.7V)
by connecting the step-down input (PVSD) to the main
output (PVM). The main 3.3V output operates directly
from the battery as a step-up (SUSD = PVSD). The 1.8V
core output now operates as a boost-buck with efficiency up to 90%. The rest of the circuit is unchanged from
Figure 1.
Figure 3. Typical Operating Circuit for 2 AA Cells
and 1-Cell Li+
The MAX1566/MAX1567 can also allow either 1-cell Li+
or 2 AA cells to power the same design. If the stepdown and main inputs are both connected to PVSU,
then both the 3.3V and 1.8V outputs operate as boostbuck converters. There is an efficiency penalty compared to stepping down VSD directly from the battery,
but that is not possible with a 1.5V input.
32
Furthermore, the cascaded boost-buck efficiency compares favorably with other boost-buck techniques.
LED, LCD, and Other Boost Applications
Any AUX channel (except for the AUX2 inverter on the
MAX1567) can be used for a wide variety of step-up
applications. These include generating 5V or some
other voltage for motor or actuator drive, generating
15V or a similar voltage for LCD bias, or generating a
step-up current source to efficiently drive a series array
of white LEDs to display backlighting. Figures 7 and 8
show examples of these applications.
Multiple-Output Flyback Circuits
Some applications require multiple voltages from a single converter channel. This is often the case when generating voltages for CCD bias or LCD power. Figure 9
shows a two-output flyback configuration with an AUX
channel. The controller drives an external MOSFET that
switches the transformer primary. Two transformer secondaries generate the output voltages. Only one positive output voltage can be fed back, so the other
voltages are set by the turns-ratio of the transformer
secondaries. The load stability of the other secondary
voltages depends on transformer leakage inductance
and winding resistance. Voltage regulation is best
when the load on the secondary that is not fed back is
small compared to the load on the one that is fed back.
Regulation also improves if the load-current range is
limited. Consult the transformer manufacturer for the
proper design for a given application.
Transformerless Inverter for Negative CCD
Bias (AUX2, MAX1567)
On the MAX1567, AUX2 is set up to drive an external Pchannel MOSFET in an inverting configuration. DL2 drives
low to turn on the MOSFET, and FB2 has inverted polarity
and a 0V threshold. This is useful for generating negative
CCD bias without a transformer, particularly with high
pixel-count cameras that have a greater negative CCD
load current. Figure 10 shows an example circuit.
Boost with Charge Pump for Positive and
Negative Outputs
Another method of producing bipolar output voltages
without a transformer is with an AUX controller and a
charge-pump circuit, as shown in Figure 11. 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 VOUT+ through D1. When the MOSFET turns on,
C1 discharges through D3, thereby charging C3 to VOUTminus the drop across D3 to create roughly the same
voltage as VOUT+ at VOUT-, but with inverted polarity.
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SEPIC Boost-Buck
The MAX1566/MAX1567s’ internal switch step-up,
main, and step-down converters can be cascaded to
make a high-efficiency boost-buck converter, but it is
sometimes desirable to build a second boost-buck
converter with an AUX_ controller.
One type of step-up/step-down converter is the SEPIC,
shown in Figure 13. Inductors L1 and L2 can be separate inductors or can be wound on a single core and
coupled like a transformer. Typically, a coupled inductor
improves efficiency since some power is transferred
through the coupling so less power passes through the
coupling capacitor (C2). Likewise, C2 should have low
ESR 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.
Adding a MAX1801 Slave
The MAX1801 is a 6-pin, SOT-slave, DC-to-DC controller
that can be connected to generate additional output voltages. It does not generate its own reference or oscillator.
Instead, it uses the reference and oscillator of the
MAX1566/MAX1567 (Figure 14). The MAX1801 controller
operation and design are similar to that of the
MAX1566/MAX1567 AUX controllers. All comments in the
AUX Controller Component Selection section also apply
to add-on MAX1801 slave controllers. For more details,
refer to the MAX1801 data sheet.
Applications for Status Outputs
The MAX1566/MAX1567 have three status outputs:
SDOK, AUX1OK, and SCF. These monitor the output of
the step-down channel, the AUX1 channel, and the status of the overload-short-circuit protection. Each output
is open drain to allow the greatest flexibility. Figures 15,
16, and 17 show some possible connections for these
outputs.
Using SDOK and AUX1OK for Power Sequencing
SDOK goes low when the step-down reaches regulation. Some microcontrollers with low-voltage cores
require that the high-voltage (3.3V) I/O rail not be powered up until the core has a valid supply. The circuit in
Figure 15 accomplishes this by driving the gate of a
PFET connected between the 3.3V output and the
processor I/O supply.
Figure 16 shows a similar application where AUX1OK
gates 5V power to the CCD only after the +15V output
is in regulation.
Alternately, power sequencing can also be implemented by connecting RC networks to delay the appropriate
converter ON_ inputs.
Using SCF for Full-Load Startup
The SCF output goes low only after the step-up reaches
regulation. It can be used to drive a P-channel MOSFET
switch that turns off the load of a selected supply in the
event of an overload. Or, it can remove the load until
the supply reaches regulation, effectively allowing fullload startup. Figure 17 shows such a connection for the
step-up output.
Setting VSD Below 1.25V
The step-down feedback voltage is 1.25V. With a standard two-resistor feedback network, the output voltage
can be set to values between 1.25V and the input voltage. If a step-down output voltage less than 1.25V is
desired, it can be set by adding a third feedback resistor from FBSD to a voltage higher than 1.25V. The stepup or main outputs are convenient for this, as shown in
Figure 18.
The equation governing output voltage in Figure 18’s
circuit is as follows:
0 = [(VSD - VFBSD) / R1] + [(0 - VFBSD) / R2] +
[(VSU - VFBSD) / R3]
where VSD is the output voltage, VFBSD is 1.25V, and
VSU is the step-up output voltage. Any available voltage that is higher than 1.25V can be used as the connection point for R3 in Figure 18, and for the VSD term
in the equation. Since there are multiple solutions for
R1, R2, and R3, the above equation cannot be written
in terms of one resistor. The best method for determining resistor values is to enter the above equation into a
spreadsheet and test estimated resistor values. A good
starting point is with 100kΩ at R2 and R3.
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33
MAX1566/MAX1567
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. One
such connection is shown in Figure 12. This circuit is
somewhat unique in that a positive-output linear regulator can regulate a negative voltage output. It does this
by controlling the charge current flowing to the flying
capacitor rather than directly regulating at the output.
MAX1566/MAX1567
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Designing a PC Board
Good PC board layout is important to achieve optimal
performance from the MAX1566/MAX1567. Poor design
can cause excessive conducted and/or radiated noise.
Conductors carrying discontinuous currents and any
high-current path should be made as short and wide as
possible. A separate low-noise ground plane containing the reference and signal grounds should connect to
the power-ground plane at only one point to minimize
the effects of power-ground currents. Typically, the
ground planes are best joined right at the IC.
34
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 be routed away from
high-impedance nodes such as FB_. Refer to the
MAX1566/MAX1567 EV kit data sheet for a full PC
board example.
Chip Information
TRANSISTOR COUNT: 9420
PROCESS: BiCMOS
______________________________________________________________________________________
Six-Channel, High-Efficiency, Digital
Camera Power Supplies
QFN THIN 6x6x0.8.EPS
D2
D
CL
D/2
b
D2/2
k
E/2
E2/2
E
(NE-1) X e
CL
E2
k
L
e
(ND-1) X e
CL
CL
L
L
e
A1
A2
e
A
PROPRIETARY INFORMATION
TITLE:
PACKAGE OUTLINE
36, 40L QFN THIN, 6x6x0.8 mm
APPROVAL
DOCUMENT CONTROL NO.
REV.
21-0141
COMMON DIMENSIONS
1
B
2
EXPOSED PAD VARIATIONS
D2
E2
PKG.
CODES
MIN. NOM. MAX. MIN. NOM. MAX.
T3666-1
3.60
3.70
3.80
3.60
3.70
3.80
T4066-1
4.00
4.10
4.20
4.00
4.10
4.20
NOTES:
1. DIMENSIONING & TOLERANCING CONFORM TO ASME Y14.5M-1994.
2. ALL DIMENSIONS ARE IN MILLIMETERS. ANGLES ARE IN DEGREES.
3. N IS THE TOTAL NUMBER OF TERMINALS.
4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL CONFORM TO JESD 95-1
SPP-012. DETAILS OF TERMINAL #1 IDENTIFIER ARE OPTIONAL, BUT MUST BE LOCATED WITHIN THE
ZONE INDICATED. THE TERMINAL #1 IDENTIFIER MAY BE EITHER A MOLD OR MARKED FEATURE.
5. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.25 mm AND 0.30 mm
FROM TERMINAL TIP.
6. ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE RESPECTIVELY.
7. DEPOPULATION IS POSSIBLE IN A SYMMETRICAL FASHION.
8. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.
PROPRIETARY INFORMATION
9. DRAWING CONFORMS TO JEDEC MO220.
10. WARPAGE SHALL NOT EXCEED 0.10 mm.
TITLE:
PACKAGE OUTLINE
36, 40L QFN THIN, 6x6x0.8 mm
APPROVAL
DOCUMENT CONTROL NO.
21-0141
REV.
B
2
2
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.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 35
© 2003 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX1566/MAX1567
Package Information
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,
go to www.maxim-ic.com/packages.)