MAXIM MAX15026BETD

19-4108; Rev 4; 2/12
KIT
ATION
EVALU
E
L
B
AVAILA
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
The MAX15026 synchronous step-down controller operates from a 4.5V to 28V input voltage range and generates an adjustable output voltage from 85% of the input
voltage down to 0.6V while supporting loads up to 25A.
The device allows monotonic startup into a prebiased
bus without discharging the output and features adaptive internal digital soft-start.
The MAX15026 offers the ability to adjust the switching
frequency from 200kHz to 2MHz with an external resistor. The MAX15026’s adaptive synchronous rectification
eliminates the need for an external freewheeling
Schottky diode. The device also utilizes the external
low-side MOSFET’s on-resistance as a current-sense
element, eliminating the need for a current-sense resistor. This protects the DC-DC components from damage
during output overloaded conditions or output shortcircuit faults without requiring a current-sense resistor.
Hiccup-mode current limit reduces power dissipation
during short-circuit conditions. The MAX15026 includes
a power-good output and an enable input with precise
turn-on/turn-off threshold, which can be used for input
supply monitoring and for power sequencing.
Additional protection features include sink-mode current limit and thermal shutdown.
Sink-mode current limit prevents reverse inductor current from reaching dangerous levels when the device is
sinking current from the output.
The MAX15026 is available in a space-saving and thermally enhanced 3mm x 3mm, 14-pin TDFN-EP package. The MAX15026 operates over the extended -40°C
to +85°C and automotive -40°C to +125°C temperature
ranges.
The MAX15026C is designed to provide additional margin for break-before-make times.
The MAX15026B/MAX15026C provide a soft-stop
feature to ramp down the output voltage at turn-off. The
soft-stop function is disabled in the MAX15026D.
Applications
Set-Top Boxes
LCD TV Secondary Supplies
Switches/Routers
Power Modules
DSP Power Supplies
Features
o
o
o
o
o
o
o
o
o
o
o
o
o
o
o
4.5V to 28V or 5V ±10% Input Supply Range
0.6V to (0.85 x VIN) Adjustable Output
Adjustable 200kHz to 2MHz Switching Frequency
Ability to Start into a Prebiased Load
Lossless, Cycle-by-Cycle Valley Mode Current
Limit with Adjustable, Temperature-Compensated
Threshold
Sink-Mode Current-Limit Protection
Adaptive Internal Digital Soft-Start
±1% Accurate Voltage Reference
Internal Boost Diode
Adaptive Synchronous Rectification Eliminates
External Freewheeling Schottky Diode
Hiccup-Mode Short-Circuit Protection
Thermal Shutdown
Power-Good Output and Enable Input for Power
Sequencing
±5% Accurate Enable Input Threshold
AEC-Q100 Qualified (MAX15026B)
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
-40°C to +85°C
14 TDFN-EP*
MAX15026BETD/V+T
-40°C to +85°C
14 TDFN-EP*
MAX15026CETD+
-40°C to +85°C
14 TDFN-EP*
MAX15026BATD+
-40°C to +125°C
14 TDFN-EP*
MAX15026CATD+
-40°C to +125°C
14 TDFN-EP*
MAX15026BETD+
MAX15026DATD+
-40°C to +125°C
14 TDFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
*EP = Exposed pad. T = Tape and reel.
/V denotes an automotive qualified part.
MAX15026C recommended for new designs.
Pin Configuration
TOP VIEW
IN
1
14
DH
VCC
2
13
LX
PGOOD
3
12
BST
EN
4
11
DL
LIM
5
10
DRV
COMP
6
9
GND
8
RT
FB
+
7
MAX15026
*EP
Points-of-Load Regulators
TDFN
(3mm x 3mm)
*EP = EXPOSED PAD.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
MAX15026
General Description
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
ABSOLUTE MAXIMUM RATINGS
IN to GND ...............................................................-0.3V to +30V
BST to GND ............................................................-0.3V to +36V
LX to GND .................................................................-1V to +30V
EN to GND................................................................-0.3V to +6V
PGOOD to GND .....................................................-0.3V to +30V
BST to LX..................................................................-0.3V to +6V
DH to LX ...............................................….-0.3V to (VBST + 0.3V)
DRV to GND .............................................................-0.3V to +6V
DL to GND ................................................-0.3V to (VDRV + 0.3V)
VCC to GND...............-0.3V to the lower of +6V and (VIN + 0.3V)
All Other Pins to GND.................................-0.3V to (VCC + 0.3V)
VCC Short Circuit to GND ...........................................Continuous
DRV Input Current.............................................................600mA
PGOOD Sink Current ............................................................5mA
Continuous Power Dissipation (TA = +70°C) (Note 1)
14-Pin TDFN-EP, Multilayer Board
(derate 24.4mW/°C above +70°C) ..............................1951mW
Operating Temperature Range
MAX15026B/CETD+, MAX15026BETD/V+.......-40°C to +85°C
MAX15026B/C/DATD+ ...................................-40°C to +125°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-60°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Soldering Temperature (reflow) .......................................+260°C
Note 1: Dissipation wattage values are based on still air with no heatsink. Actual maximum power dissipation is a function of heat
extraction technique and may be substantially higher. Package thermal resistances were obtained using the method
described in JEDEC specification JESD51-7, using a four-layer board. For detailed information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = 12V, RRT = 27kΩ, RLIM = 30kΩ, CVCC = 4.7µF, CIN = 1µF, TA = -40°C to +85°C (MAX15026B/CETD+, MAX15026BETD/V+),
TA = TJ = -40°C to +125°C (MAX15026B/C/DATD+), unless otherwise noted. Typical values are at TA = +25°C.) (Note 2)
PARAMETER
CONDITIONS
SYMBOL
MIN
TYP
MAX
UNITS
GENERAL
Input Voltage Range
VIN
Quiescent Supply Current
Shutdown Supply Current
IIN_SBY
VIN = VCC = VDRV
4.5
28
4.5
5.5
VFB = 0.9V, no switching
1.75
2.75
mA
EN = GND
290
500
µA
Enable to Output Delay
VCC High to Output Delay
V
EN = VCC
480
µs
375
µs
VCC REGULATOR
Output Voltage
VCC
6V < VIN < 28V, ILOAD = 25mA
VIN = 12V, 1mA < ILOAD < 70mA
5.0
5.25
5.5
V
VCC Regulator Dropout
VIN = 4.5V, ILOAD = 70mA
0.28
V
VCC Short-Circuit Output Current
VIN = 5V
100
200
300
mA
VCC rising
3.8
4.0
4.2
V
VCC Undervoltage Lockout
VCC_UVLO
VCC Undervoltage Lockout
Hysteresis
400
mV
ERROR AMPLIFIER (FB, COMP)
FB Input Voltage Set-Point
VFB
585
FB Input Bias Current
IFB
VFB = 0.6V
-250
FB to COMP Transconductance
gM
ICOMP = ±20µA
600
Amplifier Open-Loop Gain
Amplifier Unity-Gain Bandwidth
Capacitor from COMP to GND = 50pF
VCOMP-RAMP Minimum Voltage
COMP Source/Sink Current
2
591
1200
597
mV
+250
nA
1800
dB
4
MHz
160
ICOMP
VCOMP = 1.4V
50
µS
80
80
_______________________________________________________________________________________
mV
110
µA
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
(VIN = 12V, RRT = 27kΩ, RLIM = 30kΩ, CVCC = 4.7µF, CIN = 1µF, TA = -40°C to +85°C (MAX15026B/CETD+, MAX15026BETD/V+),
TA = TJ = -40°C to +125°C (MAX15026B/C/DATD+), unless otherwise noted. Typical values are at TA = +25°C.) (Note 2)
PARAMETER
CONDITIONS
SYMBOL
MIN
TYP
MAX
UNITS
ENABLE (EN)
EN Input High
VEN_H
VEN rising
1.14
1.20
1.26
V
EN Input Low
VEN_L
VEN falling
0.997
1.05
1.103
V
ILEAK_EN
VEN = 5.5V
-1
+1
µA
fSW
EN Input Leakage Current
OSCILLATOR
Switching Frequency
RRT = 27kΩ
540
600
660
kHz
1MHz Switching Frequency
RRT = 15.7kΩ
0.9
1
1.1
MHz
2MHz Switching Frequency
RRT = 7.2kΩ
1.8
2.0
2.4
MHz
2000
kHz
1.22
V
Switching Frequency Adjustment
Range (Note 3)
RT Voltage
200
VRT
PWM Ramp Peak-to-Peak
Amplitude
PWM Ramp Valley
1.19
1.205
VRAMP
1.8
VVALLEY
0.8
Minimum Controllable On-Time
65
V
V
100
ns
Maximum Duty Cycle
fSW = 600kHz
85
88
%
Minimum Low-Side On-Time
RRT = 15.7kΩ
75
110
150
ns
VDRV rising
4.0
4.2
4.4
V
OUTPUT DRIVERS/DRIVER SUPPLY (DRV)
DRV Undervoltage Lockout
VDRV_UVLO
DRV Undervoltage Lockout
Hysteresis
400
Low, sinking 100mA, VBST = 5V
DH On-Resistance
DL On-Resistance
mV
1
3
High, sourcing 100mA, VBST = 5V
1.5
4.5
Low, sinking 100mA, VBST = 5.2V
1
3
1.5
4.5
High, sourcing 100mA, VBST = 5.2V
Sinking
4
Sourcing
3
Ω
Ω
DH Peak Current
CLOAD = 10nF
DL Peak Current
CLOAD = 10nF
DH/DL Break-Before-Make Time
DH at 1V (falling) to DL at 1V (rising)
10 (18, Note 5)
ns
DL/DH Break-Before-Make Time
DL at 1V (falling) to DH at 1V (rising)
10 (20, Note 6)
ns
2048
Switching
Cycles
64
Steps
Sinking
4
Sourcing
3
A
A
SOFT-START
Soft-Start Duration
Reference Voltage Steps
CURRENT LIMIT/HICCUP
Current-Limit Threshold
Adjustment Range
Cycle-by-cycle valley current-limit
threshold adjustment range
valley limit = VLIM/10
30
300
mV
_______________________________________________________________________________________
3
MAX15026
ELECTRICAL CHARACTERISTICS (continued)
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
ELECTRICAL CHARACTERISTICS (continued)
(VIN = 12V, RRT = 27kΩ, RLIM = 30kΩ, CVCC = 4.7µF, CIN = 1µF, TA = -40°C to +85°C (MAX15026B/CETD+, MAX15026BETD/V+),
TA = TJ = -40°C to +125°C (MAX15026B/C/DATD+), unless otherwise noted. Typical values are at TA = +25°C.) (Note 2)
PARAMETER
CONDITIONS
SYMBOL
LIM Reference Current
ILIM
LIM Reference Current Tempco
VLIM = 0.3V to 3V (Note 4)
MIN
45
VLIM = 0.3V to 3V
TYP
MAX
50
55
UNITS
µA
2300
ppm/°C
7
Events
Soft-Start Timeout
4096
Switching
Cycles
Soft-Start Restart Timeout
8192
Switching
Cycles
4096
Switching
Cycles
mV
Number of Consecutive CurrentLimit Events to Hiccup
Hiccup Timeout
Out of soft-start
Peak Low-Side Sink Current
Limit
Sink limit = 1.5V, RLIM = 30kΩ (Note 4)
75
VIN = VCC = 5V, IBST = 10mA
3
8
Ω
90
94.5
97.5
%VFB
88
92
94.5
%VFB
+1
µA
0.4
V
BOOST
Boost Switch Resistance
POWER-GOOD OUTPUT
PGOOD Threshold Rising
PGOOD Threshold Falling
PGOOD Output Leakage
ILEAK_PGD
VIN = VPGOOD = 28V, VEN = 5V, VFB = 1V
PGOOD Output Low Voltage
VPGOOD_L
IPGOOD = 2mA, EN = GND
-1
THERMAL SHUTDOWN
Thermal-Shutdown Threshold
Temperature rising
+150
°C
Thermal-Shutdown Hysteresis
Temperature falling
20
°C
Note 2: All devices are 100% tested at room temperature and guaranteed by design over the specified temperature range.
Note 3: Select RRT as: RRT =
17.3 × 109
fSW + (1x10−7 )x(fSW 2 )
where fSW is in Hertz.
Note 4: TA = +25°C.
Note 5: 10ns for MAX15026B, 18ns for the MAX15026C/D.
Note 6: 10ns for MAX15026B, 20ns for the MAX15026C/D.
4
_______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
EFFICIENCY vs. LOAD CURRENT
(VIN = 12V, VCC = VDRV = 5V)
70
VOUT = 3.3V
VOUT = 1.2V
50
VOUT = 5V
40
VOUT = 1.8V
30
70
VOUT = 5V
60
VOUT = 3.3V
50
VOUT = 1.8V
40
30
-0.1
-0.3
-0.4
-0.5
-0.6
-0.7
20
-0.8
10
10
-0.9
0
0
2
6
4
8
10
12
-1.0
0
4
2
LOAD CURRENT (A)
6
8
10
0
12
2
4
VCC LINE REGULATION
MAX15026 toc04
5.3
5.260
5.1
5.246
5.244
4.9
VCC (V)
VCC (V)
5.245
12
50mA
5.0
5.250
10
VCC vs. TEMPERATURE
5mA
5.2
5.255
8
5.248
MAX15026 toc05
VCC vs. LOAD CURRENT
6
LOAD CURRENT (A)
LOAD CURRENT (A)
5.265
4.8
5.242
4.7
5.240
5.240
4.6
5.235
4.5
5.230
5.238
4.4
4.3
20
60
40
LOAD CURRENT (mA)
80
5.236
0
100
SWITCHING FREQUENCY
vs. RESISTANCE
1500
1000
500
15
20
25
30
-40
-15
10
35
60
VIN (V)
TEMPERATURE (°C)
SWITCHING FREQUENCY
vs. TEMPERATURE
SUPPLY CURRENT
vs. SWITCHING FREQUENCY
2000
RRT = 7.2kΩ
RRT = 15.7kΩ
1500
RRT = 27kΩ
RRT = 85kΩ
1000
85
90
MAX15026 toc08
2000
10
2500
SWITCHING FREQUENCY (kHz)
MAX15026 toc07
2500
5
MAX15026 toc09
0
80
SUPPLY CURRENT (mA)
5.225
SWITCHING FREQUENCY (kHz)
-0.2
20
0
VCC (V)
VOUT = 1.2V
MAX15026 toc03
80
0
MAX15026 toc06
60
90
EFFICIENCY (%)
EFFICIENCY (%)
80
MAX15026 toc02
90
VOUT vs. LOAD CURRENT
100
MAX15026 toc01
100
% OUTPUT FROM NOMINAL
EFFICIENCY vs. LOAD CURRENT
(MAX15026B/C)
70
60
50
40
30
20
500
10
0
0
0
20
40
60
RESISTANCE (kΩ)
80
100
0
-40
-15
10
35
TEMPERATURE (°C)
60
85
100
1000
10,000
SWITCHING FREQUENCY (kHz)
_______________________________________________________________________________________
5
MAX15026
Typical Operating Characteristics
(VIN = 12V, TA = +25°C. The following TOCs are for MAX15026B/C/D, unless otherwise noted.) (See the circuit of Figure 5.)
Typical Operating Characteristics (continued)
(VIN = 12V, TA = +25°C. The following TOCs are for MAX15026B/C/D, unless otherwise noted.) (See the circuit of Figure 5.)
LIM REFERENCE CURRENT
vs. TEMPERATURE
SINK AND SOURCE CURRENT-LIMIT
THRESHOLDS vs. RESISTANCE (RILIM)
50
40
30
20
10
MAX15026 toc11
60
LOAD TRANSIENT ON OUT
MAX15026 toc12
0.2
CURRENT-LIMIT THRESHOLDS (V)
MAX15026 toc10
70
LIM REFERENCE CURRENT (µA)
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
0.1
AC-COUPLED
VOUT
200mV/div
SINK CURRENT-LIMIT
0
-0.1
SOURCE CURRENT-LIMIT
10A
-0.2
IOUT
-0.3
1A
-0.4
0
-40
-15
10
35
60
0
85
10
20
30
40
50
60
70
400µs/div
RESISTANCE (kΩ)
TEMPERATURE (°C)
STARTUP RISE TIME
(MAX15026B)
STARTUP AND DISABLE FROM EN
(RLOAD = 1.5Ω)
POWER-DOWN FALL TIME
MAX15026 toc15
MAX15026 toc14
MAX15026 toc13
VIN
5V/div
VIN
5V/div
VOUT
1V/div
PGOOD
5V/div
VOUT
1V/div
VIN
5V/div
VOUT
1V/div
4ms/div
1ms/div
4ms/div
STARTUP RISE TIME
(MAX15026C/D)
SOFT-START WITH 0.5V
PREBIAS AT NO LOAD (MAX15026C/D)
OUTPUT SHORT-CIRCUIT BEHAVIOR MONITOR
OUTPUT VOLTAGE AND CURRENT
MAX15026 toc16
MAX15026 toc18
MAX15026 toc17
VIN
5V/div
VIN
5V/div
500mV/div
VOUT
0
VOUT
1V/div
0V OUTPUT
0.5V OUTPUT PREBIAS
VOUT
1V/div
20A/div
IOUT
0
1ms/div
6
1ms/div
_______________________________________________________________________________________
4ms/div
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
PIN
NAME
FUNCTION
1
IN
Regulator Input. Bypass IN to GND with a 1µF minimum ceramic capacitor. Connect IN to VCC when
operating in the 5V ±10% range.
2
VCC
5.25V Linear Regulator Output. Bypass VCC to GND with a minimum of 4.7µF low-ESR ceramic
capacitor to ensure stability up to the regulated rated current when VCC supplies the drive current at
DRV. Bypass VCC to GND when VCC supplies the device core quiescent current with a 2.2µF
minimum ceramic capacitor.
3
PGOOD
Open-Drain Power-Good Output. Connect PGOOD with an external resistor to any supply voltage.
4
EN
Active-High Enable Input. Pull EN to GND to disable the output. Connect EN to VCC for always-on
operation. EN can be used for power sequencing and as a UVLO adjustment input.
5
LIM
Current-Limit Adjustment. Connect a resistor from LIM to GND to adjust current-limit threshold from
30mV (RLIM = 6kΩ) to 300mV (RLIM = 60kΩ). See the Setting the Valley Current Limit section.
6
COMP
Compensation Input. Connect compensation network from COMP to FB or from COMP to GND. See
the Compensation section.
7
FB
Feedback Input. Connect FB to a resistive divider between output and GND to adjust the output
voltage between 0.6V and (0.85 x Input Voltage). See the Setting the Output Voltage section.
8
RT
Oscillator Timing Resistor Input. Connect a resistor from RT to GND to set the oscillator frequency
from 200kHz to 2MHz. See the Setting the Switching Frequency section.
9
GND
Ground
10
DRV
Drive Supply Voltage. DRV is internally connected to the anode terminal of the internal boost diode.
Bypass DRV to GND with a 2.2µF minimum ceramic capacitor (see the Typical Application Circuits).
11
DL
Low-Side Gate-Driver Output. DL swings from DRV to GND. DL is low during UVLO.
12
BST
Boost Flying Capacitor. Connect a ceramic capacitor with a minimum value of 100nF between BST
and LX.
13
LX
External Inductor Connection. Connect LX to the switching side of the inductor. LX serves as the
lower supply rail for the high-side gate driver and as a sensing input of the drain to source voltage
drop of the synchronous MOSFET.
14
DH
High-Side Gate-Driver Output. DH swings from LX to BST. DH is low during UVLO.
—
EP
Exposed Pad. Internally connected to GND. Connect EP to a large copper plane at GND potential to
improve thermal dissipation. Do not use EP as the only GND ground connection.
_______________________________________________________________________________________
7
MAX15026
Pin Description
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
MAX15026
Functional Diagram
MAX15026
VREF
FB1
CK
OSCILLATOR
RT
VREF
ENABLE
COMPARATOR
EN
OSC_ENABLE
HICCUP
CK
EN_INT
ENABLE
HICCUP TIMEOUT
DH_DL_ENABLE
VREF
BGAP_OK
VBGAP
VIN_OK
VBGAP
BANDGAP
OK
GENERATOR
PWM
COMPARATOR
BGAP_OK
VREF
CK
BGAP_OK
VL_OK
PWM
RAMP
BST
BOOST
DRIVER
CK
VCC
RAMP
GENERATOR
DC-DC
AND
OSCILLATOR
ENABLE
LOGIC
INTERNAL
VOLTAGE
REGULATOR
VCC
UVLO
COMP
gM
DAC_VREF
SOFT-START/
SOFT-STOP
LOGIC AND
HICCUP LOGIC
DH_DL_ENABLE
HICCUP
TIMEOUT
GATEP
HIGHSIDE
DRIVER
PWM
CONTROL HICCUP
LOGIC
DH
LX
DRV
BGAP_OK
VDRV
DRV
UVLO
LOWSIDE
DRIVER
VDRV_OK
DL
LIM/20
VIN_OK
LIM
IN
THERMAL
SHUTDOWN
AND ILIM
CURRENT
GEN
IN
UVLO
GND
SHUTDOWN
VIN_OK
VIN_OK
IBIAS
VREF = 0.6V
VBGAP = 1.24V
8
FB
SINK
CURRENT-LIMIT
COMPARATOR
MAIN
BIAS
CURRENT
GENERATOR
VALLEY
CURRENT-LIMIT
COMPARATOR
ENABLE
PGOOD
VREF
LIM/10
PGOOD
COMPARATOR
BANDGAP
REFERENCE
_______________________________________________________________________________________
GND
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
The MAX15026 synchronous step-down controller operates from a 4.5V to 28V input voltage range and generates an adjustable output voltage from 85% of the input
voltage down to 0.6V while supporting loads up to 25A.
As long as the device supply voltage is within 5.0V to
5.5V, the input power bus (VIN) can be as low as 3.3V.
The MAX15026 offers adjustable switching frequency
from 200kHz to 2MHz with an external resistor. The
adjustable switching frequency provides design flexibility in selecting passive components. The MAX15026
adopts an adaptive synchronous rectification to eliminate an external freewheeling Schottky diode and
improve efficiency. The device utilizes the on-resistance of the external low-side MOSFET as a currentsense element. The current-limit threshold voltage is
resistor-adjustable from 30mV to 300mV and is temperature-compensated, so that the effects of the MOSFET
RDS(ON) variation over temperature are reduced. This
current-sensing scheme protects the external components from damage during output overloaded conditions or output short-circuit faults without requiring a
current-sense resistor. Hiccup-mode current limit
reduces power dissipation during short-circuit conditions. The MAX15026 includes a power-good output
and an enable input with precise turn-on/-off threshold
to be used for monitoring and for power sequencing.
The MAX15026 features internal digital soft-start that
allows prebias startup without discharging the output.
The digital soft-start function employs sink current limiting to prevent the regulator from sinking excessive current when the prebias voltage exceeds the
programmed steady-state regulation level. The digital
soft-start feature prevents the synchronous rectifier
MOSFET and the body diode of the high-side MOSFET
from experiencing dangerous levels of current while the
regulator is sinking current from the output. The
MAX15026 shuts down at a junction temperature of
+150°C to prevent damage to the device.
DC-DC PWM Controller
The MAX15026 step-down controller uses a PWM voltage-mode control scheme (see the Functional Diagram).
Control-loop compensation is external for providing maximum flexibility in choosing the operating frequency and
output LC filter components. An internal transconductance error amplifier produces an integrated error voltage at COMP that helps to provide higher DC accuracy.
The voltage at COMP sets the duty cycle using a PWM
comparator and a ramp generator. On the rising edge of
an internal clock, the high-side n-channel MOSFET turns
on and remains on until either the appropriate duty cycle
or the maximum duty cycle is reached. During the ontime of the high-side MOSFET, the inductor current
ramps up. During the second-half of the switching cycle,
the high-side MOSFET turns off and the low-side n-channel MOSFET turns on. The inductor releases the stored
energy as the inductor current ramps down, providing
current to the output. Under overload conditions, when
the inductor current exceeds the selected valley currentlimit threshold (see the Current-Limit Circuit (LIM) section), the high-side MOSFET does not turn on at the
subsequent clock rising edge and the low-side MOSFET
remains on to let the inductor current ramp down.
Internal 5.25V Linear Regulator
An internal linear regulator (VCC) provides a 5.25V nominal supply to power the internal functions and to drive
the low-side MOSFET. Connect IN and VCC together
when using an external 5V ±10% power supply. The
maximum regulator input voltage (VIN) is 28V. Bypass IN
to GND with a 1µF ceramic capacitor. Bypass the output
of the linear regulator (VCC) with a 4.7µF ceramic capacitor to GND. The VCC dropout voltage is typically 125mV.
When VIN is higher than 5.5V, VCC is typically 5.25V. The
MAX15026 also employs an undervoltage lockout circuit
that disables the internal linear regulator when VCC falls
below 3.6V (typ). The 400mV UVLO hysteresis prevents
chattering on power-up/power-down.
The internal V CC linear regulator can source up to
70mA to supply the IC, power the low-side gate driver,
recharge the external boost capacitor, and supply small
external loads. The current available for external loads
depends on the current consumed by the MOSFET
gate drivers.
For example, when switching at 600kHz, a MOSFET
with 18nC total gate charge (at VGS = 5V) requires
(18nC x 600kHz) = 11mA. The internal control functions
consume 5mA maximum. The current available for
external loads is:
(70 – (2 x 11) – 5)mA ≅ 43mA
MOSFET Gate Drivers (DH, DL)
DH and DL are optimized for driving large-size n-channel power MOSFETs. Under normal operating conditions and after startup, the DL low-side drive waveform
is always the complement of the DH high-side drive
waveform, with controlled dead-time to prevent crossconduction or shoot-through. An adaptive dead-time
circuit monitors the DH and DL outputs and prevents
the opposite-side MOSFET from turning on until the
other MOSFET is fully off. Thus, the circuit allows the
high-side driver to turn on only when the DL gate driver
has turned off, preventing the low-side (DL) from turning on until the DH gate driver has turned off.
_______________________________________________________________________________________
9
MAX15026
Detailed Description
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
The adaptive driver dead-time allows operation without
shoot-through with a wide range of MOSFETs, minimizing delays and maintaining efficiency. There must be a
low-resistance, low-inductance path from DL and DH to
the MOSFET gates for the adaptive dead-time circuits
to function properly. The stray impedance in the gate
discharge path can cause the sense circuitry to interpret the MOSFET gate as off while the V GS of the
MOSFET is still high. To minimize stray impedance, use
very short, wide traces.
Synchronous rectification reduces conduction losses in
the rectifier by replacing the normal low-side Schottky
catch diode with a low-resistance MOSFET switch. The
MAX15026 features a robust internal pulldown transistor with a typical 1Ω RDS(ON) to drive DL low. This low
on-resistance prevents DL from being pulled up during
the fast rise time of the LX node, due to capacitive coupling from the drain to the gate of the low-side synchronous rectifier MOSFET.
High-Side Gate-Drive Supply (BST)
and Internal Boost Switch
An internal switch between BST and DH turns on to
boost the gate voltage above VIN providing the necessary gate-to-source voltage to turn on the high-side
MOSFET. The boost capacitor connected between BST
and LX holds up the voltage across the gate driver during the high-side MOSFET on-time.
The charge lost by the boost capacitor for delivering the
gate charge is replenished when the high-side MOSFET
turns off and LX node goes to ground. When LX is low,
an internal high-voltage switch connected between
VDRV and BST recharges the boost capacitor. See the
Boost Capacitor section in the Applications Information
to choose the right size of the boost capacitor.
Enable Input (EN), Soft-Start,
and Soft-Stop
Drive EN high to turn on the MAX15026. A soft-start
sequence starts to increase step-wise the reference
voltage of the error amplifier. The duration of the softstart ramp is 2048 switching cycles and the resolution
is 1/64th of the steady-state regulation voltage allowing
10
a smooth increase of the output voltage. A logic-low on
EN initiates a soft-stop sequence by stepping down the
reference voltage of the error amplifier. After the softstop sequence is completed, the MOSFET drivers are
both turned off. See Figure 1. The soft-stop feature is
disabled in the MAX15026D.
Connect EN to VCC for always-on operation. Owing to
the accurate turn-on/-off thresholds, EN can be used as
UVLO adjustment input, and for power sequencing
together with the PGOOD output.
When the valley current limit is reached during soft-start
the MAX15026 regulates to the output impedance times
the limited inductor current and turns off after 4096
clock cycles. When starting up into a large capacitive
load (for example) the inrush current will not exceed the
current-limit value. If the soft-start is not completed
before 4096 clock cycles, the device will turn off. The
device remains off for 8192 clock cycles before trying
to soft-start again. This implementation allows the softstart time to be automatically adapted to the time necessary to keep the inductor current below the limit while
charging the output capacitor.
Power-Good Output (PGOOD)
The MAX15026 includes a power-good comparator to
monitor the output voltage and detect the power-good
threshold, fixed at 94.5% of the nominal FB voltage. The
open-drain PGOOD output requires an external pullup
resistor. PGOOD sinks up to 2mA of current while low.
PGOOD goes high (high-impedance) when the regulator output increases above 94.5% of the designed nominal regulated voltage. PGOOD goes low when the
regulator output voltage drops to below 92% of the
nominal regulated voltage. PGOOD asserts low during
hiccup timeout period.
Startup into a Prebiased Output
When the MAX15026 starts into a prebiased output, DH
and DL are off so that the converter does not sink current from the output. DH and DL do not start switching
until the PWM comparator commands the first PWM
pulse. The first PWM pulse occurs when the ramping
reference voltage increases above the FB voltage.
______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
A
B
C
D
E
F
G
H
MAX15026
UVLO
I
VCC
EN
VOUT
2048 CLK
CYCLES
2048 CLK
CYCLES
DAC_VREF
DH
DL
SYMBOL
UVLO
VCC
EN
VOUT
DAC_VREF
DH
DL
A
DEFINITION
Undervoltage threshold value is provided in
the Electrical Characteristics table.
Internal 5.25V linear regulator output.
Active-high enable input.
Regulator output voltage.
Regulator internal soft-start and soft-stop signal.
Regulator high-side gate-driver output.
Regulator low-side gate-driver output.
VCC rising while below the UVLO threshold.
EN is low.
SYMBOL
DEFINITION
B
VCC is higher than the UVLO threshold. EN is low.
C
F
EN is pulled high. DH and DL start switching.
Normal operation.
VCC drops below UVLO.
VCC goes above the UVLO threshold. DH and DL
start switching. Normal operation.
G
EN is pulled low. VOUT enters soft-stop.
H
EN is pulled high. DH and DL start switching.
Normal operation.
VCC drops below UVLO.
D
E
I
Figure 1. Power-On/-Off Sequencing for MAX15026B/C.
Current-Limit Circuit (LIM)
The current-limit circuit employs a valley and sink current-sensing algorithm that uses the on-resistance of
the low-side MOSFET as a current-sensing element, to
eliminate costly sense resistors. The current-limit circuit
is also temperature compensated to track the on-resistance variation of the MOSFET over temperature. The
current limit is adjustable with an external resistor at
LIM, and accommodates MOSFETs with a wide range
of on-resistance characteristics (see the Setting the
Valley Current Limit section). The adjustment range is
from 30mV to 300mV for the valley current limit, corresponding to resistor values of 6kΩ to 60kΩ. The valley
current-limit threshold across the low-side MOSFET is
precisely 1/10th of the voltage at LIM, while the sink
current-limit threshold is 1/20th of the voltage at LIM.
Valley current limit acts when the inductor current flows
towards the load, and LX is more negative than GND
during the low-side MOSFET on-time. If the magnitude
of current-sense signal exceeds the valley current-limit
threshold at the end of the low-side MOSFET on-time,
the MAX15026 does not initiate a new PWM cycle and
lets the inductor current decay in the next cycle. The
controller also rolls back the internal reference voltage
so that the controller finds a regulation point determined by the current-limit value and the resistance of
the short. In this manner, the controller acts as a constant current source. This method greatly reduces
inductor ripple current during the short event, which
reduces inductor sizing restrictions, and reduces the
possibility for audible noise. After a timeout, the device
goes into hiccup mode. Once the short is removed, the
internal reference voltage soft-starts back up to the normal reference voltage and regulation continues.
______________________________________________________________________________________
11
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Sink current limit is implemented by monitoring the voltage drop across the low-side MOSFET when LX is more
positive than GND. When the voltage drop across the
low-side MOSFET exceeds 1/20th of the voltage at LIM
at any time during the low-side MOSFET on-time, the
low-side MOSFET turns off, and the inductor current
flows from the output through the body diode of the highside MOSFET. When the sink current limit activates, the
DH/DL switching sequence is no longer complementary.
Carefully observe the PCB layout guidelines to ensure
that noise and DC errors do not corrupt the currentsense signals at LX and GND. Mount the MAX15026
close to the low-side MOSFET with short, direct traces
making a Kelvin-sense connection so that trace resistance does not add to the intended sense resistance of
the low-side MOSFET.
Hiccup-Mode Overcurrent Protection
Hiccup-mode overcurrent protection reduces power dissipation during prolonged short-circuit or deep overload
conditions. An internal three-bit counter counts up on
each switching cycle when the valley current-limit
threshold is reached. The counter counts down on each
switching cycle when the threshold is not reached, and
stops at zero (000). The counter reaches 111 (= 7
events) when the valley mode current-limit condition
persists. The MAX15026 stops both DL and DH drivers
and waits for 4096 switching cycles (hiccup timeout
delay) before attempting a new soft-start sequence. The
hiccup-mode protection remains active during the softstart time.
Undervoltage Lockout
The MAX15026 provides an internal undervoltage lockout
(UVLO) circuit to monitor the voltage on VCC. The UVLO
circuit prevents the MAX15026 from operating when VCC
is lower than VUVLO. The UVLO threshold is 4V, with
400mV hysteresis to prevent chattering on the rising/falling
edge of the supply voltage. DL and DH stay low to inhibit
switching when the device is in undervoltage lockout.
Thermal-Overload Protection
Thermal-overload protection limits total power dissipation
in the MAX15026. When the junction temperature of the
device exceeds +150°C, an on-chip thermal sensor shuts
down the device, forcing DL and DH low, allowing the
device to cool. The thermal sensor turns the device on
again after the junction temperature cools by 20°C. The
regulator shuts down and soft-start resets during thermal
shutdown. Power dissipation in the LDO regulator and
excessive driving losses at DH/DL trigger thermal-overload protection. Carefully evaluate the total power dissipation (see the Power Dissipation section) to avoid
12
unwanted triggering of the thermal-overload protection in
normal operation.
Applications Information
Effective Input Voltage Range
The MAX15026 operates from input supplies up to 28V
and regulates down to 0.6V. The minimum voltage conversion ratio (VOUT/VIN) is limited by the minimum controllable on-time. For proper fixed-frequency PWM
operation, the voltage conversion ratio must obey the
following condition,
VOUT
> tON(MIN) × fSW
VIN
where tON(MIN) is 125ns and fSW is the switching frequency in Hertz. Pulse-skipping occurs to decrease the
effective duty cycle when the desired voltage conversion does not meet the above condition. Decrease the
switching frequency or lower VIN to avoid pulse skipping.
The maximum voltage conversion ratio is limited by the
maximum duty cycle (Dmax):
× VDROP2 + (1 − Dmax ) × VDROP1
VOUT
D
< Dmax − max
VIN
VIN
where VDROP1 is the sum of the parasitic voltage drops
in the inductor discharge path, including synchronous
rectifier, inductor, and PCB resistance. VDROP2 is the
sum of the resistance in the charging path, including
high-side switch, inductor, and PCB resistance. In
practice, provide adequate margin to the above conditions for good load-transient response.
Setting the Output Voltage
Set the MAX15026 output voltage by connecting a
resistive divider from the output to FB to GND (Figure
2). Select R2 from between 1kΩ and 50kΩ. Calculate
R1 with the following equation:
⎡⎛ V
⎞ ⎤
R1 = R2 ⎢⎜ OUT ⎟ − 1⎥
V
⎝
⎢⎣ FB ⎠ ⎥⎦
where VFB = 0.591V (see the Electrical Characteristics
table) and VOUT can range from 0.591V to (0.85 x VIN).
Resistor R1 also plays a role in the design of the Type III
compensation network. Review the values of R1 and R2
when using a Type III compensation network (see the
Type III Compensation Network (See Figure 4) section).
______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
R1
FB
R2
MAX15026
Figure 2. Adjustable Output Voltage
Setting the Switching Frequency
An external resistor connecting RT to GND sets the
switching frequency (fSW). The relationship between
fSW and RRT is:
RRT =
17.3 × 109
fSW + (1x10−7 )x(fSW 2 )
where fSW is in Hz and RRT is in Ω. For example, a
600kHz switching frequency is set with RRT = 27.2kΩ.
Higher frequencies allow designs with lower inductor
values and less output capacitance. Peak currents and
I2R losses are lower at higher switching frequencies,
but core losses, gate-charge currents, and switching
losses increase.
Inductor Selection
Three key inductor parameters must be specified for
operation with the MAX15026: inductance value (L),
inductor saturation current (ISAT), and DC resistance
(RDC). To determine the inductance value, select the
ratio of inductor peak-to-peak AC current to DC average
current (LIR) first. For LIR values which are too high, the
RMS currents are high, and therefore I2R losses are
high. Use high-valued inductors to achieve low LIR values. Typically, inductance is proportional to resistance
for a given package type, which again makes I2R losses
high for very low LIR values. A good compromise
between size and loss is a 30% peak-to-peak ripple current to average-current ratio (LIR = 0.3). The switching
V
(V − V
)
L = OUT IN OUT
VINfSWIOUTLIR
where VIN, VOUT, and IOUT are typical values (so that
efficiency is optimum for typical conditions). The switching frequency is set by R RT (see the Setting the
Switching Frequency section). The exact inductor value
is not critical and can be adjusted to make trade-offs
among size, cost, and efficiency. Lower inductor values
minimize size and cost, but also improve transient
response and reduce efficiency due to higher peak currents. On the other hand, higher inductance increases
efficiency by reducing the RMS current.
Find a low-loss inductor having the lowest possible DC
resistance that fits in the allotted dimensions. The saturation current rating (ISAT) must be high enough to ensure
that saturation can occur only above the maximum current-limit value (ICL(MAX)), given the tolerance of the onresistance of the low-side MOSFET and of the LIM
reference current (ILIM). Combining these conditions,
select an inductor with a saturation current (ISAT) of:
ISAT ≥ 1.35 x ICL(TYP)
where ICL(TYP) is the typical current-limit set-point. The
factor 1.35 includes RDS(ON) variation of 25% and 10%
for the LIM reference current error. A variety of inductors
from different manufacturers are available to meet this
requirement (for example, Coilcraft MSS1278-142ML
and other inductors from the same series).
Setting the Valley Current Limit
The minimum current-limit threshold must be high
enough to support the maximum expected load current
with the worst-case low-side MOSFET on-resistance
value as the RDS(ON) of the low-side MOSFET is used
as the current-sense element. The inductor’s valley current occurs at ILOAD(MAX) minus one half of the ripple
current. The minimum value of the current-limit threshold voltage (VITH) must be higher than the voltage on
the low-side MOSFET during the ripple-current valley:
⎛ LIR ⎞
VITH > RDS(ON,MAX) × ILOAD(MAX) × ⎜ 1 −
⎟
⎝
2 ⎠
where R DS(ON) is the on-resistance of the low-side
MOSFET in ohms. Use the maximum value for RDS(ON)
from the data sheet of the low-side MOSFET.
______________________________________________________________________________________
13
MAX15026
OUT
frequency, input voltage, output voltage, and selected
LIR determine the inductor value as follows,
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Connect an external resistor (RLIM) from LIM to GND to
adjust the current-limit threshold. The relationship
between the current-limit threshold (VITH) and RLIM is:
RLIM =
10 × VITH
50µA
where RLIM is in kΩ and VITH is in mV.
An RLIM resistance range of 6kΩ to 60kΩ corresponds
to a current-limit threshold of 30mV to 300mV. Use 1%
tolerance resistors when adjusting the current limit to
minimize error in the current-limit threshold.
Input Capacitor
The input filter capacitor reduces peak currents drawn
from the power source and reduces noise and voltage
ripple on the input caused by the switching circuitry.
The input capacitor must meet the ripple current
requirement (IRMS) imposed by the switching currents
as defined by the following equation,
IRMS = ILOAD(MAX)
VOUT (VIN − VOUT )
VIN
IRMS attains a maximum value when the input voltage
equals twice the output voltage (V IN = 2V OUT ), so
I RMS(MAX) = I LOAD(MAX) /2. For most applications,
non-tantalum capacitors (ceramic, aluminum, polymer, or OS-CON) are preferred at the inputs due to
the robustness of non-tantalum capacitors to accommodate high inrush currents of systems being powered from very low-impedance sources. Additionally,
two (or more) smaller-value low-ESR capacitors can
be connected in parallel for lower cost.
Output Capacitor
The key selection parameters for the output capacitor are
capacitance value, ESR, and voltage rating. These parameters affect the overall stability, output ripple voltage, and
transient response. The output ripple has two components:
variations in the charge stored in the output capacitor, and
the voltage drop across the capacitor’s ESR caused by
the current flowing into and out of the capacitor:
∆VRIPPLE ≅ ∆VESR + ∆VQ
The output voltage ripple as a consequence of the ESR
and the output capacitance is:
∆VESR = IP −P × ESR
IP −P
∆VQ =
8 × COUT × fSW
⎛V −V
⎞ ⎛V
⎞
IP −P = ⎜ IN OUT ⎟ × ⎜ OUT ⎟
⎝ fSW × L ⎠ ⎝ VIN ⎠
14
where IP-P is the peak-to-peak inductor current ripple
(see the Inductor Selection section). Use these equations for initial capacitor selection. Decide on the final
values by testing a prototype or an evaluation circuit.
Check the output capacitor against load-transient
response requirements. The allowable deviation of the
output voltage during fast load transients determines
the capacitor output capacitance, ESR, and equivalent
series inductance (ESL). The output capacitor supplies
the load current during a load step until the controller
responds with a higher duty cycle. The response time
(tRESPONSE) depends on the closed-loop bandwidth of
the converter (see the Compensation section). The
resistive drop across the ESR of the output capacitor,
the voltage drop across the ESL (∆VESL) of the capacitor, and the capacitor discharge, cause a voltage
droop during the load step.
Use a combination of low-ESR tantalum/aluminum electrolytic and ceramic capacitors for improved transient
load and voltage ripple performance. Nonleaded
capacitors and capacitors in parallel help reduce the
ESL. Keep the maximum output voltage deviation below
the tolerable limits of the load. Use the following equations to calculate the required ESR, ESL, and capacitance value during a load step:
∆V
ESR = ESR
ISTEP
I
×t
COUT = STEP RESPONSE
∆VQ
ESL =
∆VESL × tSTEP
ISTEP
tRESPONSE ≅
1
3 × fO
where ISTEP is the load step, tSTEP is the rise time of the
load step, tRESPONSE is the response time of the controller and fO is the closed-loop crossover frequency.
Compensation
The MAX15026 provides an internal transconductance
amplifier with the inverting input and the output available for external frequency compensation. The flexibility
of external compensation offers a wide selection of output filtering components, especially the output capacitor. Use high-ESR aluminum electrolytic capacitors for
cost-sensitive applications. Use low-ESR tantalum or
ceramic capacitors at the output for size sensitive
applications. The high switching frequency of the
MAX15026 allows the use of ceramic capacitors at the
output. Choose all passive power components to meet
the output ripple, component size, and component cost
______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
fPO =
1
2π × LOUT × COUT
The output capacitor introduces a zero at:
fZO =
1
2π × ESR × COUT
where ESR is the equivalent series resistance of the
output capacitor.
The loop-gain crossover frequency (fO), where the loop
gain equals 1 (0dB) should be set below 1/10th of the
switching frequency:
f
fO ≤ SW
10
Choosing a lower crossover frequency reduces the
effects of noise pick-up into the feedback loop, such as
jittery duty cycle.
To maintain a stable system, two stability criteria must
be met:
1) The phase shift at the crossover frequency fO, must
be less than 180°. In other words, the phase margin
of the loop must be greater than zero.
2) The gain at the frequency where the phase shift is
-180° (gain margin) must be less than 1.
Maintain a phase margin of around 60° to achieve a
robust loop stability and well-behaved transient
response.
When using an electrolytic or large-ESR tantalum output
capacitor the capacitor ESR zero fZO typically occurs
between the LC poles and the crossover frequency fO
(fPO < fZO < fO). Choose Type II (PI—proportional-integral) compensation network.
When using a ceramic or low-ESR tantalum output
capacitor, the capacitor ESR zero typically occurs
above the desired crossover frequency fO, that is fPO <
fO < fZO. Choose Type III (PID—proportional, integral,
and derivative) compensation network.
Type II Compensation Network
(Figure 3)
If fZO is lower than fO and close to fPO, the phase lead
of the capacitor ESR zero almost cancels the phase
loss of one of the complex poles of the LC filter around
the crossover frequency. Use a Type II compensation
network with a midband zero and a high-frequency
pole to stabilize the loop. In Figure 3, RF and CF introduce a midband zero (fZ1). RF and CCF in the Type II
compensation network provide a high-frequency pole
(fP1), which mitigates the effects of the output high-frequency ripple.
Follow the instructions below to calculate the component
values for the Type II compensation network in Figure 3:
1) Calculate the gain of the modulator (GAIN MOD),
comprised of the regulator’s pulse-width modulator,
LC filter, feedback divider, and associated circuitry
at the crossover frequency:
GAINMOD =
VIN
V
ESR
×
× FB
VRAMP ( 2π × fO × LOUT ) VOUT
where VIN is the input voltage of the regulator, VRAMP is
the amplitude of the ramp in the pulse-width modulator,
VFB is the FB input voltage set-point (0.591V typically,
see the Electrical Characteristics table), and VOUT is
the desired output voltage.
The gain of the error amplifier (GAINEA) in midband frequencies is:
GAINEA = gM x RF
where gM is the transconductance of the error amplifier.
The total loop gain, which is the product of the modulator gain and the error amplifier gain at fO, is 1.
GAINMOD × GAINEA = 1
So:
VIN
VRAMP
×
V
ESR
× FB × gM × RF = 1
(2π × fO × LOUT ) VOUT
Solving for RF:
V
× ( 2π × fO × LOUT ) × VOUT
RF = RAMP
VFB × VIN × gM × ESR
2) Set a midband zero (fZ1) at 0.75 x fPO (to cancel
one of the LC poles):
fZ1 =
1
= 0.75 × fPO
2π × RF × CF
______________________________________________________________________________________
15
MAX15026
requirements. Choose the small-signal components for
the error amplifier to achieve the desired closed-loop
bandwidth and phase margin.
To choose the appropriate compensation network type,
the power-supply poles and zeros, the zero crossover
frequency, and the type of the output capacitor must be
determined.
In a buck converter, the LC filter in the output stage introduces a pair of complex poles at the following frequency:
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Solving for CF:
CF =
1
2π × RF × fPO × 0.75
3) Place a high-frequency pole at fP1 = 0.5 x fSW (to
attenuate the ripple at the switching frequency, fSW)
and calculate CCF using the following equation:
CCF =
1
π × RF × fSW
−
1
CF
Type III Compensation Network
(See Figure 4)
When using a low-ESR tantalum or ceramic type, the
ESR-induced zero frequency is usually above the targeted zero crossover frequency (fO). Use Type III compensation. Type III compensation provides three poles
and two zeros at the following frequencies:
Depending on the location of the ESR zero (fZO), use
fP2 to cancel fZO, or to provide additional attenuation of
the high-frequency output ripple:
1
fP3 =
C × CCF
2π × RF × F
CF + CCF
fP3 attenuates the high-frequency output ripple.
Place the zeros and poles so the phase margin peaks
around fO.
Ensure that RF>>2/gM and the parallel resistance of R1,
R 2 , and R I is greater than 1/g M . Otherwise, a 180°
phase shift is introduced to the response making the
loop unstable.
Use the following compensation procedure:
1) With RF ≥ 10kΩ, place the first zero (fZ1) at 0.8 x fPO.
fZ1 =
So:
1
2π × RF × CF
1
fZ2 =
2π × CI × (R1 + RI)
fZ1 =
GAINMOD =
Two midband zeros (fZ1 and fZ2) cancel the pair of
complex poles introduced by the LC filter:
fP1 = 0
VIN
VRAMP
×
(2π
2) The gain of the modulator (GAINMOD), comprises
the pulse-width modulator, LC filter, feedback
divider, and associated circuitry at the crossover
frequency is:
fP1 introduces a pole at zero frequency (integrator) for
nulling DC output voltage errors:
fP2 =
1
= 0.8 × fPO
2π × RF × CF
GAINMOD =
1
2π × RI × CI
VIN
1
×
VRAMP ( 2π × f )2 × L
O
OUT × COUT
VOUT
CCF
VOUT
R1
RF
COMP
gM
R2
VREF
RI
R1
CI
RF
CF
CCF
gM
R2
VREF
Figure 3. Type II Compensation Network
16
CF
Figure 4. Type III Compensation Network
______________________________________________________________________________________
COMP
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
GAINMOD × GAINEA = 1
So:
VIN
VRAMP
×
5) Place the third pole (fP3) at 1/2 the switching frequency and calculate CCF:
CCF =
CF
(2π × 0.5 × fSW × RF × CF ) − 1
6) Calculate R2 as:
R2 =
1
(2π × fO )2 × COUT × LOUT
Solving for CI:
V
× ( 2π × fO × LOUT × COUT )
CI = RAMP
VIN × RF
3) Use the second pole (fP2) to cancel fZO when fPO <
fO < fZO < fSW/2. The frequency response of the
loop gain does not flatten out soon after the 0dB
crossover, and maintains a -20dB/decade slope up
to 1/2 of the switching frequency. This is likely to
occur if the output capacitor is a low-ESR tantalum.
Set fP2 = fZO.
When using a ceramic capacitor, the capacitor ESR
zero f ZO is likely to be located even above 1/2 the
switching frequency, fPO < fO < fSW/2 < fZO. In this
case, place the frequency of the second pole (fP2) high
enough to not significantly erode the phase margin at
the crossover frequency. For example, set fP2 at 5 x fO
so that the contribution to phase loss at the crossover
frequency fO is only about 11°:
fP2 = 5 x fPO
Once fP2 is known, calculate RI:
RI =
1
2π × fP2 × CI
4) Place the second zero (fZ2) at 0.2 x fO or at fPO,
whichever is lower, and calculate R1 using the following equation:
R1 =
1
2π × fZ2 × CI
− RI
VFB
× R1
VOUT − VFB
MOSFET Selection
The MAX15026 step-down controller drives two external
logic-level n-channel MOSFETs. The key selection
parameters to choose these MOSFETs include:
• On-Resistance (RDS(ON))
• Maximum Drain-to-Source Voltage (VDS(MAX))
• Minimum Threshold Voltage (VTH(MIN))
• Total Gate Charge (QG)
• Reverse Transfer Capacitance (CRSS)
• Power Dissipation
The two n-channel MOSFETs must be a logic-level type
with guaranteed on-resistance specifications at VGS =
4.5V. For maximum efficiency, choose a high-side
MOSFET that has conduction losses equal to the
switching losses at the typical input voltage. Ensure
that the conduction losses at minimum input voltage do
not exceed the MOSFET package thermal limits, or violate the overall thermal budget. Also, ensure that the
conduction losses plus switching losses at the maximum input voltage do not exceed package ratings or
violate the overall thermal budget. Ensure that the DL
gate driver can drive the low-side MOSFET. In particular, check that the dv/dt caused by the high-side
MOSFET turning on does not pull up the low-side
MOSFET gate through the drain-to-gate capacitance
of the low-side MOSFET, which is the most frequent
cause of cross-conduction problems.
Check power dissipation when using the internal linear
regulator to power the gate drivers. Select MOSFETs
with low gate charge so that VCC can power both drivers without overheating the device.
PDRIVE = VCC x QG_TOTAL x fSW
where QG_TOTAL is the sum of the gate charges of the
two external MOSFETs.
______________________________________________________________________________________
17
MAX15026
The gain of the error amplifier (GAINEA) in midband frequencies is:
GAINEA = 2π x fO x C1 x RF
The total loop gain as the product of the modulator gain
and the error amplifier gain at fO is 1.
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Boost Capacitor
The MAX15026 uses a bootstrap circuit to generate the
necessary gate-to-source voltage to turn on the highside MOSFET. The selected n-channel high-side
MOSFET determines the appropriate boost capacitance value (CBST in the Typical Application Circuits)
according to the following equation:
CBST =
QG
∆VBST
where Q G is the total gate charge of the high-side
MOSFET and ∆VBST is the voltage variation allowed on
the high-side MOSFET driver after turn-on. Choose
∆VBST so the available gate-drive voltage is not significantly degraded (e.g. ∆VBST = 100mV to 300mV) when
determining CBST. Use a low-ESR ceramic capacitor as
the boost flying capacitor with a minimum value of
100nF.
Power Dissipation
The maximum power dissipation of the device depends
on the thermal resistance from the die to the ambient
environment and the ambient temperature. The thermal
resistance depends on the device package, PCB copper area, other thermal mass, and airflow.
The power dissipated into the package (PT) depends
on the supply configuration (see the Typical Application
Circuits). Use the following equation to calculate power
dissipation:
PT = (VIN - VCC) x ILDO + VDRV x IDRV + VCC x IIN
where ILDO is the current supplied by the internal regulator, IDRV is the supply current consumed by the drivers at DRV, and I IN is the supply current of the
MAX15026 without the contribution of the IDRV, as given
in the Typical Operating Characteristics. For example, in
the application circuit of Figure 5, ILDO = IDRV + IIN and
VDRV = VCC so that PT = VIN x (IDRV + IIN).
Use the following equation to estimate the temperature
rise of the die:
TJ = TA + (PT x θJA)
where θJA is the junction-to-ambient thermal impedance of the package, PT is power dissipated in the
device, and TA is the ambient temperature. The θJA is
24.4°C/W for 14-pin TDFN package on multilayer
boards, with the conditions specified by the respective
JEDEC standards (JESD51-5, JESD51-7). An accurate
18
estimation of the junction temperature requires a direct
measurement of the case temperature (TC) when actual
operating conditions significantly deviate from those
described in the JEDEC standards. The junction temperature is then:
TJ = TC + (PT x θJC)
Use 8.7°C/W as θJC thermal impedance for the 14-pin
TDFN package. The case-to-ambient thermal impedance (θCA) is dependent on how well the heat is transferred from the PCB to the ambient. Solder the exposed
pad of the TDFN package to a large copper area to
spread heat through the board surface, minimizing the
case-to-ambient thermal impedance. Use large copper
areas to keep the PCB temperature low.
PCB Layout Guidelines
Place all power components on the top side of the
board, and run the power stage currents using traces
or copper fills on the top side only. Make a star connection on the top side of traces to GND to minimize voltage drops in signal paths.
Keep the power traces and load connections short,
especially at the ground terminals. This practice is
essential for high efficiency and jitter-free operation. Use
thick copper PCBs (2oz or above) to enhance efficiency.
Place the MAX15026 adjacent to the synchronous rectifier MOSFET, preferably on the back side, to keep LX,
GND, DH, and DL traces short and wide. Use multiple
small vias to route these signals from the top to the bottom side. Use an internal quiet copper plane to shield
the analog components on the bottom side from the
power components on the top side.
Make the MAX15026 ground connections as follows:
create a small analog ground plane near the device.
Connect this plane to GND and use this plane for the
ground connection for the VIN bypass capacitor, compensation components, feedback dividers, VCC capacitor, RT resistor, and LIM resistor.
Use Kelvin sense connections for LX and GND to the
synchronous rectifier MOSFET for current limiting to
guarantee the current-limit accuracy.
Route high-speed switching nodes (BST, LX, DH, and DL)
away from the sensitive analog areas (RT, COMP, LIM,
and FB). Group all GND-referred and feedback components close to the device. Keep the FB and compensation
network as small as possible to prevent noise pickup.
______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Single 4.5V to 28V Supply Operation
Figure 5 shows an application circuit for a single 4.5V to 28V power-supply operation.
4.5V TO 28V
VIN
PANASONIC
EEEFCIE331P
C1
330µF
VCC
MAX15026
(
LX
C3
0.47µF
L1
1.4µH
LIM
DL
EN
DRV
)
COILCRAFT
MSS1278-142ML
VOUT
C5
22µF
C4
470µF
BST
PGOOD
PGOOD
ON-SEMICONDUCTOR
Q1 NTMFS4835NTIG
DH
IN
Q2
SANYO
4C54701
R1*
ENABLE
C6
2.2µF
GND
COMP
C7
68pF
R3
4.02kΩ
R4
27kΩ
C9
0.022µF
R5
10kΩ
R1
11.8kΩ
RT
FB
C8
68pF
( ON-SEMICONDUCTOR
)
NTMFS4835NTIG
R6
15.4kΩ
*R1 IS A SMALL-VALUE RESISTOR TO DECOUPLE
SWITCHING TRANSIENTS CAUSED BY THE
MOSFET DRIVER (2.2Ω).
C10
4.7µF
R7
4.02kΩ
C11
1500pF
Figure 5. VIN = 4.5V to 28V
______________________________________________________________________________________
19
MAX15026
Typical Application Circuits
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Typical Application Circuits (continued)
Single 4.5V to 5.5V Supply Operation
Figure 6 shows an application circuit for a single 4.5V to 5.5V power-supply operation.
4.5V TO 5.5V
VIN
DH
IN
VCC
MAX15026
Q1
LX
L1
CBST
BST
PGOOD
PGOOD
VOUT
CF1
ENABLE
LIM
DL
EN
DRV
Q2
C1
GND
COMP
RT
RT
FB
R3
C2
C3
RLIM
C4
R2
R1
Figure 6. VCC = VIN = VDRV = 4.5V to 5.5V
20
______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Auxiliary 5V Supply Operation
Figure 7 shows an application circuit for a +12V supply to drive the external MOSFETs and an auxiliary +5V supply
to power the device.
VIN
+12V
DH
IN
VCC
MAX15026
Q1
LX
L1
CBST
BST
PGOOD
PGOOD
VOUT
CF1
ENABLE
LIM
DL
EN
DRV
Q2
C1
GND
COMP
RT
RT
FB
R3
C2
C3
R2
RLIM
C4
R1
VAUX
4.5V TO 5.5V
Figure 7. Operation with Auxiliary 5V Supply
______________________________________________________________________________________
21
MAX15026
Typical Application Circuits (continued)
MAX15026
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
Package Information
Chip Information
PROCESS: BiCMOS
22
For the latest package outline information and land patterns
(footprints), go to www.maxim-ic.com/packages. Note that a
“+”, “#”, or “-” in the package code indicates RoHS status only.
Package drawings may show a different suffix character, but
the drawing pertains to the package regardless of RoHS status.
PACKAGE
TYPE
PACKAGE
CODE
OUTLINE NO.
LAND
PATTERN NO.
14 TDFN-EP
T1433+2
21-0137
90-0063
______________________________________________________________________________________
Low-Cost, Small, 4.5V to 28V Wide Operating
Range, DC-DC Synchronous Buck Controller
REVISION
NUMBER
REVISION
DATE
0
5/08
Initial release
1
5/09
Revised General Description, Ordering Information, Absolute Maximum
Ratings, Electrical Characteristics, Power-Good Output (PGOOD) section,
and Typical Application Circuits
1–4, 10, 15, 19
2
9/10
Added MAX15026C; revised General Description, Ordering Information,
Electrical Characteristics, Typical Operating Characteristics, and Startup
into a Prebiased Output sections
1–6, 10
3
4/11
Added automotive part to Ordering Information, Absolute Maximum Ratings,
and Electrical Characteristics
1, 2, 3
4
2/12
Design modified to meet customer requirements and new OPN added to
Ordering Information
DESCRIPTION
PAGES
CHANGED
—
1–6, 10, 11
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. The parametric values (min and max limits) shown in
the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.
23 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2012 Maxim Integrated Products
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX15026
Revision History