MAXIM MAX1980

19-2298; Rev 2; 9/02
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Applications
Notebook Computers
♦ Quick-PWM Slave Controller
♦ Precise, Active Current Balance (±1.25mV )
♦ Driver Disable Improves Light Load Efficiency
♦ Accurate, Adjustable Current-Limit Threshold
♦ Optimized for Low-Output Voltages (≤ 2V)
♦ 4V to 28V Battery Input Range
♦ Selectable 200kHz/300kHz/550kHz Switching
Frequency
♦ Drive Large Synchronous-Rectifier MOSFETs
♦ 525µA (typ) ICC Supply Current
♦ 20µA Standby Supply Current
♦ Compact 20-Pin 5mm ✕ 5mm QFN and Thin QFN
Packages
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX1980EGP*
-40°C to +100°C
20 QFN (5mm x 5mm)
MAX1980ETP
-40°C to +100°C
20 Thin QFN
(5mm x 5mm)
*Contact factory for availability.
LIMIT
V+
BST
TOP VIEW
ILIM
Pin Configuration
TRIG
The MAX1980 provides the same high-efficiency, ultralow duty factor capability, and excellent transient
response as other Quick-PWM controllers. The MAX1980
differentially senses the inductor currents of both the
master and the slave across current-sense resistors.
These differential inputs and the adjustable current-limit
threshold derived from an external reference allow the
slave controller to accurately balance the inductor currents and provide precise current-limit protection. The
MAX1980’s dual-purpose current-limit input also allows
the slave controller to automatically enter a low-power
standby mode when the master controller shuts down.
The MAX1980 features a driver-disable mode that forces
both gate drivers (DL and DH) low. While the MAX1980’s
drivers are disabled, the master controller can operate in
low-power skip mode, improving light-load efficiency.
Additionally, the MAX1980 includes selectable trigger
polarity, allowing the slave controller to trigger on the rising (out-of-phase) or falling (in-phase) edge of the master’s low-side gate driver. Out-of-phase operation
staggers the master and slave’s on-times, reducing the
input ripple current and consequently the number of
input capacitors. The MAX1980 also features a selectable 200kHz/300kHz/550kHz switching frequency. The
MAX1980 is available in compact 20-pin 5mm ✕ 5mm
QFN and thin QFN packages.
Features
20
19
18
17
16
CM+
1
15
LX
CM-
2
14
DH
TON
3
13
DD
CS-
4
12
VCC
CS+
5
11
VDD
MAX1980
Servers/Desktop Computers
Quick-PWM is a trademark of Maxim Integrated Products, Inc.
7
8
9
10
GND
PGND
DL
Two-Stage (5V to VCORE) Converters
6
COMP
Single-Stage (BATT to VCORE) Converters
POL
CPU Core Supply
QFN/THIN QFN
5mm x 5mm
Typical Operating Circuit appears at end of data sheet.
________________________________________________________________ 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
MAX1980
General Description
The MAX1980 step-down slave controller is intended for
low-voltage, high-current, multiphase DC-DC applications. The MAX1980 slave controller can be combined
with any of Maxim’s Quick-PWM™ step-down controllers
to form a multiphase DC-DC converter. Existing QuickPWM controllers, such as the MAX1718, function as the
master controller, providing accurate output-voltage regulation, fast transient response, and fault protection features. Synchronized to the master’s low-side gate driver,
the MAX1980 includes the Quick-PWM constant on-time
controller, gate drivers for a synchronous rectifier, active
current balancing, and precision current-limit circuitry.
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
ABSOLUTE MAXIMUM RATINGS
V+ to GND ..............................................................-0.3V to +30V
VCC, VDD to GND .....................................................-0.3V to +6V
PGND to GND.....................................................................±0.3V
TRIG, LIMIT to GND .................................................-0.3V to +6V
DD to GND ...............................................................-0.3V to +6V
ILIM, CM+, CM-, CS+, CS-, COMP
to GND....................................................-0.3V to (VCC + 0.3V)
TON, POL to GND ......................................-0.3V to (VCC + 0.3V)
DL to PGND................................................-0.3V to (VDD + 0.3V)
BST to GND ............................................................-0.3V to +36V
DH to LX ....................................................-0.3V to (VBST + 0.3V)
LX to BST..................................................................-6V to +0.3V
Continuous Power Dissipation (TA = +70°C)
20-Pin QFN (derate 20.0mW/°C above +70°C) .............1.60W
Operating Temperature Range .........................-40°C to +100°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, VOUT = VCOMP = 1.2V, VCM+ = VCM- = VCS+ = VCS- = 1.2V, DD = VCC, TA = 0°C to
+85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
PWM CONTROLLER
Input Voltage Range
On-Time (Note 1)
Trigger Delay (Note 2)
tON
Battery voltage, V+
4.0
28
VCC, VDD
4.5
5.5
V+ = 12V,
VCOMP = 1.2V
TON = GND
171
190
209
TON = open
320
355
390
TON = VCC
464
515
566
tTRIG
75
V
ns
ns
SUPPLY CURRENTS
2
Quiescent Supply Current (V+)
I+
Measured at V+; VILIM > 0.35V
25
40
µA
Quiescent Supply Current (VDD)
IDD
Measured at VDD; VILIM > 0.35V
Quiescent Supply Current (VCC)
ICC
Measured at VCC; VILIM > 0.35V
<1
5
µA
525
800
Standby Supply Current (V+)
Measured at V+; ILIM = GND
<1
µA
5
µA
Standby Supply Current (VDD)
Measured at VDD; ILIM = GND
<1
5
µA
Standby Supply Current (VCC)
Measured at VCC; ILIM = GND
20
40
µA
Driver-Disable Supply Current (V+)
Measured at V+; DD = GND, VILIM > 0.35V
25
40
µA
Driver-Disable Supply Current
(VDD)
Measured at VDD; DD = GND, VILIM > 0.35V
<1
5
µA
Driver-Disable Supply Current
(VCC)
Measured at VCC; DD = GND, VILIM > 0.35V
525
800
µA
_______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
(Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, VOUT = VCOMP = 1.2V, VCM+ = VCM- = VCS+ = VCS- = 1.2V, DD = VCC , TA = 0°C to
+85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
CURRENT SENSING
On-Time Adjustment Range
COMP Output Current
ICOMP
0.42V < VCOMP < 2.8V, VOUT ≥ 0.7V
-40
Sink and source
30
+40
%
µA
Current-Balance Offset
(VCM+ - VCM-) - (VCS+ - VCS-), ICOMP = 0,
-100mV ≤ (VCM+ - VCM-) ≤ +100mV
Current-Balance
Transconductance
(VCM+ - VCM-) - (VCS+ - VCS-) = ±25mV
Current-Sense, Common-Mode
Range
CM+, CM-, CS+, CS-
-0.2
+2.0
V
Current-Sense Input Current
CM+, CM-, CS+, CS-
-1
1
µA
Positive Current-Limit Threshold
VC_LIM
Negative Current-Limit
Threshold
VCM+ - VCM- and
VCS+ - VCSVCS+ - VCS-
-1.25
+1.25
1.2
mV
mS
VILIM = 0.5V
47.5
50
52.5
VILIM = 1V
97.5
100
102.5
VILIM = 0.5V
-80
-75
-70
VILIM = 1V
-160
-150
-140
mV
mV
ILIM Standby Threshold Voltage
0.2
0.3
V
ILIM Input Current
-100
100
nA
LIMIT Propagation Delay
tLIMIT
LIMIT Output Low Voltage
VOL(LIMIT)
LIMIT Leakage Current
ILIMIT
Falling edge, 3mV over trip threshold
1.5
ISINK = 1mA
LIMIT forced to 5.5V
< 0.01
µs
0.1
V
1
µA
3.85
V
FAULT PROTECTION
VCC Undervoltage Lockout
Threshold
Rising edge, hysteresis = 20mV, switching
disabled below this level
Thermal-Shutdown Threshold
Rising, hysteresis = 15°C (typ)
160
VBST - VLX forced to 5V
1.0
4.5
High state (pullup)
1.0
4.5
Low state (pulldown)
0.4
2.0
IDH
DH forced to 2.5V, VBST - VLX forced to 5V
1.3
A
DL Gate-Driver Sink Current
IDL
DL forced to 2.5V
4.0
A
DL Gate-Driver Source Current
IDL
DL forced to 2.5V
1.3
A
3.45
°C
GATE DRIVERS
DH Gate-Driver On-Resistance
(Note 3)
RON(DH)
DL Gate-Driver On-Resistance
(Note 3)
RON(DL)
DH Gate-Driver Source/Sink
Current
Dead Time
Driver Disable Delay
tDD
DL rising
35
DH rising
26
DD falling (Note 4)
225
1000
DD rising (Note 4)
65
1000
Ω
Ω
ns
ns
_______________________________________________________________________________________
3
MAX1980
ELECTRICAL CHARACTERISTICS (continued)
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, VOUT = VCOMP = 1.2V, VCM+ = VCM- = VCS+ = VCS- = 1.2V, DD = VCC , TA = 0°C to
+85°C, unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
LOGIC
POL Logic Levels
VPOL
VCC = 4.5V to 5.5V
DD Logic Levels
VDD
VCC = 4.5V to 5.5V
265mV hysteresis
VTRIG
350mV hysteresis
TRIG Logic Levels
High
High
VTON
0.8
2.4
Low
High
0.6
3.0
Low
Logic high (VCC; 200kHz operation)
TON Logic Levels
2.4
Low
Open (300kHz operation)
1.2
V
V
VCC - 0.4
1.6
3.1
Logic low (GND; 550kHz operation)
Logic Input Current
V
V
0.5
TRIG
-1
+1
DD
-1
+1
POL
-2
+1
TON = GND or VDD
-2
+3
µA
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, VOUT = VCOMP = 1.2V, VCM+ = VCM- = VCS+ = VCS- = 1.2V, DD = VCC, TA = -40°C
to +100°C, unless otherwise noted.) (Note 5)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
PWM CONTROLLER
On Time (Note 1)
tON
V+ = 12V,
VCOMP = 1.2V
TON = GND (550kHz)
171
209
TON = open (300kHz)
320
390
TON = VCC (200kHz)
464
566
ns
SUPPLY CURRENTS
4
Quiescent Supply Current (V+)
I+
Quiescent Supply Current (VDD)
IDD
Quiescent Supply Current (VCC)
ICC
Measured at V+; VILIM > 0.35V
40
µA
Measured at VDD; VILIM > 0.35V,
TA = -40°C to +85°C
5
µA
Measured at VCC; VILIM > 0.35V
800
µA
Standby Supply Current (V+)
Measured at V+; ILIM = GND,
TA = -40°C to +85°C
5
µA
Standby Supply Current (VDD)
Measured at VDD; ILIM = GND,
TA = -40°C to +85°C
5
µA
Standby Supply Current (VCC)
Measured at VCC; ILIM = GND
40
µA
Driver-Disable Supply Current
(V+)
Measured at V+; DD = GND, VILIM > 0.35V
40
µA
Driver-Disable Supply Current
(VDD)
Measured at VDD; DD = GND, VILIM >
0.35V, TA = -40°C to +85°C
5
µA
Driver-Disable Supply Current
(VCC)
Measured at VCC; DD = GND, VILIM > 0.35V
800
µA
_______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
(Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, VOUT = VCOMP = 1.2V, VCM+ = VCM- = VCS+ = VCS- = 1.2V, DD = VCC , TA = -40°C
to +100°C, unless otherwise noted.) (Note 5)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
CURRENT SENSING
On-Time Adjustment Range
COMP Output Current
ICOMP
0.42V < VCOMP < 2.8V, VOUT ≥ 0.7V
-40
Sink and source
30
+40
%
µA
Current-Balance Offset
(VCM+ - VCM-) - (VCS+ - VCS-), ICOMP = 0,
-100mV ≤ (VCM+ - VCM-) ≤ +100mV
-2.0
+2.0
mV
Current-Sense, Common-Mode
Range
CM+, CM-, CS+, CS-
-0.2
+2.0
V
Positive Current-Limit Threshold
VC_LIM
Negative Current-Limit
Threshold
47.5
52.5
VILIM = 1V
97
103
VILIM = 0.5V
-80
-70
VILIM = 1V
-160
-140
0.2
0.3
V
3.45
3.90
V
VBST - VLX forced to 5V
4.5
Ω
High state (pullup)
4.5
Low state (pulldown)
2.0
VCM+ - VCM- and
VCS+ - VCSVCS+ - VCS-
VILIM = 0.5V
ILIM Standby Threshold Voltage
mV
mV
FAULT PROTECTION
VCC Undervoltage Lockout
Threshold
Rising edge, hysteresis = 20mV, switching
disabled below this level
GATE DRIVERS
DH Gate-Driver On-Resistance
(Note 3)
RON(DH)
DL Gate-Driver On-Resistance
(Note 3)
RON(DL)
Ω
LOGIC
TRIG Logic Levels
VTRIG
TON Logic Levels
VTON
350mV hysteresis
High
3.0
Low
Logic high (VCC; 200kHz operation)
Open (300kHz operation)
Logic low (GND; 550kHz operation)
1.2
V
VCC - 0.4
1.6
3.1
V
0.5
Note 1: On-time specifications are measured from 50% point to 50% point at the DH pin with LX = PGND, VBST = 5V, and a 500pF
capacitor from DH to LX to simulate external MOSFET gate capacitance. Actual in-circuit times may be different due to
MOSFET switching speeds.
Note 2: The trigger delay time, tTRIG, is measured from the time the TRIG pin transitions to the time when the DL pin goes low.
Note 3: Production testing limitations due to package handling require relaxed maximum on-resistance specifications for the QFN
package.
Note 4: The driver-disable delay time (tDD) is measured from the time the DD pin transitions to the time when the DL or DH pin transitions.
Note 5: Specifications to -40°C and +100°C are guaranteed by design and not production tested.
_______________________________________________________________________________________
5
MAX1980
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(Circuit of Figure 1, V+ = 12V, VCC = VDD = 5V, VOUT = 1.3V (ZMODE = GND) and 1V (ZMODE = VCC), DD = VCC.)
TWO-PHASE
OUTPUT VOLTAGE vs. LOAD CURRENT
(VOUT = 1.3V, VOFFSET = -10mV)
50
VIN = 20V
40
1.25
1.24
1.23
10
1
60
VIN = 12V
50
VIN = 20V
30
20
0
100
70
40
1.20
0.1
10
20
30
40
50
1
0.1
10
100
LOAD CURRENT (A)
LOAD CURRENT (A)
LOAD CURRENT (A)
TWO-PHASE
OUTPUT VOLTAGE vs. LOAD CURRENT
(VOUT = 1V, VOFFSET = -10mV)
SINGLE-PHASE EFFICIENCY
vs. LOAD CURRENT
(VOUT = 1V)
NO-LOAD INPUT CURRENT
vs. INPUT VOLTAGE
0.99
100
VIN = 8.0V
VIN = 5.0V
EFFICIENCY (%)
0.97
0.96
0.95
70
INPUT CURRENT (mA)
90
0.98
80
80
VIN = 20V
VIN = 12V
70
0.94
MAX1980 toc06
VIN = 12.0V
MAX1980 toc04
1.00
OUTPUT VOLTAGE (V)
1.26
1.21
20
VIN = 5.0V
80
1.27
1.22
30
VIN = 8.0V
90
EFFICIENCY (%)
VIN = 12V
100
MAX1980 toc05
EFFICIENCY (%)
70
60
1.28
OUTPUT VOLTAGE (V)
VIN = 5V
80
VIN = 12V
1.29
MAX1980 toc02
VIN = 8V
90
1.30
MAX1980 toc01
100
TWO-PHASE
EFFICIENCY vs. LOAD CURRENT
(VOUT = 1V)
MAX1980 toc03
TWO-PHASE
EFFICIENCY vs. LOAD CURRENT
(VOUT = 1.3V)
60
IBIAS = IDD + ICC
50
40
IIN
30
20
0.93
10
MASTER AND SLAVE
0.92
60
0
10
20
30
40
0.01
0.10
1
5
10
15
20
25
30
INPUT VOLTAGE (V)
INDUCTOR CURRENT BALANCE
vs. LOAD CURRENT
INDUCTOR CURRENT BALANCE
vs. INPUT VOLTAGE
OFFSET-VOLTAGE DEVIATION
vs. CURRENT-SENSE COMMON-MODE VOLTAGE
0.4
0.4
0.3
IOUT = NO LOAD
0.2
0.2
0.1
20
30
LOAD CURRENT (A)
40
50
OUT = CM+ = CM- = CS+ = CS25
0
-25
-50
0
10
MAX1980 toc09
IOUT = 40A
0.5
50
OFFSET-VOLTAGE DEVIATION (µV)
0.6
IL(MASTER) - IL(SLAVE) (A)
0.6
MAX1980 toc08
0.7
MAX1980 toc07
0.8
0
0
100
10
LOAD CURRENT (A)
0
6
0
LOAD CURRENT (A)
1.0
INDUCTOR CURRENT OFFSET: ILM - ILS (A)
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
0
5
10
15
INPUT VOLTAGE (V)
20
25
-0.5
0
0.5
1.0
VOUT (V)
_______________________________________________________________________________________
1.5
2.0
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
COMPENSATION OUTPUT CURRENT
vs. CURRENT-SENSE VOLTAGE DIFFERENTIAL
60
40
ICOMP (mV)
0.1
0
-0.1
-0.3
0
-20
0.5
1.0
1.5
RISING (OUT-OF-PHASE)
250
200
150
-80
50
FALLING (IN-PHASE)
0
-150
-100
-50
0
50
100
150
0
0.5
1.0
1.5
2.0
VCS+ - VCS- (V)
OVERDRIVE VOLTAGE (V)
TRIGGER PROPAGATION DELAY
vs. OVERDRIVE VOLTAGE
POSITIVE CURRENT-LIMIT THRESHOLD
vs. ILIM VOLTAGE
DRIVER-DISABLE DELAY TIME
350
300
RISING (OUT-OF-PHASE)
FALLING (IN-PHASE)
150
100
50
0
MAX1980 toc14
140
120
MAX1980 toc15
5V
A
0
STANDBY MODE
400
160
POSITIVE CURRENT LIMIT (mV)
MAX1980 toc13
450
200
300
VCOMP (V)
500
250
350
100
2.0
ON-TIME TRIGGERED
ABOVE THE LINE
400
-60
-100
0
TRIGGER PROPAGATION DELAY (ns)
20
-40
-0.2
450
TRIGGER PULSE WIDTH (ns)
0.2
OUT = CM+ = CM- = CSICOMP = GM(VCS+ - VCS-)
80
500
MAX1980 toc11
OUT = CM+ = CM- = CS+ = CSOFFSET-VOLTAGE DEVIATION (mV)
100
MAX1980 toc10
0.3
MINIMUM TRIGGER PULSE WIDTH
vs. OVERDRIVE VOLTAGE
MAX1980 toc12
OFFSET-VOLTAGE DEVIATION
vs. COMPENSATION VOLTAGE
100
80
60
MASTER OR SLAVE
40
0
20
0
B
C
0
0
0.5
1.0
1.5
2.0
0
OVERDRIVE VOLTAGE (V)
0.5
1.0
1.5
A. DD = 5V to 0, 5V/div
B. MAX1980 LX, 5V/div
VILIM (V)
EXITING LOW-POWER OPERATION
ENTERING LOW-POWER OPERATION
DRIVER-ENABLE DELAY TIME
C. MAX1718 LX, 5V/div
NO LOAD
MAX1980 toc18
MAX1980 toc17
MAX1980 toc16
A
A
5V
0
0
0
A
1.3V
1.3V
B
B
1.0V
1.0V
C
C
B
0
0
C
A. DD = 0 to 5V, 5V/div
B. MAX1980 LX, 5V/div
C. MAX1718 LX, 5V/div
NO LOAD
0
0
D
0
40µs/div
A. LOWPWR = 0 TO 5V, 5V/div
B. VOUT = 1.3V TO 1.0V, 200mV/div
C. MAX1980 LX, 10V/div
D. MAX1718 LX, 10V/div
ZMODE = LOWPWR
D
0
20µs/div
A. LOWPWR = 5V TO 0, 5V/div
B. VOUT = 1.0V TO 1.3V, 200mV/div
C. MAX1980 LX, 10V/div
D. MAX1718 LX, 10V/div
ZMODE = LOWPWR
_______________________________________________________________________________________
7
MAX1980
Typical Operating Characteristics (continued)
(Circuit of Figure 1, V+ = 12V, VCC = VDD = 5V, VOUT = 1.3V (ZMODE = GND) and 1V (ZMODE = VCC), DD = VCC.)
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Typical Operating Characteristics (continued)
(Circuit of Figure 1, V+ = 12V, VCC = VDD = 5V, VOUT = 1.3V (ZMODE = GND) and 1V (ZMODE = VCC), DD = VCC.)
SWITCHING WAVEFORMS
(IN-PHASE)
SWITCHING WAVEFORMS
(OUT-OF-PHASE)
MAX1980 toc20
MAX1980 toc19
A
20mV/div
A
20mV/div
B
5A/div
20A
20A
B
5A/div
10V
10V
C
10V/div
0
C
10V/div
0
1µs/div
1µs/div
A. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD),
B. MASTER/SLAVE INDUCTOR CURRENTS
C. MASTER/SLAVE LX WAVEFORMS,
VIN = 12.0V, IOUT = 40A, POL = VCC
A. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD),
B. MASTER/SLAVE INDUCTOR CURRENTS
C. MASTER/SLAVE LX WAVEFORMS,
VIN = 12.0V, IOUT = 40A, POL = GND
LOAD TRANSIENT
(OUT-OF-PHASE)
LOAD TRANSIENT
(IN-PHASE)
MAX1980 toc22
MAX1980 toc21
40A
40A
A
40A/div
5A
B
50mV/div
1.282V
C
10A/div
D
10A/div
0
0
20µs/div
A. LOAD CURRENT, IOUT = 5A TO 40A
B. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD)
C. SLAVE INDUCTOR CURRENT
D. MASTER INDUCTOR CURRENT
VIN = 12.0V, POL = VCC
8
A
40A/div
B
50mV/div
5A
1.282V
C
10A/div
D
10A/div
0
0
20µs/div
A. LOAD CURRENT, IOUT = 5A TO 40A
B. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD)
C. SLAVE INDUCTOR CURRENT
D. MASTER INDUCTOR CURRENT
VIN = 12.0V, POL = GND
_______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
STARTUP WAVEFORM
(NO LOAD)
DYNAMIC OUTPUT-VOLTAGE TRANSITION
MAX1980 toc24
MAX1980 toc23
5.00V
A
5V/div
0
B
200mV/div
1.30V
1.10V
A
5V/div
5V
0
B
1.0V/div
1V
0
C
10A/div
D
10A/div
0
0
0
C
10A/div
0
D
10A/div
100µs/div
40µs/div
A. MASTER SHUTDOWN, VSHDN = 0 TO 5V
B. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD)
C. SLAVE INDUCTOR CURRENT
D. MASTER INDUCTOR CURRENT
A. ZMODE = 0 TO 5V
B. OUTPUT VOLTAGE, VOUT = 1.30V (ZMODE = GND)
OR 1.10V (ZMODE = VCC)
C. SLAVE INDUCTOR CURRENT
D. MASTER INDUCTOR CURRENT
STARTUP WAVEFORM
(20A LOAD)
SHUTDOWN WAVEFORM
MAX1980 toc26
MAX1980 toc25
A
5V/div
5V
0
B
1.0V/div
1V
A
5V/div
5V
0
B
1V/div
0
0
C
10A/div
C
10A/div
D
10A/div
0
0
100µs/div
A. MASTER SHUTDOWN, VSHDN = 5V TO 0
B. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD)
C. SLAVE INDUCTOR CURRENT
D. MASTER INDUCTOR CURRENT
0
D
10A/div
0
100µs/div
A. MASTER SHUTDOWN, VSHDN = 0 TO 5V
B. OUTPUT VOLTAGE, VOUT = 1.290V (NO LOAD)
C. SLAVE INDUCTOR CURRENT
D. MASTER INDUCTOR CURRENT
ROUT = 65mΩ (IOUT = 20A)
_______________________________________________________________________________________
9
MAX1980
Typical Operating Characteristics (continued)
(Circuit of Figure 1, V+ = 12V, VCC = VDD = 5V, VOUT = 1.3V (ZMODE = GND) and 1V (ZMODE = VCC), DD = VCC.)
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
MAX1980
Pin Description
PIN
NAME
1
CM+
Master Controller’s Positive Current-Sense Input
2
CM-
Master Controller’s Negative Current-Sense Input
TON
On-Time Selection Control Input. This is a three-level input used to determine the DH on time (see the
On-Time Control and Active Current Balancing section). Connect TON as follows for the indicated
switching frequencies:
GND = 550kHz
floating = 300kHz
VCC = 200kHz.
The slave controller’s switching frequency should be selected to closely match the frequency of the master
PWM controller.
4
CS-
Slave Controller’s Negative Current-Sense Input
5
CS+
Slave Controller’s Positive Current-Sense Input
6
COMP
7
POL
3
10
DESCRIPTION
Current Balance Compensation. Connect a series resistor and capacitor between COMP and OUT. See
the Current Balance Compensation section.
TRIG Polarity Select Input. Connect POL to VCC or float to trigger on the rising edge of TRIG (out-of-phase
operation). Connect POL to GND to trigger on the falling edge of TRIG (in-phase operation).
8
GND
9
PGND
Analog Ground. Connect the QFN’s exposed pad to analog ground.
10
DL
Low-Side Gate-Driver Output. DL swings from PGND to VDD. DL is forced low when the MAX1980 enters
standby mode or the drivers are disabled (DD = low).
11
VDD
Supply Voltage Input for the DL Gate Driver. Connect to the system supply voltage (4.5V to 5.5V).
Bypass to PGND with a 1µF or greater ceramic capacitor, as close to the IC as possible.
12
VCC
Analog Supply Voltage Input for PWM Core. Connect VCC to the system supply voltage (4.5V to 5.5V)
through a series 10Ω resistor. Bypass to GND with a 0.22µF or greater ceramic capacitor, as close to
the IC as possible.
13
DD
Driver Disable Input. A logic low disables the MAX1980 slave controller by forcing DL and DH low. This
reduces the number of phases, allowing single-phase operation for low-power states. Connect to VCC
for normal operation.
14
DH
High-Side Gate-Driver Output. DH swings from LX to BST.
15
LX
Inductor Connection. Connect LX to the switched side of the inductor. LX serves as the lower supply rail
for the DH high-side gate driver.
16
BST
Boost Flying-Capacitor Connection. Connect to an external capacitor and diode according to the
Standard Application Circuit (Figure 1). An optional resistor in series with BST allows DH pullup current
to be adjusted.
Power Ground
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
PIN
NAME
DESCRIPTION
17
V+
Battery Voltage Sense Connection. Connect V+ to the input power source. V+ is used only for PWM oneshot timing (see the On-Time Control and Active Current Balancing section).
18
LIMIT
Open-Drain Current-Limit Output. Connect to the master controller’s adjustable current-limit input (ILIM)
according to the Standard Application Circuit (Figure 1). When the voltage across the master controller’s
current-sense resistor (VCM+ - VCM-) exceeds the current-limit threshold (VILIM/10), the MAX1980 pulls
LIMIT low.
19
ILIM
Dual-Mode Current-Limit Adjustment and Standby Input. The current-limit threshold voltage is 1/10 the
voltage seen at ILIM (VILIM) over a 400mV to 1.5V range. If VILIM drops below 250mV, the slave
controller enters a low-power standby mode, forcing DL low and DH low.
20
TRIG
Trigger Input. Connect to the master controller’s low-side gate driver. The trigger input’s polarity is pin
selectable: POL = VCC or floating triggers on the rising edge (out-of-phase operation), and POL = GND
triggers on the falling edge (in-phase operation).
Table 1. Component Selection for Standard
Applications
COMPONENT
Output Voltage
CIRCUIT OF FIGURE 1
0.6V to 1.75V
Input Voltage Range
7V to 24V
Maximum Load Current
40A
Inductor (each phase)
0.6µH
Sumida CDEP134H-0R6 or
Panasonic ETQP6F0R6BFA
Frequency
300kHz (TON = float)
High-Side MOSFET
(NH, each phase)
International Rectifier
(2) IRF7811W
Low-Side MOSFET
(NL, each phase)
International Rectifier
(2) IRF7822 or
Fairchild (3) FDS7764A or
Input Capacitor (CIN)
(6) 10µF, 25V
Taiyo Yuden
TMK432BJ106KM or
TDK C4532X5R1E106M
Output Capacitor (COUT)
(8) 270µF, 2.0V
Panasonic EEFUE0E271R
Current-Sense Resistors
(RCS and RCM)
1.5mΩ
Voltage Positioning Gain
(AVPS)
1
Detailed Description
The MAX1980 step-down slave controller is intended for
low-voltage, high-current, multiphase DC-DC applications. The MAX1980 slave controller can be combined
with any of Maxim’s Quick-PWM step-down controllers to
form a multiphase DC-DC converter. When compared to
single-phase operation, multiphase conversion lowers the
peak inductor current by distributing the load current
between parallel power paths. This simplifies component
selection, power distribution to the load, and thermal layout. Existing Quick-PWM controllers, such as the
MAX1718, function as the master controller, providing
accurate output-voltage regulation, fast transient
response, and multiple fault-protection features.
Synchronized to the master’s low-side gate driver, the
MAX1980 includes a constant on-time controller, synchronous rectifier gate drive, active current balancing,
and precision current-limit circuitry.
On-Time Control and Active
Current Balancing
The MAX1980 slave controller uses a constant on-time,
voltage feed-forward architecture similar to Maxim’s
Quick-PWM controllers (Figure 2). The control algorithm
is simple: the high-side switch on-time is determined
solely by a one-shot whose period is inversely proportional to input voltage and directly proportional to the
compensation voltage (VCOMP). Another one-shot sets a
minimum off-time (130ns typical). The on-time one-shot
is triggered when the following conditions are satisfied:
The slave detects a transition on the TRIG input, the
slave controller’s inductor current is below its currentlimit threshold, and the minimum off time has expired.
______________________________________________________________________________________
11
MAX1980
Pin Description (continued)
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Table 2. Component Suppliers
PHONE
COUNTRY CODE
MANUFACTURER
WEBSITE
MOSFETS
Fairchild Semiconductor
1-888-522-5372
www.fairchildsemi.com
International Rectifier
1-310-322-3331
www.irf.com
Siliconix
1-203-268-6261
www.vishay.com
CAPACITORS
Kemet
1-408-986-0424
www.kemet.com
Panasonic
1-847-468-5624
www.panasonic.com
Sanyo
65-281-3226 (Singapore)
1-408-749-9714
www.secc.co.jp
03-3667-3408 (Japan)
1-408-573-4150
www.t-yuden.com
Coilcraft
1-800-322-2645
www.coilcraft.com
Coiltronics
1-561-752-5000
www.coiltronics.com
Sumida
1-408-982-9660
www.sumida.com
Taiyo Yuden
INDUCTORS
The trigger input’s polarity is selected by connecting
POL to VCC (rising edge) or to GND (falling edge).
At the slave controller’s core is the one-shot that sets
the high-side switch’s on-time. This fast, low-jitter oneshot adjusts the on-time in response to the input voltage and the difference between the inductor currents in
the master and the slave. Two identical transconductance amplifiers (GMM = GMS) integrate the difference
between the master and slave current-sense signals.
The summed output is connected to COMP, allowing
adjustment of the integration time constant with a compensation capacitor connected at COMP. The resulting
compensation current and voltage may be determined
by the following equations:
ICOMP = GMM (VCM+ - VCM- ) - GMS (VCS+ - VCS- )
VCOMP = VOUT + ICOMP Z COMP
where ZCOMP is the impedance at the COMP output.
The PWM controller uses this integrated signal (VCOMP)
to set the slave controller’s on time. When the master
and slave current-sense signals (CM+ to CM- and CS+
to CS-) become unbalanced, the transconductance
amplifiers adjust the slave controller’s on time, allowing
the slave inductor current to increase or decrease until
the current-sense signals are properly balanced:
12
V

t ON = K  COMP 
 VIN 
I
V

Z 
= K  OUT  + K  COMP C 
V
V


 IN 
IN
= (Master’s on time) + (Slave’s on-time
correction due to current imbalance)
This control algorithm results in balanced inductor currents with the slave switching frequency synchronized to
the master. Since the master operates at nearly constant
frequency, the slave will as well. The benefits of a constant switching frequency are twofold: first, the frequency
can be selected to avoid noise-sensitive regions of the
spectrum; second, the inductor ripple-current operating
point remains relatively constant, resulting in easy design
methodology and predictable output-voltage ripple.
Multiple phase switching effectively distributes the load
among the external components, thereby improving the
overall efficiency. Distributing the load current between
multiple phases lowers the peak inductor current by the
number of phases (1/η) when compared to a singlephase converter. This significantly reduces the I2R losses
across the inductor’s series resistance, the MOSFETs
on-resistance, and the board resistance.
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
VCC
VGATE
D0
D1
TO LOGIC
DAC
INPUTS
INPUT
8V TO 24V
CIN
(6) 10µF 25V CERAMIC
V+
DM
BST
CBST(M)
0.1µF
NH(M)
DH
S0
S1
SUSPEND
INPUTS
5V BIAS
SUPPLY
C1
1µF
VDD
D2
D3
D4
MAX1980
R6
10Ω
C2
0.22µF
RCM
1.5mΩ
LM
0.6µF
LX
ZMODE
SUS
MUX CONTROL
OPTIONAL LOW-POWER LOGIC
CCC
47pF
R17
0Ω
5V BIAS
SUPPLY
ON
OVP
R8
53.6kΩ
RFB
100Ω
MAX1718
TON
FB
CFB
1000pF
SKP/SDN
R22
30kΩ
NEG
R9
100kΩ
R23
20kΩ
POS
ILIM
C5
470pF
R25
10kΩ
R2
2.8kΩ
DS
R1
301kΩ
VDD
C3
1µF
FLOAT
(300kHz)
FB
(MASTER)
R18
1kΩ
V+
BST
R7
10Ω
LIMIT
VCC
C4
0.22µF
R19
100kΩ
R4
2kΩ
TRIG
5V BIAS
SUPPLY
5V BIAS
SUPPLY
R3
1kΩ
RTIME
62kΩ
TIME
R10
34.8kΩ
C10
1000pF
LOW
POWER
R5
1kΩ
REF
FLOAT
(300kHz)
R24
100kΩ
5V BIAS
SUPPLY
MAX4322
OFF
GND
CC
CREF
0.22µF
NL(M)
DL
CCOMP
470pF
MAX1980
CBST(S)
0.1µF
LX
LS
0.6µH
POL
RCOMP
10kΩ
TON
NL(S)
DL
OUTPUT
RCS
1.5mΩ
COUT
(8) 270µF
R13
200Ω
DD
C6
100pF
R21
2kΩ
PGND
COMP
REF
(MAX1718)
R11
113kΩ
C9
1000pF
R20
1kΩ
NH(S)
DH
CS+
C7
4700pF
R14
200Ω
CS-
POWER GROUND
ILIM
CM+
R12
30.1kΩ
C8
4700pF
GND
R15
200Ω
CM-
ANALOG GROUND
(MASTER)
ANALOG GROUND
(SLAVE)
R16
200Ω
Figure 1. Standard Application Circuit
______________________________________________________________________________________
13
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Q
MAX1980
ILIM
TRIG
DD
TOFF
ONE-SHOT
BST
STANDBY
DH
0.25V
LX
VCC
PWM
CONTROLLER
SUPPLY
CONTROLLER
BIAS
TRIG
Q
TON
ONE-SHOT
R
Q
S
Q
VDD
DL
TON
PGND
ON-TIME
COMPUTE
V+
COMP
CS-
Q
GMS
CS+
NEGATIVE
CS LIMIT
POSITIVE
CS LIMIT
TRIG
EDGE
DETECTOR
TRIG
POL
CM+
GMM
CM-
17R
ILIM
R
LIMIT
2R
GND
POSITIVE
CM LIMIT
Figure 2. Functional Diagram
In-Phase and Out-of-Phase Operation
Multiphase systems can stagger the on times of each
phase (out-of-phase operation) or simultaneously turn
on all phases at the beginning of a new cycle (in-phase
operation). When configured for out-of-phase operation, high input-to-output differential voltages (VIN >
η V OUT ) prevent the on times from overlapping.
14
Therefore, the instantaneous input-current peaks of
each phase do not overlap, resulting in reduced inputand output-voltage ripple and RMS ripple current. This
lowers the input- and output-capacitor requirements,
which allows fewer or less expensive capacitors, and
decreases shielding requirements for EMI. When the on
times overlap at low input-to-output differential voltages
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
During in-phase operation, the input capacitors must
support large, instantaneous input currents when the
high-side MOSFETs turn on simultaneously, resulting in
increased ripple voltage and current when compared
to out-of-phase operation. The higher RMS ripple current degrades efficiency due to power loss associated
with the input capacitor’s effective series resistance
(ESR). This typically requires a large number of lowESR input capacitors in parallel to meet input ripple
current ratings or minimize ESR-related losses.
The polarity select input (POL) determines whether rising edges (POL = VCC) or falling edges (POL = GND)
trigger a new cycle. For low duty-cycle applications
(duty factor < 50%), triggering on the rising edge of the
master’s low-side gate driver prevents both high-side
MOSFETs from turning on at the same time. Staggering
the phases in this way lowers the input ripple current,
thereby reducing the input capacitor requirements. For
applications operating with approximately a 50% duty
factor, out-of-phase operation (POL = VCC) causes the
slave controller to complete an on-pulse coincident to
the master controller determining when to initiate its
next on time. The noise generated when the slave controller turns off its high-side MOSFET could compromise the master controller’s feedback voltage and
current-sense inputs, causing inaccurate decisions that
lead to more jitter in the switching waveforms. Under
these conditions, triggering off of the falling edge (POL
= GND) of the master’s low-side gate driver forces the
controllers to operate in-phase, improving the system’s
noise immunity.
5V Bias Supply (VCC and VDD)
The MAX1980 requires an external 5V bias supply in
addition to the battery. Typically this 5V bias supply is
the notebook’s 95% efficient 5V system supply.
Keeping the bias supply external to the IC improves
efficiency, eliminates power dissipation limitations, and
removes the cost associated with the internal, 5V linear
regulator that would otherwise be needed to supply the
PWM circuit and gate drivers. If standalone capability is
needed, the 5V supply can be generated with an external linear regulator.
The MAX1980 has a separate analog PWM supply voltage input (VCC) and gate-driver supply input (VDD).
The battery input (V+) and 5V bias inputs (VCC and
VDD) can be tied together if the input source is a fixed
4.5V to 5.5V supply.
The maximum current required from the 5V bias supply
to power VCC (PWM controller) and VDD (gate-drive
power) is:
IBIAS = ICC + fSW(QG1 + QG2) = 10mA to 45mA (typ)
where I CC is 525µA typical, f SW is the switching
frequency, and QG1 and QG2 are the MOSFET data
sheets’ total gate-charge specification limits at
VGS = 5V.
Driver Disable
When DD is driven low, the MAX1980 disables the drivers by forcing DL and DH low, effectively disabling the
slave controller. Disabling the MAX1980 for singlephase operation allows the master controller to enter
low-power pulse-skipping operation under light load
conditions.
When DD is driven high, the MAX1980 enables the drivers, allowing normal PWM operation (see the On-time
Control and Active Current Balancing section). Since
the slave controller cannot skip pulses, the master controller should be configured for forced-PWM operation
while the MAX1980’s drivers are enabled. This PWM
control scheme forces the low-side gate drive waveform to be the complement of the high-side gate drive
waveform, allowing the inductor current to reverse.
During negative load and downward output-voltage
transitions, forced-PWM operation allows the converter
to sink current, rapidly pulling down the output voltage.
Another benefit of forced-PWM operation, the switching
frequency remains relatively constant over the full load
and input voltage ranges.
Standby Mode
The MAX1980 slave controller enters a low-power
standby mode when the ILIM voltage (V ILIM) drops
below 250mV (Table 4). Standby forces DL and DH
low, and disables the PWM controller to inhibit switching; however, the bias and fault-protection circuitry
remain active so the MAX1980 can continuously monitor the ILIM input. When VILIM is driven above 250mV,
the PWM controller is enabled.
Table 3. Approximate K-Factor Errors
TON
CONNECTION
FREQUENCY
K-FACTOR
SETTING
(µs)
(kHz)
MAX
K-FACTOR
ERROR
(%)
VCC
200
5
10
Float
300
3.3
10
GND
550
1.8
10
______________________________________________________________________________________
15
MAX1980
(VIN < ηVOUT), the input currents of the overlapping
phases may sum together, increasing the total input
and output ripple voltage and RMS ripple current.
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Table 4. Operating Mode Truth Table
DD
ILIM
DL
MODE
VCC
High
(> 0.25V)
Switching
Normal
Operation
GND
High
(> 0.25V)
Low
Driver
Disable
Light load, single-phase operation. The MAX1980 disables the drivers
by forcing DL and DH low, effectively disabling the slave controller.
X
GND
(< 0.25V)
Standby
Low-power, standby mode (ICC + IDD = 20µA typ). DL and DH
forced low, and the PWM controller disabled. However, the bias and
fault-protection circuitry remain active so the MAX1980 can
continuously monitor the ILIM input.
Low
COMMENTS
Low-noise, fixed-frequency, PWM operation. The inductor current
reverses with light loads.
X = Don’t Care
When the slave controller’s current-limit voltage (VILIM) is
set through a resistive-divider between the master controller’s reference and GND (see the Current-Limit
Circuitry section), the MAX1980 automatically enters lowpower standby mode when the master controller shuts
down. As the master’s reference powers down, the resistive-divider pulls ILIM below 250mV, automatically activating the MAX1980’s low-power standby mode.
Current-Limit Circuitry
When the master’s inductor current exceeds its valley
current limit, the master extends its off time by forcing
DL high until the inductor current falls below the currentlimit threshold. Without a transition on the master’s lowside gate driver, the slave cannot initiate a new on-time
pulse so the slave’s inductor current ramps down as
well, maintaining the current balance. Therefore, the
slave’s valley current limit only needs to protect the
slave controller if the current balance circuitry or the
master current limit fails. The slave’s ILIM input voltage
should be selected to properly adjust the master’s current-limit threshold.
Dual-Mode ILIM Input
The current-limit input (ILIM) features dual-mode operation, serving as both the standby mode control input
and the current-limit threshold adjustment. The slave
controller enters a low-power standby mode when the
ILIM voltage (VILIM) is pulled below 250mV. For ILIM
voltages from 400mV to 1.5V, the current-limit threshold
voltage is precisely 0.1 ✕ VILIM. The current-limit voltage may be accurately set with a resistive voltagedivider between the master controller’s reference and
GND, allowing the MAX1980 to automatically enter the
low-power standby mode.
Slave Current Limit
The slave current-limit circuit employs a unique “valley”
current-sensing algorithm. If the current-sense signal is
16
above the current-limit threshold, the MAX1980 will not initiate a new cycle (Figure 3). The actual peak inductor current is greater than the current-limit threshold by an
amount equal to the inductor ripple current. Therefore, the
exact current-limit characteristic and maximum load
capability are a function of the current-limit threshold,
inductor value, and input voltage. The reward for this
uncertainty is robust, overcurrent sensing. When combined with master controllers that contain output undervoltage protection circuits, this current-limit method is
effective in almost every circumstance.
There also is a negative current limit that prevents
excessive reverse inductor currents when VOUT is sinking current. The negative current-limit threshold is set to
approximately 150% of the positive current-limit threshold, and tracks the positive current limit when ILIM is
adjusted.
The MAX1980 uses CS+ and CS- to differentially measure
the current across an external sense resistor (RCS) connected between the inductor and output capacitors. This
configuration provides precise current balancing, current
limiting, and voltage positioning with a 1% current-sense
resistor. Reducing the sense voltage decreases power
dissipation but increases the relative measurement error.
Carefully observe the PC board layout guidelines to
ensure that noise and DC errors don’t corrupt the current-sense signals measured at CS+ and CS-. The IC
should be mounted relatively close to the current-sense
resistor with short, direct traces making a Kelvin sense
connection.
Master Current-Limit Adjustment (LIMIT)
The Quick-PWM controllers that may be used as the
master controller typically use the low-side MOSFET’s
on-resistance as its current-sense element. This dependence on a loosely specified resistance with a large temperature coefficient causes inaccurate current limiting.
As a result, high current-limit thresholds are needed to
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
IPEAK
INDUCTOR CURRENT
ILOAD
ILIMIT
ILIMIT(VALLEY) = ILOAD(MAX)
(
2 - LIR
2η
)
0
TIME
Figure 3. “Valley” Current-Limit Threshold Point
guarantee full-load operation under worst-case conditions. Furthermore, the inaccurate current limit mandates
the use of MOSFETs and inductors with excessively high
current and power dissipation ratings.
The slave includes a precision current-limit comparator
that supplements the master’s current-limit circuitry.
The MAX1980 uses CM+ and CM- to differentially
sense the master’s inductor current across a currentsense resistor, providing a more accurate current limit.
When the master’s current-sense voltage exceeds the
current limit set by ILIM in the slave (see the Dual-Mode
ILIM Input section), the open-drain current-limit comparator pulls LIMIT low (Figure 2). Once the master triggers the current limit, a pulse-width-modulated output
signal appears at LIMIT. This signal is filtered and used
to adjust the master’s current-limit threshold.
The internal pulldown transistor that drives DL low is
robust, with a 0.4Ω (typ) on-resistance. This helps prevent 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. However, for high-current applications, some
combinations of high- and low-side FETs may cause
excessive gate-drain coupling, leading to poor efficiency, EMI, and shoot-through currents. This is often remedied by adding a resistor less than 5Ω in series with
BST, which increases the turn-on time of the high-side
FET without degrading the turn-off time (Figure 4).
INPUT
(VIN)
CBYP
V+
High-Side Gate Driver Supply (BST)
The gate drive voltage for the high-side, N-channel
MOSFET is generated by the flying capacitor boost circuit (Figure 4). The capacitor between BST and LX is
alternately charged from the external 5V bias supply
(VDD) and placed in parallel with the high-side MOSFET’s gate-source terminals.
On startup, the synchronous rectifier (low-side MOSFET) forces LX to ground and charges the boost
capacitor to 5V. On the second half of each cycle, the
switch-mode power supply turns on the high-side MOSFET by closing an internal switch between BST and DH.
This provides the necessary gate-to-source voltage to
turn on the high-side switch, an action that boosts the
5V gate drive signal above the system’s main supply
voltage (V+).
DBST
BST
(RBST)*
CBST
DH
NH
L
LX
MAX1980
( )*OPTIONAL—THE RESISTOR REDUCES
THE SWITCHING-NODE RISE TIME.
Figure 4. High-Side Gate Driver Boost Circuitry
______________________________________________________________________________________
17
MAX1980
MOSFET Gate Drivers (DH, DL)
The DH and DL drivers are optimized for driving moderately sized, high-side and larger, low-side power
MOSFETs. This is consistent with the low duty factor
seen in the notebook CPU environment, where a large
VIN - VOUT differential exists. An adaptive dead-time circuit monitors the DL output and prevents the high-side
FET from turning on until DL is fully off. There must be a
low-resistance, low-inductance path from the DL driver
to the MOSFET gate in order for the adaptive dead-time
circuit to work properly. Otherwise, the sense circuitry in
the MAX1980 will interpret the MOSFET gate as “off”
while there is actually charge still left on the gate. Use
very short, wide traces (50mils to 100mils wide if the
MOSFET is 1 inch from the device). The dead time at
the other edge (DH turning off) is determined by a fixed
35ns internal delay.
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Undervoltage Lockout
During startup, the VCC undervoltage lockout (UVLO)
circuitry forces the DL and the DH gate drivers low,
inhibiting switching until an adequate supply voltage is
reached. Once VCC rises above 3.75V, valid transitions
detected at the trigger input initiate a corresponding
on-time pulse (see the On-Time Control and Active
Current Balancing section). To ensure correct startup,
the MAX1980 slave controller’s undervoltage lockout
voltage must be lower than the master controller’s
undervoltage lockout voltage.
If the VCC voltage drops below 3.75V, it is assumed that
there is not enough supply voltage to make valid decisions. To protect the output from overvoltage faults, DL
and DH are forced low, effectively disabling the
MAX1980.
Thermal-Fault Protection
The MAX1980 features a thermal-fault-protection circuit.
When the junction temperature rises above +160°C, a
thermal sensor activates the standby logic, which pulls
DL and DH low. The thermal sensor reactivates the
slave controller after the junction temperature cools by
15°C.
Design Procedure
Firmly establish the input voltage range and maximum
load current before choosing a switching frequency
and inductor operating point (ripple-current ratio). The
primary design trade-off lies in choosing a good switching frequency and inductor operating point, and the following four factors dictate the rest of the design:
Input Voltage Range: The maximum value (VIN(MAX))
must accommodate the worst-case high AC adapter
voltage. The minimum value (VIN(MIN)) must account for
the lowest input voltage after drops due to connectors,
fuses, and battery selector switches. If there is a choice
at all, lower input voltages result in better efficiency.
Maximum Load Current: There are two values to consider. The peak load current (ILOAD(MAX)) determines
the instantaneous component stresses and filtering
requirements, and thus drives output capacitor selection, inductor saturation rating, and the design of the
current-limit circuit. The continuous load current (ILOAD)
determines the thermal stresses and thus drives the
selection of input capacitors, MOSFETs, and other critical heat-contributing components. Modern notebook
CPUs generally exhibit ILOAD = ILOAD(MAX) ✕ 80%.
For multiphase systems, each phase supports a fraction of the load, depending on the current balancing.
The highly accurate current sensing and balancing
18
implemented by the MAX1980 slave controller evenly
distributes the load among each phase:
I
ILOAD(SLAVE) = ILOAD(MASTER) = LOAD
η
where η is the number of phases.
Switching Frequency: This choice determines the
basic trade-off between size and efficiency. The optimal frequency is largely a function of maximum input
voltage, due to MOSFET switching losses that are proportional to frequency and VIN2. The optimum frequency also is a moving target, due to rapid improvements
in MOSFET technology that are making higher frequencies more practical.
Setting Switch On Time: The constant on-time control
algorithm in the master results in a nearly constant
switching frequency despite the lack of a fixed-frequency clock generator. In the slave, the high-side switch on
time is inversely proportional to V+ and directly proportional to the compensation voltage (VCOMP):
V

t ON = K  COMP 
 VIN 
where K is set by the TON pin-strap connection (Table 3).
Set the nominal on time in the slave to match the on
time in the master. An exact match is not necessary
because the MAX1980 have wide t ON adjustment
ranges (±40%). For example, if tON in the master is set
to 250kHz, the slave can be set to either 200kHz or
300kHz and still achieve good performance. Care
should be taken to ensure that the COMP voltage
remains within its output voltage range (0.42V to 2.80V).
Inductor Operating Point: This choice provides tradeoffs between size vs. efficiency and transient response
vs. output noise. Low inductor values provide better
transient response and smaller physical size, but also
result in lower efficiency and higher output noise due to
increased ripple current. The minimum practical inductor value is one that causes the circuit to operate at the
edge of critical conduction (where the inductor current
just touches zero with every cycle at maximum load).
Inductor values lower than this grant no further sizereduction benefit. The optimum operating point is usually found between 20% and 50% ripple current.
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Setting the Current Limits
The master and slave current-limit thresholds must be
great enough to support the maximum load current,
even under worst-case operating conditions. Since the
master’s current limit determines the maximum load
(see the Current-Limit Circuitry section), the procedure
for setting the current limit is sequential. First, the master’s current limit is set based on the operating conditions and the characteristics of the low-side MOSFETs.
Then the slave controller is configured to adjust the
master’s current-limit threshold based on the precise
current-sense resistor value and variation in the MOSFET characteristics. Finally, the resulting valley current
limit for the slave’s inductor occurs above the master’s
current-limit threshold. This is acceptable since the
slave’s inductor current limit only serves as a fail-safe in
case the master and slave inductor currents become
significantly unbalanced during a transient.
The basic operating conditions are determined using
the same calculations provided in any Quick-PWM regulator data sheet. The valley of the inductor current
(ILIMIT(VALLEY)) occurs at ILOAD(MAX) divided by the
number of phases minus half of the peak-to-peak
inductor current:
L=
VOUT x (VIN - VOUT ) x η
VIN x fSW x ILOAD(MAX) x LIR
where η is the number of phases. Example: η = 2,
ILOAD = 40A, VIN = 12V, VOUT = 1.3V, fSW = 300kHz,
30% ripple current or LIR = 0.3:
L=
1.3V x (12V - 1.3V ) x 2
12V x 300kHz x 40A x 0.3
= 0.64µH
Find a low-loss inductor having the lowest possible DC
resistance that fits in the allotted dimensions. Ferrite
cores are often the best choice, although powdered
iron is inexpensive and can work well at 200kHz. The
core must be large enough not to saturate at the peak
inductor current (IPEAK):
 2 + LIR 
IPEAK = ILOAD(MAX) 

 2η 
where η is the number of phases.
Transient Response
The inductor ripple current affects transient-response
performance, especially at low VIN - VOUT differentials.
Low inductor values allow the inductor current to slew
faster, replenishing charge removed from the output filter capacitors by a sudden load step. The amount of
output sag also is a function of the maximum duty factor, which can be calculated from the on time and minimum off time:
(
L ∆ILOAD(MAX)
VSAG =


K
+ tOFF(MIN) 
) 2  VOUT
VIN 



 (VIN − VOUT )K 

2ηCOUTVOUT 
- tOFF(MIN) 

VIN



where t OFF(MIN) is the minimum off time (see the
Electrical Characteristics), η is the number of phases,
and K is from Table 3.
The amount of overshoot due to stored inductor energy
can be calculated as:
VSOAR
2
∆ILOAD(MAX) ) L
(
≈
 ILOAD(MAX)   ∆IINDUCTOR 
ILIMIT(VALLEY) ≥ 

 − 

η
2


where the peak-to-peak inductor current may be determined by the following equation:
∆IINDUCTOR =
VOUT (VIN − VOUT )
VINfSWL
The master’s high current-limit threshold must be set
high enough to support the maximum load current,
even when the master’s current-limit threshold is at its
minimum tolerance value, as described in the master
controller’s data sheet. Most Quick-PWM controllers
that may be chosen as the master controller use the
low-side MOSFET’s on-resistance to sense the inductor
current. In these applications, the worst-case maximum
value for R DS(ON) plus some margin for the rise in
RDS(ON) over temperature must be used to determine
the master’s current-limit threshold. A good general rule
is to allow 0.5% additional resistance for each °C of
temperature rise. Set the master current-limit threshold
to support the maximum load current for the maximum
RDS(ON) and minimum current-limit tolerance value:
VITHM(HIGH) ≥ (ILIMIT(VALLEY))RDS(ON)(MAX)
2ηCOUT VOUT
______________________________________________________________________________________
19
MAX1980
Inductor Selection
The switching frequency and operating point (% ripple
or LIR) determine the inductor value as follows:
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
SLAVE
CONTROLLER
MASTER
CONTROLLER
RC
ILIM
REF
VITHM(HIGH) =
1  RB 
VREF
10  RA + RB 
VITHM(LOW) =

RB // RLIMIT
1 
VREF

10  RA + (RB // RLIMIT ) 
CREF
RD
MAX1980
MAX1718
RA
RLIMIT
LIMIT
ILIM
CLIMIT
RB
VITHS =
1  RD 
VREF
10  RC + RD 
Figure 5. Setting the Adjustable Current Limits
where VITHM, the master’s current-limit threshold, is typically 1/10th the voltage seen at the master’s ILIM input
(V ITHM = 0.1 ✕ V LIM(MASTER) , see the master controller’s data sheet). Connect a resistive voltage-divider
from the master controller’s internal reference to GND,
with the master’s ILIM input connected to the center tap
(Figure 5). Use 1% tolerance resistors in the divider with
10µA to 20µA DC bias current to prevent significant
errors due to the ILIM pin’s input current:
VILIM(MASTER)
20µA
≤ RB ≤
VILIM(MASTER)
10µA
 VREF(MASTER)  
RA = 
 − 1RB
 VILIM(MASTER)  
Configure the slave controller so its LIMIT output begins
to roll off after the master current-limit threshold occurs:
 VITHM(HIGH)

VITHS ≥ RCM 
+ ∆IINDUCTOR 
 RDS(ON)(MAX)

where VITHS, the slave’s current-limit threshold, is precisely one-tenth the voltage seen at the slave’s ILIM
input (VITHS = 0.1 ✕ VILIM(SLAVE)). Connect a second
resistive voltage-divider from the master controller’s
internal reference to GND, with the slave’s ILIM input
connected to the center tap (Figure 5). The external
adjustment range of 400mV to 1.5V corresponds to a
current-limit threshold of 40mV to 150mV. Use 1% tolerance resistors in the divider with 10µA to 20µA DC bias
current to prevent significant errors due to the ILIM
pin’s input current. Reducing the current-limit threshold
20
voltage lowers the sense resistor’s power dissipation,
but this also increases the relative measurement error:
VILIM(SLAVE)
20µA
≤ RD ≤
VILIM(SLAVE)
10µA
 VREF(MASTER)  
RC = 
 − 1RD
 VILIM(SLAVE)  
Now, set the current-limit adjustment ratio (A ADJ =
VITHM(HIGH)/VITHM(LOW)) greater than the maximum to
minimum on-resistance ratio (ARDS = RDS(ON)(MAX)/
RDS(ON)(MIN)):
A ADJ ≥ AROS
 R // R  RDS(ON)(MAX)
1+  A B  ≥
 RLIMIT  RDS(ON)(MIN)
Increasing AADJ improves the master’s current-limit
accuracy but also increases the current limit’s noise
sensitivity. Therefore, RLIMIT may be selected using the
following equation:
RLIMIT ≤
(RA // RB )RDS(ON)(MIN)
RDS(ON)(MAX) − RDS(ON)(MIN)
Finally, verify that the total load on the master’s reference does not exceed 50µA:

  VREF 
VREF
IBIAS(TOTAL) = 
 +
 ≤ 50µA
 RA + (RB // RLIMIT )   RC + RD 
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
∆IINDUCTOR =
1.3V x (12V - 1.3V )
12V x 300kHz x 0.6µH
= 6.4A
 50A   1

ILIMIT( VALLEY) = 
 -  x 6.4A = 21.8A
 2  2

2) Determine the master’s current-limit threshold from
the valley current limit and low-side MOSFETs’ maximum on-resistance over temperature:
VITH(MASTER) ≥ 21.8A ✕ 6mΩ = 130mV
Now select the resistive-divider values (RA and RB
in Figure 5) to set the appropriate voltage at the
master’s ILIM input:
 10 x 130mV   10 x 130mV 
RB = 
 to 
 = 65kΩ to 130kΩ
20µA   10µA


Selecting RB = 100kΩ ±1% provides the following
value for RA:


2V
RA = 
− 1 x 100kΩ ≈ 54kΩ
 10 x 130mV 
3) Determine the slave’s current-limit threshold:
 130mV

VITHS ≥ 1.5mΩ x 
+ 6.4A ≈ 42mV
 6mΩ

Select the resistive-divider values (RC and RD in
Figure 5) to set the appropriate voltage at the
slave’s ILIM input:
 10 x 42mV   10 x 42mV 
RD = 
 to 
 = 21kΩ to 42kΩ
 20µA   10µA 
Selecting RD = 30.1kΩ ±1% provides the following
value for RA:


2V
RC = 
- 1 x 30.1kΩ ≈ 113kΩ
10
x
42
mV


4) Determine RLIMIT (Figure 5) from the above equation:
RLIMIT ≤
(53.6kΩ //100kΩ) x 3mΩ ≈ 35kΩ
6mΩ - 3mΩ
5) Finally, verify that that the total bias currents do not
exceed the 50µA maximum load of the master’s reference:


2V
IBIAS(TOTAL) = 
+
 54kΩ + (100kΩ // 34.8kΩ) 
2V



 = 36µA
 30.1kΩ + 113kΩ 
When unadjusted, the on-resistance variation of the
low-side MOSFETs results in a maximum current-limit
variation (∆ILIMIT) determined by the following equation:
 A

RDS − 1
Unadjusted ∆ILIMIT = VITHM(HIGH) 

 RDS(ON)(MAX) 
where ARDS = RDS(ON)(MAX)/RDS(ON)(MIN). Using the
MAX1980 to adjust the master’s current-limit threshold
results in a maximum current-limit variation less than
the peak-to-peak inductor current:
Adjusted ∆ILIMIT ≤ ∆IINDUCTOR
As shown in Figure 6, the resulting current-limit variation of the master is dramatically reduced. For the
above example, this control scheme reduces the current-limit variation from 21.7A (unadjusted) to less than
6.4A (adjusted).
Output Capacitor Selection
The output filter capacitor must have low enough ESR to
meet output ripple and load-transient requirements, yet
have high enough ESR to satisfy stability requirements.
In CPU VCORE converters and other applications where
the output is subject to large load transients, the output
capacitor selection typically depends on how much
ESR is needed to prevent the output from dipping too
low under a load transient. Ignoring the sag due to
finite capacitance:
RESR ≤
VSTEP
∆ILOAD(MAX)
______________________________________________________________________________________
21
MAX1980
Current Limit Design Example
For the typical application circuit shown in Figure 1 VIN
= 12V, VOUT = 1.3V, fSW = 300kHz, η = 2, ILOAD(MAX)
= 50A, L = 0.6µH, RDS(ON)(MAX) = 6mΩ, RDS(ON)(MIN )
= 3mΩ.
1) Determine the peak-to-peak inductor current and
the valley current limit:
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
SLAVE CURRENT-LIMIT VOLTAGES
vs. AVERAGE INDUCTOR CURRENT
160
V
IADJ(MIN) = IPEAK = ITHS
RCM
VITHM(HIGH)
140
VOLTAGE (mV)
120
MASTER
CONTROLLER
100
VITHM(LOW)
80
RCMILM(PEAK) = RCSILS(PEAK)
60
RCMILM(VALLEY) = RCSILS(VALLEY)
40
SLAVE
CONTROLLER
VITHS
20
∆IADJ - ∆IINDUCTOR =
0
0
10
20
30
40
[
]
VOUT(VIN - VOUT)
VINfSWL
50
AVERAGE INDUCTOR CURRENT (A)
MASTER CURRENT-LIMIT VOLTAGES
vs. AVERAGE INDUCTOR CURRENT
160
UNADJUSTED ∆ILIMIT ≤ ∆ILIMIT = VITHM(HIGH)
140
VITHM(HIGH)
VOLTAGE (mV)
120
(
)
ARDS - 1
RDS(ON)(MAX)
ADJUSTED ∆ILIMIT ≤ ∆IINDUCTOR
100
80
60
VITHM(LOW)
RDS(ON)(MIN) = LLM(VALLEY)
40
RDS(ON)(MIN) = LLM(VALLEY)
20
0
0
10
20
30
40
50
AVERAGE INDUCTOR CURRENT (A)
Figure 6. Master/Slave Current-Limit Thresholds
In non-CPU applications, the output capacitor selection
often depends on how much ESR is needed to maintain
an acceptable level of output ripple voltage. The output
ripple voltage of a step-down controller equals the total
inductor ripple current multiplied by the output capacitor’s ESR. When operating multiphase systems out-ofphase, the peak inductor currents of each phase are
staggered, resulting in lower output ripple voltage by
reducing the total inductor ripple current. For out-ofphase operation, the maximum ESR to meet ripple
requirements is:
RESR ≤
22
VRIPPLE

 η   VIN − ηVOUT   VOUT 
− ( η − 1)VOUT t TRIG 
  



 L  
fSW
  VIN 

This equation may be rewritten as the single phase ripple current minus a correction due to the additional
phases:
RESR ≤
VRIPPLE


 VOUT 
 (t ON + t TRIG )
ILOAD(MAX)LIR − η( η − 1)
L 


where t TRIG is the MAX1980’s trigger propagation
delay, η is the number of phases, and K is from Table
3. When operating the MAX1980 in-phase (POL =
GND), the high-side MOSFETs turn on together, so the
output capacitors must simultaneously support the
combined inductor ripple currents of each phase.
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
RESR ≤
VRIPPLE
VRIPPLE
=
ILOAD(MAX)LIR  η   VOUT 
 f L   V  (VIN − VOUT )
 SW   IN 
The actual capacitance value required relates to the
physical size needed to achieve low ESR, as well as to
the chemistry of the capacitor technology. Thus, the
capacitor is usually selected by ESR and voltage rating
rather than by capacitance value (this is true of tantalums, OS-CONs, and other electrolytics).
When using low-capacity filter capacitors such as
ceramic or polymer types, capacitor size is usually
determined by the capacity needed to prevent VSAG
and VSOAR from causing problems during load transients. Generally, once enough capacitance is added to
meet the overshoot requirement, undershoot at the rising load edge is no longer a problem (see the VSAG and
VSOAR equations in the Transient Response section).
Output Capacitor Stability Considerations
For Quick-PWM controllers, stability is determined by
the value of the ESR zero relative to the switching frequency. The boundary of instability is given by the following equation:
f
fESR ≤ SW
π
where fESR =
1
2πRESRCOUT
For a standard 300kHz application, the ESR zero frequency must be well below 95kHz, preferably below
50kHz. Tantalum, Sanyo POSCAP, and Panasonic SP
capacitors in wide-spread use at the time of publication
have typical ESR zero frequencies below 30kHz. In the
standard application used for inductor selection, the
ESR needed to support a 30mVP-P ripple is 30mV/(40A
x 0.3) = 2.5mΩ. Eight 270µF/2.0V Panasonic SP capacitors in parallel provide 1.9mΩ (max) ESR. Their typical
combined ESR results in a zero at 39kHz.
Do not put high-value ceramic capacitors directly
across the output without taking precautions to ensure
stability. Ceramic capacitors have a high ESR zero frequency and may cause erratic, unstable operation.
However, it’s easy to add enough series resistance by
placing the capacitors a couple of centimeters downstream from the junction of the inductor and FB pin.
Unstable operation manifests itself in two related but
distinctly different ways: double-pulsing and feedback
loop instability. Double-pulsing occurs due to noise on
the output or because the ESR is so low that there isn’t
enough voltage ramp in the output voltage signal. This
“fools” the error comparator into triggering a new cycle
immediately after the minimum off-time period has
expired. Double-pulsing is more annoying than harmful,
resulting in nothing worse than increased output ripple.
However, it can indicate the possible presence of loop
instability due to insufficient ESR. Loop instability can
result in oscillations at the output after line or load
steps. Such perturbations are usually damped, but can
cause the output voltage to rise above or fall below the
tolerance limits.
The easiest method for checking stability is to apply a
very fast zero-to-max load transient and carefully
observe the output voltage ripple envelope for overshoot and ringing. It can help to simultaneously monitor
the switching waveforms (VLX and/or IINDUCTOR). Don’t
allow more than one cycle of ringing after the initial
step-response under/overshoot.
Input Capacitor Selection
The input capacitor must meet the ripple current requirement (IRMS) imposed by the switching currents. The
MAX1980 multiphase slave controllers operate out-ofphase (POL = VCC or float), staggering the turn-on times
of each phase. This minimizes the input ripple current by
dividing the load current among independent phases:


I
 VOUT (VIN − VOUT )

IRMS =  LOAD  
VIN

 η 


for out-of-phase operation.
When operating the MAX1980 in-phase (POL = GND),
the high-side MOSFETs turn on simultaneously, so
input capacitors must support the combined input ripple currents of each phase:
 V

OUT (VIN − VOUT )

IRMS = ILOAD 
VIN




for in-phase operation.
For most applications, nontantalum chemistries (ceramic,
aluminum, or OS-CON) are preferred because of their
resilience to inrush surge currents typical of systems with
a mechanical switch or connector in series with the input.
______________________________________________________________________________________
23
MAX1980
For in-phase operation, the maximum ESR to meet ripple requirements is:
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
If the master/slave converter is operated as the second
stage of a two-stage power-conversion system, tantalum input capacitors are acceptable. In either configuration, choose an input capacitor that exhibits less than
+10°C temperature rise at the RMS input current for
optimal circuit longevity.
Power MOSFET Selection
Most of the following MOSFET guidelines focus on the
challenge of obtaining high load-current capability
when using high-voltage (>20V) AC adapters. Low-current applications usually require less attention.
The high-side MOSFET (NH) must be able to dissipate
the resistive losses plus the switching losses at both
VIN(MIN) and VIN(MAX). Calculate both of these sums.
Ideally, the losses at VIN(MIN) should be roughly equal
to losses at VIN(MAX), with lower losses in between. If
the losses at VIN(MIN) are significantly higher than the
losses at VIN(MAX), consider increasing the size of NH.
Conversely, if the losses at VIN(MAX) are significantly
higher than the losses at VIN(MIN), consider reducing
the size of NH. If VIN does not vary over a wide range,
the minimum power dissipation occurs where the resistive losses equal the switching losses.
Choose a low-side MOSFET that has the lowest possible on-resistance (R DS(ON)), comes in a moderatesized package (i.e., one or two SO-8s, DPAK or
D2PAK), and is reasonably priced. Make sure that the
DL gate driver can supply sufficient current to support
the gate charge and the current injected into the parasitic gate-to-drain capacitor caused by the high-side
MOSFET turning on; otherwise, cross-conduction problems may occur.
MOSFET Power Dissipation
Worst-case conduction losses occur at the duty factor
extremes. For the high-side MOSFET (NH), the worstcase power dissipation due to resistance occurs at the
minimum input voltage:
2
V
 I

PD(NH Re sistive) =  OUT   LOAD  RDS(ON)
 VIN   η 
Generally, a small high-side MOSFET is desired to
reduce switching losses at high input voltages.
However, the RDS(ON) required to stay within package
power-dissipation often limits how small the MOSFET
can be. Again, the optimum occurs when the switching
losses equal the conduction (RDS(ON)) losses. Highside switching losses don’t usually become an issue
until the input is greater than approximately 15V.
24
Calculating the power dissipation of the high-side
MOSFET (NH) due to switching losses is difficult since it
must allow for difficult quantifying factors that influence
the turn-on and turn-off times. These factors include the
internal gate resistance, gate charge, threshold voltage, source inductance, and PC board layout characteristics. The following switching-loss calculation
provides only a very rough estimate and is no substitute for breadboard evaluation, preferably including
verification using a thermocouple mounted on NH:
PD(NH
2
VIN(MAX) ) CRSSfSWILOAD
(
Switching) =
IGATE η
where CRSS is the reverse transfer capacitance of NH
and IGATE is the peak gate-drive source/sink current
(1A typ).
Switching losses in the high-side MOSFET can become
an insidious heat problem when maximum AC adapter
voltages are applied, due to the squared term in the C
2
✕ VIN ✕ ƒSW switching-loss equation. If the high-side
MOSFET chosen for adequate RDS(ON) at low battery
voltages becomes extraordinarily hot when biased from
V IN(MAX) , consider choosing another MOSFET with
lower parasitic capacitance.
For the low-side MOSFET (NL), the worst-case power
dissipation always occurs at maximum input voltage:
2
  V
  I

OUT
LOAD


PD(NL Re sistive) = 1− 
 RDS(ON)
 
  VIN(MAX)   η 
The worst case for MOSFET power dissipation occurs
under heavy overloads that are greater than ILOAD(MAX)
but are not quite high enough to exceed the current limit
and cause the fault latch to trip. To protect against this
possibility, “overdesign” the circuit to tolerate:
 ILOAD(MAX)LIR 
ILOAD = ηIVALLEY(MAX) + 

2


where I VALLEY(MAX) is the maximum valley current
allowed by the current-limit circuit, including threshold
tolerance and on-resistance variation. The MOSFETs
must have a good-sized heatsink to handle the overload power dissipation.
Choose a Schottky diode (D1) with a forward voltage low
enough to prevent the low-side MOSFET body diode
from turning on during the dead time. As a general rule,
select a diode with a DC current rating equal to 1/(3η) of
the load current. This diode is optional and can be
removed if efficiency is not critical.
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
Setting Voltage Positioning
Voltage positioning dynamically lowers the output voltage in response to the load current, reducing the
processors power dissipation. When the output is
loaded, an external operational amplifier (Figure 7)
increases the signal fed back to the master’s feedback
input. The additional gain provided by the op amp
allows the use of low-value current-sense resistors, significantly reducing the power dissipated in the currentsense resistors when connecting the feedback voltage
directly to the current sense resistor. The load transient
response of this control loop is extremely fast yet well
controlled, so the amount of voltage change can be
accurately confined within the limits stipulated in the
microprocessor power supply guidelines. To understand the benefits of dynamically adjusting the output
voltage, see the Voltage Positioning and Effective
Efficiency section.
The voltage positioned circuit determines the load current
from the voltage across the current-sense resistors
(RSENSE = RCM = RCS) connected between the inductors
and output capacitors, as shown in Figure 7. The voltage
drop may be determined by the following equation:
MASTER
LM
5V BIAS
SUPPLY
FB
(MASTER)
RFB
RCM
RB
RA
MAX4322
BOARD
RESISTANCE
CFB
RC
RD = RA
RE = RB
SLAVE
LS
RCS = RCM
Figure 7. Voltage Positioning Gain
 ηRC   ILOAD 
VVPS = 1+

 RSENSE
RB   η 

1 R 
VVPS =  + C  ILOADRSENSE
 η RB 
where η is the number of phases summed together.
When the slave controller is disabled, the current-sense
summation maintains the proper voltage positioned
slope. Select the positive input summing resistors (RA =
RD) using the following equation:
RA = RB || ( ηRC )
Applications Information
Voltage Positioning and
Effective Efficiency
Powering new mobile processors requires careful
attention to detail to reduce cost, size, and power dissipation. As CPUs became more power hungry, it was
recognized that even the fastest DC-DC converters
were inadequate to handle the transient power requirements. After a load transient, the output instantly
changes by ESRCOUT ✕ ∆ILOAD. Conventional DC-DC
converters respond by regulating the output voltage
back to its nominal state after the load transient occurs
(Figure 8). However, the CPU only requires that the output voltage remain above a specified minimum value.
Dynamically positioning the output voltage to this lower
______________________________________________________________________________________
25
MAX1980
Current-Balance Compensation (COMP)
The current-balance compensation capacitor (CCOMP)
integrates the difference of the master and slave current-sense signals, while the compensation resistor
improves transient response by increasing the phase
margin. This allows the user to optimize the dynamics
of the current-balance loop. Excessively large capacitor values increase the integration time constant, resulting in larger current differences between the phases
during transients. Excessively small capacitor values
allow the current loop to respond cycle-by-cycle but
can result in small DC current variations between the
phases. Likewise, excessively large series resistance
can also cause DC current variations between the
phases. Small series resistance reduces the phase
margin, resulting in marginal stability in the current-balance loop. For most applications, a 470pF capacitor
and 10kΩ series resistor from COMP to the converter’s
output voltage works well.
The compensation network can be tied to V OUT to
include the feed-forward term due to the master’s on
time. (See the On-Time Control and Active Current
Balancing section.) To reduce noise pick-up in applications that have a widely distributed layout, it is sometimes helpful to connect the compensation network to
quiet analog ground rather than VOUT.
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
CAPACITIVE SOAR
(dV/dt = IOUT/COUT)
VOLTAGE POSITIONING THE OUTPUT
ESR VOLTAGE STEP
(ISTEP x RESR)
A
1.4V
VOUT
1.4V
B
A. CONVENTIONAL CONVERTER (50mV/div)
B. VOLTAGE-POSITIONED OUTPUT (50mV/div)
CAPACITIVE SAG
(dV/dt = IOUT/COUT)
RECOVERY
ILOAD
Figure 8. Voltage Positioning the Output
Figure 9. Transient Response Regions
limit allows the use of fewer output capacitors and
reduces power consumption under load.
which results in an overall power savings of:
For a conventional (nonvoltage-positioned) circuit, the
total voltage change is:
VP-P1 = 2 ✕ (ESRCOUT ✕ ∆ILOAD) + VSAG + VSOAR
where VSAG and VSOAR are defined in Figure 9. Setting
the converter to regulate at a lower voltage when under
load allows a larger voltage step when the output current suddenly decreases (Figure 8). So the total voltage
change for a voltage-positioned circuit is:
VP-P2 = (ESRCOUT ✕ ∆ILOAD) + VSAG + VSOAR
where V SAG and V SOAR are defined in the Design
Procedure section. Since the amplitudes are the same
for both circuits (VP-P1 = VP-P2), the voltage-positioned
circuit tolerates twice the ESR. Since the ESR specification is achieved by paralleling several capacitors, fewer
units are needed for the voltage-positioned circuit.
An additional benefit of voltage positioning is reduced
power consumption at high load currents. Since the
output voltage is lower under load, the CPU draws less
current. The result is lower power dissipation in the
CPU, although some extra power is dissipated in
R SENSE . For a nominal 1.6V, 22A output (R LOAD =
72.7mΩ), reducing the output voltage 2.9% gives an
output voltage of 1.55V and an output current of 21.3A.
Given these values, CPU power consumption is
reduced from 35.2W to 33.03W. The additional power
consumption of RSENSE is:
50mV x 21.3A = 1.06W,
26
35.2W - (33.03W + 1.06W) = 1.10W.
In effect, 2.2W of CPU dissipation is saved and the
power supply dissipates much of the savings, but both
the net savings and the transfer of dissipation away
from the hot CPU are beneficial. Effective efficiency is
defined as the efficiency required of a nonvoltage-positioned circuit to equal the total dissipation of a voltagepositioned circuit for a given CPU operating condition.
Calculate effective efficiency as follows:
1) Start with the efficiency data for the positioned circuit (VIN, IIN, VOUT, IOUT).
2) Model the load resistance for each data point:
RLOAD = VOUT / IOUT
3) Calculate the output current that would exist for each
RLOAD data point in a nonpositioned application:
INP = VNP / RLOAD
where VNP = 1.6V (in this example).
4) Calculate effective efficiency as:
Effective efficiency = (VNP ✕ INP) / (VIN ✕ IIN) = calculated nonpositioned power output divided by the
measured voltage-positioned power input.
5) Plot the efficiency data point at the nonpositioned
current, INP.
The effective efficiency of voltage-positioned circuits is
shown in the Typical Operating Characteristics.
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
The MAX1980 can be used with a direct battery connection (one stage) or can obtain power from a regulated 5V supply (two-stage). Each approach has
advantages, and careful consideration should go into
the selection of the final design.
The one-stage approach offers smaller total inductor
size and fewer capacitors overall due to the reduced
demands on the 5V supply. Due to the high input voltage, the one-stage approach requires lower DC input
currents, reducing input connection/bus requirements
and power dissipation due to input resistance. The
transient response of the single stage is better due to
the ability to ramp the inductor current faster. The total
efficiency of a single stage is better than the two-stage
approach.
The two-stage approach allows flexible placement due
to smaller circuit size and reduced local power dissipation. The power supply can be placed closer to the
CPU for better regulation and lower I2R losses from PC
board traces. Although the two-stage design has slower transient response than the single stage, this can be
offset by the use of a voltage-positioned converter.
Ceramic Output Capacitor Applications
Ceramic capacitors have advantages and disadvantages. They have ultra-low ESR and are noncombustible, relatively small, and nonpolarized. However,
they are also expensive and brittle, and their ultra-low
ESR characteristic can result in excessively high ESR
zero frequencies. In addition, their relatively low capacitance value can cause output overshoot when stepping from full-load to no-load conditions, unless a small
inductor value is used (high switching frequency), or
there are some bulk tantalum or electrolytic capacitors
in parallel to absorb the stored inductor energy. In
some cases, there may be no room for electrolytics,
creating a need for a DC-DC design that uses nothing
but ceramics.
The MAX1980 can take full advantage of the small size
and low ESR of ceramic output capacitors in a voltagepositioned circuit. The addition of the positioning resistor increases the ripple at FB, lowering the effective
ESR zero frequency of the ceramic output capacitor.
Output overshoot (V SOAR) determines the minimum
output capacitance requirement (see the Output
Capacitor Selection section). Often the switching frequency is increased to 550kHz, and the inductor value
is reduced to minimize the energy transferred from
inductor to capacitor during load-step recovery. The
efficiency penalty for operating at 550kHz is about 3%
when compared to the 300kHz circuit, primarily due to
the high-side MOSFET switching losses.
PC Board Layout Guidelines
Careful PC board layout is critical to achieve low
switching losses and clean, stable operation. The
switching power stage requires particular attention
(Figure 10). If possible, mount all of the power components on the top side of the board with their ground terminals flush against one another. Follow these
guidelines for good PC board layout:
1) Keep the high-current paths short, especially at the
ground terminals. This is essential for stable, jitterfree operation
2) Connect all analog grounds to a separate solid
copper plane, which connects to the GND pin of
the MAX1980. This includes the VCC bypass capacitor, COMP components, and the resistive-divider
connected to ILIM.
3) The master controller also should have a separate
analog ground. Return the appropriate noise sensitive components to this plane. Since the reference
in the master is sometimes connected to the slave,
it may be necessary to couple the analog ground in
the master to the analog ground in the slave to prevent ground offsets. A low value (≤10Ω) resistor is
sufficient to link the two grounds.
4) Keep the power traces and load connections short.
This is essential for high efficiency. The use of thick
copper PC boards (2oz vs. 1oz) can enhance fullload efficiency by 1% or more. Correctly routing PC
board traces is a difficult task that must be
approached in terms of fractions of centimeters,
where a single mΩ of excess trace resistance causes a measurable efficiency penalty.
5) Keep the high-current gate-driver traces (DL, DH,
LX, and BST) short and wide to minimize trace
resistance and inductance. This is essential for
high-power MOSFETs that require low-impedance
gate drivers to avoid shoot-through currents.
6) CS+, CS-, CM+, and CM- connections for current
limiting and balancing must be made using Kelvin
sense connections to guarantee the current-sense
accuracy.
7) When trade-offs in trace lengths must be made, it’s
preferable to allow the inductor charging path to be
made longer than the discharge path. For example,
it’s better to allow some extra distance between the
input capacitors and the high-side MOSFET than to
allow distance between the inductor and the low-
______________________________________________________________________________________
27
MAX1980
One-Stage (Battery Input) vs.
Two-Stage (5V Input) Applications
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
MAX1718
(MASTER)
MAX1980
(SLAVE)
CONNECT THE EXPOSED
PAD TO GND
VIA TO POWER
GROUND
VIA TO POWER
GROUND
CONNECT GND AND PGND
BENEATH THE CONTROLLER AT
ONE POINT ONLY AS SHOWN
≤10Ω
MASTER
VIA TO CM+
AND FB
SLAVE
LM
DM
LS
DS
VIA TO CS+
COUT
COUT
COUT
COUT
VIA TO CM-
VIA TO CSCOUT
POWER
GROUND
COUT
COUT
TOP LAYER
COUT
OUTPUT
MASTER
SLAVE
INPUT (V+)
CIN
CIN
CIN
CIN
CIN
CIN
CIN
CIN
POWER
GROUND
BOTTOM LAYER
Figure 10. Power-Stage PC Board Layout Example
28
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
5V BIAS
SUPPLY
VDD
V+
VCC
BST
POL
REF
(MASTER)
INPUT
DH
DD
LX
ILIM
DL
OUTPUT
MAX1980
FLOAT
(300kHz)
TON
ILIM
(MASTER)
LIMIT
PGND
CS+
FB
(MASTER)
COMP
CSCM+
CM-
GND
TRIG
side MOSFET or between the inductor and the output filter capacitor.
8) Route high-speed switching nodes away from sensitive analog areas (COMP, ILIM). Make all pinstrap control input connections (SHDN, ILIM, POL)
to analog ground or VCC rather than power ground
or VDD.
Layout Procedure
1) Place the power components first, with ground terminals adjacent (low-side MOSFET source, CIN, COUT,
and D1 anode). If possible, make all these connections on the top layer with wide, copper-filled areas.
2) Mount the controller IC adjacent to the low-side
MOSFET. The DL gate trace must be short and
wide (50mils to 100mils wide if the MOSFET is 1
inch from the controller IC).
3) Group the gate-drive components (BST diode and
capacitor, VDD bypass capacitor) together near the
controller IC.
4) Make the DC-DC controller ground connections as
shown in Figure 1. This diagram can be viewed as
having four separate ground planes: input/output
ground, where all the high-power components go;
the power ground plane, where the PGND pin and
V DD bypass capacitor go; the master’s analog
MASTER CURRENTSENSE RESISTOR
MASTER LOW-SIDE GATE DRIVER
ground plane where sensitive analog components,
the master’s GND pin and VCC bypass capacitor
go; and the slave’s analog ground plane where the
slave’s GND pin, and VCC bypass capacitor go.
The master’s GND plane must meet the PGND
plane only at a single point directly beneath the IC.
Similarly, the slave’s GND plane must meet the
PGND plane only at a single point directly beneath
the IC. The respective master and slave ground
planes should connect to the high-power output
ground with a short metal trace from PGND to the
source of the low-side MOSFET (the middle of the
star ground). This point must also be very close to
the output capacitor ground terminal.
5) Connect the output power planes (VCORE and system ground planes) directly to the output filter
capacitor positive and negative terminals with multiple vias. Place the entire DC-DC converter circuit
as close to the CPU as is practical.
Chip Information
TRANSISTOR COUNT: 1424
PROCESS: BiCMOS
______________________________________________________________________________________
29
MAX1980
Typical Operating Circuit
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.)
32L QFN .EPS
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
30
______________________________________________________________________________________
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
______________________________________________________________________________________
31
MAX1980
Package Information (continued)
(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.)
Package Information (continued)
(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.)
D2
0.15 C A
D
b
CL
0.10 M C A B
D2/2
D/2
PIN # 1
I.D.
QFN THIN 5x5x0.8 .EPS
MAX1980
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
k
0.15 C B
PIN # 1 I.D.
0.35x45
E/2
E2/2
CL
(NE-1) X e
E
E2
k
L
DETAIL A
e
(ND-1) X e
CL
CL
L
L
e
e
0.10 C
A
C
0.08 C
A1 A3
PROPRIETARY INFORMATION
TITLE:
PACKAGE OUTLINE
16, 20, 28, 32L, QFN THIN, 5x5x0.8 mm
APPROVAL
32
DOCUMENT CONTROL NO.
REV.
21-0140
C
______________________________________________________________________________________
1
2
Quick-PWM Slave Controller with
Driver Disable for Multiphase DC-DC Converter
COMMON DIMENSIONS
EXPOSED PAD VARIATIONS
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.
TITLE:
PACKAGE OUTLINE
16, 20, 28, 32L, QFN THIN, 5x5x0.8 mm
10. WARPAGE SHALL NOT EXCEED 0.10 mm.
APPROVAL
DOCUMENT CONTROL NO.
REV.
21-0140
C
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 ____________________ 33
© 2002 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.
MAX1980
Package Information (continued)
(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.)