MAXIM MAX1710EEG

19-4781; Rev 1; 7/00
KIT
ATION
EVALU
E
L
B
A
AVAIL
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
The MAX1710/MAX1711 step-down controllers are
intended for core CPU DC-DC converters in notebook
computers. They feature a triple-threat combination of
ultra-fast transient response, high DC accuracy, and
high efficiency needed for leading-edge CPU core
power supplies. Maxim’s proprietary Quick-PWM™
quick-response, constant-on-time PWM control scheme
handles wide input/output voltage ratios with ease and
provides 100ns “instant-on” response to load transients
while maintaining a relatively constant switching frequency.
High DC precision is ensured by a 2-wire remote-sensing scheme that compensates for voltage drops in both
the ground bus and supply rail. An on-board, digital-toanalog converter (DAC) sets the output voltage in compliance with Mobile Pentium II® CPU specifications.
The MAX1710 achieves high efficiency at a reduced
cost by eliminating the current-sense resistor found in
traditional current-mode PWMs. Efficiency is further
enhanced by an ability to drive very large synchronousrectifier MOSFETs.
Single-stage buck conversion allows these devices to
directly step down high-voltage batteries for the highest
possible efficiency. Alternatively, 2-stage conversion
(stepping down the +5V system supply instead of the
battery) at a higher switching frequency allows the minimum possible physical size.
The MAX1710/MAX1711 are identical except that the
MAX1711 have 5-bit DACs and the MAX1710 has a 4bit DAC. Also, the MAX1711 has a fixed overvoltage
protection threshold at VOUT = 2.25V and undervoltage
protection at VOUT = 0.8V whereas the MAX1710 has
variable thresholds that track VOUT. The MAX1711 is
intended for applications where the DAC code may
change dynamically.
Features
♦ Ultra-High Efficiency
♦ No Current-Sense Resistor (Lossless ILIMIT)
♦ Quick-PWM with 100ns Load-Step Response
♦ ±1% VOUT Accuracy over Line and Load
♦ 4-Bit On-Board DAC (MAX1710)
♦ 5-Bit On-Board DAC (MAX1711/MAX1712)
♦ 0.925V to 2V Output Adjust Range
(MAX1711/MAX1712)
♦ 2V to 28V Battery Input Range
♦ 200/300/400/550kHz Switching Frequency
♦ Remote GND and VOUT Sensing
♦ Over/Undervoltage Protection
♦ 1.7ms Digital Soft-Start
♦ Drive Large Synchronous-Rectifier FETs
♦ 2V ±1% Reference Output
♦ Power-Good Indicator
♦ Small 24-Pin QSOP Package
Ordering Information
PART
TEMP. RANGE
PIN-PACKAGE
MAX1710EEG
-40°C to +85°C
24 QSOP
MAX1711EEG
-40°C to +85°C
24 QSOP
Minimal Operating Circuit
BATTERY
4.5V TO 28V
+5V INPUT
VCC
Applications
OVP*
SHDN
Notebook Computers
FBS
ILIM
Docking Stations
GNDS
CPU Core DC-DC Converters
VDD
V+
BST
DH
MAX1710
MAX1711
REF MAX1712 LX
Single-Stage (BATT to VCORE) Converters
Two-Stage (+5V to VCORE) Converters
CC
OUTPUT
0.925V TO 2V
(MAX1711/MAX1712)
DL
D0
Quick-PWM is a trademark of Maxim Integrated Products.
D/A
INPUTS
Mobile Pentium II is a registered trademark of Intel Corp.
Pin Configurations appear at end of data sheet.
*MAX1710 ONLY
**MAX1711/MAX1712 ONLY
D1
PGND
D2
FB
D3
SKIP
D4** GND
________________________________________________________________ Maxim Integrated Products
1
For price, delivery, and to place orders, please contact Maxim Distribution at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX1710/MAX1711/MAX1712
General Description
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
ABSOLUTE MAXIMUM RATINGS
V+ to GND ..............................................................-0.3V to +30V
VCC, VDD to GND .....................................................-0.3V to +6V
PGND to GND.....................................................................±0.3V
SHDN, PGOOD to GND ...........................................-0.3V to +6V
OVP, ILIM, FB, FBS, CC, REF, D0–D4,
GNDS, TON to GND ..............................-0.3V to (VCC + 0.3V)
SKIP to GND (Note 1).................................-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 (BST + 0.3V)
LX to BST..................................................................-6V to +0.3V
REF Short Circuit to GND ...........................................Continuous
Continuous Power Dissipation (TA = +70°C)
24-Pin QSOP (derate 9.5mW/°C above +70°C)..........762mW
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +165°C
Lead Temperature (soldering, 10s) .................................+300°C
Note 1: SKIP may be forced below -0.3V, temporarily exceeding the absolute maximum rating, for the purpose of debugging prototype breadboards using the no-fault test mode. Limit the current drawn to -5mA maximum.
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, VBATT = 15V, VCC = VDD = 5V, SKIP = GND, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
MAX
UNIT
28
VCC, VDD
4.5
5.5
DAC codes from 1.3V to 2V
VBATT = 4.5V to 28V, includes
DAC codes from 0.925V
load regulation error
to 1.275V
-1
1
DC Output Voltage Accuracy
-1.2
1.2
Load Regulation Error
ILOAD = 0 to 7A
9
mV
Remote-Sense Voltage Error
FB - FBS or GNDS - GND = 0 to 25mV
3
mV
Line Regulation Error
VCC = 4.5V to 5.5V, VBATT = 4.5V to 28V
FB Input Bias Current
FB (MAX1710 only) or FBS
FB Input Resistance
(MAX1711/MAX1712)
5
-0.2
130
GNDS Input Bias Current
180
-1
Soft-Start Ramp Time
Rising edge of SHDN to full ILIM
On-Time
TON = GND (550kHz)
VBATT = 24V, TON = REF (400kHz)
FB = 2V
TON = open (300kHz)
(Note 2)
TON = VCC (200kHz)
Minimum Off-Time
(Note 2)
Quiescent Supply Current (VCC)
Quiescent Supply Current (VDD)
V
%
mV
0.2
µA
240
kΩ
1
1.7
µA
ms
140
160
180
175
200
225
260
290
320
380
425
470
400
500
ns
Measured at VCC, FB forced above the regulation point
600
950
µA
Measured at VDD, FB forced above the regulation point
<1
5
µA
Quiescent Battery Supply Current Measured at V+
2
TYP
2
Input Voltage Range
Battery voltage, V+
ns
25
40
µA
Shutdown Supply Current (VCC)
SHDN = 0
<1
5
µA
Shutdown Supply Current (VDD)
SHDN = 0
<1
5
µA
Shutdown Battery Supply
Current
SHDN = 0, measured at V+ = 28V, VCC = VDD = 0 or 5V
<1
5
µA
Reference Voltage
VCC = 4.5V to 5.5V, no external REF load
2
2.02
V
Reference Load Regulation
IREF = 0 to 50µA
REF Sink Current
REF in regulation
REF Fault Lockout Voltage
Falling edge, hysteresis = 40mV
1.98
0.01
10
V
µA
1.6
_______________________________________________________________________________________
V
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
MAX1710/MAX1711/MAX1712
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VBATT = 15V, VCC = VDD = 5V, SKIP = GND, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
Overvoltage Trip Threshold
MIN
TYP
MAX
UNIT
With respect to unloaded output voltage (MAX1710)
CONDITIONS
10.5
12.5
14.5
%
(MAX1711/MAX1712)
2.21
2.25
2.29
V
Overvoltage Fault Propagation
Delay
FB forced 2% above trip threshold
Output Undervoltage Protection
Threshold
With respect to unloaded output voltage (MAX1710)
(MAX1711/MAX1712)
Output Undervoltage Protection
Time
From SHDN signal going high
10
Current-Limit Threshold
(Positive Direction, Fixed)
LX to PGND, ILIM tied to VCC
90
Current-Limit Threshold
(Positive Direction, Adjustable)
LX to PGND
Current-Limit Threshold
(Negative Direction)
LX to PGND, TA = +25°C
Current-Limit Threshold
(Zero Crossing)
LX to PGND
PGOOD Propagation Delay
FB forced 2% below PGOOD trip threshold, falling edge
PGOOD Output Low Voltage
ISINK = 1mA
PGOOD Leakage Current
High state, forced to 5.5V
Thermal Shutdown Threshold
Hysteresis = 10°C
VCC Undervoltage Lockout
Threshold
Rising edge, hysteresis = 20mV,
PWM disabled below this level
DH Gate-Driver On-Resistance
1.5
65
0.76
70
0.8
100
µs
75
0.84
%
V
30
ms
110
mV
RLIM = 100kΩ
40
50
60
RLIM = 400kΩ
170
200
230
-150
-120
-80
3
mV
mV
1.5
µs
0.4
V
1
µA
150
°C
4.4
V
BST-LX forced to 5V
5
Ω
DL Gate-Driver On-Resistance
(Pullup)
DL, high state
5
Ω
DL Gate-Driver On-Resistance
(Pulldown)
DL, low state
1.7
Ω
DH Gate-Driver Source/Sink
Current
DH forced to 2.5V, BST-LX forced to 5V
1
A
DL Gate-Driver Sink Current
DL forced to 2.5V
3
A
DL Gate-Driver Source Current
DL forced to 2.5V
1
A
DL rising
35
DH rising
26
Dead Time
4.1
mV
0.5
SKIP Input Current Logic
Threshold
To enable no-fault mode, TA = +25°C
PGOOD Trip Threshold
Measured at FB with respect to unloaded output voltage,
falling edge, hysteresis = 1%
-8
Logic Input High Voltage
D0–D4, SHDN, SKIP, OVP
2.4
Logic Input Low Voltage
D0–D4, SHDN, SKIP, OVP
Logic Input Current
SHDN, SKIP, OVP
-1
Logic Input Pullup Current
D0–D4, each forced to GND
3
-1.5
-5
ns
-0.1
mA
-3
%
V
5
0.8
V
1
µA
10
µA
_______________________________________________________________________________________
3
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
ELECTRICAL CHARACTERISTICS (continued)
(Circuit of Figure 1, VBATT = 15V, VCC = VDD = 5V, SKIP = GND, TA = 0°C to +85°C, unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
VCC - 0.4
UNIT
TON VCC Level
TON logic input high level
V
TON Float Voltage
TON logic input upper-midrange level
3.15
3.85
V
TON Reference Level
TON logic input lower-midrange level
1.65
2.35
V
TON GND Level
TON logic input low level
TON Logic Input Current
TON only, forced to GND or VCC
-3
0.5
V
3
µA
ELECTRICAL CHARACTERISTICS
(Circuit of Figure 1, VBATT = 15V, VCC = VDD = 5V, SKIP = GND, TA = -40°C to +85°C, unless otherwise noted.) (Note 3)
PARAMETER
Input Voltage Range
CONDITIONS
Battery voltage, V+
MIN
TYP
MAX
UNIT
2
28
4.5
5.5
DAC codes from 1.32V to 2V
-1.5
1.5
%
DAC codes from 0.925V to
1.275V
-1.7
1.7
%
140
180
175
225
260
320
380
470
VCC, VDD
V
DC Output Voltage Accuracy
VBATT = 4.5V to 28V, for all
D/A codes, includes load
regulation error
On-Time
TON = GND (550kHz)
VBATT = 24V, TON = REF (400kHz)
FB = 2V
TON = open (300kHz)
(Note 2)
TON = VCC (200kHz)
Minimum Off-Time
(Note 2)
500
ns
Quiescent Supply Current (VCC)
Measured at VCC, FB forced above the regulation point
950
µA
Reference Voltage
VCC = 4.5V to 5.5V, no external REF load
2.02
V
%
Overvoltage Trip Threshold
Output Undervoltage
Protection Threshold
With respect to unloaded output voltage (MAX1710)
(MAX1711/MAX1712)
With respect to unloaded output voltage (MAX1710)
(MAX1711/MAX1712)
Current-Limit Threshold
(Positive Direction, Fixed)
LX to PGND, ILIM tied to VCC
Current-Limit Threshold
(Positive Direction, Adjustable)
LX to PGND
VCC Undervoltage Lockout
Threshold
1.98
10
15
2.20
2.30
V
65
75
%
0.75
0.85
V
85
115
mV
RLIM = 100kΩ
35
65
RLIM = 400kΩ
160
240
Rising edge, hysteresis = 20mV, PWM disabled below
this level
4.1
4.4
Logic Input High Voltage
D0–D4, SHDN, SKIP, OVP
2.4
Logic Input Low Voltage
D0–D4, SHDN, SKIP, OVP
Logic Input Current
SHDN, SKIP, OVP
Logic Input Pullup Current
D0–D4, each forced to GND
4
ns
mV
V
V
0.8
V
-1
1
µA
3
10
µA
_______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
(Circuit of Figure 1, VBATT = 15V, VCC = VDD = 5V, SKIP = GND, TA = -40°C to +85°C, unless otherwise noted.) (Note 3)
PARAMETER
CONDITIONS
MIN
PGOOD Trip Threshold
Measured at FB with respect to unloaded output voltage,
falling edge, hysteresis = 1%
-8.5
PGOOD Output Low Voltage
ISINK = 1mA
PGOOD Leakage Current
High state, forced to 5.5V
TYP
MAX
UNIT
-2.5
%
0.4
V
1
µA
Note 2: On-Time and Off-Time specifications are measured from 50% point to 50% point at the DH pin with LX forced to 0V, BST
forced to 5V, and a 250pF capacitor connected from DH to LX. Actual in-circuit times may differ due to MOSFET switching
speeds.
Note 3: Specifications from -40°C to 0°C are guaranteed but not production tested.
__________________________________________Typical Operating Characteristics
(7A CPU supply circuit of Figure 1, TA = +25°C, unless otherwise noted.)
VIN = 4.5V
90
VIN = 4.5V
VIN = 7V
90
EFFICIENCY vs. LOAD CURRENT
(VO = 1.3V, f = 300kHz)
100
MAX1710-02
100
MAX1710-01
100
EFFICIENCY vs. LOAD CURRENT
(VO = 1.6V, f = 300kHz)
MAX1710-03
EFFICIENCY vs. LOAD CURRENT
(VO = 2.0V, f = 300kHz)
VIN = 4.5V
90
VIN = 7V
70
VIN = 15V
60
VIN = 24V
80
EFFICIENCY (%)
EFFICIENCY (%)
EFFICIENCY (%)
VIN = 7V
80
VIN = 15V
70
VIN = 24V
60
80
70
VIN = 15V
60
VIN = 24V
50
50
40
40
0.1
1
0.1
10
0.1
1
10
EFFICIENCY vs. LOAD CURRENT
(VO = 1.6V, f = 550kHz)
FREQUENCY vs. LOAD CURRENT
(VO = 1.6V)
FREQUENCY vs. INPUT VOLTAGE
(IO = 7A)
300
VIN = 15V
316
250
200
VIN = 4.5V, SKIP MODE
150
VIN = 15V, SKIP MODE
100
VIN = 24V
1
10
VO = 2.0V
310
VO = 1.6V
308
302
0
0.1
312
304
TON = OPEN
LOAD CURRENT (A)
314
306
50
40
318
VIN = 15V, PWM MODE
FREQUENCY (kHz)
FREQUENCY (kHz)
70
320
MAX1710-06
350
MAX1710-04
80
0.01
0.01
LOAD CURRENT (A)
VIN = 7V
50
1
LOAD CURRENT (A)
VIN = 4.5V
60
40
0.01
LOAD CURRENT (A)
100
90
10
MAX1710-05
0.01
EFFICIENCY (%)
50
0.01
0.1
1
LOAD CURRENT (A)
10
TON = OPEN
300
0
5
10
15
20
25
30
INPUT VOLTAGE (V)
_______________________________________________________________________________________
5
MAX1710/MAX1711/MAX1712
ELECTRICAL CHARACTERISTICS (continued)
_____________________________Typical Operating Characteristics (continued)
(7A CPU supply circuit of Figure 1, TA = +25°C, unless otherwise noted.)
FREQUENCY vs. TEMPERATURE
(VIN = 15V, VO = 2.0V)
IO = 1A
IO = 4A
468
466
464
462
295
15
ILIM = VCC
10
5
TON = OPEN
0
456
-40
-20
0
20
40
60
80
-60
100
-40
-20
0
20
40
60
80
-60
100
0
20
40
60
80
TEMPERATURE (°C)
CONTINUOUS TO DISCONTINUOUS
INDUCTOR CURRENT POINT
vs. INPUT VOLTAGE
INDUCTOR CURRENT PEAKS AND
VALLEYS vs. INPUT VOLTAGE
(AT CURRENT-LIMIT POINT)
NO-LOAD SUPPLY CURRENTS
vs. INPUT VOLTAGE
(SKIP MODE, f = 300kHz)
0.6
VO = 1.3V
0.5
0.4
0.3
0.2
13.0
12.5
12.0
11.5
IVALLEY
11.0
0.7
0.5
0.4
0.2
10.5
0.1
0
10.0
0
10
15
20
25
0
30
5
10
15
20
25
IBATT
0.3
0.1
5
ICC
0.6
30
IDD
0
5
10
15
20
25
INPUT VOLTAGE (V)
INPUT VOLTAGE (V)
INPUT VOLTAGE (V)
NO-LOAD SUPPLY CURRENTS
vs. INPUT VOLTAGE
(SKIP MODE, f = 550kHz)
NO-LOAD SUPPLY CURRENTS
vs. INPUT VOLTAGE
(PWM MODE, f = 300kHz)
NO-LOAD SUPPLY CURRENTS
vs. INPUT VOLTAGE
(PWM MODE, f = 550kHz)
0.4
IBATT
0.2
5
10
15
20
INPUT VOLTAGE (V)
25
30
MAX1710-15
MAX1710-14
12
IDD
10
8
IBAT
6
14
12
10
IBAT
8
6
4
2
ICC
0
0
30
16
14
2
IDD
IDD
18
16
4
0.1
20
SUPPLY CURRENT (mA)
0.5
0.3
18
SUPPLY CURRENT (mA)
ICC
0.6
20
MAX1710-13
0.7
100
MAX1710-12
IPEAK
INDUCTOR CURRENT (A)
VO = 1.6V
13.5
SUPPLY CURRENT (mA)
VO = 2.0V
0.7
14.0
MAX1710-10
0.8
0
-20
TEMPERATURE (°C)
0.9
0
-40
TEMPERATURE (°C)
MAX1710-11
-60
ILIM = 100kΩ
458
IO = 1A
285
LOAD CURRENT (A)
ILIM = 400kΩ
20
IO = 4A OR 7A
460
290
6
25
CURRENT TRIP POINT (A)
305
MAX1710-09
472
470
30
MAX1710-08
IO = 7A
300
474
ON-TIME (ns)
FREQUENCY (kHz)
310
CURRENT-LIMIT TRIP POINT
vs. TEMPERATURE
ON-TIME vs. TEMPERATURE
MAX1710-07
315
SUPPLY CURRENT (mA)
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
ICC
0
0
5
10
15
20
INPUT VOLTAGE (V)
25
30
0
5
10
15
20
INPUT VOLTAGE (V)
_______________________________________________________________________________________
25
30
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
LOAD-TRANSIENT RESPONSE
(WITH INTEGRATOR)
LOAD-TRANSIENT RESPONSE
(WITHOUT INTEGRATOR)
MAX1710-18
MAX1710-17
MAX1710-16
LOAD-TRANSIENT RESPONSE
(WITH INTEGRATOR)
A
A
A
B
B
B
10µs/div
10µs/div
VIN = 15V, VO = 1.6V, IO = 0A TO 7A
A = VOUT, AC-COUPLED, 50mV/div
B = INDUCTOR CURRENT, 5A/div
LOAD-TRANSIENT RESPONSE
(WITH INTEGRATOR)
VIN = 15V, VO = 1.6V, IO = 30mA TO 7A
A = VOUT, AC-COUPLED, 50mV/div
B = INDUCTOR CURRENT, 5A/div
LOAD-TRANSIENT RESPONSE
(WITH INTEGRATOR)
STARTUP WAVEFORM
A
MAX1710-21
MAX1710-20
MAX1710-19
A
10µs/div
VIN = 15V, VO = 1.6V, IO = 30mA TO 7A
A = VOUT, AC-COUPLED, 50mV/div
B = INDUCTOR CURRENT, 5A/div
A
B
B
B
C
C
20µs/div
VIN = 4.5V, VO = 2V, IO = 30mA TO 7A
A = VOUT, AC-COUPLED, 50mV/div
B = INDUCTOR CURRENT, 5A/div
C = DL, 10V/div
C
20µs/div
VIN = 4.5V, VO = 1.3V, IO = 30mA TO 7A
A = VOUT, AC-COUPLED, 50mV/div
B = INDUCTOR CURRENT, 5A/div
C = DL, 10V/div
500µs/div
A = SHDN
B = VOUT, 0.5V/div
C = INDUCTOR CURRENT, 5A/div
_______________________________________________________________________________________
7
MAX1710/MAX1711/MAX1712
_____________________________Typical Operating Characteristics (continued)
(7A CPU supply circuit of Figure 1, TA = +25°C, unless otherwise noted.)
_____________________________Typical Operating Characteristics (continued)
(7A CPU supply circuit of Figure 1, TA = +25°C, unless otherwise noted.)
OUTPUT OVERLOAD WAVEFORM
B
MAX1710-24
MAX1710-23
A
SHUTDOWN WAVEFORM
LOAD-TRANSIENT RESPONSE
MAX1710-22
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
CERAMIC COUT
A
A
B
C
B
D
C
C
50µs/div
VOUT = 1.6V
A = VIN, AC-COUPLED, 2V/div
B = VOUT, 0.5V/div
C = INDUCTOR CURRENT, 5A/div
5µs/div
5µs/div
L = 0.7µH, VOUT = 1.6V, VIN = 15V, COUT = 47µF (x4), f = 550kHz
A = VOUT, AC-COUPLED, 100mV/div
B = INDUCTOR CURRENT, 5A/div
C = DL, 5V/div
VIN = 15V, V0 = 1.6V, I0 = 7A
A = VOUT, 0.5V/div
B = INDUCTOR CURRENT, 5A/div
C = SHDN, 2V/div
D = DL, 5V/div
Pin Description
8
PIN
NAME
FUNCTION
1
V+
Battery Voltage Sense Connection. V+ is used only for PWM one-shot timing. DH on-time is inversely proportional to V+ input voltage over a range of 2V to 28V.
2
SHDN
3
FB
Fast Feedback Input, normally connected to VOUT. FB is connected to the bulk output filter capacitors locally at the power supply. An external resistor-divider can optionally set the output voltage.
4
FBS
Feedback Remote-Sense Input, normally connected to VOUT directly at the load. FBS internally connects to
the integrator that fine tunes the DC output voltage. Tie FBS to VCC to disable all three integrator amplifiers.
Tie FBS to FB (or disable the integrators) when externally adjusting the output voltage with a resistor-divider.
5
CC
Integrator Capacitor Connection. Connect a 100pF to 1000pF (470pF typical) capacitor to GND to set the
integration time constant.
6
ILIM
Current-Limit Threshold Adjustment. Connects to an external resistor to GND. The LX-PGND current-limit
threshold defaults to +100mV if ILIM is tied to VCC. The current-limit threshold is 1/10 of the voltage forced at
ILIM. In adjustable mode, the threshold is VTH = RLIM ✕ 5µA/10.
7
VCC
Analog Supply Voltage Input for PWM Core, 4.5V to 5.5V. Bypass VCC to GND with a 0.1µF minimum
capacitor.
8
TON
On-Time Selection Control Input. This is a four-level input that sets the K factor to determine DH on-time.
GND = 550kHz, REF = 400kHz, open = 300kHz, VCC = 200kHz.
9
REF
2.0V Reference Output. Bypass REF to GND with a 0.22µF minimum capacitor. REF can source 50µA for
external loads. Loading REF degrades FB accuracy according to the REF load-regulation error
(see Electrical Characteristics).
Shutdown Control Input, active low. SHDN cannot withstand the battery voltage. In shutdown mode, DL is
forced to VDD in order to enforce overvoltage protection, even when powered down (unless OVP is high).
_______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
PIN
NAME
10
GND
FUNCTION
11
GNDS
12
PGOOD
13
DL
14
PGND
15
VDD
Supply Voltage Input for the DL Gate Driver, 4.5V to 5.5V
16
(MAX1710)
OVP
Overvoltage-Protection Disable Control Input (Table 4). GND = normal operation and overvoltage
protection active, VCC = overvoltage protection disabled.
16
(MAX1711/
MAX1712)
D4
DAC Code Input, MSB. 5µA internal pullup to VCC (Tables 1, 2, and 3).
17
D3
DAC Code Input. 5µA internal pullup to VCC.
18
D2
DAC Code Input. 5µA internal pullup.
19
D1
DAC Code Input. 5µA internal pullup.
20
D0
DAC Code Input LSB. 5µA internal pullup.
Analog Ground
Ground Remote-Sense Input, normally connected to ground directly at the load. GNDS internally connects to the integrator that fine tunes the ground offset voltage.
Open-Drain Power-Good Output
Low-Side Gate-Driver Output, swings 0 to VDD
Power Ground. Also used as the inverting input for the current-limit comparator.
21
SKIP
Low-Noise-Mode Selection Control Input. Low-noise forced-PWM mode causes inductor current
recirculation at light loads and suppresses pulse-skipping operation. Normal operation prevents
current recirculation. SKIP can also be used to disable both overvoltage and undervoltage protection
circuits and clear the fault latch (Figure 6). GND = normal operation, VCC = low-noise mode. Do not
leave SKIP floating.
22
BST
Boost Flying-Capacitor Connection. An optional resistor in series with BST allows the DH pullup
current to be adjusted (Figure 5). This technique of slowing the LX rise time can be used to prevent
accidental turn-on of the low-side MOSFET due to excessive gate-drain capacitance.
23
LX
Inductor Connection. LX serves as the lower supply rail for the DH high-side gate driver. Also used
for the noninverting input to the current-limit comparator, as well as the skip-mode zero-crossing comparator.
24
DH
High-Side Gate-Driver Output. Swings LX to BST.
Standard Application Circuit
The standard application circuit (Figure 1) generates a
low-voltage, high-power rail for supplying up to 7A to the
core CPU VCC in a notebook computer. This DC-DC
converter steps down a battery or AC adapter voltage to
sub-2V levels with high efficiency and accuracy, and
represents a good compromise between size, efficiency,
and cost.
See the MAX1710 EV kit manual for a list of components
and suppliers.
Detailed Description
The MAX1710/MAX1711/MAX1712 buck controllers are
targeted for low-voltage, high-current CPU power supplies for notebook computers. CPU cores typically exhibit 0A to 10A or greater load steps when the clock is
throttled. The proprietary Quick-PWM pulse-width modulator in the MAX1710/MAX1711/MAX1712 is specifically
designed for handling these fast load steps while maintaining a relatively constant operating frequency and
inductor operating point over a wide range of input voltages. The Quick-PWM architecture circumvents the poor
load-transient timing problems of fixed-frequency cur-
_______________________________________________________________________________________
9
MAX1710/MAX1711/MAX1712
Pin Description (continued)
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
VBATT
4.5V TO 28V
+5V
BIAS SUPPLY
C5
1µF
C6
1µF
R1
20Ω
C1 3 x 10µF/30V
15
7
1
ON/OFF
CONTROL
LOW-NOISE
CONTROL
2
21
20
19
DAC
INPUTS
V+
BST
SHDN
D0
D1
D2
17
D3
16
D4**
LX
DL
PGND
8
TON
9
REF
C3
470pF
5
CC
FB
FBS
GNDS
Q1
PANASONIC
ETQP6F2R0HFA
L1
2µH
C2
3 x 470µF
KEMET T510
23
13
D1
Q2
3
4
11
+5V
R4
1k
R2
100k
OVP* PGOOD
12
POWER-GOOD
INDICATOR
16
6
VOUT
1.25V TO 2V AT 7A (MAX1710)
0.925V TO 2V AT 7A (MAX1711)
1.1V TO 1.85V AT 7A (MAX1712)
D3
(OPTIONAL OVP
REVERSE-POLARITY
CLAMP)
14
GND
ILIM
*MAX1710 ONLY
**MAX1711/MAX1712 ONLY
24
C7
0.1µF
MAX1710
MAX1711
MAX1712
C4
1µF
TO VCC
DH
22
SKIP
18
10
D2
CMPSH-3
VDD
VCC
Q1 = IRF7807
Q2 = IRF7805
D1, D3 = MBRS130T3 (OPTIONAL)
C1 = SANYO OS-CON (30SC10M)
R3
(OPTIONAL)
Figure 1. Standard Application Circuit
rent-mode PWMs while also avoiding the problems
caused by widely varying switching frequencies in conventional constant-on-time and constant-off-time PWM
schemes.
+5V Bias Supply (VCC and VDD)
The MAX1710/MAX1711/MAX1712 require 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 and eliminates the cost associated
with the +5V linear regulator that would otherwise be
10
needed to supply the PWM circuit and gate drivers. If
stand-alone capability is needed, the +5V supply can be
generated with an external linear regulator such as the
MAX1615.
The battery and +5V bias inputs can be tied together if
the input source is a fixed 4.5V to 5.5V supply. If the +5V
bias supply is powered up prior to the battery supply, the
enable signal (SHDN) must be delayed until the battery
voltage is present in order to ensure startup. The +5V
bias supply must provide VCC and gate-drive power, so
the maximum current drawn is:
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
RLIM
V+
ILIM
TOFF
TON
FROM
D/A
ON-TIME
COMPUTE
TON
S
Q
TRIG
VCC
1-SHOT
TRIG
Q
5µA
BST
Q
R
DH
CURRENT
LIMIT
1-SHOT
Σ
OVP
+5V
MAX1710
LX
ERROR
AMP
SKIP
REF
ZERO CROSSING
VDD
10k
SHDN
OUTPUT
+5V
70k
CC
DL
REF
S
Q
gm
gm
PGND
R
gm
FB
GNDS
FBS
FB
REF
-5%
REF
+12%
REF
-30%
PGOOD
R-2R
D/A CONVERTER
S1
S2
CHIP SUPPLY
VCC
2V
REF
REF
+5V
TIMER
Q
GND
OVP/UVLO
LATCH
D0
D1
D2
D3
Figure 2. MAX1710 Functional Diagram
IBIAS = ICC + f ✕ (QG1 + QG2) = 15mA to 30mA (typ)
where ICC is 600µA (typ), f is the switching frequency,
and QG1 and QG2 are the MOSFET data sheet total
gate-charge specification limits at VGS = 5V.
Free-Running, Constant-On-Time PWM
Controller with Input Feed-Forward
The Quick-PWM control architecture is an almost fixedfrequency, constant-on-time current-mode type with volt-
age feed-forward (Figure 2). This architecture relies on
the filter capacitor’s ESR to act as the current-sense
resistor, so the output ripple voltage provides the PWM
ramp signal. The control algorithm is simple: the highside switch on-time is determined solely by a one-shot
whose period is inversely proportional to input voltage
and directly proportional to output voltage. Another oneshot sets a minimum off-time (400ns typ). The on-time
one-shot is triggered if the error comparator is low, the
______________________________________________________________________________________
11
MAX1710/MAX1711/MAX1712
VBATT 2V TO 28V
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
Table 1. MAX1710 FB Output Voltage
DAC Codes
Table 2. MAX1711 FB Output Voltage
DAC Codes
D3
D2
D1
D0
OUTPUT
VOLTAGE (V)
D4
D3
D2
D1
D0
OUTPUT
VOLTAGE (V)
0
0
0
0
2.00
0
0
0
0
0
2.00
0
0
0
1
1.95
0
0
0
0
1
1.95
0
0
1
0
1.90
0
0
0
1
0
1.90
0
0
1
1
1.85
0
0
0
1
1
1.85
0
1
0
0
1.80
0
0
1
0
0
1.80
0
1
0
1
1.75
0
0
1
0
1
1.75
0
1
1
0
1.70
0
1
1
0
1.70
0
0
1
1
1
1.65
0
0
1
1
1
1.65
1
0
0
0
1.60
0
1
0
0
0
1.60
1
0
0
1
1.55
1
0
0
1
1.55
0
1
0
1
0
1.50
0
1
0
1
0
1.50
1
0
1
1
1.45
0
1
0
1
1
1.45
1
1
0
0
1.40
1.35
1
1
0
0
1.40
0
1
1
0
1
1.35
0
1
1
0
1
1
1
1
0
1.30
0
1
1
1
0
1.30
1.25
0
1
1
1
1
Shutdown3*
1
0
0
0
0
1.275
1
0
0
0
1
1.250
low-side switch current is below the current-limit threshold, and the minimum off-time one-shot has timed out.
1
0
0
1
0
1.225
1
0
0
1
1
1.200
On-Time One-Shot (TON)
1
0
1
0
0
1.175
The heart of the PWM core is the one-shot that sets the
high-side switch on-time. This fast, low-jitter, adjustable
one-shot includes circuitry that varies the on-time in
response to battery and output voltage. The high-side
switch on-time is inversely proportional to the battery
voltage as measured by the V+ input, and directly proportional to the output voltage as set by the DAC code.
This algorithm results in a nearly constant switching frequency despite the lack of a fixed-frequency clock generator. The benefits of a constant switching frequency
are twofold: first, the frequency can be selected to avoid
noise-sensitive regions such as the 455kHz IF band;
second, the inductor ripple-current operating point
remains relatively constant, resulting in easy design
methodology and predictable output voltage ripple:
1
0
1
0
1
1.150
1
0
1
1
0
1.125
1
0
1
1
1
1.100
1
1
0
0
0
1.075
1
1
0
0
1
1.050
1
1
0
1
0
1.025
1
1
0
1
1
1.000
1
1
1
0
0
0.975
1
1
1
0
1
0.950
1
1
1
1
0
0.925
1
1
1
1
1
Shutdown3*
1
1
1
1
On-Time = K (VOUT + 0.075V) / VIN
where K is set by the TON pin-strap connection and
0.075V is an approximation to accommodate for the
expected drop across the low-side MOSFET switch.
One-shot timing error increases for the shorter on-time
12
*See Table 4.
settings due to fixed propagation delays and is approximately ±12.5% at 550kHz and 400kHz, and ±10% at the
two slower settings. This translates to reduced switching-frequency accuracy at higher frequencies (Table 5).
Switching frequency increases as a function of load current due to the increasing drop across the low-side
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
resistance, source inductance, and DH output drive
characteristics.
Two external factors that can influence switching-frequency accuracy are resistive drops in the two conduction loops (including inductor and PC board resistance)
and the dead-time effect. These effects are the largest
contributors to the change of frequency with changing
load current. The dead-time effect is a notable discontinuity in the switching frequency as the load current is
varied (see Typical Operating Characteristics). It occurs
whenever the inductor current reverses, most commonly
at light loads with SKIP high. With reversed inductor current, the inductor’s EMF causes LX to go high earlier
than normal, extending the on-time by a period equal to
the low-to-high dead time. For loads above the critical
conduction point, the actual switching frequency is:
VOUT + VDROP1
f=
t ON (VIN + VDROP2 )
D4
D3
D2
D1
D0
OUTPUT
VOLTAGE (V)
0
0
0
0
0
1.850
0
0
0
0
1
1.825
0
0
0
1
0
1.800
0
0
0
1
1
1.775
0
0
1
0
0
1.750
0
0
1
0
1
1.725
0
0
1
1
0
1.700
0
0
1
1
1
1.675
0
1
0
0
0
1.650
0
1
0
0
1
1.625
0
1
0
1
0
1.600
0
1
0
1
1
1.575
0
1
1
0
0
1.550
0
1
1
0
1
1.525
0
1
1
1
0
1.500
0
1
1
1
1
1.475
1
0
0
0
0
1.450
1
0
0
0
1
1.425
Integrator Amplifiers (CC)
1
0
0
1
0
1.400
1
0
0
1
1
1.375
1
0
1
0
0
1.350
1
0
1
0
1
1.325
1
0
1
1
0
1.300
1
0
1
1
1
1.275
1
1
0
0
0
1.250
1
1
0
0
1
1.225
1
1
0
1
0
1.200
1
1
0
1
1
1.175
1
1
1
0
0
1.150
1
1
1
0
1
1.125
1
1
1
1
0
1.100
1
1
1
1
1
Shutdown3*
There are three integrator amplifiers that provide a fine
adjustment to the output regulation point. One amplifier
monitors the difference between GNDS and GND, while
another monitors the difference between FBS and FB.
The third amplifier integrates the difference between
REF and the DAC output. These three transconductance
amplifiers’ outputs are directly summed inside the chip,
so the integration time constant can be set easily with a
capacitor. The gm of each amplifier is 160µmho (typ).
The integrator block has an ability to move and correct
the output voltage by about -2%, +4%. For each amplifier, the differential input voltage range is about ±50mV
total, including DC offset and AC ripple. The voltage
gain of each integrator is about 80V/V.
The FBS amplifier corrects for DC voltage drops in PC
board traces and connectors in the output bus path
between the DC-DC converter and the load. The GNDS
amplifier performs a similar DC correction task for the
output ground bus. The third amplifier provides an averaging function that forces VOUT to be regulated at the
average value of the output ripple waveform. If the integrator amplifiers are disabled, VOUT is regulated at the
valleys of the output ripple waveform. This creates a
slight load-regulation characteristic in which the output
*See Table 4.
MOSFET, which causes a faster inductor-current discharge ramp. The on-times guaranteed in the Electrical
Characteristics are influenced by switching delays in the
external high-side power MOSFET. The exact switching
frequency will depend on gate charge, internal gate
where VDROP1 is the sum of the parasitic voltage drops
in the inductor discharge path, including synchronous
rectifier, inductor, and PC board resistances; VDROP2
is the sum of the resistances in the charging path,
and tON is the on-time calculated by the MAX1710/
MAX1711/MAX1712.
______________________________________________________________________________________
13
MAX1710/MAX1711/MAX1712
Table 3. MAX1712 FB Output Voltage
DAC Codes (VRM 9.0)
threshold is relatively constant, with only a minor dependence on battery voltage.
∆i
VBATT - VOUT
=
L
∆t
-IPEAK
INDUCTOR CURRENT
MAX1710/MAX1711
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
I LOAD(SKIP) ≈
ILOAD = IPEAK/2
0 ON-TIME
TIME
Figure 3. Pulse-Skipping/Discontinuous Crossover Point
voltage rises approximately 1% (up to 1/2 the peak
amplitude of the ripple waveform as a limit) when under
light loads.
Integrators have both beneficial and detrimental characteristics. While they do correct for drops due to DC
bus resistance and tighten the DC output voltage tolerance limits by averaging the peak-to-peak output
ripple, they can interfere with achieving the fastest possible load-transient response. The fastest transient
response is achieved when all three integrators are disabled. This works very well when the MAX1710/
MAX1711/MAX1712 circuit can be placed very close to
the CPU.
There is often a connector, or at least many milliohms of
PC board trace resistance, between the DC-DC converter and the CPU. In these cases, the best strategy is to
place most of the bulk bypass capacitors close to the
CPU, with just one capacitor on the other side of the connector near the MAX1710/MAX1711/MAX1712 to control
ripple if the CPU card is unplugged. In this situation, the
remote-sense lines and integrators provide a real benefit.
When FBS is connected to VCC so that all three integrators are disabled, CC can be left unconnected, which
eliminates a component.
Automatic Pulse-Skipping Switchover
At light loads, an inherent automatic switchover to PFM
takes place. This switchover is effected by a comparator
that truncates the low-side switch on-time at the inductor
current’s zero crossing. This mechanism causes the
threshold between pulse-skipping PFM and nonskipping
PWM operation to coincide with the boundary between
continuous and discontinuous inductor-current operation
(also known as the “critical conduction” point;
see Continuous to Discontinuous Inductor Current Point
vs. Input Voltage graph in the Typical Operating
Characteristics). For a battery range of 7V to 24V, this
14
K
2L
where K is the On-Time Scale factor (Table 6). The loadcurrent level at which PFM/PWM crossover occurs,
ILOAD(SKIP), is equal to 1/2 the peak-to-peak ripple current, which is a function of the inductor value (Figure 3).
For example, in the standard application circuit with tON
= 300ns at 24V, VOUT = 2V, and L = 2µH, switchover to
pulse-skipping operation occurs at ILOAD = 1.65A or
about 1/4 full load. The crossover point occurs at an
even lower value if a swinging (soft-saturation) inductor
is used.
The switching waveforms may appear noisy and asynchronous when light loading causes pulse-skipping
operation, but this is a normal operating condition that
results in high light-load efficiency. Trade-offs in PFM
noise vs. light-load efficiency can be made by varying
the inductor value. Generally, low inductor values produce a broader efficiency vs. load curve, while higher
values result in higher full-load efficiency (assuming that
the coil resistance remains fixed) and less output voltage
ripple. Penalties for using higher inductor values include
larger physical size and degraded load-transient
response (especially at low input voltage levels).
Forced-PWM Mode (SKIP = High)
The low-noise, forced-PWM mode (SKIP driven high) disables the zero-crossing comparator, which controls the
low-side switch on-time. This causes the low-side gatedrive waveform to become the complement of the highside gate-drive waveform. This in turn causes the
inductor current to reverse at light loads, as the PWM
loop strives to maintain a duty ratio of VOUT/VIN. The
benefit of forced-PWM mode is to keep the switching frequency fairly constant, but it comes at a cost: the noload battery current can be as high as 40mA or more.
Forced-PWM mode is most useful for reducing audio-frequency noise, improving load-transient response, providing sink-current capability for dynamic output voltage
adjustment, and improving the cross-regulation of multiple-output applications that use a flyback transformer or
coupled inductor.
Current-Limit Circuit (ILIM)
The current-limit circuit employs a unique “valley” current-sensing algorithm that uses the on-state resistance
of the low-side MOSFET as a current-sensing element. If
the current-sense signal is above the current-limit
threshold, the PWM is not allowed to initiate a new cycle
(Figure 4). The actual peak current is greater than the
current-limit threshold by an amount equal to the induc-
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
-IPEAK
INDUCTOR CURRENT
ILOAD
ILIMIT
LX-PGND ILIMIT THRESHOLD = 100mV (NOMINAL, DEFAULT)
VOLTAGE DROP ACROSS Q2
0
TIME
Figure 4.”Valley’’ Current-Limit Threshold Point
There is also a negative current limit that prevents excessive reverse inductor currents when VOUT is sinking current. The negative current-limit threshold is set to
approximately 120% of the positive current limit, and
therefore tracks the positive current limit when ILIM is
adjusted.
The current-limit threshold can be adjusted with an external resistor (RLIM) at ILIM. A precision 5µA pullup current
source at ILIM sets a voltage drop on this resistor,
adjusting the current-limit threshold from 50mV to
200mV. In the adjustable mode, the current-limit threshold voltage is precisely 1/10th the voltage seen at ILIM.
Therefore, choose RLIM equal to 2kΩ/mV of the currentlimit threshold. The threshold defaults to 100mV when
ILIM is tied to VCC. The logic threshold for switchover to
the 100mV default value is approximately VCC - 1V.
The adjustable current limit can accommodate
MOSFETs with atypical on-resistance characteristics
(see Design Procedure).
A capacitor in parallel with RLIM can provide a variable
soft-start function.
Carefully observe the PC board layout guidelines to
ensure that noise and DC errors don’t corrupt the current-sense signals seen by LX and PGND. The IC must
be mounted close to the low-side MOSFET with short,
direct traces making a Kelvin-sense connection to the
source and drain terminals.
MOSFET Gate Drivers (DH, DL)
The DH and DL drivers are optimized for driving moderate-size, 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 VBATT - 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
MAX1710/MAX1711/MAX1712 will interpret the MOSFET
gate as “off” while there is actually still charge left on the
gate. Use very short, wide traces measuring 10 to 20
squares (50 to 100 mils wide if the MOSFET is 1 inch
from the MAX1710/MAX1711/MAX1712).
The dead time at the other edge (DH turning off) is determined by a fixed 35ns (typ) internal delay.
The internal pulldown transistor that drives DL low is
robust, with a 0.5Ω (typ) on-resistance. This helps prevent DL from being pulled up during the fast rise time of
the inductor node, due to capacitive coupling from the
drain to the gate of the massive low-side synchronousrectifier MOSFET. However, you might still encounter
some combinations of high- and low-side FETs that will
cause excessive gate-drain coupling, which can lead to
efficiency-killing, EMI-producing shoot-through currents.
This can often be remedied by adding a resistor in series
with BST, which increases the turn-on time of the highside FET without degrading the turn-off time (Figure 5).
+5V
VBATT
BST
5Ω
DH
MAX1710
MAX1711
MAX1712
LX
Figure 5. Reducing the Switching-Node Rise Time
DAC Converter (D0–D4)
The DAC programs the output voltage. It receives a digital code from pins on the CPU module that are either
hard-wired to GND or left open-circuit. The
MAX1710/MAX1711/MAX1712 contain weak internal
______________________________________________________________________________________
15
MAX1710/MAX1711/MAX1712
tor ripple current. Therefore the exact current-limit characteristic and maximum load capability are a function of
the MOSFET on-resistance, inductor value, and battery
voltage. The reward for this uncertainty is robust, lossless overcurrent sensing. When combined with the UVP
protection circuit, this current-limit method is effective in
almost every circumstance.
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
Table 4. Operating Mode Truth Table
SHDN
SKIP
OVP
DL
MODE
0
X
0
High
Shutdown1
Low-power shutdown state. DL is forced to VDD, enforcing OVP. ICC < 1µA typ.
0
X
1
Low
Shutdown2
Low-power shutdown state. DL is forced to GND, disabling OVP. ICC < 1µA typ.
Exiting shutdown triggers a soft-start cycle.
1
X
X
Low
Shutdown3
(MAX1711/
MAX1712)
DAC code = X1111 (MAX1711), DAC code = 11111 (MAX1712) (Table 2). DL is
forced to PGND, DH is forced to LX. The MAX1711/MAX1712 eventually goes
into UVP fault mode as the load current discharges the output.
1
Below
GND
X
Switching
No fault
Test mode with OVP, UVP, and thermal faults disabled and latches cleared.
Otherwise normal operation, with automatic PWM/PFM switchover for pulse
skipping at light loads (Figure 6).
1
X
1
Switching
No OVP
OVP faults disabled and OVP latch cleared. Otherwise normal operation,
with SKIP controlling PWM/PFM switchover.
1
VCC
X
Switching
Run (PWM),
Low Noise
Low-noise operation with no automatic switchover. Fixed-frequency PWM action
is forced regardless of load. Inductor current reverses at light load levels.
ICC draw = 750µA typ. IDD draw = 15mA typ.
1
GND
X
Switching
Run
(PFM/PWM)
Normal operation with automatic PWM/PFM switchover for pulse skipping at light
loads. ICC = 600µA typ. IDD draw = load dependent.
1
X
X
High
Fault
Fault latch has been set by OVP, output UVLO, or thermal shutdown. Device will
remain in FAULT mode until VCC power is cycled, SKIP is forced below ground,
or SHDN is toggled.
COMMENTS
Table 5. Frequency Selection Guidelines
FREQUENCY
(kHz)
TYPICAL
APPLICATION
COMMENT
200
4-cell Li+ notebook Use for absolute best
CPU core
efficiency.
300
4-cell Li+ notebook Considered mainstream
CPU core
by current standards.
400
Useful in 4-cell systems
3-cell Li+ notebook
for lighter loads than the
CPU core
CPU or where size is key.
550
Good operating point for
+5V-input notebook
compound buck designs
CPU core
or desktop circuits.
pullups on each input in order to eliminate external resistors.
When changing MAX1710 DAC codes while powered
up, the over/undervoltage protection features can be
activated if the code is changed more than 1LSB at a
time. For applications needing the capability of changing
DAC codes “on-the-fly,” use the MAX1711/MAX1712.
16
POR, UVLO, and Soft-Start
Power-on reset (POR) occurs when VCC rises above
approximately 2V, resetting the fault latch and soft-start
counter, and preparing the PWM for operation. VCC
undervoltage lockout (UVLO) circuitry inhibits switching
and forces the DL gate driver high (in order to enforce
output overvoltage protection) until VCC rises above
4.2V, whereupon an internal digital soft-start timer begins
to ramp up the maximum allowed current limit. The ramp
occurs in five steps: 20%, 40%, 60%, 80%, and 100%,
with 100% current available after 1.7ms ±50%.
A continuously adjustable, analog soft-start function can
be realized by adding a capacitor in parallel with RLIM at
ILIM. This soft-start method requires a minimum interval
between power-down and power-up to allow RLIM to discharge the capacitor.
Power-Good Output (PGOOD)
The output (FB) is continuously monitored for undervoltage by the PGOOD comparator, except in shutdown or
standby mode. The -5% undervoltage trip threshold is
measured with respect to the nominal unloaded output
voltage, as set by the DAC. If the DAC code increases in
steps greater than 1LSB, it is likely that PGOOD will
momentarily go low. In shutdown and standby modes,
PGOOD is actively held low. The PGOOD output is a true
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
Output Overvoltage Protection (OVP)
The OVP circuit is designed to protect against a shorted high-side MOSFET by drawing high current and
blowing the battery fuse. The FB node is continuously
monitored for overvoltage. The overvoltage trip threshold tracks the DAC code setting. If the output is more
than 12.5% above the nominal regulation point for
the MAX1710 (2.25V absolute for the MAX1711/
MAX1712), overvoltage protection OVP is triggered and
the circuit shuts down. The DL low-side gate-driver output is then latched high until SHDN is toggled or VCC
power is cycled below 1V. This action turns on the synchronous-rectifier MOSFET with 100% duty and, in turn,
rapidly discharges the output filter capacitor and forces
the output to ground.
If the condition that caused the overvoltage (such as a
shorted high-side MOSFET) persists, the battery fuse will
blow. Note that DL going high can have the effect of
causing output polarity reversal, due to energy stored in
the output LC at the instant OVP activates. If the load
can’t tolerate being forced to a negative voltage, it may
be desirable to place a power Schottky diode across the
output to act as a reverse-polarity clamp (Figure 1). The
MAX1710/MAX1711/MAX1712 themselves can be
affected by the FB pin going below ground, with the negative voltage coupling into SHDN. It may be necessary to
add 1kΩ resistors in series with FB and FBS (Figure 7).
DL is also kept high continuously when VCC UVLO is
active as well as in Shutdown1 mode (Table 4).
Overvoltage protection can be defeated via the OVP
input (MAX1710 only) or via a SKIP test mode (see Pin
Description).
Output Undervoltage Protection (UVP)
The output UVP function is similar to foldback current
limiting, but employs a timer rather than a variable current limit. If the MAX1710 output (FB) is under 70% of the
nominal value 20ms after coming out of shutdown, the
PWM is latched off and won’t restart until VCC power is
cycled or SHDN is toggled. For the MAX1711/MAX1712,
the nominal UVP trip threshold is fixed at 0.8V.
No-Fault Test Mode
The over/undervoltage protection features can complicate the process of debugging prototype breadboards
since there are (at most) a few milliseconds in which to
determine what went wrong. Therefore, a test mode is
provided to totally disable the OVP, UVP, and thermal
shutdown features, and clear to the fault latch if it has
MAX1710
MAX1711
MAX1712
APPROXIMATELY
-0.65V
SKIP
1.5mA
VFORCE
GND
Figure 6. Disabling Over/Undervoltage Protection (Test Mode)
been previously set. The PWM operates as if SKIP were
grounded (PFM/PWM mode).
The no-fault test mode is entered by sinking 1.5mA
from SKIP via an external negative voltage source in
series with a resistor (Figure 6). SKIP is clamped to
GND with a silicon diode, so choose the resistor value
equal to (VFORCE - 0.65V) / 1.5mA.
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:
1) Input voltage range. The maximum value (VBATT
(MAX)) must accommodate the worst-case high AC
adapter voltage. The minimum value (VBATT(MIN))
must account for the lowest battery 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.
2) 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%.
3) Switching frequency. This choice determines the
basic trade-off between size and efficiency. The optimal frequency is largely a function of maximum input
______________________________________________________________________________________
17
MAX1710/MAX1711/MAX1712
open-drain type with no parasitic ESD diodes. Note that
the PGOOD undervoltage detector is completely independent of the output UVP fault detector.
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
voltage, due to MOSFET switching losses that are
proportional to frequency and VBATT2. The optimum
frequency is also a moving target, due to rapid
improvements in MOSFET technology that are making
higher frequencies more practical (Table 5).
4) Inductor operating point. This choice provides
trade-offs between size vs. efficiency. Low inductor
values cause large ripple currents, resulting in the
smallest size, but poor efficiency and high output
noise. 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 size-reduction
benefit.
The MAX1710/MAX1711/MAX1712s’ pulse-skipping
algorithm initiates skip mode at the critical-conduction
point. So, the inductor operating point also determines
the load-current value at which PFM/PWM switchover
occurs. The optimum point is usually found between
20% and 50% ripple current.
The inductor ripple current also impacts transientresponse performance, especially at low VBATT - 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 is also a function of the maximum
duty factor, which can be calculated from the on-time
and minimum off-time:
(∆I LOAD(MAX) )2 × L
VSAG =
2 × CF × DUTY (VBATT(MIN) − VOUT )
Inductor Selection
The switching frequency (on-time) and operating point
(% ripple or LIR) determine the inductor value as follows:
L =
VOUT
f × LIR × I LOAD(MAX)
Example: ILOAD(MAX) = 7A, VOUT = 2V, f = 300kHz, 50%
ripple current or LIR = 0.5:
L =
2V
= 1.9µH (2µH)
300kHz × 0.5 × 7A
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 cheap and can work well at 200kHz. The core must be
large enough not to saturate at the peak inductor current
(IPEAK):
IPEAK = ILOAD(MAX) + (LIR / 2) ✕ ILOAD(MAX)
18
Setting the Current Limit
The minimum current-limit threshold must be great
enough to support the maximum load current when the
current limit is at the minimum tolerance value. The valley
of the inductor current occurs at ILOAD(MAX) minus half
of the ripple current, therefore:
ILIMIT(LOW) > ILOAD(MAX) - (LIR / 2) ✕ ILOAD(MAX)
where ILIMIT(LOW) = minimum current-limit threshold voltage divided by the RDS(ON) of Q2. For the MAX1710, the
minimum current-limit threshold (100mV default setting)
is 90mV. Use the worst-case maximum value for RDS(ON)
from the MOSFET Q2 data sheet, and add some margin
for the rise in RDS(ON) with temperature. A good general
rule is to allow 0.5% additional resistance for each °C of
temperature rise.
Examining the 7A notebook CPU circuit example with a
maximum RDS(ON) = 15mΩ at high temperature reveals
the following:
ILIMIT(LOW) = 90mV / 15mΩ = 6A
6A is greater than the valley current of 5.25A, so the circuit can easily deliver the full rated 7A using the default
100mV nominal ILIM threshold.
When adjusting the current limit, use a 1% tolerance RLIM
resistor to prevent a significant increase of errors in the
current-limit tolerance.
Output Capacitor Selection
The output filter capacitor must have low enough effective
series resistance (ESR) to meet output ripple and loadtransient requirements, yet have high enough ESR to satisfy stability requirements. Also, the capacitance value
must be high enough to absorb the inductor energy
going from a full-load to no-load condition without tripping
the OVP circuit.
In CPU VCORE converters and other applications where
the output is subject to violent load transients, the output
capacitor’s size 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 ≤
VDIP
I LOAD(MAX)
In non-CPU applications, the output capacitor’s size
depends on how much ESR is needed to maintain an
acceptable level of output voltage ripple:
RESR ≤
Vp - p
LIR × I LOAD(MAX)
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
When using low-capacity filter capacitors such as ceramic or polymer types, capacitor size is usually determined
by the capacity needed to prevent the overvoltage protection circuit from being tripped when transitioning from
a full-load to a no-load condition. The capacitor must be
large enough to prevent the inductor’s stored energy from
launching the output above the overvoltage protection
threshold. Generally, once enough capacitance is added
to meet the overshoot requirement, undershoot at the rising load edge is no longer a problem (see also VSAG
equation under Design Procedure).
With integrators disabled, the amount of overshoot due to
stored inductor energy can be calculated as:
C
× VOUT 2 + L × IPEAK 2 
∆V =  OUT
 − VOUT

COUT


where IPEAK is the peak inductor current. To absolutely
minimize the overshoot, disable the integrator first, since
the inherent delay of the integrator can cause extra “runon” switching cycles to occur after the load change.
Output Capacitor Stability Considerations
Stability is determined by the value of the ESR zero relative to the switching frequency. The point of instability is
given by the following equation:
f
f ESR =
π
1
where f ESR =
2 × π × RESR × CF
For a typical 300kHz application, the ESR zero frequency
must be well below 95kHz, preferably below 50kHz.
Tantalum and OS-CON capacitors in widespread use at
the time of publication have typical ESR zero frequencies
of 15kHz. In the design example used for inductor selection, the ESR needed to support 50mVp-p ripple is
50mV/3.5A = 14.2mΩ. Three 470µF/4V Kemet T510 lowESR tantalum capacitors in parallel provide 15mΩ max
ESR. Their typical combined ESR results in a zero at
14.1kHz, well within the bounds of stability.
Don’t put high-value ceramic capacitors directly across
the fast feedback inputs (FB to GND) without taking precautions to ensure stability. Large ceramic capacitors
can have a high ESR zero frequency and cause erratic,
unstable operation. However, it’s easy to add enough
series resistance by placing the capacitors a couple of
inches downstream from the junction of the inductor and
FB pin (see the All-Ceramic-Capacitor Application section).
Unstable operation manifests itself in two related but distinctly different ways: double-pulsing and fast-feedback
loop instability.
Double-pulsing occurs due to noise on FB or because
the ESR is so low that there isn’t enough voltage ramp in
the output voltage (FB) signal. This “fools” the error comparator into triggering a new cycle immediately after the
400ns minimum off-time period has expired. Doublepulsing is more annoying than harmful, resulting in nothing worse than increased output ripple. However, it can
indicate the possible presence of loop instability, which
is caused by insufficient ESR.
Loop instability can result in oscillations at the output
after line or load perturbations that can trip the overvoltage protection latch or cause the output voltage to fall
below the tolerance limit.
The easiest method for checking stability is to apply a
very fast zero-to-max load transient (see MAX1710
Evaluation Kit manual) and carefully observe the output
voltage ripple envelope for overshoot and ringing. It
can help to simultaneously monitor the inductor current
with an AC current probe. Don’t allow more than one
cycle of ringing after the initial step-response under- or
overshoot.
Input Capacitor Selection
The input capacitor must meet the ripple current
requirement (IRMS) imposed by the switching currents.
Nontantalum chemistries (ceramic, aluminum, or OSCON) are preferred due to their resistance to power-up
surge currents:
 V

OUT (VBATT − VOUT )
I RMS = I LOAD 


VBATT


Power MOSFET Selection
Most of the following MOSFET guidelines focus on the
challenge of obtaining high load-current capability (>5A)
when using high-voltage (>20V) AC adapters. Low-current applications usually require less attention.
For maximum efficiency, choose a high-side MOSFET
(Q1) that has conduction losses equal to the switching
losses at the optimum battery voltage (15V). Check to
ensure that the conduction losses at minimum input voltage don’t exceed the package thermal limits or violate
the overall thermal budget. Check to ensure that conduction losses plus switching losses at the maximum
______________________________________________________________________________________
19
MAX1710/MAX1711/MAX1712
The actual microfarad 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).
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
+5V
VIN = 7V TO 24V*
0.1µF
20Ω
V+
ON/OFF
VDD
VCC
SHDN
BST
SKIP
DH
DAC
INPUTS
Q1
0.5µH
1.6V AT 7A
LX
PGND
FB
CC
FBS
CPU
R2
GND
REF
C2
Q2
DL
0.22µF
R1
0.1µF
MAX1711
MAX1712
D0
D1
D2
D3
D4
C1
1µF
5Ω
1k
1k
1k
470pF
GNDS
TON
1nF
*FOR HIGHER MINIMUM INPUT VOLTAGE,
*LESS OUTPUT CAPACITANCE IS REQUIRED.
C1 = 4 x 4.7µF/25V TAIYO YUDEN (TMK325BJ475K)
C2 = 6 x 47µF/10V TAIYO YUDEN (LMK550BJ476KM)
R1 + R2 = 5mΩ MINIMUM OF PC BOARD TRACE RESISTANCE (TOTAL)
Figure 7. All-Ceramic-Capacitor Application
Table 6. Approximate K-Factors Errors
TON
K
SETTING FACTOR
(kHz)
(µs-V)
APPROXIMATE
K-FACTOR
ERROR (%)
MIN VBATT
AT VOUT = 2V
(V)
200
5
±10
2.6
300
3.3
±10
2.9
400
2.5
±12.5
3.2
550
1.8
±12.5
3.6
input voltage don’t exceed the package ratings or violate
the overall thermal budget.
Choose a low-side MOSFET (Q2) that has the lowest
possible RDS(ON), comes in a moderate to small package (i.e., SO-8), and is reasonably priced. Ensure that
the MAX1710/MAX1711/MAX1712 DL gate driver can
drive Q2; in other words, check that the gate isn’t pulled
up by the high-side switch turning on due to parasitic
drain-to-gate capacitance, causing cross-conduction
problems. Switching losses aren’t an issue for the lowside MOSFET since it’s a zero-voltage switched device
when used in the buck topology.
20
MOSFET Power Dissipation
Worst-case conduction losses occur at the duty factor
extremes. For the high-side MOSFET, the worst-case
power dissipation due to resistance occurs at minimum
battery voltage:
PD(Q1) = (VOUT / VBATT(MIN)) ✕ ILOAD2 ✕ RDS(ON)
Generally, a small high-side MOSFET is desired in order
to reduce switching losses at high input voltages.
However, the RDS(ON) required to stay within package
power-dissipation limits often limits how small the MOSFET can be. Again, the optimum occurs when the switching (AC) losses equal the conduction (RDS(ON)) losses.
High-side switching losses don’t usually become an
issue until the input is greater than approximately 15V.
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
CV2F switching loss equation. If the high-side MOSFET
you’ve chosen for adequate RDS(ON) at low battery voltages becomes extraordinarily hot when subjected to
VBATT(MAX), you must reconsider your choice of MOSFET.
Calculating the power dissipation in Q1 due to switching
losses is difficult, since it must allow for difficult-to-quanti-
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
(
PD(switching) =
CRSS × VBATT(MAX)
)
2
and bulk output capacitance must often be added (see
VSAG equation in the Design Procedure).
Dropout Design Example: VBATT = 3V min, VOUT =
2V, f = 300kHz. The required duty is (VOUT + VSW) /
(VBATT - VSW) = (2V + 0.1V) / (3.0V - 0.1V) = 72.4%. The
worst-case on-time is (VOUT + 0.075) / VBATT ✕ K =
2.075V / 3V ✕ 3.35µs-V ✕ 90% = 2.08µs. The IC duty-factor limitation is:
× f × ILOAD
IGATE
DUTY =
t ON(MIN)
t ON(MIN) + t OFF(MAX)
= 2.08µs + 500ns = 80.6%
where CRSS is the reverse transfer capacitance of Q1
and IGATE is the peak gate-drive source/sink current (1A
typ).
which meets the required duty.
For the low-side MOSFET, Q2, the worst-case power dissipation always occurs at maximum battery voltage:
Remember to include inductor resistance and MOSFET
on-state voltage drops (VSW) when doing worst-case
dropout duty-factor calculations.
PD(Q2) = (1 - VOUT / VBATT(MAX)) ✕ ILOAD2 ✕ RDS(ON)
The absolute 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, you must “overdesign” the circuit
to tolerate ILOAD = ILIMIT(HIGH) + (LIR / 2) ✕ ILOAD(MAX),
where ILIMIT(HIGH) is the maximum valley current allowed
by the current-limit circuit, including threshold tolerance
and on-resistance variation. This means that the
MOSFETs must be very well heatsinked. If short-circuit
protection without overload protection is enough, a normal ILOAD value can be used for calculating component
stresses.
Choose a Schottky diode D1 having a forward voltage
low enough to prevent the Q2 MOSFET body diode from
turning on during the dead time. As a general rule, a
diode having a DC current rating equal to 1/3 of the load
current is sufficient. This diode is optional, and if efficiency isn’t critical it can be removed.
Application Issues
Dropout Performance
The output voltage adjust range for continuous-conduction operation is restricted by the nonadjustable 500ns
(max) minimum off-time one-shot. For best dropout performance, use the slowest (200kHz) on-time setting.
When working with low input voltages, the duty-factor
limit must be calculated using worst-case values for onand off-times. Manufacturing tolerances and internal
propagation delays introduce an error to the TON K-factor. This error is higher at higher frequencies (Table 6).
Also, keep in mind that transient response performance
of buck regulators operated close to dropout is poor,
All-Ceramic-Capacitor Application
Ceramic capacitors have advantages and disadvantages. They have ultra-low ESR, are noncombustible, are
relatively small, and are nonpolarized. On the other
hand, they’re expensive and brittle, and their ultra-low
ESR characteristic can result in excessively high ESR
zero frequencies (affecting stability). In addition, they
can cause output overshoot when going abruptly from
full-load to no-load conditions, unless there are some
bulk tantalum or electrolytic capacitors in parallel to
absorb the stored energy in the inductor. In some cases,
there may be no room for electrolytics, creating a need
for a DC-DC design that uses nothing but ceramics.
The all-ceramic-capacitor application of Figure 7 has the
same basic performance as the 7A Standard Application
Circuit, but replaces the tantalum output capacitors with
ceramics. This design relies on having a minimum of
5mΩ parasitic PC board trace resistance in series with
the capacitor in order to reduce the ESR zero frequency.
This small amount of resistance is easily obtained by
locating the MAX1710/MAX1711/MAX1712 circuit 2 or 3
inches away from the CPU, and placing all the ceramic
capacitors close to the CPU. Resistance values higher
than 5mΩ just improve the stability (which can be
observed by examining the load-transient response
characteristic as shown in the Typical Operating
Characteristics). Avoid adding excess PC board trace
resistance because there’s an efficiency penalty; 5mΩ is
sufficient for the 7A circuit.
Output overshoot determines the minimum output
capacitance requirement. In this example, the switching
frequency has been increased to 550kHz and the inductor value has been reduced to 0.5µH (compared to
300kHz and 2µH for the standard 7A circuit) in order to
______________________________________________________________________________________
21
MAX1710/MAX1711/MAX1712
fy 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
a sanity check using a thermocouple mounted on Q1:
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
minimize the energy transferred from inductor to capacitor during load-step recovery. Even so, the amount of
overshoot is high enough (80mV) that for the MAX1710,
it’s wise to disable OVP or use the MAX1711/MAX1712
with their fixed 2.25V overvoltage protection threshold to
avoid tripping the fault latch (see the overshoot equation
in the Output Capacitor Selection section). The efficiency
penalty for operating at 550kHz is about 2% to 3%,
depending on the input voltage.
Two optional 1kΩ resistors are placed in series with FB
and FBS. These resistors prevent the negative output
voltage spike (that results from tripping OVP) from
pulling SHDN low via its internal ESD diode, which tends
to clear the fault latch, causing “hiccup” restarts.
Setting VOUT with a Resistor-Divider
The output voltage can be adjusted with a resistordivider rather than the DAC if desired (Figure 8). The
drawback of this practice is that the on-time doesn’t
automatically receive correct compensation for changing
output voltage levels. This can result in variable switching frequency as the resistor ratio is changed and/or
excessive switching frequency. The equation for adjusting the output voltage is:
R1 

VOUT = (VFB − 1%) 1 +


R2 
where VFB is the currently selected DAC value. When
using external resistors, FBS remote sensing is not recommended, but GNDS remote sensing is still possible.
Connect FBS to FB and GNDS to remote ground location. In resistor-adjusted circuits, the DAC code should
be set as close as possible to the actual output voltage
so that the switching frequency doesn’t become excesVBATT
VOUT
DL
R1
FB
R2
FBS
Adjusting VOUT Above 2V
The feed-forward circuit that makes the on-time dependent on battery voltage maintains a nearly constant
switching frequency as VIN, ILOAD, and the DAC code
are changed. This works extremely well as long as FB is
connected directly to the output.
When the output is adjusted higher than 2V with a resistor-divider, the switching frequency can be increased to
relatively unreasonable levels as the actual off-time
decreases and isn’t compensated for by a change in ontime; 3.3V is about the maximum limit to the practical
adjustment range. Even at the slowest TON setting and
with the DAC set to 2V, the switching rate will exceed
600kHz.
The trip threshold for output overvoltage protection
scales with the nominal output voltage setting.
2-Stage (5V-Powered) Notebook CPU
Buck Regulator
The most efficient and overall cost-effective solution for
stepping down a high-voltage battery to very low output
voltage is to use a single-stage buck regulator that’s
powered directly from the battery. However, there may
be situations where the battery bus can’t be routed near
the CPU, or where space constraints dictate the smallest
possible local DC-DC converter. In such cases, the 5Vpowered circuit of Figure 9 may be appropriate. The
reduced input voltage allows a higher switching frequency and a much smaller inductor value.
Dynamic DAC Code Changes
(MAX1711/MAX1712)
DH
MAX1710
MAX1711
MAX1712
sive. For highest accuracy, use the MAX1710 when
adjusting VOUT with external resistors. The MAX1710 FB
node has very high impedance, while the MAX1711/
MAX1712 have a 180kΩ ±35% FB impedance, which
degrades VOUT accuracy.
1k
GNDS
Changing the output voltage dynamically by switching
DAC codes “on-the-fly” can be used to help make
power-savings/performance trade-offs in the host system. Several important design issues arise from this
practice.
First, know that attempting to slew the output upward
quickly causes large current surges at the battery as the
IC goes into output current limiting during the transition.
Surge currents can be controlled either by counting the
DAC code slowly (50kHz or slower rate suggested), or
by modulating the ILIM current-limit threshold.
The DAC inputs must be driven quickly to the new value
so the device doesn’t wrongly interpret a disallowed
Figure 8. Setting VOUT with a Resistor-Divider
22
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
MAX1710/MAX1711/MAX1712
VIN
4.5V TO 5.5V
1µF
20Ω
C1
4 x 10µF/25V
1µF
V+ VDD
ILIM VCC
SHDN
ON/OFF
BST
D0
DH
D1
D/A
INPUTS
IRF7805
D2
0.1µF
D3
D4**
0.22µF
REF
MAX1710
MAX1711
MAX1712
L1
0.5µH
LX
DL
IRF7805
VOUT
1.6V AT 7A
C2
3 x 470µF
KEMET
T510
470pF
CC
PGND
FB
VCC
1k
GND
100k
GNDS
FBS
PGOOD
TON
SKIP
1k
TO REMOTE
LOAD
OVP*
*MAX1710 ONLY
**MAX1711 ONLY
Figure 9. 5V-Powered, 7A CPU Buck Regulator
DAC code from the transitory value. Use 100ns maximum rise and fall times.
Selecting the output capacitors in dynamically adjusted
V CORE applications can be tricky due to trade-offs
between capacitor capacity and ESR. In other words, if
the capacitor has sufficiently low ESR to meet the loadtransient response specification, its large capacity may
cause excessive input surge currents. On the other
hand, a purely ceramic capacitor may not have enough
capacity to prevent overvoltage during the transition from
full- to no-load condition (see the overshoot equation
under Output Capacitor Selection). It may be necessary
to mix capacitor types or use specialized capacitors
such as those shown in Figure 7 in order to achieve the
required ESR while staying within the min/max capacitance value window.
If the minimum load is very light, it may be necessary to
assert forced PWM mode (via SKIP) during the transition
period to guarantee some output sink current capability.
Otherwise, the output voltage won’t ramp downwards
until pulled down by external load current.
Using forced PWM mode repeatedly to ensure sink current capability can have side effects, however. The energy taken from the output by the synchronous rectifier
isn’t lost, but is instead returned to the input. If the frequency of the high-to-low output voltage transition is high
enough, efficiency will be degraded by the resistive “friction” losses associated with shuttling energy between
input and output capacitors. Also, if the output is being
overdriven by an external source (such as an external
docking-station power supply), forced PWM mode may
cause the battery voltage to become pumped up, possibly overvoltaging the battery.
High-Power, Dynamically
Adjustable CPU Application
The MAX1711/MAX1712 VCORE regulator of Figure 10 is
designed to have its output voltage switched between
1.3V and 1.45V in less than 100µs, while causing a minimum level of input surge current. To this end, the output
capacitors were selected for having the correct value to
a) support the needed ESR, b) prevent excess load-
______________________________________________________________________________________
23
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
+5V INPUT
VBATT
10V TO 22V
6 x 10µF/25V CERAMIC
0.1µF
1µF
20Ω
7
15
1
VDD
VCC
V+
BST
0.22µF
9
DH
REF
22
2Ω
CMPSH3
24
IRF7805
470pF
5
10
ON/OFF
LSB
2
20
19
18
DAC
INPUTS
17
MSB
16
CC
0.1µF
MAX1711
MAX1712
LX
GND
DL
SHDN
D0
PGND
23
1µH/20A
OUTPUT
+1.5V AT 15A
13
10x
220µF
4V
OS-CON
14
2 x IRF7805
20µF
CERAMIC
D1
D2
FB
3
FBS 4
11
GNDS
12
PGOOD
21
SKIP
ILIM
D3
D4
8
TON
N.C.
1k
6
40k
1%
2N7002
POWERGOOD
200k
1%
2N7002
+3.3V
0.1µF
TRANSITION DETECTOR
12
1k
13
A4
VCC
B4
Y4
10
A3
B3
1000pF
Y3
5
1N4148
820pF
5%
+3.3V
2N7002
A2
B2
Y2
6
1000pF
30k
30k
1N4148
1
1000pF
MAX986
8
74HC86
4
1k
100k
1%
1N4148
9
1k
49.9k
1%
11
1000pF
1k
100k
1%
3MΩ
14
2
A1
B1
GND
7
Y1
3
100k
1N4148
100k
2N7002
TIMER BLOCK
Figure 10.15A Dynamically Adjustable Notebook CPU Supply with Battery-Surge Current Limiting
24
______________________________________________________________________________________
2N7002
;
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
MAX1710/MAX1711/MAX1712
VBATT
GND IN
ALL ANALOG GROUNDS
CONNECT TO GND ONLY.
VIA TO PGND
NEAR Q2 SOURCE
MAX1710
MAX1711
MAX1712
VIA TO GNDS
VCC
CIN
GND
OUT
CC
REF
ILIM
GND
;;
Q1
D1
VDD
Q2
COUT
VOUT
VIA TO SOURCE
OF Q2
CONNECT GND TO PGND
BENEATH IC, 1 POINT ONLY.
SPLIT ANALOG GND PLANE AS SHOWN.
VIA TO FBS
L1
VIA TO FB
NEAR COUT+
VIA TO LX
NOTES: "STAR" GROUND IS USED.
D1 IS DIRECTLY ACROSS Q2.
INDUCTOR DISCHARGE PATH HAS LOW DC RESISTANCE.
Figure 11. Power-Stage PC Board Layout Example
recovery overshoot, and c) minimize input surge currents.
The optional 74HC86 exclusive-OR gate detects code
transitions on each of the four most-significant DAC
inputs. The transition detector output goes to a precision
pulse stretcher, a timer that extends the pulse for 75µs
(nominal). This signal then feeds three circuits: the
power-good detector, the SKIP input, and the ILIM current-limit control input, thus reducing the current-limit
threshold during the transition interval (in order to reduce
battery current surges). Likewise, SKIP going high
asserts forced PWM mode in order to drag the output
voltage down to the new value. Forced PWM mode is
incompatible with good light-load efficiency due to
inductor-current recirculation losses and gate-drive losses. Therefore, SKIP is driven high only during the 100µs
max transition interval.
The power-good output signal is the logical OR of the
75µs timer signal and the MAX1711/MAX1712 PGOOD
signal. The internal PGOOD detector circuit monitors
only output undervoltage; PGOOD will probably go low
during upward transitions, but not downward. The final
power-good output will always go low for at least 75µs
due to the timer signal.
Load current capability is 15A peak and 12A continuous
over a 10V to 22V input range. All three MOSFETs
require good heatsinking. See the MAX1711 EV kit manual for a complete bill of materials.
PC Board Layout Guidelines
Careful PC board layout is critical to achieving low
switching losses and clean, stable operation. The
switching power stage requires particular attention
(Figure 11). 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:
______________________________________________________________________________________
25
MAX1710/MAX1711/MAX1712
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
• Keep the high-current paths short, especially at the
ground terminals. This practice is essential for stable,
jitter-free operation.
• Connect GND and PGND together close to the IC.
Carefully follow the grounding instructions under step
4 of the Layout Procedure.
• Keep the power traces and load connections short.
This practice is essential for high efficiency. The use
of thick copper PC boards (2 oz vs. 1 oz) can enhance full-load 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 milliohm of excess trace resistance
causes a measurable efficiency penalty.
• LX and PGND connections to Q2 for current limiting
must be made using Kelvin sense connections in
order to guarantee the current-limit accuracy. With
SO-8 MOSFETs, this is best done by routing power to
the MOSFETs from outside using the top copper
layer, while tying in PGND and LX inside (underneath)
the SO-8 package.
• 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-side
MOSFET or between the inductor and the output filter
capacitor.
• Ensure that the FB connection to COUT is short and
direct. However, in some cases it may be desirable to
deliberately introduce some trace length between the
FB inductor node and the output filter capacitor (see
the All-Ceramic-Capacitor Application section).
• Route high-speed switching nodes away from sensitive analog areas (CC, REF, ILIM).
• Make all pin-strap control input connections (SKIP,
ILIM, etc.) to GND or VCC rather than PGND or VDD.
26
Layout Procedure
1) Place the power components first, with ground terminals adjacent (Q2 source, CIN-, COUT-, D1 anode). If
possible, make all these connections on the top layer
with wide, copper-filled areas.
2) Mount the controller IC adjacent to MOSFET Q2,
preferably on the back side opposite Q2 to keep LXPGND current-sense lines and the DL gate-drive line
short and wide. The DL gate trace must be short and
wide, measuring 10 to 20 squares (50 to 100 mils
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 11. This diagram can be viewed as
having three separate ground planes: output ground,
where all the high-power components go; the PGND
plane, where the PGND pin and VDD bypass capacitor go; and an analog GND plane, where sensitive
analog components go. The analog ground plane
and PGND plane must meet only at a single point
directly beneath the IC. These two planes are then
connected to the high-power output ground with a
short connection from VDD cap/PGND to the source
of the low-side MOSFET, Q2 (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.
______________________________________________________________________________________
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
TOP VIEW
TOP VIEW
V+ 1
24 DH
V+ 1
24 DH
SHDN 2
23 LX
SHDN 2
23 LX
FB 3
22 BST
FB 3
22 BST
FBS 4
21 SKIP
FBS 4
21 SKIP
CC 5
MAX1710
MAX1711
MAX1712
20 D0
CC 5
ILIM 6
19 D1
ILIM 6
VCC 7
18 D2
VCC 7
18 D2
TON 8
17 D3
TON 8
17 D3
REF 9
16 OVP
REF 9
16 D4
GND 10
15 VDD
GND 10
15 VDD
GNDS 11
14 PGND
PGOOD 12
13 DL
QSOP
GNDS 11
20 D0
19 D1
14 PGND
PGOOD 12
13 DL
QSOP
______________________________________________________________________________________
27
MAX1710/MAX1711/MAX1712
Pin Configurations
High-Speed, Digitally Adjusted
Step-Down Controllers for Notebook CPUs
QSOP.EPS
MAX1710/MAX1711/MAX1712
Package Information
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implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
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is a registered trademark of Maxim Integrated Products.