MAXIM MAX1586CETM

19-3089; Rev 3; 12/08
KIT
ATION
EVALU
E
L
B
AVAILA
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Features
The MAX1586/MAX1587 power-management ICs are
optimized for devices using Intel XScale® microprocessors, including Smart Phones, PDAs, internet appliances, and other portable devices requiring substantial
computing and multimedia capability at low power.
The ICs integrate seven high-performance, low-operatingcurrent power supplies along with supervisory and
management functions. Included are three step-down
DC-DC outputs, three linear regulators, and a seventh
always-on output. DC-DC converters power I/O, DRAM,
and the CPU core. The I/O supply can be preset to
3.3V or adjusted to other values. The DRAM supply on
the A and C devices is preset for 1.8V or 2.5V, while the
MAX1586B DRAM supply is preset for 3.3V or 2.5V. The
DRAM supply on all parts can also be adjusted with
external resistors. The CPU core supply is serial programmed for dynamic voltage management and, on C
devices, can supply up to 0.9A. Linear-regulated outputs are provided for SRAM, PLL, and USIM supplies.
♦ Six Regulators in One Package
Step-Down DC-DC for I/O at 1.3A
Step-Down DC-DC for Memory at 0.9A
Step-Down Serial-Programmed DC-DC for CORE
Up to 0.9A
Three LDO Outputs for SRAM, PLL, and USIM
Always-On Output for VCC_BATT
To minimize quiescent current, critical power supplies
have bypass “sleep” LDOs that can be activated when
output current is very low. Other functions include separate on/off control for all DC-DC converters, low-battery and dead-battery detection, a reset and power-OK
output, a backup-battery input, and a two-wire serial
interface.
All DC-DC outputs use fast, 1MHz PWM switching and
small external components. They operate with fixed-frequency PWM control and automatically switch from
PWM to skip-mode operation at light loads to reduce
operating current and extend battery life. The core output can be forced into PWM mode at all loads to minimize noise. A 2.6V to 5.5V input voltage range allows
1-cell lithium-ion (Li+), 3-cell NiMH, or a regulated 5V
input. The MAX1587 is available in a tiny 6mm x 6mm,
40-pin thin QFN package. The MAX1586 features an
additional linear regulator (V6) for VCC_USIM and lowbattery and dead- battery comparators. The MAX1586
is available in a 7mm x 7mm, 48-pin thin QFN package.
♦ Low Operating Current
60µA in Sleep Mode (Sleep LDOs On)
130µA with DC-DCs On (Core Off)
200µA All Regulators On, No Load
5µA Shutdown Current
♦ Optimized for XScale Processors
♦ Backup-Battery Input
♦ 1MHz PWM Switching Allows Small External
Components
♦ Tiny 6mm x 6mm, 40-Pin and 7mm x 7mm, 48-Pin
Thin QFN Packages
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX1586AETM
-40°C to +85°C
48 Thin QFN 7mm x 7mm
MAX1586BETM
-40°C to +85°C
48 Thin QFN 7mm x 7mm
MAX1586CETM
-40°C to +85°C
48 Thin QFN 7mm x 7mm
MAX1587AETL
-40°C to +85°C
40 Thin QFN 6mm x 6mm
MAX1587CETL
-40°C to +85°C
40 Thin QFN 6mm x 6mm
Pin Configurations and Selector Guide appear at end of
data sheet.
Simplified Functional Diagram
MAIN BATTERY
BACKUP
BATTERY
Applications
IN
MAX1586
MAX1587
BKBT
PDA, Palmtop, and Wireless Handhelds
Third-Generation Smart Cell Phones
Internet Appliances and Web-Books
V1
VCC_IO 3.3V
V2
VCC_MEM 2.5V
V3
VCC_CORE
0.8V TO 1.3V
MR
nRESET
RSO
V4
VCC_PLL 1.3V
nVCC_FAULT
POK
V5
VCC_SRAM 1.1V
nBATT_FAULT
DBO
V6
VCC_USIM
0V, 1.8V, 3.0V
V7
VCC_BATT
SYS_EN
ON1-2
PWR_EN
ON3-6
Intel XScale is a registered trademark of Intel Corp.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim's website at www.maxim-ic.com.
1
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
General Description
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
ABSOLUTE MAXIMUM RATINGS
IN, IN45, IN6, MR, LBO, DBO, RSO, POK, SCL, SDA,
BKBT, V7, SLP, SRAD, PWM3 to GND...............-0.3V to +6V
REF, CC_, ON_, FB_, DBI, LBI, V1, V2, RAMP, BYP,
MR to GND ...........................................-0.3V to (VIN + 0.3V)
PV1, PV2, PV3, SLPIN to IN...................................-0.3V to +0.3V
V4, V5 to GND ..........................................-0.3V to (VIN45 + 0.3V)
V6 to GND ..................................................-0.3V to (VIN6 + 0.3V)
PV1 to PG1 ............................................................-0.3V to +6.0V
PV2 to PG2 ............................................................-0.3V to +6.0V
PV3 to PG3 ............................................................-0.3V to +6.0V
LX1 Continuous Current....................................-1.30A to +1.30A
LX2 Continuous Current........................................-0.9A to +0.9A
LX3 Continuous Current........................................-0.9A to +0.9A
PG1, PG2, PG3 to GND.........................................-0.3V to +0.3V
V1, V2, V4, V5, V6 Output Short-Circuit Duration.......Continuous
Continuous Power Dissipation (TA = +70°C)
6mm x 6mm 40-Pin Thin QFN
(derate 26.3mW/°C above +70°C) ...........................2105mW
7mm x 7mm 48-Pin Thin QFN
(derate 26.3mW/°C above +70°C) ...........................2105mW
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = 0°C to +85°C, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
PV1, PV2, PV3, SLPIN, IN Supply
Voltage Range
CONDITIONS
MIN
Quiescent Current
REF Output Voltage
UNITS
5.5
V
5.5
V
VIN rising
2.25
2.40
2.55
VIN falling
2.200
2.35
2.525
2.4
No load (IPV1 +
IPV2 + IPV3 + IIN +
ISLPIN + IIN45 +
IIN6)
MAX1586
Only V7 on, VIN below
DBI threshold VIN = 3.0V MAX1587
32
REG1 and REG2 on in
switch mode, REG3 off
MAX1586
130
MAX1587
130
REG1 and REG2 on in
sleep mode, REG3 off
MAX1586
60
All REGs on
BKBT Input Current
MAX
2.6
IN45, IN6 Supply Voltage Range
IN Undervoltage-Lockout (UVLO)
Threshold
TYP
PV1, PV2, PV3, IN, and SLPIN must connect together
externally
5
MAX1587
60
MAX1586
225
MAX1587
200
ON1 = 0
4
ON1 = IN
0.8
0 to 10µA load
V
µA
µA
1.2375
1.25
1.2625
V
SYNCHRONOUS-BUCK PWM REG1
REG1 Voltage Accuracy
FB1 = GND, 3.6V ≤ VPV1 ≤ 5.5V, load = 0 to 1300mA
3.25
3.3
3.35
V
FB1 Voltage Accuracy
FB1 used with external resistors, 3.6V ≤ VPV1 ≤ 5.5V,
load = 0 to 1300mA
1.231
1.25
1.269
V
FB1 Input Current
FB1 used with external resistors
100
nA
Error-Amplifier Transconductance
Referred to FB
87
Load = 800mA
180
280
Load = 1300mA
293
450
Dropout Voltage (Note 1)
2
_______________________________________________________________________________________
µS
mV
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = 0°C to +85°C, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
p-Channel On-Resistance
n-Channel On-Resistance
CONDITIONS
MIN
TYP
MAX
ILX1 = -180mA
0.18
0.3
ILX1 = -180mA, VPV1 = 2.6V
0.21
0.35
ILX1 = 180mA
0.13
0.225
ILX1 = 180mA, VPV1 = 2.6V
0.15
0.25
Current-Sense Transresistance
0.5
p-Channel Current-Limit Threshold
-1.55
-1.80
UNITS
Ω
Ω
V/A
-2.10
A
PWM Skip-Mode Transition Load
Current
Decreasing load current (Note 2)
OUT1 Maximum Output Current
2.6V ≤ VPV1 ≤ 5.5V (Note 3)
1.3
LX1 Leakage Current
VPV1 = 5.5V, LX1 = GND or PV1, VON1 = 0V
-20
+0.1
+20
FB2 = GND, 3.6V ≤ VPV2 ≤ 5.5V, load = 0 to 900mA
2.463
2.5
2.537
MAX1586A, MAX1587A, FB2 = IN, 3.6V ≤ VPV2 ≤ 5.5V,
load = 0 to 900mA
1.773
1.8
1.827
MAX1586B, FB2 = IN, 3.6V ≤ VPV2 ≤ 5.5V,
load = 0 to 900mA
3.25
3.3
3.35
FB2 Voltage Accuracy
FB2 used with external resistors, 3.6V ≤ VPV2 ≤ 5.5V,
load = 0 to 900mA
1.231
1.25
1.269
V
FB2 Input Current
FB2 used with external resistors, VFB2 = 1.25V
100
nA
Error-Amplifier Transconductance
Referred to FB
87
Dropout Voltage
Load = 900mA (Note 1)
243
380
mV
30
mA
A
µA
SYNCHRONOUS-BUCK PWM REG2
REG2 Voltage Accuracy
p-Channel On-Resistance
n-Channel On-Resistance
ILX2 = -180mA
0.225
0.375
0.26
0.425
ILX2 = 180mA
0.15
0.25
ILX2 = 180mA, VPV2 = 2.6V
0.17
0.275
0.7
p-Channel Current-Limit Threshold
PWM Skip-Mode Transition Load
Current
µS
ILX2 = -180mA, VPV2 = 2.6V
Current-Sense Transresistance
-1.1
Decreasing load current (Note 2)
-1.275
2.6V ≤ VPV2_ ≤ 5.5V (Note 3)
0.9
LX2 Leakage Current
VPV2_ = 5.5V, LX2 = GND or PV2, VON2 = 0V
-10
Ω
Ω
V/A
-1.50
30
OUT2 Maximum Output Current
V
A
mA
A
+0.1
+10
µA
SYNCHRONOUS-BUCK PWM REG3
REG3 Output Voltage Accuracy
Error-Amplifier Transconductance
REG3 from 0.7V to
1.475V, 2.6V ≤
VPV3 ≤ 5.5V
MAX1586A, MAX1586B, MAX1587A,
load = 0 to 500mA
-1.5
+1.5
MAX1586C, MAX1587C,
load = 0 to 900mA
-1.5
+1.5
%
68
µS
_______________________________________________________________________________________
3
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
ELECTRICAL CHARACTERISTICS (continued)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
ELECTRICAL CHARACTERISTICS (continued)
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = 0°C to +85°C, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
p-Channel On-Resistance
n-Channel On-Resistance
Current-Sense Transresistance
p-Channel Current-Limit Threshold
TYP
MAX
ILX3 = -180mA
CONDITIONS
MIN
0.225
0.375
ILX2 = -180mA, VPV3 = 2.6V
0.26
0.425
ILX3 = 180mA
0.15
0.25
ILX3 = 180mA, VPV3 = 2.6V
0.17
0.275
MAX1586A, MAX1586B, MAX1587A
1.1
MAX1586C, MAX1587C
0.55
-0.60
-0.7
-0.85
MAX1586C, MAX1587C
-1.125
-1.35
-1.700
Decreasing load current (Note 2)
OUT3 Maximum Output Current
2.6V ≤ VPV3_ ≤ 5.5V
(Note 3)
LX3 Leakage Current
VPV3_ = 5.5V, LX3 = GND or PV2, VON3 = 0V
30
MAX1586A, MAX1586B, MAX1587A
0.5
MAX 1586C, MAX1587C
0.9
-10
Ω
Ω
V/A
MAX1586A, MAX1586B, MAX1587A
PWM Skip-Mode Transition Load
Current
UNITS
A
mA
A
+0.1
+10
µA
LDOS V4, V5, V6, V1 SLEEP, V2 SLEEP, AND V7 OUTPUT
V4, V5, V6, V1 SLEEP, V2 SLEEP
Output Current
35
V7 Output Current
30
REG4 Output Voltage
Load = 0.1mA to 35mA
REG4 Noise
With 1µF COUT and 0.01µF CBYP
REG5 Output Voltage
Load = 0.1mA to 35mA
IN45, IN6 Input Voltage Range
V7 Output Voltage
mA
1.261
1.3
1.067
1.1
2.4
MAX1586
1.339
15
0V setting (either ON6 low or serial programmed)
REG6 Output Voltage (POR Default
to 0V, Set by Serial Input)
mA
µVRMS
1.133
V
5.5
V
0
1.8V setting, load = 0.1mA to 35mA
1.746
1.8
1.854
2.5V setting, load = 0.1mA to 35mA
2.425
2.5
2.575
3.0V setting, load = 0.1mA to 35mA
2.91
3.0
3.09
V1 on and in regulation
VV1
Set to same output voltage as REG1 and REG2
V1 and V2 SLEEP Dropout Voltage
LOAD = 20mA
V6 Dropout Voltage
V7 Switch Voltage Drop
+3.0
%
75
150
mV
MAX1586 3V mode, load = 30mA, 2.5V mode, load = 30mA
110
200
mV
LOAD = 20mA, VBKBT = VV1 = 3.0V
100
200
V4, V5, V6 Output Current Limit
-3.0
V
V
VBKBT
V1 off
V1 and V2 SLEEP Output Voltage
Accuracy
V
40
90
BKBT Leakage
mV
mA
1
µA
1.07
MHz
OSCILLATOR
PWM Switching Frequency
0.93
1
Rising
92
94.75
97
Falling
88.5
90.5
92.5
SUPERVISORY/MANAGEMENT FUNCTIONS
POK Trip Threshold (Note 4)
4
_______________________________________________________________________________________
%
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = 0°C to +85°C, unless otherwise noted. Typical values
are at TA = +25°C.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
LBI = IN (for preset)
3.51
3.6
3.69
1.00
1.02
UNITS
LBI Threshold (Falling)
MAX1586 hysteresis is
5% (typ)
With resistors at LBI
0.98
DBI Threshold (Falling)
MAX1586 hysteresis is
5% (typ)
DBI = IN (for preset)
3.024
3.15
3.276
With resistors at LBI
1.208
1.232
1.256
RSO Threshold (Falling)
Voltage on REG7, hysteresis is 5% (typ)
2.25
2.41
2.56
V
61
65.5
70
ms
-50
-5
RSO Deassert Delay
LBI Input Bias Current
MAX1586
DBI Input Bias Current
MAX1586
Thermal-Shutdown Temperature
TJ rising
15
Thermal-Shutdown Hysteresis
V
V
nA
50
nA
+160
°C
15
°C
LOGIC INPUTS AND OUTPUTS
LBO, DBO, POK, RSO, SDA Output
Low Level
2.6V ≤ V7 ≤ 5.5V, sinking 1mA
0.4
V
LBO, DBO, POK, RSO Output Low
Level
V7 = 1V, sinking 100µA
0.4
V
LBO, DBO, POK, RSO Output-High
Leakage Current
Pin = 5.5V
0.2
µA
ON_, SCL, SDA, SLP, PWM3, MR,
SRAD Input High Level
2.6V ≤ VIN ≤ 5.5V
ON_, SCL, SDA, SLP, PWM3, MR,
SRAD Input Low Level
2.6V ≤ VIN ≤ 5.5V
ON_, SCL, SDA, SLP, PWM3, MR,
SRAD Input Leakage Current
Pin = GND, 5.5V
1.6
V
-1
0.4
V
+1
µA
400
kHz
SERIAL INTERFACE
Clock Frequency
Bus-Free Time Between START and
STOP
1.3
µs
Hold Time Repeated START Condition
0.6
µs
CLK Low Period
1.3
µs
CLK High Period
0.6
µs
Setup Time Repeated START Condition
0.6
µs
DATA Hold Time
0
µs
DATA Setup Time
100
ns
Maximum Pulse Width of Spikes that
Must be Suppressed by the Input
Filter of Both DATA and CLK Signals
Setup Time for STOP Condition
50
0.6
ns
µs
_______________________________________________________________________________________
5
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
ELECTRICAL CHARACTERISTICS (continued)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
ELECTRICAL CHARACTERISTICS
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = -40°C to +85°C, unless otherwise noted.) (Note 5)
PARAMETER
PV1, PV2, PV3, SLPIN, IN Supply
Voltage Range
CONDITIONS
PV1, PV2, PV3, IN, and SLPIN must connect together
externally
IN45, IN6 Supply Voltage Range
IN Undervoltage-Lockout (UVLO)
Threshold
MIN
MAX
UNITS
2.6
5.5
V
2.4
5.5
V
VIN rising
2.25
2.55
VIN falling
2.200
2.525
V
SYNCHRONOUS-BUCK PWM REG1
REG1 Voltage Accuracy
FB1 Voltage Accuracy
FB1 Input Current
Dropout Voltage
p-Channel On-Resistance
n-Channel On-Resistance
FB1 = GND, 3.6V ≤ VPV1 ≤ 5.5V, load = 0 to 1300mA
3.25
3.35
FB1 = IN, 3.6V ≤ VPV1 ≤ 5.5V, load = 0 to 1300mA
2.955
3.045
FB1 used with external resistors, 3.6V ≤ VPV1 ≤ 5.5V,
load = 0 to 1300mA
1.231
1.269
V
nA
FB1 used with external resistors
100
Load = 800mA (Note 1)
280
Load = 1300mA (Note 1)
450
ILX1 = -180mA
0.3
ILX1 = -180mA, VPV1 = 2.6V
0.35
ILX1 = 180mA
0.225
ILX1 = 180mA, VPV1 = 2.6V
0.25
p-Channel Current-Limit Threshold
-1.55
V
mV
Ω
Ω
-2.10
A
µA
OUT1 Maximum Output Current
2.6V ≤ VPV1 ≤ 5.5V (Note 3)
1.30
LX1 Leakage Current
VPV1 = 5.5V, LX1 = GND or PV1, VON1 = 0V
-10
+10
FB2 = GND, 3.6V ≤ VPV2 ≤ 5.5V, load = 0 to 900mA
2.463
2.537
MAX1586A, MAX1587A, FB2 = IN, 3.6V ≤ VPV2 ≤ 5.5V,
load = 0 to 900mA
1.773
1.827
MAX1586B, FB2 = IN, 3.6V ≤ VPV2 ≤ 5.5V,
load = 0 to 900mA
3.25
3.35
FB2 Voltage Accuracy
FB2 used with external resistors, 3.6V ≤ VPV2 ≤ 5.5V,
load = 0 to 900mA
1.231
1.269
V
FB2 Input Current
FB2 used with external resistors, VFB2 = 1.25V
100
nA
Dropout Voltage
Load = 900mA (Note 1)
380
mV
A
SYNCHRONOUS-BUCK PWM REG2
REG2 Voltage Accuracy
p-Channel On-Resistance
n-Channel On-Resistance
ILX2 = -180mA
0.375
ILX2 = -180mA, VPV2 = 2.6V
0.425
ILX2 = -180mA
0.25
ILX2 = -180mA, VPV2 = 2.6V
0.275
p-Channel Current-Limit Threshold
-1.1
OUT2 Maximum Output Current
2.6V ≤ VPV2_≤ 5.5V (Note 3)
0.9
LX2 Leakage Current
VPV2 = 5.5V, LX2 = GND or PV2, VON2 = 0V
-10
6
_______________________________________________________________________________________
V
Ω
Ω
-1.50
A
+10
µA
A
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = -40°C to +85°C, unless otherwise noted.) (Note 5)
PARAMETER
CONDITIONS
MIN
MAX
MAX1586A, MAX1586B, MAX1587A,
load = 0 to 500mA
-1.5
+1.5
MAX1586C, MAX1587C,
load = 0 to 900mA
-1.5
+1.5
UNITS
SYNCHRONOUS-BUCK PWM REG3
REG3 Output Voltage Accuracy
p-Channel On-Resistance
n-Channel On-Resistance
p-Channel Current-Limit Threshold
REG3 from 0.7V to
1.475V, 2.6V ≤
VPV3 ≤ 5.5V
%
ILX3 = -180mA
0.375
ILX2 = -180mA, VPV3 = 2.6V
0.425
ILX3 = 180mA
0.25
ILX3 = 180mA, VPV3 = 2.6V
0.275
MAX1586A, MAX1586B, MAX1587A
-0.60
-0.85
MAX1586C, MAX1587C
-1.125
-1.700
OUT3 Maximum Output Current
2.6V ≤ VPV3_≤ 5.5V
(Note 3)
LX3 Leakage Current
VPV3 = 5.5V, LX3 = GND or PV2, VON3 = 0V
MAX1586A, MAX1586B, MAX1587A
0.5
MAX1586C, MAX1587C
0.9
-10
Ω
Ω
A
A
+10
µA
LDOs V4, V5, V6, V1 SLEEP, V2 SLEEP, AND V7 OUTPUT
V4, V5, V6, V1 SLEEP, V2 SLEEP
Output Current
35
mA
V7 Output Current
30
mA
REG4 Output Voltage
Load = 0.1mA to 35mA
1.254
1.346
V
REG5 Output Voltage
Load = 0.1mA to 35mA
1.061
1.139
V
V
IN45, IN6 Input Voltage Range
REG6 Output Voltage (POR Default
to 0V, Set by Serial Input)
MAX1586
2.4
5.5
1.8V setting, load = 0.1mA to 35mA
1.737
1.863
2.5V setting, load = 0.1mA to 35mA
2.412
2.588
3.0V setting, load = 0.1mA to 35mA
2.895
3.105
-3.5
+3.5
%
V
V1 and V2 SLEEP Output Voltage
Accuracy
Set to same output voltage as REG1 and REG2
V1 and V2 SLEEP Dropout Voltage
Load = 20mA
150
mV
V6 Dropout Voltage
MAX1586 3V mode, load = 30mA; 2.5V mode, load = 30mA
200
mV
V7 Switch Voltage Drop
Load = 20mA, VBKBT = VV1 = 3.0V
200
mV
V4, V5, V6 Output Current Limit
40
BKBT Leakage
mA
1
µA
0.93
1.07
MHz
Rising
92
97
Falling
88.5
92.5
LBI = IN (for preset)
3.51
3.69
With resistors at LBI
0.98
1.02
OSCILLATOR
PWM Switching Frequency
SUPERVISORY/MANAGEMENT FUNCTIONS
POK Trip Threshold (Note 4)
LBI Threshold (Falling)
MAX1586,
hysteresis is 5% (typ)
%
V
_______________________________________________________________________________________
7
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
ELECTRICAL CHARACTERISTICS (continued)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
ELECTRICAL CHARACTERISTICS (continued)
(VIN = 3.6V, VBKBT = 3.0V, VLBI = 1.1V, VDBI = 1.35V, circuit of Figure 5, TA = -40°C to +85°C, unless otherwise noted.) (Note 5)
PARAMETER
CONDITIONS
MIN
MAX
DBI = IN (for preset)
2.993
3.307
With resistors at LBI
1.208
1.256
2.25
2.60
V
62
69
ms
DBI Threshold (Falling)
MAX1586,
hysteresis is 5% (typ)
RSO Threshold (Falling)
Voltage on REG7, hysteresis is 5% (typ)
RSO Deassert Delay
-50
UNITS
V
LBI Input Bias Current
MAX1586
DBI Input Bias Current
MAX1586
75
nA
nA
LBO, DBO, POK, RSO, SDA Output
Low Level
2.6V ≤ V7 ≤ 5.5V, sinking 1mA
0.4
V
LBO, DBO, POK, RSO, SDA Output
Low Level
V7 = 1V, sinking 100µA
0.4
V
LBO, DBO, POK, RSO Output-High
Leakage Current
Pin = 5.5V
0.2
µA
ON_, SCL, SDA, SLP, PWM3, MR,
SRAD Input High Level
2.6V ≤ VIN ≤ 5.5V
ON_, SCL, SDA, SLP, PWM3, MR,
SRAD Input Low Level
2.6V ≤ VIN ≤ 5.5V
ON_, SCL, SDA, SLP, PWM3, MR,
SRAD Input Leakage Current
Pin = GND, 5.5V
LOGIC INPUTS AND OUTPUTS
1.6
-1
V
0.4
V
+1
µA
400
kHz
SERIAL INTERFACE
Clock Frequency
Bus-Free Time Between START and
STOP
1.3
µs
Hold Time Repeated START
Condition
0.6
µs
CLK Low Period
1.3
µs
CLK High Period
0.6
µs
Setup Time Repeated START
Condition
0.6
µs
DATA Hold Time
0
µs
DATA Setup Time
100
ns
Setup Time for STOP Condition
0.6
µs
8
_______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Note 1: Dropout voltage is guaranteed by the P-channel switch resistance and assumes a maximum inductor resistance of 45mΩ.
Note 2: The PWM-skip-mode transition has approximately 10mA of hysteresis.
Note 3: The maximum output current is guaranteed by the following equation:
VOUT (1 − D)
2 x f xL
=
(1 − D)
1 + (RN + RL)
2 x f xL
ILIM −
IOUT max
where:
D=
VOUT + IOUT(MAX) (RN + RL)
VIN + IOUT(MAX) (RN − RP)
RN = N-channel synchronous rectifier RDS(ON)
RP = P-channel power switch RDS(ON)
RL = external inductor ESR
IOUT(MAX) = maximum required load current
f = operating frequency minimum
L = external inductor value
ILIM can be substituted for IOUT(MAX) (desired) when solving for D. This assumes that the inductor ripple current is
small relative to the absolute value.
Note 4: POK only indicates the status of supplies that are enabled (except V7). When a supply is turned off, POK does not trigger
low. When a supply is turned on, POK immediately goes low until that supply reaches regulation. POK is forced low when all
supplies (except V7) are disabled.
Note 5: Specifications to -40°C are guaranteed by design, not production tested.
and
_______________________________________________________________________________________
9
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
ELECTRICAL CHARACTERISTICS (continued)
Typical Operating Characteristics
(Circuit of Figure 6, VIN = 3.6V, TA = +25°C, unless otherwise noted.)
70
60
VIN = 4.0V
80
70
60
50
50
1
10
100
1000
1
90
VIN = 3.6V
80
70
VIN = 5.0V
60
50
VIN = 4.0V
40
10
100
0.1
1
10
VIN = 3.6V
80
VIN = 5.0V
70
60
VIN = 4.0V
100
L3 = 4.7μH
C17 = 44μF
90
80
VIN = 3.6V
MAX1586C
MAX1587C
70
60
VIN = 5.0V
50
40
20
10
40
1
10
100
1000
0.1
1
10
100
1
10
100
REG1 SLEEP LDO 3.3V OUTPUT
EFFICIENCY vs. LOAD CURRENT
REG2 SLEEP LDO 2.5V OUTPUT
EFFICIENCY vs. LOAD CURRENT
QUIESCENT CURRENT
vs. SUPPLY VOLTAGE
VIN = 5.0V
70
60
50
70
VIN = 4.0V
60
50
40
40
VIN = 5.0V
30
1
LOAD CURRENT (mA)
10
MAX1586A/86B/87A toc07
VIN = 3.6V
1000
220
BKBT BIASED AT 3.6V
200
180
INPUT CURRENT (μA)
80
80
EFFICIENCY (%)
VIN = 3.6V
90
MAX1586A/86B/87A toc06
LOAD CURRENT (mA)
MAX1586A/86B/87A toc05
LOAD CURRENT (mA)
VIN = 4.0V
0.1
0.1
1000
LOAD CURRENT (mA)
100
90
VIN = 4.0V
50
10
0.1
1000
REG3 1.3V OUTPUT WITH FORCED-PWM
EFFICIENCY vs. LOAD CURRENT
90
L3 = 4.7μH
C17 = 44μF
100
REG3 1.3V OUTPUT WITH FORCED-PWM
EFFICIENCY vs. LOAD CURRENT
30
20
10
60
1000
30
MAX1586C
MAX1587C
VIN = 5.0V
LOAD CURRENT (mA)
100
EFFICIENCY (%)
MAX1586A/86B/87A toc03B
100
VIN = 4.0V
70
LOAD CURRENT (mA)
LOAD CURRENT (mA)
REG3 1.3V OUTPUT EFFICIENCY
vs. LOAD CURRENT
80
40
0.1
10,000
EFFICIENCY (%)
0.1
VIN = 3.6V
50
40
40
EFFICIENCY (%)
VIN = 5.0V
MAX1586A/86B/87A toc04
EFFICIENCY (%)
80
VIN = 5.0V
90
MAX1586A/86B/87A toc03
VIN = 4.0V
VIN = 3.6V
90
100
MAX1586A/86B/87A toc04B
90
100
EFFICIENCY (%)
VIN = 3.6V
EFFICIENCY (%)
MAX1586A/86B/87A toc01
100
REG3 1.3V OUTPUT EFFICIENCY
vs. LOAD CURRENT
MAX1586A/86B/87A toc02
REG2 2.5V OUTPUT EFFICIENCY
vs. LOAD CURRENT
REG1 3.3V OUTPUT EFFICIENCY
vs. LOAD CURRENT
EFFICIENCY (%)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
V1, V2, AND V3 ON
160
140
V1 AND V2 ON
120
V1 ON
100
80
40
V1 AND V2 SLEEP
V1 SLEEP
20
ALL BUT V7 OFF
60
0
0.1
1
LOAD CURRENT (mA)
10
0
1
2
3
INPUT VOLTAGE (V)
______________________________________________________________________________________
4
5
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
DROPOUT VOLTAGE
vs. LOAD CURRENT
CHANGE IN OUTPUT VOLTAGE
vs. LOAD CURRENT
150
100
REG1 3.3V OUTPUT
50
0
150
100
REG1 3.3V OUTPUT
50
REG2 2.5V OUTPUT
REG3 1.3V OUTPUT
0
-50
VIN = 3.6V
-100
200
400
600
800
1000
1200
0
200
400
600
800
LOAD CURRENT (mA)
LOAD CURRENT (mA)
SWITCHING FREQUENCY
vs. SUPPLY VOLTAGE
REFERENCE VOLTAGE
vs. TEMPERATURE
1000
1.260
1.255
960
TA = +25°C
TA = -40°C
920
1200
MAX1586A/86B/87A toc11
TA = +85°C
REFERENCE VOLTAGE (V)
1040
1000
1.265
MAX1586A/86B/87A toc10
0
SWITCHING FREQUENCY (kHz)
MAX1586A/86B/87A toc09
200
CHANGE IN OUTPUT VOLTAGE (mV)
250
DROPOUT VOLTAGE (mV)
200
MAX1586A/86B/87A toc08
300
1.250
1.245
1.240
1.235
1.230
880
1.225
2.5
3.0
3.5
4.0
4.5
5.0
-40
5.5
-15
10
35
60
INPUT VOLTAGE (V)
TEMPERATURE (°C)
REG1 SWITCHING WAVEFORMS
WITH 800mA LOAD
REG1 SWITCHING WAVEFORMS
WITH 10mA LOAD
MAX1586A/86B/87A toc13
MAX1586A/86B/87A toc12
10mv/div
AC-COUPLED
V1
85
VLX1
50mv/div
AC-COUPLED
V1
VLX1
IL1
2V/div
2V/div
0
0
500mA/div
500mA/div
IL1
0
0
400ns/div
20μs/div
______________________________________________________________________________________
11
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
Typical Operating Characteristics (continued)
(Circuit of Figure 6, VIN = 3.6V, TA = +25°C, unless otherwise noted.)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Typical Operating Characteristics (continued)
(Circuit of Figure 6, VIN = 3.6V, TA = +25°C, unless otherwise noted.)
REG3 SWITCHING WAVEFORMS
WITH 250mA LOAD
REG3 PULSE-SKIP SWITCHING
WAVEFORMS WITH 10mA LOAD
MAX1586A/86B/87A toc14
MAX1586A/86B/87A toc15
10mv/div
AC-COUPLED
V3
2V/div
VLX3
10mv/div
AC-COUPLED
V3
2V/div
VLX3
0
0
500mA/div
IL3
0
500mA/div
IL3
0
400ns/div
10μs/div
REG3 FORCED-PWM SWITCHING
WAVEFORMS WITH 10mA LOAD
V7 AND RSO
STARTUP WAVEFORMS
MAX1586A/86B/87A toc17
MAX1586A/86B/87A toc16
10mv/div
AC-COUPLED
V3
2V/div
VIN
0V
VLX3
2V/div
V7
2V/div
0V
0V
500mA/div
IL3
2V/div
RSO
0mA
0V
10ms/div
400ns/div
SYS_EN STARTUP WAVEFORMS
PWR_EN STARTUP WAVEFORMS
MAX1586A/86B/87A toc18
VEN1
AND
VEN2
MAX1586A/86B/87A toc19
2V/div
VEN3
AND
VEN45
2V/div
2V/div
2V/div
V3
2V/div
2V/div
V1
V4
V2
2V/div
V5
2V/div
VPOK
2V/div
VPOK
2ms/div
12
1ms/div
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
REG1 LOAD-TRANSIENT RESPONSE
REG2 LOAD-TRANSIENT RESPONSE
MAX1586A/86B/87A toc20
MAX1586A/86B/87A toc21
V1
100mV/div
AC-COUPLED
V2
100mV/div
AC-COUPLED
ILOAD1
200mA/div
ILOAD2
200mA/div
0A
0A
200μs/div
200μs/div
REG3 LOAD-TRANSIENT RESPONSE
REG3 LOAD-TRANSIENT RESPONSE
MAX1586A/86B/87A toc22B
MAX1586A/86B/87A toc22
MAX1586C
MAX1587C
V3
100mV/div
AC-COUPLED
ILOAD3
200mA/div
V3
100mV/div
ILOAD3
500mA/div
850mA
50mA
0A
100μs/div
200μs/div
REG3 OUTPUT VOLTAGE CHANGING FROM
1.3V TO 1.0V WITH DIFFERENT VALUES OF CRAMP
REG6 USIM TRANSITIONS
MAX1586A/86B/87A toc23
CRAMP = 2200pF
CRAMP = 1500pF
MAX1586A/86B/87A toc24
500mV/div
V6
2.5V TO 3.0V
V6
1.8V TO 2.5V
CRAMP = 1000pF
CRAMP = 330pF
200μs/div
V6
0 TO 1.8V
0
10μs/div
______________________________________________________________________________________
13
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
Typical Operating Characteristics (continued)
(Circuit of Figure 6, VIN = 3.6V, TA = +25°C, unless otherwise noted.)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Pin Description
PIN
MAX
1586
MAX
1587
NAME
FUNCTION
1
—
LBI
Dual-Mode™, Low-Battery Input. Connect to IN to set the low-battery threshold to 3.6V (no resistors
needed). Connect LBI to a resistor-divider for an adjustable LBI threshold. When IN is below the set
threshold, LBO output switches low. LBO is deactivated and forced low when IN is below the dead-battery
(DBI) threshold and when all REGs are disabled.
2
40
CC1
REG1 Compensation Node. Connect a series resistor and capacitor from CC1 to GND to compensate the
regulation loop. See the Compensation and Stability section.
3
1
FB1
REG1 Feedback Input. Connect FB1 to GND to set V1 to 3.3V. Connect FB1 to external feedback resistors
for other output voltages.
4
2
BKBT
Input Connection for Backup Battery. This input can also accept the output of an external boost converter.
5
3
V7
Also known as VCC_BATT. V7 is always active if main or backup power is present. It is the first regulator
that powers up. V7 has two states:
1) V7 tracks V1 if ON1 is high and V1 is in regulation.
2) V7 tracks VBKBT when ON1 is low or V1 is out of regulation.
6
4
V1
REG1 Voltage-Sense Input. Connect directly to the REG1 output voltage. The output voltage is set by FB1
to either 3.3V or adjustable with resistors.
7
5
8
6
V2
REG2 Voltage-Sense Input. Connect directly to the REG2 output voltage. The output voltage is set by FB2
to either 1.8V/2.5V (MAX1586A, MAX1587A), 3.3V/2.5V (MAX1586B), or adjustable with resistors.
9
7
FB2
REG2 Feedback Input. Connect to GND to set V2 to 2.5V on all devices. Connect FB2 to IN to set V2 to
1.8V on the MAX1586A and MAX1587A. Connect FB2 to IN to set V2 to 3.3V on the MAX1586B. Connect
FB2 to external feedback resistors for other voltages.
10
8
CC2
REG2 Compensation Node. Connect a series resistor and capacitor from CC2 to GND to compensate the
regulation loop. See the Compensation and Stability section.
SLPIN Input to V1 and V2 Sleep Regulators. The input to the standby regulators at V1 and V2. Connect SLPIN to IN.
11
9
POK
Power-OK Output. Open-drain output that is low when any of the V1–V6 outputs are below their regulation
threshold. When all activated outputs are in regulation, POK is high impedance. POK maintains a valid low
output with V7 as low as 1V. POK does not flag an out-of-regulation condition while REG3 is transitioning
between voltages set by serial programming. POK also does not flag for any REG channel that has been
turned off; however, if all REG channels are off (V1–V6), then POK is forced low. If IN < UVLO, then POK is
low. POK is expected to connect to nVCC_FAULT.
12
10
SCL
Serial Clock Input
13
11
SDA
Serial Data Input. Data is read on the rising edge of SCL. Serial data programs the REG3 (core) and REG6
(VCC_USIM) voltage. REG3 and REG6 can be programmed even when off, but at least one of the ON_ pins
must be logic-high to activate the serial interface. On power-up, REG3 defaults to 1.3V and REG6 defaults
to 0V.
14
12
PWM3
Force V3 to PWM at All Loads. Connect PWM3 to GND for normal operation (skip mode at light loads). Drive
or connect high for forced-PWM operation at all loads for V3 only.
15
—
LBO
Low-Battery Output. Open-drain output that goes low when IN is below the threshold set by LBI.
Dual Mode is a trademark of Maxim Integrated Products, Inc.
14
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
PIN
MAX
1586
MAX
1587
NAME
FUNCTION
16
13
PV2
REG2 Power Input. Bypass to PG2 with a 4.7µF or greater low-ESR capacitor. PV1, PV2, PV3, and IN must
connect together externally.
17
14
LX2
REG2 Switching Node. Connects to REG2 inductor.
18
15
PG2
REG2 Power Ground. Connect directly to a power-ground plane. Connect PG1, PG2, PG3, and GND
together at a single point as close as possible to the IC.
19
16
IN
20
17
RAMP
V3 Ramp-Rate Control. A capacitor connected from RAMP to GND sets the rate-of-change when V3 is
changed. The output impedance of RAMP is 100kΩ. FB3 regulates to 1.28 x VRAMP.
21
18
GND
Analog Ground
22
19
REF
Reference Output. Output of the 1.25V reference. Bypass to GND with a 0.1µF or greater capacitor.
23
20
BYP
Low-Noise LDO Bypass. Low-noise bypass pin for V4 LDO. Connect a 0.01µF capacitor from BYP to GND.
24
—
DBO
Dead or Missing Battery Output. DBO is an open-drain output that goes low when IN is below the threshold
set by DBI. DBO does not deactivate any MAX1586/MAX1587 regulator outputs. DBO is expected to
connect to nBATT_FAULT on Intel CPUs.
25
21
ON2
On/Off Input for REG2. Drive high to turn on. When enabled, the REG2 output soft-starts. ON2 has
hysteresis so an RC can be used to implement manual sequencing with respect to other inputs. It is
expected that ON1, ON2, and ON6 are connected to SYS_EN.
26
—
ON4
On/Off Input for REG4. Drive high to turn on. When enabled, the REG4 output activates. ON4 has hysteresis
so an RC can be used to implement manual sequencing with respect to other inputs. It is expected that
ON4 is connected to PWR_EN.
27
23
V4
28
24
IN45
29
25
V5
30
—
ON5
On/Off Input for REG5. Drive high to turn on. When enabled, the MAX1586/MAX1587 soft-starts the REG5
output. ON5 has hysteresis so an RC can be used to implement manual sequencing with respect to other
inputs. It is expected that ON5 is connected to PWR_EN.
31
26
PG3
REG3 Power Ground. Connect directly to a power-ground plane. Connect PG1, PG2, PG3, and GND
together at a single point as close as possible to the IC.
32
27
LX3
REG3 Switching Node. Connects to the REG3 inductor.
33
28
PV3
REG3 Power Input. Bypass to PG3 with a 4.7µF or greater low-ESR ceramic capacitor. PV1, PV2, PV3, and
IN must connect together externally.
34
34
ON3
On/Off Input for REG3 (Core). Drive high to turn on. When enabled, the REG3 output ramps up. ON3 has
hysteresis so an RC can be used to implement manual sequencing with respect to other inputs. It is
expected that ON3 is driven from CPU SYS_EN.
Main Battery Input. This input provides power to the IC.
Also Known as VCC_PLL. 1.3V, 35mA linear-regulator output for PLL. Regulator input is IN45.
Power Input to V4 and V5 LDOs. Typically connected to V2, but can also connect to IN or another voltage
from 2.5V to VIN.
Also Known as VCC_SRAM. 1.1V, 35mA linear-regulator output for CPU SRAM. Regulator input is IN45.
______________________________________________________________________________________
15
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
Pin Description (continued)
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Pin Description (continued)
PIN
MAX
1586
MAX
1587
NAME
35
29
SRAD
Serial Address Bit. SRAD allows the serial address of the MAX1586/MAX1587 to be changed in case it
conflicts with another serial device. If SRAD = GND, A1 = 0. If SRAD = IN, A1 = 1.
36
30
RSO
Open-Drain Reset Output. Deasserts when V7 exceeds 2.55V (typ rising). Has 65ms delay before release.
RSO is expected to connect to nRESET on the CPU.
37
31
MR
Manual Reset Input. A low input at MR causes the RSO output to go low and also resets the V3 output to its
default 1.3V setting. MR impacts no other MAX1586/MAX1587 functions.
38
32
CC3
REG 3 Compensation Node. Connect a series resistor and capacitor from CC3 to GND to compensate the
regulation loop. See the Compensation and Stability section.
39
33
FB3
REG3 Feedback-Sense Input. Connect directly to the REG3 output voltage. Output voltage is set by the
serial interface.
40
—
ON6
On/Off Input for REG6. Drive high to turn on. When enabled, the REG6 output activates. ON6 has hysteresis
so an RC can be used to implement manual sequencing with respect to other inputs. It is expected that
ON1, ON2, and ON6 are connected to SYS_EN.
41
—
V6
Also known as VCC_USIM. Linear-regulator output. This voltage is programmable through the I2C interface
to 0V, 1.8V, 2.5V, or 3.0V. The default voltage is 0V. REG6 is activated when ON6 is high.
42
—
IN6
Power Input to the V6 LDO. Typically connected to V1, but can also connect to IN.
43
36
PG1
REG1 Power Ground. Connect directly to a power-ground plane. Connect PG1, PG2, PG3, and GND
together at a single point as close as possible to the IC.
44
37
LX1
REG1 Switching Node. Connects to the REG1 inductor.
45
38
PV1
REG1 Power Input. Bypass to PG2 with a 4.7µF or greater low-ESR ceramic capacitor. PV1, PV2, PV3, and
IN must connect together externally.
46
35
ON1
On/Off Input for REG1. Drive high to turn on REG1. When enabled, the REG1 output soft-starts. ON1 has
hysteresis so an RC can be used to implement manual sequencing with respect to other inputs. It is
expected that ON1, ON2, and ON6 connect to SYS_EN.
47
39
SLP
Sleep Input. SLP selects which regulators ON1 and ON2 turn on. SLP = high is normal operation (ON1 and
ON2 are the enables for the V1 and V2 DC-DC converters). SLP = low is sleep operation (ON1 and ON2 are
the enables for the V1 and V2 LDOs).
48
—
DBI
Dual-Mode, Dead-Battery Input. Connect DBI to IN to set the dead-battery falling threshold to 3.15V (no
resistors needed). Connect DBI to a resistor-divider for an adjustable DBI threshold.
—
22
ON45
On/Off Input for REG4 and REG5. Drive high to turn on. When enabled, the REG4 and REG5 outputs
activate. ON45 has hysteresis so an RC can be used to implement manual sequencing with respect to
other inputs. It is expected that ON45 is connected to PWR_EN.
EP
EP
EP
FUNCTION
Exposed Metal Pad. Connect the exposed pad to ground. Connecting the exposed pad to ground does not
remove the requirement for proper ground connections to the appropriate ground pins.
Purchase of I2C components from Maxim Integrated Products,
Inc. or one of its sublicensed Associated Companies, conveys
a license under the Philips I2C Patent Rights to use these components in an I2C system, provided that the system conforms
to the I2C Standard Specification as defined by Philips.
16
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
MAIN
BATT
IN
SLPIN
DBI (3.15V OR ADJ)
UVLO
AND
BATT
MON
LBI (3.6V OR ADJ)
MAX1586
PV1
STEP-DOWN
PWM
REG1
REF
REF
1.25V
OPEN-DRAIN LOW-BATT OUT
OPEN-DRAIN DEAD-BATT OUT
TO nBATT_FAULT
LX1
V1, VCC_IO
3.3V WITH FB1 = GND,
OR ADJ WITH RESISTORS
ON
LBO
PG1
DBO
V1
SLEEP
LDO
FB1
ON1
FROM CPU
SYS_EN
PV2
ON2
RUN
SLEEP
ON
SLP
TO V1
STEP-DOWN
PWM
REG2
TO BATT
LX2
V2, VCC_MEM
2.5V WITH FB2 = GND,
1.8V WITH FB2 = IN (MAX1586A, MAX1587A)
3.3V WITH FB2 = IN (MAX1586B)
OR ADJ WITH RESISTORS
BKBT
Li+
BACKUP
BATTERY
REG1 OK
PG2
V7, VCC_BATT
(1ST SUPPLY, ALWAYS ON)
TO CPU
nRESET
V7
V2
RSO
V7
RESET
2.425V
SLEEP
LDO
FB2
PV3
TO BATT
65ms
RESET INPUT
FORCE REG3
TO PWM
TO CPU
nVCC_FAULT
STEP-DOWN
PWM
REG3
MR
PWM3
LX3
V3, VCC_CORE
0.7V TO 1.475V
500mA (MAX1586A, MAX1586B, MAX1587A)
900mA (MAX1586C, MAX1587C)
PWM
POK
PG3
V1–V6
POWEROK
ADJ
ON
FB3
ON3
IN45
RAMP
TO V2
V4
FROM CPU
PWR_EN
V4, VCC_PLL
1.3V, 35mA
BYP
100kΩ
LDO
REG
4
V3
DAC
ON4
ON5
LDO
REG
5
V5, VCC_SRAM
1.1V, 35mA
V5
CC1
CC2
CC3
IN6
TO V2
V6
I 2C
SERIAL
GND
SRAD SCL SDA
LDO
REG
6
ON6
VCC_USIM
0V, 1.8V, 3.0V (DEF = 0V)
FROM CPU
SYS_EN
Figure 1. MAX1586 Functional Diagram (The MAX1587 omits some features. See the Pin Description section.)
______________________________________________________________________________________
17
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
BATT
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Detailed Description
The MAX1586/MAX1587 power-management ICs are
optimized for devices using Intel XScale microprocessors, including third-generation smart cell phones,
PDAs, internet appliances, and other portable devices
requiring substantial computing and multimedia
capability at low power. The MAX1586A/MAX1586B/
MAX1587A comply with Intel Processor Power
specifications.
The ICs integrate seven high-performance, low-operating-current power supplies along with supervisory and
management functions. Regulator outputs include three
step-down DC-DC outputs (V1, V2, and V3), three linear regulators (V4, V5, and V6), and one always-on output, V7 (Intel VCC_BATT). The V1 step-down DC-DC
converter provides 3.3V or adjustable output voltage for
I/O and peripherals. The V2 step-down DC-DC converter on the MAX1586A and MAX1587A is preset for 1.8V
or 2.5V, while the MAX1586B V2 supply is preset for
3.3V or 2.5V. V2 can also be adjusted with external
resistors on all parts. The V3 step-down DC-DC converter provides a serial-programmed output for powering microprocessor cores. The three linear regulators
(V4, V5, and V6) provide power for PLL, SRAM, and
USIM.
To minimize sleep-state quiescent current, V1 and V2
have bypass “sleep” LDOs that can be activated to
minimize battery drain when output current is very low.
Other functions include separate on/off control for all
DC-DC converters, low-battery and dead-battery
detection, a power-OK output, a backup-battery input,
and a two-wire serial interface.
All DC-DC outputs use fast, 1MHz PWM switching and
small external components. They operate with fixed-frequency PWM control and automatically switch from
PWM to skip-mode operation at light loads to reduce
operating current and extend battery life. The V3 core
output is capable of forced-PWM operation at all loads.
The 2.6V to 5.5V input voltage range allows 1-cell Li+,
3-cell NiMH, or a regulated 5V input.
The following power-supply descriptions include the
Intel terms for the various voltages in parenthesis. For
example, the MAX1586/MAX1587 V1 output is referred
to as VCC_IO in Intel documentation. See Figure 1.
V1 and V2 (VCC_IO, VCC_MEM)
Step-Down DC-DC Converters
V1 is a 1MHz current-mode step-down converter. The V1
output voltage can be preset to 3.3V or adjusted using a
resistor voltage-divider. V1 supplies loads up to 1300mA.
V2 is also a 1MHz current-mode step-down converter.
The V2 step-down DC-DC converter on the MAX1586A
and MAX1587A is preset for 1.8V or 2.5V, while the
MAX1586B V2 supply is preset for 3.3V or 2.5V. V2 can
also be adjusted with external resistors on all parts. V2
supplies loads up to 900mA.
Under moderate to heavy loading, the converters operate
in a low-noise PWM mode with constant frequency and
modulated pulse width. Switching harmonics generated
by fixed-frequency operation are consistent and easily filtered. Efficiency is enhanced under light loading (<30mA
typ), by assuming an Idle Mode™ during which the converter switches only as needed to service the load.
Synchronous Rectification
Internal n-channel synchronous rectifiers eliminate the
need for external Schottky diodes and improve efficiency. The synchronous rectifier turns on during the second half of each cycle (off-time). During this time, the
voltage across the inductor is reversed, and the inductor current falls. In normal operation (not forced PWM),
the synchronous rectifier turns off at the end of the
cycle (at which time another on-time begins) or when
the inductor current approaches zero.
100% Duty-Cycle Operation
If the inductor current does not rise sufficiently to supply the load during the on-time, the switch remains on,
allowing operation up to 100% duty cycle. This allows
the output voltage to maintain regulation while the input
voltage approaches the regulation voltage. Dropout
voltage is approximately 180mV for an 800mA load on
V1 and 220mV for an 800mA load on V2. During
dropout, the high-side p-channel MOSFET turns on,
and the controller enters a low-current-consumption
mode. The device remains in this mode until the regulator channel is no longer in dropout.
Sleep LDOs
In addition to the high-efficiency step-down converters,
V1 and V2 can also be supplied with low-quiescent current, low-dropout (LDO) linear regulators that can be
used in sleep mode or at any time when the load current
is very low. The sleep LDOs can source up to 35mA. To
enable the sleep LDOs, drive SLP low. When SLP is high,
the switching step-down converters are active. The output voltage of the sleep LDOs is set to be the same as
the switching step-down converters as described in the
Setting the Output Voltages section. SLPIN is the input to
the V1 and V2 sleep LDOs and must connect to IN.
Idle Mode is a trademark of Maxim Integrated Products, Inc.
18
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
V3 is a 1MHz current-mode step-down converter. The
MAX1586A, MAX1586B, and MAX1587A supply loads
up to 500mA from V3 while the MAX1586C and
MAX1587C supply loads up to 1A.
The V3 output is set by the I 2 C serial interface to
between 0.7V and 1.475V in 25mV increments. The
default output voltage on power-up and after a reset is
1.3V. See the Serial Interface section for programming
details. See the Applications Information for instructions
on how to increase the V3 output voltage.
Forced PWM on REG3
Under moderate to heavy loading, the V3 always operates
in a low-noise PWM mode with constant frequency and
modulated pulse width. Switching harmonics generated by
fixed-frequency operation are consistent and easily filtered.
With light loads (<30mA) and PWM3 low, V3 operates
in an enhanced-efficiency Idle Mode during which the
converter switches only as needed to service the load.
With PWM3 high, V3 operates in low-noise forced-PWM
mode under all load conditions.
Linear Regulators (V4, V5, and V6)
V4 (VCC_PLL)
V4 is a linear regulator that provides a fixed 1.3V output
and supplies loads up to 35mA. The power input for the
V4 and V5 linear regulators is IN45, which is typically
connected to V2. To enable V4 on the MAX1586, drive
ON4 high, or drive ON4 low for shutdown. On the
MAX1587, the enable pins for V4 and V5 are combined.
Drive ON45 high to enable V4 and V5, or drive ON45 low
for shutdown. V4 is intended to connect to VCC_PLL.
V5 (VCC_SRAM)
V5 is a linear regulator that provides a fixed 1.1V output
and supplies loads up to 35mA. The power input for the
V4 and V5 linear regulators is IN45, which is typically
connected to V2. To enable V5 on the MAX1586, drive
ON5 high, or drive ON5 low for shutdown. On the
MAX1587, the enable pins for V4 and V5 are combined.
Drive ON45 high to enable V4 and V5, or drive ON45 low
for shutdown. V5 is intended to connect to VCC_SRAM.
V6 (VCC_USIM—MAX1586 Only)
V6 is a linear regulator on the MAX1586 that supplies
loads up to 35mA. The V6 output voltage is programmed with the I2C serial interface to 0V, 1.8V, 2.5V,
or 3.0V. The power-up default for V6 is 0V. See the
Serial Interface section for details on changing the voltage. The power input for the V6 linear regulator is IN6,
which is typically connected to V1. To enable V6, drive
ON6 high, or drive ON6 low for shutdown. V6 is intended to connect to VCC_USIM.
V7 Always-On Output (VCC_BATT)
The V7 output is always active if V1 is enabled and in
regulation or if backup power is present. When ON1 is
high and V1 is in regulation, V7 is sourced from V1 by
an internal MOSFET switch. When ON1 is low or V1 is
out of regulation, V7 is sourced from BKBT by a second
on-chip MOSFET. V7 can supply loads up to 30mA. V7
is intended to connect to VCC_BATT on Intel CPUs.
Due to variations in system implementation, BKBT and
V7 can be utilized in different ways. See the BackupBattery and V7 Configurations section for information on
how to use BKBT and V7.
Quiescent Operating Current
in Various States
The MAX1586/MAX1587 are designed for optimum efficiency and minimum operating current for all typical
operating modes, including sleep and deep sleep.
These states are outlined in Table 1.
Table 1. Quiescent Operating Current in Various States
OPERATING
POWER MODE
DESCRIPTION
RUN
All supplies on and running
IDLE
All supplies on and running, peripherals on
SENSE
STANDBY
SLEEP
DEEP SLEEP
All supplies on, minimal loading, peripherals monitored
TYPICAL MAX1586/MAX1587
NO-LOAD OPERATING CURRENT
200µA MAX1587,
225µA MAX1586
All supplies on, minimal loading, peripherals not monitored
PWR_EN controlled voltages (V3, V4, V5) are off. V1 and V2 on.
60µA if V1 and V2 SLEEP LDOs on;
130µA if V1, V2 step-down DC-DCs enabled
All supplies off except V7. V7 biased from backup battery.
5µA MAX1587 if IN > DBI threshold;
32µA MAX1586 if IN > DBI threshold;
4µA if IN < DBI threshold
______________________________________________________________________________________
19
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
V3 (VCC_CORE) Step-Down
DC-DC Converter
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Voltage Monitors, Reset, and
Undervoltage-Lockout Functions
IN
Undervoltage Lockout
When the input voltage is below 2.35V (typ), an undervoltage-lockout (UVLO) circuit disables the IC. The
inputs remain high impedance while in UVLO, reducing
battery load under this condition. All serial registers are
maintained with the input voltage down to at least 2.35V.
Reset Output (RSO) and MR Input
The reset output (RSO) is low when the MR input is low
or when V7 is below 2.425V. V7 is powered from V1
(when enabled) or the backup-battery input (BKBT).
RSO normally goes low:
1) When power is first applied in configurations with no
separate backup battery (external diode from IN to
BKBT).
MAX1586
MAX1587
MR
Figure 2. An RC delay connected from IN to MR ensures that
the 65ms RSO release delay remains in effect for any
sequence of IN and V7.
MAIN BATTERY
R1
438kΩ
2) When power is removed in configurations with no
separate backup battery (external diode from IN to
BKBT).
3) If the backup battery falls below 2.425V when V1 is
off or out of regulation.
4) When the manual reset button is pressed (MR goes
low).
If VIN is >2.4V, an internal timer delays the release of
RSO for 65ms after V7 rises above 2.3V. However, if VIN
< 2.4V when V7 exceeds 2.3V, or if VIN and V7 rise at the
same time, RSO deasserts immediately with no 65ms
delay. There is no delay in the second case because the
timer circuitry is deactivated to minimize operating current during VIN undervoltage lockout.
If it is desired to have a 65ms RSO release delay for any
sequence of VIN and V7, the circuit in Figure 2 may be
used. An RC connected from IN to MR delays the rise of
MR until after VIN powers up. The 65ms timer is valid for
either sequence of V7 and VIN and does not release until
65ms after both are up. The only regulator output that
affects RSO is V7. RSO will not respond to V1–V6, which
are monitored by POK. Also, RSO is high impedance
and does not function if BKBT is not powered.
MR is a manual reset input for hardware reset. A low
input at MR causes the RSO output to go low for at least
65ms and also resets the V3 output to its default 1.3V setting. MR impacts no other MAX1586/MAX1587 functions.
Dead-Battery and Low-Battery Comparators—
DBI, LBI (MAX1586 only)
The DBI and LBI inputs monitor input power (usually a
battery) and trigger the DBO and LBO outputs. The
dead-battery comparator triggers DBO when the battery
20
IN
MAX1586
DBI (1.232V THRESHOLD)
R2
62kΩ
LBI (1.00V THRESHOLD)
R3
200kΩ
Figure 3. Setting the Low-Battery and Dead-Battery Thresholds
with One Resistor Chain. The values shown set a DBI threshold
of 3.3V and an LBI threshold of 3.5V (no resistors are needed
for the factory preset thresholds).
(VIN) discharges to the dead-battery threshold. The
factory-set 3.15V threshold is selected by connecting
DBI to IN, or the threshold can be programmed with a
resistor-divider at DBI. The low-battery comparator has
a factory-set 3.6V threshold that is selected by connecting LBI to IN, or its threshold can be programmed with a
resistor-divider at LBI.
One three-resistor-divider can set both DBI and LBI
(R1, R2, and R3 in Figure 3) according to the following
equations:
1) Choose R3 to be less than 250kΩ.
⎛ VDBITH ⎞
1−
VLBITH ⎜⎝
VDB ⎟⎠
VLB
2)
R1 = R3
3)
⎛
R2 = R3 × ⎜
⎝
VDBITH
VLBITH
VLB ⎞
−1
VDB ⎟⎠
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
IN
R4
334kΩ
R6
500kΩ
MAX1586
DBI (1.232V THRESHOLD)
R5
200kΩ
LBI (1.00V THRESHOLD)
R7
200kΩ
Figure 4. Setting the Low-Battery and Dead-Battery Thresholds
with Separate Resistor-Dividers. The values shown set a DBI
threshold of 3.3V and an LBI threshold of 3.5V (no resistors are
needed for factory-preset thresholds).
where VLB is the desired low-battery detection voltage
and VDB is the desired dead-battery detection voltage.
VLBITH is the LBI threshold (1.0V typ) and VDBITH is the
DBI threshold (1.232V typ).
Alternately, LBI and DBI can be set with separate tworesistor-dividers. Choose the lower resistor of the divider
chain to be 250kΩ or less (R5 and R7 in Figure 4). The
equations for upper divider-resistors as a function of
each threshold are then:
⎛ VDB
⎞
R4 = R5 × ⎜
− 1⎟
⎝ VDBITH ⎠
⎛ VLB
⎞
R6 = R7 × ⎜
− 1⎟
⎝ VLBITH ⎠
When resistors are used to set VLB, the threshold at LBI
is 1.00V. When resistors are used to set V DB , the
threshold at DBI is 1.232V. A resistor-set threshold can
also be used for only one of DBI or LBI. The other
threshold can then be factory set by connecting the
appropriate input to IN.
If BKBT is not powered, DBO does not function and is
high impedance. DBO is expected to connect to
nBATT_FAULT on Intel CPUs. If BKBT is not powered,
LBO does not function and is high impedance.
Connection to Processor
and Power Sequencing
Typical processor connections have only power-control
pins, typically labeled PWR_EN and SYS_EN. The
MAX1586/MAX1587 provide numerous on/off control
pins for maximum flexibility. In a typical application,
many of these pins are connected together. ON1, ON2,
and ON6 typically connect to SYS_EN. ON3, ON4, and
ON5 typically connect to PWR_EN. V7 remains on as long
as the main or backup power is connected. Sequencing
is not performed internally on the MAX1586/MAX1587;
however, all ON_ inputs have hysteresis and can connect
to RC networks to set sequencing. For typical connections to Intel CPUs, no external sequencing is required.
Backup-Battery Input
The backup-battery input (BKBT) provides backup
power for V7 when V1 is disabled. Normally, a primary
or rechargeable backup battery is connected to this
pin. If a backup battery is not used, then BKBT should
connect to IN through a diode or external regulator. See
the Backup-Battery and V7 Configurations section for
information on how to use BKBT and V7.
Serial Interface
An I2C-compatible, two-wire serial interface controls
REG3 on the MAX1587, and REG3 and REG6 on the
MAX1586. The serial interface operates when IN exceeds
the 2.40V UVLO threshold and at least one of ON1–ON6
is asserted. The serial interface is shut down to minimize
off-current drain when no regulators are enabled.
______________________________________________________________________________________
21
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
MAIN BATTERY
Power-OK Output (POK)
POK is an open-drain output that goes low when any
activated regulator (V1–V6) is below its regulation
threshold. POK does not monitor V7. When all active
output voltages are within 10% of regulation, POK is
high impedance. POK does not flag an out-of-regulation condition while V3 is transitioning between voltages
set by serial programming or when any regulator channel has been turned off. POK momentarily goes low
when any regulator is turned on, but returns high when
that regulator reaches regulation. When all regulators
(V1–V6) are off, POK is forced low. If the input voltage
is below the UVLO threshold, POK is held low and
maintains a valid low output with IN as low as 1V. If
BKBT is not powered, POK does not function and is
high impedance.
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Table 2. V3 and V6 Serial Programming Codes
D7
X
22
D6
X
D5
0 = PROG V3
1 = PROG V6
D4
D3
D2
D1
D0
OUTPUT
(V)
0
0
0
0
0
0
0.700
0
0
0
0
0
1
0.725
0
0
0
0
1
0
0.750
0
0
0
0
1
1
0.775
0
0
0
1
0
0
0.800
0
0
0
1
0
1
0.825
0
0
0
1
1
0
0.850
0
0
0
1
1
1
0.875
0
0
1
0
0
0
0.900
0
0
1
0
0
1
0.925
0
0
1
0
1
0
0.950
0
0
1
0
1
1
0.975
0
0
1
1
0
0
1.000
0
0
1
1
0
1
1.025
0
0
1
1
1
0
1.050
0
0
1
1
1
1
1.075
0
1
0
0
0
0
1.100
0
1
0
0
0
1
1.125
0
1
0
0
1
0
1.150
0
1
0
0
1
1
1.175
0
1
0
1
0
0
1.200
0
1
0
1
0
1
1.225
0
1
0
1
1
0
1.250
0
1
0
1
1
1
1.275
0
1
1
0
0
0
1.300
0
1
1
0
0
1
1.325
0
1
1
0
1
0
1.350
0
1
1
0
1
1
1.375
0
1
1
1
0
0
1.400
0
1
1
1
0
1
1.425
0
1
1
1
1
0
1.450
1.475
0
1
1
1
1
1
1
X
X
X
0
0
0
1
X
X
X
0
1
1.8
1
X
X
X
1
0
2.5
1
X
X
X
1
1
3.0
______________________________________________________________________________________
DESCRIPTION
V3, CORE
VOLTAGES
V6, USIM
VOLTAGES
[MAX1586
ONLY]
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
tLOW
B
tHIGH
C
D
E
F
G
H
I
J
L
K
M
SCL
SDA
tSU:STA
tHD:STA
A = START CONDITION
B = MSB OF ADDRESS CLOCKED INTO SLAVE
C = LSB OF ADDRESS CLOCKED INTO SLAVE
D = R/W BIT CLOCKED INTO SLAVE
E = SLAVE PULLS SMB DATA LINE LOW
tSU:DAT
tHD:DAT
tSU:STO tBUF
J = ACKNOWLEDGE CLOCKED INTO MASTER
K = ACKNOWLEDGE CLOCK PULSE
L = STOP CONDITION, DATA EXECUTED BY SLAVE
M = NEW START CONDITION
F = ACKNOWLEDGE BIT CLOCKED INTO MASTER
G = MSB OF DATA CLOCKED INTO SLAVE (OP/SUS BIT)
H = LSB OF DATA CLOCKED INTO SLAVE
I = SLAVE PULLS SMB DATA LINE LOW
Figure 5. I2C-Compatible Serial-Interface Timing Diagram
The serial interface consists of a serial data line (SDA)
and a serial clock line (SCL). Standard I2C-compatible
write-byte commands are used. Figure 4 shows a timing diagram for the I 2 C protocol. The MAX1586/
MAX1587 are slave-only devices, relying upon a master
to generate a clock signal. The master (typically a
microprocessor) initiates data transfer on the bus and
generates SCL to permit data transfer. A master device
communicates to the MAX1586/MAX1587 by transmitting the proper address followed by the 8-bit data code
(Table 2). Each transmit sequence is framed by a
START (A) condition and a STOP (L) condition. Each
word transmitted over the bus is 8 bits long and is
always followed by an acknowledge clock pulse.
Table 2 shows the serial data codes used to program
V3 and V6. The default power-up voltage for V3 is 1.3V
and for V6 is 0V.
Bit Transfer
One data bit is transferred during each SCL clock
cycle. The data on SDA must remain stable during the
high period of the SCL clock pulse. Changes in SDA
while SCL is high are control signals (see the START
and STOP Conditions section). Both SDA and SCL idle
high when the bus is not busy.
START and STOP Conditions
When the serial interface is inactive, SDA and SCL idle
high. A master device initiates communication by issuing a START condition. A START condition is a high-tolow transition on SDA with SCL high. A STOP condition
is a low-to-high transition on SDA while SCL is high
(Figure 5). A START condition from the master signals
the beginning of a transmission to the MAX1586/
MAX1587. The master terminates transmission by issuing a not acknowledge followed by a STOP condition
(see the Acknowledge Bit section). The STOP condition
frees the bus.
When a STOP condition or incorrect address is detected, the MAX1586/MAX1587 internally disconnect SCL
from the serial interface until the next START condition,
minimizing digital noise and feedthrough.
Acknowledge Bit (ACK)
The acknowledge bit (ACK) is the ninth bit attached to
every 8-bit data word. The receiving device always
generates ACK. The MAX1586/MAX1587 generate an
ACK when receiving an address or data by pulling SDA
low during the ninth clock period. Monitoring ACK
allows for detection of unsuccessful data transfers. An
unsuccessful data transfer occurs if a receiving device
is busy or if a system fault has occurred. In the event of
an unsuccessful data transfer, the bus master should
reattempt communication at a later time.
Serial Address
A bus master initiates communication with a slave
device by issuing a START condition followed by the
7-bit slave address (Table 3). When idle, the
MAX1586/MAX1587 wait for a START condition followed by its slave address. The serial interface compares each address value bit by bit, allowing the
interface to power down immediately if an incorrect
address is detected.
Table 3. Serial Address
SRAD
A7
A6
A5
A4
A3
A2
A1
A0
RD/W
0
0
0
1
0
1
0
0
0
1
0
0
1
0
1
0
1
0
______________________________________________________________________________________
23
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
A
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
The LSB of the address word is the read/write (R/W) bit.
R/W indicates whether the master is writing or reading
(RD/W 0 = write, RD/W 1 = read). The MAX1586/
MAX1587 only support the SEND BYTE format; therefore, RD/W is required to be 0.
After receiving the proper address, the MAX1586/
MAX1587 issue an ACK by pulling SDA low for one
clock cycle. The MAX1586/MAX1587 have two userprogrammed addresses (Table 3). Address bits A7
through A2 are fixed, while A1 is controlled by SRAD.
Connecting SRAD to GND sets A1 = 0. Connecting
SRAD to IN sets A1 = 1.
V3 Output Ramp-Rate Control
When V3 is dynamically changed with the serial interface, the output voltage changes at a rate controlled by
a capacitor (CRAMP) connected from RAMP to ground.
The voltage change is a conventional RC exponential
described by:
Vo(t) = Vo(0) + dV(1 – exp(-t/(100kΩ CRAMP)))
A useful approximation is that it takes approximately 2.2
RC time constants for V3 to move from 10% to 90% of
the voltage difference. For CRAMP = 1500pF, this time
is 330µs. For 1V to 1.3V change, this equates to
1mV/µs. See the Typical Operating Characteristics for
examples of different ramp-rate settings.
The maximum capacitor value that can be used at
RAMP is 2200pF. If larger values are used, the V3 ramp
rate is still controlled according to the above equation,
but when V3 is first activated, POK indicates an “in regulation” condition before V3 reaches its final voltage.
The RAMP pin is effectively the reference for REG3.
FB3 regulates to 1.28 times the voltage on RAMP.
Design Procedure
Setting the Output Voltages
The outputs V1 and V2 have preset output voltages, but
can also be adjusted using a resistor voltage-divider. To
set V1 to 3.3V, connect FB1 to GND. V2 can be preset to
1.8V or 2.5V on the MAX1586A and MAX1587A. To set
V2 to 1.8V on the MAX1586A and MAX1587A, connect
FB2 to IN. To set to 2.5V, connect FB2 to GND. V2 can
preset to 3.3V or 2.5V on the MAX1587B. To set V2 to
3.3V on the MAX1587B, connect FB2 to IN. To set to
2.5V, connect FB2 to GND.
To set V1 or V2 to other than the preset output voltages,
connect a resistor voltage-divider from the output voltage to the corresponding FB input. The FB_ input bias
current is less than 100nA, so choose the low-side
(FB_-to-GND) resistor (RL) to be 100kΩ or less. Then calculate the high-side (output-to-FB_) resistor (RH) using:
24
RH = RL [(VOUT/1.25) – 1]
The V3 (VCC_CORE) output voltage is set from 0.7V to
1.475V in 25mV steps by the I2C serial interface. See
the Serial Interface section for details.
Linear regulator V4 provides a fixed 1.3V output voltage. Linear regulator V5 provides a fixed 1.1V output
voltage. V4 and V5 voltages are not adjustable.
The output voltage of linear regulator V6 (VCC_USIM) is
set to 0V, 1.8V, 2.5V, or 3.0V by the I2C serial interface.
See the Serial Interface section for details.
Linear regulator V7 (VCC_BATT) tracks the voltage at
V1 as long as ON1 is high and V1 is in regulation. When
ON1 is low or V1 is not in regulation, V7 switches to the
backup battery (VBKBT).
Inductor Selection
The external components required for the step-down
are an inductor, input and output filter capacitors, and a
compensation RC network.
The MAX1586/MAX1587 step-down converters provide
best efficiency with continuous inductor current. A reasonable inductor value (LIDEAL) is derived from:
LIDEAL = [2(VIN) x D(1 - D)]/(IOUT(MAX) x fOSC)
This sets the peak-to-peak inductor current at 1/2 the
DC inductor current. D is the duty cycle:
D = VOUT/ VIN
Given LIDEAL, the peak-to-peak inductor ripple current
is 0.5 x I OUT . The peak inductor current is 1.25 x
I OUT(MAX) . Make sure the saturation current of the
inductor exceeds the peak inductor current and the
rated maximum DC inductor current exceeds the maximum output current (I OUT(MAX)). Inductance values
larger than LIDEAL can be used to optimize efficiency or
to obtain the maximum possible output current. Larger
inductance values accomplish this by supplying a
given load current with a lower inductor peak current.
Typically, output current and efficiency are improved
for inductor values up to about two times LIDEAL. If the
inductance is raised too much, however, the inductor
size may become too large, or the increased inductor
resistance may reduce efficiency more than the gain
derived from lower peak current.
Smaller inductance values allow smaller inductor sizes,
but also result in larger peak inductor current for a
given load. Larger output capacitance may then be
needed to suppress the increase in output ripple
caused by larger peak current.
Capacitor Selection
The input capacitor in a DC-DC converter reduces current peaks drawn from the battery or other input power
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
VRIPPLE(ESR) = IL(PEAK) x ESR
Output capacitor specifics are also discussed in the
Compensation and Stability section.
Compensation and Stability
The relevant characteristics for REG1, REG2, and
REG3 compensation are:
1) Transconductance (from FB_ to CC_), gmEA
2) Current-sense amplifier transresistance, RCS
3) Feedback regulation voltage, VFB (1.25V)
4) Step-down output voltage, VOUT, in V
5) Output load equivalent resistance, RLOAD = VOUT/
ILOAD
The key steps for step-down compensation are:
1) Set the compensation RC zero to cancel the RLOAD
COUT pole.
2) Set the loop crossover at or below approximately
1/10th the switching frequency.
For example, with V IN(MAX) = 5V, V OUT = 2.5V for
REG2, and IOUT = 800mA, then RLOAD = 3.125Ω. For
REG2, RCS = 0.75V/A and gmEA = 87µS.
Choose the crossover frequency, fC ≤ fOSC/10. Choose
100kHz. Then calculate the value of the compensation
capacitor, CC:
CC = (VFB/VOUT) x (RLOAD/RCS) x (gm/(2π x fC))
= (1.25/2.5) x (3.125/0.75) x (87 x
x 100,000)) = 289pF
10 -6/(6.28
Choose 330pF, the next highest standard value.
Now select the compensation resistor, RC, so transientdroop requirements are met. As an example, if 3% transient droop is allowed for the desired load step, the
Table 4. Compensation Parameters
PARAMETER
REG1
REG2
REG3
Error-Amplifier
Transconductance, gmEA
87µS
87µS
68µS
Current-Sense Amp
Transresistance, RCS
0.5V/A
0.75V/A
1.25V/A
Table 5. Typical Compensation Values
COMPONENT OR
PARAMETER
REG1
REG2
REG3
VOUT
3.3V
2.5V
1.3V
Output Current
1300mA
900mA
500mA
Inductor
3.3µH
6.8µH
10µH
Load-Step Droop
3%
3%
3%
Loop Crossover Freq (fC)
100kHz
100kHz
100kHz
CC
330pF
270pF
330pF
RC
240kΩ
240kΩ
240kΩ
COUT
22µF
22µF
22µF
input to the error amplifier moves 0.03 x 1.25V, or
37.5mV. The error-amplifier output drives 37.5mV x
gmEA, or IEAO = 37.5mV x 87µS = 3.26µA across RC to
provide transient gain. Find the value of RC that allows
the required load-step swing from:
RC = RCS x IIND(PK)/IEAO
where IIND(PK) is the peak inductor current. In a stepdown DC-DC converter, if LIDEAL is used, output current relates to inductor current by:
IIND(PK) = 1.25 x IOUT
So for an 800mA output load step with VIN = 3.6V and
VOUT = 2.5V:
RC = RCS x IIND(PK)/IEAO = (0.75V/A) x
(1.25 x 0.8A)/3.26µA = 230kΩ
We choose 240kΩ. Note that the inductor does not limit
the response in this case since it can ramp at (VIN VOUT)/L, or (3.6 - 2.5)/3.3µH = 242mA/µs.
The output filter capacitor is then selected so that the
COUT RLOAD pole cancels the RC CC zero:
COUT x RLOAD = RC x CC
For the example:
RLOAD = VOUT x ILOAD = 2.5V/0.8A =
3.125Ω
COUT = RC x CC/RLOAD = 240kΩ x 330pF/
3.125Ω = 25µF
______________________________________________________________________________________
25
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
source and reduces switching noise in the controller.
The impedance of the input capacitor at the switching
frequency should be less than that of the input source
so high-frequency switching currents do not pass
through the input source.
The output capacitor keeps output ripple small and
ensures control-loop stability. The output capacitor
must also have low impedance at the switching frequency. Ceramic, polymer, and tantalum capacitors
are suitable, with ceramic exhibiting the lowest ESR
and lowest high-frequency impedance.
Output ripple with a ceramic output capacitor is
approximately:
VRIPPLE = IL(PEAK) [1/(2π x fOSC x COUT)]
If the capacitor has significant ESR, the output ripple
component due to capacitor ESR is:
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
BATT
C11
10μF
MAIN
BATT
IN
SLPIN
DBI (3.2V OR ADJ)
UVLO
AND
BATT
MON
LBI (3.6V OR ADJ)
TO
BATT
TO V1
PV1
STEP-DOWN
PWM
REG1
REF
C19
0.1μF
R20
1MΩ
R19
1MΩ
MAX1586
REF
1.25V
LOW-BATT
WARNING
LBO
TO CPU
nBATT_FAULT
DBO
C12
4.7μF
LX1
ON
L1
3.3μH
C15
22μF
V1
VCC_IO
3.3V
1300mA
C16
22μF
V2
VCC_MEM
2.5V
900mA
C17
22μF
V3
VCC_CORE
0.7V TO 1.475V
500mA (MAX1586A, MAX1586B, MAX1587A)
900mA (MAX1586C, MAX1587C)
PG1
V1
SLEEP
LDO
FB1
ON1
FROM CPU
SYS_EN
PV2
ON2
RUN
SLEEP
ON
SLP
TO V1
STEP-DOWN
PWM
REG2
LX2
L2
6.8μH
BKBT
Li+
BACKUP
BATTERY
V7, VCC_BATT
(ALWAYS ON)
C25
1μF
REG1 OK
PG2
V7
C24
1μF
V2
RSO
TO CPU
nRESET
SLEEP
LDO
V7
RESET
2.3V
FB2
PV3
65ms
RESET INPUT
TO BATT
C13
4.7μF
STEP-DOWN
PWM
REG3
PWM
MR
PWM3
R18
1MΩ
TO BATT
C14
4.7μF
LX3
L3
10μH
PG3
TO V1
ADJ
ON
FB3
POK
TO CPU
nVCC-FAULT
ON3
IN45
V1–V6
POWEROK
TO V2
V4
RAMP
BYP
C18
1500pF
100kΩ
LDO
REG
4
C23
1μF
C20
0.01μF
LDO
REG
5
C26
330pF
V5
CC1
CC2
CC3
R22
240kΩ
C27
270pF
IN6
C22
1μF
I 2C
SERIAL
C28
330pF
GND
SRAD SCL SDA
C21
1μF
LDO
REG
6
ON6
V5
VCC_SRAM
1.1V, 35mA
TO V2
V6
R23
240kΩ
V4, VCC_PLL
1.3V, 35mA
ON4
ON5
V3
DAC
R21
240kΩ
FROM CPU
PWR_EN
V6
VCC_USIM
0V, 1.8V, 3.0V (DEF = 0V)
35mA
FROM CPU
SYS_EN
Figure 6. MAX1586 Typical Applications Circuit (The MAX1587 omits some features. See the Pin Description section.)
26
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
If the output filter capacitor has significant ESR, a zero
occurs at:
ZESR = 1/(2π x COUT x RESR)
If ZESR > fC, it can be ignored, as is typically the case
with ceramic or polymer output capacitors. If ZESR is
less than fC, it should be cancelled with a pole set by
capacitor CP connected from CC_ to GND:
CP = COUT RESR/RC
If CP is calculated to be < 10pF, it can be omitted.
Optimizing Transient Response
In applications that require load-transient response to
be optimized in favor of minimum component values,
increase the output filter capacitor to increase the R in
the compensation RC. From the equations in the previous section, doubling the output cap allows a doubling
of the compensation R, which then doubles the transient gain.
MAX1586
MAX1587
PV3
TO BATT
V3
VCC_CORE
1.55V MAX
LX3
STEP-DOWN
PWM
REG3
R24**
3.3Ω
PG3
FB3
185.5kΩ
R25
100kΩ
**OTHER R24 VALUES:
R24 = 5.5k, V3: 0.759V TO 1.60V
R24 = 7.7k, V3: 0.783V TO 1.65V
Figure 7. Addition of R24 and R25 increases maximum core
voltage. The values shown raise the maximum core from
1.475V to 1.55V.
column in Table 2, and 185,500 is the internal resistance of the FB3 pin.
Applications Information
Backup-Battery and V7 Configurations
Extending the Maximum Core
Voltage Range
The MAX1586/MAX1587 include a backup-battery connection, BKBT, and an output, V7. These can be utilized
in different ways for various system configurations.
The V3 output can be serially programmed to supply
from 0.7V to 1.475V in 25mV steps. In some cases, a
higher CPU core voltage may be desired. The V3 voltage range can be increased by adding two resistors as
shown in Figure 7.
R24 and R25 add a small amount of gain. They are set
so that an internally programmed value of 1.475V
results in a higher actual output at V3. The resistors
shown in Figure 1 set a maximum output of 1.55V, 1.6V,
or 1.65V. All output steps are shifted and the step size
is also slightly increased.
The output voltage for each programmed step of V3 in
Figure 7 is:
V3 = V3PROG + (R24[(V3PROG/R25) +
(V3PROG/185,500)])
where V3 is the actual output voltage, V3PROG is the
original programmed voltage from the "OUTPUT (V)"
Primary Backup Battery
A connection with a primary (nonrechargeable) lithium
coin cell is shown in Figure 6. The lithium cell connects to
BKBT directly. V7 powers the CPU VCC_BATT from either
V1 (if enabled) or the backup battery. It is assumed
whenever the main battery is good, V1 is on (either with
its DC-DC converter or sleep LDO) to supply V7.
No Backup Battery (or Alternate Backup)
If no backup battery is used, or if an alternate backup
and VCC_BATT scheme is used that does not use the
MAX1586/MAX1587, then BKBT should be biased from
IN with a small silicon diode (1N4148 or similar, as in
Figure 8). BKBT must still be powered when no backup
battery is used because DBO, RSO, and POK require
this supply to function. If BKBT is not powered, these
outputs do not function and are high impedance.
______________________________________________________________________________________
27
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
We choose 22µF.
Recalculate RC using the selected COUT.
RC = COUT x RLOAD/CC = 208kΩ
Note that the pole cancellation does not have to be
exact. RC x CC need only be within 0.75 to 1.25 times
RLOAD x COUT. This provides flexibility in component
selection.
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
MAIN
POWER
Rechargeable Li+ Backup Battery
If more backup power is needed and a primary cell has
inadequate capacity, a rechargeable lithium cell can be
accommodated as shown in Figure 9. A series resistor
and diode charge the cell when the 3.3V V1 supply is
active. In addition to biasing V7, the rechargeable battery may be required to also power other supplies.
IN
4.7μF
MAX1586
MAX1587
BKBT
D1
1N4148
V7
1μF
Figure 8. BKBT connection when no backup battery is used, or
if an alternate backup scheme, not involving the
MAX1586/MAX1587, is used.
MAIN
POWER
PCB Layout and Routing
IN
Good PCB layout is important to achieve optimal performance. Conductors carrying discontinuous currents and
any high-current path should be made as short and wide
as possible. A separate low-noise ground plane containing the reference and signal grounds should connect to
the power-ground plane at only one point to minimize the
effects of power-ground currents. Typically, the ground
planes are best joined right at the IC.
4.7μF
MAX1586
MAX1587
1kΩ
V1
BKBT
1-CELL
Li+ RECHARGEABLE
BACKUP BATTERY
4.7μF
V7
1μF
Figure 9. A 1-cell rechargeable Li+ battery provides more backup power when a primary cell is insufficient. The cell is charged
to 3.3V when V1 is active. Alternately, the battery can be
charged from IN if the voltages are appropriate for the cell type.
1N4148
10kΩ
4.7μF
BATT
IN
4.7μF
MAX1586
MAX1587
LX
MAX1724
EZK30
SHDN
GND
Keep the voltage feedback network very close to the
IC, preferably within 0.2in (5mm) of the FB_ pin. Nodes
with high dV/dt (switching nodes) should be kept as
small as possible and should be routed away from
high-impedance nodes such as FB_. Refer to the
MAX1586 or MAX1587 evaluation kit data sheets for a
full PCB example.
MAIN
POWER
MURATA
LQH32C 10μH
1-CELL
NiMH
RECHARGEABLE
BACKUP BATTERY
Rechargeable NiMH Backup Battery
In some systems, a NiMH battery may be desired for
backup. Usually this requires multiple cells because
the typical NiMH cell voltage is only 1.2V. By adding a
small DC-DC converter (MAX1724), the low-battery
voltage is boosted to 3V to bias BKBT (Figure 10). The
DC-DC converter’s low operating current (1.5µA typ)
allows it to remain on constantly so the 3V BKBT bias is
always present. A resistor and diode trickle charge the
NiMH cell when the main power is present.
OUT
10μF
3.0V
BKBT
V7
1μF
Figure 10. A 1-cell NiMH battery can provide backup by boosting with a low-power DC-DC converter. A series resistor-diode
trickle charges the battery when the main power is on.
28
______________________________________________________________________________________
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
REG2 PRESET VOLTAGE
(ALSO ADJUSTABLE)
REG3 (VCC_CORE)
OUTPUT CURRENT
MAX1586A
1.8V, 2.5V
0.5A
MAX1586B
3.3V, 2.5V
0.5A
MAX1586C
1.8V, 2.5V
0.9A
MAX1587A
1.8V, 2.5V
0.5A
MAX1587C
1.8V, 2.5V
0.9A
PART
OTHER FUNCTIONS
VCC_USIM (V6) linear regulator,
LBO and DBO battery monitors
—
4
27 LX3
5
26 PG3
FB2
CC2
POK
7
25 V5
24 IN45
8
23 V4
9
22 ON45
21 ON2
SCL 10
REF
BYP
GND
PV2
LX2
PG2
IN
RAMP
SDA
PWM3
11 12 13 14 15 16 17 18 19 20
MR
32 LX3
31 PG3
V7 5
V1 6
SLPIN 7
V2 8
FB2 9
CC2 10
MAX1586AETM
MAX1586BETM
MAX1586CETM
30 ON5
29 V5
28 IN45
27 V4
26 ON4
POK 11
SCL 12
25 ON2
13 14 15 16 17 18 19 20 21 22 23 24
THIN QFN
6mm × 6mm
THIN QFN
7mm × 7mm
Chip Information
PROCESS: BiCMOS
ON6
FB3
CC3
34 ON3
33 PV3
4
DBO
28 PV3
REF
BYP
3
35 SRAD
3
RAMP
GND
29 SRAD
LX2
2
36 RSO
2
PG2
IN
30 RSO
1
LBO
PV2
1
LB1
CC1
FB1
BKBT
SDA
PWM3
FB1
BKBT
V7
V1
SLPIN
V2
MAX1587AETL
MAX1587CETL
LX1
PG1
IN6
V6
48 47 46 45 44 43 42 41 40 39 38 37
40 39 38 37 36 35 34 33 32 31
6
SLP
ON1
PV1
DBI
MR
FB3
CC3
LX1
PG1
ON1
ON3
CC1
TOP VIEW
SLP
PV1
Pin Configurations
Package Information
(For the latest package outline information and land patterns,
go to www.maxim-ic.com/packages.)
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
40 Thin QFN
T4066-5
21-0141
48 Thin QFN
T4877-6
21-0144
______________________________________________________________________________________
29
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
Selector Guide
MAX1586A/MAX1586B/MAX1586C/MAX1587A/MAX1587C
High-Efficiency, Low-IQ PMICs with
Dynamic Core for PDAs and Smart Phones
Revision History
REVISION
NUMBER
REVISION
DATE
3
12/08
DESCRIPTION
Corrected equations to calculate resistors in the Dead-Battery and Low-Battery
Comparators—DBI, LBI (MAX1586 only) section.
PAGES
CHANGED
20, 21
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.
30 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2008 Maxim Integrated Products
is a registered trademark of Maxim Integrated Products, Inc.