INTERSIL ZL2005ALNFT1

ZL2005
Data Sheet
February 18, 2009
FN6848.0
Digital-DC™ Integrated Power Management and Conversion IC
Description
Features
The ZL2005 is an innovative mixed-signal power
management and conversion IC that combines a compact, efficient, synchronous DC/DC buck controller,
adaptive drivers and key power and thermal management functions in one IC, providing flexibility and
scalability while decreasing board space requirements
and design complexity. Zilker Labs’ Digital-DC technology enables a unique blend of performance and
features not available in either traditional analog or
newer digital approaches, resolving the issues associated with providing multiple, low-voltage power
domains on a single PCB.
Power Management
• Digital soft start/stop
• Precision delay and ramp-up
• Power good/enable
• Voltage tracking, sequencing and margining
• Voltage/current/temperature monitoring
• I2C/SMBus communication
• Output overvoltage and overcurrent protection
• PMBus compliant
Power Conversion
• Efficient synchronous buck controller
• 3 V to 14 V input range
• 0.6 V to 5.5 V output range
• ± 1% output accuracy
• Internal 3 A drivers support >30 A power stage
• Fast load transient response
• Phase interleaving
• RoHS compliant (6 x 6 mm) QFN package
The ZL2005 is designed to be a flexible building block
for DC power and can be easily adapted to designs
ranging from a single-phase power supply operating
from a 3.3 V input to a multi-phase supply operating
from a 12 V input. The ZL2005 eliminates the need
for complicated power supply managers as well as
numerous external discrete components.
All operating features can be configured by simple
pin-strap selection, resistor selection or through the
on-board serial port. The PMBus™-compliant
ZL2005 uses the SMBus™ serial interface for communication with other Digital-DC products or a host
controller.
Applications
•
•
•
•
Servers/storage equipment
Telecom/datacom equipment
Power supplies (memory, DSP, ASIC, FPGA)
Point of load converters
DLY FC ILIM
EN PG (0,1) (0,1) (0,1) CFG UVLO V25 VR VDD
V (0,1)
SS (0,1)
VTRK
MGN
SYNC
LDO
POWER
MANAGEMENT
DRIVER
SCL
SDA
SALRT
NONVOLATILE
MEMORY
PWM
CONTROLLER
I2 C
MONITOR
ADC
SA (0,1)
CURRENT
SENSE
BST
GH
SW
GL
ISENA
ISENB
TEMP
SENSOR
VTRK
VSEN
TACH XTEMP
PGND SGND DGND
Figure 1. Block Diagram
1
Figure 2. Efficiency vs. Load Current
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 1-888-468-3774 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright Intersil Americas Inc. 2009. All Rights Reserved
All other trademarks mentioned are the property of their respective owners.
ZL2005
Table of Contents
1
2
3
4
5
6
7
8
Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pin Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Typical Application Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
ZL2005 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.1
Digital-DC Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.2
Power Conversion Overview. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.3
Power Management Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.4
Multi-mode Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power Conversion Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.1
Internal Bias Regulators and Input Supply Connections. . . . . . . . . . . . . . . . . . . . . .
5.2
High-side Driver Boost Circuit. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.3
Output Voltage Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.4
Start-up Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.5
Soft Start Delay and Ramp Times . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.6
Power Good . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.7
Switching Frequency and PLL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.8
Selecting Power Train Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.9
Current Limit Threshold Selection. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.10 Loop Compensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.11 Non-Linear Response Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.12 Efficiency Optimized Driver Dead-time Control. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power Management Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.1
Input Undervoltage Lockout (UVLO). . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.2
Output Overvoltage Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.3
Output Pre-Bias Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.4
Output Overcurrent Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.5
Thermal Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.6
Voltage Tracking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.7
Voltage Margining . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.8
I2C/SMBus Communications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.9
I2C/SMBus Device Address Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.10 Phase Spreading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.11 Output Sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.12 Monitoring via I2C/SMBus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.13 Temperature Monitoring Using the XTEMP Pin . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.14 Fan Monitoring using the TACH Pin . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.15 Device Security Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Package Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Ordering Information. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2
3
8
10
11
11
12
13
13
15
15
15
15
16
17
18
18
20
23
26
27
28
29
29
29
30
30
31
31
33
33
33
34
34
35
35
36
36
37
38
FN6848.0
February 18, 2009
ZL2005
1
Electrical Characteristics
Table 1. Absolute Maximum Ratings
Operating beyond these limits may cause permanent damage to the device. Functional operation beyond the recommended
operating conditions is not implied. Unless otherwise specified, all voltages are measured with respect to SGND.
Parameter
Pin(s)
Value
Unit
DC supply voltage
VDD
DLY(0,1), EN, ILIM(0,1),
MGN, PG, SA(0,1), SALRT,
SCL, SDA, SS(0,1), SYNC,
TACH, UVLO, V(0,1)
ISENB, VSEN, VTRK,
XTEMP,
ISENA
Logic I/O voltage
Analog input voltages
-0.3 to 17
V
-0.3 to 6.5
V
-0.3 to 6.5
V
V
V
mA
V
mA
V
V
V
MOSFET drive reference
VR
Logic reference
V25
High-side supply voltage
High-side drive voltage
Low-side drive voltage
Boost to switch differential voltage
(VBST - VSW)
Switch node continuous
Switch node transient
(<100 ns)
Ground voltage differential
(VDGND-VSGND), (VPGND-VSGND)
Junction temperature
Storage temperature range
Lead temperature
(soldering, 10 s)
ESD HBM tolerance
(100 pF, 1.5 kΩ)
BST
GH
GL
-1.5 to +30
-0.3 to 6.5
120
-0.3 to 3
120
-0.3 to +30
(VSW - 0.3) to (VBST+0.3)
(PGND-0.3) to (VR+0.3+PGND)
BST, SW
-0.3 to 8
V
SW
(PGND-0.3) to 30
V
SW
(PGND-5) to 30
V
DGND, SGND, PGND
-0.3 to +0.3
V
–
–
-55 to 150
-55 to 150
oC
–
300
All
2
3
o
C
o
C
kV
FN6848.0
February 18, 2009
ZL2005
Table 2. Recommended Operating Conditions and Thermal Information
Parameter
Input Supply Voltage Range, VDD
Output Voltage Range
Operating Junction Temperature Range
Junction to Ambient Thermal
Impedance1
Junction to Case Thermal Impedance2
Symbol
Min
Typ
Max
Unit
VR tied to VDD (Figure 9)
VR floating (Figure 9)
VOUT
TJ
3.0
4.5
0.6
-40
–
–
–
5.5
14
5.5
125
V
V
V
°C
ΘJA
–
35
–
°C/W
ΘJC
–
5
–
°C/W
NOTES:
1. ΘJA is measured in free air with the device mounted on a multi-layer FR4 test board and the exposed metal pad soldered to a low impedance ground plane
using multiple vias.
2. For ΘJC, the “case” temperature is measured at the center of the exposed metal pad
Table 3. Electrical Specifications
Unless otherwise specified VDD = 12 V, TA = -40oC to +85oC. Typical values are at TA = 25oC.
Parameter
Condition
Min
Input and Supply Characteristics
Supply current (IDD)
(No load on GH and GL)
Standby supply current (IDD)
VR reference voltage (VR)
V25 reference voltage (V25)
Typ
Max
Unit
–
–
16
25
30
50
mA
mA
–
2
5
mA
4.5
5.2
5.5
V
2.25
2.5
2.75
V
0.6
–
–
–
10
±0.025
5.5
–
–
Over line, load and temperature
VSEN = 5.5 V
-1
–
–
110
1
200
V
mV
% of
F.S.1
%
µA
VISENA - VISENB
-100
–
100
mV
VISENA - VISENB
-100
–
100
mV
Ground referenced
-100
–
100
µA
ISENA
-1
–
1
µA
ISENB
-100
–
100
µA
Set using DLY pin or resistor
Configurable via I2C/SMBus
7
0.007
–
–
–
6
200
500
–
ms
s
ms
fSW = 200 kHz
fSW = 2,000 kHz
EN = Low
2
no I C/SMBus activity
VDD ≥ 6 V
IVR < 50 mA
VR ≥ 3 V
IV25 < 50 mA
Output Characteristics
Output voltage adjustment range
Set using resistors
Output voltage setpoint resolution
Output voltage accuracy
VSEN input bias current
Current sense differential input
voltage (ground referenced)
Current sense differential input
voltage ( VOUT referenced)
Current sense input bias current
Set using I2C/SMBus
NOTE:
1. Percentage of Full Scale (F.S.) with temperature compensation applied
Current sense input bias current
(VOUT referenced,
VOUT <= 3.6V)
Soft start delay duration range
Soft start delay duration accuracy
4
FN6848.0
February 18, 2009
ZL2005
Table 3. Electrical Specifications
Unless otherwise specified VDD = 12 V, TA = -40oC to +85oC. Typical values are at TA = 25oC. (Continued)
Parameter
Condition
Min
Typ
Max
Soft start ramp duration range
Set using SS pin or resistor
Configurable via I2C/SMBus
Soft start ramp duration accuracy
Unit
0
0
–
–
–
100
200
200
–
ms
ms
µs
-10
–
10
μA
-1
-1
–
–
2
–
–
–
1.4
–
1
1
0.8
–
–
mA
mA
V
V
V
Logic Input/Output Characteristics
EN, PG, SCL, SDA, SALRT,
TACH
During configuration restore
Logic input bias current
MGN input bias current
Logic input low threshold (VIL)
Logic input OPEN (N/C)
Logic input high threshold (VIH)
Multi-mode logic pins
Logic output low (VOL)
IOL <= 4 mA
–
–
0.4
V
Logic output high (VOH)
IOH >= - 2 mA
2.25
–
–
V
200
–
2000
kHz
-5
–
5
%
95
150
-13
–
–
–
–
–
13
%
ns
%
150
1
-10
–
–
–
–
500
10
ns
Hz
%
Oscillator and Switching Characteristics
Switching frequency range
Switching frequency setpoint
accuracy
Maximum PWM duty cycle
Minimum SYNC pulse width
Input clock frequency drift tolerance
Predefined settings
(See table 14)
Factory default
External clock signal
Tachometer Characteristics
TACH pulse width
TACH frequency range
TACH accuracy
5
FN6848.0
February 18, 2009
ZL2005
Table 3. Electrical Specifications
Unless otherwise specified VDD = 12 V, TA = -40oC to +85oC. Typical values are at TA = 25oC. (Continued)
Parameter
Condition
Min
Typ
Max
Gate Drivers
High-side driver voltage
(VBST - VSW)
High-side driver peak gate drive
current (pull down)
High-side driver pull-up resistance
High-side driver pull-down
resistance
Low-side driver peak gate drive
current (pull-up)
Low-side driver peak gate drive
current (pull-down)
Low-side driver pull-up resistance
Low-side driver pull-down
resistance
Unit
–
4.5
–
V
2
3
–
A
–
0.8
2
Ω
–
0.5
2
Ω
VR = 5 V
–
2.5
–
A
VR = 5 V
–
1.8
–
A
–
1.2
2
Ω
–
0.5
2
Ω
–
5
20
ns
–
5
20
ns
–
– 100
110
200
+ 100
µA
mV
(VBST - VSW) = 4.5 V
(VBST - VSW) = 4.5 V,
(VBST - VGH) = 50 mV
(VBST - VSW) = 4.5 V,
(VGH - VSW) = 50 mV
VR = 5 V,
(VR - VGL) = 50 mV
VR = 5 V,
(VGL - PGND) = 50 mV
Switching timing
GH rise and fall time
GL rise and fall time
(VBST - VSW) = 4.5 V,
CLOAD = 2.2 nF
VR = 5 V,
CLOAD = 2.2 nF
Tracking
VTRK input bias current
VTRK tracking threshold
VTRK = 5.5 V
VTRK >= 0.3 V
6
FN6848.0
February 18, 2009
ZL2005
Table 3. Electrical Specifications
Unless otherwise specified VDD = 12 V, TA = -40oC to +85oC. Typical values are at TA = 25oC. (Continued)
Parameter
Condition
Min
Typ
Max
Fault Protection Characteristics
UVLO threshold range
UVLO setpoint accuracy
UVLO hysteresis
Factory default
Configurable via I2C/SMBus
UVLO delay
2.85
-100
–
0
–
–
–
3
–
–
16
100
–
100
2.5
Power good VOUT low threshold
Factory default
–
90
–
Power good VOUT high threshold
Factory default
–
115
–
Factory default
Set using pin-strap or resistor4
Configurable via I2C/SMBus
–
0
0
5
–
–
–
200
500
85
–
–
110
115
–
Power good VOUT hysteresis
Power good delay
Factory default
V
mV
%
%
µs
%
VOUT
%
VOUT
%
ms
s
%
VOUT
%
VOUT
%
VOUT
%
VOUT
µs
µs
VSEN undervoltage threshold
Configurable via I2C/SMBus
0
Factory default
VSEN overvoltage threshold
VSEN undervoltage/overvoltage
fault response time
Current limit setpoint accuracy
(VOUT referenced)
Current limit setpoint accuracy2
(Ground referenced)
Current limit protection delay
Temperature compensation of
current limit protection threshold
Thermal protection threshold
Unit
Configurable via I2C/SMBus
0
–
115
Factory default
Configurable via I2C/SMBus
–
5
16
–
–
60
–
±10
–
%
F.S.1
|VISENA - VISENB|> 12 mV
–
±10
–
% F.S.
Factory default
Configurable via I2C/SMBus
Factory default
Configurable via I2C/SMBus
Factory default
Configurable via I2C/SMBus
–
1
–
100
–
- 40
–
5
–
4400
–
125
–
15
–
32
–
12700
–
125
–
τSW3
Thermal protection hysteresis
ppm/
°C
°C
°C
°C
NOTES:
1. Percentage of Full Scale (F.S.) with temperature compensation applied
2. TA = 0oC to +85oC
3. τSW = 1/fSW, fSW switching frequency
4. Automatically set to same value as soft start ramp time
7
FN6848.0
February 18, 2009
ZL2005
Pin Descriptions
28
29
31
30
32
33
34
1
27
2
26
36-Pin MLF
6 x 6 mm
3
4
25
24
5
23
6
Exposed Paddle
22
7
Connect to SGND
21
18
17
16
15
14
VDD
BST
GH
SW
PGND
GL
VR
ISENA
ISENB
FC0
FC1
V0
V1
UVLO
SS0
SS1
VTRK
VSEN
13
19
12
20
9
11
8
10
DGND
SYNC
SA0
SA1
ILIM0
ILIM1
SCL
SDA
SALRT
35
36
PG
DLY1
DLY0
EN
CFG
MGN
TACH
XTEMP
V25
2
Figure 3. Pin Assignments (top view)
Table 4. Pin Descriptions
Pin
Label
Type1
1
DGND
PWR
2
SYNC
I/O, M2
3
4
5
6
7
8
9
10
11
12
13
SA0
SA1
ILIM0
ILIM1
SCL
SDA
SALRT
FC0
FC1
V0
V1
14
UVLO
Description
Digital ground. Connect to low impedance ground plane.
Clock synchronization input. Used to set the frequency of the internal switch
clock, to sync to an external clock or to output internal clock.
I, M
Serial address select pins. Used to assign unique address for each individual
device or to enable certain management features.
I, M
Current limit select. Sets the overcurrent threshold voltage for ISENA, ISENB.
I/O
I/O
O
I
I
Serial clock. Connect to external host and/or to other ZL2005s.
Serial data. Connect to external host and/or to other ZL2005s.
Serial alert. Connect to external host if desired.
I, M
Output voltage selection pins. Used to set VOUT setpoint and VOUT max.
I, M
Undervoltage lockout selection. Sets the minimum value for VDD voltage to
enable VOUT.
Loop compensation selection pins.
NOTES:
1. I = Input, O = Output, PWR = Power or Ground, M = Multi-mode pin (refer to Section 4.4, “Multi-mode Pins,” )
2. The SYNC pin can be used as a logic pin, a clock input or a clock output.
3. VDD is measured internally and the value is used to modify the PWM loop gain.
8
FN6848.0
February 18, 2009
ZL2005
Table 4. Pin Descriptions (Continued)
Type1
Pin
Label
15
16
17
18
19
20
21
22
23
24
25
26
27
28
SS0
SS1
VTRK
VSEN
ISENB
ISENA
VR
GL
PGND
SW
GH
BST
VDD3
V25
I, M
Soft start pins. Set the output voltage ramp time during turn-on and turn-off.
I
I
I
I
PWR
O
PWR
PWR
O
PWR
PWR
PWR
29
XTEMP
I
30
TACH
I
31
MGN
I
32
CFG
I
33
34
35
36
EN
DLY0
DLY1
PG
I
Tracking sense input. Used to track an external voltage source.
Output voltage feedback. Connect to output regulation point.
Differential voltage input for current limit.
Differential voltage input for current limit. High voltage tolerant.
Internal 5V reference used to power internal drivers.
Low side FET gate drive.
Power ground. Connect to low impedance ground plane.
Drive train switch node.
High-side FET gate drive.
High-side drive boost voltage.
Supply voltage.
Internal 2.5 V reference used to power internal circuitry.
External temperature sensor input. Connect to external 2N3904 diode connected
transistor.
Tachometer input used to measure fan speed. Connect to TACH output of
external fan.
Digital VOUT margin control
Configuration pin. Used to control the switching phase offset, sequencing and
other management features.
Enable. Active signal enables PWM switching.
I, M
ePad
SGND
PWR
O
Description
Softstart delay select. Sets the delay from when EN is asserted until the output
voltage starts to ramp.
Power good output.
Exposed thermal pad. Connect to low impedance ground plane. Internal
connection to SGND.
NOTES:
1. I = Input, O = Output, PWR = Power or Ground, M = Multi-mode pin (refer to Section 4.4, “Multi-mode Pins,” )
2. The SYNC pin can be used as a logic pin, a clock input or a clock output.
3. VDD is measured internally and the value is used to modify the PWM loop gain.
9
FN6848.0
February 18, 2009
ZL2005
Typical Application Example
VIN 12V
CIN
3 x 10 µF
25 V
VR
POWER GOOD
OUTPUT
1 DGND
VR
DB
BAT54
1 µF
16 V
CB
BST 26
3 SA0
GH 25
4 SA1
SW 24
ZL2005
QH
Si7344
VIN 27
2 SYNC
5 ILIM0
VOUT
LOUT
2.2 µH
PGND 23
6 ILIM1
GL 22
EPAD
SGND
18 VSEN
17 VRTK
16 SS1
ISENB 19
15 SS0
9 SALRT
14 UVLO
ISENA 20
13 V1
VR 21
8 SDA
12 V0
7 SCL
11 FC1
I2C/SMBus™
10 µF
4V
V25 28
XTEMP 29
MGN 31
TACH 30
EN 33
CFG 32
DLY0 34
PG 36
DLY1 35
CV25
10 FC0
3
COUT
47 µF
6.3 V
CVR
4.7 µF
QL
NTMSF4108
6.3 V
470 µF
2.5 V
POS-CAP
2*220 µF
6.3 V
100 m
RTN
Ω
Notes:
1. Conditions: VIN = 12 V, VOUT = 1.8 V, Freq = 400 kHz, IOUT = 20 A
2. The I2C/SMBus requires pullup resistors. Please refer to the I2C/SMBus specifications for more details.
Figure 4. Typical Application Circuit
10
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February 18, 2009
ZL2005
4
ZL2005 Overview
4.1
Digital-DC Architecture
The ZL2005 is an innovative mixed-signal power conversion and power management IC based on Zilker
Labs’ patented Digital-DC technology that provides
an integrated, high performance step-down converter
for a wide variety of power supply applications. Its
unique digital PWM loop utilizes an innovative
mixed-signal topology to enable precise control of the
power conversion process with no software required,
resulting in a very flexible device that is also easy to
use. An extensive set of power management functions
is fully integrated and can be configured using simple
pin connections or via the I2C/SMBus hardware interface using standard PMBus commands. The user configuration can be saved in an on-chip non-volatile
memory (NVM), allowing ultimate flexibility.
Once enabled, the ZL2005 is immediately ready to
regulate power and perform power management tasks
with no programming required. The ZL2005 can be
configured by simply connecting its pins according to
the tables provided in this document. Advanced configuration options and real-time configuration changes
are available via the I2C/SMBus interface if desired,
and continuous monitoring of multiple operating
parameters is possible with minimal interaction from a
host controller. Integrated sub-regulation circuitry
enables single supply operation from any supply
between 3V and 14V with no secondary bias supplies
needed.
Zilker Labs provides a comprehensive set of on-line
tools and application notes to assist with power supply
design and simulation. An evaluation board is also
available to help the user become familiar with the
device. This board can be evaluated as a stand-alone
platform using pin configuration settings. Additionally, a Windows™-based GUI is provided to enable
full configuration and monitoring capability via the
I2C/SMBus interface using an available computer and
the included USB cable.
Please refer to www.zilkerlabs.com for access to the
most up-to-date documentation and the PowerPilotTM
simulation tool, or call your local Zilker Labs’ sales
office to order an evaluation kit.
11
FN6848.0
February 18, 2009
ZL2005
4.2
Power Conversion Overview
INPUT VOLTAGE BUS
PG
EN
MGN ILIM(0,1) SS(0,1) DLY(0,1) V(0,1) FC(0,1)
TACH
VR LDO
POWER MANAGEMENT
VTRK
DIGITAL
COMPENSATOR
SYNC
GEN
VR
BST
MOSFET
DRIVERS
D-PWM
NLR
PLL
SYNC
VDD
ADC
GH
SW
GL
VOUT
- VSEN
Σ
+
REFCN
DAC
ISENB
ISENA
ADC
SMBUS
{
VDD
SALRT
SDA
SCL
SA(0,1)
COMMUNICATION
ADC
MUX
VSEN
XTEMP
TEMP
SENSOR
Figure 5. ZL2005 Detailed Block Diagram
The ZL2005 operates as a voltage-mode, synchronous
buck converter with a selectable, constant frequency
Pulse Width Modulator (PWM) control scheme that
uses external MOSFETs, inductor and capacitors to
perform power conversion.
Figure 6 illustrates the basic synchronous buck converter topology showing the primary power train components. This converter is also called a step-down
converter, as the output voltage must always be lower
than the input voltage.
In its most simple configuration, the ZL2005 requires
two external N-channel power MOSFETs, one for the
top control MOSFET (QH) and one for the bottom
synchronous MOSFET (QL). The amount of time that
QH is on as a fraction of the total switching period is
known as the duty cycle D, which is described by the
following equation:
V OUT
D ≈ ---------------V IN
VIN
DB
VR
QH
GH
ZL2005
CIN
BST
SW
GL
L1
CB
VOUT
QL
COUT
Figure 6. Synchronous Buck Converter
12
FN6848.0
February 18, 2009
ZL2005
During time D, QH is on and VIN – VOUT is applied
across the inductor. The current ramps up as shown in
Figure 7.
ILpk
0
Io
ILv
-VOUT
D
CURRENT (A)
VOLTAGE
(V)
VIN – VOUT
1-D
Time
Figure 7. Inductor Waveform
When QH turns off (time 1-D), the current flowing in
the inductor must continue to flow from the ground up
through QL, during which the current ramps down.
Since the output capacitor COUT exhibits a low impedance at the switching frequency, the AC component of
the inductor current is filtered from the output voltage
so the load sees nearly a DC voltage.
Typically, buck converters specify a maximum duty
cycle that effectively limits the maximum output voltage that can be realized for a given input voltage. This
duty cycle limit ensures that the low-side MOSFET is
allowed to turn on for a minimum amount of time during each switching cycle, which enables the bootstrap
capacitor (CB in Figure 6) to be charged up and provide adequate gate drive voltage for the high-side
MOSFET. See Section 5.2, “High-side Driver Boost
Circuit,” for more details.
In general, the size of components L1 and COUT as
well as the overall efficiency of the circuit are
inversely proportional to the switching frequency, fSW.
Therefore, the highest efficiency circuit may be realized by switching the MOSFETs at the lowest possible
frequency; however, this will result in the largest component size. Conversely, the smallest possible footprint may be realized by switching at the fastest
possible frequency but this gives a somewhat lower
efficiency. Each user should determine the optimal
combination of size and efficiency when determining
the switching frequency for each application.
The block diagram for the ZL2005 is illustrated in
Figure 5. In this circuit, the target output voltage is
regulated by connecting the VSEN pin directly to the
13
output regulation point. The VSEN signal is then compared to a reference voltage that has been set to the
desired output voltage level by the user. The error signal derived from this comparison is converted to a digital value with a low-resolution, analog to digital (A/
D) converter. The digital signal is applied to an adjustable digital compensation filter, and the compensated
signal is used to derive the appropriate PWM duty
cycle for driving the external MOSFETs in a way that
produces the desired output.
The ZL2005 also incorporates a non-linear response
(NLR) loop to reduce the response time and output
deviation in response to a load transient. The ZL2005
has an efficiency optimization circuit that continuously monitors the power converter’s operating conditions and adjusts the turn-on and turn-off timing of the
high-side and low-side MOSFETs to optimize the
overall efficiency of the power supply.
4.3
Power Management Overview
The ZL2005 incorporates a wide range of configurable
power management features that are simple to implement with no external components. Additionally, the
ZL2005 includes circuit protection features that continuously safeguard the load from damage due to
unexpected system faults. The ZL2005 can continuously monitor input voltage, output voltage/current,
internal temperature, and the temperature of an external thermal diode. A Power Good output signal is provided to enable power-on reset functionality for an
external processor.
All power management functions can be configured
using either simple pin configuration techniques (Figure 8) or via the I2C/SMBus interface. Monitoring
parameters can be pre-configured to provide alerts for
specific conditions. See Application Note AN13 for
more details on SMBus monitoring.
4.4
Multi-mode Pins
In order to simplify circuit design, the ZL2005 incorporates patented multi-mode pins that allow the user to
easily configure many aspects of the device without
requiring the user to program the IC. Most power management features can be configured using these pins.
The multi-mode pins can respond to four different
connections as shown in Table 5. Any combination of
connections is allowed among the multi-mode pins.
FN6848.0
February 18, 2009
ZL2005
These pins are sampled when power is applied or by
issuing a PMBus Restore command (See Application
Note AN13).
Table 5. Multi-mode Pin Configuration
Pin Tied To
Value
GND
(Logic low)
OPEN
(N/C)
HIGH
(Logic high)
Resistor to GND
< 0.8 VDC
No connection
> 2.0 VDC
Set by resistor value
Figure 8. Pin-strap and Resistor Setting
Examples
14
Pin-strap Settings: This is the simplest implementation method, as no external components are required.
Using this method, each pin can take on one of three
possible states: GND, OPEN, or HIGH. These pins
can be connected to the VR or V25 pins for logic
HIGH settings, as either pin provides a regulated voltage greater than 2V. Using a single pin, the user can
select one of three settings, and using two pins, the
user can select one of nine settings.
Resistor Settings: This method allows a greater range
of adjustability when connecting a finite valued resistor (in a specified range) between the multi-mode pin
and SGND. Standard 1% resistor values are used, and
only every fourth E96 resistor value is used so that the
device can reliably recognize the value of resistance
connected to the pin while eliminating the errors associated with the resistor accuracy. A total of 25 unique
selections are available using a single resistor.
I2C/SMBus Settings: Almost any ZL2005 function
can be configured via the I2C/SMBus interface using
standard PMBus commands. Additionally, any value
that has been configured using the pin-strap or resistor
setting methods can also be re-configured and/or verified via the I2C/SMBus. See Application Note AN13
for details.
FN6848.0
February 18, 2009
ZL2005
5
Power Conversion Functional Description
5.1
Internal Bias Regulators and Input
Supply Connections
The ZL2005 employs two internal low dropout (LDO)
regulators to supply bias voltages for internal circuitry,
allowing it to operate from a single input supply. The
internal bias regulators are as follows:
VR: The VR LDO provides a regulated 5V bias supply
for the MOSFET driver circuits. It is powered
from the VDD pin and can supply up to 100mA
output current. A 4.7 µF filter capacitor is
required at the VR pin.
V25: The V25 LDO provides a regulated 2.5V bias
supply for the main controller circuitry. It is
powered from an internal 5V node and can supply up to 50 mA output current. A 10 µF filter
capacitor is required at the V25 pin.
Note: The internal bias regulators are designed for
powering internal circuitry only. Do not attach external loads to any of these pins. The multi-mode pins
may be connected to the VR or V25 pins for logic
HIGH settings.
When the input supply (VDD) is higher than 5.5V, the
VR pin should not be connected to any other pin. It
should only have a filter capacitor attached as shown
in Figure 9. Due to the dropout voltage associated with
the VR bias regulator, the VDD pin must be connected
to the VR pin for designs operating from a VDD supply from 3.0V to 5.5V. Figure 9 illustrates the required
connections for both cases. For input supplies between
4.5V and 5.5V, either method can be used.
5.2
High-side Driver Boost Circuit
The gate drive voltage for the upper MOSFET driver
is generated by a floating bootstrap capacitor, CB (see
Figure 4). When the lower MOSFET (QL) is turned
on, the SW node is pulled to ground and the capacitor
is charged from the internal VR bias regulator through
diode DB. When QL turns off and the upper MOSFET
(QH) turns on, the SW node is pulled up to VDD and
the voltage on the BST pin is boosted approximately
5V above VIN to provide the necessary voltage for the
high-side driver. A Schottky diode should be used for
DB to maximize the high-side drive voltage.
5.3
Output Voltage Selection
The output voltage may be set to any voltage between
0.6V and 5.5V provided that the input voltage is
higher than the desired output voltage by an amount
sufficient to prevent the device from exceeding its
maximum duty cycle specification. By connecting the
V0 and V1 pins to logic high, logic low, or leaving
them floating, VOUT can be set to any of nine standard
voltages as shown in Table 6.
Table 6. Pin-strap Output Voltage Settings
V1
LOW
OPEN
HIGH
LOW
0.6V
1.2V
2.5V
V0
OPEN
0.8V
1.5V
3.3V
HIGH
1.0V
1.8V
5.0V
If an output voltage other than those in Table 6 is
desired, the resistor setting method can be used. Using
this method, resistors R0 and R1 are selected to produce a specific voltage between 0.6V and 5.5V in 10
mV steps. Resistor R1 provides a coarse setting and
R0 a fine adjustment, thus eliminating the additional
errors associated with using two 1% resistors in a standard analog implementation (this typically adds 1.4%
error using two 1% resistors).
Figure 9. Input Supply Connections
15
FN6848.0
February 18, 2009
ZL2005
To set VOUT using resistors, follow the steps below to
calculate an index value and then use Table 7 to select
the resistor that corresponds to the calculated index
value as follows:
9,1
*+
1. Calculate Index1:
Index1 = 4 x VOUT
=/
6:
9287
9
*/
9
2. Round the result down to the nearest whole number.
3. Select the value for R1 from Table 7 using the
Index1 rounded value from step 2.
4. Calculate Index0 using equation
Index0 = 100 x VOUT - 25 x Index1...
5. Select the value for R0 from Table 7 using Index0
from step 4.
Table 7. Resistors for Setting Output Voltage
Index
R0 or R1
Index
R0 or R1
0
1
2
3
4
5
6
7
8
9
10
11
12
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
28.7 kΩ
31.6 kΩ
13
14
15
16
17
18
19
20
21
22
23
24
34.8 kΩ
38.3 kΩ
42.2 kΩ
46.4 kΩ
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
75 kΩ
82.5 kΩ
90.9 kΩ
100 kΩ
Example:
For VOUT = 1.33V:
Index1 = 4 x 1.33V = 5.32 (5);
From Table 7, using Index = 5
R1 = 16.2 kΩ
Index0 = (100 x 1.33V) - (25 x 5) = 8;
From Table 7; R0 = 21.5 kΩ
16
9
5
5
Nȍ
Nȍ
Figure 10. Output Voltage Resistor Setting
Example
The output voltage may also be set to any value
between 0.6V and 5.5V using the I2C/SMBus interface. See Application Note AN13 for details.
5.4
Start-up Procedure
The ZL2005 follows a specific internal start-up procedure after power is applied to the VDD pin. Table 8
describes the start-up sequence.
If the device is to be synchronized to an external clock
source, the clock must be stable prior to asserting the
EN pin. The device requires approximately 10-20 ms
to check for specific values stored in its internal memory. If the user has stored values in memory, those values will be loaded. The device will then check the
status of all multi-mode pins and load the values associated with the pin settings.
Once this process is completed, the device is ready to
accept commands via the I2C/SMBus interface and the
device is ready to be enabled. Once enabled, the
device requires approximately 6 ms before its output
voltage may be allowed to start its ramp-up process. If
a soft start delay period less than 6 ms has been configured (using the DLY (0,1) pins), the device will
default to a 6 ms delay period. If a delay period of 6
ms or higher is configured, the device will wait for the
configured delay period before starting to ramp its output.
After the delay period has expired, the output will
begin to ramp towards its target voltage according to
the pre-configured soft-start ramp time (using the SS
(0,1) pins).
FN6848.0
February 18, 2009
ZL2005
Table 8. ZL2005 Start-up Sequence
Step #
1
2
3
4
5
5.5
Step Name
Description
Time Duration
Power Applied Input voltage is applied to the ZL2005’s VDD pin
Internal
Memory Check
Multi-mode
Pin Check
Device Ready
Pre-ramp
Delay
Depends on input supply
ramp time
The device will check for values stored in its internal memory. Approx 10-20 ms (device
This step is also performed after a Restore command.
will ignore an enable signal
or PMBus traffic during
The device loads values configured by multi-mode pins.
this period)
The device is ready to accept an enable signal.
—
The device requires approximately 6 ms following an enable
signal and prior to ramping its output. Additional pre-ramp
Approx. 6 ms
delay may be configured using the Delay pins.
Soft Start Delay and Ramp Times
In some system applications, it may be necessary to set
a delay from when an enable signal is received until
the output voltage starts to ramp to its nominal value.
In addition, the designer may wish to precisely set the
time required for VOUT to ramp to its nominal value
after the delay period has expired. The ZL2005 gives
the system designer several options for precisely and
independently controlling both the delay and ramp
time periods for VOUT. These features may be used as
part of an overall in-rush current management strategy
or to precisely control how fast a load IC is turned on.
The soft start delay period begins when the Enable pin
is asserted and ends when the delay time expires. The
soft-start delay period is set using the DLY (0,1) pins.
The soft start ramp enables a controlled ramp to the
nominal VOUT value that begins once the delay period
has timed out. The ramp-up is guaranteed monotonic
and its slope may be precisely set by setting the softstart ramp time using the SS (0,1) pins.
The soft start delay and ramp times can be set to standard values according to Table 9 and Table 10 respectively.
Table 9. Soft Start Delay Settings
LOW
DLY1
1
LOW
0 ms
OPEN
5 ms1
50 ms
HIGH
DLY0
OPEN
HIGH
Reserved
10 ms
20 ms
100 ms
200 ms
NOTE:
1. When the device is set to 0 ms or 5 ms delay, it will begin its ramp up
after the internal circuitry has initialized (approx. 6 ms).
Table 10. Soft Start Ramp Settings
LOW
LOW
SS1
OPEN
HIGH
1
0 ms
5 ms
50 ms
SS0
OPEN
1 ms
HIGH
2 ms
10 ms
100 ms
20 ms
200 ms
NOTE:
1. When the soft start ramp is set to zero, the device will ramp up as
quickly as the internal circuitry and output load capacitance will allow.
If the desired soft start delay and ramp times are not
one of the values listed in Table 8 and Table 9, the
times can be set to a custom value by connecting a
resistor from the DLY0 or SS0 pin to SGND using the
appropriate resistor value from Table 11. The value of
this resistor is measured upon start-up or Restore and
will not change if this resistor is varied after power has
been applied to the ZL2005. See Figure 11 for typical
connections using resistors.
Note: Do not connect a resistor to the DLY1 or SS1
pin. These pins are not utilized for setting soft-start
delay and ramp times. Connecting an external resistor
to these pins may cause conflicts with other device settings.
17
FN6848.0
February 18, 2009
ZL2005
5.6
The ZL2005 provides a Power Good (PG) signal that
indicates the output voltage is within a specified tolerance of its target level and no fault condition exists. By
default, the PG pin will assert if the output is within 10%/+15% of the target voltage These limits may be
changed via the I2C/SMBus interface. See Application
Note AN13 for details.
DLY0
DLY1
Power Good
RDLY
N/C
RSS
SS1
SS0
ZL2005
N/C
Figure 11. DLY and SS Pin Resistor
Connections
Table 11. DLY and SS Resistor Values
DLY or
SS
RDLY or
RSS
DLY or
SS
RDLY or
RSS
0 ms
10 ms
20 ms
30 ms
40 ms
50 ms
60 ms
70 ms
80 ms
90 ms
100 ms
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
110 ms
120 ms
130 ms
140 ms
150 ms
160 ms
170 ms
180 ms
190 ms
200 ms
28.7 kΩ
31.6 kΩ
34.8 kΩ
38.3 kΩ
42.2 kΩ
46.4 kΩ
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
The soft start delay and ramp period can be set to custom values via the I2C/SMBus interface. When the
soft start delay is set to 0 ms, the device will begin its
ramp up after the internal circuitry has initialized
(approx. 6ms).
A PG delay period is defined as the time from when all
conditions within the ZL2005 for asserting PG are met
to when the PG pin is actually asserted. This feature is
commonly used instead of using an external reset controller to control external digital logic. By default, the
ZL2005 PG delay is set equal to the soft-start ramp
time setting. Therefore, if the soft-start ramp time is
set to 10 ms, the PG delay will be set to 10 ms. The PG
delay may be set independently of the soft-start ramp
using the I2C/SMBus as described in Application Note
AN13.
5.7
Switching Frequency and PLL
The ZL2005 incorporates an internal phase locked
loop (PLL) to clock the internal circuitry. The PLL can
be driven by an internal oscillator or driven from an
external clock source connected to the SYNC pin.
When using the internal oscillator, the SYNC pin can
be configured as a clock output for use by other
devices. The SYNC pin is a unique pin that can perform multiple functions depending on how it is configured. The CFG pin is used to select the operating mode
of the SYNC pin as shown in Table 12. Figure 12
illustrates the typical connections for each mode.
Table 12. SYNC Pin Function Selection
CFG Pin
LOW
OPEN
HIGH
18
SYNC Pin Function
SYNC is configured as an input
Auto Detect mode
SYNC is configured as an output
fSW = 400 kHz (default)
FN6848.0
February 18, 2009
ZL2005
SYNC
200 kHz – 2 MHz
200 kHz – 2 MHz
ZL2005
ZL2005
A) SYNC = output
ZL2005
Open
OR
Logic
low
SYNC
N/C
ZL2005
SYNC
OR
RSYNC
CFG
N/C
Logic
high
CFG
200 kHz – 2 MHz
B) SYNC = input
CFG
N/C
SYNC
CFG
SYNC
CFG
Logic
high
ZL2005
C) SYNC = Auto Detect
Figure 12. SYNC Pin Configurations
Configuration A: SYNC OUTPUT
Configuration C: SYNC AUTO DETECT
When the SYNC pin is configured as an output (CFG
pin is tied HIGH), the device will operate from its
internal oscillator and will drive the resulting internal
oscillator signal (preset to 400 kHz) onto the SYNC
pin so other devices can be synchronized to it. The
SYNC pin will not be checked for an incoming clock
signal while in this configuration.
When the SYNC pin is configured in auto detect mode
(CFG pin is left OPEN), the device will automatically
check for a clock signal on the SYNC pin after enable
is asserted.
Configuration B: SYNC INPUT
When the SYNC pin is configured as an input (CFG
pin is tied LOW), the device will automatically check
for a clock signal on the SYNC pin each time EN is
asserted. The ZL2005’s oscillator will then synchronize with the rising edge of external clock.
The incoming clock signal must be in the range of 200
kHz to 2 MHz and must be stable when the enable pin
is asserted. The clock signal must also exhibit the necessary performance requirements (see Table 3). In the
event of a loss of the external clock signal, the output
voltage may show transient over/undershoot.
If this happens, the ZL2005 will turn off the power
FETs (QH and QL in Figure 4) typically within 10 μS.
Users are discouraged from removing an external
SYNC clock while the ZL2005 is operating with
Enable asserted.
19
If a clock signal is present, The ZL2005’s oscillator
will then synchronize the rising edge of the external
clock. Refer to SYNC INPUT description.
If no incoming clock signal is present, the ZL2005 will
configure the switching frequency according to the
state of the SYNC pin as listed in Table 13. In this
mode, the ZL2005 will only read the SYNC pin connection during the start-up sequence. Changes to
SYNC pin connections will not affect fSW until the
power (VDD) is cycled off and on.
Table 13. Switching Frequency Selection
SYNC Pin Setting
LOW
OPEN
HIGH
Resistor
Frequency
200 kHz
400 kHz
1 MHz
See Table 14
If the user wishes to run the ZL2005 at a frequency
other than those listed in Table 13, the switching frequency can be set using an external resistor, RSYNC,
connected between SYNC and SGND using Table 14.
FN6848.0
February 18, 2009
ZL2005
Table 14. RSYNC Resistor Values
fSW
RSYNC
fSW
RSYNC
200 kHz
222 kHz
242 kHz
267 kHz
296 kHz
320 kHz
364 kHz
400 kHz
421 kHz
471 kHz
533 kHz
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
571 kHz
615 kHz
667 kHz
727 kHz
889 kHz
1000 kHz
1143 kHz
1333 kHz
1600 kHz
2000 kHz
28.7 kΩ
31.6 kΩ
34.8 kΩ
38.3 kΩ
46.4 kΩ
51.1 kΩ
56.2 kΩ
68.1 kΩ
82.5 kΩ
100 kΩ
The switching frequency can also be set to any value
between 200 kHz and 2 MHz using the I2C/SMBus
interface. The available frequencies are bounded by
the relation fsw = 8 MHz/N, ( with 4<= N <= 40). See
Application Note AN13 for details on configuring the
switching frequency using the I2C/SMBus interface.
If multiple ZL2005s are used together, connecting the
SYNC pins together will force all devices to synchronize to one another. The CFG pin of one device must
have its SYNC pin set as an output and the remaining
devices must have their SYNC pins set as an input or
all devices must be driven by the same external clock
source.
Note: The switching frequency read back using the
appropriate PMBus command will differ slightly from
the selected value in Table 14. The difference is due to
hardware quantization.
5.8
Selecting Power Train Components
The ZL2005 is a synchronous buck controller that uses
external MOSFETs, inductor and capacitors to perform the power conversion process. The proper selection of the external components is critical for
optimized performance. Zilker Labs offers an online
circuit design and simulation tool, PowerPilot, to
assist designers in this task.
Please visit http://www.zilkerlabs.com to access PowerPilot. For more detailed guidelines regarding component selection, please refer to Application Note
AN11.
20
To select the appropriate power stage components for
a set of desired performance goals, the power supply
requirements listed in Table 15 must be known.
Table 15. Power Supply Requirements
Example
Parameter
Example
Value
Range
Input voltage (VIN)
3.0 – 14.0 V
Output voltage (VOUT)
0.6 – 5.0 V
0 to ~25 A
Output current (IOUT)
Output voltage ripple
< 3% of
(Vorip)
VOUT
Output load step (Iostep)
< Io
Output load step rate
—
Allowable output
—
deviation due to load step
Maximum PCB temp.
120°C
Desired efficiency
—
Other considerations
Various
12 V
1.2 V
20 A
1% of
VOUT
50% of Io
10 A/µS
± 50 mV
85°C
85%
Optimize
for small
size
Design Trade-offs
The design of a switching regulator power stage
requires the user to consider trade-offs between cost,
size and performance. For example, size can be optimized at the expense of efficiency. Additionally, cost
can be optimized at the expense of size. For a detailed
description of circuit trade-offs, refer to Application
Note AN11.
To start a design, select a switching frequency (fSW)
based on Table 16. This frequency is a starting point
and may be adjusted as the design progresses.
Table 16. Circuit Design Considerations
Frequency
Range
Efficiency
Circuit Size
200 – 400 kHz
400 – 800 kHz
800 kHz – 2 MHz
Highest
Moderate
Lower
Larger
Smaller
Smallest
Inductor Selection
The output inductor selection process will include several trade-offs. A high inductance value will result in a
low ripple current (Iopp), which will reduce the output
capacitance requirement and produce a low output ripple voltage, but may also compromise output transient
load performance. Therefore, a balance must be
FN6848.0
February 18, 2009
ZL2005
struck between output ripple and optimal load transient performance. A good starting point is to select
the output inductor ripple current (Iopp) equal to the
expected load transient step magnitude (Iostep):
I opp = I ostep
(3)
Now the output inductance can be calculated using the
following equation:
LOUT =
(
VOUT × 1 − VVOUT
INM
f sw × I opp
)
(4)
where VINM is the maximum input voltage.
The average inductor current is equal to the maximum
output current. The peak inductor current (ILpk) is calculated using the following equation where IOUT is the
maximum output current:
IL pk = I OUT +
I opp
2
(5)
Select an inductor rated for the average DC current
with a peak current rating above the peak current computed above.
In over-current or short-circuit conditions, the inductor
may have currents greater than 2X the normal maximum rated output current. It is desirable to use an
inductor that is not saturated at these conditions to protect the load and the power supply MOSFETs from
damaging currents.
Once an inductor is selected, the DCR and core losses
in the inductor are calculated. Use the DCR specified
in the inductor manufacturer’s datasheet.
PLDCR = DCR × I Lrms
2
(6)
core loss and the DCR loss and compare the total loss
to the maximum power dissipation recommendation in
the inductor datasheet.
Output Capacitor Selection
Several trade-offs also must be considered when
selecting an output capacitor. Low ESR values are
needed to have a small output deviation during transient load steps (Vosag) and low output voltage ripple
(Vorip). However, capacitors with low ESR, such as
semi-stable (X5R and X7R) dielectric ceramic capacitors, also have relatively low capacitance values.
Many designs can use a combination of high capacitance devices and low ESR devices in parallel.
For high ripple currents, a low capacitance value can
cause a significant amount of output voltage ripple.
Likewise, in high transient load steps, a relatively
large amount of capacitance is needed to minimize the
output voltage deviation while the inductor current
ramps up to the new steady state output current value.
As a starting point, allocate one-half of the output voltage ripple to the capacitor ESR and the other half to its
capacitance, as shown in the following equations:
COUT =
ESR =
I opp
8 × f sw ×
Vorip
I Lrms = I OUT +
2
I opp 2
(7)
12
where IOUT is the maximum output current. Next, calculate the core loss of the selected inductor. Since this
calculation is specific to each inductor and manufacturer, refer to the chosen inductor’s datasheet. Add the
21
(9)
2 × I opp
Use these values to make an initial capacitor selection,
using a single capacitor or several capacitors in parallel.
After a capacitor has been selected, the resulting output voltage ripple can be calculated using the following equation:
Vorip = I opp × ESR +
ILrms is given by:
(8)
Vorip
2
I opp
(10)
8 × f sw × COUT
Because each part of this equation was made to be less
than or equal to half of the allowed output ripple voltage, the Vorip should be less than the desired maximum
output ripple.
FN6848.0
February 18, 2009
ZL2005
For more information on the performance of the power
supply in response to a transient load, refer to Application Note AN11.
Calculate the desired maximum RDS(ON) as follows:
2
(14)
= P /I
R
Input Capacitor
It is highly recommended that dedicated input capacitors be used in any point-of-load design, even when
the supply is powered from a heavily filtered 5 or 12 V
“bulk” supply. This is because of the high RMS ripple
current that is drawn by the buck converter topology.
This input ripple (ICINrms) can be determined from the
following equation:
Note that the RDS(ON) given in the manufacturer’s
datasheet is measured at 25°C. The actual RDS(ON) in
the end-use application will be much higher. For
example, a Vishay Si7114 MOSFET with a junction
temperature of 125°C has an RDS(ON) 1.4 times higher
than the value at 25°C.
I CINrms = I OUT × D × (1 − D )
Without capacitive filtering near the power supply
input circuit, this current would flow through the supply bus and return planes, coupling noise into other
system circuitry. The input capacitors should be rated
at 1.2X the ripple current calculated above to avoid
overheating of the capacitors due to the high ripple
current, which can cause premature failure. Ceramic
capacitors with X7R or X5R dielectric with low ESR
and 1.1X the maximum expected input voltage are recommended.
Bootstrap Circuit Component Selection
The high-side driver boost circuit utilizes an external
Schottky diode (DB) and an external bootstrap capacitor (CB) to supply sufficient gate drive for the highside MOSFET driver. DB should be a 20 mA, 30 V
Schottky diode or equivalent device and CB should be
a 1 µF ceramic type rated for at least 6.3V.
QL Selection
The bottom MOSFET should be selected primarily
based on the device’s RDS(ON) and secondarily based
on its gate charge. To choose QL, use the following
equation and allow 2–5% of the output power to be
dissipated in the RDS(ON) of QL (lower output voltages
and higher step-down ratios will be closer to 5%):
= 0 . 05 × V OUT × I OUT
(12)
Calculate the RMS current in QL as follows:
I botrms = I Lrms × 1 − D
22
(13)
QL botrms
Select a candidate MOSFET, and calculate the
required gate drive current as follows:
I g = f sw × Qg
(11)
Please refer to Application Note AN11 for detailed
derivation including efficiency and ripple current.
PQL
DS(ON)
(15)
Keep in mind that the total allowed gate drive current
for both QH and QL is 80 mA.
MOSFETs with lower RDS(ON) tend to have higher
gate charge requirements, which increases the current
and resulting power required to turn them on and off.
Since the MOSFET gate drive circuits are integrated
in the ZL2005, this power is dissipated in the ZL2005
according to the following equation:
PQL = f sw × Qg × VINM
(16)
QH Selection
In addition to the RDS(ON) loss and gate charge loss,
QH also has switching loss. The procedure to select
QH is similar to the procedure for QL. First, assign 2–
5% of the output power to be dissipated in the RDS(ON)
of QH using the equation for QL above. As was done
with QL, calculate the RMS current as follows:
I toprms = I Lrms × D
(17)
Calculate a starting RDS(ON) as follows, in this example using 5%:
PQH
= 0 . 05 × V OUT × I OUT
RDS(ON) = PQH / Itoprms2
(18)
(19)
Select a MOSFET and calculate the resulting gate
drive current. Verify that the combined gate drive current from QL and QH does not exceed 80 mA.
FN6848.0
February 18, 2009
ZL2005
Next, calculate the switching time using
tsw =
Qg
VIN
GH
(20)
ZL2005
GL
where Qg is the gate charge of the selected QH and
Igdr is the peak gate drive current available from the
ZL2005.
Although the ZL2005 has a typical gate drive current
of 3 A, use the minimum guaranteed current of 2 A for
a conservative design. Using the calculated switching
time, calculate the switching power loss in QH using
Pswtop = VINM × t sw × I OUT × f sw
(21)
The total power dissipated by QH is given by the following equation:
P QHtot
VOUT
SW
I gdr
= P QH + P swtop
(22)
CL
R2
Figure 13. DCR Current Sensing
These components should be selected according to the
following equation:
τRC = L / DCR-------------------------- (24)
R1 should be in the range of 500 Ω to 5 kΩ in order to
minimize the power dissipation through it. The user
should make sure the resistor package size is appropriate for the power dissipated. Once R1 has been calculated, the value of R2 should be selected based on the
following equation:
R2 = 5 x R1 -----------------------------(25)
MOSFET Thermal Check
Once the power dissipations for QH and QL have been
calculated, the MOSFETs junction temperature can be
estimated. Using the junction-to-case thermal resistance (Rth) given in the MOSFET manufacturer’s
datasheet and the expected maximum printed circuit
board temperature, calculate the junction temperature
as follows:
Tj max = Tpcb + PQ × Rth
ISENA
ISENB
R1
(23)
For further details of thermal analysis and design see
Application Note AN10.
Current Sensing Components
Once the current sense method has been selected
(Refer to Section 5.9, “Current Limit Threshold Selection,” ), the procedure to select the component is the
following:
When using the inductor DCR sensing method, the
user must also select an R/C network comprised of R1
and CL (see Figure 13).
If RDS(ON) is being used the external low side MOSFET will act as the sensing element as indicated in
Figure 14.
5.9
Current Limit Threshold Selection
It is recommended that the user include a current limiting mechanism in their design to protect the power
supply from damage and prevent excessive current
from being drawn from the input supply in the event
that the output is shorted to ground or an overload condition is imposed on the output. Current limiting is
accomplished by sensing the current flowing through
the circuit during a portion of the duty cycle.
Output current sensing can be accomplished by measuring the voltage across a series resistive sensing element according to equation 26.
VLIM = ILIM x RSENSE ---------- -------(26)
Where:
ILIM is the desired maximum current that should
flow in the circuit
RSENSE is the resistance of the sensing element
VLIM is the voltage across the sensing element at
the point the circuit should start limiting the output current.
23
FN6848.0
February 18, 2009
ZL2005
The ZL2005 supports “lossless” current sensing, by
measuring the voltage across a resistive element that is
already present in the circuit. This eliminates additional efficiency losses incurred by devices that must
use an additional series resistance in the circuit.
To set the current limit threshold, the user must first
select a current sensing method. The ZL2005 incorporates two methods for current sensing, synchronous
MOSFET RDS(ON) sensing and inductor DC resistance
(DCR) sensing; Figure 14 shows a simplified schematic for each method.
VIN
GH
ZL2005
In addition to selecting the current sensing method, the
ZL2005 gives the power supply designer several
choices for the fault response during over or under
current condition. The user can select the number of
violations allowed before declaring fault, a blanking
time and the action taken when a fault is detected.
The blanking time represents the time when no current
measurement is taken. This is to avoid taking a reading
just after a current load step (Less accurate due to
potential ringing).It is a configurable parameter.
VOUT
SW
ISENA
The current sensing method can be selected using the
ILIM1 pin using Table 17. The ILIM0 pin must have a
finite resistor connected to ground in order for
Table 17 to be valid. If no resistor is connected
between ILIM0 and ground, the default method is
MOSFET RDS(ON) sensing. The current sensing
method can be modified via the I2C/SMBus interface.
Please refer to Application Note AN13 for details.
GL
ISENB
MOSFET RDS,ON Sensing
Table 17 includes default parameters for the number of
violations and the blanking time using pin-strap.
VIN
GH
VOUT
SW
ZL2005
GL
ISENA
ISENB
Inductor DCR Sensing
Figure 14. Current Sensing Methods
Table 17. Current Sensing Method Selection
ILIM0 Pin
1
ILIM1 Pin
RILIM0
LOW
RILIM0
OPEN
RILIM0
HIGH
Current Limiting Configuration
Ground-referenced (RDS,ON) sensing
Blanking time: 672 ns
Output-referenced, down-slope sensing
(Inductor DCR sensing)
Blanking time: 352 ns
Output-referenced, up-slope sensing
(Inductor DCR sensing)
Blanking time: 352 ns
Resistor
Number of
Violations
Allowed2
Comments
4
Best for low duty cycle
and low fSW
4
Best for low duty cycle
and high fSW
4
Best for high duty cycle
Depends on resistor value used; see Table 18
NOTES:
1. 10 kΩ < RILIM0 < 100 kΩ
2. The number of violations allowed prior to issuing a fault response.
24
FN6848.0
February 18, 2009
ZL2005
Table 18. Resistor Configured Current Sensing Method Selection
RILIM1
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
28.7 kΩ
31.6 kΩ
34.8 kΩ
38.3 kΩ
42.2 kΩ
46.4 kΩ
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
75 kΩ
82.5 kΩ
90.9 kΩ
Current Sensing Method
Ground-referenced (RDS,ON) sensing
Best for low duty cycle and low fSW
Blanking time: 672 ns
Output-referenced, down-slope sensing (Inductor DCR sensing)
Best for low duty cycle and high fSW
Blanking time: 352 ns
Output-referenced, up-slope sensing (Inductor DCR sensing)
Best for high duty cycle
Blanking time: 352 ns
Number of Violations
Allowed1
1
3
5
7
9
11
13
15
1
3
5
7
9
11
13
15
1
3
5
7
9
11
13
15
NOTES:
1. The number of violations allowed prior to issuing a fault response.
25
FN6848.0
February 18, 2009
ZL2005
Once the sensing method has been selected, the user
must select the voltage threshold (VLIM) based on
equation 26, the desired current limit threshold, and
the resistance of the sensing element.
The current limit threshold can be selected by simply
connecting the ILIM0 and ILIM1 pins as shown in
Table 19. The ground-referenced sensing method is
being used in this mode.
Table 19. Current Limit Threshold Voltage Settings
ILIM1
LOW
OPEN
HIGH
LOW
20 mV
50 mV
80 mV
ILIM0
OPEN
30 mV
60 mV
90 mV
HIGH
40 mV
70 mV
100 mV
The threshold voltage can also be selected in 5 mV
increments by connecting a resistor, RLIM0, between
the ILIM0 pin and ground according to Table 20. This
method is preferred if the user does not desire to use or
does not have access to the I2C/SMBus interface and
the desired threshold value is contained in Table 20.
5.10 Loop Compensation
The ZL2005 operates as a voltage-mode synchronous
buck controller with a fixed frequency PWM scheme.
Although the ZL2005 uses a digital control loop, it
operates much like a traditional analog PWM controller. See Figure 15 for a simplified block diagram of the
ZL2005 control loop, which differs from an analog
control loop by the constants in the PWM and compensation blocks. As in the analog controller case, the
compensation block compares the output voltage to
the desired voltage reference and compensation zeros
are added to keep the loop stable. The resulting integrated error signal is used to drive the PWM logic,
converting the error signal into a duty cycle value to
drive the external MOSFETs.
VIN
D
VOUT
1-D
Table 20. Current Limit Threshold Voltage Settings
VLIM
RLIM0
VLIM
RLIM0
0 mV
5 mV
10 mV
10 kΩ
11 kΩ
12.1 kΩ
55 mV
60 mV
65 mV
28.7 kΩ
31.6 kΩ
34.8 kΩ
15 mV
20 mV
25 mV
13.3 kΩ
14.7 kΩ
16.2 kΩ
70 mV
75 mV
80 mV
38.3 kΩ
42.2 kΩ
46.4 kΩ
30 mV
35 mV
40 mV
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
85 mV
90 mV
95 mV
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
45 mV
50 mV
100 mV
26.1 kΩ
L
DPWM
C
RO
RC
Compensation
Figure 15. Control Loop Block Diagram
In the ZL2005, the compensation zeros are set by configuring the FC0 and FC1 pins or via the I2C/SMBus
interface once the user has calculated the required settings. This method eliminates the inaccuracies due to
the component tolerances associated with using external resistors and capacitors. Most applications can be
served by using the pin-strap compensation settings
listed in Table 21. These settings will yield a conservative crossover frequency at a fixed fraction of the
switching frequency (fSw/20) and 60° of phase margin.
The current limit threshold can be set via the I2C/
SMBus interface. Please refer to Application Note
AN13 for further details on setting current limit
parameters.
26
FN6848.0
February 18, 2009
ZL2005
Table 21. Pin-Strap Setting for Loop Compensation
FC0 Range
FC0 Pin
fsw/60 < fn < fsw/30
HIGH
fsw/120 < fn < fsw/60
OPEN
fsw/240 < fn < fsw/120
LOW
Step 1: Using the following equation, calculate the
resonant frequency of the LC filter, fn.
1
f n = -----------------------2π L × C
(27)
Step 2: Based on Table 21, determine the FC0 setting.
Step 3: Calculate the ESR zero frequency (fZESR).
1
f zesr = -----------------2 πCRc
(28)
Step 4: Based on Table 21, determine the FC1 setting.
The parameters of the feedback compensation can also
be set using the I2C/SMBus interface. Refer to Application Note AN13 for details.
Refer to Application Note AN16 for details on setting
FC0 and FC1.
The Zilker Labs web site (www.zilkerlabs.com) provides an on-line tool (PowerPilot) which computes
compensation coefficients, and provides a parameterdriven design tool, schematic and BOM generation,
and circuit simulation including control loop simulation.
27
FC1 Range
FC1 Pin
fzesr > fsw/10
fsw/10 > fzesr > fsw/30
TBD
fzesr > fsw/10
fsw/10 > fzesr > fsw/30
TBD
fzesr > fsw/10
fsw/10 > fzesr > fsw/30
TBD
HIGH
OPEN
LOW
HIGH
OPEN
LOW
HIGH
OPEN
LOW
5.11 Non-Linear Response Settings
The ZL2005 incorporates a non-linear response (NLR)
loop that decreases the response time and the output
voltage deviation in the event of a sudden output load
current step. The NLR loop incorporates a secondary
error signal processing path that bypasses the primary
error loop when the output begins to transition outside
of the standard regulation limits. This scheme results
in a higher equivalent loop bandwidth than is possible
using a traditional linear loop.
When a load current step function imposed on the output causes the output voltage to drop below the lower
regulation limit, the NLR circuitry will force a positive
correction signal that will turn on the upper MOSFET
and quickly force the output to increase. Conversely, a
negative load step (i.e., removing a large load current)
will cause the NLR circuitry to force a negative correction signal that will turn on the lower MOSFET and
quickly force the output to decrease.
The ZL2005 has been pre-configured with appropriate
NLR settings that correspond to the loop compensation settings in Table 21.
FN6848.0
February 18, 2009
ZL2005
5.12 Efficiency Optimized Driver Deadtime Control
The ZL2005 utilizes a closed loop algorithm to optimize the dead-time applied between the gate drive signals for the top and bottom FETs. In a synchronous
buck converter, the MOSFET drive circuitry must be
designed such that the top and bottom MOSFETs are
never in the conducting state at the same time. (Potentially damaging currents flow in the circuit if both top
and bottom MOSFETs are simultaneously on for periods of time exceeding a few nanoseconds.) Conversely, long periods of time in which both MOSFETs
are off reduce overall circuit efficiency by allowing
current to flow in their parasitic body diodes.
It is therefore advantageous to minimize this deadtime to provide optimum circuit efficiency. In the first
order model of a buck converter, the duty cycle is
determined by the equation:
D = VOUT /VIN -------------------- (29)
However, non-idealities exist that cause the real duty
cycle to extend beyond the ideal. Deadtime is one of
those non-idealities that can be manipulated to
improve efficiency. The ZL2005 has an internal algorithm that constantly adjusts deadtime non-overlap to
minimize duty cycle, thus maximizing efficiency. This
circuit will null out deadtime differences due to component variation, temperature and loading effects.
This algorithm is independent of application circuit
parameters such as MOSFET type, gate driver delays,
rise and fall times and circuit layout. In addition, it
does not require drive or MOSFET voltage or current
waveform measurements.
28
FN6848.0
February 18, 2009
ZL2005
6
Power Management Functional Description
6.1
Input Undervoltage Lockout (UVLO)
The input undervoltage lockout (UVLO) prevents the
ZL2005 from operating when the input falls below a
preset threshold, indicating the input supply is out of
its specified range. The UVLO threshold (VUVLO)
can be set between 2.85 V and 16 V using the UVLO
pin. The simplest implementation is to connect the
UVLO pin as shown in Table 22. If the UVLO pin is
left unconnected, the UVLO threshold will default to
4.5 V.
Table 22. UVLO Threshold Settings
Pin Setting
UVLO Threshold
LOW
OPEN
HIGH
3V
4.5 V
10.8 V
3. Initiate an immediate shutdown until the fault has
been cleared. The user can select a specific number of retry attempts.
The default response from a UVLO fault is an immediate shutdown of the device. The device will continuously check for the presence of the fault condition. If
the fault condition is no longer present, the ZL2005
will be re-enabled.
Please refer to Application Note AN13 for details on
how to configure the UVLO threshold or to select specific UVLO fault response options via the I2C/SMBus
interface.
6.2
If the desired UVLO threshold is not one of the listed
choices, the user can configure a threshold between
2.85 V and 16 V by connecting a resistor between the
UVLO pin and GND by selecting the appropriate
resistor from Table 23.
Table 23. UVLO Resistor Values
UVLO
RUVLO
UVLO
RUVLO
2.85 V
3.14 V
3.44 V
3.79 V
4.18 V
4.59 V
5.06 V
5.57 V
6.13 V
6.75 V
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
28.7 kΩ
31.6 kΩ
34.8 kΩ
38.3 kΩ
42.2 kΩ
7.42 V
8.18 V
8.99 V
9.9 V
10.9 V
12 V
13.2 V
14.54 V
16 V
46.4 kΩ
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
75 kΩ
82.5 kΩ
90.9 kΩ
100 kΩ
VUVLO can also be set to any value between 2.85 V
and 16 V via I2C/SMBus.
Once an input undervoltage fault condition occurs, the
device can respond in a number of ways as follows:
1. Continue operating without interruption.
2. Continue operating for a given delay time, followed by shutdown if the fault still persists at the
29
end of the delay period. The device will remain in
shutdown until permitted to restart.
Output Overvoltage Protection
The ZL2005 offers an internal output overvoltage protection circuit that can be used to protect sensitive load
circuitry from being subjected to a voltage higher than
its prescribed limits. This feature is especially useful
in protecting expensive processors, FPGAs, and
ASICs from excessive voltages.
A hardware comparator is used to compare the actual
output voltage (seen at the VSEN pin) to a threshold
set to 15 % higher than the target output voltage by
default. If the voltage at the VSEN pin exceeds this
upper threshold level, the PG pin will de-assert. The
device can then respond in a number of ways as follows:
1. Initiate an immediate shutdown until the fault has
been cleared. The user can select a specific number of retry attempts.
2. Turn off the high-side MOSFET and turn on the
low-side MOSFET. The low-side MOSFET
remains ON until the device attempts a restart.
The default response from an overvoltage fault is an
immediate shutdown of the device. The device will
continuously check for the presence of the fault condition. If the fault condition is no longer present, the
ZL2005 will be re-enabled.
Please refer to Application Note AN13 for details on
how to select specific overvoltage fault response
options via the I2C/SMBus interface.
FN6848.0
February 18, 2009
ZL2005
6.3
Output Pre-Bias Protection
An output pre-bias condition exists when an externally
applied voltage is present on a power supply’s output
before the power supply’s control IC is enabled. Certain applications require that the converter not be
allowed to sink current during start up if a pre-bias
condition exists at the output. The ZL2005 provides
pre-bias protection by sampling the output voltage
prior to initiating an output ramp.
If a pre-bias voltage lower than the target voltage
exists after the pre-configured delay period has
expired, the target voltage is set to match the existing
pre-bias voltage and both drivers are enabled. The output voltage is then ramped to the final regulation value
at the ramp rate set by the SS (0,1) pins. The actual
time the output will take to ramp from the pre-bias
voltage to the target voltage will vary depending on
the pre-bias voltage but the total time elapsed from
when the delay period expires and when the output
reaches its target value will match the pre-configured
ramp time. See Figure 16.
If the pre-bias voltage is higher than the target voltage
exists after the pre-configured delay period has
expired, the target voltage is set to match the existing
pre-bias voltage and both drivers are enabled with a
PWM duty cycle that would ideally create the pre-bias
voltage. Once the pre-configured soft-start ramp
period has expired, the Power Good pin will be
asserted (assuming the pre-bias voltage is not higher
than the overvoltage limit). The PWM will then adjust
its duty cycle to match the original target voltage and
the output will ramp down to the pre-configured output voltage.
If a pre-bias voltage higher than the overvoltage limit,
the device will not initiate a turn-on sequence and will
declare an overvoltage fault condition to exist. In this
case, the device will respond based on the output overvoltage fault response method that has been selected.
See Section 6.2, “Output Overvoltage Protection,” for
response options due to an overvoltage condition.
6.4
Output Overcurrent Protection
The ZL2005 can protect the power supply from damage if the output is shorted to ground or if an overload
condition is imposed on the output. Once the current
limit threshold has been selected (see Section 5.9,
“Current Limit Threshold Selection,” ), the user may
determine the desired course of action to be taken
when an overload condition exists.
I
VOUT
Target
voltage
Pre-bias
voltage
SS
Delay
Time
SS
Ramp
The following overcurrent protection response options
are available:
1. Initiate a shutdown and attempt to restart an infinite number of times with a preset delay time.
VPREBIAS < VTARGET
2. Initiate a shutdown and attempt to restart the
power supply a preset number of times with a preset delay between attempts.
VOUT
Pre-bias
voltage
Target
voltage
3. Continue operating throughout a specific delay
time, followed by shutdown.
4. Continue operating throughout the fault (this
could result in permanent damage to the power
supply).
SS
Delay
SS
Ramp
Time
PG
Delay
VPREBIAS > VTARGET
Figure 16. Output Response to Pre-Bias
Voltages
30
5. Initiate an immediate shutdown.
The default response from an overcurrent fault is an
immediate shutdown of the device. The device will
continuously check for the presence of the fault condition. If the fault condition is no longer present, the
ZL2005 will be re-enabled.
FN6848.0
February 18, 2009
ZL2005
Please refer to Application Note AN15 for details on
how to select specific overcurrent fault response
options via the I2C/SMBus interface.
6.5
Thermal Protection
The ZL2005 includes an on-chip thermal sensor that
continuously measures the internal temperature of the
die and will shut down the device when the temperature exceeds the preset limit. The default temperature
limit is set to 125°C in the factory, but the user may set
the limit to a different value if desired. See Application Note AN13 for details. Note that setting a higher
thermal limit via the I2C/SMBus interface may result
in permanent damage to the device. Once the device
has been disabled due to an internal temperature fault,
the user may select one of several fault response
options as follows:
1. Initiate a shutdown and attempt to restart an infinite number of times with a preset delay time.
2. Initiate a shutdown and attempt to restart the
power supply a preset number of times with a preset delay between attempts.
3. Continue operating throughout a specific delay
time, followed by shutdown.
4. Continue operating throughout the fault (this
could result in permanent damage to the power
supply).
5. Initiate an immediate shutdown.
If the user has configured the device to restart, the
device will wait the preset delay period (if configured
to do so) and will then check the temperature. If the
temperature has dropped below a value that is approximately 15°C lower than the selected temperature limit
(the over-temperature warning threshold), the device
will attempt to re-start. If the temperature is still
above the over-temperature warning threshold, the
device will wait the preset delay period and retry
again.
6.6
Voltage Tracking
Numerous high performance systems place stringent
demands on the order in which the power supply voltages are turned on. This is particularly true when
powering FPGAs, ASICs, and other advanced processor devices that require multiple supply voltages to
power a single die. In most cases, the I/O operates at a
higher voltage than the Core and therefore the Core
supply voltage, must not exceed the I/O supply voltage
by some amount (typically 300 mV).
Voltage tracking protects these sensitive ICs by limiting the differential voltage between multiple power
supplies during the power-up and power down
sequence. The ZL2005 integrates a lossless tracking
scheme that allows its output to track a voltage that is
applied to the VTRK pin with no external components
required. The VTRK pin is an analog input that, when
tracking mode is enabled, configures the voltage
applied to the VTRK pin to act as a reference for the
device’s output regulation.
The ZL2005 offers two modes of tracking:
1. Coincident. This mode configures the ZL2005 to
ramp its output voltage at the same rate as the voltage applied to the VTRK pin.
2. Ratiometric. This mode configures the ZL2005 to
ramp its output voltage at a rate that is a percentage of the voltage applied to the VTRK pin. The
default setting is 50%, but an external resistor
string may be used to configure a different tracking ratio.
Figure 17 illustrates the typical connection and the two
tracking modes.
The default response from a temperature fault is an
immediate shutdown of the device. The device will
continuously check for the presence of the fault condition. If the fault condition is no longer present, the
ZL2005 will be re-enabled.
Please refer to Application Note AN13 for details on
how to select specific temperature fault response
options via the I2C/SMBus interface.
31
FN6848.0
February 18, 2009
ZL2005
VIN
Q1
GH
SW
VTRK
ZL2005
L1
Q2
GL
VOUT
C1
VTRK
VOUT
VTRK
VOUT
Time
Coincident
The master ZL2005 device in a tracking group is
defined as the device that has the highest target output
voltage within the group. This master device will control the ramp rate of all tracking devices and is not
configured for tracking mode. A delay of at least 10
ms must be configured into the master device using
the DLY0/1 pins, and the user may also configure a
specific ramp rate using the SS0/1 pins. Any device
that is configured for tracking mode will ignore its
soft-start delay and ramp time settings (SS0/1 and
DLY0/1 pins) and its output will take on the turn-on/
turn-off characteristics of the reference voltage present
at the VTRK pin. The tracking mode for all other
devices can be set by connecting a resistor from the
SS1 pin to ground according to Table 24. All of the
ENABLE pins in the tracking group must be connected together and driven by a single logic source.
VOUT
VTRK
VOUT
Time
Ratiometric
Figure 17. Tracking Modes
.
Table 24. Tracking Mode Configuration
RSS1
Tracking
Ratio
No resistor
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
100%
50%
Upper Track Limit
Ramp-up/Ramp-down Behavior
Tracking mode is disabled
Limited by target voltage and 110% of
Output not allowed to decrease before PG
V(0,1) pin-strap setting
Output will always follow VTRK
Limited by VTRK pin voltage 110%
of V(0,1) pin-strap setting
Output not allowed to decrease before PG
Limited by target voltage and 110% of
V(0,1) pin-strap setting
Output not allowed to decrease before PG
Limited by VTRK pin voltage 110%
of V(0,1) pin-strap setting
Output not allowed to decrease before PG
32
Output will always follow VTRK
Output will always follow VTRK
Output will always follow VTRK
FN6848.0
February 18, 2009
ZL2005
6.7
Voltage Margining
6.9
I2C/SMBus Device Address Selection
The ZL2005 offers a simple means to vary its output
higher or lower than its nominal voltage setting in
order to determine whether the load device is capable
of operating over its specified supply voltage range.
The MGN pin is a TTL-compatible input that is continuously monitored and can be driven directly by a
processor I/O pin or other logic-level output.
When communicating with multiple ZL2005s using
the I2C/SMBus serial interface, each device must have
its own unique address so the host can distinguish
between the devices. The device address can be set
according to the pin-strap options listed in Table 25 to
provide up to eight unique device addresses. Address
values are right-justified.
The ZL2005’s output will be forced higher than its
nominal setpoint when the MGN pin is driven HIGH,
and the output will be forced lower than its nominal
setpoint when the MGN pin is driven LOW. When the
MGN pin is left floating (high impedance), the
ZL2005’s output voltage will be set to its nominal
voltage setpoint determined by the V0 and V1 pins
and/or the I2C/SMBus settings that configure the nominal output voltage. Default margin limits of VNOM
±5% are pre-loaded in the factory, but the margin limits can be modified through the I2C/SMBus interface
to as high as VNOM + 10% or as low as 0V, where
VNOM is the nominal output voltage setpoint determined by the V0 and V1 pins.
Table 25. Serial Bus Device Address Selection
The margin limits and the MGN command can both be
set individually through the I2C/SMBus interface.
Additionally, the transition rate between the nominal
output voltage and either margin limit can be configured through the I2C/SMBus interface. Please refer to
Application Note AN13 for detailed instructions on
modifying the margining configurations.
6.8
I2C/SMBus Communications
The ZL2005 provides an I2C/SMBus digital interface
that enables the user to configure all aspects of the
device operation as well as monitor the input and output parameters. The ZL2005 can be used with any
standard 2-wire I2C host device. In addition, the
device is compatible with SMBus version 2.0 and
includes an SALRT line to help mitigate bandwidth
limitations related to continuous fault monitoring. The
ZL2005 accepts most standard PMBus commands.
SA1
SA0
LOW
OPEN
HIGH
LOW
OPEN
HIGH
0x20
0x21
0x22
0x23
0x24
0x25
0x26
0x27
Reserved
If additional device addresses are required, a resistor
can be connected to the SA0 pin according to Table 26
to provide up to 25 unique device addresses. In this
case the SA1 pin should be tied to SGND.
Table 26. SMBus Address Values
SMBus
Address
RSA0
0x00
0x01
0x02
0x03
0x04
0x05
0x06
0x07
0x08
0x09
0x0A
0x0B
0x0C
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
28.7 kΩ
31.6 kΩ
SMBus
Address
RSA0
0x0D
0x0E
0x0F
0x10
0x11
0x12
0x13
0x14
0x15
0x16
0x17
0x18
34.8 kΩ
38.3kΩ
42.2 kΩ
46.4 kΩ
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
75 kΩ
82.5 kΩ
90.9 kΩ
100 kΩ
If more than 25 unique device addresses are required
or if other SMBus address values are desired, both the
SA0 and SA1 pins can be configured with a resistor to
SGND according to the equation (30) and Table 27.
SMBus address = 25 x (SA1 index) + (SA0 index)
(30)
33
FN6848.0
February 18, 2009
ZL2005
Using this method, the user can theoretically configure
up to 625 unique SMBus addresses, however the
SMBus is inherently limited to 128 devices so
attempting to configure an address higher than 128
will cause the device address to repeat (i.e, attempting
to configure a device address of 129 would result in a
device address of 1). Therefore, the user should use
index values 0-4 on the SA1 pin and the full range of
index values on the SA0 pin, which will provide 125
device address combinations.
RSA
0
1
2
3
4
5
6
7
8
9
10
11
12
10 kΩ
11 kΩ
12.1 kΩ
13.3 kΩ
14.7 kΩ
16.2 kΩ
17.8 kΩ
19.6 kΩ
21.5 kΩ
23.7 kΩ
26.1 kΩ
28.7 kΩ
31.6 kΩ
Phase offset = device address x 45°
For example:
A device address of 0x00 or 0x20 would configure no phase offset
A device address of 0x01 or 0x21 would configure 45° of phase offset
Table 27. SMBus Address Index Values
SA0 or
SA1 Index
Selecting the phase offset for the device is accomplished by selecting a device address according to the
following equation:
SA0 or
SA1
Index
RSA
13
14
15
16
17
18
19
20
21
22
23
24
34.8 kΩ
38.3 kΩ
42.2 kΩ
46.4 kΩ
51.1 kΩ
56.2 kΩ
61.9 kΩ
68.1 kΩ
75 kΩ
82.5 kΩ
90.9 kΩ
100 kΩ
A device address of 0x02 or 0x22 would configure 90° of phase offset.
The phase offset of each device may also be set to any
value between 0° and 337.5° in 22.5° increments via
the I2C/SMBus interface. Please refer to Application
Note AN13 for details.
6.11 Output Sequencing
A group of ZL2005 devices may be configured to
power up in a predetermined sequence. This feature is
especially useful when powering advanced processors,
FPGAs, and ASICs that require one supply to reach its
operating voltage prior to another supply reaching its
operating voltage. Multi-device sequencing can be
achieved by configuring each device through the I2C/
SMBus interface or by using Zilker Labs’ patented
autonomous sequencing mode.
6.10 Phase Spreading
When multiple point of load converters share a common DC input supply, it is desirable to adjust the clock
phase offset of each device such that not all devices
start to switch simultaneously. Setting each converter
to start its switching cycle at a different point in time
can dramatically reduce input capacitance requirements and efficiency losses. Since the peak current
drawn from the input supply is effectively spread out
over a period of time, the peak current drawn at any
given moment is reduced and the power losses proportional to the IRMS2 are reduced dramatically.
In order to enable phase spreading, all converters must
be synchronized to the same switching clock. The
CFG pin is used to set the configuration of the SYNC
pin for each device as described in Section 5.7,
“Switching Frequency and PLL,” .
34
Autonomous sequencing mode configures sequencing
using status information broadcast by ZL2005 onto the
I2C/SMBus pins SCL and SDA. No I2C or SMBus
host device is involved in this method, but the SCL
and SDA pins must be interconnected between all
devices that the user wishes to sequence using this
method. Note: Pull-up resistors on SCL and SDA are
required and should be selected using the criteria in
the SMBus 2.0 specification.
The sequence order is determined using each device’s
I2C/SMBus device address.
Using autonomous
sequencing mode (configured using the CFG pin), the
devices must exhibit sequential device addresses with
no missing addresses in the chain. This mode will also
constrain each device to have a phase offset according
to its device address as described in Section 6.10,
“Phase Spreading” on this page.
FN6848.0
February 18, 2009
ZL2005
The group will turn on in order starting with the device
with the lowest address and will continue to turn on
each device in the address chain until all devices connected have been turned on. When turning off, the
device with the highest address will turn off first followed in reverse order by the other devices in the
group.
addresses differ in only the three least significant bits
of the address. For example, addresses 20, 25 and 27
are all within the same group. Addresses 1F, 20 and 28
are all in different groups. Devices in the same address
group can broadcast power on and power off sequencing and fault spreading events with each other.
Devices in different groups cannot.
Sequencing is configured by connecting a resistor
from the CFG pin to ground as described in Table 28.
The CFG pin is used to set the configuration of the
SYNC pin as well as to determine the sequencing
method and order. Please refer to Switching Frequency
and PLL for more details on the operating parameters
of the SYNC pin.
The Enable pins of all devices in a sequencing group
must be tied together and driven high to initiate a
sequenced turn-on of the group. Enable must be driven
low to initiate a sequenced turnoff of the group.
.
Table 28. CFG Pin Configurations for
Sequencing
RCFG
SYNC Pin
Config
10 kΩ
11 kΩ
12.1 kΩ
14.7 kΩ
16.2 kΩ
Input
Auto detect
Output
Input
Auto detect
17.8 kΩ Output
21.5 kΩ Input
23.7 kΩ Auto detect
26.1 kΩ Output
31.6 kΩ Input
34.8 kΩ Auto detect
38.3 kΩ Output
Sequencing
Configuration
Sequencing is disabled
The ZL2005 is configured
as the first device in a
nested sequencing group.
Turn-on order is based on
the device SMBus address.
The ZL2005 is configured
as a last device in a nested
sequencing group. Turn-on
order is based on the device
SMBus address.
The ZL2005 is configured
as the middle device in a
nested sequencing group.
Turn-on order is based on
the device SMBus address
Multiple device sequencing may also be achieved by
issuing PMBus commands to assign the preceding
device in the sequencing chain as well as the device
that will follow in the sequencing chain. This method
places less restrictions on device address (no need of
sequential address) and also allows the user to assign
any phase offset to any device irrespective of its
device address.
Please refer to Application Note AN13 for details on
sequencing via the I2C/SMBus interface.
6.12 Monitoring via I2C/SMBus
A system controller can monitor a wide variety of different ZL2005 system parameters through the I2C/
SMBus interface. The controller can monitor for fault
conditions by monitoring the SALRT pin, which will
be asserted when any number of pre-configured fault
or warning conditions occur. The system controller
can also continuously monitor for any number of
power conversion parameters including but not limited
to the following:
1. Input voltage
2. Output voltage
3. Output current
4. Internal junction temperature
5. Temperature of an external device
6. Switching frequency
7. Duty cycle
Please refer to Application Note AN13 for details on
how to monitor specific parameters via the I2C/
SMBus interface.
6.13 Temperature Monitoring Using the
XTEMP Pin
The ZL2005 supports measurement of an external
device temperature using either a thermal diode integrated in a processor, FPGA or ASIC, or using a discrete diode-connected NPN transistor such as a
Event based sequencing and fault spreading are broadcast in address groups of up to eight ZL2005 devices.
An address group consists of all devices whose
35
FN6848.0
February 18, 2009
ZL2005
2N3904 or equivalent. Figure 18 illustrates the typical
connections required.
XTEMP
ZL2005
2N3904
SGND
Discrete NPN
µP
FPGA
DSP
ASIC
XTEMP
ZL2005
SGND
Embedded Thermal Diode
Figure 18. External Temperature Monitoring
6.14 Fan Monitoring using the TACH Pin
The ZL2005 can monitor the tachometer pulse of an
external 3-wire fan connected to the TACH pin. The
device will report a revolutions per minute (RPM)
value assuming one pulse per revolution. The TACH
pin is only monitored when the device is enabled or
when it is configured to always be in monitoring
mode. Refer to Application Note AN13 for more
details on configuring specific operating modes.
36
6.15 Device Security Features
Note that the ZL2005 integrates several security measures to ensure that the user can only restore the device
to a level that has been made available to them. During
the initialization process, the ZL2005 checks for
stored values contained in its internal memory. The
ZL2005 offers two internal memory storage units that
are accessible by the user as follows:
1. Default Store: A power supply module manufacturer may want to protect the module from damage
by preventing the user from being able to modify
certain values that are related to the physical construction of the module. In this case, the module
manufacturer would use the Default Store and
would allow the user to restore the device to its
default setting but would restrict the user from
restoring the device to the factory setting.
2. User Store: The manufacturer of a piece of equipment may want to provide the ability to modify
certain power supply settings while still protecting
the equipment from modifying values that can
lead to a system level fault. The equipment manufacturer would use the User Store to achieve this
goal.
Please refer to Application Note AN13 for details on
how to set specific security measures via the I2C/
SMBus interface.
FN6848.0
February 18, 2009
ZL2005
7
Package Dimensions
NOTES:
1.
DIMENSIONING AND TOLERANCING CONFORM TO ASME Y14.5M. – 1994.
2.
ALL DIMENSIONS ARE IN MILLIMETERS (mm), O IS IN DEGREES.
3.
N IS THE TOTAL NUMBER OF TERMINALS.
4.
DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.15 AND 0.30 mm FROM
TERMINAL TIP. IF THE TERMINAL HAS THE OPTIONAL RADIUS ON THE OTHER END OF THE TERMINAL, THE
DIMENSION b SHOULD NOT BE MEASURED IN THAT RADIUS AREA.
5.
ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE, RESPECTIVELY.
6.
MAXIMUM PACKAGE WARPAGE IS 0.05 mm.
7.
MAXIMUM ALLOWABLE BURRS IS 0.076 mm IN ALL DIRECTIONS.
8.
PIN #1 ID ON TOP WILL BE LASER MARKED.
9.
BILATERAL COPLANARITY ZONE APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.
10. THIS DRAWING CONFORMS TO JEDEC REGISTERED OUTLINE MO-220.
37
FN6848.0
February 18, 2009
ZL2005
8
Ordering Information
ZL2005ALNFT
Product Designator
Shipping Option
T = Tape & Reel 100 pcs
T1 = Tape & Reel 1000 pcs
Contact factory for other options
Lead Finish
F = Lead-free Matte Tin
Firmware Revision
Alpha character
Operating Temperature Range
L = -40 to +85°C
Package Designator
A = QFN package
Related Documentation
The following application support documents and tools are available to help simplify your design.
Item
Description
ZL2005EVK1
AN10
AN11
AN13
AN15
AN16
AN21
AN22
AN23
Evaluation Kit: 12V to 3.3V, 20A DC/DC Converter with Power Management
Application Note: ZL2005 and ZL2105 Thermal and Layout Guidelines
Application Note: ZL2005 Component Selection Guide
Application Note: PMBus Command Set
Application Note: ZL2005 Current Protection and Measurement
Application Note: ZL2005 Digital Control Loop Compensation
Application Note: Protecting Configuration During Manufacturing
Application Note: Autonomous Sequencing Technology
Application Note: Voltage Tracking with the ZL2005
Revision History
Revision Number
Description
Date
1.0
1.1
1.2
FN6848.0
Initial release
Table 3 update
Table 3, 28 update
Assigned file number FN6848 to datasheet as this will be
the first release with an Intersil file number. Replaced
header and footer with Intersil header and footer. Updated
disclaimer information to read "Intersil and it's subsidiaries
including Zilker Labs, Inc." No changes to datasheet
content
2/16/06
4/25/06
9/07/06
2/18/09
38
FN6848.0
February 18, 2009
ZL2005
Zilker Labs, Inc.
4301 Westbank Drive
Building A-100
Austin, TX 78746
Tel: 512-382-8300
Fax: 512-382-8329
© 2006, Zilker Labs, Inc. All rights reserved. Zilker Labs, Digital-DC, Autonomous Sequencing and
the Zilker Labs logo are trademarks of Zilker Labs, Inc. All other products or brand names mentioned
herein are trademarks of their respective holders.
This document contains information on a product under development. Specifications are subject to
change without notice. Pricing, specifications and availability are subject to change without notice.
Please see www.zilkerlabs.com for updated information. This product is not intended for use in connection with any high-risk activity, including without limitation, air travel, life critical medical operations, nuclear facilities or equipment, or the like.
The reference designs contained in this document are for reference and example purposes only. THE
REFERENCE DESIGNS ARE PROVIDED "AS IS" AND "WITH ALL FAULTS" AND INTERSIL
CORPORATION AND IT'S SUBSIDIARIES INCLUDING ZILKER LABS, INC. DISCLAIMS ALL
WARRANTIES, WHETHER EXPRESS OR IMPLIED. ZILKER LABS SHALL NOT BE LIABLE
FOR ANY DAMAGES, WHETHER DIRECT, INDIRECT, CONSEQUENTIAL (INCLUDING
LOSS OF PROFITS), OR OTHERWISE, RESULTING FROM THE REFERENCE DESIGNS OR
ANY USE THEREOF. Any use of such reference designs is at your own risk and you agree to indemnify Intersil Corporation and it's subsidiaries including Zilker Labs, Inc. for any damages resulting
from such use.
39
FN6848.0
February 18, 2009