NSC LM27213MTDX

LM27213
Single Phase Hysteretic Buck Controller
General Description
Features
The LM27213 is a single-phase synchronous buck regulator
controller designed to fully support a portable microprocessor. On-chip gate drive makes for a compact, single chip
solution. Output currents in excess of 25 Amps are possible.
The IC employs a current mode hysteretic control mechanism. Inductor current is sensed through a low value sense
resistor.
The LM27213 will operate over an input voltage range of 5V
to 30V. The output voltage is programmed through 6 Voltage
Identification (VID) pins and ranges from 0.700V to 1.708V in
64 steps.
Since the error in the output voltage directly sets the inductor
current, the dynamic response to a large, fast load transient
is close to a square wave. This is optimal for mode transition
requirements. Also, due to the intrinsic input voltage feedforward characteristic of hysteretic control, the line transient
response is excellent as well.
The IC provides cycle-by-cycle peak current limit, overvoltage protection, and a power good signal. The LM27213
fully supports the Stop CPU and Sleep modes offered by
some processors. When enabled, the IC enters a powersaving “diode emulator” mode which helps prolong battery
runtime for portable systems.
n
n
n
n
n
n
n
n
n
n
n
n
n
Ideal load and line transient responses
5V to 30V input range
On-chip gate drive
Convenient CLK_EN# signal
Input under-voltage lockout
High light-load efficiency
Adjustable analog soft start
Peak current limit
Over-voltage protection
Error correction for good static accuracy
± 1% DAC accurcy over temperature
Interfaces with the LM2647 system supply
Available in TSSOP or tiny LLP package
Applications
n Core voltage supply for Low Power Processors
n Low voltage high current buck regulators
Benefits
n Single chip core power solution
n Minimum output capacitance required
n Low cost, compact design
The LM27213 also has a soft start feature for the external
adjustment of soft start speed.
Typical Application
20154330
© 2006 National Semiconductor Corporation
DS201543
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LM27213 Single Phase Hysteretic Buck Controller
February 2006
LM27213
Connection Diagrams
Top View
Top View
20154301
48-Lead TSSOP (MTD)
See NS Package Number MTD48
20154302
48-Lead LLP
NS Package Number SQA48A
Ordering Information
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Order Number
Package Drawing
Supplied As
LM27213MTD
MTD48
38 Units/Rail
LM27213MTDX
MTD48
1000 Units Tape and Reel
LM27213SQ
SQA48A
1000 Units Tape and Reel
LM27213SQX
SQA48A
4500 Units Tape and Reel
2
Pins 20 NC: No connect.
Pin 1, CBOOT: Connection for the high-side drive bootstrap
capacitor.
Pin 21, NC: No connect
Pin 22, P_Z0: Factory reference trim, do not connect. This
pin must float.
Pin 2, HG: High-side FET gate drive output.
Pin 3, SW: Connect to switch node (drain of bottom power
FET) to detect inductor current reversal. Also serves as the
return path for the high-side FET gate drive currents.
Pin 4, NC:No connect.
Pin 23, SGND: Signal Ground.
Pin 24, VDD: Chip power supply.
Pin 25, SS: : Soft start, soft shutdown and slew rate control.
Connect a capacitor between this pin and ground to control
the soft start and soft shutdown speed. The value of the
capacitor will also define the slew rate of the dynamic VID
transitions.
Pin 26, VIR7: 1.7V reference voltage.
Pin 5, SRCK: Source Kelvin. Connect directly to source of
low-side FET to detect negative inductor current.
Pin 6, NC: No connect
Pin 7, ILIM: Over-current sense. Voltage between this pin
and the regulator output is the voltage across the current
sense resistor.
Pin 27, VBOOT: Initial output voltage desired after soft start
completes. Connect this pin to the desired reference level.
Pin 28, VSLP: Desired Voltage in Sleep Mode. Connect this
pin to the desired reference level.
Pin 29, NC: : No connect.
Pin 8, ILIMREF: Current limit reference. Voltage between
this pin and the regulator output sets the inductor current
limit level.
Pin 9, CMP: Current sense. Voltage between this pin and
the regulator output sets the cycle by cycle inductor current.
Pin 30, NC: No connect.
Pin 31, VDAC: Buffered Digital-to-Analog converter output.
Pins 32, VSTP: Desired output voltage in Stop CPU mode.
Connect this pin to the desired reference level.
Pin 33, SLP: When this pin is logic high, VREF voltage is
equal to that on the VSLP pin.
Pin 10, CMPREF: Inductor current reference. Voltage between this pin and the regulator output programs the inductor current.
Pin 11, VREF: Desired regulator output voltage under no
load.
Pin 12, CLK_EN#: Signal to start clock chip PLL locking. A
low level indicates that the core supply is now stable and the
CPU can begin clocking.
Pin 13, DGND: Digital ground.
Pin 14, PGOOD: Power good flag. Open-drain output. Logic
high when output voltage enters the power good window and
XPOK is asserted. Masked during transitions.
Pin 15, XPOK: Input that tells the LM27213 that the supply
voltage for the Memory Controller Hub is up. The LM27213
will regulate the output voltage to VBOOT until XPOK transitions to a high state. PGOOD is forced low as long as this
pin is low.
Pin 16, SENSE: Regulator output voltage sense. Connect
directly to output.
Pin 17, VOVP: Over-voltage protection level. Connect this
pin to the desired reference voltage to set the trigger level for
over-voltage protection.
Pins 18 P_Z2: Factory reference trim, do not connect. This
pin must float.
Pin 19, P_Z1: Factory reference trim, do not connect. This
pin must float.
Pin 34, STP_CPU#: When this pin is logic low, VREF voltage is equal to that on the VSTP pin.
Pin 35, DE_EN#: Power saving mode trigger signal. Enables diode emulation.
Pin 36, VID5: 6th and most significant bit to program the
output voltage.
Pin 37, VID4: 5th bit to program the output voltage.
Pin 38, VID3: 4th bit to program the output voltage.
Pin 39, VID2: 3rd bit to program the output voltage.
Pin 40, VID1: 2nd bit to program the output voltage.
Pin 41, VID0: First and least significant bit to program the
output voltage.
Pin
Pin
Pin
Pin
Pin
Pin
Pin
3
42,
43,
44,
45,
46,
47,
48,
VR_ON: Chip enable input.
NC: No connect
NC: No connect.
PGND: Power Ground. Connect to ground plane.
NC: Power ground connection.
LG: Low-side FET gate drive output.
PVDD: Power input for the gate drives.
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LM27213
Pin Descriptions (TSSOP/LLP)
LM27213
VID
VID
5
4
3
2
1
0
Voltage
(V)
0
0
0
0
0
0
1.708
1
0
0
0
0
0
1.196
0
0
0
0
0
1
1.692
1
0
0
0
0
1
1.180
0
0
0
0
1
0
1.676
1
0
0
0
1
0
1.164
0
0
0
0
1
1
1.660
1
0
0
0
1
1
1.148
0
0
0
1
0
0
1.644
1
0
0
1
0
0
1.132
0
0
0
1
0
1
1.628
1
0
0
1
0
1
1.116
0
0
0
1
1
0
1.612
1
0
0
1
1
0
1.100
0
0
0
1
1
1
1.596
1
0
0
1
1
1
1.084
0
0
1
0
0
0
1.580
1
0
1
0
0
0
1.068
0
0
1
0
0
1
1.564
1
0
1
0
0
1
1.052
0
0
1
0
1
0
1.548
1
0
1
0
1
0
1.036
0
0
1
0
1
1
1.532
1
0
1
0
1
1
1.020
0
0
1
1
0
0
1.516
1
0
1
1
0
0
1.004
0
0
1
1
0
1
1.500
1
0
1
1
0
1
0.988
0
0
1
1
1
0
1.484
1
0
1
1
1
0
0.972
0
0
1
1
1
1
1.468
1
0
1
1
1
1
0.956
0
1
0
0
0
0
1.452
1
1
0
0
0
0
0.940
0
1
0
0
0
1
1.436
1
1
0
0
0
1
0.924
0
1
0
0
1
0
1.420
1
1
0
0
1
0
0.908
0
1
0
0
1
1
1.404
1
1
0
0
1
1
0.892
0
1
0
1
0
0
1.388
1
1
0
1
0
0
0.876
0
1
0
1
0
1
1.372
1
1
0
1
0
1
0.860
0
1
0
1
1
0
1.356
1
1
0
1
1
0
0.844
0
1
0
1
1
1
1.340
1
1
0
1
1
1
0.828
0
1
1
0
0
0
1.324
1
1
1
0
0
0
0.812
0
1
1
0
0
1
1.308
1
1
1
0
0
1
0.796
0
1
1
0
1
0
1.292
1
1
1
0
1
0
0.780
0
1
1
0
1
1
1.276
1
1
1
0
1
1
0.764
0
1
1
1
0
0
1.260
1
1
1
1
0
0
0.748
0
1
1
1
0
1
1.244
1
1
1
1
0
1
0.732
0
1
1
1
1
0
1.228
1
1
1
1
1
0
0.716
0
1
1
1
1
1
1.212
1
1
1
1
1
1
0.700
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5
4
3
2
1
0
Voltage
(V)
4
SQA, TA = 25˚C, (Note 2)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Junction Temperature
ESD Rating (Note 4)
2kV
VDD, DVDD XPOK,
VR_ON, DE_EN#, VOVP,
VBOOT, VID0 to VID5,
STP_CPU#, SLP, VSLP,
VSTP, SENSE, CMP1,
CMP2, CMPREF, ILIM1,
ILIM2, ILIMREF
Storage Temp Range
-65˚C to +150˚C
Soldering Dwell Time,
Temperature
Wave
Infrared
Vapor Phase
4sec, 260˚C
10sec, 240˚C
75sec, 219˚C
-0.3V to 7V
PGOOD
-0.3V to 6V
SW to GND (Note 6)
-2V to 30V
CBOOT to SW
-0.3V to 8V
Power Dissipation
TSSOP, TA = 25˚C, (Note
2)
LM27213
Absolute Maximum Ratings (Note 1)
4.9W
+150˚C
Functional Temp. Range
-20˚C to +110˚C
Operating Ratings (Note 1)
VDD
4.75V to 6V
Junction Temperature
-5˚C to +110˚C
Ambient Temperature
-5˚C to +105˚C
1.56W
Electrical Characteristics Specifications with standard typeface are for TJ = 25˚C, and those in bold face
type apply over a junction temperature range of -5˚C to +110˚C. Unless otherwise specified, VDD = 5V, SGND = DGND =
PGND = SRCK = 0V, unless otherwise stated. (Note 5)
Symbol
Parameter
Conditions
Min
Typ
Max
Units
Chip Supply
Isd
VDD Shutdown Current
VR_ON = 0V, VDD = 6V
1
10
µA
Iq
VDD Normal Operating Current
VR_ON = 3.3V
3
4.2
mA
4.5
UVLO Threshold
VDD = V5A = V5B, rising from 0V
4
4.3
UVLO Hysteresis
VDD = V5A = V5B falling from UVLO
Threshold
0.2
0.66
V
V
VLH
VR_ON, STP_CPU#, XPOK and SLP
Input Logic High
VR_ON, STP_CPU#, XPOK or SLP
rising from 0V
2.31
1.9
V
VLL
VR_ON, STP_CPU#, XPOK and SLP
Input Logic Low
VR_ON, STP_CPU#, XPOK or SLP
falling from 3.3V
CLK_EN# Sink Current
CLK_EN# = 0.1V and asserted
2.5
7
VPGH
Power Good Upper Threshold As A
Percentage of VREF
SENSE voltage rising from 0V
108
114
119
%
VPGL
Power Good Lower Threshold As A
Percentage of VREF
SENSE voltage falling from above
VREF
85
88
91
%
Logic
1.43
0.99
V
mA
Power Good
Hysteresis
5
%
tdpgood
Power Good Delay
3
µs
Ipgood
PGOOD Sink Current
mA
PGOOD = 0.1V and asserted
2.5
7
SS = 0V
16
22
Output Voltage Slew Rate Control
Iss(on)
Soft Start Current
Iss(off)
Soft Shutdown Current
33
VID and Mode Change Slew Rate
Control Current
255
0.63
0.56
Iss(slew)
32
µA
45
57
µA
337
415
µA
DAC and References
VIDLH
VID Pins Input Logic High
VIDLL
VID Pins Input Logic Low
0.48
5
V
0.315
V
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LM27213
Electrical Characteristics Specifications with standard typeface are for TJ = 25˚C, and those in bold face
type apply over a junction temperature range of -5˚C to +110˚C. Unless otherwise specified, VDD = 5V, SGND = DGND =
PGND = SRCK = 0V, unless otherwise stated. (Note 5) (Continued)
Symbol
Vdac
V1R7
Parameter
DAC Accuracy
Conditions
Min
Typ
Max
Measured at VREF pin
%
DAC codes from 0.7V to 0.828V
-1.3
1.3
DAC codes from 0.844V to 1.004V
-1.1
1.1
DAC codes from 1.020V to 1.196V
-0.9
0.9
DAC codes from 1.212V to 1.356V
-1
1
DAC codes from 1.372V to 1.500V
-1.1
1.1
DAC codes from 1.516V to 1.708V
-1.3
V1R7 Accuracy
17kΩ from V1R7 to GND
VSTP Offset
VSTP = 1.398V, Measured at VREF
pin
VBOOT Offset
Units
-1.674
1.3
1.708
1.742
V
-5
5
mV
VBOOT = 1.00V, Measured at VREF
pin
-5
5
mV
-5
VSLP Offset
VSLP = 0.748V, Measured at VREF pin
IVREF
VREF Driving Capability
source
1.3
sink
12.6
mA
IVDAC
VDAC Driving Capability
source
1.3
mA
sink
13.4
mA
µA
IV1R7
V1R7 Driving Capability
5
mV
mA
source
90
549
Error Comparator Input Bias Current
(Sourcing)
CMP = 1.436V.
12
21
33
µA
VOSEC
Error Comparator Input Offset Voltage
CMPREF = 1.436V.
-3
3
mV
IHYST
Hysteresis Current (bi-directional)
Rhys = 17kW
38
50
68
µA
Error Comparator
IBEC
Rhys = 170kW
5
µA
Current Limit
IBCLC
VOSCLC
Current Limit Comparator Input Bias
Current
9
Current Limit Comparator Input Offset
Voltage
ILIMREF = 1.436V.
Current Limit Setting Current
Rhys = 17kW, ILIMREF < ILIMx
21
-2
280
Rhys = 17kW, ILIMREF > ILIMx
Rhys = 170kW, ILIMREF < ILIMx
337
35
µA
2
mV
395
µA
250
µA
30
µA
Time Delays
tBOOT
tCPU_PWRGD
tMASK
tdPG
VBOOT Voltage Holdup Time
From assertion of XPOK to assertion of
CLK_EN#.
10
17
30
µs
Power Good Mask For Initial VID
Voltage Settling
From assertion of CLK_EN# to
assertion of PGOOD.
3
5
9
ms
100
129
179
µs
Power Good Mask For VID Changes
Power Good De-assertion Delay Upon
Shutdown
Delay From VR_ON de-assertion to
PGOOD de-assertion
60
ns
Over-voltage Protection
VTRIP
SENSE Voltage As A Percentage of
VOVP
VOVP = V1R7
109
125
0.63
0.56
139
%
System
DE_EN#LH
DE_EN# Input Logic High
DE_EN#LL
DE_EN# Input Logic Low
IDE_EN#
VSDT
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DE_EN# Pin Leakage Current
DE_EN# = 7.5V
Soft Shutdown Finish Threshold
Low-side driver enabled after shutdown
6
V
0.47
0.315
V
6
100
µA
0.3
V
LM27213
Electrical Characteristics Specifications with standard typeface are for TJ = 25˚C, and those in bold face
type apply over a junction temperature range of -5˚C to +110˚C. Unless otherwise specified, VDD = 5V, SGND = DGND =
PGND = SRCK = 0V, unless otherwise stated. (Note 5) (Continued)
Symbol
Parameter
Conditions
Min
Typ
Max
Units
14
100
µA
Drivers
Iqdriver
Driver Quiescent current
High drive = low, Low drive = high
VCBOOT = VDVDD = 5V
Top Driver pull-up current
VDVdd = 5V, Load = 0.1Ω
3
A
Top Drive pull-up Rds_on
ICBOOT = IHG = 0.7A
1.2
Ω
Top Drive pull-down current
VDVdd = 5V, Load = 0.1Ω
-3.2
A
Top Drive pull-down Rds_on
Isw = IHG = 0.7A
0.6
Ω
TRISEHG
Top drive rise time
Cload = 3.3nF, (10% to 90%)
17
ns
tFALLHG
Top drive fall time
Cload = 3.3nF, (10% to 90%)
12
ns
Bottom driver pull-up current
VDVdd = 5V, Load = 0.1Ω
3.2
A
Bottom Drive pull-up Rds_on
ICBOOT = IlG = 0.7A
2.9
Ω
Bottom Drive pull-down currrent
VDVdd = 5V, Load = 0.1Ω
3.2
A
Bottom Drive pull-down Rds_on
Isw = IlG = 0.7A
0.6
Ω
TRISELG
Bottom Drive rise time
Cload = 3.3nF, (10% to 90%)
17
ns
TFALLLG
Bottom Drive fall time
Cload = 3.3nF, (10% to 90%)
14
ns
Prop delay, CMP to top driver
CMP rising above CMPREF (20mV
overdrive) to HG dropping to VSW +
0.9 VDVdd, Cload = 3.3nF
89
ns
TDLY
Note 1: Absolute maximum ratings indicate limits beyond which damage to the device may occur. Operating Ratings are conditions under which operation of the
device is guaranteed. For guaranteed performance limits and associated test conditions, see the Electrical Characteristics table. Functional temperature range is the
range within which the device performs its intended functions, but not necessarily meeting the limits specified in the Electrical Characteristic table.
Note 2: The maximum allowable power dissipation is calculated by using PDmax = (TJMAX - TA) /θJA , where TJMAX is the maximum junction temperature, TA is the
ambient temperature, and θJA is the junction-to-ambient thermal resistance of the specified package. The TSSOP rating of 1.56W results from using 150˚C, 25˚C,
and 80˚C/W for TJMAX, TA, and θJA respectively. The θJA of 90˚C/W represents the worst-case condition with no heat sinking of the 48-Pin TSSOP. Heat sinking
allows the safe dissipation of more power. The Absolute Maximum power dissipation should be de-rated by 12.5mW per ˚C above 25˚C ambient. The SQA rating
of 5.2W results from using 150˚C, 25˚C, and 24.2˚C/W for TJMAX, TA, and θJA respectively. The Absolute Maximum power dissipation should be de-rated by 41mW
per ˚C above 25˚C ambient. The LM27213 actively limits its junction temperature to about 150˚C.
Note 3: For detailed information on soldering plastic small-outline packages, refer to the Packaging Databook available from National Semiconductor Corporation.
Note 4: For testing purposes, ESD was applied using the human-body model, a 100pF capacitor discharged through a 1.5kΩ resistor.
Note 5: All limits are guaranteed at room temperature (standard face type) and at temperature extremes (bold face type). All room temperature limits are 100%
production tested. All limits at temperature extremes are guaranteed via correlation using Statistical Quality Control (SQC) methods. All limits are used to calculate
Average Outgoing Quality Level (AOQL).
Note 6: The SW pin can have -2V to -0.5 volts applied for a maximum duty cycle of 10% with a minimum frequency of 1Hz. There is no duty cycle or maximum
period limitation for a SW pin voltage range of -0.5V to 30 Volts.
7
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LM27213
Typical Application
20154304
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8
LM27213
Block Diagram
20154303
9
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LM27213
Typical Performance Characteristics
Turn-On Waveforms
Transient Response
20154305
20154306
Ch1: VOUT
Ch3: VRON, VIN = 13V, IOUT = 0
3.5A to 12A load step
Cursor lines are spec limits
Ch1: VOUT
Ch4: IOUT, 8A/div
Turn-Off Waveforms
VID Change, VID 5 from 1 to 0
20154307
20154308
Ch1: VOUT
Ch 3: VRON
Ch1: VOUT
Ch 3: VID5
Ch 4: PGOOD
Ch 4: PGOOD
Start-Up, VBOOT to VID Transition
VID Change, VID 5 from 0 to 1
20154310
20154309
Ch1: VOUT
Ch2: CLK_EN#
Ch1: VOUT
Ch 3: XPOK
Ch 3: PGOOD
Ch2: VID5
Ch 4: PGOOD
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10
LM27213
Typical Performance Characteristics
(Continued)
Light Load, Diode Emulator Mode
LM29213 Typical Efficiency
20154311
Ch1: Switch Node
Ch2: VID5
20154312
Ch 3: VOUT
ILIMREF Bias vs VIN at 25˚C
Hysteresis Current vs VIN at 25˚C
20154313
20154314
ILIM vs Temperature
Hysteresis Current vs Temperature
20154316
20154315
11
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LM27213
Typical Performance Characteristics
(Continued)
DAC 100100 (1.32V) vs Temperature
UVLO Rising Threshold vs Temperature
20154317
20154318
DAC 100100 vs VIN
UVLO Falling Threshold vs Temperature
20154320
20154319
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12
LM27213
Applications Information
The LM27213 is a single phase current-mode hysteretic
controller intended for controlling a power supply for a low
voltage CPU core. It is capable of currents up to approximately 25A with conventional surface mount power devices.
Hysteretic control assures the fastest possible transient response and a nearly ideal voltage positioning droop response.
THEORY OF OPERATION
The LM27213 controls the inductor ripple current on a cycle
by cycle basis. Several reference voltages are available
depending on the mode of operation selected. There is an
internal DAC that gets programmed via 6 VID (Voltage Identification) bits. In addition, there are several inputs that allow
separate references to be selected in various “sleep modes”.
An internal MUX selects the reference to be used by the
control loop. A softstart function controls the rate at which the
selected reference is allowed to ramp up at turn on. There is
a cycle by cycle current limit loop as well as over voltage
protection.
20154321
FIGURE 1.
CONTROL LOOP OPERATION
The main regulator loop is a current mode hysteretic design
that maintains control over the buck inductor’s peak-peak
ripple current. A small hysteresis current is forced to flow
through resistor RH which is connected between the CMP
pin and the left side of the current sense resistor. When the
high-side switch is on, this current flows into the pin forcing
CMP below CMPREF. As the inductor current increases, the
voltage at CMP rises. The error comparator turns off the
high-side switch and turns on the low-side switch when the
inductor current exceeds the demand. When the high-side
switch turns off the hysteresis current is reversed and current is sourced from the CMP pin. The error comparator now
allows the inductor current to decay until the new threshold is
crossed. Refer to Figure 1 below. The hysteresis current
actually consists of four components. The main hysteresis
source is programmed by the current out of the V1R7 reference pin. The total divider resistance on this pin controls the
magnitude of this current which is mirrored and sent to the
CMP pin. This source will only be active when the high-side
switch is on. In addition, there’s a small correction current
that varies as a function of duty factor. Its magnitude is
approximately 74µA*DF, where DF is the duty factor. At
typical operating duty factors, it will be around 7µA and in the
same direction as the main hysteresis current. This current
will flow at all times. The tail current from the current sense
comparator also needs to be accounted for. This 16µA flows
from the CMP pin when PWM is high, and from the CMPREF
pin when PWM is low. Its direction is opposite that of the
hysteresis current source and so subtracts from the total
hysteresis current. The final contribution to the hysteresis
current is the 50uA that is sourced continuously and serves
as the “off” hysteresis. It is recommended that approximately
100µA be programmed through the V1R7 pin. At this level
the “on” and “off” currents are approximately symmetrical
around zero.
The current through the V1R7 pin is simply 1.708V divided
by Req. Therefore the effective divider resistance should be
approximately 17kΩ. The hysteresis current when the highside switch is on (assuming a roughly 10% duty factor) is
100µA +7µA -16µA - 50µA = 41µA. When the high-side
switch is off Ihyst is only 7µA -50µA = - 43µA. It is the
difference between these two levels that controls the pk-pk
inductor current or:
∆Ihyst = IV1R7 -16µA
Note that the correction current (74µA *DF) does not appear
in this equation. It serves only to move the output voltage
slightly as a function of duty factor to correct for offsets that
are inherent in the topology.
Figure 2 shows a higher level picture of the control loop. The
reference that the CMP voltage is compared to is the voltage
at the CMPREF pin. Assume that the CMPREF pin is simply
tied to a fixed reference voltage (R2 open). The control loop
would force the peak voltage at point A minus the hysteresis
voltage to equal the reference level. Since the on and off
hysteresis currents are symmetrical around zero, the average voltage at point A is therefore equal to the reference
voltage. There will be a voltage droop as a function of load
(load line) equal to the value of Rsense, the current sense
resistor. Adding resistors R1 and R2 allows this load line
slope to be increased without raising the value of the sense
resistor. The voltage across R2 will equal the voltage across
the sense resistor, Rs. So, if R1 = R2 the load line will be
twice Rs. Algebraically,
LL = Rs x (1+R1/R2)
When the high-side switch has been turned off, the 16µA
comparator input bias current now flows out of the CMPREF
pin through the parallel combination of R1 and R2. This
results in a small increase in the reference voltage (about
1mV with typical values) and will reduce the size of the
hysteresis band by an equal amount.
13
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LM27213
Applications Information
(Continued)
Where:
Rs is the value of the current sense resistor in Ohms
L is the inductor value in µH
∆Ihyst is the hysteresis current in Amps
Rhys is the value of the hysteresis resistor in Ohms
This equation is greatly simplified and fails to account for the
effects of output ripple, comparator delay times etc. There
are far too many subtle variables involved in this topology to
be able to make very accurate operating frequency estimates. This equation should provide a ballpark starting point
with the final value of the hysteresis resistor arrived at empirically. At high frequency the delays through the comparator and driver will be the dominant factor in determining the
operating frequency.
CURRENT LIMITING
Current limit is achieved by comparing the instantaneous
voltage across the current sense resistor with the voltage
developed across the current limit threshold resistor, R13 in
the typical application circuit. If the controller sees this
threshold exceeded, the current switching cycle is terminated and the hysteresis current dropped in half. The voltage
across the current limit set point resistor is determined by the
value of the resistor and the magnitude of the current
through the ILIMREF pin. This current is nominally three
times the current drawn through the V1R7 reference pin.
When current limit is reached, this current is reduced to
250% of the V1R7 current. Be sure to use the full load DC
current plus 1⁄2 the pk-pk inductor ripple current when determining the required current sense threshold.
20154322
FIGURE 2.
Figure 3 below shows the theoretical waveform that is to be
expected at the CMP pin. Zero output ripple voltage is assumed. In reality these signals ride on top of the regulator’s
output ripple and may be very hard to discern. There’s a
small delay time from the instant the voltage on the CMP pin
crosses the voltage on CMPREF. This delay will result in the
inductor peak current overshooting the hysteresis setting.
For high step-down ratios the inductor current down-slope
will be much more shallow than the up-slope. Therefore, the
undershoot magnitude will be less than the overshoot magnitude. As a result of these delays the actual hysteresis will
be somewhat greater than programmed.
The actual wave shapes will be very dependant on the type
of output capacitor selected. The resistive component of
electrolytic type capacitors (ESR) will serve to provide a
significant amount of instantaneous feedforward due to the
current flow through the capacitors. By contrast, if an all
ceramic output capacitor decoupling network is employed,
the current flow through the capacitor is integrated over time,
and current information is phase shifted. This tends to alter
the regulator’s behavior somewhat. In particular, the operating frequency will be very hard to predict since decoupling
parasitics play a significant part in shaping the waveforms at
the CMP pin. As such, it is generally simplest to choose the
final value for the hysteresis resistor empirically.
POWER GOOD
The output voltage is sensed at the Sense pin (16) and
monitored by a window comparator with thresholds set to
nominally 88% and 112% of the selected output voltage set
point. As long as Vcore remains within the window, the power
good signal will be logic high. This output is an open drain
device and requires an external pull up. At power up, the
LM27213 will wait approximately 5ms after XPOK is asserted before releasing PGOOD. If the output voltage is then
within the ± 12% window, the flag will be asserted.
OVER-VOLTAGE PROTECTION
The sense pin is also used to provide the input to the
over-voltage protection circuitry. If at any time the output is
determined to be more than a nominal 120% of the voltage
set on the VOVP pin (17), the high-side FET is turned off and
the low-side FET is turned on. The soft start capacitor will
also be discharged. This state is latched. In order to initiate
a restart, remove and restore power to the controller or
toggle the VRON pin.
SOFT START
When VRON is enabled the regulator begins a normal start
sequence that actively controls the rise of output voltage. An
internal 20µA current source supplies current through the
Soft Start pin (25) that charges the soft start capacitor. The
output voltage is forced to track this voltage up. The result is
a linear output voltage rise. The capacitor value required is
20154323
FIGURE 3.
The approximate operating frequency is:
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14
comes a nearly ideal diode. Due to the hysteretic control
mode, the regulator operating frequency will be greatly reduced at light loads. High-side switch on-time will not change
significantly compared to normal operation, but the off times
will extend greatly. Care must be taken to connect the SRCK
(Source Kelvin, pin 5) close to the low-side switch source
connection, as this is the reference input to the zero cross
detector.
(Continued)
simply 20µA divided by the desired slew rate. For an output
voltage rate of rise of 1V/ms, the capacitor should be about
20nF.
SOFT STOP
When VRON is deasserted, the LM27213 starts to discharge
the soft start capacitor with an internal 45µA current sink.
Vcore is forced to follow the resulting linear ramp voltage on
the soft start capacitor downward. When Vcore reaches approximately 300mV the high-side FET is disabled and the
low-side FET is turned on to quickly discharge the output to
zero and hold it there. This forces a controlled turn off slew
rate that eliminates the possibility of the output voltage ringing significantly below ground. It can also be helpful in the
sequencing of multiple supply rails.
Component Selection
There are numerous tradeoffs to be made in settling on a
final set of component choices and as a result the process
tends to be somewhat iterative. There’s always more than
one combination of parts that will work in a given application.
We will start with a few rule of thumb assumptions and then
adjust as required to find a combination that meets the
specification requirements and is cost effective. Some of the
choices can be thought of as somewhat philosophical.
Let’s start the design by choosing an inductor and then
develop the remainder of the design around that choice.
STARTUP SEQUENCING
At initial power up the LM27213 targets a voltage equal to
Vboot. This is the voltage level set at the VBOOT pin (27) by
a resistor divider that is powered by the V1R7 reference
output (pin 26). This divider also has taps for the OVP
threshold and deeper sleep voltage set point. The regulator’s
output will remain at Vboot until a time Tboot after the XPOK
flag clears. Tboot is nominally 20µs. After the Tboot time
expires CLK_EN# will be asserted and the output will transition to the voltage selected by the VID bits. Power good will
be enabled nominally 5ms after CLK_EN# is asserted.
INDUCTOR SELECTION
A good place to start is by choosing an appropriate buck
inductor. A decent rule of thumb is to allow the worst case,
peak to peak ripple current to be on the order of 40% to 50%
of the full load output current. So, for a design of 12A at full
load, the ripple current should be in the range of 4.8A to 6A.
Larger or smaller ripple currents may well be acceptable but
there are tradeoffs associated with these choices. As inductor value increases, there is a corresponding need to increase the amount of output capacitance to handle load
transients. Conversely, as inductance is reduced, the RMS
switch currents tend to rise and therefore efficiency suffers
slightly while dynamic performance is improved.
DYNAMIC VID TRANSITIONS
Upon detecting a VID or mode change the LM27213 masks
the power good comparator for a period of approximately
130µs. During the blanking interval the power good output is
forced high while the output voltage is in slew to the newly
selected level. The slew rate is determined by the soft start
capacitor value. The charge/discharge current driving the
soft start capacitor will be 350µA typically. The programmed
slew rate is therefore 350µA divided by the soft start pin
capacitance.
The worst case ripple current will occur at the combination of
maximum input and output voltage. Let’s assume an output
voltage of 1.180V and a maximum input of 16V. This will
assume operation on a wall adapter while battery voltage
may be only 12V maximum. Another assumption that must
be made is the intended operating frequency. Again there
exists a tradeoff between dynamic performance and efficiency. The “sweet spot” at the time of this writing is roughly
in the range of 300kHz to 400kHz. That will in all likelihood
shift positive in time as FET technology improves. The hysteretic architecture also varies the operating frequency as a
function of input voltage with the regulator tending to run a bit
slower at high input voltages. Let’s assume a 300kHz frequency at high input line. Also, since the efficiency is of
somewhat less of a concern when operating from a wall
adapter we’ll design for the high end of the ripple current
range under this condition. The ripple current will be lower
when operating from a battery since the input voltage will be
lower and the switching frequency will be somewhat higher.
With all that settled let’s calculate a value for L.
L = (VIN-VO)VO/(∆I x VIN x fSW)
Where:
L is the inductor value
Vin is the input voltage
Vo is the output voltage
∆I is the ripple current
fsw is the switching frequency
So,
L = (16V-1.18V)1.18V/(6A x 16V x 300kHz)
STOP CPU MODE
If the STP_CPU# pin (34) is asserted with SLP de-asserted
the VREF pin voltage will be forced to the voltage on the
VSTP pin (32). The output will slew at a rate determined as
above to the new value. The PGOOD mask is in effect for
130µs.
SLEEP MODE
To enable sleep mode both STP_CPU# and SLP need to be
asserted. The VREF pin voltage will transition to the voltage
on the VSLP pin with a slew rate as discussed under ynamic
VID transitions and the PGOOD mask is activated for 130µs.
POWER SAVING MODE
The LM27213 allows for high efficiency operation at very low
power levels by employing a diode emulator mode. This can
be activated in either deep sleep or deeper sleep modes
only. Assert the DE_EN# pin while in a sleep mode to
activate this function. When operating at low power the
LM27213 detects inductor current reversal with a zero cross
detector connected to the drain of the low-side FET. The
voltage at this node is normally below ground when the low
side FET is on but will become positive when the inductor
current reverses. When the inductor current reversal is detected the low side switch is turned off and essentially be15
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LM27213
Applications Information
LM27213
Component Selection
This calculation assumes perfect capacitors (ESR = 0) and is
a reasonable assumption for an all ceramic solution only.
More capacitance will be required if aluminum-poly type
capacitors are used due to their higher ESR. However, that
will generally not be a problem since they tend to have large
capacitance values. If using 22 µF, 1206 case ceramic capacitors, this design would require approximately 44 capacitors distributed around the processor. Only capacitors with
either X5R or X7R dielectrics should be considered. Lower
cost devices have voltage and temperature coefficients that
make them unusable in these applications. Using a small
number of physically large ceramic capacitors is not recommended since the lead inductance will be excessive. They
tend not to provide adequate high frequency bypassing.
(Continued)
L = 0.60 µH
If the switching frequency is pushed up a bit the inductor
value may be reduced accordingly. In general for a 12A, low
voltage CPU, a value between 0.56 µH and 0.7 µH works out
well. The inductor chosen should be capable of handling the
full load current continuously. It must not hard saturate under
fault conditions. The saturation specifications for most inductors indicate when the inductance has fallen off by a given
percentage. This percentage will vary by manufacturer and
is not standardized. As such, it’s best to look at the published
curves of inductance vs. DC current. If the inductor maintains more than 1/3 of it’s specified no load inductance under
short circuit conditions, it will probably work just fine. There
will also most likely be an RMS current rating for the inductor
as well. This relates to the heating to be expected at the
rated DC current. In most processor applications it’s safe to
assume the average DC current for thermal analysis purposes will be approximately 80% of the specified maximum
load current. The inductor should be specified for at least this
value of continuous current.
A reasonable way to reduce the capacitor count is through
the addition of several aluminum-poly type capacitors. A
typical example may be the Panasonic SP series. A 330µF,
2.5V device is available with an ESR of only 5mΩ. Adding a
pair of these will permit reducing the number of ceramic
capacitors considerably.
A reasonable estimate of the soar voltage when the load is
suddenly reduced when using primarily alminum-poly type
capacitors can be obtained from the following equation:
OUTPUT CAPACITOR SELECTION
Once an inductor value is chosen it’s time to look at the
output capacitors. There are several possible basic approaches to take with regards to output de-coupling. It’s
possible to use ceramic capacitors exclusively. This will require a rather large number of small case size capacitors. It
is also possible to use primarily aluminum-polymer type
devices for the bulk decoupling with a relatively small number of ceramic capacitors for high frequency bypassing. The
third approach is something that’s more a combination of the
two approaches, using a moderate number of ceramic capacitor and a couple of large bulk caps. The design criteria
will be slightly different with the various approaches.
The controlling factor in a CPU core voltage regulator is
generally the load-off transient. When the processor load
drops dramatically, all the energy stored in the inductor will
get transferred into the output capacitors. The energy stored
in an inductor is L x I2/2 while the energy stored in a capacitor is C x V2/2. So:
Cmin = L(Imax2 - Imin2)/(Vmax2-Vinit2)
Where:
Cmin is the minimum capacitance required to meet the specified voltage limits.
L is the inductor value
Imax is the peak inductor current at the time the load step
occurs
Imin is the load current after the transient has settled
Vmax is the maximum allowed output voltage at the low load
condition
Vinit is the initial output voltage at the time of the load step
It’s recommended that the current used for Imax be equal to
the full load output current plus 1⁄2 the estimated pk-pk ripple
current
From the example being examined earlier, if we assume a
12A full load, a 0.56µH inductor, an initial voltage of 1.144V,
a minimum current of 3.5A and a maximum voltage of
1.197V, the minimum allowable output capacitance is calculated as:
Since ripple current is approximately 6A,
Imax = 12A + 3A = 15A
Cmin = 0.56µH(15A2 - 3.5A2)/1.197V2-1.144V2) = 960µF
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Where:
V(T) is the instantaneous capacitor voltage increase above
the initial DC voltage at the instant the load is reduced
C is output capacitance in µF.
Io is the inductor current at the instant the load is decreased
ESR is the output capacitor ESR
m is the inductor current down slope equal to Vout/L
The maxima occurs at :
Simply solve for Tmax and substitute into the equation for
V(T) to calculate the maximum output voltage rise. This
equation accounts for the decrease in voltage across the
ESR as the capacitors are being charged by the decreasing
inductor current.
Using numbers from the previous example:
Tmax = (12A-2.043A/µs*0.0025Ω*660µF)/2.043A/µs =
4.22µs
And Vmax = 0.058V
This is just a bit higher than the specification allows but does
not account for improvements expected as a result of having
a number of ceramic output capacitors on the board. The
performance of combinations of capacitors is best examined
using a circuit simulator as the mathematics gets unwieldy. A
simple model would be an inductor connected in parallel with
the output capacitors. Set the initial conditions for the peak
inductor current at full load and the capacitor voltage to the
lowest point on the load line. A current source in parallel with
the output that is set for the minimum load current will allow
the simulation of load steps that are less than 100% of full
load.
16
An Si7390 high-side switch and an Si7336 low-side switch
meet this requirement
If the same analysis is done assuming a 12A continuous load
current the results suggest a low-side FET with an onresistance of 2.7mΩ and a high-side FET on-resistance of
8.6mΩ.
(Continued)
A simulation of the above conditions with the addition of 10
pieces of a 22µF ceramic capacitor yields a peak excursion
of 1.180V, which is well within the specified limit.
MOSFET SELECTION
The choice of power FETs is driven primarily by efficiency or
thermal considerations. There are two main loss components to consider, conduction losses and switching losses.
The switching losses are primarily due to parasitics in the
FETs and are very hard to estimate with any degree of
accuracy. The conduction losses are much easier to characterize. The switching losses in the synchronous FET are very
low since it’s essentially a zero voltage switched device.
However, the high-side device’s switching losses are usually
comparable to its conduction losses. The primary contributor
to high-side FET switching losses is related to the reverse
recovery characteristics of the synchronous FET’s body diode. During the small dead band where both FETs are off
every cycle, the synchronous FET’s body diode will carry the
inductor current. Problems arise because the body diode
exhibits a significant reverse recovery time, trr. During this
time, the FET looks like a short circuit. When the high-side
FET is subsequently turned on, there is a shoot through path
from the input supply to ground. A larger high-side FET will
tend to exhibit a larger shoot through current. Therefore, it is
undesirable to oversize the high-side device. Since the synchronous FET looks like a short, the entire supply voltage is
impressed across the high-side device, along with a simultaneous high current. The result is very high momentary
power dissipation. The total power lost is a direct function of
the switching frequency.
For a single-phase design something on the order of 1W of
dissipation in the power switches is a reasonable place to
start. Assume further that this will be split equally between
the high and low side FETs. Since the low-side FET switches
at nearly zero volts the transition losses will be very low. The
high-side switch will, however, sustain large switching
losses. In all likelihood they will be comparable to, or exceed,
the conduction losses.
GATE DRIVE REQUIREMENTS
The bootstrap capacitor choice is based largely on the gate
charge requirements of the high-side FET. The charge
stored on the bootstrap cap should be about 20X the highside FET’s gate charge. For the Si7390 the specified gate
charge is 15nC max. So the bootstrap capacitor should store
a minimum of 300nC at 5V. This translates to a capacitance
of 0.06µF or larger. A 0.10µF or larger X5R dielectric capacitor would be a good choice. Under sizing the bootstrap
capacitor will result in inadequate gate drive to the high-side
switch.
INPUT CAPACITOR SELECTION
The input capacitor selection is based largely on ripple current capability. The instantaneous pulse currents drawn by
the power supply must be deliv-ered by the input capacitors.
This is related to the fact that the input power source, be it a
battery pack or a wall adapter, will place a substantial impedance in series with the input path. As such, their ability to
deliver large, fast rise time current pulses is limited. The
input capacitors need to average these pulse currents and
smooth the current demand placed on the source.
Ceramic capacitors offer a good combination of ripple current capability and voltage rating, however they tend to do so
with relatively low capacitance values. It’s also not uncommon to find wall adapters and batteries with impedances on
the order of several hundred milliohms. The result is that
while cycle-by-cycle current demand may be met, the input
capacitor network cannot deliver enough energy to prevent
significant amounts of voltage ripple when the load current is
varied at a low rate. In particular, if the load varies at a
frequency in the 2kHz to 4kHz range, the resulting large
variation in voltage observed at the power supply input will
result in noticeable audio noise being produced by the piezo
electric effects that are characteristic of ceramic capacitors.
There are several ways to mitigate this problem. The first is
to use physically small ceramic capacitors since they tend to
be less efficient noise generators. That, however, would tend
to limit the amount of capacitance to an unacceptably low
value. The use of aluminum-poly type capacitors such as
Sanyo’s Poscap series is a viable option as well. They can
provide adequate levels of capacitance with very good ripple
current capability. The down side of this solution is cost.
Another possible approach is to use relatively large ceramic
capacitors and add a relatively large aluminum electrolytic
capacitor to hold up the supply voltage. The ceramics deliver
the high frequency pulse currents while the bulk caps
smooth the longer term variation. In general a few hundred
microfarads is adequate for this purpose. As long as the AC
ripple voltage impressed on the ceramic capacitors is small,
on the order of a few tenths of a volt, the ceramic capacitors
are not going to be excessively noisy.
For purposes of sizing the high frequency input decoupling,
the RMS input ripple current must be estimated. The input
ripple current will be approximately 50% of the output current
at a 50% duty factor and decrease as duty factor drops.
Figure 5 shows this relationship.
With 500mΩ allocated to the synchronous switch dissipation
we can calculate the required on-resistance. Assume the hot
on-resistance will be about 140% of the room temp Rds(on).
Therefore:
Rds(on) = Pdiss/(I2 x 1.4 x (1-DF))
Where: DF = duty factor or Vout/Vin
Pdiss = allowed dissipation
And I is the design thermal current
As a general rule of thumb, assume the design thermal
current is approximately 80% of full load current unless the
specification indicates otherwise. In this case, assume a
current of 9.6A. Also, duty factor should be calculated at high
input line voltage. Assume 16V for our example. So the
maximum on-resistance for the synchronous switch will be:
Rds(on) = 0.5W/(9.6A2 x 1.4 x (1-1.15V/16V))
Rds(on) = 4.2mΩ
In a similar fashion the high-side switch can be sized. Allot 1⁄2
of the total dissipation to switching losses. The on interval is
now DF rather than 1-DF and low input line is assumed:
Rds(on) = Pdiss/(I2 x 1.4 x (DF))
Rds(on) = 0.25W/(9.6A2 x 1.4 x 1.15V/8V)
Rds(on) = 13.4mΩ
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LM27213
Component Selection
LM27213
Component Selection
shoot for is approximately 500ns. So for R2 = 100Ω, something around a 4700pF capacitor should prove helpful. If this
capacitor is made too large the result will be large overshoot
and undershoot in the response to load transients. See the
section below on load line setting for more information about
choosing these resistors.
(Continued)
Load Line Setting Resistors
Resistors R1, R2, and the current sense resistor (see Figure
2) are used to control the slope of the load line. In the
simplest configuration R1 = 0 ohms and R2 is omitted. In this
case the load line is nominally equal to the current sense
resistor value. For relatively low current designs this configuration can work acceptably well. At higher current levels the
DC drop across the power planes may well contribute an
excessive error since the distribution path between the
sense resistor and the load is effectively in series with the
current sense resistor, and therefore, will steepen the load
line. For designs with relatively steep load lines (3 mΩ) the
power dissipation is also excessive at high currents. The
solution is to lower the sense resistor value and add the R1,
R2 divider to synthesize a steeper slope. The load line is
calculated from:
LL = Rs x (1+R1/R2)
Since the power plane resistance will increase the load line
by an amount that’s nearly impossible to estimate accurately,
the simplest approach is to install the values calculated for
the ideal, lossless power path, and run the circuit. Record
the no load and full load output voltage and calculate the
load line impedance.
LL = (V0 – Vfull)/Ifull
Where:
V0 is the no load output voltage
Vfull is the full load output voltage
20154327
FIGURE 4. RMS Input Ripple Current as a Percentage
of DC Output Current
So for a design that must operate at a steady state load
current of 12A, with 1.4V out and 8V in, the RMS input ripple
current would be about 37% of 12A or 4.4A RMS. A sufficient
number of capacitors must be connected in parallel to
handle this current. For capacitors rated at 1.5A each, a
minimum of 3 would be required. If it’s desired to add enough
bulk capacitance to control the input’s low frequency ripple
voltage, the characteristic impedance of the input power
source must be well understood.
Bypassing Considerations
The LM27213 should have its supply pin (24) well bypassed.
Generally a 1µF capacitor connected between the Vdd pin
and the SGND pin (23), should be adequate. It’s a good idea
to add a resistor of about 10Ω in series with the input source
to provide some decoupling from noise on the 5V rail. The
LM27213’s own gate drive pulse currents can corrupt the 5V
rail enough to cause problems without this filter. There also
needs to be a 1µF or larger ceramic capacitor connected
between the driver supply pin PVDD (48) and PGND (45).
The bypass capacitors should be located very close to the
pins to provide a low inductance path. This is particularly
important for the PVDD bypass. This capacitor must supply
all of the low-side gate drive pulse currents as well as the
charging current for the high-side bootstrap capacitor. It’s
also a good idea to install a 0.1µF capacitor between the
VREF pin (11) and SGND. In addition, there should be small
filter capacitors connected between the ILIM and ILIMREF
pins and the CMP and CMPREF pins. Typically, a 1200pF
capacitor will prove adequate for this purpose.
And Ifull is the full load current
Use this information along with the installed values of R1 and
R2 to calculate the effective sense resistor value:
Rse = LL/(1+R1/R2)
Now using this value of sense resistor, recalculate a new
value for R1:
R1 = R2(LL/Rse –1)
Installing these values for R1 and R2 should yield a nearly
perfect load line.
Layout Guidelines
As is true for any high-current power supply design, care
needs to be taken when doing an LM27213 layout. As a
general rule, it makes the most sense to start the layout by
placing the power path components to connect in a logical
power flow. The input ceramic capacitors should be connected as close as physically possible to the source of the
low side FET and the drain of the high-side FET. The loop
area enclosed by the input capacitors and FETs needs to be
minimized to control ringing and optimize the switch rise and
fall times. A good practice is to connect the FETs on the top
side of the board with the bypass capacitors located immediately below on the back side. The capacitors’ ground pads
should be located directly beneath the low-side FET’s source
pad and a collection of vias used to hook the two together
and at the same time tie to the internal ground plane. Figure
on allowing one amp of load current per via if the hole
diameter is less than 15 mils and two Amps per via if greater
than 20 mils. More vias are almost always better than fewer.
Current Sense Resistor
The maximum value allowed for the current sense resistor is
a value equal to the desired load line slope. Increasing
beyond this value will make the load line excessively steep
with no way to reduce the slope. Lower values are permissible and values as low as 1mΩ have been used successfully. The regulator will have a tendency to exhibit excessive
amounts of pulse jitter if the sense resistor is too small since
the current sense signal is reduced as well. One way to
mitigate this problem is to add a little filtering to the load line
setting resistor R2 in Figure 3. A typical time constant to
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18
a separate via close to PGND or directly to the PGND pin
with a very short trace. One grounding option is to define a
signal ground plane that connects to ground through this
point only and resides under and around the IC. An alternative is to daisy chain a ground trace around the controller to
pick up all the signal ground referenced components while
maintaining only a single connection to the ground plane at
the SGND pin. If doing the later and not defining signal
ground as a separate net, it will not be possible to use vias to
connect to other layers unless your board layout package
has the ability to isolate these vias from the ground plane.
Keeping the signal ground separate from the system ground
plane ensures that signal ground is “quiet” relative to all
internal signals in the controller. The main ground plane is
usually a very noisy environment and not the absolute zero
volt reference it tends to be thought of. Pains should be
taken at every opportunity to ensure that sources of large
pulse currents into the ground plane are bypassed as well as
possible to minimize the disturbances to the ground plane.
Under no circumstances should the controller be grounded
at a point between the low-side FET source connection and
the input capacitor ground connection point. This is a very
noisy area.
Pin 5, SRCK, is the low-side FET source Kelvin connection
and as the name implies needs to be connected directly to
the low side FET source pads. This pin is used as the
reference potential for the diode emulator circuit. If not connected correctly, the supply will behave erratically at light
loads. The correct connection for SRCK is to tie the pin to
one of the vias connecting the low-side FET source to the
internal ground plane on an internal layer or the back side of
the board. The trace need not be wide. A 10mil trace is
adequate, as this line carries essentially no current.
(Continued)
Keep the switch node connection between the two FETs and
the inductor as short and wide as possible. The inductor
should be located very close to the FETs. The inductor
should then flow in to the sense resistor that needs to be
immediately adjacent to the processor decoupling capacitors.
The LM27213 needs to be located relatively close to the
FETs to minimize the gate drive lengths. Also, route the
high-side gate signal (pin 2) and the SW pin (3) parallel to
and very close to each other to minimize the inductance of
the loop enclosed. These traces should be at least 15 mils
wide. The connections to the current sense resistor must be
made as Kelvin connections. Again, route these two traces in
parallel if possible to minimize noise susceptibility. The
sense pin (16) is best connected to the core voltage near the
center of the CPU socket, but will in all likelihood work
correctly if connected at the bypass capacitors located
around the periphery of the CPU socket. This line is the
source of output voltage information for the over voltage
protection circuit and power good comparators.
Probably the most critical consideration for the controller is
grounding. There are several ground-referenced pins that
need to be treated quite differently. A good practice is to tie
the power ground pin (45) to the main power plane with a
single via. This pin is the ground connection for the gate
drive and as such will carry very large pulse currents. The
bypass capacitor for DVDD should connect very close to this
ground connection if at all possible. DGND (13) is not particularly critical and should tie to the main ground plane as
well. It only carries the return currents for the digital portions
of the controller, which are not very large. The SGND pin
(23) is the most critical and should also tie to the plane with
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LM27213
Layout Guidelines
LM27213
Layout Guidelines
(Continued)
20154328
The circuit above is an example of a single phase supply at
much higher current. The FETs chosen lend themselves well
to the use of a heatsink if desired. The transient response is
quite good for a single phase below, high current design as
seen from the scope photo below.
20154329
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20
LM27213
Physical Dimensions
inches (millimeters) unless otherwise noted
48-Lead TSSOP Package
Order Number LM27213MTD
NS Package Number MTD48
48-Lead LLP Package
Order Number LM27213SQ
NS Package Number SQA48A
21
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LM27213 Single Phase Hysteretic Buck Controller
Notes
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves
the right at any time without notice to change said circuitry and specifications.
For the most current product information visit us at www.national.com.
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