IRF IR3082M

Data Sheet No. PD94710
IR3082
XPHASETM AMD OPTERONTM/ATHLON 64TM CONTROL IC
DESCRIPTION
The IR3082 Control IC combined with an IR XPhaseTM Phase IC provides a full featured and flexible way
to implement a complete Opteron or Athlon64 power solution. The “Control” IC provides overall system
control and interfaces with any number of “Phase ICs” which each drive and monitor a single phase of a
multiphase converter. With simple 5 bit voltage programming and a few external components, the IR3082
is also well suited for general purpose multiphase applications. The XPhaseTM architecture results in a
power supply that is smaller, less expensive, and easier to design while providing higher efficiency than
conventional approaches.
FEATURES
•
•
•
•
•
•
•
•
•
•
•
5 bit VID with 1% overall system set point accuracy
Programmable Dynamic VID Slew Rate
+/-300mV Differential Remote Sense
Programmable 150kHz to 1MHz oscillator
Programmable VID Offset and Load Line output impedance
Programmable Softstart
Programmable Hiccup Over-Current Protection with Delay to prevent false triggering
Simplified Power Good output provides indication of proper operation and avoids false triggering
Operates from 12V input with 9.75V Under-Voltage Lockout
7.0V/5mA Bias Regulator provides System Reference Voltage
Small thermally enhanced 20L MLPQ package
APPLICATION CIRCUIT
POWER GOOD
12V
10
0.1uF
L
E
D
/
S
S
C
ENABLE
9
1
0
2
VID0
1
VID1
2
VID2
3
VID3
4
VID4
5
E
L
B
A
N
VID0 E
7
1
L
E
D
/
S
S
T
U
O
P
M
R
6
1
D
N
G
L
IR3082
CONTROL
IC
VID1
VID2
VID3
VID4
8
1
D
G
R
W
P
S
N
S
O
V
6
EAOUT
FB
VDRP
C
S
O
R
7
C
S
O
R
VCC
VBIAS
C
A
D
V
8
T
E
S
C
O
9
N
II
15
0.1uF
14
5 Wire Analog Bus
(to PHASE ICs)
13
12
11
RVDRP
0
1
ROCSET
RVDAC
RVFB
VCC SENSE
CVDAC
VSS SENSE
Page 1 of 1
12/17/04
IR3082
ORDERING INFORAMATION
Device
Order Quantity
IR3082MTR
3000 per reel
* IR3082M
100 piece strips
* Samples only
ABSOLUTE MAXIMUM RATINGS
Operating Junction Temperature……………..150oC
Storage Temperature Range………………….-65oC to 150oC
ESD Rating………………………………………HBM Class 1C JEDEC standard
PIN #
PIN NAME
VMAX
VMIN
ISOURCE
ISINK
1-5
6
7
8
9
10
VID0-4
VOSNSROSC
VDAC
OCSET
IIN
20V
0.5V
20V
20V
20V
20V
-0.3V
-0.5V
-0.5V
-0.3V
-0.3V
-0.3V
1mA
10mA
1mA
1mA
1mA
1mA
1mA
10mA
1mA
1mA
1mA
1mA
11
12
13
VDRP
FB
EAOUT
20V
20V
10V
-0.3V
-0.3V
-0.3V
5mA
1mA
20mA
5mA
1mA
20mA
14
VBIAS
20V
-0.3V
50mA
10mA
15
VCC
20V
-0.3V
1mA
50mA
16
LGND
n/a
n/a
50mA
1mA
17
RMPOUT
20v
-0.3V
1mA
1mA
18
SS/DEL
20V
-0.3V
1mA
1mA
19
PWRGD
20V
-0.3V
1mA
20mA
20
ENABLE
20V
-0.3V
1mA
1mA
Page 2 of 2
12/17/04
IR3082
ELECTRICAL SPECIFICATIONS
Unless otherwise specified, these specifications apply over: 9.6V ≤ VCC ≤ 16V, -0.3V ≤ VOSNS- ≤ 0.3V,
0 oC ≤ TJ ≤ 100 oC, ROSC = 24KΩ, CSS/DEL = 0.1µF +/-10%
PARAMETER
VDAC Reference
System Set-Point Accuracy
(Deviation from Table 1 per
test circuit in Figure 1 which
emulates in-VR operation)
Source Current
Sink Current
VIDx Input Threshold
VIDx Input Bias Current
VIDx 11111 Blanking Delay
Error Amplifier
Input Offset Voltage
FB Bias Current
DC Gain
Gain Bandwidth Product
Corner Frequency
Slew Rate
Source Current
Sink Current
Max Voltage
Min Voltage
VDRP Buffer Amplifier
Input Offset Voltage
Source Current
Sink Current
Bandwidth
Slew Rate
IIN Bias Current
VBIAS Regulator
Output Voltage
Current Limit
Enable Input
Threshold Voltage
Threshold Voltage
Threshold Hysteresis
Bias Current
Page 3 of 3
TEST CONDITION
MIN
10KΩ ≤ ROSC ≤ 91KΩ, RFB selected to
provide 50mV VID offset
-1
Includes OCSET current
0V ≤ VID0-4 ≤ VCC
Measure Time till PWRGD drives low
Measure V(FB) – V(VDAC) with EAOUT
tied to FB. Applies to all VID codes.
Note 2.
Note 1
Note 1
45 deg Phase Shift, Note 1
Note 1
VBIAS–VEAOUT (referenced to VBIAS)
Normal operation or Fault mode
V(VDRP) – V(IIN), 0.5V ≤ V(IIN) ≤ 5V
0.5V ≤ V(IIN) ≤ 5V
0.5V ≤ V(IIN) ≤ 5V
Note 1
Note 1
-5mA≤ I(VBIAS) ≤ 0
ENABLE rising
ENABLE falling
0V ≤ V(ENABLE) ≤ VCC
TYP
MAX
UNIT
1
%
101
92
1.04
-5
0.5
110
100
1.24
0
0.7
119
108
1.44
5
1
µA
µA
V
µA
µs
-5
1.5
6
mV
-53.5
90
6
-51
100
10
400
3.2
0.7
0.9
375
125
-48.5
110
µA
dB
MHz
Hz
V/µs
mA
mA
mV
mV
6
5.0
4.1
-2
-1
3.0
1.4
6
10
-0.3
0.4
mV
mA
mA
MHz
V/µs
µA
6.6
-35
7.0
-20
7.4
-6
V
mA
1.15
1.08
40
-5
1.27
1.205
65
0
1.39
1.31
90
5
V
V
mV
µA
1.4
0.4
0.5
250
30
-10
1.2
0.2
1
5
1
1.4
525
200
12/17/04
IR3082
PARAMETER
Soft Start and Delay
Start Delay (See Fig 10)
Soft Start Time (See Fig 10)
PWRGD Delay (See Fig 10)
OC Delay Time
SS/DEL to FB Input Offset
Voltage
Charge Current
Discharge Current
Charge/Discharge Current
Ratio
OC Discharge Current
Charge Voltage
Delay Comparator Threshold
Delay Comparator Threshold
Delay Comparator Hysteresis
Discharge Comparator
Threshold
Over-Current Comparator
Input Offset Voltage
OCSET Bias Current
PWRGD Output
Output Voltage
Leakage Current
Oscillator
Switching Frequency
Peak Voltage (5V typical,
measured as % of VBIAS)
Valley Voltage (1V typical,
measured as % of VBIAS)
VCC Under-Voltage Lockout
Start Threshold
Stop Threshold
Hysteresis
General
VCC Supply Current
VOSNS- Current
TEST CONDITION
MIN
TYP
MAX
UNIT
1.2
0.85
1.0
150
0.95
1.9
1.95
2.0
250
1.3
2.6
3.0
3.0
350
1.6
ms
ms
ms
us
V
40
4
9.5
66
6
11
100
9
12.5
µA
µA
µA/µA
20
3.65
50
40
3.9
70
60
4.15
90
µA
V
mV
85
115
145
mV
15
175
35
225
50
275
mV
mV
-10
-54
0
-51.5
10
-49
mV
µA
150
0
300
10
mV
µA
450
70
500
71
550
74
kHz
%
10
13
15
%
Start – Stop
9.0
8.4
550
9.75
9.0
750
10.4
9.6
1150
V
V
mV
-0.3V ≤ VOSNS- ≤ 0.3V, All VID Codes
8
-4.5
10
-3.5
12.5
-2.5
mA
mA
VID = 1.3V (VID4-0 = 01010)
VID = 1.3V (VID4-0 = 01010)
With FB = 0V, adjust V(SS/DEL) until
EAOUT drives high
Note 1
Relative to Charge Voltage, SS/DEL
rising
Relative to Charge Voltage, SS/DEL
falling
1V ≤ V(OCSET) ≤ 5V
I(PWRGD) = 4mA
V(PWRGD) = 5.5V
Note 1: Guaranteed by design, but not tested in production
Note 2: VDAC Output is trimmed to compensate for Error Amp input offsets errors
Page 4 of 4
12/17/04
IR3082
IR3082
EAOUT
+
-
ERROR
AMP
FB
RFB
OCSET
+
+
ISOURCE
"FAST"
VDAC
-
VDAC
ISINK
VDAC
BUFFER
AMP
IOFFSET IROSC
CURRENT
SOURCE
GENERATOR
IROSC IOCSET
RVDAC
SYSTEM
SET POINT
VOLTAGE
CVDAC
ROSC
BUFFER
AMP
+
ROSC
-
+
ROSC
1.2V
VOSNS-
Figure 1 – System Set Point Test Circuit
PIN DESCRIPTION
PIN#
1-5
6
7
PIN SYMBOL
VID4-0
VOSNSROSC
8
VDAC
9
OCSET
10
IIN
11
VDRP
12
FB
13
14
EAOUT
VBIAS
15
16
17
18
VCC
LGND
RMPOUT
SS/DEL
19
PWRGD
20
ENABLE
Page 5 of 5
PIN DESCRIPTION
Inputs to VID D to A Converter.
Remote Sense Input. Connect to ground at the Load.
Connect a resistor to VOSNS- to program oscillator frequency and OCSET, FB, and
VDAC bias currents.
Regulated voltage programmed by the VID inputs. Connect an external RC network
to VOSNS- to program Dynamic VID slew rate and provide compensation for the
internal Buffer Amplifier.
Programs the hiccup over-current threshold through an external resistor tied to
VDAC and an internal current source. Over-current protection can be disabled by
connecting a resistor from this pin to VDAC to program the threshold higher than the
possible signal into the IIN pin from the Phase ICs but no greater than 5V (do not
float this pin as improper operation will occur).
Current Sense input from the Phase IC(s). If current feedback from the Phase ICs is
not required for implementing droop or over-current protection connect to the LGND
pin. To ensure proper operation do not float this pin.
Buffered IIN signal. Connect an external RC network to FB to program converter
output impedance.
Inverting input to the Error Amplifier. Converter output voltage is offset from the
VDAC voltage through an external resistor connected to the converter output voltage
at the load and an internal current source.
Output of the Error Amplifier.
6.8V/5mA Regulated output used as a system reference voltage for internal circuitry
and the Phase ICs.
Power Input for internal circuitry.
Local Ground for internal circuitry and IC substrate connection.
Oscillator Output voltage. Used by Phase ICs to program Phase Delay
Controls Converter Start-up and Over-Current Timing. Connect an external capacitor
to LGND to program.
Open Collector output that drives low during Start-Up and any external fault
condition. Connect external pull-up.
Enable Input. A logic low applied to this pin puts the IC into Fault mode. Do not float
this pin as the logic state will be undefined.
12/17/04
IR3082
SYSTEM THEORY OF OPERATION
XPhaseTM Architecture
The XPhaseTM architecture is designed for multiphase interleaved buck converters which are used in applications
requiring small size, design flexibility, low voltage, high current, and fast transient response. The architecture can
be used in any multiphase converter ranging from 1 to 16 or more phases where flexibility facilitates the design
trade-off of multiphase converters. The scalable architecture can be applied to other applications which require
high current or multiple output voltages.
As shown in Figure 2, the XPhaseTM architecture consists of a Control IC and a scalable array of phase converters
each using a single Phase IC. The Control IC communicates with the Phase ICs through a 5-wire analog bus, i.e.
bias voltage, phase timing, average current, error amplifier output, and VID voltage. The Control IC incorporates all
the system functions, i.e. VID, PWM ramp oscillator, error amplifier, bias voltage, and fault protections etc. The
Phase IC implements the functions required by the converter of each phase, i.e. the gate drivers, PWM comparator
and latch, over-voltage protection, and current sensing and sharing.
There is no unused or redundant silicon with the XPhaseTM architecture compared to others such as a 4 phase
controller that can be configured for 2, 3, or 4 phase operation. PCB Layout is easier since the 5 wire bus
eliminates the need for point-to-point wiring between the Control IC and each Phase. The critical gate drive and
current sense connections are short and local to the Phase ICs. This improves the PCB layout by lowering the
parasitic inductance of the gate drive circuits and reducing the noise of the current sense signal.
POWER GOOD
VR HOT
PHASE FAULT
12V
ENABLE
VID0
VID1
IR3082
CONTROL
IC
CIN
+SEN
>> BIAS VOLTAGE
>> PHASE TIMING
VID2
<< CURRENT SENSE
VID3
>> PWM CONTROL
VID4
>> VID VOLTAGE
CURRENT SHARE
VDD_CORE
IR3086
PHASE
IC
COUT
GND
CURRENT SHARE
CCS
RCS
CCS
RCS
-SEN
IR3086
PHASE
IC
ADDITIONAL PHASES
CONTROL BUS
INPUT/OUTPUT
Figure 2 – System Block Diagram
Page 6 of 6
12/17/04
IR3082
PWM Control Method
The PWM block diagram of the XPhaseTM architecture is shown in Figure 3. Feed-forward voltage mode control with
trailing edge modulation is used. A high-gain wide-bandwidth voltage type error amplifier in the Control IC is used
for the voltage control loop. An external RC circuit connected to the input voltage and ground is used to program the
slope of the PWM ramp and to provide the feed-forward control at each phase. The PWM ramp slope will change
with the input voltage and automatically compensate for changes in the input voltage. The input voltage can change
due to variations in the silver box output voltage or due to drops in the PCB related to changes in load current.
VIN
CONTROL IC
PHASE IC
SYSTEM
REFERENCE
VOLTAGE
BIASIN
50%
DUTY
CYCLE
RAMP GENERATOR
VPEAK
RMPOUT
RAMPIN+
RPHS1
VVALLEY
RAMPIN-
PWM
LATCH
CLOCK
PULSE
GENERATOR
+
-
+
RPWMRMP
PWMRMP
VOSNS-
-
CPWMRMP
+
VDAC
-
GATEL
+
RAMP
DISCHARGE
CLAMP
SCOMP
BODY
BRAKING
COMPARATOR
VOSNS-
+
+
SHARE
ADJUST
ERROR
AMP
CSCOMP
-
RVFB
+
-
X 0.9
+
ISHARE
FB
CURRENT
SENSE
AMPLIFIER
20mV
10K
-
CSIN+
+
IFB
+
IROSC
RDRP
VDRP
AMP
GND
ENABLE
RAMP
SLOPE
ADJUST
EAOUT
ERROR
AMP
VOUT
R
+
RPHS2
VDAC
VBIAS
REGULATOR
VOSNS+
RESET
DOMINANT
COUT
-
EAIN
VBIAS
GATEH
S
PWM
COMPARATOR
X34
+
-
CCS
RCS
CCS
RCS
CSIN-
DACIN
VDRP
+
-
IIN
PHASE IC
SYSTEM
REFERENCE
VOLTAGE
BIASIN
RAMPIN+
+
RPHS1
RAMPIN-
-
PWM
LATCH
CLOCK
PULSE
GENERATOR
-
EAIN
GATEH
S
PWM
COMPARATOR
RESET
DOMINANT
R
GATEL
+
RPHS2
PWMRMP
RPWMRMP
ENABLE
RAMP
SLOPE
ADJUST
+
RAMP
DISCHARGE
CLAMP
SCOMP
CPWMRMP
CSCOMP
SHARE
ADJUST
ERROR
AMP
BODY
BRAKING
COMPARATOR
+
+
+
ISHARE
CURRENT
SENSE
AMPLIFIER
20mV
10K
-
X 0.9
-
CSIN+
+
+
+
X34
-
CSIN-
DACIN
Figure 3 – IR3082 PWM Block Diagram
Frequency and Phase Timing Control
The oscillator is located in the Control IC and its frequency is programmable from 150kHz to 1MHZ by an external
resistor. The output of the oscillator is a 50% duty cycle triangle waveform with peak and valley voltages of
approximately 5V and 1V. This signal is used to program both the switching frequency and phase timing of the
Phase ICs. The Phase IC is programmed by resistor divider RRAMP1 and RRAMP2 connected between the VBIAS
reference voltage and the Phase IC LGND pin. A comparator in the Phase ICs detects the crossing of the oscillator
waveform with the voltage generated by the resistor divider and triggers a clock pulse that starts the PWM cycle.
The peak and valley voltages track the VBIAS voltage reducing potential Phase IC timing errors. Figure 4 shows the
Phase timing for an 8 phase converter. Note that both slopes of the triangle waveform can be used for
synchronization by swapping the RAMP+ and RAMP- pins, as shown in Figure 3.
Page 7 of 7
12/17/04
IR3082
50% RAMP
DUTY CYCLE
SLOPE = 80mV / % DC
VPEAK (5.0V)
)
MC
OI
R
F
(L
O
R
PT
MN
AO
RC
VPHASE4&5 (4.5V)
SLOPE = 1.6mV / ns @ 200kHz
SLOPE = 8.0mV / ns @ 1MHz
VPHASE3&6 (3.5V)
VPHASE2&7 (2.5V)
VPHASE1&8 (1.5V)
VVALLEY (1.00V)
CLK1
CLK2
S
E
S
L
U
P
K
C
O
L
C
C
I
E
S
A
H
P
CLK3
CLK4
CLK5
CLK6
CLK7
CLK8
Figure 4 – 8 Phase Oscillator Waveforms
PWM Operation
The PWM comparator is located in the Phase IC. Upon receiving a clock pulse, the PWM latch is set, the PWMRMP
voltage begins to increase, the low side driver is turned off, and the high side driver is then turned on. When the
PWMRMP voltage exceeds the Error Amp’s output voltage the PWM latch is reset. This turns off the high side
driver, turns on the low side driver, and activates the Ramp Discharge Clamp. The clamp quickly discharges the
PWMRMP capacitor to the VDAC voltage of the Control IC until the next clock pulse.
The PWM latch is reset dominant allowing all phases to go to zero duty cycle within a few tens of nanoseconds in
response to a load step decrease. Phases can overlap and go to 100% duty cycle in response to a load step
increase with turn-on gated by the clock pulses. An Error Amp output voltage greater than the common mode input
range of the PWM comparator results in 100% duty cycle regardless of the voltage of the PWM ramp. This
arrangement guarantees the Error Amp is always in control and can demand 0 to 100% duty cycle as required. It
also favors response to a load step decrease which is appropriate given the low output to input voltage ratio of most
systems. The inductor current will increase much more rapidly than decrease in response to load transients.
This control method is designed to provide “single cycle transient response” where the inductor current changes in
response to load transients within a single switching cycle maximizing the effectiveness of the power train and
minimizing the output capacitor requirements. An additional advantage is that differences in ground or input voltage
at the phases have no effect on operation since the PWM ramps are referenced to VDAC.
Page 8 of 8
12/17/04
IR3082
Body BrakingTM
In a conventional synchronous buck converter, the minimum time required to reduce the current in the inductor in
response to a load step decrease is;
L ⋅ ( I MAX − I MIN )
TSLEW =
VO
The slew rate of the inductor current can be significantly increased by turning off the synchronous rectifier in
response to a load step decrease. The switch node voltage is then forced to decrease until conduction of the
synchronous rectifier’s body diode occurs. This increases the voltage across the inductor from Vout to Vout + VBODY
DIODE. The minimum time required to reduce the current in the inductor in response to a load transient decrease is
now;
L ⋅ ( I MAX − I MIN )
TSLEW =
VO + VBODYDIODE
Since the voltage drop in the body diode is often higher than output voltage, the inductor current slew rate can be
increased by 2X or more. This patent pending technique is referred to as “Body Braking” and is accomplished
through the “Body Braking Comparator” located in the Phase IC. If the Error Amp’s output voltage drops below 91%
of the VDAC voltage this comparator turns off the low side gate driver.
Figure 5 depicts PWM operating waveforms under various conditions.
PHASE IC
CLOCK
PULSE
EAIN
PWMRMP
VDAC
91% VDAC
GATEH
GATEL
STEADY-STATE
OPERATION
DUTY CYCLE INCREASE
DUE TO LOAD
INCREASE
DUTY CYCLE DECREASE
DUE TO VIN INCREASE
(FEED-FORWARD)
DUTY CYCLE DECREASE DUE TO LOAD
DECREASE (BODY BRAKING) OR FAULT
(VCC UV, OCP, VID=11111)
STEADY-STATE
OPERATION
Figure 5 – PWM Operating Waveforms
Lossless Average Inductor Current Sensing
Inductor current can be sensed by connecting a series resistor and a capacitor network in parallel with the inductor
and measuring the voltage across the capacitor. The equation of the sensing network is,
vC ( s ) = vL ( s )
1
RL + sL
= iL ( s )
1 + sRCS CCS
1 + sRCS CCS
Usually the resistor Rcs and capacitor Ccs are chosen so that the time constant of Rcs and Ccs equals the time
constant of the inductor which is the inductance L over the inductor DCR (RL). If the two time constants match, the
voltage across Ccs is proportional to the current through L, and the sense circuit can be treated as if only a sense
resistor with the value of RL was used. The mismatch of the time constants does not affect the measurement of
inductor DC current, but affects the AC component of the inductor current.
Page 9 of 9
12/17/04
IR3082
The advantage of sensing the inductor current versus high side or low side sensing is that actual output current
being delivered to the load is obtained rather than peak or sampled information about the switch currents. The
output voltage can be positioned to meet a load line based on real time information. Except for a sense resistor in
series with the inductor, this is the only sense method that can support a single cycle transient response. Other
methods provide no information during either load increase (low side sensing) or load decrease (high side sensing).
An additional problem associated with peak or valley current mode control for voltage positioning is that they suffer
from peak-to-average errors. These errors will show in many ways but one example is the effect of frequency
variation. If the frequency of a particular unit is 10% low, the peak to peak inductor current will be 10% larger and
the output impedance of the converter will drop by about 10%. Variations in inductance, current sense amplifier
bandwidth, PWM prop delay, any added slope compensation, input voltage, and output voltage are all additional
sources of peak-to-average errors.
Current Sense Amplifier
A high speed differential current sense amplifier is located in the Phase IC, as shown in figure 6. Its gain decreases
with increasing temperature and is nominally 34 at 25ºC and 29 at 125ºC (-1470 ppm/ºC). This reduction of gain
tends to compensate the 3850 ppm/ºC increase in inductor DCR. Since in most designs the Phase IC junction is
hotter than the inductor these two effects tend to cancel such that no additional temperature compensation of the
load line is required.
The current sense amplifier can accept positive differential input up to 100mV and negative up to -20mV before
clipping. The output of the current sense amplifier is summed with the DAC voltage and sent to the Control IC and
other Phases through an on-chip 10KΩ resistor connected to the ISHARE pin. The ISHARE pins of all the phases
are tied together and the voltage on the share bus represents the total current through all the inductors and is used
by the Control IC for voltage positioning and current limit protection.
L
RL
Rcs
Ccs
Co
CSOUT
+
CS AM P
-
Figure 6 – Inductor Current Sensing and Current Sense Amplifier
Average Current Share Loop
Current sharing between phases of the converter is achieved by the average current share loop in each Phase IC.
The output of the current sense amplifier is compared with the share bus less a 20mV offset. If current in a phase is
smaller than the average current, the share adjust amplifier of the phase will activate a current source that reduces
the slope of its PWM ramp thereby increasing its duty cycle and output current. The crossover frequency of the
current share loop can be programmed with a capacitor at the SCOMP pin so that the share loop does not interact
with the output voltage loop.
Page 10 of 10
12/17/04
IR3082
IR3082 THEORY OF OPERATION
Block Diagram
The Block diagram of the IR3082 is shown in figure 7 and discussed in the following sections.
VCC
FAULT
LATCH
-
+
+
VCC
UVLO
COMPARATOR
9.75V
9.0V
0.225V
-
ENABLE
-
ENABLE
COMPARATOR
-
DISCHARGE
COMPARATOR
+
R
E
V
O
+
PWRGD
S
T
N
E
R
R
U
C
T
N
A
N
I
T M
E O
S D
R
+
70mV
115mV
+
+
+
-
-
ON
OC
DISCHG
CURRENT
40uA
ON
IHICCUP
IDISCHG
6uA
-
OFF
ICHG
66uA
SS/DEL
VID INPUT
COMPARATORS
(1 OF 5
SHOWN)
VID2
VID1
+
+
-
+
50%
DUTY
CYCLE
+
+
-
SOFTSTART
CLAMP
EAOUT
ERROR
AMP
FB
IFB
LGND
"FAST"
VDAC
+
ISOURCE
VDAC
-
ISINK
-
-
RMPOUT
OCSET
-
IROSC
1.24V
VOSNS-
IIN
+
IOCSETIROSC
VID0
VDRP
AMP
DISABLE
DIGITAL TO
ANALOG
CONVERTER
+
VDRP
+
OC
COMPARATOR
1.3V
-
VID3
700ns
BLANKING
SS/DEL
DISCHARGE
+
VID4
F
F
O
=
D
I
V
+
-
VCHG
3.9V
1.270V
1.205V
-
DELAY
COMPARATOR
RAMP GENERATOR
5.0V
VDAC
BUFFER
AMP
IROSC
VBIAS
VBIAS
REGULATOR
+
VBIAS
1.0V
+
7.0V
-
ROSC
BUFFER
AMP
+
CURRENT
SOURCE
GENERATOR
-
ROSC
Figure 7 – IR3082 Block Diagram
VID Control
A 5-bit VID voltage compatible with AMD’s Opteron/Athlon64, as shown in Table 1, is available at the VDAC pin.
The VID pins require an external bias voltage and should not be floated. The VID input comparators, with 1.2V
reference, monitor the VID pins and control the 6 bit Digital-to-Analog Converter (DAC) whose output is sent to the
VDAC buffer amplifier. The output of the buffer amp is the VDAC pin. The VDAC voltage is trimmed to compensate
for the input offsets of the Error Amp to provide 1% system set-point accuracy and is pre-positioned 50mV higher
than Vout listed in Table1 for load positioning. The actual VDAC voltage does not determine the system accuracy
and has a wider tolerance.
The IR3082 can accept changes in the VID code while operating and vary the DAC voltage accordingly. The
sink/source capability of the VDAC buffer amp is programmed by the same external resistor that sets the oscillator
frequency. The slew rate of the voltage at the VDAC pin can be adjusted by an external capacitor between VDAC
pin and the VOSNS- pin. A resistor connected in series with this capacitor is required to compensate the VDAC
buffer amplifier. Digital VID transitions result in a smooth analog transition of the VDAC voltage and converter
output voltage minimizing inrush currents in the input and output capacitors and overshoot of the output voltage.
Page 11 of 11
12/17/04
IR3082
VID4
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
VID3
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
VID2
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
VID1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
VID0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
Vout (V)
1.550
1.525
1.500
1.475
1.450
1.425
1.400
1.375
1.350
1.325
1.300
1.275
1.250
1.225
1.200
1.175
1.150
1.125
1.100
1.075
1.050
1.025
1.000
0.975
0.950
0.925
0.900
0.875
0.850
0.825
0.800
OFF4
Note: 4 Output disabled (Fault mode)
Table 1 – VID Table
Adaptive Voltage Positioning
Adaptive voltage positioning is needed to reduce the output voltage deviations during load transients and the power
dissipation of the load when it is drawing maximum current. The circuitry related to voltage positioning is shown in
Figure 8. Resistor RFB is connected between the Error Amp’s inverting input pin FB and the converter’s output
voltage. An internal current source whose value is programmed by the same external resistor that programs the
oscillator frequency pumps current into the FB pin. The error amp forces the converter’s output voltage lower to
maintain a balance at its inputs. RFB is selected to program the desired amount of fixed offset voltage below the
DAC voltage.
Page 12 of 12
12/17/04
IR3082
The voltage at the VDRP pin is a buffered version of the share bus and represents the sum of the DAC voltage and
the average inductor current of all the phases. The VDRP pin is connected to the FB pin through the resistor RVDRP.
Since the Error Amp will force the loop to maintain FB to be equal to the VDAC reference voltage, current will flow
into the FB pin equal to (VDRP-VDAC) / RVDRP. When the load current increases, the adaptive positioning voltage
increases accordingly. More current flows through the feedback resistor RFB, and makes the output voltage lower
proportional to the load current. The positioning voltage can be programmed by the resistor RVDRP so that the droop
impedance produces the desired converter output impedance. The offset and slope of the converter output
impedance are referenced to and therefore independent of the VDAC voltage.
Control IC
VDAC
Phase IC
Error
Amplifier
Current Sense
Amplifier
ISHARE
EA
CS+
+
+
FB
Vo
If b
VDAC
CS-
10k
-
Rf b
Droop
Amplifier
.
.
.
.
.
.
Rv drp
VDRP
Phase IC
IIN
Current Sense
Amplifier
ISHARE
+
CS+
+
VDAC
VDAC
CS-
10k
-
Figure 8 - Adaptive voltage positioning
Inductor DCR Temperature Correction
If the thermal compensation of the inductor DCR provided by the temperature dependent gain of the current sense
amplifier is not adequate, a negative temperature coefficient (NTC) thermistor can be used for additional correction.
The thermistor should be placed close to the inductor and connected in parallel with the feedback resistor as shown
in Figure 9. The resistor in series with the thermistor is used to reduce the nonlinearity of the thermistor.
Control IC
VDAC
Error
Amplifier
EA
+
Rf b
FB
If b
Rf b
Vo
Rt
Rv drp
Droop
Amplifier
VDRP
IIN
+
Figure 9 - Temperature compensation of inductor DCR
Page 13 of 13
12/17/04
IR3082
Remote Voltage Sensing
To compensate for impedance in the ground plane, the VOSNS- pin is used for remote sensing and connects
directly to the load. The VDAC voltage is referenced to VOSNS- to avoid additional error terms or delay related to a
separate differential amplifier. The capacitor connecting the VDAC and VOSNS- pins ensure that high speed
transients are fed directly into the error amp without delay.
Soft Start, Over-Current Fault Delay, and Hiccup Mode
The IR3082 has a programmable soft-start function to limit the surge current during the converter start-up. A
capacitor connected between the SS/DEL and LGND pins controls soft start as well as over-current protection delay
and hiccup mode timing. A charge current of 66uA and discharge current of 6uA control the up slope and down
slope of the voltage at the SS/DEL pin respectively. Soft start-up waveforms are shown in Figure 10.
Figure 11 depicts the various operating modes as controlled by the SS/DEL function. If there is no fault, the SS/DEL
pin will begin to be charged. The error amplifier output is clamped low until SS/DEL reaches 1.3V. The error
amplifier will then regulate the converter’s output voltage to match the SS/DEL voltage less the 1.3V offset until it
reaches the level determined by the VID inputs. The SS/DEL voltage continues to increase until it rises above 3.83V
and allows the PWRGD signal to be asserted. SS/DEL finally settles at 3.9V, indicating the end of the soft start.
Under Voltage Lock Out and VID=11111 faults as well as a low signal on the ENABLE input immediately sets the
fault latch causing SS/DEL to begin to discharge. The SS/DEL capacitor will continue to discharge down to 0.2V. If
the fault has cleared the fault latch will be reset by the discharge comparator allowing a normal soft start to occur.
A delay is included if an over-current condition occurs after a successful soft start sequence. This is required since
over-current conditions can occur as part of normal operation due to load transients or VID transitions. If an overcurrent fault occurs during normal operation it will initiate the discharge of the capacitor at SS/DEL but will not set
the fault latch immediately. If the over-current condition persists long enough for the SS/DEL capacitor to discharge
below the 115mV offset of the delay comparator, the Fault latch will be set pulling the error amp’s output low
inhibiting switching in the phase ICs and de-asserting the PWRGD signal. The delay can be reduced by adding a
resistor in series with the delay capacitor. The delay comparator’s offset voltage is reduced by the drop in the
resistor caused by the discharge current. To prevent the charge current from creating an offset exceeding the
SS/DEL to FB input offset voltage the value of the resistor should be 10KΩ or less to avoid interference with the soft
start function.
The SS/DEL capacitor will continue to discharge until it reaches 0.2V and the fault latch is reset allowing a normal
soft start to occur. If an over-current condition is again encountered during the soft start cycle the fault latch will be
set without any delay and hiccup mode will begin. During hiccup mode the 11 to 1 charge to discharge ratio results
in a 9% hiccup mode duty cycle regardless of at what point the over-current condition occurs.
If SS/DEL pin is pulled below 0.9V, the converter can be disabled.
Under Voltage Lockout (UVLO)
The UVLO function monitors the IR3082’s VCC supply pin and ensures that IR3082 has a high enough voltage to
power the internal circuit. The IR3082’s UVLO is set higher than the minimum operating voltage of compatible
Phase ICs thus providing UVLO protection for them as well. During power-up the fault latch is reset when VCC
exceeds 9.75V and there is no other fault. If the VCC voltage drops below 9.0V the fault latch will be set. For
converters using a separate 5V supply for gate driver bias an external UVLO circuit can be added to prevent
operation until adequate voltage is present. A diode connected between the 5V supply and the SS/DEL pin provides
a simple 5V UVLO function.
Page 14 of 14
12/17/04
IR3082
Over Current Protection (OCP)
The current limit threshold is set by a resistor connected between the OCSET and VDAC pins. If the IIN pin voltage,
which is proportional to the average current plus DAC voltage, exceeds the OCSET voltage, the over-current
protection is triggered.
VID = 11111 Fault
VID code of 11111 will set the fault latch and disable the error amplifier. An 800ns delay is provided to prevent a
fault condition from occurring during Dynamic VID changes.
Power Good Output
The PWRGD pin is an open-collector output and should be pulled up to a voltage source through a resistor. During
soft start, the PWRGD remains low until the output voltage is in regulation and SS/DEL is above 3.83V. The
PWRGD pin becomes low if the fault latch is set. A high level at the PWRGD pin indicates that the converter is in
operation and has no fault, but does not ensure the output voltage is within the specification. Output voltage
regulation within the design limits can logically be assured however, assuming no component failure in the system.
Load Current Indicator Output
The IIN pin voltage represents the average current of the converter plus the DAC voltage. The load current can be
retrieved by subtracting the VDAC voltage from the IIN voltage.
System Reference Voltage (VBIAS)
The IR3082 supplies a 7.0V/5mA precision reference voltage from the VBIAS pin. The oscillator ramp trip points are
based on the VBIAS voltage so it should be used to program the Phase ICs phase delay to minimize phase errors.
Enable Input
Pulling the ENABLE pin below 1.27V sets the Fault Latch.
Page 15 of 15
12/17/04
IR3082
9.0V
UVLO
VCC
(12V)
ENABLE
(VTT)
1.27V
3.83V
SS/DEL
1.3V
VOUT
PWRGD
START
(ENABLE ENDS
FAULT MODE)
START DELAY
1.9ms
SOFT START TIME
1.95ms
PWRGD
DELAY
2.0ms
NORMAL
OPERATION
POWER-DOWN
(VCC UVL
INITIATES
FAULT MODE)
Figure 10 – Start-up Waveforms
9.0V
UVLO
VCC
(12V)
ENABLE
3.785V
3.83V
SS/DEL
1.3V
VOUT
PWRGD
OCP THRESHOLD
IOUT
START-UP
(ENABLE GATES
FAULT MODE)
NORMAL OPERATION
(VOUT CHANGES DUE TO
LOAD AND VID CHANGES)
OCP
DELAY
HICCUP OVER-CURRENT
PROTECTION
RE-START
AFTER OCP
CLEARS
POWER-DOWN
(VCC GATES
FAULT MODE)
Figure 11 – Operating Waveforms
Page 16 of 16
12/17/04
IR3082
APPLICATIONS INFORMATION
POWERGOOD
VRHOT
PHASE FAULT
12V
RCSQGATE
RVCC
10 ohm
RBIASIN
CCS+
CCS-
20k
DBST
RCS+
RGATE
CVCC
0.1uF
DGATE
1
1
E
S
A
H
P
R
0
2
1
2
3
4
L
E
D
/
S
S
R
ENABLE
5
CFB
0.1uF
L
E
D
/
S
S
C
0
2
VID0
1
VID1
2
VID2
3
VID3
4
VID4
5
9
1
E
L
B
A
VID0 N
E
RFB1
8
1
7
1
L
E
D
/
S
S
D
G
R
W
P
D
N
G
L
IR3082
CONTROL
IC
VID1
VID2
VID3
VID4
S
N
S
O
V
6
VCC
VBIAS
EAOUT
FB
VDRP
C
S
O
R
7
T
E
S
C
O
C
A
D
V
8
9
15
14
RCP
+
N
I
S
C
HOTSET
VRHOT
CIN
VCCH
IR3086
PHASE
IC
RMPIN-
GATEH
PGND
GATEL
ISHARE
VCCL
P
M
O
C
S
N
I
A
E
7
P
M
R
M
W
P
8
P
M
R
M
W
P
C
CSCOMP
15
12
VOUT SENSE+
CBST
14
L
13
VOUT+
12
DISTRIBUTION
IMPEDANCE
11
COUT
VOUTD
N
G
L
CVCCL
C
C
V
RVCC
0
1
9
VOUT SENSE-
RPWMRMP
CVCC
RCS-
13
CCP1
RBIASIN
11
1
2
E
S
A
H
P
R
1
4
5
RCS+
6
1
7
1
NI
S
C
T
L
F
S
H
P
N
I
C
A
D
RMPIN+
+
N
I
S
C
HOTSET
VRHOT
GATEH
PGND
GATEL
ISHARE
VCCL
P
M
O
C
S
N
I
A
E
7
P
M
R
M
W
P
8
P
M
R
M
W
P
C
CSCOMP
D
N
G
L
CIN
15
14
L
13
12
11
CVCCL
C
C
V
RVCC
0
1
9
DBST
CBST
VCCH
IR3086
PHASE
IC
RMPIN-
6
3
2
E
S
A
H
P
R
8
1
9
1
N
I
S
AI
B
2
2
E
S
A
H
P
R
CCS+
CCS-
20k
0
2
2
RVDAC
CVDAC
6
1
NI
S
C
T
L
F
S
H
P
N
I
C
A
D
RMPIN+
6
3
ROSC
7
1
CCP
RDRP
N
II
0
1
ROCSET
N
I
S
AI
B
2
1
E
S
A
H
P
R
3
1
E
S
A
H
P
R
6
1
T
U
O
P
M
R
RFB
8
1
9
1
RPWMRMP
CVCC
RCS-
RBIASIN
1
3
E
S
A
H
P
R
0
2
1
2
3
4
5
7
1
+
N
I
S
C
HOTSET
VRHOT
CBST
VCCH
IR3086
PHASE
IC
RMPIN-
GATEH
PGND
GATEL
ISHARE
VCCL
P
M
O
C
S
N
I
A
E
7
P
M
R
M
W
P
8
P
M
R
M
W
P
C
CSCOMP
D
N
G
L
9
DBST
RCS+
6
1
NI
S
C
T
L
F
S
H
P
N
I
C
A
D
RMPIN+
6
3
3
E
S
A
H
P
R
8
1
9
1
N
I
S
AI
B
2
3
E
S
A
H
P
R
CCS+
CCS-
20k
CIN
15
14
L
13
12
11
CVCCL
C
C
V
RVCC
0
1
RPWMRMP
CVCC
RCS-
RBIASIN
1
4
E
S
A
H
P
R
0
2
1
2
3
4
5
NI
S
C
RMPIN+
+
N
I
S
C
HOTSET
VRHOT
CBST
VCCH
IR3086
PHASE
IC
RMPIN-
GATEH
PGND
GATEL
ISHARE
VCCL
6
N
I
A
E
7
P
M
R
M
W
P
CSCOMP
D
N
G
L
9
8
P
M
R
M
W
P
C
DBST
RCS+
6
1
7
1
T
L
F
S
H
P
N
I
C
A
D
P
M
O
C
S
3
4
E
S
A
H
P
R
8
1
9
1
N
I
S
AI
B
2
4
E
S
A
H
P
R
CCS+
CCS-
20k
CIN
15
14
L
13
12
11
CVCCL
C
C
V
RVCC
0
1
RPWMRMP
CVCC
RCS-
RBIASIN
1
5
E
S
A
H
P
R
0
2
1
2
3
4
5
2
5
E
S
A
H
P
R
3
5
E
S
A
H
P
R
CCS+
CCS-
20k
8
1
9
1
N
I
S
AI
B
7
1
NI
S
C
T
L
F
S
H
P
N
I
C
A
D
RMPIN+
RCS+
6
1
+
N
I
S
C
VCCH
IR3086
PHASE
IC
RMPINHOTSET
VRHOT
GATEH
PGND
GATEL
ISHARE
VCCL
P
M
O
C
S
6
CSCOMP
N
I
A
E
7
P
M
R
M
W
P
8
P
M
R
M
W
P
C
D
N
G
L
9
CIN
15
14
L
13
12
11
CVCCL
C
C
V
0
1
DBST
CBST
RVCC
RPWMRMP
CVCC
Figure 12 – IR3082/3086 5 Phase Converter for Opteron Processor
Page 17 of 17
12/17/04
IR3082
PERFORMANCE CHARACTERISTICS
Figure 13 - Oscillator Frequency vs. ROSC
Figure 14 IFB, IOCSET vs. ROSC
Oscillator Freq. (kHz)
1050
120
950
110
850
100
90
750
80
uA
650
550
70
60
50
450
40
350
30
250
20
150
10
10
20
30
40
50
60
70
80
90
10
20
30
ROSC (KOhm)
50
60
70
80
90
ROSC (KOhm)
Figure 16 - Bias Current Accuracy vs. ROSC
Figure 15 - VDAC Source and Sink Currents vs. ROSC
5
Isource
Isink
230
210
190
170
150
130
110
90
70
50
30
FB, OCSET Bias Current
4.5
+/-3 Sigma Variation (%)
250
uA
40
VDAC Sink Current
4
VDAC Source Current
3.5
3
2.5
2
1.5
1
0.5
0
10
10
20
30
40
50
60
70
80
90
10
20
30
40
50
60
70
80
90
ROSC (KOhm)
ROSC (KOhm)
Figure 17 – Error Amplifier Frequency Response
200
Gain
Phase
150
100
50
0
-50
10
100
1K
Page 18 of 18
10K
100K
1M
10M
100M
12/17/04
IR3082
DESIGN PROCEDURES – IR3082 AND IR3086 CHIPSET
IR3082 EXTERNAL COMPONENTS
Oscillator Resistor Rosc
The oscillator of IR3082 generates a triangle waveform to synchronize the phase ICs, and the switching frequency
of the each phase converter equals the oscillator frequency, which is set by the external resistor ROSC according to
the curve in Figure 13.
Soft Start Capacitor CSS/DEL and Resistor RSS/DEL
Because the capacitor CSS/DEL programs three different time parameters, i.e. soft start time, over current latch
delay time, and the frequency of hiccup mode, they should be considered together while choosing CSS/DEL.
The SS/DEL pin voltage controls the slew rate of the converter output voltage, as shown in Figure 10. After the
ENABLE pin voltage rises above 1.23V, there is a soft-start delay time tSSDEL, after which the error amplifier output
is released to allow the soft start. The soft start time tSS represents the time during which the output voltage rises
from zero to Vo. tSS can be programmed by an external capacitor, which is determined by Equation (1).
CSS / DEL =
I CHG ⋅ tSS 66 ⋅ 10−6 ⋅ tSS
=
VO
VO
(1)
Once CSS/DEL is chosen, the soft start delay time tSSDEL, the over-current fault latch delay time tOCDEL, and the
delay time tVccPG from output voltage (Vo) in regulation to Power Good are fixed and shown in Equations (2), (3),
(4) and (5) respectively.
tSSDEL =
CSS / DEL ⋅ 1.3 CSS / DEL ⋅ 1.3
=
66 ⋅ 10− 6
I CHG
C SS / DEL ⋅ 0.09 C SS / DEL ⋅ 0.09
=
I DISCHG
6 ⋅10 − 6
t OCDEL =
tVccPG =
C SS / DEL ⋅ (3.73 − VO − 1.3) C SS / DEL ⋅ (3.73 − VO − 1.3)
=
I CHG
66 ⋅10 − 6
(2)
(3)
(4)
The hiccup mode duty cycle of over current protection is determined by the charge current ICHG and discharge
current IDISCHG of CSS/DEL and is fixed at 9%. However, the hiccup frequency is determined by the load current and
over-current set value.
If faster over-current protection is required, a resistor in series with the soft start capacitor CSS/DEL can be used to
reduce the over-current fault latch delay time tOCDEL, and the resistor RSS/DEL is determined by Equation (5).
Equation (1) for soft start capacitor CSS/DEL and Equation (4) for power good delay time tVccPG are unchanged,
while the equation for soft start delay time CSS/DEL (Equation 2) is changed to Equation (6).
0.09 −
RSSDEL =
Page 19 of 19
⋅ 6 ⋅ 10 −6
t OCDEL ⋅ I DISCHG
t
0.09 − OCDEL
C SS / DEL
C SS / DEL
=
I DISCHG
6 ⋅ 10 −6
(5)
12/17/04
IR3082
tSSDEL =
CSS / DEL ⋅ (1.3 − RSS / DEL ⋅ I CHG ) CSS / DEL ⋅ (1.3 − RSS / DEL ⋅ 66 ⋅ 10−6 )
=
I CHG
66 ⋅ 10− 6
(6)
VDAC Slew Rate Programming Capacitor CVDAC and Resistor RVDAC
The slew rate of VDAC down-slope SRDOWN can be programmed by the external capacitor CVDAC as defined in
Equation (7), where ISINK is the sink current of VDAC pin as shown in Figure 15. The resistor RVDAC is used to
compensate VDAC circuit and is determined by Equation (8). The slew rate of VDAC up-slope SRUP is proportional
to that of VDAC down-slope and is given by Equation (9), where ISOURCE is the source current of VDAC pin as
shown in Figure15.
CVDAC =
I SINK
SR DOWN
RVDAC = 0.5 +
SRUP =
3.2 ⋅ 10−15
2
CVDAC
I SOURCE
CVDAC
(7)
(8)
(9)
Over Current Setting Resistor ROCSET
The inductor DC resistance is utilized to sense the inductor current. The copper wire of inductor has a constant
temperature coefficient of 3850 PPM, and therefore the maximum inductor DCR can be calculated from Equation
(10), where RL_MAX and RL_ROOM are the inductor DCR at maximum temperature TL_MAX and room temperature
T_ROOM respectively.
R L _ MAX = R L _ ROOM ⋅ [1 + 3850 ⋅ 10 −6 ⋅ (TL _ MAX − TROOM )]
(10)
The current sense amplifier gain of IR3086 decreases with temperature at the rate of 1470 PPM, which
compensates part of the inductor DCR increase. The phase IC die temperature is only a couple of degrees Celsius
higher than the PCB temperature due to the low thermal impedance of MLPQ package. The minimum current sense
amplifier gain at the maximum phase IC temperature TIC_MAX is calculated from Equation (11).
GCS _ MIN = GCS _ ROOM ⋅ [1 − 1470 ⋅ 10 −6 ⋅ (TIC _ MAX − TROOM )]
(11)
The total input offset voltage (VCS_TOFST) of current sense amplifier in phase ICs is the sum of input offset
(VCS_OFST) of the amplifier itself and that created by the amplifier input bias currents flowing through the current
sense resistors RCS+ and RCS-.
VCS _ TOFST = VCS _ OFST + I CSIN + ⋅ RCS + − I CSIN − ⋅ RCS −
(12)
The over current limit is set by the external resistor ROCSET as defined in Equation (13), where ILIMIT is the required
over current limit. IOCSET, the bias current of OCSET pin, changes with switching frequency setting resistor ROSC
and is determined by the curve in Figure 14. KP is the ratio of inductor peak current over average current in each
phase and is calculated from Equation (14).
ROCSET = [
KP =
Page 20 of 20
I LIMIT
⋅ R L _ MAX ⋅ (1 + K P ) + VCS _ TOFST ] ⋅ G CS _ MIN / I OCSET
n
(V I − VO ) ⋅ VO /( L ⋅ V I ⋅ f SW ⋅ 2)
IO / n
(13)
(14)
12/17/04
IR3082
No Load Output Voltage Setting Resistor RFB and Adaptive Voltage Positioning Resistor RDRP
A resistor between FB pin and the converter output is used to create output voltage offset VO_NLOFST, which is the
difference between VDAC voltage and output voltage at no load condition. Adaptive voltage positioning lowers the
converter voltage by Ro times Io, where Ro is the required output impedance of the converter.
RFB is not only determined by IFB, the current flowing out of the FB pin as shown in Figure 14, but also affected by
the total input offset voltage of current sense amplifiers. RFB and RDRP are determined by (15) and (16)
respectively.
RFB =
R L _ MAX ⋅ VO _ NLOFST − VCS _ TOFST ⋅ n ⋅ RO
R DRP =
I FB ⋅ R L _ MAX
R FB ⋅ R L _ MAX ⋅ GCS _ MIN
n ⋅ RO
(15)
(16)
IR3086 EXTERNAL COMPONENTS
PWM Ramp Resistor RPWMRMP and Capacitor CPWMRMP
PWM ramp is generated by connecting the resistor RPWMRMP between a voltage source and PWMRMP pin as well
as the capacitor CPWMRMP between PWMRMP and LGND. Choose the desired PWM ramp magnitude VRAMP and
the capacitor CPWMRMP in the range of 100pF and 470pF, and then calculate the resistor RPWMRMP from Equation
(17). To achieve feed-forward voltage mode control, the resistor RRAMP should be connected to the input of the
converter.
R PWMRMP =
VO
V IN ⋅ f SW ⋅ C PWMRMP ⋅ [ln(V IN − V DAC ) − ln(V IN − V DAC − V PWMRMP )]
(17)
Inductor Current Sensing Capacitor CCS+ and Resistors RCS+ and RCSThe DC resistance of the inductor is utilized to sense the inductor current. Usually the resistor RCS+ and capacitor
CCS+ in parallel with the inductor are chosen to match the time constant of the inductor, and therefore the voltage
across the capacitor CCS+ represents the inductor current. If the two time constants are not the same, the AC
component of the capacitor voltage is different from that of the real inductor current. The time constant mismatch
does not affect the average current sharing among the multiple phases, but affect the current signal ISHARE as well
as the output voltage during the load current transient if adaptive voltage positioning is adopted.
Measure the inductance L and the inductor DC resistance RL. Pre-select the capacitor CCS+ and calculate RCS+ as
follows.
RCS + =
L RL
C CS +
(18)
The bias current flowing out of the non-inverting input of the current sense amplifier creates a voltage drop across
RCS+, which is equivalent to an input offset voltage of the current sense amplifier. The offset affects the accuracy of
converter current signal ISHARE as well as the accuracy of the converter output voltage if adaptive voltage
positioning is adopted. To reduce the offset voltage, a resistor RCS- should be added between the amplifier inverting
input and the converter output. The resistor RCS- is determined by the ratio of the bias current from the non-inverting
input and the bias current from the inverting input.
RCS − =
Page 21 of 21
I CSIN +
⋅ RCS +
I CSIN −
(19)
12/17/04
IR3082
If RCS- is not used, RCS+ should be chosen so that the offset voltage is small enough. Usually RCS+ should be less
than 2 kΩ and therefore a larger CCS+ value is needed.
Over Temperature Setting Resistors RHOTSET1 and RHOTSET2
The threshold voltage of VRHOT comparator is proportional to the die temperature TJ (ºC) of phase IC. Determine
the relationship between the die temperature of phase IC and the temperature of the power converter according to
the power loss, PCB layout and airflow etc, and then calculate HOTSET threshold voltage corresponding to the
allowed maximum temperature from Equation (20).
V HOTSET = 4.73 ⋅ 10 −3 ⋅ TJ + 1.241
(20)
There are two ways to set the over temperature threshold, central setting and local setting. In the central setting,
only one resistor divider is used, and the setting voltage is connected to HOTSET pins of all the phase ICs. To
reduce the influence of noise on the accuracy of over temperature setting, a 0.1uF capacitor should be placed next
to HOTSET pin of each phase IC. In the local setting, a resistor divider per phase is needed, and the setting voltage
is connected to HOTSET pin of each phase. The 0.1uF decoupling capacitor is not necessary. Use VBIAS as the
reference voltage. If RHOTSET1 is pre-selected, RHOTSET2 can be calculated as follows.
R HOTSET 2 =
R HOTSET 1 ⋅ V HOTSET
V BIAS − V HOTSET
(21)
Phase Delay Timing Resistors RPHASE1 and RPHASE2
The phase delay of the interleaved multiphase converter is programmed by the resistor divider connected at
RMPIN+ or RMPIN- depending on which slope of the oscillator ramp is used for the phase delay programming of
phase IC, as shown in Figure 3.
If the upslope is used, RMPIN+ pin of the phase IC should be connected to RMPOUT pin of the control IC and
RMPIN- pin should be connected to the resistor divider. When RMPOUT voltage is above the trip voltage at
RMPIN- pin, the PWM latch is set. GATEL becomes low, and GATEH becomes high after the non-overlap time.
If down slope is used, RMPIN- pin of the phase IC should be connected to RMPOUT pin of the control IC and
RMPIN+ pin should be connected to the resistor divider. When RMPOUT voltage is below the trip voltage at
RMPIN- pin, the PWM latch is set. GATEL becomes low, and GATEH becomes high after the non-overlap time.
Use VBIAS voltage as the reference for the resistor divider since the oscillator ramp magnitude from control IC
tracks VBIAS voltage. Try to avoid both edges of the oscillator ramp for better noise immunity. Determine the ratio
of the programming resistors, RAPHASEx, corresponding to the desired switching frequencies and phase numbers. If
the resistor RPHASEx1 is pre-selected, the resistor RPHASEx2 is determined as:
R PHASEx 2 =
RAPHASEx ⋅ R PHASEx1
1 − RAPHASEx
(22)
Combined Over Temperature and Phase Delay Setting Resistors RPHASE1, RPHASE2 and RPHASE3
The over temperature setting resistor divider can be combined with the phase delay resistor divider to save one
resistor per phase.
Calculate the HOTSET threshold voltage VHOTSET corresponding to the allowed maximum temperature from
Equation (20). If the over temperature setting voltage is lower than the phase delay setting voltage,
VBIAS*RAPHASEx, connect RMPIN+ or RMPIN- pin between RPHASEx1 and RPHASEx2 and connect HOTSET pin
between RPHASEx2 and RPHASEx3 respectively. Pre-select RPHASEx1, then calculate RPHASEx2 and RPHASEx3,
Page 22 of 22
12/17/04
IR3082
R PHASEx 2 =
( RAPHASEx ⋅ V BIAS − V HOTSET ) ⋅ R PHASEx1
V BIAS ⋅ (1 − RAPHASEx )
(23)
R PHASEx 3 =
V HOTSET ⋅ R PHASEx1
V BIAS ⋅ (1 − RAPHASEx )
(24)
If the over temperature setting voltage is higher than the phase delay setting voltage, VBIAS times RAPHASEx,
connect HOTSET pin between RPHASEx1 and RPHASEx2 and connect RMPIN+ or RMPIN- between RPHASEx2 and
RPHASEx3 respectively. Pre-select RPHASEx1,
R PHASEx 2 =
(V HOTSET − RAPHASEx ⋅ V BIAS ) ⋅ R PHASEx1
V BIAS − V HOTSET
(25)
R PHASEx 3 =
RAPHASEx ⋅ V BIAS ⋅ R PHASEx1
V BIAS − V HOTSET
(26)
Bootstrap Capacitor CBST
Depending on the duty cycle and gate drive current of the phase IC, a 0.1uF to 1uF capacitor is needed for the
bootstrap circuit.
Decoupling Capacitors for Phase IC
0.1uF-1uF decoupling capacitors are required at VCC and VCCL pins of phase ICs.
VOLTAGE LOOP COMPENSATION
The adaptive voltage positioning (AVP is usually used in the computer applications to improve the transient
response and reduce the power loss at heavy load. Like current mode control, the adaptive voltage positioning loop
introduces extra zero to the voltage loop and splits the double poles of the power stage, which make the voltage
loop compensation much easier.
Resistors RFB and RDRP are chosen according to Equations (15) and (16), and the selection of compensation types
depends on the capacitors used. For the applications using Electrolytic, Polymer or AL-Polymer capacitors, type II
compensation shown in Figure 18 (a) is usually enough. While for the applications with only ceramic capacitors,
type III compensation shown in Figure 18 (b) is preferred.
CCP1
CCP1
RCP
CFB
RCP
RFB
T
U
O
A
E
T
U
O
A
E
T
U
O
A
E
T
U
O
A
E
RDRP
+
C
A
D
V
(a) Type II compensation
P
R
D
V
+
C
A
D
V
P
R
D
V
RDRP
CCP
-
B
F
+
O
V
-
B
F
+
O
V
RFB
RFB1
CCP
(b) Type III compensation
Figure 18. Voltage loop compensation network
Page 23 of 23
12/17/04
IR3082
Type II Compensation
Determine the compensation at no load, the worst case condition. Choose the crossover frequency fc between 1/10
and 1/5 of the switching frequency per phase. Assume the time constant of the resistor and capacitor across the
output inductors matches that of the inductor, RCP and CCP can be determined by equations (27) and (28).
RCP =
CCP =
(2π ⋅ f C ) 2 ⋅ LE ⋅ C E ⋅ RFB ⋅ VPWMRMP
1 + (2π ⋅ f C ⋅ C E ⋅ RCE ) 2 ⋅ Vo
10 ⋅ L E ⋅ C E
(27)
(28)
RCP
where LE and RCE are the equivalent output inductance and ESR of output capacitors respectively. CCP1 is optional
and may be needed in some applications to reduce the jitter caused by the high frequency noise. A ceramic
capacitor between 10pF and 220pF is usually enough.
Type III Compensation
Determine the compensation at no load, the worst case condition. Choose the crossover frequency fc between 1/10
and 1/5 of the switching frequency per phase. Assume the time constant of the resistor and capacitor across the
output inductors matches that of the inductor, RCP and CCP can be determined by equations (29) and (30), where CE
is equivalent output capacitance.
RCP =
C CP =
(2π ⋅ f C ) 2 ⋅ L E ⋅ C E ⋅ V PWMRMP
Vo
10 ⋅ L E ⋅ C E
(29)
(30)
RCP
Choose resistor RFB1 according to Equation (31), and determine CFB from Equations (32).
1
2
to
(31)
R FB1 = R FB
R FB1 = R FB
2
3
C FB =
1
4π ⋅ f C1 ⋅ RFB1
(32)
CCP1 is optional and may be needed in some applications to reduce the jitter caused by the high frequency noise. A
ceramic capacitor between 10pF and 220pF is usually enough.
CURRENT SHARE LOOP COMPENSATION
The crossover frequency of the current share loop should be at least one decade lower than that of the voltage loop
in order to eliminate the interaction between the two loops. A capacitor from SCOMP to LGND is usually enough for
most of the applications. Choose the crossover frequency of current share loop (fCI) based on the crossover
frequency of voltage loop (fC), and determine the CSCOMP,
CSCOMP =
0.65 ⋅ RPWMRMP ⋅ VI ⋅ I O ⋅ GCS _ ROOM ⋅ RLE ⋅ [1 + 2π ⋅ fCI ⋅ CE ⋅ (VO I O )] ⋅ FMI
VO ⋅ 2π ⋅ fCI ⋅1.05 ⋅106
(33)
Where FMI is the PWM gain in the current share loop,
CSCOMP =
Page 24 of 24
RPWMRMP ⋅ CPWMRMP ⋅ f SW ⋅ VPWMRMP
(VO − VPWMRMP − VDAC ) ⋅ (VI − VDAC )
(34)
12/17/04
IR3082
DESIGN EXAMPLE ― 5-PHASE OPTERON CONVERTER
SPECIFICATIONS
Input Voltage: VI=12 V
DAC Voltage: VDAC=1.3 V
No Load Output Voltage Offset: VO_NLOFST=15mV
Maximum Output Current: IOMAX=100 ADC
Output Impedance: RO=0.75 mΩ
Soft Start Time: tSS = 2 mS
Dynamic VID Down-Slope Slew Rate: SRDOWN=2.5mV/uS
Over Temperature Threshold: TPCB=115 ºC
POWER STAGE
Phase Number: n=5
Switching Frequency: fSW=600 kHz
Output Inductors: L=220 nH, RL=0.42 mΩ
Output Capacitors: C=47uF, RC= 2mΩ, Number Cn=32
IR3082 EXTERNAL COMPONENTS
Oscillator Resistor Rosc
Once the switching frequency is chosen, ROSC can be determined from the curve in Figure 13. For switching
frequency of 600kHz per phase, choose ROSC=18.2kΩ
Soft Start Capacitor CSS/DEL
Calculate the soft start capacitor from the required soft start time.
C SS / DEL =
I CHG ⋅ t SS
66 ⋅10 −6 ⋅ 2 ⋅10 −3
=
= 0.0988uF , choose C SS / DEL = 0.1uF
VO
1.3 + (50 − 15) ⋅10 −3
The soft start delay time is
t OCDEL =
C SS / DEL ⋅ 0.09 C SS / DEL ⋅ 0.09
=
= 1.5ms
I DISCHG
6 ⋅10 − 6
tVccPG =
C SS / DEL ⋅ (3.73 − VO − 1.3) 0.1 ⋅10 −6 ⋅ (3.73 − 1.335 − 1.3)
=
= 1.64ms
I CHG
66 ⋅10 − 6
VDAC Slew Rate Programming Capacitor CVDAC and Resistor RVDAC
From Figure 15, the sink current of VDAC pin corresponding to 600kHz (ROSC=18.2kΩ) is 125uA. Calculate the
VDAC down-slope slew-rate programming capacitor from the required down-slope slew rate.
CVDAC =
I SINK
125 ⋅ 10−6
=
= 50nF , Choose CVDAC=47nF
SRDOWN 2.5 ⋅ 10−3 / 10− 6
Calculate the programming resistor.
RVDAC = 0.5 +
3.2 ⋅ 10−15
3.2 ⋅ 10−15
= 0.5 +
= 2Ω
2
(47 ⋅ 10−9 ) 2
CVDAC
Page 25 of 25
12/17/04
IR3082
From Figure 15, the source current of VDAC pin is 170uA. The VDAC up-slope slew rate is
SRUP =
I SOURCE 170 ⋅10 −6
=
= 3.6mV / uS
CVDAC
47 ⋅10 − 9
Over Current Setting Resistor ROCSET
The room temperature is 25ºC and the target PCB temperature is 100 ºC. The phase IC die temperature is about 1
ºC higher than that of phase IC, and the inductor temperature is close to PCB temperature.
Calculate Inductor DC resistance at 100 ºC,
RL _ MAX = RL _ ROOM ⋅ [1 + 3850⋅10−6 ⋅ (TL _ MAX − TROOM )] = 0.42 ⋅10−3 ⋅ [1 + 3850⋅10−6 ⋅ (100 − 25)] = 0.54mΩ
The current sense amplifier gain is 34 at 25ºC, and its gain at 101ºC is calculated as,
G CS _ MIN = G CS _ ROOM ⋅ [1 − 1470 ⋅10 −6 ⋅ (T IC _ MAX − T ROOM )] = 34 ⋅ [1 − 1470 ⋅10 −6 ⋅ (101 − 25)] = 30.2
Set the over current limit at 115A. From Figure 14, the bias current of OCSET pin (IOCSET) is 65uA with
ROSC=18.2kΩ. The total current sense amplifier input offset voltage is 0.6mV, which includes the offset created by
the current sense amplifier input resistor mismatch.
Calculate constant KP, the ratio of inductor peak current over average current in each phase,
KP =
(V I − VO ) ⋅ VO /( L ⋅ V I ⋅ f SW ⋅ 2) (12 − 1.335) ⋅1.335 /( 220 ⋅10 −9 ⋅12 ⋅ 600 ⋅10 3 ⋅ 2)
=
= 0.147
115 / 5
I LIMIT / n
ROCSET = [
=(
RLIMIT
⋅ RL _ MAX ⋅ (1 + K P ) + VCS _ TOFST ] ⋅ GCS _ MIN / I OCSET
n
115
⋅ 0.54 ⋅10 − 3 ⋅1.147 + 0.6 ⋅10 − 3 ) ⋅ 30.2 /(65 ⋅10 − 6 ) = 6.9 kΩ
5
No Load Output Voltage Setting Resistor RFB and Adaptive Voltage Positioning Resistor RDRP
From Figure 14, the bias current of FB pin is 65uA with ROSC=18.2kΩ.
R FB =
R L _ MAX ⋅ V O _ NLOFST − V CS _ TOFST ⋅ n ⋅ R O
I FB ⋅ R L _ MAX
=
0 .54 ⋅ 10 −3 ⋅ 15 ⋅ 10 −3 − 0 .6 ⋅ 10 −3 ⋅ 5 ⋅ 0 .75 ⋅ 10 −3
= 230 Ω
65 ⋅ 10 − 6 ⋅ 0 .54 ⋅ 10 − 3
Select RFB = 232 Ω.
RDRP =
RFB ⋅ RL _ MAX ⋅ GCS _ MIN
n ⋅ RO
Page 26 of 26
=
232 ⋅ 0.54 ⋅ 10−3 ⋅ 30.2
= 1.01kΩ
5 ⋅ 0.75 ⋅ 10−3
12/17/04
IR3082
IR3086 EXTERNAL COMPONENTS
PWM Ramp Resistor RRAMP and Capacitor CRAMP
Set PWM ramp magnitude VPWMRMP=0.8V. Choose 100pF for PWM ramp capacitor CPWMRMP, and calculate the
resistor RPWMRMP,
VO
RPWMRMP =
VIN ⋅ f SW ⋅ CPWMRMP ⋅ [ln(VIN − VDAC ) − ln(VIN − VDAC − VPWMRMP )]
=
1.30
= 17.9kΩ , choose RPWMRMP=18.2kΩ
12 ⋅ 600 ⋅10 3 ⋅100 ⋅10 −12 ⋅ [ln(12 − 1.30) − ln(12 − 1.30 − 0.8)]
Inductor Current Sensing Capacitor CCS+ and Resistors RCS+ and RCSChoose CCS+=47nF and calculate RCS+,
RCS + =
L RL 220 ⋅ 10−9 /(0.42 ⋅ 10−3 )
=
= 11.2kΩ
CCS +
47 ⋅ 10−9
Choose RCS + = 11.5kΩ . The bias currents of CSIN+ and CSIN- are 0.25uA and 0.4uA respectively. Calculate resistor
RCS-,
RCS − =
0.25
0.25
⋅ RCS + =
⋅10.0 ⋅10 3 = 7.19kΩ , choose RCS-=7.15kΩ
0.4
0.4
Over Temperature Setting Resistors RHOTSET1 and RHOTSET2
Use central over temperature setting and set the temperature threshold at 115 ºC, which corresponds the IC die
temperature of 116 ºC. Calculate the HOTSET threshold voltage corresponding to the temperature thresholds.
V HOTSET = 4.73 ⋅10 −3 ⋅ T J + 1.241 = 4.73 ⋅10 −3 ⋅116 + 1.241 = 1.79V , choose RHOTSET1=20.0kΩ,
RHOTSET 2 =
RHOTSET 1 ⋅ VHOTSET 20 ⋅ 103 ⋅ 1.79
=
= 7.14kΩ
VBIAS − VHOTSET
6.8 − 1.79
Phase Delay Timing Resistors RPHASE1 and RPHASE2
The phase delay resistor ratios for phases 1 to 5 at 600kHz of switching frequencies are RAPHASE1=0.646,
RAPHASE2=0.400, RAPHASE3=0.158, RAPHASE4=0.291 and RAPHASE5=0.561 starting from down-slope. Preselect RPHASE11=RPHASE21=RPHASE31=RPHASE41=RPHASE51= RPHASE61=20kΩ,
R PHASE12 =
RAPHASE1
0.646
⋅ R PHASE11 =
⋅ 20 ⋅10 3 = 36.5kΩ
1 − RAPHASE1
1 − 0.646
RPHASE22=13.3kΩ, RPHASE32=3.74kΩ, RPHASE42=8.2kΩ, PPHASE52=25.5kΩ
Bootstrap Capacitor CBST
Choose CBST=0.1uF
Decoupling Capacitors for Phase IC and Power Stage
Choose CVCC=0.1uF, CVCCL=0.1uF
Page 27 of 27
12/17/04
IR3082
VOLTAGE LOOP COMPENSATION
All ceramic output capacitors are used in the design, type III compensation as shown in Figure 18(b) is used here.
Choose the desired crossover frequency fc =80 kHz and determine Rcp and CCP:
RCP =
(2π ⋅ fC )2 ⋅ LE ⋅ CE ⋅ RFB ⋅ VPWMRMP (2π ⋅ 80 ⋅103 )2 ⋅ (220 ⋅10−9 / 5) ⋅ (47 ⋅10−6 ⋅ 32) ⋅ 230 ⋅ 0.8
=
= 2.31kΩ
Vo
1.335
10 ⋅ L E ⋅ C E
C CP =
RCP
=
10 ⋅ (220 ⋅10 −9 / 5) ⋅ (47 ⋅10 −6 ⋅ 32)
2.31 ⋅10 3
= 35.2nF , Choose CCP=33nF
R FB1 =
1
1
⋅ R FB = ⋅ 230 = 115Ω
2
2
C FB =
1
1
=
= 8.54nF , choose CFB=10nF
4π ⋅ f C ⋅ R FB1 4π ⋅ 80 ⋅10 3 ⋅100
Choose RFB1=100Ω
Choose CCP1=220pF to reduce high frequency noise.
CURRENT SHARE LOOP COMPENSATION
The crossover frequency of the current share loop fCI should be at least one decade lower than that of the voltage
loop fC. Choose the crossover frequency of current share loop fCI=10kHz, and calculate CSCOMP,
FMI =
RPWMRMP ⋅ CPWMRMP ⋅ f SW ⋅V PWMRMP 18.2 ⋅ 103 ⋅ 100 ⋅ 10−12 ⋅ 600 ⋅ 103 ⋅ 0.8
=
= 0.011
(VI − VPWMRMP − VDAC ) ⋅ (VI − VDAC )
(12 − 0.8 − 1.35) ⋅ (12 − 1.35)
CSCOMP =
0.65 ⋅ RPWMRMP ⋅ VI ⋅ I O ⋅ GCS _ ROOM ⋅ RLE ⋅ [1 + 2π ⋅ fCI ⋅ CE ⋅ (VO I O )] ⋅ FMI
VO ⋅ 2π ⋅ fCI ⋅ 1.05 ⋅ 106
=
0.65 ⋅18.2 ⋅10 3 ⋅12 ⋅100 ⋅ 34 ⋅ (0.42 ⋅10 −3 5) ⋅ [1 + 2π ⋅10 ⋅10 3 ⋅1504 ⋅10 −6 ⋅ (1.33 − 100 ⋅ 7.5 ⋅10 −4 ) 100] ⋅ 0.011
(1.33 − 100 ⋅ 7.5 ⋅10 − 4 ) ⋅ 2π ⋅10 ⋅10 3 ⋅1.05 ⋅10 6
= 12.4nF
Choose CSCOMP=22nF
Page 28 of 28
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IR3082
LAYOUT GUIDELINES
The following layout guidelines are recommended to reduce the parasitic inductance and resistance of the PCB
layout, therefore minimizing the noise coupled to the IC.
•
•
•
•
•
•
Dedicate at least one middle layer for a ground plane LGND.
Connect the ground tab under the control IC to LGND plane through a via.
Place the following critical components on the same layer as control IC and position them as close as possible
to the respective pins, ROSC, ROCSET, RVDAC, CVDAC, CVCC, CSS/DEL and RCC/DEL. Avoid using any via for the
connection.
Place the compensation components on the same layer as control IC and position them as close as possible to
EAOUT, FB and VDRP pins. Avoid using any via for the connection.
Use Kelvin connections for the remote voltage sense signals, VOSNS+ and VOSNS-, and avoid crossing over
the fast transition nodes, i.e. switching nodes, gate drive signals and bootstrap nodes.
Control bus signals, VDAC, RMPOUT, IIN, VBIAS, and especially EAOUT, should not cross over the fast
transition nodes.
Page 29 of 29
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IR3082
METAL AND SOLDER RESIST
• The solder resist should be pulled away from the metal lead lands by a minimum of 0.06mm. The solder
resist mis-alignment is a maximum of 0.05mm and it is recommended that the lead lands are all Non
Solder Mask Defined (NSMD). Therefore pulling the S/R 0.06mm will always ensure NSMD pads.
• The minimum solder resist width is 0.13mm, therefore it is recommended that the solder resist is
completely removed from between the lead lands forming a single opening for each “group” of lead
lands.
• At the inside corner of the solder resist where the lead land groups meet, it is recommended to provide a
fillet so a solder resist width of ≥ 0.17mm remains.
• The land pad should be Solder Mask Defined (SMD), with a minimum overlap of the solder resist onto
the copper of 0.06mm to accommodate solder resist mis-alignment. In 0.5mm pitch cases it is allowable
to have the solder resist opening for the land pad to be smaller than the part pad.
• Ensure that the solder resist in-between the lead lands and the pad land is ≥ 0.15mm due to the high
aspect ratio of the solder resist strip separating the lead lands from the pad land.
• The single via in the land pad should be tented with solder resist 0.4mm diameter, or 0.1mm larger than
the diameter of the via.
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PCB METAL AND COMPONENT PLACEMENT
• Lead land width should be equal to nominal part lead width. The minimum lead to lead spacing should
be ≥ 0.2mm to minimize shorting.
• Lead land length should be equal to maximum part lead length + 0.2 mm outboard extension + 0.05mm
inboard extension. The outboard extension ensures a large and inspectable toe fillet, and the inboard
extension will accommodate any part misalignment and ensure a fillet.
• Center pad land length and width should be equal to maximum part pad length and width. However, the
minimum metal to metal spacing should be ≥ 0.17mm for 2 oz. Copper (≥ 0.1mm for 1 oz. Copper and ≥
0.23mm for 3 oz. Copper)
• A single 0.30mm diameter via shall be placed in the center of the pad land and connected to ground to
minimize the noise effect on the IC.
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IR3082
STENCIL DESIGN
• The stencil apertures for the lead lands should be approximately 80% of the area of the lead lands.
Reducing the amount of solder deposited will minimize the occurrence of lead shorts. Since for 0.5mm
pitch devices the leads are only 0.25mm wide, the stencil apertures should not be made narrower;
openings in stencils < 0.25mm wide are difficult to maintain repeatable solder release.
• The stencil lead land apertures should therefore be shortened in length by 80% and centered on the lead
land.
• The land pad aperture should be striped with 0.25mm wide openings and spaces to deposit
approximately 50% area of solder on the center pad. If too much solder is deposited on the center pad
the part will float and the lead lands will be open.
• The maximum length and width of the land pad stencil aperture should be equal to the solder resist
opening minus an annular 0.2mm pull back to decrease the incidence of shorting the center land to the
lead lands when the part is pushed into the solder paste.
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IR3082
PACKAGE INFORMATION
20L MLPQ (5 x 5 mm Body) – θJA = 30oC/W, θJC = 3oC/W
Data and specifications subject to change without notice.
This product has been designed and qualified for the Consumer market.
Qualification Standards can be found on IR’s Web site.
IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105
TAC Fax: (310) 252-7903
Visit us at www.irf.com for sales contact information.
www.irf.com
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