IRF IR3523MTRPBF

IR3523
DATASHEET
XPHASE3TM DUAL OUTPUT CONTROL IC
DESCRIPTION
The IR3523 Control IC provides a full featured and flexible way to implement a complete dual output DDR &
CPU VTT multiphase power solution for Intel VR11.1 motherboards. Each output interfaces with any number of
TM
xPHASE3 Phase ICs each driving and monitoring a single phase. Output 1 includes a 3 bit VR11.x VID, 1.1V
boot voltage and droop to implement the CPU VTT rail which is typically 1 phase. Output 2 includes a 3 bit VID for
TM
margining and supports any number of phases and DDR DIMM modules. The xPHASE3 architecture results in a
power supply that is smaller, less expensive, and easier to design while providing higher efficiency than
conventional approaches.
INDEPENDENT FEATURES FOR BOTH OUTPUT 1 & 2
•
•
•
•
•
•
•
•
•
Enable Input
Power Good (PG) Output
0.5% overall system set point accuracy
Programmable Softstart
High speed error amplifier with wide bandwidth of 30MHz and fast slew rate of 12V/us
Remote sense amplifier provides differential sensing and requires less than 50uA bias current
Programmable over current threshold triggers constant converter output current limit during start-up and
hiccup protection during normal operation
Over voltage condition communicated to phase ICs by IIN (ISHARE) and system by ROSC/OVP pins
Detection and protection of open remote sense lines
OUTPUT 1 ADDITIONAL FEATURES
•
•
•
•
•
3 bit Intel VR11.x VID (VID4, VID3, VID2)
Programmable VID offset
1.1 V Boot Voltage
Programmable output impedance
Programmable VID-on-the-Fly Slew Rate
OUTPUT 2 ADDITIONAL FEATURES
•
•
3 bit VID provides 1.5 V with ±150mV margining
Programmable VID-on-the-Fly Slew Rate
FEATURES SHARED BY BOTH OUTPUTS 1 & 2
•
•
•
•
Programmable per phase switching frequency of 250kHz to 1.5MHz
Daisy-chain digital phase timing provides accurate phase interleaving without external components
Gate Drive and IC bias linear regulator control with programmable output voltage and UVLO
Over voltage signal to system with over voltage detection during powerup and normal operation
ORDERING INFORMATION
Device
Package
IR3523MTRPBF
40 Lead MLPQ (6 x 6 mm body)
3000 per reel
40 Lead MLPQ (6 x 6 mm body)
100 piece strips
* IR3523MPBF
* Samples only
Page 1 of 37
Order Quantity
June 20, 2008
IR3523
APPLICATION CIRCUIT
12V
Q1
RVCCLFB1
RVCCLFB2
12V
To Pow er Stage
VCCL
To Phase IC
VCCL & GATE
DRIVE BIAS
CVCCL
4.7uF
RVCCLDRV
PG2
VID2_0
VID2_1
PHSIN
VID2_2
CLKOUT
CCP21
32
31
CLKOUT
PHSOUT
34
35
33
PHSIN
VCCL
VCCLFB
37
36
OCSET1
RFB22
CFB2
NC
FB1
EAOUT1
30
29
28
PG1
27
OVP FLAG
26
ROSC
25
CSS/DEL1
24
RVDAC1
CVDAC1
23
22
ISHARE1
ROCSET1
VDAC1
21
EAOUT1
CDRP1
To Output 2
Remote
Sense
RFB21
CFB1
RFB12
RFB11
RCP1
CCP11
CCP12
RFB13
VOUT2 SENSE +
3 Wire Analog
Control Bus to
Output 1 Phase
ICs
RDRP1
RTHERMISTOR1
CCP22
3 w ire Digital
Daisy Chain Bus
to Phase ICs
20
19
VOUT1
18
EAOUT2
VOSNS1+
OCSET2
11
RCP2
VCCLDRV
38
VDAC1
VOUT2
VDAC2
NC
10
IIN1
SS/DEL1
13
9
VDRP1
SS/DEL2
FB2
ROCSET2
PG2
39
IIN2
12
7
RVDAC2
8
VONSN1-
6
CSS/DEL2
CVDAC1
ROSC/OVP
IR3523
CONTROL
IC
ENABLE1
17
5
PG1
ENABLE2
16
ENABLE 1
VID1_2
VOSNS2-
4
NC
LGND
15
3
VID1_3
VOSNS2+
VID1_2
ENABLE 2
VID1_4
14
2
VID2_0
1
VID1_3
VID2_1
VID1_4
VID2_2
40
PHSOUT
Load Line NTC
Thermistor; Locate
close to Output 1
Pow er Stage
VOUT1 SENSE +
VOUT2 SENSE -
VOUT1 SENSE EAOUT2
VREF2
ISHARE2
To Output 2
Remote Sense
3 Wire Analog
Control Bus to
Output 2 Phase
ICs
Figure 1 – IR3523 Application Circuit
PIN DESCRIPTION
PIN#
1-3
4
PIN SYMBOL
VID1_4,
VID1_3, VID1_2
ENABLE2
5
ENABLE1
6
IIN2
7
SS/DEL2
8
VDAC2
9
OCSET2
10
11,20,30
EAOUT2
NC
Page 2 of 37
PIN DESCRIPTION
VID inputs for Output 1
Enable input. A logic low applied to this pin puts output 2 into fault mode. A
logic high signal on this pin enables output 2. Do not float as the logic state will
be undefined.
Enable input. A logic low applied to this pin puts output 2 into fault mode. A
logic high signal on this pin enables output 2. Do not float as the logic state will
be undefined.
Output 2 average current input from the output 2 phase IC(s). This pin is also
used to communicate over voltage condition to the output 2 phase ICs.
Programs output 2 startup and over current protection delay timing. Connect an
external capacitor to LGND to program.
Output 2 reference voltage. Connect an external RC network to LGND to
provide compensation for the internal buffer amplifier
Programs the output 2 constant converter output current limit and hiccup overcurrent threshold through an external resistor tied to VDAC2 and an internal
current source from this pin. Over-current protection can be disabled by
connecting a resistor from this pin to VDAC2 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).
Output 2 error amplifier output
No Connection
June 20, 2008
IR3523
PIN#
12
13
14
15
16
17
18
19
21
22
PIN SYMBOL
FB2
VOUT2
VOSEN2+
VOSEN2VOSEN1VOSEN1+
VOUT1
FB1
EAOUT1
OCSET1
23
VDAC1
24
SS/DEL1
25
IIN1
26
VDRP1
27
ROSC/OVP
28
29
31
PG1
LGND
CLKOUT
32
PHSOUT
33
34
PHSIN
VCCL
35
VCCLFB
36
VCCLDRV
37
38, 39,
40
PG2
VID2_0,
VID2_1, VID2_2
Page 3 of 37
PIN DESCRIPTION
Output 2 Error Amplifier inverting input
Output 2 remote sense amplifier output.
Output 2 remote sense amplifier input. Connect to output at the load.
Output 2 remote sense amplifier input. Connect to ground at the load.
Output 1 remote sense amplifier input. Connect to ground at the load.
Output 1 remote sense amplifier input. Connect to output at the load.
Output 1 remote sense amplifier output.
Inverting input to the output 1 Error Amplifier
Output 1 error amplifier output
Programs the output 1 constant converter output current limit and hiccup overcurrent threshold through an external resistor tied to VDAC1 and an internal
current source from this pin. Over-current protection can be disabled by
connecting a resistor from this pin to VDAC1 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).
Output 1 reference voltage programmed by the VID inputs and error amplifier
non-inverting input. Connect an external RC network to LGND to program
dynamic VID slew rate and provide compensation for the internal buffer
amplifier.
Programs output 1 startup and over current protection delay timing. Connect an
external capacitor to LGND to program.
Output 1 average current input from the output 1 phase IC(s). This pin is also
used to communicate over voltage condition to phase ICs.
Output 1 Buffered IIN signal. Connect an external RC network to FB1 to
program converter output impedance.
Connect a resistor to LGND to program oscillator frequency and OCSET,
VDAC1 and VREF2 bias currents. Oscillator frequency equals switching
frequency per phase. The pin voltage is 0.6V during normal operation and
higher than 1.6V if over-voltage condition is detected.
Open collector output. Asserted when Output 1 is regulated.
Local Ground for internal circuitry and IC substrate connection.
Clock output at switching frequency multiplied by phase number. Connect to
CLKIN pins of phase ICs.
Phase clock output at switching frequency per phase. Connect to PHSIN pin of
the first phase IC.
Feedback input of phase clock. Connect to PHSOUT pin of the last phase IC.
Output of the voltage regulator, and power input for clock oscillator circuitry.
Connect a decoupling capacitor to LGND.
Non-inverting input of the voltage regulator error amplifier. Output voltage of the
regulator is programmed by the resistor divider connected to VCCL.
Output of the VCCL regulator error amplifier to control external transistor. The
pin senses the converter input voltage through a resistor.
Open collector output. Asserted when Output 2 output is regulated.
VID inputs for Output 2
June 20, 2008
IR3523
ABSOLUTE MAXIMUM RATINGS
Absolute maximum ratings indicate sustained limits beyond which damage to the device may occur. All voltages are
absolute voltages referenced to the LGND pin.
o
Operating Junction Temperature……………..0 to 150 C
o
o
Storage Temperature Range………………….-65 C to 150 C
ESD Rating………………………………………HBM Class 1C JEDEC Standard
MSL Rating………………………………………2
o
Reflow Temperature…………………………….260 C
PIN #
1
2
3
4
5
6
7
8
9
10
12
13
14
15
16
17
18
19
21
22
23
24
25
26
27
28
29
31
32
33
34
35
36
37
38
39
40
Page 4 of 37
PIN NAME
VID1_4
VID1_3
VID1_2
ENABLE2
ENABLE1
IIN2
SS/DEL2
VDAC2
OCSET2
EAOUT2
FB2
VOUT2
VOSEN2+
VOSEN2VOSEN1VOSEN1+
VOUT1
FB1
EAOUT1
OCSET1
VDAC1
SS/DEL1
IIN1
VDRP1
ROSC/OVP
PG1
LGND
CLKOUT
PHSOUT
PHSIN
VCCL
VCCLFB
VCCLDRV
PG2
VID2_0
VID2_1
VID2_2
VMAX
8V
8V
8V
3.5V
3.5V
8V
8V
3.5V
8V
8V
8V
8V
8V
1.0V
1.0V
8V
8V
8V
8V
8V
3.5V
8V
8V
8V
8V
8V
n/a
8V
8V
8V
8V
3.5V
10V
8V
8V
8V
8V
VMIN
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.5V
-0.5V
-0.5V
-0.5V
-0.5V
-0.5V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.5V
-0.3V
n/a
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
-0.3V
ISOURCE
1mA
1mA
1mA
1mA
1mA
5mA
1mA
1mA
1mA
25mA
1mA
5mA
5mA
5mA
5mA
5mA
5mA
1mA
25mA
1mA
1mA
1mA
5mA
35mA
1mA
1mA
20mA
100mA
10mA
1mA
1mA
1mA
1mA
1mA
1mA
1mA
1mA
June 20, 2008
ISINK
1mA
1mA
1mA
1mA
1mA
1mA
1mA
1mA
1mA
10mA
1mA
25mA
1mA
1mA
1mA
1mA
25mA
1mA
10mA
1mA
1mA
1mA
1mA
1mA
1mA
20mA
1mA
100mA
10mA
1mA
20mA
1mA
50mA
20mA
1mA
1mA
1mA
IR3523
RECOMMENDED OPERATING CONDITIONS FOR RELIABLE OPERATION WITH MARGIN
o
o
4.75V ≤ VCCL ≤ 7.5V, -0.3V ≤ VOSEN-x ≤ 0.3V, 0 C ≤ TJ ≤ 100 C, 7.75 kΩ ≤ ROSC ≤ 50 kΩ, CSS/DELx = 0.1uF
ELECTRICAL CHARACTERISTICS
The electrical characteristics involve the spread of values guaranteed within the recommended operating
conditions (unless otherwise specified). Typical values represent the median values, which are related to 25°C.
PARAMETER
System Set Point Accuracy
Deviation from Table 1 for Output
1 and deviation from Table 2 for
Output 2 per test circuit in Figure
4a and 4b, respectively
TEST CONDITION
MIN
TYP
MAX
UNIT
Output 2 and Output 1
-0.5
0.5
%
Output 2 at 1.8V (only)
-1.5
1.5
%
Increasing
Decreasing (VID2_0 and VID2_1 Only)
Hysteresis (VID2_0 and VID2_1 Only)
0.85
550
190
100
.95
650
300
175
1.05
750
410
250
V
mV
mV
kΩ
-10%
See
Figure 2
0.600
+10%
kHz
0.625
1
V
V
1
1
V
V
1
70
V
%
8
30
0.6
1
mV
mA
mA
MHz
V/µs
µA
VIDx Interface
Input Thresholds
Pull-Down Resistance
Oscillator
PHSOUT Frequency
ROSC Voltage
CLKOUT High Voltage
CLKOUT Low Voltage
PHSOUT High Voltage
PHSOUT Low Voltage
PHSIN Threshold Voltage
0.575
I(CLKOUT)= -10 mA, measure V(VCCL) –
V(CLKOUT).
I(CLKOUT)= 10 mA
I(PHSOUT)= -1 mA, measure V(VCCL) –
V(PHSOUT)
I(PHSOUT)= 1 mA
Compare to V(VCCL)
30
50
-8
2
0.2
0
VDRP1 Buffer Amplifiers
Input Offset Voltage
Source Current
Sink Current
Unity Gain Bandwidth
Slew Rate
IIN Bias Current
V(VDRP) – V(IIN), 0.5V ≤ V(IIN) ≤ 3.3V
0.5V ≤ V(IIN1) ≤ 3.3V
0.5V ≤ V(IIN1) ≤ 3.3V
Note 1
Note 1
-1
0.4
8
4.7
0
3.0
-3
6.4
0
9.0
3
MHz
mV
0.5
2
2
1
12
4
1.7
18
8
mA
mA
V/us
30
30
50
50
250
1
uA
uA
mV
V
+8%
µA
+11%
µA
Remote Sense Differential Amplifiers
Unity Gain Bandwidth
Input Offset Voltage
Source Current
Sink Current
Slew Rate
VOSEN+ Bias Current
VOSEN- Bias Current
Low Voltage
High Voltage
VDAC1 & VDAC2 Outputs
Source Currents
Sink Currents
Page 5 of 37
Note 1
0.5V≤ V(VOSENx+) - V(VOSENx-) ≤ 1.6V,
Note 2
0.5V≤ V(VOSENx+) - V(VOSENx-) ≤ 1.6V
0.5V≤ V(VOSENx+) - V(VOSENx-) ≤ 1.6V
0.5V≤ V(VOSENx+) - V(VOSENx-) ≤ 1.6V,
Note 1
0.5 V < V(VOSENx+) < 1.6V
-0.3V ≤ VOSENx- ≤ 0.3V, All VID Codes
V(VCCL) = 7V
V(VCCL) – V(VOUTx)
0.5
Includes I(OCSET)
-8%
Includes I(OCSET)
-11%
3000*Vrosc(
V)/
ROSC(kΩ)
1000*Vrosc
V)/
ROSC(kΩ)
June 20, 2008
IR3523
PARAMETER
Soft Start and Delay
Start Delay
Start-up Time
OC Delay Time
SS/DELx to FB Input Offset
Voltage
Charge Current
OC Delay Discharge Currents
Fault Discharge Current
Hiccup Duty Cycle
Charge Voltage (Output 1,2)
Delay Comparator Threshold
Delay Comparator Threshold
TEST CONDITION
MIN
TYP
MAX
UNIT
Measure Enable to EAOUTx activation
Measure Enable activation to PGx
V(IINx) – V(OCSETx) = 500 mV
1
3
200
2.9
8
650
3.5
13
1000
ms
ms
us
With FB = 0V, adjust V(SS/DEL) until
EAOUTx drives high
0.7
1.4
1.9
V
-30
-50
47
4.5
10
3.9
70
-70
µA
µA
µA
µA/µA
V
mV
Measure at charge voltage
I(Fault) / I(Charge)
2.5
8
3.5
Relative to Charge Voltage, SS/DELx
rising - Note 1
Relative to Charge Voltage, SS/DELx
falling - Note 1
Delay Comparator Hysteresis
VID1 Sample Delay Comparator
Threshold
Discharge Comp. Threshold
6.5
12
4.2
135
mV
2.8
65
3.0
3.2
mV
V
150
200
300
mV
-1
0
1
mV
-5%
Vrosc(V)*100
0 /Rosc(KΩ)
+5%
µA
-1
100
20
5.5
0.4
5.0
500
0
110
30
12
0.85
8.5
780
120
300
1
135
40
20
1
12.0
950
250
600
µA
dB
MHz
V/µs
mA
mA
mV
mV
mV
Error Amplifiers
Input Offset Voltage
Measure V(FBx) – V(VDACx)). Note 2
o
o
25 C ≤ TJ ≤ 100 C
FB1 Bias Current
FB2 Bias Current
DC Gain
Bandwidth
Slew Rate
Sink Current
Source Current
Maximum Voltage
Minimum Voltage
Open Control Loop Detection
Threshold
Open Control Loop Detection
Delay
Note 1
Note 1
Note 1
Measure V(VCCL) – V(EAOUTx)
Measure V(VCCL) - V(EAOUT), Relative
to Error Amplifier maximum voltage.
Measure PHSOUT pulse numbers from
V(EAOUTx) = V(VCCL) to PGx = low.
125
8
Pulse
ENABLE Inputs
Threshold Increasing
Threshold Decreasing
Threshold Hysteresis
Bias Current
Blanking Time
PGx Outputs
Under Voltage Threshold - Voutx
Decreasing
Under Voltage Threshold - Voutx
Increasing
Under Voltage Threshold
Hysteresis
Output Voltage
Leakage Current
VCCL_DRV Activation Threshold
Page 6 of 37
1.38
0.8
470
-5
75
1.65
0.99
620
0
250
1.94
1.2
800
5
400
V
V
mV
uA
ns
Reference to VDAC
-365
-315
-265
mV
Reference to VDAC
-325
-275
-225
mV
5
53
110
mV
1.0
150
0
2.0
300
10
3.6
mV
µA
V
0V ≤ V(x) ≤ 3.5V
Noise Pulse < 100ns will not register an
ENABLE state change. Note 1
I(PGx) = 4mA
V(PGx) = 5.5V
I(PGx) = 4mA, V(PGx) < 400mV,
V(VCCL) = 0
June 20, 2008
IR3523
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
1.85
1.39
100
-25
1.95
1.47
125
3
2.05
1.55
150
25
V
V
mV
mV
1.87
1.93
1.99
V
1.24
1.33
1.37
V
25
50
75
mV
90
180
ns
1.2
0.2
V
V
150
300
ns
5
15
Ω
Over Voltage Protection (OVP) Comparators
Threshold at Power-up (Output 2)
Threshold at Power-up (Output 1)
Voutx Threshold Voltage
OVP Release Voltage during
Normal Operation
Threshold during Dynamic VID
down (Output 2)
Threshold during Dynamic VID
down (Output 1)
Dynamic VID Detect Comparator
Threshold
Propagation Delay to IIN
OVP High Voltage
OVP Power-up High Voltage
Propagation Delay to OVP
Compare to V(VDACx)
Compare to V(VDACx)
Note 1
Measure time from V(Voutx) > V(VDACx)
(250mV overdrive) to V(IINx) transition to >
0.9 * V(VCCL).
Measure V(VCCL)-V(ROSC/OVP)
V(VCCLDRV)=1.8V. Measure V(VCCL)V(ROSC/OVP)
Measure time from V(Voutx) > V(VDAC)
(250mV overdrive) to V(ROSC/OVP)
transition to >1V.
0
0
IIN Pull-up Resistance
Over-Current Comparators
Input Offset Voltage
1V ≤ V(OCSETx) ≤ 3.3V
-35
0
35
mV
-5%
Vrosc(V)*1000/
Rosc(KΩ)
+5%
µA
11.3
16
23.1
kΩ
14.4
20
29.1
kΩ
150
200
250
mV
35
60
85
mV
86.5
89.0
91.5
%
0.36
0.40
0.44
V
V(Voutx) = 100mV
200
500
700
uA
1.2
0
30
93.5
85.0
8.25
1.25
1
Compare to V(VCCL)
Compare to V(VCCL)
Compare to V(VCCL)
1.15
-1
10
89.0
81.0
7.0
97.0
89.0
9.5
V
uA
mA
%
%
%
4
10
15
mA
OCSET Bias Current
2048-4096 Count Threshold
1024-2048 Count Threshold
Adjust ROSC value to find threshold
Note 1
Adjust ROSC value to find threshold
Note 1
Open Sense Line Detection
Sense Line Detection Active
Comparator Threshold Voltage
Sense Line Detection Active
Comparator Offset Voltage
VOSEN+ Open Sense Line
Comparator Threshold
VOSEN- Open Sense Line
Comparator Threshold
Sense Line Detection Source
Currents
V(Voutx) < [V(VOSEN+) – V(LGND)] / 2
Compare to V(VCCL)
VCCL Regulator Amplifier
Reference Feedback Voltage
VCCLFB Bias Current
VCCLDRV Sink Current
UVLO Start Threshold
UVLO Stop Threshold
Hysteresis
General
VCCL Supply Current
Note 1: Guaranteed by design, but not tested in production
Note 2: VDACx Outputs are trimmed to compensate for Error & Amp Remote Sense Amp input offsets
Page 7 of 37
June 20, 2008
IR3523
PHSOUT FREQUENCY VS RROSC CHART
PHSOUT FREQUENCY vs. RROSC
1600
1500
1400
1300
Frequency (KHz)
1200
1100
1000
900
800
700
600
500
400
300
200
5
10
15
20
25
30
35
40
45
50
55
RROSC (KOhm)
Figure 2 - PHSout Frequency vs. RROSC chart
Page 8 of 37
June 20, 2008
IR3523
IR3523 block diagram
ENABLE2
250nS
BLANKING
+
ENABLE
COMPARATOR
1.65V
1.0V
PG2
ENABLE1
-
250nS
BLANKING
ENABLE +
COMPARATOR
1.65V
1.0V
UV2
SSCLF2
DLY OUT2
VCCLDRV
UV1
DLY OUT1
OVLATCH
PG1
400k
400k
OV1_2
VCCL REGULATOR
AMPLIFIER
S
Q
SS/DEL CLEARED
FAULT LATCH1
SET
DOMINANT
+
R
-
SS/DEL CLEARED
FAULT LATCH2
0.94
0.86
1.2V
INTERNAL
DIS
CIRCUIT
BIAS
VCCL UVLO
OC1 AFTER VRRDY
OC1 Bf VRRDY
Q
S
SET
DOMINANT
R
VCCL UVLO
OC2 AFTER VRRDY
OC2 Bf VRRDY
+
-
VCCL UVL
COMPARATOR
S
Q
SET
DOMINANT
DIS
OC DELAY
COUTERDIS
R
80mV
120mV
DIS
DELAY
COMPARATOR
+
TBS
OV
OPEN SENSE1
OPEN CONTROL1
R
S
Q
SET
DOMINANT
OPEN SENSE2
OPEN CONTROL2
POWER-UP
OK LATCH
PHSOUT
DIS
OC DELAY
IROSC
DLY OUT2
COUTER
DIS
DIS
S
Q
RESET
DOMINANT
-
DISCHARGE
COMPARATOR
R
80mV
DELAY
COMPARATOR 120mV
POWER-UP
OK LATCH
PHSOUT
IROSC
DLY OUT1
Q
S
RESET
DOMINANT
Q
reset
3.9V
DISCHARGE
COMPARATOR
R
-
SSCLF1
+
ICHG
50uA
0.2V
Q
reset
SS/DEL1
-
SSCLF2
FLT1
+
ICHG
50uA
0.2V
FLT2
IDCHG
4.5uA
OV1
PHSOUT
DCHG2
DIS
47uA
-
8 Pulse
Delay
DIS
OC LIMIT
COMPARATOR
IDCHG2
DIS
IROSC
OC LIMIT
COMPARATOR
IIN2
IOCSET
0.3V
OV1_2
+
-
1.4V
SOFT
START
CLAMP
+
+
VDAC2
IROSC
OV2
OV1
PG2
-
275mV
315mV
PG1
-
OVER
VOLTAGE
COMPARATOR
OV2
1.8V
DYNAMIC VID2 DOWN
DETECT COMPARATOR
-
VDAC2
-
+
+
OV2
50mV
+
DYNAMIC VID1 DOWN
DETECT COMPARATOR
OV1
DETECTION PULSE1
25k
VOSEN2+
60mV
+
-
REMOTE SENSE
AMPLIFIER
+
IVOSEN-
25k
200mV
-
DETECTION PULSE2
-
IVOSENVCCL
DETECTION PULSE1
+
4 OPEN SENSE
LINE DETECT
COMPARATORS
4 OPEN SENSE
LINE DETECT
COMPARATORS
VCCL RESET
VCCL*0.9
+
OPEN SENSE LINE1
+
0.4V
-
200mV
+
VCCL RESET
VCCL*0.9
VIDSEL
VCCL
VIDSEL
VCCL
VOSEN1IVOSEN1-
IVOSEN1+
-
VCCL
25k
-
IVOSEN2+
VOSEN1+
25k
REMOTE SENSE
AMPLIFIER
+
IVOSEN2-
25k
60mV
-
25k
VOSEN2-
VOUT1
25k
50mV
25k
+
VOUT2
UV1
+
-
-
1.2V
VOUT1 UV
COMPARATOR
+
UV2
VDAC1
OVER VOLTAGE
COMPARATOR
125mV
275mV
315mV
IFB
125mV
+
VOUT2 UV
COMPARATOR
FB1
DLY OUT1
OV1
SOFT
START
CLAMP
+
ERROR
AMPLIFIER
FB2
EAOUT1
ERROR
AMPLIFIER
-
FLT2
DLY OUT2
VDAC1
+
IROSC
1.4V
EAOUT2
DISABLE1
FLT1
IOCSET
DISABLE2
VCCL
-
+
OPEN CONTROL
LOOP COMPARATOR
+
IIN1
OCSET1
OPEN CONTROL
LOOP COMPARATOR
+
+
OCSET2
-
VDRP
AMPLIFIER
-
PHSOUT
DIS
8 Pulse
Delay
DIS
0.3V
VDRP1
+
+
OV2
VCCL
DCHG1
47uA
DIS
VCCL
IDCHG
4.5uA
DIS
IDCHG1
SS/DEL2
VCCL
VCCL
OPEN DAISY
Q
S
SET
DOMINANT
R
UV CLEARED
FAULT LATCH2
OV
OPEN DAISY
UV CLEARED
FAULT LATCH1
-
VCCLFB
+
VCCLDRV
0.4V
OPEN SENSE LINE2
-
-
+
+
+
+
ISOURCE
ISOURCE
VDAC1
IROSC
VDAC2
IROSC
ISINK
ISINK
-
VID2_0
VID0
VID1_4
VID3
1.0V
DIGITAL TO
ANALOG
CONVERTERS
INTERNAL
VID3
VDAC
VID2
VID1
VCCL UVLO
VIDSEL
DYNAMIC DOWN VID2
PHSIN
VID INPUT
COMPARATORS
(1 of 3 SHOWN)
VID1
ROSC BUFFER
AMPLIFIER
0.6V
PHSOUT
VCCL - 1.2V
CLKOUT PHSIN PHSOUT
VBOOT
(1.1V)
Q
S
SET
DOMINANT
R
OV
FAULT LATCH 1
SAMPLE DELAY
VID1 SAMPLE AND
DELAY COMPARATOR
SS/DEL1
-
1.0V
CLKOUT
INTERNAL
VID3
VDAC
VID2
+
-
VID0
+
175k
CURRENT
SOURCE
GENERATOR
3.0V
Figure 3 – IR3523 BLOCK DIAGRAM
Page 9 of 37
LGND
-
VID1_2
VID2
IROSC
VID0
VIDSEL
DYNAMIC DOWN VID1
VID1_3
OPEN DAISY
FAULT
CHAIN
+
175k
-
VID2_1
VID2
+
VID3
VID2_2
-
VDAC BUFFER
AMPLIFIER
VDAC BUFFER
AMPLIFIER
June 20, 2008
ROSC
IR3523
SYSTEM SET POINT TEST
Converter output voltage is determined by the system set point voltage which is the voltage that appears at the
FBx pins when the converter is in regulation. The set point voltage includes error terms for the VDAC digital-toanalog converters, Error Amp input offsets, and Remote Sense input offsets. The voltage appearing at the
VDACx pins is not the system set point voltage. System set point voltage test circuits for Outputs 1 and 2 are
shown in Figures 4A & 4B.
IR3523
ERROR
AMPLIFIER
VDAC
BUFFER
AMPLIFIER
EAOUT1
+
-
FB1
+
"FAST"
VDAC
ISOURCE
VDAC1
OCSET1
ISINK
ROCSET
-
IFB1
IOCSET1
IROSC
IROSC
RVDAC
CVDAC
ROSC BUFFER
AMPLIFIER
1.2V
LGND
+
CURRENT
SOURCE
GENERATOR
IROSC
ROSC
RROSC2
VOUT1
EAOUT
SYSTEM
SET POINT
VOSNSVOLTAGE
REMOTE SENSE
AMPLIFIER
VOSEN1+
+
VOSEN1-
-
Figure 4A - Output 1 System Set Point Test Circuit
IR3523
ERROR
AMPLIFIER
VDAC
BUFFER
AMPLIFIER
EAOUT2
+
-
FB2
+
ISOURCE
"FAST"
VDAC
VDAC2
OCSET2
ISINK
ROCSET3
-
IOCSET1
IROSC
RVDAC3
CVDAC3
CURRENT
SOURCE
GENERATOR
ROSC BUFFER
AMPLIFIER
1.2V
LGND
+
IROSC
ROSC
RROSC3
VOUT2
REMOTE SENSE
AMPLIFIER
VOSEN2+
EAOUT
SYSTEM
SET POINT
VOSNSVOLTAGE
VOSEN2-
+
-
Figure 4B - Output 2 System Set Point Test Circuit
Page 10 of 37
June 20, 2008
IR3523
SYSTEM THEORY OF OPERATION
PWM Control Method
TM
The PWM block diagram of the xPHASE3 architecture is shown in Figure 5. 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. Input voltage is sensed in phase ICs and feed-forward control is realized. The
PWM ramp slope will change with the input voltage automatically compensating for changes in the input voltage.
The input voltage can change due to variations in the silver box output voltage or due to the wire and PCB-trace
voltage drop related to changes in load current.
GATE DRIVE
VOLTAGE
VIN
IR3523 CONTROL IC
PHASE IC
PHSOUT
CLOCK GENERATOR
CLKOUT
VCC
CLKIN
VCCH
CLK Q
PWM
LATCH
D
PHSOUT
PHSIN
GATEH
VOSNS1+
SW
RESET
DOMINANT
VOUT1
COUT
-
EAIN
R
VCCL
+
GND
GATEL
ENABLE
REMOTE SENSE
AMPLIFIER
CBST
S
PWM
COMPARATOR
PHSIN
+
+
VID6
-
-
RAMP
DISCHARGE
CLAMP
VOUT1
BODY
BRAKING
COMPARATOR
+
PGND
VOSNS1-
-
VDAC1
SHARE ADJUST
ERROR AMPLIFIER
LGND
ERROR
AMPLIFIER
+
VDAC
CURRENT
SENSE
AMPLIFIER
+
EAOUT1
+
ISHARE
-
-
-
3K
RCP1
VID6
VID6
+
CCP12
RFB12
RFB11
FB1
IROSC
VDRP1 AMP
CFB1
CDRP1
+
CSIN-
DACIN
RDRP1
VDRP1
-
PHASE IC
PHSOUT
VCC
CLKIN
CLK Q
Output 1 Only
CCS RCS
-
+
CCP11
IFB1
CSIN+
+
VID6
VID6 +
IIN1
VCCH
PWM
LATCH
D
PHSIN
GATEH
CBST
S
PWM
COMPARATOR
-
EAIN
SW
RESET
DOMINANT
R
VCCL
+
GATEL
ENABLE
+
VID6
-
RAMP
DISCHARGE
CLAMP
BODY
BRAKING
COMPARATOR
+
PGND
-
SHARE ADJUST
ERROR AMPLIFIER
CURRENT
SENSE
AMPLIFIER
+
ISHARE
-
3K
-
VID6
VID6
+
CSIN+
+
VID6
VID6 +
+
CCS RCS
-
CSIN-
DACIN
Figure 5 - PWM Block Diagram
Frequency and Phase Timing Control
The oscillator is located in the Control IC and the system clock frequency is programmable from 500kHz to 9MHZ
by an external resistor. The control IC system clock signal (CLKOUT) is connected to CLKIN of all the phase ICs.
The phase timing of the phase ICs is controlled by the daisy chain loop, where control IC phase clock output
(PHSOUT) is connected to the phase clock input (PHSIN) of the first phase IC, and PHSOUT of the first phase IC is
connected to PHSIN of the second phase IC, etc. and PHSOUT of the last phase IC is connected back to PHSIN of
the control IC. During power up, the control IC sends out clock signals from both CLKOUT and PHSOUT pins and
detects the feedback at PHSIN pin to determine the phase number and monitor any fault in the daisy chain loop.
Figure 6 shows the phase timing for a four phase converter.
Page 11 of 37
June 20, 2008
IR3523
Control IC CLKOUT
(Phase IC CLKIN)
Control IC PHSOUT
(Phase IC1 PHSIN)
Phase IC1
PWM Latch SET
Phase IC 1 PHSOUT
(Phase IC2 PHSIN)
Phase IC 2 PHSOUT
(Phase IC3 PHSIN)
Phase IC 3 PHSOUT
(Phase IC4 PHSIN)
Phase IC4 PHSOUT
(Control IC PHSIN)
Figure 6 - Four Phase Oscillator Waveforms
PWM Operation
The PWM comparator is located in the phase IC. Upon receiving the falling edge of 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 after the non-overlap time. When the PWMRMP voltage exceeds the error amplifier’s output voltage, the
PWM latch is reset. This turns off the high side driver and then turns on the low side driver after the non-overlap
time; it activates the ramp discharge clamp, which quickly discharges the PWMRMP capacitor to the output voltage
of share adjust amplifier in phase 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 up to 100% duty cycle in response to a load step
increase with turn-on gated by the clock pulses. An error amplifier 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 amplifier 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 of the architecture is that differences in
ground or input voltage at the phases have no effect on operation since the PWM ramps are referenced to VDAC.
Figure 7 depicts PWM operating waveforms under various conditions.
Page 12 of 37
June 20, 2008
IR3523
PHASE IC
CLOCK
PULSE
EAIN
PWMRMP
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 FAULT)
STEADY-STATE
OPERATION
Figure 7 - PWM Operating Waveforms
Body Braking
TM
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;
TSLEW =
L * ( I MAX − I MIN )
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 +
VBODYDIODE. The minimum time required to reduce the current in the inductor in response to a load transient
decrease is now;
TSLEW =
L * ( I MAX − I MIN )
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 amplifier’s output voltage drops below
the VDAC voltage or a programmable voltage, this comparator turns off the low side gate driver.
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, as shown in Figure 8. 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 13 of 37
June 20, 2008
IR3523
vL
iL
Current
Sense Amp
L
RL
RCS
CCS
VO
CO
c
vCS
CSOUT
Figure 8 - Inductor Current Sensing and Current Sense Amplifier
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 8. Its gain is
nominally 34 at 25ºC, and the 3850 ppm/ºC increase in inductor DCR should be compensated in the voltage loop
feedback path.
The current sense amplifier can accept positive differential input up to 50mV and negative up to -10mV 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 3KΩ 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 average current through all the inductors and is used
by the control IC for voltage positioning and current limit protection.
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 average current at the share bus. If current in a phase is
smaller than the average current, the share adjust amplifier of the phase will pull down the starting point of the PWM
ramp thereby increasing its duty cycle and output current; if current in a phase is larger than the average current,
the share adjust amplifier of the phase will pull up the starting point of the PWM ramp thereby decreasing its duty
cycle and output current. The current share amplifier is internally compensated so that the crossover frequency of
the current share loop is much slower than that of the voltage loop and the two loops do not interact.
Page 14 of 37
June 20, 2008
IR3523
IR3523 THEORY OF OPERATION
Block Diagram
The Block diagram of the IR3523 is shown in Figure 3, and specific features are discussed in the following sections.
All the features are described using one output but suitable for both unless otherwise specified.
VIDx Control
The IR3523 converter outputs are independently controlled by two three-bit input interfaces (see Table 1-2): VDAC1
(VOUT1) and VDAC2 (VOUT2). The VID codes are stored and then inputted to the Digital-to-Analog Converter
(DAC) whose output is sent to the VDAC buffer amplifier. The output of the buffer amplifier is the VDAC pin.
VDAC1 will initially boot to 1.1V when Vout1 is enabled then will transition to the stored VID1 value once SS/DEL1
reached 3.0 V. The VDAC voltage, input offsets of error amplifier and remote sense differential amplifier, are postpackage trimmed to provide 0.5% system set-point accuracy. The actual VDAC voltage does not determine the
system accuracy, which has a wider tolerance. The VID pins, VID2_x and VID1_x, require an external bias voltage
and should not be floated.
The IR3523 can accept changes in the VID code while operating and vary DAC voltage accordingly. The
sink/source capability of the VDAC buffer amplifier is programmed by the same external resistor that sets the
oscillator frequency. The slew rate of the voltage at the VDAC pins can be adjusted by the external capacitors
between VDAC pins and LGND pin. A resistor connected in series with this capacitor is required to compensate the
VDAC buffer amplifiers. The stepped VID transition results in a smooth analog transition of the VDAC voltage and
converter output voltage. This analog transition minimizes inrush currents in the input (and output) capacitors and
reduces overshoot of the output voltage.
VID1_4
0
0
0
0
1
1
1
1
VID1_3
0
0
1
1
0
0
1
1
VID1_2
0
1
0
1
0
1
0
1
VDAC1
1.200
1.175
1.150
1.125
1.100
1.075
1.050
1.025
Table 1: Output (1) 3-bit VID table
VID2_2
0
0
0
0
1
1
1
1
VID2_1
0
0
1
1
0
0
1
1
VID2_0
0
1
0
1
0
1
0
1
VDAC2
1.350
1.400
1.450
1.500
1.550
1.600
1.650
1.800
Table 2: Output (2) 3-bit VID table
Page 15 of 37
June 20, 2008
IR3523
Output 1 (Vtt) Adaptive Voltage Positioning
Adaptive Voltage Positioning is needed to reduce the output voltage deviations during load transients and the power
dissipation of the load at heavy load. IR3523 only provides AVP on output1. The circuitry related to the voltage
positioning is shown in Figure 9. Resistor RFB1 is connected between the error amplifier’s inverting input pin FB1
and the remote sense differential amplifier output. An internal current source whose value is programmed by the
same external resistor that programs the oscillator frequency sinks current from the FB1 pin. The error amplifier
forces the converter’s output voltage higher to maintain a balance at its inputs. RFB1 is selected to program the
desired amount of fixed offset voltage above the DAC voltage.
The VDRP1 pin voltage is a buffered reproduction of the IIN1 pin which is connected to the current share bus
ISHARE. The voltage on ISHARE represents the system average inductor current information. At each phase IC, an
RC network across the inductor provides current information which is gained up 32.5X and then added to the
VDACX voltage. This phase current information is provided on the ISHARE bus via a 3K resistor in the phase ICs.
The VDRP1 pin is connected to the FB1 pin through the resistor RDRP1. Since the error amplifier will force the loop
to maintain FB1 to be equal to the VDAC1 reference voltage, an additional current will flow into the FB1 pin equal to
(VDRP1-VDAC1) / RDRP1. When the load current increases, the adaptive positioning voltage increases accordingly.
More current flows through the feedback resistor RFB1, and makes the output voltage lower proportional to the load
current. The positioning voltage can be programmed by the resistor RDRP1 so that the droop impedance produces
the desired converter output impedance. The offset and slope of the converter output impedance are referenced to
VDAC1 and therefore independent of the VDAC1 voltage.
Control IC
VDAC1
Phase IC
VDAC1
Current Sense
Amplifier
CSIN+
-
VDAC
+
EAOUT1
3k
+
ISHARE
Error
Amplifier
CSIN-
RDRP1
Phase IC
VDRP1
Current Sense
Amplifier
+
ISHARE
VOUT1
VDAC
+
VOSEN1+
-
Remote
Sense
Amplifier
IIN1
VOSEN1-
3k
CSIN+
-
-
+
VDRP
Amplifier
... ...
RFB1
FB1
IFB
CSIN-
Figure 9 - Adaptive voltage positioning
Page 16 of 37
June 20, 2008
IR3523
Output1 Inductor DCR Temperature Compensation
A negative temperature coefficient (NTC) thermistor can be used for Output1 inductor DCR temperature
compensation. The thermistor should be placed close to the Output1 inductors and connected in parallel with the
feedback resistor, as shown in Figure 10. The resistor in series with the thermistor is used to reduce the nonlinearity
of the thermistor.
Control IC
VDAC1
VDAC1
Error
Amplifier
+
EAOUT1
IFB
FB1
VDRP
Amplifier
+
RFB11
RFB12
Rt
RDRP1
VDRP1
IIN1
VOUT1
+
VOSEN1+
-
Remote
Sense
Amplifier
VOSEN1-
Figure 10 - Temperature compensation of Output1 inductor DCR
Remote Voltage Sensing
VOSENX+ and VOSENX- are used for remote sensing and connected directly to the load. The remote sense
differential amplifiers with high speed, low input offset, and low input bias current ensure accurate voltage sensing
and fast transient response.
Start-up Sequence
The IR3523 has a programmable soft-start function to limit the surge current during the converter start-up. A
capacitor connected between the SS/DELx and LGND pins controls soft start timing, over-current protection delay
and hiccup mode timing. A charge current of 50uA and discharge currents of 47uA and 4.5uA control the up slope
and down slope of the voltage at the SS/DEL pin respectively.
Page 17 of 37
June 20, 2008
IR3523
Figure 11 depicts the start-up sequence. If the ENABLE input is asserted and there are no faults, the SS/DELx pins
will start charging, the VID codes are read and stored. VDAC2 transitions to the stored VID code, while VDAC1
transitions to a 1.1V internal boot voltage. The error amplifier output EAOUTx is clamped low until SS/DELx reaches
1.4 V. The error amplifier will then regulate the converter’s output voltage to match the SS/DELx voltage less the
1.4 V offset until the converter VOUT2 reaches programmed VID code and VOUT1 reaches 1.1V (boot voltage).
When SS/DEL1 reaches 3.0 V, VDAC1 will transition to the stored VID1 code shifting VOUT1 to the new regulation
value. The SS/DELx voltage continues to increase until it rises above the threshold of Delay Comparator (3.93V).
The PGx output is then de-asserted (allowed to go high).
VCCL under voltage, over current, and a low signal on the ENABLE input immediately sets a fault latch, which
causes the EAOUT pin to drive low turning off the phase IC drivers. The PGx pins also drives low and SS/DELx
begin to discharge until the voltage reaches 0.2 V. If the fault has cleared, the fault latch will be reset by the
discharge comparator allowing a normal soft start to occur.
Other fault conditions, such as over voltage, open sense lines, and open daisy chain, set different fault latches,
which start discharging SS/DELx, pull down EAOUTx voltage and drive PG low. However, the latches can only be
reset by cycling VCCL power (see Table 3).
If SS/DELx pins are pulled below 0.6V, the converter can be disabled.
VCC
(12V)
ENABLE
VID1_x
READ & STORE
VID On-Hold
VID
TANSITION
VID2_x
READ & STORE
VID On-Hold
VID
TRANSITION
VIDx set voltage
VID2 Voltage
1.1V boot (Vout1)
0.5V
0.5V
VID1 Voltage
VDACx
4.0V
3.92V
3.0V
1.4V
SS/DELx
EA2
EA1
VOUT2 (No Vboot)
EAOUTx
1.1V Boot
(Vout1 ONLY)
VOUT1 = VID1
VOUTX
PGx
START
DELAY
STARTUP
TIME
VID ON
THE FLY
PROCESSION
NORMAL
OPERATION
Shutdown
Figure 11 - Start-up Sequence Transition
Page 18 of 37
June 20, 2008
IR3523
Over-Current Hiccup Protection after Soft Start
The over current limit threshold is set by a resistor connected between OCSETx and VDACx pins. Figure 12 shows
the hiccup over-current protection with delay after PGx is asserted. The delay is required since over-current
conditions can occur as part of normal operation due to load transients or VID transitions.
If the IINx pin voltage, which is proportional to the average current plus VDACx voltage, exceeds the OCSETx
voltage after PGx is asserted, it will initiate the discharge of the capacitor at SS/DELx through the discharge current
47uA. If the over-current condition persists long enough for the SS/DELx capacitor to discharge below the 120mV
offset of the delay comparator, a fault latch will be set pulling the error amplifier’s output low and inhibiting switching
in the phase ICs and de-asserting the PGx signal. The SS/DEL capacitor will then continue to discharge through a
4.7uA discharge current until it reaches 200 mV, and the fault latch is reset allowing a normal soft start to occur.
The output current is not controlled during the delay time. If an over-current condition is again encountered during
the soft start cycle, the over-current action will repeat and the converter will be in hiccup mode.
ENABLE
SS/DEL
4.0V
3.92V
3.88V
1.1V
EA
VOUT
VRRDY
OCP THRESHOLD
IOUT
START-UP WITH
OUTPUT SHORTED
HICCUP OVER-CURRENT
PROTECTION (OUTPUT
SHORTED)
NORMAL
START-UP
OCP
DELAY
OVER-CURRENT
NORMAL
NORMAL
PROTECTION
START-UP OPERATION POWER-DOWN
(OUTPUT SHORTED)
(OUTPUT
NORMAL
OPERATION SHORTED)
Figure 12 - Hiccup over-current waveforms
Linear Regulator Output (VCCL)
The IR3523 has a built-in linear regulator controller, and only an external NPN transistor is needed to create a
linear regulator. The output voltage of the linear regulator can be programmed between 4.75V and 7.5V by the
resistor divider at VCCLFB pin. The regulator output powers the gate drivers and other circuits of the phase ICs
along with circuits in the control IC, and the voltage is usually programmed to optimize the converter efficiency. The
linear regulator can be compensated by a 4.7uF capacitor at the VCCL pin. As with any linear regulator, due to
stability reasons, there is an upper limit to the maximum value of capacitor that can be used at this pin and it’s a
function of the number of phases used in the multiphase architecture and their switching frequency. Figure 13
shows the stability plots for the linear regulator with 5 phases switching at 750 kHz.
Page 19 of 37
June 20, 2008
IR3523
Figure 13 - VCCL regulator stability with 5 phases and PHSOUT equals 750 kHz
VCCL Under Voltage Lockout (UVLO)
The IR3523 has no under voltage lockout protection for the converter input voltage (VCC), but monitors the VCCL
voltage instead. The VCCL is used to power both the control IC and phase ICs including the phase ICs internal gate
drivers. During power up, the UVLO fault latch will be reset if VCCL is above 94% of the voltage set by resistor
divider at VCCLFB pin. If VCCL voltage drops below 86% of the set value, the UVLO fault latch will be set.
Power Good (PG1, 2)
The PGx pin is an open-collector output and should be pulled up to a voltage source through a resistor. During soft
start, the PGx remains low until the output voltage is in regulation and SS/DELx is above 3.93V. The PGx pin
becomes low if any of the fault latches are triggered (See Table 3).
PGx monitors the output voltage. If any of the voltage planes fall out of regulation, PGx will become low, but the VR
will continue to attempt to regulate the output voltages. Output voltage out of spec is defined as 315mV to 275mV
below nominal voltage. VID on-the-fly transition, which is a voltage plane transitioning between two different VID
codes, is not considered to be out of specification.
A high level at the PGx pins indicates that the converter is in operation with no fault and ensures the output voltage
is within the regulation.
The PG outputs derive power from either VCCL or VCCLDRV to ensure they can assert with input voltage as low as
possible.
Open Control Loop Detection
The error amplifier’s output voltage is monitored to ensure the control loop is in regulation. If any fault condition
forces the error amplifier output above VCCL-1.08 V for 8 switching cycles, the Open Control Loop fault latch is set.
This fault latch can only be cleared by cycling power to VCCL.
Load Current Indicator Output
The VDRP pin voltage represents the average current of the converter plus the VDAC1 voltage. The load current
information can be retrieved by using a differential amplifier to subtracts the VDAC1 voltage from the VDRP1
voltage.
Page 20 of 37
June 20, 2008
IR3523
Enable Input
Pulling the ENABLE pin below 1.0 V sets the Fault Latch. Forcing ENABLE to a voltage above 1.65V results in the
3-bit VID codes to be read and stored. SS/DELX pins are also allowed to begin their power-up cycles as long as no
fault conditions are present.
Over Voltage Protection (OVP)
Output over-voltage might occur due to a high side MOSFET short or if the output voltage sense path is
compromised. If the over-voltage protection comparators sense that either VOUTX pin voltage exceeds VDACX by
125mV, the over voltage fault latch is set which pulls the error amplifier output low turning off both converters power
stage. The IR3523 communicates an OVP condition to the system by raising the ROSC pin voltage to within
V(VCCL) – 1.2 V. An OVP condition is also communicated to the phase ICs by forcing the IIN pin (which is tied to
the ISHARE bus and ISHARE pins of the phase ICs) to VCCL as shown in Figure 14. In each phase IC, the OVP
circuit overrides the normal PWM operation to ensure the low side MOSFET turn-on within approximately 130ns.
The low side MOSFET will remain on until the ISHARE pins fall below V(VCCL) - 800mV. An over voltage fault
condition is latched in the IR3523 and can only be cleared by cycling the power to VCCL.
During dynamic VID down at light to no load, false OVP triggering is prevented by increasing the OVP threshold to a
fixed 1.2 V (VOUT1) and 1.8 V (VOUT2) whenever a dynamic VID is detected and the difference between output
voltage and the fast internal VDAC is more than 50mV, as shown in Figure 15. The over-voltage threshold is
changed back to VDAC+125mV if the difference between output voltage and the fast internal VDAC is less than
50mV.
The overall system must be considered when designing for OVP. In many cases the over-current protection of the
AC-DC or DC-DC converter supplying the multiphase converter will be triggered thus providing effective protection
without damage as long as all PCB traces and components are sized to handle the worst-case maximum current. If
this is not possible, a fuse can be added in the input supply to the multiphase converter.
OUTPUT
VOLTAGE
(Vout)
OVP
THRESHOLD
VCCL-800 mV
IIN
(PHASE IC
ISHARE)
GATEH
(PHASE IC)
GATEL
(PHASE IC)
FAULT
LATCH
ERROR
AMPLIFIER
OUTPUT
(EAOUT)
VDAC
NORMAL OPERATION
OVP CONDITION
AFTER
OVP
Figure 14 - Over-voltage protection during normal operation
Page 21 of 37
June 20, 2008
IR3523
VID
VDAC
1.73V
OV
THRESHOLD
VDAC + 130mV
OUTPUT
VOLTAGE
(VO)
VDAC
50mV
50mV
NORMAL
OPERATION
VID DOWN
LOW VID
VID UP
NORMAL
OPERATION
Figure 15 - Over-voltage protection during dynamic VID
Open Remote Sense Line Protection
If either remote sense line VOSENX+ or VOSENX- is open, the output of Remote Sense Amplifier (VOUTX) drops.
The IR3523 continuously monitors the VOUTX pin and if VOUTX is lower than 200 mV, two separate pulse currents
are applied to the VOSENX+ and VOSENX- pins to check if the sense lines are open. If VOSENX+ is open, a voltage
higher than 90% of V(VCCL) will be present at VOSENX+ pin and the output of Open Line Detect Comparator will
be high. If VOSENX- is open, a voltage higher than 400mV will be present at VOSENX- pin and the Open Line
Detect Comparator output will be high. With either sense line open, the Open Sense Line Fault Latch will be set to
force the error amplifier output low and immediately shut down the converter. SS/DELX will be discharged and the
Open Sense Fault Latch can only be reset by cycling the power to VCCL.
Open Daisy Chain Protection
IR3523 checks the daisy chain every time it powers up. It starts a daisy chain pulse on the PHSOUT pin and
detects the feedback at PHSIN pin. If no pulse comes back after 32 CLKOUT pulses, the pulse is restarted again. If
the pulse fails to come back the second time, the open daisy chain fault is registered, and SS/DEL is not allowed to
charge. The fault latch can only be reset by cycling the power to VCCL.
After powering up, the IR3523 monitors PHSIN pin for a phase input pulse equal or less than the number of phases
detected. If PHSIN pulse does not return within the number of phases in the converter, another pulse is started on
PHSOUT pin. If the second started PHSOUT pulse does not return on PHSIN, an open daisy chain fault is
registered.
Phase Number Determination
After a daisy chain pulse is started, the IR3523 checks the timing of the input pulse at PHSIN pin to determine the
phase number.
Page 22 of 37
June 20, 2008
IR3523
The Fault Table below describes ten different faults that can occur during normal operation and how the IR3523 IC
will react to protect the supply and the load from possible damage. The fault types that can occur are listed in row
one. Row two and three describes the type and the method of clearing the faults, respectively. The first four faults
are latched in the UV fault and require the VCCL supply to be recycled (below UVLO threshold) to regain operation.
The rest of the faults, except for UVLO Vout, are latched in a SS fault which do not need VCCL supply recycled, but
instead will automatically resume operation when these fault conditions are no longer impinging on the system.
Most of the faults will disable the error amplifier (EA) and discharge the soft start capacitor. All of the faults flag
PGood. PGood returns to high impedance state (high) when the fault clears. The Delay row shows reaction time
after detecting a fault condition. Delays are provided to minimize the possibility of nuisance faults. Additional flagged
responses are used to communicate externally of a fault event (Over Voltage) so additional action can be taken.
System Fault Table
Fault
Type
Latch
Fault
Clearing
Method
Outputs
Affected
Error
Amp
Disables
SS/DELx
Discharge
Flags
PGood
Delays
Open
Daisy
Open
Sense
Open
Control
UV Latch
Over Voltage
Disable
Recycle VCCL
Both
Single
UVLO
OC
(VCCL)
Before
SS Latch
OC
After
SS discharge below 0.2V
Both
Both
Both
UVLO
(Vout)
No
No
Single
Single
Yes
No
Yes
No
Yes
32
Clock
Pulses
No
8
PHSOUT
Pulses
No
250ns
Blanking
Time
Yes,
Additional
IINx and Rosc pins
Flagged
No
pulled-up to VCCL**
Response
* Pulse number range depends on Rosc value selected (See Specifications Table)
** Clears when OV condition ends
No
PHSOUT
Pulses*
SS/DELx
Discharge
Threshold
No
Table 3 - IR3523 system fault responses
Page 23 of 37
June 20, 2008
No
IR3523
APPLICATIONS INFORMATION
P12V_DDR3_FILTED
Q16
VCCL
C131
R55
R54
C135
C136
R56
C379
NC2
13
1
2
6
7
VCC
GATEL
PGND
VCCL
12
Q27
VTT_SEN+
5
VTT_SEN+
1
2 3
6 4
7
11
10 C186
1
2
VTT+
L30
9
Q28
C187
5
C188
R100
COUT
3
4
CSIN+
15
14
SW
VCCL
8
25
24
CSIN-
16
PHSIN
26
C182
C244
IR3505
PHASE GATEH
BOOST
IC
CLKIN
R67
4
PHSOUT
27
VTT_VRRDY
LGND
7
28
VTT-
C138
C374
R69
23
VTT_SEN-
VTT_SEN-
22 R71
VDAC_VTT
21
41
No Stuf f
C142
R72
R73
R78
R77
C381
DACIN
3
6
EAIN
PAD
ISHARE
2
VDAC_VTT
29
20
FB1
VOUT1
VOSEN1+
EAOUT1
19
18
EAOUT2
1
30
5
CLKOUT
31
32
33
34
VCCL
PHSIN
PHSOUT
37
38
39
35
VCCLFB
VCCLDRV
PG2
OCSET1
11
C380
R75
VID2_0
VDAC1
OCSET2
17
10
IIN1
SS/DEL1
VDAC2
NC1
R70
VDRP1
SS/DEL2
VOSEN1-
9
VDAC_VDDR3
IIN2
16
8
ROSC/OVP
IR3523
CONTROL
IC
ENABLE1
VOSEN2-
7
ENABLE2
15
R68
PG1
WOSEN2+
C378
VID1_2
14
6
C137
C139
VID2_1
40
5
ENABLE_VTT
R66
NC3
LGND
VOUT2
4
ENABLE_DDR3
P12V_CPU_FILTED
U71
VID1_3
FB2
3
VID1_4
13
2
12
1
VID2_2
U1
VID_VTT_4
VID_VTT_3
VID_VTT_2
36
R65
VDDR3_VRRDY
VID_DDR3_0
VID_DDR3_1
VID_DDR3_2
R76
P12V_DDR3_FILTED
C377
C376
EA_VDDR3
R244
C192
C375
R80
R243
EA_VDDR3
1
2
6
7
VCC
16
DACIN
LGND
PHSIN
GATEH
BOOST
VCCL
NC2
15
Q30
14
C194
R92
VTT_SEN+
5
13
12
VCCL
VDDR3_SEN+
L24
3
4
19
17
18
CSIN-
SW
IR3508
PHASE
IC
PSI
1
2
VDDR3+
C189
11
C191
Q29
COUT
5
10
9
8
7
6
3
4
NC1
5
IOUT
1
2
6
7
4
C193
GATEL
3
PGND
2
PSI_PH5
VDAC_VDDR3
CLKIN
1
VDDR3_SEN-
PHSOUT
VDDR3_SEN+
CSIN+
VTT_SEN-
EAIN
NC3
U74
20
C197
VTT_SEN+
VDDR3VTT_SEN-
VDDR3_SEN-
P12V_DDR3_FILTED
EA_VDDR3
LGND
1
2
6
7
BOOST
VCCL
NC2
15
Q32
14
12
C203
R93
5
13
L25
3
4
17
16
VCC
CSIN-
CSIN+
18
19
PHSIN
GATEH
VCCL
1
2
1
2
6
7
DACIN
C198
11
C200
Q31
5
10
9
8
7
6
3
4
NC1
5
SW
IR3508
PHASE
IC
PSI
GATEL
4
C202
IOUT
PGND
3
CLKIN
2
PHSOUT
1
PSI_PH5
VDAC_VDDR3
EAIN
NC3
20
C205
U79
P12V_DDR3_FILTED
C210
EA_VDDR3
LGND
PHSIN
1
2
6
7
VCC
BOOST
VCCL
12
C212
R94
5
13
L27
VCCL
1
2
C207
11
C209
Q33
5
17
10
9
8
7
6
3
4
NC2
Q34
14
3
4
CSIN-
19
18
16
GATEH
15
1
2
6
7
DACIN
NC1
5
SW
IR3508
PHASE
IC
PSI
GATEL
4
C211
IOUT
PGND
3
CLKIN
VDAC_VDDR3
2
CSIN+
NC3
PSI_PH5
PHSOUT
1
EAIN
20
C214
U80
Figure 16 - IR3523 \ IR3508 Three Phases VDDR3 and a Single Phase (IR3505) Vtt One Phase Converter
Page 24 of 37
June 20, 2008
IR3523
DESIGN PROCEDURES - IR3523 AND IR3505 CHIPSET
IR3523 EXTERNAL COMPONENTS
All the output components are selected using one output but suitable for both unless otherwise specified.
Oscillator Resistor Rosc
The IR3523 generates square-wave pulses to synchronize the phase ICs. The switching frequency of the each
phase converter equals the PHSOUT frequency, which is set by the external resistor RROSC, use Figure 2 to
determine the RROSC value. The CLKOUT frequency equals the switching frequency multiplied by the phase
number.
Soft Start Capacitor CSS/DEL
The Soft Start capacitor CSS/DEL programs four different time parameters, soft start delay time, soft start time,
PGx delay time and over-current fault latch delay time after PGx.
SS/DELx pin voltage controls the slew rate of the converter output voltage, as shown in Figure 10. Once the
ENABLE pin rises above 1.65V, there is a soft-start delay time TD1 during which SS/DEL pin is charged from
zero to 1.4V. Once SS/DEL reaches 1.4V, the error amplifier output is released to allow the soft start. The soft
start time, TD2, represents the time during which converter voltage rises from zero to VID2 or VOUT1’s boot
voltage (1.1V). The SS/DELx pins voltage rises from 1.4V to VID2 (or VOUT1 boot) plus 1.4V. Power good delay
time, TD3, is the time period from between where VR reaches the VID voltage and PGx signal assertion.
Calculate CSS/DEL based on the required soft start time TD2.
C SS / DEL =
TD 2 * I CHG TD 2 * 50 * 10 −6
=
VID
VID
(1)
The soft start delay time TD1 and VR ready delay time TD3 are determined by equation (2) and (3) respectively.
TD1 =
C SS / DEL * 1.4 C SS / DEL * 1.4
=
I CHG
50 * 10 −6
TD3 =
C SS / DEL * (3.93 − VID − 1.4) C SS / DEL * (3.93 − VID − 1.4)
=
I CHG
50 * 10 − 6
(2)
(3)
Once CSS/DEL is chosen, use equation (4) to calculate the maximum over-current fault latch delay time tOCDEL.
t OCDEL = 2.5 ∗
C SS / DEL * 0.12
C
* 0.12
= 2.5 ∗ SS / DEL −6
I DISCHG
47 * 10
(4)
Due to the exponential turn-on slope of the discharge current (47uA), a correction factor (X2.5) is added to the
equation (4) to accurately predict over-current delay time.
Page 25 of 37
June 20, 2008
IR3523
VDAC Slew Rate Programming Capacitor CVDAC and Resistor RVDAC
The slew rate of VDACx down-slope SRDOWN can be programmed by the external capacitor CVDAC as defined in
(5), where ISINK is the sink current of VDAC pin. The slew rate of VDAC up-slope is three times greater that of
down-slope. The resistor RVDAC is used to compensate VDAC circuit and is determined by (6).
CVDAC =
I SINK
SR DOWN
RVDAC = 0.5 +
3.2 ∗ 10 −15
CVDAC 2
(5)
(6)
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/°C, and therefore the maximum inductor DCR can be calculated from (7),
where RL_MAX and RL_ROOM are the inductor DCR at maximum temperature TL_MAX and room temperature
TL_ROOM respectively.
RL _ MAX = RL _ ROOM ∗ [1 + 3850 *10−6 ∗ (TL _ MAX − TL _ ROOM )]
(7)
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 current flowing through the current
sense resistor RCS.
VCS _ TOFST = VCS _ OFST + I CSIN + ∗ RCS
(8)
The over current limit is set by the external resistor ROCSET as defined in (9). ILIMIT is the required over current
limit. IOCSET is the bias current of OCSET pin and can be calculated with the equation in the ELECTRICAL
CHARACTERISTICS Table. GCS is the gain of the current sense amplifier. KP is the ratio of inductor peak current
over average current in each phase and can be calculated from (10).
ROCSET = [
KP =
I LIMIT
∗ RL _ MAX ∗ (1 + K P ) + VCS _ TOFST ] ∗ GCS / I OCSET
n
(VI − VO ) ∗ VO /( L ∗ VI ∗ f SW ∗ 2)
IO / n
(9)
(10)
VCCL Programming Resistor RVCCLFB1 and RVCCLFB2
Since VCCL voltage is proportional to the MOSFET gate driver loss and inversely proportional to the
MOSFET conduction loss, the optimum voltage should be chosen to maximize the converter efficiency. VCCL
linear regulator consists of an external NPN transistor, a ceramic capacitor and a programmable resistor
divider. Pre-select RVCCLFB1, and calculate RVCCLFB2 from (11).
RVCCLFB 2 =
Page 26 of 37
RVCCLFB1 *1.23
VCCL − 1.23
(11)
June 20, 2008
IR3523
No Load Offset Setting Resistor RFB11, RFB13, RTHERM1 and Adaptive Voltage Positioning Resistor
RDRP11 for Output1
Define RFB_R is the effective offset resistor at room temperature equals to RFB11//(RFB13+RTHERM1). Given the
offset voltage VO_NLOFST above the DAC voltage, calculate the sink current from the FB1 pin IFB1 using the
equation in the ELECTRICAL CHARACTERISTICS Table, then the effective offset resistor value RFB1 can be
determined from (12).
RFB _ R =
VO _ NLOFST
(12)
I FB1
Adaptive voltage positioning lowers the converter voltage by RO*IO, where RO is the required output impedance of
the converter. Pre-select feedback resistor RFB, and calculate the droop resistor RDRP,
RDRP11 =
RFB _ R ∗ RL _ ROOM * GCS
(13)
n ∗ RO
Calculate the desired effective feedback resistor at the maximum temperature RFB_M using (14)
RFB _ M =
RDRP11 ∗ RO * n
GCS ∗ RL _ MAX
(14)
A negative temperature constant (NTC) thermistor RTHERM1 is required to sense the temperature of the power
stage for the inductor DCR thermal compensation. Pre-select the value of RTHERM. RTHERM must be bigger than
RFB_R at room temperature but also bigger than RFB_M at the maximum allowed temperature. RTMAX1 is defined
as the NTC thermistor resistance at maximum allowed temperature, TMAX. RTMAX1 is calculated from (15).
RTMAX 1 = RTHERM 1 * EXP[ BTHERM 1 * (
1
TL _ MAX
−
1
T _ ROOM
(15)
)]
Select the series resistor RFB13 by using equation (16). RFB13 is incorporated to linearize the NTC thermistor
which has non-linear characteristics in the operational temperature range.
R FB 13 =
( RTHERM 1 + RTMAX 1 ) 2 − 4 * ( RTHERM 1 * RTMAX 1 − ( RTHERM 1 − RTMAX 1 ) * R FB _ R * R FB _ M /( R FB _ R − R FB _ M )) − ( RTHERM 1 + TTMAX 1 )
2
Use equation (17) to determine RFB11.
1
RFB11
Page 27 of 37
=
1
RFB _ R
−
1
RFB13 + RTHERM 1
(17)
June 20, 2008
(16)
IR3523
VOLTAGE LOOP COMPENSATION
The adaptive voltage positioning (AVP) is usually adopted 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.
Adaptive voltage positioning lowers the converter voltage by RO*IO, where RO is the required output impedance of
the converter.
The selection of compensation types depends on the output capacitors used in the converter. For the applications
using Electrolytic, Polymer or AL-Polymer capacitors and running at lower frequency, type II compensation shown
in Figure (a) is usually enough. While for the applications using only ceramic capacitors and running at higher
frequency, type III compensation shown in Figure 21(b) is preferred.
For applications where AVP is not required, the compensation is the same as for the regular voltage mode
control. For converter using Polymer, AL-Polymer, and ceramic capacitors, which have much higher ESR zero
frequency, type III compensation is required as shown in Figure 21(b) with RDRP and CDRP removed.
CCP1
CCP1
RFB
RCP
CCP
VO+
RCP
CCP
RFB1
CFB
FB
-
RFB
VO+
FB
EAOUT
-
RDRP
EAOUT
RDRP
VDAC
VDRP
+
(a) Type II compensation
EAOUT
VDAC
VDRP
EAOUT
+
CDRP
(b) Type III compensation
Figure 17 - Voltage loop compensation network
Type II Compensation for AVP Applications
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, and determine RCP and CCP from (23) and (24), where LE and
CE are the equivalent inductance of output inductors and the equivalent capacitance of output capacitors
respectively.
(2π ∗ fC ) 2 ∗ LE ∗ CE ∗ RFB ∗ 5
(23)
RCP =
VI * 1 + ( 2π * fC * C * RC ) 2
CCP =
10 ∗ LE ∗ C E
RCP
(24)
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.
Page 28 of 37
June 20, 2008
IR3523
Type III Compensation for AVP Applications
Determine the compensation at no load, the worst case condition. Assume the time constant of the resistor and
capacitor across the output inductors matches that of the inductor, the crossover frequency and phase margin of
the voltage loop can be estimated by (25) and (26), where RLE is the equivalent resistance of inductor DCR.
f C1 =
RDRP
2π * CE ∗ GCS * RFB ∗ RLE
θ C1 = 90 − A tan(0.5) ∗
(25)
180
(26)
π
Choose the desired crossover frequency fc around fc1 estimated by (25) or choose fc between 1/10 and 1/5 of
the switching frequency per phase, and select the components to ensure the slope of close loop gain is -20dB
/Dec around the crossover frequency. Choose resistor RFB1 according to (27), and determine CFB and CDRP from
(28) and (29).
1
R FB
2
R FB1 =
CFB =
R FB1 =
to
2
R FB
3
1
(28)
4π ∗ fC ∗ RFB1
C DRP =
(27)
( R FB + R FB1 ) ∗ C FB
R DRP
(29)
RCP and CCP have limited effect on the crossover frequency, and are used only to fine tune the crossover
frequency and transient load response. Determine RCP and CCP from (30) and (31).
RCP =
CCP =
(2π ∗ fC ) 2 ∗ LE ∗ CE ∗ RFB ∗ 5
VI
10 ∗ LE ∗ C E
(30)
(31)
RCP
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 for Non-AVP Applications
Resistor RDRP and capacitor CDRP are not needed. Choose the crossover frequency fc between 1/10 and 1/5 of
the switching frequency per phase and select the desired phase margin θc. Calculate K factor from (32), and
determine the component values based on (33) to (37),
π
θ
K = tan[ ∗ ( C + 1.5)]
4 180
RCP = RFB ∗
( 2π ∗ LE ∗ CE ∗ fC ) 2 ∗ 5
VI ∗ K
(32)
(33)
CCP =
K
2π ∗ fC ∗ RCP
(34)
CCP1 =
1
2π ∗ fC ∗ K ∗ RCP
(35)
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IR3523
CFB =
R FB1 =
K
2π ∗ fC ∗ RFB
1
2π ∗ f C ∗ K ∗ C FB
(36)
(37)
CURRENT SHARE LOOP COMPENSATION
The internal compensation of current share loop ensures that crossover frequency of the current share loop is at least
one decade lower than that of the voltage loop so that the interaction between the two loops is eliminated.
DESIGN EXAMPLE – THREE PHASE (DDR) AND ONE PHASE (VTT) CONVERTER
(FIGURE 16)
SPECIFICATIONS:
Input Voltage: VI = 12 V
DAC1 Voltage: VDAC1 = 1.22 V
DAC2 Voltage: VDAC2 = 1.5 V
No Load Output Voltage Offset for output1: VO_NLOFST = 20 mV
Output1 Current: IO1 = 28A DC
Output2 Current: IO2 = 85A DC
Output1 Over Current Limit: Ilimit1 =42A DC
Output2 Over Current Limit: Ilimit2 = 125A DC
Output1 Impedance: RO1 = 6.0 mΩ
Dynamic VID Slew Rate Rise: SR = 3.25mV/uS
Over Temperature Threshold: TMAX = 110 ºC
POWER STAGE:
Phase Number: n1 = 1, n2 = 3
Switching Frequency: fSW = 750 kHz
Output Inductors: L1 = 150 nH, L2 = 90nH, RL1 = 0.47mΩ, RL2 = 0.47mΩ
Output Capacitors: Ceramics, C = 22uF, RC = 1.5 mΩ, Number Cn1 = 15, Cn2 = 6
Output Capacitors: Ceramics, C = 10uF, RC = 1 mΩ, Number Cn1 = 0, Cn2 = 70 (10 per DIMM)
Oscillator Resistor RROSC
Once the switching frequency is chosen, RROSC can be determined from Figure 2. For switching frequency of 750
kHz per phase, choose ROSC = 15.8 kΩ.
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Soft Start Capacitor CSS/DEL
Determine the soft start capacitor from the required soft start time.
TD 2 * I CHG 2 * 10 −3 * 50 * 10 −6
=
= 0.1uF
Vboot
1.1
TD 2 * I CHG 2 * 10 −3 * 50 * 10 −6
C SS / DEL 2 =
=
= 0.1uF
VID 2
1.5
C SS / DEL 1 =
The soft start delay time is
TD1 =
C SS / DEL * 1.4 0.1 * 10 −6 * 1.4
=
= 2.8mS
I CHG
50 * 10 −6
The power good delay time is
C SS / DEL1 * (3.93 − Vboot − 1.4) 0.1 * 10 −6 * (3.93 − 1.1 − 1.4)
TD3(1) =
=
= 2.9mS
I CHG
50 * 10 − 6
TD3( 2) =
C SS / DEL 2 * (3.92 − VID 2 − 1.4) 0.1 * 10 −6 * (3.92 − 1.5 − 1.4)
=
= 2.0mS
I CHG
50 * 10 − 6
The maximum over current fault latch delay time is
t OCDEL = 2.5 *
C SS / DEL * 0.12
0.1 * 10 −6 * 0.12
= 2.5 *
= 0.638mS
I DISCHG
47 * 10 −6
VDAC Slew Rate Programming Capacitor CVDAC and Resistor RVDAC
CVDAC =
I Source
113 ∗ 10 −6
=
= 34.7 nF , Choose CVDAC = 33nF
SR DOWN 3.25 * 10 3
RVDAC = 0.5 +
3.2 ∗ 10 −15
CVDAC
2
= 3.3Ω
Over Current Setting Resistor ROCSET
The output1 over current limit is 42A and the output2 over current limit is 125A. The OCSET bias current
calculates out to be 38uA with ROSC = 15.8 kΩ (see Electrical Characteristics Table). The total current sense
amplifier input offset voltage is typically 0mV. KP, the ratio of inductor peak current over average current in each
phase, is calculated with the following equations:
(V I − VO ) ∗ VO /( L ∗ V I ∗ f SW ∗ 2) (12 − 1.22) ∗ 1.22 /(150 * 10 −9 ∗ 12 ∗ 750 * 10 3 ∗ 2)
K P1 =
=
= 0.156
I LIMIT / n
42 / 1
KP 2 =
(12 − 1.5) ∗ 1.5 /(90 * 10 −9 ∗ 12 ∗ 750 * 10 3 ∗ 2)
= 0.23 .
41.6
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IR3523
The over current set resistor (Rocset) can be calculated as follows:
ROCSET 1 = [
=(
42
∗ 0.52 * 10 − 3 ∗ 1.156 ) * 32.5 /(38 * 10 − 6 ) = 21.6 kΩ ,
1
ROCSET 2 = [
=(
I LIMIT
∗ R L ∗ (1 + K P ) + VCS _ TOFST ] ∗ G CS / I OCSET ,
n
I LIMIT
∗ RL ∗ (1 + K P ) + VCS _ TOFST ] ∗ GCS / I OCSET ,
n
125
∗ 0.47 * 10 − 3 ∗ 1.23) * 32.5 /(38 * 10 − 6 ) = 20.6 kΩ .
3
VCCL Programming Resistor RVCCLFB1 and RVCCLFB2
Choose VCCL=7V to maximize the converter efficiency. Pre-select RVCCLFB1=20kΩ, and calculate RVCCLFB2.
RVCCLFB 2 =
RVCCLFB1 *1.23 20 *103 *1.23
=
= 4.26kΩ
VCCL − 1.23
7 − 1.23
No Load Offset Setting Resistor RFB11 and Adaptive Voltage Positioning Resistor RDRP11 for
Output1
Given the desired offset voltage (VO_NLOFST) and calculating the FB1 sink current using the equation in the
ELECTRICAL CHARACTERISTICS Table, the effective offset resistor value RFB11 can be determined by:
R FB11 =
VO _ NLOFST
I FB1
=
20 * 10 −3
= 526Ω = 523Ω (Actual Value).
38 * 10 −6
Adaptive voltage positioning lowers the converter voltage by RO*IO, where RO is the required output impedance of
the converter. RDRP11 is calculated with the following equation:
R DRP11 =
R FB11 ∗ R L _ ROOM * GCS
n ∗ RO
=
523 * 0.47 * 10 −3 * 32.5
= 1.33KΩ .
1 * 6 * 10 −3
In the case of thermal compensation is required, use equation (14) to (17) to select the RFB network resistors.
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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 VCCL decoupling capacitor VCCL as close as possible to VCCL and LGND pins.
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, and CSS/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, VO 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.
Avoid analog control bus signals, VDAC, IIN, and especially EAOUT, crossing over the fast transition nodes.
Separate digital bus, CLKOUT, PHSOUT and PHSIN from the analog control bus and other compensation
components.
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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 + 0.3 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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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.
• 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 or plugged from bottom boardside with solder resist.
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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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PACKAGE INFORMATION
O
O
40L MLPQ (6 X 6 MM BODY) ΘJA = 18 C/W, ΘJC = 0.5 C/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
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June 20, 2008