US3022
4-1
Rev. 1.0
11/2/99
TYPICAL APPLICATION
TYPICAL APPLICATION
DESCRIPTION
DESCRIPTION
The US3022 is the first controller IC with five controller in
one package specifically designed to meet Intel specifi-
cation for next generation microprocessor applications
requiring multiple on board regulators . The US3022 pro-
vides a single chip controller IC for the Vcore , 4
LDO controllers, one with the automatic select pin
that connects to the TYPE DETECT pin of the AGP
slot for the AGP Vddq supply, one for GTL+ , the
other for the 1.8V chip set regulator as well as 2.5V
for the clock as required for the next generation
PC applications. The US3022 typically uses Bipolar
transistors for Vout3(1.5V) and Vout4(1.8V) and Vout5
however if Vaux pin is connected to 12V, then
MOSFETs can also be used as external pass ele-
ments. No external resistor divider is necessary for
any of the regulators. The switching regulator feature
a patented topology that in combination with a few ex-
ternal components as shown in the typical application
circuit ,will provide well in excess of 20A of output cur-
rent for an on- board DC/DC converter while automati-
cally providing the right output voltage via the 5 bit inter-
nal DAC .The US3022 also features, loss less current
sensing for both switcher by using the Rds-on of
the high side Power MOSFET as the sensing resis-
tor, an output under voltage shutdown that detects
short circuit condition for the linear outputs and
latches the system off, and a Power Good window
comparator that switches its open collector output low
when any one of the outputs is outside of a pre pro-
grammed window.
Provides Single Chip Solution for Vcore,
GTL+ ,AGP Bus, 1.8V , 2.5V
Automatic Voltage Selection for AGP slot's
Vddq supply
4 Linear regulator controller on board to
achieve lowest system cost solution
Standby Vref provides reference for the ACPI
regulators
Designed to meet Intel Latest VRM specifica-
tion for next generation micrprocessors
On board DAC programs the output voltage
from 1.3V to 2.05V
On board resistor dividers provides lowest
component count
Loss less Short Circuit Protection for all
outputs
Synchronous operation allows maximum
efficiency
Patented architecture allows fixed frequency
operation as well as 100% duty cycle during
dynamic load
Soft Start
High current totem pole driver for direct
driving of the external Power MOSFET
Power Good function Monitors all Outputs
OVP Circuitry Protects the Switcher Output
and generates a Fault output
PACKAGE ORDER INFORMATION
PACKAGE ORDER INFORMATION
PRELIMINARY DATASHEET
FEATURES
FEATURES
4 BIT PROGRAMMABLE SYNCHRONOUS BUCK
PLUS FOUR LDO CONTROLLER
APPLICATIONS
APPLICATIONS
Total Power Soloution for Next Generation Intel
Processor application
Ta (
C) Device Package
0 TO 70 US3022CW 28 pin Plastic SOIC WB
3022app3-1.0
LINEAR
CONTROL
LINEAR
CONTROL
SWITCHER
CONTROL
US3022
Vout3
5V
Vout1
Vout4
LINEAR
CONTROL
Vout2
3.3V
LINEAR
CONTROL
Vout5
4-2
Rev. 1.0
11/2/99
US3022
ELECTRICAL SPECIFICATIONS
ELECTRICAL SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS
ABSOLUTE MAXIMUM RATINGS
V5 supply Voltage ........................................... 7V
V12 Supply Voltage ............................................ 20V
Storage Temperature Range ................................. -65 TO 150
C
Operating Junction Temperature Range .......... 0 TO 125
C
PACKAGE INFORMATION
PACKAGE INFORMATION
28 PIN WIDE BODY PLASTIC SOIC (W)
JA
=80
C/W
Unless otherwise specified ,these specifications apply over ,V12 = 12V, V5 = 5V and Ta=0 to 70
C. Typical values
refer to Ta =25
C. Low duty cycle pulse testing are used which keeps junction and case temperatures equal to the
ambient temperature.
PARAMETER
SYM
TEST CONDITION
MIN
TYP
MAX
UNITS
Supply UVLO Section
UVLO Threshold-12V
Supply ramping up
10
V
UVLO Hysterises-12V
0.6
V
UVLO Threshold-5V
Supply ramping up
4.4
V
UVLO Hysterises-5V
0.3
V
Supply Current
Operating Supply Current
V12
6
mA
V5
30
Switching Controllers; Vcore (Vsen 1) and AGP (Vsen 2)
VID Section (Vcore only)
DAC output voltage (note 1)
0.99Vs
Vs
1.01Vs
V
DAC Output Line Regulation
0.1
%
DAC Output Temp Variation
0.5
%
VID Input LO
0.8
V
VID Input HI
2
V
VID input internal pull-up
resistor to V5
27
k
Vsen2 Voltage
Select<0.8V
1.5
V
Select>2V
3.3
V
4
3
2
1
25
26
27
28
14
7
6
5
15
22
23
24
TOP VIEW
13
16
12
17
11
18
10
19
9
20
8
21
Drive2
Vsen5
Vref
VID3
VID2
VID1
VID0
PGood
Vsen2
Drive5
Select
SS
Fault / Rt
Vsen4
Drive4
Vaux
Gnd
Drive3
Vsen3
V5
Fb
Vsen1
OCSet
PGnd
LGate
Phase
UGate
V12
US3022
4-3
Rev. 1.0
11/2/99
Error Comparator Section
Input bias current
2
uA
Input Offset Voltage
-2
+2
mV
Delay to Output
Vdiff=10mV
100
nS
Current Limit Section
C.S Threshold Set Current
200
uA
C.S Comp Offset Voltage
-5
+5
mV
Hiccup Duty Cycle
Css=0.1 uF
10
%
Output Drivers Section
Rise Time
CL=3000pF
70
nS
Fall Time
CL=3000pF
70
nS
Dead band Time Between
High side and Synch Drive
(Vcore Switcher Only)
CL=3000pF
200
nS
Oscillator Section (internal)
Osc Frequency
Rt=Open
217
Khz
1.8V Regulator (Vsen 4)
Vsense Voltage
Vo4
Ta=25, Drive4 = Vsen4
1.800
V
Vsense Voltage
1.800
V
Input bias current
2
uA
Output Drive Current
Vaux-Vdrive>0.6V
50
mA
1.5V Regulator (Vsen 3)
Vsense Voltage
Vo3
Ta=25, Drive3 = Vsen3
1.500
V
Vsense Voltage
1.500
V
Input bias current
2
uA
Output Drive Current
Vaux-Vdrive>0.6V
50
mA
2.5V Regulator (Vsen 5)
Vsense Voltage
Vo5
Ta=25, Drive5 = Vsen5
2.500
V
Vsense Voltage
2.500
V
Input bias current
2
uA
Output Drive Current
Vaux-Vdrive>0.6V
50
mA
Power Good Section
Vsen1 UV lower trip point
Vsen1 ramping down
0.90Vs
V
Vsen1 UV upper trip point
Vsen1 ramping up
0.92Vs
V
Vsen1 UV Hysterises
.02Vs
V
Vsen1 HV upper trip point
Vsen1 ramping up
1.10Vs
V
Vsen1 HV lower trip point
Vsen1 ramping down
1.08Vs
V
Vsen1 HV Hysterises
.02Vs
V
Vsen2 trip point
Select<0.8V
1.100
V
Select>2V
2.560
V
Vsen4 trip point
1.320
V
Vsen3 trip point
1.140
V
Vsen5 trip point
1.875
V
Power Good Output LO
RL=3mA
0.4
V
Power Good Output HI
RL=5K pull up to 5V
4.8
V
Fault (Overvoltage) Section
Core O.V. upper trip point
Vsen1 ramping up
1.17Vs
V
Core O.V. lower trip point
Vsen1 ramping down
1.15Vs
V
FAULT Output HI
Io=3mA
10
V
Soft Start Section
Soft Start Current
OCset=0V , Phase=5V
20
uA
Note 1: Vs refers to the set point voltage given in Table 1.
4-4
Rev. 1.0
11/2/99
US3022
VID3
VID2
VID1
VID0
Vs
1
1
1
1
1.30
1
1
1
0
1.35
1
1
0
1
1.40
1
1
0
0
1.45
1
0
1
1
1.50
1
0
1
0
1.55
1
0
0
1
1.60
1
0
0
0
1.65
0
1
1
1
1.70
0
1
1
0
1.75
0
1
0
1
1.80
0
1
0
0
1.85
0
0
1
1
1.90
0
0
1
0
1.95
0
0
0
1
2.00
0
0
0
0
2.05
Table 1 - Set point voltage vs. VID codes
Pin Description
LSB input to the DAC that programs the output voltage. This pin is TTL compatible that
realizes a logic "1" as either HI or Open. When left open,his pin is pulled up internally by
a 27k
resistor to 5V supply.
Input to the DAC that programs the output voltage. This pin is TTL compatible that real-
izes a logic "1" as either HI or Open. When left open,his pin is pulled up internally by a
27k
resistor to 5V supply.
Input to the DAC that programs the output voltage. This pin is TTL compatible that real-
izes a logic "1" as either HI or Open. When left open,his pin is pulled up internally by a
27k
resistor to 5V supply.
MSB input to the DAC that programs the output voltage. This pin is TTL compatible that
realizes a logic "1" as either HI or Open. When left open,his pin is pulled up internally by
a 27k
resistor to 5V supply.
This pin provides a 2V reference that remains on when the 5V pin is connected to the 5V
standby of the ATX supply. In this application, the Vref pin is used to provide reference for
the ACPI regulators.
This pin is an open collector output that switches LO when any of the outputs are outside
of the specified under voltage trip point. It also switches low when Vsen1 pin is more than
10% above the DAC voltage setting.
This pin provides the feedback for the synchronous switching regulator. Typically this pin
can be connected directly to the output of the switching regulator. However, a resistor
divider is recommended to be connected from this pin to vout1 and GND to adjust the
output voltage for any drop in the output voltage that is caused by the trace resistance.
The value of the resistor connected from Vout1 to FB1 must be less than 1000
.
This pin controls the gate of an external MOSFET for the AGP linear regulator.
This pin controls the gate of an external transistor for the 2.5V Clock linear regulator.
PIN# PIN SYMBOL
7
VID0
6
VID1
5
VID2
4
VID3
3
Vref
8
PGOOD
21
FB
1
Drive2
10
Drive5
PIN DESCRIPTIONS
PIN DESCRIPTIONS
Vref Section
Vref Initial Accuracy
No Load,Ta=25
1.980
2.000
2.020
V
Vref Initial Accuracy
No Load, Over Temp
1.960
2.000
2.040
V
Vref Change with Load
No Load to 30K load
-2
%
Vref Output Impedance
150
300
600
Ohm
US3022
4-5
Rev. 1.0
11/2/99
Pin Description
This pin is internally connected to the undervoltage and overvoltage comparators sensing
the Vcore status. It must be connected directly to the Vcore supply.
This pin provides the feedback for the AGP linear regulator. The Select pin when con-
nected to the "Type Detect" pin of the AGP slot automatically selects the right voltage for
the AGP Vddq.
This pin controls the gate of an external MOSFET for the 1.8V chip set linear regulator.
This pin is connected to the Drain of the power MOSFET of the Core supply and it
provides the positive sensing for the internal current sensing circuitry. An external resis-
tor programs the C.S threshold depending on the Rds of the power MOSFET. An external
capacitor is placed in parallel with the programming resistor to provide high frequency
noise filtering.
This pin is connected to the Source of the power MOSFET for the Core supply and it
provides the negative sensing for the internal current sensing circuitry.
This pin provides the soft start for all the regulators. An internal current source charges
an external capacitor that is connected from this pin to GND which ramps up the outputs
of the regulators, preventing the outputs from overshooting as well as limiting the input
current. The second function of the Soft Start cap is to provide long off time (HICCUP) for
the synchronous MOSFET during current limiting.
This pin has dual function. It acts as an output of the OVP circuitry or it can be used to
program the frequency using an external resistor . When used as a fault detector, if any
of the switcher outputs exceed the OVP trip point, the FAULT pin switches to 12V and
the soft start cap is discharged. If the FAULT pin is to be connected to any external
circuitry, it needs to be buffered.
This pin controls the gate of an external transistor for the 1.5V GTL+ linear regulator.
This pin provides the feedback for the linear regulator that its output drive is Drive3.
This pin is normally connected to 3.3V or 5V input. When connected to the 12V supply,
it provides gate drive voltage for the # 3, #4 and #5 (Drive 3,4,5) linear regulator's pass
transistors in case MOSFET transistors are being used instead of Bipolars.
This pin provides the feedback for the linear regulator that its output drive is Drive4.
This pin serves as the ground pin and must be connected directly to the ground plane.
This pin serves as the Power ground pin and must be connected directly to the GND
plane close to the source of the synchronous MOSFET. A high frequency capacitor
(typically 1 uF) must be connected from V12 pin to this pin for noise free operation.
Output driver for the synchronous power MOSFET for the Core supply.
Output driver for the high side power MOSFET for the Core supply.
This pin is connected to the 12 V supply and serves as the power Vcc pin for the output
drivers. A high frequency capacitor (typically 1 uF) must be placed close to this pin and
PGND pin and be connected directly from this pin to the GND plane for the noise free
operation.
5V supply voltage. A high frequency capacitor (0.1 to 1 uF) must be placed close to this
pin and connected from this pin to the GND plane for noise free operation.
This pin provides automatic voltage selection for the AGP switching regulator. When it is
pulled LO, the voltage is 1.5V and when left open or pulled to HI, the voltage is 3.3V.
This pin provides the feedback for the linear regulator that its output drive is Drive5.
PIN# PIN SYMBOL
22
Vsen1
9
Vsen2
15
Drive4
23
OCSET
26
PHASE
12
SS
13
FAULT/Rt
18
Drive3
19
Vsen3
16
Vaux
14
Vsen4
17
GND
24
PGND
25
LGATE
27
UGATE
28
V12
20
V5
11
Select
2
Vsen5
4-6
Rev. 1.0
11/2/99
US3022
BLOCK DIAGRAM
BLOCK DIAGRAM
Figure 1 - Simplified block diagram of the US3022.
PWM
Control
V12
V12
3022blk1-1.0
Osc
Slope
Comp
+
1.26V
4Bit
DAC
Enable
Soft
Start &
Fault
Logic
200uA
0.9Vset
1.1Vset
1.17Vset
Vset
Enable
UVLO
Vset
Enable
PGood
Vsen2
Drive4
Select
Drive3
Vsen1
Drive2
V5
V12
SS
Gnd
Fault / Rt
Phase
OCSet
LGate
UGate
Fb
Vsen4
Vsen3
PGnd
Over
Current
Over
Voltage
Vaux
Vref
VID3
VID2
VID1
VID0
R
3R
R
3R
1.5V
3.3V
Vsen5
Drive5
R
3R
2.5V
+
2V
US3022
4-7
Rev. 1.0
11/2/99
TYPICAL APPLICATION
TYPICAL APPLICATION
5VSB
6MV1500DX
23
28
16
1
9
11
18
19
15
14
17
12
3
5
6
7
8
20
21
22
24
25
26
27
4
13
US3022
Vref(2V)
VID3
VID2
VID1
VID0
6MV1500DX
2
10
Fault/Rt
The Vref(2V) can be used to provide reference for
the ACPI regulatos. In this application the ACPI
regulators are designed using op-amp and discrete
transistors.
C4
220PF
Q1
IRL3103S
+
C2
1500uf
+
C3
1500uf
+
C7
1500uf
R2
5.1
Q3
IRL3103S
R3
5.1
+
C8
1500uf
+
C9
1500uf
+
C10
1500uf
+
C11
1500uf
+
C12
1500uf
R1
2.21K
L2
2.5UH
C5
1UF
L1
1UH
+
C1
680uf
Q2
IRL3103S
+
C13
680uf
+
C6
220UF
C14
1UF
C18
0.1uF
+
C16
680uf
+
C15
680uf
Q6
PMBT2222A
+
C17
220uf
C19
0.1uF
Q5
MJD200
Q4
MJD200
VCORE
12V
+5Vin
Vout2(1.5V or 3.3V)
3.3Vin
Vout3 (1.5V)
TYPE DETECT#
Vout4(1.8V)
PGood
Vout5(2.5V)
Figure 2 - Typical application of US3022 for an on board DC-DC converter providing power for the Vcore , GTL+,
1.8V chip set supply, 2.5V clock supply as well as auto select AGP supply for the next generation PC applica-
tions.
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