AIC AIC1341

AIC1341
High Performance, Triple-Output, AutoTracking Combo Controller
n FEATURES
n GENERAL DESCRIPTION
l
Provide Triple Accurate Regulated Voltages
The AIC1341 combines a synchronous voltage
l
Optimized Voltage-Mode PWM Control
mode PWM controller with two linear controllers
l
Dual N-Channel MOSFET Synchronous Drivers
as well as the monitoring and protection functions
l
Fast Transient Response
in this chip. The PWM controller regulates the
l
Adjustable Over Current Protection using RDS(ON).
No External Current Sense Resistor Required.
output voltage with a synchronous rectified stepdown converter. The built-in N-Channel MOSFET
drivers also help to simplify the design of step-
l
Programmable Softstart Function
l
200KHz Free-Running Oscillator
l
Robust Outputs Auto-Tracking Characteristics
The PWM controller features over current protec-
l
Sink and Source Capabilities with External Circuit
tion using RDS(ON). It improves efficiency and saves
down converter. It is able to power CPUs, GPUs,
memories, chipsets and multi-voltage applications.
cost, as there is no expensive current sense resis-
n APPLICATIONS
tor required.
l
Advanced PC Mboards
l
Information PCs
l
Servers and Workstations
that regulates power for multiple system I/O. Out-
l
Internet Appliances
put voltage of both linear regulators can also be
l
PC Add-On Cards
adjusted by means of the external resistor divider.
l
DDR Termination
Both linear regulators feature current limit. For a
Two built-in adjustable linear controllers drive an
external MOSFETs to form two linear regulators
system I/O requires current less than 500mA, the
AIC1340 is recommended for saving one external
MOSFET.
The programmable soft-start design provodes a
controlled output voltage rise, which limits the current rate during power on time.
The shutdown function is also provided for disabling the combo controller.
Analog Integrations Corporation 4F, 9, Industry E. 9th Rd, Science Based Industrial Park, Hsinchu Taiwan, ROC
DS-1341-00 May 24, 01
TEL: 886-3-5772500
FAX: 886-3-5772510
www.analog.com.tw
1
AIC1341
n TYPICAL APPLICATION CIRCUIT
AIC1341CS
+12VIN
VCC
+5VIN
4
14
5
2
SS
1
OCSET
UGATE
+
GND
Q1
PHASE
VOUT1
+3.3VIN
VIN2
GATE3
VOUT3
7
16
LGATE
+
Q2
10
FB3
15
11
PGND
+
+3.3VIN
FB1
13
GATE2
8
VOUT2
FB2
6
+
12 COMP1
14
3
SD
GND
Typical Triple-Output Application
n ORDERING INFORMATION
ORDER NUMBER
AIC1341-XX
PACKAGING TYPE
S: SMALL OUTLINE
TEMPERATURE RANGE
C: O °C~+70°C
AIC1341CS
(SO 16)
PIN CONFIGURATION
PHASE
1
UGATE 2
16 LGATE
15 PGND
SD
3
14 OCSET
VCC
4
13 F B 1
SS 5
FB2 6
12 COMP1
11 F B 3
VIN2
7
10 GATE3
GATE2
8
9
GND
2
AIC1341
n ABSOLUTE MAXIMUM RATING
Absolute Maximum Ratings
Supply Voltage (VCC).............................................................................................................. 15V
UGATE....................................................................................................GND - 0.3V to VCC + 0.3V
LGATE ....................................................................................................GND - 0.3V to VCC + 0.3V
Input Output and I/O Voltage .................................................................................GND - 0.3V to 7V
Operating Conditions
Ambient Temperature Range ........................................................................................ 0° C to 85°C
Maximum Operating Junction Temperature ............................................................................. 100°C
Supply Voltage, VCC....................................................................................................... 15V±10%
Thermal Information
Thermal Resistance θJA (°C/W)
SOIC Package ....................................................................................................... 100°C/W
Maximum Junction Temperature (Plastic Package).................................................................. 150°C
Maximum Storage Temperature Range.......................................................................-65°C to 150°C
Maximum Lead Temperature (Soldering 10s)........................................................................... 300°C
n TEST CIRCUIT
Refer to APPLICATION CIRCUIT.
n ELECTRICAL CHARACTERISTICS
(Vcc=12V, T J=25°C, Unless otherwise
specified)
PARAMETER
TEST CONDITIONS
SYMBOL
UGATE, LGATE, GATE2 and
GATE3 open
ICC
MIN.
TYP.
MAX.
UNIT
1.8
5
mA
VCC SUPPLY CURRENT
Supply Current
POWER ON RESET
Rising VCC Threshold
VOCSET=4.5V
VCCTHR
8.6
9.5
10.4
V
Falling VCC Threshold
VOCSET=4.5V
VCCTHF
8.2
9.2
10.2
V
Rising VIN2 Under-Voltage
Threshold
VIN2THR
2.5
2.6
2.7
V
VIN2 Under-Voltage Hysteresis
VIN2HYS
130
mV
Rising VOCSET1 Threshold
VOCSETH
1.3
V
3
AIC1341
n ELECTRICAL CHARACTERISTICS
(Continued)
SYMBOL
MIN.
TYP.
MAX.
UNIT
F
170
200
230
KHz
FB2 Reference Voltage
VREF2
1.245
1.270
1.295
V
FB3 Reference Voltage
VREF3
1.250
1.275
1.300
V
+2.5
%
80
%
PARAMETER
TEST CONDITIONS
OSCILLATOR and REFERENCE
Free Running Frequency
LINEAR CONTROLLER
Regulation
0 < IGATE2/3 < 10mA
Under-Voltage Level
FB2/3 falling
-2.5
FB2/3UV
70
PWM CONTROLLER ERROR AMPLIFIER
DC GAIN
Gain Bandwidth Product
Slew Rate
COMP1=10pF
76
dB
GBWP
11
MHz
SR
6
V/µS
PWM CONTROLLER GATE DRIVER
Upper Drive Source
VCC=12V, VUGATE=11V
RUGH
5.2
6.5
Ω
Upper Drive Sink
VCC=12V, VUGATE =1V
RUGL
3.3
5
Ω
Lower Drive Source
VCC=12V, VLGATE=11V
RLGH
4.1
6
Ω
Lower Drive Sink
VCC=12V, VLGATE=1V
RLGL
3
5
Ω
ISS
11
PROTECTION
Soft-Start Current
Chip Shutdown Soft Start
Threshold
µA
1.0
V
4
AIC1341
n PIN DESCRIPTIONS
Pin 1:
Pin 2:
Pin 3:
Pin 4:
Pin 5:
Pin 6:
Pin 7:
PHASE: Over-current detection pin. Connect the PHASE pin to source of
the
external
high-side
NMOSFET. This pin detects the
voltage drop across the high-side
N-MOSFET RDS(ON) for overcurrent protection.
UGATE: External high-side N-MOSFET
gate drive pin. Connect UGATE
to gate of the external high-side
N-MOSFET.
SD:
VCC:
SS:
FB2:
VIN2:
To shut down the system, active
high or floating. If connecting a
resistor to ground, keep the resistor less than 4.7KΩ
The chip power supply pin. It also
provides the gate bias charge for
all the MOSFETs controlled by
the IC. Recommended supply
voltage is 12V.
Soft-start pin. Connect a capacitor from this pin to ground. This
capacitor, along with an internal
10µA (typically) current source,
sets the soft-start interval of the
converter.
Pulling this pin low will shut down
the IC.
Connect this pin to a resistor divider to set the linear regulator
output voltage.
This pin supplies power to the
internal regulator. Connect this
pin to a suitable 3.3V source.
Additionally, this pin is used to
monitor the 3.3V supply. If, following a start-up cycle, the voltage drops below 2.6V (typically),
the chip shuts down. A new softstart cycle is initiated upon re-
turn of the 3.3V supply above
the under-voltage threshold.
Pin 8:
GATE2: Linear Controller output drive pin.
This pin can drive either a Darlington NPN transistor or a Nchannel MOSFET.
Pin 9:
GND:
Signal GND for IC. All voltage
levels are measured with respect
to this pin.
Pin 10: GATE3: Linear Controller output drive pin.
This pin can drive either a Darlington NPN transistor or an Nchannel MOSFET.
Pin 11: FB3
Negative feedback pin for the
linear controller error amplifier
connect this pin to a resistor divider to set the linear controller
output voltage.
Pin 12: COMP1 External compensation pin. This
pin is connected to error amplifier output and PWM comparator.
A RC network is connected to
FB1 to compensate the voltage
control feedback loop of the converter.
Pin 13: FB1
The error amplifier inverting input
pin. The FB1 pin and COMP1 pin
are used to compensate the voltage-control feedback loop.
Pin 14: OCSET: Current limit sense pin. Connect
a resistor ROCSET from this pin to
the drain of the external high-side
N-MOSFET. ROCSET, an internal
200µA current source (IOCSET ),
and the upper N-MOSFET onresistance (RDS(ON)) set the overcurrent trip point according to the
following equation:
I PEAK =
I OCSET × ROCSET
RDS(ON)
5
AIC1341
Pin 15: PGND:
Driver power GND pin. PGND
should be connected to a low
impedance ground plane in close
to lower N-MOSFET source.
Pin 16: LGATE: Lower N-MOSFET gate drive pin.
n TYPICAL PERFORMANCE CHARACTERISTICS
UGATE
UGATE
LGATE
LGATE
Fig.1 The gate drive waveforms
FAULT
SS
VOUT1 =3.5V
SS
VOUT1 =2V
Over Load
Applied
Inductor Current
10A/div
Fig.2 Over-Current Operation on Inductor
VOUT1 =1.3V
Fig.3 Soft start initiates PWM Output
6
AIC1341
n TYPICAL PERFORMANCE CHARACTERISTICS (Continued)
VOUT1
VOUT3 ( 2mV/div)
2.0VDC
5A to 12A Load Step
1A to 2A Load Step
Fig.4 Transient Response of PWM Output
Fig.5 Transient Response of Linear Controller
n BLOCK DIAGRAM
VCC
VIN2
SS
FB3
+
+
+
GATE3
LUV
+
OCSET
1.3V
9.5V
200uA
+
0.3V
+
2.6V
+
GATE2
SS
1.26V
POR
FB2
INHIBIT
OC1
+
PHASE
VCC
COUNT 3
LUV
3.6V
OC1
S
R
-
S
UGATE
Q
R
+
Q
POR
+
GATE CONTROL
5V
R
S
10uA
0.2V
PWM COMP
Q
VCC
R
+
200KHz
OSCILLATOR
SS
SS
SLOW DISCHARGE
4V
LGATE
PGND
+
FAST DISCHARGE
1.3V
20uA
5V
70K
GND
ERROR AMP
SD
FB1
COMP1
7
AIC1341
n DESCRIPTION
The AIC1341 is designed for applications with
multiple voltage demand. This IC has one PWM
controller and two linear controllers. The PWM
controller is designed to regulate the voltage
(V OUT1) by driving 2 MOSFETs (B y UGATE and
LGATE) in a synchronous rectified buck converter
configuration. The voltage is regulated to a level,
which is decided by a resistor devide network.
The Power-On Reset (POR) function continually
monitors the input supply voltage +12V at VCC
pin, the 5V input voltage at OCSET pin, and the
3.3V input at VIN2 pin. The POR function initiates
soft-start operation after all three input supply
voltage exceeds their POR thresholds.
Soft-Start
The POR function initiates the soft-start sequence.
Initially, the voltage on SS pin rapidly increases to
approximate 1V. Then an internal 10µA current
source charges an external capacitor (CSS) on the
SS pin to 4V. As the SS pin voltage slews from
1V to 4V, the PWM error amplifier reference input
(Non-inverting terminal) and output (COMP1 pin) is
clamped to a level proportional to the SS pin voltage. As the SS pin voltage slew from 1V to 4V,
the output clamp generates PHASE pulses of increasing width that charge the output capacitors.
Additionally both linear regulator’s reference inputs are clamped to a voltage proportional to the
SS pin voltage. This method provides a controlled
output voltage smooth rise.
cient voltage the input reference clamp slows the
rate of output voltage rise.
Over-Current Protection
All outputs are protected against excessive overcurrent. The PWM controller uses upper
MOSFET’s on-resistance, RDS(ON) to monitor the
current for protection against shorted outputs.
Both the linear regulator and controller monitor
FB2 and FB3 for under-voltage to protect against
excessive current.
When the voltage across Q1 (ID • RDS(ON)) exceeds the level (200µA•ROCSET ), this signal inhibit all outputs. Discharge soft-start capacitor
(Css) with 10µA current sink, and increments the
counter. Css recharges and initiates a soft-start
cycle again until the counter increments to 3. This
sets the fault latch to disable all outputs. Fig. 2
illustrates the over-current protection until an over
load on OUT1.
Should excessive current cause FB2 or FB3 to fall
below the linear under-voltage threshold, the LUV
signal sets the over-current latch if Css is fully
charged. Cycling the bias input power off then on
reset the counter and the fault latch.
The over-current function for PWM controller will
trip at a peak inductor current (IPEAK) determined
by:
IPEAK =
Fig.3 shows the soft-start sequence for the typical
application. The internal oscillator’s triangular
waveform is compared to the clamped error amplifier output voltage. As the SS pin voltage increases, the pulse width on PHASE pin increases.
The interval of increasing pulse width continues
until output reaches sufficient voltage to transfer
control to the input reference clamp.
Each linear output (V OUT2 and VOUT3) initially
follows a ramp. When each output reaches suffi-
IOCSET × R OCSET
R DS(ON)
The OC trip point varies with MOSFET’s temperature. To avoid over-current tripping in the normal
operating load range, determine the ROCSET resistor from the equation above with:
1. The maximum RDS(ON) at the highest junction.
2. The minimum IOCSET from the specification table.
3. Determine IPEAK > IOUT(MAX ) + (inductor ripple
current) /2.
8
AIC1341
Shutdown
Q1, Q2 loop. The GND and PGND pins
Compatible with the TTL logic level, by holding the
should be shorted right at the IC. This help to
SD (pin3) pin low will activate the controller. If
minimize internal ground disturbances in the
connecting a resistor to ground, make sure the
IC and prevents differences in ground potential
resistor is less than 4.7KΩ for normal operation.
from disrupting internal circuit operation.
5) The wiring traces from the control IC to the
Layout Considerations
MOSFET gate and source should be sized to
Any inductance in the switched current path gen-
carry 1A current. Locate COUT2 close to the
erates a large voltage spike during the switching
AIC1341 IC.
interval. The voltage spikes can degrade efficiency,
6) The Vcc pin should be decoupled directly to
radiate noise into the circuit, and lead to device
GND by a 1µF ceramic capacitor, trace
over-voltage stress. Careful component selection
lengths should be as short as possible.
and tight layout of critical components, and short,
wide metal trace minimize the voltage spike.
A multi-layer printed circuit board is recom-
1) A ground plane should be used. Locate the
mended. Figure 6 shows the connections of the
input capacitors (CIN) close to the power
critical components in the converter. The CIN and
switches. Minimize the loop formed by CIN,
COUT could each represent numerous physical ca-
the upper MOSFET (Q1) and the lower
pacitors. Dedicate one solid layer for a ground
MOSFET (Q2) as possible. Connections
plane and make all critical component ground
should be as wide as short as possible to
connections with vias to this layer.
minimize loop inductance.
2) The connection between Q1, Q2 and output
inductor should be as wide as short as practi-
PWM Output Capacitors
cal. Since this connection has fast voltage
The load transient for the microprocessor core re-
transitions will easily induce EMI.
quires high quality capacitors to supply the high
3) The output capacitor (COUT ) should be locat-
slew rate (di/dt) current demand.
ed as close the load as possible. Because
The ESR (equivalent series resistance) and ESL
minimize the transient load magnitude for high
(equivalent series inductance) parameters rather
slew rate requires low inductance and resis-
than actual capacitance determine the buck ca-
tance in circuit board
pacitor values. For a given transient load magni-
4) The AIC1341 is best placed over a quiet
ground plane area. The GND pin should be
connected to the groundside of the output ca-
tude, the output voltage transient change due to
the output capacitor can be note by the following
equation:
∆IOUT
,
∆T
pacitors. Under no circumstances should
∆VOUT = ESR × ∆IOUT + ESL ×
GND be returned to a ground inside the CIN,
∆IOUT is transient load current step.
where
9
AIC1341
+
+12V
VCC
+3.3VIN
GND
VIN2
OCSET
GATE3
UGATE
+5VIN
+
Q3
+
C IN
Q1
VOUT3
PHASE
+
LOUT
COUT3
VOUT
+
LGATE
COUT
Q2
Q4
GATE2
PGND
SS
V OUT2
Css
+
COUT2
Power Plane Layer
Circuit Plane Layer
Via Connection to Ground Plane
Fig.6 Printed circuit board power planes and islands
After the initial transient, the ESL dependent term
The response time to a transient is different for the
drops off. Because the strong relationship be-
application of load and remove of load.
tween output capacitor ESR and output load transient, the output capacitor is usually chosen for
ESR, not for capacitance value. A capacitor with
L × ∆IOUT
L × ∆IOUT
, tFALL =
.
VIN − VOUT
VOUT
Where ∆IOUT is transient load current step.
tRISE =
suitable ESR will usually have a larger capacitance value than is needed for energy storage.
In a typical 5V input, 2V output application, a 3µH
A common way to lower ESR and raise ripple cur-
inductor has a 1A/µS rise time, resulting in a 5µS
rent capability is to parallel several capacitors. In
delay in responding to a 5A load current step. To
most case, multiple electrolytic capacitors of
optimize performance, different combinations of
small case size are better than a single large
input and output voltage and expected loads may
case capacitor.
require different inductor value. A smaller value of
Output Inductor Selection
Inductor value and type should be chosen based
on output slew rate requirement, output ripple requirement and expected peak current. Inductor
value is primarily controlled by the required current
response time. The AIC1341 will provide either 0%
or 85% duty cycle in response to a load transient.
inductor will improve the transient response at the
expense of increase output ripple voltage and inductor core saturation rating.
Peak current in the inductor will be equal to the
maximum output load current plus half of inductor
ripple current. The ripple current is approximately
equal to:
10
AIC1341
I RIPPLE =
(V IN − VOUT) × VOUT
;
f × L × VIN
dissipated by the AIC1341. However, the gate
charge increases the switching interval, tSW, which
increase the upper MOSFET switching losses.
f = 200KHz oscillator frequency.
Ensure that both MOSFETs are within their
The inductor must be able to withstand peak cur-
maximum junction temperature at high ambient
rent without saturation, and the copper resistance
temperature by calculating the temperature rise
in the winding should be kept as low as possible
according to package thermal resistance specifi-
to minimize resistive power loss
cations.
IOUT × VIN × tSW × f
2
× RDS(ON) × (1 − D)
PUPPER = IOUT 2 × RDS(ON) × D +
Input Capacitor Selection
Most of the input supply current is supplied by the
PLOWER = IOUT 2
input bypass capacitor, the resulting RMS current
The equations above do not model power loss due
flow in the input capacitor will heat it up. Use a
to the reverse recovery of the lower MOSFET’s
mix of input bulk capacitors to control the voltage
body diode.
overshoot across the upper MOSFET. The ce-
The RDS(ON) is different for the two previous equa-
ramic capacitance for the high frequency decou-
tions even if the type devices is used for both.
pling should be placed very close to the upper
This is because the gate drive applied to the upper
MOSFET to suppress the voltage induced in the
MOSFET is different than the lower MOSFET.
parasitic circuit impedance. The buck capacitors
Logic level MOSFETs should be selected based
to supply the RMS current is approximate equal
on on-resistance considerations, RDS(ON)
to:
be chosen base on input and output voltage, al-
IRMS = (1− D) × D × I2 OUT +
, where D =
1  VIN × D
×

12  f × L 
2
VOUT
VIN
The capacitor voltage rating should be at least
1.25 times greater than the maximum input voltage.
should
lowable power dissipation and maximum required
output current. Power dissipation should be calculated based primarily on required efficiency or
allowable thermal dissipation.
Rectifier Schottky diode is a clamp that prevent
the loss parasitic MOSFET body diode from conducting during the dead time between the turn off
of the lower MOSFET and the turn on of the upper
PWM MOSFET Selection
MOSFET. The diode’s rated reverse breakdown
voltage must be greater than twice the maximum
In high current PWM application, the MOSFET
input voltage.
power dissipation, package type and heatsink are
the dominant design factors. The conduction loss
is the only component of power dissipation for the
lower MOSFET, since it turns on into near zero
voltage. The upper MOSFET has conduction loss
Linear Controller MOSFET Selection
The power dissipated in a linear regulator is :
PLINEAR = IOUT × (VIN2 − VOUT)
and switching loss. The gate charge losses are
Select a package and heatsink that maintains
proportional to the switching frequency and are
junction temperature below the maximum rating
11
AIC1341
while operation at the highest expected ambient
Notes
temperature.
VOUT1 - The PWM output
VOUT2 - The linear controller dominated by FB2,
Linear Output Capacitor
The output capacitors for the linear controller
GATE2 and VIN2
VOUT3 - The linear controller dominated by FB3
provide dynamic load current. The linear controller
and
uses dominant pole compensation integrated in
GATE3
the error amplifier and is insensitive to output ca-
All the designators mentioned above are refering
pacitor selection. COUT2 and COUT3 should be se-
to the TYPICAL APPLICATION CIRCUIT in pre-
lected for transient load regulation.
vious page.
12
AIC1341
n APPLICATION CIRCUIT
1000pF
K
AIC1341CS
10
+12VIN
1 µH
2K
VCC
1µ F
4
14
SS
2
5
0.1µF
1
+
OCSET
UGATE
+5VIN
6030L
1000µF*2
0.1 µF
PHASE
GND
5V OUT
+5.0VIN
VIN2
7µ H
7
16
6030L
GATE3
VOUT3
6030L
+
1000µ F *5
10
FB3
15
11
3.3V
LGATE
PGND
3.9K
+
2.4K
24K
+5.0VIN
FB1
13
GATE2
6030L
8.2K
8
VOUT2
33pF
91K
COMP1
1000pF
FB2
6
2.5V
+
2.4K
12
2.4K
14
GND
3
SD
Circuit 1 Multiple Voltage Power application Circuit
13
AIC1341
n PACKAGE DIMENSIONS
16 LEAD PLASTIC SO (300 mil) (unit: mm)
D
E
H
SYMBOL
MIN
MAX
A
2.35
2.65
A1
0.10
0.30
B
0.33
0.51
C
0.23
0.32
D
10.10
10.50
E
7.40
7.60
e
e
1.27(TYP)
A
A1
l
B
c
L
H
10.00
10.65
L
0.40
1.27
14