INTERSIL HIP6017

HIP6017
Data Sheet
Advanced PWM and Dual Linear Power
Control
The HIP6017 provides the power control and protection for
three output voltages in high-performance microprocessor
and computer applications. The IC integrates a PWM
controller, a linear regulator and a linear controller as well as
the monitoring and protection functions into a single 28 lead
SOIC package. The PWM controller regulates the
microprocessor core voltage with a synchronous-rectified
buck converter. The linear controller regulates power for the
GTL bus and the linear regulator provides power for the
clock driver circuits.
The HIP6017 includes an Intel-compatible, TTL 5-input
digital-to-analog converter (DAC) that adjusts the core PWM
output voltage from 2.1VDC to 3.5VDC in 0.1V increments
and from 1.8VDC to 2.05VDC in 0.05V steps. The precision
reference and voltage-mode control provide ±1% static
regulation. The linear regulator uses an internal pass device
to provide 2.5V ±2.5%. The linear controller drives an
external N-Channel MOSFET to provide 1.5V ±2.5%.
The HIP6017 monitors all the output voltages. A single
Power Good signal is issued when the core is within ±10% of
the DAC setting and the other levels are above their undervoltage levels. Additional built-in over-voltage protection for
the core output uses the lower MOSFET to prevent output
voltages above 115% of the DAC setting. The PWM overcurrent function monitors the output current by using the
voltage drop across the upper MOSFET’s rDS(ON), thus
eliminating the need for a current sensing resistor.
Pinout
HIP6017 (SOIC)
TOP VIEW
April 1998
File Number
4496.1
Features
• Provides 3 Regulated Voltages
- Microprocessor Core, Clock and GTL Power
• Drives N-Channel MOSFETs
• Operates from +3.3V, +5V and +12V Inputs
• Simple Single-Loop PWM Control Design
- Voltage-Mode Control
• Fast Transient Response
- High-Bandwidth Error Amplifier
- Full 0% to 100% Duty Ratios
• Excellent Output Voltage Regulation
- Core PWM Output: ±1% Over Temperature
- Other Outputs: ±2.5% Over Temperature
• TTL-Compatible 5-Bit Digital-to-Analog Core Output
Voltage Selection
- Wide Range . . . . . . . . . . . . . . . . . . . 1.8VDC to 3.5VDC
- 0.1V Steps . . . . . . . . . . . . . . . . . . . . 2.1VDC to 3.5VDC
- 0.05V Steps . . . . . . . . . . . . . . . . . . 1.8VDC to 2.05VDC
• Power-Good Output Voltage Monitor
• Microprocessor Core Voltage Protection Against Shorted
MOSFET
• Over-Voltage and Over-Current Fault Monitors
- Does Not Require Extra Current Sensing Element,
Uses MOSFET’s rDS(ON)
• Small Converter Size
- Constant Frequency Operation
- 200kHz Free-Running Oscillator; Programmable from
50kHz to over 1MHz
Applications
NC 1
28 VCC
NC 2
27 UGATE1
VID4 3
26 PHASE1
VID3 4
25 LGATE1
VID2 5
24 PGND
VID1 6
23 OCSET1
VID0 7
22 VSEN1
PGOOD 8
GND2 9
• Full Motherboard Power Regulation for Computers
• Low-Voltage Distributed Power Supplies
Ordering Information
PART NUMBER
21 FB1
HIP6017CB
20 COMP1
HIP6017EVAL1
TEMP. RANGE
(oC)
0 to 70
PACKAGE
28 Ld SOIC
PKG. NO.
M28.3
Evaluation Board
19 FB3
V33 10
NC 11
18 GATE3
SS 12
17 GND
16 VOUT2
FAULT/RT 13
15 VIN2
FB2 14
2-210
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
http://www.intersil.com or 407-727-9207 | Copyright © Intersil Corporation 1999
Block Diagram
+
+
-
+
2-211
0.3V
-
V33
LINEAR
UNDERVOLTAGE
200µA
-
-
+
-
+
+
0.23A
PGOOD
90%
+
VOUT2
-
-
RESET (POR)
+
-
+
VCC
POWER-ON
110%
INHIBIT
VIN2
-
OCSET1
VSEN1
FB3
GATE3
1.26V
115%
FB2
OC2
-
UPPER
DRIVE
OV
VCC
UGATE1
OC1
+
-
VIN2
PHASE1
INHIBIT
-
+
2.5V
+
-
+
-
-
+
ERROR
AMP
+
-
GATE
CONTROL
+
VCC
4.3V
LGATE1
LOWER
DRIVE
11µA
TTL D/A
CONVERTER
(DAC)
PGND
GND
DACOUT
OSCILLATOR
4V
SS
VCC
PWM
PWM
COMP
VID4
VID0
VID2
VID1
VID3
FIGURE 1.
FB1
COMP1
RT
GND2
HIP6017
SOFTSTART
& FAULT
LOGIC
FAULT
+
LUV
HIP6017
Simplified Power System Diagram
+5VIN
+3.3VIN
LINEAR
REGULATOR
VOUT2
PWM1
CONTROLLER
VOUT1
HIP6017
LINEAR
CONTROLLER
VOUT3
FIGURE 2.
Typical Application
+12VIN
+5VIN
LIN
CIN
VCC
OCSET1
VIN2
+3.3VIN
V33
VOUT2
2.5V
POWERGOOD
PGOOD
VOUT2
UGATE1
FB2
COUT2
Q1
LOUT1
PHASE1
Q2
LGATE1
Q3
VOUT3
1.5V
HIP6017
FB3
VSEN1
FB1
COUT3
COMP1
VID0
VID1
VID2
FAULT/RT
VID3
VID4
SS
GND
GND2
FIGURE 3.
2-212
COUT1
CR1
PGND
DRIVE3
CSS
VOUT1
1.8V TO 3.5V
HIP6017
Absolute Maximum Ratings
Thermal Information
Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +15V
PGOOD, RT, FAULT, and GATE Voltage . . . GND - 0.3V to VCC + 0.3V
Input, Output or I/O Voltage . . . . . . . . . . . . . . . . . . GND -0.3V to 7V
Thermal Resistance (Typical, Note 1)
θJA (oC/W)
SOIC Package. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
60
SOIC Package (with 3 in2 of copper) . . . . . . . . . . .
50
Maximum Junction Temperature (Plastic Package) . . . . . . . .150oC
Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . .300oC
(SOIC - Lead Tips Only)
Operating Conditions
Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . +12V ±10%
Ambient Temperature Range . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC
Junction Temperature Range . . . . . . . . . . . . . . . . . . . . 0oC to 125oC
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the
device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
NOTE:
1. θJA is measured with the component mounted on an evaluation PC board in free air.
Electrical Specifications
Recommended Operating Conditions, Unless Otherwise Noted. Refer to Figures 1, 2 and 3
PARAMETER
SYMBOL
TEST CONDITIONS
MIN
TYP
MAX
UNITS
-
10
-
mA
VCC SUPPLY CURRENT
Nominal Supply
ICC
UGATE1, DRIVE3, LGATE1, and VOUT4 Open
POWER-ON RESET
Rising VCC Threshold
VOCSET = 4.5V
8.6
-
10.4
V
Falling VCC Threshold
VOCSET = 4.5V
8.2
-
10.2
V
2.45
2.55
2.65
V
VIN2 Under-Voltage Hystersis
-
500
-
mV
Rising VOCSET1 Threshold
-
1.25
-
V
Rising VIN2 Under-Voltage Threshold
OSCILLATOR
Free Running Frequency
RT = OPEN
185
200
215
kHz
Total Variation
6kΩ < RT to GND < 200kΩ
-15
-
+15
%
-
1.9
-
VP-P
DAC(VID0-VID4) Input Low Voltage
-
-
0.8
V
DAC(VID0-VID4) Input High Voltage
2.0
-
-
V
∆VOSC
Ramp Amplitude
RT = Open
REFERENCE AND DAC
DACOUT Voltage Accuracy
-1.0
-
+1.0
%
1.240
1.265
1.290
V
-2.5
-
+2.5
%
-
75
87
%
-
6
-
%
Over Current Protection
180
230
-
mA
Over Current Protection During Start-Up
560
700
-
mA
-2.5
-
+2.5
%
-
75
87
%
-
6
-
%
20
40
-
mA
-
88
-
dB
-
15
-
MHz
Reference Voltage (Pin FB2 and FB3)
LINEAR REGULATOR
Regulation
10mA < IVOUT2 < 150mA
Under Voltage Level
FB2UV
FB2 Rising
Under Voltage Hysteresis
LINEAR CONTROLLER
Regulation
VSEN3 = DRIVE3, 0 < IDRIVE3 < 20mA
Under Voltage Level
FB3UV
FB3 Rising
Under Voltage Hysteresis
Output Drive Current
IDRIVE3
VIN2 - VDRIVE3 > 0.6V
PWM CONTROLLER ERROR AMPLIFIER
DC Gain
Gain-Bandwidth Product
GBWP
2-213
HIP6017
Electrical Specifications
Recommended Operating Conditions, Unless Otherwise Noted. Refer to Figures 1, 2 and 3 (Continued)
PARAMETER
SYMBOL
Slew Rate
SR
TEST CONDITIONS
MIN
TYP
MAX
UNITS
COMP = 10pF
-
6
-
V/µs
PWM CONTROLLER GATE DRIVER
Upper Drive Source
IUGATE
VCC = 12V, VUGATE1 = 6V
-
1
-
A
Upper Drive Sink
RUGATE
VUGATE1-PHASE1 = 1V
-
1.7
3.5
Ω
Lower Drive Source
ILGATE
VCC = 12V, VLGATE1 = 1V
-
1
-
A
Lower Drive Sink
RLGATE
VLGATE1 = 1V
-
1.4
3.0
Ω
VSEN1 Rising
112
115
118
%
PROTECTION
VOUT1 Over-Voltage Trip
FAULT Sourcing Current
IOVP
VFAULT/RT = 10V
10
14
-
mA
OCSET1 Current Source
IOCSET
VOCSET = 4.5VDC
170
200
230
µA
-
11
-
µA
-
-
1.0
V
Soft-Start Current
ISS
Chip Shutdown Soft-Start Threshold
POWER GOOD
VOUT1 Upper Threshold
VSEN1 Rising
108
-
110
%
VOUT1 Under-Voltage (Lower Threshold)
VSEN1 Rising
92
-
94
%
VOUT1 Hysteresis (VSEN1/DACOUT)
Upper/Lower Threshold
-
2
-
%
IPGOOD = -4mA
-
-
0.5
V
PGOOD Voltage Low
VPGOOD
Typical Performance Curves
100
CGATE = 4800pF
CUGATE1 = CLGATE1 = CGATE
VVCC = 12V, VIN = 5V
80
RT PULLUP
TO +12V
ICC (mA)
RESISTANCE (kΩ)
1000
100
10
60
CGATE = 3600pF
40
CGATE = 1500pF
20
RT PULLDOWN TO VSS
CGATE = 660pF
0
10
100
1000
SWITCHING FREQUENCY (kHz)
FIGURE 4. RT RESISTANCE vs FREQUENCY
Functional Pin Descriptions
VSEN1 (Pin 22)
This pin is connected to the PWM converter’s output voltage.
The PGOOD and OVP comparator circuits use this signal to
report output voltage status and for over-voltage protection.
OCSET1 (Pin 23)
Connect a resistor (ROCSET) from this pin to the drain of the
respective upper MOSFET. ROCSET, an internal 200µA
current source (IOCSET), and the upper MOSFET on-
2-214
100
200
300
400
500
600
700
800
900 1000
SWITCHING FREQUENCY (kHz)
FIGURE 5. BIAS SUPPLY CURRENT vs FREQUENCY
resistance (rDS(ON)) set the converter over-current (OC) trip
point according to the following equation:
I OCSET xR OCSET
I PEAK = ------------------------------------------------r DS ( ON )
An over-current trip cycles the soft-start function. Sustaining
an over-current for 2 soft-start intervals shuts down the IC.
Additionally, OCSET1 is an output for the inverted FAULT
signal (FAULT). If a fault condition causes FAULT to go high,
OCSET1 will be simultaneously pulled to ground though an
internal MOS device (typical rDS(ON) = 100Ω).
HIP6017
SS (Pin 12)
Connect a capacitor from this pin to ground. This capacitor,
along with an internal 11µA current source, sets the softstart interval of the converter.
Pulling this pin low with an open drain signal will shutdown
the IC.
VID0, VID1, VID2, VID3, VID4 (Pins 7, 6, 5, 4 and 3)
VID0-4 are the input pins to the 5-bit DAC. The states of these
five pins program the internal voltage reference (DACOUT).
The level of DACOUT sets the core converter output voltage.
It also sets the core PGOOD and OVP thresholds.
COMP1 and FB1 (Pins 20, and 21)
COMP1 and FB1 are the available external pins of the PWM
error amplifier. The FB1 pin is the inverting input of the error
amplifier. Similarly, the COMP1 pin is the error amplifier
output. These pins are used to compensate the voltagecontrol feedback loop of the PWM converter.
GND and GND2 (Pins 17 and 9)
Signal grounds for the IC. All voltage levels are measured
with respect to these pins.
200kHz switching frequency is increased according to the
following equation:
6
5x10
Fs ≈ 200kHz + --------------------R T ( kΩ )
(RT to GND)
Conversely, connecting a pull-up resistor (RT) from this pin
to VCC reduces the switching frequency according to the
following equation:
7
4x10
Fs ≈ 200kHz – --------------------R T ( kΩ )
(RT to 12V)
Nominally, this pin voltage is 1.26V, but is pulled to VCC in
the event of an over-voltage or over-current condition.
GATE3 (Pin 18)
Connect this pin to the gate of an external MOSFET or the
base of an external bipolar NPN transistor. This pin provides
the drive for the linear controller’s pass transistor.
FB3 (Pin 19)
Connect this pin to a resistor divider to set the linear
controller output voltage.
VOUT2 (Pin 16)
PGOOD (Pin 8)
PGOOD is an open collector output used to indicate the
status of the PWM converter output voltages. This pin is
pulled low when the core output is not within ±10% of the
DACOUT reference voltage and the other outputs are below
their under-voltage thresholds. The PGOOD output is open
for VID codes that inhibit operation. See Table 1.
PHASE1 (Pin 26)
Connect the PHASE pin to the PWM converter’s upper
MOSFET source. This pin is used to monitor the voltage
drop across the upper MOSFET for over-current protection.
Output of the linear regulator. Supplies current up to 230mA.
FB2 (Pin 14)
Connect this pin to a resistor divider to set the linear
regulator output.
VIN2 (Pin 15)
VIN2 provides the input power to the integrated linear
regulator. Connect this pin to the 3.3VDC supply. This pin is
also monitored for UV events.
V33 (Pin 10)
Connect this pin to the 3.3VDC supply.
UGATE1 (Pin 27)
Connect UGATE pin to the PWM converter’s upper MOSFET
gate. This pin provides the gate drive for the upper MOSFET.
Description
Operation
PGND (Pin 24)
This is the power ground connection. Tie the synchronous
PWM converter’s lower MOSFET source to this pin.
LGATE1 (Pin 25)
Connect LGATE1 to the synchronous PWM converter’s
lower MOSFET gate. This pin provides the gate drive for the
lower MOSFET.
VCC (Pin 28)
Provide a 12V bias supply for the IC to this pin. This pin also
provides the gate charge for all the MOSFETs controlled by
the IC.
FAULT/RT (Pin 13)
This pin provides oscillator switching frequency adjustment.
Placing a resistor (RT) from this pin to GND, the nominal
2-215
The HIP6017 monitors and precisely controls 3 output
voltage levels (Refer to Figures 1, 2, and 3). It is designed for
microprocessor computer applications with 3.3V and 5V
power and 12V bias input from an ATX power supply. The IC
has one PWM controller, a linear controller, and a linear
regulator. The PWM controller (PWM) is designed to
regulate the microprocessor core voltage (VOUT1). PWM
controller drives 2 MOSFETs (Q1 and Q2) in a synchronousrectified buck converter configuration and regulates the core
voltage to a level programmed by the 5-bit digital-to-analog
converter (DAC). An integrated linear regulator supplies the
2.5V clock generator power (VOUT2). The linear controller
drives an external MOSFET (Q3) to supply the GTL bus
power (VOUT3).
HIP6017
Initialization
The HIP6017 automatically initializes upon receipt of input
power. By the time the soft-start (SS) voltage reaches 4V,
the 3.3V input has to be high enough such that the two linear
outputs (VOUT2, VOUT3) have exceeded their under-voltage
threshold. A typical ATX supply meets this requirement. The
Power-On Reset (POR) function continually monitors the
input supply voltages. The POR monitors the bias voltage
(+12VIN) at the VCC pin and the 5V input voltage (+5VIN) at
the OCSET1 pin. The normal level on OCSET1 is equal to
+5VIN less a fixed voltage drop (see over-current protection).
The POR function initiates soft-start operation after both
input supply voltages exceed their POR thresholds.
PGOOD
(2V/DIV)
0V
SOFT-START
(1V/DIV)
0V
VOUT2 ( = 2.5V)
VOUT1 (DAC = 2V)
Soft-Start
The POR function initiates the soft-start sequence. Initially,
the voltage on the SS pin rapidly increases to approximately
1V (this minimizes the soft-start interval). Then an internal
11µA current source charges an external capacitor (CSS) on
the SS pin to 4V. The PWM error amplifier reference input
(+ terminal) and output (COMP1 pin) are clamped to a level
proportional to the SS pin voltage. As the SS pin voltage
ramps from 1V to 4V, the output clamp allows generation of
PHASE pulses of increasing width that charge the output
capacitor(s). After this initial stage, the reference input clamp
slows the output voltage rate-of-rise and provides a smooth
transition to the final set voltage. Additionally, both linear
regulator’s reference inputs are clamped to a voltage
proportional to the SS pin voltage. This method provides a
rapid and controlled output voltage rise.
Figure 6 shows the soft-start sequence for the typical
application. At T0 the SS voltage rapidly increases to
approximately 1V. At T1, the SS pin and error amplifier
output voltage reach the valley of the oscillator’s triangle
wave. The oscillator’s triangular waveform is compared to
the clamped error amplifier output voltage. As the SS pin
voltage increases, the pulse-width on the PHASE pin
increases. The interval of increasing pulse-width continues
until each output reaches sufficient voltage to transfer
control to the input reference clamp. If we consider the 2.0V
output (VOUT1) in Figure 6, this time occurs at T2. During
the interval between T2 and T3, the error amplifier reference
ramps to the final value and the converter regulates the
output to a voltage proportional to the SS pin voltage. At T3
the input clamp voltage exceeds the reference voltage and
the output voltage is in regulation.
The remaining outputs are also programmed to follow the SS
pin voltage. Each linear output (VOUT2 and VOUT3) initially
follows a ramp similar to that of the PWM output. When each
output reaches sufficient voltage the input reference clamp
slows the rate of output voltage rise. The PGOOD signal
toggles ‘high’ when all output voltage levels have exceeded
their under-voltage levels. See the Soft-Start Interval section
under Applications Guidelines for a procedure to determine
the soft-start interval.
2-216
OUTPUT
VOLTAGES
(0.5V/DIV)
VOUT3 ( = 1.5V)
0V
T0 T1
T2
T4
T3
TIME
FIGURE 6. SOFT-START INTERVAL
Fault Protection
All three outputs are monitored and protected against
extreme overload. A sustained overload on any linear
regulator output or an over-voltage on the PWM output
disables all converters and drives the FAULT/RT pin to VCC.
LUV
OVER
CURRENT
LATCH
INHIBIT
S Q
OC1
R
0.15V
S
+
COUNTER
-
R
SS
+
4V
FAULT
LATCH
VCC
S Q
UP
-
POR
R
FAULT
OV
FIGURE 7. FAULT LOGIC - SIMPLIFIED SCHEMATIC
Figure 7 shows a simplified schematic of the fault logic. An
over-voltage detected on VSEN1 immediately sets the fault
latch. A sequence of three over-current fault signals also
sets the fault latch. A comparator indicates when CSS is
fully charged (UP signal), such that an under-voltage event
on either linear output (FB2 or FB3) is ignored until after
the soft-start interval (T4 in Figure 6). At start-up, this
During operation, a short on the upper PWM MOSFET (Q1)
causes VOUT1 to increase. When the output exceeds the
over-voltage threshold of 115% (typical) of DACOUT, the
over-voltage comparator trips to set the fault latch and turns
Q2 on as required in order to regulate VOUT1 to 1.15 x
DACOUT. This blows the input fuse and reduces VOUT1.
The fault latch raises the FAULT/RT pin close to VCC
potential.
A separate over-voltage circuit provides protection during
the initial application of power. For voltages on the VCC pin
below the power-on reset (and above ~4V), VOUT1 is
monitored for voltages exceeding 1.26V. Should VSEN1
exceed this level, the lower MOSFET (Q2) is driven on as
needed to regulate VOUT1 to 1.26V.
Over-Current Protection
All outputs are protected against excessive over-currents.
The PWM controller uses the upper MOSFET’s onresistance, rDS(ON) to monitor the current for protection
against shorted outputs. The linear regulator monitors the
current of the integrated power device and signals an overcurrent condition for currents in excess of 230mA.
Additionally, both the linear regulator and the linear controller
monitor FB2 and FB3 for under-voltage to protect against
excessive currents.
Figures 8 and 9 illustrate the over-current protection with
an overload on OUT1. The overload is applied at T0 and
the current increases through the output inductor (LOUT1).
At time T1, the OVER-CURRENT1 comparator trips when
the voltage across Q1 (ID • rDS(ON)) exceeds the level
programmed by ROCSET. This inhibits all outputs,
discharges the soft-start capacitor (CSS) with a 11mA
current sink, and increments the counter. CSS recharges at
T2 and initiates a soft-start cycle with the error amplifiers
clamped by soft-start. With OUT1 still overloaded, the
inductor current increases to trip the over-current
comparator. Again, this inhibits all outputs, but the soft-start
voltage continues increasing to 4V before discharging. The
counter increments to 2. The soft-start cycle repeats at T3
and trips the over-current comparator. The SS pin voltage
increases to 4V at T4 and the counter increments to 3. This
sets the fault latch to disable the converter. The fault is
reported on the FAULT/RT pin.
FAULT
REPORTED
10V
0V
COUNT
=1
SOFT-START
Over-Voltage Protection
INDUCTOR CURRENT
allows VOUT2 and VOUT3 to slew up without generating a
fault. Cycling the bias input voltage (+12VIN on the VCC
pin) off then on resets the counter and the fault latch.
FAULT/RT
HIP6017
COUNT
=2
COUNT
=3
4V
2V
0V
OVERLOAD
APPLIED
0A
T0 T1
T2
T3
T4
TIME
FIGURE 8. OVER-CURRENT OPERATION
The linear regulator operates in the same way as PWM1 to
over-current faults. Additionally, the linear regulator and
linear controller monitor the feedback pins for an undervoltage. Should excessive currents 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. Blanking the
LUV signal during the CSS charge interval allows the linear
outputs to build above the under-voltage threshold during
normal start-up. Cycling the bias input power off then on
resets the counter and the fault latch.
Resistor ROCSET1 programs the over-current trip level for the
PWM converter. As shown in Figure 9, the internal 200µA
current sink develops a voltage across ROCSET (VSET) that is
referenced to VIN . The DRIVE signal enables the over-current
comparator (OVER-CURRENT1). When the voltage across
the upper MOSFET (VDS(ON)) exceeds VSET, the overcurrent comparator trips to set the over-current latch. Both
VSET and VDS are referenced to VIN and a small capacitor
across ROCSET helps VOCSET track the variations of VIN due
to MOSFET switching. The over-current function will trip at a
peak inductor current (IPEAK) determined by:
I OCSET × R OCSET
I PEAK = ---------------------------------------------------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 temperature.
2. The minimum IOCSET from the specification table.
3. Determine IPEAK for IPEAK > IOUT(MAX) + (∆I) / 2, where
∆I is the output inductor ripple current.
2-217
HIP6017
For an equation for the output inductor ripple current see the
section under component guidelines titled ‘Output Inductor
Selection’.
OVER-CURRENT TRIP: VDS > VSET
VIN = +5V
(iD x rDS(ON) > IOCSET • ROCSET)
OCSET
IOCSET
200µA
ROCSET
VSET +
iD
Shutdown
The PWM output does not switch until the soft-start voltage
(VSS) exceeds the oscillator’s valley voltage. Additionally, the
reference on each linear’s amplifier is clamped to the softstart voltage. Holding the SS pin low with an open drain or
collector signal turns off all three regulators.
The VID codes resulting in an INHIBIT as shown in Table 1
also shuts down the IC.
TABLE 1. VOUT1 VOLTAGE PROGRAM
VCC
+
UGATE
DRIVE
OC1
+
PHASE
-
OVERCURRENT1
PWM
VCC
LGATE
GATE
CONTROL
VPHASE = VIN - VDS
VOCSET = VIN - VSET
PGND
HIP6017
FIGURE 9. OVER-CURRENT DETECTION
OUT1 Voltage Program
The output voltage of the PWM converter is programmed to
discrete levels between 1.8VDC and 3.5VDC . This output is
designed to supply the microprocessor core voltage. The
voltage identification (VID) pins program an internal voltage
reference (DACOUT) through a TTL-compatible 5-bit
digital-to-analog converter. The level of DACOUT also sets
the PGOOD and OVP thresholds. Table 1 specifies the
DACOUT voltage for the different combinations of
connections on the VID pins. The VID pins can be left open
for a logic 1 input, because they are internally pulled up to
+5V by a 10µA (typically) current source. Changing the VID
inputs during operation is not recommended. The sudden
change in the resulting reference voltage could toggle the
PGOOD signal and exercise the over-voltage protection. All
VID pin combinations resulting in an INHIBIT disable the IC
and the open-collector at the PGOOD pin.
Application Guidelines
Soft-Start Interval
Initially, the soft-start function clamps the error amplifier’s
output of the PWM converter. After the output voltage
increases to approximately 80% of the set value, the
reference input of the error amplifier is clamped to a voltage
proportional to the SS pin voltage. Both linear outputs follow
a similar start-up sequence. The resulting output voltage
sequence is shown in Figure 6.
The soft-start function controls the output voltage rate of rise
to limit the current surge at start-up. The soft-start interval is
programmed by the soft-start capacitor, CSS. Programming
a faster soft-start interval increases the peak surge current.
The peak surge current occurs during the initial output
voltage rise to 80% of the set value.
2-218
PIN NAME
VID4
VID3
VID2
VID1
VID0
NOMINAL
OUT1
VOLTAGE
DACOUT
0
1
X
X
X
INHIBIT
0
0
1
1
X
INHIBIT
0
0
1
0
1
1.80
0
0
1
0
0
1.85
0
0
0
1
1
1.90
0
0
0
1
0
1.95
0
0
0
0
1
2.00
0
0
0
0
0
2.05
1
1
1
1
1
INHIBIT
1
1
1
1
0
2.1
1
1
1
0
1
2.2
1
1
1
0
0
2.3
1
1
0
1
1
2.4
1
1
0
1
0
2.5
1
1
0
0
1
2.6
1
1
0
0
0
2.7
1
0
1
1
1
2.8
1
0
1
1
0
2.9
1
0
1
0
1
3.0
1
0
1
0
0
3.1
1
0
0
1
1
3.2
1
0
0
1
0
3.3
1
0
0
0
1
3.4
1
0
0
0
0
3.5
VDS
NOTE: 0 = connected to GND or VSS, 1 = open or connected to 5V
through pull-up resistors, X = don’t care
Layout Considerations
MOSFETs switch very fast and efficiently. The speed with
which the current transitions from one device to another
causes voltage spikes across the interconnecting
impedances and parasitic circuit elements. The voltage
spikes can degrade efficiency, radiate noise into the circuit,
and lead to device over-voltage stress. Careful component
HIP6017
The power components should be placed first. Locate the
input capacitors close to the power switches. Minimize the
length of the connections between the input capacitors and
the power switches. Locate the output inductor and output
capacitors between the MOSFETs and the load. Locate the
PWM controller close to the MOSFETs.
The critical small signal components include the bypass
capacitor for VCC and the soft-start capacitor, CSS. Locate
these components close to their connecting pins on the
control IC. Minimize any leakage current paths from SS node
because the internal current source is only 11µA.
A multi-layer printed circuit board is recommended.
Figure 10 shows the connections of the critical components
in the converter. Note that capacitors CIN and COUT could
each represent numerous physical capacitors. Dedicate one
solid layer for a ground plane and make all critical
component ground connections with vias to this layer.
Dedicate another solid layer as a power plane and break this
plane into smaller islands of common voltage levels. The
power plane should support the input power and output
power nodes. Use copper filled polygons on the top and
bottom circuit layers for the phase nodes. Use the remaining
printed circuit layers for small signal wiring. The wiring traces
from the control IC to the MOSFET gate and source should
be sized to carry 1A currents. The traces for OUT2 need only
be sized for 0.2A. Locate COUT2 close to the HIP6017 IC.
PWM Controller Feedback Compensation
Both PWM controllers use voltage-mode control for output
regulation. This section highlights the design consideration
for a voltage-mode controller. Apply the methods and
considerations to both PWM controllers.
+3.3VIN
+12V
CIN
CVCC
COCSET1
VCC GND
VIN2
OCSET1
VOUT3
Q3
GATE3 UGATE1
ROCSET1
Q1
LOUT1
Q2
COUT1
LOAD
HIP6018
VOUT2 LGATE1
CR1
SS PGND
CSS
VOUT2
KEY
COUT2
ISLAND ON POWER PLANE LAYER
ISLAND ON CIRCUIT PLANE LAYER
VIA CONNECTION TO GROUND PLANE
FIGURE 10. PRINTED CIRCUIT BOARD POWER PLANES AND
ISLANDS
Figure 11 highlights the voltage-mode control loop for a
synchronous-rectified buck converter. The output voltage is
regulated to the reference voltage level. The reference voltage
level is the DAC output voltage for the PWM controller. The
error amplifier output (VE/A) is compared with the oscillator
(OSC) triangular wave to provide a pulse-width modulated
wave with an amplitude of VIN at the PHASE node. The PWM
wave is smoothed by the output filter (LO and CO).
VIN
DRIVER
OSC
∆ VOSC
PWM
COMP
LO
-
DRIVER
VOUT
PHASE
+
CO
ESR
(PARASITIC)
ZFB
VE/A
ZIN
ERROR
AMP
+
REFERENCE
DETAILED FEEDBACK COMPENSATION
ZFB
VOUT
C2
C1
ZIN
C3
R2
R3
R1
COMP
+
HIP6017
FB
REFERENCE
FIGURE 11. VOLTAGE-MODE BUCK CONVERTER
COMPENSATION DESIGN
2-219
VOUT1
PHASE1
LOAD
There are two sets of critical components in a DC-DC
converter using a HIP6017 controller. The power
components are the most critical because they switch large
amounts of energy. The critical small signal components
connect to sensitive nodes or supply critical bypassing
current.
+5VIN
LOAD
layout and printed circuit design minimizes the voltage
spikes in the converter. Consider, as an example, the turnoff
transition of the upper PWM MOSFET. Prior to turnoff, the
upper MOSFET was carrying the full load current. During the
turnoff, current stops flowing in the upper MOSFET and is
picked up by the lower MOSFET (and/or parallel Schottky
diode). Any inductance in the switched current path
generates a large voltage spike during the switching interval.
Careful component selection, tight layout of the critical
components, and short, wide circuit traces minimize the
magnitude of voltage spikes. Contact Intersil for evaluation
board drawings of the component placement and printed
circuit board.
HIP6017
Modulator Break Frequency Equations
1
F LC = ---------------------------------------2π × L O × C O
1
F ESR = ----------------------------------------2π × ESR × C O
The compensation network consists of the error amplifier
internal to the HIP6017 and the impedance networks ZIN
and ZFB . The goal of the compensation network is to
provide a closed loop transfer function with an acceptable
0dB crossing frequency (f0dB) and adequate phase margin.
Phase margin is the difference between the closed loop
phase at f0dB and 180 degrees. The equations below relate
the compensation network’s poles, zeros and gain to the
components (R1, R2, R3, C1, C2, and C3) in Figure 11.
Use these guidelines for locating the poles and zeros of the
compensation network:
100
FZ1 FZ2
FP1
FP2
80
OPEN LOOP
ERROR AMP GAIN
60
GAIN (dB)
The modulator transfer function is the small-signal transfer
function of VOUT/VE/A. This function is dominated by a DC
gain and the output filter, with a double pole break frequency
at FLC and a zero at FESR. The DC gain of the modulator is
simply the input voltage, VIN , divided by the peak-to-peak
oscillator voltage, ∆VOSC .
40
20
20LOG
(R2/R1)
0
20LOG
(VIN/∆VOSC)
MODULATOR
GAIN
-20
COMPENSATION
GAIN
CLOSED LOOP
GAIN
-40
FLC
-60
10
100
1K
FESR
10K
100K
1M
10M
FREQUENCY (Hz)
FIGURE 12. ASYMPTOTIC BODE PLOT OF CONVERTER GAIN
1. Pick Gain (R2/R1) for desired converter bandwidth
The compensation gain uses external impedance networks
ZFB and ZIN to provide a stable, high bandwidth loop. A
stable control loop has a 0dB gain crossing with
-20dB/decade slope and a phase margin greater than 45
degrees. Include worst case component variations when
determining phase margin.
2. Place 1ST Zero Below Filter’s Double Pole (~75% FLC)
Component Selection Guidelines
3. Place 2ND Zero at Filter’s Double Pole
4. Place 1ST Pole at the ESR Zero
Output Capacitor Selection
5. Place 2ND Pole at Half the Switching Frequency
The output capacitors for each output have unique
requirements. In general the output capacitors should be
selected to meet the dynamic regulation requirements.
Additionally, the PWM converters require an output capacitor
to filter the current ripple. The linear regulator is internally
compensated and requires an output capacitor that meets
the stability requirements. The load transient for the
microprocessor core requires high quality capacitors to
supply the high slew rate (di/dt) current demands.
6. Check Gain against Error Amplifier’s Open-Loop Gain
7. Estimate Phase Margin - Repeat if Necessary
Compensation Break Frequency Equations
1
F Z1 = ----------------------------------2π × R 2 × C1
1
F P1 = ------------------------------------------------------C1 × C2
2π × R 2 ×  ----------------------
 C1 + C2
1
F Z2 = ------------------------------------------------------2π × ( R1 + R3 ) × C3
1
F P2 = ----------------------------------2π × R 3 × C3
Figure 12 shows an asymptotic plot of the DC-DC
converter’s gain vs frequency. The actual modulator gain has
a peak due to the high Q factor of the output filter at FLC,
which is not shown in Figure 12. Using the above guidelines
should yield a compensation gain similar to the curve
plotted. The open loop error amplifier gain bounds the
compensation gain. Check the compensation gain at FP2
with the capabilities of the error amplifier. The closed loop
gain is constructed on the log-log graph of Figure 12 by
adding the modulator gain (in dB) to the compensation gain
(in dB). This is equivalent to multiplying the modulator
transfer function to the compensation transfer function and
plotting the gain.
PWM Output Capacitors
Modern microprocessors produce transient load rates above
10A/ns. High frequency capacitors initially supply the
transient and slow the current load rate seen by the bulk
capacitors. The bulk filter capacitor values are generally
determined by the ESR (effective series resistance) and ESL
(effective series inductance) parameters rather than actual
capacitance.
High frequency decoupling capacitors should be placed as
close to the power pins of the load as physically possible. Be
careful not to add inductance in the circuit board wiring that
could cancel the usefulness of these low inductance
components. Consult with the manufacturer of the load on
specific decoupling requirements.
Use only specialized low-ESR capacitors intended for
switching regulator applications for the bulk capacitors. The
bulk capacitor’s ESR determines the output ripple voltage
and the initial voltage drop after a high slew-rate transient.
An aluminum electrolytic capacitor’s ESR value is related to
2-220
HIP6017
the case size with lower ESR available in larger case sizes.
However, the equivalent series inductance of these
capacitors increases with case size and can reduce the
usefulness of the capacitor to high slew-rate transient
loading. Unfortunately, ESL is not a specified parameter.
Work with your capacitor supplier and measure the
capacitor’s impedance with frequency to select suitable
components. In most cases, multiple electrolytic capacitors
of small case size perform better than a single large case
capacitor. For a given transient load magnitude, the output
voltage transient response due to the output capacitor
characteristics can be approximated by the following
equation:
dI TRAN
V TRAN = ESL × --------------------- + ESR × I TRAN
dt
Linear Output Capacitors
The output capacitors for the linear regulator and the linear
controller provide dynamic load current. The linear controller
uses dominant pole compensation integrated in the error
amplifier and is insensitive to output capacitor selection.
Capacitor, COUT3 should be selected for transient load
regulation.
The output capacitor for the linear regulator provides loop
stability. The linear regulator (OUT2) requires an output
capacitor characteristic shown in Figure 13. The upper line
plots the 45 phase margin with 150mA load and the lower
line is the 45 phase margin limit with a 10mA load. Select a
COUT2 capacitor with characteristic between the two limits.
0.7
0.6
ESR (Ω)
0.5
0.4
0.3
current. The ripple voltage and current are approximated by
the following equations:
V IN – V OUT V OUT
∆I = -------------------------------- × ---------------V IN
FS × LO
∆V OUT = ∆I × ESR
Increasing the value of inductance reduces the ripple current
and voltage. However, the large inductance values reduce
the converter’s response time to a load transient.
One of the parameters limiting the converter’s response to a
load transient is the time required to change the inductor
current. Given a sufficiently fast control loop design, the
HIP6017 will provide either 0% or 100% duty cycle in
response to a load transient. The response time is the time
interval required to slew the inductor current from an initial
current value to the post-transient current level. During this
interval the difference between the inductor current and the
transient current level must be supplied by the output
capacitors. Minimizing the response time can minimize the
output capacitance required.
The response time to a transient is different for the
application of load and the removal of load. The following
equations give the approximate response time interval for
application and removal of a transient load:
L O × I TRAN
t RISE = -------------------------------V IN – V OUT
L O × I TRAN
t FALL = ------------------------------V OUT
where: ITRAN is the transient load current step, tRISE is the
response time to the application of load, and tFALL is the
response time to the removal of load. With a +5V input
source, the worst case response time can be either at the
application or removal of load, and dependent upon the
output voltage setting. Be sure to check both of these
equations at the minimum and maximum output levels for the
worst case response time.
Input Capacitor Selection
LE N
AB IO
ST RAT
E
OP
0.2
0.1
10
100
1000
CAPACITANCE (µF)
FIGURE 13. COUT2 OUTPUT CAPACITOR
Output Inductor Selection
The PWM converter requires an output inductor. The output
inductor is selected to meet the output voltage ripple
requirements and sets the converter’s response time to a
load transient. The inductor value determines the converter’s
ripple current and the ripple voltage is a function of the ripple
2-221
The important parameters for the bulk input capacitor are the
voltage rating and the RMS current rating. For reliable
operation, select the bulk capacitor with voltage and current
ratings above the maximum input voltage and largest RMS
current required by the circuit. The capacitor voltage rating
should be at least 1.25 times greater than the maximum
input voltage and a voltage rating of 1.5 times is a
conservative guideline.
Use a mix of input bypass capacitors to control the voltage
overshoot across the MOSFETs. Use ceramic capacitance
for the high frequency decoupling and bulk capacitors to
supply the RMS current. Small ceramic capacitors should be
placed very close to the upper MOSFET to suppress the
voltage induced in the parasitic circuit impedances.
For a through hole design, several electrolytic capacitors
(Panasonic HFQ series or Nichicon PL series or Sanyo
MV-GX or equivalent) may be needed. For surface mount
designs, solid tantalum capacitors can be used, but caution
HIP6017
must be exercised with regard to the capacitor surge current
rating. These capacitors must be capable of handling the
surge-current at power-up. The TPS series available from
AVX, and the 593D series from Sprague are both surge
current tested.
absolute gate-to-source voltage rating exceeds the
maximum voltage applied to VCC .
+5V OR LESS
+12V
VCC
MOSFET Selection/Considerations
The HIP6017 requires 3 N-Channel power MOSFETs. Two
MOSFETs are used in the synchronous-rectified buck
topology of the PWM converter. The linear controller drives a
MOSFET as a pass transistor. These should be selected
based upon rDS(ON) , gate supply requirements, and thermal
management requirements.
HIP6017
UGATE
PHASE
-
+
PWM1 MOSFET Selection and Considerations
In high-current PWM applications, the MOSFET power
dissipation, package selection and heatsink are the
dominant design factors. The power dissipation includes two
loss components; conduction loss and switching loss. These
losses are distributed between the upper and lower
MOSFETs according to duty factor (see the equations
below). The conduction loss is the only component of power
dissipation for the lower MOSFET. Only the upper MOSFET
has switching losses, since the lower device turns on into
near zero voltage.
The equations below assume linear voltage-current
transitions and do not model power loss due to the reverserecovery of the lower MOSFET’s body diode. The gatecharge losses are proportional to the switching frequency
(FS) and are dissipated by the HIP6017, thus not
contributing to the MOSFETs’ temperature rise. However,
large gate charge increases the switching interval, tSW
which increases the upper MOSFET switching losses.
Ensure that both MOSFETs are within their maximum
junction temperature at high ambient temperature by
calculating the temperature rise according to package
thermal resistance specifications. A separate heatsink may
be necessary depending upon MOSFET power, package
type, ambient temperature and air flow.
2
I O × r DS ( ON ) × V OUT I O × V IN × t SW × F S
P UPPER = ------------------------------------------------------------ + ---------------------------------------------------V IN
2
2
I O × r DS ( ON ) × ( V IN – V OUT )
P LOWER = --------------------------------------------------------------------------------V IN
The rDS(ON) is different for the two previous equations even
if the type device is used for both. This is because the gate
drive applied to the upper MOSFET is different than the
lower MOSFET. Figure 14 shows the gate drive where the
upper gate-to-source voltage is approximately VCC less the
input supply. For +5V main power and +12VDC for the bias,
the gate-to-source voltage of Q1 is 7V. The lower gate drive
voltage is +12VDC. A logic-level MOSFET is a good choice
for Q1 and a logic-level MOSFET can be used for Q2 if its
2-222
Q1
LGATE
NOTE:
VGS ≈ VCC -5V
Q2
CR1
PGND
NOTE:
VGS ≈ VCC
GND
FIGURE 14. OUTPUT GATE DRIVERS
Rectifier CR1 is a clamp that catches the negative inductor
voltage swing during the dead time between the turn off of
the lower MOSFET and the turn on of the upper MOSFET.
The diode must be a Schottky type to prevent the lossy
parasitic MOSFET body diode from conducting. It is
acceptable to omit the diode and let the body diode of the
lower MOSFET clamp the negative inductor swing, but
efficiency might drop one or two percent as a result. The
diode's rated reverse breakdown voltage must be greater
than twice the maximum input voltage.
Linear Controller MOSFET Selection
The main criteria for selection of MOSFET for the linear
regulator is package selection for efficient removal of heat.
The power dissipated in a linear regulator is:
P LINEAR = I O × ( V IN – V OUT )
Select a package and heatsink that maintains the junction
temperature below the maximum rating while operating at
the highest expected ambient temperature.
HIP6017
HIP6017 DC-DC Converter Application Circuit
Figure 15 shows an application circuit of a power supply for
a microprocessor computer system. The power supply
provides the microprocessor core voltage (VOUT1), the GTL
bus voltage (VOUT3) and clock generator voltage (VOUT2)
from +3.3VDC, +5VDC and +12VDC . For detailed
+12VIN
F1
+5VIN
15A
L1
1µH
C1-4
4x1000µF
GND
information on the circuit, including a Bill-of-Materials and
circuit board description, see Application Note AN9800. Also
see Intersil’s web page (http://www.intersil.com) or Intersil
AnswerFAX (407-724-7800) document number 99800 for the
latest information.
+
C15
1µF
C16
1µF
C18
VCC
1000pF
R2
28
GND2
23
OCSET1 1.3K
9
POWERGOOD
8
NC
NC
1
2
27
26
PGOOD
Q1
HUF76139S3S
UGATE1
PHASE1
L3
VOUT1
(1.8 TO 3.5V)
2.9µH
25
24
VIN2
+3.3VIN
+
V33
C19
1000µF
NC
HIP6017
15
22
10
21
C24-36 +
7x1000µF
Q2
HUF76139S3S
LGATE1
PGND
R4
4.99K
VSEN1
FB1
R8
C40
2.21K
0.68µF
11
20
COMP1
C41
10pF
Q3
HUF75307D3S
DRIVE3
VOUT3
R11
(1.5V)
1.87K
+
C43-46
4x1000µF
R13
(2.5V)
10K
C47
270µF
18
6
5
19
4
R12
10K
VOUT2
VOUT2
+
FB3
7
FB2
R14
10K
3
16
12
14
VID0
C42
R10
0.01µF
150K
R9
732K
VID0
VID1
VID2
VID3
VID4
VID1
VID2
VID3
VID4
SS
C48
0.039µF
13
17
GND
FAULT/RT
FIGURE 15. APPLICATION CIRCUIT
All Intersil semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certification.
Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
For information regarding Intersil Corporation and its products, see web site http://www.intersil.com
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