FN4838.1

HIP6602

Dual Channel Synchronous-Rectified

Buck MOSFET Driver

The HIP6602 is a high frequency, two power channel
MOSFET driver specifically designed to drive four power
N-Channel MOSFETs in a synchronous-rectified buck
converter topology. These drivers combined with a HIP63xx
series of Multi-Phase Buck PWM controller and Intersil's
UltraFETs® form a complete core voltage regulator solution
for advanced microprocessors.

The HIP6602 drives both upper and lower gates over a
range of 5V to 12V. This drive-voltage flexibility provides the
advantage of optimizing applications involving trade-offs
between switching losses and conduction losses.

The output drivers in the HIP6602 have the capacity to
efficiently switch power MOSFETs at high frequencies. Each
driver is capable of driving a 3000pF load with a 30ns
propagation delay and 50ns transition time. This device
implements bootstrapping on the upper gates with only a
single external capacitor required for each power channel.
This reduces implementation complexity and allows the use
of higher performance, cost effective, N-Channel MOSFETs.
Adaptive shoot-through protection is integrated to prevent
both MOSFETs from conducting simultaneously.

Features

· Drives Four N-channel MOSFETs

· Adaptive Shoot-Through Protection

· Internal Bootstrap Devices

· Supports High Switching Frequency

- Fast Output Rise Time
- Propagation Delay 30ns

· Small 14-Lead SOIC Package

· 5V to 12V Gate-Drive Voltages for Optimal Efficiency

· Three-State Input for Bridge Shutdown

· Supply Under-Voltage Protection

Applications

· Core Voltage Supplies for Intel Pentium® III

and AMD®

Athlon

Microprocessors.

· High Frequency Low Profile DC/DC Converters

· High Current Low Voltage DC/DC Converters

Pinout

HIP6602CB

(SOIC)

TOP VIEW

Ordering Information

PART NUMBER

TEMP. RANGE

(°C)

PACKAGE

PKG. NO.

HIP6602CB

0 to 85

14 Ld SOIC

M14.15

HIP6602CB-T

14 Ld SOIC Tape and Reel

PWM1

PWM2

GND

LGATE1

PHASE1

UGATE1

BOOT1

PVCC

BOOT2

UGATE2

PHASE2

VCC

PGND

LGATE2

Data Sheet

August 2000

CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.

1-888-INTERSIL or 1-888-468-3774

Intersil Corporation 2000, 2005

Pentium

is a registered trademark of Intel Corporation.; AMD

is a registered trademark of Advanced Micro Devices, Inc.

UltraFET® is a registered trademark of Intersil Corporation. AthlonTM is a trademark of Advanced Micro Devices, Inc.

NOT

RECO

MME

NDED

FOR

NEW

DES

IGNS

POSS

IBLE

SUB

STITU

TE P

ROD

UCTS

(ISL6

6014

, ISL6

614A

, and

ISL6

614B

)

Absolute Maximum Ratings

Thermal Information

Supply Voltage (VCC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15V
Supply Voltage (PVCC) . . . . . . . . . . . . . . . . . . . . . . . . . VCC + 0.3V
BOOT Voltage (V

BOOT

- V

PHASE

) . . . . . . . . . . . . . . . . . . . . . . .15V

Input Voltage (VPWM) . . . . . . . . . . . . . . . . . . . . . . GND - 0.3V to 7V
UGATE. . . . . . . . . . . . . . . . . . . . . . V

PHASE

- 0.3V to V

BOOT

+ 0.3V

LGATE . . . . . . . . . . . . . . . . . . . . . . . . .GND - 0.3V to V

PVCC

+ 0.3V

ESD Rating

Human Body Model (Per MIL-STD-883 Method 3015.7) . . . . .3kV
Machine Model (Per EIAJ ED-4701 Method C-111) . . . . . . .200V

Operating Conditions

Ambient Temperature Range. . . . . . . . . . . . . . . . . . . . . 0°C to 85°C
Maximum Operating Junction Temperature. . . . . . . . . . . . . . . 125°C
Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12V

10%

Supply Voltage Range PVCC . . . . . . . . . . . . . . . . . . . . . 5V to 12V

Thermal Resistance (Note 1)

(°C/W)

SOIC Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Maximum Junction Temperature (Plastic Package) . . . . . . . . 150°C
Maximum Storage Temperature Range . . . . . . . . . . -65°C to 150°C
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . . 300°C

(SOIC - Lead Tips Only)

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:

is measured with the component mounted on a high effective thermal conductivity test board in free air. See Tech Brief TB379 for details.

Electrical Specifications

Recommended Operating Conditions, Unless Otherwise Noted

PARAMETER

SYMBOL

TEST CONDITIONS

MIN

TYP

MAX

UNITS

VCC SUPPLY CURRENT

Bias Supply Current

VCC

PWM

= 500kHz, V

PVCC

= 12V

3.7

5.0

Power Supply Current

PVCC

PWM

= 500kHz, V

PVCC

= 12V

2.0

4.0

POWER-ON RESET

VCC Rising Threshold

9.7

9.95

10.4

VCC Falling Threshold

9.0

9.2

9.5

PWM INPUT

Input Current

PWM

= 0 or 5V (See Block Diagram)

500

PWM Rising Threshold

PVCC

= 12V

3.45

3.6

PWM Falling Threshold

PVCC

= 12V

1.45

1.55

UGATE Rise Time

UGATE

PVCC

= V

VCC

= 12V, 3nF Load

LGATE Rise Time

LGATE

PVCC

= V

VCC

= 12V, 3nF Load

UGATE Fall Time

UGATE

PVCC

= V

VCC

= 12V, 3nF Load

LGATE Fall Time

LGATE

PVCC

= V

VCC

= 12V, 3nF Load

UGATE Turn-Off Propagation Delay

TPDL

UGATE

PVCC

= V

VCC

= 12V, 3nF Load

LGATE Turn-Off Propagation Delay

TPDL

LGATE

PVCC

= V

VCC

= 12V, 3nF Load

Shutdown Window

1.4

3.6

Shutdown Holdoff Time

230

OUTPUT

Upper Drive Source Impedance

UGATE

VCC

= 12V, V

PVCC

= 5V

1.7

3.0

VCC

= V

PVCC

= 12V

3.0

5.0

Upper Drive Sink Impedance

UGATE

VCC

= 12V, V

PVCC

= 5V

2.3

4.0

VCC

= V

PVCC

= 12V

1.1

2.0

Lower Drive Source Current

LGATE

VCC

= 12V, V

PVCC

= 5V

400

580

VCC

= V

PVCC

= 12V

500

730

Lower Drive Sink Impedance

LGATE

VCC

= 12V, V

PVCC

= 5V or 12V

1.6

4.0

HIP6602

Functional Pin Descriptions

PWM1 (Pin 1) and PWM2 (Pin 2)

The PWM signal is the control input for the driver. The PWM
signal can enter three distinct states during operation, see the
three-state PWM Input section under DESCRIPTION for further
details. Connect this pin to the PWM output of the controller.

GND (Pin 3)

Bias and reference ground. All signals are referenced to this
node.

LGATE1 (Pin 4) and LGATE2 (Pin 7)

Lower gate drive outputs. Connect to gates of the low-side
power N-Channel MOSFETs.

PVCC (Pin 5)

This pin supplies the upper and lower gate drivers bias.
Connect this pin from +12V down to +5V.

PGND (Pin 6)

This pin is the power ground return for the lower gate
drivers.

PHASE2 (Pin 8) and PHASE1 (Pin 13)

Connect these pins to the source of the upper MOSFETs
and the drain of the lower MOSFETs. The PHASE voltage is
monitored for adaptive shoot-through protection. These pins
also provide a return path for the upper gate drive.

UGATE2 (Pin 9) and UGATE1 (Pin 12)

Upper gate drive outputs. Connect to gate of high-side
power N-Channel MOSFETs.

BOOT 2 (Pin 10) and BOOT 1 (Pin 11)

Floating bootstrap supply pins for the upper gate drivers.
Connect the bootstrap capacitor between these pins and the

PHASE pin. The bootstrap capacitor provides the charge to
turn on the upper MOSFETs. See the Internal Bootstrap
Device section under DESCRIPTION for guidance in
choosing the appropriate capacitor value.

VCC (Pin 14)

Connect this pin to a +12V bias supply. Place a high quality
bypass capacitor from this pin to GND. To prevent forward
biasing an internal diode, this pin should be more positive
then PVCC during converter start-up.

Description

Operation

Designed for versatility and speed, the HIP6602 two channel,
dual MOSFET driver controls both high-side and low-side
N-Channel FETs from two externally provided PWM signals.

The upper and lower gates are held low until the driver is
initialized. Once the VCC voltage surpasses the VCC Rising
Threshold (See Electrical Specifications), the PWM signal
takes control of gate transitions. A rising edge on PWM
initiates the turn-off of the lower MOSFET (see Timing
Diagram). After a short propagation delay [TPDL

LGATE

], the

lower gate begins to fall. Typical fall times [TF

LGATE

] are

provided in the Electrical Specifications section. Adaptive
shoot-through circuitry monitors the LGATE voltage and
determines the upper gate delay time [TPDH

UGATE

] based

on how quickly the LGATE voltage drops below 1.0V. This
prevents both the lower and upper MOSFETs from
conducting simultaneously or shoot-through. Once this delay
period is complete the upper gate drive begins to rise
[TR

UGATE

] and the upper MOSFET turns on.

Timing Diagram

PWM

UGATE

LGATE

TPDL

LGATE

TPDH

UGATE

TPDL

UGATE

TPDH

LGATE

HIP6602

A falling transition on PWM indicates the turn-off of the
upper MOSFET and the turn-on of the lower MOSFET. A
short propagation delay [TPDL

UGATE

] is encountered

before the upper gate begins to fall [TF

UGATE

]. Again, the

adaptive shoot-through circuitry determines the lower gate
delay time, TPDH

LGATE

. The PHASE voltage is monitored

and the lower gate is allowed to rise after PHASE drops
below 0.5V. The lower gate then rises [TR

LGATE

], turning

on the lower MOSFET.

Three-State PWM Input

A unique feature of the HIP6602 drivers is the addition of a
shutdown window to the PWM input. If the PWM signal
enters and remains within the shutdown window for a set
holdoff time, the output drivers are disabled and both
MOSFET gates are pulled and held low. The shutdown state
is removed when the PWM signal moves outside the
shutdown window. Otherwise, the PWM rising and falling
thresholds outlined in the ELECTRICAL SPECIFICATIONS
determine when the lower and upper gates are enabled.

Adaptive Shoot-Through Protection

The drivers incorporate adaptive shoot-through protection to
prevent upper and lower MOSFETs from conducting
simultaneously and shorting the input supply. This is
accomplished by ensuring the falling gate has turned off one
MOSFET before the other is allowed to rise.

During turn-off of the lower MOSFET, the LGATE voltage is
monitored until it reaches a 1.0V threshold, at which time the
UGATE is released to rise. Adaptive shoot-through circuitry
monitors the PHASE voltage during UGATE turn-off. Once
PHASE has dropped below a threshold of 0.5V, the LGATE
is allowed to rise. If the PHASE does not drop below 0.5V
within 250ns, LGATE is allowed to rise. This is done to
generate the bootstrap refresh signal. PHASE continues to
be monitored during the lower gate rise time. If the PHASE
voltage exceeds the 0.5V threshold during this period and
remains high for longer than 2

s, the LGATE transitions low.

This is done to make the lower MOSFET emulate a diode.
Both upper and lower gates are then held low until the next
rising edge of the PWM signal.

Power-On Reset (POR) Function

During initial start-up, the VCC voltage rise is monitored and
gate drives are held low until a typical VCC rising threshold
of 9.95V is reached. Once the rising VCC threshold is
exceeded, the PWM input signal takes control of the gate
drives. If VCC drops below a typical VCC falling threshold of
9.2V during operation, then both gate drives are again held
low. This condition persists until the VCC voltage exceeds
the VCC rising threshold.

Internal Bootstrap Device

Both drivers feature an internal bootstrap device. Simply
adding an external capacitor across the BOOT and PHASE
pins completes the bootstrap circuit.

The bootstrap capacitor must have a maximum voltage
rating above PVCC + 5V. The bootstrap capacitor can be
chosen from the following equation:

Where Q

GATE

is the amount of gate charge required to fully

charge the gate of the upper MOSFET. The

BOOT

term is

defined as the allowable droop in the rail of the upper drive.

As an example, suppose a HUF76139 is chosen as the
upper MOSFET. The gate charge, Q

GATE

, from the data

sheet is 65nC for a 10V upper gate drive. We will assume a
200mV droop in drive voltage over the PWM cycle. We find
that a bootstrap capacitance of at least 0.325

F is required.

The next larger standard value capacitance is 0.33

Gate Drive Voltage Versatility

The HIP6602 provides the user flexibility in choosing the
gate drive voltage. Simply applying a voltage from 5V up to
12V on PVCC will set both driver rail voltages.

Power Dissipation

Package power dissipation is mainly a function of the switching
frequency and total gate charge of the selected MOSFETs.
Calculating the power dissipation in the driver for a desired
application is critical to ensuring safe operation. Exceeding the
maximum allowable power dissipation level will push the IC
beyond the maximum recommended operating junction
temperature of 125°C. The maximum allowable IC power
dissipation for the 14 lead SOIC package is approximately
1000mW. Improvements in thermal transfer may be gained by
increasing the PC board copper area around the HIP6602.
Adding a ground pad under the IC to help transfer heat to the
outer peripheral of the board will help. Also keeping the leads to
the IC as wide as possible and widening this these leads as
soon as possible to further enhance heat transfer will also help.

When designing the driver into an application, it is
recommended that the following calculation be performed to
ensure safe operation at the desired frequency for the
selected MOSFETs. The total chip power dissipation is
approximated as:

where f

is the switching frequency of the PWM signal. Q

and Q

is the upper and lower gate charge determined by

MOSFET selection and any external capacitance added to
the gate pins. The I

DDQ

VCC product is the quiescent power

of the driver and is typically 40mW.

The 1.05 term is a correction factor derived from the
following characterization. The base circuit for characterizing
the drivers for different loading profiles and frequencies is
provided. C

and C

are the upper and lower gate load

capacitors. Decoupling capacitors [0.15

F] are added to the

BOOT

GATE

BOOT

------------------------

P = 1.05 x f

x V

PVCC

[

+ Q

) + (Q

+ Q

)

]

+ I

DDQ

x VCC

HIP6602

PVCC and VCC pins. The bootstrap capacitor value in the
test circuit is 0.01

The power dissipation approximation is a result of power
transferred to and from the upper and lower gates. But, the
internal bootstrap device also dissipates power on-chip
during the refresh cycle. Expressing this power in terms of
the upper MOSFET total gate charge is explained below.

The bootstrap device conducts when the lower MOSFET or
its body diode conducts and pulls the PHASE node toward
GND. While the bootstrap device conducts, a current path is
formed that refreshes the bootstrap capacitor. Since the
upper gate is driving a MOSFET, the charge removed from
the bootstrap capacitor is equivalent to the total gate charge
of the MOSFET. Therefore, the refresh power required by
the bootstrap capacitor is equivalent to the power used to
charge the gate capacitance of the upper MOSFETs.

where Q

LOSS

is the total charge removed from the bootstrap

capacitors and provided to the upper gate loads.

In Figure 1, C

and C

values are the same and frequency

is varied from 10kHz to 2MHz. PVCC and VCC are tied
together to a +12V supply.

Figure 2 shows the dissipation in the driver with 1nF loading
on both gates and each individually. Figure 3 is the same as
Figure 2 except the capacitance is increased to 3nF.

The impact of loading on power dissipation is shown in
Figure 4. Frequency is held constant while the gate
capacitors are varied from 1nF to 5nF. VCC and PVCC are

tied together and to a +12V supply. Figures 5 through 7
show the same characterization for PVCC tied to +5V
instead of +12V. The gate supply voltage, PVCC, within the
HIP6602 sets both upper and lower gate driver supplies at
the same 5V level for the last three curves.

Test Circuit

REFRESH

LOSS

PVCC

BOOT1

UGATE1

PHASE1

LGATE1

PWM1

PVCC

VCC

0.15

100k

2N7002

0.01

+5V OR +12V

+12V

HIP66

0
2

UGATE2

PHASE2

LGATE2

100k

2N7002

0.01

PGND

PWM2

GND

BOOT2

+5V OR +12V

Typical Performance Curves

FIGURE 1. POWER DISSIPATION vs FREQUENCY

FIGURE 2. 1nF LOADING PROFILE

1200

1000

800

600

400

200

500

1000

1500

FREQUENCY (kHz)

WER (

PVCC = 12V

VCC = 12V

= C

= 2nF

= C

= 1nF

= C

= 3nF

= 4nF

= 5nF

1200

800

600

400

200

500

1000

2000

FREQUENCY (kHz)

WER (

1500

PVCC = VCC = 12V

1000

= C

= 1nF

= 1nF, C

= 0nF

= 1nF, C

= 0nF

HIP6602

FIGURE 3. 3nF LOADING PROFILE

FIGURE 4. POWER DISSIPATION vs LOADING

FIGURE 5. POWER DISSIPATION vs FREQUENCY, PVCC = 5V

FIGURE 6. POWER DISSIPATION vs FREQUENCY, PVCC = 5V

FIGURE 7. POWER DISSIPATION vs LOADING, PVCC = 5V

Typical Performance Curves

(Continued)

1200

800

600

400

200

500

1000

FREQUENCY (kHz)

POWE

R (m

1500

PVCC = VCC = 12V

1000

= C

= 3nF

= 3nF, C

= 0nF

= 3nF, C

= 0nF

10kHz

30kHz

100kHz

200kHz

500kHz

1200

1000

800

600

400

200

WER (mW)

GATE CAPACITANCE (C

= C

), (nF)

PVCC = VCC = 12V

PVCC = 5V, VCC = 12V

= C

= 4nF

= C

= 5nF

= C

= 2nF

= C

=1nF

800

700

500

600

300

100

500

1500

2000

FREQUENCY (kHz)

WER (mW)

1000

200

400

= C

= 3nF

500

1000

1500

2000

FREQUENCY (kHz)

350

300

250

200

150

100

WER (m

PVCC = 5V, VCC = 12V

= 1nF, C

= 0nF

= C

= 1nF

= 1nF, C

= 0nF

30kHz

100kHz

200kHz

500kHz

1MHz

2MHz

1.5MHz

PVCC = 5V,

VCC = 12V

POW

R (

600

500

400

300

200

100

GATE CAPACITANCE (C

= C

), (nF)

HIP6602

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 with-
out 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 www.intersil.com

HIP6602

Small Outline Plastic Packages (SOIC)

NOTES:

1. Symbols are defined in the "MO Series Symbol List" in Section 2.2 of

Publication Number 95.

2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
3. Dimension "D" does not include mold flash, protrusions or gate burrs.

Mold flash, protrusion and gate burrs shall not exceed 0.15mm (0.006
inch) per side.

4. Dimension "E" does not include interlead flash or protrusions. Interlead

flash and protrusions shall not exceed 0.25mm (0.010 inch) per side.

5. The chamfer on the body is optional. If it is not present, a visual index

feature must be located within the crosshatched area.

6. "L" is the length of terminal for soldering to a substrate.
7. "N" is the number of terminal positions.
8. Terminal numbers are shown for reference only.
9. The lead width "B", as measured 0.36mm (0.014 inch) or greater

above the seating plane, shall not exceed a maximum value of
0.61mm (0.024 inch).

10. Controlling dimension: MILLIMETER. Converted inch dimensions

are not necessarily exact.

INDEX

AREA

-B-

0.25(0.010)

C A

B S

-A-

-C-

SEATING PLANE

0.10(0.004)

h x 45

0.25(0.010)

M14.15

(JEDEC MS-012-AB ISSUE C)

14 LEAD NARROW BODY SMALL OUTLINE PLASTIC
PACKAGE

SYMBOL

INCHES

MILLIMETERS

NOTES

MIN

MAX

MIN

MAX

0.0532

0.0688

1.35

1.75

0.0040

0.0098

0.10

0.25

0.013

0.020

0.33

0.51

0.0075

0.0098

0.19

0.25

0.3367

0.3444

8.55

8.75

0.1497

0.1574

3.80

4.00

0.050 BSC

1.27 BSC

0.2284

0.2440

5.80

6.20

0.0099

0.0196

0.25

0.50

0.016

0.050

0.40

1.27

Rev. 0 12/93

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