MIC5021BM TR - MICROCHIP TECHNOLOGY

July 2005 1 MIC5021

MIC5021 Micrel, Inc.

MIC5021

High-Speed High-Side MOSFET Driver

Ordering Information

Part Number Temperature

Range

Package

Standard Pb-Free

MIC5021BM MIC5021YM –40ºC to +85ºC 8-pin SOIC

MIC5021BN MIC5021YN –40ºC to +85ºC 8-pin Plastic DIP

Features

• 12V to 36V operation

• 550ns rise/fall time driving 2000pF

• TTL compatible input with internal pull-down resistor

• Overcurrent limit

• Gate to source protection

• Internal charge pump

• 100kHz operation guaranteed over full temperature and

operating voltage range

• Compatible with current sensing MOSFETs

• Current source drive reduces EMI

Applications

• Lamp control

• Heater control

• Motor control

• Solenoid switching

• Switch-mode power supplies

• Circuit breaker

General Description

The MIC5021 high-side MOSFET driver is designed to oper-

ate at frequencies up to 100kHz (5kHz PWM for 2% to 100%

duty cycle) and is an ideal choice for high speed applications

such as motor control, SMPS (switch mode power supplies),

and applications using IGBTs. The MIC5021 can also operate

as a circuit breaker with or without automatic retry.

A rising or falling edge on the input results in a current source

pulse or sink pulse on the gate output. This output current

pulse can turn on a 2000pF MOSFET in approximately 550ns.

The MIC5021 then supplies a limited current (< 2mA), if

necessary, to maintain the output state.

An overcurrent comparator with a trip voltage of 50mV makes

the MIC5021 ideal for use with a current sensing MOSFET. An

external low value resistor may be used instead of a sensing

MOSFET for more precise overcurrent control. An optional

external capacitor placed from the CT pin to ground may be

used to control the current shutdown duty cycle (dead time)

from 20% to < 1%. A duty cycle from 20% to about 75% is

possible with an optional pull-up resistor from CT to VDD.

The MIC5021 is available in 8-pin SOIC and plastic DIP

packages.

Other members of the MIC502x family include the MIC5020

low-side driver and the MIC5022 half-bridge driver with a

cross-conduction interlock.

Typical Application

VDD

Input

Gnd

VB O OS T

Gate

Se n se-

Se n se+

TTL Input

SENSE

N-Channel

Power MOSFET

+12V to +36V

MIC5021

10µF

2.7

Load

RSENSE = 50mV

ITR I P

* increases time before retry

optional*

High-Side Driver with Overcurrent Trip and Retry

Micrel, Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel + 1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com

MIC5021 Micrel, Inc.

MIC5021 2 July 2005

Pin Description

Pin Number Pin Name Pin Function

1 VDD Supply: +12V to +36V. Decouple with ≥ 10µF capacitor.

2 Input TTL Compatible Input: Logic high turns the external MOSFET on. An inter-

nal pull-down returns an open pin to logic low.

3 CT Retry Timing Capacitor: Controls the off time (tG(OFF)) of the overcurrent

retry cycle. (Duty cycle adjustment.)

• Open = approx. 20% duty cycle.

• Capacitor to Ground = approx. 20% to < 1% duty cycle.

• Pull-up resistor = approx. 20% to approx. 75% duty cycle.

• Ground = maintained shutdown upon overcurrent condition.

4 Gnd Circuit Ground

5 Sense + Current Sense Comparator (+) Input: Connect to high side of sense resistor

or current sensing MOSFET sense lead. A built-in offset in conjunction with

RSENSE sets the load overcurrent trip point.

6 Sense – Current Sense Comparator (–) Input: Connect to the low side of the sense

resistor (usually the high side of the load).

7 Gate Gate Drive: Drives the gate of an external power MOSFET. Also limits VGS

to 15V max. to prevent Gate-to-Source damage. Will sink and source cur-

rent.

8 VBOOST Charge Pump Boost Capacitor: A bootstrap capacitor from VBOOST to the

FET source pin supplies charge to quickly enhance the Gate output during

turn-on.

Pin Conﬁguration

VDD

Input

Gnd

VB O OS T

Gate

Sense-

Sense+

VB O OS T

Gate

Sense-

Sense+

VDD

Input

Gnd

Block Diagram

Sense-

Sense+

6V Internal Regulator

CINT

2I1

50mV

Input

ONE-

SHOT

Gate

OFF

Fault

Normal

10I2

15V

C H A R G E

PU M P

VDD

VB OO S T

↓

↑

Transistor: 106

DIP Package SOIC Package

(N) (M)

July 2005 3 MIC5021

MIC5021 Micrel, Inc.

Electrical Characteristics

TA = 25°C, Gnd = 0V, VDD = 12V, CT = Open, Gate CL = 1500pF (IRF540 MOSFET) unless otherwise speciﬁed

Symbol Parameter Condition Min Typ Max Units

D.C. Supply Current VDD = 12V, Input = 0V 1.8 4 mA

VDD = 36V, Input = 0V 2.5 6 mA

VDD = 12V, Input = 5V 1.7 4 mA

VDD = 36V, Input = 5V 2.5 6 mA

Input Threshold 0.8 1.4 2.0 V

Input Hysteresis 0.1 V

Input Pull-Down Current Input = 5V 10 20 40 µA

Current Limit Threshold Note 1 30 50 70 mV

Gate On Voltage VDD = 12V Note 2 16 18 21 V

VDD = 36V Note 2 46 50 52 V

tG(ON) Gate On Time, Fixed Sense Differential > 70mV 2 6 10 µs

tG(OFF) Gate Off Time, Adjustable Sense Differential > 70mV, CT = 0pF 10 20 50 µs

tDLH Gate Turn-On Delay Note 3 500 1000 ns

tR Gate Rise Time Note 4 400 500 ns

tDLH Gate Turn-Off Delay Note 5 800 1500 ns

tF Gate Fall Time Note 6 400 500 ns

fmax Maximum Operating Frequency Note 7 100 150 kHz

Note 1 When using sense MOSFETs, it is recommended that RSENSE < 50Ω. Higher values may affect the sense MOSFET’s current transfer ratio.

Note 2 DC measurement.

Note 3 Input switched from 0.8V (TTL low) to 2.0V (TTL high), time for Gate transition from 0V to 2V.

Note 4 Input switched from 0.8V (TTL low) to 2.0V (TTL high), time for Gate transition from 2V to 17V.

Note 5 Input switched from 2.0V (TTL high) to 0.8V (TTL low), time for Gate transition from 20V (Gate on voltage) to 17V.

Note 6 Input switched from 2.0V (TTL high) to 0.8V (TTL low), time for Gate transition from 17V to 2V.

Note 7 Frequency where gate on voltage reduces to 17V with 50% input duty cycle.

Absolute Maximum Ratings

Supply Voltage (VDD) ................................................... +40V

Input Voltage .................................................–0.5V to +15V

Sense Differential Voltage .......................................... ±6.5V

Sense + or Sense – to Gnd ...........................–0.5V to +36V

Timer Voltage (CT) ......................................................+5.5V

VBOOST Capacitor ..................................................... 0.01µF

Operating Ratings

Supply Voltage (VDD) ..................................... +12V to +36V

Temperature Range

PDIP ..................................................................... –40°C to +85°C

SOIC ...................................................... –40°C to +85°C

MIC5021 Micrel, Inc.

MIC5021 4 July 2005

0.0

0.5

1.0

1.5

2.0

2.5

5 10 15 20 25 30 35 40

ISUPPLY (mA)

VSUPPLY (V)

Supply Current vs.

Supply Voltage

VIN = 0V

VIN = 5V

650

700

750

800

850

900

5 10 15 20 25 30 35 40

tON 4V (ns)

VSUPPLY (V)

Gate Turn-On Dalay vs.

Supply Voltage

VGATE = VSUPPLY + 4V

CL= 1500pF (IRCZ34)

CBOOST = 0.01µF

INCLUDES PROPAGATION DELAY

750

800

850

900

950

1000

5 10 15 20 25 30 35 40

tON 10V (ns)

VSUPPLY (V)

Gate Turn-On Delay vs.

Supply Voltage

VGATE = VSUPPLY + 10V

CL= 1500pF (IRCZ34)

CBOOST = 0.01µF

INCLUDES PROPAGATION DELAY

0.0

0.5

1.0

1.5

2.0

2.5

1x1001x1011x1021x1031x1041x105

tON (µs)

CGATE (pF)

Gate Turn-On Delay vs.

Gate Capacitance

VGATE = VSUPPLY + 4V

VSUPPLY = 12V

INCLUDES PROPAGATION DELAY

750

1000

1250

1500

1750

2000

5 10 15 20 25 30 35 40

tOFF 4V (ns)

VSUPPLY (V)

Gate Turn-Off Delay vs.

Supply Voltage

VG AT E = VSUPPLY + 4V

RL= 400

INCLUDES PROPAGATION DELAY

CG AT E = 1500pF

(IRCZ34)

0.1 1 10 100 1000 10000

RETRY DUTY CYCLE (%)

CT (pF)

NOT E:

tON, tOFF T I ME

INDEPENDENT

OF VSUPPLY

Overcurrent Retry Duty

Cycle vs. Timing Capacitance

tON = 5µs

VSUPPLY = 12V

5 10 15 20 25 30 35 40

VGATE (V)

VSUPPLY (V)

Gate Voltage Change

vs. Supply Voltage

VG AT E = VG AT E – VSUPPLY

100

0 5 10 15 20 25

IIN (µA)

VIN (V)

Input Current vs.

Input Voltage

VSUPPLY = 12V

Typical Characteristics

Timing Diagram 2. Fault Condition, CT = Open Timing Diagram 3. Fault Condition, CT = Grounded

Input 0V

TTL (H)

Source

50mV

Sense +,–

Differential

Gate

15V (max.)

6µs

20µs

Input 0V

TTL ( H)

Source

50mV

Sense +,–

Differential

Gate

15V (max.)

6µs

Input 0V

TTL ( H)

Source

50mV

Sense +,–

Differential

Gate

15V (max.)

Timing Diagram 1. Normal Operation

-60 -30 0 30 60 90 120 150

VOLTAGE (mV)

TEMPERATURE (°C)

Sense Threshold vs.

Temperature

July 2005 5 MIC5021

MIC5021 Micrel, Inc.

Functional Description

Refer to the MIC5021 block diagram.

Input

A signal greater than 1.4V (nominal) applied to the MIC5021

INPUT causes gate enhancement on an external MOSFET

turning the MOSFET on.

An internal pull-down resistor insures that an open INPUT

remains low, keeping the external MOSFET turned off.

Gate Output

Rapid rise and fall times on the GATE output are possible

because each input state change triggers a one-shot which

activates a high-value current sink (10I2) for a short time.

This draws a high current though a current mirror circuit

causing the output transistors to quickly charge or discharge

the external MOSFET’s gate.

A second current sink continuously draws the lower value

of current used to maintain the gate voltage for the selected

state.

An internal charge pump utilizes an external “boost” capacitor

connected between VBOOST and the source of the external

MOSFET. (Refer to typical application.) The boost capacitor

stores charge when the MOSFET is off. As the MOSFET

turns on, its source to ground voltage increases and is added

to the voltage across the capacitor, raising the VBOOST pin

voltage. The boost capacitor charge is directed through

the GATE pin to quickly charge the MOSFET’s gate to 16V

maximum above VDD. The internal charge pump maintains

the gate voltage.

An internal zener diode protects the external MOSFET by

limiting the gate to source voltage.

Sense Inputs

The MIC5021’s 50mV (nominal) trip voltage is created by

internal current sources that force approximately 5µA out of

SENSE + and approximately 15µA (at trip) out of SENSE –.

When SENSE – is 50mV or more below SENSE +, SENSE –

steals base current from an internal drive transistor shutting

off the external MOSFET.

Overcurrent Limiting

Current source I1 charges CINT upon power up. An optional

external capacitor connected to CT is kept discharged through

a MOSFET Q1.

A fault condition (> 50mV from SENSE + to SENSE –) causes

the overcurrent comparator to enable current sink 2I1 which

overcomes current source I1 to discharge CINT in a short

time. When CINT is discharged, the INPUT is disabled, which

turns off the gate output, and CINT and CT are ready to be

charged.

When the gate output turns the MOSFET off, the overcurrent

signal is removed from the sense inputs which deactivates

current sink 2I1. This allows CINT and the optional capacitor

connected to CT to recharge. A Schmitt trigger delays the

retry while the capacitor(s) recharge. Retry delay is increased

by connecting a capacitor to CT (optional).

The retry cycle will continue until the fault is removed or the

input is changed to TTL low.

If CT is connected to ground, the circuit will not retry upon a

Supply Voltage

The MIC5021’s supply input (VDD) is rated up to 36V. The

supply voltage must be equal to or greater than the voltage

applied to the drain of the external N-channel MOSFET.

A 16V minimum supply is recommended to produce continu-

ous on-state, gate drive voltage for standard MOSFETs (10V

nominal gate enhancement).

When the driver is powered from a 12V to 16V supply, a

logic-level MOSFET is recommended (5V nominal gate

enhancement).

PWM operation may produce satisfactory gate enhancement

at lower supply voltages. This occurs when fast switching

repetition makes the boost capacitor a more signiﬁcant volt-

age supply than the internal charge pump.

Applications Information

The MIC5021 MOSFET driver is intended for high-side

switching applications where overcurrent limiting and high

speed are required. The MIC5021 can control MOSFETs

that switch voltages up to 36V.

High-Side Switch Circuit Advantages

High-side switching allows more of the load related com-

ponents and wiring to remain near ground potential when

compared to low-side switching. This reduces the chances

of short-to-ground accidents or failures.

Speed Advantage

The MIC5021 is about two orders of magnitude faster than

the low cost MIC5014 making it suitable for high-frequency

high-efﬁciency circuit operation in PWM (pulse width modu-

lation) designs used for motor control, SMPS (switch mode

power supply) and heating element control.

Switched loads (on/off) beneﬁt from the MIC5021’s fast

switching times by allowing use of MOSFETs with smaller

safe operating areas. (Larger MOSFETs are often required

when using slower drivers.)

MIC5021 Micrel, Inc.

MIC5021 6 July 2005

Logic-Level MOSFET Precautions

Logic-level MOSFETs have lower maximum gate-to-source

voltage ratings (typically ±10V) than standard MOSFETs

(typically ±20V). When an external MOSFET is turned on,

the doubling effect of the boost capacitor can cause the

gate-to-source voltage to momentarily exceed 10V. Internal

zener diodes clamp this voltage to 16V maximum which

is too high for logic-level MOSFETs. To protect logic-level

MOSFETs, connect a zener diode (5V≤VZener<10V) from

gate to source.

Overcurrent Limiting

A 50mV comparator is provided for current sensing. The low

level trip point minimizes I2R losses when a power resistor

is used for current sensing.

The adjustable retry feature can be used to handle loads with

high initial currents, such as lamps or heating elements, and

can be adjusted from the CT connection.

CT to ground maintains gate drive shutdown following an

overcurrent condition.

CT open, or a capacitor to ground, causes automatic retry.

The default duty cycle (CT open) is approximately 20%. Refer

to the electrical characteristics when selecting a capacitor for

reduced duty cycle.

CT through a pull-up resistor to VDD increases the duty cycle.

Increasing the duty cycle increases the power dissipation

in the load and MOSFET under a “fault” condition. Circuits

may become unstable at a duty cycle of about 75% or higher,

depending on conditions. Caution: The MIC5021 may be

damaged if the voltage applied to CT exceeds the absolute

maximum voltage rating.

Boost Capacitor Selection

The boost capacitor value will vary depending on the supply

voltage range.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

+12V to +20V

MIC5021

10µF

0.01

µF

Load

Figure 1. 12V to 20V Conﬁguration

A 0.01µF boost capacitor is recommended for best perfor-

mance in the 12V to 20V range. Refer to ﬁgure 1. Larger

capacitors may damage the MIC5021.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

+12V to +36V

MIC5021

10µF

2.7

Load

Figure 2. 12V to 36V Conﬁguration

If the full 12V to 36V voltage range is required, the boost

capacitor value must be reduced to 2.7nF. Refer to Figure

2. The recommended conﬁguration for the 20V to 36V range

is to place the capacitor is placed between VDD and VBOOST

as shown in Figure 3.

VDD

Input

Gnd

VBOOST

Gate

Sense-

Sense+

TTL Input

+12V to +36V

MIC5021

10µF

Load

0.01

µF

Figure 3. Preferred 20V to 36V Conﬁguration

Do not use both boost capacitor between VBOOST and the

MOSFET source and VBOOST and VDD at the same time.

Current Sense Resistors

Lead length can be signiﬁcant when using low value (< 1Ω)

resistors for current sensing. Errors caused by lead length

can be avoided by using four-teminal current sensing re-

sistors. Four-terminal resistors are available from several

manufacturers.

July 2005 7 MIC5021

MIC5021 Micrel, Inc.

The diode should have a peak forward current rating greater

than the load current. This is because the current through

the diode is the same as the load current at the instant the

MOSFET is turned off.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

RSENSE

N-Channel

Power MOSFET

(IRF540)

+20V to +36V

MIC5021

10µF

Solenoid

(24V, 47Ω)

0.01

µF

Schottky

Diode

(1N5822)

(+24V)

(< 0.08Ω)

Figure 5. Solenoid Driver

with Current Sensing

Sense Pin Considerations

The sense pins of the MIC5021 are sensitive to negative volt-

ages. Forcing the sense pins much below –0.5V effectively

reverses the supply voltage on portions of the driver resulting

in unpredictable operation or damage.

M O S FE T

Turnoff

Negative

Spike

~VDD

VDD

Input

Gate

MIC5021

Inductive

Load

Current flows from ground (0V)

through the diodes to the load

during negative transcients.

Forward drop across diodes

allows leads to go negative.

Figure 6. Inductive Load Turnoff

Figure 6 shows current ﬂowing out of the sense leads of an

MIC5021 during a negative transient (inductive kick). Internal

Schottky diodes attempt to limit the negative transient by

maintaining a low forward drop.

Although the internal Schottky diodes can protect the driver

in low-current resistive applications, they are inadequate for

inductive loads or the lead inductance in high-current resis-

tive loads. Because of their small size, the diodes’ forward

voltage drop quickly exceeds 0.5V as current increases.

Circuits Without Current Sensing

Input

Gnd

B O O S T

Gate

Sense-

Sense+

TTL Input

Load

N-Channel

Power MOSFET

V+

MIC5021

10µF

0.01

µF

Figure 4a. Connecting Sense to Source

Input

Gnd

B O O S T

Gate

Sense-

Sense+

TTL Input

Load

N-Channel

Power MOSFET

V+

MIC5021

10µF

0.01

µF

Figure 4b. Connecting Sense to Supply

Current sensing may be omitted by connecting the SENSE +

and SENSE – pins to the source of the MOSFET or to the sup-

ply. Connecting the SENSE pins to the supply is preferred for

inductive loads. Do not connect the SENSE pins to ground.

Inductive Load Precautions

Circuits controlling inductive loads, such as solenoids (Figure

5) and motors, require precautions when controlled by the

MIC5021. Wire wound resistors, which are sometimes used

to simulate other loads, can also show signiﬁcant inductive

properties.

An inductive load releases stored energy when its current

ﬂow is interrupted (when the MOSFET is switched off). The

voltage across the inductor reverses and the inductor at-

tempts to force current ﬂow. Since the circuit appears open

(the MOSFET appears as a very high resistance) a very large

negative voltage occurs across the inductor.

Limiting Inductive Spikes

The voltage across the inductor can be limited by connect-

ing a Schottky diode across the load. The diode is forward

biased only when the load is switched off. The Schottky diode

clamps negative transients to a few volts. This protects the

MOSFET from drain-to-source breakdown and prevents the

transient from damaging the charge pump by way of the boost

capacitor. Also see Sense Pin Considerations below.

MIC5021 Micrel, Inc.

MIC5021 8 July 2005

External Protection

Resistors placed in series with each SENSE connection limit

the current drawn from the internal Schottky diodes during a

negative transient. This minimizes the forward drop across

the diodes.

VDD

Input

Gnd

VB O O S T

Gate

Sense-

Sense+

N-Channel

Power MOSFET

MIC5021

Load

5µA

15µA

VR2

VR1

= VR2

to avoid skewing

the 50mV trip point.

(5mV suggested)

≅

VR1

50mV nominal

(at trip)

Figure 7. Resistor Voltage Drop

During normal operation, sensing current from the sense pins

is unequal (5µA and 15µA). The internal Schottky diodes are

reverse biased and have no effect. To avoid skewing the trip

voltage, the current limiting resistors must drop equal volt-

ages at the trip point currents. See Figure 7. To minimize

resistor tolerance error, use a voltage drop lower than the

trip voltage of 50mV. 5mV is suggested.

External Schottky diodes are also recommended. See D2

and D3 in Figure 8. The external diodes clamp negative

transients better than the internal diodes because their larger

size minimizes the forward voltage drop at higher currents.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

Inductive

Load

N-Channel

Power MOSFET

+12V to +36V

MIC5021

10µF

2.7

RSENSE

1.0k

330Ω

11DQ03

Figure 8. Protection from Inductive Kick

High-Side Sensing

Sensing the current on the high side of the MOSFET isolates

the SENSE pins from the inductive spike.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

Wirewound

Resistor

(3Ω)

N-Channel

Power MOSFET

(IRFZ44)

+12V to +20V

RSENSE

(< 0.01Ω)

(+12V)

MIC5021

10µF

0.01

µF

Figure 9. High Side Sensing

Lamp Driver Application

Incandescent lamps have a high inrush current (low resis-

tance) when turned on. The MIC5021 can perform a “soft

start” by pulsing the MOSFET (overcurrent condition) until

the ﬁlament is warm and its current decreases (resistance

increases). The sense resistor value is selected so the voltage

drop across the sense resistor decreases below the sense

threshold (50mV) as the ﬁlament becomes warm. The FET

is no longer pulsed and the lamp turns completely on.

VDD

Input

Gnd

VB O O S T

Gate

Sense-

Sense+

TTL Input

RSENSE

(0.041Ω)

N-Channel

Power MOSFET

(IRF540)

V+

MIC5021

10µF

0.01

µF

Incandescent

Lamp (#1157)

(+12V)

"( )" values apply to demo circuit.

See text.

Figure 10. Lamp Driver with

Current Sensing

A lamp may not fully turn on if the ﬁlament does not heat up

adequately. Changing the duty cycle, sense resistor, or both to

match the ﬁlament characteristics can correct the problem.

Soft start can be demonstrated using a #1157 dual ﬁlament

automotive lamp. The value of RS shown in Figure 10 allows

for soft start of the higher-resistance ﬁlament (measures ap-

prox. 2.1Ω cold or 21Ω hot).

July 2005 9 MIC5021

MIC5021 Micrel, Inc.

Remote Overcurrent Limiting Reset

In circuit breaker applications where the MIC5021 maintains

an off condition after an overcurrent condition is sensed, the

CT pin can be used to reset the MIC5021.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

RSENSE

N-Channel

Power

MOSFET

+12V to +20V

MIC5021

10µF

0.01

µF

Load

74HC04

(example)

2N3904

10k to

100k

Retry (H)

Maintained (L)

Figure 11. Remote Control Circuit

Switching Q1 on pulls CT low which keeps the MIC5021 GATE

output off when an overcurrent is sensed. Switching Q1 off

causes CT to appear open. The MIC5021 retries in about

20µs and continues to retry until the overcurrent condition

is removed.

For demonstration purposes, a 680Ω load resistor and 3Ω

sense resistor will produce an overcurrent condition when the

load’s supply (V+) is approximately 12V or greater.

Low-Temperature Operation

As the temperature of the MIC5021AJB (extended temperature

range version—no longer available) approaches –55°C, the

driver’s off-state, gate-output offset from ground increases.

If the operating environment of the MIC5021AJB includes

low temperatures (–40°C to –55°C), add an external 2.2MΩ

resistor as shown in Figures 12a or 12b. This assures that

the driver’s gate-to-source voltage is far below the external

MOSFET’s gate threshold voltage, forcing the MOSFET

fully off.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

RSENSE

+12V to +36V

MIC5021AJB

10µF

2.7

Load

2.2M

add resistor for

–40

C to –55

operation

Figure 12a. Gate-to-Source Pull Down

The gate-to-source conﬁguration (refer to Figure 12a) is

appropriate for resistive and inductive loads. This also causes

the smallest decrease in gate output voltage.

VDD

Input

Gnd

VB O O S T

Gate

Sense -

Sense +

TTL Input

RSENSE

+12V to +36V

MIC5021AJB

10µF

2.7

Load

2.2M

add resistor for

–40

C to –55

operation

Figure 12b. Gate-to-Ground Pull Down

The gate-to-ground conﬁguration (refer to Figure 12b) is ap-

propriate for resistive, inductive, or capacitive loads. This

conﬁguration will decrease the gate output voltage slightly

more than the circuit shown in Figure 12a.

MIC5021 Micrel, Inc.

MIC5021 10 July 2005

Package Information

0.380 (9.65)

0.370 (9.40) 0.135 (3.43)

0.125 (3.18)

PIN 1

DIMENSIONS:

INCH (MM)

0.018 (0.57)

0.100 (2.54)

0.013 (0.330)

0.010 (0.254)

0.300 (7.62)

0.255 (6.48)

0.245 (6.22)

0.380 (9.65)

0.320 (8.13)

0.0375 (0.952)

0.130 (3.30)

8-Pin Plastic DIP (N)

45°

0°–8°

0.244 (6.20)

0.228 (5.79)

0.197 (5.0)

0.189 (4.8) SEATING

PLANE

0.026 (0.65)

MAX)

0.010 (0.25)

0.007 (0.18)

0.064 (1.63)

0.045 (1.14)

0.0098 (0.249)

0.0040 (0.102)

0.020 (0.51)

0.013 (0.33)

0.157 (3.99)

0.150 (3.81)

0.050 (1.27)

TYP

PIN 1

DIMENSIONS:

INCHES (MM)

0.050 (1.27)

0.016 (0.40)

8-Pin SOIC (M)

MICREL INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA

TEL + 1 (408) 944-0800 FAX + 1 (408) 474-1000 WEB http://www.micrel.com

This information furnished by Micrel in this data sheet is believed to be accurate and reliable. However no responsibility is assumed by Micrel for its use.

Micrel reserves the right to change circuitry and speciﬁcations at any time without notiﬁcation to the customer.

Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can

reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into

the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a signiﬁcant injury to the user. A Purchaser's

use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser's own risk and Purchaser agrees to fully indemnify

Micrel for any damages resulting from such use or sale.