MIC5021 Datasheet, PDF(5/9 Page) Micrel Semiconductor – High-Speed High-Side MOSFET Driver

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MIC5021 Datasheet, PDF (5/9 Pages) Micrel Semiconductor – High-Speed High-Side MOSFET Driver

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MIC5021

Micrel

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.

An internal zener diode protects the external MOSFET by

limiting the gate to source voltage.

Sense Inputs

The MIC5021âs 50mV (nominal) trip voltage is created by

internal current sources that force approximately 5ÂµA out of

SENSE + and approximately 15ÂµA (at trip) out of SENSE â.

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

steals base current from an internal drive transistor shutting

off the external MOSFET.

Gate Output

Overcurrent Limiting

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

Current source I1 charges CINT upon power up. An optional

external capacitor connected to CT is kept discharged through

a MOSFET Q1.

draws a high current though a current mirror circuit causing

the output transistors to quickly charge or discharge the

external MOSFETâs gate.

A second current sink continuously draws the lower value of

current used to maintain the gate voltage for the selected

state.

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

An internal charge pump utilizes an external âboostâ capacitor signal is removed from the sense inputs which deactivates

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

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 in-

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

to the voltage across the capacitor, raising the VBOOST pin

creased by connecting a capacitor to CT (optional).

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

voltage. The boost capacitor charge is directed through the input is changed to TTL low.

GATE pin to quickly charge the MOSFETâs gate to 16V

maximum above VDD. The internal charge pump maintains

the gate voltage.

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

fault condition.

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 compo-

nents 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 MIC5021âs fast

switching times by allowing use of MOSFETs with smaller

safe operating areas. (Larger MOSFETs are often required

when using slower drivers.)

Supply Voltage

The MIC5021âs 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 enhance-

ment).

PWM operation may produce satisfactory gate enhancement

at lower supply voltages. This occurs when fast switching

repetition makes the boost capacitor a more significant

voltage supply than the internal charge pump.

October 1998

5-173

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