MIC5014YM Micrel Inc, MIC5014YM Datasheet - Page 6
MIC5014YM
Manufacturer Part Number
MIC5014YM
Description
IC DRIVER MOSF HI/LOW SIDE 8SOIC
Manufacturer
Micrel Inc
Datasheet
1.MIC5014YM_TR.pdf
(12 pages)
Specifications of MIC5014YM
Configuration
High or Low Side
Input Type
Non-Inverting
Delay Time
2.5ms
Number Of Configurations
1
Number Of Outputs
1
Voltage - Supply
2.75 V ~ 30 V
Operating Temperature
-40°C ~ 85°C
Mounting Type
Surface Mount
Package / Case
8-SOIC (3.9mm Width)
Device Type
High Side / Low Side
Module Configuration
High Side / Low Side
Input Delay
2.5ms
Output Delay
6µs
Supply Voltage Range
2.75V To 30V
Driver Case Style
SOIC
No. Of Pins
8
Number Of Drivers
1
Driver Configuration
Non-Inverting
Driver Type
High Side/Low Side
Input Logic Level
TTL
Operating Supply Voltage (max)
30V
Operating Supply Voltage (min)
2.75V
Turn Off Delay Time
30us
Turn On Delay Time (max)
8ms
Operating Temp Range
-40C to 85C
Operating Temperature Classification
Industrial
Mounting
Surface Mount
Pin Count
8
Package Type
SOIC
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Current - Peak
-
High Side Voltage - Max (bootstrap)
-
Lead Free Status / Rohs Status
Compliant
Other names
576-2352
MIC5014YM
MIC5014YM
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
MIC5014YM
Manufacturer:
MICREL
Quantity:
179
Part Number:
MIC5014YM
Manufacturer:
MIC
Quantity:
20 000
MIC5014/5015
Low Side Driver (Figure 2) A key advantage of this topology,
as previously mentioned, is speed. The MOSFET gate is
driven to near supply immediately when the MIC5014/15 is
turned on. Typical circuits reach full enhancement in 50µs or
less with a 15V supply.
Bootstrapped High Side Driver (Figure 3) The turn-on time of
a high side driver can be improved to faster than 40µs by
bootstrapping the supply with the MOSFET source. The
Schottky barrier diode prevents the supply pin from dropping
more than 200mV below the drain supply and improves turn-
on time. Since the supply current in the “off” state is only a
small leakage, the 100nF bypass capacitor tends to remain
charged for several seconds after the MIC5014/15 is turned
off. Faster speeds can be obtained at the expense of supply
voltage (the overvoltage shutdown will turn the part off when
the bootstrapping action pulls the supply pin above 35V) by
using a larger capacitor at the junction of the two 1N4001
diodes. In a PWM application (this circuit can be used for either
PWM’ed or continuously energized loads), the chip supply is
sustained at a higher potential than the system supply, which
improves switching time.
High Side Driver With Current Sense (Figure 4) Although no
current sense function is included on the MIC5014/15 devices,
a simple current sense function can be realized via the addition
of one more active component; an LM301A op amp used as
a comparator. The positive rail of the op amp is tied to V
the negative rail is tied to ground. This op amp was chosen as
it can withstand having input transients that swing below the
negative rail, and has common mode range almost to the
positive rail.
The inverting side of this comparator is tied to a voltage divider
which sets the voltage to V
is tied to the node between the drain of the FET and the sense
resistor. If the overcurrent trip point is not exceeded , this node
will always be pulled above V
comparator will be high which feeds the control input of the
MIC5014 (polarities should be reversed if the MIC5015 is
used). One the overcurrent trip point has been reached, the
comparator will go low, which shuts off the MIC5014. When the
MIC5014/5015
OFF
ON
Figure 3. Bootstrapped Hgh-Side Driver
Control Input
1
2
3
4
V+
Input
Source
Gnd
MIC5015
100nF
+
– V
Gate
+
NC
NC
NC
– V
1N5817
TRIP
8
7
6
5
1N4001 (2)
TRIP
+2.75V to +30V
. The non inverting side
, and the output of the
1µF
1RF540
+
, and
6
the short is removed, feedback to the input pin insures that the
MIC5014 will turn back on. This output can also be level
shifted and sent to an I/O port of a microcontroller for intelli-
gent control.
Current Shunts (R
use at R
to 50mΩ, at 2 to 10W. If a precise overcurrent trip point is
not necessary, then a nonprecision resistor or even a mea-
sured PCB trace can serve as R
resistor values with such resistors is temperature coefficient;
the designer should be aware that a linear, 500 ppm/°C
change will contribute as much as 10% shift in the overcurrent
trip point. If this is not acceptable, a power resistor designed
for current shunt service (drifts less than 100 ppm/°C), or a
Kelvin-sensed resistor may be used.
† Suppliers of Precision Power Resistors:
3131
International Resistive Co., P.O. Box 1860, Boone,NC 28607-1860.
Isotek Corp., 566 Wilbur Ave. Swansea, MA 02777. (508) 673-2900
Kelvin, 14724 Ventura Blvd., Ste. 1003, Sherman Oaks, CA 91403-3501.
(818) 990-1192
RCD Components, Inc., 520 E. Industrial Pk. Dr., Manchester, NH 03103.
(603) 669-0054
Ultronix, Inc., P.O. Box 1090, Grand Junction, CO 81502 (303) 242-0810
High Side Driver With Delayed Current Sense (Figure 5)
Delay of the overcurrent detection to accomodate high inrush
loads such as incandescent or halogen lamps can be accom-
plished by adding an LM3905 timer as a one shot to provide
an open collector pulldown for the comparator output such
that the control input of the MIC5015 stays low for a preset
amount of time without interference from the current sense
circuitry. Note that an MIC5015 must be used in this applica-
tion (figure 5), as an inverting control input is necessary. The
delay time is set by the RC time constant of the external
components on pins 3 and 4 of the timer; in this case, 6ms was
chosen.
An LM3905 timer was used instead of a 555 as it provides a
clean transition, and is almost impossible to make oscillate.
Good bypassing and noise immunity is essential in this circuit
to prevent spurious op amp oscillations.
Figure 4. High Side Driver with Overcurrent Shutdown
(704) 264-8861
Dale Electronics, Inc., 2064 12th Ave., Columbus, NE 68601. (402) 565-
10µF
S
. Resistors are available with values ranging from 1
1
2
3
4
V+
Input
Source
Gnd
MIC5014
S
). Low valued resistors are necessary for
Gate
NC
NC
NC
8
7
6
5
S
. The major cause of drift in
R
0.06Ω
S
1kΩ
R4
12V
†
R1
1kΩ
R2
120kΩ
On
V
LM301A
I
TRIP
TRIP
= V
= 1.7A
= R1/(R1+R2)
2.2kΩ
Micrel, Inc.
June 2005
TRIP
/R
S
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