MAX16914AUB/V+ Maxim Integrated Products, MAX16914AUB/V+ Datasheet - Page 8

MAX16914AUB/V+

Manufacturer Part Number

MAX16914AUB/V+

Description

IC CTRLR IDEAL DIODE 10UMAX

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX16914AUBV.pdf (9 pages)

Specifications of MAX16914AUB/V+

Applications

Battery Backup, Industrial/Automotive, High Current Switch

Fet Type

P-Channel

Number Of Outputs

Internal Switch(s)

Voltage - Supply

4.5 V ~ 19 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

10-MSOP, Micro10™, 10-uMAX, 10-uSOP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Supply

Delay Time - On

Delay Time - Off

Lead Free Status / Rohs Status

Details

Current page: 8 of 9
Download datasheet (2Mb)

Ideal Diode, Reverse-Battery, and Overvoltage Protection

Switch/Limiter Controllers with External MOSFETs

The MAX16914/MAX16915 include an active-low,

open-drain overvoltage-indicator output (OV). For the

MAX16914, OV asserts low when V

grammed overvoltage threshold. OV deasserts when the

overvoltage condition is over.

For the MAX16915, OV asserts if V

programmed overvoltage threshold. OV deasserts when

level. If the overvoltage condition continues, OV may

toggle with the same frequency as the overvoltage limiter

FET (P2). If the P2 device is turned on for a very short

period (less than t

To obtain a logic-level output, connect a 45kI pullup

resistor from OV to a system voltage less than 44V. A

capacitor connected from OV to GND helps extend the

time that the logic level remains low.

Most automotive applications run off a multicell “12V”

lead-acid battery with a nominal voltage that swings

between 9V and 16V (depending on load current, charg-

ing status, temperature, battery age, etc.). The battery

voltage is distributed throughout the automobile and is

locally regulated down to voltages required by the differ-

ent system modules. Load dump occurs when the alter-

nator is charging the battery and the battery becomes

disconnected. The alternator voltage regulator is tem-

porarily driven out of control. Power from the alternator

flows into the distributed power system and elevates the

voltage seen at each module. The voltage spikes have

rise times typically greater than 5ms and decays within

several hundred milliseconds but can extend out to 1s

or more depending on the characteristics of the charg-

ing system. These transients are capable of destroying

sensitive electronic equipment on the first “fault event.”

TERM and SET provide an accurate means to set the

overvoltage level for the MAX16914/MAX16915. Use a

resistive divider to set the desired overvoltage condition

(see the

1.20V threshold with a 4% falling hysteresis. Begin by

selecting the total end-to-end resistance:

For high accuracy, choose R

rent equivalent to a minimum 100 x I

input bias current at SET.

OUT

______________________________________________________________________________________

drops 4% (typ) below the overvoltage threshold

Typical Operating Circuit). V

Overvoltage Indicator Output (OV)

Setting Overvoltage Thresholds

Applications Information

OVBPD

TOTAL

), the OV pin may not toggle.

= R1 + R2

TOTAL

SET

to yield a total cur-

OUT

exceeds the pro-

SET

where I

Load Dump

exceeds the

has a rising

SET

is the

For example:

With an overvoltage threshold (V

< 20V/(100 x I

Use the following formula to calculate R2:

where V

the desired overvoltage threshold.

Then, R2 = 12.0kI.

Use the nearest standard-value resistor lower than the

calculated value. A lower value for total resistance dissi-

pates more power but provides slightly better accuracy.

To determine R1:

Then, R1 = 188kI.

Use the nearest standard-value resistor lower than the

calculated value. A lower value for total resistance dissi-

pates more power but provides slightly better accuracy.

Select the external output MOSFET according to the

application current level. The MOSFET’s on-resistance

minimum voltage drop at full load to limit the MOSFET

power dissipation. Determine the device power rating to

accommodate an overvoltage fault when operating the

MAX16915 in overvoltage-limiting mode. During normal

operation for either IC, the external MOSFET dissipates

little power. The power dissipated in the MOSFET during

normal operation is:

where P

in normal operation, I

and R

MOSFET. Worst-case power dissipation in the output

MOSFET occurs during a prolonged overvoltage event

when operating the MAX16915 in voltage-limiting mode.

The power dissipated across the MOSFET is as follows:

where P

overvoltage-limiting operation, V

the MOSFET’s drain and source, and I

current.

DS(ON)

OVLO

NORM

) should be chosen low enough to have a

is the 1.20V SET rising threshold and V

SET

is the power dissipated in the MOSFET in

is the drain-to-source resistance of the

R2 = (V

NORM

is the power dissipated in the MOSFET

), where I

OVLO

TOTAL

= I

LOAD

Output p-Channel MOSFET (P2)

= V

LOAD

x R

SET

= R2 + R1

< 200kI

is the output load current,

TOTAL

= 1FA (max).

x I

x R

MOSFET Selection

LOAD

DS(ON)

) set to 20V, R

)/V

is the voltage across

LOAD

is the load

TOTAL

MAX16914AUB/V+ Maxim Integrated Products, MAX16914AUB/V+ Datasheet - Page 8

MAX16914AUB/V+

Specifications of MAX16914AUB/V+

Related parts for MAX16914AUB/V+