LM25011MY-EVAL/NOPB National Semiconductor, LM25011MY-EVAL/NOPB Datasheet - Page 13

LM25011MY-EVAL/NOPB

Manufacturer Part Number

LM25011MY-EVAL/NOPB

Description

EVAL BOARD FOR LM25011

Manufacturer

National Semiconductor

Datasheet

1.LM25011MYNOPB.pdf (20 pages)

Specifications of LM25011MY-EVAL/NOPB

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plied to the SS pin must be current limited to a maximum of 1

mA.

Shutdown Function

The SS pin can be used to shutdown the LM25011 by ground-

ing the SS pin as shown in Figure 4. Releasing the pin allows

normal operation to resume.

Power Good Output (PGD)

The Power Good output (PGD) indicates when the voltage at

the FB pin is close to the internal 2.51V reference voltage.

The rising threshold at the FB pin for the PGD output to switch

high is 95% of the internal reference. The falling threshold for

the PGD output to switch low is approximately 3.3% below the

rising threshold.

The PGD pin is internally connected to the drain of an N-

channel MOSFET switch. An external pull-up resistor

7V, is required at PGD to indicate the LM25011’s status to

other circuitry. When PGD is low, the pin’s voltage is deter-

mined by the current into the pin. See the graph “PGD Low

Voltage vs. Sink Current”.

Upon powering up the LM25011, the PGD pin is high until the

voltage at V

As V

takes the voltage at the FB pin above 95% of the internal ref-

erence voltage, at which time PGD switches high. As V

decreased (during shutdown) PGD remains high until either

the voltage at the FB pin falls below

erence, or when V

whichever occurs first. PGD then switches low, and remains

low until V

If the LM25011 is used as a tracking regulator (see the Soft-

start section), the PGD output is high as long as the voltage

at the FB pin is above the thresholds mentioned above.

Thermal Shutdown

The LM25011 should be operated so the junction temperature

does not exceed 125°C. If the junction temperature increases

above that, an internal Thermal Shutdown circuit activates

(typically) at 155°C, taking the controller to a low power reset

state by disabling the buck switch and taking the SS pin to

ground. This feature helps prevent catastrophic failures from

accidental device overheating. When the junction tempera-

ture reduces below 135°C (typical hysteresis = 20°C) normal

operation resumes.

Applications Information

EXTERNAL COMPONENTS

The procedure for calculating the external components is il-

lustrated with a design example using the LM25011. Refer-

ring to the Block Diagram, the circuit is to be configured for

the following specifications:

•

PGD

OUT

), connected to an appropriate voltage not exceeding

is increased PGD stays low until the output voltage

= 5V

FIGURE 4. Shutdown Implementation

falls below 2V, at which time PGD switches high.

reaches 2V, at which time PGD switches low.

falls below its lower UVLO threshold,

≊

92% of the internal ref-

30094626

•

their ratio is calculated from:

For this example, R

be chosen from standard value resistors in the range of 1.0

kΩ – 10 kΩ which satisfy the above ratio. For this example,

4.99 kΩ is chosen for both resistors, providing a 5.02V output.

ing frequency. First check that the desired frequency does not

require an on-time or off-time shorter than the minimum al-

lowed values (90 ns and 150, respectively). The minimum on-

time occurs at the maximum input voltage. For this example:

The minimum off-time occurs at the minimum input voltage.

For this example:

Both the on-time and off-time are acceptable since they are

significantly greater than the minimum value for each. The

input voltage:

A standard value 118 kΩ resistor is selected. The minimum

on-time calculates to 152 ns at V

on-time calculates to 672 ns at Vin = 8V

L1: The parameters controlled by the inductor are the inductor

current ripple amplitude (I

tude across the current sense resistor R

current is used to determine the maximum allowable ripple in

order to maintain continuous conduction mode (the lower

peak does not reach 0 mA). This is not a requirement of the

LM25011, but serves as a guideline for selecting L1. For this

example, the maximum ripple current should be less than:

For applications where the minimum load current is zero, a

good starting point for allowable ripple is 20% of the maximum

load current. In this case substitute 20% of I

(min)

8 is then used in the following equation:

A standard value 10 µH inductor is chosen. Using this inductor

value, the maximum ripple current amplitude, which occurs at

maximum V

is 1736 mA at maximum load current. Ensure the selected

FB2

: This resistor sets the on-time, and (by default) the switch-

Minimum load current for continuous conduction mode

Maximum load current (I

Switching frequency (F

Soft-start time = 5 ms

resistor is calculated from equation 6 using the minimum

in equation 8. The ripple amplitude calculated in Equation

OUT(min)

and R

= 8V to 36V

OR(max)

FB1

= 300 mA

, calculates to 472 mAp-p, and the peak current

FB2

: These resistors set the output voltage, and

= 2 x I

FB1

FB2

= (V

OUT(min)

FB1

) = 1.0 MHz

OUT

OUT(max)

), and the ripple voltage ampli-

= 0.992. R

/2.51V) - 1

= 600 mA p-p

= 36V, and the maximum

= 1.5 A

FB1

. The minimum load

and R

OUT(max)

www.national.com

FB2

for I

should

OUT

(7)

(8)

LM25011MY-EVAL/NOPB National Semiconductor, LM25011MY-EVAL/NOPB Datasheet - Page 13

LM25011MY-EVAL/NOPB

Specifications of LM25011MY-EVAL/NOPB

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