BD3502FVM-TR Rohm Semiconductor, BD3502FVM-TR Datasheet - Page 14

BD3502FVM-TR

Manufacturer Part Number

BD3502FVM-TR

Description

IC REG LDO 1.2V NCH FET 8MSOP

Manufacturer

Rohm Semiconductor

Type

Positive Fixedr

Datasheet

1.BD3502FVM-TR.pdf (17 pages)

Specifications of BD3502FVM-TR

Number Of Outputs

Voltage - Output

1.2V

Voltage - Input

4.5 ~ 5.5 V

Operating Temperature

-10°C ~ 100°C

Package / Case

8-MSOP

Polarity

Positive

Output Type

Fixed

Output Voltage

1.2 V

Line Regulation

0.5 % / V

Load Regulation

10 mV

Input Voltage Max

5.5 V

Maximum Operating Temperature

+ 100 C

Minimum Operating Temperature

- 40 C

Maximum Power Dissipation

437.5 mW

Mounting Style

SMD/SMT

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Supply

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

BD3502FVM-TR

Manufacturer:

ROHM/罗姆

Quantity:

20 000

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10. Output capacitor (C5)

11. Input capacitor setting method (C1, C4)

12. NRCS terminal capacitor setting method (C3)

13. SCP terminal capacitor setting method (C2)

14. Input terminals (VCC, VIN, EN)

15. Maximum output current (maximum load)

16. Operating ranges

17. Allowable loss Pd

18. The use in the strong electromagnetic field may sometimes cause malfunction, to which care must be taken.

19.In the event that load containing a large inductance component is connected to the output terminal, and generation of

20. We are certain that examples of applied circuit diagrams are recommendable,

Connect the output capacitor between Vo1, Vo2 terminals and GND terminal without fail in order to stabilize output voltage.

The output capacitor has a role to compensate for the phase of loop gain and to reduce output voltage fluctuation when

load is rapidly changed. When there is an insufficient capacity value, there is a possibility to cause oscillation, and when

the equivalent serial resistance (ESR) of the capacitors is large, output voltage fluctuation is increased when load is rapidly

changed. About 220 µF high-performance electrolytic capacitors are recommended, but this greatly depends on the gate

capacity of external MOSFET and mutual conductance (gm), temperature and load conditions. In addition, when only

ceramic capacitors with low ESR are used, or various capacitors are connected in series, the total phase allowance of loop

gain becomes not sufficient, and oscillation may result. Thoroughgoing confirmation at application temperature and

under load range conditions is requested.

The input capacitor plays a part to lower output impedance of a power supply connected to input terminals (Vcc, VIN).

When output impedance of this power supply increases, the input voltages (Vcc, VIN) become unstable and there is a

possibility of giving rise to oscillation and degraded ripple rejection characteristics. The use of capacitors of about 10 µF

with low ESR, which provide less capacity value changes caused by temperature changes, is recommended, but since

input capacitor greatly depends on characteristics of the power supply used for input, substrate wiring pattern, and

MOSFET gate-drain capacity, thoroughgoing confirmation under the application temperature, load range, and M-MOSFET

conditions is requested.

To the present IC, there mounted is a function (Non Rush Current on Start-up: NRCS) to prevent rush current from VIN to

load and output capacitor via Vo at the output voltage start-up. When the EN terminal is reset from Hi or UVLO, constant

current is allowed to flow from the NRCS terminal. By this current, voltage generated at the NRCS terminal becomes the

reference voltage and output voltage is started. In order to stabilize the NRCS set time, it is recommended to use a

capacitor (B special) with less capacity value change caused by temperature change.

The present IC incorporates a timer-latch type short-circuit protection circuit in order to prevent MOSFET from being

destroyed by abnormal current when output terminal is short-circuited (operates at the time of NRCS, too). When the

output terminal voltage drops 30% from output setting voltage, IC judges that the output is short-circuited. In such event,

constant current begins to flow. When the voltage generated in the SCP terminal reaches 1.3V (Typ) by this current, the

gate terminal is brought to the Low level. In order to stabilize the SCP setting time, a capacitor (B special) with less

capacity value change caused by temperature changes is recommended.

short-circuit the SCP terminal to the GND terminal. In addition, when the output terminal is short-circuited, the MOSFET

gate voltage reaches the Vcc voltage and the large current that meets MOSFET characteristics flows to the output while

the timer latch type protection circuit operates. When the current capacity of VIN terminal power supply lacks, the Vin

terminal voltage lowers and the UVLO circuit operates, and the latch operation may not be finished. In such event,

connect a limiting resistor across drain terminal and VIN terminal of MOSFET.

In the present IC, N terminal, VIN terminal, and VCC terminal have an independent construction. In addition, in order to

prevent malfunction at the time of low input, the UVLO function is equipped with the VIN terminal and the VCC terminal.

They begin to start output voltage when all the terminals reach threshold voltage without depending on the input order of

input terminals.

The maximum output current capacity of the power supply which is composed by the use of the present IC depends on the

external FET. Consequently, confirm the characteristics of the power required for the set to be used, choose the external

FET.

If it is within the operating ranges, certain circuit functions and operations are warranted in the working ambient

temperature range.

characteristics but there are no sudden variations in characteristic values within these ranges.

With respect to the allowable loss, the thermal derating characteristics are shown in the Exhibit, which we hope would be

used as a good-rule-of-thumb. Should the IC be used in such a manner to exceed the allowable loss, reduction of current

capacity due to chip temperature rise, and other degraded properties inherent to the IC would result. You are strongly

urged to use the IC within the allowable loss.

back-EMF at the start-up and when output is turned OFF is assumed, it is requested to insert a protection diode.

but you are requested to thoroughly confirm the characteristics before using the IC.

In addition, when the IC is used with the external circuit changed, decide the IC

with sufficient margin provided

while consideration is being given not only to static characteristics but also

variations of external parts and our IC including transient characteristics.

With respect to characteristic values, it is unable to warrant standard values of electric

14/16

When the SCP function is not used,

(Example)

OUTPUT PIN

Technical Note

2010.05 - Rev.A

BD3502FVM-TR Rohm Semiconductor, BD3502FVM-TR Datasheet - Page 14

BD3502FVM-TR

Specifications of BD3502FVM-TR

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