BD52E42G-TR Datasheet BD52E42G-TR, BD53E29G-TR | P10-P12

Datasheet

10/12

BD52Exxx series BD53Exxx series

TSZ02201-0R7R0G300080-1-

22.May.2013 Rev.004

www.rohm.com

TSZ22111・15・001

●Circuit Applications

1) Examples of a common power supply detection reset circuit

Application examples of BD52Exxx series (Open Drain

output type) and BD53Exxx series (CMOS output type)

are shown below.

CASE1: Power supply of the microcontroller (V

DD2

)

differs from the power supply of the reset detection

DD1

Use an open drain output type (BD52Exxx) with a load

resistance R

attached as shown Figure.18.

CASE2: Power supply of the microcontroller (V

DD1

) is the

same as the power supply of the reset detection (V

DD1

Use a CMOS output type (BD53Exxx) device or open

drain output type (BD52Exxx) device with a pull up

resistor attached between the output and V

DD1

When a capacitance C

for noise filtering is connected to

the V

OUT

pin (the reset signal input terminal of the

microcontroller), please take into account the waveform

of the rise and fall of the output voltage (V

OUT

Please refer to Operational Notes for recommendations

on resistor and capacitor values.

2) The following is an example of a circuit application in which an OR connection between two types of detection voltage

resets the microcontroller.

To reset the microcontroller when many independent power supplies are used in the system, OR connect an open drain

output type (BD52Exxx series) to the microcontroller’s input with pull-up resistor to the supply voltage of the microcontroller

DD3

) as shown in Fig. 20. By pulling-up to V

DD3

, output “High” voltage of micro-controller power supply is possible.

DD1

BD52Exxx

DD2

GND

（Noise-filtering

Capacitor）

Micro

controller

Figure.18 Open Drain Output Type

（Noise-filtering

Capacitor）

DD1

BD53Exxx

GND

Micro

controller

Figure.19 CMOS Output Type

VDD1 VDD3

GND

RST

microcontroller

VDD2

BD52Exxx

NO.1

BD52Exxx

NO.2

Fig.20

Datasheet

11/12

BD52Exxx series BD53Exxx series

TSZ02201-0R7R0G300080-1-

22.May.2013 Rev.004

www.rohm.com

TSZ22111・15・001

3) Examples of the power supply with resistor dividers

In applications wherein the power supply voltage of an IC comes from a resistor divider circuit, an in-rush current will flow

into the circuit when the output level switches from “High” to “Low” or vice versa. In-rush current is a sudden surge of

current that flows from the power supply (VDD) to ground (GND) as the output logic changes its state. This current flow

may cause malfunction in the systems operation such as output oscillations, etc.

Figure.21

When an in-rush current (I1) flows into the circuit (Refer to Fig. 21) at the time when output switches from “Low” to “High”,

a voltage drop of I1×R2 (input resistor) will occur in the circuit causing the VDD supply voltage to decrease. When the VDD

voltage drops below the detection voltage, the output will switch from “High” to “Low”. While the output voltage is at “Low”

condition, in-rush current will stop flowing and the voltage drop will be reduced. As a result, the output voltage will switches

again from “Low” to “High” which causes an in-rush current and a voltage drop. This operation repeats and will result to

oscillation.

Figure.22 IDD Peak Current vs. Power Supply Voltage

This data is for reference only.

The figures will vary with the application, so please confirm actual operating conditions before use.

VOUT

VDD

BD52Exxx

BD53Exxx

GND

CIN

IDD

VDET

Through

Current

V D D - ID D Peak C urrent T a=25°C

0.001

0.01

0.1

3 4 5 6 7 8 9 10

V D D [V ]

ID D -peak[m A ]

B D 52Exxx

B D 53Exxx

Datasheet

12/12

BD52Exxx series BD53Exxx series

TSZ02201-0R7R0G300080-1-

22.May.2013 Rev.004

www.rohm.com

TSZ22111・15・001

●

●●

●Operational Notes

1) Absolute maximum ratings

Operating the IC over the absolute maximum ratings may damage the IC. The damage can either be a short circuit

between pins or an open circuit between pins. Therefore, it is important to consider circuit protection measures, such

as adding a fuse, in case the IC is operated over the absolute maximum ratings.

2) Ground Voltage

The voltage of the ground pin must be the lowest voltage of all pins of the IC at all operating conditions. Ensure that no

pins are at a voltage below the ground pin at any time, even during transient condition.

3) Recommended operating conditions

These conditions represent a range within which the expected characteristics of the IC can be approximately obtained.

The electrical characteristics are guaranteed under the conditions of each parameter.

4) Bypass Capacitor for Noise Rejection

To help reject noise, put a 1µF capacitor between V

DD pin and GND and 1000pF capacitor between VOUT pin and GND.

Be careful when using extremely big capacitor as transient response will be affected.

5) Short between pins and mounting errors

Be careful when mounting the IC on printed circuit boards. The IC may be damaged if it is mounted in a wrong

orientation or if pins are shorted together. Short circuit may be caused by conductive particles caught between the pins.

6) Operation under strong electromagnetic field

Operating the IC in the presence of a strong electromagnetic field may cause the IC to malfunction.

7) The V

line impedance might cause oscillation because of the detection current.

8) A V

to GND capacitor (as close connection as possible) should be used in high VDD line impedance condition.

9) Lower than the mininum input voltage puts the VOUT in high impedance state, and it must be VDD in pull up (VDD)

condition.

10) External parameters

The recommended value of R

Resistor is 50k to 1M. The recommended value of C

Capacitor is over 100pF to

0.1µF. There are many factors (board layout, etc) that can affect characteristics. Please verify and confirm using

practical applications.

11) Power on reset operation

Please note that the power on reset output varies with the V

rise time. Please verify the behavior in the actual

operation.

12) Testing on application boards

When testing the IC on an application board, connecting a capacitor directly to a low-impedance output pin may subject

the IC to stress. Always discharge capacitors completely after each process or step. The IC’s power supply should

always be turned off completely before connecting or removing it from the test setup during the inspection process. To

prevent damage from static discharge, ground the IC during assembly and use similar precautions during transport and

storage.

13) Rush current

When power is first supplied to the IC, rush current may flow instantaneously. It is possible that the charge current to

the parasitic capacitance of internal photo diode or the internal logic may be unstable. Therefore, give special

consideration to power coupling capacitance, power wiring, width of GND wiring, and routing of connections.

14) C

pin discharge

Due to the capabilities of the C

pin discharge transistor, the C

pin may not completely discharge when a short input

pulse is applied, and in this case the delay time may not be controlled. Please verify the actual operation.

P1-P3 P4-P6 P7-P9 P10-P12 P13-P15

BD52E42G-TR

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