BD9E301EFJ-LB(E2) [ROHM]

本产品是面向工业设备市场的产品，保证可长期稳定供货。BD9E301EFJ-LB是内置低导通电阻的功率MOSFET的同步整流降压型开关稳压器。输入电压范围大(7V～36V)，可生成5.0V等低电压。是电流模式控制DC/DC转换器，具有高速瞬态响应性能，可轻松设定相位补偿。BD9E301EFJ-LB也备有250个装的小批量卷轴产品→BD9E301EFJ-LBH2a.productlink{color: #dc2039; text-decoration: underline !important;}a.productlink:hover {opacity: 0.6;};


型号：	BD9E301EFJ-LB(E2)
厂家：	ROHM
描述：	本产品是面向工业设备市场的产品，保证可长期稳定供货。BD9E301EFJ-LB是内置低导通电阻的功率MOSFET的同步整流降压型开关稳压器。输入电压范围大(7V～36V)，可生成5.0V等低电压。是电流模式控制DC/DC转换器，具有高速瞬态响应性能，可轻松设定相位补偿。BD9E301EFJ-LB也备有250个装的小批量卷轴产品→BD9E301EFJ-LBH2a.productlink{color: #dc2039; text-decoration: underline !important;}a.productlink:hover {opacity: 0.6;} 开关转换器稳压器
文件：	总33页 (文件大小：1656K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

Datasheet

7.0V to 36V Input, 2.5A Integrated MOSFET

Single Synchronous Buck DC/DC Converter

BD9E301EFJ-LB BD9E301UEFJ-LB

General Description

Key Specifications

This is the product guarantees long time support in

Industrial market.

◼

Input Voltage Range:

7.0V to 36V

1.0V to VIN×0.7V

2.5A (Max)

Output Voltage Range:

Output Current:

Switching Frequency:

High-Side MOSFET ON-Resistance:170mΩ (Typ)

Low-Side MOSFET ON-Resistance: 140mΩ (Typ)

BD9E301EFJ-LB BD9E301UEFJ-LB is a synchronous buck

switching regulator with built-in power MOSFETs. It is

capable of an output current of up to 2.5A. It is a current

mode control DC/DC converter and features high-speed

transient response. Phase compensation can also be set

easily.

570kHz (Typ)

Standby Current:

0μA (Typ)

Package

HTSOP-J8

W (Typ) x D (Typ) x H (Max)

4.90mm x 6.00mm x 1.00mm

Features

◼

Long Time Support Product for Industrial

Applications.

◼

Synchronous single DC/DC converter.

Over-Current Protection.

Short Circuit Protection.

Thermal Shutdown Protection.

Undervoltage Lockout Protection.

Soft Start.

HTSOP-J8 package (Exposed Pad).

Applications

◼

Industrial Equipment.

Power supply for FA’s industrial device using 24V

bass.

HTSOP-J8

◼

Consumer applications such as home appliance.

Distribution type power supply system for 12V, and

24V.

Typical Application Circuit

VIN

24V

VIN

BOOT

BD9E301EFJ-LB

BD9E301UEFJ-LB

BD9E301EFJ-LB

10μF

0.1μF

6.8μH

VOUT

Enable

22μF×2

COMP

AGND

PGND

12kΩ

15kΩ

3kΩ

4700pF

Figure 1. Application circuit

○Product structure：Silicon monolithic integrated circuit. ○This product has no designed protection against radioactive rays.

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Pin Configuration

(TOP VIEW)

E-Pad

BOOT

VIN

PGND

COMP

AGND

Figure 2. Pin assignment

Pin Description(s)

Pin No

Pin Name

Description

Connect a bootstrap capacitor of 0.1µF between this terminal and SW terminal.

The voltage of this capacitor is the gate drive voltage of the high-side MOSFET.

BOOT

Power supply terminal for the switching regulator and control circuit.

Connecting a 10µF ceramic capacitor is recommended.

VIN

Turning this terminal signal low-level (0.8V or lower) forces the device to enter the shut

down mode. Turning this terminal signal high-level (2.5V or higher) enables the device.

This terminal must be terminated.

AGND

Ground terminal for the control circuit.

Inverting input node for the gm error amplifier.

See page 22 on how to calculate the resistance of the output voltage setting.

Input terminal for the gm error amplifier output and the output switch current comparator.

Connect a frequency phase compensation component to this terminal.

See page 23 on how to calculate the resistance and capacitance for phase

compensation.

COMP

PGND

Ground terminal for the output stage of the switching regulator.

Switch node. This terminal is connected to the source of the high-side MOSFET and

drain of the low-side MOSFET. Connect a bootstrap capacitor of 0.1µF between this

terminal and BOOT terminal. In addition, connect an inductor considering the direct

current superimposition characteristic.

Exposed pad. Connecting this to the internal PCB ground plane using multiple vias

provides excellent heat dissipation characteristics.

E-Pad

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Block Diagram

BOOT

BOOTREG

VREG3

VREG

SCP

OVP

OCP

RCP

VIN

UVLO

TSD

OSC

VIN

VOUT

DRIVER

LOGIC

ERR

SLOPE

PWM

COMP

PGND

SOFT

START

AGND

Figure 3. Block diagram

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Description of Block

• VREG3

Block creating internal reference voltage 3V (Typ).

• VREG

Block creating internal reference voltage 5V (Typ).

• BOOTREG

Block creating gate drive voltage.

• TSD

This is the thermal shutdown block. Thermal shutdown circuit shuts down the whole system if temperature exceeds 175°C

(Typ). When the temperature decreases, it returns to normal operation with hysteresis of 25°C (Typ).

• UVLO

This is the under voltage lock-out block. IC shuts down when VIN is under 6.4V (Typ). The threshold voltage has a

hysteresis of 200mV (Typ).

• ERR

This circuit compares the feedback voltage at the output to the reference voltage. The output of this circuit is the COMP

terminal voltage and this determines the switching duty. Also, because of soft start during start-up, COMP terminal voltage

is controlled by internal slope voltage.

• OSC

Block generating oscillation frequency.

• SLOPE

This circuit creates a triangular wave from generated clock in OSC. The voltage converted from current sense signal of

high side MOSFET and the triangular wave is sent to PWM comparator.

• PWM

This block determines the switching duty by comparing the output COMP terminal voltage of error amplifier and output of

SLOPE block.

• DRIVER LOGIC

This is the DC/DC driver block. Input to this block is signal from PWM and output drives the MOSFETs.

• SOFT START

This circuit prevents the overshoot of output voltage and In-rush current by forcing the output voltage to rise slowly, thus,

avoiding surges in current during start-up.

• OCP

This block limits the current flowing in high side MOSFET for each cycle of switching frequency during over-current.

• RCP

This block limits the current flowing in low side MOSFET for each cycle of switching frequency during over-current.

• SCP

The short circuit protection block compares the FB terminal voltage with the internal standard voltage VREF. When the FB

terminal voltage has fallen below 0.85V (Typ) and remained in that state for 1.0msec (Typ), SCP activates and stops the

operation for 16msec (Typ) and subsequently initiates a restart.

• OVP

Over voltage protection function (OVP) compares FB terminal voltage with the internal standard voltage VREF. When the

FB terminal voltage exceeds 1.30V (Typ), it turns output MOSFETs off. When output voltage drops until it reaches the

hysteresis, it will return to normal operation.

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Absolute Maximum Ratings (Ta = 25°C)

Parameter

Symbol

Rating

Unit

Supply Voltage

VIN

VEN

-0.3 to +40

-0.3 to +45

-0.3 to +7

EN Input Voltage

Voltage from GND to BOOT

Voltage from SW to BOOT

FB Input Voltage

VBOOT

⊿VBOOT

VFB

-0.3 to +7

COMP Input Voltage

VCOMP

VSW

-0.3 to +7

SW Input Voltage

-0.5 to VIN + 0.3

3.75 ^{(Note 1)}

-40 to +150

-55 to +150

Allowable Power Dissipation

Operating Junction Temperature Range

Storage Temperature Range

C

Tstg

(Note 1) Derating in done 30.08 mW/°C for operating above Ta≧25°C (Mount on 4-layer 70.0mm x 70.0mm x 1.6mm board)

Caution1: 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 and the internal circuitry. 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.

Caution2: Reliability is decreased at junction temperature greater than 125C.

Recommended Operating Conditions

Rating

Typ

Parameter

Supply Voltage

Symbol

Unit

Min

7.0

Max

VIN

IOUT

Output Current

2.5

Output Voltage Range

VRANGE

1.0^{(Note 2)}

VIN × 0.7

(Note 2) Please use it in I/O voltage setting of which output pulse width does not become 150nsec (Typ) or less. See the page 22 for how to calculate the

resistance of the output voltage setting.

Electrical Characteristics (Unless otherwise specified V_IN=24V V_EN=3V Ta=25°C)

Limit

Typ

Parameter

Symbol

Unit

Conditions

VFB = 1.1V

Min

Max

2.5

Supply Current in Operating

IOPR

1.5

No switching

Supply Current in Standby

Reference Voltage

ISTBY

VFB

0.98

-1

1.00

1.02

µA

VEN = 0V

FB Input Current

IFB

µA

kHz

VFB = 0V

484

570

656

Switching frequency

FOSC

Maxduty

RONH

RONL

ILIMIT

VUVLO

VUVLOHYS

VENH

VENL

Maximum Duty ratio

High-side FET on-resistance

Low-side FET on-resistance

Over Current limit

170

140

5.0

6.4

200

mΩ

ISW = 100mA

UVLO detection voltage

UVLO hysteresis voltage

EN high-level input voltage

EN low-level input voltage

EN Input current

6.1

100

2.5

6.7

300

VIN

0.8

8.4

VIN falling

IEN

2.1

4.2

µA

VEN = 3V

EN rising to

FB=0.85V

Soft Start time

TSS

1.5

3.0

6.0

msec

●

VFB : FB Input Voltage. VEN : EN Input Voltage.

Pd should not be exceeded.

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Typical Performance Curves

3.0

1.0

0.8

0.6

0.4

0.2

0.0

2.5

2.0

1.5

1.0

0.5

0.0

VIN =36V

VIN=24V

VIN =36V

VIN =24V

VIN =12V

VIN =7V

-40 -20

40 60

80 100 120

-40 -20

20 40

60 80 100 120

Temperature[℃]

Figure 5. Stand-by Current vs Junction Temperature

Figure 4. Operating Current vs Junction Temperature

1.0

0.8

1.02

VIN =24V

VIN =36V

0.6

1.01

1.00

0.99

0.98

VIN =24V

0.4

0.2

0.0

-0.2

-0.4

-0.6

-0.8

-1.0

VIN =12V

VIN =7V

-40 -20

20 40 60 80 100 120

-40 -20

20 40 60 80 100 120

Temperature[℃]

Figure 6. FB Voltage Reference vs Junction Temperature

Figure 7. FB Input Current vs Junction Temperature

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Typical Performance Curves - continued

655

VIN =7V

638

VIN =12V

621

604

587

570

553

536

519

502

485

VIN =24V

VIN =36V

VIN =24V

VIN =7V

VIN =12V

VIN =36V

-40

-20

100 120

-40 -20

40 60

80 100 120

Temperature[℃]

Figure 8. Switching Frequency vs Junction Temperature

Figure 9. Maximum Duty vs Junction Temperature

300

350

VIN =24V

250

300

250

200

150

100

200

150

100

-40 -20

20 40 60 80 100 120

-40 -20

20 40 60 80 100 120

Temperature[℃]

Figure 10. High Side MOSFET ON - Resistance vs

Junction Temperature

Figure 11. Low Side MOSFET ON -Resistance vs

Junction Temperature

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Typical Performance Curves - continued

6.5

6.9

6.8

6.7

6.6

6.5

6.4

6.3

6.2

6.1

VOUT =5V

6.0

Tj =-40°C

VIN Sweep up

5.5

5.0

4.5

Tj =150°C

4.0

3.5

3.0

2.5

Tj =25°C

VIN Sweep down

12 15 18 21 24 27 30 33 36

Input Voltage[V]

-40 -20

80 100 120

Temperature[℃]

Figure 12. Current Limit vs Input Voltage

Figure 13. UVLO Threshold vs Junction Temperature

300

275

250

225

200

175

150

125

100

2.4

2.2

2.0

1.8

1.6

1.4

1.2

1.0

0.8

EN Sweep up

EN Sweep down

-40 -20

20 40 60 80 100 120

-40 -20

20 40

60 80 100 120

Temperature[℃]

Temperature[°C]

Figure 14. UVLO Hysteresis vs Junction Temperature

Figure 15. EN Threshold vs Junction Temperature

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Typical Performance Curves - continued

8.0

5.0

4.0

3.0

2.0

1.0

VIN =36V

VIN =24V

EN=3V

7.0

6.0

5.0

4.0

3.0

2.0

VIN =12V

VIN =7V

-40 -20

20 40

60 80 100 120

-40 -20

20 40

60 80 100 120

Temperature[°C]

Temperature[℃]

Figure 16. EN Input Current vs Junction Temperature

Figure 17. Soft Start Time vs Junction Temperature

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Typical Performance Curves - continued

100

VIN = 7V

VIN = 12V

VIN = 24V

VIN = 12V

VIN = 18V

VIN = 24V

EN = 3V

VOUT = 5.0V

EN = 3V

VOUT = 3.3V

0.0

0.5

1.0

1.5

2.0

2.5

0.0

0.5

1.0

1.5

2.0

2.5

Output Current[A]

Figure 18. Efficiency vs Output Current

(VOUT = 3.3V, L = 6.8µH)

Figure 19. Efficiency vs Output Current

(VOUT = 5.0V, L = 6.8µH)

100

VIN = 18V

VIN = 24V

VIN = 36V

EN = 3V

VOUT = 12V

0.0

0.5

1.0

1.5

2.0

2.5

Output Current[A]

Figure 20. Efficiency vs Output Current

(VOUT = 12V, L = 6.8µH)

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Typical Performance Curves - continued

Time=1ms/div

VIN=10V/div

EN=10V/div

VIN=10V/div

EN=10V/div

VOUT=2V/div

SW=10V/div

VOUT=2V/div

SW=10V/div

Figure 21. Power Up (VIN = EN)

(VOUT = 5.0V)

Figure 22. Power Down (VIN = EN)

(VOUT = 5.0V)

Time=1ms/div

VIN=10V/div

Time=1ms/div

VIN=10V/div

EN=2V/div

VOUT=2V/div

SW=10V/div

VOUT=2V/div

SW=10V/div

Figure 23. Power Up (EN = 0V→5V)

Figure 24. Power Down (EN = 5V→0V)

(VOUT = 5.0V)

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Typical Performance Curves - continued

Time=1μs/div

VOUT=20mV/div

SW=10V/div

Figure 25. VOUT Ripple

(VIN = 24V, VOUT = 5V, IOUT = 0A)

Figure 26. VOUT Ripple

(VIN = 24V, VOUT = 5V, IOUT = 2.5A)

Time=1μs/div

VIN=100mV/div

SW=10V/div

Figure 27. VIN Ripple

(VIN = 24V, VOUT = 5V, IOUT = 0A)

Figure 28. VIN Ripple

(VIN = 24V, VOUT = 5V, IOUT = 2.5A)

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Typical Performance Curves - continued

Time=1μs/div

IL=1.0A/div

SW=5V/div

Figure 29. Switching Waveform

(VIN = 12V, VOUT = 5V, IOUT = 2.5A)

Figure 30. Switching Waveform

(VIN = 24V, VOUT = 5V, IOUT = 2.5A)

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Typical Performance Curves - continued

2.0

1.5

1.0

2.0

1.5

1.0

IOUT=0A

0.5

IOUT=0A

0.5

0.0

-0.5

-1.0

-1.5

-2.0

IOUT=2.5A

-1.0

IOUT=2.5A

VOUT = 3.3V

VOUT = 5.0V

-1.5

-2.0

12 15 18 21 24 27 30 33 36

VIN Input Voltage[V]

12 15 18 21 24 27 30 33 36

VIN Input Voltage[V]

Figure 31. VOUT Line Regulation

Figure 32. VOUT Line Regulation

2.0

1.5

1.0

IOUT=0A

0.5

0.0

-0.5

-1.0

-1.5

-2.0

IOUT=2.5A

VOUT = 12V

14 16 18 20 22 24 26 28 30 32 34 36

VIN Input Voltage[V]

Figure 33. VOUT Line Regulation

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Typical Performance Curves - continued

2.0

1.5

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-0.5

-1.0

-1.5

-2.0

VIN = 24V

VOUT = 3.3V

VIN = 24V

VOUT = 5.0V

-1.5

-2.0

0.0

0.5

1.0

1.5

2.0

2.5

0.0

0.5

1.0

1.5

2.0

2.5

Output Current[A]

Figure 35. VOUT Load Regulation

Figure 34. VOUT Load Regulation

2.0

1.5

1.0

0.5

0.0

-0.5

-1.0

-1.5

-2.0

VIN=24V

VOUT=12V

0.0

0.5

1.0

1.5

2.0

2.5

Output Current[A]

Figure 36. VOUT Load Regulation

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Typical Performance Curves – continued

180

135

180

135

VIN=12V

VIN=24V

VOUT=5V

VOUT=3.3V

phase

-20

-40

-60

-80

-45

-90

-135

-180

-20

-45

-90

-135

-180

gain

-40

-60

-80

100

10K

100K

100

10K

100K

Frequency[Hz]

Figure 37. Loop Response

Figure 38. Loop Response

(VIN=12V, VOUT=3.3V, IOUT=2.5A, COUT=Ceramic22μF×2)

(VIN=24V, VOUT=5V, IOUT=2.5A, COUT=Ceramic22μF×2)

Time=1ms/div

VOUT=100mV/div

IOUT=1.0A/div

VOUT=100mV/div

IOUT=1.0A/div

Figure 39. Load Transient Response IOUT=0A – 2.5A

(VIN=12V, VOUT=3.3V, COUT=Ceramic22μF×2)

Figure 40. Load Transient Response IOUT=0A – 2.5A

(VIN=24V, VOUT=5.0V, COUT=Ceramic22μF×2)

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Function Description

1. Enable Control

The IC shutdown can be controlled by the voltage applied to the EN terminal. When EN voltage reaches 2.5V (Typ), the

internal circuit is activated and the IC starts up. Setting the shutdown interval (Low Level interval) of EN to 100µs or longer

will enable the shutdown control with the EN terminal.

VEN

EN terminal

VENH

VENL

VOUT

Output Voltage

VOUT×0.85

TSS

Figure 41. Timing Chart with Enable Control

2. Protective Functions

The protective circuits are intended for the prevention of damages caused by unexpected accidents. Do not use

them for continuous protective operation.

(1) Short Circuit Protection (SCP)

The short circuit protection block compares the FB terminal voltage with the internal reference voltage VREF. When

the FB terminal voltage has fallen below 0.85V (Typ) and remained in that state for 1.0msec (Typ), SCP activates and

stops the operation for 16msec (Typ) and subsequently initiates a restart.

Table 1. Short Circuit Protection Function

EN pin

FB pin

0.30V (Typ)≧FB

0.30V (Typ)＞B≧0.85V (Typ)

FB＞0.85V (Typ)

Short circuit protection

Enabled

Switching Frequency

142.5kHz (Typ)

285kHz (Typ)

570kHz (Typ)

OFF

2.5V or higher

0.8V or lower

Disabled

Soft start

3.0msec (typ.)

V_OUT

SCP detection time

1.0msec (typ.)

SCP detection time

1.0msec (typ.)

1.0V

FB terminal

SCP threshold voltage：

0.85Ｖ(typ.)

SCP detection released

Upper MOSFET

gate

LOW

Lower MOSFET

gate

OCP

Threshold

Inductor

current

IC internal

SCP signal

16msec (typ.)

SCP reset

Figure 42. Short Circuit Protection (SCP) Timing Chart

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(2) Under Voltage Lockout Protection (UVLO)

The under voltage lockout protection circuit monitors the VIN terminal voltage.

The operation enters standby when the VIN terminal voltage is 6.4V (Typ) or lower.

The operation starts when the VIN terminal voltage is 6.6V (Typ) or higher.

V_IN

UVLO OFF

hys

UVLO ON

V_OUT

Soft start

terminal

High-side

MOSFET gate

Low-side

MOSFET gate

Normal operation

UVLO

Normal operation

Figure 43. UVLO Timing Chart

(3) Thermal Shutdown (TSD)

When the chip temperature exceeds Tj = 175C, the DC/DC converter output is stopped. The thermal shutdown

circuit is intended for shutting down the IC from thermal runaway in an abnormal state with the temperature

exceeding Tjmax = 150C. It is not meant to protect or guarantee the soundness of the application. Do not use the

function of this circuit for application protection design.

(4) Over Current Protection (OCP)

The over-current protection function is realized by using the current mode control to limit the current that flows

through the high-side MOSFET at each cycle of the switching frequency.

(5) Reverse Current Protection (RCP)

The reverse current protection function is realized by using the current mode control to limit the current that flows

through the low-side MOSFET at each cycle of the switching frequency.

(6) Over Voltage Protection (OVP)

Over voltage protection function (OVP) compares FB terminal voltage with internal standard voltage VREF. When the

FB terminal voltage exceeds 1.30V (Typ), it turns output MOSFETs off. When output voltage drops until it reaches the

hysteresis, it will return to normal operation.

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Application Example

C_BOOT

COUT

BOOT

VIN

VOUT

VIN

PGND

BD9E301EFJ-LB

BD9E301UEFJ-LB

BD9E301EFJ-LB

COMP

CIN

AGND

Figure 44. Application Circuit

Table 2. Recommendation Component Valves

VIN

VOUT

CIN

CBOOT

12V

24V

3.3V

10μF

0.1μF

4.7μH

6.8kΩ

3.0kΩ

6.8kΩ

10μF

0.1μF

4.7μH

6.8kΩ

3.0kΩ

6.8kΩ

10μF

0.1μF

4.7μH

6.8kΩ

3.0kΩ

6.8kΩ

10μF

0.1μF

6.8μH

12kΩ

3.0kΩ

15kΩ

10μF

0.1μF

6.8μH

12kΩ

3.0kΩ

15kΩ

10μF

0.1μF

6.8μH

12kΩ

3.0kΩ

15kΩ

6800pF

Ceramic 10μF

and

Aluminum

100μF

4700pF

Ceramic 10μF

and

Aluminum

100μF

Ceramic

22μF×2

Ceramic

10μF×3

Ceramic

22μF×2

Ceramic

10μF×3

COUT

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Selection of Components Externally Connected

1. Output LC Filter

The DC/DC converter requires an LC filter for smoothing the output voltage in order to supply a continuous current to the

load. Selecting an inductor with a large inductance causes the ripple current ∆IL that flows into the inductor to be small,

decreasing the ripple voltage generated in the output voltage, but it is not advantageous in terms of the load transient

response characteristic. Selecting an inductor with a small inductance improves the transient response characteristic but

causes the inductor ripple current to be large, which increases the ripple voltage in the output voltage, showing a trade-off

relationship. Here, select an inductance so that the size of the ripple current component of the inductor will be 20% to 50%

of the average output current (average inductor current).

VIN

I_L

Inductor saturation current > I_OUTMAX+⊿I_L/2

VOUT

IOUTMAX

Driver

⊿I_L

C_OUT

Average inductor current

Figure 45. Waveform of current through inductor

Figure 46. Output LC filter circuit

Computation with VIN = 24V, VOUT = 5V, L = 6.8μH, switching frequency FOSC = 570kHz, the method is as below.

Inductor ripple current

ΔIL

= V_OUT× (V_IN-V_OUT) ×

= 1.0 [A]

V_IN× F_OSC× L

where :

ΔI^Lis the inductor ripple current

F_OSCis the swithing frequency

L is the inductor

V_INis the input voltage

V_OUTis the output voltage

Also for saturation current of inductor, select the one with larger current than maximum output current added by 1/2 of

inductor ripple current ∆IL.

Output capacitor COUT affects output ripple voltage characteristics. Select output capacitor COUT so that necessary ripple

voltage characteristics are satisfied.

Output ripple voltage can be expressed in the following method.

ΔV_RPL= ΔI_L× (R_ESR

) [V]

8 ×C_OUT× F_OSC

where :

ΔV_RPLis the output ripple voltage

R_ESRis the serialequivalent seriesresistance

C_OUTis the output capacitor

With COUT = 44µF, RESR = 10mΩ the output ripple voltage is calculated as

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ΔV_RPL= 1.0 × (10m+

) = 15 [mv]

8 × 44μ × 570k

* When selecting the value of the output capacitor COUT, please note that the value of capacitor CLOAD will add up to

the value of COUT to be connected to VOUT

Charging current to flow through the CLOAD, COUT and the IC startup, must be completed within the soft-start time this

charge. Over-current protection circuit operates when charging is continued beyond the soft-start time, the IC may not

start. Please consider in the calculation the condition that the lower maximum value capacitor CLOAD that can be

connected to VOUT (max) is other than COUT.

Inductor ripple current maximum value of start-up (ILSTART)

Over Current Protection Threshold 3.8 [A](min)

Inductor ripple current maximum value of start-up (ILSTART) can be expressed in the following method.

⊿IL

ILSTART = Output maximum load current(IOMAX) + Charging current to the output capacitor (ICAP) +

[mV]

Charging current to the output capacitor (ICAP) can be expressed in the following method.

(C_OUT+ C _LOAD) ×V_OUT

I_CAP

[A]

T_SS

where :

C_OUTis the output capacitance

C _LOADis the output loadcapacitance

T_SSis the soft start time

From the above equation, VIN = 24V, VOUT = 5V, L = 4.7μH, IOMAX = 2.5A (max), switching frequency FOSC = 484kHz (min),

the output capacitor COUT = 44μF, TSS = 1.5ms soft-start time (min), it becomes the following equation when calculating

the maximum output load capacitance CLOAD (max) that can be connected to VOUT.

(3.8 - I_OMAX- ΔI_L/2)×T_SS

C _LOAD(max)<

- C_OUT= 165 [ μF]

V_OUT

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2. Output Voltage Set Point

The output voltage value can be set by the feedback resistance ratio.

R₁+ R₂

R₂

VOUT

V_OUT

× 1.0 [V]

－

ERR

＋

※

Minimum pulse range that can be produced at the output

stably through all the load area is 150nsec for

BD9E301EFJ-LB BD9E301UEFJ-LB.

Use input/output condition which satisfies the following

method.

1.0V

V_OUT

150(nsec)

≤

V_IN× F_OSC

Figure 47. Feedback Resistor Circuit

3. Input voltage start-up

V_IN

V_OUT×0.85

V_IN

≧

0.7

V_OUT

UVLO

release

（6.6Vtyp.)

V_OUT×0.85

TSS

Figure 48. Input Voltage Start-up Time

Soft-start function is designed for the IC so that the output voltage will start according to the time it was decided internally.

After UVLO release, the output voltage range will be less than 70% of the input voltage at soft-start operation. Please be

sure that the input voltage of the soft-start after startup is as follows.

V_OUT× 0.85

V_IN

≥

[V]

0.7

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4. Phase Compensation

A current mode control buck DC/DC converter is a two-pole, one-zero system. The two poles are formed by an error

amplifier and load and the one zero point is added by the phase compensation. The phase compensation resistor R_CMP

determines the crossover frequency F_CRSwhere the total loop gain of the DC/DC converter is 0 dB. The high value of this

crossover frequency F_CRSprovides a good load transient response characteristic but inferior stability. Conversely,

specifying a low value for the crossover frequency F_CRSgreatly stabilizes the characteristics but the load transient

response characteristic is impaired.

(1) Selection of Phase Compensation Resistor R_CMP

The phase compensation resistance R_CMPcan be determined by using the following equation.

2π ×V_OUT× F_CRS× C_OUT

R_CMP

[Ω] ꢀ

V_FB× G_MP× G_MA

where :

V_OUTis the output voltage

F_CRSis the crossoverfrequency

C_OUTis the output capacitance

V_FBis the feedback referencevoltage (1.0 V (Typ))

G_MPis the current sensegain(7 A/V (Typ))

G_MAis the error amplifier transconductance(150μA/V (Typ))

(2) Selection of phase compensation capacitance C_CMP

For stable operation of the DC/DC converter, inserting a zero point under 1/6 of the zero crossover frequency cancels

the phase delay due to the pole formed by the load often, thus, providing favorable characteristics.

The phase compensation capacitance C_CMPcan be determined by using the following equation.

C_CMP

[F]

2π × R_CMP× F_Z

where

_Zꢀis the Zeropoint inserted

(3) Loop stability

To ensure the stability of the DC/DC converter, make sure that a sufficient phase margin is provided. Phase margin

of at least 45 degrees in the worst conditions is recommended. The feed forward capacitor C_RUPis used for the

purpose of forming a zero point together with the resistor R_UPto increase the phase margin within the limited

frequency range. Using a C_RUPis effective when the R_UPresistance is larger than the combined parallel resistance of

R_UPand R_DW

V_OUT

(a)

Gain [dB]

R_UP

C_RUP

GBW(b)

COMP

FCRS

Phase[deg]

R_DW

1.0V

C_CMP

R_CMP

－90°

－90

PHASE MARGIN

－180°

－180

Figure 49. Phase compensation circuit

Figure 50. Bode plot

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PCB Layout Design

In buck DC/DC converters, a large pulsed current flows in two loops. The first loop is the one into which the current flows

when the High Side FET is turned on. The flow starts from the input capacitor CIN, runs through the FET, inductor L and

output capacitor COUT and back to ground of CIN via ground of COUT. The second loop is the one into which the current flows

when the Low Side FET is turned on. The flow starts from the Low Side FET, runs through the inductor L and output

capacitor COUT and back to ground of the Low Side FET via ground of COUT. Tracing these two loops as thick and short as

possible allows noise to be reduced for improved efficiency. It is recommended to connect the input and output capacitors, in

particular, to the ground plane. The PCB layout has a great influence on the DC/DC converter in terms of all of the heat

generation, noise and efficiency characteristics.

V_IN

V_OUT

MOS FET

C_IN

C_OUT

Figure 51. Current Loop of Buck Converter

Accordingly, design the PCB layout with particular attention paid to the following points.



Provide the input capacitor as close to the VIN terminal as possible on the same plane as the IC.

If there is any unused area on the PCB, provide a copper foil plane for the ground node to assist in heat dissipation

from the IC and the surrounding components.



Switching nodes such as SW are susceptible to noise due to AC coupling with other nodes. Trace to the inductor as

thick and as short as possible.



Provide lines connected to FB and COMP as far as possible from the SW node.

Provide the output capacitor away from the input capacitor in order to avoid the effect of harmonic noise from the

input.

COUT

VOUT

GND

CIN

CBOOT

VIN

Top Layer

Bottom Layer

Figure 52. Example of Sample Board Layout Pattern

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Power Dissipation

When designing the PCB layout and peripheral circuitry, sufficient consideration must be given to ensure that the power

dissipation is within the allowable dissipation curve.

4.0

3.75W

3.0

θJA=33.3°C/W

4 layer board

(back side copper foil area:70mm×70mm)

2.0

1.0

75 85 100

125

150

Temperature:Ta [°C]

Figure 53. Power Dissipation (HTSOP-J8)

I/O equivalence circuit(s)

1. BOOT 8. SW

3. EN

BOOTREG

280kΩ

BOOT

VIN

294kΩ

146kΩ

REG

AGND

PGND

5. FB

6. COMP

VREG

COMP

AGND

Figure 54. I/O Equivalent Circuit Chart

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Operational Notes

Reverse Connection of Power Supply

Connecting the power supply in reverse polarity can damage the IC. Take precautions against reverse polarity when

connecting the power supply, such as mounting an external diode between the power supply and the IC’s power supply

terminals.

Power Supply Lines

Design the PCB layout pattern to provide low impedance supply lines. Separate the ground and supply lines of the

digital and analog blocks to prevent noise in the ground and supply lines of the digital block from affecting the analog

block. Furthermore, connect a capacitor to ground at all power supply pins. Consider the effect of temperature and

aging on the capacitance value when using electrolytic capacitors.

Ground Voltage

Ensure that no pins are at a voltage below that of the ground pin at any time, even during transient condition.

Ground Wiring Pattern

When using both small-signal and large-current ground traces, the two ground traces should be routed separately but

connected to a single ground at the reference point of the application board to avoid fluctuations in the small-signal

ground caused by large currents. Also ensure that the ground traces of external components do not cause variations

on the ground voltage. The ground lines must be as short and thick as possible to reduce line impedance.

Thermal Consideration

Should by any chance the power dissipation rating be exceeded, the rise in temperature of the chip may result in

deterioration of the properties of the chip. The absolute maximum rating of the Pd stated in this specification is when

the IC is mounted on a 70mm x 70mm x 1.6mm glass epoxy board. In case of exceeding this absolute maximum rating,

increase the board size and copper area to prevent exceeding the Pd rating.

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.

Inrush Current

When power is first supplied to the IC, it is possible that the internal logic may be unstable and inrush

current may flow instantaneously due to the internal powering sequence and delays, especially if the IC

has more than one power supply. Therefore, give special consideration to power coupling capacitance,

power wiring, width of ground wiring, and routing of connections.

Operation Under Strong Electromagnetic Field

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

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.

10. Inter-pin Short and Mounting Errors

Ensure that the direction and position are correct when mounting the IC on the PCB. Incorrect mounting may result in

damaging the IC. Avoid nearby pins being shorted to each other especially to ground, power supply and output pin.

Inter-pin shorts could be due to many reasons such as metal particles, water droplets (in very humid environment) and

unintentional solder bridge deposited in between pins during assembly to name a few.

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Operational Notes – continued

11. Unused Input Terminals

Input pins of an IC are often connected to the gate of a MOS transistor. The gate has extremely high impedance and

extremely low capacitance. If left unconnected, the electric field from the outside can easily charge it. The small charge

acquired in this way is enough to produce a significant effect on the conduction through the transistor and cause

unexpected operation of the IC. So unless otherwise specified, unused input pins should be connected to the power

supply or ground line.

12. Regarding Input Pins of the IC

This monolithic IC contains P+ isolation and P substrate layers between adjacent elements in order to keep them

isolated. P-N junctions are formed at the intersection of the P layers with the N layers of other elements, creating a

parasitic diode or transistor. For example (refer to figure below):

When GND > Pin A and GND > Pin B, the P-N junction operates as a parasitic diode.

When GND > Pin B, the P-N junction operates as a parasitic transistor.

Parasitic diodes inevitably occur in the structure of the IC. The operation of parasitic diodes can result in mutual

interference among circuits, operational faults, or physical damage. Therefore, conditions that cause these diodes to

operate, such as applying a voltage lower than the GND voltage to an input pin (and thus to the P substrate) should be

Resistor

Transistor (NPN)

Pin A

Pin B

Pin A

P⁺

Parasitic

Elements

Parasitic

Elements

P Substrate

GND GND

P Substrate

GND

Parasitic

Elements

Parasitic

Elements

N Region

close-by

avoided.

Figure 55. Example of monolithic IC structure

13. Ceramic Capacitor

When using a ceramic capacitor, determine the dielectric constant considering the change of capacitance with

temperature and the decrease in nominal capacitance due to DC bias and others.

14. Area of Safe Operation (ASO)

Operate the IC such that the output voltage, output current, and power dissipation are all within the Area of Safe

Operation (ASO).

15. Thermal Shutdown Circuit (TSD)

This IC has a built-in thermal shutdown circuit that prevents heat damage to the IC. Normal operation should always be

within the IC’s power dissipation rating. If however the rating is exceeded for a continued period, the junction

temperature (Tj) will rise which will activate the TSD circuit that will turn OFF all output pins. When the Tj falls below the

TSD threshold, the circuits are automatically restored to normal operation.

Note that the TSD circuit operates in a situation that exceeds the absolute maximum ratings and therefore, under no

circumstances, should the TSD circuit be used in a set design or for any purpose other than protecting the IC from heat

damage.

16. Over Current Protection Circuit (OCP)

This IC incorporates an integrated overcurrent protection circuit that is activated when the load is shorted. This

protection circuit is effective in preventing damage due to sudden and unexpected incidents. However, the IC should

not be used in applications characterized by continuous operation or transitioning of the protection circuit.

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Ordering Information

B D 9 E

E F

LBH2

Production Line

NONE:

Production Line A

“U”:

Package

EFJ: HTSOP-J8

Product class

LB: for Industrial applications

Packaging and forming specification

H2: Embossed tape and 18cm reel

(Quantity : 250pcs)

Production Line B

B D 9 E

E F

LBE2

Production Line

NONE:

Production Line A

“U”:

Package

EFJ: HTSOP-J8

Product class

LB: for Industrial applications

Packaging and forming specification

E2: Embossed tape and 32.8cm reel

(Quantity : 2500pcs)

Production Line B

Package

HTSOP-J8

Part Number

Remarks

BD9E301EFJ-LBH2

BD9E301EFJ-LBE2

Production Line A^{(Note 1)}

Production Line B^{(Note 1)}

BD9E301UEFJ-LBH2

BD9E301UEFJ-LBE2

(Note 1) For the purpose of improving production efficiency, Production Line A and B have a multi-line configuration.

Electrical characteristics noted in Datasheet does not differ between Production Line A and B.

Production Line B is recommended for new product.

Marking Diagrams

HTSOP-J8 (TOP VIEW)

Part Number Marking

D 9 E 3 0 1

LOT Number

1PIN MARK

HTSOP-J8 (TOP VIEW)

Part Number Marking

9 E 3 0 1 U

LOT Number

1PIN MARK

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Physical Dimension, Tape and Reel Information

Package Name

HTSOP-J8

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Revision History

Date

Revision

001

Changes

01.Nov.2013

21.Feb.2014

New Release

Delete sentence “and log life cycle” in General Description and Futures.

Change “Packaging and forming specification” from E2 to H2.

Add E2 rank of “Packaging and forming specification”

Add BD9E301UEFJ-LB

002

14.May.2014

01.Nov.2022

003

004

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Notice

Precaution on using ROHM Products

(Note 1)

1. If you intend to use our Products in devices requiring extremely high reliability (such as medical equipment

aircraft/spacecraft, nuclear power controllers, etc.) and whose malfunction or failure may cause loss of human life,

bodily injury or serious damage to property (“Specific Applications”), please consult with the ROHM sales

representative in advance. Unless otherwise agreed in writing by ROHM in advance, ROHM shall not be in any way

responsible or liable for any damages, expenses or losses incurred by you or third parties arising from the use of any

ROHM’s Products for Specific Applications.

(Note1) Medical Equipment Classification of the Specific Applications

JAPAN

USA

CHINA

CLASSⅢ

CLASSⅣ

CLASSⅡb

CLASSⅢ

2. ROHM designs and manufactures its Products subject to strict quality control system. However, semiconductor

products can fail or malfunction at a certain rate. Please be sure to implement, at your own responsibilities, adequate

safety measures including but not limited to fail-safe design against the physical injury, damage to any property, which

a failure or malfunction of our Products may cause. The following are examples of safety measures:

[a] Installation of protection circuits or other protective devices to improve system safety

[b] Installation of redundant circuits to reduce the impact of single or multiple circuit failure

3. Our Products are not designed under any special or extraordinary environments or conditions, as exemplified below.

Accordingly, ROHM shall not be in any way responsible or liable for any damages, expenses or losses arising from the

use of any ROHM’s Products under any special or extraordinary environments or conditions. If you intend to use our

Products under any special or extraordinary environments or conditions (as exemplified below), your independent

verification and confirmation of product performance, reliability, etc, prior to use, must be necessary:

[a] Use of our Products in any types of liquid, including water, oils, chemicals, and organic solvents

[b] Use of our Products outdoors or in places where the Products are exposed to direct sunlight or dust

[c] Use of our Products in places where the Products are exposed to sea wind or corrosive gases, including Cl2,

H2S, NH3, SO2, and NO2

[d] Use of our Products in places where the Products are exposed to static electricity or electromagnetic waves

[e] Use of our Products in proximity to heat-producing components, plastic cords, or other flammable items

[f] Sealing or coating our Products with resin or other coating materials

[g] Use of our Products without cleaning residue of flux (Exclude cases where no-clean type fluxes is used.

However, recommend sufficiently about the residue.); or Washing our Products by using water or water-soluble

cleaning agents for cleaning residue after soldering

[h] Use of the Products in places subject to dew condensation

4. The Products are not subject to radiation-proof design.

5. Please verify and confirm characteristics of the final or mounted products in using the Products.

6. In particular, if a transient load (a large amount of load applied in a short period of time, such as pulse, is applied,

confirmation of performance characteristics after on-board mounting is strongly recommended. Avoid applying power

exceeding normal rated power; exceeding the power rating under steady-state loading condition may negatively affect

product performance and reliability.

7. De-rate Power Dissipation depending on ambient temperature. When used in sealed area, confirm that it is the use in

the range that does not exceed the maximum junction temperature.

8. Confirm that operation temperature is within the specified range described in the product specification.

9. ROHM shall not be in any way responsible or liable for failure induced under deviant condition from what is defined in

this document.

Precaution for Mounting / Circuit board design

1. When a highly active halogenous (chlorine, bromine, etc.) flux is used, the residue of flux may negatively affect product

performance and reliability.

2. In principle, the reflow soldering method must be used on a surface-mount products, the flow soldering method must

be used on a through hole mount products. If the flow soldering method is preferred on a surface-mount products,

please consult with the ROHM representative in advance.

For details, please refer to ROHM Mounting specification

Notice-PAA-E

Rev.004

Precautions Regarding Application Examples and External Circuits

1. If change is made to the constant of an external circuit, please allow a sufficient margin considering variations of the

characteristics of the Products and external components, including transient characteristics, as well as static

characteristics.

2. You agree that application notes, reference designs, and associated data and information contained in this document

are presented only as guidance for Products use. Therefore, in case you use such information, you are solely

responsible for it and you must exercise your own independent verification and judgment in the use of such information

contained in this document. ROHM shall not be in any way responsible or liable for any damages, expenses or losses

incurred by you or third parties arising from the use of such information.

Precaution for Electrostatic

This Product is electrostatic sensitive product, which may be damaged due to electrostatic discharge. Please take proper

caution in your manufacturing process and storage so that voltage exceeding the Products maximum rating will not be

applied to Products. Please take special care under dry condition (e.g. Grounding of human body / equipment / solder iron,

isolation from charged objects, setting of Ionizer, friction prevention and temperature / humidity control).

Precaution for Storage / Transportation

1. Product performance and soldered connections may deteriorate if the Products are stored in the places where:

[a] the Products are exposed to sea winds or corrosive gases, including Cl₂, H₂S, NH₃, SO₂, and NO₂

[b] the temperature or humidity exceeds those recommended by ROHM

[c] the Products are exposed to direct sunshine or condensation

[d] the Products are exposed to high Electrostatic

2. Even under ROHM recommended storage condition, solderability of products out of recommended storage time period

may be degraded. It is strongly recommended to confirm solderability before using Products of which storage time is

exceeding the recommended storage time period.

3. Store / transport cartons in the correct direction, which is indicated on a carton with a symbol. Otherwise bent leads

may occur due to excessive stress applied when dropping of a carton.

4. Use Products within the specified time after opening a humidity barrier bag. Baking is required before using Products of

which storage time is exceeding the recommended storage time period.

Precaution for Product Label

A two-dimensional barcode printed on ROHM Products label is for ROHM’s internal use only.

Precaution for Disposition

When disposing Products please dispose them properly using an authorized industry waste company.

Precaution for Foreign Exchange and Foreign Trade act

Since concerned goods might be fallen under listed items of export control prescribed by Foreign exchange and Foreign

trade act, please consult with ROHM in case of export.

Precaution Regarding Intellectual Property Rights

1. All information and data including but not limited to application example contained in this document is for reference

only. ROHM does not warrant that foregoing information or data will not infringe any intellectual property rights or any

other rights of any third party regarding such information or data.

2. ROHM shall not have any obligations where the claims, actions or demands arising from the combination of the

Products with other articles such as components, circuits, systems or external equipment (including software).

3. No license, expressly or implied, is granted hereby under any intellectual property rights or other rights of ROHM or any

third parties with respect to the Products or the information contained in this document. Provided, however, that ROHM

will not assert its intellectual property rights or other rights against you or your customers to the extent necessary to

manufacture or sell products containing the Products, subject to the terms and conditions herein.

Other Precaution

1. This document may not be reprinted or reproduced, in whole or in part, without prior written consent of ROHM.

2. The Products may not be disassembled, converted, modified, reproduced or otherwise changed without prior written

consent of ROHM.

3. In no event shall you use in any way whatsoever the Products and the related technical information contained in the

Products or this document for any military purposes, including but not limited to, the development of mass-destruction

weapons.

4. The proper names of companies or products described in this document are trademarks or registered trademarks of

ROHM, its affiliated companies or third parties.

Notice-PAA-E

Rev.004

Daattaasshheeeett

General Precaution

1. Before you use our Products, you are requested to carefully read this document and fully understand its contents.

ROHM shall not be in any way responsible or liable for failure, malfunction or accident arising from the use of any

ROHM’s Products against warning, caution or note contained in this document.

2. All information contained in this document is current as of the issuing date and subject to change without any prior

notice. Before purchasing or using ROHM’s Products, please confirm the latest information with a ROHM sales

representative.

3. The information contained in this document is provided on an “as is” basis and ROHM does not warrant that all

information contained in this document is accurate and/or error-free. ROHM shall not be in any way responsible or

liable for any damages, expenses or losses incurred by you or third parties resulting from inaccuracy or errors of or

concerning such information.

Notice – WE

Rev.001

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