Specification	BD9B300MUV-E2

Current - Output	3 A
Frequency - Switching	2 MHz, 1 MHz
Function	Step-Down
Mounting Type	Surface Mount
Number of Outputs	1
Operating Temperature [Max]	85 C
Operating Temperature [Min]	-40 ¯C
Output Configuration	Positive
Output Type	Adjustable
Package / Case	16-VFQFN Exposed Pad
Supplier Device Package	VQFN016V3030
Synchronous Rectifier	True
Topology	Buck
Voltage - Input (Max) [Max]	5.5 V
Voltage - Input (Min) [Min]	2.7 V
Voltage - Output (Max) [Max]	4.4 V
Voltage - Output (Min/Fixed)	0.8 V

BD9B300 Series

Part	Outputs and Type	Outputs and Type	Board Type	Supplied Contents	Main Purpose	Utilized IC / Part	Contents	Voltage - Input [Max]	Voltage - Input [Min]	Voltage - Output	Current - Output	Regulator Topology	Voltage - Output (Min/Fixed)	Mounting Type	Operating Temperature [Max]	Operating Temperature [Min]	Supplier Device Package	Synchronous Rectifier	Number of Outputs	Voltage - Input (Min) [Min]	Voltage - Output (Max) [Max]	Output Type	Voltage - Input (Max) [Max]	Function	Package / Case	Output Configuration	Topology	Frequency - Switching
Rohm Semiconductor BD9B300MUV-EVK-101	1	1 Non-Isolated Output Non-Isolated	Fully Populated	Board(s)	DC/DC Step Down	BD9B300	Board(s)	5.5 V	2.7 V	3.3 V	3 A	Buck
Rohm Semiconductor BD9B300MUV-E2											3 A		0.8 V	Surface Mount	85 C	-40 ¯C	VQFN016V3030		1	2.7 V	4.4 V	Adjustable	5.5 V	Step-Down	16-VFQFN Exposed Pad	Positive	Buck	1 MHz 2 MHz

Pricing

Prices provided here are for design reference only. For realtime values and availability, please visit the distributors directly

Distributor	Package	Quantity	$

Digikey	Cut Tape (CT)	1	$ 1.74
		10	$ 1.10
		25	$ 0.94
		100	$ 0.75
		250	$ 0.65
		500	$ 0.60
		1000	$ 0.55
	Digi-Reel®	1	$ 1.74
		10	$ 1.10
		25	$ 0.94
		100	$ 0.75
		250	$ 0.65
		500	$ 0.60
		1000	$ 0.55
	N/A	3142	$ 0.98
	Tape & Reel (TR)	3000	$ 0.34
Newark	Each	1	$ 1.67
		10	$ 0.96
		100	$ 0.79
		500	$ 0.75
		1000	$ 0.71
		2500	$ 0.67
		5000	$ 0.66

Description

General part information

BD9B300 Series

BD9B300MUV is a synchronous buck switching regulator with built-in low on-resistance power MOSFETs. This IC, which is capable of providing current up to 3A, features fast transient response by employing constant on-time control system. It offers high oscillating frequency at low inductance. With its original constant on-time control method which operates low consumption at light load, this product is ideal for equipment and devices that demand minimal standby power consumption.

Documents

Technical documentation and resources

BD9B300MUV-E2 Flammability

Thermal Resistance

BD9B300MUV-E2

Deep-Dive with AI

BD9B300MUV-E2

Deep-Dive with AI

Technical Specifications

BD9B300 Series

Pricing

Description

BD9B300 Series

Documents

BD9B300MUV-E2 Flammability

VQFN016V3030 Taping Spec

Factory Information

θ<sub>JC</sub> and Ψ<sub>JT</sub>

Thermal Resistance

What Is Thermal Design

PCB Layout for BD9B300MUV

Evaluation Board User's Guide for BD9B300MUV-E2EVK-101

Precautions When Measuring the Rear of the Package with a Thermocouple

Solder Joint Rate and Thermal Resistance of Exposed Pad

Considering Polarity of Power Inductor to Reduce Radiated Emission of DC-DC converter

Efficiency of Buck Converter

Measurement Method for Phase Margin with Frequency Response Analyzer (FRA)

Buck DC/DC Converter Recommended Inductor List

BD9B300MUV Data Sheet

Judgment Criteria of Thermal Evaluation

The Important Points of Multi-layer Ceramic Capacitor Used in Buck Converter circuit

Suppression Method of Switching Noise Using Linear Regulator and Low Pass Filter

Two-Resistor Model for Thermal Simulation

Capacitor Calculation for Buck converter IC

Five Steps for Successful Thermal Design of IC

Considering Input Filter to Reduce Conducted Emissions by DCDC Converter

Calculation of Power Dissipation in Switching Circuit

Compliance with the ELV directive

PCB Layout Essential Check sheet for Switching Regulator

Bootstrap Circuit in the Buck Converter

Evaluation Board User's Guide for BD9B300MUV-EVK-001

How to Use the Two-Resistor Model

Three Steps for Successful Design of DC-DC Converters

Inductor Calculation for Buck converter IC

Diode Selection Method for Asynchronous Converter

Precautions for PCB Layout Regarding Common Mode Filters

Basics of Thermal Resistance and Heat Dissipation

PCB Layout Thermal Design Guide

Resistor Value Table to set Output Voltage of Buck Converter IC

Heat Dissipation Effect of Thermal Via in Exposed Pad Type Package

PCB Layout Techniques of Buck Converter

Design Guide and Example of Stencil for Exposed Pad

Cutting-Edge Web Simulation Tool "ROHM Solution Simulator" Capable of Complete Circuit Verification of Power Devices and Driver ICs

BD9B300MUV Reference Circuits and Bomlist

How to Use the Thermal Resistance and Thermal Characteristics Parameters

θ<sub>JA</sub> and Ψ<sub>JT</sub>

Method for Determining Constants of Peripheral Parts of Buck DC/DC Converter

Calculation of Power Loss (Synchronous)

Power Supply Sequence Circuit with General Purpose Power Supply IC

Step-down DC-DC converter PCB layout EMC Design guide

Impedance Characteristics of Bypass Capacitor

Considerations for Power Inductors Used for Buck Converters

Method for Calculating Junction Temperature from Transient Thermal Resistance Data

Overview of ROHM's Simulation Models(for ICs and Discrete Semiconductors)

Anti-Whisker formation

Types of Capacitors Used for Output Smoothing of Switching Regulators and their Precautions

Snubber Circuit for Buck Converter IC

Phase Compensation Design for Current Mode Buck Converter

Product Change Notice EN

BD9B300 Series