Specification	DTA123TCAT116

Current - Collector (Ic) (Max) [Max]	100 mA
Current - Collector Cutoff (Max) [Max]	500 nA
DC Current Gain (hFE) (Min) @ Ic, Vce [Min]	100
Frequency - Transition	250 MHz
Mounting Type	Surface Mount
Package / Case	SOT-23-3, TO-236-3, SC-59
Power - Max [Max]	200 mW
Resistor - Base (R1)	2.2 kOhm
Supplier Device Package	SST3
Transistor Type	PNP - Pre-Biased
Vce Saturation (Max) @ Ib, Ic	300 mV
Voltage - Collector Emitter Breakdown (Max) [Max]	50 V

DTA123 Series

PNP, SOT-416, R1=R2 Potential Divider Type Digital Transistor (Bias Resistor Built-in Transistor) for automotive

Part	Package / Case	Transistor Type	Resistor - Base (R1)	Current - Collector (Ic) (Max) [Max]	Resistors Included	Supplier Device Package	Resistor - Emitter Base (R2)	Voltage - Collector Emitter Breakdown (Max) [Max]	Frequency - Transition	Mounting Type	DC Current Gain (hFE) (Min) @ Ic, Vce [Min]	Current - Collector Cutoff (Max) [Max]	Power - Max [Max]	Vce Saturation (Max) @ Ib, Ic	Qualification	Grade
Rohm Semiconductor DTA123JKAT146	SC-59 SOT-23-3 TO-236-3	PNP - Pre-Biased	2.2 kOhm	100 mA	R1 R2	SMT3	47 kOhms	50 V	250 MHz	Surface Mount	80	500 nA	200 mW	300 mV
Rohm Semiconductor DTA123JU3HZGT106	SC-70 SOT-323	PNP - Pre-Biased	2.2 kOhm	100 mA		UMT3	47 kOhms	50 V	250 MHz	Surface Mount	80	500 nA	200 mW	300 mV	AEC-Q101	Automotive
Rohm Semiconductor DTA123TCAT116	SC-59 SOT-23-3 TO-236-3	PNP - Pre-Biased	2.2 kOhm	100 mA		SST3		50 V	250 MHz	Surface Mount	100	500 nA	200 mW	300 mV
Rohm Semiconductor DTA123YE3HZGTL	SC-75 SOT-416	PNP - Pre-Biased	2.2 kOhm	100 mA		EMT3	10 kOhms	50 V	250 MHz	Surface Mount	33	500 nA	150 mW	300 mV	AEC-Q101	Automotive
Rohm Semiconductor DTA123JETL	SC-75 SOT-416	PNP - Pre-Biased	2.2 kOhm	100 mA		EMT3	47 kOhms	50 V	250 MHz	Surface Mount	80	500 nA	150 mW	300 mV
Rohm Semiconductor DTA123EMT2L	SOT-723	PNP - Pre-Biased	2.2 kOhm	100 mA		VMT3	2.2 kOhms	50 V	250 MHz	Surface Mount		500 nA	150 mW	300 mV
Rohm Semiconductor DTA123ECAHZGT116	SC-59 SOT-23-3 TO-236-3	PNP - Pre-Biased	2.2 kOhm	100 mA		SST3	2.2 kOhms	50 V	250 MHz	Surface Mount	20	500 nA	200 mW	300 mV	AEC-Q101	Automotive
Rohm Semiconductor DTA123EEFRATL	SC-75 SOT-416	PNP - Pre-Biased	2.2 kOhm	100 mA		EMT3	2.2 kOhms		250 MHz	Surface Mount	20		150 mW	300 mV	AEC-Q101	Automotive
Rohm Semiconductor DTA123YU3HZGT106	SC-70 SOT-323	PNP - Pre-Biased	2.2 kOhm	100 mA		UMT3	10 kOhms	50 V	250 MHz	Surface Mount	33	500 nA	200 mW	300 mV	AEC-Q101	Automotive
Rohm Semiconductor DTA123JU3T106	SC-70 SOT-323	PNP - Pre-Biased	2.2 kOhm	100 mA		UMT3	47 kOhms		250 MHz	Surface Mount	80		200 mW	300 mV

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	$ 0.33
	Digi-Reel®	1	$ 0.33
	Tape & Reel (TR)	3000	$ 0.04
		6000	$ 0.03
		9000	$ 0.03
		15000	$ 0.03
		21000	$ 0.03
		30000	$ 0.02
		75000	$ 0.02
		150000	$ 0.02
		300000	$ 0.02

Description

General part information

DTA123 Series

DTA123YU3HZG is an digital transistor (Resistor built-in type transistor). Built-in bias resistors enable the configuration of an inverter circuit without connecting external input resistors. This is a high-reliability product of automotive grade qualified to AEC-Q101.

Documents

Technical documentation and resources

Method for Calculating Junction Temperature from Transient Thermal Resistance Data

Thermal Design

Notes for Calculating Power Consumption:Static Operation

Thermal Design

Calculation of Power Dissipation in Switching Circuit

Schematic Design & Verification

How to Use LTspice® Models

Schematic Design & Verification

DTA123TCA Data Sheet

Data Sheet

Moisture Sensitivity Level - Transistors

Package Information

Basics of Thermal Resistance and Heat Dissipation

Thermal Design

Temperature derating method for Safe Operating Area (SOA)

Schematic Design & Verification

Taping Information

Package Information

Measurement Method and Usage of Thermal Resistance RthJC

Thermal Design

DTA123TCAT116

Deep-Dive with AI

DTA123TCAT116

Deep-Dive with AI

Technical Specifications

DTA123 Series

Pricing

Description

DTA123 Series

Documents

Importance of Probe Calibration When Measuring Power: Deskew

PCB Layout Thermal Design Guide

Notes for Temperature Measurement Using Thermocouples

Impedance Characteristics of Bypass Capacitor

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

Types and Features of Transistors

Explanation for Marking

Compliance of the RoHS directive

Notes for Temperature Measurement Using Forward Voltage of PN Junction

Certificate of not containing SVHC under REACH Regulation

Two-Resistor Model for Thermal Simulation

Anti-Whisker formation - Transistors

What Is Thermal Design

Precautions When Measuring the Rear of the Package with a Thermocouple

Part Explanation

Package Dimensions

About Flammability of Materials

About Export Regulations

List of Transistor Package Thermal Resistance

What is a Thermal Model? (Transistor)

Condition of Soldering / Land Pattern Reference

How to Use LTspice&reg; Models: Tips for Improving Convergence

Reliability Test Result

Method for Monitoring Switching Waveform

Method for Calculating Junction Temperature from Transient Thermal Resistance Data

Notes for Calculating Power Consumption:Static Operation

Calculation of Power Dissipation in Switching Circuit

How to Use LTspice&reg; Models

DTA123TCA Data Sheet

Moisture Sensitivity Level - Transistors

Basics of Thermal Resistance and Heat Dissipation

Temperature derating method for Safe Operating Area (SOA)

Taping Information

Measurement Method and Usage of Thermal Resistance RthJC

DTA123 Series

How to Use LTspice® Models: Tips for Improving Convergence

How to Use LTspice® Models