Transistors - Bipolar (BJT)

Transistors - Bipolar (BJT) - Arrays

Image	Part Number	Description / PDF	Quantity	Rfq
	XP0160100L Panasonic	TRANS NPN/PNP 50V 0.1A SMINI5	0
	XN0640100L Panasonic	TRANS 2PNP 50V 0.1A MINI6	0
	XP0555400L Panasonic	TRANS 2NPN 40V 0.1A SMINI6	0
	XP0460100L Panasonic	TRANS NPN/PNP 50V 0.1A SMINI6	0
	DMC206010R Panasonic	TRANS 2NPN 50V 0.1A MINI6	0
	DMC204B30R Panasonic	TRANS 2NPN 50V/20V MINI6	0
	XN0440100L Panasonic	TRANS 2PNP 50V 0.1A MINI6	0
	XP0550100L Panasonic	TRANS 2NPN 50V 0.1A SMINI6	0
	DMG904010R Panasonic	TRANS NPN/PNP 50V 0.1A SSMINI6	0
	XN0B30100L Panasonic	TRANS NPN/PNP DARL 50V MINI5	0
	XN0560100L Panasonic	TRANS NPN/PNP 50V 0.1A MINI6	0
	XN0654300L Panasonic	TRANS 2NPN 10V 0.065A MINI6	0
	UP0450100L Panasonic	TRANS 2NPN 50V 0.1A SSMINI6	0
	XN0440400L Panasonic	TRANS 2PNP 10V 0.5A MINI6	0
	DMA202010R Panasonic	TRANS 2PNP 50V 0.1A MINI5	0
	DME20C010R Panasonic	TRANS NPN/PNP DARL 50V MINI5	0
	XP0440100L Panasonic	TRANS 2PNP 50V 0.1A SMINI6	0
	XN0153100L Panasonic	TRANS 2NPN 10V 0.05A MINI5	0
	XN0150400L Panasonic	TRANS 2NPN 20V 0.3A MINI5	0
	DMC201010R Panasonic	TRANS 2NPN 50V 0.1A MINI5	0

Transistors - Bipolar (BJT) - Arrays

1. Overview

Bipolar Junction Transistor (BJT) Arrays are integrated packages containing multiple discrete BJTs on a single semiconductor substrate. They share common thermal and electrical characteristics while maintaining individual transistor functionality. These arrays are critical in analog and digital circuits for amplification, switching, and signal processing. Their importance in modern electronics stems from reduced PCB space requirements, improved reliability, and matched transistor parameters in high-precision applications.

2. Main Types and Functional Classification

Type	Functional Features	Application Examples
Single Arrays	Independent BJTs in one package	General-purpose amplifiers
Darlington Arrays	High current gain through cascaded pairs	Power amplifiers, motor drivers
Complementary Arrays	NPN+PNP transistor pairs	Push-pull amplifiers, H-bridges
High-Frequency Arrays	Optimized for RF/microwave performance	Radio transceivers, test equipment
Low-Noise Arrays	Matched transistors for noise cancellation	Medical imaging sensors

3. Structure and Composition

BJT arrays typically consist of:

Silicon epitaxial layers forming individual transistor cells
Common substrate with thermal coupling for matched performance
Metal interconnects for input/output terminals
Polymer encapsulation (e.g., SOIC, DIP, or SOT packages)

Advanced designs use dielectric isolation to minimize cross-talk between elements. Chip-level wire bonding connects transistor terminals to external leads.

4. Key Technical Specifications

Parameter	Description	Importance
Current Gain (hFE)	Amplification factor per transistor	Determines signal amplification capability
Max Operating Voltage	Breakdown voltage rating	Defines safe operating limits
Transition Frequency (fT)	Frequency response limit	Critical for high-speed applications
Power Dissipation	Thermal handling capacity	Affects reliability and derating
Collector Saturation Voltage	Voltage drop in on-state	Impacts efficiency in switching
Noise Figure	Signal-to-noise degradation	Essential for low-noise designs

5. Application Fields

Key industries include:

Telecommunications: RF power amplifiers, optical transceivers
Industrial Automation: Motor controllers, PLC systems
Consumer Electronics: Audio amplifiers, DC-DC converters
Automotive: Engine control units (ECUs), LED drivers
Medical: Diagnostic imaging detectors, patient monitoring

Case Example: ULN2003 Darlington array used in 7-channel relay drivers for industrial control systems.

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Specifications
TI (Texas Instruments)	ULN2003A	7x 500mA Darlington pairs, 50V rating
ON Semiconductor	MCZ33900	High-side switch array for automotive
Infineon Technologies	BTS724GX	Smart power array with diagnostics
STMicroelectronics	VND5N07-E	High-voltage industrial switch array
Rohm Semiconductor	BD68470EFV	Low-saturation complementary array

7. Selection Guidelines

Key considerations:

Match voltage/current ratings to application requirements
Verify frequency response for high-speed operations
Evaluate thermal resistance for power applications
Assess transistor matching (critical for differential pairs)
Consider package compatibility with PCB design
Analyze cost/performance trade-offs (e.g., integrated vs discrete)

8. Industry Trends

Future development focuses on:

Miniaturization: 3D packaging and chip-scale arrays
High-frequency capabilities beyond 100GHz for 6G applications
Improved thermal management through advanced substrates
Integration with CMOS drivers in smart power arrays
Wide bandgap materials (SiC/GaN) for high-power arrays
Environmental compliance: Lead-free packaging and RoHS adherence