TT Electronics/IRC

GS7B037501FAT

GS7B037501FAT Description

The GS7B037501FAT from TT Electronics/IRC is a high-performance ceramic resistor network designed for precision applications. This 14-pin narrow SOIC device features 13 bussed resistors with a 7.5KΩ resistance value and an absolute tolerance of ±1%, ensuring consistent performance in demanding circuits. Its thin-film technology and ±25ppm/°C temperature coefficient provide excellent stability across a wide temperature range (70°C to 125°C). With a power rating of 0.7W (0.05W per resistor) and a maximum voltage rating of 100V, this network is ideal for compact, high-density designs. The SOIC package (8.66mm x 5.99mm x 1.45mm) offers robust mechanical protection and ease of surface-mount assembly.

GS7B037501FAT Features

• Bussed Network Design: Simplifies circuit layout with 13 interconnected resistors.
• High Precision: ±1% absolute tolerance and ±0.05% ratio tolerance for critical applications.
• Stable Performance: ±25ppm/°C TCR ensures minimal resistance drift.
• Robust Construction: Ceramic case enhances thermal and mechanical durability.
• Space-Efficient: SOIC package (14-pin) optimizes board space in dense layouts.
• Wide Operating Range: -55°C to +125°C with derated power up to 125°C.
• Gull Wing Termination: Facilitates reliable surface-mount soldering.

GS7B037501FAT Applications

This resistor network excels in:

• Analog Signal Conditioning: Precision voltage dividers and sensor interfaces.
• Industrial Control Systems: Stable performance in harsh environments.
• Medical Electronics: Reliable operation in diagnostic equipment.
• Automotive Electronics (non-AECQ): Non-safety-critical circuits like infotainment.
• Test & Measurement Equipment: High-accuracy calibration circuits.

Conclusion of GS7B037501FAT

The GS7B037501FAT combines precision, durability, and compact design, making it a superior choice for engineers requiring stable resistor networks in space-constrained applications. Its ceramic construction, tight tolerances, and bussed architecture offer distinct advantages over standard arrays, particularly in high-temperature or precision-critical systems. While not PPAP or automotive-grade, it remains a cost-effective solution for industrial and medical electronics.