TT Electronics/IRC

GS7B015230GFT

GS7B015230GFT Description

The GS7B015230GFT from TT Electronics/IRC is a high-performance ceramic resistor network designed for precision applications in demanding environments. This 14-pin narrow SOIC package features 13 bussed resistors with a 523Ω resistance value and a tight ±2% absolute tolerance, ensuring reliable signal integrity. Built with thin-film technology, it offers excellent stability with a ±100ppm/°C temperature coefficient, making it suitable for temperature-sensitive circuits. The device operates within a -70°C to +125°C range and delivers a 0.7W total power rating (0.05W per resistor). Its 100V maximum voltage rating and gull-wing termination enable robust surface-mount assembly in compact PCB designs.

GS7B015230GFT Features

• Ceramic substrate for enhanced thermal and mechanical durability.
• Bussed network topology simplifies circuit design for shared voltage/current paths.
• Low TCR (±100ppm/°C) ensures minimal resistance drift across temperature fluctuations.
• High power density (0.7W total) in a compact 8.66mm × 5.99mm × 1.45mm SOIC package.
• Precision tolerance (±2% absolute, ±1% ratio) for matched performance in differential circuits.
• RoHS non-compliant (contains lead), ideal for legacy or high-reliability systems.

GS7B015230GFT Applications

This resistor network excels in:

• Analog signal conditioning (e.g., voltage dividers, sensor interfaces).
• Industrial control systems requiring stable, high-temperature operation.
• Power management circuits where bussed resistors reduce component count.
• Test & measurement equipment demanding tight tolerance and low drift.
• Aerospace/defense electronics due to ceramic robustness and wide temperature range.

Conclusion of GS7B015230GFT

The GS7B015230GFT stands out for its ceramic construction, precision tolerances, and bussed architecture, offering engineers a reliable solution for space-constrained, high-performance designs. While not automotive-grade or PPAP-capable, its thin-film stability and SOIC footprint make it ideal for industrial, instrumentation, and legacy systems. For applications prioritizing thermal resilience and signal accuracy, this network delivers superior performance over standard epoxy-based arrays.