TT Electronics/IRC

GS7B023322FCT

GS7B023322FCT Description

The GS7B023322FCT from TT Electronics/IRC is a high-precision ceramic resistor network designed for demanding electronic applications. This 14-pin Narrow SOIC device features 13 bussed resistors with a 33.2KΩ resistance value, offering an absolute tolerance of ±1% and a ratio tolerance of ±0.25%. Built with thin-film technology, it ensures stable performance across a wide temperature range (70°C to 125°C) and exhibits a low temperature coefficient of ±50ppm/°C. The SOIC package (8.66mm x 5.99mm x 1.45mm) with gull-wing terminations facilitates easy surface-mount assembly, making it ideal for compact PCB designs.

GS7B023322FCT Features

• High Precision: ±1% absolute tolerance and ±0.25% ratio tolerance for critical signal conditioning.
• Robust Construction: Ceramic case ensures durability and thermal stability.
• Low TCR: ±50ppm/°C minimizes resistance drift under temperature fluctuations.
• Power Handling: 0.05W per resistor (0.7W total) with a 100V maximum voltage rating.
• Automation-Friendly: Gull-wing terminations and 1.27mm pitch for reliable SMT placement.
• Non-Automotive/Non-PPAP: Suitable for industrial and commercial applications.

GS7B023322FCT Applications

This resistor network excels in:

• Precision analog circuits requiring tight tolerance matching (e.g., instrumentation amplifiers).
• Voltage dividers and sensor interfaces where ratio stability is critical.
• Medical and test equipment demanding low drift over temperature.
• Communication systems (RF modules, filters) benefiting from its thin-film accuracy.
• Industrial control PCBs needing compact, high-density resistor arrays.

Conclusion of GS7B023322FCT

The GS7B023322FCT stands out for its ceramic-based reliability, exceptional tolerance precision, and thermal performance, making it a superior choice for precision electronics. While not PPAP-qualified, its thin-film technology and SOIC footprint cater to high-reliability industrial designs. Engineers seeking stable, space-saving resistor networks for signal processing or conditioning will find this model optimally balanced for performance and cost.