TT Electronics/IRC

GS7B021962JFT

GS7B021962JFT Description

The GS7B021962JFT from TT Electronics/IRC is a high-performance ceramic resistor network designed for precision applications in demanding electronic circuits. Housed in a 14-pin narrow SOIC package, this bussed (BUS) configuration integrates 13 thin-film resistors, each with a 19.6KΩ resistance and a ±5% absolute tolerance. The device operates over a wide temperature range of -55°C to +125°C, with a derated power range of 70°C to 125°C, ensuring reliability in thermally challenging environments. Its ±50ppm/°C temperature coefficient and ±1% ratio tolerance make it ideal for applications requiring stable resistance matching.

GS7B021962JFT Features

• Ceramic substrate for enhanced thermal stability and durability.
• Thin-film technology delivers low noise and high precision.
• Bussed network (BUS) simplifies circuit design by interconnecting resistors.
• 14-pin SOIC package with gull-wing leads for easy surface mounting.
• Power rating of 0.7W total (0.05W per resistor) and 100V maximum voltage rating.
• Tight dimensional tolerances: ±0.1mm (length/height), ±0.2mm (depth).
• Non-automotive (PPAP: No) and EU RoHS non-compliant, suited for industrial use.

GS7B021962JFT Applications

This resistor network excels in:

• Precision analog circuits requiring matched resistance values.
• Signal conditioning and voltage division in measurement equipment.
• Industrial control systems where thermal stability is critical.
• Embedded systems needing compact, high-density resistor arrays.
• Test & instrumentation applications demanding low TCR and tight ratio tolerances.

Conclusion of GS7B021962JFT

The GS7B021962JFT stands out for its ceramic construction, thin-film accuracy, and bussed topology, making it a robust choice for precision electronics. Its SOIC package and stable performance under thermal stress cater to industrial and instrumentation needs, though it is not suited for automotive or RoHS-compliant designs. Engineers will appreciate its ease of integration and consistent performance in critical circuits.