TT Electronics/IRC

GS8B011622FDT

GS8B011622FDT Description

The GS8B011622FDT from TT Electronics/IRC is a high-performance ceramic resistor network designed for precision applications in demanding electronic circuits. This 16-pin Narrow SOIC device features 15 bussed resistors with a 16.2KΩ resistance value, offering an absolute tolerance of ±1% and a ratio tolerance of ±0.5%. Built with thin-film technology, it ensures stable performance across a wide temperature range (70°C to 125°C) and delivers a power rating of 0.8W (0.05W per resistor). The SOIC package with gull-wing termination facilitates easy surface-mount assembly, while its compact dimensions (9.91mm x 5.99mm x 1.45mm) make it ideal for space-constrained designs.

GS8B011622FDT Features

• Ceramic case style for enhanced thermal stability and durability.
• ±100ppm/°C temperature coefficient ensures minimal resistance drift.
• Bussed circuit design simplifies routing in bus-oriented applications.
• 1.27mm terminal pitch for compatibility with standard PCB layouts.
• 100V maximum voltage rating for robust operation in high-voltage circuits.
• Non-compliant with EU RoHS, suitable for non-regulated industrial uses.
• Unconfirmed part status; verify suitability for critical applications.

GS8B011622FDT Applications

This resistor network excels in:

• Analog signal conditioning and voltage division in measurement systems.
• Bus termination for digital communication interfaces (e.g., I²C, SPI).
• Industrial control systems requiring stable, high-precision resistance.
• Power management circuits where derated power handling (up to 125°C) is critical.
• Automotive test environments (though not PPAP/automotive-qualified).

Conclusion of GS8B011622FDT

The GS8B011622FDT stands out for its precision, compact form factor, and robust ceramic construction, making it a reliable choice for industrial and instrumentation applications. While not RoHS-compliant, its thin-film technology and tight tolerances provide superior performance over standard thick-film networks. Engineers should evaluate its unconfirmed status for mission-critical designs but can leverage its high power density and thermal resilience in prototyping or non-regulated systems.