TT Electronics/IRC

GS8B019531BBT

GS8B019531BBT Description

The GS8B019531BBT from TT Electronics/IRC is a high-precision ceramic resistor network designed for demanding electronic applications. This 16-pin narrow SOIC device features 15 bussed resistors with a 9.53KΩ resistance value, offering an absolute tolerance of ±0.1% and a ratio tolerance of ±0.1%. Built with thin-film technology, it ensures excellent stability and low noise, making it ideal for precision circuits. The SOIC package (9.91mm x 5.99mm x 1.45mm) with gull-wing termination provides reliable surface-mount compatibility. Rated for 100V maximum voltage and 0.8W total power dissipation, it operates within a temperature range of -70°C to +125°C, with a ±100ppm/°C temperature coefficient.

GS8B019531BBT Features

• High Precision: ±0.1% tolerance ensures accurate signal conditioning.
• Robust Construction: Ceramic case enhances thermal and mechanical stability.
• Bussed Network: Simplifies circuit design with shared connections.
• Wide Temperature Range: Reliable performance from -70°C to +125°C.
• Thin-Film Technology: Delivers low noise and high stability.
• Surface-Mount Ready: Gull-wing terminals and 1.27mm pitch for easy PCB integration.
• Power Efficiency: 0.05W per resistor (1/20W) with 0.8W total rating.

GS8B019531BBT Applications

This resistor network excels in:

• Precision Analog Circuits: Voltage dividers, feedback networks.
• Industrial Control Systems: Signal conditioning, sensor interfaces.
• Test & Measurement Equipment: Calibration, reference circuits.
• Medical Electronics: High-reliability instrumentation.
• Automotive (Non-Automotive Rated): Prototyping or non-safety-critical systems.

Conclusion of GS8B019531BBT

The GS8B019531BBT stands out for its exceptional accuracy, thermal resilience, and compact SOIC footprint. While not PPAP or automotive-qualified, its thin-film ceramic design and tight tolerances make it a top choice for precision applications. Engineers will appreciate its ease of integration and consistent performance in harsh environments. For high-reliability networks requiring minimal drift and superior stability, this model is a compelling solution.