TT Electronics/IRC

GS8A016981BT

GS8A016981BT Description

The GS8A016981BT from TT Electronics/IRC is a high-precision thin-film resistor network designed for demanding isolation and signal conditioning applications. Housed in a 16-pin SOIC ceramic package, it features 8 isolated resistors, each with a 6.98KΩ resistance and an ultra-tight 0.1% tolerance. The device operates over a wide temperature range (-70°C to +125°C) with a low ±100ppm/°C temperature coefficient, ensuring stability in harsh environments. Its 0.8W total power rating (0.1W per resistor) and 100V maximum voltage rating make it suitable for precision analog circuits. The gull-wing termination and surface-mount design facilitate automated assembly, while the ceramic case enhances thermal and mechanical reliability.

GS8A016981BT Features

• High Precision: 0.1% tolerance and ±100ppm/°C TCR for accurate signal processing.
• Robust Construction: Ceramic SOIC package ensures durability and thermal performance.
• Isolated Design: 8 independent resistors (ISOL configuration) prevent crosstalk.
• Wide Operating Range: -70°C to +125°C with derated power up to 125°C.
• Surface-Mount Ready: Gull-wing terminals (1.27mm pitch) for efficient PCB integration.
• Non-Automotive: Not PPAP-capable, ideal for industrial and instrumentation use.
• Non-RoHS: Contains materials exempt from EU RoHS compliance.

GS8A016981BT Applications

This resistor network excels in:

• Precision Analog Circuits: Voltage dividers, feedback networks, and DAC/ADC interfaces.
• Isolation Modules: Signal isolation in medical equipment or test/measurement systems.
• High-Temperature Environments: Industrial controls, aerospace, and power management.
• Legacy Systems: Where non-RoHS compliance is permissible.

Conclusion of GS8A016981BT

The GS8A016981BT combines high accuracy, isolation, and ruggedness in a compact SOIC package, making it a standout choice for precision electronics. Its ceramic construction and thin-film technology deliver superior performance over plastic-encapsulated alternatives, particularly in thermal and mechanical stress scenarios. While unsuitable for automotive applications, it is ideal for industrial, medical, and aerospace systems requiring stable, low-drift resistance networks. Engineers will appreciate its ease of integration and reliability in critical signal-path designs.