TT Electronics/IRC

GS8A0186R6DCT

GS8A0186R6DCT Description

The GS8A0186R6DCT from TT Electronics/IRC is a high-precision 8-resistor isolated network in a 16-pin narrow SOIC package, designed for demanding surface-mount applications. Featuring 86.6Ω resistance per element with an absolute tolerance of ±0.5% and ratio tolerance of ±0.25%, this thin-film ceramic network ensures exceptional stability and accuracy. Its ±100ppm/°C temperature coefficient and 0.1W power rating per resistor (0.8W total) make it suitable for environments with operating temperatures up to 125°C. The 100V maximum voltage rating and isolated circuit design enhance reliability in high-voltage or noise-sensitive circuits.

GS8A0186R6DCT Features

• Precision Thin Film Technology: Delivers low TCR (±100ppm/°C) and tight tolerances (±0.5%) for stable performance.
• Robust Ceramic Construction: SOIC-C series case ensures durability and thermal stability.
• Isolated Resistors: Independent elements reduce crosstalk, ideal for signal conditioning.
• High-Density Packaging: 16-pin SOIC (9.91mm × 5.99mm × 1.45mm) saves board space.
• Wide Temperature Range: Derated power operation from 70°C to 125°C.
• Gull Wing Termination: Facilitates reliable surface mounting with 1.27mm pitch.

GS8A0186R6DCT Applications

This resistor network excels in:

• Precision Analog Circuits: Voltage dividers, feedback networks, and sensor interfaces.
• Industrial Controls: PLCs, motor drives, and instrumentation requiring stable resistance.
• Medical Electronics: Patient monitoring systems with high noise immunity.
• Automotive (Non-Automotive Rated): Test equipment or prototyping where isolation is critical.
• Communication Systems: Signal attenuation and impedance matching in RF modules.

Conclusion of GS8A0186R6DCT

The GS8A0186R6DCT combines precision, isolation, and compactness, making it a standout choice for engineers needing reliable resistor networks in space-constrained, high-performance designs. Its ceramic substrate, thin-film technology, and tight tolerances outperform generic arrays in stability-critical applications. While not PPAP or automotive-qualified, it remains a cost-effective solution for industrial, medical, and communication systems demanding accuracy under thermal stress.