TT Electronics/IRC

GQ8A031072GT

GQ8A031072GT Description

The GQ8A031072GT from TT Electronics/IRC is a high-performance 8-resistor thin-film network designed for precision applications. Encased in a ceramic QSOP package, it offers 10.7KΩ resistance per resistor with a tight 2% tolerance and a low ±25ppm/°C temperature coefficient, ensuring stability across a wide operating temperature range of -70°C to +125°C. The isolated (ISOL) circuit design provides independent resistors, making it suitable for complex circuit configurations. With a 0.75W (3/4W) total power rating and 100V maximum voltage rating, this 16-pin gull-wing SMD component is ideal for space-constrained, high-reliability designs.

GQ8A031072GT Features

• Precision Thin Film Technology: Delivers low noise and high accuracy (±25ppm/°C).
• Ceramic QSOP Package: Enhances thermal performance and durability in harsh environments.
• Isolated Resistor Network: 8 independent 10.7KΩ resistors (2% tolerance) for flexible circuit design.
• High Power Handling: 0.1W per resistor (0.75W total) with derating up to 125°C.
• Surface-Mount Gull Wing Terminals: 0.64mm pitch for compact PCB layouts.
• Robust Construction: ±0.1mm height/length tolerances ensure consistent mounting.
• Non-Automotive (PPAP No): Optimized for industrial, medical, and telecom applications.

GQ8A031072GT Applications

• Signal Conditioning: Precision voltage dividers in instrumentation and sensor interfaces.
• Medical Electronics: Stable resistance networks in diagnostic equipment.
• Telecom Infrastructure: High-frequency analog circuits requiring low TCR drift.
• Industrial Control Systems: Isolated feedback networks in power supplies and motor drives.
• Aerospace & Defense: Reliable performance in extreme-temperature environments.

Conclusion of GQ8A031072GT

The GQ8A031072GT excels in precision, thermal stability, and compactness, making it a superior choice for high-reliability applications where resistor isolation and low TCR are critical. Its ceramic QSOP package and thin-film technology provide advantages over polymer-based networks, particularly in high-temperature or high-voltage scenarios. While not RoHS-compliant, it remains a top-tier solution for industrial, medical, and telecom designs demanding uncompromising performance.