TT Electronics/IRC

GQ8B013320FBT

GQ8B013320FBT Description

The GQ8B013320FBT from TT Electronics/IRC is a high-precision thin-film resistor network designed for demanding surface-mount applications. This 16-pin QSOP package integrates 15 resistors with a uniform 332Ω resistance, offering 1% tolerance and a ±100ppm/°C temperature coefficient for stable performance across a wide -70°C to +125°C range. Encased in a ceramic substrate, it delivers superior thermal stability and durability, with a 0.75W (3/4W) total power rating (0.05W per resistor). Its gull-wing termination ensures reliable solder joints, while the 100V maximum voltage rating makes it suitable for high-voltage circuits.

GQ8B013320FBT Features

• Precision Engineering: Thin-film technology ensures low noise and high accuracy (±1% tolerance).
• Robust Construction: Ceramic case enhances thermal dissipation and mechanical strength.
• Space-Efficient: Compact 4.9mm × 6.02mm × 1.47mm footprint ideal for dense PCB layouts.
• Wide Operating Range: Derated power capability up to 125°C for harsh environments.
• Automated Assembly Friendly: 0.64mm terminal pitch and gull-wing leads optimize pick-and-place efficiency.
• Non-Automotive: Not PPAP-capable, but excels in industrial and telecom applications.

GQ8B013320FBT Applications

This resistor network is ideal for:

• Voltage Division Circuits: Precision dividers in test equipment or sensor interfaces.
• Signal Conditioning: Buffering and impedance matching in data acquisition systems.
• Power Management: Current-limiting networks in power supplies or LED drivers.
• Industrial Controls: Robust performance in PLCs, motor drives, and instrumentation.
• Telecom Infrastructure: Stable operation in base stations and RF modules.

Conclusion of GQ8B013320FBT

The GQ8B013320FBT stands out for its combination of precision, power handling, and compact design, making it a versatile choice for engineers prioritizing reliability in space-constrained, high-temperature environments. While not RoHS-compliant, its ceramic construction and thin-film technology offer superior performance over polymer-based alternatives. Ideal for industrial and telecom systems requiring stable, low-drift resistance networks.