TT Electronics/IRC

GS7B011301GFT

GS7B011301GFT Description

The GS7B011301GFT from TT Electronics/IRC is a high-performance ceramic resistor network designed for precision applications. This 14-pin narrow SOIC device features 13 bussed resistors with a 1.3KΩ resistance value and a tight ±2% absolute tolerance (±1% ratio tolerance). Built with thin-film technology, it offers excellent stability with a ±100ppm/°C temperature coefficient. The SOIC package ensures compact surface-mount integration, with dimensions of 8.66mm (L) × 5.99mm (D) × 1.45mm (H) and gull-wing terminations for reliable PCB connections. Rated for 0.05W per resistor (0.7W total), it operates across a 70°C to 125°C derated range, with a 100V maximum voltage rating.

GS7B011301GFT Features

• Bussed Network Design: Simplifies circuit layout with shared connections.
• High Power Density: 0.7W total power rating in a compact SOIC footprint.
• Stable Performance: ±100ppm/°C TCR ensures minimal resistance drift.
• Precision Tolerance: ±2% absolute (±1% ratio) for matched performance.
• Robust Construction: Ceramic case enhances thermal and mechanical durability.
• Automation-Friendly: Gull-wing leads and 1.27mm pitch enable high-speed PCB assembly.
• Wide Voltage Range: Supports up to 100V, ideal for industrial and instrumentation use.

GS7B011301GFT Applications

• Voltage Divider Networks: Precision signal conditioning in sensor interfaces.
• Industrial Control Systems: Reliable performance in harsh environments (e.g., PLCs, motor drives).
• Test & Measurement Equipment: Stable resistance for calibration circuits.
• Power Management: Current limiting and load sharing in compact power supplies.
• Automotive Electronics: Non-automotive grade but suitable for benign-environment prototypes.

Conclusion of GS7B011301GFT

The GS7B011301GFT excels in space-constrained, precision circuits requiring low drift and high power density. Its ceramic construction and thin-film technology provide superior reliability over polymer-based networks, while the bussed design reduces component count. Though not PPAP or automotive-qualified, it is ideal for industrial, medical, and instrumentation applications demanding tight tolerances and thermal stability. A cost-effective solution for engineers prioritizing performance, compactness, and repeatability.