TT Electronics/IRC

GS7B013832FFT

GS7B013832FFT Description

The GS7B013832FFT from TT Electronics/IRC is a high-precision ceramic resistor network designed for demanding electronic applications. Housed in a 14-pin narrow SOIC package, this bussed network integrates 13 thin-film resistors, each with a 38.3KΩ resistance and a tight ±1% absolute tolerance. The device operates over a wide temperature range of -70°C to +125°C, with a derated power capability up to 125°C, ensuring reliability in harsh environments. Its ±100ppm/°C temperature coefficient and 100V maximum voltage rating make it suitable for precision circuits requiring stable performance under thermal stress. The SOIC-C series construction features a compact rectangular ceramic case (8.66mm x 5.99mm x 1.45mm) with gull-wing terminations for robust surface-mount assembly.

GS7B013832FFT Features

• 13 bussed resistors in a 14-pin SOIC package, optimized for space-constrained designs.
• Thin-film technology delivers high accuracy (±1% tolerance) and low TCR (±100ppm/°C).
• Ceramic substrate enhances thermal stability and power dissipation (0.7W total, 0.05W per resistor).
• Wide operating range: -70°C to +125°C, derated to 125°C for sustained performance.
• 100V maximum voltage rating and 1.27mm terminal pitch for high-density PCB layouts.
• Non-automotive and non-PPAP compliant, ideal for industrial and instrumentation use.
• Tube packaging ensures safe handling and storage.

GS7B013832FFT Applications

This resistor network excels in precision analog and digital systems, including:

• Voltage dividers and pull-up networks in sensor interfaces.
• Signal conditioning circuits for ADCs/DACs, where ratio tolerance (±1%) is critical.
• Industrial control systems requiring stable resistance under thermal cycling.
• Medical electronics leveraging its ceramic-based reliability and low drift.
• Test and measurement equipment demanding repeatable performance.

Conclusion of GS7B013832FFT

The GS7B013832FFT stands out for its ceramic-based durability, thin-film precision, and bussed topology, making it a superior choice over polymer-based networks in high-temperature or precision-critical applications. While not RoHS-compliant, its robust construction and tight tolerances cater to specialized industrial, medical, and instrumentation needs where performance outweighs regulatory constraints. Engineers will appreciate its balance of compactness, thermal resilience, and electrical consistency in complex circuit designs.