TT Electronics/IRC

GS8B025110FDT

GS8B025110FDT Description

The GS8B025110FDT from TT Electronics/IRC is a high-performance ceramic resistor network designed for precision applications in demanding electronic circuits. Housed in a 16-pin narrow SOIC package, this bussed network integrates 15 resistors with a common 511Ω resistance value, offering ±1% absolute tolerance and ±0.5% ratio tolerance. Its thin-film technology ensures stable performance with a low ±50ppm/°C temperature coefficient, making it ideal for environments requiring tight resistance matching and thermal stability. The device operates over a wide temperature range of -55°C to +125°C (derated up to 125°C) and supports a maximum voltage rating of 100V. With a power rating of 0.8W (0.05W per resistor), it balances compactness and reliability in surface-mount designs.

GS8B025110FDT Features

• Ceramic Construction: Enhances thermal durability and mechanical strength.
• Precision Tolerance: ±1% absolute, ±0.5% ratio tolerance for matched resistance networks.
• Stable Performance: ±50ppm/°C TCR ensures minimal drift across temperatures.
• High-Density Integration: 15 resistors in a 9.91mm × 5.99mm SOIC package.
• Robust Termination: Gull-wing leads for reliable surface-mount soldering.
• Wide Operating Range: -55°C to +125°C with derated power up to 125°C.
• Low-Power Efficiency: 0.05W per resistor (0.8W total) suits energy-sensitive designs.

GS8B025110FDT Applications

• Analog Signal Conditioning: Precision voltage dividers in sensor interfaces.
• Industrial Control Systems: Stable resistance networks for PLCs and motor drives.
• Medical Electronics: High-reliability circuits in diagnostic equipment.
• Automotive Subsystems (non-AECQ): Non-safety-critical bus networks.
• Test & Measurement: Calibration circuits requiring tight tolerance matching.

Conclusion of GS8B025110FDT

The GS8B025110FDT excels in applications demanding precision, thermal stability, and compact integration. Its ceramic substrate, thin-film technology, and tight tolerances make it superior to standard thick-film networks, particularly in high-temperature or precision-analog environments. While not PPAP or automotive-qualified, it is a cost-effective solution for industrial, medical, and instrumentation designs where reliability and performance are critical.