TT Electronics/IRC

GS7B022052CCT

GS7B022052CCT Description

The GS7B022052CCT 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 (BUS) configuration device integrates 13 thin-film resistors, each with a 20.5KΩ resistance and an exceptional ±0.25% absolute tolerance. Its ±50ppm/°C temperature coefficient ensures stability across a wide operating range of -70°C to +125°C, making it suitable for environments with thermal fluctuations. The SOIC-C series construction features a rectangular ceramic case with gull-wing terminations, optimized for surface-mount (SMD) assembly. With a 0.7W total power rating (0.05W per resistor) and 100V maximum voltage rating, it balances performance and reliability in compact designs.

GS7B022052CCT Features

• Precision Tolerance: ±0.25% absolute and ratio tolerance for critical signal conditioning.
• Robust Construction: Ceramic substrate enhances thermal dissipation and mechanical durability.
• Wide Temperature Range: Derated power operation up to 125°C for harsh environments.
• Thin-Film Technology: Delivers low noise and high stability compared to thick-film alternatives.
• Compact SOIC Package: 8.66mm × 5.99mm × 1.45mm dimensions with ±0.1mm length/height tolerances for high-density PCBs.
• Automated Assembly Friendly: 1.27mm terminal pitch and gull-wing leads simplify pick-and-place processes.

GS7B022052CCT Applications

Ideal for precision analog circuits, this resistor network excels in:

• Industrial Control Systems: Voltage dividers, feedback loops in PLCs.
• Medical Electronics: Signal conditioning in diagnostic equipment.
• Telecommunications: Impedance matching in RF modules.
• Test & Measurement: Calibration circuits requiring tight tolerance.
• Aerospace & Defense: Avionics where temperature stability is critical.

Conclusion of GS7B022052CCT

The GS7B022052CCT stands out for its ceramic-based reliability, precision tolerances, and broad thermal performance, making it a superior choice over polymer-based networks. While not RoHS-compliant, its thin-film technology and SOIC footprint cater to engineers prioritizing accuracy and space efficiency. Recommended for applications demanding long-term stability under thermal stress.