TT Electronics/IRC

GS4B034641JDT

GS4B034641JDT Description

The GS4B034641JDT from TT Electronics/IRC is a high-performance 7-resistor bussed network in an 8-pin narrow SOIC package, designed for precision applications requiring stable thin-film resistance. With a 4.64KΩ resistance value and ±5% absolute tolerance, this ceramic-based network ensures reliable performance in demanding environments. Its ±25ppm/°C temperature coefficient and 0.05W (1/20) power rating per resistor make it ideal for circuits where thermal stability and low power dissipation are critical. The SOIC-C series construction offers robust mechanical integrity, while the gull-wing termination facilitates easy surface-mount assembly.

GS4B034641JDT Features

• Ceramic substrate for enhanced thermal and mechanical stability.
• Thin-film technology ensures low noise and high precision (±0.5% ratio tolerance).
• Bussed circuit design simplifies PCB layout for common voltage distribution.
• Wide operating range: -70°C to +125°C with derated power up to 125°C.
• Compact dimensions: 4.9mm (L) × 5.99mm (D) × 1.45mm (H) with tight tolerances (±0.1mm height/length).
• 100V maximum voltage rating and 0.4W total power rating for robust performance.
• Non-automotive and non-PPAP compliant, suited for industrial and commercial use.

GS4B034641JDT Applications

This resistor network excels in:

• Voltage divider circuits requiring precise ratio matching (±0.5%).
• Signal conditioning in instrumentation and sensor interfaces.
• Power supply bus termination for stable voltage distribution.
• Embedded systems where space-efficient, high-density PCBs are critical.
• Medical and test equipment demanding low TCR and long-term reliability.

Conclusion of GS4B034641JDT

The GS4B034641JDT combines precision, durability, and compact design, making it a standout choice for engineers needing reliable resistor networks in industrial and commercial electronics. Its ceramic construction, tight tolerances, and bussed architecture offer superior performance over generic arrays, particularly in thermally variable or space-constrained applications. While not RoHS-compliant, its thin-film stability and low TCR ensure consistent operation in critical circuits.