TT Electronics/IRC

GS4B036652BT

GS4B036652BT Description

The GS4B036652BT from TT Electronics/IRC is a high-precision 7-resistor bussed network in an 8-pin narrow SOIC package, designed for demanding surface-mount applications. This ceramic-based thin-film resistor network offers an exceptional ±0.1% tolerance and a low ±25ppm/°C temperature coefficient, ensuring stability across a wide operating range of -70°C to +125°C. With a 66.5KΩ resistance value per element and a 0.4W total power rating, it is engineered for precision analog and digital circuits where minimal drift and high accuracy are critical. The SOIC-C series construction provides robust mechanical integrity, while the gull-wing termination ensures reliable solderability in automated assembly processes.

GS4B036652BT Features

• Ultra-Precise Tolerance: ±0.1% absolute tolerance for critical signal conditioning.
• Low TCR: ±25ppm/°C ensures minimal resistance drift under thermal stress.
• High Power Handling: 0.4W total (0.05W per resistor) with derating up to 125°C.
• Bussed Network Design: Simplifies PCB layout in voltage divider or bus termination applications.
• Robust Construction: Ceramic substrate with thin-film technology for long-term reliability.
• Automation-Friendly: Gull-wing leads and SOIC package compatible with pick-and-place systems.
• Wide Voltage Rating: Supports up to 100V, suitable for industrial and instrumentation use.

GS4B036652BT Applications

• Precision Analog Circuits: Voltage dividers, feedback networks, and sensor interfaces.
• Industrial Controls: PLCs, motor drives, and power management systems requiring stable resistance.
• Test & Measurement Equipment: Calibration tools and high-accuracy signal processing.
• Medical Electronics: Patient monitoring devices where consistency is paramount.
• Automotive (Non-Automotive Rated): Prototyping or non-safety-critical automotive subsystems.

Conclusion of GS4B036652BT

The GS4B036652BT stands out for its combination of precision, thermal stability, and compact SOIC footprint, making it ideal for space-constrained, high-reliability designs. While not PPAP or automotive-qualified, its ceramic thin-film construction and tight tolerances make it superior to standard thick-film networks in environments with fluctuating temperatures or stringent accuracy requirements. Engineers will benefit from its ease of integration and consistent performance in precision electronics.