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Y1365V0195AA0R

Y1365V0195AA0R Description

The Y1365V0195AA0R from VPG Foil Resistors is a high-precision, surface-mount resistor network designed for demanding military applications. Part of the SMN series, this 4-resistor array features an ultra-tight tolerance of ±0.05% and an exceptional temperature coefficient (±0.2ppm/°C), ensuring stability in extreme environments. With resistances of 400Ω and 2kΩ arranged in an isolated circuit configuration, it delivers unmatched accuracy for critical signal conditioning and voltage division tasks. The compact 5.00mm x 3.99mm footprint and low 1.86mm profile make it ideal for space-constrained designs.

Y1365V0195AA0R Features

• Military-Grade Reliability: Compliant with EAR99 and HTSUS 8533.21.0010, suitable for defense systems.
• Precision Performance: ±0.05% resistor matching ratio and ±0.5ppm/°C ratio drift for minimal error over temperature.
• Robust Construction: 100mW power rating per element and bulk packaging ensure durability.
• Optimized Layout: 8-pin configuration with isolated resistors reduces crosstalk in high-frequency circuits.
• Superior Stability: Foil resistor technology outperforms thin-film or thick-film alternatives in long-term drift.

Y1365V0195AA0R Applications

This resistor network excels in:

• Aerospace & Defense: Precision instrumentation, radar systems, and avionics where thermal stability is critical.
• Test & Measurement: Calibration equipment and high-accuracy DAC/ADC reference circuits.
• Medical Electronics: Patient monitoring devices requiring minimal drift over time.
• Industrial Automation: Closed-loop control systems demanding repeatable performance.

Conclusion of Y1365V0195AA0R

The Y1365V0195AA0R sets a benchmark for precision resistor networks, combining VPG Foil's proprietary technology with military-grade ruggedness. Its ultra-low TCR, unmatched tolerance, and compact design make it indispensable for applications where accuracy and reliability cannot be compromised. Engineers seeking to eliminate thermal drift and long-term degradation will find this model superior to conventional arrays.