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Y5076V0488VV9L

Y5076V0488VV9L Description

The Y5076V0488VV9L from VPG Foil Resistors is a high-precision voltage divider resistor network from the VHD200 series, designed for applications demanding ultra-low tolerance and thermal stability. This through-hole-mounted dual-resistor network features resistances of 4.2857kΩ and 10kΩ with a matched ±0.005% tolerance and ±2ppm/°C temperature coefficient, ensuring minimal drift under varying thermal conditions. Its ±0.1ppm/°C resistor-ratio drift and ±0.005% matching ratio make it ideal for critical analog circuits requiring long-term stability. Encased in a compact 11.05mm x 4.70mm bulk package with a 14.35mm max height, it balances precision with space efficiency.

Y5076V0488VV9L Features

• Ultra-High Precision: TCR-matched resistors with ±0.005% tolerance for minimal deviation.
• Exceptional Thermal Stability: ±2ppm/°C tempco and ±0.1ppm/°C ratio drift ensure performance across temperature ranges.
• Robust Construction: Through-hole design with 100mW power handling per element.
• Optimized for Voltage Division: Precisely matched 4.2857kΩ/10kΩ ratio for accurate signal scaling.
• Reliable Compliance: EAR99 ECCN and HTSUS 8533.21.0050 certified for global use.

Y5076V0488VV9L Applications

This resistor network excels in:

• Precision Instrumentation: High-accuracy voltage references in test/measurement equipment.
• Aerospace & Defense: Stable signal conditioning in harsh environments.
• Medical Electronics: Critical analog front-ends where drift is unacceptable.
• Industrial Automation: Feedback networks in high-resolution ADCs/DACs.

Conclusion of Y5076V0488VV9L

The Y5076V0488VV9L stands out for its unmatched precision, thermal resilience, and ratio stability, making it a top choice for engineers designing mission-critical systems. Its VHD200-series pedigree ensures reliability in applications where even minor deviations can compromise performance. For voltage division tasks requiring sub-ppm-level accuracy, this model delivers superior performance over conventional resistor arrays.