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Y0006V0100TT0L

Y0006V0100TT0L Description

The Y0006V0100TT0L from VPG Foil Resistors is a high-precision 2-resistor network designed for voltage divider applications with TCR-matched performance. This through-hole component features ultra-tight tolerances (±0.01% resistance and ratio matching) and an exceptional ±2ppm/°C temperature coefficient, ensuring stability in demanding environments. Its compact 7.49mm x 2.54mm footprint and 8.13mm height make it suitable for space-constrained designs. The resistor network operates at 100mW per element with resistance values of 2kΩ and 20kΩ, optimized for precision analog circuits.

Y0006V0100TT0L Features

• Ultra-High Precision: ±0.01% tolerance and ±0.01% resistor matching ratio for critical accuracy.
• Low TCR: ±2ppm/°C temperature coefficient minimizes drift over temperature variations.
• Ratio Stability: ±0.5ppm/°C resistor-ratio-drift ensures consistent voltage division.
• Robust Construction: Bulk packaging and non-MSLA (Moisture Sensitivity Level Not Applicable) for reliability in harsh conditions.
• TCR-Matched Pair: Ideal for applications requiring thermal tracking between resistors.
• Wide Compliance: EAR99 and HTSUS 8533.21.0050 classified for global use.

Y0006V0100TT0L Applications

This resistor network excels in:

• Precision voltage dividers for reference circuits, DACs, and ADCs.
• Test & measurement equipment (e.g., calibrators, bridges) demanding sub-ppm stability.
• Aerospace and defense systems where thermal drift and long-term reliability are critical.
• Medical instrumentation (e.g., high-resolution sensors, diagnostic devices).
• Industrial automation for feedback networks in control systems.

Conclusion of Y0006V0100TT0L

The Y0006V0100TT0L stands out for its unmatched precision, thermal stability, and rugged design, making it a top choice for engineers requiring ultra-low drift and TCR-matched performance. Its combination of tight tolerances, compact size, and high power handling (100mW) positions it as a superior alternative to conventional resistor networks in mission-critical applications.