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SLD1X10K00DB

SLD1X10K00DB Description

The SLD1X10K00DB from VPG Foil Resistors is a high-precision voltage divider network designed for applications demanding ultra-stable resistance ratios and minimal thermal drift. This 2-resistor network features matched 10kΩ resistors with a tight ±0.1% resistor matching ratio and an exceptional ±0.5% tolerance, ensuring consistent performance in critical circuits. Its ±5ppm/°C temperature coefficient (TCR) and ±3ppm/°C resistor-ratio drift make it ideal for environments with fluctuating temperatures. Encased in a compact through-hole package (7.50mm x 2.20mm), it combines precision with durability, meeting EAR99 and HTSUS 8533.21.0050 compliance standards.

SLD1X10K00DB Features

• Ultra-Precision Matching: ±0.1% resistor ratio tolerance for balanced voltage division.
• Low TCR & Ratio Drift: ±5ppm/°C TCR and ±3ppm/°C ratio drift ensure stability across temperature ranges.
• Robust Construction: Through-hole mounting with a 0.315" (8.00mm) height for secure PCB integration.
• Wide Application Suitability: MSL Not Applicable for humidity resilience; bulk packaging for cost efficiency.
• Industry-Leading Accuracy: ±0.5% resistance tolerance outperforms standard networks.

SLD1X10K00DB Applications

The SLD1X10K00DB excels in precision analog circuits, including:

• Voltage references and sensor signal conditioning where ratio stability is critical.
• Medical instrumentation (e.g., patient monitors) requiring long-term accuracy.
• Aerospace & defense systems subjected to thermal stress.
• Calibration equipment and high-end test gear demanding minimal drift.

Conclusion of SLD1X10K00DB

The SLD1X10K00DB sets a benchmark for precision resistor networks, combining VPG Foil’s expertise in TCR-matched designs with rugged through-hole reliability. Its unmatched ratio stability, low drift, and tight tolerances make it indispensable for mission-critical electronics. Engineers seeking uncompromising performance in voltage division or ratio-sensitive circuits will find this model a superior choice over conventional arrays.