0 60 35 A 220 KATのデータシート:性能とテストデータの概要

2026-01-29 19:09:05

Design Value: This guide distills nominal specs, C vs. temperature behavior, ESR/DF guidance, and environmental trends into actionable design decisions to validate procurement lots and lab verification steps.

Background: Quick Specifications Snapshot

Part Identity & Nominal Specs

Extract core parameters for rapid comparison: package size (0603), capacitance (220 nF), tolerance (±10%), and dielectric class (X7R). This allows engineers to screen for voltage and stability before integration.

Typical Applications & Operating Envelope

Optimized for decoupling and RF bypass. Recommended derating: apply 50–80% of rated voltage for high-temp stability. Avoid biasing at the dielectric knee to preserve capacitance stability.

Key Performance Metrics

Capacitance Stability Visualization

Nominal C

220 nF

Tolerance Low

198 nF

Tolerance High

242 nF

* Visual representation of ±10% manufacturing spread based on 220nF nominal value.

Field	Value / Technical Note
Package	0603 (EIA Metric: 1608)
Nominal Capacitance	220 nF (0.22 µF)
Tolerance	±10% Standard
Rated Voltage	Refer to part marking (Utilize derated bias for longevity)
Dielectric	X7R (Stable performance across mid-temp range)

Electrical Parameters: ESR, Loss Tangent, DC Leakage

ESR/DF and leakage determine effectiveness. Target impedance at crossover frequency should be maintained by low ESR. Translate Dissipation Factor (DF) into expected insertion loss during transient events for power-rail hold-up.

Reliability & Stress Results

Environmental: Dielectric aging shows
Leakage: Remains sub-microamp even after humidity soak qualification.
Mechanical: Withstands standard JEDEC lead-free reflow profiles without body cracking.

Test Methodology

Reproduce datasheet metrics using calibrated LCR meters (1 kHz for capacitance) and impedance analyzers. Minimize lead inductance with short traces and Kelvin connections for measurements up to 10 MHz.

CASE STUDY Decoupling with 06035A220KAT

Placement Strategy

Place within 1–3 mm of IC power pins. Combine with lower-ESL capacitors to flatten impedance across a wider frequency range. Use single vias to reduce parasitic inductance.

Simulation Deviations

On-board ripple attenuation may be 10–30% lower than idealized models. Measure Z(f) on-board to refine placement and adjust power-rail topology.

Actionable Checklist

Procurement & Inspection

Verify date codes and packaging integrity.
Sample check C at 1 kHz and DC leakage at rated bias.
Benchmark against AQL standards for 30-piece lots.

PCB Layout Best Practices

Use wide traces and pad geometry matching land patterns.
Follow standard lead-free reflow profiles precisely.
Conduct post-reflow solder fillet and X-ray inspection.

Summary

Performance Stable mid-band decoupling with budget for worst-case C loss.

Reliability Accept ≤±10% permanent shift; maintain leakage in microamp range.

Integration Proximity (1-3mm) and via count are critical for transient performance.

Common Questions

How should a lab verify capacitance and leakage for incoming 06035A220KAT parts? +

Use simple, repeatable checks. Measure capacitance at 1 kHz and DC leakage at rated bias using an LCR meter and a picoammeter. If values deviate beyond the ±10% tolerance, escalate to a 30-piece statistical sample and request manufacturer lot data.

What reflow profile and mechanical checks are recommended for assembly? +

Follow JEDEC lead-free peak temperature profiles. Inspect solder fillets visually or via AOI, and perform shear/pull tests on a sample lot to ensure no internal cracking or delamination occurs during the thermal cycles.

Which on-board measurements best reveal deviations from datasheet performance? +

Impedance sweep (Z vs f) and time-domain transient tests are most informative. Differences between board measurements and component-only curves usually point to layout parasitics, guiding fixes like adding parallel capacitors or improving via placement.

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