AMELH6030S-100MT DCR & Isat Guide

DCR ≈ 44 mΩ max Isat ≈ 6.5 A Rated current ~6.5 A

This engineer-focused, data-driven walkthrough covers the AMELH6030S-100MT electrical limits, focusing on how DCR and Isat impact I²R loss and saturation in buck converter designs.

Background: Part Overview & Where This Inductor Fits

Physical and Electrical Footprint

The AMELH6030S-100MT is a molded power inductor with a compact surface-mount footprint. Tighter tolerance on inductance reduces the safety margin required for ripple control, while its molded construction provides excellent EMI performance.

Typical Applications

Primarily designed for synchronous buck converters, point-of-load (POL) regulators, and power filtering. Its low DCR is optimized for tight-efficiency budgets in high-density PCB layouts.

Data Deep-Dive: Key Specs — DCR, Isat, Rated DC Current

Current I (A)	Formula (I²·DCR)	P_loss (W) @ 44 mΩ
2.0 A	2² × 0.044	0.176 W
4.0 A	4² × 0.044	0.704 W
6.0 A	6² × 0.044	1.584 W

DCR & Thermal Impact

Using a typical θJA of 30°C/W, the 1.584 W loss at 6A generates approximately a 48°C rise. Always correct DCR for operating temperature as copper's resistance increases by ~0.39% per °C.

Isat vs. Rated Current

Isat (magnetic limit) and Rated Current (thermal limit) are both ~6.5A. For stability, pick an Isat 1.2–1.5× higher than your peak DC bias to prevent ripple spikes from core saturation.

DCR vs Isat: Performance Trade-offs & Thermal Derating

Efficiency vs. Headroom

Thicker copper reduces DCR but can limit the number of turns or core volume, affecting Isat. For POL designs, lower DCR is prioritized, while high-peak systems require greater Isat headroom at the cost of slight DCR penalties.

Thermal Derating Rules

Ambient temperature and PCB layout significantly dictate allowable current. Standard safety margins suggest derating continuous current by 10–30% depending on copper weight and airflow conditions.

How to Measure DCR and Isat (Practical Test Methods)

1

Four-wire (Kelvin) DCR Measurement
Eliminate lead and fixture resistance by using Kelvin probes. Apply 100–500 mA current to achieve mΩ resolution without causing significant self-heating during the test.
2

Pulsed Isat Testing
To avoid thermal skew, use pulsed current to measure inductance (L) vs. DC bias. Log the point where L drops by 20%—this is your operational saturation limit.

PCB Integration & Cooling

Maximize copper pours under the inductor and use thermal vias to transfer heat to inner planes. Align the component with prevailing airflow and avoid placement near other high-heat components like FETs or CPUs.

Mechanical Reliability

Molded packages are robust, but long-term reliability requires validating solder joints against thermal cycling. For high-vibration environments, verify the adhesive integrity of the molded body to the lead frame.

Summary

DCR & Isat: ~44 mΩ max DCR and ~6.5 A Isat define the core performance envelope.

Thermal Limit: Calculate ΔT using 30°C/W as a baseline; apply 10-30% derating for safety.

Verification: Use Kelvin sensing for DCR and pulsed bias for L-vs-I curve mapping.

Checklist: Confirm DCR, check Isat margin (1.2-1.5x), and validate board-level heat rise.

Frequently Asked Questions

What is the max safe continuous current for the AMELH6030S-100MT? +

Safe continuous current depends on your PCB thermal resistance and acceptable temperature rise. Derive using P_loss = I²·DCR and ΔT = P_loss·θJA; then ensure operating temperature stays within material limits and apply a 10–30% derating margin. Validate on-board with thermal measurements under expected ambient and airflow.

How should I measure DCR and Isat for AMELH6030S-100MT to get repeatable results? +

Measure DCR using four-wire Kelvin technique at 25°C with a low, stable measurement current to avoid self-heating. For Isat, sweep DC bias and log inductance using an LCR meter with DC bias or a pulsed-current setup; define saturation consistently (e.g., L drop of 20%) and use pulsed tests to prevent thermal effects.

How do DCR and Isat trade off when choosing AMELH6030S-100MT for a buck converter? +

Lower DCR reduces conduction loss and improves efficiency but may come with reduced saturation margin. Ensure Isat comfortably exceeds expected peak DC bias (1.2–1.5×) to avoid excessive inductance loss and increased ripple; if tight efficiency and high peaks coincide, evaluate thermal mitigation or alternate parts with higher Isat.