Counterfeit and defect prevention
Visual and packaging inspection
Electrical performance verification
Service Email:
[email protected]
>
MLG0603P15NHT000
TDK Corporation
FIXED IND 15NH 250MA 1.2 OHM SMD
405290 Pcs New Original In Stock
15 nH Unshielded Multilayer Inductor 250 mA 1.2Ohm Max 0201 (0603 Metric)
Request Quote
(Ships tomorrow)
*Quantity
Minimum 1
Minimum 1
5.0 / 5.0
- (217 Ratings)
MLG0603P15NHT000
Product Overview
6644481
DiGi Electronics Part Number
MLG0603P15NHT000-DGManufacturer
TDK Corporation
MLG0603P15NHT000
Description
FIXED IND 15NH 250MA 1.2 OHM SMDInventory
405290 Pcs New Original In Stock
15 nH Unshielded Multilayer Inductor 250 mA 1.2Ohm Max 0201 (0603 Metric)
Quantity
Minimum 1
Minimum 1
Purchase and inquiry
Warranty & Returns
How to Order
Shipping & Delivery
Quality Assurance
365 - Day Quality Guarantee - Every part fully backed.
90 - Day Refund or Exchange - Defective parts? No hassle.
Limited Stock, Order Now - Get reliable parts without worry.
Global Shipping & Secure Packaging
Worldwide Delivery in 3-5 Business Days
100% ESD Anti-Static Packaging
Real-Time Tracking for Every Order
Secure & Flexible Payment
Credit Card, VISA, MasterCard, PayPal, Western Union, Telegraphic Transfer(T/T) and more
All payments encrypted for security
MLG0603P15NHT000 Technical Specifications
Category
Fixed Inductors
Packaging
Tape & Reel (TR)
Series
MLG-P
Product Status
Active
Type
Multilayer
Material - Core
Non-Magnetic
Inductance
15 nH
Tolerance
±3%
Current Rating (Amps)
250 mA
Current - Saturation (Isat)
-
Shielding
Unshielded
DC Resistance (DCR)
1.2Ohm Max
Q @ Freq
14 @ 500MHz
Frequency - Self Resonant
3.2GHz
Ratings
-
Operating Temperature
-55°C ~ 125°C
Inductance Frequency - Test
500 MHz
Mounting Type
Surface Mount
Package / Case
0201 (0603 Metric)
Supplier Device Package
0201 (0603 Metric)
Size / Dimension
0.024" L x 0.012" W (0.60mm x 0.30mm)
Height - Seated (Max)
0.013" (0.33mm)
Datasheet & Documents
HTML Datasheet
MLG0603P15NHT000-DG
Environmental & Export Classification
RoHS Status
ROHS3 Compliant
Moisture Sensitivity Level (MSL)
1 (Unlimited)
REACH Status
REACH Unaffected
ECCN
EAR99
HTSUS
8504.50.8000
Additional Information
Other Names
MLG0603P15NHT000-DG
445-MLG0603P15NHT000CT
445-MLG0603P15NHT000DKR
445-MLG0603P15NHT000TR
Standard Package
15,000
Reviews
5.0/5.0-(Show up to 5 Ratings)
Dec 02, 2025
가격이 착하고 배송도 빠르니 써볼 만한 가치를 충분히 느낍니다.
Dec 02, 2025
Der Versandprozess war klar kommuniziert und extrem schnell abgewickelt.
Dec 02, 2025
DiGi Electronicsの製品はいつも期待以上の性能です。スタッフも非常に親切で感謝しています。
Dec 02, 2025
Their diverse collection of products means I can find everything I need in one place.
Dec 02, 2025
DiGi Electronics always ensures their support is both friendly and knowledgeable.
Dec 02, 2025
Support responsiveness has been invaluable during urgent situations.
Dec 02, 2025
The timely delivery and professional assistance from their support staff make my procurement process smooth.
Dec 02, 2025
The attention to packaging detail at DiGi Electronics minimizes damage and enhances customer satisfaction.
Dec 02, 2025
The product quality from DiGi Electronics is outstanding, with durable components that stand the test of time.
Dec 02, 2025
Efficient logistics meant I received my order right on time without any issues.
Publish Evalution
Evalution Message
Please enter your review message.
Please post honest comments and do not post ilegal comments.
Frequently Asked Questions (FAQ)
Can the MLG0603P15NHT000 be safely used in a 2.4 GHz RF matching network given its self-resonant frequency of 3.2 GHz, and what layout precautions are critical to avoid parasitic effects?
Yes, the MLG0603P15NHT000 can be used in 2.4 GHz applications since its self-resonant frequency (3.2 GHz) is well above the operating band, but extreme care must be taken with PCB layout. Due to its 0201 package and unshielded construction, nearby ground planes or traces can introduce parasitic capacitance that lowers the effective SRF. Maintain at least 0.5 mm clearance from adjacent conductive features, use a solid ground plane beneath only if necessary for thermal management, and avoid routing high-speed signals parallel to the inductor. Always validate impedance with a network analyzer or EM simulation to confirm performance at 2.4 GHz.
What are the risks of replacing the MLG0603P15NHT000 with a similarly sized 15 nH inductor like the Murata LQG18FN15NJ00D in a high-density RF front-end design?
While both the MLG0603P15NHT000 and Murata LQG18FN15NJ00D offer 15 nH in 0603 packages, direct replacement introduces risks due to differing core materials and Q-factor profiles. The TDK part uses a non-magnetic multilayer structure with Q=14 @ 500 MHz, whereas Murata’s LQG series typically exhibits higher Q but may have different parasitic behavior above 1 GHz. Additionally, the LQG18FN15NJ00D has a slightly higher DCR (1.4 Ω vs. 1.2 Ω max), which increases insertion loss in low-power RF paths. Always re-tune matching networks and verify return loss and gain flatness across the band before committing to a drop-in swap.
How does the unshielded nature of the MLG0603P15NHT000 impact EMI performance in a compact IoT module with mixed digital and RF sections?
The unshielded design of the MLG0603P15NHT000 makes it susceptible to both radiating and picking up electromagnetic interference, which is a critical concern in tightly packed IoT modules. Magnetic flux can couple into adjacent signal lines or power rails, potentially degrading SNR in sensitive RF receivers or causing false triggering in digital circuits. To mitigate this, orient the inductor perpendicular to high-current or high-speed traces, maintain a minimum 1 mm spacing from other components, and consider adding a grounded guard ring around it. In noise-critical designs, evaluate shielded alternatives like TDK’s MLK series, even if they require slightly larger footprints.
Is the MLG0603P15NHT000 suitable for power integrity applications such as decoupling in a 1.8 V digital supply rail drawing up to 200 mA, and what are the limitations?
The MLG0603P15NHT000 is not recommended for bulk decoupling or power filtering despite its 250 mA current rating, because its primary design intent is RF signal applications, not DC power handling. At 200 mA, the 1.2 Ω DCR results in 48 mW of power dissipation and ~48 mV of IR drop—acceptable in theory but risky under transient loads. More critically, multilayer ceramic inductors like this exhibit significant inductance reduction under DC bias, which isn’t specified in the datasheet. For power integrity, use dedicated ferrite beads or power inductors with stable L vs. I characteristics, such as TDK’s VLS201610CX series, and reserve the MLG0603P15NHT000 for RF matching or filtering roles only.
Given the MLG0603P15NHT000’s ±3% tolerance and 0201 package, how should I handle tolerance stacking in a narrowband 900 MHz matching network where component variation affects link budget?
In narrowband 900 MHz designs, the ±3% tolerance of the MLG0603P15NHT000 can shift resonant frequency enough to degrade return loss by 3–6 dB if not accounted for. Combine this with capacitor tolerances (e.g., ±5% on Class-II MLCCs), and impedance mismatch may exceed acceptable limits. Mitigate this by using tighter-tolerance capacitors (C0G/NP0 ±1%) and designing the matching network with slight overcoupling to allow post-assembly tuning. Alternatively, implement a tunable matching network using a low-loss RF switch and a capacitor array, enabling factory calibration. Always perform Monte Carlo analysis during schematic design to quantify yield impact before finalizing the BOM.
Quality Assurance (QC)
DiGi ensures the quality and authenticity of every electronic component through professional inspections and batch sampling, guaranteeing reliable sourcing, stable performance, and compliance with technical specifications, helping customers reduce supply chain risks and confidently use components in production.
MLG0603P15NHT000 CAD Models
TDK Corporation MLG0603P15NHT000 PCB symbols & footprints
productDetail
