Passive Components Blog
No Result
View All Result
  • Home
  • NewsFilter
    • All
    • Aerospace & Defence
    • Antenna
    • Applications
    • Automotive
    • Capacitors
    • Circuit Protection Devices
    • electro-mechanical news
    • Filters
    • Fuses
    • Inductors
    • Industrial
    • Integrated Passives
    • inter-connect news
    • Market & Supply Chain
    • Market Insights
    • Medical
    • Modelling and Simulation
    • New Materials & Supply
    • New Technologies
    • Non-linear Passives
    • Oscillators
    • Passive Sensors News
    • Resistors
    • RF & Microwave
    • Telecommunication
    • Weekly Digest

    Bourns Introduces Automotive BMS Signal Transformer with Integrated Common Mode Chokes

    Itelcond Introduces High‑Voltage Aluminium Capacitors for Modern IGBT DC‑links

    Bourns Introduces Automotive Shielded Power Inductors for Compact DC‑DC Converters

    EMC Design Fundamentals: Safe Use of Varistors and Common Mode Chokes in Mains and Data-Line Filters

    Murata Unveils Lead Disc Ceramic Capacitors for Automotive Safety and EMI Suppression

    SCHURTER Releases Intelligent Three‑Terminal Fuses for Safer Li‑ion Battery Systems

    Can Copper Conductive Inks Displace Silver in Hybrid Electronics?

    Square-Wave Harmonics and RMS Currents in Power Converters

    LeanBOM: Practical Cross‑Technology Capacitor Search by Real Working Conditions

    Trending Tags

    • Ripple Current
    • RF
    • Leakage Current
    • Tantalum vs Ceramic
    • Snubber
    • Low ESR
    • Feedthrough
    • Derating
    • Dielectric Constant
    • New Products
    • Market Reports
  • VideoFilter
    • All
    • Antenna videos
    • Capacitor videos
    • Circuit Protection Video
    • Filter videos
    • Fuse videos
    • Inductor videos
    • Inter-Connect Video
    • Non-linear passives videos
    • Oscillator videos
    • Passive sensors videos
    • Resistor videos

    EMC Design Fundamentals: Safe Use of Varistors and Common Mode Chokes in Mains and Data-Line Filters

    Ferrite versus Nanocrystalline Power Inductor Cores: Turns, Gap and Size

    KYOCERA AVX Presents Antenna Integrator Studio Tutorial for Antenna Placement and RF Design

    Power Design Simulation Tools for Faster Inductor Selection and Loss Optimization

    EMC‑Compliant PCB and Connector Design Guidelines

    Why Isolated DC/DC Power Supplies Fail Late, Würth Elektronik Podcast

    Designing 800 V DC EMC Filters: Calculation, Simulation and Measurement

    Current Sense Transformer Datasheet and Design‑in Guide

    Designing a USB Type‑C Flyback Planar Transformer with Frenetic’s Planar Tool

    Trending Tags

    • Capacitors explained
    • Inductors explained
    • Resistors explained
    • Filters explained
    • Application Video Guidelines
    • EMC
    • New Products
    • Ripple Current
    • Simulation
    • Tantalum vs Ceramic
  • Knowledge Blog
  • Dossiers
    • AI Hardware Dossier
    • Power Converter Dossier
    • Automotive Dossier
    • Capacitor Dossier
    • Resistor Dossier
    • Inductor Dossier
    • Circuit Protection Dossier
  • Suppliers
    • Who is Who
  • PCNS
    • PCNS 2025
    • PCNS 2023
    • PCNS 2021
    • PCNS 2019
    • PCNS 2017
  • Events
  • Home
  • NewsFilter
    • All
    • Aerospace & Defence
    • Antenna
    • Applications
    • Automotive
    • Capacitors
    • Circuit Protection Devices
    • electro-mechanical news
    • Filters
    • Fuses
    • Inductors
    • Industrial
    • Integrated Passives
    • inter-connect news
    • Market & Supply Chain
    • Market Insights
    • Medical
    • Modelling and Simulation
    • New Materials & Supply
    • New Technologies
    • Non-linear Passives
    • Oscillators
    • Passive Sensors News
    • Resistors
    • RF & Microwave
    • Telecommunication
    • Weekly Digest

    Bourns Introduces Automotive BMS Signal Transformer with Integrated Common Mode Chokes

    Itelcond Introduces High‑Voltage Aluminium Capacitors for Modern IGBT DC‑links

    Bourns Introduces Automotive Shielded Power Inductors for Compact DC‑DC Converters

    EMC Design Fundamentals: Safe Use of Varistors and Common Mode Chokes in Mains and Data-Line Filters

    Murata Unveils Lead Disc Ceramic Capacitors for Automotive Safety and EMI Suppression

    SCHURTER Releases Intelligent Three‑Terminal Fuses for Safer Li‑ion Battery Systems

    Can Copper Conductive Inks Displace Silver in Hybrid Electronics?

    Square-Wave Harmonics and RMS Currents in Power Converters

    LeanBOM: Practical Cross‑Technology Capacitor Search by Real Working Conditions

    Trending Tags

    • Ripple Current
    • RF
    • Leakage Current
    • Tantalum vs Ceramic
    • Snubber
    • Low ESR
    • Feedthrough
    • Derating
    • Dielectric Constant
    • New Products
    • Market Reports
  • VideoFilter
    • All
    • Antenna videos
    • Capacitor videos
    • Circuit Protection Video
    • Filter videos
    • Fuse videos
    • Inductor videos
    • Inter-Connect Video
    • Non-linear passives videos
    • Oscillator videos
    • Passive sensors videos
    • Resistor videos

    EMC Design Fundamentals: Safe Use of Varistors and Common Mode Chokes in Mains and Data-Line Filters

    Ferrite versus Nanocrystalline Power Inductor Cores: Turns, Gap and Size

    KYOCERA AVX Presents Antenna Integrator Studio Tutorial for Antenna Placement and RF Design

    Power Design Simulation Tools for Faster Inductor Selection and Loss Optimization

    EMC‑Compliant PCB and Connector Design Guidelines

    Why Isolated DC/DC Power Supplies Fail Late, Würth Elektronik Podcast

    Designing 800 V DC EMC Filters: Calculation, Simulation and Measurement

    Current Sense Transformer Datasheet and Design‑in Guide

    Designing a USB Type‑C Flyback Planar Transformer with Frenetic’s Planar Tool

    Trending Tags

    • Capacitors explained
    • Inductors explained
    • Resistors explained
    • Filters explained
    • Application Video Guidelines
    • EMC
    • New Products
    • Ripple Current
    • Simulation
    • Tantalum vs Ceramic
  • Knowledge Blog
  • Dossiers
    • AI Hardware Dossier
    • Power Converter Dossier
    • Automotive Dossier
    • Capacitor Dossier
    • Resistor Dossier
    • Inductor Dossier
    • Circuit Protection Dossier
  • Suppliers
    • Who is Who
  • PCNS
    • PCNS 2025
    • PCNS 2023
    • PCNS 2021
    • PCNS 2019
    • PCNS 2017
  • Events
No Result
View All Result
Passive Components Blog
No Result
View All Result

TDK Releases Ultra‑small EMI Noise Suppression Filters

8.4.2026
Reading Time: 5 mins read
A A

TDK has introduced the MAF0603GWY series of ultra‑small noise suppression filters for audio lines in compact consumer devices such as smartphones and wearables.

These components address the growing challenge of high‑frequency EMI in densely packed RF platforms while preserving audio quality, making them relevant for both hardware design engineers and purchasing teams working on next‑generation mobile and wearable designs.

RelatedPosts

TDK Releases Compact SMD Gate Drive Transformers for xEV

TDK Releases DC-link Film Capacitors with Ultra-low Inductance for SiC Power Converters

TDK Introduces High‑Voltage Common‑Mode Chokes for Compact 1250 V DC Converters

Key features and benefits

The MAF0603GWY series is a family of common‑mode EMI noise suppression filters optimized for audio lines in small mobile devices. They are supplied in an 0603 metric package measuring 0.6 mm × 0.3 mm × 0.3 mm (L × W × H), making them suitable where board space and component height are tightly constrained.

Key characteristics include:

  • Industry‑leading high‑frequency attenuation in the 5 GHz band, with impedance up to 3220 Ω at 5 GHz depending on the part number.
  • Newly developed low‑distortion ferrite material that minimizes changes to audio line characteristics and significantly reduces audio distortion compared to typical chip bead solutions.
  • Lower DC resistance than conventional products, which helps reduce attenuation of the wanted audio signal and supports a wide dynamic range.
  • Form factor compatible with high‑density audio/RF sections in smartphones, tablets, and wearable devices where routing of audio signals often runs close to antennas.

In practice, the combination of high impedance at 5 GHz and low DC resistance helps designers maintain audio signal integrity while suppressing radiated noise that would otherwise couple into Bluetooth, Wi‑Fi, or cellular antennas.

Typical applications

The primary use case for the MAF0603GWY series is EMI suppression on audio lines in mobile and wearable platforms that integrate multiple RF subsystems. Typical applications include:

  • Audio lines in smartphones and tablets, especially near Bluetooth and Wi‑Fi front‑ends in the 2.4 GHz, 5 GHz, and 6 GHz bands.
  • Headset and speaker outputs in wearable devices such as smartwatches and true wireless earbuds, where antenna coexistence is critical.
  • Audio interfaces in devices prepared for current and emerging wireless standards, including 5G Sub‑6 and future 6G systems.

These EMI filters are particularly relevant where conventional chip beads have been used on audio lines but have led to audible degradation in sound quality or reduced dynamic range.

Technical highlights

The series currently comprises three catalog part numbers with different impedance levels and current ratings at the same compact size:

Part numberImpedance typ. @ 900 MHzImpedance typ. @ 5 GHzDC resistance typ.DC resistance max.Rated current max.
MAF0603GWY211AT000210 Ω1370 Ω0.89 Ω1.30 Ω0.15 A
MAF0603GWY301AT000300 Ω1890 Ω1.15 Ω1.50 Ω0.14 A
MAF0603GWY551AT000550 Ω3220 Ω1.81 Ω2.20 Ω0.125 A

From a design perspective:

  • Higher impedance options (such as the 550 Ω type) provide stronger attenuation at 5 GHz, which can help in particularly noisy layouts or where antennas are very close to audio traces.
  • The relatively low rated currents (up to 0.15 A) are appropriate for typical audio line loads in mobile devices and help keep the component size extremely small.
  • DC resistance values below approximately 2 Ω limit insertion loss on the audio line, supporting high dynamic range audio paths.

The newly developed low‑distortion ferrite material is central to maintaining linearity in the audio frequency band while still providing strong impedance at RF frequencies, which is often a trade‑off with conventional ferrites or chip beads.

Design‑in notes for engineers

When replacing chip beads on audio lines, the MAF0603GWY devices can be considered where EMI at 5 GHz and above is problematic and audio quality cannot be compromised.

Practical design‑in considerations:

  • Place the filter as close as possible to the noise source or to the connector/codec pin to minimize the length of unfiltered trace acting as an antenna.
  • Consider starting with the mid‑range impedance type (for example, 300 Ω typ. at 900 MHz) and evaluate both EMI performance and audio distortion in the actual layout before switching to higher or lower impedance variants.
  • Use the datasheet impedance vs. frequency plots to match the filter’s peak attenuation region to the dominant interference bands in your design (for example, Wi‑Fi at 5 GHz or 6 GHz).
  • Check rated current and derating curves against the maximum expected load current and any DC bias conditions on the audio line.

From a layout and sourcing perspective:

  • The 0603 metric footprint (0.6 × 0.3 mm) requires tight assembly tolerances; coordinate with the PCB and manufacturing teams regarding pad design, solder mask openings, and inspection.
  • Ensure the procurement team differentiates the GWY material variant from other MAF0603 families, since the low‑distortion ferrite material is a key feature for audio performance and should not be substituted without engineering approval.

Engineers should also review TDK’s application notes and technical support documents on noise suppression filters for audio lines to understand recommended evaluation methods, including audio distortion measurements and radiated EMI tests around 5 GHz.

Source

This article is based on the official TDK Corporation press release on the MAF0603GWY series noise suppression filters and the associated product documentation, with additional editorial context added for design engineers and component buyers.

References

  1. TDK press release: EMC Components – MAF0603GWY noise suppression filters
  2. TDK product catalog: MAF0603GW series noise suppression filters

Related

Recent Posts

RF Filters and Passive Components Enabling the 7 Missile RF Subsystems

9.7.2026
57

Designing 800 V DC EMC Filters: Calculation, Simulation and Measurement

4.6.2026
263

Qi2 Wireless Charging: Inductors, Capacitors and EMC Filters

21.5.2026
112

Kyocera Offers Small SAW Filters for IoT RF Modules

23.2.2026
51

Transient Suppression Guide

22.5.2026
1.1k

Overvoltage and Transient Protection for DC/DC Power Modules

13.11.2025
426

3-Phase EMI Filter Design, Simulation, Calculation and Test

22.5.2026
2.4k

Kyocera Launches New SAW Filter for GNSS 1.6GHz Satellite Communications

30.9.2025
92

Space Evaluation Testing on SAW Filter Based on Piezo-On-Insulator Technology

29.9.2025
123

Upcoming Events

Jul 21
16:00 - 17:00 CEST

Safety by design: X and Y Interference suppression capacitors for power line filters

Jul 28
8:00 - 11:00 CEST

Post Procurement Testing of EEE Components for LEO Space Applications

Jul 29
17:30 - 18:30 CEST

To Ferrite or to Nanocrystalline in Transformer Design

View Calendar

Popular Posts

  • Boost Converter Design and Calculation

    0 shares
    Share 0 Tweet 0
  • Buck Converter Design and Calculation

    0 shares
    Share 0 Tweet 0
  • YAGEO Announces July 2026 Capacitor Price Increase

    0 shares
    Share 0 Tweet 0
  • Flyback Converter Design and Calculation

    0 shares
    Share 0 Tweet 0
  • LLC Resonant Converter Design and Calculation

    0 shares
    Share 0 Tweet 0
  • MLCC and Ceramic Capacitors

    0 shares
    Share 0 Tweet 0
  • Earthing Systems and IEC Classification Explained

    0 shares
    Share 0 Tweet 0
  • MLCCs in the Age of AI: Q2 2026 Market Tightness

    0 shares
    Share 0 Tweet 0
  • Nvidia Vera Rubin: Why One AI Rack Needs So Many More MLCC Capacitors

    0 shares
    Share 0 Tweet 0
  • Dual Active Bridge (DAB) Topology

    0 shares
    Share 0 Tweet 0

Newsletter Subscription

 

Passive Components Blog

© EPCI - Leading Passive Components Educational and Information Site

  • Home
  • Privacy Policy
  • EPCI Membership & Advertisement
  • About

No Result
View All Result
  • Home
  • Knowledge Blog
  • Dossiers
  • PCNS

© EPCI - Leading Passive Components Educational and Information Site

This website uses cookies. By continuing to use this website you are giving consent to cookies being used. Visit our Privacy and Cookie Policy.
Go to mobile version