EMI/RFI Filters (LC, RC Networks)

Part Number	Description / PDF	Quantity
VEMI65AB-HCI-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/24PF SMD	2534
VEMI85AA-HGK-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/36PF SMD	4028
VEMI65A6-FC2-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/90PF SMD	0
VEMI65AA-HCI-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/36PF SMD	6084
VEMI45AA-HNH-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/36PF SMD	8919
VEMI85AB-HGK-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/24PF SMD	0
VEMI85AC-HGK-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/13PF SMD	0
VEMI65AC-HCI-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/13PF SMD	17695
VEMI355A-HAF-G-08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 50 OHM/37PF SMD	0
VEMI45AB-HNH-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/24PF SMD	0
VEMI353A-HAF-G-08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 30 OHM/37PF SMD	0
VEMI35AA-HAF-G-08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/37PF SMD	0
VEMI45AC-HNH-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/13PF SMD	11975
VEMI255A-HS3-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 50 OHM/37PF SMD	0
VEMI355A-HA3-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 50 OHM/37PF SMD	0
VEMI353A-HA3-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 30 OHM/37PF SMD	0
VEMI35AA-HA3-GS08 Vishay General Semiconductor – Diodes Division	FILTER RC(PI) 100 OHM/37PF SMD	0

EMI/RFI Filters (LC, RC Networks)

1. Overview

EMI/RFI (Electromagnetic Interference/Radio-Frequency Interference) filters are passive components designed to suppress unwanted high-frequency noise in electronic circuits. These filters utilize LC (inductor-capacitor) or RC (resistor-capacitor) networks to attenuate noise while allowing desired signals to pass. In modern electronics, they are critical for ensuring electromagnetic compatibility (EMC), preventing interference between devices, and meeting regulatory standards in industries such as automotive, aerospace, and telecommunications.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
LC Filters	Use inductors and capacitors to create low-pass or band-pass filtering; high attenuation at target frequencies	Power supplies, motor drives, RF transceivers
RC Filters	Resistor-capacitor networks for broadband noise suppression; lower cost, simpler design	Signal lines, analog circuits, medical devices
LCR Filters	Combines inductors, capacitors, and resistors for enhanced damping and stability	High-precision instrumentation, industrial automation
Multi-stage Filters	Cascaded LC/RC stages for improved attenuation over wide frequency ranges	Switching power supplies, EV charging systems

3. Structure and Components

A typical EMI/RFI filter consists of: - Inductors (L): Wound coils or ferrite beads that block high-frequency currents. - Capacitors (C): Ceramic or film capacitors that shunt noise to ground. - Resistors (R): Used for damping oscillations in LCR filters. - Enclosure: Shielded metal or plastic housing to prevent radiation. - Terminals: Screw, PCB, or panel-mount interfaces for integration. The components are arranged in (Pi), T, or ladder configurations based on filtering requirements.

4. Key Technical Specifications

Parameter	Description	Importance
Cutoff Frequency	Frequency at which attenuation reaches -3dB	Determines noise suppression range
Insertion Loss	Signal loss at target frequencies (dB)	Measures filtering effectiveness
Rated Voltage/Current	Max continuous operating voltage/current	Ensures safe operation
Impedance	Matching with source/load impedance ( )	Optimizes performance
Temperature Range	Operating temperature limits ( C)	Affects reliability
ESR (Equivalent Series Resistance)	Internal resistance of capacitors	Influences damping and efficiency

5. Application Areas

EMI/RFI filters are used in: - Consumer Electronics: Smartphones, TVs, switching power supplies. - Industrial Automation: PLCs, motor drives, sensors. - Automotive: On-board chargers (OBC), CAN bus systems. - Medical Devices: MRI machines, ECG monitors. - Telecommunications: 5G base stations, fiber optic transceivers. - Aerospace: Avionics, satellite communication systems.

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
TDK Corporation	FK18 series	Miniature LC filters for DC power lines, 100kHz 1GHz range
Murata Manufacturing	NXU series	Multi-layer ceramic EMI filters for automotive applications
Schaffner Group	FN9266	High-current 3-phase filter for industrial motor drives
Coilcraft	1500R series	RC networks for signal line filtering in IoT devices
Bourns Inc.	2008-RC	Surface-mount LC filters for telecom infrastructure

7. Selection Guidelines

Key considerations for selecting EMI/RFI filters: 1. Frequency Range: Match cutoff frequency to target noise spectrum. 2. Circuit Impedance: Ensure impedance compatibility (e.g., 50 systems). 3. Physical Constraints: Size, mounting type (through-hole/SMD), and weight. 4. Environmental Factors: Temperature, humidity, and vibration resistance. 5. Cost vs. Performance: Balance attenuation requirements with budget. 6. Compliance: Certifications (CE, FCC, CISPR) for target markets. Example: For a 12V DC motor driver, select an LC filter with a 1MHz cutoff frequency, 5A current rating, and IP67 enclosure.

8. Industry Trends

Future developments include: - Miniaturization: Increased integration of LC/RC components in chip-scale packages. - High-Frequency Support: Filters for 5G (up to 40GHz) and mmWave applications. - Wide Bandgap Compatibility: Optimized for GaN/SiC devices in EVs and fast chargers. - Smart Filters: Embedded sensors for real-time EMI monitoring. - Environmental Compliance: Lead-free materials and RoHS/WEEE adherence. The global EMI filter market is projected to grow at 8.2% CAGR through 2030, driven by IoT and electrified transportation.