Ceramic Filters

Image	Part Number	Description / PDF	Quantity	Rfq
	CER0109B CTS Corporation	CER FILTER 1.95GHZ BAND PASS	0
	CER0230C CTS Corporation	CER FILTER 836.5MHZ BAND PASS	0
	CER0325C CTS Corporation	CER FILTER 3.5GHZ BAND PASS	0
	CER0244A CTS Corporation	CER FILTER 1.88GHZ BAND PASS	0
	KFF6433A CTS Corporation	CER FILTER BAND PASS	0
	CER0245E CTS Corporation	CER FILTER BAND PASS	0
	CER0499A CTS Corporation	CER FILTER 2.14GHZ BAND PASS	0
	CER0110A CTS Corporation	CER FILTER 2.14GHZ BAND PASS	0
	CER0540A CTS Corporation	CERAMIC FILTER	0
	CER0111A CTS Corporation	CER FILTER 1.88GHZ BAND PASS	0
	CER0021A CTS Corporation	CER FILTER 1.96GHZ BAND PASS	0
	CER0644A CTS Corporation	CERAMIC FILTER	0
	CER0183A CTS Corporation	CER FILTER 3.285GHZ BAND PASS	0
	CER0839B CTS Corporation	CER FILTER BAND PASS	0
	CER0284A CTS Corporation	CER FILTER BAND PASS	0
	CER0846A CTS Corporation	CER FILTER BAND PASS	0
	KFF6516A CTS Corporation	CER FILTER 1.09GHZ BAND PASS	0
	KFF6136A CTS Corporation	CER FILTER BAND PASS	0
	CER0247C CTS Corporation	CER FILTER 1.8425GHZ BAND PASS	0
	CER0370C CTS Corporation	CER FILTER BAND PASS	0

Ceramic Filters

1. Overview

Ceramic filters are electronic components utilizing ceramic materials' dielectric or piezoelectric properties to selectively pass or reject specific frequency bands. Their high Q-factor, compact size, and temperature stability make them critical in RF/microwave signal processing systems. Modern wireless communication, IoT devices, and industrial sensors rely on ceramic filters for signal integrity and interference suppression.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Dielectric Ceramic Filters	High permittivity, low loss tangent, suitable for GHz-range filtering	5G base stations, WLAN routers
Piezoelectric Ceramic Filters	Convert electrical/mechanical energy, precise frequency control	Ultrasonic cleaners, medical imaging
Monolithic Ceramic Filters	Integrated multilayer structure, wide bandwidth	Automotive radar, GPS modules
LTCC Filters	Low-temperature co-fired ceramic, multilayer integration	Smartphones, wearable devices

3. Structure and Composition

Typical ceramic filter structures include:

Ceramic substrate: Alumina (Al O ), Zirconia (ZrO ), or Titanate materials
Conductive elements: Silver/palladium electrodes with precise patterning
Encapsulation: Epoxy or metal housing for environmental protection
Temperature compensation: Special dopants to stabilize frequency drift

Cross-sectional design optimizes electromagnetic field distribution through resonator coupling.

4. Key Technical Specifications

Parameter	Description	Importance
Frequency Range	Operational bandwidth (MHz-GHz)	Determines application suitability
Insertion Loss	Signal attenuation in passband (0.5-5 dB)	Impacts system sensitivity
Bandwidth (BW)	3dB bandwidth (1-1000 MHz)	Defines frequency selectivity
Temperature Stability	50 ppm/ C typical	Ensures operational reliability
Power Handling	1-100 W maximum	Limits in high-power applications

5. Application Fields

Major application areas:

Telecommunications: 5G NR filters, Wi-Fi 6E front-end modules
Automotive: 77GHz millimeter-wave radar systems
Medical: MRI machine RF coils and ultrasound probes
Industrial: Wireless sensor networks for predictive maintenance

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Murata Manufacturing	NFU087HC Series	0.6-6.0 GHz, 1.0dB insertion loss
TDK Corporation	CKF1010 Series	GPS L1/L2 dual-band filtering
Kemet Electronics	KC_LF Series	LTCC technology for IoT devices
Qorvo Inc.	QM78003	5G massive MIMO filter array

7. Selection Guidelines

Key selection factors:

Match frequency specifications with system requirements
Evaluate power handling in high-power applications
Consider temperature stability for harsh environments
Verify packaging compatibility (SMD/BGA/connectorized)
Assess cost-performance balance for volume production

8. Industry Trends

Emerging trends include:

Sub-6GHz and mmWave filter development for 6G
AI-driven filter design optimization
Nano-ceramic materials for higher Q-factors (Q>10,000)
Integration with antenna systems (Antenna-in-Package)
Environmental compliance (RoHS, REACH)

Market forecasts predict 8.2% CAGR through 2030, driven by 5G infrastructure and automotive radar demand.