Resonators

Part Number	Description / PDF	Quantity
CSTCR7M37G53Z-R0 TOKO / Murata	CER RESONATOR	0
CSTNE8M00GH5C000R0 TOKO / Murata	CERAMIC RES 8.0000MHZ 33PF SMD	4855
CSTCR4M00G55-R0 TOKO / Murata	CERAMIC RES 4.0000MHZ 39PF SMD	13
CSTLS4M00G56Z-A0 TOKO / Murata	CERAMIC RES 4.0000MHZ 47PF T/H	2212
CSTNE12M0GH5L000R0 TOKO / Murata	CERAMIC RES 12.0000MHZ 33PF SMD	15273
CSTLS3M68G56-B0 TOKO / Murata	CERAMIC RES 3.6800MHZ 47PF T/H	0
CSTNE12M2G55A000R0 TOKO / Murata	CERAMIC RES 12.2880MHZ 33PF SMD	2727
CSTCR4M72G53-R0 TOKO / Murata	CER RESONATOR	0
CSTLS3M60G56-B0 TOKO / Murata	CERAMIC RES 3.6000MHZ 47PF T/H	357
CSTNE11M0G550000R0 TOKO / Murata	CERAMIC RES 11.0000MHZ 33PF SMD	0
CSTNE16M0V53Z000R0 TOKO / Murata	CERAMIC RES 16.0000MHZ 15PF SMD	22221
CSTCR4M00G55Z-R0 TOKO / Murata	CERAMIC RES 4.0000MHZ 39PF SMD	249
CSTNE12M0G55Z000R0 TOKO / Murata	CERAMIC RES 12.0000MHZ 33PF SMD	2605
CSTCR4M60G55-R0 TOKO / Murata	CER RESONATOR	0
CSTNE16M0V53C000R0 TOKO / Murata	CERAMIC RES 16.0000MHZ 15PF SMD	3110
CSTCW48M0X51-R0 TOKO / Murata	CERAMIC RES 48.0000MHZ 6PF SMD	2465
CSTNE10M0G55A000R0 TOKO / Murata	CERAMIC RES 10.0000MHZ 33PF SMD	3000
CSTNE14M7V530000R0 TOKO / Murata	CERAMIC RES 14.7460MHZ 15PF SMD	0
CSTCR4M50G53-R0 TOKO / Murata	CER RESONATOR	0
CSACW24M0X53-R0 TOKO / Murata	CERAMIC RES 24.0000MHZ SMD	2825

Resonators

1. Overview

Resonators are passive electronic components that generate stable frequencies by utilizing the mechanical resonance of piezoelectric materials (e.g., quartz, ceramic) or surface acoustic waves (SAW). They are critical for timing, frequency control, and signal processing in modern electronics. Oscillators integrate resonators with active circuitry to produce periodic signals, while crystals refer to raw piezoelectric elements. These components ensure synchronization and reliability in communication systems, industrial equipment, and consumer devices.

2. Main Types and Functional Classification

Type	Function Features	Applications
Quartz Crystal Resonators	High Q-factor, excellent temperature stability	Microprocessors, GPS modules
Ceramic Resonators	Lower cost, moderate stability	Remote controls, IoT sensors
SAW Resonators	High-frequency operation (GHz range), compact size	5G base stations, automotive radar
MEMS Resonators	Miniaturized, temperature-compensated	Wearables, medical implants

3. Structure and Composition

A typical resonator includes: - Piezoelectric Material: Quartz (for crystal resonators) or ceramic (for ceramic resonators) that vibrates under electric fields. - Electrodes: Metal coatings (e.g., silver, gold) to apply voltage and detect vibrations. - Encapsulation: Metal or ceramic housing to protect against environmental factors. - SAW Resonators: Feature interdigital transducers (IDTs) on piezoelectric substrates (e.g., lithium niobate) to generate surface acoustic waves.

4. Key Technical Parameters

Parameter	Description & Importance
Frequency Tolerance	Deviation from nominal frequency ( ppm), critical for system synchronization
Q-Factor	Quality factor indicating energy loss; higher Q ensures better frequency selectivity
Temperature Stability	Frequency drift per C (e.g., 30 ppm/ C), vital for harsh environments
Equivalent Series Resistance (ESR)	Affects oscillator startup time and signal purity
Load Capacitance	Required for tuning in oscillator circuits

5. Application Fields

Telecommunications: 5G transceivers, fiber-optic networks
Automotive: Engine control units (ECUs), tire pressure sensors
Consumer Electronics: Smartphones, smartwatches
Industrial: PLCs, precision sensors
Medical: Pacemakers, ultrasound imaging devices

6. Leading Manufacturers and Products

Manufacturer	Representative Products
Murata Manufacturing	CSTCE Series Ceramic Resonators
TDK Corporation	FK1610 Series MEMS Oscillators
Epson Electronics	SG-8003 Series Crystal Oscillators
Sitime Corporation	SIM3-Series Automotive MEMS Resonators
Kyocera	DF23SA Series SAW Filters

7. Selection Guidelines

Consider the following factors when choosing resonators: - Frequency Requirements: Match tolerance and stability to application needs. - Environmental Conditions: High-temperature stability for automotive or industrial use. - Size Constraints: MEMS resonators for miniaturized designs. - Cost vs. Performance: Ceramic resonators for budget-sensitive projects with relaxed stability needs. - Integration: Ensure compatibility with oscillator circuit design (e.g., load capacitance).

8. Industry Trends

Future developments include: - Micromachining: MEMS resonators achieving higher stability and shock resistance. - Higher Frequencies: Demand for sub-6GHz and mmWave SAW resonators in 5G. - Low-Power Solutions: Optimization for IoT and wearable devices. - AI Integration: Self-adjusting resonators using machine learning for dynamic environments. - Material Innovation: Use of aluminum nitride (AlN) and gallium nitride (GaN) for improved thermal performance.