Crystals

Part Number	Description / PDF	Quantity
830003151 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 8.0 MHZ;	0
830003237 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 16.0 MHZ;	0
830065460 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 30.0 MHZ;	0
830003260 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 3.68640 M	1000
830011263 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 16.0 MHZ;	0
830108340909 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 26.0 MHZ;	0
830003271B Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 8.1920 MH	100
830108212709 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 27.12 MHZ	0
830108212909 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 32.0 MHZ;	3000
830059530 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 24.0 MHZ;	0
830026386 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 14.318180	0
830003166 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 10.0 MHZ;	1000
830027527 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 7.1750 MH	0
830068911 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 25.0 MHZ;	0
830108213509 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 48.0 MHZ;	0
830003312B Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 22.11840	100
830103552209 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 32.0 MHZ;	0
830009706 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 32.7680 K	0
830106163301 Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 13.56 MHZ	0
830003215B Würth Elektronik Midcom	WE-XTAL QUARTZ CRYSTAL 12.0 MHZ;	90

Crystals

1. Overview

Crystals, oscillators, and resonators are passive electronic components that generate stable frequency signals for timing and synchronization in electronic systems. Crystals (e.g., quartz) utilize piezoelectric properties to produce precise oscillations. Oscillators integrate active circuitry to generate periodic signals, while resonators provide frequency-selective feedback. These components are critical in communication systems, computing devices, industrial controls, and consumer electronics.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Quartz Crystals	High frequency stability, low phase noise	Microprocessors, GPS modules, RF transceivers
Ceramic Resonators	Lower cost, moderate stability	Remote controls, toys, low-precision sensors
MEMS Resonators	Miniaturized, shock-resistant	IoT devices, wearables, automotive sensors
Crystal Oscillators (XO)	Integrated driver circuitry	Network switches, test equipment, precision clocks

3. Structure and Composition

A typical quartz crystal consists of a precision-cut piezoelectric wafer (AT-cut or SC-cut), metallized electrodes (silver or gold), and a hermetically sealed package (glass or ceramic). MEMS resonators use silicon-based microstructures with electrostatic or piezoelectric transducers. Ceramic resonators employ zirconium titanate (PZT) materials with printed electrodes.

4. Key Technical Specifications

Parameter	Description	Importance
Frequency Range	Operating frequency band (kHz-MHz)	Determines circuit timing resolution
Frequency Tolerance	Initial accuracy at 25 C (ppm)	Impacts system synchronization
Temperature Stability	Frequency drift over temperature (ppm/ C)	Critical for harsh environments
Equivalent Series Resistance (ESR)	Internal resistance affecting startup time	Impacts oscillator reliability
Aging Rate	Long-term frequency shift (ppm/year)	System longevity consideration

5. Application Fields

Key industries include:

Telecommunications: 5G base stations, optical transceivers
Industrial Automation: PLCs, robotics controllers
Consumer Electronics: Smartphones, smartwatches
Automotive: ECUs, tire pressure sensors
Medical Devices: Pacemakers, diagnostic equipment

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Epson	SG-8003	32.768 kHz TCXO for real-time clocks
Murata	XRCGB32M000F	32 MHz ceramic resonator
SiTime	SiT8924	MEMS-based automotive-grade oscillator
TXC Corporation	9B-26.000MHZ	26 MHz quartz crystal for Bluetooth modules

7. Selection Guidelines

Key considerations:

Required frequency and stability (temperature/vibration)
Power consumption constraints
Environmental operating conditions
Package size and mounting type
Cost vs. precision trade-offs

Example: For IoT edge devices, prioritize MEMS resonators with low power (<10 A) and 50 ppm stability.

8. Industry Trends

Emerging trends include:

Miniaturization: 0.4x0.2 mm MEMS devices for wearable integration
Higher frequency adoption: 100+ MHz crystals for 5G infrastructure
Integrated solutions: Oscillators with built-in frequency modulation
Automotive-grade reliability: AEC-Q100 qualified components for EVs
AI-driven testing: Machine learning for crystal defect detection