Oscillators

Part Number	Description / PDF	Quantity
TSM75-H50CQ33ST-54.000M Transko	54MHZ XTAL OSC CERAMIC SMD	177
TSM75-H50GM33SN-66.666667M Transko	66.666667M XTAL OSC CERAMIC SMD	381
TSM22-H50CQ18ST-28.63636M-TR Transko	28.63636MHZ XTAL OSC CERAMIC SMD	8000
TSM32-H25HQ18ST-93.75M Transko	93.75MHZ XTAL OSC CERAMIC SMD	385
TSM21-H50CQ33ST-25.000M Transko	25MHZ XTAL OSC CERAMIC SMD	295
TSM32-H50CQ18RT-14.31818M-TR Transko	14.31818MHZ XTAL OSC CERAMIC SMD	1000
TSM53-H30HM33ST-20.000M Transko	20MHZ XTAL OSC CERAMIC SMD	294
THS32-H10CQ33ST-27.000M Transko	27MHZ XTAL OSC CERAMIC SMD	100
TSMV-H50HM33ST2C-74.17582M Transko	74.17582MHZ VCXO 7X5MM SMD 6PAD	1000
TSM21-H50CT18ST-33.333M-TR Transko	33.333MHZ XTAL OSC CERAMIC SMD	1000
TSMV-H50HM33ST2C-74.250M Transko	74.250MHZ VCXO 7X5MM SMD 6 PAD	1000
TPSM-P25HM33ST1-156.250M-TR Transko	156.25MHZ XTAL OSC CERAMIC SMD	2000
TSM75-H50CQ33ST-62.500M-TR Transko	62.5MHZ XTAL OSC CERAMIC SMD	1000
TSM22-H50CQ18ST-1.000M Transko	1MHZ XTAL OSC CERAMIC SMD	10
TSM22-H50CQ18ST-68.000M Transko	68MHZ XTAL OSC CERAMIC SMD	1005
TSM75-H50CQ33ST-18.432M Transko	18.432MHZ XTAL OSC CERAMIC SMD	322
TSM32-H50HM33ST-54.000M-TR Transko	54MHZ XTAL OSC CERAMIC SMD	1000
TSM21-H50CQ18ST-25.000M Transko	25MHZ XTAL OSC CERAMIC SMD	650
TSM53-H50HM33SN-33.333M Transko	33.333MHZ XTAL OSC CERAMIC SMD	100
TSM75-H20GM33ST-35.4688M Transko	35.4688MHZ XTAL OSC CERAMIC SMD	241

Oscillators

1. Overview

Oscillators are electronic components that generate stable periodic signals, serving as frequency references in electronic systems. Crystals and resonators are core elements that determine frequency stability through mechanical vibration. These components are critical in modern technology for ensuring synchronization, timing accuracy, and signal integrity in applications ranging from consumer electronics to aerospace systems.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
Crystal Oscillator (XO)	Fixed frequency output, high stability	Microcontrollers, clocks
Voltage-Controlled Crystal Oscillator (VCXO)	Frequency adjustable via control voltage	Telecom networks, phase-locked loops
Temperature-Compensated Crystal Oscillator (TCXO)	Integrated temperature compensation circuit	GPS devices, mobile phones
Oven-Controlled Crystal Oscillator (OCXO)	Heated enclosure for ultra-high stability	Test equipment, military radar
Microwave Resonator	High-frequency operation using dielectric materials	5G base stations, satellite communication

3. Structure and Components

A typical oscillator consists of:

Crystal unit (quartz or ceramic resonator)
Amplification circuit (transistor/IC)
Feedback network (LC/pi-filter)
Power supply regulation
Metal/ceramic hermetic enclosure

Quartz crystals are cut in AT or SC configurations for optimal temperature response. Advanced packages integrate phase noise reduction circuitry and digital control interfaces.

4. Key Technical Specifications

Parameter	Description	Importance
Frequency Range	Operational frequency band (kHz to GHz)	Determines application suitability
Stability (ppm)	Frequency deviation over temperature/time	System reliability indicator
Phase Noise	Short-term frequency fluctuations (dBc/Hz)	Critical for RF communication
Start-up Time	Time to reach stable oscillation	Power-sensitive applications
Operating Temperature	Functional temperature range	Environmental adaptability

5. Application Fields

Telecommunications: 5G base stations, optical transceivers
Consumer Electronics: Smartphones, wearables
Automotive: ADAS sensors, engine control units (ECUs)
Industrial: Test equipment, precision sensors
Aerospace: Satellite navigation systems, flight computers

Case Study

The SiTime SiT5358 MEMS oscillator ( 0.1ppm stability) enables 5G small cells to maintain synchronization within 1588v2 standards. Compared to traditional TCXO solutions, it reduces holdover drift by 80% while maintaining better vibration resistance.

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Specifications
Epson	TG-5500	32.768kHz TCXO, 0.03ppm stability
SiTime	SiT8924	0.1ppm MEMS oscillator with 70MHz output
TXC Corporation	7B-26.000MAAJ	26MHz VCXO for Bluetooth modules
Crystek	CFOV-950-100.000	100MHz OCXO with -145dBc/Hz phase noise

7. Selection Guidelines

Determine frequency requirements (fundamental vs overtone mode)
Evaluate stability needs (temperature range, aging tolerance)
Assess phase noise requirements (critical for high-speed ADC/DAC)
Consider package size (common: 2016, 3225, 5032)
Verify power consumption (important for IoT devices)
Select appropriate compensation method (TCXO vs OCXO)

8. Industry Trends

Key developments include:

MEMS oscillators replacing quartz in high-vibration environments
Integration of digital control (I2C programmable oscillators)
Development of sub-ppm stability at consumer price points
Miniaturization to meet wearable device demands
Increased adoption of differential output formats (LVPECL, HCSL)

The market is projected to grow at 6.8% CAGR through 2028, driven by 5G infrastructure and automotive electronics demand.