Pin Configurable/Selectable Oscillators

Image	Part Number	Description / PDF	Quantity	Rfq
	512CCA001032AAGR Silicon Labs	XTAL OSC XO 3.3V 6SMD	0
	534AC002464DG Silicon Labs	XTAL OSC XO 3.3V 8SMD	0
	547BAA002534BBG Silicon Labs	XO DIFF QUAD FREQ 0.2-1500MHZ	0
	547DAB002465BBG Silicon Labs	XTAL OSCILLATOR	0
	513ABA000346AAGR Silicon Labs	XTAL OSC XO 3.3V 6SMD	0
	532QC000809DGR Silicon Labs	XTAL OSC XO 3.3V 6SMD	0
	552BF000270DG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	552AG000403DGR Silicon Labs	DIFFERENTIAL/SINGLE-ENDED	0
	552AD000112DG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	534EC000533DG Silicon Labs	XTAL OSC XO 2.5V 8SMD	0
	552CE000270DGR Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	516BHB000132AAG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	552AA000374DG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	554CC000189DG Silicon Labs	XTAL OSC VCXO 3.3V 8SMD	0
	552CF000174DG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	552AE000164DG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	532AA000857DG Silicon Labs	XTAL OSC XO 3.3V 6SMD	0
	552AJ000230DG Silicon Labs	XTAL OSC VCXO 3.3V 6SMD	0
	554AC000405DG Silicon Labs	XTAL OSC VCXO 3.3V 8SMD	0
	532BA000043DGR Silicon Labs	XTAL OSC XO 3.3V 6SMD	0

Pin Configurable/Selectable Oscillators

1. Overview

Pin configurable/selectable oscillators are frequency generation devices that allow users to adjust output parameters (frequency, mode, or configuration) through physical pin settings or control signals. Unlike fixed-frequency oscillators, these devices offer flexibility for multi-application use cases. Their importance stems from adaptability in modern electronics, including communication systems, industrial automation, and IoT devices, where dynamic frequency adjustments reduce component redundancy and simplify design scalability.

2. Major Types and Functional Classification

Type	Functional Characteristics	Application Examples
Frequency Selectable Oscillators	Switch between predefined frequencies via pin voltage levels or logic inputs	Wireless base stations, multi-band routers
Pin-Controlled Multi-Frequency Oscillators	Support continuous frequency tuning through analog voltage or digital codes on control pins	Test equipment, software-defined radios
Programmable Selectable Oscillators	Use I C/SPI interfaces for configuration storage and dynamic frequency changes	Embedded systems, industrial controllers
Temperature-Compensated Pin Configurable Oscillators	Combine pin-selectable frequencies with onboard temperature compensation circuits	Automotive sensors, precision instrumentation

3. Structure and Components

A typical pin configurable oscillator consists of:

Quartz crystal/resonator as the primary frequency reference
Voltage-Controlled Oscillator (VCO) core with programmable dividers
Digital/analog control circuits for pin input decoding
Output drivers (CMOS, LVDS, or LVPECL standards)
On-chip memory for configuration retention (in programmable types)

4. Key Technical Specifications

Parameter	Typical Values	Importance
Frequency Range	1kHz - 1GHz	Determines application suitability
Stability	20ppm to 100ppm	Impacts long-term reliability
Operating Temperature	-40 C to +125 C	Environmental robustness
Supply Voltage	1.8V - 5.5V	Compatibility with system power rails
Phase Noise/Jitter	0.1ps RMS to 1ps RMS	Critical for high-speed signaling
Configuration Time	1ms - 100ms	System responsiveness factor

5. Application Fields

Major industries include:

Telecommunications: 5G NR base stations, optical transceivers
Industrial: Precision test equipment, PLC controllers
Consumer: Smartphones with multi-network support
Automotive: ADAS radar systems, ECU clocking
Medical: MRI timing circuits, patient monitoring devices

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Key Features
Texas Instruments	LMK00304	4-channel output, 100fs jitter
STMicroelectronics	VCO1000	1MHz-1GHz tuning range
Microchip Technology	DSC6000	MEMS-based programmable oscillator
NXP Semiconductors	FXLS8971	Low-power accelerometer-coupled clocking
Renesas Electronics	IDT5P49V60	PCIe Gen4 compliant timing solution

7. Selection Guidelines

Key considerations:

Frequency requirements: Range, step size, and switching speed
Control interface: Hardware pin control vs. digital programming
Environmental conditions: Temperature, vibration, and EMI tolerance
Power constraints: Supply voltage and consumption limits
Package compatibility: Footprint and thermal management needs
Cost vs. performance trade-offs

8. Industry Trends

Future developments focus on:

Higher integration with clock distribution functions
Sub-picosecond jitter performance for 800Gbps+ optical systems
AI-driven frequency optimization in smart devices
Automotive-grade devices meeting AEC-Q100 standards
Green manufacturing with lead-free packaging