The SiT3702AC-J4-33-K-13.560000D is a precision MEMS oscillator from SiTime, designed to provide a stable and accurate clock signal for a variety of electronic systems. Utilizing advanced MEMS (Micro-Electro-Mechanical Systems) technology, this oscillator delivers exceptional frequency stability, low jitter, and robustness over a wide range of operating conditions.

Applications:

• Wireless communication devices
• Industrial control systems
• Medical devices
• Automotive electronics
• High-performance microprocessors and microcontrollers

Features:

• MEMS resonator for superior stability and reliability
• Frequency of 13.56 MHz
• Frequency stability of ±25 ppm
• Operating temperature range of -40°C to +85°C
• Low jitter for enhanced signal integrity
• Supply voltage of 3.3V
• Small form factor package

Benefits:

• Highly accurate and stable clock signal for reliable system operation
• Robust performance in harsh environments due to MEMS technology
• Improved signal integrity and reduced noise with low jitter
• Simplified circuit design with integrated load capacitors
• Enhanced energy efficiency due to low power consumption
• Long-term reliability, minimizing downtime and maintenance costs

Additional Details:

The SiT3702AC-J4-33-K-13.560000D oscillator employs a silicon-based MEMS resonator, which offers significant advantages over traditional quartz crystals in terms of stability, shock resistance, and vibration immunity. The integrated load capacitors simplify circuit design and reduce the need for external components. The oscillator is available in a compact package, making it suitable for space-constrained applications. Its low power consumption contributes to improved energy efficiency and longer battery life in portable devices. The device is ideal for applications requiring a precise and stable clock source with excellent environmental performance and long-term reliability. The specified frequency of 13.56 MHz is commonly used in RFID (Radio-Frequency Identification) and NFC (Near-Field Communication) applications.