The CC0402CRNPO9BN2R2L is a multilayer ceramic capacitor (MLCC) manufactured by Yageo. This capacitor features a 2.2 pF capacitance value, a NPO (C0G) dielectric material, and a 50V voltage rating. It is available in a 0402 case size, making it suitable for high-density circuit designs.

Applications

• Mobile phones: Filtering, decoupling, and tuning in RF circuits.
• Wireless communication devices: Used in impedance matching and filtering networks.
• High-frequency circuits: Suitable for applications requiring stable capacitance at high frequencies.
• Consumer electronics: Used in various electronic devices for signal filtering and decoupling.
• Medical devices: Ensuring stable and reliable performance in medical equipment.

Features

• NPO (C0G) dielectric: Offers excellent capacitance stability over temperature and voltage.
• Small 0402 case size: Enables high-density circuit designs.
• High Q factor: Provides low energy loss at high frequencies.
• Low ESR (Equivalent Series Resistance): Minimizes power dissipation in high-frequency circuits.
• RoHS compliant: Meets environmental regulations for hazardous substances.

Benefits

• Stable performance: The NPO dielectric ensures consistent capacitance over a wide range of temperatures and voltages.
• Compact design: The small 0402 case size allows for the creation of smaller and more efficient electronic devices.
• Improved signal integrity: The high Q factor and low ESR minimize signal distortion and power loss.
• Reliable operation: The robust construction and stable performance ensure dependable operation in demanding applications.
• Environmentally friendly: The RoHS compliance ensures that the capacitor is free from hazardous substances.

Additional Details

The Yageo CC0402CRNPO9BN2R2L has a capacitance tolerance of ±0.1 pF. The operating temperature range is typically -55°C to +125°C. The capacitor is designed for surface mount technology (SMT) assembly. The termination is typically nickel barrier with tin plating. The self-resonant frequency is very high due to the small size and low capacitance.