The CGA4J3X5R1H225KT0Y0N is a multilayer ceramic capacitor (MLCC) manufactured by TDK Corporation. This capacitor is designed for high-capacitance, general-purpose applications, providing stable and reliable performance in a compact package.

Applications:

• Bypass Capacitors: Filtering noise and stabilizing voltage in various electronic circuits.
• Decoupling Capacitors: Reducing noise on power rails for integrated circuits.
• Smoothing Capacitors: Reducing ripple in power supplies.
• General Electronic Devices: Suitable for use in consumer electronics, industrial equipment, and automotive applications.
• Power Supply Circuits: Providing stable power for sensitive components.

Features:

• Capacitance: 2.2 µF (225)
• Voltage Rating: 50 V (1H)
• Temperature Characteristic: X5R (Stable capacitance over temperature)
• Tolerance: ±10% (K)
• Size Code: 1210 (EIA) / 3225 (JIS)
• Termination: Nickel barrier with tin plating
• RoHS Compliant: Complies with Restriction of Hazardous Substances directive.

Benefits:

• Stable Capacitance: X5R dielectric provides stable capacitance over a wide temperature range (-55°C to +85°C).
• High Capacitance Value: 2.2 µF capacitance in a compact 1210 package.
• Reliable Performance: TDK's high-quality manufacturing ensures consistent and reliable performance.
• RoHS Compliance: Environmentally friendly composition, meeting regulatory requirements.
• Versatile Applications: Suitable for a broad range of general-purpose applications.
• Cost-Effective: Provides a high-performance solution at a competitive price.

Additional Details:

The CGA4J3X5R1H225KT0Y0N utilizes TDK's advanced ceramic material technology to ensure stable and reliable performance. The X5R dielectric ensures that the capacitance remains relatively stable over the operating temperature range, making it suitable for demanding applications. The nickel barrier termination provides excellent solderability and prevents silver leaching during soldering. This capacitor is commonly used in a variety of electronic devices where high capacitance and stable performance are required.