The 0603CS-R1OXJLW is a ceramic wirewound chip inductor manufactured by Coilcraft, designed for radio frequency (RF) and microwave applications. This inductor is characterized by its high Q factor, tight tolerance, and stable performance, making it suitable for critical circuits where precision is essential. It is designed to meet the rigorous demands of modern wireless communication and electronic devices.

Applications

• RF filters for signal conditioning
• Impedance matching networks to maximize power transfer
• Wireless communication systems, including transceivers
• Mobile devices, such as smartphones and tablets
• GPS receivers for navigation systems
• Satellite communication equipment for reliable signal transmission
• RFID readers for identification and tracking
• Broadband amplifiers for signal boosting

Features

• High Q factor for low signal loss
• Tight inductance tolerance for precise circuit tuning
• Ceramic construction for thermal stability and reliability
• Wirewound design for high current handling capability
• Compact 0603 package size for space-constrained applications
• RoHS compliant, adhering to environmental standards

Benefits

• Improved RF circuit performance due to minimal signal loss
• Accurate circuit behavior due to tight tolerance
• Stable performance across temperature variations
• Suitable for high-current circuits
• Reduced board space requirements due to small size
• Environmentally responsible choice

Additional Details

The 0603CS-R1OXJLW inductor has an inductance value of 0.1uH (100nH). Its self-resonant frequency (SRF) is designed to be high, allowing it to operate effectively at the desired frequencies. The operating temperature range is typically from -55°C to +125°C. The construction includes a ceramic core and wire winding, which contribute to its high Q factor and stable performance. It is designed for automated assembly processes, which reduces manufacturing costs. This inductor's combination of performance characteristics and small size makes it a valuable component for modern RF circuit designs.