The TSL1112S-153JR12-PF is a shielded wire-wound ceramic chip inductor manufactured by TDK Corporation. Designed for high-frequency applications where minimizing electromagnetic interference (EMI) is critical, this inductor provides stable inductance and a high Q-factor. Its compact size and robust construction make it suitable for integration into dense electronic devices.

Applications:

• RF filters in mobile communication devices.
• Wireless LAN (WLAN) applications.
• Bluetooth modules.
• Impedance matching circuits.
• Noise suppression in high-frequency circuits.

Features:

• Shielded wire-wound construction.
• Compact 1112 case size.
• High Q-factor for low losses.
• Inductance value of 15 μH.
• High self-resonant frequency (SRF).
• RoHS compliant.

Benefits:

• Reduced electromagnetic interference (EMI).
• Improved RF signal quality due to low losses.
• Stable performance in high-frequency circuits.
• Space-saving design for compact devices.
• Reliable operation under various environmental conditions.

Additional Details:

The TSL1112S-153JR12-PF features a nominal inductance of 15 μH (microhenries) with a tolerance of ±5%. The 1112 case size denotes its compact dimensions, facilitating its use in densely populated circuit boards. The shielded wire-wound construction is key to minimizing electromagnetic interference, ensuring clean signal transmission and reception. Its high Q-factor minimizes energy losses in high-frequency circuits. The self-resonant frequency (SRF) is optimized to ensure effective performance at target frequencies. The rated current is approximately 80mA. The inductor is designed to withstand reflow soldering temperatures, making it compatible with modern automated assembly processes. Its operating temperature range generally spans from -55°C to +125°C. The ‘PF’ suffix denotes that the component is lead-free and complies with RoHS environmental standards. By providing both stable inductance and effective EMI shielding, the TSL1112S-153JR12-PF enhances the overall performance and reliability of electronic devices.