The 23Z104SM is a common mode choke manufactured by Pulse Electronics. Common mode chokes are passive electronic components used to suppress common-mode noise while allowing differential signals to pass through with minimal attenuation. They are essential for reducing electromagnetic interference (EMI) and improving signal integrity in electronic circuits.

Applications:

• Power line filtering
• USB interfaces
• CAN bus systems
• Ethernet interfaces
• Signal line filtering

Features:

• High common mode impedance
• Low differential mode impedance
• Compact size
• Wide frequency range
• High current capacity
• RoHS compliant

Benefits:

• Effective suppression of common-mode noise.
• Minimal attenuation of differential signals.
• Improved EMI performance.
• Enhanced signal integrity.
• Reduced electromagnetic interference.
• Increased system reliability.

Additional Details:

The 23Z104SM is designed to provide high common-mode impedance over a broad frequency range, effectively blocking unwanted noise that propagates equally on multiple conductors. Simultaneously, it presents a low differential-mode impedance, allowing the desired signals to pass through with minimal loss. This characteristic is crucial in maintaining signal quality and preventing data corruption. The choke's compact size makes it suitable for use in space-constrained applications. Its high current capacity enables it to handle significant current levels without saturation or performance degradation. The device is compliant with RoHS standards, ensuring that it does not contain hazardous substances. It is commonly used in various communication and data transmission systems to improve their electromagnetic compatibility (EMC) performance. The specific impedance characteristics and current ratings of the 23Z104SM are detailed in the manufacturer's datasheet. It is often used in combination with other filtering components to achieve optimal EMI suppression. Its robust construction and reliable performance make it a popular choice for applications requiring high levels of noise immunity and signal integrity.