JAJSJI6B December 2020 – January 2023 LM25149-Q1
PRODUCTION DATA
Active EMI filtering uses a capacitive multiplier to reduce the magnitude of the LC filtering components. Extra compensation components are needed, but the reduction in LC size outweigh the required network. The active EMI filter design steps are as follows:
The active EMI filter is intended to cancel differential-mode noise in steady-state conditions. Large pertubations or low-frequency transients on the VIN-EMI node can potentially limit the amplifier noise canceling ability.
Use Equation 21 to determine the attenuation required. Table 9-4 lists the recommended compensation and sensing component values. Use low FSW component values if FSW ≤ 1 MHz and high FSW component values if FSW > 1MHz.
AEF COMPONENT | LOW FSW | HIGH FSW | DESCRIPTION |
---|---|---|---|
CSEN | 0.1 µF | 0.1 µF | Sensing capacitor |
RAEFC | 1 kΩ | 200 Ω | Compensation |
CAEFC | 1 nF | 5 nF | Compensation |
RINC | 0.47 Ω | 0.47 Ω | Compensation |
CINC | 0.1 µF | 0.1 µF | Compensation |
RAEFVDD | 3 Ω | 3 Ω | Decoupling |
CAEFVDD | 2.2 µF | 2.2 µF | Decoupling |
Select the desired LIN. Determine the Active EMI filter capacitance CINJ from Equation 26.
Determine the Active EMI damping resistor RDAMP from Equation 27.
Determine the Active EMI damping capacitance CDAMP from Equation 28. CDAMP is not needed for FSW > 1 MHz.