SLYT823 March   2022 LM25149-Q1

 

  1. 1Introduction
  2. 2AEF compensation
  3. 3AEF damping
  4. 4AEF performance with both compensation and damping
  5. 5Conclusion
  6. 6References
  7. 7Related Websites

2 AEF compensation

Figure 2-1(a) shows an AEF with no compensation. In Figure 2-1, VS is a noise source, ZS is the internal impedance, ZL represents the impedance of line-impedance stability networks or power sources, Cin represents the input capacitors of power converters, L is the differential-mode inductor, Csense and Cinj are the sensing and injection capacitors, RDC_fb is to provide DC feedback for the Op_amp and Cpara is the parasitic capacitance between the power trace and ground.

As an op amp-based feedback circuit, the AEF in Figure 2-1(a) could become unstable, which would saturate the op amp. In such cases, the performance of the AEF could be significantly affected, and the AEF may consume more power and inject extra noise into the system [3]. Since the loading network of the op amp is complex, the AEF in Figure 1a could be unstable at both low and high frequencies.

At low frequencies (such as between 10 kHz and 50 kHz), the phase of the loop gain can go to positive 180 degrees and the system can become unstable, primarily because of the voltage dividers formed by Cinj and L, and by Csen and RDC_fb. One method for low-frequency compensation is to add Rcomp and Ccomp in parallel with RDC_fb, as shown in Figure 2-1(b). Ccomp is for low-frequency compensation by making the feedback network capacitive at low frequencies. Rcomp is to ensure the performance of the AEF. In addition, there are typically electrolytic capacitors at the input of the converter to store energy and ensure converter stability. The equivalent series resistance (ESR) of the electrolytic capacitors also helps with low-frequency stability.

Figure 2-1 An AEF with no compensation (a); with compensation (b).

At high frequencies, the output impedance of the op amp and Cpara will generate a pole and cause phase lag of the loop gain. In addition, op amps typically have a low-frequency pole. As a result, the loop gain will have two poles at high frequency and its phase goes close to negative 180°, which can cause high-frequency instability. Rcomp1 and Ccomp1 in Figure 2-1(b) are for high-frequency compensation, which can be 100 nF and 0.5 Ω. Rcomp1 and Ccomp1 can boost the phase of the loop gain at high frequencies so that the system has enough phase margin to ensure high-frequency stability. In certain applications, high-frequency ceramic capacitors (such as 10 nF or 100 nF) are necessary for high-frequency noise filtering or for protection circuits, such as smart diodes for reverse protection. In such cases, there are several ways to maintain high-frequency stability:

  • Insert ferrite beads between the sense/inject node and the high-frequency ceramic capacitors to decouple them.
  • Add small resistors in series with the high-frequency capacitors for compensation.
  • Place high-frequency capacitors far from the AEF, since the ESRs and equivalent series inductances (ESLs) of the ceramic capacitors and printed circuit board traces can also help with high-frequency stability.

Overall, it is essential to make sure that the impedance of the sense/inject node to ground is not dominated by capacitance at high frequencies (between 10 MHz to 50 MHz).