SNVSCF4 Data sheet

SNVSCF4 July 2025 LM25139-Q1

PRODUCTION DATA

Package Options

Mechanical Data (Package|Pins)

RGT|16
- MPQF119H

Thermal pad, mechanical data (Package|Pins)

RGT|16
- QFND802A

Orderable Information

7.1.2 Error Amplifier and Compensation

Figure 7-3 shows a type-ll compensator using a transconductance error amplifier (EA). The dominant pole of the EA open-loop gain is set by the EA output resistance, R_O-EA, and effective bandwidth-limiting capacitance, C_BW, as shown by Equation 25.

Equation 25.

G_{E A (o p e n l o o p)} (s) = - \frac{g_{m} \times R_{O - E A}}{1 + s \times R_{O - E A} \times C_{B W}}

The EA high-frequency pole is neglected in the above expression. Equation 26 calculates the compensator transfer function from output voltage to COMP node, including the gain contribution from the (internal or external) feedback resistor network.

Equation 26.

G_{c} (s) = \frac{{\hat{v}}_{c} (s)}{{\hat{v}}_{o u t} (s)} = - \frac{V_{R E F}}{V_{O U T}} \times \frac{g_{m} \times R_{O - E A} \times (1 + \frac{s}{ω_{z 1}})}{(1 + \frac{s}{ω_{p 1}}) \times (1 + \frac{s}{ω_{p 2}})}

where

V_REF is the feedback voltage reference of 0.8V.
g_m is the EA gain transconductance of 1.1mS.
R_O-EA is the error amplifier output impedance of 10MΩ.

Equation 27.

ω_{z 1} = \frac{1}{R_{C O M P} \times C_{C O M P}}

Equation 28.

ω_{p 1} = \frac{1}{R_{O - E A} \times (C_{C O M P} + C_{H F} + C_{B W})} ≅ \frac{1}{R_{O - E A} \times C_{C O M P}}

Equation 29.

ω_{p 2} = \frac{1}{R_{C O M P} \times (C_{C O M P} | | (C_{H F} + C_{B W}))} ≅ \frac{1}{R_{C O M P} \times C_{C O M P}}

The EA compensation components create a pole close to the origin, a zero, and a high-frequency pole. Typically, R_COMP << R_O-EA and C_COMP >> C_BW and C_HF, so the approximations are valid.

LM25139-Q1 Error Amplifier
and Compensation Network

Figure 7-3 Error Amplifier and Compensation Network