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LDO PSRR Measurement Simplified
What is PSRR?
Power Supply Rejection Ratio or Power Supply Ripple Rejection (PSRR) is a measure of a circuit's power
supply's rejection expressed as a log ratio of output noise to input noise. PSRR provides a measure of
how well a circuit rejects ripple, of various frequencies, injected at its input. The ripple can be either from
the input supply such as a 50Hz/60Hz supply ripple, switching ripple from a DC/DC converter, or ripple
due to the sharing of an input supply between different circuit blocks on the board. In the case of LDOs,
PSRR is a measure of the regulated output voltage ripple compared to the input voltage ripple over a wide
frequency range (10Hz to 1MHz is common) and is expressed in decibels (dB). The PSRR is very critical
parameter in many audio and RF applications.
Measuring PSRR of LDO
The following sections explain different methods of measuring the PSRR of an LDO.
1. Measuring PSRR using LC summing node method:
The basic method of measuring PSRR is shown in Figure 2. In this method, DC voltage and AC
voltages are summed together and applied at the input of the LDO. VDC is the operating point bias
voltage and VAC is the noise source used in the test. Capacitor C prevents VAC from shoring VDC
and inductor L prevents VDC from shorting VAC. So L and C are used for isolating both the sources,
VDC and VAC, from each other.
The L and C will create a high pass filter for VAC which will limit how low in frequency we can measure
the PSRR. The 3dB point of this filter is determined by Equation 2. Frequencies below the 3dB point
will start to be attenuated which will make measurements more difficult. The highest frequency that can
be measured is determined by the self resonant frequencies of the L and C components.
Fmin = 1/ 2Π √LC (2)
A drawback to this method is that it works well only for mid-range frequencies (approximately 1 kHz to
500 kHz).
2. Measuring PSRR using summing amplifier
To improve the measurement of PSRR, a recommended method is described using a high-bandwidth
amplifier as summing node to inject the signals and provides the isolation between VAC and VDC. This
method is tested and verified using TPS72715 LDO and THS3120 high-speed amplifier from Texas
Instruments. The basic set-up is shown in Figure 3. The PSRR is measured with a no-load condition
and the resulting measured PSRR graph corresponds with the datasheet graph of PSRR.
Keep in mind the following while measuring the PSRR using this method:
a. The input capacitor of LDO should be removed before the measurement because this capacitor
could cause the high-speed amplifier to go unstable.
b. Vin and Vout should be measured with high-impedance probes (either scope or network analyzer)
immediately at the Vin or Vout pins to minimize the set-up inductance effects.
c. There test set-up should not have any long wires since this will add inductance and impact the
results.
d. While selecting the values of AC and DC inputs, the following conditions should be considered:
VAC (max) + VDC < VABS (max) of LDO
VDC � VAC > VUVLO of LDO
Also, the best results will be obtained if:
VDC�VAC>Vout + Vdo + 0.5 where Vout is the output voltage of the LDO and Vdo is the
specified drop out voltage at the operating point.
e. At very high frequencies, the response of the amplifier will start to attenuate the VAC signal that is
applied to the LDO. At some point, the attenuated VAC will be too small to measure on the output
of the LDO.
f. As load current increases, the open-loop output impedance of LDO decreases (Since a MOSFET
output impedance is inversely proportional to the drain current), thus lowering the gain. Increasing
the load current also pushes the output pole to higher frequencies, which increases the feedback
DatasheetDoc-Texas Instruments TI pdf datasheet download
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