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Testing PSRR with High-Frequency Ripple

Power supply rejection ratio (PSRR) is an important parameter for many electronic systems because it measures system performance, enabling designers to verify a system meets required performance specification. This white paper discusses how to drive high-frequency sinusoidal ripple over capacitive loads for PSRR testing

By Anoop Joshi, Cadence Design Systems, Oct. 01, 2015 – 

Introduction

This white paper discusses a method for driving high-frequency sinusoidal ripple over capacitive loads for power supply rejection ratio (PSRR) testing, an important performance parameter for many electronic systems such as RF and wireless systems, power management systems, data converters, clocking systems, and high-speed serial interface systems. PSRR measures how well a circuit rejects ripple coming from input power supply at various frequencies, measuring system performance with a ripple (e.g., sinusoidal ripple) of specific amplitude and frequency added to the power supply, and verifying that it meets the required performance specifications.

One key factor while adding supply ripple is the presence of a decoupling capacitor at the supply pin. Systems usually have decoupling capacitors on all their supplies to decouple the power supply from the switching noise caused by switching currents across the PCB trace inductance. As the ripple frequencies increase, the shunt impedance to ground presented by the decoupling capacitors decreases and the current required to achieve a specific ripple amplitude across the capacitor increases. For example, for a 0.1μF decoupling capacitor, the impedance for a 1MHz ripple frequency is about 1/(Cω)=1.59Ω, which is fairly low. To achieve a 200mVpp (70.72mVrms) sinusoidal ripple amplitude at the supply pin with the decoupling capacitor in place requires a root mean square (RMS) current of 70.72mVrms/1.59 Ω, which is nearly 45mArms. As frequencies go even higher, the currents required will scale up accordingly. This makes the required ripple amplitudes somewhat difficult to achieve when driven by normally available signal sources or op-amp-based circuits, and may require high-performance components with high current driving capacity, wide signal bandwidths, and tolerance of high-capacitive loads-which may be expensive. Even with these components, it may not be easy to achieve the desired results, and the system may have stability issues due to the capacitance load, especially in op-amp-based approaches. An easy solution would be to remove the decoupling capacitors during the PSRR tests, but this may not be acceptable for highly automated test systems, where all the tests are supposed to run one after the other at the click of a button without any interruptions.

The circuits discussed in this white paper use the higher current drive capability of the DC power supplies by deriving the AC current for generating the ripple directly from the supplies, and thus isolate the signal source/ op-amp amplifier from the task of delivering this load current across the decoupling capacitors. In addition to the basic circuit used to drive a sine/square supply ripple at a supply pin without the decoupling capacitor in place, this white paper discusses two enhanced versions, one that drives a 1MHz sinusoidal 200mVpp supply ripple across a 0.1μF decoupling capacitor, and another that delivers a 30MHz sinusoidal 50mVpp supply ripple across a 0.1μF decoupling capacitor. All circuits have been simulated using Cadence® OrCAD® PCB Designer with PSPICE® tool.

Circuits

This white paper describes three circuits:

  1. Basic circuit for adding supply ripple (no decoupling capacitor)
  2. Circuit for adding supply ripple (with decoupling capacitor)
  3. Circuit for adding supply ripple at frequencies greater than 10MHz (with decoupling capacitor)/li>

Circuits 2 and 3 are modified versions of the basic circuit, and are both capable of driving a supply ripple even when a decoupling capacitor is present. This approach allows designers to leave the decoupling capacitors on the board during PSRR testing, saving time during the testing stage and enabling more automation.

Circuit 1: Basic circuit for adding supply ripple (no decoupling capacitor)

Figure 1 shows a basic circuit that drives a sine/square supply ripple without a decoupling capacitor. This circuit makes use of negative feedback to ensure that the ripple signal is an exact replica of the signal applied on the non-inverting terminal of the op-amp. It works well for even square wave ripple with faster rising edges and for high-ripple frequencies up to 100MHz, assuming appropriate high-speed op-amps and MOSFETS are chosen. However, because the output node is part of the negative feedback loop, supply decoupling capacitors must be removed for testing to avoid instability.

In this circuit, the signal required to be replicated at the supply pin is applied to the non-inverting input of the op-amp U1. For illustrative purposes, consider a case where a 1MHz 200mVpp sine/square ripple riding on a 3.63V DC supply is required. A 1MHz 200mVpp sine/square signal riding on 3.63V DC level is applied to the op-amp non-inverting input using a signal generator. The op-amp output drives the gate terminal of the N-channel enhancement MOSFET T1. The drain terminal of T1 is connected to a 10V DC supply (a 5V DC supply may be adequate, depending on the DC level required at the output). The source terminal of T1 is connected to the inverting input of U1, with the RC combination (consisting of R2, R3, and C1) connected between the source terminal and ground. The functionality of R1, R4, and R5 will be discussed later in this white paper. The final output signal appears at the source terminal, denoted by node VM1.

Once the required input signal is applied at the non-inverting op-amp input, the op-amp tries to replicate the same signal on the inverting input by resorting to negative feedback to reduce the difference or error between the inverting and non-inverting inputs. In this case, the inverting input is not directly connected to the op-amp output, but to the source terminal of T1, and op-amp output is connected to the MOSFET gate terminal. The op-amp can control how much the MOSFET turns on by setting the gate voltage to allow the MOSFET to turn on just enough so that the current that flows across it from drain to source (derived from the 10V DC supply) creates a voltage across the R2, R3, and C1 combination that closely mimics the voltage applied on the op-amp non-inverting terminal. Here, the MOSFET behaves somewhat like a voltage variable resistor controlled by Vgs. Thus, we replicate this signal at the output node, but the required current is fully delivered by the 10V DC supply and not by the op-amp or signal source.

When implementing this circuit in hardware, there are practical considerations that the designer must keep in mind to realize the performance achieved in simulations, such as choosing the proper components and reducing of the effects of board parasitics on circuit operation. Additional considerations are listed below:

Figure 2 shows the input and output waveforms from simulation for a 1MHz 200mVpp sine and square signal riding on 3.63V DC level. VM1 is the output and VM2 is the input. The output tracks the input closely, as both signals overlap almost perfectly in both cases.

Circuit 2: Adding supply ripple (with decoupling capacitor)

Figure 3 shows a circuit that drives a 1MHz 200mVpp sinusoidal supply ripple across a 0.1μF decoupling capacitor. This circuit does not require designers to remove the decoupling capacitor for PSRR testing, saving testing time and enabling more automation.

If a decoupling capacitor is added directly to the T1 source terminal in the circuit in Figure 1, a capacitor is connected directly to the inverting input of the op-amp, which contributes to a phase lag within the negative feedback loop. This affects the loop function and may make the circuit unstable, as shown in Figure 4. It is also difficult to compensate for this phase lag using phase lead compensation and other compensation methods, and will continue to affect the negative feedback operation to some degree.

To prevent the negative feedback loop being affected by the decoupling capacitor's capacitive load , an extra output stage with a MOSFET T2 identical to T1 is added as shown in Figure 3. The gate terminal of T2 is shorted to match T1 so that both receive the same gate voltage from the op-amp. An RC combination consisting of R4 and C2 (which is the decoupling capacitor) is connected between the source terminal of T2 and ground.

It is not as straightforward as simply shorting the gate signals of the 2 MOSFETS together. For just a DC level, we could use an R4 value that is the same as R2 and would receive an identical DC output. In this case, for the AC signal component, the load impedance present at the output of the second MOSFET is much lower compared to the first one due to the decoupling capacitor. This is calculated by ~1/(Cω), and is approximately 1.59Ω for a frequency of 1MHz and C=0.1uF. The AC current required to flow across the MOSFET to get a 100mV amplitude is likewise higher, i.e., a sinusoidal current of around 45mArms or around 64mA amplitude should flow across it. To allow for the full swing of this AC current, the DC current must be biased to a high enough value (at least 64mA) so that the AC current is not clipped during the negative cycle, as the current across the MOSFET cannot be negative. The circuit uses a much lower value of 50Ω for R, so that the DC current bias point is set high enough to allow for the full range of variation for the AC current. This is critical to make the output stage MOSFET react well enough to the gate signal to deliver the required AC current across the output load per the AC excitation, and to improve its linearity. Ensure R4 has the required power dissipation capability.

In turn, the DC and AC component of the gate excitation for T2 must be scaled sufficiently higher to achieve the required output. The easiest way to find the scaling required for the gate voltage's DC and AC components is to simulate using a simple circuit as shown in Figure 5 and find what DC and AC signal levels are required at the MOSFET gate to achieve the required DC and AC levels at the output. For example, for this circuit and components, the required gate input for a 1MHz 200mVpp sine wave riding on 3.63V DC level at the output is a 240mVpp sine wave signal of the same

This is achieved in Circuit 2 by using the indicated values for R2, R3, and R5. For the DC signal, the feedback point connected to the inverting input is taken from the junction of the resistive voltage divider formed by R2 and R5. The AC signal is taken from the junction of the voltage divider, which consists of R5 at the top and the parallel combination of R2 and R3. (The impedance of C1 is in series with R3, but at frequencies as high as 1MHz, the series combination would still be nearly equal to R3 as the capacitive reactance will be negligible in comparison.) This ensures that the DC and AC components in the op-amp output are individually scaled by the respective values required, and this signal is applied to the gates of both MOSFETs.

This architecture will not work well with square waves, as the amount of switching current required for getting sharp rising edges across the capacitive load will be too high, and the edges will start to slow down and become distorted. The scope for this circuit is restricted only to sinusoidal ripple.

Figure 6 shows the input and output waveforms from simulation of a 1MHz 200mVpp sinusoidal signal riding on 3.63V DC level. VM1 is the output and VM2 is the input. The output tracks the input fairly accurately even though there is a small phase shift, which should not be an issue.

Proper thermal management for the MOSFETs is important, because MOSFET power dissipation can be non-trivial especially at higher ripple frequencies or higher capacitance load values. MOSFET power dissipation can be calculated as IDS X VDS , where IDS is the drain to source current of the MOSFET and VDS is the drain to source voltage differential. Clearly, the choice of a lower drain voltage (e.g., 5V instead of 10V) can reduce this power dissipation. Designers should also reduce the MOSFET junction-to-ambient thermal resistance using good heat-sinking practices to minimize the internal temperature increases with power dissipation. This is required because MOSFET operating characteristics can be affected by temperature changes, and the performance may deviate from expectations if thermal management is not adequately managed. The goal should be to limit the junction temperature rise as much as possible for the given ripple amplitude,frequency specifications and decoupling capacitor value.

Circuit 3: Adding supply ripple at frequencies greater than 10MHz (with decoupling capacitor)

Figure 7 shows a circuit that drives a 30MHz 50mVpp sinusoidal supply ripple across a 0.1μF decoupling capacitor This circuit is an enhanced version of Circuit 2 shown in Figure 3 that is capable of driving comparatively higher ripple frequencies by using a much faster op-amp.

The Circuit 3 architecture uses a different op-amp than Circuit 2, with a much higher bandwidth (420MHz) and slew rate. This is required for the negative feedback to work fast enough to adequately track the input signal. If a lower bandwidth/slew rate op-amp is used, the input signal applied to the non inverting op-amp input may need to be scaled up to attain the desired output ripple amplitude. Also, the values for the R2, R3, and R9 resistors have been changed to set the appropriate scaling ratios for the AC and DC components of the signal. In addition, an even lower value of 10Ω has been used for R4 to account for the higher DC biasing current required to support the higher output swing for the AC current.

Figure 8 shows the simulation input and output waveforms for a 30MHz 50mVpp sinusoidal signal riding on 3.63V DC level. VM1 is the output and VM2 is the input. The output tracks the input fairly accurately even though there is a noticeable phase shift, which should not be an issue.

Note that, at high speeds (≥10MHz), the PCB layout, the choice of the components, and the parasitics of the components?especially the MOSFETs, trace parasitics, etc.?become extremely important. Also, supplying the right amount of current to achieve the desired ripple amplitude becomes more difficult as the speeds increase, because the impedance across which the ripple voltage is to be generated scales down with the ripple frequency. For instance, at 30MHz, the load impedance becomes ~53mΩ, so the load current required to achieve a particular ripple amplitude becomes that much higher. Also, if you are using a current feedback op-amp as in this case, you have to carefully follow the circuit recommendations, usually given in the datasheets for such amplifiers. For example, do not use a feedback resistor with a value less than the suggested value (in this circuit, R9 can be considered the feedback resistor), and ensure the board parasitic capacitance at the op-amp pins is low enough by removing the ground planes from beneath them. Also make sure that the DC power supply can drive the required output current.

Conclusion

Affecting PSRR measurements with the decoupling capacitors in place for the supplies can be challenging. This white paper discusses how to insert high-frequency ripple on a DC supply to affect PSRR measurements without removing the decoupling capacitor on the supply pin. This capability is especially important in highly automated test and measurement systems where all the tests are run on batches of devices without changing the hardware setups. With this solution, designers can avoid spending the time and money required to implement a dedicated PSRR test hardware setup without decoupling capacitors. To ensure the most effective circuit, designers should pay attention to the practical considerations such as optimal component choice, proper thermal management practices, and reduction of board parasitics.

References

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