The antialias filter consists of a passive first-order input filter, an active second-order filter, and a passive first-order output filter. The filter is fourth-order overall, necessitated by the selection of a low value of OSR (32). OSR 32 results in less than two decades of frequency range between the Nyquist frequency at f_DATA and the f_MOD frequency. The fourth-order filter provides 90dB rolloff over this frequency range. The filter rolloff at f_MOD is the key function of the filter.

The THS4551 amplifier is selected for the active filter stage because of the 135MHz gain-bandwidth product (GBP) and 50ns settling time. The amplifier GBP is sufficient to maintain the filter rolloff at 12.8MHz, even with the dc gain of 15dB. For example, for applications where gain is desired, a 10MHz amplifier has marginal GBP to fully support the required rolloff at the f_MOD frequency. The settling time specification of the THS4551 also makes the device a good choice for driving the ADC sampled inputs.

The design of the active filter section begins with an equal-R assumption to reduce the number of determined component values. The dc gain of the filter is R₃ / (R₁ + R₂). Use of 1kΩ resistors are low enough to keep resistor noise and amplifier input current noise from affecting the noise of the ADC.

The 1kΩ input resistor is divided into two 499Ω resistors (R₁ and R₂) to implement the first-order filter using C₁. The first-order filter is decoupled from the second-order active filter, but shares R₁ and R₂ to determine each filter stage corner frequency. The corner frequency is given by C₁ and the Thevenin resistance at the terminals of C₁ (R_TH = 2 × 250Ω).

The Design Methodology for MFB Filters in ADC Interface Applications application note provides filter design equations used in this example. The design inputs are filter f_O and filter Q for the multiple-feedback active filter topology. Given an arbitrary selection of R₄, the values of the C₃ feedback capacitors and the single 330pF differential capacitor (C₂) are determined. R₄ is 2 × 499Ω and C₃ is 2 × 180pF in this case. The differential capacitor (C₄) is not part of the filter design but helps improve filter phase margin. The 5Ω resistors (R₅) isolate the amplifier outputs from stray capacitance to further improve filter phase margin.

The final stage RC filter at the ADC inputs serves two purposes. First, the filter provides a fourth pole to the overall filter response, thereby increasing the filter rolloff. The other purpose of the filter is a charge reservoir to filter the capacitor sampled input of the ADC. The charge reservoir reduces the instantaneous charge demand of the amplifier, maintaining low distortion and low gain error that otherwise degrades from incomplete amplifier settling. The input filter values are 2 × 22Ω and 2.2nF. The 22Ω resistors are outside the THS4551 filter loop to isolate the amplifier outputs from the 2.2nF capacitor to maintain phase margin.

Low voltage-coefficient C0G capacitors are used everywhere in the signal path for the low distortion properties. The amplifier gain resistors are 0.1% tolerance to provide best possible THD performance. The ADC VCM output connection to the amplifier VOCM input pin is optional because the same function is provided by the amplifier.

See the THS4551 data sheet for additional examples of active filter designs and application.