- Must I consider high frequency issues when driving a slow ADC?
Because things are not always what they seem. Consider the quagga - the last one died in Amsterdam zoo on the 12th August 1883 and they have long been considered extinct. Recent genetic research on the remains of a number of quaggas show that they were not a separate species, but a pattern variant of the basic African plains zebra. There is a good chance that a selective breeding program can resurrect the quagga, allowing it to be returned to its former habitat. This project is now in hand and the results, which I hope to have seen by the time you read this, are very encouraging
Similarly a "dc" ADC input is often nothing of the sort. The analog inputs of many different types of ADCs contain switched capacitors. Sometimes they are buffered with amplifiers, but generally the circuits driving the ADC input terminals must tolerate the fast transient currents that flow as the capacitors are switched. The repetition rate of these current pulses may be the system sampling clock frequency, but sometimes it is the much higher conversion clock frequency of the ADC. If the input interface cannot tolerate these fast current pulses, there is a serious risk that the system will malfunction and suffer from nonlinearity, or even missing codes.
We can handle the problem in two ways. The simplest is to place a capacitor between the ADC input and ground, allowing the transient currents to flow in the capacitor rather than in the drive circuit. The alternative is to use a driver/interface circuit that can tolerate fast current transients.
If we use the capacitor, we may be reducing our system's frequency response. It is important, if we use this approach, to ensure that the circuitry driving the ADC input will be stable with the additional capacitive load, and that the system bandwidth will still be as large as necessary.
If we choose to use a drive circuit capable of handling the transients without an added capacitor, we must confirm (probably by experiment - spice macro models may not be detailed enough to predict the effect of such fast transients) that the amplifier or other driver will handle the transients over the whole input dynamic range, as the pulse amplitude may well vary with input level.
It is also very important to remember that the reference input of an ADC has the same structure as the signal input - and may have similar transients. The load capacitor of the reference IC normally prevents adverse effects - but some voltage references are promoted as "not needing output capacitors." This may be true when they are used with resistive loads, but is certainly not true when these transient currents are present.
Download this article (pdf)
Have an interesting question?... Ask James!
Visit our Rarely Asked Questions library for a complete listing of all our RAQs.
For More Information:
A/D Converters Home Page
AD7356 Differential Input, Dual, 5 MSPS, 12-Bit, SAR
AD7980 16-bit, 1 MSPS PulSAR® ADC in MSOP/QFN
AD9640 14-bit, 80/105/125/150 MSPS, 1.8 V Dual ADC
AD9254 14-Bit, 150 MSPS, 1.8 V Analog-to-Digital Converter
View ADI's ADC Drivers