Industry analysts have identified the system trends of portability, “green” energy reduction, and more sensors in end equipment. These trends drive the need for higher channel count, higher speed, and higher performance from analog-to-digital converters (ADCs) and digital-to-analog converters (DACs), while still demanding lower power budgets, smaller size, and lower cost.
Data converter manufacturers are responding to these demands by creating more data converters that are integrated with other circuit components. While many microcontroller cores are surrounded by a rich set of peripherals, some performance demands are driving the creation of specific analog front ends or other analog “companion” chips that work together with a separate processor.
For example, the Texas Instruments ADS1298 is a complete front end for electrocardiogram (ECG) systems. It packs eight 24-bit ADCs with programmable gain amplifiers (PGAs) and a host of ancillary circuitry into a single ball-grid array (BGA) or thin quad flat pack (TQFP) package.
As data converters become part of an integrated system in a single package, they tend to become more application-specific. The datasheet for the ADS1298 refers to many specific functions and terminology that manufacturers outside the ECG equipment space may not be familiar with. Does that mean that you can only use the ADS1298 for ECG applications?
Links In The Signal Chain
Looking at these integrated devices, as well as how they can benefit your system, is simply a matter of breaking them down and seeing how they implement what is called the signal chain (see the figure). In fact, the block diagram could represent just about any system that processes a signal.
If it’s a measurement or data acquisition system, then the chain starts at the sensor, proceeds through signal conditioning circuitry, into an ADC, and then ends with the processor. If it’s a control system, an audio processing system, or even a software-defined radio, then there is likely some output from the processor that must be turned back into an analog signal, as shown in the right half of the diagram.
Regardless of the type of system you need to design, there’s a good approach to deciding on the components that realize your signal chain. Generally, the processor is the first component selected. This selection usually is made based on familiarity with the device (it’s one your company has used for previous designs) or for a certain set of peripherals and capabilities that it offers. Thus, you begin at the center of the diagram and work your way outward.
This would imply that the data converter is the next choice, and it’s a logical place to start with the analog circuitry. Let’s assume we’re designing a measurement system, so we’re only dealing with an ADC. The big decisions here are how much resolution you need for your measurement and how fast you need to measure things.
There’s a number of other things to consider, of course, but the big two are speed and resolution. Notice that I haven’t said anything about how many bits the data converter has yet—just how much, in physical parameters, you need to resolve in your measurement. At this point it’s better to say that your measurement system needs to resolve at least 250 ppm, rather than decide on a 12-bit converter.
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