SSZTBY7 November   2015 ADC3244

 

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    2.     How the Chopper Feature Works
    3.     The Chopper in Action
    4.     Additional Resources

Thomas Neu

Until recently, industrial applications such as precision motor control or plasma etchers couldn’t take full advantage of modern high-speed data converters. Because these systems monitor a small input signal at a few hundred kilohertz and its even smaller harmonics, they are very sensitive to the 1/f noise or flicker noise of the high-speed data converter (see Figure 1).

GUID-1B2FAE03-63E3-4733-9519-44538879E8B1-low.jpg Figure 1 Wanted Signal and Its Harmonics in the Presence of 1/F Noise

Unfortunately for these applications, high-speed analog-to-digital converters (ADCs) are moving toward finer, more advanced process geometries. The 1/f noise corner of bipolar transistors is around 100kHz; for complementary metal-oxide semiconductor (CMOS) transistors (depending on actual process geometry), it is around 10MHz or greater. So the 1/f noise corner of CMOS ADCs is significantly worse/higher compared to bipolar transistors and directly overlaps with the very-low-frequency input range used in many industrial applications.

You can overcome this limitation, however, with a clever but very effective design feature called a chopper front end. Many designers of industrial applications are already finding the new ADC3k family because it is outfitted with an internal chopper front end.

How the Chopper Feature Works

The name “chopper” originated many years ago from a circuit that converted a DC voltage input into a variable DC output voltage. In modern electronics, all kinds of different switching circuits that shift unwanted noise around are labeled as chopper circuits.

In the ADC3k, the key idea of the chopper is to transfer the 1/f noise to a different frequency range, away from the input signal close to DC. The chopper circuit basically consists of a passive mixer (operating at half the sampling rate) plus some digital logic. Instead of shifting the 1/f noise away, the passive mixer basically inverts the input-frequency spectrum prior to the sampling instant. Thus, it transfers the low-frequency input signal to the opposite end of the Nyquist zone of the ADC. After sampling, a digital mixer inverts the spectrum once more, transforming everything back to its original location as illustrated in Figure 2.

GUID-B0FF0CEE-1342-4B01-B193-CEDAE6035D86-low.jpg Figure 2 Chopper Implementation Details of the ADC3244

The Chopper in Action

The fast Fourier transform (FFT) spectrum with chopper disabled (Figure 3, left) shows the input signal along with the 1/f noise close to DC. After enabling the chopper feature, the input signal remains unchanged at 10MHz, while the low-frequency 1/f noise is now shifted to the opposite side of the Nyquist zone at Fs/2.

The chopper feature does bring one additional, unwanted byproduct. As you can see in the FFT plot on the right side of Figure 3, the passive mixer also generates a large spur at Fs/2. This is known as the local oscillator (LO) feedthrough, where the LO input is coupling into the output spectrum. This spur, along with the unwanted 1/f noise, is far away from the frequency range of interest; however, you can remove both with a digital filter.

GUID-F0B3E97F-6BDA-48B3-8A2B-16F40DE40EC2-low.jpg Figure 3 A 10MHz Input Signal with the Chopper Disabled (Left) and Enabled (Right)

Industrial applications requiring very good noise performance in the low-frequency region could traditionally only use bipolar transistor-based high-speed ADCs that provide the lowest 1/f noise profiles. A chopper is a very innovative feature that eliminates this inherent disadvantage of CMOS converters. Adding the chopper feature allows system designers to take advantage of modern, much lower-power CMOS data converters.

How would you like to use a chopper-stabilized ADC in your next design? Let us know with a comment below.

Additional Resources