TEST & MEASUREMENT u ANALOG DEVICES How to realise power-saving analogue-to-digital


conversion for highly accurate measurements This article presents a low power analogue-to-digital converter (ADC) solution for high precision measurement applications. Thomas Brand, Field Applications Engineer, Analog Devices, says a typical application in electrical engineering is the recording of physical quantities by sensors and forwarding of these quantities to a microcontroller for further processing.


A


DCs are needed to convert the analogue sensor output signals into


digital signals. In high precision applications, either SAR-ADCs or sigma-delta ADCs are used. With low power applications, every mW that can be saved counts.


SIGNAL CONVERSION WITH SIGMA-DELTA ADCS Sigma-delta ADCs offer a few advantages over SAR-ADCs. For one, they often have higher resolutions. In addition, they often come integrated with programmable gain amplifiers (PGAs) and general-purpose inputs/ outputs (GPIOs). Thus, sigma-delta ADCs are well suited for DC and low frequency high precision signal conditioning and measurement applications. However, due to the high, fixed


oversampling rate, a sigma-delta ADC often has a higher power consumption, which translates to a lower lifetime in the case of battery-operated applications. If the input voltage is small – that


is, in the millivolt range – it first has to be amplified so that it can be more easily managed by the ADC. A PGA analogue front end (AFE) is required to connect a small voltage with a 10mV output voltage. For example, to connect small


voltages from a bridge circuit to a sigma-delta ADC with a 2.5V input range, the PGA has to have a gain of 250. This, however, leads to additional noise at the ADC input because the noise voltage is also amplified. The effective resolution of a 24-bit sigma-delta ADC is thereby drastically reduced down to 12-bit. However, in some circumstances, there is no requirement to use all


codes in the ADC and at some point, further amplification no longer provides a dynamic range improvement. Another disadvantage of sigma-delta ADCs is the usually higher costs resulting from their internal complexity.


BENEFITS OF COMBINING A SAR-ADC WITH AN IN- AMP


A similarly accurate but more cost effective and more efficient alternative is to utilise a SAR- ADC in combination with an instrumentation amplifier (in-amp), as shown in Figure 1.


The function of a SAR-ADC can be divided into two phases: the data acquisition phase and the conversion phase. Basically, in the data acquisition phase, the current consumption is low. Most SAR-ADCs even power down between conversions. So, the conversion phase draws the most current. The power consumption is dependent on the conversion rate and linearly scales with the sample rate. For power-saving applications for slow-response measurements - that is, measurements in which the measured quantities change slowly (for example, temperature measurements) - a low conversion rate should be used to keep the current draw and thus the losses low. Figure 2 shows the power losses in the AD4003 at various sampling rates as an example. At 1kSPS, the power loss is approximately 10µW; at 1MSPS, it has already risen to 10mW. In contrast to such slow


measurements, sigma-delta ADCs have the strengths of oversampling, while using a much higher internal oscillator frequency


14 January 2024 Irish Manufacturing


Figure 1 – a schematic diagram showing a simplified bridge measurement circuit combined with an in-amp and a SAR-ADC


Figure 2 – power loss in the AD4003 as a function of sampling rate


than the output rate. This allows designers to optimise sampling for higher speeds with worse noise performance or for lower speeds with more filtering, noise shaping (pushing the noise into the frequency band outside the area of measurement interest), and better noise performance. However, that means a lot more power consumption with sigma-delta ADCs compared to SAR-ADCs. The effective resolution and noise- free resolution of many sigma-delta ADCs are mentioned in their data sheets, making it easy to compare the trade-offs.


CONCLUSION Both sigma-delta ADCs in combination with PGAs and SAR- ADCs with an in-amp are suitable for signal conversion in high precision measurement applications. The solutions both have a similar accuracy. For power-saving or battery- operated measurement applications, however, the combination of the SAR-ADC and the in-amp is better because it offers a lower power consumption and lower costs compared with the solution consisting of the PGA and the sigma-delta ADC.


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