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The circuit that converts analog signals into digital signals is called analog-to-digital converter (abbreviated as a/d converter or adc, analog to digital converter). The function of A/D conversion is to convert time-continuous and continuous-amplitude analog quantities It is converted into a digital signal with discrete time and discrete amplitude. Therefore, A/D conversion generally involves four processes: sampling, holding, quantization, and encoding. In actual circuits, some of these processes are combined. For example, sampling and holding, quantization and coding are often implemented simultaneously during the conversion process.

A short video introducing a/d converter:

Electronic Basics: ADC (Analog to Digital Converter) 

 


Catalog

 

I What is A/D converter?

II Wiring Layout of Successive   Approximation A/D Converter

III Wiring Layout of High-precision ∑-△   A/D Converter

IV Conclusion

FAQ

 


I What is A/D converter?

The process of converting analog to digital is called the analog-to-digital converter, and the circuit that completes the conversion is called the A/D converter (abbreviate  ADC). Its function is making the analog signal whose time and amplitude are continuously converted to discrete digital signal whose time and amplitude are also discrete. 

Basic operation of an A/D converter

Fig. 1 Basic operation of an A/D converter

The conversion accuracy of monolithic integrated A/D converters is described by resolution and conversion errors, and the layout of A/D converter is also changing as the conversion accuracy of AD converters increases. Specifically, the resolution rate of A/D converter refers to the number of discrete digital signals that can be output for analog signals within the allowable range, and the conversion error is usually given in the form of the maximum output error. In general, it represents the difference between the actual output of the A/D converter and the theoretical output. The multiples of the lowest significant bits are commonly represented it. For example, the relative error between −1/2 LSB and +1/2 LSB, shows that the error between the actual output digital quantity and the theoretical output digital quantity should be less than half a word of the lowest bit.

Relationship between analog input and digital output

Fig. 2 Relationship between analog input and digital output

 

At first, A/D converters originated in the analog paradigm, in which most of the physical silicon was analog. With the development of new design topology, this paradigm has evolved into a digital component as the main part in low-speed A/D converters. Although the leading role of the A/D converter change from analogue to digital, the wiring criterion of it has not changed. When cabling designers design mixed-signal circuits, basic wiring knowledge is still needed to achieve efficient wiring. In this paper, we take the successive approximation A/D converters and ∑-type A/D converters as examples to discuss the PCB routing strategy for the A/D converters. 

An 8-level ADC coding scheme

Fig. 3  An 8-level ADC coding scheme

 


II Wiring Layout of Successive Approximation A/D Converter

The successive approximation A/D converters have 8-bit, 10-bit, 12-bit, 16-bit, and 18-bit resolution. Initially, the process and structure of these converters were bipolar with R-2R trapezoidal resistor networks. However, these devices have been transferred to the CMOS process by using the capacitance-charge distribution topology recently. But this migration does not change the system routing strategy of these converters. Except for high resolution devices, the basic wiring methods are consistent. For these devices, special care is needed to prevent digital feedback from converter serial or parallel output interfaces.

From the point of view of circuits and on-chip resources dedicated to different fields, analog plays a dominant role in successive approximation A/D converters. Fig. 4 is a block diagram of a 12-bit CMOS successive approximation A/D converter.

Block diagram of a 12-bit CMOS successive approximation A/D converter

Fig. 4 Block diagram of a 12-bit CMOS successive approximation A/D converter

This converter uses the charge distribution formed by the capacitor array. In this block diagram, most of the sample/hold, comparator, digital-to-analog converter (DAC) and 12-bit successive approximation A/D converter are simulated. The rest of the circuit is digital. Therefore, most of the energy and current needed for this converter are used in internal analog circuits. This device requires very small digital current, only D/A converters and digital interfaces will have a small amount of switch-on and off.

In addition, these types of converters can have multiple ground and power connection pins. The names of pin are often misunderstood because pin labels used to distinguish analog and digital connections. These labels are not intended to describe system connections to PCB, but to determine how digital and analog currents flow out of the chip. Knowing that this information and main resources consumed in the chip are analog, you will understand the significance of connecting the power supply and the ground pin on the same plane, such as the analog plane.

Fig. 5 The successive approximation A/D converter, regardless of its resolution, usually has at least two connecting ends: AGND and DGND. Take Microchip's A/D converters, MCP3201 and MCP3008, as the examples in this article.

Pin configurations for typical 10-bit and 12-bit converters

Fig. 5 Pin configurations for typical 10-bit and 12-bit converters

More details about these devices, two grounding pins are usually pulled out of the chip: AGND and DGND. The power supply has one lead, when using these chips for PCB wiring, AGND and DGND should be connected to the analog ground plane. And the analog and digital power pins should also be connected to the analog power plane or at least to the analog power rail, in general, every power pin is connected closely to an appropriate bypass capacitor as close as possible. But the devices such as MCP3201 have only one ground pin and one positive power pin, the only reason for this is due to the limitation of the number of packaged pins. However, isolating the grounding can improve the converter's performance and the repeatable accuracy.

For the power strategy of all these converters, the analog plane should connect all ground, positive and negative power pins. Also, a “COM” pin or an “IN” pin associated with an input signal should be connected as close to the signal grounding as possible.

For higher-resolution successive approximation A/D converters (16-bit and 18-bit converters), separate digital noise from "quiet" analog converters and power supply planes requires additional attention. So external digital buffers should be used for noise-free operation when these devices are interfaced with single-chip computers. Although these types of successive approximation A/D converters usually have internal double buffers on the digital output side, external buffers are still needed to further isolate the analog circuits in the converters from the digital bus noise. 

Correct power policy for this system

Fig. 6 Correct power policy for this system

 

For high-resolution successive approximation A/D converters, the power and grounding of the converter should be connected to the analog plane. Then, the digital output of the A/D converter should be buffered with external tristate output buffers. These buffers have the function of isolating the analog and digital sides in addition to the high-drive capability.

Layout block diagram of successive approximation A/D converter

 

Fig. 7 Layout block diagram of successive approximation A/D converter

 


III Wiring Layout of High-precision ∑-△ A/D Converter

Schematic diagram of high-precision ∑-△ type A/D converter

Fig. 8  Schematic diagram of high-precision ∑-△ type A/D converter

The main part of a silicon board in high precision ∑-△ type A /D converter is digital. In the early stage of converter production, the shift in the example prompted users to use PCB planes to isolate digital and analog noise. Like successive approximation A/D converters, these types of A/D converters may have multiple analog grounding, digital grounding, and power pins. Digital or analog design engineers tend to separate the pins and connect them to different planes. However, this is wrong, especially if you try to solve the serious noise problem of 16-bit to 24-bit precision devices.

For a high-resolution ∑-△ type A/D converter with 10Hz data rate, the clock (internal or external) added to the converter may be 10MHz or 20MHz. This high-frequency clock is used for switching modulators and over-sampling engines. For these circuits, the AGND and DGND pins are connected on the same ground plane as the successive approximation A/D converters. Also, analog and digital power pins are best connected on the same plane. The requirement of analog and digital power plane is the same as that of high-resolution successive approximation A/D converter.

There must be a ground plane, which means that at least two panels are required. On this double panel, the ground plane should cover at least 75% of the total panel area. The purpose of the ground plane layer is to reduce the grounding impedance and inductance, and to provide shielding that against electromagnetic interference (EMI) and radio frequency interference (RFI). If an internal connection line is required on the ground plane side of the circuit board, the line should be as short as possible and perpendicular to the earth current loop.


IV Conclusion

For low-precision A/D converters, such as six-bit, eight-bit or maybe even 10-bit A/D converters, the analog and digital pins are not separated. But when the converter accuracy and resolution of the selected converters increase, wiring requirements become more stringent. High-resolution successive approximation A/D converters and ∑-△ type A/D converters need to be directly connected to low-noise analog ground and power plane.

 


FAQ

 

1. How does an AD converter work?

Analog-to-Digital converters (ADC) translate analog signals, real world signals like temperature, pressure, voltage, current, distance, or light intensity, into a digital representation of that signal. This digital representation can then be processed, manipulated, computed, transmitted or stored.

 

2. What are ad DA converters used for?

DACs are commonly used in music players to convert digital data streams into analog audio signals. They are also used in televisions and mobile phones to convert digital video data into analog video signals. These two applications use DACs at opposite ends of the frequency/resolution trade-off.

 

3. What is the main role of an ADC?

In more practical terms, an ADC converts an analog input, such as a microphone collecting sound, into a digital signal. An ADC performs this conversion by some form of quantization – mapping the continuous set of values to a smaller (countable) set of values, often by rounding.

 

4. What is the difference between AD and DA converters?

A D/A converter takes a precise number (most commonly a fixed-point binary number) and converts it into a physical quantity (example: voltage or pressure). ... An ideal D/A converter takes abstract numbers from a sequence of impulses that are then processed by using a form of interpolation to fill in data between impulses.

 

5. Why is a DAC needed?

Any time you want to listen to a digital audio signal (like an MP3 or the audio from a digital video) through an analog output (like wired headphones and speakers), you need a DAC to convert the digital signal from the source into an analog signal at the point of connection. ... This is why you need a separate DAC.

 

6. How are AD converters categorized?

Main Types of ADC Converters. Successive Approximation (SAR) ADC. Delta-sigma (ΔΣ) ADC. Dual Slope ADC. Pipelined ADC.

 

7. Which is fastest ADC?

flash ADC. The flash ADC is the fastest type available. A flash ADC uses comparators, one per voltage step, and a string of resistors. A 4-bit ADC will have 16 comparators, an 8-bit ADC will have 256 comparators.

 

8. What is better analog or digital signal?

The smooth analog signal matches the recorded sound wave better than the steps of a digital recording. However, the analog medium (vinyl or magnetized tape) the recording is imprinted on can have tiny imperfections that cause cracking and popping noise.

 

9. Why are ADC and DAC required in an embedded system?

An embedded system uses the ADC to collect information about the external world (data acquisition system.) The input signal is usually an analog voltage, and the output is a binary number.

 

10. Why ADC is used in microcontroller?

An analog-to-digital converter (ADC) is used to convert an analog signal such as voltage to a digital form so that it can be read and processed by a microcontroller. Most microcontrollers nowadays have built-in ADC converters. It is also possible to connect an external ADC converter to any type of microcontroller.

 

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