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I'm still not sure about info I read on the internet. It said that to get the analog value also known as output bits of ADC use this formula:

Analog Value=(Analog Input*Max Value of ADC bit)/Analog Reference

Do you think the analog reference is the same as the voltage reference?

My real question is, do you think "Max Value of ADC bits" is same as 2^b where b is the number of bits?

I'm sure its maximum value of ADC bit must be (2^b)-1

I read in this article:

enter image description here

I cropped that picture from here, that article assumes a 10-bit ADC so it uses a maximum value of 1024, while I think it must be 1023. I think what they mean with 1024 is the possibilites not maximum value of an n-bit ADC.

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    \$\begingroup\$ \$\left(2^{b}\right)\text{-1}\$ \$\endgroup\$
    – rdtsc
    Commented May 14, 2021 at 11:57
  • \$\begingroup\$ If it's 1023 at the denominator, you expect 1023 to be generated at EXACTLY Vref at input. But it is not the case in ADCs. \$\endgroup\$
    – Mitu Raj
    Commented May 14, 2021 at 12:34

3 Answers 3

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There is a simple relationship between the voltages and digital values involved in a ADC: $$\frac{V_{IN}}{V_{REF}} = \frac{DigitalOutput}{2^N}$$ where \$N\$ is the number of bits.

If \$V_{IN} = 0\$ you would certainly expect the digital output to be integer 0.

The step size (voltage equivalent of a change in LSB) is $$V_{LSB} = \frac{1}{2^N} \times V_{REF}$$

So the voltage that will produce the largest digital output value is $$V_{MAX} = \frac{2^N-1}{2^N} \times V_{REF}$$

So, for a 10-bit ADC with a reference voltage of \$3.3\,\text{V}\$, the integer output value of 1023 (0x3FF) corresponds to a voltage of approximately \$3.297\,\text{V}\$. Any voltage above this value will also give a digital output of 1023.

There is one additional wrinkle. Some ADCs will offset the switching thresholds by \$\frac{1}{2}V_{LSB}\$ to reduce the quantization error. These ADCs have slightly different behavior; check the datasheet for details.

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  • \$\begingroup\$ As an extension to that wrinkle, some ADCs are designed so that if they repeatedly read a signal that would yield a value of e.g. 123.4, they'll consistently read 123 (which would be off by 0.4 LSB), while others are designed so that they'll read 123 about 60% of the time and 124 about 40% of the time. Taking ten readings and averaging them together might yield a value less than 1233 or greater than 1235, but it would usually yield a value that was closer to the ideal one than an individual reading would be. \$\endgroup\$
    – supercat
    Commented May 15, 2021 at 3:59
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10 bit can represent the numbers from 0 to 1023 OR from -512 to +511. That really depends whether the signal you are sampling is bi-polar (like audio) or just positive (like video).

The quantization step is the same in both cases, it's \$V_{ref}/2^b\$ where \$V_{ref}\$ is the reference voltage of the ADC and \$b\$ the number of bits.

To make things easy, let's assume we have 3 bit ADC and a reference Voltage of 8V. Then the output will increment in 1V steps representing either 0V to +7V OR -4V to +3V.

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  • \$\begingroup\$ ee.se uses \$. I vaguely remember it's because of the dollar sign, \$\endgroup\$
    – a concerned citizen
    Commented May 14, 2021 at 15:02
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    \$\begingroup\$ Thanks. It seems to be different for ever stack exchange site which can be confusing \$\endgroup\$
    – Hilmar
    Commented May 14, 2021 at 22:58
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10 bits leads to $$2^{10}$$ values, i.e. 1024. But one of them has to be zero. Thus the maximum value equating to 3.30 V must be 1023. If you exclude zero, you'd need a 10.0014 bit ADC.

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