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How to convert using circuits analogue signal to digital signal?

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تم إضافة السؤال من قبل hamdi Basuony , electronic and communication engineer , electronics
تاريخ النشر: 2013/05/12
gamil abdullah ali alasri
من قبل gamil abdullah ali alasri , MAINTENANCE SUPERVISOR , GRIFFIN COMPANY

using ADC integrated circuit

hamdi Basuony
من قبل hamdi Basuony , electronic and communication engineer , electronics

4-channel stereo multiplexed analog-to-digital converter WM8775SEDS made by Wolfson Microelectronics placed on an X-Fi Fatal1ty Pro sound card.
An analog-to-digital converter (abbreviated ADC, A/D or A to D) is a device that converts a continuous physical quantity (usually voltage) to a digital number that represents the quantity's amplitude.
The conversion involves quantization of the input, so it necessarily introduces a small amount of error.
The inverse operation is performed by a digital-to-analog converter (DAC).
Instead of doing a single conversion, an ADC often performs the conversions ("samples" the input) periodically.
The result is a sequence of digital values that have converted a continuous-time and continuous-amplitude analog signal to a discrete-time and discrete-amplitude digital signal.
An ADC may also provide an isolated measurement such as an electronic device that converts an input analog voltage or current to a digital number proportional to the magnitude of the voltage or current.
However, some non-electronic or only partially electronic devices, such as rotary encoders, can also be considered ADCs.
The digital output may use different coding schemes.
Typically the digital output will be a two's complement binary number that is proportional to the input, but there are other possibilities.
An encoder, for example, might output a Gray code.
[edit] Fig.
1.
An 8-level ADC coding scheme.
The resolution of the converter indicates the number of discrete values it can produce over the range of analog values.
The values are usually stored electronically in binary form, so the resolution is usually expressed in bits.
In consequence, the number of discrete values available, or "levels", is a power of two.
For example, an ADC with a resolution of 8 bits can encode an analog input to one in 256 different levels, since 28 = 256.
The values can represent the ranges from 0 to 255 (i.e.
unsigned integer) or from −128 to 127 (i.e.
signed integer), depending on the application.
Resolution can also be defined electrically, and expressed in volts.
The minimum change in voltage required to guarantee a change in the output code level is called the least significant bit (LSB) voltage.
The resolution Q of the ADC is equal to the LSB voltage.
The voltage resolution of an ADC is equal to its overall voltage measurement range divided by the number of discrete values: Q = \dfrac{E_ \mathrm {FSR}}{{2^M}-1}, where M is the ADC's resolution in bits and EFSR is the full scale voltage range (also called 'span').
EFSR is given by E_ \mathrm {FSR} = V_ \mathrm {RefHi} - V_ \mathrm {RefLow}, \, where VRefHi and VRefLow are the upper and lower extremes, respectively, of the voltages that can be coded.
Normally, the number of voltage intervals is given by N = 2^M - 1, \, where M is the ADC's resolution in bits.[1] That is, one voltage interval is assigned in between two consecutive code levels.
Example: * Coding scheme as in figure 1 (assume input signal x(t) = Acos(t), A = 5V) * Full scale measurement range = -5 to 5 volts * ADC resolution is 8 bits: 28 - 1 = 256 - 1 = 255 quantization levels (codes) * ADC voltage resolution, Q = (10 V − 0 V) / 255 = 10 V / 255 ≈ 0.039 V ≈ 39 mV.
In practice, the useful resolution of a converter is limited by the best signal-to-noise ratio (SNR) that can be achieved for a digitized signal.
An ADC can resolve a signal to only a certain number of bits of resolution, called the effective number of bits (ENOB).
One effective bit of resolution changes the signal-to-noise ratio of the digitized signal by 6 dB, if the resolution is limited by the ADC.
If a preamplifier has been used prior to A/D conversion, the noise introduced by the amplifier can be an important contributing factor towards the overall SNR.
Response type [edit] Most ADCs are linear types.
The term linear implies that the range of input values has a linear relationship with the output value.
Some early converters had a logarithmic response to directly implement A-law or μ-law coding.
These encodings are now achieved by using a higher-resolution linear ADC (e.g.
12 or 16 bits) and mapping its output to the 8-bit coded values.
Accuracy [edit] An ADC has several sources of errors.
Quantization error and (assuming the ADC is intended to be linear) non-linearity are intrinsic to any analog-to-digital conversion.
There is also a so-called aperture error which is due to a clock jitter and is revealed when digitizing a time-variant signal (not a constant value).
These errors are measured in a unit called the least significant bit (LSB).
In the above example of an eight-bit ADC, an error of one LSB is 1/256 of the full signal range, or about 0.4%.
Quantization error [edit] Main article: Quantization error Quantization error (or quantization noise) is the difference between the original signal and the digitized signal.
Hence, the magnitude of the quantization error at the sampling instant is between zero and half of one LSB.
Quantization error is due to the finite resolution of the digital representation of the signal, and is an unavoidable imperfection in all types of ADCs.
Non-linearity [edit] All ADCs suffer from non-linearity errors caused by their physical imperfections, causing their output to deviate from a linear function (or some other function, in the case of a deliberately non-linear ADC) of their input.
These errors can sometimes be mitigated by calibration, or prevented by testing.
Important parameters for linearity are integral non-linearity (INL) and differential non-linearity (DNL).
These non-linearities reduce the dynamic range of the signals that can be digitized by the ADC, also reducing the effective resolution of the ADC.
Aperture error

Pravesh Ahlawat
من قبل Pravesh Ahlawat

a number of companies providing IC to serve the purpose.
you can choose any one from them as per your application.
like microchip has TC500A is a dual slope adc but its a bit slow as it is based on dual slope principle of conversion.
secondly you have SAR( successive appromixation register) ic which can serve the purpose well and is bit fast too.
microchip version MCP300X series.

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