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Table of Contents




What is Sensor Interfacing?


  • Interfacing enables a system to read out information from an input signal that is generated by a sensor and then providing an output signal that is easy for the host system to display and process
  • Interfacing of sensors usually involves a mix of amplification, filtering and other signal conditioning in order to produce an output signal that the computer would be able to process
  • There are two main signals that are used: Analog and Digital

Analog 


  • Analog Signal 

    • An analog signal is a continuous signal in which one time-varying quantity (such as voltage, pressure, etc.) represents another time-based variable.
    • An analog system allows for a theoretically infinite number of values to be represented
    • Video and audio transmissions are often transferred or recorded using analog signals.
    • Pure audio signals are also analog.
    • The signal that comes out of a microphone is full of analog frequencies and harmonics
  • Analog Electronics 

    • Most electronic components are analog (Ex: resistors, capacitors, inductors and diodes)
    • Circuits built with a combination of the components are usually analog 
    • Analog sensors can be complex designs which include many components or they can be vey simple 


Analog Sine Wave
Analog Signal Graph 
  • Analog to digital converter (ADC)

    • ADC's translate analog electrical signals for data processing purposes. 

    • Converting from analog to digital enables us to use electronics to interface to the analog world. 
    • In the real world, physical quantities such as temperature, humidity, weight, velocity etc, are analog in nature, ADC's convert these values into a machine readable(digital) format. 
    • The most common ADC technique uses the analog voltage to charge up an internal capacitor and then measure the time it takes to discharge across an internal resistor. The microcontroller monitors the number of clock cycles that pass before the capacitor is discharged. This number of cycles is the number that is returned once the ADC is complete [1]. 


ADC Concept 

 

Digital


  • Digital Signal

    • Digital signals must have a finite set of possible values

    • The set of values can be between two and a large number that is not infinity

    • Most commonly, the values will be one of the two values

      • For example, it can be 0V or 5V

    • Or the digital signal can be discrete representation of an analog waveform

      • From far away it looks like the line is smooth and analog but when zoomed in there are small discrete steps as the signal tries to approximate the value

    • Examples of digital signals are HDMI for video (the audio), MIDI, I2S, or AC'97 for the audio



Digital Signal Changes between two ValuesWhen Digital Signal Represents an Analog Waveform
  • Digital Electronics

    • Digital circuits operate by using digital, discrete signals

    • These systems are usually made of a combination of transistors, logics gates and at higher levels, microcontrollers, and other computing chips

    • Most processors whether they are big and found in a computer or tiny microcontroller, they usually operate in the digital realm

    • Digital circuits usually used binary scheme for digital signaling

    • These systems assign two different voltages as different logic levels

      • A high value usually 5V, 3.3V, or 1.8V represent one values

      • The other low value is usually 0V

    • Digital circuits are usually easier to design however they can be expensive to build than an analog circuit that would do the same tasks

References

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