Analog-to-Digital Converters (ADC) - Charge-Balancing and Delta-Sigma ADC

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  • Опубліковано 29 лис 2024

КОМЕНТАРІ • 29

  • @ife.tugraz
    @ife.tugraz  2 роки тому

    This video is part of the second course of our *ElectrONiX* massive open online course (MOOC) series.
    You can sign up for the course *ElectrONiX - Digital* for free on the following link: imoox.at/course/digital
    ElectrONiX MOOC series: imoox.at/series/electronix

  • @d4rcym
    @d4rcym 2 роки тому +30

    The cafe analogy is genius. how have I never seen that before! Thank you :)

    • @ife.tugraz
      @ife.tugraz  2 роки тому +3

      We are glad you like it :)
      Often pictorial descriptions help to comprehend such complex things more easily.

    • @Vitonolable
      @Vitonolable Рік тому +1

      I love it! Engineer has to stay caffinated to get through the day!

  • @inspecteurthierryroland3690
    @inspecteurthierryroland3690 2 роки тому +15

    This video is so well made, that's a shame it hasn't more views. Anyway thank you, i have a project at school to present delta-sigma modulator and this video really explain the basics in an understandable way, with good diagramm and good analogy (coffe shop is awesome).

    • @ife.tugraz
      @ife.tugraz  2 роки тому +1

      Thank you for your feedback. We are glad you like it :)
      Feel free to share and recommend our videos to others.
      Additionally we also develop a massive open online course series. The first course on amplifiers already started and is available at [1].
      [1] imoox.at/mooc/local/landingpage/course.php?shortname=amps&lang=en

    • @onelivingsoul2962
      @onelivingsoul2962 6 місяців тому

      Great videos/knowledge related videos are Not meant to garner views like the cheap videos does.

  • @준형김-q1x
    @준형김-q1x Рік тому +2

    Thanks to Michael and his colleagues for making this video. 😊😊😊 I couldn't unsubscribe. ❤❤❤

    • @ife.tugraz
      @ife.tugraz  Рік тому

      You are welcome. We are happy, that you like our channel :)

  • @amanjonathanprakash1044
    @amanjonathanprakash1044 Рік тому +1

    thank you for the crystal clear explanation. Very helpful

  • @funwithy
    @funwithy 7 місяців тому +1

    …sehr guter Kanal.
    Macht weiter so.Sehr verständlich 👍🏻👍🏻👍🏻

  • @Vitonolable
    @Vitonolable Рік тому +1

    This is such a great explanation, thank you for putting so much effort.

    • @ife.tugraz
      @ife.tugraz  Рік тому

      We are glad that you like our videos :)

  • @danm5551
    @danm5551 Рік тому

    Congrats!. Your presentation is very good, since avoids complicated maths, understandable for not very high skilled but interested people as well. Great job!

  • @tarungarg15
    @tarungarg15 7 місяців тому +1

    Amazing explanation!

  • @mmh1922
    @mmh1922 Рік тому +1

    Excellent presentation!

  • @SachinSingh-md6kv
    @SachinSingh-md6kv 9 місяців тому +1

    very well explained

  • @tranhuuthong07
    @tranhuuthong07 2 роки тому

    Great tutorial. Thank you so much!

  • @tarihad1145
    @tarihad1145 Рік тому +1

    many thanks for this informative and cristal clear explanations

  • @Hexor1211
    @Hexor1211 2 роки тому +2

    The only thing missing, and what I'm searching, is about how and at what point of the ADC system there is a transition from single bit data to multiple bits of data. For example, how you get from single bit stream to 16 bit audio

    • @ife.tugraz
      @ife.tugraz  2 роки тому +3

      Thank you for your question, that is indeed a very important question to fully understand Sigma-Delta ADCs.
      We can recommend, that you have a look at this website: www.analog.com/en/design-center/interactive-design-tools/sigma-delta-adc-tutorial.html
      There you can find a nice tool to "reproduce" the behaviour of a sigma-delta ADC step-by-step.
      In the example on the bottom of the website, they use a bit-stream which is 8-bit long, Vin=1.0V and Vref=2.5V.
      They receive a bit-stream of 1 0 1 1 1 0 1 1. We can see, that 6 of 8 outputs are high and 2 of 8 outputs are low. This means, that 75% of all outputs are high. Translating this back to a voltage would mean, that we are at 75% of the input range (in this case between -2.5V and +2.5V). Calculation gives Vout=-2.5V+5V*0.75=1.25V.
      If we are looking for a digital value: As we have 8 bits in the (unary) stream, this corresponds to 3 bits (=log2(8)) in a binary representation. In our case it would mean, that we would get a digital output value of 110 or 6 in decimal.
      Some more examples to understand the concept:
      unary -> binary
      00000000 -> 000
      10000000 -> 001
      00000001 -> 001
      00010000 -> 001
      01010101 -> 100
      10101010 -> 100
      We hope this help in understanding the concept :)

  • @kabandajamir9844
    @kabandajamir9844 Рік тому

    So nice thanks sir

  • @dcy1936
    @dcy1936 5 місяців тому +1

    🤝👍

  • @apurvpandey1627
    @apurvpandey1627 3 роки тому +1

    Can we design TRNG using this?

    • @ife.tugraz
      @ife.tugraz  3 роки тому

      In this video we only focussed on the basic principle of Sigma-Delta ADCs. Your question however, whether we can build a True Random Number Generator (TRNG) with these ADCs, is quite straightforward.
      It seems like there is some research [1], [2] ongoing in this topic, but we do not have any research experience there. So we would recommend having a look at current literature.
      [1] doi.org/10.1109/LSSC.2020.3010901
      [2] doi.org/10.1109/ISCAS.2016.7527159

  • @cahitskttaramal3152
    @cahitskttaramal3152 2 роки тому

    everybody tells one bit modulator which is useless to comprehend the issue

    • @ife.tugraz
      @ife.tugraz  2 роки тому

      Thank you for your feedback. How would you prefer to describe it?