DIY Analog-to-Digital Converter project.Audio measurements tool
Does anyone would be interested by an high-end analog to digital converter ?
For my own use, i develop a new ADC .It's main use is a high performance measurements tool, for testing my DIY audio projects.
It's main features are :
Cirrus Logic CS5381KZZ 24 bits 192kHz flagship ADC
Fully differential and single-ended switchable analog inputs.
AC and DC coupling input switchable.
48, 96 and 192kHz on the fly selectable sampling rate.
Optical (toslink) and BNC SPDIF digital outputs.
Very small from factor (120x70x20mm)
Zero calibration allow all offset cancellation.
+/-10V FS input sensitivity.
Standard SMD or TentLab Master clock oscillator
Need +/-15Vdc power supply (SSR01/02 or other low noise PS. Allow 4 wires with sense connexions)
Use MAX3000 PLD functions controlling (no uC)
Allow low-cost or Scientific-Conversion High-end SPDIF digital transformer.
This is my 2nd ADC design (the first use the AK5394 ADC).
Here the PCB design use 4 layers with massive ground plane and very clean signal path routing
Now, the schematics and the PCB design is done, but not already sent to the PCB manufacturer.
I verify again and again each one before to order it.
If some DIYers are interested by this project, i can post more details about it.
Below, You can see what it should look like.
Very interested - the only similar project I'm aware of is AD24QS - Audio Analog to Digital Converter 24 Bit / 192 kHz
Audio ADC, the schematic...
With only one reply, i'm not really sure that many people are interested by the project. :cool:
I post the full schematic in pdf, constructive comments are welcome.
Below, the PCB design finished (only the top layer is displayed).
The ADC is designed as audio measurements tool. It replace a sound card, with more easy to use because it's an external unit with direct BNC connexion.
It allow DC or AC coupling, single ended or differential input, offset calibration,
overload detection on each channel and 48/92 and 192kHz sampling rate are supported.
The digital output can use optical or coaxial link (SPDIF).
It need only a low noise dual rail +/-15V dc power supply.
I wait comments...:Pawprint::Pawprint::Pawprint:
Impressive pcb work, fine.
Maybe you are looking for something readymade, and possible unbeatable, take a look at TI's PCM4222EVM ( US $ 149,-- +shipping ).
You just need a dual 15V and single 5V powersupply.
Here a FFT; source Krohn-Hite 4400A, both units SLA battery driven, PC interface RME-PAD via AES/EBU.
I have already build another high-end ADC, with AK5394.
It's actually my measurement reference, largely better than I/O of my ESI Juli@ sound card. I know the PCM4222 from TI, it's also a top grade ADC chip.
I prefer largely build my own device, for many reason.
First for the pleasure (DIY or not DIY !).
Second, it's technically very interesting to investigate on each steps
of this type of design.
Third, i build exactly for my need, with all convenience i want.
I love too when the finished work is "beautiful" to look. :happy2:
About the spectrum of the EVM, how exactly the measure has been done ?
Digital, analog, all setup ?..
AES/EBU-out to AES/EBU-in RME-Digi96/8-PAD -> Spectralab 5.0 demo.
I think this is an interesting project. However, I do not understand how it works. Could you explain how to acquire and analyze the converted digital signal? Do you have software that will do real-time analysis of a digital stream?
Thanks for sharing it with us!
It's easy to use.
The ADC has a SPDIF digital output, then you need in your PC a sound card
with digital input. Be careful, if you want use the ADC at high sampling rate the SPDIF input of your sound card must support it.
I personally use the ESI "Juli@", it's a low cost solution and very powerful solution (~100$).
After that, you can make all processing you want with the digital stream with appropriate software. Many FFT software are available to do that.
Spectralab is one of the best, but it's very expensive.
Oscillometerz is also very good software.
All of this software allow to make real-time processing including FFT spectrum and much more...
You're probably a little impatient, give us a few days to chew over your good work:D
1. +-15v supplies are bad for portability. Think +-12 or even +-9V.
2. Put TWO pre-amp options on: one for adjustable for audio levels and one fixed that can see right down to the thermal floor, which means using a low-noise opamp like AD797 or LT1028 in the first stage.
<puts flamesuit on>
Your comment is welcome. I'm not so impatient.:D
The ADC has been designed for +/-15v supply, but it can be supply with +/-12V without modification. For +/-9v operation, it need probably only slight modifications.
In my schematic, the analog input stage use OPA134, because i want use this instrument with many sources of signal, with high and low source impedance.
The opa134 is very good compromise for high input impedance, low voltage noise and very good THD specifications.
LT1028 and AD797 are the lowest noise available AOP, but it's bias current is very high and current noise too.
Any "single" AOP can be use in place of the OPA134.
Of course, maybe sligh value modifications can be done for optimisation.
Last thing, if you change OPA134 with LT1028/AD797, you must add much more $$. ;)
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