Category Archives: DIY

Sony MXP 3000 DOA Mic Preamp

The Journey to make a 312 Microphone Preamp for the Sony MXP 3000 Series Console

Sony MXP 3000
The Sony MXP 3000 series console the mic preamp was designed to fit into.

Background

This console came with the ability to have stereo microphone preamplifiers on each channel, even thought the channels are mono. When my boss had scrapped out a previous Sony MXP 3000 he kept all of the modules from that console, which had these dual microphone preamp. The only issue was that nearly all of them had faulty potentiometers, which are extremely difficult to find and replace. So this lead me to the idea of making a 312 like mic preamp because we have ~20 of the Jensen JT-115K-E.

Circuit and Initial Design

I had captured the schematic for a full 312 a wile back when I was first starting to work on this idea over a year ago, but I stopped due to not having transformers that I wanted to use. As well I was unsure how Paul Wolf had used the output transformer exactly in his design. So when I had to come up with a new project for the PCB design class I was taking at Pasadena City College I thought it was the prefect opportunity to make some of these mic preamps for our Sony MXP 3000.  I removed the output transformer as well as the pad and phantom power. This was due to single sided boards that we were using on the Othermill.  And finally the board had to shrink in length.

API 312 Schematic for Sony MXP 3000
The schematic for the 312 mic pre

Milling out the PCB

Just making sure I had the correct dimensions for the PCB width, edge connector, as well as the discrete op amp.

When I first built the mic pre, there were a few issues that I found. First I had the capacitor, that is part of the shunt circuity in the wrong place. It was above the potentiometer instead of following it so that is the red wire that you can see. The second issue that I has was that there was very little gain from the preamp. This was because I had gotten the position of the feedback and shunt resistors in the wrong position. But, once I figured that out preamp came to life.

Just another view of the prototype without the discrete opamp

For the initial testing we are using the Gar2520 opamp kits from CAPI.

PCC Othermill prototype
The is the first fully assembled prototype that was made on the OtherMill at Pasadena City College

Measurements

Below is a graph showing the frequency response of the my preamp versus the stock transformer coupled mic preamp that came with the Sony MXP 3000. The blue trace is the stock Sony MXP 3000 transformer coupled mic preamp you can see the the transformer is boosting some of the high frequencies that the unit I built is not, I believe that this is due to the zobel network that I have to dampen the transformer.

 

Rev A PCB

After fixing a the issues that I found with building the Othermill PCB I changed those and added back the phantom power and pad circuitry. 

Here is the assembled Rev A PCB. Again there were a few issues that came to light mainly around the pad circuity, the resistors are very close to the switch so I had to mount the switch off the PCB slightly. Secondly, the pot works in the reverse manner. Both of these issues I have addressed in the Rev B schematic.

This is the assembled PCB form Bay Area Circuits

This past weekend I did a session at AEA and got to try out two of the mic preamps. They sound much better than the stock IC transformer-less that the Sony MXP 3000 has. And, just as good as the transformer coupled mic preamps that we already have.

Side by side comparison between the prototype and the Rev A PCB
Inserting the new preamp into on of the Sony MXP 3000 channel strips

Going Forward

Now that I have done some initial listening test and some measurements it is time for the Rev B PCB. One of the things that I am contemplating about doing is adding a DC servo to the design. If you noticed in the Rev A design I do not have a coupling capacitor on the output to block DC offset. Granted at this time I have not measured the output to see if there is a major offset. Adding the servo does add more complexity to the design but I think it may be a better choice over a coupling capacitor.  I plan on adding both and listening to how they preform.

Adding a DC servo to the 312 mic preamp to avoid the DC blocking capacitor.

Atari Punk Console

So here it is the final presentation. This is a complete over view of what goes into building an Atari Punk Console. I used Autodesk Maya to render the parts and show the assembly of the PCB, as well as the electrons flowing around the PCB. The videos was edited together in Adobe Premier. Bay Area Circuits manufactured the PCBs and I got the parts for assembly at Frys electronics. The total build cost was about $15, and took about 10 min to do the assembly.

The Atari Punk console is an astable square wave oscillator driving a monostable oscillator that creates a single pulse. The two controls, are for the frequency of the oscillator and one to control the width of the pulse. The controls are usually potentiometer but the circuit can also be controlled by light, temperature, pressure etc. by replacing a potentiometer with a suitable sensor (e.g., photo resistor for light sensitivity). Most of the time there is also a power switch (often a toggle switch) and a volume knob.

 

 

Background on the Atari Punk Console:

The Atari Punk Console (commonly shortened to APC) is a popular circuit that utilizes two 555 timer ICs or a single 556 dual timer IC. The original circuit, called a “Sound Synthesizer”, was published in a Radio Shack booklet: “Engineer’s Notebook: Integrated Circuit Applications” in 1980 and later called “Stepped Tone Generator” in “Engineer’s Mini-Notebook – 555 Circuits” by its designer, Forrest M. Mims III (Siliconcepts, 1984). It was named “Atari Punk Console” (APC) by Kaustic Machines crew because its “low-fi” sounds resemble classic Atari console games from the 1980s, with a square wave output similar to the Atari 2600. Kaustic Machines added a -4db line level output to the circuit which was originally designed to drive a small 8 ohm speaker.

~ Wikipedia

 

Atari Punk Console
These are the raw pcbs from bay area circuits
First we start by installing the DIP Sockets
First we start by installing the DIP Sockets
Adding the resistors
Adding the resistors
Adding the capacitors
Adding the capacitors
Adding the pin header and 9v battery snap
Adding the pin header and 9v battery snap
Added the 1M pot.
Adding the 1M pot.

Sorry it been so quite around here I have been keeping my self rather busy of late. But here is an update on one of the projects that I have been working on.

I am in the process of building four NV73 microphone preamps for someone local. This is a really cool kit, I would not recommend it as a your first microphone preamp kit to build as it is rather complex and can take a bit of trouble shooting.  Here are some photos of the build. I currently have two finished and two more to complete.

 

Here are all four units after the first round of building
Here are all four units after the first round of building
Watching the Fifth element and working
Watching the Fifth element and working

Build Progress

Now with transformers
Now with transformers
All four units mocked up
All four units mocked up
I hate these connectors
I hate these connectors
NV73 microphone preamp
NV73 microphone preamp
NV73 microphone preamp
NV73 microphone preamp