As I said, I will release a new revision of the Buffalo shield that will have better support for the B3SE.
Since that will probably take some time, in the meanwhile, this is what B3SE (or 32s or II) owners should do to their shields in order to support the B3SE:
The idea is to connect the photosensor side of one of the optoisolators directly to the IP_S header on the B3SE. In order to do that, you will have to cut one trace on the PCB and solder directly onto one of the optoisolator’s pins. That’s pretty much it.
On the new revision of the shield there will be a jumper where you have to cut the trace plus an extra pin so that you don’t have to solder onto the isolator’s pin.
Here is version 1.06 of the code:
TFT_HiFiDuino_v1.06b.zip (7155 downloads )
(11/12/2013: Update to v1.06b. Reason: minor bugfix) (Note: As always, the code on this page may not be the current one, i.e. there may be a newer version available. The latest version is always up at the project’s official page.)
The main difference is the support of Buffalo 3SE as well as an “always on” feature that bypasses the remote on/off sections of the code.
Here is the official change log:
– Compatible with Buffalo 3 and Buffalo 3 SE. Just comment out the relevant statement.
– Fixed “OS Filt” & “SR disp”.. They were not working correctly.
– Blue select boxes are gone.. they looked quite bad.
– Some other minor (mainly aesthetic) fixes..
A new revision of the shield is to follow (for improved B3SE compatibility).
This is what DipTrace thinks the board ought to look like:
And this is what it actually looks like:
Close enough..
This shield features:
– Galvanic isolation for the I2C signals as well as 2 digital outputs (Arduino -> Buffalo) and 1 digital input (Buffalo -> Arduino).
– EEPROM chip (24LC256) either in SMT or DIP footprint.
– Backlight control for the TFT through a PWM-controlled transistor.
– Headers for two rotary encoders.
– Output for power relay (for remote on/off).
– Header for IR receiver.
This is the schematic for the shield:
And this is the resulting PCB:
This is a description of the various headers:
IR: Use a standard 38KHz IR Receiver Module, like the TSOP4838.
1: Signal (Pin 9)
2: GND
3: 3.3V
RotaryEncoder1: Use any simple rotary encoder.
1: Left pin (Pin 7)
2: Right pin (Pin 6)
3: Selector pin 1 (Pin 5)
4: Middle Pin & Selector pin 2 (GND)
RotaryEncoder2: Use any simple rotary encoder.
1: Left pin (Pin A3)
2: Right pin (Pin A4)
3: Selector pin 1 (Pin A3)
4: Middle Pin & Selector pin 2 (GND)
I2C_In:
1: SDA
2: SCL
(note: this is the I2C connection to the Arduino. SDA should be connected to pin 20 and SCL to pin 21)
I2C_Bypass:
1: GND
2: SDA
3: SCL
(use this if / when an isolator IC (U2) is not used to send the I2C signal to the Buffalo)
Isolated_Outs:
1: Out 1 (Pin A2)
2: Out 2 (Pin A7)
TFT_power:
1: TFT Backlight LED (dimmed by Pin 8)
2, 3: 3.3V (for TFT power & pin RD)
4: GND
PowerInput:
1: GND
2: Vin (8V-12V)
(connect here the power supply to the Arduino)
PowerRelay:
1: GND
2: 3.3V out (Pin A0) in case of Due, 5V in case of MEGA
(connect here the power relay that powers on the DAC)
It took quite a bit longer than I had expected but I am happy to report that Phase 1 of the TFT HiFiDuino project is complete.
The objectives of Phase 1 were the following:
– Have full control over the parameters of the ES9018 chip. Essentially be able to write to all of the useful registers.
– Be able to have full IR remote control functionality.
– Be compatible with both the MEGA as well as the Due Arduino boards.
– Be able to switch between all 8 of the supported s/pdif inputs, as well as between I2S sources (USB in my case).
– Develop an Arduino shield that would simplify the wiring of the thing as much as possible as well as provide galvanic isolation between the Arduino and the DAC board.
If you happen to come across a bug, please let me know by posting a comment below.
Feel free to use it whichever way you see fit, modify it, redistribute it, whatever, as long as you do not profit from it.
Requirements:
– UTFT Library
– Fonts (included in the ZIP)
I will also make available the schematics & PCB for the shield, although it is not really necessary for operation of the controller.
Here is a preview:
Download from here: B3_arduino_code_v0_95(Note: As always, the code on this page may not be the current one, i.e. there may be a newer version available. The latest version is always up at the project’s official page.)
Here is a partial changelog:
– Changed rotary encoder code. Should work for MEGA as well as Due (no longer using interrupts).
– Added remote control codes for virtually all of the functionality that is offered by the encoder so now all of the parameters can be set via remote.
Bugs:
– Selection bar is still buggy. Haven’t gotten around to sorting it out.
Missing functionality:
– Disply backlight handling. It is next in line to be sorted.
– Sleep mode. Much research is needed, so won’t be implemented soon.
Also, I’m working on a simple MEGA / Due shield that should simplify things a lot. It is a work in progress, so I’m not ready to publish schematics or anything, but you can have a look at the current version’s 3D model:
This is the result of me soldering an SMD with a standard soldering iron:
And this is what I accomplished with a hot air rework station, practically on my first try:
That’s it.. I’m hooked on hot air soldering! 🙂
BTW, in case you’re wondering, the first IC is a Si8605 (I2C galvanic isolator) while the second one is a Si8440 (I2S galvanic isolator). Both will be used in my ongoing Buffalo III project.
I was going to wait until I had gotten to the point that I had a version that I could call “v1” but a fellow DIYer kind of forced my hand. So this is v.0.91g.(Note: As always, the code on this page may not be the current one, i.e. there may be a newer version available. The latest version is always up at the project’s official page.)
I have included in the ZIP file all of the necessary fonts, but you will also need the UTFT library. You should get it from here.
There is a number of things that you should keep in mind:
The code supports both the MEGA as well as the Due. You have to set the appropriate setting in the code. It is not hard to find.. search for #define ARDUMEGA
Keep in mind that the rotary encoder does not yet work on the Due. The relevant code is still a little buggy, but it should be fixed soon. Also the selection bars are buggy as well..
This version of the code requires the addition of a 24LC256 EEPROM chip. That is necessary in order to support the Due, since it does not have any on-chip EEPROM. You should wire it like this (making the necessary connections to the correct pins SDA/SCL for the MEGA/Due): http://www.hobbytronics.co.uk/arduino-external-eeprom
If you plan on using a MEGA (even though I would advise against it, see the video that follows) you could easily adapt the code to use the MEGA’s EEPROM (essentially use the original hifiduino code for the specific functionality) and omit the 24LC256.
You should use a compatible remote control. You will know it is compatible if you see the IR codes displaying on the top right of the screen when you press the various keys. You will need to change the IR codes in the code to the numbers corresponding to your specific remote control (see CASE statement).
I have implemented a remote power on/off feature but the TFT’s backlight remains on all the time. That can easily be remedied by wiring a transistor as control for the TFT’s backlight.. However, since I plan on implementing dimming for the TFT, I will do it more elegantly in a future version of the code.
This version of the code supports all 8 s/pdif inputs of the ES9018 as well as a 9th input (named USB) which is used for I2S/DSD input. You can of course easily change the number of the inputs as well as their names. I am using a sidecar for the switching between I2S & s/pdif.
Finally, here is a short video comparing the performance of the MEGA versus the Due:
I’ve been asked what is the correct way to wire a 3.2″ TFT to an Arduino MEGA (or Due) in order to make it work with the UTFT library.
The answer of course depends on the exact model of the TFT that we have on hand. The below instructions apply to a generic 3.2″ TFT with wide aspect ratio and resolution of 240 x 400 that I got off of Ebay.
This is its pinout according to the manufacturer:
This is nice, but I want to use a standard 40-pin ribbon cable which I have left over from an old computer, and its conductor numbering is a little different. At first I thought I’d try to make sense of it as I went but it didn’t take long for me to realize that it would actually save me time if I made a “conversion table”. So I came up with what you see here:
What we have here is the actual conductor number in the grey background (counting the conductors in the ribbon cable from left to right) and then above and below them the corresponding signal lines according to the above pinout. Above and below the signal lines I have noted the actual Arduino pins that correspond to the signals.
For example, pin 2 (the second pin on the flex cable looking at it from the left) corresponds to the DB0 signal which should be connected to the D37 pin on the Arduino MEGA (or Due). Note that the connections are made according to UTFT’s documentation and are applicable specifically to UTFT.
So we have to connect signals D0 through to D15 to the necessary digital pins. Then we also have to connect pins RS, WR, CS and REST to whichever pins we like (we must declare these pins in our sketch, see UTFT documentation). Pin 11 is RD and it must be pulled high, which means connecting it to +3.3V. Pin 37 is the backlight illumination which means it must also be connected to +3.3V. This leaves pin 1 which must be connected to ground and pin 3 which must be connected to Vcc which in our case is 5V.
Note that I have not really gotten around to using the touchscreen capabilities or the SD reader, so I have not connected them to my Arduinos. It shouldn’t be difficult though.
Now, there is one more thing that I should point out and it is very important. The Arduino MEGA is using 5V logic while the TFT is expecting 3.3V logic. This means that if you connect the D0-D15 and RS, WR, CS, REST lines directly to the MEGA you will most likely damage the TFT. You need to connect a 10K resistor in series with each and every one of the lines. That will bring the voltage down to acceptable levels. Do not forget to do this!
In case of the Due the resistors are not necessary since it uses 3.3V logic so it is directly compatible.
Here is a little video I made of the 3.2″ TFT running a UTFT demo sketch:
