Difference between revisions of "USB-SATA powerswitch"

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Reading from the device is necessary, because it needs to dump its output. If you don't read it's output, the device may (or will) freeze.
Reading from the device is necessary, because it needs to dump its output. If you don't read it's output, the device may (or will) freeze.

John tells us that he uses the following windows script.
::startsatabat
::port parameters
MODE COM3:96,N,8,1
::For reading info from COM port
type COM3
::For sending info to COM port
sleep -m 200
echo s2 > COM3
sleep -m 200
echo s1 > COM3
sleep -m 200
echo s0 > COM3



The devices are shipped with the following .hex file programmed:<br>
The devices are shipped with the following .hex file programmed:<br>

Revision as of 07:45, 6 November 2012

USB SATA powerswitch

This is the documentation page for the USB SATA powerswitch PCB.

overview

The USB SATA powerswitch PCB has an USB connector and connection points for 3 power rails. The brains of the PCB is an at90usb162 (or compatible) chip. The 12V power rail is switched with an IRF9333 FET, and the 5V and 3,3V rails are switched with FDS8884 FETs.

External resources

pinout

  • led1 is connected to VCC
  • led2 is connected to PD6
  • led3 is connected to PD5
  • led4 is connected to PD4
  • led5 is connected to PD3
  • led6 is connected to PD0 (12V FET)
  • led7 is connected to PD1 (5V FET)
  • led8 is connected to PD2 (3,3V FET)
  • led9 is connected to 12V in
  • led10 is connected to 5V in
  • led11 is connected to 3,3V in

Viewing with the USB connector on the left side, and the power pads on the lower side:

  • 12V OUT (12V IN for V1.1)
  • 12V IN (12V OUT for V1.1)
  • GND
  • GND
  • 5V IN
  • 5V OUT
  • GND
  • GND
  • 3,3V IN
  • 3,3V OUT

Mind the reversed order for the 12V pads, compared to the 5V and 3,3V pads!

Default operation

The device acts as a usb-serial port, and under Linux, will be available under /dev/ttyACMn (n=0 for the first device, 1 for the second, etc.).

At BitWizard, we use the following script for turning om our harddisks:

#!/bin/sh
tty=/dev/ttyACM0
stty -echo -icrnl -onlcr < $tty
cat $tty &
pid=$!
(sleep 0.2; echo s0 ; sleep 0.2 ; echo s1 ; sleep 0.2 ; echo s2 ) > $tty
sleep 0.5
kill $pid

"s0" means "set output zero", which is the 12V output. "s1" id the 5V output, and "s2" is the 3V3 output. The four status LEDs are connected to output 3,4, 5, and 6. To turn off an output, simply send "c0", meaning "clear output zero".

Reading from the device is necessary, because it needs to dump its output. If you don't read it's output, the device may (or will) freeze.

John tells us that he uses the following windows script.

::startsatabat
::port parameters
MODE COM3:96,N,8,1
::For reading info from COM port
type COM3
::For sending info to COM port
sleep -m 200
echo s2 > COM3
sleep -m 200
echo s1 > COM3
sleep -m 200
echo s0 > COM3


The devices are shipped with the following .hex file programmed:
File:Usb-sata powerswitch.hex
For info on how to flash this .hex into your controller, see the section on programming below.

programming

This section describes how you get your program into the processor.

In general what you need to know is that the processor will boot into the code you programmed into it on powerup. Once you're done developing your program, that's the way you'll use it: Powerup, run.

If there is no program loaded or if you press the reset button the chip comes up in "firmware upload mode". This is done by a bootloader. You should take care not to overwrite or erase the bootloader, because there is no way to put the bootloader back once it is gone.

Linux

Get the dfu-programmer for atmel chips package. (link?)

On sufficiently recent Ubunu distributions that is as simple as:

 sudo apt-get  install dfu-programmer

I recommend creating a script called "dfu":

#!/bin/sh
if [ -z "$CHIP" ]  ; then 
  chip=at90usb162
else
  chip=$CHIP
fi

hex=$1
sudo dfu-programmer $chip erase
sudo dfu-programmer $chip flash --suppress-bootloader-mem $hex
sudo dfu-programmer $chip start

TODO: figure out how to get rid of the "sudo" commands here...

Now downloading and starting a program is as simple as pressing the reset button and then:

dfu <yourbinary>.hex

TODO: When I'm developing, I'm likely to modify the code, and when I want to program the chip I hit the "reset" button on the board. Then the computer will see my chip re-enumerate as the Atmel DFU chip. A simple script could watchout for that and invoke dfu <mycurrentbinary>.hex the moment the chip has enumerated. Once that's running downloading and starting the latest code becomes as simple as hitting the reset button.

Apparently the FLIP program is now available for Linux too. See below.

windows

Get the "flip" program from Atmel. http://www.atmel.com/dyn/products/tools_card.asp?tool_id=3886

writing programs

The chip is an at90usb162. http://www.atmel.com/dyn/resources/prod_documents/doc7707.pdf

You can program the processor as if it is a normal AVR processor without USB. Just like an arduino. Or you can program it to have USB support. For this the LUFA package is very useful. http://www.fourwalledcubicle.com/LUFA.php


Depending on what you want you can start from these examples:

DONE: Find out if we can jump to the bootloader from our code so that we can issue a "go get yourself updated" command over the USB (yes, but the documentation says nothing about what address to jump to). This comes in handy if the reset button is difficult to reach because the device is built-in somewhere. http://www.atmel.com/dyn/resources/prod_documents/doc7618.pdf

Hacking

If you want to switch other things than a harddisk, keep in mind that the 12V is switched with a P-fet that is spec-ed for >10V VGS operation. So reducing the 12V to something else is not recommended.

Similarly, the 5V and 3.3V outputs are switched by logic level N-FETS which are driven with their gates to 12V. So for the 5V output the drive on the gate is 7V. As this is a logic-level N-FET, this works just fine. But increase the switched voltage on the 5V line to more than 8V and things become critical.

future hardware enhancements

  • Replace the SMD inductor with an TH version

future software enhancements

  • program the LUFA bootloader.

Changelog

1.1

  • Switched order of 12V pads, so that the input and output are in the same order as the 5V and 3V3 pads.
  • replaced the SMD switch with an TH version
  • Added mounting holes

1

  • Initial release