OMAP3 LVDS — различия между версиями

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Hello,
 
Hello,
  
I thought I'd share a little hack I put together back at the end of September for a Rev B Beagleboard, in case anyone's interested.  I hadn't got round to uploading the pictures at the time (and forgot    since then) but I think LVDS-on-Beagleboard will get get more topical    again this month with the release of the excellent RevC update with    the OMAP3 LCD outputs available.
+
I thought I’d share a little hack I put together back at the end of September for a Rev B Beagleboard, in case anyone’s interested.  I hadn’t got round to uploading the pictures at the time (and forgot    since then) but I think LVDS-on-Beagleboard will get get more topical    again this month with the release of the excellent RevC update with    the OMAP3 LCD outputs available.
  
So...
+
So…
  
 
The aim of the project was to drive an LVDS TFT panel directly from    the Beagleboard, *without* first going to DVI, then externally    converting to LVDS (IMHO icky).  The LCD panel was an AUO B089AW01,    which is the 1024x600 18-bit colour TFT featured on several of the    netbooks available (e.g. Acer Aspire One).
 
The aim of the project was to drive an LVDS TFT panel directly from    the Beagleboard, *without* first going to DVI, then externally    converting to LVDS (IMHO icky).  The LCD panel was an AUO B089AW01,    which is the 1024x600 18-bit colour TFT featured on several of the    netbooks available (e.g. Acer Aspire One).
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** Use a NatSemi DS90C363 LVDS serialiser to drive three LVDS pairs    (plus one clock) to the TFT panel.
 
** Use a NatSemi DS90C363 LVDS serialiser to drive three LVDS pairs    (plus one clock) to the TFT panel.
  
Total cost:  about 10UKP of parts (3xSN74AVC8T245 octal buffers (dual    power rails), 1xDS90C363, misc connectors/passives) plus a small PCB    (homemade in kitchen with Iron-On(TM) toner transfer technology) plus    time.  (A lot of time.  You'll see the soldering below; it was    enormously enormously time-consuming.)
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Total cost:  about 10UKP of parts (3xSN74AVC8T245 octal buffers (dual    power rails), 1xDS90C363, misc connectors/passives) plus a small PCB    (homemade in kitchen with Iron-On™ toner transfer technology) plus    time.  (A lot of time.  You’ll see the soldering below; it was    enormously enormously time-consuming.)
  
So, it's not pretty but it works, as the saying goes....  >:-)  Anyone    want to see?
+
So, it’s not pretty but it works, as the saying goes….  >:-)  Anyone    want to see?
  
Here's the board:
+
Here’s the board:
  
 
[[File:LVDSBoard.jpg|640px]]
 
[[File:LVDSBoard.jpg|640px]]
  
Here's the space once occupied by the TFP410, with 33 gauge wirewrap    wires being soldered on (apologies for the crappy picture quality).    The flux is making it look a little messy, but it cleaned up.
+
Here’s the space once occupied by the TFP410, with 33 gauge wirewrap    wires being soldered on (apologies for the crappy picture quality).    The flux is making it look a little messy, but it cleaned up.
  
 
[[File:LVDSLoupe.jpg|640px]]
 
[[File:LVDSLoupe.jpg|640px]]
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[[File:LVDSAttachedToBB.jpg|640px]]
 
[[File:LVDSAttachedToBB.jpg|640px]]
  
Naturally I forgot to take a final shot before it got whisked away abroad (d'oh! :) ), but it worked splendidly.  I believe the prototype    photos of a certain OMAP3-based device announced this week are it in    action.....
+
Naturally I forgot to take a final shot before it got whisked away abroad (d’oh! :)), but it worked splendidly.  I believe the prototype    photos of a certain OMAP3-based device announced this week are it in    action…..
  
Am looking forward to (I think Keith Williams's) revC daughterboard.    One thing to note is that most LCDs will require a lot of current on    the 3.3V rail and will require an extra 3.3V power supply/regulator    from the BB's 5V supply; software side of things was easy, and it was    a lot of fun.  :) Hope that is of some interest, Matt
+
Am looking forward to (I think Keith Williams’s) revC daughterboard.    One thing to note is that most LCDs will require a lot of current on    the 3.3V rail and will require an extra 3.3V power supply/regulator    from the BB’s 5V supply; software side of things was easy, and it was    a lot of fun.  :) Hope that is of some interest, Matt
 
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Версия 23:09, 5 апреля 2011

Скопировано с LVDS on Rev B Beagleboard — Beagle Board | Группы Google


Matt Evans:

Hello,

I thought I’d share a little hack I put together back at the end of September for a Rev B Beagleboard, in case anyone’s interested.  I hadn’t got round to uploading the pictures at the time (and forgot   since then) but I think LVDS-on-Beagleboard will get get more topical   again this month with the release of the excellent RevC update with   the OMAP3 LCD outputs available.

So…

The aim of the project was to drive an LVDS TFT panel directly from   the Beagleboard, *without* first going to DVI, then externally   converting to LVDS (IMHO icky).  The LCD panel was an AUO B089AW01,   which is the 1024x600 18-bit colour TFT featured on several of the   netbooks available (e.g. Acer Aspire One).

General plan:

    • Remove TFP410 DVI serialiser.
    • Use buffers to step the 1.8V OMAP3 LCD outputs up to 3.3V.
    • Use a NatSemi DS90C363 LVDS serialiser to drive three LVDS pairs   (plus one clock) to the TFT panel.

Total cost:  about 10UKP of parts (3xSN74AVC8T245 octal buffers (dual   power rails), 1xDS90C363, misc connectors/passives) plus a small PCB   (homemade in kitchen with Iron-On™ toner transfer technology) plus   time.  (A lot of time.  You’ll see the soldering below; it was   enormously enormously time-consuming.)

So, it’s not pretty but it works, as the saying goes….  >:-)  Anyone   want to see?

Here’s the board:

LVDSBoard.jpg

Here’s the space once occupied by the TFP410, with 33 gauge wirewrap   wires being soldered on (apologies for the crappy picture quality).   The flux is making it look a little messy, but it cleaned up.

LVDSLoupe.jpg

The umbilical wires in place:

LVDSWires.jpg

Finally, the two welded together:

LVDSAttachedToBB.jpg

Naturally I forgot to take a final shot before it got whisked away abroad (d’oh! :)), but it worked splendidly.  I believe the prototype   photos of a certain OMAP3-based device announced this week are it in   action…..

Am looking forward to (I think Keith Williams’s) revC daughterboard.   One thing to note is that most LCDs will require a lot of current on   the 3.3V rail and will require an extra 3.3V power supply/regulator   from the BB’s 5V supply; software side of things was easy, and it was   a lot of fun.  :) Hope that is of some interest, Matt