view ueda/doc/overview.txt @ 0:cd92449fdb51

initial import of ueda and ifctf-part-lib from ifctfvax CVS
author Space Falcon <falcon@ivan.Harhan.ORG>
date Mon, 20 Jul 2015 00:24:37 +0000
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Welcome to uEDA, an EDA suite for UNIX!
(for board level design)

The uEDA project has been inspired by gEDA (http://geda.seul.org/) and intends
to do for the UNIX culture what gEDA has done for the GNU/Linux culture.

First a disclaimer is in order.  Different people write Free Software based on
different motivations.  Like most Free Software written by Michael Sokolov,
uEDA is based on the "scratching a personal itch" development model.  In other
words, I have written the software to satisfy my own internal need, and I
don't really care if you like it or not.  Please keep this observation in mind
as you discover that it lacks some feature you need or want, or that its flow
is not to your liking.  I have written it to satisfy *my* needs.  I could have
written it for myself and never released it, but I believe in sharing and
letting others have what I have (though whether they like it or not is not my
concern).  So there you have it.

uEDA has been written by a hard-core UNIX programmer (as in real UNIX in 4
capitals running on Big Iron, not the cheap modern crap), and is designed to
allow one to design hardware using not only a UNIX host environment, but also
the intellectual creation flow model associated with the UNIX culture, one that
revolves around the concepts of source code files, generated files and
Makefiles.  I won't explain these concepts here; if they are foreign to you,
uEDA is not for you.

Note my choice of words: "the intellectual creation flow model" of the UNIX
culture, rather than "the UNIX programming model".  I fully acknowledge that
hardware engineering is very different from SW eng, and uEDA does not try to
"make hardware like software".  However, the UNIX culture's intellectual
creation flow model has already been extended many times to various intellectual
products other than software.  Consider for example an author writing a book in
troff.  The troff source files take the place of C source code, PostScript or
other typesetter files for the print house take the place of the executable
binary, and a Makefile is used to drive the flow.  The author edits the book
source files with vi and regenerates the generated files on each iteration by
running 'make'.  It isn't software, but the intellectual creation flow is
virtually identical.  uEDA applies the same model to hardware design.

So what is the source code for hardware, and what is the final product that
should be generated by 'make all'?  Well, the ultimate final product is the
physical board which you can hold in your hand, but the most "final" product
that can be made on a computer would be a set of gerber files for PCB
fabrication, a bill of materials (BOM) for the purchasing or other procurement
of parts, and a set of assembly instructions to be handed to the assembly line
workers who populate the parts on the board.  The starting source code would
be the schematic design.

The ultimate UNIX-model EDA suite would thus be one that can generate all final
manufacturing files from the schematic source code with a single 'make' command.
uEDA is almost there, except for the layout step.

The problem is that even with the best EDA technology PCB layout still involves
considerable human effort, and is thus not something that can be done by a batch
program that works from stdin to stdout.  Therefore, the PCB layout file is
subject to human editing and is not just an intermediate file between schematics
and gerbers like a .o file in the software compilation flow.

The uEDA solution is to view the job of designing a board as two separate
intellectual creation jobs, each with its own UNIX-model Makefile-driven flow.
These two jobs are the design and the layout.  uEDA addresses the design.  The
uEDA suite does not really get involved in the layout, but is designed with the
assumption that the layout will be done with the free & open source PCB program
(http://pcb.sourceforge.net/).  The two are connected by the "pre-layout" step
described in prelayout.txt.

(Note that such separation of the design and layout jobs is additionally
 supported by the fact that in many engineering companies these jobs are done
 by different people.)

In the design phase addressed by uEDA, the source code is the set of schematic
sources and the Master Component List (MCL), a human-edited text file documented
in mcldoc.txt.  The products that can be generated from these sources with a
Makefile are:

* Printable schematics (PostScript or PDF) for documentation;
* A set of "pre-layout materials" for handing to the PCB layout person;
* Bill of Materials (BOM) in different formats for part procurement, for
  assembly and for quick reference.

In the layout phase the .pcb that is both read and written by the PCB GUI is the
source code, and pcb can be invoked from the command line without the GUI to
generate gerbers, PostScript prints of the layout and other product files from
it; those generations can be codified in a Makefile, once again creating the
traditional UNIX flow.

Design source code structure

The source code for a board design in uEDA consists of 3 major parts:

* Information about all components on the board;
* Electrical interconnect information: how these components are interconnected
  with nets;
* Graphical information used to construct PostScript prints of the schematic
  sheets.

The core philosophy of uEDA is that these 3 kinds of information should be kept
as orthogonal as possible.  Component information is stored in the Master
Component List (MCL) documented in mcldoc.txt, whereas the interconnect and
graphical schematic information is stored in the schematic sheets (.usch files)
documented in uschemlang.txt.  Although the electrical interconnect and
graphical information are stored together, the uschem language is designed to
provide a high degree of orthogonality between the two.  Schematic sheets can
be either graphical or non-graphical.

Further reading:

bom_model.txt	Describes the uEDA approach to BOM handling
drc.txt		Describes the means for helping ensure a match between the
		actual electrical interconnect and the graphical representation
graphsyms.txt	Information about graphical symbols used on schematic sheets
mcldoc.txt	Master Component List document
netlisting.txt	Describes uEDA's handling of netlist information
prelayout.txt	Describes what I mean by "pre-layout"
psfeatures.txt	Describes the features available in the PostScript prints of
		schematic sheets made with uschem-print(1)
uschemlang.txt	uschem language document
*.1		Man pages for all uEDA utilities