Placing
Components
Generally, it is best to
place parts only on the top side of the board.
When placing components,
make sure that the snap-to-grid is turned on.
Usually, a value of 0.050" for the snap grid is best for
this job.
First place all the
components that need to be in specific locations. This
includes connectors, switches, LEDs, mounting holes,
heat sinks or any other item that mounts to an external
location.
Give careful thought when
placing component to minimize trace lengths. Put parts
next to each other that connect to each other. Doing a
good job here will make laying the traces much
easier.
Arrange ICs in only one or
two orientations: up or down, and, right or left. Align
each IC so that pin one is in the same place for each
orientation, usually on the top or left sides.
Position polarized parts
(i.e. diodes, and electrolytic caps) with the positive
leads all having the same orientation. Also use a square
pad to mark the positive leads of these components.
You will save a lot of time
by leaving generous space between ICs for traces.
Frequently the beginner runs out of room when routing
traces. Leave 0.350" - 0.500" between ICs, for large ICs
allow even more.
Parts not found in the
component library can be made by placing a series of
individual pads and then grouping them together. Place
one pad for each lead of the component. It is very
important to measure the pin spacing and pin diameters
as accurately as possible. Typically, dial or digital
calipers are used for this job.
After placing all the
components, print out a copy of the layout. Place each
component on top of the layout. Check to insure that you
have allowed enough space for every part to rest without
touching each other.
Placing Power and Ground
Traces
After the components are
placed, the next step is to lay the power and ground
traces. It is essential when working with ICs to have
solid power and ground lines, using wide traces that
connect to common rails for each supply. It is very
important to avoid snaking or daisy chaining the power
lines from part-to-part.
One common configuration is
shown below. The bottom layer of the PC board is used
for both the power and ground traces. A power rail is
run along the front edge of the board and a ground rail
along the rear edge. From these rails attach traces that
run in between the ICs. The ground rail should be very
wide, perhaps 0.100", and all the other supply lines
should be 0.050". When using this configuration, the
remainder of the bottom layer is then reserved for the
vertical signal traces.
Placing Signal
Traces
When placing traces, it is always a good practice to
make them as short and direct as possible.
Use vias (also called
feed-through holes) to move signals from one layer to
the other. A via is a pad with a plated-through
hole.
Generally, the best strategy
is to lay out a board with vertical traces on one side
and horizontal traces on the other. Add via where needed
to connect a horizontal trace to a vertical trace on the
opposite side.
A good trace width for low
current digital and analog signals is 0.010".
Traces that carry
significant current should be wider than signal traces.
The table below gives rough guidelines of how wide to
make a trace for a given amount of current.
0.010" 0.3
Amps 0.015" 0.4 Amps 0.020" 0.7 Amps 0.025" 1.0
Amps 0.050" 2.0 Amps 0.100" 4.0 Amps 0.150" 6.0
Amps
When placing a trace, it is
very important to think about the space between the
trace and any adjacent traces or pads. You want to make
sure that there is a minimum gap of 0.007" between
items, 0.010" is better. Leaving less blank space runs
the risk of a short developing in the board
manufacturing process. It is also necessary to leave
larger gaps when working with high voltage.
When routing traces, it is
best to have the snap-to-grid turned on.
Setting the snap grid spacing to 0.050" often works
well. Changing to a value of 0.025" can be helpful when
trying to work as densely as possible. Turning off the
snap feature may be necessary when connecting to parts
that have unusual pin spacing.
It is a common practice to
restrict the direction that traces run to horizontal,
vertical, or 45 degree angles.
When placing narrow traces,
0.012" or less, avoid sharp right angle turns. The
problem here is that in the board manufacturing process,
the outside corner can be etched a little more narrow.
The solution is to use two 45 degree bends with a short
leg in between.
It is a good idea to place
text on the top layer of your board, such as a product
or company name. Text on the top layer can be helpful to
insure that there is no confusion as to which layer is
which when the board is manufactured.
Checking Your Work
After all the traces are
placed, it is best to double check the routing of every
signal to verify that nothing is missing or incorrectly
wired. Do this by running through your schematic, one
wire at a time. Carefully follow the path of each trace
on your PC layout to verify that it is the same as on
your schematic. After each trace is confirmed, mark that
signal on the schematic with a yellow highlighter.
Inspect your layout, both
top and bottom, to insure that the gap between every
item (pad to pad, pad to trace, trace to trace) is
0.007" or greater. Use the Pad Information tool
to determine the diameters of pads that make up a
component.
Check for missing vias.
ExpressPCB will automatically insert a via when
changing layers as a series of traces are placed. Users
often forget that via are not automatically inserted
otherwise. For example, when beginning a new trace, a
via is never inserted. An easy way to check for missing
via is to first print the top layer, then print the
bottom. Visually inspect each side for traces that don't
connect to anything. When a missing via is found, insert
one. Do this by clicking on the Pad in the side
toolbar; select a via (0.056" round via is often a good
choice) from the drop down listbox, and click on the
layout where the via is missing.
Check for traces that cross
each other. This is easily done by inspecting a printout
of each layer.
Metal components such as heat sinks, crystals,
switches, batteries and connectors can cause shorts if
they are placed over traces on the top layer. Inspect
for these shorts by placing all the metal components on
a printout of the top layer. Then look for traces that
run below the metal components. |