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Construction of electronic systems
C.Bohm
Components
+
connections
2-pole (resistors), 3-pole (transistors)
4-pole (transformers)+..+10-pole vacuum tubes)
John Pinkerton
First one used components mounted on isolating cards, connected by soldered connections
Increased component density demanded other methods
Integrated circuits
DIL (dual in line) packages
Hole mounted <30 legs
+
single or double sided circuit boards
wire wrapped circuit boards
DIL
wrapped circuit boards
printed circuit boards
crossing leads problems with single sided boards (can be solved by jumpers)
You can use vias on double sided boards (metal deposited holes usually 0.2-1 mm)
LSI (large) ic-circuits
+
Large DIL <100 legs
PGA (pin grid array) better <350 legs
PGA
multi layer boards
many routing layers
Special power planes supply power to the components
Long connections have inductance
Active component
“Ground bounce”
Varying current transport
Power plane with low inductance
Nearby decoupling capacitors
Deliver charges that can supply the current transients
They work like energy reservoirs
Ground plane with low inductance
Ground and power plane have also
good shielding properties
Return current
Low frequent
Signal current
Minimize
resistance
A cut in the ground plane forces the return current to deviate
which affects the signal quality
High frequent
Signal current
Return current
Minimize
inductance
A cut in the ground plane can also increase
the cross talk between nearby signals
Micro strip
Stripline
Wide trace and small distance gives a large
capacitance – difficult to drive
Circuit board materials:
FR4 (flame retardent 4)
Roger (brand name) high speed
Poly imide (Kapton) – flexfoïls
Rigid flex = combination FR4-Flex foil
Multi layer boards allows blind and covered vias
Thru
blind
hole blind
Usually <10 layers
Trace widths>0.1 mm
Isolations distance>0.1 mm
Vias>0.25 mm dia
dold
covered
Vias through power planes
Sufficiently large diameter
to match
The drill tolerance
Surface mounting Drop via
Higher densities
vias
> 0.25mm
SO
≤28 legs
>0.5 mm/leg
Via to powerplane
Thermal via to simplify
usually < 10 layers
trace widths >0.1mm soldering
PQFP
<400 legs
>0.4mm/leg
BGA
<600 legs
1.27mm/leg
micro BGA, CSP <2000 <1mm/leg
Difficult to extract the signals between the balls
Many layers are needed
Alternative: use laser drilled thin micro via layers which
supports very thin traces
Pictures from elektrotryck.se
Laser drilled vias
Pictures from elektrotryck.se
From PCBpro.com
Step#1 Film Generation:
Generated from your design files, we create an exact film
representation of your design. We will create one film per layer.
Step#2 Shear Raw Material:
Industry standard 0.059" thick, copper clad, two sides. Panels
will be sheared to accommodate many boards.
Step#3 Drill Holes:
Using NC machines and carbide drills.
Step#4 Electroless Copper:
Apply thin copper deposit in hole barrels.
From PCBpro.com
Step#5 Apply Image:
Apply photosensitive dryfilm (plate resist) to panel. Use light
source and film to expose panel. Develop selected areas from
panel.
Step#6 Pattern Plate:
Electrochemical process to build copper in the holes and on the
trace area. Apply tin to surface.
Step#7 Strip & Etch:
Remove dryfilm, then etch exposed copper. The tin protects the
copper circuitry from being etched.
Step#8 Solder mask:
Apply solder mask area to entire board with the exception of
solder pads.
From PCBpro.com
Step#9 Solder coat:
Apply solder to pads by immersing into tank of solder. Hot air
knives level the solder when removed from the tank.
Step#10 Nomenclature:
Apply white letter marking using screen printing process
Step#11 Fabrication:
Route the perimeter of the board using NC equipment
PCB manufacture
· PCB laminate about 0.2mm – different types: FR4, Polyimide (Kapton) and Roger
· drill
· electrolytic plating of holes– connect a voltage source to the two sides while in a
bath
· add photo resist
· illuminate pattern
· rinse
· etch
· build the layer chemically
· glue several layer
· component print
· lack layer
· test with beds of nails or flying probes
Mounting components
Hole mounting
·
·
·
mount components
wave soldering
test
Surface mounting
·
·
·
·
·
·
solder mask
spread solder paste
mount components (with robot)
heat in oven
next side
test
Circuit board data
generate pattern for the different layers – artwork
generate drill files
Control files to milling machine (to separate and shape the boards)
Different layers
Cupper pattern
Component print
Lack layer
Solder mask
Different physical layers
1
signal_1
2
power_1
3
power_2
4
signal_2
pad_1
pad_2
(artwork order)
Start by creating a schematic
Decide board size – shape, silkscreen print, mounting holes, placing and routing zones
Make sure there is a pattern for each component – pads, holes, vias and component print
connect schematic symbols with legs to component pattern with pads
package circuit board data – translate schematics with symbols to component pattern and net list
place components on the board (side, position, orientation, ref nr) – manual, automatic or combined
draw traces in the connection layer (with support from schematics) – manual, automatic or combined –
different trace which gives different impedances
split ground plane – avoid couplings between analogue and digital parts
area fills – fill empty areas with grounded cupper surfaces
Soldering
Soldering in solder oven:
Double sided mounting
difficult
Temperature profile
Solder quality
OK
OK
Not
solder
För enough
lite lödtenn
Insufficient wetting
Dålig vätning
Inferior wetting depend on poor heating or insufficient amount of flux
Lead free solder enforced in industry – higher temperatures
Conductive glue is sometimes an alternative
ESD-protection
ESD = Electrostatic Discharge
ESD damage
ESD floors (ground conductive floors)
ESD shoes (ground feet against floors)
ESD wrist band (grounds arm against table top)
At 50% humidity the human discharges
rarely produce more than 2000V
At 5% they can easily reach 15000V
Burn-in
Accelerated aging at elevated temperatures
Failure rate
Inputs are often protected by diodes
Shaking to provoke cold solder joints
Thermal cycling
Bath tub curve
time
Burn-in