Printed Circuit Board (PCB) Layout

A printed circuit board (PCB) mechanically supports and electrically connects electronic components using conductive tracks, pads and other features etched from copper sheets laminated onto a non-conductive substrate. PCB's can be single sided (one copper layer), double sided (two copper layers) or multi-layer. Conductor on different layers are connected with plated-through holes called vias. Advanced PCB's may contain components - capacitors, resistors or active devices - embedded in the substrate.

The connections on a PCB should be identical to its corresponding circuit diagram, but while the circuit diagram is arranged to be readable, the PCB layout is arranged to be functional, so there is rarely any visible correlation.

PCB layout can be performed manually (using CAD) or in combination with an Autorouter. The best results are usually still achieved using atleast some manual routing - simply because the design engineer has a far better judgement of how to arrange circuitry. Surprisingly, many autorouted boards are often completely illogical in their track routing - the program has optimised the connections, and sacrificed any small amount of order that may have been put in place by manual routing. Generally autorouted boards are somewhat harder for a technician to repair or debug, for this reason. Historically, PCBs used to be laid out by using stick on paper shapes and tape on mylar drafting film, - that really WAS manual routing!

The CAD PCB layout consists of several layers, for illustration often the layers will be coloured and compressed into the one overlay image. (Click here to see a typical overlay, and Click here to see a colour coded key diagram) The circuit design and the PCB overlay image will usually be supplied by the designer to the client in a PDF document produced by the CAD package. The PCB overlay may quite easily be printed out actual size, cut out, and used for approximate size comparisons with mechanical items - for instance the print can be placed inside the actual enclosure, to see how it will be positioned in relation to other parts. Components can also be placed up against the pad markings as a quick idiot-check of dimensions.

It is worth putting a bit of effort into the PCB design - it is somewhere where quality of design can make a difference. The width of the tracks is a trade-off based on current flow, space available, size of parts, and electromagnetic interference. The track layout is a similar trade-off that also picks when to dodge from one side of the board to the other to avoid an obstacle, but overall normally aims to find the shortest regular path between the connected points. Given the impedance, susceptibility, and signal on tracks, the loop area is another trade-off that is considered as the design proceeds. And then, added to all that is Design-for-manufacture.

These days most circuit boards are automatically assembled and tested - but people still install and repair them. Having a quality design can make all the difference between a product that is pleasant to work on and one that they will hate. Machine test points, for ATE (Automated Test Equipment) bed of nails testing, only need to be plain pads or lands. Some test points, however, are really intended to be for engineering test or modification - for these it is better to put in labelled, circled pads.

Most PCBs have a silkscreen identification overlay (usually white on Green PCBs). Improving the overlay is another way to make a better PCB. The silkscreen contains important information that assists people to build, service and install the product. Aside from the PCB functionality (which is rather obvious) the overlay is the chief distinguishing feature between a purpose-built product, and a general-purpose controller or ready made PLC. A well made custom or purpose-built product would label terminals as: "+12v red" "-pwr black" "solenoid+" "solenoid-" whereas a general purpose kit board may often just give you: "A1 A2 A3 A4". The makers of the kit board don't have much of a choice - they have no idea what you will attach to the terminals.

As PCB component density rises, it is often necessary to reduce the labelling - there is just not enough room. The first best measure is to drop the size of the lettering. Then either move the component values under components (where they may possibly be read before board assembly, and definitely still read in the documentation overlay diagram) or omit the values. Then last do the same, if absolutely needed, for the designators. The pin 1 labelling and orientation labelling for components and connectors cannot be removed - even when automated pick and place machines are used, the visual backup is imperative for assembly and repair.

The silkscreen is the primary method for labelling connectors, replaceable parts, orientation, and even installation notes (for instance "Remove J2 while replacing battery - observe battery polarity"). It can also used as a backup for manufacturing notes (for example "Mount R2 approx 5mm off circuit board due to high temperature", or more likely "Space up 5mm: HOT") although now it is probably more usual to put these notes in the BOM. With the way the electronics industry is changing at present, there are more third-party boards with a substantial amount of Chinese language labelling on the Silkscreen. It certainly makes those boards more difficult (for us) to use.

The PCB layout also needs to take account of electrical interference. The main techniques used are shielding using areas of copper, and reduced power supply impedance using either multilayer boards (the best, although more expensive, solution) or increased width of power supply tracks. There is further information on this EMI and ESD compliance page. AirBorn has an (older) tutorial on designing PCBs - it steps through the CAD process from schematic to layout. AirBorn Electronics supports the (free) Autotrax CAD package. For those intending to design PCBs themselves, we recommend this manual on PCB layout.

Most standard Etched PCB laminates are:
Double sided Laminate
Two layers of copper tracks, one each side of the board
In progressively smaller Quantities
4 Layer, 6 Layer, 8 Layer
The real advantage with 4 layer boards is that the internal layers are usually dedicated power distribution - this decreases the loop area and power supply impedance giving a dramatic boost to EMI performance. 6 layers and above adds extra layers for PCB tracks, allowing denser higher performance circuitry. As a very rough rule of thumb, PCBs are often priced "per layer" - ie the bare laminate for an 8 layer board may perhaps be 4 times the price of its 2 layer equivalent.
Plated Through Hole
PTH - each hole is copper plated providing a circuit between sides of the PCB. Normally AirBorn also Tent the vias - cover them with solder mask - others may do this or leave the soldermask open over vias so that they fill up when wave soldered.
Fibreglass-resin laminate (FR4) is the standard dielectric material.
Solder Mask Over Bare Copper
SMOBC - green insulating ink everywhere except connections (Other colours are available - commonly White, Black, Blue, Red)
Component legend
Identifying lettering, component outlines and values (usually) in white ink
Immersion Silver for ROHS compliant work (a definition for ROHS is further below)
Silver plate on all exposed copper, prevents oxidation and so keeps the surface solderable. An alternative is electroless gold.
Tinned For non-ROHS work
Tinning is application of Lead-Tim Solder to all exposed copper, increasing solderability
Hot Air Solder Levelled: HASL
Hot oil - or hot air (HASL) - levelling makes the tinning flat, so that surface mount components can be positioned reliably.
Different methods of PCB construction:
Conventional
A rigid PCB (usually of thickness 1.6mm), with wire-leaded components mounted on only one side of the PCB, with all the leads through holes, soldered and clipped. Conventional circuitry is generally easier to debug and repair than Surface mount.
Surface Mount Technology (SMT) or devices (SMD)
A PCB with tag-leaded components soldered flush to PCB pads. Holes are still needed on the PCB, but not where the component leads are attached. Surface mount circuitry is generally smaller than conventional. Surface mount is generally more suited to automated assembly than conventional.
Surface mount & conventional mix
In practice, most boards are a mix of surface mount and conventional components. This can have its disadvantages as the two technologies require different methods of insertion and soldering.
Double sided Laminate
A bare PCB laminate having tracks on both sides, normally with PTH holes connecting circuitry on the two sides together.
Double sided Component Assembly
Mounting components on both sides of the PCB. Normally only surface mount circuitry would be mounted on both sides of a PCB, but some conventional components (such as LEDs) may be mounted on the reverse of a PCB to suit the enclosure design.
Multi-layer
A PCB Laminate may be manufactured with more than two layers of copper tracks by using a sandwich construction. The cost of the laminate reflects the number of layers. The extra layers may be used to route more complicated circuitry, and/or distribute the power supply more effectively.
Gold plated
Certain areas on a PCB may be gold plated for use as contact pads or as a ROHS-compliant board finish. Normally only a thin gold plating is required, and this can be achieved with electroless gold. If a thicker gold plating is required (for instance a quality 50um contact) an electrolytic process is needed. Normally this is limited to pads on the edge of a PCB, as an electrolytic plating bar must be attached to the pads, and then removed part way through the PCB manufacturing process. Gold plating normally needs a nickel underplate or the Gold quickly disappears through migration effects into the underlying copper.
Immersion Silver plating
A ROHS-compliant board finish that is a cost effective alternative to Gold
ROHS Compliance
Simple definition: Getting rid of the Lead in PCBs and components which poisons groundwater when it leaches out of discarded boards put in landfill waste dumps. Actually, lead is not the only substance covered, but it is the main one. Frankly it would also help if people stopped throwing away so much electronics, and that would be helped if boards were made to last.
Flexible PCB
A technique used extensively with membrane keyboards, combination connector/circuit boards, and circuit boards to fit in awkward shapes - e.g. cameras.
Chip On Board (COB)
Where the IC die is attached direct to a PCB, and bond out wires from the IC connect directly to PCB lands. The chip is then covered with a black blob of epoxy. A technique used mostly with very high volume, cost sensitive applications, e.g. musical greeting cards, LCD modules, calculators, some toys.
Phenolic PCB
As distinct from Fibreglass, Phenolic is a cheaper PCB laminate material.
Single sided Laminate
Most PCB laminates produced these days are double sided - wtih tracks on both sides of the board, and PTH vias joining the two sides. An alternative, most usually used with Phenolic PCBs, is single sided: Tracks on just one side. A limited number of connections are usually still needed on the top side of the board, and these are made with wire links. Single sided boards are cheaper to manufacture as no plating line is needed, and copper is only required on one face of the laminate, halving the resist and exposure work. However, in todays market, the price difference between single and double sided is not that great. The savings are realistic only for huge runs of relatively unsophisticated consumer electronics, such as pocket calculators.
Daughterboard
A circuit board mounted to another circuit board - such as a plug in card.

AirBorn Electronics Project Work


ChngRF1: Link Authentication Unit

Link Authentication Unit - Challenge/response type
Can Authenticate over RF Link
Gold Plated contact DB25 connectors
Plugpack powered




485hub1: RS485 Active Hub (5 port)

5 signal buffered party line data ports
Industrial grade pluggable wiring block connectors
Handles all NRZ protocols (Protocol independent)
Plugpack or 12v supply

485hub1: Technical documentation

ChngSMT1: DB25 to DB25 full duplex serial protocol converter, signal powered

Serial Protocol converter
Gold Plated DB25 connectors
Miniature, In-line
Normally placed between PC and Modem
RS232 signal powered
Custom programmed to clients protocol conversion requirements

AntSpik1: RS232 Anti-spike

Protects against spikes on RS232 COMs lines
Miniature, In-Line, DB25
6ns, 6kv ESD SCR clamps
Protects pins 1-8,20,22
Fusible MetFilm resistors

RS232 surge protectors are available commercially from most computer retailers. However, these rather inferior devices usually contain just two metal oxide varistors from the RS232 data lines to ground. In the event of a high voltage, the cheap protectors divert the surge current through the ground of the computer (without limiting it) and even then they do not isolate the source of the surge from the computer RS232 data lines.

In Contrast AntSpik1 protects all the PC RS232 lines and limits the current surge through fusible metfilm series resistors. Should the surge be too great, the metfilm resistors blow open circuit, protecting the equipment. The current flowing into the computer ground is limited. Any surge voltages are clamped very quickly using SCR clamp devices. AntSpik1 is probably the best surge protection you can buy that can be placed in-line with the equipment in a standard DB25 enclosure.

LiteKey1: Light coded key

Pulse Code Modulated Green light key
Key number in EEPROM
Miniature keyfob case
Field programmable
3v Battery operation

The Light key has the advantage that an IR learning remote cannot be used (in unmodified form) to steal the pass number of a borrowed key and thus gain unauthorised access.

RomEm2: Rom Emulator unit, 1 Megabit

Emulates 27C256 to 27C010 type EPROMs
Fast parallel download from PC
Auto target reset
Plugpack/target powered
Addressable-Gangable

SPD1: Single pump fuel access control unit

Large digit LCD and keyboard
RF key reader
CPU Based on 89C51 and 8/32kb EEPROM
separate Power Supply PCB with robust interface circuits

BatChg1: Battery pack conditioner-charger

Charges and Discharges to Battery spec - 24V 20 Cell packs
Dual unit - Charges/Discharges 2 packs at once
Standard 240VAC plug & 24VDC mobile version
Discharge switch for battery conditioning

Watcher1: Serial COMs display

AT89C2051 FLASH CPU based serial COMs monitor
Miniature, attaches to LCD display
DB9 Serial - PC compatible
Option dipswitch/ Attn Switch
Plug pack powered

232Mon1: RS232 Monitor/Talkover

Monitors both sides half duplex COMs with 1 port
Passively powered
Talkover switch
Loads lines only slightly
2 Test, 2 PC DB25's

NoisInj1: Serial Noise Injector

Injects wideband serial test noise at a button push
DB25 connectors
Miniature, In-line
RS232 powered
Gold plated connectors

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