Using Eagle for PCB design Part 2, high speed mixed signal design techniques Mike Twieg Case Western...
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Transcript of Using Eagle for PCB design Part 2, high speed mixed signal design techniques Mike Twieg Case Western...
Using Eagle for PCB designPart 2, high speed mixed signal design techniques
Mike TwiegCase Western Reserve UniversityNovember 21st 2011
Overview
• Wrap up from part 1: Exporting design files from Eagle, and submitting files for manufacturing
• Recommendations on SMT packages• High speed signal propagation• Mixed signal layout design• 4 layer design techniques
Design finishing checklist
• Make sure the design rule checker (DRC) settings match the design for manufacture (DFM) rules for the manufacturer
• No DRC errors (unless you are sure they are benign)• No outstanding ERC warnings. No design inconsistencies• No unrouted traces
– Turn off all layers except “unrouted,” you should see nothing
• If you intend to have a silkscreen printed:– You can export any layers to the silkscreen during the CAM process– Common layers: Names, values, place, docu
Gerber files
Gerber is a common CAD format which describes images using vectors
Industry standard is now RS-274X (extended Gerber format)Several Gerber files are needed, each having info from multiple
layers in your layout editor
Information on drill hits is not included in Gerber files.Excellon files contain drill coordinates and sizes.
The CAM processor
The CAM processor is used to export the Gerber and Excellon filesOpen the CAM processor through the layout toolbar The CAM uses job files to perform specific tasks• Export Gerber files with gerb274x.cam• Export Excellon drill file with excellon.cam
Exporting Gerber filesEach tab is a different Gerber file
to be generatedWe highlight which layers in the
layout editor are exported to each Gerber file
Eagle does most of the work for usFor two layer designs, we should
only need to choose which layers to export to the silkscreen(s). Usually dimension, place, value, and/or docu layers.
Make sure all the layers you want to export are enabled in the layout editor!!
Exporting Excellon drill fileNow open up the job excellon.camExporting the Excellon file is even
easier than the Gerber filesUse default options, unless you
really know what you are doing!
Make sure all the layers you want to export are enabled in the layout editor!!
Preparing design files
After running the gerb274x and excellon job files, you should end up with up to 9 files total with the following extensions
• Filename.cmp (top copper layer)• Filename.sol (bottom copper layer)• Filename.stc (top soldermask layer)• Filename.sts (bottomsoldermask layer)• Filename.plc (top silkscreen layer)• Filename.pls (bottom silkscreen layer)• Filename.drd (excellon drill file)• Filename.dri (info on drill toolset – not needed)• Filename.gpi (general board info – not needed)
Rename each file with its specific function, and put them all in one ZIP archive
Previewing Gerber filesIf you want to examine your Gerber files, you can use Pentalogix Viewmate.
The free version allows you to easily view, but not edit, gerber files.
Hint: if your drill data looks “exploded” when imported, check the settings on leading/trailing zeros
Submitting files for fabrication
The steps for submitting files will depend heavily on the manufacturer
It is highly recommended that you first use the manufacturer’s DFM (Design for Manufacturing) checker to check that your design conforms to their capabilities
If you don’t pass their DFM checker, then you must change your DRC rules to be consistent
We will be using Advanced Circuits as an example
Using Advanced Circuits
First use the DFM checker at freedfm.com• When submitting the files for a DFM check, you will upload the zip file
with your design• You must tell the DFM checker which file corresponds to which layer or
function• You must also tell it some specifications of the design (number or layers,
size, etc)• Submit the files and wait for results via email…
If you pass the DFM checker, you may then submit the design for fabrication
The process for ordering boards is almost identical to using the DFM checker, plus shipping and billing information
Advanced circuits free DFM checker
Advanced circuits DFM checker
Using the DFM checker
After submitting, you should receive an automated analysis from freeDFM.com, which includes two things of importance:
• Plots layer review, which shows you PDF images of each layer• Any DFM errors found. All “show stoppers” should be fixed. Potential
problems can often be left alone (especially ones relating to silkscreen layers)
If you pass the DFM check, then you can order the board for real. The process for ordering is almost exactly the same as for the DFM check.
Leaded IC packages
SOP, SOIC
SSOP, QSOP
TQFP
MSOP, VSOP
EQFP
1.27mm (easy) 0.65mm (medium) 0.5mm (difficult)
SOT23
SC70 SC75
Leaded IC packages
QFN
0.5-0.65mm (not too bad) 0.4-0.5mm (pretty hard) BGA (death is certain)
LFCSP
DFNMany varieties
Two terminal packages
For resistors/capacitors and inductors, 0805 is a good compromise between difficulty and density:
For diodes, SOD123 and SOD323 are good choices:
Often larger packages are needed in order to dissipate enough power or store more energy. Pay attention to component ratings!
High speed layout techniques
Special care must be taken when designing PCBs for high speed digital communication and analog systems
These techniques apply well to signals in the regime where transmission line effects are still negligible
• 50mbps for digital data signals, 100MHz for analog• Remember, digital signals have bandwidths far above their baud rates!• Normally care about up to 5th-7th harmonics for data signals, 7th-9th
harmonics for clock signals!
First we look at how to preserve intentional signals
High speed signal propagation
All high speed signals should be adjacent to at least one reference planeAt high frequencies, currents in traces will return in any adjacent planes
Cross section of microstrip trace Cross section of stripline trace
Return current pathsExample: one microstrip trace with a source and a load
?
ALZ
Return current paths
At high frequencies, return currents want to form smallest loopsTherefore they try to run underneath the signal traces
Current distributions for high speed microstrip trace
Return current pathsReturn currents can be interrupted by split reference planes
These large current loops will cause distortion and emit additional EMI!
Bypass capacitorsBypass capacitors are critical for keeping low loop areas and low
impedances at high frequencies
Bypass capacitor selectionFor bypass caps to be effective:• Should be placed as close to the IC supply pins as possible• Use at least one per IC
Capacitors are not perfect: self resonance• Can deal with self resonance by using
several capacitors in parallel of different sizes
• Smaller packages will have lower ESL, higher SRF
Stitching capacitorsCan bridge plane splits with capacitors, allowing return currents to pass
This will reduce isolation between the two planes at HF. This is not wise, especially when crossing to or from analog partitions!
Signals changing layersSometimes it is necessary to have a signal change layers with a viaWhen this is done, the return current also changes layers!Need to provide a good path for the return current between layers
• Use vias to locally connect the two planes
• This only works when those two planes are actually the same potential!!
Signals changing layersWhen changing layers AND changing reference planes, we cannot use a via
for return currentsThis is often the case with 4 layer board stackups (signal, GND, Vs, signal)We can use stitching caps to improve return currentsEven so, this is a mess and is not suitable for very high speeds…Simply put, high speed signals should not change reference planes!
Differential signaling
Differential signals use pairs of traces to form closed current loopsReturn currents on reference planes are greatly reducedPairs must be routed close together to be effective
Not a perfect solution: can still carry common mode return currents. Not the same as signal isolation!
When all else fails…If EMC/crosstalk performance is critical, then complete isolation may be
necessary to cross splitsIsolation can be optical or galvanic
x Always some propagation delay, and limited bandwidthx Large packages, costly Can be used for logic level translation Very useful for interfacing to I/O ports where isolation is important
Basic optocoupler Digital magnetic coupler
Mixed signal designMixed signal design: any design where analog and digital systems
operate in the same environmentIf you have a DAC or ADC in your design, it’s mixed signal.Power supplies may be considered analog systems
Good mixed signal design is critical when digital and analog portions work at overlapping bandwidths
Mixed signal design goalsOur goal is to prevent unintentional signals form causing
interaction between digital and analog systemsInteraction can be caused by conduction and field couplingMost basic rule is to spatially partition analog and digital sections
Design example: ADS8329 16 bit ADC• 3.3V digital supply• 5.0V analog supply• 25MHz SPI interface• External analog shunt reference voltage• Use 9 pin header for digital signals and power supplies• Use edge SMC connector for analog signal in
Example schematic
Example Layout
Example LayoutAll high speed signals have their own return paths
Reference is grounded on analog side
Bypass caps close to supply pins
Ferrite bead across split
Example Layout (bottom layer only
Partitioning
We can make multiple sub-partitions by making additional splits in the reference planes
This can decrease crosstalk between analog channels
Partitioning
We do not split the ground plane completelyThe analog and digital supply pins of ADCs/DACs must be kept close to the
same potentialCommon practice is to join the supply planes only underneath the ADCs/DACsSignal traces may only cross between partitions at that point
Q: Do we need completely different power supplies for different partitions?A: No, but we need to partition that power supply using split planes, ferrite
beads, and bypass capacitors so that the two partitions do not share current paths at HF
Choking suppliesExample: Using one regulator for both digital and analog partitions
A ferrite bead provides HF current loops between the two partitions
Ferrite beads
Capacitors are useful for encouraging HF current to flow along certain pathsFerrite beads are high impedances at HF, and prevent HF currents from
flowing through themFerrite beads are not inductorsBoth imaginary and real
impedance increase with frequency, peak, and then decrease
Forms damped resonances with bypass capacitors, so much less ringing
Considerations for SMPSSwitch mode power supplies present great challengeGenerate high dv/dt and di/dt, which causes lots of emissionsPrevent B field emissions by minimizing loop areasPrevent E field coupling by screening with reference planes
Considerations for SMPSSwitch mode power supplies present great challengeGenerate high dv/dt and di/dt, which causes lots of emissionsPrevent B field emissions by minimizing loop areasPrevent E field coupling by screening with reference planes
Very high di/dt
Considerations for SMPSSwitch mode power supplies present great challengeGenerate high dv/dt and di/dt, which causes lots of emissionsPrevent B field emissions by minimizing loop areasPrevent E field coupling by screening with reference planes
Very high dv/dt
Very high di/dt
Considerations for SMPS• High di/dt loop is minimized• Capacitive coupling from
high dv/dt node may be an issue
• Can use ground layer as a screen by putting other sensitive components on bottom side
• Always best to move SMPS as far from analog circuitry as possible
Beyond two layersWhen it is not possible to adhere to good design techniques, you may need
more layers
Spacing between each layer may not be equal! Very important for high speed design.
Distributed capacitance between inner reference layers is useful for high frequency bypassing
Common four layer stackup:• One inner layer is for ground
plane(s) only.• Other inner layer is reserved
for non-ground supply rails• Outer layers are for traces and
components
Four layersFour layer designs have two key advantages• Separate layer for power supply routing• Both sides are freely available for components and signal tracesThis allows for much easier design and higher density
However, in general, signals cannot change layers in this stackup without changing reference planesProperly guiding return currents across multiple reference planes is difficultTherefore, unless you do not need signals to change layers, four layer designs are not suitable for high frequency designs!
Six layersOne common six layer stackup: equivalent to four layer stackup with two
more outer signal layers addedSignal layers 1 and 2 both use reference layer 3 for returnSignal layers 5 and 6 both use reference layer 4 for returnTraces on layer 1/6 run orthogonal to traces on layer 2/5, to reduce crosstalk
Six layersAnother six layer stackup: equivalent to four layer stackup with two more
inner signal layers addedSignal layers 1 and 3 both use reference layer 3 for returnSignal layers 4 and 6 both use reference layer 5 for returnTraces on layers 3 and 4 should run orthogonal to prevent crosstalk
ConclusionsEffective high layout design is all about controlling current paths• Intended current paths should be uninterrupted and low impedance• Unintended current paths should be minimized with proper partitioning
and isolation
Number of layers and stackup type will depend on design requirements
• It is perfectly reasonable to have very high bandwidth systems on 2 layer boards. However, traces cannot cross or change layers easily
• Moving to four layers allows more freedom for routing traces, on both sides, but traces still cannot change layers without risking signal integrity
• In complex designs in which signal busses must cross, at least six layers will usually be necessary
ConclusionsProper mixed signal design is achieved by preventing shared
current paths between analog and digital systems• Component placement is at least as important as signal routing• We do not use completely split ground planes, but rather partitioned
planes which connect at specific locations• Multiple sub-partitions can be made by further dividing the reference
planes• Analog and digital partitions can share supply rails, but care must be taken
to introduce new high frequency current paths
Any questions?