Signal Integrity Design
Signals that behave — by design and by verification. Best practices combined with post-layout simulation to guarantee long-term quality.
SI Problems Are Preventable — If You Design for Them
Signal integrity problems — reflections, crosstalk, ground bounce, power rail noise, setup/hold violations — are among the most difficult and time-consuming issues to debug on a physical board. They manifest as intermittent failures, data corruption, system lock-ups, and reduced operating margins that only appear under specific temperature, voltage, or loading conditions.
They are also almost entirely preventable through disciplined design practice applied during schematic and layout. At Pabst Electronics, signal integrity engineering begins at the schematic stage and continues through PCB layout and post-layout simulation — ensuring that every high-speed and sensitive signal behaves correctly before the first board is fabricated.
This combination of disciplined practice and systematic verification gives designs the robustness needed to guarantee long-term quality in the field — across production variation, temperature extremes, and component aging.
SI Engineering Process
From Schematic to Verified Layout
〰️ Controlled Impedance Routing
High-speed signal traces routed to controlled impedance specifications — microstrip, stripline, and coplanar waveguide topologies selected based on layer assignment, frequency, and manufacturing capabilities of the target PCB fabricator.
↔️ Differential Pair Management
Differential pair routing with length matching, intra-pair skew control, and matched impedance — for USB, Ethernet, LVDS, HDMI, PCIe, and other differential interfaces. Common-mode filtering and ESD protection co-designed with the routing strategy.
🔄 Return Path Engineering
Every signal has a return current path. We engineer return paths to be short, continuous, and low-impedance — avoiding reference plane splits under high-speed signals, managing via transitions, and placing stitching capacitors at plane discontinuities.
⚡ Power Distribution Network (PDN)
PDN design for stable power delivery across the full frequency range — from DC load transients to high-frequency switching noise. Decoupling capacitor selection, placement optimization, bulk capacitance, and VRM loop bandwidth co-designed for each power rail.
🔇 Crosstalk Mitigation
Spacing rules between aggressor and victim traces, guard routing where required, and layer assignment to minimize capacitive and inductive coupling — applied to both single-ended and differential signals in high-density layouts.
🔬 Post-Layout Simulation
Post-layout signal integrity simulation using extracted layout parasitics — eye diagram analysis, timing margin verification, crosstalk analysis, and PDN impedance profile. Simulation results documented and design changes implemented before first fabrication.
- Signal integrity design guidelines and routing rules document
- Controlled impedance specifications for PCB fabricator
- PDN design — decoupling capacitor selection and placement rationale
- Post-layout SI simulation report — eye diagrams, timing margins, crosstalk analysis
- PDN impedance profile
- SI design review findings and resolution log
Dealing with High-Speed Signals or Mixed-Signal Complexity?
Let our signal integrity engineers define the stack-up, routing rules, and PDN strategy for your design — and verify the result through post-layout simulation before the first board is fabricated.
Talk to an SI Engineer