-
- News
- Books
Featured Books
- design007 Magazine
Latest Issues
Current IssueAdvanced Packaging and Stackup Design
This month, our expert contributors discuss the impact of advanced packaging on stackup design—from SI and DFM challenges through the variety of material tradeoffs that designers must contend with in HDI and UHDI.
Rules of Thumb
This month, we delve into rules of thumb—which ones work, which ones should be avoided. Rules of thumb are everywhere, but there may be hundreds of rules of thumb for PCB design. How do we separate the wheat from the chaff, so to speak?
Partial HDI
Our expert contributors provide a complete, detailed view of partial HDI this month. Most experienced PCB designers can start using this approach right away, but you need to know these tips, tricks and techniques first.
- Articles
- Columns
Search Console
- Links
- Media kit
||| MENU - design007 Magazine
Estimated reading time: 1 minute
Beat the Traffic Jam - Effective Routing of Multiple Loads
In a previous Beyond Design, Impedance Matching: Terminations, I discussed various termination strategies and concluded that a series terminator is best for high-speed transmission lines. Different terminating strategies have advantages and disadvantages depending on the application, but, in general, series termination is excellent for point-to-point routes, one load per net. In summary, series termination reduces ringing and ground bounce.
But, what if there are a number of loads--how should these transmission lines be routed? For perfect transfer of energy and to eliminate reflections, the impedance of the source must equal the impedance of the trace(s) to the load.
Bifurcated transmission lines, traces that are split into two or more T-sections, are sometimes used to distribute signals to multiple loads. The impedance of the bifurcated line is not constant along the trace route, as the traces branching from the T-section are virtually in parallel when you consider the equivalent AC circuit. In this case, proper termination has not been provided and an impedance discontinuity can be seen at the branch point. In Figure 1, a 50 ohm signal from the driver is split into two transmission lines of 50 ohms and then into the loads. At branch (A), the two 50 ohm traces in parallel equate to a 25 ohm equivalent trace, and a mismatch in impedance. Figure 2 illustrates the resultant waveform of the unmatched transmission line.
Editor's Note: This column originally appeared in the February 2014 issue of The PCB Design Magazine.
More Columns from Beyond Design
Beyond Design: High-speed Rules of ThumbBeyond Design: Integrated Circuit to PCB Integration
Beyond Design: Does Current Deliver the Energy in a Circuit?
Beyond Design: Termination Planning
Beyond Design: Dielectric Material Selection Guide
Beyond Design: The Art of Presenting PCB Design Courses
Beyond Design: Embedded Capacitance Material
Beyond Design: Return Path Optimization