Transmission

What’s Transmission?

 

In telecommunications, Transmission is the process of sending and propagating an analog signal or digital signal using a wired, optical, or wireless electromagnetic transmission medium.

Transmission technologies typically refer to physical layer protocol duties such as modulation, demodulation, line coding, equalization, error control, bit synchronization and multiplexing, but it may also involve higher-layer protocol duties, for example, digitizing an analog signal, and data compression.

 

Common PCB Transmission Lines

 

In PCB design, some interfaces or ICs need to be combined into the circuit board. The transmission lines are required impedance controlled with tolerances, like +/-5%, +/-7% and +/-10%, in PCB fabrication process. Here MADPCB introduces you some common PCB transmission lines.

Guiding the Wave

 

Microwave signals are transmitted from location-to-location by waveguides or antennas. The chief difference between the two is that a waveguide confines the electromagnetic field to an area along the path, while an antenna radiates the electromagnetic field into space. In a waveguide, radiation is bad. In an antenna, radiation is the goal.

A transmission line is a sub-category of waveguides that uses some physical configuration of metal and/or dielectrics to direct a signal along the desired path. Most familiar transmission lines (e.g., microstrip line) use two conductors; signal and ground, however, there are single conductor transmission lines (e.g., rectangular waveguide).

For analysis, we want to be able to predict two important parameters of a transmission line: the characteristic impedance and the electrical length. Knowing these allows you to easily simulate or calculate circuit performance. These parameters can be obtained from closed-form equations, numerical approximations, and 2-D, 2½-D, or 3-D electromagnetic simulations.

 

The Simplest Transmission Line – Coaxial Line

 

The simplest transmission line configuration is coaxial line. It is simple because a there is an exact solution for its impedance and propagation velocity in terms of the physical parameters (conductor sizes). Equations for many transmission line types have been derived by mapping their physical shape into a coaxial shape where the solution is known exactly.

You might think that coaxial lines are not useful in printed circuit board (PCB) design because they are not planar. However, there are a couple of places you may want to use the coaxial line.

The first situation is encountered when routing a signal through the printed circuit board. Passing from one layer of the printed-circuit board to another is done with round pads on each layer and holes that are plated with metal to connect these pads. The pad for the via is surrounded by a ground plane. The pad and its surrounding ground plane cut-out form a very short section of coaxial transmission line. You can use coaxial line equations to match these transmission lines to the surrounding circuitry and thus minimize the discontinuity.

Very small coaxial lines are available in semi-rigid form having quite small outer diameters – down to 0.2mm (0.008in.). These coaxial lines are a perfect way to provide a fully shielded path for signals on printed-circuit boards in low volume production, as rework, and for prototyping. Sizes around 0.5mm (0.020in.) bend readily and are easy to cut and strip with an Exacto knife. Just trim the ends and solder the shield to the ground plane.

 

Stripline Family

 

Stripline was invented by flattening the coaxial line configuration. It has also been called Triplate or sandwich line. The presence of both top and bottom shields provides good isolation from other signals on the printed-circuit board.

Some useful forms of stripline include centered stripline, off-center stripline, and dual orthogonal stripline. Centered stripline is the ideal situation, however layout decisions may require an off-center stripline. The dual orthogonal stripline configuration is useful in high density routing situations and is accomplished by routing two off-center layers at right angles to each other.

 

Microstrip Line Family

 

The microstrip line simplifies the stripline by removing the upper ground planes. It is probably the most popular planar transmission line because of its ease of fabrication and the ready availability of the signals for probing and circuit connections. Its disadvantage over stripline is that some of the energy transmitted may be coupled into space or adjacent traces.

The most useful configurations for designers are microstrip line, embedded microstripline, and covered microstrip line. Embedded microstrip line is the situation encountered when the microstrip line is covered with solder mask or a thin layer of epoxy. Covered microstrip line is a transitional structure somewhere between microstrip line and stripline. When an electrically close shield covers the circuit you will want to analyze it as a covered microstrip line.

 

Coplanar Waveguide Family

 

All of the transmission lines so far scale the signal conductor’s dimensions to the separation of the ground conductor to set the impedance. Once you choose the dielectric thickness the other dimensions are determined. Sometimes this can be inconvenient when connecting to other components.

For example, when you need to transition to a connector or device pin that has a specific pin size, the trace width may turn out to be too wide to fit between pins. You could taper the dielectric substrate thickness to allow the signal conductor’s width to narrow but that is usually impractical. Fortunately, the coplanar waveguide family solves this problem.

Coplanar waveguide (CPW) uses a ground conductor that is coplanar with the signal conductor. Therefore, the impedance is controlled by the signal line width and the ground gap. What this means is that you can keep the impedance constant as you taper the signal conductor’s width down to meet a pin. This is perfect for matching to a component pin width without changing the substrate thickness.

The coplanar waveguide configurations that are most likely to be useful are: coplanar waveguide and coplanar waveguide with ground. Coplanar waveguide concentrates the field in the gap so it will have the best ability to taper in to a pin. However, it may require special attention if you are transitioning from microstrip line into CPW. In this situation, coplanar waveguide with ground (CPWG) may be easier to deal with since you can start with a wide gap (microstripline) and gradually transition to the coplanar waveguide with ground configuration.