Explanation of characteristic impedance of high-speed circuit board design
A good stack structure can effectively control the impedance, and its routing can form an understandable and predICtable transmission line structure. The field solution tool can deal with this kind of problem very well. As long as the number of variables is controlLED to the minimum, a fairly accurate result can be obtained.
However, when more than three signals are stacked together, this is not necessarily the case. The reason is very subtle. The target impedance value depends on the process technology of the device. High speed CMOS technology can generally reach about 70 Ω; High speed TTL devices can generally reach about 80 Ω to 100 Ω. Because the impedance value usually has a great impact on noise tolerance and signal switching, it is necessary to be very careful when selecting impedance; The product manual should give guidance on this.
The initial results of the field resolution tool may encounter two problems. First of all, the field of vision is limited. The on-site solution tool only analyzes the impact of nearby routing, and does not consider the non parallel routing on other layers that affect impedance. The field solution tool cannot know the details before wiring, that is, when allocating the wiring width, but the above paired arrangement method can minimize this problem.
It is worth mentioning the impact of partial power planes. The outer circuit board is often crowded with grounding copper wires after wiring, which is conducive to EMI suppression and balance placing. If only such measures are taken for the outer layer, the laminated structure recommended in this paper will have very little impact on the characteristic impedance.
The effect of using a large number of adjacent signal layers is very significant. Some on-site solution tools cannot find the existence of copper foil, because they can only check the printed wire and the whole layer, so the analysis result of impedance is incorrect. When there is metal on the adjacent layer, it is like an unreliable ground wire layer. If the impedance is too low, the instantaneous current will be large, which is a practical and sensitive EMI problem.
Another cause of impedance analysis tool failure is distributed capacitance. These analysis tools generally can not reflect the influence of pins and vias (this influence is usually analyzed by emulators). This effect can be significant, especially on the backplane. The reason is very SIMple: the characteristic impedance can usually be calculated by the following formula:
√L/C
Where L and C are inductance and capacitance per unit length, respectively.
If the pins are evenly arranged, the additional capacitance will greatly affect the calculation result. The formula will become:
√L/(C+C')
C 'is the pin capacitance per unit length.
If the connectors are connected in a straight line as on the backplane, the total line capacitance and the total pin capacitance except the first and last pins can be used. In this way, the effective impedance will be reduced, even from 80 Ω to 8 Ω. To obtain the effective value, divide the original impedance value by:
√(1+C'/C)
This calculation is important for component selection.
PCB manufacturers, PCB designers and PCBA manufacturers will explain the characteristic impedance of high-speed PCB design.