53.7.4 Calculating the Correct Crystal Decoupling Capacitor

The model shown in Figure 53-11 can be used to calculate correct load capacitor for a given crystal. This model includes internal capacitors C_Ln, external parasitic capacitance C_ELn and external load capacitance C_Pn.

Figure 53-11. Crystal Circuit With Internal, External and Parasitic Capacitance

Using this model, the total capacitive load for the crystal can be calculated as shown in the equation below:

\sum C_{tot} = \frac{(C_{L 1} + C_{P 1} + C_{EL 1}) (C_{L 2} + C_{P 2} + C_{EL 2})}{C_{L 1} + C_{P 1} + C_{EL 1} + C_{L 2} + C_{P 2} + C_{EL 2}}

where:

C_tot is the total load capacitance seen by the crystal. This value must be equal to the load capacitance value found in the crystal data sheet.

The parasitic capacitance C_ELn can be in most applications be disregarded as these are usually very small. If accounted for, these values are dependent on the PCB material and PCB layout.

For some crystal, the internal capacitive load provided by the device itself can be enough. To calculate the total load capacitance in this case. C_ELn and C_Pn are both zero, C_L1 = C_L2 = C_L, and the equation reduces to the following:

\sum C_{tot} = \frac{C_{L}}{2}

For equivalent internal pin capacitance values, refer to the section Crystal Oscillator Characteristics.