Complicated Configurations
Two-port matrices may be cascaded ad infinitum to create structures of arbitrary complexity. Presuming a number of two-port sections A 1 , A 2 ... A N have been cascaded, you may calculate the overall circuit gain.
Equation C.20
The various sections could represent, for example,
- A series-connected two-port representing the output impedance of the driver on an integrated circuit die: z 1 ( w ) = j w L DIE + R DIE
- A series-connected two-port representing the series impedance of a wire-bond connection to the chip package: z 2 ( w ) = j w L WIREBOND + R WIREBOND
- A shunt-connected two-port representing the wire-bond landing pad capacitance ,
- A transmission-line two-port representing the characteristic impedance, delay, and loss of the BGA routing track
- A series-connected two-port representing the BGA ball inductance
- A shunt-connected two-port representing the BGA ball capacitance
- A series of three two-port models: shunt, series, and shunt, representing a pi-model of the pcb via
- A transmission-line two-port representing a skinny breakout track as it winds its way out of the BGA ball field
- A transmission-line two-port representing a regular track proceeding a long distance towards a receiver
- A series of three two-port models: shunt, series, and shunt, representing a pi-model of an intermediate pcb via,
...and so on until the model is sufficiently rich to satisfy your desire for accuracy.
The TDR response of a complicated two-port model involving N stages, defined as the gain from the input voltage source on the left to a point just to the right of (after) stage M, is
Equation C.21
