A lossless microstrip transmission line consists of a trace of width π€. It is drawn over a practically infinite ground plane and is separated by a dielectric slab of thickness π‘ and relative permittivity π_{π} > 1. The inductance per unit length and the characteristic impedance of this line are πΏ and π_{0}, respectively.

Which one of the following inequalities is always satisfied?

This question was previously asked in

GATE EC 2016 Official Paper: Shift 2

Option 2 : \({Z_0} < \sqrt {\frac{{Lt}}{{{\varepsilon _0}{\varepsilon _r}w}}} \)

CT 1: Ratio and Proportion

2846

10 Questions
16 Marks
30 Mins

**Concept:**

A lossless microstrip transmission line consists of a trace of width ‘w’ as shown:

The characteristic impedance of the transmission line is given as:

\({Z_0} = \sqrt {\frac{L}{C}} \) , where \(C = \frac{{\varepsilon A}}{d}\)

**Application: **As we know \({Z_0} = \sqrt {\frac{L}{C}} \) where \(C = \frac{{\varepsilon A}}{d}\)

here d = t, A ≅ w, and ε = εeff

\(\therefore C = \frac{{{\varepsilon _{eff}}w}}{t}\)

The above is the actual capacitance, with no fringing taken into account.

\(\therefore {Z_0} = \sqrt {\frac{L}{{\frac{{{\varepsilon _{eff}} \cdot w}}{t}}}} = \sqrt {\frac{{L.t}}{{w\;{\varepsilon _{eff}}}}} \)

Let the characteristic impedance of a practical transmission line be Z0’.

Since in practice, the capacitance C will be smaller than the actual capacitance due to the fringing effects, i.e.since εeff < ε0 εr, we can write:

Z0’ > Z0, i.e.

\({Z_0} < \sqrt {\frac{{Lt}}{{{\varepsilon _0}{\varepsilon _r}w}}} \)

This is because the capacitance is inversely related to the characteristic impedance, i.e. smaller the C, larger is the impedance.