Inset Fed Patch Antenna Calculator Now

The input resistance from the edge (inset depth) is: [ R_\textin(y=y_0) = R_\textin(0) \cos^2\left(\frac\piLy_0\right) ]

[ \Delta L = 0.412 \times 1.6 \frac(4.18+0.3)(37.3/1.6+0.264)(4.18-0.258)(37.3/1.6+0.8) \approx 0.74 \text mm ]

[ \varepsilon_\textreff = \frac4.4+12 + \frac4.4-12\left(1+12\frac1.637.3\right)^-0.5 \approx 4.18 ] inset fed patch antenna calculator

1. Introduction A rectangular microstrip patch antenna is one of the most common planar antennas. Feeding it directly with a microstrip line creates an impedance mismatch because the patch edge has high impedance (typically 150–300 Ω), while the feed line is usually 50 Ω. The inset fed (or recessed microstrip line feed) technique solves this by placing the feed point inside the patch, where the input resistance drops to 50 Ω at a specific inset depth.

To match the feed line impedance ( Z_0 ) (e.g., 50 Ω): [ Z_0 = R_\textin(0) \cos^2\left(\frac\piLy_0\right) ] [ y_0 = \fracL\pi \cos^-1\sqrt\fracZ_0R_\textin(0) ] The input resistance from the edge (inset depth)

[ y_0 = \frac28.4\pi \cos^-1\sqrt\frac50297 \approx 9.04 \times \cos^-1(0.41) \approx 9.04 \times 1.148 \approx 10.4 \text mm ]

[ L = \frac3e82\times2.45e9\sqrt4.18 - 2\times0.00074 \approx 28.4 - 0.00148 \approx 28.4 \text mm ] The inset fed (or recessed microstrip line feed)

If ( R_\textin(0) ) is not known from the exact formula, use the approximation: [ R_\textin(0) \approx 90\frac\varepsilon_r^2\varepsilon_r - 1\left(\fracLW\right)^2 \quad (\textfor thin substrates) ] Given: ( f_r = 2.45 \text GHz ) ( \varepsilon_r = 4.4 ) (FR4) ( h = 1.6 \text mm ) ( Z_0 = 50\ \Omega )