The Derivation of Intrinsic Impedance
The intrinsic impedance of any uniform medium is dependent on the permittivity and permeability of the medium. When the conductivity of the medium varies, the intrinsic impedance also changes.
For a uniform plane wave traveling in a given medium, E/H is a constant and gives the intrinsic impedance.
The value of intrinsic impedance corresponding to free space is 120π, which is approximately equal to 377Ω.
In wireless communication systems, when an electromagnetic wave propagates through free space, it encounters the characteristic impedance of the free space, called intrinsic impedance
The atmospheric propagation of electromagnetic waves is a part of all wireless communication systems. When an electromagnetic wave propagates through free space, it encounters the characteristic impedance of the free space, called intrinsic impedance (𝜼).
Intrinsic impedance describes the magnitude of the magnetic and electric fields present in the free space. The derivation of the intrinsic impedance of any uniform medium is dependent on the permittivity and permeability of the medium. When the conductivity of the medium varies, the intrinsic impedance also changes.
Deriving Intrinsic Impedance
The atmospheric air is typically a low-loss medium with little magnetization. It can be modeled as a vacuum or otherwise called free space. Free space is non-conductive, 𝞂=0, where 𝞂 is the conductivity of the medium. The permeability (𝜇) and permittivity (𝜀) of free space is represented by 𝜇0 and 𝜀0, respectively. As there are no physical conductances or resistances in free space, the equation of intrinsic impedance reduces to one with permeability and permittivity.
In general, the intrinsic impedance or wave intrinsic impedance of an electromagnetic wave traveling through a medium can be given by the ratio of its electric to magnetic field intensities, that is, E/H. For a uniform plane wave traveling in a given medium, E/H is a constant and provides the impedance. The units of E and H are volts per meter and amperes per meter, respectively. Taking the ratio of E/H, the unit is Volts/ ampere which is equal to Ohms.
Consider a uniform plane wave traveling in the positive y-direction. The electric field is varying in the z-direction and the magnetic field in the x-direction. The electric field can be given by the equation:
Using the relationship given by equation (2):
The magnetic field can be derived as:
To derive the intrinsic impedance of the free space, take the ratio of equations (1) and (3):
The intrinsic impedance is complex-valued and magnitude can be given as follows:
Intrinsic Impedance Values
The intrinsic impedance value varies with each medium, as the 𝝈, 𝜇, 𝜖 are different for different mediums. Any medium in which the electromagnetic wave propagates can be compared with that of free space using the relative permeability and permittivity values represented by 𝜇r, and 𝜖r.
In a lossy medium, the intrinsic wave impedance is complex. In such a medium, the electric and magnetic fields exponentially decay in the direction of wave propagation. The electric and magnetic fields are out of phase by an angle equal to the phase angle of the intrinsic impedance.
In a lossless medium, the intrinsic wave impedance is purely real. As there is no phase angle associated with intrinsic impedance in a lossless medium, the electric and magnetic fields are in phase with each other.
Substituting the values of permeability and permittivity of air in the intrinsic impedance equation, the value corresponding to free space is obtained as 120π, which is approximately equal to 377Ω.
From the derivation of intrinsic impedance, it is clear that the ratio of E/H of an electromagnetic wave remains constant at any given instant in a medium. The intrinsic impedance is a parameter that represents the characteristics of the medium of propagation in wireless communication systems.
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