THE RADAR EQUATION ELC 451.

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THE RADAR EQUATION ELC 451

RADAR EQUATION: DEFINITION The radar equation represents the physical dependences of the transmit power, that is the wave propagation up to the receiving of the echo-signals. The power PR returning to the receiving antenna is given by the radar equation, depending on the transmitted power Pt, the slant range R, and the reflecting characteristics of the target (described as the the radar scattering cross section). At known sensibility of the radar receiver, the radar equation determines what can be achieved by a given radar set theoretically maximum range. In general, the performance of the radar system can be assessed with the radar equation.

DEFINITION The Radar Equation represents the fundamental relation between the characteristics of the radar, the target, and the received signal. Scatterer

RADAR EQUATION: DERIVATION (1) If high-frequency energy is emitted by an isotropic transmitter, the energy propagate uniformly in all directions. The same amount of energy spreads out on an incremental basis on spherical surface with an incremented spherical radius. That means: the power density on the surface of a sphere is inversely proportional to the square of the radius of the sphere and can be represented as: where Ss is the power density at the scatterer. Scatterer

RADAR EQUATION: DERIVATION (2) To obtain the total power intercepted by the scatterer, the power density must be multiplied by the effective receiving area of the scatterer: The effective area Ars is not the actual area of the incident beam intercepted by the scatterer, but rather is the area of the incident beam from which all power would be removed if one assumed that the power going through all the rest of the beam continued uninterrupted. The actual value of Ars depends on the effectiveness of the scatterer as a receiving antenna.

RADAR EQUATION: DERIVATION (3) Some of the power received by the scatterer is absorbed in losses in the scatterer. The rest is reradiated in various directions. If the fraction absorbed is fa, then fraction reradiated is 1- fa, and the total reradiated power is:

RADAR EQUATION: DERIVATION (4) The conduction and displacement currents that flow in the scatterer result in re-radiation that has a pattern (like an antenna pattern). The effective receiving area of the scatterer is a function of its orientation relative to the incoming beam, so that Ars applies only for the direction of the incoming beam.  The re-radiation pattern may not be the same as the pattern of Ars, and the gain in the direction of the receiver is the relevant value in the re-radiation pattern. Hence: Where Pts is the total reradiated power, Gts is the gain of the scatterer in the direction of the receiver and Si is called the spreading factor for the re-radiation. 

RADAR EQUATION: DERIVATION (5) The power entering the receiver is where the area Ar is the effective aperture of the receiving antenna, not its actual area. Not only is Ar function of direction, but it is also a function of the load impedance the receiver provides to the antenna. For example, Pr would have to be zero if the load were a short circuit or an open circuit.

RADAR EQUATION: DERIVATION (6) Combining equations discussed in 1-17 above yields: The factors associated with the scatterer are combined in the square brackets.  These factors are difficult to measure individually, and their relative contributions are not of interest to one wishing to know the size of the received radar signal. Hence they are normally combined into one factor, the radar scattering cross section:

RADAR EQUATION: DERIVATION (7) The final form of the radar equation is:

RADAR EQUATION: DERIVATION (8) The most common situation is that for which receiving and transmitting locations are the same, so that the transmitter and receiver distances are the same and the same antenna is used for transmitting and receiving, so the gains and effective apertures are the same, that is:

RADAR EQUATION: DERIVATION (9) Since the effective area of an antenna is related to its gain by The radar equation can be written as:

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