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Antenna Arrays (Phased Arrays)


An antenna array (often called a 'phased array') is a set of 2 or more antennas. The signals from the antennas are combined or processed in order to achieve improved performance over that of a single antenna. The antenna array can be used to:

  • increase the overall gain

  • provide diversity reception

  • cancel out interference from a particular set of directions

  • "steer" the array so that it is most sensitive in a particular direction

  • determine the direction of arrival of the incoming signals

  • to maximize the Signal to Interference Plus Noise Ratio (SINR)

  • To understand antenna arrays and phased arrays, navigate through the following pages:

    1. Basic Concepts and Intro to Antenna Arrays

    Benefits of Antenna Arrays, Array Factor

    2. Weighting Methods Used in Antenna Arrays

    Phased Arrays, Schelkunoff (Null Placement) Weighting, Analysis of Uniform Antenna Arrays, Grating Lobes Array Factors for Uniform Arrays, 2D Uniform Phased Arrays, Dolph-Chebyshev Weights, MMSE Weighting, Adaptive Antenna Arrays: LMS Weighting Algorithm

    3. Geometry Optimization in Antenna Arrays

    Hexagonally Sampled Antenna Arrays, Thinned Antenna Arrays


    Antenna Array Basics

    An antenna array is a set of N spatially separated antennas. The number of antennas in an array can be as small as 2, or as large as several thousand (as in the AN/FPS-85 Phased Array Radar Facility operated by U. S. Air Force). In general, the performance of an antenna array (for whatever application it is being used) increases with the number of antennas (elements) in the array; the drawback of course is the increased cost, size, and complexity.

    The following figures show some examples of antenna arrays.

    example of a patch microstrip antenna array or phased array

    Figure 1. Four-element microstrip antenna array (phased array).

    antenna array for mobile phones

    Figure 2. Cell-tower Antenna Array. These Antenna Arrays are typically used in groups of 3 (2 receive antennas and 1 transmit antenna).

    The general form of an antenna array can be illustrated as in Figure 3. An origin and coordinate system are selected, and then the N elements are positioned, each at location given by:

    positions of antennas in phased arrays

    The positions of the elements in the phased array are illustrated in the following Figure.

    geometry of antenna positions of antenna arrays

    Figure 3. Geometry of an arbitrary N element antenna array.

    Let output signal from antenna in phased array represent the output from antennas 1 thru N, respectively. The output from these antennas are most often multiplied by a set of N weights - weight for antenna in phased array- and added together as shown in Figure 4.

    summing and weighting of signals in antenna array

    Figure 4. Weighting and summing of signals from the antennas to form the output in a Phased Array.

    The output of an antenna array can be written succinctly as:

    output of phased antenna array

    This is what is going on in an antenna array. However, I haven't answered what the benefits of a phased array are. To understand what happens in an antenna array, navigate to the next section on Antenna Arrays.

    Benefits of Antenna Arrays

    To understand the benefits of antenna arrays, we will consider a set of 3-antennas located along the z-axis, receiving a signal (plane wave or the desired information) arriving from an angle relative to the z-axis of polar angle, as shown in Figure 4.

    example of antenna array or phased array receiving signal from angle theta

    Figure 4. Example 3-element Antenna Array receiving a plane wave.

    The antennas in the phased array are spaced one-half wavelength apart (centered at z=0). The E-field of the plane wave (assumed to have a constant amplitude everywhere) can be written as:

    E-field (e electric field) for a plane wave - phase propagation across antenna array

    In the above, k is the wave vector, which specifies the variation of the phase as a function of position.

    The (x,y) coordinates of each antenna is (0,0); only the z-coordinate changes for each antenna. Further, assuming that the antennas are isotropic sensors, the signal received from each antenna is proportional to the E-field at the antenna location. Hence, for antenna i, the received signal is:

    received field at each element in phased array

    The received signals are distinct by a complex phase factor, which depends on the antenna separations and the angle of arrival on the plane wave. If the signals are summed together, the result is:

    sum of received signals

    The interesting thing is if the magnitude of Y is plotted versus theta (the angle of arrival of the plane wave). The result is given in Figure 5.

    radiation (or reception) pattern for antenna array

    Figure 5. Magnitude of the output as a function of the arrival angle for Antenna Array.

    Figure 5 shows that the phased array actually processes the signals better in some directions than others. For instance, the antenna array is most receptive when the angle of arrival is 90 degrees. In contrast, when the angle of arrival is 45 or 135 degrees, the antenna array has zero output power, no matter how much power is in the incident plane wave. In this manner, a directional radiation pattern is obtained even though the antennas were assumed to be isotropic. Even though this was shown for receiving antennas, due to reciprocity, the transmitting properties would be the same.

    The value and utility of an antenna array lies in its ability to determine (or alter) the received or transmitted power as a function of the arrival angle.

    By choosing the weights and geometry of an antenna array properly, the phased array can be designed to cancel out energy from undesirable directions and receive energy most sensitively from other directions.

    Before considering weight and geometry selection, we first turn to the fundamental function of antenna array theory, the Array Factor.


    Next: The Array Factor

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