Microstrip Antennas: The Patch Antenna Microstrip (Patch) Antennas 1. In this section, we'll discuss the microstrip antenna, which is also commonly referred to as the patch antenna. Note: I'll use the terms microstrip antenna and patch antenna interchangeably.
The rectangular patch antenna is analyzed, and what is learned here will be applied to understanding. (Home) Rectangular Microstrip Antenna Introduction to Patch Antennas Microstrip or patch antennas are becoming increasingly useful because they can be printed directly onto a circuit board.
Microstrip antennas are becoming very widespread within the mobile phone market. Patch antennas are low cost, have a low profile and are easily fabricated.
Consider the microstrip antenna shown in Figure 1, fed by a microstrip transmission line. The patch antenna, microstrip transmission line and ground plane are made of high conductivity metal (typically copper). The patch is of length L, width W, and sitting on top of a substrate (some dielectric circuit board) of thickness h with. The thickness of the ground plane or of the microstrip is not critically important. Typically the height h is much smaller than the wavelength of operation, but should not be much smaller than 0.025 of a wavelength (1/40th of a wavelength) or the will be degraded. (a) Top View of Patch Antenna (b) Side View of Microstrip Antenna Figure 1. Geometry of Microstrip (Patch) Antenna.
The frequency of operation of the patch antenna of Figure 1 is determined by the length L. The center frequency will be approximately given by: The above equation says that the microstrip antenna should have a length equal to one half of a wavelength within the dielectric (substrate) medium. The width W of the microstrip antenna controls the input impedance. Larger widths also can increase the bandwidth. For a square patch antenna fed in the manner above, the input impedance will be on the order of 300 Ohms. By increasing the width, the impedance can be reduced.
However, to decrease the input impedance to 50 Ohms often requires a very wide patch antenna, which takes up a lot of valuable space. The width further controls the. The normalized radiation pattern is approximately given by: In the above, k is the free-space, given. The magnitude of the fields, given by: The fields of the microstrip antenna are plotted in Figure 2 for W= L=0.5. Normalized Radiation Pattern for Microstrip (Patch) Antenna.
The directivity of patch antennas is approximately 5-7 dB. The fields are linearly polarized, and in the horizontal direction when viewing the microstrip antenna as in Figure 1a (we'll see why in the next section). Next we'll consider more aspects involved in Patch (Microstrip) antennas. Fringing Fields for Microstrip Antennas Consider a square patch antenna fed at the end as before in Figure 1a.
Assume the substrate is air (or styrofoam, with a permittivity equal to 1), and that L= W=1.5 meters, so that the patch is to resonate at 100 MHz. The height h is taken to be 3 cm. Note that microstrips are usually made for higher frequencies, so that they are much smaller in practice. When matched to a 200 Ohm load, the magnitude of is shown in Figure 3. Magnitude of S11 versus Frequency for Square Patch Antenna.
Some noteworthy observations are apparent from Figure 3. First, the bandwidth of the patch antenna is very small.
Rectangular patch antennas are notoriously narrowband; the bandwidth of rectangular microstrip antennas are typically 3%. Secondly, the microstrip antenna was designed to operate at 100 MHz, but it is at approximately 96 MHz.
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This shift is due to fringing fields around the antenna, which makes the patch seem longer. Hence, when designing a patch antenna it is typically trimmed by 2-4% to achieve resonance at the desired frequency. The fringing fields around the antenna can help explain why the microstrip antenna radiates. Consider the side view of a patch antenna, shown in Figure 4. Note that since the current at the end of the patch is zero (open circuit end), the current is maximum at the center of the half-wave patch and (theoretically) zero at the beginning of the patch. This low current value at the feed explains in part why the impedance is high when fed at the end (we'll address this again later). Since the patch antenna can be viewed as an open circuited transmission line, the voltage reflection coefficient will be 1 (see the for more information).
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When this occurs, the voltage and current are out of phase. Hence, at the end of the patch the voltage is at a maximum (say +V volts).
At the start of the patch antenna (a half-wavelength away), the voltage must be at minimum (-V Volts). Hence, the fields underneath the patch will resemble that of Figure 4, which roughly displays the fringing of the fields around the edges. Side view of patch antenna with E-fields shown underneath.
It is the fringing fields that are responsible for the radiation. Note that the fringing fields near the surface of the patch antenna are both in the +y direction. Hence, the fringing E-fields on the edge of the microstrip antenna add up in phase and produce the radiation of the microstrip antenna.
This paragraph is critical to understanding the patch antenna. The current adds up in phase on the patch antenna as well; however, an equal current but with opposite direction is on the ground plane, which cancels the radiation. This also explains why the microstrip antenna radiates but the microstrip transmission line does not. The microstrip antenna's radiation arises from the fringing fields, which are due to the advantageous voltage distribution; hence the radiation arises due to the voltage and not the current.
The patch antenna is therefore a 'voltage radiator', as opposed to the, which radiate because the currents add up in phase and are therefore 'current radiators'. As a side note, the smaller is, the more 'bowed' the fringing fields become; they extend farther away from the patch. Therefore, using a smaller permittivity for the substrate yields better radiation. In contrast, when making a microstrip transmission line (where no power is to be radiated), a high value of is desired, so that the fields are more tightly contained (less fringing), resulting in less radiation. This is one of the trade-offs in patch antenna design.
There have been research papers written were distinct dielectrics (different permittivities) are used under the patch antenna and transmission line sections, to circumvent this issue. Next, we'll look at alternative methods of feeding the microstrip antenna (connecting the antenna to the receiver or transmitter).
Next: Top: This page on microstrip antennas and patch antennas is copyrighted. No portion can be reproduced except by permission from the author. Copyright 2011-2016, antenna-theory.com. Patch antennas, microstrip antennas.
. Radar timing performance. The Radar Equation. Classification of Radar systems. Frequency Diversity Radar. Phased Array Antenna. Coherent-on-Receive Radar.
Coherent Radar. Superheterodyne. Appendices. English. Figure 1: Cutaway view of a simple patch antenna Patch Antenna or Microstrip Antenna A patch antenna or microstrip antenna is a narrowband, wide-beam antenna.
It is also called printed antenna. It has two dimensional physical geometry. The simplest patch antenna uses a patch which is one-half wavelength long, so that the metal surface acts as a resonator similarly to the. A patch antenna is usually fabricated by mounting a shaped metal sheet on an insulating dielectric substrate, such as a printed circuit board, with a continuous metal layer bonded to the opposite side of the substrate which forms a ground plane. Hence it is easy to design and inexpensive to manufacture. Some patch antennas do not use a dielectric substrate and instead made of a metal patch mounted above a ground plane using dielectric spacers. The resulting structure is less rugged but has a wider bandwidth.
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Patch antennas can be designed from the to as high as 100 GHz. Common patch antenna shapes are square, rectangular, circular and elliptical. However the shape is not restricted. Any continuous shape is feasible. Patch antennas are mechanically rugged and can be shaped to conform to the curving skin of a vehicle. They are often mounted on the exterior of aircraft and spacecraft, or are incorporated into mobile radio communications devices. They have high diversity and can be used for multiple feed points.
Figure 2: The patch antenna array of a maritime FMCW navigation radar in Disadvantages. Narrow band width (1%), while mobiles need (8%). Low efficiency, especially for short circuited microstrip antenna. Some feeding techniques like aperture and proximity coupling are difficult to fabricate. Best software engineering universities. An array suffers presence of feed network decreasing efficiency. Microstrip antennas occurred during the 1980s.
Advantages Of Patch Antenna
Initially it was a military development, at the cost did not matter. In the 1990s this technology has also been adopted for devices for communication as a low-cost technology. But the performance of a microstrip array was well below that of a reflector antenna.
Welcome to Rozendal Associates! Rozendal Associates, Inc. Develops and manufactures quality innovative microwave products to meet the unique requirements of our customers.
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These products include radar reflectors, radomes, and microwave antennas. Rozendal also performs microwave testing and provides quantitative results. Rozendal Associates is a custom manufacturing company that provides microwave products and services to our customers.
If you have a specific manufacturing or testing need, please contact us with your requirements and we will respond shortly to your inquiry.
Welcome to Rozendal Associates! Rozendal Associates, Inc.
Develops and manufactures quality innovative microwave products to meet the unique requirements of our customers. These products include radar reflectors, radomes, and microwave antennas. Rozendal also performs microwave testing and provides quantitative results. Rozendal Associates is a custom manufacturing company that provides microwave products and services to our customers. If you have a specific manufacturing or testing need, please contact us with your requirements and we will respond shortly to your inquiry.
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