The patch edges perpendicular to the feed line create fringing fields that radiate into free space. Figure 2-3: Microstrip feed line and nominal dimensions The nominal HFSS antenna design defined is fed by an open-circuit terminated microstrip line 0.739 λ in length (see Figure 2-3). Abstract-Microstrip patch antennas becomes most popular these. To determine the width (W), the microstrip patch antenna calculator was used to provide an initial starting point. The length (L) was chosen to be the same as. Length due to fringing effects between patch and field. 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. The fringing field has an important effect on the accurate theoretical modeling and performance analysis of microstrip patch antennas. Though, fringing fields effects on the performance of antenna. Microstrip patch antenna can be fed by a variety of methods (Ojha et al,2011) These methods can be classified into two categories-contacting and non contacting.In the. Fringing field which is a function of effective dielectric constant (Amit kumar et al, 2013, K. Praveen Kumar, et al, 2013,Brajlata Chauhan et al,2013).
A microstrip antenna array for a satellite television receiver.
History of Aperture-Coupled Microstrip Patch Antenna Aperture coupled microstrip patch antennas have become a viable option for wireless and telecommunication systems over traditional microstrip patch antennas. Research and development in the 1980s contributed to the discovery of the aperture-coupled microstrip patch antenna [2].
Diagram of the feed structure of a microstrip antenna array.
Winfiol 7 serial killers. In telecommunication, a microstrip antenna (also known as a printed antenna) usually means an antenna fabricated using microstrip techniques on a printed circuit board (PCB).[1] It is a kind of internal antenna. They are mostly used at microwavefrequencies. An individual microstrip antenna consists of a patch of metal foil of various shapes (a patch antenna) on the surface of a PCB (printed circuit board), with a metal foil ground plane on the other side of the board. Most microstrip antennas consist of multiple patches in a two-dimensional array. The antenna is usually connected to the transmitter or receiver through foil microstriptransmission lines. The radio frequency current is applied (or in receiving antennas the received signal is produced) between the antenna and ground plane. Microstrip antennas have become very popular in recent decades due to their thin planar profile which can be incorporated into the surfaces of consumer products, aircraft and missiles; their ease of fabrication using printed circuit techniques; the ease of integrating the antenna on the same board with the rest of the circuit, and the possibility of adding active devices such as microwave integrated circuits to the antenna itself to make active antennas.
Patch antenna[edit]
The most common type of microstrip antenna is the patch antenna. Antennas using patches as constitutive elements in an array are also possible. A patch antenna is a narrowband, wide-beam antenna fabricated by etching the antenna element pattern in metal trace bonded to 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. Common microstrip antenna shapes are square, rectangular, circular and elliptical, but any continuous shape is possible. Some patch antennas do not use a dielectric substrate and instead are made of a metal patch mounted above a ground plane using dielectric spacers; the resulting structure is less rugged but has a wider bandwidth. Because such antennas have a very low profile, 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.
Advantages[edit]
Microstrip antennas are relatively inexpensive to manufacture and design because of the simple 2-dimensional physical geometry. They are usually employed at UHF and higher frequencies because the size of the antenna is directly tied to the wavelength at the resonant frequency. A single patch antenna provides a maximum directive gain of around 6-9 dBi. It is relatively easy to print an array of patches on a single (large) substrate using lithographic techniques. Patch arrays can provide much higher gains than a single patch at little additional cost; matching and phase adjustment can be performed with printed microstrip feed structures, again in the same operations that form the radiating patches. The ability to create high gain arrays in a low-profile antenna is one reason that patch arrays are common on airplanes and in other military applications.
Such an array of patch antennas is an easy way to make a phased array of antennas with dynamic beamforming ability.[2]
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An advantage inherent to patch antennas is the ability to have polarization diversity. Patch antennas can easily be designed to have vertical, horizontal, right hand circular (RHCP) or left hand circular (LHCP) polarizations, using multiple feed points, or a single feedpoint with asymmetric patch structures.[3] This unique property allows patch antennas to be used in many types of communications links that may have varied requirements.
Rectangular patch[edit]
The most commonly employed microstrip antenna is a rectangular patch which looks like a truncated microstrip transmission line. It is approximately of one-half wavelength long. When air is used as the dielectric substrate, the length of the rectangular microstrip antenna is approximately one-half of a free-space wavelength. As the antenna is loaded with a dielectric as its substrate, the length of the antenna decreases as the relative dielectric constant of the substrate increases. The resonant length of the antenna is slightly shorter because of the extended electric 'fringing fields' which increase the electrical length of the antenna slightly. An early model of the microstrip antenna is a section of microstrip transmission line with equivalent loads on either end to represent the radiation loss.
Specifications[edit]
The dielectric loading of a microstrip antenna affects both its radiation pattern and impedance bandwidth. As the dielectric constant of the substrate increases, the antenna bandwidth decreases which increases the Q factor of the antenna and therefore decreases the impedance bandwidth. This relationship did not immediately follow when using the transmission line model of the antenna, but is apparent when using the cavity model which was introduced in the late 1970s by Lo et al.[4] The radiation from a rectangular microstrip antenna may be understood as a pair of equivalent slots. These slots act as an array and have the highest directivity when the antenna has an air dielectric and decreases as the antenna is loaded by material with increasing relative dielectric constant.
The half-wave rectangular microstrip antenna has a virtual shorting plane along its center. This may be replaced with a physical shorting plane to create a quarter-wavelength microstrip antenna. This is sometimes called a half-patch. The antenna only has a single radiation edge (equivalent slot) which lowers the directivity/gain of the antenna. The impedance bandwidth is slightly lower than a half-wavelength full patch as the coupling between radiating edges has been eliminated.
Other types[edit]
Another type of patch antenna is the planar inverted-F antenna (PIFA).The PIFA is common in cellular phones (mobile phones) with built-in antennas.[5][6]The antenna is resonant at a quarter-wavelength (thus reducing the required space needed on the phone), and also typically has good SAR properties.This antenna resembles an inverted F, which explains the PIFA name. The PIFA is popular because it has a low profile and an omnidirectional pattern.[7]These antennas are derived from a quarter-wave half-patch antenna. The shorting plane of the half-patch is reduced in length which decreases the resonance frequency.[8]Often PIFA antennas have multiple branches to resonate at the various cellular bands. On some phones, grounded parasitic elements are used to enhance the radiation bandwidth characteristics.
The folded inverted conformal antenna (FICA)[9] has some advantages with respect to the PIFA, because it allows a better volume reuse.
References[edit]
External links[edit]
Retrieved from 'https://en.wikipedia.org/w/index.php?title=Microstrip_antenna&oldid=911127123'
From Wikipedia, the free encyclopedia
In telecommunication, there are severaltypes of microstrip antennas (also known asprinted antennas) the most common of which is themicrostrip patch antenna or patch antenna. Apatch antenna is a narrowband, wide-beamantennafabricated by etching the antenna element pattern in metal tracebonded to an insulating dielectric substrate with a continuousmetal layer bonded to the opposite side of the substrate whichforms a groundplane. Common microstrip antenna radiator shapes aresquare, rectangular, circular and elliptical, but any continuousshape is possible. Some patch antennas eschew a dielectricsubstrate and suspend a metal patch in air above a ground planeusing dielectric spacers; the resulting structure is less robustbut provides better bandwidth. Because such antennas have a verylow profile, are mechanically rugged and can be conformable, theyare often mounted on the exterior of aircraft and spacecraft, orare incorporated into mobile radio communications devices.
Microstrip antennas are also relatively inexpensive tomanufacture and design because of the simple 2-dimensional physicalgeometry. They are usually employed at UHF and higher frequencies because the sizeof the antenna is directly tied to the wavelength at the resonance frequency. A single patch antennaprovides a maximum directive gain of around 6-9 dBi. It isrelatively easy to print an array of patches on a single (large)substrate using lithographic techniques. Patch arrays can providemuch higher gains than a single patch at little additional cost;matching and phase adjustment can be performed with printedmicrostrip feed structures, again in the same operations that formthe radiating patches. The ability to create high gain arrays in alow-profile antenna is one reason that patch arrays are common onairplanes and in other military applications.
Microstrip Patch Antenna Calculator
Such an array of patch antennas is an easy way to make a phased array ofantennas with dynamic beamforming ability.[1]
The most commonly employed microstrip antenna is a rectangularpatch. The rectangular patch antenna is approximately a one-halfwavelength long section of rectangular [[microstrip] transmissionline. When air is the antenna substrate, the length of therectangular microstrip antenna is approximately one-half of afree-space wavelength.As the antenna is loaded with a dielectric as its substrate, thelength of the antenna decreases as the relative dielectric constant of the substrateincreases. The resonant length of the antenna is slightly shorterbecause of the extended electric 'fringing fields' which increasethe electrical length of the antenna slightly. An early model ofthe microstrip antenna is a section of microstrip transmission linewith equivalent loads on either end to represent the radiationloss.
The dielectric loading of a microstrip antenna affects both itsradiation pattern and impedance bandwidth. As the dielectricconstant of the substrate increases, the antenna bandwidthdecreases which increases the Q factor of the antenna and thereforedecreases the impedance bandwidth. This relationship did notimmediately follow when using the transmission line model of theantenna, but is apparent when using the cavity model which wasintroduced in the late 1970s by Lo et al.[2] Theradiation from a rectangular microstrip antenna may be understoodas a pair of equivalent slots. These slots act as an array and havethe highest directivity when the antenna has an air dielectric anddecreases as the antenna is loaded by material with increasingrelative dielectric constant.
An advantage inherent to patch antennas is the ability to havepolarization diversity. Patchantennas can easily be designed to have Vertical, Horizontal, RightHand Circular (RHCP) or Left Hand Circular (LHCP) Polarizations,using multiple feed points, or a single feedpoint with asymmetricpatch structures. [3] Thisunique property allows patch antennas to be used in many types ofcommunications links that may have varied requirements.
The half-wave rectangular microstrip antenna has a virtualshorting plane along its center. This may be replaced with aphysical shorting plane to create a quarter-wavelength microstripantenna. This is sometimes called a half-patch. The antenna onlyhas a single radiation edge (equivalent slot) which lowers thedirectivity/gain of the antenna. The impedance bandwidth isslightly lower than a half-wavelength full patch as the couplingbetween radiating edges has been eliminated.
Microstrip Patch Antenna Impedance
Another type of patch antenna is the Planar Inverted F Antenna(PIFA) common in cellular phones with built-in antennas.[4] Theseantennas are derived from a quarter-wave half-patch antenna. Theshorting plane of the half-patch is reduced in length whichdecreases the resonance frequency. Often PIFA antennas havemultiple branches to resonate at the various cellular bands. Onsome phones, grounded parasitic elements are used to enhance theradiation bandwidth characteristics.
The Folded Inverted ConformalAntenna (FICA)[5] hassome advantages with respect to the PIFA, because it allows abetter volume reuse.
References
ExternallinksMicrostrip Patch Antenna Pdf
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