U Slot Patch Antenna Calculator

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The fabricated antenna front view (left) and backview (right). CONCLUSION In this paper a broadband asymmetric U-slot patch antenna with narrow probe presented. From this antenna capabilities compared to symmetric U-slot patch antenna, it can be indicated that, it has reducedsize, lowerprobediameter, withoutreductioninbandwidth. Length of Patch W E Width of E-Shape Slot U E Width of U-Shape Slot SCD Surface Current Distribution LTE Long Term Evolution UMTS Universal Mobile Telecommunication System PCS Personal Communication System GSM Global System for Mobile Communication FET Field Effect Transistor.

U Slot Patch Antenna Calculator players! Strictly 18+ New players only. Min deposit $/€10. Bonus spins valid on Fruit Shop. 35x wagering within 10 days. U Slot Patch Antenna Calculator Bonus funds 100% up to $/€100. 35x (bonus) wagering. Must be used within 30 days, unused bonus removed. This paper presents design and analysis of an efficient U-Slot Rectangular microstrip patch antenna for the application of Wireless LAN for operating frequency 2.45 GHz.U-shaped slot on the patch of the coaxially fed rectangular patch antenna.

The standard rectangular microstrip patch is a narrowband antenna and provides 6-8 dBi Gain with linear polarization. This example based on the work done in [1],[2], models a broadband patch antenna using a slot in the radiator and develops a dual-band and a tri-band variation from it. In the process, the single wide response has been split into multiple narrow band regions catering to specific bands in the WiMAX standard. These patch antennas have been probe-fed.

Building the Single U-Slot Patch

Define Parameters The basic U-slot patch antenna consists of a rectangular patch radiator within which a U-shaped slot has been cut out. As discussed in [1], the patch itself is on an air substrate and thick so as to enable higher bandwidths to be achieved. The presence of the slot structure achieves additional capacitance within the structure which combines with the inductance of the long probe feed to create a double resonance within the band. The geometry parameters based on [2] are defined and shown in a drawing below.

Define radiator shape - Single U-slot

Use the rectangle shape primitives in Antenna Toolbox™ to create the U-slot patch radiator shape. Boolean subtraction operation is used among the shape primitives for this purpose.

Define ground shape

Create the ground plane shape for the antenna. The groundplane in this case is rectangular and 71 mm x 52 mm in size.

Define stack

Use the pcbStack to define the metal and dielectric layers and the feed for the single U-slot patch antenna. The layers are defined top-down. In this case, the top-most layer is a metal layer defined by the U-slot patch shape. The second layer is a dielectric material, air in this case, and the third layer is the metal ground plane.

Calculate and Plot Reflection Coefficient

Mesh the structure by using a maximum edge length which is one-tenth the wavelength at the highest frequency of operation which is 6 GHz for this example. Compute and plot the reflection coefficient for this antenna over the band. The reflection coefficient is plotted with a reference impedance of 50 ohms.

Calculate and plot pattern

Plot the radiation pattern for this antenna at the frequencies of best match in the band.

Dual-band U-Slot Patch Antenna

Define Parameters

To achieve dual-band behavior as shown in [1], [2], the double resonance is modified such that the two contributing resonances, i.e. from the patch and from the slot do not merge. To do so the existing slot parameters are adjusted and a second slot is introduced into the structure. The parameters for the double U-slot are listed below as per [2] and a figure annotated with the variables used is shown.

Create Double U-slot radiator

As before use the shape primitives, to create the geometry by using Boolean operations.

Modify Layers in Stack

Modify the existing stack by introducing the new radiator in the Layers property.

Mesh and Plot Reflection Coefficient

Mesh the structure at the highest frequency of operation and calculate the reflection coefficient.

Triple-Band U-slot Patch Antenna Parameters

For triple-band operation a third U-slot is introduced and the existing slot parameters are adjusted. The parameters are shown below based on [2].

Create Triple U-slot radiator

Modify Layers in Stack

Mesh and Plot Reflection Coefficient

Conclusion

The models of the multi-band single layer U-slot patch antenna as discussed in [1], and [2] have been built and analyzed and agree well with results reported.

Reference

[1] K. F. Lee, S. L. S. Yang and A. Kishk, 'The versatile U-slot patch antenna,' 2009 3rd European Conference on Antennas and Propagation, Berlin, 2009, pp. 3312-3314.

[2] W. C. Mok, S. H. Wong, K. M. Luk and K. F. Lee, 'Single-Layer Single-Patch Dual-Band and Triple-Band Patch Antennas,' in IEEE Transactions on Antennas and Propagation, vol. 61, no. 8, pp. 4341-4344, Aug. 2013.

The microstrip antenna is a convenient, planar, easy-to-fabricate antenna with some attractive attributes and features, as well as some distinct limitations.

The passive antenna is a critical part of any wireless communications link, for both transmit and receive sides. Depending on the application, the same antenna may be used for both roles, or radically different ones may be employed. This FAQ looks at antennas in brief and at a specific antenna embodiment: the microstrip (patch) antenna.

Q: What are the functions and objectives of any antenna?

A. An antenna is an energy transducer (Figure 1). A transmitting antenna takes electrical and electronic power (and energy) originating at an amplifier and which is in a confined space such as a wire or a waveguide and disperses (radiates) it as electromagnetic (EM) power into free space. A receiving antenna performs the complementary operation, capturing this EM energy in free space and confining it to a well-defined path (again, a wire or waveguide, as examples), then sending it to an RF front end.

Q: What are some of the key parameters which are used to characterize antennas?

A: As with any electronic component, whether active or passive, there are some top-tier factors which define performance. For antennas, these are:

• Center frequency
• Radiation pattern
• Radiation pattern bandwidth
• Sidelobe level
• Directivity
• Gain
• Efficiency
• Effective area
• Aperture efficiency
• Polarization
• Input impedance

The references explain these in more detail; some are “intuitive,” while others require a deeper understanding of EM physics. One or more of these will be more dominant factors in design and selection than the others. Still, there is no formal ranking of their importance, as the relative ranking is a function of the application and its priorities.

Q: How does an antenna differ from many other passive components?

A: Antennas have tradeoffs (also called “compromises”) as do all components, but they often not so much related to compromise but instead focused on optimizing the antenna’s match to the application. There is no such thing as an “ideal” antenna because every application has its own priorities. For example, some applications need high directivity while others need the omnidirectional capability, Or some want wider bandwidth, and others need only narrower bandwidth. These are not tradeoffs or compromises: they are deliberate choices made to better-fit the antenna to the application needs. With antennas, there are many degrees of freedom to consider; some of these are tightly linked to each other, while others are more loosely linked.

Q: What does a typical antenna look like?

A: That question cannot be answered as there is no such thing as a “typical” antenna. The classic whip or discrete wire antenna of decades ago, and often seen in movies, is just one of many physical antenna types (Figures 2 through 4).

Q: What does the antenna genealogy “family tree” look like?

Square Patch Antenna Calculator

A: That’s a simple question with a complicated answer, as it depends on the perspective of the person drawing that genealogy tree; Figure 5 is one example. Some classifications are based on the underlying EM physics principles. In contrast, others are derived from the actual physical realization, which is somewhat related to principles but not strictly defined by them.

Among the basic antenna groups, the earliest antenna belongs to what is called the “wire” style (although often made of tubing or pipes in reality) such as the long wire, whip, and dipole antennas. Using very different embodiments of the same EM physics principles, there are small resonant antennas used in smartphones. There are also reflective antennas which use a parabolic dish or plane reflector behind the electrically connected main element, horn antennas, and microstrip antennas, to cite just a few basic types.

Q: Is that all?

A: Not at all. Antennas come in countless variations and permutations on their basic styles, and in many cases, are a blend of several types. For example, a parabola dish antenna may have a folded dipole or horn at its focal point. The many antenna physical realizations in use are clear proof of the art and ingenuity of designers as they work to meet specific goals and priorities. (If you need further evidence, take a look at some issues of QST, the flagship publication of the ARRL – the American Radio Relay League).

Q: How are antennas designed?

A: Decades ago, an antenna design started with an idea for the configuration and some basic analysis based on Maxwell’s equations for the sizing of antenna elements, followed by building and testing. In recent years, the design mode has shifted radically to the designer establishing a configuration and then modeling it in detail using an “EM field solver” application. These advanced applications take into account the real-world factors such as fringing and parasitics, which affect antenna dimensions, configuration, and performance, and which were nearly impossible to assess in advance using “rules of thumb” and experience alone.

However, these advanced analysis and modeling applications cannot suggest radically new configurations; in most cases, that is done by leveraging and expanding on existing approaches or the intuition or experience of the designer. These hunches can then be verified and fine-tuned by the EM field-solver software and extended to “what if?” modes and sensitivity analysis.

Q: What is a microstrip antenna?

A: A microstrip antenna, also called a patch antenna or printed antenna, is an antenna which is primarily a two-dimensional flat structure (Figure 6. In its simplest form, it uses a conducting “patch” one-half wavelength long, so that the metal surface acts as a resonator similarly to the half-wave dipole antennas.

Q: Is that it, or is there more to the story?

A: Of course there is more! It is often built by simply mounting or fabricating a suitably dimensioned metal sheet or surface on an insulating dielectric substrate, such as a printed circuit board. The opposite side of the PC board substrate is also cladded and so forms a ground plane, or another conductive surface is added ion the other side of the dielectric. As a result, it is easy to design and inexpensive to manufacture. They can be built as standalone, discrete devices as a “sandwich” of conductive material, dielectric, and conductive material as the ground plane.

Microstrip antennas are useful about 500 MHz to as high as 100 GHz; at the lower frequencies, they can be fairly large due to their half-wavelength dimension. As with many simple antennas, the basic EM theory and Maxwell’s equations needed to model them start simple, but fringing, physical reality, tolerances, and parasitics play a large role in their actual performance.

Part 2 of this FAQ will explore the microstrip antenna in more detail, including its primary attributes, advantages and disadvantages, and variations.

Patch Antenna Design Calculator

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References and Resources

Basics and tutorials

U Slot Patch Antenna Calculator Ti-84

1. Maxtena, “Microstrip Patch Antennas”
2. IOP Conference Series: Materials Science and Engineering, “Design, simulation and analysis: a microstrip antenna using PU-EFB substrate”
3. Pasternack, “Microstrip Patch Antenna Calculator”
4. EU Radar Tutorial, “Patch Antenna or Microstrip Antenna”
5. Ranga Rodrigo, Arab Academy for Science, Technology, and Maritime Transport, “Fundamental Parameters of Antennas”
6. Pongsak University, Thailand, “Chapter 2 : Fundamental parameters of antennas
7. Tutorials Point, “Antenna Theory – Micro Strip”
8. Universal Engineering College, University of Calicut, “Radiation and Propagation: Fundamentals of Antenna”
9. ResearchGate, “An Overview Of Microstrip Antenna”
10. ResearchGate, “Design of rectangular microstrip patch antenna”
11. ResearchGate, “Methods to Design Microstrip Antennas for Modern Applications”
12. Science Direct, “Microstrip Antenna”
13. Science Direct, “Stripline”
14. Antenna-Theory.com, “Microstrip (Patch) Antennas”
15. Antenna-Theory.com,“PIFA – The Planar Inverted-F Antenna”

Advanced microstrip antenna implementations

1. Elsevier, Science Direct, “A Novel Compact Dual Frequency Microstrip Antenna”
2. Elsevier, Journal of Applied Research and Technology, “Design of triple-layer double U-slot patch antenna for wireless applications”
3. ResearchGate, “Methods to Design Microstrip Antennas for Modern Applications”