Substrate integrated waveguides polarisation printed circuit manufacture Q-factor slot antennas frequency 13 GHz to 17 GHz high-gain planar tapered slot antenna Ku-band applications high-gain antipodal linearly tapered slot antenna substrate integrated waveguide feeding structure Q-factors planar printed circuit board fabrication process low.

• Abstract—An Ultrawideband (UWB) high gain compact Vivaldi antenna with end fire radiation patterns is presented for radar and microwave imaging applications. The antenna is operating for 2.9GHz to more than 11GHz with -10dB impedance bandwidth and is designed on low cost FR4 substrate of thickness 0.8mm.
• Current ultra-wide bandwidth (UWB) and high-gain antennas include mainly log-periodic antenna, traditional transverse electromagnetic (TEM) horn antenna, spiral antenna, bow-tie antenna, tapered slot antenna, and microstrip patch antenna. However, the traditional Yagi antenna and microstrip patch antenna have narrow bandwidth.

Main Article Content

Abstract

A broadband gradient refractive index (GRIN) metamaterial is used to improve the gain of the tapered slot antenna. The proposed metamaterial is capable of reducing the side lobe level of the antenna. The gradient refractive index (GRIN) metamaterial is constructed by using non-resonant parallel-line unit cells with different refractive index. Due to the non-resonant structure, the proposed unit cell exhibits low loss and large frequency bandwidth. The metamaterial, whose effective refractive index is lower than that of the substrate on which the antenna is printed. Therefore, the proposed metamaterial is act as a regular lens in beam focusing. The GRIN metamaterial is integrated in front of the antenna which has the capability to manipulate electromagnetic wave accurately. The measurement results indicate that the reflection coefficient of the antenna is below -10 dB over the frequency band from 3 to 11 GHz. The radiation pattern of the antenna shows the beam width becomes narrow and directive with low side lobe level. The peak gain is increased by 2.1 dB at 9.5 GHz.

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References

High Gain Tapered Slot Antenna Design

1. Gibson P. J., The Vivaldi Aerial, 9th European Microwave Conference, 101–105, 1979.
   View Article


2. B. Zhou and T. J. Cui, Directivity enhancement to Vivaldi antennas using compactly anisotropic zeroindex metamaterials, IEEE Antennas Wirel. Propag. Lett., 10: 326–329, 2011.
   View Article


3. L. Chen, Z. Lei, R. Yang, J. Fan, and X. Shi, A broadband artificial material for gain enhancement of antipodal tapered slot antenna, IEEE Trans. Antennas Propag., 63: No. 1, 395–400, 2015.
   View Article


4. L. M. Zhong and T. J. Cui, Experimental realization of a broadband bend structure using gradient index metamaterials, Opt. Exp., 17: No. 20,18354-18363, 2009.
   View Article


5. X. Chen, T. M. Grzegorczyk, B. I. Wu, J. Pacheco, and J. A. Kong, Robust method to retrieve the constitutive effective parameters of metamaterials, Phys. Rev. E, 70: Feb. 2004, Art. ID 016608.
   View Article


6. E. Gazit, Improved design of the Vivaldi antenna, Inst. Elect. Eng. Proc., 135: No. 2, 89–92, 1988.
   View Article


7. Schüppert B., Microstrip/slot line transition: modelingand experimental investigation, IEEE Trans. Microw.Theory Tech., 36: No. 8, 1272 –1282, 1988.


8. [8] A. Dhouibi, S. N. Burokur, A. de Lustrac and A. Priou, Low-profile substrate-integrated lens antenna using metamaterials, IEEE Antennas Wireless Propag. Lett., 12: 43-46, 2013.
   View Article


9. K. Ma, Z. Q. Zhao, J. N. Wu, M. S. Ellis and Z. P. Nie, A printed Vivaldi Antenna with improved radiation patterns by using two pairs of Eye-Shaped Slots for UWB applications, Progress In Electromagnetics Research, 148: 63-71, 2014.
   View Article


10. A. De Oliveira, M. Perotoni, S. Kofuji, and J. Justo, A palm tree antipodal Vivaldi antenna with exponential slot edge for improved radiation pattern, IEEE Antennas Wireless Propag. Lett., 14: 1334–1337, 2015.
    View Article


11. de Oliveira, Alexandre M., João F. Justo, Marcelo B. Perotoni, Sérgio T. Kofuji, Alfredo G. Neto, Regis C. Bueno, and Henri Baudrand, A high directive Koch fractal Vivaldi antenna design for medical near-field microwave imaging applications, Microwave Opt. Technol. Lett., 59, No. 2: 337-346, 2017.
    View Article


12. Singha Rahul and Vakula Damera, Directive beam of the monopole antenna using broadband gradient refractive index metamaterial for ultra-wideband application, IEEE Access, 5: 9757–9763, 2017.
    View Article

Having backed the new LimeSDR mini crowdsupply campaign, I am expecting delivery of a highly capable software radio with the ability to receive and transmit at frequencies up to 3.8GHz. This is brilliant and the small size means that it can always be in my bag as and when I need to investigate some RF signals. But what antenna do I use?

Most people would settle for a mag-mount monopole, but these are inherently narrow band and while you can telescopically adjust the length it is pain and hard to get the frequency spot on. Also as an omni-directional antenna its not much good for hunting unknown signals.

What I wanted was a small very wide-band antenna with plenty of gain. The solution is the Ultra Wide Band(UWB) antenna. In this series of posts I will discuss some of the candidate antennas, detail why I selected the one I did, discuss the chosen design, introduce some of the tweaks to improve performance, and provide some measured results.

Introducing the Ultra Wide Band Antenna

A UWB antenna is designed to work on a wide range of frequencies. Typically much more than an octave of bandwidth. Thats a lot when most antennas stuggle to acheive more the 20 or 30% bandwidths. Often these antenna designs are used for UWB comms systems. These are designed to spread their transmit power over a really large portion of bandwidth such that the interference to any particular conventional RF channel is negligible. Its an interesting technology but with a few exceptions has yet to catch on on a large scale commercially.

These antennas are also often referred to as Frequency Independent antennas, but for the purpose of this blog I will stick to UWB.

There are some downsides to UWB antennas. Primarily, a narrrow band antenna acts as a first stage filter for your receiver. This prevents strong out of band signals from overloading you receiver and causing spurious signals. If you only need to work on one or two bands, a UWB antenna is not the best choice.

Mighty Morphing Antenna

As with most antenna’s there are a number of ways to look at how they work. Personally, I like to imagine how the antenna can be created by gradually adapting the shape of an antenna that I previously understood. At every point in this transformation a new antenna can be created that should in theory work, although may need some tweaks with the feed structure and impedance matching. This is often the way I will explain to people how an antenna works, so here is a quick example.

From top.; Horn Antenna, Open Horn Antenna, Tapered Slot Antenna, Open Horn Antenna, Fat Bowtie, Discone Antenna

In the above image you can see one possible relationship between a Horn and Dipole Antenna. Along the way I created a Tapered Slot Antenna.

Example UWB antennas

So what are the candidates for my UWB antenna. There are many ways to make such an antenna. Each has it’s pro’s and con’s and books can be filled about each varient.

This list is by no means exhaustive, but I think it covers the majority. Again, I wont go into the analysis or performance of these antenna in detail, but merely present them so that you can see the rough form factor of each.

Discone

The discone is literally constructed with disc placed on top of a cone and a feed between the two shapes.

There are a few ways to look at how this antenna works. One way I like to look at this is as a Bowtie style antenna, where it has been revolved into 3D and the top element is squashed flat.

Another way to look at this antenna is as a form of Tapered Slot Antenna(see below) that has been revolved in 3D around its feed point -to make a 3d shape. Or alternately as a circular horn antenna.

High Gain Tapered Slot Antenna Booster

The discone is normally made of wire elements rather than solid metal, but the performance is very similar. Some even have a aditional vertical element on top to provide extra performance at the bottom end.

If you have a mast and can only put up one antenna, the discone is a great option.

Log periodic dipole array (LPDA)

Log Periodic Dipole Array

Normally just called a Log Periodic or Log-P. This is like a Yagi but with progressively shorter directing elements.

In this antenna the non-resonant elements present a poor impedance match to the feed signal. When the feed reaches an element of appropriate length it can flow down that arm. The elements in front and behind this resonating element act as a director and reflector in a similar way to a standard Yagi. Hence this antenna has a small amount of gain, which is fairly stable over the frequency range.

This antenna is regularly used in EMC testing labs. Probably because the gain is fairly constant over frequency.

High Gain Tapered Slot Antenna Box

There are several examples of PCB versions of this antenna, which make it easy to fabricate and also fairly thin and light.

Log periodic tooth antenna

Log Periodic Tooth Antenna with it’s complementary version.

The Log Periodic Tooth Antenna is derived from Bowtie dipole antenna. This is a really cool antenna as it can also be manufactured by cutting the shape into sheet of metal. In this form it is a complementary antenna.

I havent seen this antenna in much real world use, but its cool nonetheless.

Spiral antenna

There exist many types of spiral antenna. The one shown is ans Archimedean Spiral Type, but logarithmic types are also popular. The antenna has circular polarisation and maximum gain in the direction of the central axis. Gain can be increased by placing this above a ground plane.

If you need wide band circular polarisation, this or a variant of it is a great candidate.

Horn Antenna

High Gain Tapered Slot Antennas

Horn Antenna

Very popular at high frequencies and can have really high gain as it has a very large aperture.

Dual Ridged Horn Antenna (DRHA)

A kind of combination of a Vivaldi(i’ll get to this one) antenna and a Horn antenna. Often used as a gain standard for antenna measurement ranges and chambers.

UWB Monopole/Dipole

UWB Monopoles and Dipoles

Normally a 2d PCB printed antenna, this normally consists of a circlular (or semi-circular) antenna element above a ground plane(or above another circular element for a dipole style). Sometimes these antenna use elliptical or exponential curves instead of pure circles. In 3D implementations they use 3D spheres orhemi-spheres.

I havent seen many of these in the wild, but here is a great example built from ikea parts. https://discourse.myriadrf.org/t/making-antennas/1793/40

Tapered Slot Antenna (TSA)

I see this as a 2D slice of a horn antenna. Because of it’s 2D nature the effective aperture is somewhat less and hence this antenna has less gain. Like a standard slot antenna the impedance can be tuned at a given frequency by moving the feed towards or away from the shorted end of the slot.

My Chosen Antenna

In the follow on to this post I will show the antenna that I have chosen. Its a really cool variant of the Tapered Slot Antenna.

Other resources

I owe a huge debt of thanks to others who have shared valuable antenna design information online. I have a number of good books on this subject and I may provide some recommendations in a future post, but for now these sites are well worth looking into for anyone who needs more information about UWB antennas in particular.

Antenna-Theory.com is an amazing source of information and tutorials on a whole host of antenna designs. What I really like about this site is its intuitive apporach that really reduces the amount of math required. As the author says,

“The subject of Antennas is best understood intuitively; this is in stark contrast to the methods in University, where complex pervades every page. I do not think this approach effectively teaches antenna theory.”

I agree wholeheartedly.

Microwave101 encyclopedia this site goes wider than just antennas, but the content is just brilliant.