KR100881639B1 - Antenna for ultra high frequency - Google Patents

Abstract

Microwave small antenna according to the present invention is a microstrip substrate; A feeding part formed on one side of an upper surface of the microstrip substrate and receiving a wireless signal of a band to be resonated; A radiation unit formed on an opposite side of the microstrip substrate on an opposite side to the side where the power supply unit is located and inducing resonance; And a feed line formed in a longitudinal direction on the upper surface of the microstrip substrate and providing a path through which the input signal is transmitted from the feed unit to the radiation unit. Broadband characteristics are secured by the inductive coupling between the patch and the ground plane, and there is an advantage in tuning the resonant frequency in the future by inserting a matching circuit stage.

Description

Antenna for ultra high frequency {Antenna for ultra high frequency}

Figure 1a is a front view as seen from the front of the microwave antenna for microwaves according to the present invention.

Figure 1b is a side view of the microwave antenna of the present invention viewed from the side.

Figure 1c is a rear view of the ultra-short microwave antenna according to the present invention from behind.

2 is a view showing an embodiment of a matching circuit of the microwave antenna for the microwave according to the present invention.

Figure 3 is a view showing the results of the simulation using a microwave microwave CST Microwave Studio of a commercial EM simulator according to the present invention.

4 is a view summarizing the gain characteristics of the microwave antenna for the microwave according to the present invention calculated based on the simulation.

The present invention relates to a small antenna for microwaves for reception of European Digital Broadcasting (DVBH).

An antenna is a conductor laid in the air to efficiently radiate radio waves into a space for radio communication or to maintain an electromotive force by radio waves, and is an apparatus for transmitting or receiving electromagnetic waves to a space for transmission and reception. The antenna varies in shape depending on the frequency used. The antenna is resonated at a frequency to be used for the antenna to operate efficiently. However, there are various wireless communication standards in the world, and since each uses a different frequency band, an antenna must have a plurality of resonant frequencies in order to use them in all of them in one frequency band. In addition, as portable wireless communication devices such as mobile phones are becoming smaller and lighter among the wireless communication devices that are becoming a necessity in the modern society, antennas are also becoming smaller and lighter. In addition to miniaturization, the demand for multiband or wideband antennas is increasing rapidly. Therefore, there is a lot of research to make the size smaller while further improving the performance of the antenna.

The frequency band in which the DVBH service is provided is a UHF band (470-702 MHz) and has a broadband characteristic of 40%. The DVBH service allows users to watch data broadcasts such as TV, movies, music, and news while on the move, which is similar to the DMB service in Korea. However, due to the long wavelength characteristics of the UHF band, it is very difficult to realize an internally miniaturized internal antenna with a typical Planar Inverted-F Antenna (PIFA) or whip antenna. The research on the terminal built-in multi-band antenna using the PIFA structure has already been progressed and commercialized. However, the research on the antenna having the broadband characteristics of the UHF band such as DVBH is insufficient.

In addition to the trend of circuit development in the field of wireless communication portable devices, in recent years, the portable device equipped with a built-in antenna as an alternative to satisfying the needs of consumers, while complementing the shortcomings of the existing external antenna, is convenient for users. In addition to the achievements, it is emerging recently. The requirements for antennas that can be miniaturized and mounted in portable wireless devices have been steadily raised, and have been successfully applied to slim portable devices. However, there is a problem that a small broadband antenna to cope with a new type of service such as DVBH is difficult to implement with a conventional PIFA or whip antenna.

The technical problem to be achieved by the present invention is to solve the above problems, and relates to a microwave antenna for receiving microwave mobile broadcasting (DVBH, Digital Video Broadcasting for Handheld), in more detail the folded form of radiation By using a ground plane formed with a device and a slot, it is to provide a reception antenna for a DVBH that has a wide bandwidth and a miniaturization.

In order to achieve the above technical problem, the microwave antenna for a microwave according to the present invention comprises a microstrip substrate; A feeding part formed on one side of an upper surface of the microstrip substrate and receiving a wireless signal of a band to be resonated; On the upper surface of the microstrip substrate is formed on the opposite side of the side where the feed section is located, bent in the back direction of the microstrip substrate, but not in contact with the rear surface of the microstrip substrate to maintain a constant space with the back of the microstrip substrate A radiation unit for inducing resonance by forming; And a feed line formed in a length direction on the upper surface of the microstrip substrate and providing a path through which the input signal is transmitted from the feed unit to the radiation unit. do.

In another embodiment of the microwave antenna according to the present invention to achieve the above technical problem, the wideband plane antenna is made of at least one variable energy storage element and one port is connected to the feeder, the other port The apparatus may further include a two port passive matching circuit unit connected to the feed line.

In another embodiment of the microwave antenna according to the present invention to achieve the above technical problem, the microstrip substrate forms an insulating region having a semicircular shape at a lower side by a length suitable for the resonance from the end of the rear surface thereof. It is characterized by being.

In another embodiment of the microwave antenna according to the present invention in order to achieve the above technical problem, the radiation portion at the bottom by a length suitable for the resonance to occur in the direction of the feed portion from the radiation portion on the back of the microstrip substrate An insulating region having a semicircular shape is formed.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1A is a front view of a microwave microwave antenna for DVBHDigital Video Broadcasting for Handheld according to the present invention, and FIG. 1B is a side view of a microwave antenna for DVBH according to the present invention. The rear view of the microwave antenna for the DVBH system according to the present invention. 2 is a view showing an embodiment of a matching circuit unit of a microwave antenna for a DVBH scheme according to the present invention. On the other hand, Figure 3 is a view showing the results of the simulation using a microwave microwave microwave antenna for the DVBH method according to the present invention using a commercial EM simulator of CST, finally Figure 4 is calculated based on the simulation Shows the gain characteristics of the microwave antenna for the DVBH system.

First, referring to FIGS. 1A to 1C, a configuration of a microwave antenna for microwaves according to the present invention will be described. A 50 ohm feed line 102 is patterned (patterned) on the top surface of the PCB substrate 101, and the ends of the feed line 102 are three-dimensional rectangular patches, i.e., radiators, having a bent structure 106. Connected to 103. Here, the radiation section 103 is formed by bending the copper foil remaining after removing the dielectric section from a part of one end of the substrate. The radiation part 103 forms the bending structure with respect to the part to which copper foil was exposed. Referring to Figure 1b looks at the view from the side. It can be seen that the side surface 107 of the microstrip substrate and the radiation portion 106 are bent, and the bent one side surface and the side surface 107 of the microstrip substrate form a space by a predetermined distance d1. have. Here, 103 and 106 are not separate from each other, and the radiation unit 103 is bent to the rear surface of the microstrip substrate 101, and is spaced apart from the rear surface by a predetermined distance d1 and 111 to form a constant space. This type induces a coupling phenomenon between the radiating element and the ground plane of the rear surface, leading to a broadband resonance phenomenon. Whether it is bent at right angles or bent in a circle with a constant radius of curvature, it does not matter. As the distance d1 increases, the resonance becomes clearer, but there is a trade off relationship with the antenna thickness. Therefore, it is important to determine an appropriate distance d1. And it is desirable to place the matching circuit portion 104 between the feed probe 105 and the feed line 102 for further improved reflection coefficient characteristics and tuning. At the rear of the antenna, a ground plane 110 having a slot 109 is formed.

Referring to FIG. 1C, which is viewed from the rear of FIG. 1A, a slot 109 having a 'U' shape is formed in the ground plane 110 in contact with the radiation unit 108, which contributes to the miniaturization of the antenna size. Region 108 shows an area in which the radiation portion 103 shown in FIG. 1A is continuously formed on the rear surface of the microstrip substrate. In FIG. 1C, the slot 109 having a 'U' shape is connected to the ground plane 110 in the rear surface of the microstrip substrate, and the copper foil is removed, that is, formed in an insulated state. As the distance d2 increases, the resonant frequency shifts to the low frequency band. Select the appropriate slot length (d2) to induce resonance in the DVBH band.

2 is a view showing an embodiment of a matching circuit of the microwave antenna for the DVBH method according to the present invention, it can be inserted between the feed probe 105 and the radiation element 103 to implement a more improved matching characteristics. . To this end, it has a filter form consisting of an inductor and a capacitor, and also has an advantage in properly tuning by using variable elements to reflect a change in resonance characteristics caused by influence of peripheral elements when an antenna is mounted in the future. The matching circuit shown in FIG. 2 is merely an example and may be configured in various different forms. The specific value may be different according to the resonance frequency, and obtaining the value may be easily understood by those skilled in the art to which the present invention pertains, and thus description thereof will be omitted.

In addition, it is preferable to use the FR4 substrate, which is widely used for producing a microstrip antenna, in terms of ease of production and cost.

As described above, the microwave antenna for the microwave according to the present invention is simple to implement using a planar structure, but can operate in a wide band.

Advantages and features of the microwave antenna according to the present invention can be easily seen with reference to FIGS. 4 and 5. 4 is a simulation result of the antenna according to the present invention using Microwave Studio of CST, a commercial EM simulator. When the reflection coefficient criterion is -1dB, the resonance characteristic is shown between 460-796 MHz. The reason why the reflection coefficient criterion is -1dB is because it satisfies the DVBH reception gain requirement sufficiently.

5 is a gain characteristic of the DVBH antenna calculated based on the above simulation. The gain requirement of the DVBH antenna is recommended to be -10dBi or higher at the lowest frequency of 470MHz and -7dBi or higher at the highest frequency of 702MHz. The antenna presented in the present invention is -5.21dBi at 470MHz and -0.9dBi at 702MHz, which is more than 5dBi higher than the recommended recommendation, so it can be considered a valid design as a receiving antenna.

As described above, optimal embodiments have been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the microwave antenna for the DVBH method according to the present invention secures broadband characteristics by using an inductive coupling phenomenon between a patch of a simplified folding structure and a ground plane, and inserts a matching circuit stage to resonate in the future. There is also an advantage to tuning. In addition, the 'U' shaped slot is formed on the ground plane to reduce the overall antenna size.

Therefore, the present invention can be miniaturized as a broadband broadband antenna for commercial DVBH communication and can be produced in a light and inexpensive technology. In addition, it can contribute greatly as a portable antenna embedded broadband antenna in the future.

Claims (3)

Microstrip substrates; A feeding part formed on one side of an upper surface of the microstrip substrate and receiving a wireless signal of a band to be resonated; On the upper surface of the microstrip substrate is formed on the opposite side of the side where the feed section is located, bent in the back direction of the microstrip substrate, but not in contact with the rear surface of the microstrip substrate to maintain a constant space with the back of the microstrip substrate A radiation unit for inducing resonance by forming; And And a feed line formed in a length direction on the upper surface of the microstrip substrate and providing a path through which the input signal is transmitted from the feed portion to the radiating portion. The small antenna of claim 1, wherein It is made of at least one variable energy storage element, one port is connected to the feeder, the other port is a two-port (two ports) passive matching circuit portion further comprises; Miniature antenna. The method of claim 1, wherein the microstrip substrate is And an insulating region having a semicircular shape at a lower side of the microstrip substrate so that the resonance occurs from the radiating portion toward the feeding portion on the rear surface of the microstrip substrate.

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