KR20220028904A - Antenna with broad high frequency bandwidth for amplitude modulation radio - Google Patents

Abstract

The present invention relates to a complex HF antenna for an AM radio, which comprises: a balun installed by being hung on a hanging member positioned at a predetermined height and performing signal conversion between a signal of a balanced circuit and a signal of an unbalanced circuit; a plurality of radiation elements which are installed left and right around the balun such that a top view seen from the complex HF antenna for the AM radio forming a bow-tie shape, wherein one end thereof is connected to an output port of the balun and the other end is fixated on the ground; and a coaxial cable connected to an input port of the balun, wherein the AM radio is connected to the coaxial cable. The present invention can support efficient remote communications by maintaining the NVIS characteristics in frequencies with 10 MHz or less using ionospheric reflection propagation, support terrestrial communications in bandwidth of 10 MHz or more, and enhance operational efficiency by adopting a non-control manner for the length of the radiation elements.

Description

Complex HF antenna for AM radio {Antenna with broad high frequency bandwidth for amplitude modulation radio}

The present invention relates to an antenna, and more particularly, to a complex HF antenna for an AM radio that enables terrestrial communication with NVIS (Near Vertical Incidence Skywave) through the ionosphere and does not require antenna length adjustment according to frequency.

Shortwave (High Frequency) is repeatedly reflected by the ionosphere and the ground, so that the airwaves can reach long distances. Using this characteristic, it is also used for international radio broadcasting targeting foreign listeners.

The shortwave (HF) communication device is a lightweight, single radio without a separate relay device, enabling easy-to-move and convenient long-distance (hundreds of kilometers) communication. HF Shortwave communication method can be said to be the only long-distance wireless communication method that is very strong in terms of survivability compared to other communication networks in wartime situations. Therefore, even with the development of various communication methods, in developed countries such as the US military, it is still the main communication method (voice and data) and forms an important axis of military communication.

However, in operation, communication failure is frequent due to the blind zone called Skip-Zone (about 30Km ~ 120Km), which acts as a hindrance to the success rate of the call between the transmitter and the receiver.

1 is a diagram showing operational difficulties and their causes in HF communication. The maximum terrestrial coverage distance in the communication skip-zone is normally 20Km based on the 50W AM radio output, and when using the ionospheric reflected wave, the minimum Reception is possible from more than 120km. The dead zone (about 30Km ~ 120Km) is an area where mutual communication is difficult and usually occurs due to the low angle of radio wave emission at the transmitting station. In particular, in the HF band near the lowest frequency of 2MHz, it cannot be used in the field due to the complexity of the installation and securing the antenna site area to secure stable impedance, including high radio wave emission angle and stable gain characteristics.

In addition, there are many difficulties in operation, such as manually adjusting the length of the antenna according to the frequency of the field antenna, which is currently electrified for military use. Figure 2 shows an example of the use of a conventional AM radio antenna, after calculating the average median value of the frequency band used, the dipole is fixed and operated, and it is difficult for non-skilled persons to use it because it is necessary to adjust the length of the radiating element for each frequency used. , the antenna efficiency is low and the NVIS function is not supported. In addition, due to the above-mentioned causes that impede the success rate of military wireless communication in tactical situations according to changes in various operational environments, especially the difficulty of using ionospheric reflected wave communication, the avoidance of equipment from users is further aggravating.

Therefore, it is necessary to actively support communication in various operational environments, and to solve the phenomenon of avoidance of equipment by users by resolving factors that hinder the success rate of HF communication.

The problem to be solved by the present invention was created to solve the above problems, and due to the narrowband characteristic, which is a communication impediment factor, the manual adjustment method of the radiating element according to the frequency used is eliminated, and the operation efficiency is increased by applying the non-adjustment method , frequencies below 10 MHz using ionospheric reflections maintain NVIS (Near Vertical Incidence Skywave) characteristics to support efficient long-distance communication, and in bands above 10 MHz to support terrestrial communication. It is to provide a composite HF antenna.

The composite HF antenna for AM radio according to an exemplary embodiment of the present invention for achieving the above technical problem is installed by hanging on a locking member located at a predetermined height, and a balanced signal and an unbalanced circuit signal. Converting Balun (BALUN); It is installed on the left and right about the balun so that the top view of the composite HF antenna for AM radio has a bow-tie shape, and one end is connected to the output port of the balun and the other end is on the ground. A plurality of radiating elements are fixed; and a coaxial cable connected to the input port of the balun, wherein an AM radio is connected to the coaxial cable.

The plurality of radiating elements are characterized in that when viewed from the side of the composite HF antenna for the AM radio, a triangular shape, a straight shape, or an inverted triangular shape around the balun. The composite HF antenna for the AM radio transmits the signal output from the AM radio through the coaxial cable to perform terrestrial communication in a frequency band of 10 MHz to 30 MHz, and a Near Vertical Incidence Skywave (NVIS) function in a frequency band of 10 MHz or less. It is characterized in that the ionospheric reflected wave communication is performed through the The balun includes a ferrite core of high capacity ferromagnetic material, and the impedance conversion ratio is 1:4 ferrite core balun.

According to the composite HF antenna for AM radio according to the present invention, a frequency of 10 MHz or less using an ionospheric reflected wave can support NVIS (Near Vertical Incidence Skywave) characteristics to support efficient long-distance communication, and terrestrial communication can be supported in a band of 10 MHz or more. .

And, according to the present invention, it is possible to eliminate the manual adjustment method of the radiating element according to the frequency used due to the narrowband characteristic, which is a communication impediment factor of HF shortwave communication, and to apply the non-adjustment method to increase the operating efficiency.

In addition, according to the present invention, the weight does not exceed 5Kg and can be installed by two people in the field, and by enabling installation in a short time, it is light and easy to move and install with a small number of people.

In addition, according to the present invention, by using an AM radio that is currently powered and operating, NVIS antennas that can be used in various ionospheric vertical reflection methods are developed to overcome the chronic skip zone of shortwave (HF) communication and to achieve HF band communication. By more activation, power can be maximized and reliability and survivability of communication during wartime and peacetime can be increased. It can be applied to industrial fields that can activate HF band communication by overcoming skip zone, a chronic problem of short wave (HF) communication, by using ionospheric vertical reflection with high efficiency by using HF band antenna in conjunction with AM radio. Do.

1 is a view for explaining the difficulties of operation and the cause in HF communication.
2 shows an example of using a conventional antenna for AM radio.
3 shows a composite HF antenna for AM radio according to an embodiment of the present invention.
Figure 4 is for explaining the long-distance communication and short-distance communication function of the composite HF antenna for AM radio according to the present invention.
5 shows an embodiment of a composite HF antenna for AM radio according to the present invention.
6 shows the NVIS incidence angle for communication distance and skip zone resolution.
7 shows an example of the structure of a Ferrite Core Transformer of a Balun, which is an impedance matching device in a composite HF antenna for an AM radio according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments described in this specification and the configurations shown in the drawings are only a preferred embodiment of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and variations.

3 shows a composite HF antenna for AM radio according to an embodiment of the present invention. 3, the composite HF antenna 300 for AM radio according to an embodiment of the present invention includes a balun (BALUN, 310), a plurality of radiating elements (320, 330), and a coaxial cable (340).

The balun (BALUN, 310) serves to convert a balanced signal into an unbalance signal and an unbalance signal into a balanced signal, and is a matching transformer used when feeding a balanced antenna with an unbalanced feeder (coaxial cable). It is installed by hanging on the support member 305 located in the cladding member 365, and converts a signal of a balanced circuit (Balanced Signal) and a signal of an unbalanced circuit (Unbalanced Signal). The balun 300 may include a ferrite core, which is a high-capacity ferromagnetic material, to prevent saturation of the BALUN, which is an impedance matching device, under the condition of an RF input of 50W, and the impedance conversion ratio may be a ferrite core balun of 1:4. In order to satisfy the wide bandwidth (specific bandwidth of 175%), the balun 300 is a BALUN matching device using a ferrite element, which is a type of concentrated element, to achieve a wide impedance bandwidth.

The plurality of radiating elements 320 and 330 are installed left and right around the balun 310 so that the top view of the composite HF antenna for the AM walkie-talkie forms a bow-tie shape, and one end is It is connected to the output port of the balun and the other end is fixed to the ground through a fixing member 360 . The plurality of radiating elements 320 and 330 form a triangular shape, a straight shape, or an inverted triangular shape centered on the balun 310 when viewed from the side view of the composite HF antenna 300 for AM radio according to the present invention. and NVIS (Near Vertical Incidence Skywave) characteristics can be performed through this shape.

NVIS communication refers to an operation method in which radio waves are reflected from the F1 layer of the ionosphere to communicate with a distant counterpart, but the angle of incidence is increased to communicate as close as possible to the maximum coverage of terrestrial waves. In order to obtain the NVIS effect, the radio wave energy needs to be radiated at an angle of 75° or more based on the frequency at which the ionospheric reflection is possible. In addition, in NVIS communication, it is necessary to select a frequency lower than the critical frequency (CF) in order to smooth the ionospheric reflection of radio waves that are incident near-vertically. Here, the critical frequency refers to a frequency below the optimum traffic frequency (FOT) of about 85% of the maximum usable frequency (MUF) because it is advantageous for ionospheric reflection but has a large signal attenuation.

The composite HF antenna 300 for AM radio according to the present invention is a bow-tie type extending the concept of a triangular flat antenna, and broadband is possible, and by having a plurality of radiating elements 320 and 330, Due to the narrowband characteristics, it is possible to eliminate the inconvenience of manually adjusting the radiating element according to the frequency used, and to apply the non-adjustment method, and it can have a high gain in the range of -3 to +3 dBi.

One end of the coaxial cable 340 is connected to the input port of the balun 310 , and the other end is connected to the AM radio 350 . An input power of 50W is possible through the AM radio 350, and both a mobile station and a fixed station can be used.

The composite HF antenna 300 for AM radio according to the present invention is a combination of spatial wave (operating below 10 MHz) and terrestrial wave (10-30 MHz), and the signal output from the AM radio 350 is transmitted through the coaxial cable 340 and 10 MHz Terrestrial communication is performed in the ~30MHz frequency band, and ionospheric reflected wave communication through the NVIS (Near Vertical Incidence Skywave) function can be performed in the frequency band below 10MHz. It can be installed in time (eg 10 minutes), so it is easy to move and install.

On the other hand, the composite HF antenna 300 for AM radio according to the present invention will be described in more detail. The present invention can solve the dead zone, which is a chronic problem of shortwave (HF) communication, through an NVIS antenna that can be operated in an ionospheric vertical reflection method using an AM radio and activate HF band communication more. Through this, the reliability and survivability of communication during wartime and normal times can be increased, and when applied to the military, power can be increased.

In the military, shortwave communication has been using separate antennas for terrestrial and ionospheric reflection waves. It supports terrestrial waves (direct wave, reflected wave, and ground wave) by using a half-wavelength vertical grounding antenna. It is mainly used in fixed stations for short-distance communication of less than 30Km. was used in

The present invention is an HF band antenna having two functions of long-distance communication as well as short-distance communication. 4 is a view for explaining the long-distance communication and short-distance communication function of the composite HF antenna for AM radio according to the present invention. Referring to FIG. 4, the composite HF antenna for AM radio according to the present invention is 5Kg or less and is easy to carry, supports terrestrial waves in a frequency band of 10MHz to 30MHz, and enables ionospheric reflected wave communication through the NVIS function in a frequency band of 10MHz or less. it's an antenna In the frequency band of 10 MHz or less, the incident angle of the traveling wave going straight to the ionosphere (F layer) is incident in a near-vertical (75 ^O or more) direction. This can be explained as the concept of moistening the area around the lawn with the hose outlet as the center when the direction of the water flowing from the lawn is fixed to the sky. Through this, the skip zone area of the HF band can be resolved, and the receiving point can receive radio waves uniformly regardless of the azimuth.

5 shows an embodiment of the composite HF antenna for AM radio according to the present invention, and the composite HF antenna for AM radio according to the present invention has a V-conical structure and broadband characteristics, and a method for manually operating a radiating element It eliminates inconvenience and is easy to operate. In addition, it provides an environment that is easy to receive in the Skip Zone after incident signals in the low frequency band at a high angle (over 75 ^° ) even in the unadjusted state, and supports NVIS characteristics regardless of the user's skill level through stable matching performance. . The composite HF antenna for AM radio according to the present invention can allocate the lowest and highest frequencies (LUF, MUF) to 2 to 9 MHz for use of spatial waves in a frequency band of 10 MHz or less, and 9 MHz or more in a frequency band of 10 MHz or higher. It can operate terrestrial waves and can operate at high power to extend the mastery distance.

As shown in FIG. 5, the composite HF antenna for AM radio according to the present invention is a broadband antenna of a Bowtie-Plate structure based on a V-Conical antenna, and provides good gain in the entire bandwidth, and a conventional 2-Wire type AM radio. It has an antenna for multi-wire structure. This can significantly improve the frequency characteristics of the half-wavelength dipole antenna compared to the conventional 2-Wire type AM radio antenna, and through this, the problem of adjusting the length of the radiation element according to the frequency can be solved. In addition, as a portable field antenna, it is easy to use in the field and can provide stable gain and high VSWR characteristics.

In the related art, as shown in FIG. 2, after calculating the average median value of the frequency band used, the dipole is fixed and operated, and it is necessary to adjust the length of the radiating element for each frequency used, so it is difficult for unskilled people to use it, the antenna efficiency is low, and the NVIS function is not supported.

On the other hand, the composite HF antenna for AM radio according to the present invention can be easily installed by two people in a short time, and there is no need to adjust the length of the radiating element for each frequency used, so non-skilled people can install it, and it can be operated to have a stable NVIS function. there is. The present invention can overcome the 70m range of half-wavelength length deviation of 2MHz and 30MHz frequencies in an unadjusted manner.

In addition, by using a ferromagnetic material that guarantees linearity under high-capacity 50W rated RF input conditions, an appropriate circuit can be designed for the antenna, and the length and weight of the antenna can be reduced by reducing the material weight. In addition, the balun used in the present invention can stably match impedance in a wide band.

A stable NVIS function, which is one of the characteristics of the composite HF antenna for AM radio according to the present invention, will be described in more detail.

6 shows the NVIS incidence angle for communication distance and skip zone resolution. Although the skip zone is somewhat different for each document, it can be defined as an area of 30Km to ^120Km based on the transmit antenna. The present invention provides a function as a vertical ground antenna for the 10 MHz to 30 MHz band supporting the ground wave. Antenna operates by the interaction of radiation pattern and frequency (bandwidth) and impedance and gain. In particular, the radiation pattern has a close function relationship with the frequency and is very dependent on the antenna bandwidth. Although there are broadband antennas (cylindrical, conical, etc.) of complex structures for NVIS performance, the composite HF antenna for AM radio according to the present invention has a very simple shape (bow-tie) and can be easily installed and operated in the field.

7 shows an example of the structure of a Ferrite Core Transformer of a Balun, which is an impedance matching device in a composite HF antenna for an AM radio according to the present invention. In actual use of an antenna, the transmission line is usually a real number, whereas the antenna exists as a complex number, so the part used as a device to compensate for this can be called a balun, The method can be designed with a ferrite core balun with an impedance conversion ratio of 1:4 by using ferrite, a type of concentrator. In addition, if the design and configuration of the ferrite balun are well combined, a wide bandwidth can be manufactured, and the shape diagram can be manufactured as shown in FIG. 7 .

Although the present invention has been described with reference to the embodiment shown in the drawings, which is only exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

300: Composite HF antenna for AM radio
305: support member
310: Balun (BALUN)
320: radiating element
330: radiating element
340: coaxial cable
350: AM radio
360: locking member
365: fixing member

Claims (4)

In the composite HF antenna for AM radio,
A balun that is installed by hanging on a locking member located at a certain height and converts a signal of a balanced circuit and a signal of an unbalanced circuit (BALUN);
It is installed on the left and right about the balun so that the top view of the composite HF antenna for AM radio has a bow-tie shape, and one end is connected to the output port of the balun and the other end is on the ground. A plurality of radiating elements are fixed; and
and a coaxial cable connected to the input port of the balun,
A composite HF antenna for AM radio, characterized in that the AM radio is connected to the coaxial cable. According to claim 1, wherein the plurality of radiating elements
Composite HF antenna for AM radio, characterized in that when viewed from the side of the complex HF antenna for AM radio, it forms a triangular shape, a straight shape, or an inverted triangular shape around the balun. According to claim 1, wherein the composite HF antenna for AM radio
The signal output from the AM radio is transmitted through the coaxial cable to perform terrestrial communication in a frequency band of 10 MHz to 30 MHz, and to perform ionospheric reflected wave communication through the NVIS (Near Vertical Incidence Skywave) function in a frequency band of 10 MHz or less. A composite HF antenna for AM radio. The method of claim 1, wherein the balun
A composite HF antenna for AM radio, comprising a ferrite core of high capacity ferromagnetic material.

Images