KR100479383B1 - Microstripline - Fed Slot Loop Antenna - Google Patents

Abstract

The present invention relates to a slotted loop antenna for feeding, and to a small antenna of a terminal or a wireless recognition card which requires a non-directional radiation characteristic by widening the frequency bandwidth without forming a separate matching circuit and reducing the size and thickness of the antenna itself. Application is possible.

To this end, the feeding slot loop antenna of the present invention includes a connector for transmitting and receiving RF power with an external transceiver, a feeding member for generating a resonance frequency from the RF power by connecting a conductive metal to one end of the connector in a longitudinal direction; A dielectric layer formed on the front surface of the feed member to guide the resonance frequency generated by the feed member, an anti-radiation layer formed of a conductive metal on the dielectric layer, and a region where the resonance frequency is waveguided in the anti-radiation layer. Exposing the portion in the form of a loop, it is made of a radiating member for radiating RF power corresponding to the resonance frequency through the first slot and the second slot formed respectively along the inner and outer peripheral surface of the loop.

Description

Feeding slot loop antenna {Microstripline-Fed Slot Loop Antenna}

The present invention relates to a feed slot loop antenna that can widen the frequency bandwidth without forming a separate matching circuit, and can also reduce the size and thickness of the antenna itself.

In general, microstripline fed slot loop antennas are small in size, light in weight, easy to integrate, easy to mass-produce, have a variety of shapes, and are compatible with integrated circuits (ICs). It is widely used in the field of detection radar, cellular base station or satellite communication operating in the microwave band.

Such a feed slot loop antenna generally forms a slot 13 in the anti-radiation layer 12, as shown in FIG. 1, and is not shown through the microstripline 10 disposed below the dielectric layer 11. Power is supplied to the connector or the dielectric layer 11, or the power is supplied using a CPW (Coplanar Waveguide) transmission line (not shown) formed on the anti-radiation layer 12, and in the center of the slot 13 for impedance matching Using a method of positioning the feed line by giving a horizontal offset, or cross-shaped at one end of the microstrip line 10, such as the "microstripline feed slot loop antenna" (Application No. 20-2002-0007297) previously filed Alternatively, a T-shaped stub (not shown) may be formed and fed.

Among these, in particular, the previously filed "Microstripline feed slot loop antenna" (application number 20-2002-0007297) has a feed region and a stub of the feed resonator each of the first and second stubs with respect to the center point of the slot. In addition, the third offset interval is used to have a broadband characteristic without adding a special matching circuit.

However, even if these feed slot loop antennas can have broadband characteristics without the addition of special matching circuits, the open stubs of the microstrip lines are connected long, increasing the size and thickness of the antennas themselves, and thus the omnidirectional nature of the radiation characteristics. There is a problem that is difficult to apply to the small antenna of the terminal or the wireless recognition card required.

Accordingly, the present invention was developed to solve the above problems, and to provide a feeding slot loop antenna that can increase the frequency bandwidth without forming a separate matching circuit, and can also reduce the size and thickness of the antenna itself. There is this.

The present invention provides a connector for transmitting and receiving RF power to and from an external transceiver, a feeding member for generating a resonant frequency from the RF power by connecting a conductive metal to one end of the connector in a longitudinal direction, and the feeding member on a lower surface thereof. Exposing the dielectric layer to guide the resonant frequency generated by the feeding member, an anti-radiation layer formed of a conductive metal on the upper surface of the dielectric layer, and a predetermined region where the resonant frequency is guided in the anti-radiation layer in a loop form, And a radiating member that radiates RF power corresponding to the resonance frequency through first and second slots respectively formed along outer and inner circumferential surfaces of the loop.

In addition, one end portion of the feeding member may have a first offset interval corresponding to a distance spaced in the x-axis direction and a second offset interval corresponding to a distance spaced in the y-axis direction with the corner of the upper portion of the first slot as a center point. Characterized in having a.

The apparatus may further include a radome case for protecting the power supply member, the dielectric layer, and the radiation member, wherein the radome case is made of a dielectric.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

First, the feed slot loop antenna of the present invention, as shown in Figure 2, the connector 20 for transmitting and receiving RF power with an external transceiver (not shown) and a conductive metal on one side of the connector 20 A power feeding member 21 connected in the longitudinal direction to generate a resonance frequency from the RF power, and a dielectric layer 22 to guide the resonance frequency generated by the power feeding member 21 by disposing the power feeding member 21 below; And an anti-radiation layer 23 formed of a conductive metal on the entire upper surface of the dielectric layer 22 to prevent radiation of the resonant frequency guided by the dielectric layer 22, and the resonant frequency of the anti-radiation layer 23 is waveguided. By exposing a predetermined region in the form of a loop 26 RF power corresponding to the resonance frequency through the first slot 24 and the second slot 25 respectively formed along the outer circumferential surface and the inner circumferential surface of the loop 26 Radiating room It consists of four members (27).

In this way, in the feed slot loop antenna, the connector 20 is electrically connected to an external transmission / reception device (not shown) to transmit and receive RF (Radio Frequency) power.

The power feeding member 21 is formed of a micro strip line integrally formed with a conductive metal, and one end thereof is formed long in the longitudinal direction to be electrically connected to the connector 20 to generate a resonance frequency from the RF power.

On the other hand, the dielectric layer 22 is formed on the upper front surface of the power supply member 21 to guide the resonance frequency generated by the power supply member 21.

The anti-radiation layer 23 is formed of a conductive metal such as copper on the entire upper surface of the dielectric 22 and is grounded. The radiation member 27 has an anti-radiation layer 23 corresponding to an area where the resonance frequency is waveguided. The first slot 24 and the second slot 25 are formed along the outer circumference and inner circumference of the loop 26 by exposing a portion of the loop 26 in the form of a loop 26 and exposing the loop 26. By radiating the RF power corresponding to the resonance frequency in the front or rear direction of the first slot 24 or the second slot 25.

As described above, the slotted slot antenna of the present invention is formed with a slot and a loop together in the radiating member to generate and radiate resonance with respect to the incoming RF power, and thus can be easily applied to frequencies of various bands.

In addition, it is preferable to cover and protect the feed member 21, the dielectric layer 22, and the radiation member 27 with a radome case (not shown) in the feed slot loop antenna. It is preferable to use those made.

Meanwhile, in the above description, only the case in which the RF power input through the connector is resonated and radiated through the slot is described. However, contrary to the above description, the RF power applied through the slot may be induced and output through the connector.

Next, in order to cause resonance of the feed slot loop antenna at a desired frequency, a loop should be appropriately set according to the resonance frequency of the slot loop antenna, which will be described with reference to FIG. 3.

First, the dielectric constant and thickness of the dielectric layer 22 are selected to predetermined values, and the width W1 of the first slot 24 is fixed to 0.23 lambda (wavelength) and the length L1 is changed to find the resonance frequency. The length L1 of the first slot 24 is an optimized value, and it is preferable to use 0.57λ, which is a value measured through an experiment.

In addition, when the width W1 and the length L1 of the first slot 24 are determined, the width W2 of the loop 26 and the width (2) of the second slot 25 are used to finely adjust the resonance frequency. W3), and the length L2 of the loop 26 and the length L3 of the second slot are respectively adjusted according to a predetermined resonance frequency, and the gaps between the slots and the loops lgap ₁ , lgap ₂ , lgap ₃ , and lgap _{In the} present invention, it is preferable to fix lgap ₃ and lgap ₄ to 1 mm, and to adjust the resonant frequency finely by changing only lgap ₁ and lgap ₂ , and in particular, widen lgap ₁ and L1 and L2. Reducing together, we can get a smaller resonance frequency at a smaller size.

4A and 4B are graphs showing real and imaginary impedance changes according to the change offx length of a feed slot loop antenna according to the present invention, and the length offy is fixed and offx is 11.00 mm, 8.56 mm, and 6.13, respectively. It is a graph measuring the change of impedance by changing to mm, 3.69mm and 1.25mm.

As shown here, in order to operate at the resonant frequency, since the point of imaginary impedance is 0 is the resonance point, the optimum impedance matching is to find the point where the reactance is 0 and the impedance is 50 Ω to fix the offset to radiate the electromagnetic waves without power loss. 4A and 4B, the offset point is 6.13mm, that is, 6.13mm, which is a distance spaced in the (-) direction on the x-axis from the right edge A of the upper portion of the first slot 24 as a center point. to be.

Meanwhile, FIGS. 5A and 5B are graphs of real and imaginary impedance changes according to the varying offy lengths of the feed slot loop antenna according to the present invention, and the lengths offx are fixed and the offys are respectively 1.4 mm, 2.9 mm, This is a graph measuring the change of impedance by changing 4.4mm, 5.9mm and 7.4mm.

As described above, in order to operate at the resonant frequency, since the point with imaginary impedance is 0 is the resonance point, the optimum impedance matching is to find the point where the reactance is 0 and the impedance is 50 Hz and fix the offset to radiate the electromagnetic waves without power loss. 5A and 5B have an offset point of 2.9 mm, that is, a distance of 2.9 mm spaced apart in the y-axis with respect to the right edge A of the upper part of the first slot 24 as a center point. .

In summary, one end of the power feeding member 21 of the present invention corresponds to a distance spaced in the (-) direction on the x axis with the center of the right edge A of the upper portion of the first slot 24 as the center point. It is preferable to have a first offset interval (offx) and a second offset interval (offy) corresponding to the distance spaced in the negative direction (-) in the y-axis, the first offset interval (offx) is 6.13mm, Most preferably, the second offset interval is 2.9 mm (offy), which is an optimal value measured through the aforementioned experimental results.

As described above, the impedance matching of the feeding slot loop antenna of the present invention can be finely adjusted by the offset change after setting the resonance frequency by adjusting the size of the slot loop antenna, and also appropriately setting the length parameters of the slot and the loop of the radiating member. As a result, the antenna may be designed to have a wideband frequency, and thus the resonance frequency may be lower than that of the conventional slot antenna, thereby reducing the size and thickness of the antenna.

As described in detail above, the feed slot loop antenna of the present invention can widen the frequency bandwidth without forming a separate matching circuit, and can also reduce the size and thickness of the antenna itself, thereby requiring a non-directional radiation characteristic. It can be applied to the small antenna of the wireless recognition card, and the impedance matching can be finely adjusted by the offset change of the feeding member after setting the resonance frequency by adjusting the size of the slot loop antenna.

Although the invention has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

1 is a diagram illustrating a general feeding slot loop antenna,

2 is an exploded view illustrating a feed slot loop antenna according to the present invention;

3 is a view for explaining a preferred mode of use of the feed slot loop antenna of the present invention.

4A and 4B are graphs showing changes in real and imaginary impedance according to the change offx length of a feed slot loop antenna according to the present invention;

5A and 5B are graphs showing changes in real and imaginary impedances according to the change offy length of a feed slot loop antenna according to the present invention.

Explanation of symbols on the main parts of the drawings

20: connector 21: feeding member

22 dielectric layer 23 anti-radiation layer

24: loop 25: first slot

26: second slot 27: radiation member

Claims (5)

A connector for transmitting and receiving RF power with an external transceiver; A feeding member configured to connect a conductive metal to one end of the connector in a longitudinal direction to generate a resonance frequency from the RF power; A dielectric layer disposing the power feeding member to guide the resonance frequency generated by the power feeding member; An anti-radiation layer formed of a conductive metal on the entire upper surface of the dielectric layer; Exposing a predetermined region in which the resonance frequency is waveguided in the anti-radiation layer in the form of a loop, and exposing the loop to the resonance frequency through first and second slots respectively formed along the outer and inner circumferential surfaces of the loop. Feed slot loop antenna, consisting of a radiating member for radiating a corresponding RF power. According to claim 1, wherein the feeding member; One end thereof has a first offset distance (offx) corresponding to a distance spaced in the (-) direction on the x axis with the right edge A of the upper portion of the first slot as a center point, and in the (-) direction on the y axis. A feed slot loop antenna, characterized in that it has a second offset offset corresponding to the spaced distance (offy). The method of claim 1, wherein the first offset interval (offx); 6.13mm, The second offset offset; A feeding slot loop antenna, characterized in that 2.9mm. The method of claim 1, And a radome case configured to surround and protect the feeding member, the anti-radiation layer, and the radiation member in a circumferential direction. The method of claim 4, wherein the radome case; A feed slot loop antenna, characterized in that consisting of a dielectric.