KR20050008032A - Duplexer of mm wave - Google Patents

Abstract

PURPOSE: A duplexer of millimeter waves is provided to duplex a millimeter wave band by duplexing a frequency corresponding to the range by implementing an NRD filter on a T-junction waveguide tube. CONSTITUTION: A duplexer of millimeter waves includes a transmission dielectric waveguide tube(210), a reception dielectric waveguide tube(200), a waveguide tube assembly(220), and a conductive window(230). The transmission dielectric waveguide tube and the reception dielectric waveguide tube are formed to have different lengths from each other by arranging a plurality of NRD(Non-Radiative Dielectric) filter(D1-D23) according to a frequency to be guided. The waveguide tube assembly electrically shields the transmission dielectric waveguide tube and the reception dielectric waveguide tube by taking the waveguide tubes apart from each other. The conductive window is formed on both sides of the waveguide tube assembly for an impedance matching of the transmission dielectric waveguide tube and the reception dielectric waveguide tube.

Description

Duplexer of mm wave

The present invention provides a simple structure in which a plurality of NRD filters having different sizes exhibiting specific frequency cut-off characteristics are arranged in the transmitting end and the receiving end in different numbers, and conductors are interposed therebetween for impedance matching between the NRD filters arranged at the transmitting end and the receiving end. It relates to a millimeter wave duplexer that arranges a T-junction waveguide with a window to duplex the frequencies of the millimeter wave band.

In general, a duplexer is a device used to separate them so that the transmitting frequency of the transmitting end and the receiving frequency of the receiving end do not mix with each other in a mobile communication terminal having a transmitting end and a receiving end using one antenna.

That is, since the corresponding bands of the transmission frequency and the reception frequency are similar in the mobile communication terminal, it can be used as one antenna without using two antennas.

In addition, the use of two antennas, the overall shape of the terminal is not only strange, but also increases the unit cost, there are many disadvantages such as interference between the antennas. Therefore, a device developed to overcome these disadvantages is a duplexer, which separates them so that the transmitting frequency and the receiving frequency of the receiving end do not mix with each other in a mobile communication terminal having a transmitting end and a receiving end sharing a single antenna. It is an element used.

Such a duplexer can be implemented with a combination of LC filters, but in most cases is made using a resonator because the frequency selectivity is inferior. FIG. 1 is a diagram illustrating such a general duplexer.

As shown here, a general duplexer is a combination of a coaxial ceramic resonator (Coaxial Ceramic Resonator or Bar Dielectric Resonator)

A band pass filter (BPF) is implemented in each of the transmitter 100 and the receiver 110, and the band pass filter 100 of the transmitter and the band pass filter 110 of the receiver, in particular, include an inductor L and a capacitor. Through (C), one antenna port is connected.

However, such a duplexer is somewhat limited in the frequency band used. As the frequency band increases, a frequency loss occurs during duplexing due to a capacitor, and thus attenuation occurs at the corresponding frequencies of the transmitter and the receiver. In particular, in recent years, many communications that cannot be accommodated only by the microwave band Because frequency is used, there is a need for a new duplexer that can perform duplexing in millimeter wave bands higher than this microwave band without frequency loss.

Accordingly, the present invention was developed to solve the above problems, and an object thereof is to provide a millimeter wave duplexer capable of duplexing a transmission frequency and a reception frequency even in a millimeter wave band.

In accordance with this object, the present invention provides a simple structure in which a plurality of NRD filters having different sizes exhibiting specific frequency cut-off characteristics are arranged in different numbers at each of the transmitting end and the receiving end, and for impedance matching between the NRD filters disposed at the transmitting end and the receiving end. In the meantime, a T-junction waveguide with a conductor window is arranged to duplex the transmit and receive frequencies in the millimeter wave band.

To this end, the millimeter wave duplexer according to the present invention includes a transmitting dielectric waveguide and a receiving dielectric waveguide formed by differently arranging a plurality of non-radial dielectric (NRD) filters having different lengths and widths according to a frequency to be waveguided; A waveguide assembly, wherein the transmitting dielectric waveguide and the receiving dielectric waveguide are spaced apart and electrically shielded from each other so that no coupling occurs between them; And conductive windows formed on both sides of the waveguide assembly for impedance matching of the transmitting dielectric waveguide and the receiving dielectric waveguide.

In addition, it is preferable that the conductor window uses an inductive iris.

In addition, the transmitting dielectric waveguide and the receiving dielectric waveguide are each bonded to both ends of the waveguide assembly, and the waveguide assembly is T-shaped.

It is preferable to use a (T-juntion) dielectric waveguide.

1 is a diagram illustrating a general duplexer;

2 shows a millimeter wave duplexer according to the present invention;

3 illustrates the receiving dielectric waveguide of FIG. 2;

4 shows the transmission dielectric waveguide of FIG. 2;

5 shows the waveguide assembly of FIG. 2;

6 shows frequency characteristics of the receiving dielectric waveguide of FIG. 3;

FIG. 7 is a diagram illustrating frequency characteristics of the transmitting dielectric waveguide of FIG. 4.

Explanation of symbols on the main parts of the drawings

200: receiving dielectric waveguide 210: transmitting dielectric waveguide

220: waveguide assembly 230: conductor window

240: Conductor conduit D1 ~ D23: NRD filter

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

First, a millimeter wave duplexer according to the present invention will be described with reference to FIG.

In FIG. 2, reference numeral 200 denotes a receiving dielectric waveguide formed by differently arranging a plurality of non-radial dielectric (NRD) filters having different lengths and widths according to a reception frequency to be waveguided.

Further, reference numeral 210 denotes a transmission dielectric waveguide for disposing a NRD (Non-Radiative dielectric) filter more than the reception dielectric waveguide and forming a length longer than the length of the reception dielectric waveguide 200 to guide a transmission frequency different from the reception frequency. to be.

Reference numeral 220 denotes a waveguide assembly, in which the receiving dielectric waveguide 200 and the transmitting dielectric waveguide 210 are spaced apart from each other so as not to cause coupling, and electrically shielded. A conductive window is formed on both sides of the waveguide assembly 220 for impedance matching between the receiving dielectric waveguide 200 and the transmitting dielectric waveguide 210.

Finally, reference numeral 240 denotes a conductor conductor 240 that surrounds the waveguide assembly 220 in which the transmission dielectric waveguide 200, the reception dielectric waveguide 210, and the conductor window 230 are formed.

In the duplexer of the present invention having such a structure, the receiving dielectric waveguide 200 is connected to a plurality of non-radial dielectric (NRD) filters having different sizes and widths to form a high attenuation dielectric waveguide, and the NRD filter is connected. The number of s and the arrangement thereof depend on the millimeter wave transmission frequency in the several GHz band to be waveguided.

The waveguide assembly 220 joins the reception dielectric waveguide 200 and the transmission dielectric waveguide 210 by a predetermined distance so that coupling does not occur between them.

For example, the receiving dielectric waveguide 200 is bonded to one end of the waveguide assembly, and the transmitting dielectric waveguide 210 is bonded to the other end of the waveguide assembly so that the two waveguides 200 and 210 are separated by a predetermined distance. Electrically shield the waveguide and the receiving dielectric waveguide.

In order to prevent mutual interference between the reception frequency waved by the reception dielectric waveguide 200 and the transmission frequency waveguided by the transmission dielectric waveguide 210 and to perform impedance matching, both sides of the waveguide assembly 220 are formed. Each of the conductor windows 240 is formed, and it is preferable that the conductor windows use an inductive iris.

The connection port of the waveguide assembly 220 and the two waveguides 200 and 210 may be a first connection port of the waveguide assembly 220 and the receiving dielectric waveguide 200, the waveguide assembly 220, and the waveguide assembly 220. The second connection port of the transmitting dielectric waveguide 210 acts as a stub to reflect either frequency upon waveguide of the transmission frequency and the reception frequency.

As described above, according to the present invention, the millimeter wave duplexer has a simple structure in which a plurality of NRD filters having different sizes exhibiting specific frequency blocking characteristics are arranged in different numbers at each of the transmitting end and the receiving end, and between the NRD filters disposed at the transmitting end and the receiving end. T-junction waveguides with conductor windows are placed between them for impedance matching, allowing the frequency of the millimeter wave band to be duplexed.

Next, FIG. 3 is an enlarged view illustrating the receiving dielectric waveguide 200 of FIG. 2 in more detail.

Here, in the receiving dielectric waveguide 200 of the present invention, a plurality of non-radial dielectric (NRD) filters having different sizes and widths are connected to form a high attenuation dielectric waveguide.

At this time, the number and arrangement of NRD filters to be connected are determined according to the millimeter wave transmission frequency of several GHz band to be waveguided. For example, in order to guide the transmission frequency of the 24 GHz band, the NRD filters D1 to D8 are in order Arranged and connected, D8 is bonded to one side of the waveguide assembly, the NRD filter of the D1 ~ D8 is used the following width and length.

Product Name Length width D1 3 2.1 D2 0.8 1.0 D3 1.45 2.1 D4 1.65 1.0 D5 1.46 2.1 D6 1.65 1.0 D7 1.45 2.1 D8 0.8 1.0

Next, FIG. 4 is an enlarged view showing the transmission dielectric waveguide 210 of FIG. 2 in more detail.

In FIG. 4, in the transmission dielectric waveguide 210 of the present invention, a plurality of non-radial dielectric (NRD) filters having different sizes and widths are connected to form a high attenuation dielectric waveguide.

In this case, the NRD filter is disposed more than the receiving dielectric waveguide 200 so as to be longer than the length of the receiving dielectric waveguide 200 to guide the transmission frequency different from the receiving frequency.

The number and arrangement of the NRD filters are determined according to the millimeter wave transmission frequency in the several GHz band to be waveguided. For example, in order to waveguide the transmission frequency in the 26 GHz band, the NRD filters D12 to D23 are arranged in order. D9 is connected to the other side of the waveguide assembly. The NRD filters of D9 to D20 have a width and length as shown in Table 2 below.

Product Name Length width D12 0.82 1.0 D13 2.55 2.1 D14 1.75 1.0 D15 2.63 2.1 D16 1.94 1.0 D17 2.64 2.1 D18 1.94 1.0 D19 2.63 2.1 D20 1.75 1.0 D21 2.55 2.1 D22 0.82 1.0 D23 2.5 2.1

Next, FIG. 5 is an enlarged view showing the waveguide assembly 220 of FIG. 2 in more detail.

The waveguide assembly 220 joins the receiving dielectric waveguide 200 and the transmitting dielectric waveguide 210 by a predetermined distance so that no coupling occurs between them.

For example, the receiving dielectric waveguide 200 is bonded to one end of the waveguide assembly, and the transmitting dielectric waveguide 210 is bonded to the other end of the waveguide assembly so that the two waveguides are spaced apart by a predetermined distance. Is electrically shielded.

In order to prevent mutual interference between the reception frequency waveguided in the reception dielectric waveguide and the transmission frequency waveguided in the transmission dielectric waveguide and to perform impedance matching, conductor windows are formed on both sides of the waveguide assembly 220. (Iii) It is preferable to use an inductive iris as the conductor window.

Meanwhile, the connection port of the waveguide assembly and the waveguide, that is, the first connection port of the waveguide assembly and the receiving dielectric waveguide, and the second connection port of the waveguide assembly and the transmitting dielectric waveguide operate as a stub to transmit This function reflects either frequency during waveguide of frequency and reception frequency.

The waveguide assembly is composed of an NRD filter (D10) and NRD filters (D9, D11) bonded to respective ends of both sides thereof. Table 3 shows the width and length of the NRD filter used when duplexing the transmission frequency of the 24 GHz band and the receiving frequency of the 26 GHz band.

Product Name Length width D9 0.9 2.1 D10 2.1 6.1 D11 0.9 2.1

Next, FIG. 6 is a diagram illustrating frequency characteristics of a receiving dielectric waveguide.

Looking at the frequency characteristics shown in the above 6, the gain in the reception band is -1.85dB and -2.26dB at 26.3GHz ~ 26.7GHz, the attenuation is -61.76dB and -57.97dB at 24.59GHz ~ 24.75GHz The results show that it is possible to duplex receive frequencies in the millimeter wave band, such as 26 GHz in the receive band.

In addition, Figure 7 is a diagram showing the frequency characteristics of the transmission dielectric waveguide, as shown in Figure 7, the gain in the transmission band is -2.88dB and -2.75dB at 24.59GHz to 24.75GHz, attenuation is 26.3 From GHz to 26.7 GHz, it came out at -64.40 dB and -67.17 dB, which shows that it is possible to duplex the transmit frequency in the millimeter wave band, such as 24 GHz in the transmit band.

As described in detail above, the millimeter wave duplexer according to the present invention has a simple structure, and a plurality of NRD filters having different sizes exhibiting specific frequency blocking characteristics are arranged in different numbers at each of the transmitting end and the receiving end, and arranged at the transmitting end and the receiving end. T-junction waveguides with conductor windows are placed between them for impedance matching between the NRD filters, so that the frequency of the millimeter wave band can be duplexed. In addition, there is a relatively low cost, can be manufactured in a small size, and there is an effect that can be mass-produced.

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.

Claims (5)

A transmission dielectric waveguide and a reception dielectric waveguide, the plurality of non-radial dielectric (NRD) filters arranged differently according to a frequency to be waveguided to have different lengths; A waveguide assembly, wherein the transmitting dielectric waveguide and the receiving dielectric waveguide are spaced apart and electrically shielded from each other so that no coupling occurs between them; And a millimeter wave duplexer formed of conductor windows formed on both sides of the waveguide assembly for impedance matching of the transmitting dielectric waveguide and the receiving dielectric waveguide. The method of claim 1, wherein the conductor window; A millimeter wave duplexer characterized by being an inductive iris. 2. The method of claim 1, wherein the transmitting dielectric waveguide and the receiving dielectric waveguide comprise: A millimeter wave duplexer, characterized in that each bonded to both ends of the waveguide assembly. 4. The waveguide assembly of claim 1 or 3, wherein the waveguide conjugate; A millimeter wave duplexer, characterized in that it is a T-juntion dielectric waveguide. 4. The waveguide assembly of claim 1 or 3, wherein the waveguide conjugate; A first NRD filter formed long in the center; A millimeter wave duplexer, characterized in that the second NRD filter having a length shorter than the first NRD filter on each side of the first NRD filter.