KR101070035B1 - 1:3 Ultra wideband power divider/combiner - Google Patents

Abstract

The present invention relates to an ultra-wideband power divider / combiner, and more particularly, to capacitively couple two T-shaped transmission line portions having a transmission line of λ / 4 length to each other, and to a bandwidth and attenuation in each transmission line of the transmission line portion. The present invention relates to an ultra-wideband power divider / combiner that distributes the magnitude of an output signal or combines an input signal by using a λ / 2-length short circuit that is capacitively coupled to a transmission line to adjust a pole.

The ultra-wideband power divider according to the present invention adjusts the magnitude of the capacitive coupling between the transmission line and the short-circuit line to accurately set the bandwidth of the input / output signal to the desired ultra-wideband. In addition, the ultra-wideband power divider according to the present invention is a capacitive coupling of the T-shaped transmission line unit by capacitively coupling the transmission line and the short-circuit line of each T-shaped transmission line unit while capacitively combining two T-shaped transmission line unit. By controlling the size of the transmission line of each T-shaped transmission line or the size of the capacitive coupling of the short-circuit line differently, the size of the output signal can be varied uniformly or differentially.

Ultra Wideband, Power Distribution, Power Coupling, Wilkinson Power Divider, Narrowband, Capacitive Coupling, T Transmission Lines

Description

1: 3 Ultra wideband power divider / combiner}

The present invention relates to an ultra-wideband power divider / combiner, and more particularly, to capacitively couple two T-shaped transmission line portions having a transmission line of λ / 4 length to each other, and to a bandwidth and attenuation in each transmission line of the transmission line portion. It relates to an ultra-wideband power divider / combiner that distributes the magnitude of the output signal or couples the input signal by using a λ / 2-length short circuit capacitively coupled to each transmission line so as to control the pole.

One of the various passive components used in wireless, radar, and broadcast communications is a power divider / combiner. A power divider / combiner is a circuit that divides one input signal into two or more output signals or combines two or more input signals into one output signal to output. That is, the power divider / combiner distributes a high frequency signal to two or more power amplifiers or other high frequency circuits at a constant rate or combines two or more high frequency signals to provide them to a power amplifier or other high frequency circuit.

1 illustrates a 1: 2 Wilkinson power divider as an example of a narrow band power divider widely used in the conventional high frequency communication field. Referring to FIG. 1, the power divider 10 includes one input terminal 11 and two output terminals 13 and 15. Then, for impedance matching between the input terminal 11 and the first output terminal 13 and between the input terminal 11 and the second output terminal 15, the input terminal 11 and the first output terminal 13. First and second impedance matching circuits 12 and 14 are connected between and between the input terminal 11 and the second output terminal 15, respectively. Then, the high frequency signal applied to the input terminal 11 is branched into two output terminals 13 and 15, and conversely, the high frequency signals applied to the two output terminals 13 and 15 are synthesized into one high frequency signal. And is output through the input terminal (11). Here, Z _in , Z _O2 , Z _O3 , Z _a and Z _b are the input terminal 11, the first output terminal 13, the second output terminal 15, the first impedance matching circuit 12, and The impedance of the second impedance matching circuit 14 is shown.

Recently, ultra wideband (UWB) communication technology has emerged as a wireless communication technology that realizes high speed communication with low power over a very wide band compared to the existing spectrum. Ultra-wideband communication technology transmits and receives data using a wide frequency band of several GHz. The maximum data transmission speed is 100Mbps per second, and the circuit consumes only several tens of mW. Compared to telecommunications, power consumption is as low as 1/10 to 1/100.

Ultra-wideband communication has been used for military purposes since its inception, but in February 2002, the Federal Communications Commission of the United States approved the use of commercial applications, laying the groundwork for a variety of applications. Examples of radar applications include aircraft collision avoidance devices, vehicle collision avoidance devices, explosives detection, underground exploration radars, wall penetration radars, high-precision location tracking, access security systems, and loss prevention systems. The field of application is being developed as a series of communication services related to electronic devices in personal spaces.

In each country, the occupied bandwidths of the center frequencies used in ultra-wideband communications are different from each other. The Federal Communications Commission (FCC) calls Ultra WideBand communications "over 25% of the center frequency. Wireless transmission technology that has bandwidth or occupies over 500MHz of bandwidth. In the United States, short-range wireless communication technology that realizes high speed communication at speeds of 100 Mbps or more in the 3.1 GHz to 10.6 GHz band is generally defined as ultra wide band communication.

Ultra-wideband communication technology has the advantage of transmitting and receiving large-capacity contents wirelessly by using low output and ultra-wideband frequency, so it is applied to wireless USB, wireless 1394, etc. that eliminates cable lines such as real-time streaming of HD video and high-capacity file transfer. This is possible and is expected to be applied to various fields such as next generation wireless home networking.

In order to implement an ultra-wideband power divider / combiner that can be used for such ultra-wideband communication, a multi-stage Wilkinson power divider / combiner having a plurality of Wilkinson power dividers / combiners described above is used.

In ultra-wideband communication, which is expected to be widely used in various fields in the future, in order to distribute one ultra-wideband input signal into two or more ultra-wideband output signals or combine two or more ultra-wideband input signals into one ultra-wideband output signal, There is a problem in that a narrow band distributor or combiner cannot be used as it is. In other words, the multi-stage Wilkinson power divider / combiner is composed of a plurality of Wilkinson power dividers / combiners described above, and one Wilkinson power divider / combiner is implemented as a transmission line having a length of about 1/4 of the center frequency wavelength. Since the conventional Wilkinson power divider / combiner is arranged, the size of the power divider is increased and the manufacturing cost is increased. Moreover, there is a limitation in the ultra-wideband range that can be set by the multi-stage Wilkinson power divider / combiner, and it is difficult to accurately set the bandwidth of the frequency to be used as a broadband.

It is therefore an object of the present invention to provide a 1: 3 ultra wideband power divider / combiner that can be used in ultra wideband communication.

Another object of the present invention is to provide a 1: 3 bandwidth that can be accurately set in ultra-wideband by using a short-circuit line that capacitively couples two T-shaped transmission line portions to each other and at the same time capacitively couples the transmission lines of the transmission line portion. To provide an ultra-wideband power divider / combiner.

It is still another object of the present invention to provide a 1: 3 ultra-wideband power divider / combiner capable of simply setting the bandwidth of an input / output signal to an ultra-wideband using only a short-line which forms capacitive coupling with a transmission line. will be.

In order to achieve the object of the present invention, a 1: 3 ultra-wideband power divider according to an embodiment of the present invention is a first transmission line unit having three transmission lines, and a second transmission line having three transmission lines. And two transmission lines of the transmission lines of the first short circuit line section and the second transmission line section, each having two short circuit lines capacitively coupled to two transmission lines of the transmission lines of the first transmission line section. A second short circuit section having two short circuit lines each having a capacitive coupling, wherein a transmission line and a second transmission which are not capacitively coupled with the short circuit of the first short circuit section among the transmission lines of the first transmission line section Among the transmission lines of the line portion, the transmission lines that do not combine the short circuit with the short circuit of the second short circuit portion are characterized in that they are capacitively coupled to each other.

Preferably, a signal is input to a first short-circuit line forming a capacitive coupling with the transmission line of the first transmission line unit, and the input signal is output to a transmission line making a capacitive coupling with the remaining short-circuits except for the first short-circuit line. It is characterized by.

Each short-circuit line of the first short circuit line part and the second short-circuit line part is disposed at an upper portion or a lower part of the short-circuit line part in parallel with each transmission line based on the transmission line of the first transmission line part and the second transmission line part, thereby capacitively coupling the transmission line. To achieve.

Here, the size of the capacitive coupling between the short-circuit line and the transmission line is controlled by the area of the short-circuit line spaced apart in parallel with the transmission line, or is controlled by the separation distance between the transmission line and the short-circuit line.

The ultra-wideband power divider according to the present invention has various effects as follows as compared to the conventional power divider.

First, the ultra-wideband power divider according to the present invention can accurately set the bandwidth of the input / output signal to the desired ultra-wideband by adjusting the size of the capacitive coupling between the transmission line and the short-circuit line.

Secondly, the ultra-wideband power divider according to the present invention combines two T-shaped transmission line portions capacitively with each other and at the same time capacitively couples the transmission line and the short-circuit line of each T-shaped transmission line portion, By varying the size of the coupling or the size of the capacitive coupling of the transmission line and the shorting line of each T-shaped transmission line portion, it is possible to vary the size of the output signal evenly or differentially.

Third, the ultra-wideband power divider according to the present invention is composed of only a short-circuit line forming a capacitive coupling with the transmission line can be miniaturized and can be manufactured inexpensively.

Fourth, the ultra-wideband power divider according to the present invention can simply adjust the bandwidth by controlling the bandwidth of the input / output signal by adjusting the size of the capacitive coupling between the transmission line and the short-circuit line.

Hereinafter, an ultra-wideband power divider according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing a 1: 3 ultra-wideband power divider / combiner composed of two T-shaped transmission line portions and a shorting line portion capacitively coupled with the transmission lines of each T-shaped transmission line portion, according to an embodiment of the present invention. 3 is a perspective view illustrating in more detail an example of two T-shaped transmission line units according to the present invention.

Referring to FIGS. 2 and 3, the transmission lines and the capacities of the two transmission line parts 110 and 120 and the transmission line parts 110 and 120 are respectively provided on one side and the other side of the opposing inner side of the housing 20. Four short circuit lines 210, 220, 230, and 240 are formed to form a coupling. In the first transmission line unit 110 disposed on one surface of the inner surface of the housing 20, three transmission lines extend at a predetermined distance from the center point O, and the first transmission line unit 110. ) And three transmission lines of the second transmission line part 120 arranged parallel to each other at predetermined intervals also extend at a predetermined separation angle with respect to the center point O '. The three transmission lines constituting the first transmission line unit 110 and the three transmission lines constituting the second transmission line unit 120 are extended to the same length, and preferably the center frequency wavelength λ of the band used. Are equally extended to one quarter of the length.

The first transmission line unit 110 has a left transmission line 113 and a center transmission line 111 spaced apart at a first separation angle in a counterclockwise direction with respect to the center transmission line 111 and the center transmission line 111. The right transmission line 115 is spaced apart at a first separation angle in the clockwise direction. On the other hand, the second transmission line unit 120 is the center transmission line 121, the left transmission line 123 and the center transmission line spaced apart at a second separation angle in the counterclockwise direction relative to the central transmission line 121, the central transmission line 121. The right transmission line 125 is spaced apart at a second separation angle in the clockwise direction with respect to the reference numeral 121. The first transmission line unit 110 and the second transmission line unit 120 are arranged in parallel at predetermined intervals, and the central transmission line 111 and the second transmission line unit 120 of the first transmission line unit 110. The central transmission line 121 of) is spaced apart in parallel to each other on the same vertical line or in parallel so that only a part of the central transmission line 111 and the central transmission line 121 overlap each other on different vertical lines. Spaced apart. Hereinafter, the central transmission line 111 of the first transmission line unit 110 and the central transmission line 121 of the second transmission line unit 120 are referred to as a combined transmission line.

The right transmission line 115 of the first transmission line unit 110 may be disposed at a different distance from the left transmission line 113, and the left transmission line 123 of the second transmission line unit 120 may be right. The transmission line 125 may be disposed at different separation angles. On the other hand, the first separation angle and the second separation angle may be the same, more preferably the first separation angle and the second separation angle is 90 degrees, that is, characterized in that the T-shape.

The first short circuit line part and the second transmission part which form a capacitive coupling with the left transmission line 113 and the right transmission line 115 of the first transmission line part 110 on the other surface facing the inner side surface of the housing 20. The second short-circuit line part which forms capacitive coupling with the left transmission line 123 and the right transmission line 125 of the line part 120 is arrange | positioned. The first short circuit line section and the first transmission line section 110 and the first short circuit line 110 are arranged in parallel in a line at a predetermined interval to form a capacitive coupling with the left transmission line 113 of the first transmission line section 110. It consists of a short-circuit line 220 is arranged in parallel in a line at a predetermined interval to form a capacitive coupling with the right transmission line 115 of the (). On the other hand, the second short circuit line portion and the second short circuit line 230 and the second transmission line portion arranged in parallel in a row at a predetermined interval so as to form a capacitive coupling with the left transmission line 123 of the second transmission line portion 120. It consists of a short-circuit line 240 arranged in parallel in a predetermined spaced interval to form a capacitive coupling with the right transmission line 125 of the (120).

Each short-circuit line 210, 220, 230, 240 is spaced apart in parallel with each transmission line 113, 115, 123, 125 on top of each transmission line 113, 115, 123, 125 for capacitive coupling. Instead, the lower portion of the transmission line 113, 115, 123, 125 may be spaced apart in parallel with the transmission line (113, 115, 123, 125). In addition, the short circuit lines 210, 220, 230, and 240 may have different shapes under the condition that the first parallel line forms a capacitive coupling with the transmission line in addition to the "c" shape according to the field to which the present invention is applied. Therefore, the configuration of the power splitter / combiner illustrated in FIGS. 2 and 3 is an example for describing the present invention, and may be variously modified and used in the scope of the present invention according to the field to which the present invention is applied. , Which belongs to the scope of the present invention.

Short-circuit connecting holes (via, 610) penetrating the inner surface of the inner surface of the housing 20 and electrically connected to one side of each of the short-circuit lines 210, 220, 230, and 240 are formed. The connection hole 610 is electrically connected to a short circuit terminal (not shown) formed on the outer surface of the housing 20. In addition, an input connection hole via 620 is formed on the other surface of the inner surface of the housing 20 and penetrates the other side surface of the housing 20 and is electrically connected to one side of the short circuit line 210. In addition, the output connection hole via which penetrates the other surface of the inner surface of the housing 20 and is electrically connected to one side of the transmission lines 115, 123, 125 except for the first transmission line 113. 630 is formed. The input connection hole 620 is electrically connected to an input terminal 300 formed on an outer surface of the housing 20, to which a signal is input, and the output connection hole 630 evenly distributes the input signal. The output terminal is electrically connected to an output terminal 400 formed on the outer surface of the housing 20.

Looking at the operation example of the ultra-wideband power divider according to the present invention having the configuration described above, the signal input through the input terminal 300 is input to the input short-circuit line 210 through the input connection hole 620. The length of the left transmission line 113 of the first transmission line portion 110, which is capacitively coupled with the short circuit line 210, is λ / 4, and the capacitiveness between the short circuit 210 and the left transmission line 113 is increased. By adjusting the size of the coupling, the bandwidth of the input signal flowing to the left transmission line 113 can be controlled based on the center frequency of the frequency band used. By inputting the input signal through the short-circuit line 210 instead of directly inputting it to the left transmission line 113, an effect of effectively filtering out an unwanted rejection band signal occurs.

On the other hand, the remaining transmission lines 115, 123, 125 except for the left transmission line 113 of the first transmission line unit 110 distributes the input signal evenly, the length is λ / 4 and each transmission line ( Capacitive coupling is formed with short-circuit lines 220, 230, and 240 that are spaced apart in parallel on top of the 115, 123, and 125. Since the remaining transmission lines 115, 123, and 125 serve as output transmission lines that evenly output the actual input signal, the remaining transmission lines are referred to as output transmission lines hereinafter. Bandwidth of the signal distributed and output to the output transmission line 115, 123, 125 by adjusting the size of the capacitive coupling of each output transmission line 115, 123, 125 and each short circuit line 220, 230, 240. It can be controlled based on the center frequency of the frequency band using. The signal output to the output transmission lines 115, 123, and 125 is output to the output terminal 400 through the output connection hole 630.

4 is a perspective view illustrating in detail the arrangement state of the left transmission line 113 and the short-circuit line 210 to which a signal is input, and FIG. 5 shows the output transmission lines 115, 123, and 125 to which a signal is output. It is a perspective view which shows the arrangement state of the short circuit line 220, 230, 240 more concretely.

Looking at the arrangement of the left transmission line 113 and the input short-circuit line 210 in detail with reference to Figure 4, the input short-circuit line 210 of the "c" shape is transmitted to the left side of the upper left transmission line 113 Spaced apart parallel to the track 113. The input short-circuit line 210 is a first parallel line 211 forming a capacitive coupling with the left transmission line 113 and a right angle line perpendicular to the first parallel line 211 on the same plane as the first parallel line 211. 213 and a second parallel line 215 perpendicular to the right angle line 213 and spaced apart in parallel with the first parallel line 211 on the same plane as the first parallel line 211. An input connection hole 620 for electrically connecting the first parallel line 211 and the input terminal is formed at a portion where the first parallel line 211 ends on the right angle line 213. In addition, a short-circuit connecting hole 611 for electrically connecting the second parallel line 215 and the short-circuit terminal is formed at a portion where the second parallel line 215 ends with respect to the right angle line 213.

Since the first parallel line 211 is disposed at the upper portion of the left transmission line 113 in parallel with the left transmission line 113 in a line in the vertical direction, the left transmission line 113 and the first parallel line 211. ) Between the left transmission line 113 and the first parallel line 211 according to the overlapping area or the separation distance d1 between the left transmission line 113 and the first parallel line 211. Capacitive coupling occurs. The bandwidth of the input signal flowing through the left transmission line 113 may be controlled according to the magnitude of the capacitive coupling generated between the left transmission line 113 and the first parallel line 211.

The arrangement of the output transmission line and the shorting line will be described in more detail with reference to FIG. 5. The arrangement state of the short-circuit line 220 capacitively coupled with the output transmission line 115 The arrangement state of the short-circuit line 230 capacitively coupled with the output transmission line 115, the output state of the output transmission line 125 and the capacitance Since the arrangement state of the short-circuit line 240 forming the sex coupling is the same, the arrangement of the output transmission line 115 and the short-circuit line 220 among the output transmission lines 115, 123, and 125 will be described below. A short-circuit line 220 having a "c" shape is spaced apart in parallel to the output transmission line 115 on the output transmission line 115. A first parallel line 221 capacitively coupled to the output transmission line 115, a right angle line 223 perpendicular to the first parallel line 221 on the same plane as the first parallel line 221, and a right angle line ( It consists of a second parallel line 225 perpendicular to the 223 and spaced apart in parallel to the first parallel line 221 on the same plane as the first parallel line 221. At the end where the output transmission line 115 extends with respect to the center point, an output connection hole 630 for electrically connecting the output transmission line 115 and the output terminal is formed and based on the right angle line 223. As a result, at the portion where the second parallel line 225 ends, a shorting connection hole 612 is formed to electrically connect the second parallel line 225 and the short circuit terminal. Since the first parallel line 221 is spaced apart in parallel with the output transmission line 115 in a line in the vertical direction above the output transmission line 115, the output transmission line 115 and the first parallel line 221. ) Between the output transmission line 115 and the first parallel line 221 according to the overlapping area or the separation distance d2 between the output transmission line 115 and the first parallel line 221. Capacitive coupling occurs. The bandwidth of the signal output from the output transmission line 115 may be controlled according to the magnitude of the capacitive coupling generated between the output transmission line 115 and the first parallel line 221.

6 is a view for explaining an example of controlling the size of the capacitive coupling between the central transmission line of the first transmission line portion and the central transmission line of the second transmission line portion.

Referring to FIG. 6, the central transmission line 121 of the second transmission line unit 120 is spaced apart in parallel in a vertical direction on an upper portion of the central transmission line 111 of the first transmission line unit 110. It is. The width length of the center transmission line 111 and the width length of the center transmission line 121 are equal to each other, and the width direction center of the center transmission line 111 and the width direction center of the center transmission line 121 are on the same vertical line. It is located. That is, the central transmission line 111 and the central transmission line 121 are arranged in a line so as to overlap in parallel with each other. As shown in FIGS. 6 (a) and 6 (b), as the length of the central transmission line 121 overlapping in parallel with one surface of the central transmission line 111 increases from l1 to l2, the central transmission line 111 ) And the size of the capacitive coupling between the central transmission line 121 and the signal transmitted to the second transmission line portion as the size of the capacitive coupling between the central transmission line 111 and the central transmission line 121 increases. The bandwidth of is increased.

7 is a view for explaining another example of controlling the size of the capacitive coupling between the central transmission line of the first transmission line portion and the central transmission line of the second transmission line portion.

Referring to FIG. 7, the central transmission line 121 is spaced apart from the central transmission line 111 in parallel with the central transmission line 111 at a predetermined distance D1. Moreover, the width direction center of the center transmission line 111 and the width direction center of the center transmission line 121 are arrange | positioned so that it may be located on the same vertical line A. FIG. By moving the center transmission line 121 on the same vertical line (A) to reduce the separation distance between the central transmission line 111 and the central transmission line 121 from D1 to D2, the central transmission line 111 and the central transmission line The size of the capacitive coupling between 121 increases, and as the size of the capacitive coupling between the central transmission line 111 and the central transmission line 121 increases, the bandwidth of the signal transmitted to the second transmission line portion increases. .

On the other hand, the upper portion of the central transmission line 111 on the horizontal line (B) of the central transmission line 121 so that the vertical projection area of the central transmission line 111 and the central transmission line 121 only partially overlap or do not overlap each other. It is arrange | positioned at the horizontal separation distance D3 with respect to the same vertical line A. FIG. As the horizontal separation distance increases with respect to the same vertical line A, the size of the capacitive coupling between the central transmission line 111 and the central transmission line 121 is decreased, and the central transmission line 111 and the central transmission line are reduced. As the size of the capacitive coupling between the lines 121 decreases, the bandwidth of the signal transmitted to the second transmission line portion decreases.

6 and 7 to control the size of the capacitive coupling between the central transmission line 111 of the first transmission line unit 110 and the central transmission line 121 of the second transmission line unit 120 described above. May be used interchangeably. For example, the area of the central transmission line 121 overlapping with the central transmission line 111 may be increased or decreased, or the separation distance between the central transmission line 111 and the central transmission line 121 may be increased or decreased. Increase or decrease the horizontal separation distance of 121) to control the magnitude of the capacitive coupling between the central transmission line 111 and the central transmission line 121, thereby increasing or decreasing the bandwidth of the input signal transmitted to the second transmission line portion. I can regulate it.

8 is a view for explaining an example of controlling the size of the capacitive coupling between the left transmission line and the short-circuit line of the first transmission line unit.

Referring to FIG. 8, first parallel lines 211 of the short-circuit line 210 are spaced apart in parallel in a vertical direction on an upper portion of the left transmission line 113 of the first transmission line unit 110. . The width length of the left transmission line 113 and the width length of the first parallel line 211 are equal to each other, and the width direction center of the left transmission line 113 and the width direction center of the first parallel line 211 are the same vertical. Located on board. That is, the first parallel line 211 of the left transmission line 113 and the input short circuit line 210 are arranged in a line so as to overlap in parallel with each other. The area of one surface of the input short-circuit line 210 overlapping with one surface of the left transmission line 113 varies according to the length of the first parallel line 211. As the length of the first parallel line 211 is increased to L1, L2, and L3, respectively, the area of the input short circuit line 210 overlapping one surface of the left transmission line 113 increases. As the area of one side of the input shorting line 210 overlapping one side of the left transmission line 113 increases, the size of the capacitive coupling between the left transmission line 113 and the input shorting line 210 increases, and the left side As the magnitude of the capacitive coupling between the transmission line 113 and the input short circuit line 210 increases, the bandwidth of the input signal increases.

9 is a view for explaining another example of controlling the size of the capacitive coupling between the left transmission line and the input short-circuit line of the first transmission line unit.

Referring to FIG. 9, the first parallel line 211 of the input short circuit line 210 is spaced apart in parallel with the left transmission line 113 at a predetermined distance D4 on an upper portion of the left transmission line 113. have. Further, the widthwise center of the left transmission line 113 and the widthwise center of the first parallel line 211 are disposed on the same vertical line A '. As the left transmission line 113 is moved on the same vertical line A 'and the separation distance between the left transmission line 113 and the first parallel line 211 is reduced from D4 to D5, the input with the left transmission line 113 is performed. The magnitude of the capacitive coupling between the short circuit lines 210 increases, and as the magnitude of the capacitive coupling between the left transmission line 113 and the input short circuit lines 210 increases, the bandwidth of the input signal increases.

On the other hand, the horizontal line B 'of the first parallel line 211 so that the vertical projection area of the left transmission line 113 and the first parallel line 211 partially overlap or do not overlap each other on the upper portion of the left transmission line 113. Is spaced apart from each other at a horizontal separation distance D6 based on the same vertical line A '. As the horizontal separation distance increases with respect to the same vertical line A ', the magnitude of the capacitive coupling between the left transmission line 113 and the input short circuit line 210 decreases, and the left transmission line 113 and the input short circuit are reduced. As the size of the capacitive coupling between the lines 200 decreases, the bandwidth of the input signal decreases.

The method of controlling the size of the capacitive coupling between the left transmission line and the input short circuit described above with reference to FIGS. 8 and 9 may be used interchangeably. For example, increase or decrease the area of the input shorting line overlapping the left transmission line, increase or decrease the separation distance between the left transmission line and the input shorting line, increase or decrease the horizontal separation distance of the input shorting line, or combine the left transmission lines By controlling the magnitude of the capacitive coupling between the line and the input short circuit, the bandwidth of the input signal can be increased or decreased.

Meanwhile, the method of controlling the size of the capacitive coupling between the left transmission line and the input short circuit of the first transmission line unit described with reference to FIGS. 8 and 9 above is a capacitive connection between the output transmission line 115 and the short circuit 220. In the same way to control the size of the coupling, the size of the capacitive coupling between the output transmission line 123 and the shorting line 230, and the size of the capacitive coupling between the output transmission line 125 and the shorting line 240 Can be used.

The ultra-wideband power divider according to the present invention having the above configuration also operates as an ultra-wideband power combiner. When operating as an ultra-wideband power combiner, the output terminal 400 and the output connection hole 630 are input terminals and input connections, respectively. It operates alone, and the output transmission line operates as an input transmission line to which a signal is input. On the other hand, when operating as an ultra-wide band power combiner, the input terminal 300 and the input connection hole 620 operate as output terminals and output connection holes, respectively, and the input short-circuit line combines the input signal to the output terminal through the output connection hole. It acts as an output short-circuit line.

Looking at the operation example of the ultra-wideband power coupler according to the present invention, the signal input through the input terminal 400 is input to the input transmission line (115, 123, 125) through the input connection hole (630). The length of the input transmission line 115, 123, 125 is λ / 4, and the input transmission line 115, 123, 125 and the short-circuit line 220, 230, 240 each form a capacitive coupling, so that the input transmission line 115 By controlling the size of the capacitive coupling between the circuits 123 and 125 and the short circuits 220, 230, and 240, the bandwidth of the input signal flowing through the input transmission lines 115, 123, and 125 can be controlled to a desired bandwidth. .

Meanwhile, except for the input transmission lines 115, 123, and 125, the remaining transmission lines 113 combine the signals input to the input transmission lines 115, 123, and 125, and the length is λ / 4 and the transmission line 113. A capacitive coupling is formed with the output short-circuit line 210 which is spaced apart in parallel to the upper portion of the output short circuit 210. By adjusting the size of the capacitive coupling between the transmission line 113 and the output short circuit 210, the bandwidth of the combined signal output to the output short circuit 210 can be controlled to a desired bandwidth. The signal output to the output short circuit line 210 is output to the output terminal 300 through the output connection hole 620.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. For example, the shorting line may have various shapes under the condition of capacitive coupling with the transmission line in addition to the "c" shape, and the size of the capacitive coupling between the transmission line and the shorting line may overlap the transmission line with the shorting line. It can be adjusted by the area or the separation distance. In addition, the width lengths of the shorting line and the transmission line or the width lengths of the first transmission line portion and the second transmission line portion may be the same or different from each other. In addition, in a condition that each transmission line and a short circuit are capacitively coupled, the short circuits that form a capacitive coupling with the transmission line are all spaced apart in parallel or parallel to the transmission line above or below the transmission line. Spaced apart and the rest can be spaced parallel to the bottom. On the other hand, the transmission line can be increased or decreased in a predetermined error range according to the application field and the purpose of the present invention in a quarter length of the center frequency wavelength (λ) of the use band, the short circuit is the center frequency wavelength (λ) of the use band It can be used by increasing / decreasing it to a predetermined error range according to the field of use and the purpose of the present invention at 1/2 length).

Accordingly, the various embodiments of the present invention described above are only one reference in determining the scope of the present invention, and the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1 illustrates a 1: 2 Wilkinson power divider as an example of a narrow band power divider widely used in the conventional high frequency communication field.

2 is a perspective view showing a 1: 3 ultra-wideband power divider / combiner composed of two T-shaped transmission line portions and a shorting line portion capacitively coupled with the transmission lines of each T-shaped transmission line portion, according to an embodiment of the present invention. to be.

3 is a perspective view illustrating in more detail an example of two T-shaped transmission line units according to the present invention.

4 is a perspective view showing an arrangement state of a left transmission line and a shorting line to which a signal is input.

5 is a perspective view showing an arrangement of an output transmission line and a short circuit line through which signals are output.

6 is a view for explaining an example of controlling the size of the capacitive coupling between the central transmission line of the first transmission line portion and the central transmission line of the second transmission line portion.

7 is a view for explaining another example of controlling the size of the capacitive coupling between the central transmission line of the first transmission line portion and the central transmission line of the second transmission line portion.

8 is a view for explaining an example of controlling the size of the capacitive coupling between the left transmission line and the short-circuit line of the first transmission line unit.

9 is a view for explaining another example of controlling the size of the capacitive coupling between the left transmission line and the input short-circuit line of the first transmission line unit.

Description of the main parts of the drawing

20: housing

110: first transmission line portion 120: second transmission line portion

111, 113, 115: Transmission line 121, 123, 125: Transmission line

210, 220, 230, 240: short circuit

300: input terminal 400: output terminal

610: short circuit connection hole 620: input connection hole

630: output connection hole

Claims (10)

A first transmission line unit having three transmission lines; A second transmission line unit having three transmission lines; A first short circuit line section having two short circuit lines each capacitively coupled to two transmission lines among transmission lines of the first transmission line section; And A second shorting line part having two shorting lines each of which is capacitively coupled to two transmission lines among the transmission lines of the second transmission line part, A first coupling transmission line not capacitively coupled with the shorting line of the first shorting line part among the transmission lines of the first transmission line part, and a shorting line of the second shorting line part among the transmission lines of the second transmission line part; And the second coupled transmission line, which is not capacitively coupled, is capacitively coupled to each other. The method of claim 1, And a signal is input to a first short-circuit line forming a capacitive coupling with the transmission line of the first transmission line part. The method of claim 2, And the input signal is output to a transmission line that is capacitively coupled with the remaining short lines except for the first short line. 4. The short circuit line of claim 3, wherein each of the short circuit lines of the first short circuit line portion and the second short circuit line portion And a capacitive coupling with the transmission line, the upper transmission line being spaced apart from the transmission line in the upper part or the lower part of the second transmission line part in parallel with the transmission lines. 5. The method of claim 4 wherein the magnitude of the capacitive coupling between the shorting line and the transmission line is And an area of the short-circuit line spaced apart from and parallel to the transmission line. 5. The method of claim 4 wherein the magnitude of the capacitive coupling between the shorting line and the transmission line is And a controlled separation distance between the transmission line and the short circuit. The method according to claim 5 or 6, The first combined transmission line and the second combined transmission line are spaced apart in parallel to each other, and the magnitude of the capacitive coupling between the first combined transmission line and the second combined transmission line is equal to the first combined transmission line. And the second combined transmission line is spaced apart from each other and controlled by a size or a distance of an overlapping area. The method of claim 7, wherein And said transmission line has a quarter length of a center frequency wavelength [lambda] of a frequency band used. The method of claim 8, The short-circuit line has a length of 1/2 of the center frequency wavelength (λ) of the frequency band used. The method of claim 9, wherein the reference of the center frequency is An ultra-wideband power divider, characterized in that the center frequency of the frequency band used.

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