KR0146759B1 - Flat type power distributor - Google Patents

Abstract

According to the present invention, even after being implemented as a single device, by designating input terminals differently, planar power using a transmission line that can be applied to various elements such as two 2-way power divider, 3-way power divider, power attenuator, and output coupler In order to achieve the above object, the present invention provides a first to tenth transmission line (TL-1 to TL-10) and the first to tenth transmission line forming two loops. And the eleventh through sixteenth transmission lines ITL-1 through ITL-6 connected between the connection points of the TL-1 through TL-10 and the input / output terminals.

Accordingly, the present invention can be used as a power divider that was originally intended, as well as a multi-function device that can be used as a variety of test measurement devices such as power attenuators, output couplers, etc. by specifying input terminals differently. In view of the fact that (ultra) high frequency circuits or system components are generally expensive, the present invention is very economically effective.

Description

Planar power divider

1 is a block diagram of a planar three-way power divider according to an embodiment of the present invention.

2 is a graph showing the electrical characteristics of the three-way power divider according to the present invention,

(a) is a graph of matching (or input / output return loss) characteristics at each input / output terminal.

(b) is a graph of input / output insertion loss (or conversion loss) characteristics.

(c) is a graph of isolation (or isolation) characteristics between terminals.

* Explanation of symbols for main parts of the drawings

TL-1 to TL-10: Transmission line

ITL-1 to ITL-6: I / O Transmission Line

R-1 to R-6: Terminating resistor (50Ω)

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to power dividers applied to (ultra) high frequency circuits or systems that require two or three output powers using a single input power. In particular, different input terminals provide different output terminals as well as output power ratios. The present invention relates to a planar power divider that can be variously applied to a power attenuator, an output coupler, and the like.

The power divider is a very important element in the application of ultra-high frequency circuits and systems. E.J. Wilkinson published the IRE Trans. Microwave Theory Tech., Vol. Since the first N-way power divider in the MTT-8, there have been numerous variants of the Wilkinson N-way power divider, including power dividers, 90 ° hybrid branch line power dividers, circular hybrid power dividers, and range combiners. A study of power dividers has been published. And the basic structure of the 2-way power divider known so far is configured in the form of having three or four terminals.

However, in the conventional (ultra) high frequency circuits or systems as described above, a divider having a power distribution function is manufactured once for any purpose. There was a problem to implement.

Accordingly, an object of the present invention devised to solve the above problems is to designate two input terminals differently even after being manufactured and implemented as a single device, such as two 2-way power dividers, 3-way power dividers, power attenuators, and output couplers. The present invention provides a planar power divider that can be applied to various devices.

In order to achieve the above object, the present invention, the first to sixth transmission line connected to each other in series to form a loop, the connection point of the fourth transmission line and the fifth transmission line, the sixth transmission line and the first transmission line The seventh to tenth transmission lines connected to each other in series and connected to each other in series to form a loop including the fifth and sixth transmission lines, among the connection points of the first transmission line and the second transmission line, and among the input, output, and termination terminals. An eleventh transmission line connected between terminals (hereinafter, referred to as terminals) used as any terminal, a twelfth transmission line connected between a connection point of the second transmission line and the third transmission line and a terminal, and the third transmission line A thirteenth transmission line connected between the connection point of the furnace and the fourth transmission line and the terminal, a fourteenth transmission line connected between the connection point and the terminal of the ninth transmission line and the tenth transmission line, and the eighth transmission line and the ninth transmission line. Transmission line And a transmission line 15 to the second connection point is connected between the terminal and a second transmission line 16 is connected between the connection point and the terminal in the eighth transmission line to the seventh transmission line.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

1 is an overall configuration diagram of a planar three-way power divider according to an embodiment of the present invention.

As shown in the figure, the structure according to the present invention does not need an internal resistance separately, and is very easy to implement since it is a completely planar structure. In addition, the structure according to the present invention theoretically has perfect matching performance (or input / output return loss performance) and separation performance (or isolation performance) between terminals.

The input terminals that can be used for application of the power divider according to the present invention shown in the drawings as a 3-way power divider are ①, ③, ④ and ⑥. If the input terminal is ①, the output terminals are ②, ⑥, ④. If the input terminal is ③, the output terminals are ⑥, ④, ②. If the input terminal is ④, the output terminals are ①, ③, ⑤. If the input terminal is ⑥, the output terminals are ⑤, ①, ③. However, the drawing shows a structure showing the terminal is set when (1) is arbitrarily set as the input terminal.

In the figure, [ITL-1] to [ITL-6] represent transmission lines of each input / output terminal having a characteristic impedance Zo of 50 ohms and an electrical length Eo of 90 °. Here, the electrical length of the transmission line does not necessarily have to be 90 °, and may be arbitrarily selected. In this case, only the phase difference of the input / output is changed, but the main performance (input / output reflection loss, insertion loss, separation between terminals, etc.) does not change. . In addition, the resistances of [R-1] to [R-6] in Fig. 1 refer to equivalent characteristic impedances observed at the input / output terminal nodes ① to ⑥.

The electrical lengths of [TL-1] to [TL-10], all transmission lines surrounding loop 1 and loop 2, are all 90 °. The characteristic impedance of [TL-1] to [TL-8] is determined by the output ratio between each output terminal, and the characteristic impedance of [TL-9] to [TL-10] has a very small influence only on the bandwidth. Since it does not significantly affect the input / output electrical characteristics of the power divider, it can be set to an arbitrary value. In the present invention, it is set to a value such as Zo.

Assuming that the invented structure operates as a 3-way power divider and the power ratio at each output terminal is M: N: K, the characteristic impedance of the transmission lines around loop 1 and loop 2 is as follows.

Here, Zo is the characteristic impedance of the transmission line shown by transmission line [ITL-1]-[ITL-6]. For example, when the power ratio at each output stage is equal to 1: 1: 1, that is, when the input power is divided by (1/3), the characteristic impedance of each transmission line is M = N = K = 1, so Z1 = Z3 = 1.22Zo, Z2 = Z4 = 1.73Zo, Z5 = Z6 = Z7 = Z8 = 1.41Zo, Z9 = Z10 = Zo, if you want to design with 3: 2: 1 power divider, M = 3, N = 2, K = 1, so Z1 = Z2 = Z3 = Z4 =

1.41 Zo, Z5 = Z7 = 1.22 Zo, Z6 = Z8 = 1.73 Zo, Z9 = Z10 = Zo. All electrical performances of the theoretical 3-way power divider with a power ratio of 1: 1: 1 at each output stage are shown in FIG.

(A) of FIG. 2 shows matching (or I / O return loss) characteristics at each input / output terminal, (b) shows input / output insertion loss (or conversion loss) characteristics, and (c) shows isolation (or Separation characteristics).

The inventive power divider can be used not only as a 3-way power divider with an M: N: K output power ratio, but also as a two-way power divider with an M: N output power ratio operating simultaneously. It can also be used as one 2-way power divider.

In detail, that is, in order to utilize the two-way power divider that operates simultaneously using the invented power divider, the input terminal of one 2-way power divider is set to ②, and the output terminals are ① and ③. Set to. At the same time, the input terminal of the other 2-way power divider is set to ⑤, and the output terminals are set to ④ and ⑥.

In addition, in order to utilize one 2-way power divider, input terminals are set to ②, output terminals are set to ① and ③, and the remaining terminals ④, ⑤ and ⑥ are terminated by terminating resistor (50Ω). And another method of utilizing the present invention as one 2-way power divider is to set the input terminal to ⑤, the output terminal to ④, ⑥, the remaining terminals ①, ②, ③ is a terminating resistor (50Ω) Terminate.

At this time, the characteristic impedance of each transmission line is determined when the required output power ratio of the 2-way power divider is set.

Thus, the present invention configured as described above, while the existing 2-way power dividers are a single structure-single function element, the power divider according to the present invention can be used as the power divider originally intended as well as the input terminal. Given the fact that (high-frequency) circuits or system components are generally expensive, they can be specified as multi-function devices that can also be used as various test measurement devices such as power attenuators, output couplers, etc. The present invention is very economical.

Claims (10)

The first to sixth transmission lines TL-1 to TL-4, TL-9, and TL-10 connected in series to each other to form a loop, and the fourth transmission line TL-4 and the fifth transmission line ( The connection points of the TL-10 and the connection points of the sixth transmission line TL-9 and the first transmission line TL-1 are connected to each other in series to connect the fifth and sixth transmission lines TL-9 and TL-10. Connection points, inputs, and outputs of the seventh through tenth transmission lines TL-5 through TL-8, the first transmission line TL-1, and the second transmission line TL-2, including a loop; And an eleventh transmission line ITL-1 connected between a terminal (hereinafter, referred to as a terminal) used as any one terminal terminal, and the second transmission line TL-2 and the third transmission line TL-. A twelfth transmission line ITL-2 connected between the connection point and the terminal of 3) and a thirteenth transmission line connected between the connection point and the terminal of the third transmission line TL-3 and the fourth transmission line TL-4; Connection point between the furnace ITL-3, the ninth transmission line TL-7 and the tenth transmission line TL-8. Fourteenth transmission line ITL-4 connected between the terminals, and a fifteenth transmission line ITL-5 connected between the terminal and the connection point of the eighth transmission line TL-6 and the ninth transmission line TL-7. And a sixteenth transmission line (ITL-6) connected between a connection point and a terminal of the seventh transmission line (TL-5) and the eighth transmission line (TL-6). The terminal of claim 1, wherein the terminal to which the eleventh transmission line ITL-1 is connected is set as an input terminal, and the twelfth, sixteenth, and fourteenth transmission lines ITL-2, ITL-6, and ITL-4. Planar power divider, characterized in that configured as a 3-way power divider by setting the terminal connected to the output terminal. The terminal of claim 1, wherein the terminal to which the thirteenth transmission line ITL-3 is connected is set as an input terminal, and the sixteenth, fourteenth, and twelfth transmission lines ITL-6, ITL-4, and ITL-2. Planar power divider, characterized in that configured as a 3-way power divider by setting the terminal connected to the output terminal. The terminal of claim 1, wherein the terminal to which the fourteenth transmission line ITL-4 is connected is set as an input terminal, and the eleventh, thirteenth, and fifteenth transmission lines ITL-1, ITL-3, and ITL-5 are used. Planar power divider, characterized in that configured as a 3-way power divider by setting the terminal connected to the output terminal. The terminal of claim 1, wherein the terminal to which the sixteenth transmission line ITL-6 is connected is set as an input terminal, and the fifteenth, eleventh, and thirteenth transmission lines ITL-5, ITL-1, and ITL-3. Planar power divider, characterized in that configured as a 3-way power divider by setting the terminal connected to the output terminal. The method according to any one of claims 2 to 5, wherein the eleventh to sixteenth transmission lines ITL-1 to ITL-6 each have a characteristic impedance Zo of 50 ohms and an electrical length Eo of 90 °. Planar power divider, characterized in that configured to be. The method of claim 6, wherein the first to fourth transmission lines TL-1 to TL-4 and the seventh to tenth transmission lines TL-5 to TL-8 are configured such that their electrical lengths are 90 degrees. Planar power divider, characterized in that. The terminal of claim 1, wherein the terminal to which the twelfth transmission line ITL-2 is connected is set as an input terminal, and the terminals to which the eleventh and thirteenth transmission lines ITL-1 and ITL-3 are connected are output terminals. Set to 1 to configure a two-way power divider, the terminal connected to the 15th transmission line (ITL-5) is set as an input terminal, the 14th, 16th transmission line (ITL-4, ITL-6) ) Is configured as an output terminal to the terminal connected to the other two-way power divider to configure a two-way power divider comprising two two-way power splitter operating simultaneously. The terminal of claim 1, wherein the terminal to which the twelfth transmission line ITL-2 is connected is set as an input terminal, and the terminals to which the eleventh and thirteenth transmission lines ITL-1 and ITL-3 are connected are output terminals. And the fourteenth, fifteenth, and sixteenth transmission lines (ITL-4, ITL-5, and ITL-6) are terminated by terminating elements. The terminal of claim 1, wherein the terminal to which the fifteenth transmission line ITL-5 is connected is set as an input terminal, and the terminals to which the fourteenth and sixteenth transmission lines ITL-4 and ITL-6 are connected are output terminals. And the eleventh, twelfth, and thirteenth transmission lines (ITL-1, ITL-2, and ITL-3) are terminated by terminating elements.