KR20040066523A - Reflection type phase shifter using complex reflection load - Google Patents

Abstract

PURPOSE: A reflection type phase shifter using a complex reflection rod is provided to improve an input/output reflection coefficient by inserting an inductor into the complex reflection rod. CONSTITUTION: A reflection type phase shifter using a complex reflection rod includes a complex reflection rod(100). The complex reflection rod includes a hybrid coupler(20) of 90 degrees, a first varactor diode(D1), a second varactor diode(D2), a first DC shielding capacitor(C1), and a second shielding capacitor(C2). The complex reflection rod further includes a first inductor(L1) and a second inductor(L2). The first inductor is connected in parallel between a front end of the first DC shielding capacitor and one port of the hybrid coupler of 90 degrees. The second inductor is connected in parallel between a front end of the second DC shielding capacitor and the other port of the hybrid coupler of 90 degrees and load impedance is operated as inductor under specified capacitance by inserting an inductor into the reflection rod of the shifter.

Description

Reflection type phase shifter using composite reflection rod {REFLECTION TYPE PHASE SHIFTER USING COMPLEX REFLECTION LOAD}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a phase shifter. Specifically, an inductor is inserted into a reflective rod portion of a reflection type phase shifter so that the impedance of the rod portion acts as an inductor when the impedance of the rod portion is below a specific capacitance. It relates to a reflection type phase shifter using a complex reflection rod to be obtained.

Beam steering has many applications. What matters is the application in the field of telecommunications. The geographic area serviced by wireless telecommunications is divided into many spatially distinct areas called " cells. &Quot; Typically, each cell has an irregular shape (even if it is idealized as a hexagon), depending on the topography. Typically, each cell includes a base station that includes a radio and an antenna, among other equipment, which uses the radio and antenna to communicate with a wireless terminal within that cell. In communication calls, it is desirable to adjust the geographic reach of a particular base station from time to time, due to instantaneous geographic changes. This can be accomplished by beam steering.

The free space distribution of the electromagnetic signal emitted by the base station is determined by the antenna radiation pattern. This antenna radiation pattern is typically characterized by one main lobe and several side lobes in azimuth and elevation planes. In most cases, it is desirable to have a very narrow main lobe, also referred to as an "antenna beam," in one or both angular dimensions. Narrow antenna beams are very directional and have the advantage of very high angular power density in the main lobe. The increase in power density of the main lobe by narrowing the beam width is also referred to as "antenna gain".

If the beamwidth of the antenna is very small, it is sensitive to proper physical adjustment. This is important because it is often necessary to change the angular position of the antenna beam ("beam steering") or to modify the antenna's overall radiation pattern ("beam steering", eg change in beam width, etc.) over time. Because of all this, remote beam steering / beam shaping capabilities are provided in the desired antenna panel.

The high gain antenna (ie narrow beam) consists of an array of radiating antenna elements implemented in a flat array. The plate also has a feed network that distributes radio frequencies to the radiating elements. The number of array elements in each physical dimension is the antenna gain in the corresponding angular dimension. The more elements and the larger their spacing, the greater the maximum gain that can be achieved. That is, the width of the beam becomes smaller. The final beam shape and position of this array can be adjusted by changing the relative signal amplitude and signal phase of all radiating elements. In most cases, however, it is only necessary to tune the phase of the signal at each radiating element. This signal phase adjustment can be accomplished by implementing a phase shifter in the signal line or feed grid to the radiating element.

Proper phase shifter design depends on the type and application of the particular antenna. Competitive markets in telecommunications require small, low-cost solutions. Since there is no costly sealed enclosure outdoors, high stability is required against changing weather conditions, temperature cycling, humidity and corrosion. Moreover, high power capability is required (up to 200W average per antenna panel). This also means high linearity over RF signal power. For passive devices the insertion loss should be very low.

There are many designs of known phase shifters. One type of phase shifter uses switchable delay lines of different lengths. The second type of line-stretcher, known as a phase shifter, uses a coaxial transmission line that can be telescoped. The third type of phase shifter uses solid state electronics such as varactor diodes.

The reflection type phase shifter 10 of the phase shifter using the varactor diode includes a 90 ° hybrid coupler 20 and a reflection rod 30 as shown in FIG. 1.

The 90 ° hybrid coupler 20 combines or separates the input signal with a phase difference of 90 ° and outputs the result.

The reflective rod 20 includes the first and second varactor diodes D1 and D2 and the first and second DC blocking capacitors C1 and C2. The first varactor diode (D1) has a cathode connected in parallel on a line connected from one port of the 90 ° hybrid coupler 20 to the other port, and the anode is connected to the ground to the reverse bias voltage value Vcc input. The capacitance changes accordingly, and the second varactor diode D2 has a reverse bias in which cathodes are connected in parallel on a line connected from one port of the 90 ° hybrid coupler 20 to another port, and the anode is grounded and input. The capacitance changes according to the voltage value Vcc. The first DC blocking capacitor C1 is connected between the connection node of the first varactor diode D1 and one port of the 90 ° hybrid coupler 20 so as to provide a DC bias voltage value Vcc of the first varactor diode D1. ) Is prevented from entering the RF path of the 90 ° hybrid coupler 20, and the second DC blocking capacitor C2 is connected to the connection node of the second varactor diode D2 and the other port of the 90 ° hybrid coupler 20. It is connected between the DC bias voltage value (Vcc) of the second varactor diode (D2) is prevented from flowing into the RF path of the 90 ° hybrid coupler (20). Here, the first and second DC blocking capacitors C1 and C2 are capacitors having a minimum impedance value at an operating frequency.

When the reflection type phase shifter 10 assumes that the first and second varactor diodes D1 and D2 and the 90 ° hybrid coupler 20 are ideal, the reflection coefficient is represented by Equation 1 below.

At this time, the reflection coefficients of the first and second varactor diodes D1 and D2 viewed from the 90 ° hybrid coupler 20 are The impedance of the first and second varactor diodes D1 and D2 is to be. Where Z _O is 50 Ω and C _V is f (V _DC ).

As shown in Equation 1, the reflection coefficient S11 of the phase shifter 10 is completely matched to "0", and S21 is as shown in Equation 2 below, so that only the phase of the first and second varactor diodes D1 is lost without loss. , D2) is changed by the phase of the reflection coefficient.

However, since the conventional reflection type phase shifter uses the capacitance change of the varactor diode, even if it is assumed that the capacitor alone is ideal, the phase change does not exceed 180 °, and the capacitance variation of the varactor diode is limited. In actual implementation, the variable phase range has a problem that is not much less than 180 degrees.

Accordingly, an object of the present invention is to solve the above problems, by inserting an inductor into the reflective rod portion of the reflection type phase shifter to operate as an inductor in the impedance of the load portion below a specific capacitance, the input and output reflection coefficient is excellent and variable The purpose of this is to obtain a phase section above 180 °.

1 is a block circuit diagram schematically showing a conventional reflection type phase shifter according to the related art

2 is a block circuit diagram schematically illustrating a reflection type phase shifter using a complex reflection rod according to an embodiment of the present invention;

3 is a block circuit diagram schematically illustrating a reflection type phase shifter using a complex reflection rod according to another embodiment of the present invention;

4 is a block circuit diagram schematically illustrating a reflection type phase shifter using a complex reflection rod according to another embodiment of the present invention;

<Description of the symbols for the main parts of the drawings>

20: 90 ° hybrid coupler 30, 100: reflection rod

C1, C2: first and second DC blocking capacitors D1, D2: first and second varactor diodes

L1 to L4: First to fourth inductors

Features of the present invention for achieving the above object,

A 90 ° hybrid coupler configured to output an input signal by combining or separating the signals with a phase difference of 90 °; A first varactor diode having a cathode connected in parallel on a line connected from one port to the other port of the 90 ° hybrid coupler, the anode being grounded to ground, and having a capacitance changed according to an input reverse bias voltage value; A second varactor diode having a cathode connected in parallel on a line connected from one port to another port of the hybrid coupler, the anode being grounded to the ground, and having a capacitance changed according to an input reverse bias voltage value, and the first bar A first DC blocking capacitor connected between the connection node of the racter diode and one port of the 90 ° hybrid coupler to prevent the DC bias voltage value of the first varactor diode from entering the RF path of the 90 ° hybrid coupler; Between the connection node of the first varactor diode and the other port of the 90 ° hybrid coupler. Is linked to the reflection-type phase shifter portion formed of the reflection load consisting of the capacitor for the 2DC blocked to prevent the DC bias voltage value of the second varactor diode flowing in the RF path of the 90 ° hybrid coupler,

The reflective rod portion,

A first inductor having one end connected in parallel between the front end of the first DC blocking capacitor and one port of the 90 ° hybrid coupler and the other end grounded to ground to widen the variable phase section;

And a second inductor having one end connected in parallel between the front end of the second DC blocking capacitor and the other port of the 90 ° hybrid coupler and the other end grounded to ground to widen the variable phase section.

Another feature of the invention,

A 90 ° hybrid coupler configured to output an input signal by combining or separating the signals with a phase difference of 90 °; A first varactor diode having a cathode connected in parallel on a line connected from one port to the other port of the 90 ° hybrid coupler, the anode being grounded to ground, and having a capacitance changed according to an input reverse bias voltage value; A second varactor diode having a cathode connected in parallel on a line connected from one port to another port of the hybrid coupler, the anode being grounded to the ground, and having a capacitance changed according to an input reverse bias voltage value, and the first bar A first DC blocking capacitor connected between the connection node of the racter diode and one port of the 90 ° hybrid coupler to prevent the DC bias voltage value of the first varactor diode from entering the RF path of the 90 ° hybrid coupler; Between the connection node of the first varactor diode and the other port of the 90 ° hybrid coupler. Is linked to the reflection-type phase shifter portion formed of the reflection load consisting of the capacitor for the 2DC blocked to prevent the DC bias voltage value of the second varactor diode flowing in the RF path of the 90 ° hybrid coupler,

The reflective rod portion,

A first inductor connected in series with a rear end of the first varactor diode to widen the variable phase section;

And a second inductor connected to the connection node of the second varactor diode in series at a rear end thereof to widen the variable phase section.

Another feature of the invention,

A 90 ° hybrid coupler configured to output an input signal by combining or separating the signals with a phase difference of 90 °; A first varactor diode having a cathode connected in parallel on a line connected from one port to the other port of the 90 ° hybrid coupler, the anode being grounded to ground, and having a capacitance changed according to an input reverse bias voltage value; A second varactor diode having a cathode connected in parallel on a line connected from one port to another port of the hybrid coupler, the anode being grounded to the ground, and having a capacitance changed according to an input reverse bias voltage value, and the first bar A first DC blocking capacitor connected between the connection node of the racter diode and one port of the 90 ° hybrid coupler to prevent the DC bias voltage value of the first varactor diode from entering the RF path of the 90 ° hybrid coupler; Between the connection node of the first varactor diode and the other port of the 90 ° hybrid coupler. Is linked to the reflection-type phase shifter portion formed of the reflection load consisting of the capacitor for the 2DC blocked to prevent the DC bias voltage value of the second varactor diode flowing in the RF path of the 90 ° hybrid coupler,

The reflective rod portion,

A first inductor having one end connected in parallel between the front end of the first DC blocking capacitor and one port of the 90 ° hybrid coupler and the other end grounded to ground to widen the variable phase section;

A second inductor connected in series to a rear end of the first varactor diode to widen the variable phase section;

A third inductor having one end connected in parallel between the front end of the second DC blocking capacitor and the other port of the 90 ° hybrid coupler, and the other end being grounded to ground to widen the variable phase section;

And a fourth inductor connected to the connection node of the second varactor diode in series at a rear end thereof to widen the variable phase section.

Hereinafter, the configuration of the reflection type phase shifter using the composite reflection rod according to the present invention will be described in detail with reference to FIGS. 2 to 4. In Fig. 2 to Fig. 4, the same parts as those in Fig. 1 are denoted by the same reference numerals as those in Fig. 1.

2 is a block circuit diagram schematically illustrating a reflection type phase shifter using a complex reflection rod according to an embodiment of the present invention, and FIG. 3 schematically illustrates a reflection type phase shifter using a complex reflection rod according to another embodiment of the present invention. 4 is a block circuit diagram schematically illustrating a reflection type phase shifter using a complex reflection rod according to another embodiment of the present invention.

2 to 4, the reflection type phase shifter 10 using the composite reflection rod according to the present invention includes a 90 ° hybrid coupler 20 and a reflection rod part 100.

The 90 ° hybrid coupler 20 combines or separates the input signal with a phase difference of 90 ° and outputs the result.

The reflective rod part 100 includes first and second varactor diodes D1 and D2, first and second DC blocking capacitors, and first and second inductors L1 and L2.

The first varactor diode (D1) has a cathode connected in parallel on a line connected from one port of the 90 ° hybrid coupler 20 to the other port, and the anode is connected to the ground to the reverse bias voltage value Vcc input. The capacitance changes accordingly, and the second varactor diode D2 has a reverse bias in which cathodes are connected in parallel on a line connected from one port of the 90 ° hybrid coupler 20 to another port, and the anode is grounded and input. The capacitance changes according to the voltage value Vcc.

The first DC blocking capacitor C1 is connected between the connection node of the first varactor diode D1 and one port of the 90 ° hybrid coupler 20 so as to provide a DC bias voltage value Vcc of the first varactor diode D1. ) Is prevented from flowing into the RF path of the 90 ° hybrid coupler 20, and the second DC blocking capacitor C2 is connected to the connection node of the second varactor diode D2 and the other port of the 90 ° hybrid coupler 20. It is connected between the DC bias voltage value (Vcc) of the second varactor diode (D2) is prevented from flowing into the RF path of the 90 ° hybrid coupler (20).

As shown in FIG. 2, the first inductor L1 has one end connected in parallel between the front end of the first DC blocking capacitor C1 and one port of the 90 ° hybrid coupler 20, and the other end is grounded to change the ground. Widening the phase section, the second inductor (L2) is connected in parallel between the front end of the second DC blocking capacitor (C2) and the other port of the 90 ° hybrid coupler (20), the other end is grounded to the variable phase section Widen.

Here, as shown in FIG. 3, the first inductor L1 is connected in series to the rear end of the connection node of the first varactor diode D1 to widen the variable phase section, and the second inductor L2 is the second varactor diode. It is also possible to widen the variable phase section by serially connecting to the connection node of (D2) at a later stage.

Here, as shown in FIG. 4, the first inductor L1 has one end connected in parallel between the front end of the first DC blocking capacitor C1 and one port of the 90 ° hybrid coupler 20, and the other end is connected to ground. The grounded to widen the variable phase section, the second inductor (L2) is connected in series to the rear end of the connection node of the first varactor diode (D1) to widen the variable phase section, the third inductor (L3) is a second DC blocking capacitor ( One end is connected in parallel between the front end of C2) and the other port of the 90 ° hybrid coupler 20, and the other end is grounded to widen the variable phase section, and the fourth inductor L4 is the second varactor diode D2. It is also possible to widen the variable phase section by being connected in series at the rear end of the connection node.

Hereinafter, the operation of the reflection type phase shifter using the complex reflection rod according to the present invention will be described in detail with reference to FIGS. 2 to 4.

First of all, the main point of the present invention is that when the reflective rod is decorated in a manner that only the varactor diode is used to change the pattern, it does not exceed 180 ° even when considered as an ideal varactor diode. A certain amount of inductor is connected in series or in parallel or in series and in parallel to use a complex reflection rod.

This makes the mixed (serial or parallel or series, parallel) load appear as an inductor at a constant capacitance (constant control voltage value). The reflection coefficient of the inductor is at the top of the Smith chart, and at the resonance frequency of this inductor and varactor diode, the reflection coefficient of the mixed rod will meet open (in parallel) or short (in series). As a result, a phase change of 180 ° or more can be obtained.

On the other hand, the value of inductance is obtained as follows.

In FIG. 4, the parallel impedance is expressed by Equation 3 below.

In this case, the impedance of the reflective rod part 100 viewed from the 90 ° hybrid coupler is expressed by Equation 4 below.

Here, the phase of the reflection coefficient is expressed by Equation 5 below.

By substituting the minimum and maximum capacitances of the varactor diodes into inductance values, the values satisfying the range shown in Equation 6 below can be obtained.

Therefore, the inductor is inserted in parallel or in series into the structure of the conventional general reflection type phase shifter to widen the variable phase range, and the input and output reflection coefficient is excellent because the shape of the existing reflection type phase shifter is used.

As described above, according to the reflection type phase shifter using the composite reflection rod according to the present invention, an inductor is inserted into the reflection rod portion of the reflection type phase shifter so that the impedance of the load portion acts as an inductor below a specific capacitance. The coefficient is excellent and the variable phase section can be obtained more than 180 °.

Claims (3)

A 90 ° hybrid coupler configured to output an input signal by combining or separating the signals with a phase difference of 90 °; A first varactor diode having a cathode connected in parallel on a line connected from one port to the other port of the 90 ° hybrid coupler, the anode being grounded to ground, and having a capacitance changed according to an input reverse bias voltage value; A second varactor diode having a cathode connected in parallel on a line connected from one port to another port of the hybrid coupler, the anode being grounded to the ground, and having a capacitance changed according to an input reverse bias voltage value, and the first bar A first DC blocking capacitor connected between the connection node of the racter diode and one port of the 90 ° hybrid coupler to prevent the DC bias voltage value of the first varactor diode from entering the RF path of the 90 ° hybrid coupler; Between the connection node of the first varactor diode and the other port of the 90 ° hybrid coupler. Is linked to the reflection-type phase shifter portion formed of the reflection load consisting of the capacitor for the 2DC blocked to prevent the DC bias voltage value of the second varactor diode flowing in the RF path of the 90 ° hybrid coupler, The reflective rod portion, A first inductor having one end connected in parallel between the front end of the first DC blocking capacitor and one port of the 90 ° hybrid coupler and the other end grounded to ground to widen the variable phase section; And a second inductor having one end connected in parallel between the front end of the second DC blocking capacitor and the other port of the 90 ° hybrid coupler and the other end grounded to ground to extend a variable phase section. Reflection type phase shifter used. A 90 ° hybrid coupler configured to output an input signal by combining or separating the signals with a phase difference of 90 °; A first varactor diode having a cathode connected in parallel on a line connected from one port to the other port of the 90 ° hybrid coupler, the anode being grounded to ground, and having a capacitance changed according to an input reverse bias voltage value; A second varactor diode having a cathode connected in parallel on a line connected from one port to another port of the hybrid coupler, the anode being grounded to the ground, and having a capacitance changed according to an input reverse bias voltage value, and the first bar A first DC blocking capacitor connected between the connection node of the racter diode and one port of the 90 ° hybrid coupler to prevent the DC bias voltage value of the first varactor diode from entering the RF path of the 90 ° hybrid coupler; Between the connection node of the first varactor diode and the other port of the 90 ° hybrid coupler. Is linked to the reflection-type phase shifter portion formed of the reflection load consisting of the capacitor for the 2DC blocked to prevent the DC bias voltage value of the second varactor diode flowing in the RF path of the 90 ° hybrid coupler, The reflective rod portion, A first inductor connected in series with a rear end of the first varactor diode to widen the variable phase section; And a second inductor connected to the connection node of the second varactor diode in series at a rear end thereof to widen the variable phase section. A 90 ° hybrid coupler configured to output an input signal by combining or separating the signals with a phase difference of 90 °; A first varactor diode having a cathode connected in parallel on a line connected from one port to the other port of the 90 ° hybrid coupler, the anode being grounded to ground, and having a capacitance changed according to an input reverse bias voltage value; A second varactor diode having a cathode connected in parallel on a line connected from one port to another port of the hybrid coupler, the anode being grounded to the ground, and having a capacitance changed according to an input reverse bias voltage value, and the first bar A first DC blocking capacitor connected between the connection node of the racter diode and one port of the 90 ° hybrid coupler to prevent the DC bias voltage value of the first varactor diode from entering the RF path of the 90 ° hybrid coupler; Between the connection node of the first varactor diode and the other port of the 90 ° hybrid coupler. Is linked to the reflection-type phase shifter portion formed of the reflection load consisting of the capacitor for the 2DC blocked to prevent the DC bias voltage value of the second varactor diode flowing in the RF path of the 90 ° hybrid coupler, The reflective rod portion, A first inductor having one end connected in parallel between the front end of the first DC blocking capacitor and one port of the 90 ° hybrid coupler and the other end grounded to ground to widen the variable phase section; A second inductor connected in series to a rear end of the first varactor diode to widen the variable phase section; A third inductor having one end connected in parallel between the front end of the second DC blocking capacitor and the other port of the 90 ° hybrid coupler, and the other end being grounded to ground to widen the variable phase section; And a fourth inductor connected to a connection node of the second varactor diode in series at a rear end thereof to widen a variable phase section.