JPH08191219A - Mixer circuit - Google Patents

Abstract

PURPOSE: To attain impedance matching without using an impedance conversion circuit. CONSTITUTION: A closed loop line is constituted of lines 4a, 4b, 5a to 5c. The impedance of a local oscillation signal input terminal 22 and a high frequency signal input terminal 21 are respectively set up to Z1 and Zr. The impedance of a mixer diode 7a including a line 6a observed from a terminal 26a is set up to Zd and the impedance of a mixer diode 7b including a line 6b observed from a terminal 26b is set up to Zd. When the characteristic impedance of the lines 5a to 5c is set up to (2×Z1×za)<1/2> and that of the lines 4a, 4b is set up to (2×Zr×Zd)<1/2> , the impedance matching of respective terminals can be attained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mixer circuit used for communication equipment or the like.

[0002]

2. Description of the Related Art A single balanced mixer is often used as a mixer circuit in a communication device or the like because it has an advantage that a local oscillation signal input terminal and a high frequency signal input terminal have good isolation. The single balanced mixer has a circuit configuration of 1
An 80 degree phaser is required. The rat race circuit is one of several types of 180-degree phasers that have been devised.

FIG. 4 is a pattern wiring diagram of a conventional mixer circuit using a rat race circuit proposed in Japanese Patent Laid-Open No. 63-46808. 31 is a high frequency signal input line, 32 is a local oscillation signal input line, 33 is an intermediate frequency signal output line, 34 is a ring-shaped closed loop line, 36a,
36b is a line connecting the closed loop line 34 and a mixer diode described later, 37a and 37b are mixer diodes,
38 is a short-circuit line for short-circuiting a high frequency signal, 39a,
39b is a line which constitutes a low pass filter, 39c is a bonding wire which connects the low pass filter and the intermediate frequency signal output line 33, and 40 is a dielectric substrate.

The high frequency signal input from the high frequency signal input line 31 is distributed via the lines 36a and 36b, and is input to the mixer diodes 37a and 37b in the same phase. The local oscillation signal input from the local oscillation signal input line 32 is distributed via the lines 36a and 36b, input to the mixer diodes 37a and 37b with a phase difference of 180 degrees, and mixed with the high frequency signal. And the high frequency signal is
The intermediate frequency signal is short-circuited by the short-circuit line 38 having the open end of the quarter wavelength, and the intermediate frequency signal is output to the intermediate frequency signal output line 33 via the low pass filter including the lines 39a and 39b and the bonding wire 39c.

[0005]

Each input / output terminal of the above mixer circuit is designed as a line characteristic impedance of 50Ω. However, a transistor chip or the like may be connected to the local oscillation signal input side and the high frequency signal input side, and their characteristic impedance is 50Ω.
Often not. Therefore, the conventional mixer circuit has a problem in that it is necessary to provide an impedance conversion circuit for impedance matching, which complicates the circuit configuration and the circuit layout. The present invention has been made to solve the above problems, and an object of the present invention is to provide a mixer circuit capable of impedance matching without a conventional impedance conversion circuit.

[0006]

According to the present invention, a local oscillation signal input terminal and a first mixer diode connection terminal for connecting a first mixer diode are provided between the mixer diode connection terminal and a high frequency signal input terminal. Between the high frequency signal input terminal and the second mixer diode connection terminal for connecting the second mixer diode, and between the mixer diode connection terminal and the intermediate frequency signal output terminal. The first, second, third and fourth lines forming a closed loop line having a length of 1/4 wavelength of a signal are provided, and a high frequency wave used between the intermediate frequency signal output terminal and the local oscillation signal input terminal. A rat race having a fifth line that constitutes a closed loop line having a length of ½ wavelength of a signal, and adjusting characteristic impedances of the first, second, third, fourth, and fifth lines In which impedance matching of the road and the terminals.

Further, the impedance Z1 of the local oscillation signal input terminal, the impedance Zr of the high frequency signal input terminal,
According to the impedance Zd of the first and second mixer diode connection terminals, the characteristic impedances of the first, fourth, and fifth lines are set to (2 × Z1 × Zd) ^1/2 , respectively, and the second and third The characteristic impedance of each line is (2 ×
Zr × Zd) ^1/2 . Further, between the first mixer diode connection terminal and the first mixer diode, and between the second mixer diode connection terminal and the second mixer diode, 1/8 to 3/8 of the high frequency signal used.
The transmission lines each have a wavelength length.

[0008]

According to the present invention, the local oscillation signal input terminal and the first
A first line connecting the mixer diode connection terminal of, a second line connecting the mixer diode connection terminal and the high frequency signal input terminal, and a third line connecting the high frequency signal input terminal and the second mixer diode connection terminal By adjusting the characteristic impedances of the fourth line connecting the mixer diode connection terminal and the intermediate frequency signal output terminal and the fifth line connecting the intermediate frequency signal output terminal and the local oscillation signal input terminal, a closed loop is obtained. Impedance matching between the line and each terminal is realized.

Further, the impedance Z1 of the local oscillation signal input terminal, the impedance Zr of the high frequency signal input terminal,
According to the impedance Zd of the first and second mixer diode connection terminals, the characteristic impedance of the first, fourth, and fifth lines is set to (2 × Z1 × Zd) ^1/2, and the second and third lines are set. By setting the characteristic impedance of (2 × Zr × Zd) ^1/2 , impedance matching of each terminal is realized. In addition, the length of the line connecting the first and second mixer diode connection terminals to the first and second mixer diodes respectively is set to ⅛ to ⅜ wavelength of the high frequency signal used, thereby forming a closed loop line. And impedance matching of the mixer diode is realized.

[0010]

FIG. 1 is a pattern wiring diagram of a mixer circuit showing an embodiment of the present invention. 1 is a high frequency signal input line, 2 is a local oscillation signal input line, 3 is an intermediate frequency signal output line, 5
a, 4a, 4b, 5b and 5c are first to fifth lines that form a ring-shaped closed loop line, 6a and 6b are lines that connect the mixer diode and the closed loop line, and 7a and 7b are first and second lines. Mixer diodes, 8 is a short-circuit block for short-circuiting high-frequency signals, 9a and 9b are lines forming a low-pass filter, 10 is a dielectric substrate, and 12 is a transistor chip connected to the local oscillation signal input line 2. is there.

Further, 21 is a high frequency signal input terminal which is a connection point between the high frequency signal input line 1 and the closed loop line, 22 is a local oscillation signal input terminal which is a connection point between the local oscillation signal input line 2 and the closed loop line, and 23 is an intermediate point. Frequency signal output terminal, 2
Reference numerals 6a and 26b are first and second mixer diode connection terminals which are connection points between the lines 6a and 6b and the closed loop line.

In such a mixer circuit, the length and impedance of each line are determined as follows. First, the first line 5a forming the closed loop line,
The second line 4a, the third line 4b, and the fourth line 5b are designed to have a length of ¼ wavelength of the used high-frequency signal, and the fifth line 5c has a length of ½ wavelength of the high-frequency signal. Designed to be

The high frequency signal input line 1 is connected to the closed loop line with an impedance Z0 (= 50Ω).
The local oscillation signal input line 2 is designed in accordance with the impedance characteristics of the transistor chip 12 in the previous stage, and the line 2 when viewed from the local oscillation signal input terminal 22.
The length is determined so that the value of the impedance on the output side of the transistor chip 12 including Z is Z1.

The line 6a is designed in accordance with the impedance characteristic of the first mixer diode 7a, and the impedance of the mixer diode 7a including the line 6a when viewed from the first mixer diode connection terminal 26a. The length is determined so that the value is Zd.
Similarly, the length of the line 6b is determined so that the impedance value of the mixer diode 7b including the line 6b when viewed from the second mixer diode connection terminal 26b is Zd.

Then, the first line 5a and the fourth line 5
The characteristic impedances of b and the fifth line 5c are designed to be (2 × Z1 × Zd) ^1/2 , respectively,
The characteristic impedances of the second line 4a and the third line 4b are designed to be (2 × Z0 × Zd) ^1/2 , respectively. FIG. 2 is a diagram showing the characteristic impedance as described above.

The high frequency signal input from the high frequency signal input line 1 is distributed via the lines 4a, 4b, 6a and 6b and input to the mixer diodes 7a and 7b in the same phase.
Further, the local oscillation signal is amplified by the transistor chip 12, distributed through the local oscillation signal input line 2 and the lines 5a, 5b, 5c, 6a and 6b, and is supplied to the mixer diodes 7a and 7b at 180 degrees. It is input with a phase difference and mixed with a high frequency signal.

At this time, the local oscillation signals cancel each other out in the high-frequency signal input line 1 with a phase difference of 180 degrees, so that they do not propagate to the input line 1. Impedance matching is realized at each terminal as described later, and the high frequency signal and the local oscillation signal are input to the mixer diodes 7a and 7b without loss. The intermediate frequency signal, which is a difference between the high frequency signal and the local oscillation signal, which is generated as a result of such mixing, is output to the intermediate frequency signal output line 3 through the low pass filter including the lines 9a and 9b.
In this way, a mixer circuit that operates similarly to the example of FIG. 4 is realized.

Next, impedance matching of this embodiment will be described. With the above line configuration, the impedance Z of the two mixer diode connection terminals 26a and 26b is
d (characteristic impedance of the mixer diodes 7a and 7b including the lines 6a and 6b when viewed from the closed loop line)
When viewed from the high-frequency signal input terminal 21, each becomes {(2 × Z0 × Zd) ^1/2 } ² / Zd = 2 × Z0, which matches the impedance Z0 of the high-frequency signal input terminal 21.

When viewed from the local oscillation signal input terminal 22, the two impedances Zd are {(2 × Z
1 × Zd) ^1/2 } ² / Zd = 2 × Z1, which matches the impedance Z1 of the local oscillation signal input terminal 22. Since the high frequency signal input side and the local oscillation signal input side are isolated from each other, they are not easily affected by the impedance of each other. In this way, impedance matching of each terminal is realized.

According to the above configuration, no impedance conversion circuit is required on the output side of the transistor chip 12,
Further, impedance matching between the mixer diodes 7a and 7b and the closed loop line can be achieved without the impedance conversion circuit.

However, the line 4 constituting the closed loop line
Since the characteristic impedances of a, 4b, and 5a to 5c are determined based on the impedance Zd described above, when the characteristic impedance of the mixer diodes 7a and 7b included in the impedance Zd is low, the impedance of the example of FIG. When the layout of the circuit is tried according to the design, the characteristic impedance of the lines 4a, 4b, 5a to 5c becomes low, and the line width may become too large, which is not realistic. Therefore, in such a case, another measure is required.

FIG. 3 is a pattern wiring diagram of a mixer circuit showing another embodiment of the present invention. The same parts as those in FIG. 1 are designated by the same reference numerals. Reference numeral 11 is a transistor chip connected to the high-frequency signal input line 1, and 16a and 16b are lines having a length of 1/8 to 3/8 wavelength of the high-frequency signal used.

Local oscillation signal input line 2, lines 4a, 4
The configurations of b, 5a to 5c are similar to those of the example of FIG. 1, but in the present embodiment, the closed loop line and the mixer diodes 7a and 7b are used.
The lengths of the lines 16a and 16b for connecting the and are set to ⅛ to ⅜ wavelength of the high frequency signal used. As a result, both the impedance Zd of the mixer diode 7a including the line 16a viewed from the mixer diode connection terminal 26a and the impedance Zd of the mixer diode 7b including the line 16b viewed from the mixer diode connection terminal 26b can be made high impedance.

This is because the impedance becomes highest when the lengths of the lines 16a and 16b are set to ¼ wavelength of the high frequency signal, and becomes equal to the original Zd when set to ½ wavelength. Zd has a high impedance by setting the wavelength from ⅛ centering on / 4 (2/8) wavelength to ⅜ wavelength. Above track 16a,
By impedance conversion by 16b, impedance matching between the mixer diodes 7a and 7b and the closed loop line can be realized even if the impedances of the mixer diodes 7a and 7b are low.

In this embodiment, the transistor chip 11 is also connected to the high frequency signal input line 1,
In this case, the design may be similar to that of the local oscillation signal input line 2. That is, the high-frequency signal input line 1 at this time is the line 1 when viewed from the high-frequency signal input terminal 21.
The length may be determined so that the value of the impedance on the output side of the transistor chip 11 including Zr becomes Zr. Then, the characteristic impedances of the second line 4a and the third line 4b that form the closed loop line are respectively (2 × Zr ×
If the design is such that Zd) ^1/2 , impedance matching similar to the example of FIG. 1 can be realized.

[0026]

According to the present invention, impedance matching between the closed loop line and each terminal can be realized by adjusting each characteristic impedance of the first to fifth lines forming the closed loop line of the rat race circuit. As a result, an impedance conversion circuit is not required, and the circuit can be simplified and miniaturized. Especially, as in a monolithic microwave integrated circuit, an amplifier for local oscillation signal and low noise for high frequency signal are provided on the same semiconductor substrate. A great effect can be obtained when an amplifier or the like is formed together with a mixer circuit.

Further, the impedance Z1 of the local oscillation signal input terminal, the impedance Zr of the high frequency signal input terminal,
According to the impedance Zd of the first and second mixer diode connection terminals, the characteristic impedances of the first, fourth, and fifth lines are set to (2 × Z1 × Zd) ^1/2 , respectively, and the second and third The characteristic impedance of the line is (2 × Zr × Z
By setting d) ^1/2 , impedance matching of each terminal can be easily realized.

Further, the lengths of the lines connecting the first and second mixer diode connection terminals and the first and second mixer diodes respectively are set to 1/8 to 3/8 of the used high frequency signal.
By setting the wavelength, the impedance matching between the closed loop line and the mixer diode can be realized even if the impedances of the first and second mixer diodes are low.

[Brief description of drawings]

FIG. 1 is a pattern wiring diagram of a mixer circuit showing an embodiment of the present invention.

FIG. 2 is a diagram showing a state of characteristic impedance in the mixer circuit of FIG.

FIG. 3 is a pattern wiring diagram of a mixer circuit showing another embodiment of the present invention.

FIG. 4 is a pattern wiring diagram of a conventional mixer circuit using a rat race circuit.

[Explanation of symbols]

1 ... High-frequency signal input line, 2 ... Local oscillation signal input line,
3 ... Intermediate frequency signal output lines 4a, 4b, 5a-5c ...
Closed loop line, 6a, 6b, 16a, 16b ... Line, 7
a, 7b ... Mixer diode, 21 ... High frequency signal input terminal, 22 ... Local oscillation signal input terminal, 23 ... Intermediate frequency signal output terminal, 26a, 26b ... Mixer diode connection terminal.

Claims (3)

[Claims] 1. A mixer circuit using a rat race circuit in which an input / output terminal is added to a closed loop line having a length of 3/2 wavelength of a used high frequency signal, wherein a local oscillation signal input terminal and a first mixer diode are connected. A second mixer diode connection terminal for connecting the high-frequency signal input terminal and the second mixer diode, and a high-frequency signal input terminal for connecting the high-frequency signal input terminal and the high-frequency signal input terminal. First, second, and second terminals constituting the closed loop line having a length of ¼ wavelength of the high-frequency signal used, respectively, between the mixer diode connection terminal and the intermediate-frequency signal output terminal.
A fifth line, which includes third and fourth lines, is provided between the intermediate frequency signal output terminal and the local oscillation signal input terminal to form the closed loop line having a length of ½ wavelength of the used high frequency signal. A mixer circuit, comprising: adjusting characteristic impedances of the first, second, third, fourth, and fifth lines to obtain impedance matching between the rat race circuit and each terminal. 2. The mixer circuit according to claim 1, wherein the impedance of the local oscillation signal input terminal is Z1, the impedance of the high frequency signal input terminal is Zr, and the impedance of the first and second mixer diode connection terminals is Zd. , The characteristic impedances of the fourth and fifth lines are (2 × Z1 × Zd) ^1/2, and the characteristic impedances of the second and third lines are (2 × Zr × Zd) ^1/2. Mixer circuit characterized by. 3. The mixer circuit according to claim 2, wherein the mixer circuit is used between the first mixer diode connection terminal and the first mixer diode, and between the second mixer diode connection terminal and the second mixer diode. A mixer circuit having transmission lines each having a length of ⅛ to ⅜ wavelength of a high frequency signal.