JPH02274106A - Mixer circuit - Google Patents

Abstract

PURPOSE:To obtain a circuit with low distortion and high gain with low noise by connecting a resistor having a lower resistance than a gate input impedance of the balanced mixer and an output impedance of an unbalanced-balanced converter between ground and a connecting point of an input terminal of the balanced mixer and an output terminal of the unbalanced-balanced converter. CONSTITUTION:An RF signal and an LO signal inputted from an RF signal input terminal 130 and an LO signal input terminal 131 are converted into a balanced signal with an unbalanced-balanced converter comprising FETs 105-107 and 108-110 respectively, inputted to a double balanced mixer comprising FETs 101-104 and the IF signal subject to frequency conversion is outputted to IF signal output terminals 132, 133. Since the signal level in the gate is very large in this case and the distortion component is increased as the signal level is larger, resistors 162, 163 are connected to prevent it, the signal level in the gate is decreased and the distortion component is reduced. Thus, the circuit with high gain, low noise and low noise distortion is obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a mixer circuit with low noise and low distortion.

BACKGROUND OF THE INVENTION In recent years, as high-frequency equipment has become more sophisticated, there has been a strong demand for mixer circuits with low noise and low distortion.

A conventional mixer circuit will be explained below.

FIG. 6 shows a conventional double balanced mixer circuit. In FIG. 6, 101 to 110 are FETs (field effect transistors), 111 to 120 are resistors, and 121
~128 is a capacitor, 130 is an LO signal input terminal, 1
31 is an RF signal input terminal, 132 and 133 are intermediate frequency signal (hereinafter referred to as IF multiplied signal) output terminals, 140 to 142
are gate bias application terminals of FETs 101 to 104, 106 to 106, and 108 to 109, respectively; 160 is a power supply terminal; and 161 is a ground.

The operation of the double balanced mixer circuit configured as above will be explained.

Signals input from the RF terminal 31 and the LO terminal 130 are input to FETs 105 to 1oA and FET 108, respectively.
The unbalanced signal is converted into an unbalanced signal by an unbalanced-to-balanced conversion circuit comprised of FETs 1o1 to 110, and input to a double balanced mixer comprised of FETs 1o1 to 104. Now fl the RF multiplied signal frequency.

If the LO multiplied signal frequency is f2, then f) the RF and LO signals are frequency mixed by a double balanced mixer,
A signal with a frequency of If1±f2 multiplied by IF is output to IF terminals 132 and 133. At this time, the second-order distortion generated within the double-balanced mixer can be canceled by the balanced-unbalanced converter connected to the IF output terminal.

Problems to be Solved by the Invention However, in the conventional configuration described above, in order to obtain a large conversion gain, the RF multiplied signal is output from the terminal 13o, and the L signal is output from the terminal 131.
When the O times signal is input, the amplitude of the RF times signal input to the gates of FETs 101 to 104 becomes too large, and the FETs
Since the maximum permissible input amplitude (hereinafter referred to as dynamic range) of FETs 101 to 104 is exceeded, the third-order distortion generated in FETs 101 to 104 becomes large.

Also, due to the nonlinearity of FETs 108 and 109, the second-order
It also had the disadvantage of generating third-order distortion.

The present invention solves the above-mentioned conventional problems, and aims to provide a mixer circuit with low distortion, high gain, and low noise.

Means for Solving the Problems To achieve this object, the mixer circuit of the present invention has the following features: (1) Between the connection point of the input end of the balanced mixer using FET and the output end of the unbalanced-balanced converter and ground. (d) Connecting to a resistor having a resistance value lower than the input impedance of the balanced mixer and the output impedance of the unbalanced-balanced converter.

(2) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using FETs, a resistor is connected in series to the source terminal of each FET constituting the balanced mixer. .

(3) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using FETs, a connection point between the source common connection point of the balanced mixer and the output end of the unbalanced-balanced converter. and a resistor connected in series.

(4) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using FETs, the unbalanced-balanced converter connected to the source of the FET constituting the balanced mixer. multiple FEs
A resistor is connected in series to the source terminals of FETs forming a differential pair of the differential amplifier.

(5) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using FETs, the unbalanced-balanced converter is connected to the gate of the FET constituting the balanced mixer. , multiple FEs
A feedback circuit is connected between the gate terminal and drain terminal of each FET forming a differential pair of the differential amplifier.

Effect: With this configuration, (1) the amplitude of the RF multiplied signal input to the FETs forming the double balanced mixer can be reduced;

(2) The dynamic range of the FETs constituting the double-balanced mixer can be expanded.

(3) Same as (2) (4) Differential MH that performs RF double signal unbalanced-balanced conversion
The dynamic range of the FET forming the II device can be expanded.

(5) The input impedance of the FET constituting the differential amplifier that performs unbalanced-balanced RF multiplied signal conversion can be lowered, and the amplitude of the input signal can be reduced.

Therefore, it is possible to realize a double-balanced mixer with low distortion, high gain, and low noise.

EXAMPLE An example of the present invention will be described below with reference to the drawings.

FIG. 1 shows a circuit diagram of a double balanced mixer according to an embodiment of claim 1 of the present invention. 1st
In the figure, 101 to 110 are FETs, 111 to 12
0,162,163 is a resistor, 121-128,160
, 161 is a capacitor, 130 is an RF signal input terminal, 1
31 is an LO signal input terminal, 132 and 133 are IF signal output terminals, 140 to 142 are FET bias voltage application terminals, 150 is a power supply terminal, and 161 is a ground. The operation of the double balanced mixer circuit configured as above will be explained. RF multiplied signal frequency f1) input from the RF signal input terminal 130 and the LO signal input terminal 131
and LO multiplied signal frequency f2) are FET1o
After being converted into a balanced signal by an unbalanced-balanced converter composed of 6 to 107 and 108 to 110, FET1o1 to
The IF multiplied signal frequency If, ±f21 inputted to the double balanced mixer composed of 104 and subjected to frequency conversion is outputted to IF signal output terminals 132 and 133.

At this time, the unbalanced RF multiplied signal is input from a signal line with a characteristic impedance of 60 Ω to the gate of the FET, which has an impedance of several hundred to several Ω, but since the input and output powers are equal, vtn”Rin=”ou
According to t'/Rout, the signal amplitude at the gate becomes very large. The larger the signal amplitude, the larger the distortion component, so to prevent this, resistors 162 and 163 having a resistance of 100 to 300 Ω are connected to reduce the signal amplitude at the gate and reduce the distortion component. .

FIG. 2 shows a first embodiment of claim 2 of the present invention. In Figure 2, the differences from Figure 1 are as follows:
Capacitors 180, 161 and resistors 162, 163
is omitted, and resistors 1 to 3 are connected. The basic operation of the circuit shown in FIG. 2 is the same as that of the embodiment according to claim 1, but the dynamic range of the FETs 101 to 104 constituting the double balanced mixer can be expanded by the resistors 170 to 173. .

FIG. 3 shows an embodiment of claim 3 of the present invention. The difference from FIG. 2 is that resistors 170 to 174 are omitted and resistors 180 and 181 are connected. By using the resistors 180-181, the same effect as the circuit shown in FIG. 2 can be obtained.

FIG. 4 shows an embodiment of claim 4 of the present invention. The difference from FIG. 1 is that capacitors 160, 16
1 and resistors 162 and 163 are omitted, and resistors 190 and 19 are replaced.
This is because it was connected to 1. The operation of the circuit of FIG. 4 is similar to the embodiment of claim 1, except that resistors 190, 1
91, the dynamic range of the FETs 108 and 109 can be expanded.

FIG. 6 shows an embodiment of claim 6 of the present invention. The difference from FIG. 1 is that capacitors 160, 16
1 and resistors 162 and 163 are omitted, and the capacitor 200 is
．． 2Q1 and a feedback circuit formed by resistors 202 and 203 are connected. 3. The operation of the circuit shown in FIG. The amplitude of the RF input signal at the gate can be reduced.

Effects of the Invention As described above, the present invention not only obtains high gain and low noise by inputting an RF multiplied signal to the gate of the FET constituting the double balanced mixer and an LO multiplied signal to the source, but also achieves the following O ) to (4), a double-balanced mixer with low distortion can be realized at the same time.

(1) By grounding the connection point between the output of the unbalanced-balanced conversion circuit on the RF signal side and the gate input of the double-balanced mixer with a low resistance, the RF multiplied signal amplitude is input to the double-balanced mixer. suppress.

(2) FETs that make up the Dove 7 rebalanced mixer
By connecting a resistor in series to the source of the FET, the dynamic range of the FET is expanded.

(3) Connect a resistor between the source common contact point of the FETs constituting the double balanced mixer and the output of the unbalanced-balanced converter on the LO side.

(4) FET constituting the unbalanced-balanced converter on the RF side
By connecting a resistor in series to the source of the FET, the dynamic range of the FET is expanded.

(5) By connecting a feedback circuit between the gate and source of the FET that constitutes the unbalanced-balanced converter on the RF side, the FET
Lower the input impedance of ET.

[Brief explanation of drawings]

1 to 5 are mixer circuit diagrams of each embodiment of the present invention, and FIG. 6 is a circuit diagram of a conventional double-balanced mixer. 101~110...FET 11j~120
゜182, 163...Resistor. Name of agent: Patent attorney Shigetaka Awano and 1 other person (Ujiguchi), 3

Claims (5)

[Claims] (1) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using field-effect transistors, the connection point between the input end of the balanced mixer and the output end of the unbalanced-balanced converter. and ground, a mixer circuit having a resistor having a resistance value lower than the gate input impedance of the balanced mixer and the output impedance of the unbalanced-balanced converter. (2) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using field effect transistors, a resistor is connected in series to the source terminal of each slang resistor that constitutes the balanced mixer. mixer circuit. (3) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using field-effect transistors, the source common connection point of the transistors of the balanced mixer and the output terminal of the unbalanced-balanced converter are connected to each other. A mixer circuit with a resistor connected in series to the connection point. (4) In a circuit in which unbalanced-balanced converters are connected to the gate and source of a balanced mixer using field effect transistors, respectively, the unbalanced-balanced converter is connected to the source of the transistor constituting the balanced mixer. A mixer circuit in which a converter is constituted by a differential amplifier made up of a plurality of transistors, and a resistor is connected in series to the source terminals of the transistors forming a differential pair of the differential amplifier. (5) In a circuit in which an unbalanced-balanced converter is connected to the gate and source of a balanced mixer using field effect transistors, the unbalanced-balanced converter is connected to the gate of the transistor constituting the balanced mixer. A mixer circuit comprising a differential amplifier comprising a plurality of transistors, and a feedback circuit is connected between the gate terminal and drain terminal of each of the transistors forming a differential pair of the differential amplifier.