JPS62159502A - Directional coupler - Google Patents

Abstract

PURPOSE:To form a directional coupler not affected by the frequency and tem perature characteristic by connecting a resistor to a coupling line via a high frequency switch. CONSTITUTION:High frequency switches 4-6 are connected to a desired position on the way of a coupling line 3, the high frequency switches 4-6 are grounded via resistors 8-10 in series and a changeover circuit 11 applies on/off control to the high frequency switches 4-6. When any of the high frequency switches 4-6 is turned off, an output proportional to a reflected wave of a transmission line 2 appears at a point (a) and an output proportional to a traveling wave appears at a point (c). Then the output proportional to the reflected wave is attenuated while being terminated by a termination resistor 7 and only the output proportional to the traveling wave is outputted at a terminal 13. Let the length between the points (a, c) of the coupling line 3 be l1, the intensity of the traveling wave output outputted at a terminal 13 is proportional to the length l1. For example, in selecting l2=l1/2, since the electrostatic coupling and the induction coupling between the lines 2 and 3 are halved respectively, the output of the traveling wave outputted at the terminal 13 is 1/4 of the output of the length l1.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a directional coupler used in cellular car telephones, personal radios, etc., for extracting a part of the transmission output.

(Prior art) Wireless communication devices such as cellular car phones and personal radios are equipped with a high frequency coupling circuit to detect the transmission level, and a part of the transmission output is extracted from this high frequency coupling circuit to control the transmission output. Many transmission power control circuits that perform this function are widely used. A simple coupling circuit is one that connects a small-capacity capacitor in the middle of a transmission line and combines it at a high frequency to extract a high-frequency signal. and could not be used for the transmission power control circuit. Therefore,
There is a directional coupler using a microstrip line as a coupling circuit that detects only traveling waves. This conventional directional coupler is shown in FIG.

In FIG. 6, 1 is a high frequency signal source, 2 is a transmission line as a transmission path, 3 is a coupling line that is high frequency coupled to the transmission line 2, 7 is a terminating resistor, 12 is an antenna, 13
is the terminal that takes out the traveling wave. Transmission radio waves are supplied from a high frequency signal source 1 to a transmission line 2 and transmitted from an antenna 12. Then, a part of the high frequency signal is extracted through a coupling line 3 provided close to the transmission line 2. Here, an output proportional to the reflected wave appears at point a of the coupling line 3, and an output proportional to the traveling wave appears at point 0. Therefore, by connecting the terminating resistor 7 for attenuating the reflected wave to the point a, the transmission line 2 is connected from the terminal I3 connected to the 0 point.
Only the output proportional to the traveling wave can be extracted.

By the way, in recent years, there have been many types of radio equipment that switch the transmission output stepwise, and in such radio equipment, the detection output of high-frequency signals must be switched in conjunction with the transmission output so that it is inversely proportional to the transmission output. Usually, a high frequency attenuator is provided after the 0 point of the coupling line 3, and this high frequency attenuator is switched by a switch. A conventional example of a directional coupler equipped with such a high frequency attenuator is shown in FIG. In the seventh part, 32 to 34 are switches for switching high frequency attenuators 35 and 36, each having a preset amount of attenuation, and 11 is a switching circuit for switching the switches 32 to 34. The traveling wave taken out by the coupling line 3 passes through the switch selected and turned on by the switching circuit 11 among the switches 32 to 34, and then passes through the high frequency attenuator: '15.3
6 or output to terminal 13 without being attenuated. For example, when the switch 33 is turned on in response to an instruction from the switching circuit 11, the traveling wave high frequency signal is attenuated to a certain degree by the high frequency attenuator 36 and output to the end f13.

Further, as another conventional example, a directional coupler using a variable high frequency attenuator is shown in FIG. In FIG. 8, 37 is a DC blocking capacitor, 38 is a variable high frequency attenuator composed of a bin diode, 39 is a switch, 40 is a resistor, 4
1 is a DC power supply. The traveling wave high frequency signal is inputted from the coupling line 3 via the capacitor 37 to the variable high frequency attenuator 38 . A DC current is supplied to the variable high frequency attenuator 38 from a DC power source 41 via a resistor 40 and a switch 39, and attenuation (2) is determined by the DC current value. Therefore, one or more of the switches 39 is selectively turned on, one of the resistors 40 is selected, and the amount of attenuation of the variable high frequency attenuator 38 is determined by the resistance value of this resistor. In this way, the high frequency signal is attenuated by the variable high frequency g table 38 which is set to a predetermined amount of attenuation by selecting the switch 39, and then outputted to the terminal 13.

(Problems to be Solved by the Invention) By the way, in the conventional example shown in FIG. There is a problem in that it disturbs the input/output matching of the attenuators 35 and 36, making it very difficult to achieve matching. In addition, in order to improve the isolation of the high frequency attenuators 35 and 36, switches 32 and 33 are provided on both the input and output sides, but these switches 32 and 33 complicate the circuit configuration and make wiring difficult. There was a problem with that.

In the conventional example shown in FIG. 8, a bin diode is used as the variable attenuation element 38, and since the attenuation amount of this bin diode is controlled by the bias current, the DC power supply 41
It is necessary to improve the stability of the circuit and has temperature characteristics, and these characteristics must be corrected, which poses a problem in that the circuit configuration becomes complicated.

An object of the present invention was to solve the problems of the conventional directional coupler described above.The purpose of the present invention is to change the degree of coupling by changing the length of the coupling line, thereby simplifying the circuit configuration and improving frequency characteristics. The object of the present invention is to provide a directional coupler that is not affected by temperature characteristics.

(Means for Solving the Problems) In order to achieve the above object, the directional coupler of the present invention includes a coupling line provided close to a high frequency signal transmission path,
By providing a switch means and a resistor connected to the switch means in this coupling line, constructing a directional coupler by grounding this resistor, and switching the switch means,
It is configured to switch the degree of coupling between the transmission path and the coupling line.

(Effect) W/, 4 $rnJ l-1a
if 7 4-+ +-W t# J,, 9
．． By switching the switch means, the position of the terminating resistor of the coupling line is changed, and the length of the coupling line coupled to the transmission line is changed. For this reason, the degree of coupling between the transmission path and the coupling line can be switched, and the level of the high frequency signal taken out from the coupling line can be changed.

(Description of Examples) Hereinafter, examples according to the present invention will be described with reference to FIG. FIG. 1 is a circuit diagram of a first embodiment of a directional coupler of the present invention. In FIG. 1, the same members as those in FIGS. 6 to 8 are given the same reference numerals, and redundant explanations will be omitted.

In FIG. 1, 4, 5.6 are high frequency switches as switching means, and 8, 9.10 are resistors. High frequency switches 4, 5.6 are connected to desired locations along the coupling line 3, and resistors 8, 9, . . . are connected to these high frequency switches 4, 5, 6.
10 are connected in series to ground, and the switching circuit 1
1 controls on/off of the high frequency switches 4, 5.6.

When both high frequency switches 4 and 5.6 are off, a
An output proportional to the reflected wave of the transmission line 2 appears at the point, and an output proportional to the traveling wave appears at the 0 point. Therefore, the output proportional to the reflected wave is terminated and attenuated by the terminating resistor 7, and only the output proportional to the traveling wave is outputted to the terminal 13. At this time, the length between point a and point 0 of connection line 3 is 21
Then, the traveling wave output output to the terminal 13 has a length fL
The intensity is proportional to l.

Next, when, for example, the high frequency switch 5 is turned on in response to an instruction from the switching circuit II, the high frequency switch 5 is connected to point b in the middle of the coupling line 3, so the resistor 9 connected to the high frequency switch 5 acts as a terminating resistor. A reflected wave of the high frequency signal taken out between point b and point 0 of the coupling line 3 is terminated at the resistor 9, and a traveling wave is output to the terminal 13. In addition, the reflected wave of the high frequency signal taken out between point a and point b of the coupling line 3 terminates at the terminating resistor 7, and the traveling wave terminates at the resistor 9.
Terminates with. The traveling wave output to the terminal 13 is proportional to the length jZ2 between the point b and the 0 point of the coupling line 3, and the output is proportional to the length 12 compared to the output proportional to the length 11. Since it is in the relationship of Itl > R2, it naturally becomes small. For example, mourning Ml, the relationship of 12 is seen 2 = Dan 1
/2, the electrostatic coupling and inductive coupling between transmission line 2 and coupling line 3 will each be 1/2, so the traveling wave output to terminal 13 will be 1/4 of the output with length 11. .

In this way, the high frequency switches 4, 5.6 are connected to the coupling line 3.
If the switching circuit 11 controls the on/off of the high frequency switches 4, 5.6, the traveling wave can be extracted from the transmission line 2 with a desired degree of coupling.

FIG. 2 shows a circuit diagram of a second embodiment of the directional coupler of the present invention. In FIG. 2, reference numeral 3a indicates a stepwise bent coupling line, which has two stages depending on the distance between the transmission line 2 and the coupling line 3a or the position in the length direction of the coupling line 3a. .

The bent point of the coupling line 3a is designated as a point d, and the d point is grounded via a high frequency switch 5 and a resistor 9 in series, and the high frequency switch 5 is controlled on/off by a switching circuit 11. If the distance between the transmission line 2 and the coupling line 3a from point a to point d of the coupling line 3a is di, and the distance from point d to point 0 is dl, then when the high frequency switch 5 is off, the coupling is Line 3a has length 23 with distance fid+ and length 1
2 and is coupled to the transmission line 2 at a distance d2. Furthermore, when the high frequency switch 5 is on, the resistor 9 becomes a terminating resistor, as in the first embodiment described above, and the connecting line 3 is connected to the point d and 0.
The reflected wave taken out between the points is terminally attenuated by the resistor 9,
Only the traveling wave is output to the end %+3. At this time, the distance between the d point and the 0 point of the transmission line 2 and the coupling line 3a is dl, and the setting is dl > dl, so the degree of coupling is changed more greatly than simply switching the length. be able to. Therefore, the range of coupling degree switching can be further expanded.

FIG. 3 shows a circuit diagram of a third embodiment of the directional coupler of the present invention. In FIG. 3, one end of the coupling line 3b is opened and inclined with respect to the transmission line 2, and the length of the coupling line 3b is changed, and the transmission line 2 and the coupling line 3
The distance between the bonding lines 3b and 3b is varied depending on the position in the length direction of the bonding line 3b, thereby increasing the change in the degree of bonding.

FIG. 4 shows a circuit diagram of a fourth embodiment of the directional coupler of the present invention. In the fourth embodiment, the high frequency switch is formed of a switching diode, and the switching operation is performed electronically.

In FIG. 4, I4 is a switching diode, 15
is a high frequency bypass capacitor, 16 is a choke coil, 17 is a bias resistor that determines the bias current of the switching diode 14, 18 is a transistor, 19.2
0 is a bias resistor for the transistor 18, 21 is a switch, and 22 is a DC power supply. One end of the switching diode 14 is connected to the coupling line 3, and the other end is grounded through a resistor 9 and a bypass capacitor 15 in series. The switching diode '+4 has a transistor I
8 collector to bias resistor 17 and choke coil 1
6 in series, a bias current flows into the connection point between resistor 9 and bypass capacitor 15, and is supplied roughly through resistor 9. A DC power supply 22 is connected to the emitter of the transistor 18, and a voltage divided from the DC power supply 22 by resistors 19 and 20 is applied to the base, and the resistor 20 is grounded via a switch 21. This switch 21
The transistor 18 performs switching by turning on/off the transistor 18, and the switching diode 14 switches in response to the switching of the transistor 18, thereby switching the length of the coupling line 3. When the switch 21 is turned on, the transistor 18 is turned on, and the bias current determined by the bias resistor 17 is passed from the DC power supply 22 through the transistor 18 to the choke coil 16, the resistor 9, the switching diode 14, the coupling line 3, and the terminating resistor 7. Further, it flows to the ground, and by passing a bias current of several mA through the switching diode 14, the switching diode 14 becomes conductive in an alternating current manner, and the resistor 9 acts as a terminating resistor. Further, when the switch 21 is turned off, the transistor 18 is turned off, and no bias current is supplied to the switching diode 14, so that the switching diode 14 is turned off. Since the DC power supply 22 mainly only supplies a bias current to the switching diode 14 to make it conductive, there is little influence U due to the voltage stability. No, it's not required.

FIG. 5 shows an automatic transmission power control circuit (APC) that automatically adjusts the transmission output of the F8 transmitter based on the traveling wave of the high frequency signal obtained by the directional couplers of the first to fourth embodiments.
circuit). In FIG. 5, 23 is a power amplifier that amplifies the high frequency signal to be transmitted, 24 is a directional coupler that takes out a part of the high frequency signal to be transmitted, 25 is a switch circuit, 26 is a detector that detects the high frequency signal, and 27 28 is an output setting circuit that outputs a reference signal and switches the reference signal level to switch the transmission output; 28 is a comparison amplifier that compares the detection output with the reference signal level; 29 is a comparison amplifier 28
30 is an input terminal to which a high frequency signal is input;
Reference numeral 1 denotes an input terminal to which a control signal for switching the transmission output is input. 'A part of the high frequency signal outputted from the power amplifier 23 is extracted by the directional synthesizer 24, this extracted high frequency signal is detected by the detector 26, and the detected output is inputted to the comparator amplifier 28. A reference signal is input from the output setting circuit to the comparator amplifier 28 , the detected output and the reference signal level are compared and amplified, and an amplified output of the difference between the detected output and the reference signal level is input to the voltage control circuit 29 . The voltage control circuit 29 performs power amplification based on the output of the comparison amplifier 28? : Control i23 to suppress fluctuations in transmission output due to fluctuations in power supply voltage and temperature changes. When switching the transmission output, a control signal is input from the input terminal 31 to switch the reference signal level output from the output setting circuit 27, and when the switching range of the transmission output is large, the detector 26
Since the dynamic range is insufficient, the switch circuit 25 is switched to change the amount of attenuation of the high frequency signal and the APC circuit is operated in a state where the detector 26 is not saturated.

The directional coupler of the present invention is, for example, a combination of the directional coupler 24 and the switch circuit 25 used in the APC circuit described in Of course, the use of the APC circuit is not limited to the above-mentioned APC circuit.

(Effects of the Invention) As explained above, according to the directional coupler of the present invention,
Since it has a simple configuration in which a resistor is connected to the coupling line via a high-frequency switch, there is no need for complicated wiring, and there is no problem of matching due to the impedance of the wiring. In addition, in order to attenuate high-frequency signals, the length of the coupling line is changed to change the degree of coupling, eliminating the need for a special attenuator unlike conventional methods, and eliminating the effects of the frequency and temperature characteristics of the attenuator. There is no need for a correction circuit for these characteristics, and the excellent effect is that the high frequency signal taken out from the coupling line can be reliably changed with an extremely simple configuration.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram of a first embodiment of the directional coupler of the present invention, FIG. 2 is a circuit diagram of a second embodiment of the directional coupler of the present invention, and FIG. , FIG. 4 is a circuit diagram of a fourth embodiment of the directional coupler of the present invention, and FIG. 5 is a circuit diagram of a fourth embodiment of the directional coupler of the present invention. There is a block circuit diagram showing an APC circuit which is an example of the application of a directional coupler. Fig. 6 is a circuit diagram showing the basics of a directional coupler, and Fig. 7 is a circuit diagram showing the basics of a directional coupler. This is an example circuit diagram, and FIG. 8 is a circuit diagram 1 of another example of a conventional directional coupler. 1. High frequency signal source, 2. Transmission line, 3.3a, 3b: Coupling line, 4.5.6. High frequency switch, 7. Terminating resistor, 8, 9.10: Resistor, 11. Switching circuit, 12: Antenna, 13: Terminal. Figure 5 Figure 6 Yゝ41

Claims (2)

[Claims] (1) A coupling line is provided in close proximity to the high-frequency signal transmission path, a switch means and a resistor connected to the switch means are provided on the coupling line, and this resistor is grounded to constitute a directional coupler; A directional coupler characterized in that the degree of coupling between the transmission line and the coupling line is switched by switching a switch means. (2) The directional coupler according to claim 1, wherein the switch means is switched in conjunction with switching the output of the high-frequency signal transmitted through the transmission line.