JPS6338138B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an ultra-high frequency modulation/demodulation circuit that modulates or demodulates an ultra-high frequency signal, and particularly to an ultra-high frequency phase modulation/demodulation circuit using a strip line and a slot line.

2. Description of the Related Art Conventionally, there is a super high frequency phase modulation circuit as shown in FIG.

In the conventional slot line type modulation circuit shown in Fig. 1, 1 is an input terminal to which a carrier wave is applied, 2 is an output terminal where a modulated ultra-high frequency signal appears, and 3 is an input terminal to which a carrier wave is applied.
is an input terminal for a low frequency signal for modulation, 4 and 8 are strip lines, 5 is a through hole connecting the strip line 4 on one side of the dielectric substrate and the coplanar line 6 on the other side, 6 is a coplanar line, and 7 is a slot line. , 9 and 10 are diodes, and 11 is a low-pass filter (or band-pass filter), respectively. The polarity of the diode is changed so that when a positive voltage is applied to terminal 3 with respect to ground, diode 9 becomes conductive, and conversely, when a negative voltage is applied to terminal 3 with respect to ground, diode 10 becomes conductive. selected. Further, both A and B in FIG. 1 are λ/4.

In this circuit configuration, when a positive voltage is first applied to the terminal 3, the modulated signal current flows through the input terminal 3, the low-pass filter 11, the strip line 4, the through hole 5, the coplanar line 6, and the diode. 9
flowing through the branches of With this, the carrier signal becomes
The signal is transmitted to the input terminal 1, the strip line 4, the through hole 5, the coplanar line 6, the diode 9, the slot line 7, the strip line 8, and the output terminal 2 in this order.

On the other hand, when a negative voltage is applied to the terminal 3, the modulated signal current flows through the diode 10, the coplanar line 6, the through hole 5, the strip line 4, the low pass filter 11, and the branch of the input terminal 3. With this, the carrier signal is transmitted through the input terminal 1, the strip line 4, the through hole 5, the coplanar line 6,
The signal is transmitted to the diode 10, the slot line 7, the strip line 8, and the output terminal 2 in this order.

Therefore, when a positive voltage is applied to the terminal 3 and when a negative voltage is applied, the ultrahigh frequency signal appearing at the terminal 2 is caused by the action of the anti-phase branch circuit including the coplanar line 6 and the slot line 7. Therefore, they are in opposite phase to each other. Therefore, by changing the polarity of the voltage applied to terminal 3, the phase of the ultra-high frequency signal appearing at terminal 2 can be changed, and two-phase phase modulation is performed.

However, in the modulation circuit of FIG.
Since the voltage of the modulation signal applied to the modulation signal is with respect to ground, there is a drawback that a change in the reference potential causes a modulation amplitude error and a modulation phase error. Further, since the diodes 9 and 10 cannot be mounted on the surface of the dielectric substrate on which the strip lines 4 and 8 are formed, when integrating with other circuits, the external components are mounted on both sides. Therefore, there are disadvantages in that it is difficult to attach parts and inspect the mechanism.

The aim of the invention is to eliminate the above-mentioned drawbacks.

Embodiments of the present invention will be described below with reference to the drawings.

Referring to FIG. 2, a modulation circuit according to an embodiment of the present invention includes a first modulator having an electrical length of λ/2 (indicated by C in FIG. 2) formed on one surface of a dielectric substrate.
a first diode 9 having one end connected to one end of the first strip line 14, and a second diode having one end connected to the other end of the first strip line 14. 10 and
a second strip line 4 formed on the one surface of the dielectric substrate to which the other ends of the first and second diodes are connected; and a second strip line 4 formed on the other surface of the dielectric substrate. the first strip line 14 at the center position of the first strip line 14;
a slot line 7 that intersects with the slot line 7, and a slot line 7 formed on the one surface of the dielectric substrate.
and a third strip line 8 coupled to the third strip line 8.

The modulation circuit according to this embodiment uses a strip line 14 with an electrical length of λ/2 whose both ends are connected to one end of two diodes 9 and 10, respectively, and a slot line 7 which intersects with this strip line on the other side. The feature is that it forms a phase branch circuit.

That is, the input terminal 1 to which the carrier signal is applied is connected to one end of the strip line 4. Also,
An input terminal 3 for a modulating low frequency signal is connected to the strip line 4 via a low pass filter (or band pass filter) 11. The other end of this strip line 4 is connected to the anode of a diode 9. The cathode of this diode 9 is connected to one end of a strip line 14 having an electrical length of λ/2, which is a feature of the present invention. An input terminal 12 for a modulating low frequency signal is connected to this strip line 14 having an electrical length of λ/2 via a low pass filter (or band pass filter) 13.
The other end of the strip line 14 having an electrical length of λ/2 is connected to the anode of the diode 10. The cathode of this diode 10 is connected to the other end of the strip line 4. Further, at the center of the strip line 14 having an electrical length of λ/2, a slot line 7 is inserted which intersects the strip line 14 on the other side.
is configured. The output signal of this slot line 7 is guided to a strip line 8. The output terminal 2 is connected to the strip line 8. In FIG. 2, both A and B are λ/4.

When the potential of terminal 3 is higher than the potential of terminal 12, diode 9 becomes conductive;
The polarity of the diode is selected such that when the potential at is lower than the potential at terminal 12, diode 10 is conductive.

With this circuit configuration, when the potential of terminal 3 is higher than the potential of terminal 12, the modulation signal current is transmitted to input terminal 3, low-pass filter 11, strip line 4, diode 9, strip line 14,
It flows through a branch of the low-pass filter 13 and the input terminal 12. As a result, the carrier signal is transmitted to the input terminal 1, the strip line 4, the diode 9, the strip line 14, the slot line 7, the strip line 8, and the output terminal 2 in this order. Conversely, when the potential at terminal 3 is lower than the potential at terminal 12, the modulated signal current flows through input terminal 12, low-pass filter 13, strip line 14, diode 10, strip line 4, and low-pass filter. 11, flows through a branch of input terminal 3. As a result, the carrier signal is transmitted to input terminal 1,
Strip line 4, diode 10, strip line 14, slot line 7, strip line 8,
It is transmitted in order of output terminal 2.

When the potential of the input terminal 3 is higher or lower than the potential of the input terminal 12, the ultra-high frequency signal appearing at the output terminal 2 is transmitted through the strip line 1 of electrical length λ/2.
4 and a slot line 7 which is formed at the center and intersects with the slot line 7 on the other side, the lines are in opposite phases. Therefore, by changing the polarity of the potential difference between the modulation signals applied to input terminal 3 and input terminal 12, output terminal 2
It is possible to change the phase of the ultra-high frequency signal appearing in the , and two-phase phase modulation with balanced drive is performed. In this way, in the circuit of this embodiment, in order to selectively drive diodes 9 and 10, terminal 3 and terminal 1
The signal given to 2 may be a balanced signal unrelated to grounding.

Furthermore, the phase modulator shown in FIG. 2 directly serves as a phase demodulator. That is, it functions as a phase demodulator that detects the phase difference between the super high frequency signals applied to terminals 1 and 2. The demodulated outputs obtained at terminals 3 and 12 at this time are balanced signals.
Furthermore, even if terminal 1 and terminal 2 are used in reverse in FIG. 2, the same phase modulation and demodulation operation as described above can be performed.

Next, a modulation circuit according to another embodiment of the present invention shown in FIG. 3 will be explained. In Fig. 3, 1 is an input terminal to which a carrier wave is applied, 2 is an output terminal where a modulated ultra-high frequency signal appears, 3 and 12 are input terminals for a low frequency signal for modulation, 4, 8 and 14 are strip lines, and 7 is a Slot line, 9 and 10 are diodes,
11, 13 and 15 are low-pass filters (or band-pass filters), 16 and 17 are capacitors, and 18 is an output terminal for a modulating low-frequency signal, respectively.
An output terminal 18 for a low frequency signal for modulation is connected to the strip line 4 via a low pass filter 15.
This output terminal 18 is grounded. The modulation circuit of this embodiment is constructed by inserting capacitors 16 and 17 in the middle of a strip line 14 with an electrical length of λ/2 whose both ends are connected to one end of two diodes 9 and 10, respectively. The feature is that the diodes 9 and 10 can be driven independently.

In the circuit configuration shown in FIG. 3, when a positive voltage is applied to terminal 3 and a negative voltage is applied to terminal 12, and when a positive voltage is applied to terminal 12 and a negative voltage is applied to terminal 3, terminal 2 The appearing ultra-high frequency signals are reversed to each other by the action of an anti-phase branch circuit including a strip line 14 with an electrical length of λ/2 and a slot line 7 formed at the center thereof and intersecting this on the other side. It becomes the phase. Therefore, by changing the polarity of the voltage of the modulation signal applied to input terminal 3 and input terminal 12, the phase of the ultra-high frequency signal appearing at terminal 2 can be changed, and two-phase phase modulation is performed.

The phase modulator shown in FIG. 3 also serves as a phase demodulator as it is, as in the case of the phase modulator shown in FIG.

In addition, in FIGS. 2 and 3, various other coupling circuits can be considered for the output side slot line 7 and strip line 8. For example, the electrical length λ/4
By using an electrically open surface instead of the slot line (the part shown by B), and a through hole as shown in Fig. 1 instead of the strip line with an electrical length of λ/4 (the part shown by A). The same effect can be obtained.

According to the present invention, as explained above, the modulation/demodulation signal is a balanced signal and becomes a single signal unrelated to grounding. Therefore, modulation amplitude errors and modulation/demodulation phase errors do not occur due to changes in the reference potential of the modulation/demodulation signal, and operation accuracy can be significantly improved. Further, since the diode can be mounted on the surface on which the strip line is formed, when integrating with other circuits, the external components are mounted on one side. Therefore, it is possible to easily attach parts and inspect the mechanism.

[Brief explanation of the drawing]

FIG. 1 is a plan view showing a conventional ultra-high frequency modulation circuit, and FIGS. 2 and 3 are plan views showing an embodiment of the present invention. 1, 3, 12... Input terminal, 2, 18... Output terminal, 4, 8, 14... Strip line, 5...
Through hole, 6... Coplanar line, 7... Slot line, 9, 10... Diode, 11, 1
3,15...Low pass filter, 16,17...Capacitor.

Claims (1)

[Claims] 1 In an ultra-high frequency modulation/demodulation circuit that modulates or demodulates an ultra-high frequency signal, a first strip line with an electrical length of λ/2 (where λ is the wavelength of the ultra-high frequency signal handled) formed on one surface of a dielectric substrate. and,
a first diode having one end connected to one end of the first strip line; a second diode having one end connected to the other end of the first strip line; and one of the dielectric substrates. a second strip line formed on the surface of the dielectric substrate to which the other ends of the first and second diodes are connected; and a center of the first strip line formed on the other surface of the dielectric substrate. a slot line that intersects the first strip line at a position; and a third strip line formed on the one surface of the dielectric substrate and coupled to the slot line; A terminal for inputting or outputting a super high frequency signal is connected to the strip line No. 3, respectively, and a terminal for inputting or outputting a low frequency signal is connected to the first and second strip lines, respectively. Ultra-high frequency modulation/demodulation circuit.