JPH07297606A - S/n enhancer - Google Patents

Abstract

PURPOSE:To provide an S/N enhancer which has a wide operating frequency band. CONSTITUTION:An S/N enhancer 10 includes a 1st 90 deg.-hybrid 20, and the 1st output terminal of the hybrid 20 is connected to the input terminal of a limiter consisting of a magnetostatic wave element 62a applying a surface magnetostatic wave mode. Then the 2nd output terminal of the hybrid 20 is connected to the input terminal of a filter consisting of a magnetostatic wave element 62b that has the same structure as the element 62a via a resistor 32 serving as a 1st attenuator. The output terminal of the limiter is connected to the input terminal of a 2nd 90 deg.-hybrid 40 via a resistor 52 serving as a 2nd attenuator. Furthermore the output terminal of the filter is connected to the 2nd input terminal of the hybrid 40.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an S / N enhancer, and more particularly to a S / N enhancer which has a limiter for limiting the amplitude of the main signal in the input signal and which has a ratio (S / N) is improved, and for example, the present invention relates to an S / N enhancer used for satellite broadcast reception.

[0002]

2. Description of the Related Art An example of a conventional S / N enhancer is disclosed in JP-A-4-123502. FIG. 11 is a circuit diagram showing an example of such a conventional S / N enhancer. The S / N enhancer 1 shown in FIG. 11 includes an input terminal 2. The input terminal 2 is connected to the input end of a directional coupler 3 as a distributor. This directional coupler 3 has an input terminal 2
It is for distributing the input signal input to the high level signal having the same level as the input signal and the low level signal attenuated by, for example, about 30 dB.

Two output terminals of the directional coupler 3 are provided with two magnetostatic wave filters 4 and 5 utilizing a surface magnetostatic wave mode.
Are respectively connected to the input terminals of. These magnetostatic wave filters 4 and 5 have similar frequency-selective nonlinear amplitude limiting characteristics. The frequency-selective non-linear amplitude limiting characteristic means that even if the signal of a certain frequency f ₁ exceeds the saturation level and is subject to amplitude limitation, a signal of a frequency f ₂ different from the frequency f ₁ is below the saturation level. Then, the signal of the frequency f _{2 has} a characteristic that the amplitude is not limited. That is, the frequency-selective non-linear amplitude limiting characteristic is a characteristic in which the amplitude limiting due to the saturation operation that occurs when the signal exceeds the saturation level occurs independently at each frequency. The magnetostatic wave filter 4 is used as a limiter for limiting the amplitude of the high-level main signal in the high-level signal output from the directional coupler 3. The other magnetostatic wave filter 5 is used to pass the low level signal output from the directional coupler 3.

The output end of the magnetostatic wave filter 4 is connected to the input end of the attenuator 6. The attenuator 6 is for attenuating the level of the signal output from the magnetostatic wave filter 4. The output end of the other magnetostatic wave filter 5 is connected to the input end of the delay line 7. This delay line 7
This is for delaying the phase of the signal output from the magnetostatic wave filter 5. Further, the output end of the attenuator 6 and the output end of the delay line 7 are connected to the directional coupler 8 as a combiner.
Connected to each of the two input terminals. This directional coupler 8
Is for attenuating the level of the signal output from the attenuator 6 and synthesizing the signal whose level is attenuated and the signal output from the delay line 7. Also, the directional coupler 8
The output terminal of is connected to the output terminal 9.

Therefore, in this S / N enhancer 1, the first signal path is formed between the input terminal 2 and the output terminal 9 by the directional coupler 3, the magnetostatic wave filter 4, the attenuator 6 and the directional coupler 8. The directional coupler 3, the magnetostatic wave filter 5, the delay line 7 and the directional coupler 8 constitute a second
Signal path is configured.

In the S / N enhancer 1, when an input signal including a main signal having a high level and noise having a different frequency and a low level from the main signal is input to the input terminal 2, the input signal is input. Is a high-level signal of approximately the same level as the input signal by the directional coupler 3,
It is distributed to a low level signal attenuated by about 0 dB. In this case, the high-level signal includes high-level main signals having different frequencies and low-level noise, and the low-level signal includes low-level main signals having different frequencies and further low-level noise.

On the other hand, in the magnetostatic wave filter 4, the main signal in the high-level signal has a high level and thus is limited in amplitude. However, the noise in the high-level signal has a frequency different from the frequency of the main signal and a low level. No restrictions. On the other hand, in the other magnetostatic wave filter 5, the main signal and noise in the low-level signal are both low in level and therefore not subject to amplitude limitation. The levels of the high-level signal and the low-level signal are slightly attenuated due to the insertion loss in the magnetostatic wave filters 4 and 5.

The level of the signal output from one magnetostatic wave filter 4 is attenuated by the attenuator 6, and the phase of the signal output from the other magnetostatic wave filter 5 is the delay line 7.
Delayed by. The level of the signal output from the attenuator 6 is attenuated by the directional coupler 8,
The signal whose level is attenuated and the signal output from the delay line 7 are combined. In this case, the level of the signal output from the magnetostatic wave filter 4 is attenuated by the attenuator 6 so that the noises in the two signals synthesized by the directional coupler 8 have the same level and opposite phases. The phase of the signal output from the magnetostatic wave filter 5 is delayed by the delay line 7. Therefore, the noise passing through the first signal path including the magnetostatic wave filter 4 and the noise passing through the second signal path including the magnetostatic wave filter 5 are canceled in the directional coupler 8. Further, the main signal passing through the first signal path is subjected to amplitude limitation by the magnetostatic wave filter 4, while the main signal passing through the second signal path is not subjected to amplitude limitation by the magnetostatic wave filter 5. Therefore, at the output terminal or the output terminal 9 of the directional coupler 8, a main signal corresponding to the amount of which the amplitude is limited can be obtained. Therefore, with this S / N enhancer 1, the S / N of the input signal is improved.

In addition, in this S / N enhancer 1, S / N
The minimum level of the input signal that can improve N is -12 dBm.
And the level of the input signal that starts to improve the S / N is -1.
Since it is 9 dBm and the difference between these levels is as small as 7 dB, a great effect can be obtained, for example, in improving the S / N during satellite broadcast reception.

[0010]

However, this S / N
Since the enhancer 1 uses the delay line 7 to set the phase difference between the first signal path and the second signal path to 180 degrees,
The operating frequency band with a desired enhancement amount, for example, 20 dB or more, is as narrow as about 100 MHz (Toshihiro Nomoto,
"S / N Enhancer Using Two MSSW Filters and Its Application," IEICE Technical Report, MW91-99, pp. 15-2
1 (1991)). Therefore, this S / N enhancer 1
Then, about 3 which is the whole band of satellite broadcasting reception in Japan.
It cannot cover the 00 MHz band. Therefore, the S / N enhancer 1 cannot collectively improve the S / N of signals of all channels for satellite broadcasting reception in Japan.

Further, in the S / N enhancer 1, since the operating frequency band is narrow as described above, when the temperature changes, the operating frequency band fluctuates and tends to deviate from the frequency actually desired to be used. It is difficult to adjust the operating frequency band so that the operating frequency falls within the operating frequency band, and it takes a long time of, for example, 2 to 3 hours to adjust the operating frequency band.

Therefore, a main object of the present invention is to provide an S / N enhancer having a wide operating frequency band.

[0013]

According to the present invention, an input signal including a main signal has a first phase difference in a wide band.
Of the first hybrid for distributing to the first signal and the second signal, and the first hybrid provided after the first hybrid.
A limiter for limiting the amplitude of the main signal in the signal of
It is provided after the limiter and the first hybrid,
A second hybrid for combining the signal output from the limiter and the second signal output from the first hybrid with the second phase difference in a wide band, and the first phase difference and the second hybrid It is an S / N enhancer whose sum with the phase difference is (2n + 1) × 180 degrees (n = 0, 1, 2, 3, ...).

In the S / N enhancer according to the present invention, the first hybrid and the second hybrid are, for example, the first 90-degree hybrid and the second hybrid.
90 degree hybrid, 0 degree hybrid and 180 degree
A degree hybrid, or a 180 degree hybrid and a 0 degree hybrid can be used. The first
It is preferable to use a 90-degree hybrid as each of the second hybrid and the second hybrid for the reason described below.

Further, in the S / N enhancer according to the present invention, a filter such as a low-pass filter, a high-pass filter, a band-pass filter or a band-elimination filter which is composed of a magnetostatic wave element can be used as the limiter. It is preferable to use a magnetostatic wave device for the limiter for the reason described below. In this case, it is more preferable to use a magnetostatic wave element using a surface magnetostatic wave mode as the magnetostatic wave element for the reason described later.

Further, the S / N enhancer according to the present invention is provided between the first hybrid and the second hybrid to match the noise levels in the two signals synthesized by the second hybrid. It is preferable to include the level adjusting means for the reasons described below. The level adjusting means is provided, for example, between the first hybrid and the second hybrid, and is provided with a first attenuator for attenuating the level of the second signal output from the first hybrid. A filter provided between the first attenuator and the second hybrid, having an input / output characteristic similar to that of the limiter, for passing a signal output from the first attenuator, the limiter and the second And a second attenuator for attenuating the level of the signal output from the limiter.

That is, as the S / N enhancer according to the present invention, for example, a first signal for distributing an input signal including a main signal into a first signal and a second signal having a phase difference of 90 degrees in a wide band. And a limiter for limiting the amplitude of the main signal in the first signal, which is provided in the subsequent stage of the first 90-degree hybrid and uses the magnetostatic wave element using the surface magnetostatic wave mode. A first attenuator provided after the first 90-degree hybrid for attenuating the level of the second signal, and a magnetostatic wave using a surface magnetostatic wave mode provided after the first attenuator. An element is used and has an input / output characteristic similar to that of a limiter, and is provided with a filter for passing the signal output from the first attenuator and a limiter of the signal output from the limiter, which is provided after the limiter. A second attenuator for attenuating the Le, provided after the second attenuator and the filter,
A second 90-degree hybrid for combining the signal output from the second attenuator and the signal output from the filter with a phase difference of 90 degrees in a wide band;
The level of noise in the two signals combined by the 90 degree hybrid is matched by the first attenuator, the filter and the second attenuator, and the phase difference between the two signals combined by the second 90 degree hybrid. By the first 90 degree hybrid and the second 90 degree hybrid (2n +
1) × 180 degrees (n = 0, 1, 2, 3, ...) S / N enhancers are preferred.

[0018]

The main signal and the noisy input signal are distributed by the first hybrid into a first signal and a second signal having a first phase difference in a wide band. In this case, the first signal and the second signal each include a main signal and noise.

The main signal in the first signal is limited in amplitude by the limiter.

Further, the signal output from the limiter and the second signal output from the first hybrid are the second
Of the second phase difference in the wide band. In this case, the sum of the first phase difference and the second phase difference is (2n + 1) × 180 degrees (n = 0, 1, 2,
3, ...). Therefore, the two signals combined by the second hybrid have opposite phases in a wide band.

Therefore, the noise in the two signals combined by the second hybrid is canceled in the wide band. Further, at the output end of the second hybrid, the main signal corresponding to the amount of which the limiter has limited the amplitude is obtained.

[0022]

According to the present invention, since the phases of the two signals synthesized by the second hybrid are opposite to each other in a wide band, the operating frequency band in which the desired enhancement amount is, for example, 20 dB or more is wide band, for example, approximately. An S / N enhancer of 350 MHz is obtained. Therefore, in the S / N enhancer according to the present invention, if it is used for satellite broadcast reception, it is possible to completely cover the entire band of satellite broadcast reception in Japan of about 300 MHz.

Further, since the S / N enhancer according to the present invention has a wide operating frequency band, even if the operating frequency band fluctuates when the temperature changes, the S / N enhancer does not easily deviate from the actually used frequency and also operates. It is easy to adjust the operating frequency band so that the used frequency falls within the frequency band, and it takes only a short time to adjust the operating frequency band.

In the present invention, when 90-degree hybrids are used as the first hybrid and the second hybrid, respectively, similar hybrids may be prepared as the first hybrid and the second hybrid. The production efficiency of the hybrid and the second hybrid is improved.

Further, in the present invention, when the magnetostatic wave element is used for the limiter, the signal of a wider band is subjected to the amplitude limitation by the limiter, so that the signal of a wider band can be dealt with.

In the present invention, if the magnetostatic wave element using the surface magnetostatic wave mode is used as the limiter, the minimum level of the main signal whose amplitude is limited by the limiter, that is, the saturation level of the limiter becomes low, so that the main signal Even if the level is low, the S / N of the input signal can be improved.

Further, in the present invention, when the level adjusting means is included, the level adjusting means matches the noise levels in the two signals synthesized by the second hybrid, so that the noises are further reduced. Can be offset. Therefore, the S / N can be further improved.

The above-mentioned objects, other objects, features and advantages of the present invention will become more apparent from the following detailed description of the embodiments with reference to the drawings.

[0029]

1 is a plan view showing an embodiment of the present invention, and FIG. 2 is a front view thereof. This S / N enhancer 1
0 includes, for example, a rectangular substrate 12 made of a dielectric such as synthetic resin or ceramic.

The substrate 12 has four through holes 14
a, 14b, 14c and 14d are formed. In this case, the two through holes 14a and 14c are
2 is formed slightly from the center in the longitudinal direction from one end, and another two through holes 14b and 14d are
It is formed slightly from the center in the longitudinal direction of the substrate 12 to the other end. The through hole 14a is formed in the vicinity of one long side of the substrate 12, and the through hole 14b is formed slightly from the center of the substrate 12 in one long side.
The through hole 14c is formed slightly from the center of the substrate 12 to the other long side, and the through hole 14d is formed to the substrate 12
Is formed in the vicinity of the other long side of the.

On one main surface of the substrate 12, a first 90-degree hybrid 20, for example, is formed as a first hybrid from one end in the longitudinal direction to the center side. The first 90 degree hybrid 20 includes two line electrodes 22 and 24, for example in the shape of a crank.

One of the line electrodes 22 has a wide one end side portion 22a extending from one end in the longitudinal direction of the substrate 12 along one long side, an intermediate portion 22b extending parallel to the short side of the substrate 12, and the substrate The other end side portion 22c is wide and extends along the other long side of 12. As shown in FIGS. 3 and 4, the intermediate portion 22b of the line electrode 22 includes two thin line portions 22b1 and 22b2 which are arranged in parallel at a distance from each other. One line portion 22b1 is formed to extend from the one end side portion 22a, and the other line portion 22b2 is formed to extend from the other end side portion 22c. Further, both ends of the one line portion 22b1 are provided on both ends of the other line portion 22b2, for example, two U-shaped lead wires, for example, gold wires and aluminum wires 23a and 2a.
3b are electrically connected to each other by, for example, a wire bonding method.

As shown in FIG. 1, the other line electrode 24 is parallel to the short side of the substrate 12 and a wide one end side portion 24 a extending from one end side in the longitudinal direction of the substrate 12 along the other long side. And a wide end portion 24c extending along one long side of the substrate 12 to the vicinity of the through hole 14a. As shown in FIGS. 3 and 4, the intermediate portion 24b of the line electrode 24 includes, for example, three thin line portions 24b1, 24b2, and 24b3 that are formed in parallel with each other at intervals. One line portion 24b1 is formed between the two line portions 22b1 and 22b2 of the line electrode 22 and extends from the one end side portion 24a to the other end side portion 24c.
Further, the other two line parts 24b2 and 24b3 are
On both sides of the line parts 22b1 and 22b2, the line parts 24b1 are formed to extend from the one end side part 24a and the other end side part 24c and have a length of one half of the line part 24b1. In addition, the line portion 2 is provided at the center of the line portion 24b1 in the longitudinal direction.
The tips of 4b2 and 24b3 are electrically connected by, for example, two U-shaped lead wires, for example, gold wires and aluminum wires 25a and 25b, respectively, by a wire bonding method, for example.

At one end side portion 24a of the line electrode 24,
As shown in FIG. 1, one end of a resistor 26 of, for example, 50Ω is connected as a terminator. The other end of this resistor 26 is grounded.

The first 90-degree hybrid 20 described above is
Input signal including main signal and noise is 1.4G
It is for distributing to the 1st signal and 2nd signal which have a 90 degree phase difference in the wide band of Hz-2.4 GHz. In this case, in the first 90-degree hybrid 20, the one end side portion 22a of the line electrode 22 is used as the input end, the other end side portion 24c of the line electrode 24 is used as the first output end, and the line electrode 22 The other end side part 2
2c is used as the second output terminal. Then, the input signal input to the input terminal is distributed to the first signal and the second signal having a level that is ½ of the level of the input signal at the first output terminal and the second output terminal. . The second
The phase of the signal of 1 lags the phase of the first signal by 90 degrees.

Further, on one main surface of the substrate 12, for example, an L-shaped lead-out electrode extends from the vicinity of the other end side portion 22c of the one line electrode 22 of the first 90-degree hybrid 20 to the vicinity of the through hole 14c. 30 is formed. Then, the other end side portion 22c and the extraction electrode 3
0 is, for example, a resistor 3 of 50Ω as the first attenuator.
Both ends of 2 are connected respectively. The resistor 32 is for attenuating the level of the second signal output from the second output end of the first 90-degree hybrid 20 by, for example, 30 dB.

A second 90-degree hybrid 40, for example, is formed as a second hybrid on one main surface of the substrate 12 from the center side in the longitudinal direction to the other end. This second 90 degree hybrid 40 is
It has the same structure as the hybrid 20.

That is, the second 90-degree hybrid 40
Includes two line electrodes 42 and 44, for example in the form of cranks.

The one line electrode 42 has a wide one end side portion 42a extending along one long side of the substrate 12, an intermediate portion 42b extending parallel to the short side of the substrate 12, and the substrate 1
A wide end portion 42c extending along the other long side of 2
Consists of. The intermediate portion 42b of the line electrode 42 is
As shown in FIGS. 3 and 4, two thin line portions 42b1 and 42b are arranged in parallel with each other at a distance.
Including 2. One line portion 42b1 is one end side portion 42a
And the other line portion 42b2 is formed to extend from the other end side portion 42c. Further, both ends of one line portion 42b1 are electrically connected to both ends of the other line portion 42b2 by, for example, two U-shaped lead wires, for example, gold wires or aluminum wires 43a and 43b, respectively, by a wire bonding method, for example. Connected by.

As shown in FIG. 1, the other line electrode 44 has a wide one end side portion 44a extending from the vicinity of the through hole 14d along the other long side of the substrate 12, and the substrate 12
A middle portion 44b extending parallel to the short side of the substrate 12 and a wide end 44c extending along one long side of the substrate 12. The intermediate portion 44b of the line electrode 44 is shown in FIG.
As shown in FIG. 4 and FIG. 4, for example, three thin line portions 44b1 and 44b which are formed in parallel with each other at intervals.
2 and 44b3. One line portion 44b1 is
Two line portions 42b1 and 42b of the line electrode 42
Between the two, one end side portion 44a to the other end side portion 44c
Is formed to extend. In addition, another two line portions 44b
2 and 44b3 are line portions 42b1 and 42b2.
On the outer side of the one end side portion 44a and the other end side portion 4
It extends from 4c and is formed to be half the length of the line portion 44b1. Further, at the center of the line portion 44b1 in the longitudinal direction, the tips of the line portions 44b2 and 44b3 are
For example, two U-shaped lead wires, for example, gold wires and aluminum wires 45a and 45b are electrically connected by, for example, a wire bonding method.

At the other end portion 42c of the line electrode 42,
As shown in FIG. 1, one end of a resistor 46 of, for example, 50Ω is connected as a terminator. The other end of this resistor 46 is grounded.

The second 90 degree hybrid 40 described above
The two input signals are, for example, 1.4 GHz to 2.4
This is for synthesizing with a phase difference of 90 degrees in a wide band of GHz. In this case, the second 90 degree hybrid 4
At 0, the one end side portion 42a of the line electrode 42 is used as the first input end, and the one end side portion 44 of the line electrode 44 is used.
a is used as the second input end, and the other end side portion 44c of the line electrode 44 is used as the output end. Then, the first input end of the second 90-degree hybrid 40 and the second
The two signals input to the input terminal of are combined at the output terminal. When the two signals are combined, the phase of the signal input to the second input end lags the phase of the signal input to the first input end by 90 degrees.

Further, on one main surface of the substrate 12, for example, an L-shaped lead electrode 50 extending from the vicinity of the one end side portion 42a of the one line electrode 42 of the second 90-degree hybrid 40 to the vicinity of the through hole 14b. Is formed. Then, the one end side portion 42a and the extraction electrode 5
0 is, for example, a resistor 5 of 50Ω as a second attenuator.
Both ends of 2 are connected respectively. The resistor 52 is for attenuating the level of the signal input to the first input end of the second 90-degree hybrid 40 by, for example, 30 dB.

On the other main surface of the substrate 12, four transducers 60a, 60b, 60c and 60d composed of four line electrodes are provided in the central portion in the longitudinal direction.
Through holes 14a, 14b, 14c and 14d
Is formed parallel to the long side of the substrate 12 from the vicinity. In this case, these transducers 60a, 60b, 60c
And one end of 60d has through holes 14a, 14b,
Through 14c and 14d, they are electrically connected to the other end side portion 24c of the line electrode 24, the extraction electrode 50, the extraction electrode 30, and the one end side portion 44a of the line electrode 44, respectively. In addition, these transducers 60a
The other ends of the ~ 60d are grounded.

On the other main surface of the substrate 12, one magnetostatic wave element 62a is mounted on the two transducers 60a and 60b, and the other magnetostatic wave element 62b is mounted on the other two transducers 60c and 60d. To be These magnetostatic wave elements 62a and 62b
Each include, for example, a strip-shaped GGG substrate, and a YIG thin film as a ferrimagnetic substrate is formed on one main surface of each of the GGG substrates. The magnetostatic wave elements 62a and 62b are respectively connected to the YIG
The surface of the thin film is attached so as to face the other main surface of the substrate 12. Magnetostatic wave absorbers 64 for absorbing unnecessary magnetostatic waves generated in the YIG thin film are formed on both ends of the surface of the YIG thin film in the longitudinal direction.

Further, on the other main surface of the substrate 12, permanent magnets 66a and 66b made of, for example, ferrite are attached to both sides of the magnetostatic wave elements 62a and 62b, respectively. In this case, the permanent magnets 66a and 66b
Between the transducers 60a-60
It is arranged so that a magnetic field is generated in the extending direction of d. Therefore, a magnetic field is applied to the magnetostatic wave elements 62a and 62b in the extending direction of the transducers 60a to 60d. Therefore, these magnetostatic wave elements 62a and 62
Each of b is a magnetostatic wave element using the surface magnetostatic wave mode.

The two transducers 60a,
60b, the magnetostatic wave element 62a, etc. are used as a limiter. This limiter has a frequency-selective nonlinear amplitude limiting characteristic. This limiter is for limiting the amplitude of the main signal in the first signal output from the first output end of the first 90-degree hybrid 20. In this case, in this limiter, one end of the transducer 60a is used as the input end and the transducer 60b is used.
Is used as an output terminal.

In addition, another two transducers 60
The c, 60d and the magnetostatic wave element 62b are used as a filter. Since this filter has the same structure as the above-mentioned limiter, it has the same input / output characteristics as the above-mentioned limiter. This filter is for passing an input signal. In this case, in this filter, one end of the transducer 60c is used as an input end and one end of the transducer 60d is used as an output end.

The other main surface of the substrate 12 covers the magnetostatic wave elements 62a and 62b and the permanent magnets 66a and 66b, and is made of a magnetic material and has a U-shaped cross section.
8 is attached. This yoke 68 is a permanent magnet 66.
This is for reducing the magnetic resistance between a and 66b and protecting the magnetostatic wave elements 62a, 62b and the permanent magnets 66a, 66b.

Therefore, this S / N enhancer 10
Has the circuit shown in FIG.

That is, in this S / N enhancer 10, the first output end of the first 90-degree hybrid 20 is
It is connected to the input terminal of a limiter using the magnetostatic wave element 62a. Further, the second output terminal of the first 90-degree hybrid 20 is connected to the input terminal of the filter using the magnetostatic wave element 62b via the resistor 32 as the first attenuator.
Further, the output terminal of the limiter is connected to the first of the second 90-degree hybrid 40 via the resistor 52 as the second attenuator.
Connected to the input end of. Further, the output end of the filter is connected to the second input end of the second 90-degree hybrid 40.

Therefore, in the S / N enhancer 10, between the input end and the output end, the first 90-degree hybrid 20, the limiter including the magnetostatic wave element 62a, the second attenuator including the resistor 52, and the second attenuator are provided. 90 of 2
The first signal path is composed of the hybrid 40,
The 90-degree hybrid 20, the first attenuator including the resistor 32, the filter including the magnetostatic wave element 62b, and the second 90-degree hybrid 40 form a second signal path.

Next, the operation of the S / N enhancer 10 will be described.

In this S / N enhancer 10, the input signal containing the main signal and the noise whose frequency is different from that of the main signal and whose level is low is the first 90-degree hybrid 2
0 input end, that is, one end side portion 22a of the line electrode 22
Input signal is input to the first and second signals having a 90-degree phase difference in a wide band of 1.4 GHz to 2.4 GHz by the first 90-degree hybrid 20. . In this case, the input signal is the first output of the first 90 degree hybrid 20 and the second output of the 90 degree hybrid 20.
At the output end of the input signal is divided into a first signal and a second signal having a level half that of the input signal. Also,
The first signal and the second signal each include a main signal and low-level noise. Furthermore, the phase of the second signal lags the phase of the first signal by 90 degrees.

The main signal in the first signal is the magnetostatic wave element 62.
Amplitude is limited by a limiter composed of a and the like. On the other hand, the noise in the first signal is different from the frequency of the main signal in the first signal and has a low level, so that the limiter does not limit the amplitude. The level of the first signal is slightly attenuated by the insertion loss of the limiter.

The level of the second signal is attenuated by 30 dB by the first attenuator including the resistor 32.

Furthermore, since the attenuated second signal has a low level, it passes through the filter including the magnetostatic wave element 62b. The attenuated second signal is slightly attenuated in level due to the insertion loss of the filter.

The level of the signal output from the limiter is 30 by the second attenuator composed of the resistor 52.
Attenuates by dB.

Then, the signal output from the second attenuator and the signal output from the filter are 1.4 GHz to 2.4 GHz by the second 90-degree hybrid 40.
Are combined with a phase difference of 90 degrees in a wide band of. In this case, the levels of noise in the two signals in the first signal path and the second signal path that are combined by the second 90-degree hybrid 40 are determined by the first attenuator, the filter and the first signal path as the level adjusting means. Matched by two attenuators.
Further, the phase difference between the two signals in the first signal path and the second signal path combined by the second 90-degree hybrid 40 is determined by the first 90-degree hybrid 20 and the second signal path.
90 degree hybrid 40 of 1 in wide band
80 degrees, that is, the opposite phase. Therefore, the second 9
The noise in the two signals in the first signal path and the second signal path that are combined in the 0 degree hybrid 40 is canceled in the wide band. Further, at the output end of the second 90-degree hybrid 40, the main signal corresponding to the amount of which the limiter has limited the amplitude is obtained.

In this S / N enhancer 10, the second 9
Since the two signals in the first signal path and the second signal path combined by the 0 degree hybrid 40 have opposite phases in the wide band, the wide band, for example, about 350M.
At Hz, the desired amount of enhancement, for example 20
An operating frequency band equal to or higher than dB is obtained. for that reason,
If this S / N enhancer 10 is used for satellite broadcast reception, it is possible to fully cover the entire band of satellite broadcast reception in Japan of about 300 MHz.

Further, since the S / N enhancer 10 has a wide operating frequency band, even if the operating frequency band fluctuates when the temperature changes, it does not easily deviate from the actually used frequency, and the operating frequency band is increased. It is easy to adjust the operating frequency band so that the used frequency falls within the range, and it takes only a short time to adjust the operating frequency band.

Further, in this S / N enhancer 10,
Since 90-degree hybrids are used as the first hybrid and the second hybrid, respectively, similar hybrids may be produced as the first hybrid and the second hybrid. Therefore, production of the first hybrid and the second hybrid is performed. Efficient.

Further, in the S / N enhancer 10, since the magnetostatic wave element is used as the limiter, the wideband signal is subjected to the amplitude limitation by the limiter, and the wideband signal can be dealt with.

In this S / N enhancer 10, since the magnetostatic wave element using the surface magnetostatic wave mode is used as the limiter, the minimum level of the main signal whose amplitude is limited by the limiter, that is, the saturation level of the limiter is low.
Even if the level of the main signal is low, the S / N of the input signal can be improved.

Further, in this S / N enhancer 10,
By the level adjusting means including the first attenuator, the filter and the second attenuator, the levels of the noises in the two signals combined in the second hybrid are matched with each other, and the noises are reliably canceled. be able to. Therefore, the S / N can be surely improved.

That is, in this S / N enhancer 10, the level of the input signal is set to 10 dB with reference to 10 dBm.
FIG. 6 shows the transmission characteristics when it is decreased at the B interval. Figure 6
As is clear from the graph shown in Fig. 6, in the S / N enhancer 10, the enhancement amount of 10 dB is about twice as wide as that of the conventional example, that is, about 600 MHz, and the enhancement amount of 20 dB is about 3.5 times as much as that of the conventional example. Each is obtained in a wide band of 350 MHz.

FIG. 7 shows the input / output characteristic of the S / N enhancer 10 at 1.9 GHz. As is clear from the graph shown in FIG. 7, in this S / N enhancer 10, the minimum level PH of the input signal capable of improving the S / N is −8 dBm, and the level of the input signal at which the S / N starts to be improved. Since PL is -17 dBm and the difference between the levels is as small as 9 dB, a great effect can be obtained, for example, in improving the S / N ratio during satellite broadcast reception.

Further, in this S / N enhancer 10,
The input level shown in FIG. 8 is 1.8 dB at 0 dBm, 1. GHz.
When input signals including three-wave signals of 95 GHz and 2.1 GHz are simultaneously input, the output signal shown in FIG. 9 is obtained. As is clear from the graphs shown in FIGS. 8 and 9, the S / N enhancer 10 has a noise of 10d at a frequency detuned by about 10 MHz from each signal.
Attenuated more than B, and S / N independently for each signal
You can see that the enhancer is working.

C when the S / N enhancer 10 is applied to satellite broadcast reception and when not applied.
The relationship between / N and S / N is shown in FIG. In this case, C /
The relationship between N and S / N was measured using a video signal having an average image level of 50%, that is, a video signal containing 50% of a signal for white and 50% of a signal for black. Figure 1
As is clear from the graph shown in FIG. 0, when the S / N enhancer 10 is applied to satellite broadcasting reception, the C / N enhancer is C compared to when the S / N enhancer is not applied to satellite broadcasting reception.
S / N can be improved by 2 to 8 dB when / N is 9 dB or less, and S / N is 0.5 dB even when C / N is 9 dB or more.
You can see that it can be improved.

As the first hybrid and the second hybrid, 90-degree hybrids are used in the above-mentioned embodiments, but in the present invention, 0-degree hybrids and 180-degree hybrids, or 18-degree hybrids are used.
Zero degree hybrids and zero degree hybrids may be used. In order to form a 0-degree hybrid or a 180-degree hybrid, two 90-degree hybrids may be used in consideration of their phase difference.

As the limiter, the magnetostatic wave element using the surface magnetostatic wave mode having the bandpass function is used as the limiter, but the magnetostatic wave element using the volume advancing magnetostatic wave mode or the volume receding magnetostatic wave mode is used. Magnetic wave element,
A filter such as a low-pass filter using a magnetostatic wave, a high-pass filter using a magnetostatic wave, or a band elimination filter using a magnetostatic wave may be used.

Further, as the level adjusting means, the first attenuator, the filter and the second attenuator are used in the above-mentioned embodiment, but instead of the first attenuator and the second attenuator, An attenuator may be provided before the first hybrid, an amplifier may be provided before the limiter, and an amplifier may be provided after the filter. Or first
An amplifier and an attenuator may be provided in the front stage of the hybrid, the front stage and the rear stage of the limiter, and the front stage and the rear stage of the filter, respectively.

The "90 degrees" and "18" referred to in the present invention
"0 degree" includes substantially the same range centered on the literal value in view of the object and effect of the present invention.

[Brief description of drawings]

FIG. 1 is a plan view showing an embodiment of the present invention.

FIG. 2 is a front view of the embodiment shown in FIG.

FIG. 3 is a plan view showing a main part of a first 90-degree hybrid (second 90-degree hybrid) used in the embodiment shown in FIG.

4 is a circuit diagram showing a main part of a first 90-degree hybrid (second 90-degree hybrid) used in the embodiment shown in FIG.

5 is a circuit diagram of the embodiment shown in FIG.

6 is a graph showing a transmission characteristic when the level of the input signal is reduced at 10 dB intervals with reference to 10 dBm in the embodiment shown in FIG.

7 is a graph showing input / output characteristics at 1.9 GHz in the example shown in FIG.

8 is a graph showing an example of an input signal input to the embodiment shown in FIG.

9 is a graph showing an output signal output from the embodiment shown in FIG. 1 when the input signal shown in FIG. 8 is input to the embodiment shown in FIG.

FIG. 10 is a graph showing the relationship between C / N and S / N when the embodiment shown in FIG. 1 is applied to satellite broadcast reception and when it is not applied.

FIG. 11 is a circuit diagram showing an example of a conventional S / N enhancer.

[Explanation of symbols]

 10 S / N enhancer 12 Substrate 14a-14d Through hole 20 First 90 degree hybrid 32 Resistor 40 Second 90 degree hybrid 52 Resistor 60a-60d Transducer 62a, 62b Magnetostatic wave element 66a, 66b Permanent magnet 68 Yoke

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Satoru Shinmura 2-26-10 Tenjin, Nagaokakyo-shi, Kyoto Inside Murata Manufacturing Co., Ltd. (72) Inventor Fumio Kanaya 2-26-10 Tenjin, Nagaokakyo-shi, Kyoto No. Stock Company Murata Manufacturing Co., Ltd. (72) Inventor Shinichiro Ichiguchi 2-26-10 Tenjin, Nagaokakyo City, Kyoto Prefecture Murata Manufacturing Co., Ltd. (72) Inventor Toshihito Umegaki 2-26 Tenjin, Nagaokakyo City, Kyoto Prefecture No. 10 Murata Manufacturing Co., Ltd. (72) Inventor Toshihiro Nomoto 1-10-11 Kinuta, Setagaya-ku, Tokyo Inside the Japan Broadcasting Corporation Broadcasting Technology Laboratory

Claims (7)

[Claims] 1. A first hybrid for distributing an input signal containing a main signal and a noise into a first signal and a second signal having a first phase difference in a wide band, and a first hybrid after the first hybrid. A limiter for limiting the amplitude of the main signal in the first signal, and a signal output from the limiter provided after the limiter and the first hybrid, and the first limiter.
A second hybrid for combining the second signal output from the hybrid of the second phase difference with a second phase difference in a wide band, and the sum of the first phase difference and the second phase difference is ( 2n +
1) An S / N enhancer that is 180 degrees (n = 0, 1, 2, 3, ...). 2. The first hybrid and the second
The S / N enhancer according to claim 1, wherein 90-degree hybrids are used as the respective hybrids. 3. The S / N enhancer according to claim 1, wherein a magnetostatic wave element is used for the limiter. 4. The S / N enhancer according to claim 3, wherein the magnetostatic wave element is a magnetostatic wave element utilizing a surface magnetostatic wave mode. 5. Further, there is provided level adjusting means provided between the first hybrid and the second hybrid for matching the levels of noises in two signals synthesized by the second hybrid. An S / N enhancer according to any one of claims 1 to 4, including. 6. The level adjusting means is provided between the first hybrid and the second hybrid, and is provided for attenuating a level of the second signal output from the first hybrid. One attenuator, which is provided between the first attenuator and the second hybrid, has the same input / output characteristics as the limiter, and allows the signal output from the first attenuator to pass therethrough. 6. The S / N enhancer of claim 5, further comprising: a filter, and a second attenuator provided between the limiter and the second hybrid for attenuating a level of a signal output from the limiter. 7. A first 90 degree hybrid for distributing an input signal containing a main signal and noise into a first signal and a second signal having a phase difference of 90 degrees in a wide band, the first 90 degree A limiter that is provided in the latter stage of the hybrid, uses a magnetostatic wave element that utilizes a surface magnetostatic wave mode, and is provided in the latter stage of the first 90-degree hybrid, for limiting the amplitude of the main signal in the first signal. A first attenuator for attenuating the level of the second signal, a magnetostatic wave element using a surface magnetostatic wave mode provided at a stage subsequent to the first attenuator, and similar to the limiter. A filter for passing a signal output from the first attenuator, the input / output characteristic of the filter being provided after the limiter to attenuate the level of the signal output from the limiter. The second attenuator and the second attenuator and the filter are provided after the second attenuator, and the signal output from the second attenuator and the signal output from the filter have a phase difference of 90 degrees in a wide band. At a level of noise in the two signals combined by the second 90-degree hybrid, the second 90-degree hybrid for combining the first attenuator, the filter, and the second attenuation. The phase difference between the two signals which are matched by the second 90 degree hybrid and combined by the second 90 degree hybrid by the first 90 degree hybrid and the second 90 degree hybrid.
S / N enhancer set to degrees (n = 1, 2, 3, ...).