JP3166807B2 - Switch circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switch circuit for switching an input signal to an arbitrary output and outputting the signal, and more particularly to a switch circuit having good isolation characteristics between a main signal and an unnecessary signal (leakage signal). .

[0002]

2. Description of the Related Art FIG. 10 shows a first configuration example of a conventional switch circuit. In FIG. 10, 100 ₁ , 100 ₂ ,
, 100 _M are M input terminals to which input signals having frequencies within a predetermined frequency band F _IN are input, respectively, and each input signal is supplied to the input / output controller 50. In _{addition, 200 1, 200 2, ...} , 200 N
Are N output terminals for outputting signals supplied from the input / output controller 50, respectively.

[0003] output controller 50, the input terminals 100 _1, ..., 100 connected to the _M a switch 2 _1, 2
_2, ..., and 2 _M, the output terminals 200 _1, ..., 200 connected to the _N synthesis unit 5 _1, 5 _2, ..., are provided with 5 _N. Reference numerals 3 and 3 are control input terminals for supplying a predetermined switching signal Sc to the input / output controller 50 from outside.

[0004] switch 2 _1, ..., each of 2 _M, and the corresponding connected to the input terminal 100 an input terminal 2IN, N number of output terminals 2OUT _1, ..., is provided with a 2OUT _N, The input terminal 2IN is connected to any one of the output terminals 2OUT based on the switching signal Sc supplied from the control input terminal 3. On the other hand, each of the synthesizers 5 ₁ ,.
Each of _N is, M number of input terminals 5IN _1, ..., and output connected 5OUT to the output terminal 100 and the corresponding 5IN _M is provided with, each of the input terminals 5IN _1, ..., a 5IN _M The input signals are combined and output from the output terminal 5OUT. Then, each switch 2 ₁ ,..., 2 _M
Each combiner 5 _1, ..., between 5 _N is, k-th (k =. 1 to
M) N output terminals of the switch 2 _k are connected to the respective combiners 5
₁ ,..., 5 _N are wired so as to be connected to the k-th input terminal among the M input terminals.

In the above configuration, the input terminals 100 ₁ ,
, 100 _M , a switching signal Sc for determining the output destination of these signals is sent from the control input terminals 3 and 3 to the input / output controller 5.
0 is supplied. In the input / output controller 50,
Based on the content of the switching signal Sc, the input terminal 2IN of each switch 2 to which the input signal is supplied and any one output terminal 2OU
T is connected.

In the switch 2 to which the input signal is supplied, a signal is output from an output terminal 2OUT connected to the input terminal 2IN, and the signal is supplied to a combiner 5 connected to the output terminal 2OUT. Next, in the combiner 5 to which a signal is supplied via one or more input terminals 5IN, the supplied signals are combined, and the combined signal is output to an output terminal 200 connected to the combiner 5. Supplied to

[0007] As an example, the case where the signal S2 inputted synthesized and inputted to the signal S1 to the input terminal 100 ₂ is outputted from the output terminal 200 ₁ to the input terminal 100 _1. In this case, so that the signal inputted to the input terminals 100 ₁ and 100 ₂ are supplied both to the combiner 5 _1, controls the control signal Sc for to switch the internal connection state of the switching device 2 ₁ and 2 _2, respectively From the input terminal 3. Thus, the signal S1 and switch 2 ₂ signal S2 supplied to the supplied to the switch 2 ₁ are both supplied to the synthesizer 5 _1, combined with the output terminal 200 ₁
Output from

[0008] As another example, from the output terminal 200 ₁ signal S1 input to the input terminal 100 _1, whereas, the case of outputting a signal S2 input to the input terminal 100 ₂ from the output terminal 200 _2. In this case, the signal input to the input terminal 100 ₁ is supplied to a combiner 5 _1, the internal connection state of the switching device 2 ₁ and 2 ₂ so that the signals input to the input terminal 100 ₂ is supplied to the synthesizer 5 ₂ Are input from the control input terminal 3 for switching the respective signals. Thus, signal S1 supplied to the switch 2 ₁ is supplied to a combiner 5 _1, is output from the output terminal 200 _1. On the other hand, the signal S2 supplied to the switch 2 ₂
Is supplied to a combiner 5 _2, is output from the output terminal 200 _2.

Next, FIG. 11 shows a second configuration example of a conventional switch circuit. 11, the same reference numerals are given to the same parts as those in FIG. 10, and the description thereof will be omitted. In FIG. 11, 8 ₁ ,..., 8 _M are frequency converters,
₁ ,..., 14 _M are filters. The frequency converters 8 ₁ ,
.., 8 _M each include a mixer 12 and a local frequency oscillator 13 that outputs a local oscillation signal having a predetermined frequency. This frequency is determined by each frequency converter 8 ₁ ,
... it is set with a predetermined frequency interval for each 8 _M, respectively frequencies f1, ..., and is set to fM. Hereinafter, these frequencies f1,..., FM are called local oscillation frequencies.

[0010] The mixer 12 of each frequency converter 8 mixes a signal having a frequency belonging to the frequency band F _IN input from the corresponding input terminal 100 and a local oscillation signal supplied from the local frequency oscillator 13. Outputs the input side intermediate frequency signal. The intermediate frequency signal contains a plurality of frequency components, and the filter 14 removes unnecessary frequency components out of the predetermined frequency band. Next, reference numeral 17 denotes a synthesizing / distributing unit, and each of the filters 14 ₁ ,..., 14 _M
Are combined at the same level and distributed to each of the frequency converters 21 ₁ ,..., 21 _N described below.

Each of the frequency converters 21 ₁ ,..., 21 _N has a frequency converter 7, a control circuit 16 and a filter 1.
1 is provided. The frequency converter 7 includes a mixer 9 and a variable frequency local oscillator 10. The control circuit 16 supplies the variable frequency local oscillator 10 with a control signal Sc for determining which input terminal 100 should output a signal. Variable frequency local oscillator 10, each of the frequency converter _81, ..., the local oscillation frequency f1 oscillated respectively at 8 _N, ..., a can oscillate a signal having the same frequency as one of fM, the control signal Sc
Outputs the same local oscillation signal as that of the frequency converter 8 connected to the input terminal 100 designated by.

The mixer 9 mixes the local oscillation signal output from the variable frequency local oscillator 10 with each input-side intermediate frequency signal supplied from the synthesizing / distributing unit 17 and outputs an output-side intermediate frequency signal. I do. That is, each frequency converter 7 is connected to the input terminal 1 designated by the control circuit 16.
From 00, the frequency of the input intermediate frequency signal input through the frequency converter 8, the filter 14, and the synthesizing / distributing unit 17 is converted to the original frequency and output. The frequency of the input-side intermediate frequency signal input via the frequency converter 8, the filter 14, and the combining / distributing unit 17 is converted to a frequency different from the original frequency and output.

Next, the filter 11 in each frequency converter 21 has a pass band characteristic corresponding to the above-mentioned frequency band F _IN , and out of the output-side intermediate frequency signals supplied from the frequency converter 7, , And passes only the signal converted to the original frequency to output to the output terminal 200. This second
In a broad sense, the configuration shown in the configuration example of FIG.
00 ₁ each to 100 _M side is connected the transmission circuit of a plurality of broadcast stations may correspond to the form in which the receiving circuit is connected respectively to the output terminals 100 ₁ to 100 _N side a plurality of receiving stations.

[0014]

In the first configuration example (see FIG. 10), the switches 2 ₁ ,..., 2 _M and the combiners 5 ₁ ,. , due to the influence of the distributed capacitance and electromagnetic induction and the like caused by the intersection line between the 5 _N, there is a problem that some of the signal leaks to the other wiring from the wiring to be originally pass. For example,
The signal S1 input to the input terminal 100 ₁ and the signal S2 input to the input terminal 100 ₂ are output from the output terminal 2
00 _1, 200 for the problem that arises when each from ₂ to output, will be described with reference to FIG. 12. FIG. 12 (a)
In each of the drawings (a) to (d), the horizontal axis represents the frequency, and the vertical direction (the vertical axis is omitted) represents the magnitude of the signal level.

[0015] Now, the signal S1 in the frequency band F _IN as shown in FIG. 12 (a) is input to the input terminal 100 _1, while the frequency band as shown in FIG. 12 (b) to the input terminal 100 _{2 Assuming} that the signal S2 in the FIN is input, these signals are transmitted to the switch 2 ₁ in the input / output controller 50,
2 ₂ is supplied to the synthesizer 5 _1, 5 ₂ via respectively.
Then, the synthesizer 5 _1, the signal as shown in FIG. 12 (c) is output. As shown in the figure, the signal to be originally outputted, namely, in addition to the main signal S1 'corresponding to the input signal S1, originally should be output from the synthesizer 5 _2, part of the signal S2 A certain leakage signal S2x 'is output. On the other hand, the synthesizer 5 _2, signals as shown in FIG. 12 (d) is output. Again, the signal to be originally outputted, namely, in addition to the main signal S2 'corresponding to the input signal S2, originally should be output from the synthesizer 5 _1,
A leakage signal S1x 'which is a part of the signal S1 is output.

The ratio between the level of the main signal and the level of the leakage signal obtained at each output terminal is defined as an "isolation value". That is, the higher the level of the main signal compared to the level of the leakage signal, the better the isolation characteristics. Here, as shown in FIGS. 12C and 12D, the level of the leakage signal is lower than the level of the main signal, but as the number of input / output terminals increases, the number of cross wirings increases, and the isolation characteristics deteriorate. There is a problem of doing. In order to improve this and improve the isolation characteristics, it is necessary to increase the spacing between the wirings and shield the wirings, so that the structure of the switch circuit becomes complicated and its size becomes large. There were drawbacks.

In the second configuration example (see FIG. 11), as described above, the combining / distributing section 17 combines a plurality of input-side intermediate frequency signals at the same level.
The synthesized signal is supplied to each of the frequency converters 21 ₁ ,..., 21 _{N. The} problem that occurs in this case will be described with reference to FIG. In each of FIGS. 13A and 13B, similarly to FIG. 12, the horizontal axis indicates frequency and the vertical direction indicates signal level.

Here, the input terminals 100 ₁ , 100 ₂ ,
Signals S1, S2, S3 are respectively supplied to the 100 _3,
A case where a signal corresponding to the signal S1 is output from the output terminal 2001 will be described. Each of the signals S1, S2, S
3 are converted into input-side intermediate frequency signals in the corresponding frequency converters 8. Then, after being combined into one signal in the combining / distributing section 17, each frequency converting section 21
_1, ..., it is distributed to 21 _N.

[0019] In the frequency converter 7 of the frequency converter 21 _1, the frequency of the supplied input intermediate frequency signal is converted by a local oscillation frequency f1, the output-side intermediate-frequency signal as shown in FIG. 13 (a) It is supplied to the filter 11 _1. As shown in the figure, signal component S1, corresponding to the signal S1 in the passband of the filter 11 ₁ ', The filter 1
Signal the location of the boundary between the 1 ₁ the passband and passband S2
Corresponding signal component S2 to 'is also the signal component S3 corresponding to the signal S3 outside the pass band of the filter 11 _1' is present.

Thus, the local oscillation frequencies f1, f2,
.., Depending on the set interval of...
Other unnecessary signals exist in the pass band of the filter 11. In this case, from the filter 11, FIG.
A signal as shown in (b) is output. As shown in the figure, of the signals S2 'and S3' to be removed, part of S2 'has passed through the filter 11 and is output to the output terminal 200 as a leakage signal. As a result, the above-described isolation characteristic of the switch circuit is reduced. In such a case, the following method can be considered to improve the isolation characteristics.

The set interval of the local oscillation frequencies f1 to fM in the frequency converters 8 ₁ to 8 _M on the input terminal side is set to the pass band width of the filter 11 provided in the frequency converters 21 _{1 to} 21 _N on the output terminal side. Take above. For example, in the case of FIG. 13, the set interval of the local oscillation frequency is set to twice the interval Df shown in the figure. From the operating band characteristics of the switch circuit, the local oscillation frequency f1
If it is not possible to widen the set interval of ｆfM, the frequency interval of the signals input to the frequency converters 21 _{1 to} 21 _N becomes narrower, so that it is necessary to use a narrow band filter 11.

In the above case, as the number of input / output terminals of the switch circuit increases, the frequency width from the local oscillation frequency f1 to the local oscillation frequency fM increases, and a wideband characteristic is required for the switch circuit. There are cases.
In the above case, the price of the filter is high because of the narrow band,
Alternatively, a filter having satisfactory characteristics may not be obtained. In each case, since the level of the unnecessary leak signal is equal to the level of the main signal, it is necessary to prepare a filter having a relatively large signal suppression amount outside the pass band.

Further, in the second configuration example, the synthesis /
Since each input signal is synthesized using the distribution unit 17 and then distributed to each frequency conversion unit 21, there is a disadvantage that the signal loss is large as compared with the first configuration example (see FIG. 10). Was. The present invention has been made in view of the above circumstances, and has as its object to provide a switch circuit that can improve the isolation characteristics between a main signal and a leakage signal and can be reduced in size as compared with the related art.

[0024]

According to a first aspect of the present invention, at least one input terminal and at least one output terminal are provided. A switching circuit that switches an input / output state so that each signal within a predetermined frequency band is output from any output terminal.
Command means for instructing each of the at least one output terminal to output each signal input to one of the input terminals; and oscillating at one of a plurality of types of frequencies corresponding to the number of the output terminals. Signal to be generated,
When an input signal is supplied from the predetermined input terminal, a signal having a frequency corresponding to the output terminal commanded by the command means is oscillated and mixed with the input signal, and the input signal is converted into a predetermined intermediate frequency signal. A frequency converting means for each input terminal to output the intermediate frequency signal output from the frequency converting means for each input terminal, a switching means for outputting the intermediate frequency signal to a path corresponding to the output terminal commanded by the command means, A signal having a frequency unique to the output terminal is oscillated and mixed with the signal output by the switching means, the intermediate frequency signal is converted into a signal in the predetermined frequency band before conversion, and an unnecessary leakage signal is converted into the predetermined frequency band. Frequency converting means for each output terminal, which converts the signal into a signal outside the frequency band and outputs the signal, and outputs only the signal within the predetermined frequency band among the signals output by the frequency converting means for each output terminal. It is characterized by comprising a filter for a given frequency band outputted to the output terminal means for commanding.

According to a second aspect of the present invention, in the first aspect of the present invention, the intermediate frequency for outputting only the predetermined intermediate frequency signal among the signals output by the frequency conversion means for each input terminal. It is characterized by having a band filter.

According to the third aspect of the present invention, the apparatus has an input terminal and an output terminal, and switches whether to output a signal in a predetermined frequency band input to the input terminal from the output terminal. In the switch circuit, command means for instructing whether to output a signal input to the input terminal to the output terminal, and a signal oscillating at any one of first and second frequencies can be generated, When an input signal is supplied from an input terminal, when the command means instructs to output a signal to an output terminal, a signal of a first frequency is oscillated and mixed with the input signal, and the input signal is converted to a first signal. When the command means instructs not to output the signal to the output terminal, the signal of the second frequency is oscillated and mixed with the input signal, and Is the second intermediate frequency signal An input terminal-side frequency converting means for converting and outputting, and a path corresponding to the output terminal for an intermediate frequency signal output by the input terminal-side frequency converting means only when the command means instructs to output a signal to an output terminal. Switching means for outputting the first intermediate frequency signal, and oscillating the signal of the first frequency to mix with the signal output by the switching means to convert the first intermediate frequency signal into a signal in the predetermined frequency band before conversion. Or, output terminal side frequency conversion means for converting the leakage component of the second intermediate frequency signal into a signal outside the predetermined frequency band and outputting the signal, and among the signals output by the output terminal side frequency conversion means, A filter for a predetermined frequency band that outputs only a signal within the predetermined frequency band to the output terminal. According to a fourth aspect of the present invention, in the third aspect of the present invention, an intermediate signal for outputting only the first or second intermediate frequency signal out of the signals output by the input terminal side frequency conversion means. It is characterized by having a frequency band filter.

Further, according to the invention of claim 5, it has an input terminal and an output terminal, and switches whether to output a signal within a predetermined frequency band input to the input terminal from the output terminal. In the switch circuit, command means for instructing whether to output a signal input to the input terminal to the output terminal, and a signal oscillating at a predetermined frequency can be generated, and an input signal is supplied from the input terminal. When done
When the command means instructs to output a signal to an output terminal, the signal of the predetermined frequency is oscillated and mixed with the input signal, and the input signal is converted into a predetermined intermediate frequency signal and output. When the command means instructs not to output a signal to an output terminal, an input terminal side frequency conversion means for outputting the input signal as it is as a signal within the predetermined frequency band, and the command means outputs a signal to an output terminal. Switching means for outputting a signal output by the input terminal-side frequency conversion means to a path corresponding to the output terminal only when instructed to output, a signal of a predetermined frequency which can be generated in the input terminal-side frequency conversion means Oscillates and mixes with the signal output by the switching means to convert the predetermined intermediate frequency signal into a signal within the predetermined frequency band before conversion, or An output terminal-side frequency conversion unit that converts unnecessary leakage signals in several bands into a signal outside the predetermined frequency band and outputs the signals, and among the signals output by the output terminal-side frequency conversion unit, A filter for a predetermined frequency band that outputs only a signal to the output terminal.

Further, according to the invention described in claim 6, there is provided at least one input terminal and at least one output terminal, and each of the signals within a predetermined frequency band inputted to each input terminal is any one of them. Command means for commanding which of the at least one output terminal each signal input to the at least one input terminal is output to in a switch circuit for switching an input / output state so as to be output from an arbitrary output terminal When an input signal is supplied from the predetermined input terminal, a signal having a frequency unique to the input terminal is oscillated and mixed with the input signal, and the input signal is converted into a predetermined intermediate frequency signal and output. Input terminal-dependent frequency conversion means, and the intermediate frequency signal output by each input terminal-specific frequency conversion means, to a path corresponding to the output terminal commanded by the command means. Switching means, and a signal oscillating at any of a plurality of types of frequencies corresponding to the number of the input terminals, and oscillating a signal having a frequency corresponding to the input terminal commanded by the command means. And the intermediate frequency signal is converted into a signal within the predetermined frequency band before conversion, and an unnecessary leakage signal is converted into a signal outside the predetermined frequency band and output. A frequency conversion means for each terminal, and a filter for a predetermined frequency band that outputs only a signal within the predetermined frequency band to an output terminal instructed by the command means among signals output by the frequency conversion means for each output terminal. It is characterized by:

[0029]

According to the first and second aspects of the present invention, when an input signal within a predetermined frequency band is supplied from a predetermined input terminal to a frequency conversion means for each input terminal, a plurality of types corresponding to the number of output terminals are provided. The signal of the frequency corresponding to the output terminal instructed by the instructing means is oscillated and mixed with the input signal, and the input signal is converted into a predetermined intermediate frequency signal and output. Then, each signal output from the input terminal frequency conversion means is output by the switching means to a path corresponding to the output terminal commanded by the command means, and is output to the output terminal frequency conversion means connected to the path. Supplied. In the frequency conversion means for each output terminal, a signal having a frequency unique to a predetermined output terminal is oscillated and mixed with the supplied signal, and the intermediate frequency signal is converted into a signal in a predetermined frequency band before conversion. At the same time, unnecessary mixed signals having frequencies outside the predetermined intermediate frequency band are converted into signals outside the predetermined frequency band and output. Then, by the filter for the predetermined frequency band, only the signal within the predetermined frequency band among the output signals is output to the output terminal designated by the command means. In this way, a low-leakage signal having a different frequency band from the main signal is finally easily removed through the filter for the predetermined frequency band. Therefore, the isolation characteristic between the main signal and the leakage signal is improved.

According to the third and fourth aspects of the present invention,
When an input signal within a predetermined frequency band is supplied from the input terminal to the input terminal side frequency conversion means, a signal of the first frequency is oscillated when the command means instructs to output the signal to the output terminal. The input signal is mixed with a signal, and the input signal is converted into a first intermediate frequency signal and output. On the other hand, when the command means instructs not to output the signal to the output terminal, the signal of the second frequency is oscillated and mixed with the input signal, and the input signal is converted into the second intermediate frequency signal and output. Is done. The intermediate frequency signal output from the input terminal side frequency conversion means is output to a path corresponding to the output terminal only when the command means instructs to output a signal to the output terminal, and the output terminal connected to the path is output. It is supplied to the side frequency conversion means. In the output terminal side frequency converter, a signal of the first frequency is oscillated and mixed with the supplied signal, and the first intermediate frequency signal is converted into a signal in a predetermined frequency band before conversion. Alternatively, the unnecessary leakage signal in the second intermediate frequency band is converted into a signal outside the predetermined frequency band and output. Then, only the signals within the predetermined frequency band out of the output signals are output to the output terminal by the predetermined frequency band filter. As described above, a low-level leakage signal having a different level in a frequency band, which is generated when a command to output no signal is issued, is finally easily removed via the filter for a predetermined frequency band.

According to the fifth aspect of the present invention, when an input signal within a predetermined frequency band is supplied from the input terminal to the input terminal side frequency conversion means, the command means instructs to output the signal to the output terminal. In this case, a signal of a predetermined frequency is oscillated and mixed with an input signal, and the input signal is converted into a predetermined intermediate frequency signal and output. On the other hand, when the command means instructs not to output a signal to the output terminal, the input signal is output as it is as a signal within a predetermined frequency band. The intermediate frequency signal output from the input terminal side frequency conversion means is output to a path corresponding to the output terminal only when the command means instructs to output a signal to the output terminal, and the output terminal connected to the path is output. It is supplied to the side frequency conversion means. In the output terminal side frequency conversion means, the signal of the predetermined frequency is oscillated and mixed with the supplied signal, or the predetermined intermediate frequency signal is converted into a signal in a predetermined frequency band before conversion, Alternatively, the unnecessary leak signal within the predetermined frequency band is converted into a signal outside the predetermined frequency band and output. And
By the filter for the predetermined frequency band, only the signal within the predetermined frequency band among the output signals is output to the output terminal. As described above, when it is instructed not to output a signal, the input signal is supplied to the output terminal side frequency conversion means in a through manner, and is converted into a signal in a predetermined intermediate frequency band, that is, a signal outside the predetermined frequency band. Therefore, it is finally easily removed through the filter for the predetermined frequency band.

According to the configuration of claim 6, when an input signal within a predetermined frequency band is supplied from the predetermined input terminal to the frequency conversion means for each input terminal, a signal having a frequency unique to the input terminal is supplied. Oscillated and mixed with the input signal, the input signal is converted into a predetermined intermediate frequency signal and output. Then, each signal output from the input terminal frequency conversion means is output by the switching means to a path corresponding to the output terminal commanded by the command means, and is output to the output terminal frequency conversion means connected to the path. Supplied. In the output terminal frequency conversion means, of a plurality of types of frequencies corresponding to the number of each input terminal, a signal of a frequency corresponding to the input terminal commanded by the command means is oscillated and mixed with the supplied signal, The intermediate frequency signal is converted into a signal within a predetermined frequency band before conversion, and unnecessary leakage signals are converted into signals outside the predetermined frequency band and output. Then, by the filter for the predetermined frequency band, only the signal within the predetermined frequency band among the output signals is output to the output terminal designated by the command means.
In this way, a unique local oscillation frequency is set for the frequency conversion means on each input terminal side, and the local oscillation frequency in each frequency conversion means on each output terminal side is set to a local oscillation frequency corresponding to the input destination of the supplied signal. By combining
The isolation characteristics between the main signal and the leakage signal can be improved.

[0033]

An embodiment of the present invention will be described below with reference to the drawings. <First Embodiment> FIG. 1 is a diagram showing a configuration of a switch circuit according to a first embodiment of the present invention.
The same reference numerals are given to the parts common to the respective parts, and the description thereof will be omitted. In FIG. 1, a control circuit 15 sets an output destination of an input signal supplied to each of the input terminals 100 _{1 to} 100 _M , and specifies a local oscillation frequency in each of the frequency converters 7 ₁ ′ to 7 _M ′. Sc1 to ScM are supplied to these frequency converters 7 ', and a control signal Sc for setting the internal connection mode of the switch 2 in the input / output controller 50 is supplied to the input / output controller 50 in accordance with the setting contents.

The frequency converters 7 ₁ ′ to 7 _M ′ have the same configuration as the frequency converter 7 shown in FIG. 11, and the variable frequency local oscillator 10 in each frequency converter 7 ′ can be set. .., FN, a local oscillation signal having a frequency corresponding to the output destination indicated by the control signal Sc supplied from the control circuit 15 is output.
Here, the local oscillation frequencies f1,..., FN are set at predetermined frequency intervals, and the frequency intervals are set to be equal to or greater than the pass band of the filter 24 connected to each output terminal 200. I have.

The mixer 9 of each frequency converter 7 'mixes the signal supplied from the corresponding input terminal 100 with the local oscillation signal supplied from the variable frequency local oscillator 10, and outputs an input-side intermediate frequency signal. . The reason why the input signal is converted into the intermediate frequency signal is to receive a desired signal on the output side (to be described later in detail) and to adapt to the operating frequency band inside the switch circuit.

Next, 8 ₁ ′ to 8 _N ′ are frequency converters having the same configuration as the frequency converter 8 shown in FIG. In each frequency converter 8 ′, the input intermediate frequency signal supplied via the corresponding synthesizer 5 and the local frequency oscillator 1
The mixer 12 mixes the local oscillating signal output from the mixer 3 with an output side intermediate frequency signal. Here, the local frequency oscillators 13 of the respective frequency converters 8 ₁ ′ to 8 _N ′ output signals of local oscillation frequencies f 1,..., F N, respectively. Therefore, the frequency of the input intermediate frequency signal supplied to the mixer 12 is converted to the original frequency. 24 _{1 to} 24
_N is a filter having a pass band characteristic corresponding to the frequency band F _IN .

Next, the operation of this embodiment will be described with reference to FIG. Here, the output terminal 200 ₁ signal S1 to be input to the input terminal 100 _1, illustrating a case of outputting a signal S ₂ to be input to the input terminal 100 ₂ to the output terminal 200 ₂ as an example. In each of FIGS. 2A to 2H, the horizontal axis represents frequency, and the vertical direction (vertical axis is omitted) represents the signal level.

[0038] When the signal S1 as shown in FIG. 2 (a) is inputted to the input terminal 100 _1, the signal S1 is supplied to a mixer 9 of the frequency converter 7 ₁ ', a variable frequency local oscillator 1
0 and mixed with the signal supplied to the mixer 9. Here, based on the control signal Sc1 from the control circuit 15, the oscillation frequency of the variable frequency local oscillator 10 is changed to the output terminal 200.
_The local oscillation frequency f1 corresponding to ₁ is set.

On the other hand, when the signal S2 as shown in FIG. 2 (b) is inputted to the input terminal 100 _2, the signal S2 is supplied to a mixer 9 of the frequency converter 7 ₂ ', from the variable frequency local oscillator 10 The signal is mixed with the signal supplied to the mixer 9. Here, based on the control signal Sc2 from the control circuit 15, the oscillation frequency of the variable frequency local oscillator 10 is set to the local oscillation frequency f2 corresponding to the output terminal 200 _2.

Then, the input side intermediate frequency signal S1j as shown in FIG. 2C is output from the mixer 9 of the frequency converter 7 ₁ ′. On the other hand, the mixer 9 of the frequency converter 7 ₂ ′ outputs an input-side intermediate frequency signal S 2 j as shown in FIG. 2D.

The input side intermediate frequency signal S1j is supplied to the control circuit 15
Input / output controller 50 based on a control signal Sc from
It is supplied from the switch 2 ₁ of the inner to the combiner 5 _1, combiner 5 ₁
Outputs a signal as shown in FIG. As shown in the figure, the output from the combiner 5 _1, a main signal S1
In addition to j, the signal to be outputted from the original synthesizer 5 ₂ S2j
, A signal S2x having a low level as a leakage component is included. The reason that the leakage signal from another path is mixed in addition to the main signal is due to the influence of the cross wiring in the input / output controller 50 and the like.

On the other hand, the input-side intermediate frequency signal S2j is supplied from the switching unit 2 ₂ based on the control signal Sc from the same control circuit to the combiner 5 _2, from synthesizer 5 _2, FIG. 2 (f)
Is output. In this case, as the output of the combiner 5 _1, the output from the combiner 5 _2, in addition to the main signal 2j, the level of the leakage component of the signal S1j to be output from the original synthesizer 5 ₁ Is included.

The signal output from the combiner 5 ₁ is mixed with a local oscillation signal of the frequency f1 in the frequency converter ₈₁ ', the output-side intermediate frequency signal filter 24 _1, as shown in FIG. 2 (g) Supplied. As shown in the figure, the main signal S1j is converted signal S1 'filters 24 ₁ of passband by the frequency f1, whereas, the leakage signal S2x
Is converted by the frequency f1 and the signal S2x 'is
4 exists outside the _first passband. Therefore, the output terminal 200
₁ outputs only the signal S1 'as the main signal.

On the other hand, the signal output from the combiner 5 _2,
In the frequency converter 8 ₂ ′, the output intermediate frequency signal as shown in FIG. 2H is mixed with the local oscillation signal of the frequency f ₂ and supplied to the filter 242. As shown in the figure, the main signal S2j is converted into a signal S2 converted by the frequency f2.
'In the within the passband of the filter 24 _2, whereas, signal the leakage signal S1x is converted by the frequency f2 S1x' 2 is present outside the passband of the filter 24 _2. Accordingly, only the signal S2 'as the main signal is output to the output terminal 200 _2.

[0045] In general, it is difficult to sharpen the passband characteristic of the filter 24, in this switch circuit, the connections between the switch 2 ₁ to 2 _M and the combiner 5 ₁ to 5 _N Since the degree of electrostatic or electromagnetic coupling between the paths is designed to be low, the level of the leakage signal generated in the switch circuit is considerably lower than the level of the main signal. Accordingly, it is not necessary to particularly increase the signal suppression amount outside the pass band of the filter 24, and the local oscillation frequency f1
By appropriately selecting the interval of fN, a switch circuit having high isolation characteristics can be easily realized.

<Second Embodiment> FIG. 3 is a diagram showing a configuration of a switch circuit according to a second embodiment of the present invention. In FIG. Omitted. In this embodiment, each of the frequency converters 7 ₁ ′ to 7 _M ′
Is different from the first embodiment in that a filter 26 is provided after the first embodiment. The filter 26 removes an extra signal (a signal component having a frequency other than the desired intermediate frequency band) included in the signal after the frequency conversion in the frequency converter 7 '. Also, the reliability of the switch circuit is further improved.

<Third Embodiment> FIG. 4 is a diagram showing a configuration of a switch circuit according to a third embodiment of the present invention. The same reference numerals as in FIG. 3 denote the same parts, and a description thereof will be given. Omitted. This configuration is a switch circuit that outputs a signal input from one input terminal 100 to one of the two output terminals 200 ₁ and 2002 _2. The switch 28 and the control circuit 35
And

The control circuit 35 supplies a control signal for setting the output destination of the signal input from the input terminal 100 to one of output terminals 200 _1, 200 ₂ to the frequency converter 7 'and switch 28. The frequency converter 7 'sets the local oscillation frequency of the variable frequency local oscillator 10 to either f1 or f2 according to the control signal. The switch 28 is 1
It has one input terminal and two output terminals a and b, and connects the input terminal to one of the output terminals a and b in accordance with a control signal from the control circuit 35. This input is connected to a filter 26, while the outputs a and b are connected to frequency converters 8 ₁ ′ and 8 ₂ ′.
Connected to each other.

Next, the operation of this embodiment will be described with reference to FIG. Here, the signal S input to the input terminal 100 is
The case where ₁ is output to the output terminal 2001 will be described as an example.
In each of FIGS. 5A to 5F, similarly to FIG. 2 described above, the horizontal axis indicates the frequency, and the vertical axis indicates the magnitude of the signal level. Now, when a signal S1 as shown in FIG. 5A is input to the input terminal 100, the signal S1 is converted to the frequency converter 7 '.
, The frequency is converted by the local oscillation signal of the local oscillation frequency f1 based on the control signal supplied from the control circuit 35. Then, the converted input-side intermediate frequency signal is supplied to the filter 26, and the filter 26 outputs a signal S1j as shown in FIG. In the switch 28, an input terminal and an output terminal a are connected based on a control signal supplied from the control circuit 35.

The input-side intermediate frequency signal S1j is output from the output terminal a according to the internal connection state of the switch 28, and a signal as shown in FIG. 5C is supplied to the frequency converter 8 ₁ '. Here, in the process of transmitting a signal from the switch 28 to the frequency converter 8 ₁ ′, the adjacent frequency converter 8 ₂ ′ is
The signal S1x having a low level as shown in FIG.
Frequency converter 8 ₁ 'signal S1j supplied to is mixed with the local oscillation signal of the frequency f1, 5 output the intermediate frequency signal S1 as shown in (e)' is supplied to the filter 24 _1.
As shown in the figure, the signal S1 'is present in the passband of the filter 24 _1, is output to the output terminal 200 _1. On the other hand, the frequency converter ₈₂ 'above leakage signal S1x supplied to is mixed with the local oscillation signal of frequency f2, FIG. 5 (f) signal S1x shown in' is supplied to the filter 24 _2. As shown in the figure, the signal S1x 'is present outside the pass band of the filter 24 _2, to the output terminal 200 ₂ is not output.

The above has described the case of outputting a signal S1 to the output terminal 200 _1, output the signal S1 terminal 20
The same applies to the case of outputting the 0 _2. In this case, the local oscillation frequency in the frequency converter 7 'is set to f2 by the control circuit 35, and the switch 28
Is switched so that the input terminal and the output terminal b are connected. As a result, only the signal S1 'is output from the output terminal 20.
0 is output from the _2. As described above, in a switch circuit that switches a signal input from a specific input terminal to any one of the two output terminals and outputs the signal, high isolation characteristics can be realized. The filter 26 does not have to be provided as in the first embodiment.

<Fourth Embodiment> FIG. 6 is a diagram showing a configuration of a switch circuit according to a fourth embodiment of the present invention. The same reference numerals as in FIG. 3 or 4 denote the same parts in FIG. The description is omitted. This configuration is a switch circuit that switches whether to output a signal input from one input terminal 100 to one output terminal 200, and includes a switch 29 and a control circuit 35 '.

The control circuit 35 ′ supplies a control signal for setting whether or not to output a signal input from the input terminal 100 to the output terminal 200 to the frequency converter 7 ′ and the switch 29. The frequency converter 7 'outputs an input signal to an output terminal 200 according to a control signal supplied from the control circuit 35'.
To output to, set the local oscillation frequency to f1,
On the other hand, when not outputting, the local oscillation frequency is set to f2.

The switch 29 has an input terminal connected to the filter 26 and an output terminal connected to the frequency converter 8 ', and outputs an input signal based on a control signal from the control circuit 35'. When the terminal 200 outputs, the input terminal and the output terminal are set to a connected state (ON state), and when not output, the input terminal and the output terminal are set to a disconnected state (OFF state). .

Next, the operation of this embodiment will be described with reference to FIGS. In each of the figures (a) to (d), similarly to FIG. 2 or FIG. 5, the horizontal axis represents frequency, and the vertical axis represents signal level. When Outputting an Input Signal (FIG. 7) First, the signal S1 input to the input terminal 100 is output to the output terminal 2
The case of outputting to 00 will be described. Now, when a signal S1 as shown in FIG. 7A is input to the input terminal 100, the signal S1 is converted into a signal of frequency f1 by the frequency converter 7 'based on the control signal supplied from the control circuit 35'. The frequency is converted by the local oscillation signal. Then, the converted input-side intermediate frequency signal is supplied to the filter 26, and a signal S 1 j as shown in FIG. 7B is output from the filter 26 and supplied to the switch 29. In the switch 29,
The input terminal and the output terminal are set to the above-mentioned ON state by the control signal from the control circuit 35 '.

Next, the input side intermediate frequency signal S1j is supplied to the switch 2
The signal output from the output terminal 9 and shown in FIG. 7 (c) is supplied to the frequency converter 8 'and mixed with the local oscillation signal of the frequency f1. From the frequency converter 8 ', FIG.
The output-side intermediate frequency signal S1 'as shown in the output, is supplied to the filter 24 _1. As shown in FIG.
1 'exists in the pass band of the filter 24 ₁ and is output to the output terminal 200.

Next, when the input signal is not output (FIG. 8), the signal S1 input to the input terminal 100 is output to the output terminal 2
The case where the output is not performed at 00 will be described. Now, when a signal S1 as shown in FIG. 8A is input to the input terminal 100, the signal S1 is converted into a frequency f2 by the frequency converter 7 'based on the control signal supplied from the control circuit 35'.
The frequency is converted by the local oscillation signal. Then, the converted input-side intermediate frequency signal is supplied to the filter 26, and a signal S 1 k as shown in FIG. 8B is output from the filter 26 and supplied to the switch 29. In the switch 29, the input terminal and the output terminal are set to the above-mentioned OFF state by the control signal from the control circuit 35 '.

The signal S1k supplied to the switch 29 should not be output from the output terminal because the input terminal and the output terminal of the switch 29 are separated. However, in practice, the switch 29 cannot completely shut off the signal supplied to the input terminal even in the off state, and a part of the signal leaks and is output from the output terminal. In this case, a low-level leakage signal S1y as shown in FIG. 8C is output from the output terminal.

Then, in the frequency converter 8 ', the leakage signal S1y is mixed with the local oscillation signal having the frequency f1.
A signal S1y 'as shown in FIG. As shown in FIG.
No. 4 is not output to the output terminal 200 because it exists outside the pass band.

As described above, according to the switch circuit of this embodiment, regardless of whether the signal input from the input terminal is output from the output terminal or not.
Good isolation characteristics can be obtained. The filter 26 does not have to be provided as in the first embodiment. In this case, when a signal input from the input terminal 100 is not output to the output terminal 200,
By inputting the input signal S1 directly to the switch 29 without operating the frequency converter 7 'and converting and shifting the frequency of the leakage signal supplied to the frequency converter 8', the leakage through the filter 24 is performed. It is also possible to eliminate the signal. In such a case, it is sufficient that the frequency converter 7 'can generate only a local oscillation signal having the same frequency f1 as the frequency converter 8'.

<Fifth Embodiment> This embodiment particularly assumes the following applications. In the case where centralized control of signals (or channels) is performed in mobile communication or the like, it is necessary to receive signals distributed to each zone again via a switch circuit. In such a case, for example, a signal output from a transmission source to a zone connected to each output terminal using the switch circuit according to the first embodiment (see FIG. 1) is
By returning the signal to the transmission source via the switch circuit described below, highly reliable centralized control can be performed.

Next, the configuration of this embodiment will be described. FIG. 9 is a diagram showing the configuration of the switch circuit according to the present embodiment. The same reference numerals are given to portions common to FIG. 11, and description thereof will be omitted. Since this embodiment is intended for the use described above, it is assumed here that a signal output from the output terminal of the switch circuit in FIG. 1 is input to the input terminal in FIG. Therefore, the number of output terminals of the switch circuit of FIG. 1 (N pieces) and the input terminal 100 ₁ to 100 _N which corresponds to, likewise the number of input terminals in the switching circuit Fig 1 (M number) corresponding to the output terminals 200 ₁ to
It is assumed that 200 _M is provided.

Next, in FIG. 9, reference numeral 40 denotes an input / output controller, and reference numeral 45 denotes a control circuit. The control circuit 45 sets the output destination of the input signal supplied to each of the input terminals 100 _{1 to} 100 _N and outputs a control signal for switching the internal connection mode of the switches 42 _{1 to} 42 _M in the input / output controller 40 described later. A control signal for specifying the local oscillation frequency in each of the frequency converters 7 _{1 to} 7 _M is supplied to each of the frequency converters 7 while being supplied to the input / output controller 40.

[0064] The output controller 40, the distributor 41 ₁ to 41 _N which are connected to input terminals 100 ₁ to 100 _N
And switchers 42 _{1 to} 42 _M connected to the output terminals 200 ₁ to 200 _M , respectively. Each distributor 41 has an input terminal connected to the corresponding input terminal 100 and M output terminals, and a signal input to the input terminal is distributed to each output terminal. It has become.

On the other hand, each of the switches 42 is provided with N input terminals and an output terminal connected to the corresponding output terminal 200, based on a control signal supplied from the control circuit 45. One of the input terminals and the output terminal are connected. Then, each distributor 41 _{1 to} 41 _N and each switch 42 ₁
Between the through 42 _M, the distributor 41 of the k-th (k = 1 to N)
_k output terminals are connected to the respective switches 42 ₁ ,..., 42
It is wired so as to be connected to the k-th input terminal of the N input terminals of _M.

As described above, the configuration of the input / output controller 40 is equivalent to a configuration in which the input / output controller 50 of FIG. 1 is inverted, and the output side is used as the input side, and the input side is used as the output side. Also, each local oscillation frequency f1 in the frequency converter 8 ₁ to 8 _N, ..., setting interval of fN is,
The frequency is set to be equal to or higher than the pass band of the filter 11 connected to each frequency converter 7.

Next, the operation of this embodiment will be described. Now, the output terminal 200 20 ₁ to 20 of the switching circuit of FIG. 1
The signal output from each of the input terminals 0 _N is input terminal 1 of FIG.
It is assumed that the values are input to 00 _{1 to} 100 _N. These signals are frequency-converted by the frequency converter 8, and the converted input-side intermediate frequency signals are supplied to distributors 41 _{1 to} 41 _N in the input / output controller 40.

[0068] The signal supplied to the distributor 41 is distributed to respective output terminals and supplied to the corresponding input terminal of the switching device 42 ₁ through 42 _M. As a result, signals are supplied from a plurality of input terminals in each switch 42. In each switch 42, one of the input terminals and the output terminal are connected based on the control signal supplied from the control circuit 45, and the signal output from the connected output terminal is connected to the corresponding frequency converter. 7 is supplied.

In each frequency converter 7, the control circuit 4
5, the local oscillation frequency f1
To fN, a frequency that matches the switching content of the corresponding switch 42, that is, the local oscillation frequency on the input side corresponding to the selected input terminal of the switch 42 is selected and set. Then, the input-side intermediate frequency signal supplied to the frequency converter 7 is mixed with the signal of the local oscillation frequency and converted into a signal of the original frequency. Then, the converted output-side intermediate frequency signal is output to the corresponding output terminal 200 via the filter 11. Here, the signal supplied to each frequency converter 7 includes not only the intended main signal but also a leak signal due to factors such as cross wiring in the input / output controller 40. After being frequency-converted in, it is outside the pass band of the filter 11 and is not output to the output terminal 200.

In this way, each of the output terminals 200 ₁ to 200 ₁
00 desired signal _M only (the main signal) is obtained, the input terminal 10 of the switch circuit of Figure 1 described above these signals
Be supplied to the 0 ₁ to 100 _M, it is possible to perform centralized control of the signal as described above. That is, on the receiving side of the switch circuit having the configuration of “input terminal → frequency converter → switcher → combiner → frequency converter → output terminal”, “input terminal → frequency converter → distributor → switcher → frequency conversion By connecting a switch circuit having the configuration of “device → output terminal”, it is possible to realize the above-described centralized control with good isolation characteristics.

As described above, in each of the above embodiments, if the set intervals of the local oscillation frequencies f1, f2,... Are set to be equal to or greater than the band of the filter provided immediately before the output terminal,
Switching control of the switching means and switching control of each local oscillation frequency are performed in conjunction with each other through a control circuit as a command means, and a desired main signal is obtained at each output terminal and a leakage signal is removed. . Therefore, better isolation characteristics than before can be obtained. Further, even when it is difficult to set each interval of the local oscillation frequency to be equal to or more than the pass band of the filter 24, for example, when the number of input / output terminals is considerably large, the level of the leakage signal is small.
As compared with 3 (b) and the like, better isolation characteristics than before can be obtained.

[0072]

As described above, according to the present invention, the frequency band of the leakage signal generated due to the influence of the wiring such as the switching means is controlled so as to be finally different from the frequency band of the main signal. Therefore, only the leakage signal is removed by the filter for the predetermined frequency band provided before each output terminal. Further, since the level of the leakage signal is smaller than the level of the main signal, the leakage signal can be easily removed without particularly increasing the out-of-band signal suppression amount as a characteristic of the predetermined frequency band filter. Thereby, the isolation characteristics between the main signal and the leakage signal can be improved as compared with the related art. Therefore, there is an advantage in that the signal wiring in the switch circuit can be shielded only slightly, and the wiring interval in the circuit can be made relatively small, so that the circuit can be downsized.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a configuration of a switch circuit according to a first embodiment of the present invention.

FIG. 2 is a diagram showing the state of each signal in the operation of the first embodiment.

FIG. 3 is a diagram illustrating a configuration of a switch circuit according to a second embodiment of the present invention.

FIG. 4 is a diagram illustrating a configuration of a switch circuit according to a third embodiment of the present invention.

FIG. 5 is a diagram showing the state of each signal in the operation of the third embodiment.

FIG. 6 is a diagram illustrating a configuration of a switch circuit according to a fourth embodiment of the present invention.

FIG. 7 is a diagram showing the state of each signal in the operation of the fourth embodiment.

FIG. 8 is a diagram showing the state of each signal in the operation of the fourth embodiment.

FIG. 9 is a diagram illustrating a configuration of a switch circuit according to a fifth embodiment of the present invention.

FIG. 10 is a diagram illustrating a first configuration example of a conventional switch circuit.

FIG. 11 is a diagram illustrating a second configuration example of a conventional switch circuit.

FIG. 12 is a diagram showing states of an input signal and an output signal in a first conventional configuration example.

FIG. 13 is a diagram showing a state of an output signal in a second conventional configuration example.

[Explanation of symbols]

7 ', 8 Frequency converter (frequency conversion means for each input terminal) 8', 7 Frequency converter (frequency conversion means for each output terminal) 15, 35, 35 ', 45 Control circuit (command means) 24 Filter (predetermined frequency band) Filter 26 filter (intermediate frequency band filter) 28, 29 switch (switching means) 40, 50 input / output controller (switching means) 100 input terminal 200 output terminal

Claims (6)

(57) [Claims] 1. An input terminal having at least one input terminal and at least one output terminal, wherein each signal within a predetermined frequency band input to each input terminal is input so as to be output from any arbitrary output terminal. In a switch circuit for switching an output state, a command means for instructing which of the at least one output terminal each signal input to the at least one input terminal is output, and a number corresponding to the number of each of the output terminals A signal oscillating at any of a plurality of types of frequencies can be generated, and when an input signal is supplied from the predetermined input terminal, a signal having a frequency corresponding to an output terminal commanded by the command means is oscillated. Input terminal frequency conversion means for mixing the input signal with the input signal, converting the input signal into a predetermined intermediate frequency signal, and outputting the signal. A switching means for outputting an intermediate frequency signal output by the switching means to a path corresponding to an output terminal commanded by the command means, and a signal output from the switching means by oscillating a signal having a frequency unique to the predetermined output terminal. And output terminal frequency conversion means for converting the intermediate frequency signal into a signal within the predetermined frequency band before conversion and converting an unnecessary leakage signal into a signal outside the predetermined frequency band and outputting the signal. Of the signals output by the frequency conversion means for each output terminal,
A switch circuit, comprising: a filter for a predetermined frequency band that outputs only a signal within the predetermined frequency band to an output terminal commanded by the command means. 2. The switch circuit according to claim 1, further comprising an intermediate frequency band filter that outputs only the predetermined intermediate frequency signal among the signals output by the input terminal frequency conversion means. 3. A switch circuit having an input terminal and an output terminal, and switching whether or not to output a signal within a predetermined frequency band input to the input terminal from the output terminal, wherein the signal is input to the input terminal. Command means for commanding whether or not to output a signal to the output terminal; and a signal oscillating at any one of the first and second frequencies can be generated, and when an input signal is supplied from the input terminal, When the command means instructs to output a signal to an output terminal, oscillates a signal of a first frequency, mixes the signal with the input signal, converts the input signal into a first intermediate frequency signal, and outputs the signal. On the other hand, when the command means instructs not to output a signal to the output terminal, a signal of the second frequency is oscillated and mixed with the input signal, and the input signal is converted into a second intermediate frequency signal. Input terminal side frequency to output Switching means, and switching means for outputting an intermediate frequency signal output by the input terminal side frequency conversion means to a path corresponding to the output terminal only when the command means instructs to output a signal to an output terminal; and Oscillates a signal of frequency 1 and mixes with the signal output by the switching means, or converts the first intermediate frequency signal into a signal within the predetermined frequency band before conversion, or
An output terminal-side frequency converter that converts a leakage component of the second intermediate frequency signal into a signal outside the predetermined frequency band and outputs the signal, and a signal output by the output terminal-side frequency converter.
A switch circuit, comprising: a filter for a predetermined frequency band that outputs only a signal within the predetermined frequency band to the output terminal. 4. An intermediate frequency band filter for outputting only the first or second intermediate frequency signal out of the signals output by the input terminal side frequency conversion means. Switch circuit. 5. A switch circuit having an input terminal and an output terminal, and switching whether or not to output a signal within a predetermined frequency band input to the input terminal from the output terminal, wherein the input terminal is input to the input terminal. Command means for commanding whether or not to output a signal to the output terminal; and a signal oscillating at a predetermined frequency can be generated. When an input signal is supplied from the input terminal, the command means outputs a signal. When instructing to output to a terminal, the signal of the predetermined frequency is oscillated and mixed with the input signal, and the input signal is converted into a predetermined intermediate frequency signal and output, while the command means outputs the signal. An input terminal-side frequency conversion unit that outputs the input signal as it is as a signal within the predetermined frequency band when instructing not to output to the output terminal; and that the instruction unit outputs a signal to the output terminal. Switching means for outputting a signal output from the input terminal side frequency conversion means to a path corresponding to the output terminal only when instructing; and oscillating a signal of a predetermined frequency which can be generated in the input terminal side frequency conversion means. Mixing the signal with the signal output by the switching means and converting the predetermined intermediate frequency signal into a signal in the predetermined frequency band before conversion, or converting an unnecessary leakage signal in the predetermined frequency band into the predetermined frequency band. An output terminal-side frequency converter that converts the signal into a signal outside the frequency band and outputs the signal, and among the signals output by the output terminal-side frequency converter,
A switch circuit, comprising: a filter for a predetermined frequency band that outputs only a signal within the predetermined frequency band to the output terminal. 6. It has at least one input terminal and at least one output terminal, and inputs each of the signals within a predetermined frequency band input to each input terminal such that each signal is output from any one of the output terminals. In a switch circuit for switching an output state, command means for instructing each of the at least one output terminal to output each signal input to the at least one input terminal, and an input signal from the predetermined input terminal When supplied, the input terminal oscillates a signal having a frequency unique to the input terminal, mixes the signal with the input signal, converts the input signal into a predetermined intermediate frequency signal, and outputs the converted signal. Switching means for outputting an intermediate frequency signal output by the frequency conversion means for each input terminal to a path corresponding to an output terminal commanded by the command means; and each of the input terminals A signal oscillating at any one of a plurality of types of frequencies corresponding to the number can be generated, and a signal having a frequency corresponding to an input terminal commanded by the command means is oscillated and mixed with a signal output by the switching means. A frequency conversion means for each output terminal for converting the intermediate frequency signal into a signal within the predetermined frequency band before conversion and converting an unnecessary leakage signal into a signal outside the predetermined frequency band and outputting the signal; Of the signals output by the different frequency conversion means,
A switch circuit, comprising: a filter for a predetermined frequency band that outputs only a signal within the predetermined frequency band to an output terminal commanded by the command means.