JP2016213724A - Transmission system, transmission method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a transmission system capable of, when a failure occurs in one transmitter in a transmission system having two or more transmitters, appropriately switching the transmitter to the other transmitter.SOLUTION: A transmission system 1 includes a first transmitter 10A and a second transmitter 10B respectively having modulators 101A, 101B for generating and outputting a modulation signal corresponding to an input signal; oscillators 105A, 105B for outputting a local signal which oscillates at a predetermined frequency; amplifiers 106A, 106B for amplifying a signal for transmission obtained by superimposing the modulation signal on the local signal; and monitoring parts 110A, 110B for monitoring the amplified signal for transmission. The monitoring part 110B of the second transmitter 10B monitors the signal for transmission amplified by the amplifier 106A of the first transmitter 10A.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a transmission system, a transmission method, and a program.

In general, a transmission system that transmits a video signal used for television broadcasting or the like to the public through electromagnetic waves is required to be continuously operated. Therefore, a transmission system in which redundancy of the transmitter or the like is made in preparation for failure of the transmitter or the like has been put into practical use.
For example, the transmission system includes two identical transmitters, transmits a transmission signal using one of the two transmitters, and waits for the other. When any abnormality (failure, failure) is detected in the active transmitter that outputs the transmission signal, the transmission signal is immediately switched to the standby transmitter that has been waiting ( For example, see Patent Document 1).
In this way, even when a failure occurs in the transmitter, the video signal can be transmitted without being interrupted.

  As a technique related to the above, a complex computer system in which a plurality of computers and a plurality of PCI devices are connected by a PCI switch, particularly when a failure occurs in the active system with the active and standby computers. Discloses a control technique for operating a standby system and taking over a PCI device (see Patent Document 2).

JP 2002-112123 A JP 2009-258978 A

  In the above transmission system, for example, each transmitter has a function of monitoring each internal process and performing a self-diagnosis (self-check). In this case, if any abnormality is detected in the active transmitter as a result of self-diagnosis, the transmission system automatically outputs the final output from the active transmitter using the output selection unit. Perform the process of switching to the transmitter.

  However, there are various types of failures that can occur inside the transmitter, and it has been found that they are caused by various factors. There are also many faults that cannot be self-diagnosed by the transmitter itself due to its structural mechanism. Then, depending on a failure that has occurred in the active transmitter, it may not be possible to detect the occurrence of the failure, and the standby transmitter may not be switched appropriately.

  The present invention solves the above-described problem, and its object is to appropriately switch to one transmitter when a failure occurs in one transmitter in a transmission system having two or more transmitters. Another object of the present invention is to provide a transmission system, a transmission method, and a program.

  One embodiment of the present invention includes a modulator that generates and outputs a modulation signal corresponding to an input signal, an oscillator that outputs a local signal that oscillates at a predetermined frequency, and the modulation signal superimposed on the local signal. A first transmitter and a second transmitter each having an amplifier for amplifying a transmission signal and a monitoring unit for monitoring the amplified transmission signal; and the monitoring unit of the second transmitter includes A transmission system for monitoring the transmission signal amplified by the amplifier of a first transmitter.

  In one embodiment of the present invention, a modulator that generates and outputs a modulation signal according to an input signal, an oscillator that outputs a local signal that oscillates at a predetermined frequency, and the modulation signal is superimposed on the local signal. A transmission method performed using a first transmitter and a second transmitter each having an amplifier that amplifies the transmission signal and a monitoring unit that monitors the amplified transmission signal, In the transmission method, the monitoring unit of the transmitter includes a step of monitoring the transmission signal amplified by the amplifier of the first transmitter.

  In one embodiment of the present invention, a modulator that generates and outputs a modulation signal according to an input signal, an oscillator that outputs a local signal that oscillates at a predetermined frequency, and the modulation signal is superimposed on the local signal. Each of the first transmitter and the second transmitter each having an amplifier for amplifying the transmission signal, which functions as monitoring means for monitoring the amplified transmission signal, The monitoring means of the second transmitter is a program for monitoring the transmission signal amplified by the amplifier of the first transmitter.

  According to the above-described transmission system, transmission method, and program, when a failure occurs in one transmitter in a transmission system having two or more transmitters, it is possible to appropriately switch to the other transmitter.

It is a figure which shows the function structure of the transmission system which concerns on 1st Embodiment. It is a figure which shows the function structure of the transmission system which concerns on contrast. It is a figure which shows the function structure of the transmission system which concerns on the modification of 1st Embodiment. It is a figure which shows the function structure of the transmission system which concerns on 2nd Embodiment. It is a figure which shows the processing flow of the transmission system which concerns on 2nd Embodiment. It is a figure which shows the function structure of the transmission system which concerns on the modification of 2nd Embodiment.

<First Embodiment>
Hereinafter, the transmission system according to the first embodiment and its modifications will be described in detail with reference to FIGS.
The transmission system 1 shown in FIG. 1 receives an input of a video signal that is an input signal to the transmission system 1, and outputs a transmission signal corresponding to the video signal. Here, the video signal is a digital signal including specific broadcast contents (video, audio, etc.) in information such as television broadcasting. The transmission signal is a signal for superimposing information contained in the video signal on the electromagnetic wave and radiating it into the atmosphere. Specifically, the transmission signal is a high frequency (UHF) that can be radiated into the atmosphere as an electromagnetic wave. The signal oscillates at a frequency belonging to a band or the like and is modulated in accordance with the video signal.

(overall structure)
As shown in FIG. 1, the transmission system 1 includes a first transmitter 10A, a second transmitter 10B, a switching control unit 20, and an output selection unit 21.
The first transmitter 10A and the second transmitter 10B are devices that convert video signals that are sequentially input into signals for transmission and output them. Here, the first transmitter 10 </ b> A and the second transmitter 10 </ b> B are devices of the same type manufactured with the same specifications. One of the first transmitter 10A and the second transmitter 10B is an active system (transmitter that is actually used in the operation of the transmission system 1), and the other is a standby system (active transmitter). It is considered as an alternative machine when an abnormality occurs.

The switching control unit 20 controls the output selection unit 21 based on a predetermined control signal (abnormal alarm signal) output from the first transmitter 10A and the second transmitter 10B.
The output selection unit 21 selects and outputs one of the transmission signal output from the first transmitter 10A and the transmission signal output from the second transmitter 10B. The transmission signal selected here becomes the final output of the transmission system 1. The output selection unit 21 performs selection switching based on the control signal for switching control from the switching control unit 20.

(Functional configuration of the first transmitter)
As shown in FIG. 1, the first transmitter 10A includes a control unit 100A, a modulator 101A, a distortion compensation unit 102A, a D / A converter 103A, a mixer 104A, an oscillator 105A, and an amplifier 106A. , A distributor 107A, a mixer 108A, an A / D converter 109A, a monitoring unit 110A, and a switch 111A.

  The control unit 100A is a processor that performs overall processing of the first transmitter 10A. Specifically, the control unit 100A performs modulation processing control in the modulator 101A, amplification degree control (gain control) in the amplifier 106A, and the like. In addition, the control unit 100A receives an input of the monitoring result from the monitoring unit 110A, and when any abnormality is detected, the control unit 100A issues an abnormality to notify and notify the outside (the switching control unit 20 or the like). An information signal is output.

  The modulator 101A generates and outputs a modulated signal corresponding to the video signal sequentially input to the first transmitter 10A. Specifically, the modulation signal generated by the modulator 101A is a digital signal conforming to a modulation scheme (OFDM (Orthogonal Frequency Division Multiplexing) or the like) defined in advance.

  The distortion compensator 102A compensates for the occurrence of distortion accompanying amplification by the amplifier 106A. Specifically, the distortion compensator 102A acquires a distortion characteristic generated in the transmission signal by taking a part of the transmission signal (amplified transmission signal) output from the amplifier 106A, and this distortion characteristic. Inverse distortion for canceling is previously superimposed on the modulation signal. In this way, the distortion characteristics generated in the amplifier 106A are fed back to the upstream side to cancel out, so that a high-quality transmission signal with reduced distortion is output.

  The D / A converter 103A converts a modulated signal that is a digital signal (a modulated signal that has been subjected to distortion compensation by the distortion compensator 102A) into an analog signal.

  The mixer 104A superimposes a local signal (described later) output from the oscillator 105A on the modulation signal converted into an analog signal by the D / A converter 103A, and up-converts the signal to the frequency of the transmission signal. Thereby, a transmission signal in which the modulation signal is superimposed on the local signal is generated.

  The oscillator 105A is an oscillation source (local oscillator) that outputs a local signal that oscillates at a predetermined frequency defined in advance in the first transmitter 10A. Here, the local signal output from the oscillator 105A is a sine wave high-frequency signal that oscillates at a high frequency (a frequency belonging to the UHF band or the like) as a carrier wave of an electromagnetic wave.

The amplifier 106A amplifies and outputs the transmission signal (the signal in which the modulation signal is superimposed on the local signal) generated in the mixer 104A. The transmission signal amplified by the amplifier 106A is output from the first transmitter 10A.
The amplifier 106A can cause distortion mainly in accordance with the amplitude of the transmission signal, but the distortion generated here is reduced by the processing of the distortion compensator 102A.

  The distributor 107A distributes the transmission signal (the transmission signal output from the first transmitter 10A) amplified by the amplifier 106A, and a part thereof is compensated feedback by the distortion compensator 102A, or , And output as a feedback signal used for monitoring (described later) by the monitoring unit 110B of the second transmitter 10B. The feedback signal output from the distributor 107A is output toward the switch 111A of the first transmitter 10A and the switch 111B of the second transmitter 10B.

  The mixer 108A sends a feedback signal (amplified transmission signal of the amplified signal) via the switch 111A described later via the distributor 107A of the first transmitter 10A or the distributor 107B of the second transmitter 10B. The local signal output from the oscillator 105A is superimposed on a part of the signal and down-converted to the frequency of the modulation signal as an analog signal. Thereby, a modulation signal corresponding to the transmission signal amplified by the amplifier 106A or the transmission signal amplified by the amplifier 106B is extracted from the feedback signal.

The A / D converter 109A converts a modulation signal (modulation signal extracted from the feedback signal) that is an analog signal into a digital signal.
The modulated signal extracted from the feedback signal output from the distributor 107A is converted into a digital signal by the A / D converter 109A and then output toward the distortion compensator 102A. The distortion compensator 102A analyzes the distortion characteristics generated in the transmission signal amplified by the amplifier 106A based on this modulation signal, and performs a distortion compensation operation (inverse distortion superimposition) to cancel this.

The monitoring unit 110A of the first transmitter 10A monitors the transmission signal (the transmission signal output from the second transmitter 10B) amplified by the amplifier 106B of the second transmitter 10B. Specifically, the monitoring unit 110A is based on the modulated signal extracted from the feedback signal output from the distributor 107B of the second transmitter 10B and converted into a digital signal by the A / D converter 109A. (2) The quality of the transmission signal amplified by the amplifier 106B of the transmitter 10B is monitored.
The monitoring unit 110A outputs the result of monitoring the quality of the transmission signal to the control unit 100A. The control unit 100A that has received the result of monitoring by the monitoring unit 110A considers that an abnormality has occurred in the second transmitter 10B when the quality level of the transmission signal does not satisfy a predetermined condition. Thus, the above-described abnormality notification signal is output to the switching control unit 20 or the like.
The “quality” of the transmission signal to be monitored by the monitoring unit 110A is specifically IM (Inter Modulation), MER (Modulation Error Ratio), and the like.

The switch 111A accepts input of the feedback signal acquired via the distributor 107A of the first transmitter 10A and the feedback signal acquired via the distributor 107B of the second transmitter 10B, and Select either one and output.
When the switch 111A selects the feedback signal from the distributor 107A of the first transmitter 10A, the feedback signal from the distributor 107A is output to the mixer 108A. As described above, this feedback signal is used for the distortion compensation operation by the distortion compensator 102A.
On the other hand, when the switch 111A selects the feedback signal from the distributor 107B of the second transmitter 10B, the feedback signal from the distributor 107B is output to the mixer 108A. This feedback signal is used by the monitoring unit 110A to monitor the transmission signal (the transmission signal output from the second transmitter 10B) amplified by the amplifier 106B of the second transmitter 10B.

(Functional configuration of the second transmitter)
As shown in FIG. 1, the second transmitter 10B includes a control unit 100B, a modulator 101B, a distortion compensation unit 102B, a D / A converter 103B, a mixer 104B, an oscillator 105B, and an amplifier 106B. , A distributor 107B, a mixer 108B, an A / D converter 109B, a monitoring unit 110B, and a switch 111B.

  The control unit 100B is a processor that performs overall processing of the second transmitter 10B. Specifically, the control unit 100B performs control of modulation processing in the modulator 101B, control of the degree of amplification in the amplifier 106B, and the like. In addition, the control unit 100B receives an input of the monitoring result from the monitoring unit 110B, and when any abnormality is detected, the control unit 100B issues an abnormality to notify and notify the outside (the switching control unit 20 or the like). An information signal is output.

The modulator 101B generates and outputs a modulation signal corresponding to the video signal that is sequentially input to the second transmitter 10B. The function and performance of the modulator 101B of the second transmitter 10B are the same as those of the modulator 101A of the first transmitter 10A.
Note that the same video signal is simultaneously input in parallel to the modulator 101A of the first transmitter 10A and the modulator 101B of the second transmitter 10B.

  The distortion compensator 102B compensates for the occurrence of distortion accompanying amplification by the amplifier 106B. Specifically, similarly to the distortion compensation unit 102A of the first transmitter 10A, the distortion compensation unit 102B takes in a part of the transmission signal amplified by the amplifier 106B and displays the distortion characteristics generated in the transmission signal. At the same time as acquisition, reverse distortion for canceling out this distortion characteristic is preliminarily superimposed on the modulation signal.

  As with the D / A converter 103A of the first transmitter 10A, the D / A converter 103B converts the modulation signal that is a digital signal (the modulation signal that has been subjected to distortion compensation by the distortion compensation unit 102B) into an analog signal.

  The mixer 104B superimposes the local signal output from the oscillator 105B on the modulation signal converted into an analog signal by the D / A converter 103B, and up-converts the signal to the frequency of the transmission signal. Thereby, a transmission signal in which the modulation signal is superimposed on the local signal is generated.

  The oscillator 105B is an oscillation source (local oscillator) that outputs a local signal that oscillates at a predetermined frequency in the second transmitter 10B. Here, the local signal output from the oscillator 105B is a sine wave high-frequency signal that oscillates at the same frequency as the local signal output from the oscillator 105A of the first transmitter 10A.

The amplifier 106B amplifies and outputs the transmission signal (the signal in which the modulation signal is superimposed on the local signal) generated in the mixer 104B. The transmission signal amplified by the amplifier 106B is output from the second transmitter 10B.
The function and performance of the amplifier 106B are the same as those of the amplifier 106A of the first transmitter 10A.

  The distributor 107B distributes the transmission signal (the transmission signal output from the second transmitter 10B) amplified by the amplifier 106B, and a part thereof is compensated for feedback by the distortion compensation unit 102B, or , And output as a feedback signal used for monitoring by the monitoring unit 110A of the first transmitter 10A described above. The feedback signal output from the distributor 107B is output toward the switch 111B of the second transmitter 10B and the switch 111A of the first transmitter 10A.

  The mixer 108B receives the feedback signal (amplified transmission signal after amplification) via the switch 111B, which will be described later, via the distributor 107B of the second transmitter 10B or the distributor 107A of the first transmitter 10A. The local signal output from the oscillator 105B is superimposed on a part of the signal and down-converted to the frequency of the modulation signal as an analog signal. As a result, a transmission signal amplified by the amplifier 106B or a modulation signal corresponding to the transmission signal amplified by the amplifier 106A is extracted from the feedback signal.

The A / D converter 109B converts a modulation signal that is an analog signal (a modulation signal extracted from the feedback signal) into a digital signal.
The modulated signal extracted from the feedback signal output from the distributor 107B is converted into a digital signal by the A / D converter 109B and then output toward the distortion compensator 102B. The distortion compensator 102B analyzes the distortion characteristics generated in the transmission signal amplified by the amplifier 106B based on the modulation signal, and performs a distortion compensation operation (superimposition of inverse distortion) to cancel this.

The monitoring unit 110B of the second transmitter 10B monitors the transmission signal (the transmission signal output from the first transmitter 10A) amplified by the amplifier 106A of the first transmitter 10A. Specifically, the monitoring unit 110B is based on the modulated signal extracted from the feedback signal output from the distributor 107A of the first transmitter 10A and converted into a digital signal by the A / D converter 109B. The quality of the signal for transmission amplified by the amplifier 106A of one transmitter 10A is monitored.
The monitoring unit 110B outputs the result of monitoring the quality of the transmission signal to the control unit 100B. The control unit 100B that has received the result of monitoring by the monitoring unit 110B considers that an abnormality has occurred in the first transmitter 10A when the quality level of the transmission signal does not satisfy a predetermined condition. Thus, the above-described abnormality notification signal is output to the switching control unit 20 or the like.
The mode of monitoring in the monitoring unit 110B is the same as the mode performed in the monitoring unit 110A of the first transmitter 10A.

The switch 111B accepts inputs of the feedback signal acquired via the distributor 107B of the second transmitter 10B and the feedback signal acquired via the distributor 107A of the first transmitter 10A, Select either one and output.
When the switch 111B selects the feedback signal from the distributor 107B of the second transmitter 10B, the feedback signal from the distributor 107B is output to the mixer 108B. As described above, this feedback signal is used for the distortion compensation operation by the distortion compensator 102B.
On the other hand, when the switch 111B selects the feedback signal from the distributor 107A of the first transmitter 10A, the feedback signal from the distributor 107A is output to the mixer 108B. The feedback signal is used by the monitoring unit 110B to monitor the transmission signal (the transmission signal output from the first transmitter 10A) amplified by the amplifier 106A of the first transmitter 10A.

(Transmission system operation)
As described above, the transmission system 1 according to the first embodiment includes two transmitters (first transmitter 10A and second transmitter 10B) having the same function and performance. In this transmission system 1, the monitoring unit 110B of the second transmitter 10B monitors the transmission signal amplified by the amplifier 106A of the first transmitter 10A, and the monitoring unit 110A of the first transmitter 10A performs the second transmission. The transmission signal amplified by the amplifier 106B of the machine 10B is monitored.

Here, when the first transmitter 10A is the active system and the second transmitter 10B is the standby system (that is, the transmission signal output from the first transmitter 10A by the output selection unit 21 is the final output). Think if it was selected). In this case, in the switch 111A of the first transmitter 10A and the switch of the second transmitter 10B, the feedback signal output from the distributor 107A of the first transmitter 10A that is the active system is selected.
As a result, the modulation signal extracted from the feedback signal output from the distributor 107A is input to the distortion compensator 102A, and a distortion compensation operation for compensating for distortion that may occur in the amplifier 106A of the first transmitter 10A is performed. The Also, the monitoring unit 110B of the second transmitter 10B receives the modulation signal extracted from the feedback signal output from the distributor 107A, and monitors the transmission signal amplified by the amplifier 106A of the first transmitter 10A. Made.

On the other hand, when the second transmitter 10B is the active system and the first transmitter 10A is the standby system (that is, the transmission signal output by the second transmitter 10B is selected as the final output by the output selection unit 21). Think if you were). In this case, in the switch 111A of the first transmitter 10A and the switch of the second transmitter 10B, the feedback signal output from the distributor 107B of the second transmitter 10B that is the active system is selected.
As a result, the modulation signal extracted from the feedback signal output from the distributor 107B is input to the distortion compensator 102B, and a distortion compensation operation for compensating for distortion that may occur in the amplifier 106B of the second transmitter 10B is performed. The Also, the monitoring unit 110A of the first transmitter 10A receives the modulated signal extracted from the feedback signal output from the distributor 107B, and monitors the transmission signal amplified by the amplifier 106B of the second transmitter 10B. Made.

(Function and effect)
FIG. 2 is a diagram illustrating a functional configuration of the transmission system according to the comparison.
Here, while comparing the transmission system 1 (FIG. 1) according to the first embodiment and the transmission system 9 (FIG. 2) according to the comparison, the operational effects of the transmission system 1 according to the first embodiment. Will be described.

As shown in FIG. 2, the transmission system 9 is similar to the transmission system 1 according to the first embodiment, in which the first transmitter 10A, the second transmitter 10B, the switching control unit 20, and the output selection unit 21 are used. And.
Also in the transmission system 9, the first transmitter 10 </ b> A and the second transmitter 10 </ b> B are devices of the same type manufactured with the same specifications, and either the first transmitter 10 </ b> A or the second transmitter 10 </ b> B is currently used. The system is operated as the standby system and the other as the standby system. The functions of the switching control unit 20 and the output selection unit 21 are the same as those of the transmission system 1 according to the first embodiment.

  As shown in FIG. 2, the first transmitter 10A and the second transmitter 10B constituting the transmission system 9 include a monitoring unit 110A and a monitoring unit in addition to the distortion compensation function by the distortion compensation unit 102A and the distortion compensation unit 102B, respectively. It has a self-diagnosis function based on 110B.

That is, in the transmission system 9, the monitoring unit 110A of the first transmitter 10A monitors the transmission signal (the transmission signal output from the first transmitter 10A) amplified by the amplifier 106A. More specifically, the monitoring unit 110A is amplified by the amplifier 106A based on the modulation signal extracted from the feedback signal output from the distributor 107A and converted into a digital signal by the A / D converter 109A. Monitor the quality of the transmitted signal.
The monitoring unit 110A outputs the result of monitoring the quality of the transmission signal to the control unit 100A. The control unit 100A that has received the result of monitoring by the monitoring unit 110A has assumed that some abnormality has occurred in the first transmitter 10A itself when the quality level of the transmission signal does not satisfy a predetermined condition. In view of this, the above-described abnormal alarm signal is output to the switching control unit 20 or the like.

Similarly, in the transmission system 9, the monitoring unit 110B of the second transmitter 10B monitors the transmission signal (the transmission signal output from the second transmitter 10B) amplified by the amplifier 106B. More specifically, the monitoring unit 110B is amplified by the amplifier 106B based on the modulation signal extracted from the feedback signal output from the distributor 107B and converted into a digital signal by the A / D converter 109B. Monitor the quality of the transmitted signal.
The monitoring unit 110B outputs the result of monitoring the quality of the transmission signal to the control unit 100B. The control unit 100B that has received the result of monitoring by the monitoring unit 110B indicates that some abnormality has occurred in the second transmitter 10B itself when the degree of quality of the transmission signal does not satisfy a predetermined condition. In view of this, the above-described abnormal alarm signal is output to the switching control unit 20 or the like.

  According to the self-diagnosis function of the first transmitter 10A in the transmission system 9 described above, for example, when an abnormality occurs in the amplification characteristic of the amplifier 106A, the monitoring unit 110A is based on the modulation signal extracted from the feedback signal. Thus, the abnormality can be detected (the same applies to the second transmitter 10B).

However, in the transmission system 9, for example, when abnormality (frequency fluctuation, deterioration of phase noise, etc.) occurs in the characteristics of the local signal output from the oscillator 105A, the following events are assumed.
That is, the mixer 104A generates a transmission signal by superimposing the modulation signal on the local signal output from the oscillator 105A in which an abnormality has occurred. On the other hand, the mixer 108A extracts the modulation signal from the feedback signal (a part of the transmission signal amplified by the amplifier 106A) based on the local signal having the same abnormality. Then, since up-conversion (modulation signal superimposition) and down-conversion (modulation signal extraction) are performed based on the same local signal in which an abnormality has occurred, the local signal is included in the modulation signal input to the monitoring unit 110A. The abnormality is not reflected.
Therefore, a failure occurring in the oscillator 105A cannot be detected by the self-diagnosis function based on the monitoring unit 110A of the transmission system 9 according to the comparison (the same applies to the second transmitter 10B).

On the other hand, according to the transmission system 1 according to the first embodiment, the monitoring unit 110B of the second transmitter 10B monitors the transmission signal amplified by the amplifier 106A of the first transmitter 10A.
In this way, the modulation signal is superimposed on the local signal output from the oscillator 105A of the first transmitter 10A, and the modulation signal is converted from the feedback signal based on the local signal output from the oscillator 105B of the second transmitter 10B. Is extracted. That is, the local signal used for up-conversion and the local signal used for down-conversion are different. Then, even if there is an abnormality in the local signal on which the modulation signal is superimposed, which is output from the oscillator 105A of the first transmitter 10A, the local signal that is output from the oscillator 105B of the second transmitter 10B and has no abnormality. Since the modulation signal is extracted based on the above, the abnormality of the oscillator 105A is reflected in the modulation signal.
Therefore, according to the transmission system 1 according to the first embodiment, a failure occurring in the oscillator 105A of the first transmitter 10A can be detected by the monitoring unit 110B of the second transmitter 10B.

Further, according to the transmission system 1 according to the first embodiment, the monitoring unit 110A of the first transmitter 10A monitors the transmission signal amplified by the amplifier 106B of the second transmitter 10B.
By doing in this way, even if an abnormality has occurred in the local signal on which the modulation signal is superimposed, which is output from the oscillator 105B of the second transmitter 10B, an abnormality is output from the oscillator 105A of the first transmitter 10A. Since the modulation signal is extracted based on the local signal that has not occurred, the abnormality of the oscillator 105A is reflected in the modulation signal.
Therefore, according to the transmission system 1 according to the first embodiment, a failure occurring in the oscillator 105B of the second transmitter 10B can be detected by the monitoring unit 110A of the first transmitter 10A.

As described above, the transmission system 1 according to the first embodiment can detect abnormalities that cannot be self-diagnosed by the transmitter itself by monitoring the active transmitter using the standby transmitter. it can.
As described above, according to the transmission system 1 according to the first embodiment, in a transmission system having two or more transmitters, when a failure occurs in one transmitter, it is possible to appropriately switch to the other transmitter. it can.

In addition, according to the transmission system 1 according to the first embodiment, one of the transmission signal output from the first transmitter 10A and the transmission signal output from the second transmitter 10B is selected. An output selection unit 21 for final output is further provided.
By doing in this way, even if a failure occurs in one of the first transmitter 10A and the second transmitter 10B, it is possible to immediately switch to the output of the other transmitter. Therefore, the video signal can be transmitted without being interrupted.

Further, according to the transmission system 1 according to the first embodiment, the monitoring unit 110B of the second transmitter 10B performs the first operation during the period in which the transmission signal output from the first transmitter 10A is selected as the final output. The transmission signal amplified by the amplifier 106A of one transmitter 10A is monitored. Also, the monitoring unit 110A of the first transmitter 10A transmits the transmission signal amplified by the amplifier 106B of the second transmitter 10B during the period in which the transmission signal output from the second transmitter 10B is selected as the final output. To monitor.
In this way, even if either the first transmitter 10A or the second transmitter 10B is selected as the active transmitter, the active transmitter is selected in the other transmitter selected as the standby transmitter. The output of the system transmitter is monitored. Therefore, the active transmitter in the transmission system 1 can be easily switched.

(Modification of the first embodiment)
The transmission system 1 according to the first embodiment has been described in detail above, but the specific aspect of the transmission system 1 is not limited to the above-described one, and various designs can be made without departing from the scope of the invention. It is possible to make changes.

FIG. 3 is a diagram illustrating a functional configuration of a transmission system according to a modified example of the first embodiment.
As illustrated in FIG. 3, the second transmitter 10B of the transmission system 1 according to the modification of the first embodiment further includes a comparison unit 112B.
The comparison unit 112B receives inputs of the modulated signal generated by the modulator 101A of the first transmitter 10A and the modulated signal generated by the modulator 101B of the second transmitter 10B and compares them. Further, the comparison unit 112B outputs the comparison result (whether or not both match) to the sequential control unit 100B.
The control unit 100B that has received the result of the comparison by the comparison unit 112B receives the modulation signal generated by the modulator 101A of the first transmitter 10A and the modulation signal generated by the modulator 101B of the second transmitter 10B. If they are different, it is assumed that some abnormality has occurred in the modulator 101A of the first transmitter 10A, and the above-described abnormality report signal is output to the switching control unit 20 or the like.

In the transmission system 9 according to the comparison, when an abnormality (latch error, data corruption, etc.) occurs in the modulation processing of the modulator 101A, there is no comparison target (correct modulation signal), and thus self-diagnosis cannot be performed. .
On the other hand, according to the transmission system 1 according to the modified example of the first embodiment described above, when any abnormality occurs in the modulator 101A of the first transmitter 10A, the second transmitter 10B is compared by the comparator 112B. In comparison with the modulated signal from the modulator 101B, a determination result indicating that they do not match is output. Therefore, when an abnormality occurs in the modulator 101A, the abnormality can be detected.

  As described above, according to the transmission system 1 according to the modification of the first embodiment, both the case where an abnormality occurs in the oscillator 105A and the oscillator 105B and the case where an abnormality occurs in the modulator 101A and the modulator 101B are detected. can do.

In the transmission system 1 according to the modified example of the first embodiment, the comparison unit 112B is described as being included in the second transmitter 10B. However, the other embodiments are not limited to this mode. .
For example, the comparison unit 112B may be included in the first transmitter 10A, or may be included in another device that is neither the first transmitter 10A nor the second transmitter 10B. May be.
Further, the comparison unit 112B may output the comparison result (whether or not they match) not to the control unit 100B of the second transmitter 10B but to the control unit 100A of the first transmitter 10A. Good.

<Second Embodiment>
Next, a transmission system according to the second embodiment and its modification will be described in detail with reference to FIGS.
In the transmission system 1 according to the first embodiment described above, when any abnormality occurs in the oscillator 105A of the first transmitter 10A that is the active system, the oscillator 105B and the monitoring unit of the second transmitter 10B that is the standby system It has been explained that the abnormality can be detected through 110B. However, in this case, although the oscillator 105A of the first transmitter 10A that is the active system is normal, an abnormality has occurred in the oscillator 105B of the second transmitter 10B that is the standby system. It is also assumed that this is detected. That is, it is impossible to determine which of the oscillator 105A of the first transmitter 10A and the oscillator 105B of the second transmitter 10B is actually abnormal.
Also in the transmission system 1 according to the modification of the first embodiment, the modulation signal output from the modulator 101A of the first transmitter 10A and the modulation signal output from the modulator 101B of the second transmitter 10B are one. Even if it does not do it, it cannot be determined which abnormality has occurred.

(Functional configuration of monitoring unit)
FIG. 4 is a diagram illustrating a functional configuration of the transmission system according to the second embodiment.
Therefore, as shown in FIG. 4, the transmission system 1 according to the second embodiment includes a monitoring unit in addition to the first transmitter 10A, the second transmitter 10B, the switching control unit 20, and the output selection unit 21. 30.
The monitoring unit 30 is a unit (modulation unit) incorporated in the first transmitter 10 </ b> A or the second transmitter 10 </ b> B, and is normally stored as a spare in the operation of the transmission system 1.
Specifically, as shown in FIG. 4, the monitoring unit 30 includes an oscillator 305, a mixer 308, an A / D converter 309, a monitoring unit 310, and a switch 311.

  The oscillator 305 is an oscillation source (local oscillator) that outputs a local signal that oscillates at a predetermined frequency. The oscillator 305 outputs a high frequency signal of a sine wave that oscillates at the same frequency as the oscillator 105A of the first transmitter 10A and the oscillator 105B of the second transmitter 10B as a local signal.

  The mixer 308 and the A / D converter 309 are the same as the mixer 108A (mixer 108B) and the A / D converter 109A (A / D converter 109B) of the first transmitter 10A (second transmitter 10B). It has the function and performance.

The monitoring unit 310 of the monitoring unit 30 includes a transmission signal (a transmission signal output from the first transmitter 10A) amplified by the amplifier 106A of the first transmitter 10A and an amplifier of the second transmitter 10B. One of the transmission signals amplified by 106B (the transmission signal output from the second transmitter 10B) is monitored.
The monitoring unit 310 outputs the result of monitoring the quality of the transmission signal to the control unit 100A of the first transmitter 10A and the control unit 100B of the second transmitter 10B.
The monitoring mode in the monitoring unit 310 is the same as the mode performed in the monitoring unit 110A of the first transmitter 10A and the monitoring unit 110B of the second transmitter 10B.

  The switch 311 accepts the input of the feedback signal acquired via the distributor 107A of the first transmitter 10A and the feedback signal acquired via the distributor 107B of the second transmitter 10B, and Select either one and output.

Here, when the first transmitter 10A is the active system and the second transmitter 10B is the standby system (that is, the transmission signal output from the first transmitter 10A by the output selection unit 21 is the final output). Think if it was selected). In this case, in the switch 111A of the first transmitter 10A, the switch of the second transmitter 10B, and the switch 311 of the monitoring unit 30, the feedback signal output by the distributor 107A of the first transmitter 10A that is the active system is selected. Is done.
Thus, the modulation signal extracted from the feedback signal output from the distributor 107A of the second transmitter 10B is input to the monitoring unit 310 of the monitoring unit 30 and amplified by the amplifier 106A of the first transmitter 10A. The transmission signal is monitored.

Similarly, when the second transmitter 10B is the active system and the first transmitter 10A is the standby system (that is, the transmission signal output from the second transmitter 10B in the output selection unit 21 is the final output). Think if it was selected). In this case, in the switch 111A of the first transmitter 10A, the switch of the second transmitter 10B, and the switch 311 of the monitoring unit 30, the feedback signal output from the distributor 107B of the second transmitter 10B as the active system is selected. Is done.
As a result, the modulation signal extracted from the feedback signal output from the distributor 107B of the second transmitter 10B is input to the monitoring unit 310 of the monitoring unit 30 and amplified by the amplifier 106B of the second transmitter 10B. The transmission signal is monitored.

(Transmission system operation)
FIG. 5 is a diagram illustrating a processing flow of the transmission system according to the second embodiment.
The processing flow shown in FIG. 5 is started when the transmission system 1 according to the second embodiment is activated.
First, the switching control unit 20 of the transmission system 1 selects the signal for transmission output from the first transmitter 10A through the output selection unit 21 as the final output (step S01). That is, here, the first transmitter 10A is the active system, and the second transmitter 10B is the standby system. Here, the switch 111A of the first transmitter 10A, the switch 111B of the second transmitter 10B, and the switch 311 of the monitoring unit 30 are all acquired via the distributor 107A of the first transmitter 10A. Select feedback signal.

  The monitoring unit 110B of the second transmitter 10B, which is a standby system, and the monitoring unit 310 of the monitoring unit 30 are each based on the feedback signal output from the distributor 107A of the first transmitter 10A. The transmission signal amplified by the 10A amplifier 106A is monitored (step S02). Here, the control unit 100B of the second transmitter 10B uses the first transmitter 10A as the active system when there is no abnormality in both the result of monitoring by the monitoring unit 110B and the result of monitoring by the monitoring unit 310. Is continued (step S02: YES).

  During the operation of the first transmitter 10A as the active system, at least one of the monitoring result of the monitoring unit 110B of the second transmitter 10B or the monitoring result of the monitoring unit 310 of the monitoring unit 30 When an abnormality is detected (step S02: NO), the control unit 100B of the second transmitter 10B determines which of the monitoring unit 110B and the monitoring unit 310 has detected an abnormality (step S03).

  When an abnormality is detected in both the monitoring unit 110B and the monitoring unit 310 (step S03: “both”), the control unit 100B considers that an abnormality has occurred in the first transmitter 10A, and the first transmitter 10A Output an abnormal alarm signal for. Thereby, the occurrence of an abnormality in the first transmitter 10A is notified. Further, when the abnormality control signal is received, the switching control unit 20 switches the selection in the output selection unit 21 from the transmission signal output by the first transmitter 10A to the transmission signal output by the second transmitter 10B. (Step S04). Thereby, the operation | movement which uses the normal 2nd transmitter 10B as an active system is made | formed.

  On the other hand, when an abnormality is detected only by the monitoring unit 110B (step S03: “only the monitoring unit 110B”), the control unit 100B has some abnormality in the second transmitter 10B, not the first transmitter 10A. As a result, an abnormal alarm signal for the second transmitter 10B is output. Thereby, the occurrence of an abnormality in the second transmitter 10B is notified (step S05).

  When an abnormality is detected only by the monitoring unit 310 (step S03: “only the monitoring unit 310”), the control unit 100B regards that an abnormality has occurred in the monitoring unit 30, and An abnormal alarm signal is output. Thereby, the occurrence of an abnormality in the monitoring unit 30 is notified (step S06).

  Note that the flowchart shown in FIG. 5 describes the case where the first transmitter 10A is selected as the active system in step S01, but the case where the second transmitter 10B is selected as the active system in step S01. Can be implemented with the same flowchart. However, in this case, the switch 111A of the first transmitter 10A, the switch 111B of the second transmitter 10B, and the switch 311 of the monitoring unit 30 are all acquired via the distributor 107B of the second transmitter 10B. Select the feedback signal to be used.

(Function and effect)
As described above, according to the transmission system 1 according to the second embodiment, the oscillator 305 that outputs a local signal having the same frequency as the oscillator 105A of the first transmitter 10A and the transmission amplified by the amplifier 106A of the first transmitter 10A. And a monitoring unit 30 having a monitoring unit 310 that monitors the credit signal.
In this way, it is possible to accurately determine which of the first transmitter 10A and the second transmitter 10B is actually abnormal by referring to the monitoring result of the monitoring unit 310 of the monitoring unit 30. can do.

Further, according to the transmission system 1 according to the second embodiment, the output selection unit 21 detects that an abnormality is detected in at least one of the monitoring unit 110A of the first transmitter 10A and the monitoring unit 110B of the second transmitter 10B. When the monitoring unit 310 of the monitoring unit 30 detects an abnormality, the selection as the final output is switched.
By doing so, it is determined that an abnormality has occurred in the active transmitter when both the standby transmitter and the monitoring unit 30 have detected an abnormality, and the selection is made as the final output. Switch. Therefore, when an abnormality occurs in the active transmitter, automatic switching from the output of the active transmitter to the output of the standby transmitter can be performed with higher accuracy.

(Modification of the second embodiment)
Although the transmission system 1 according to the second embodiment has been described in detail above, the specific mode of the transmission system 1 is not limited to the above-described one, and various designs can be made without departing from the gist. It is possible to make changes.

FIG. 6 is a diagram illustrating a functional configuration of a transmission system according to a modification of the second embodiment.
As shown in FIG. 6, the second transmitter 10B according to the modification of the second embodiment includes the comparison unit 112B described in the modification (FIG. 3) of the first embodiment. The monitoring unit 30 further includes a modulator 301 and a comparison unit 312.

The modulator 301 of the monitoring unit 30 has the same function and performance as the modulator 101A of the first transmitter 10A and the modulator 101B of the second transmitter 10B.
The comparison unit 312 of the monitoring unit 30 has the same function and performance as the comparison unit 112B of the second transmitter 10B.
In the following description, it is assumed that the first transmitter 10A is operated as an active system and the second transmitter 10B is operated as a standby system.

As in the modification of the first embodiment (FIG. 3), the comparison unit 112B of the second transmitter 10B and the modulation signal generated by the modulator 101A of the first transmitter 10A and the second transmitter 10B The input of the modulation signal generated by the modulator 101B is received and compared. Then, the comparison unit 112B outputs the comparison result (whether or not both match) to the sequential control unit 100B.
On the other hand, the comparison unit 312 of the monitoring unit 30 receives inputs of the modulation signal generated by the modulator 101A of the first transmitter 10A and the modulation signal generated by the modulator 301 of the monitoring unit 30. Compare the two. Then, the comparison unit 312 outputs the comparison result (whether or not they match) sequentially to the control unit 100B.

  The control unit 100B, based on the comparison result by the comparison unit 112B, the modulation signal generated by the modulator 101A of the first transmitter 10A, the modulation signal generated by the modulator 101B of the second transmitter 10B, It can be grasped whether or not. Similarly, the control unit 100B determines the modulation signal generated by the modulator 101A of the first transmitter 10A and the modulation signal generated by the modulator 301 of the monitoring unit 30 based on the comparison result by the comparison unit 312. And can be grasped.

Here, the control unit 100B determines that the modulation signal generated by the modulator 101A of the first transmitter 10A that is the active system is the modulation signal generated by the modulator 101B of the second transmitter 10B, and the monitoring unit. If both of the modulation signals generated by the 30 modulators 301 do not match, it is assumed that an abnormality has occurred in the modulator 101A of the first transmitter 10A that is the active system, and an abnormal alarm signal is output. To do.
By doing so, the modulator 101A also determines that an abnormality has occurred in the active transmitter when both the standby transmitter and the monitoring unit 30 detect the abnormality. , Switch the selection as the final output. Therefore, when an abnormality occurs in the modulator of the active transmitter, automatic switching from the output of the active transmitter to the output of the standby transmitter can be performed with higher accuracy.

  When the second transmitter 10B is operated as an active system, the comparison unit 312 of the monitoring unit 30 performs the modulation signal generated by the modulator 101B of the second transmitter 10B and the modulation of the monitoring unit 30. A comparison is made with the modulation signal generated by the device 301.

In the second embodiment and its modification, the monitoring unit 30 is a component (unit) stored in advance as a spare, and is a modulation unit incorporated in the first transmitter 10A and the second transmitter 10B. However, the present invention is not limited to this aspect in other embodiments.
For example, the monitoring unit 30 may be a transmitter itself (third transmitter) having the same function and performance as the first transmitter 10A and the second transmitter 10B.

In the first and second embodiments and the modifications thereof, the input signal to the transmission system 1 has been described as being a “video signal”. However, the other embodiments are not limited to this mode. That is, the input signal to the transmission system 1 may be an “audio signal” used for digital radio or the like and other various digital data.
In the first and second embodiments and the modifications thereof, the local signal output from the oscillators 105A and 105B (and 305) has been described as oscillating at a predetermined frequency. The form is not limited to this aspect. That is, the oscillators 105A and 105B (305) may be devices that can oscillate at an arbitrary frequency, such as a frequency synthesizer.

  As mentioned above, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the invention described in the claims and equivalents thereof, as long as they are included in the scope and gist of the invention.

1 Transmission System 10A First Transmitter 100A Control Unit 101A Modulator 102A Distortion Compensation Unit 103A D / A Converter 104A Mixer 105A Oscillator 106A Amplifier 107A Divider 108A Mixer 109A A / D Converter 110A Monitoring Unit 111A Switch 10B First 2 transmitter 100B control unit 101B modulator 102B distortion compensation unit 103B D / A converter 104B mixer 105B oscillator 106B amplifier 107B distributor 108B mixer 109B A / D converter 110B monitoring unit 111B switch 112B comparison unit 20 switching control unit 21 Output Selection Unit 30 Monitoring Unit 301 Modulator 305 Oscillator 308 Mixer 309 A / D Converter 310 Monitoring Unit 311 Switch 312 Comparison Unit 9 Transmission System

Claims (10)

A modulator that generates and outputs a modulation signal according to an input signal, an oscillator that outputs a local signal that oscillates at a predetermined frequency, and an amplifier that amplifies a transmission signal in which the modulation signal is superimposed on the local signal And a monitoring unit that monitors the amplified signal for transmission, each including a first transmitter and a second transmitter,
The monitoring unit of the second transmitter monitors the signal for transmission amplified by the amplifier of the first transmitter. The transmission system according to claim 1, further comprising a comparison unit that compares the modulated signal generated by the modulator of the first transmitter and the modulated signal generated by the modulator of the second transmitter. . The output selection part which selects either the said signal for transmission which the said 1st transmitter outputs, and the said signal for transmission which the said 2nd transmitter outputs, and makes it a final output is further provided. The transmission system according to claim 2. The monitoring unit of the second transmitter transmits the transmission signal amplified by the amplifier of the first transmitter during a period in which the transmission signal output from the first transmitter is selected as a final output. The transmission system according to claim 3. The monitoring unit of the first transmitter is configured to transmit the transmission signal amplified by the amplifier of the second transmitter during a period when the transmission signal output from the second transmitter is selected as a final output. The transmission system according to claim 4. The output selection unit switches selection as a final output when at least one of the monitoring unit of the first transmitter and the monitoring unit of the second transmitter detects an abnormality. Item 6. The transmission system according to any one of Items 5 to 6. A monitoring unit further comprising: an oscillator that outputs a local signal having the same frequency as that of the oscillator of the first transmitter; and a monitoring unit that monitors the transmission signal amplified by the amplifier of the first transmitter. The transmission system according to any one of claims 3 to 5. The output selection unit detects an abnormality in at least one of the monitoring unit of the first transmitter and the monitoring unit of the second transmitter, and the monitoring unit of the monitoring unit detects an abnormality. The transmission system according to claim 7, wherein the selection as a final output is switched in the event of a failure. A modulator that generates and outputs a modulation signal according to an input signal, an oscillator that outputs a local signal that oscillates at a predetermined frequency, and an amplifier that amplifies a transmission signal in which the modulation signal is superimposed on the local signal And a monitoring unit that monitors the amplified signal for transmission, and a transmission method that is performed using a first transmitter and a second transmitter, respectively.
The monitoring method of the second transmitter has a step of monitoring the signal for transmission amplified by the amplifier of the first transmitter. A modulator that generates and outputs a modulation signal according to an input signal, an oscillator that outputs a local signal that oscillates at a predetermined frequency, and an amplifier that amplifies a transmission signal in which the modulation signal is superimposed on the local signal And a program for causing each processor of the first transmitter and the second transmitter, respectively, to function as monitoring means for monitoring the amplified transmission signal,
The program for the monitoring means of the second transmitter to monitor the signal for transmission amplified by the amplifier of the first transmitter.

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