JP2012029204A - Broadcast transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a broadcast transmission device that takes over setting information of a channel unit before abnormality occurrence in the channel unit to a spare unit so that a transmission environment before the abnormality occurrence can be continued.SOLUTION: A broadcast transmission device that is a rebroadcasting device for transmitting a broadcast signal includes: plural channel units 20 respectively allocated to plural channels; a spare unit 40 for performing predetermined processing for a broadcast input signal to generate an output signal and outputting the output signal as the broadcast signal; and an integrated control unit 50 for switching a channel unit 20 in which abnormality is detected to the spare unit 40. When switching the channel unit 20 in which abnormality is detected to the spare unit 40, the integrated control unit 50 acquires predetermined setting information in the channel unit 20 in which abnormality is detected and configures the spare unit 40 based on the setting information.

Description

  The present invention relates to a broadcast transmission apparatus that transmits broadcast waves.

  2. Description of the Related Art Conventionally, in a broadcast system for TV broadcasting, a rebroadcast device has been used to transmit broadcast waves to difficult viewing areas such as mountainous areas. This rebroadcasting device is installed inside a relay station built near the top of the mountain, receives radio waves transmitted from broadcasting stations with antennas, performs signal amplification and unnecessary wave removal, etc. here, The transmission signal is formed again and transmitted to the target difficult viewing area.

  This rebroadcasting apparatus includes a receiving antenna, a receiving amplifier, a power amplifier, and a transmitting antenna. The receiving antenna receives broadcast waves and outputs an input signal to a receiving amplifier. The receiving amplifier includes a plurality of channel units, and demultiplexes the input signal output from the receiving antenna for each channel and outputs the demultiplexed signals to the plurality of channel units. Each of the plurality of channel units converts the input signal of the channel assigned to itself to an intermediate signal of an intermediate frequency, removes unnecessary waves, etc., and then converts the intermediate signal again to a transmission frequency to be an output signal. The level adjustment unit performs level adjustment and outputs. The receiving amplifier synthesizes the output signals from the respective channel units with an output mixer and transmits it to the power amplifier. The power amplifier amplifies the output signal and outputs it to the transmission antenna. The transmit antenna retransmits the output signal.

  The reception amplifier is configured with a spare unit. This spare unit is used by switching from a channel unit in which an abnormality has occurred in any of a plurality of channel units. Like the channel unit, this spare unit is used for the channel assigned to itself. After the input signal is converted to an intermediate signal having an intermediate frequency, unnecessary waves are removed and level amplification is performed, the intermediate signal is converted again to a transmission frequency and output as an output signal. Thus, when an abnormality occurs in any of the plurality of channel units, rebroadcasting can be continued by switching the channel unit in which the abnormality has occurred to a spare unit (see, for example, Patent Document 1). .

JP 2003-309738 A

  However, in the conventional re-broadcasting device as described in Patent Document 1, when the channel unit in which an abnormality has occurred is switched to the spare unit, the spare unit is simply switched and used in the initial setting state. Unlike the setting status of the channel unit in which the error occurred, the setting environment could not continue the retransmission environment before the error occurred.

  For example, FIG. 9 shows an explanatory diagram for explaining the influence of the setting state on the signal level. As described above, the rebroadcast apparatus 100 includes the reception antenna 101, the reception amplifier 102, the power amplifier 103, and the transmission antenna 104. The reception amplifier 102 and the power amplifier 103 are mutually connected by the coaxial cable 105. It is connected. Here, it is assumed that broadcast waves 106 of four channels A to D having different reception levels are being rebroadcast by the rebroadcast device 100.

  Here, when the output level is set in the level adjustment unit (not shown) at the final stage of each channel unit so that the output signals output from each channel unit of the reception amplifier 102 have the same level. The output signal 107 output at the same level from each channel unit of the reception amplifier 102 is affected by the frequency characteristics 108 of the coaxial cable 105, and is input to the power amplifier 103 as input signals 109 having different levels. Further, under the influence of the frequency characteristic 110 of the power amplifier 103, an output signal 111 having a non-uniform level is output from the power amplifier 103 via the transmission antenna 104.

  This is because the coaxial cable 105 has a frequency characteristic that attenuates a high-frequency signal more, so that the level of the output signal that has passed through the coaxial cable 105 differs between the channels. is there. In particular, this influence becomes greater as the coaxial cable 105 is longer. Further, regarding the power amplifier 103, the frequency characteristics are not constant over the entire frequency band and have a frequency deviation, so that the level of the output signal amplified by the power amplifier 103 differs between the channels. Because it becomes.

  In order to cancel the influence of the frequency characteristics 108 and 110, conventionally, the output level of the level adjusting unit of each channel unit is set so that the output signals output from the channel units of the receiving amplifier 102 are not equal to each other. Is set. When set in this way, the output signal 112 output at a non-identical level from the level adjustment unit of each channel unit becomes the input signal 113 due to the influence of the frequency characteristic 108 of the coaxial cable 105, and further the power amplifier As a result, the output signal 114 having a uniform level is output from the power amplifier 103 via the transmission antenna 104.

  However, as described above, in the conventional rebroadcast apparatus 100, when the channel unit in which an abnormality has occurred is switched to a spare unit, the spare unit is simply switched and used in the initial setting state. The adjustment unit is also used at the initial output level, and there is a possibility that the level of the output signal output from the power amplifier 103 via the transmission antenna 104 will be different as a result. .

  Such a problem in the conventional rebroadcast apparatus 100 also exists in broadcast transmission apparatuses other than the rebroadcast apparatus 100. That is, as a broadcast transmitting apparatus that performs broadcasting, there is an apparatus such as a simple independent broadcast apparatus, for example, in addition to the rebroadcast apparatus 100. In the past, when switching a failed channel unit to a spare unit, the spare unit was simply used in its initial setting state. As in the case of the rebroadcast apparatus 100, the output signal levels may possibly differ from each other.

  The present invention has been made in view of the above, and in the case where a channel unit in which an abnormality has occurred is switched to a spare unit, the setting information before the occurrence of the abnormality of the channel unit is taken over to the spare unit, so that An object of the present invention is to provide a broadcast transmission apparatus that can continue the transmission environment and can improve the stability of the broadcast environment.

  In order to solve the above-described problems and achieve the object, the broadcast transmission device according to claim 1 is a broadcast transmission device that transmits a broadcast signal, and outputs the broadcast input signal by performing predetermined processing. A channel unit that generates and outputs a signal, the plurality of channel units assigned to each of a plurality of channels, and the broadcast input signal to generate an output signal by performing predetermined processing on the broadcast input signal. A spare unit that transmits as a signal; and a control unit that switches the channel unit that has detected the abnormality to the spare unit when any abnormality is detected in the plurality of channel units, and the control unit includes the abnormality When switching the channel unit that detected this to the spare unit, the channel unit that detected the abnormality It acquires predetermined setting information that is broadcast transmitting apparatus for setting the protection unit based on the setting information.

  The broadcast transmission device according to claim 2 is the broadcast transmission device according to claim 1, wherein each of the plurality of channel units and the spare unit adjusts a level of the output signal to a predetermined level. The control means acquires, as the setting information, an output level of the level adjustment unit in the channel unit in which the abnormality is detected, and sets the output level in the level adjustment unit of the spare unit.

  The broadcast transmission device according to claim 3 is the broadcast transmission device according to claim 1 or 2, wherein when the control unit detects that the channel unit that has detected the abnormality is recovered, the recovered channel When the unit is switched to the spare unit and the restored channel unit is switched to the spare unit, the setting information in the spare unit is acquired, and the restored channel unit is set based on the setting information.

  The broadcast transmission apparatus according to claim 4 indicates that the broadcast transmission apparatus according to claim 3 is restored when the control unit detects that the channel unit that has detected the abnormality is restored. When the output is performed through a predetermined output unit and an instruction to execute the recovery control is received through the predetermined input unit, the recovered channel unit is switched to the spare unit.

  According to the broadcast transmission device of claim 1, when the channel unit in which the abnormality is detected is switched to the spare unit, the predetermined setting information in the channel unit in which the abnormality is detected is acquired, and the standby is based on the setting information. Since the unit is set, the transmission environment in the channel unit where the abnormality is detected can be taken over by the spare unit, and the stability of the broadcasting environment can be improved. In particular, the setting information of the channel unit in which an error has been detected can be automatically transferred to the spare unit. This eliminates the need for the maintenance staff to manually set the spare unit. Technology is no longer necessary.

  According to the broadcast transmission device of claim 2, since the output level of the level adjustment unit in the channel unit in which the abnormality is detected is acquired and the output level is set in the level adjustment unit of the standby unit, the channel in which the abnormality is detected The output level of the level adjustment unit in the unit can be taken over by the spare unit, and the influence of the frequency characteristics of the coaxial cable 105 and the power amplifier at the rear stage of the reception amplification unit can be canceled as before the occurrence of the abnormality.

  According to the broadcast transmitting apparatus of claim 3, when the restored channel unit is switched to the spare unit, the setting information in the spare unit is acquired and the restored channel unit is set based on the setting information. The transmission environment in the channel unit in which the abnormality is detected can be taken over to the restored channel unit via the spare unit, and the stability of the broadcasting environment can be improved. In particular, when repairing a channel unit that detects an abnormality, even if the setting information is inadvertently changed or deleted, the setting information for that channel unit is automatically set when the abnormality occurs. Therefore, it is not necessary for the maintenance staff to manually set the channel unit, and no special technique for manually setting the channel unit is required.

  According to the broadcast transmission apparatus of claim 4, when the control unit detects that the channel unit that has detected the abnormality is recovered, the control unit performs an output indicating the recovery through the predetermined output unit, When the recovery control execution instruction is received via the specified input means, the recovered channel unit is switched to the spare unit, so the recovery detection is performed automatically and quickly, and the final switching to the recovered channel unit is performed. The judgment of availability can be made carefully by maintenance personnel, and the stability of the broadcasting environment can be improved.

It is a block diagram which shows the whole structure of the rebroadcast apparatus which concerns on one embodiment of this invention. It is a block diagram of a receiving amplifier. It is a block diagram of a channel unit. It is a block diagram of a reserve unit. It is a flowchart of an abnormality detection process. It is a flowchart of an abnormality switching process. It is a flowchart of a recovery detection process. It is a flowchart of a recovery switching process. It is explanatory drawing for demonstrating the influence which a setting state has on a signal level.

  Hereinafter, an embodiment of a broadcast transmission apparatus according to the present invention will be described in detail with reference to the accompanying drawings. First, after explaining the basic concept of the present embodiment, the specific contents of the present embodiment will be described, and finally, modifications to the present embodiment will be described. However, the present invention is not limited by the present embodiment.

[I] Basic concept of the present embodiment First, a basic concept common to the present embodiment will be described. The present invention is an apparatus that transmits a broadcast signal, and can be applied to any broadcast transmission apparatus that may perform transmission by switching a channel unit to a spare unit. As a typical example of such a broadcast transmission apparatus, a rebroadcast apparatus or a simple independent broadcast apparatus (for example, an audio signal or a video signal is received as an input signal, and the input signal is encoded or modulated to output an output signal. Generated and transmitted as a broadcast signal). Note that “transmitting a broadcast signal” includes transmitting the broadcast signal wirelessly as a broadcast wave, and transmitting the broadcast signal via a wire or an optical transmission line. Hereinafter, in the present embodiment, a case where the present invention is applied to a rebroadcast apparatus will be described.

  The rebroadcast apparatus according to the present embodiment is an apparatus that receives a broadcast wave as an input signal in a TV broadcast system, generates a signal that is subjected to processing including frequency conversion, and rebroadcasts. In this type of rebroadcasting apparatus, an input signal is mixed with a signal of a predetermined frequency from an oscillator, and once converted into an intermediate signal for processing. In this state, unnecessary waves are removed by the filter, and necessary signal amplification is performed. The intermediate signal that has undergone these processes is converted again and output to the same frequency as the input signal or an arbitrary frequency.

  In the rebroadcasting device, the receiver for receiving the broadcast wave and the transmitter for transmitting the broadcast wave are separated from each other and placed in different places depending on the installation form, and the receiver and the transmitter are mutually connected. There are a separation type connected by a transmission line and a non-separation type in which a receiver and a transmitter are arranged at one place. The present embodiment is applied to any form of rebroadcasting apparatus. be able to. Hereinafter, the case of the non-separable type will be described. Further, the rebroadcast apparatus to which the present embodiment is applied includes a case where it is arranged as a reception amplifier for common hearing in an apartment house, in addition to a case where it is arranged in a mountainous area or the like for measures against difficult viewing.

  Here, one of the features of the present embodiment is that when the control unit included in the rebroadcast apparatus switches the channel unit in which the abnormality is detected to the spare unit, predetermined setting information in the channel unit in which the abnormality is detected is stored. The spare unit is acquired based on the setting information. As a result, the transmission environment before the occurrence of an abnormality can be continued, and the stability of the broadcast environment can be improved.

  As the setting information to be acquired and set as described above, any information can be used as long as it is information that can be acquired by the control unit as the setting information of the channel unit in which the abnormality is detected and can be used for setting of the spare unit. Can be targeted. For example, when each channel unit is provided with a squelch for blocking a signal, and the level of a signal to be blocked by this squelch is set, the level can be used as setting information. Alternatively, each channel unit is provided with an AGC (Auto Gain Controller) for automatically adjusting the signal level, and when the target level of the signal is set in this AGC, the target level is set as setting information. be able to. In addition, the setting information acquisition source and setting destination are not limited to the channel unit. For example, if a storage unit that stores the setting information of each channel unit collectively is provided outside the channel unit, May be acquired from the storage unit, and the acquired setting information may be stored in the storage unit as the setting information of the spare unit. In the following, as setting information, the output level of the level adjustment unit for adjusting the level of the output signal of each channel unit is targeted, and the output level acquired from the level adjustment unit of the channel unit is used as the spare unit. A case where the level adjustment unit is set will be described.

[II] Specific contents (configuration) of the present embodiment
Next, specific contents of the present embodiment will be described. First, the configuration of the rebroadcast apparatus will be described. FIG. 1 is a block diagram showing the overall configuration of the rebroadcast apparatus according to the present embodiment. As shown in FIG. 1, the rebroadcasting device 1 is a device that receives and retransmits a broadcast wave, and includes a receiving antenna 2, a receiving amplifier 3, a power amplifier 4, and a transmitting antenna 5. The receiving amplifier 3 and the power amplifier 4 are connected via a coaxial cable 6.

  The receiving antenna 2 is receiving means for receiving a broadcast wave (broadcast input signal) and outputting the input signal to the receiving amplifier 3.

  The receiving amplifier 3 performs frequency conversion and unnecessary wave removal processing on the signal for each channel. FIG. 2 is a block diagram of the reception amplifier 3. The receiving amplifier 3 is generally configured to include a plurality of channel units 20, and demultiplexes the input signal output from the receiving antenna 2 for each channel and outputs the demultiplexed signals to the plurality of channel units 20. Each of the plurality of channel units 20 converts the input signal of the channel assigned to itself into an intermediate signal of an intermediate frequency, removes unnecessary waves from the intermediate signal, etc., and then converts the intermediate signal back to a transmission frequency. Output signal, and the output signal is level-adjusted and output as a broadcast signal. Details of the configuration of the receiving amplifier 3 will be described later.

  In FIG. 1, a power amplifier 4 is an amplifying means that amplifies an output signal and outputs it at a specified transmission output level. The power amplifier 4 is connected to the reception amplifier 3 via a coaxial cable 6, and an output signal output from the reception amplifier 3 via the coaxial cable 6 is amplified and output to the transmission antenna 5. .

  The transmission antenna 5 retransmits the output signal output from the power amplifier 4 as a broadcast signal.

(Configuration-receiving amplifier)
Next, the configuration of the reception amplifier 3 will be described in more detail. As shown in FIG. 2, the reception amplifier 3 includes an input terminal 7, a distributor 8, a mixer 9, an amplifier 10, a signal detection unit 11, an output terminal 12, a plurality of channel units 20, a spare unit 40, and an overall control unit. 50.

  The input terminal 7 is input means for receiving an input signal output from the receiving antenna 2. The distributor 8 is a distribution unit that distributes the input signal received at the input terminal 7 and outputs it to each channel unit 20 and the spare unit 40. The mixer 9 is a mixing unit that mixes and outputs the output signals output from the channel units 20 and the spare unit 40. The amplifier 10 is an amplifying unit that amplifies the output signal mixed by the mixer 9. The signal detection unit 11 is level detection means for detecting the level of the output signal amplified by the amplifier 10. The output terminal 12 is output means for outputting the output signal amplified by the amplifier 10 to the power amplifier 4 via the coaxial cable 6.

  The plurality of channel units 20 are units that generate and output an output signal by performing predetermined processing on an input signal by broadcast waves, and are units assigned to each of the plurality of channels. Hereinafter, the plurality of channel units 20 will be described as being distinguished as a channel unit 20A and a channel unit 20B. However, when there is no need to distinguish between them, they are simply referred to as channel units 20 collectively. In FIG. 2, only two channel units 20 are shown, but the number of channel units 20 corresponding to the number of channels to be broadcast can be provided. The plurality of channel units 20 have the same configuration.

  FIG. 3 is a block diagram of the channel unit 20. Each channel unit 20 includes filters 21 and 27, amplifiers 22 and 31, AGC 23, frequency control units 24 and 28, oscillators 25 and 29, frequency conversion units 26 and 30, a level adjustment unit 32, an output switch 33, and a signal detection unit 34. , 35, a restoration light 36, a restoration switch 37, and a unit control unit 38.

  The filter 21 is a band-pass filter that passes only an input signal having a frequency assigned to the channel unit 20 in which the filter 21 is provided. The amplifier 22 is an amplification unit that amplifies the input signal that has passed through the filter 21. The AGC 23 is an automatic gain control means for adjusting the feedback gain so that the level of the input signal falls within a predetermined reference value.

  The frequency control unit 24, the oscillator 25, and the frequency conversion unit 26 are intermediate frequency conversion units that convert an input signal into an intermediate signal having a predetermined intermediate frequency that can be easily processed. That is, the frequency control unit 24 is an oscillator control unit that controls the oscillator 25 so as to have a predetermined frequency set by a setting switch (not shown). The oscillator 25 is a local oscillating means composed of an oscillator and a PLL circuit, and its output is driven so as to have a predetermined frequency set by a setting switch. That is, the frequency oscillated from the oscillator by the control of the frequency control unit 24 is phase-synchronized with a predetermined frequency by the PLL circuit of the oscillator 25 and is output to the frequency conversion unit 26 as a reference frequency. The frequency conversion unit 26 generates an intermediate signal having a frequency difference between the input signal and the signal from the oscillator 25.

  The filter 27 is a narrowband filter that removes unnecessary waves other than the desired wave from the intermediate signal generated by the frequency converter 26. The frequency control unit 28, the oscillator 29, and the frequency conversion unit 30 are broadcast frequency conversion units that convert intermediate signals into broadcast frequency output signals. The frequency control unit 28, the oscillator 29, and the frequency conversion unit 30 are configured similarly to the frequency control unit 24, the oscillator 25, and the frequency conversion unit 26, except that the conversion frequencies are different.

  The amplifier 31 is an amplification unit that amplifies the output signal generated by the frequency conversion unit 30. The level adjustment unit 32 is a GC (Gain Controller) that adjusts the output signal to a predetermined level. The output switch 33 is an output switching unit that switches presence / absence of an output signal under the control of the unit control unit 38. The signal detector 34 is a level detector that detects the level of the input signal that has passed through the filter 21 and outputs it to the unit controller 38. The signal detection unit 35 is a level detection unit that detects the level of the output signal whose level has been adjusted by the level adjustment unit 32 and outputs the level to the unit control unit 38.

  The recovery lamp 36 is a recovery notification means that blinks or lights up when the channel unit 20 provided with the recovery lamp 36 is recovered from an abnormal state to a normal state under the control of the unit control unit 38. The recovery switch 37 receives a recovery instruction input for switching the spare unit 40 to the channel unit 20 when the channel unit 20 provided with the recovery switch 37 is recovered from an abnormal state to a normal state. It is an input means. The unit controller 38 is a control means for controlling each part of the channel unit 20. The unit control unit 38 is composed of, for example, an MPU (Micro Processing Unit), and each unit is controlled by interpreting and executing a program stored in a memory (not shown) by the MPU (units described later). The same applies to the control unit 43 and the overall control unit 50). Specific control contents of the unit controller 38 will be described later.

  Next, the spare unit 40 in FIG. 2 will be described. FIG. 4 is a block diagram of the spare unit 40. The spare unit 40 is a unit that generates and outputs an output signal by performing predetermined processing on an input signal by a broadcast wave. However, among the constituent elements of the spare unit 40, constituent elements having the same functions as those of the channel unit 20 are given the same names and symbols as the constituent elements of the channel unit 20, and the description thereof is omitted. .

  The spare unit 40 is provided with a plurality of filters 41, a selection switch 42, and a unit controller 43. The same number of filters 41 as the number of channel units 20 are provided. In the following, the plurality of filters 41 will be described separately as a filter 41A and a filter 41B. However, when there is no need to distinguish between them, they are simply referred to as a filter 41. Each of the filters 41 is configured in the same manner as the filter 21 of each channel unit 20 and passes only an input signal having a frequency assigned to each channel unit 20. For example, the filter 41A passes only input signals having the same frequency as the filter 21 of the channel unit 20A, and the filter 41B passes only input signals having the same frequency as the filter 21 of the channel unit 20B. The selection switch 42 is a changeover switch that passes only an input signal having one frequency among the input signals that have passed through the filters 41 and outputs the input signal to the subsequent stage. The unit controller 43 is a control means for controlling each part of the spare unit 40. Specific control contents of the unit control unit 43 will be described later.

  The overall control unit 50 in FIG. 2 will be described. The overall control unit 50 is a control unit for controlling each unit of the rebroadcast apparatus 1 and corresponds to the control unit in the claims. In particular, the overall control unit 50 is electrically connected to the unit control unit 38 and the signal detection unit 11 of each channel unit 20, and based on the outputs from the unit control unit 38 and the signal detection unit 11, An abnormality of the unit 20 is detected, the channel unit 20 in which the abnormality is detected is switched to the spare unit 40, and the spare unit 40 is switched to the channel unit 20 that has recovered from the abnormality. Specific control contents of the overall control unit 50 will be described later.

(processing)
Next, the process of the rebroadcast apparatus 1 configured as described above will be described. This process includes a rebroadcast process for performing rebroadcast by the channel unit 20, an abnormality detection process for detecting an abnormality in the channel unit 20, an abnormality switching process for switching the channel unit 20 in which the abnormality is detected to the spare unit 40, and the spare unit 40 It is roughly divided into a recovery detection process for detecting recovery and a recovery switching process for switching the spare unit 40 to the channel unit 20 that has recovered from the abnormality. However, since the rebroadcasting process for performing the rebroadcasting by the channel unit 20 can be executed in the same manner as the known rebroadcasting apparatus 1, the description thereof is omitted.

(Processing-Abnormality detection processing)
First, the abnormality detection process will be described. FIG. 5 is a flowchart of the abnormality detection process. This abnormality detection process is started after the rebroadcast device 1 is turned on. In this process, the unit controller 38 of each channel unit 20 monitors the level of the input signal detected via the signal detector 34 and the level of the output signal detected via the signal detector 35, Based on these levels, the presence or absence of abnormality of the channel unit 20 provided with the unit control unit 38 is monitored (SA1). Here, based on the level of the input signal and the level of the output signal, the broadcast state and the state of the channel unit 20 can be any one of the following three states: broadcasting, broadcasting suspension, and failure (broadcasting / abnormal oscillation). It is determined that an abnormality has occurred if it is in a failure state.

  Specifically, when “there is an input signal and there is an output signal”, the broadcast is in progress, when “no input signal and no output signal”, the broadcast is suspended, “there is an input signal, and If there is no output signal ”or“ no input signal and there is an output signal ”, a failure (= abnormal) is determined. However, “input signal is present” or “output signal is present” corresponds to the case where the input signal or output signal exceeds the zero level, and the case where the level is equal to or higher than the predetermined level. It may be determined as a thing. When the unit control unit 38 of each channel unit 20 determines that the channel unit 20 provided with the unit control unit 38 has an abnormality (SA1, Yes), the overall control unit 50 sends an abnormality notification signal. (SA2).

  The overall control unit 50 monitors the abnormality notification signal from the unit control unit 38 of each channel unit 20 (SA3), and when the abnormality notification signal is received (SA3, Yes), the channel that has output the abnormality notification signal It is determined that an abnormality has occurred in the unit 20, and an abnormality switching process for switching the channel unit 20 (hereinafter referred to as the switching target unit 20) that has been determined to have the abnormality to the spare unit 40 is started (SA4). Further, the overall control unit 50 outputs an abnormality notification signal to a remote monitoring center by wire or wireless (SA5). This completes the abnormality detection process.

(Processing-Abnormal switching process)
Next, the abnormality switching process will be described. FIG. 6 is a flowchart of the abnormality switching process. This abnormality switching process is started by the overall control unit 50 in the abnormality detection process. In this process, the overall control unit 50 controls the selection switch 42 of the backup unit 40 (SB1), and thereby the filter 22 corresponding to the frequency assigned to the switching target unit 20 (hereinafter referred to as switching target frequency) is connected to the amplifier 22. Connect to. Further, the overall control unit 50 sets the switching target frequency in the frequency control unit 28 of the standby unit 40 (SB2), thereby causing the frequency control unit 28 to execute control for setting the frequency of the output signal as the switching target frequency. . This switching target frequency can be determined, for example, by previously storing the frequency of each channel unit 20 in the overall control unit 50 and referring to the stored contents as necessary. Alternatively, it may be acquired from the frequency control unit 28 of the switching target unit 20. Further, the overall control unit 50 controls the output switch 33 of the standby unit 40 to be ON (SB3). Thus, rebroadcasting of the channel of the switching target frequency is started via the spare unit 40.

  The overall control unit 50 controls the output switch 33 of the switching target unit 20 to be OFF (SB4). Thus, the switching target unit 20 can be disconnected from the rebroadcast system. In addition, as a method of performing this separation, for example, the amplifier 31 of the switching target unit 20 may be stopped and controlled.

  Here, the overall control unit 50 takes over the setting information of the switching target unit 20 to the spare unit 40 when switching the switching target unit 20 to the spare unit 40 as described above. Specifically, the overall control unit 50 acquires the output level set in the level adjustment unit 32 of the switching target unit 20 via the unit control unit 38 of the switching target unit 20 (SB5). Then, the overall control unit 50 sets the output level of the level adjustment unit 32 of the backup unit 40 to the output level acquired from the switching target unit 20 via the unit control unit 43 of the backup unit 40 (SB6).

(Processing-Recovery detection processing)
Next, the recovery detection process will be described. FIG. 7 is a flowchart of the recovery detection process. This recovery detection process is started after the abnormal switching process is completed. Here, the person in charge of the monitoring center who knows that an abnormality has occurred in the channel unit 20 from the abnormality notification signal output from the overall control unit 50 in the abnormality detection process goes to the installation location of the rebroadcast device 1 and from the rebroadcast device 1. It is assumed that the switching target unit 20 is removed and repaired, and the switching target unit 20 after the repair is attached to the rebroadcast apparatus 1.

  When the switching target unit 20 attached to the rebroadcast device 1 is turned on, the unit control unit 38 of the switching target unit 20 determines whether or not the switching target unit 20 provided with the switching target unit 20 has been restored. . In this determination, the same determination as the abnormality detection in the above-described abnormality detection process is performed, and when no abnormality is detected, it is determined that it has been restored (SC1, Yes). If the restored state continues for a predetermined time (for example, several seconds) (Yes in SC2, Yes), the restoration light 36 is set to indicate that the switching target unit 20 has been restored from the abnormal state to the normal state. Turn on or blink (SC3). When the person in charge who confirms the lighting or blinking of the recovery lamp 36 operates the recovery switch 37 of the switching target unit 20 (SC4, Yes), the unit control unit 38 transmits a recovery request signal to the overall control unit 50 ( SC5).

  The overall control unit 50 monitors the recovery request signal from the unit control unit 38 of each channel unit 20 (SC6), and when the recovery request signal is received (SC6, Yes), the switching that outputs the recovery request signal It is determined that the target unit 20 has been recovered, and a recovery switching process for switching the spare unit 40 to the switching target unit 20 is activated (SC7). Also, the overall control unit 50 outputs a recovery notification signal to a remote monitoring center by wire or wireless (SC8). This completes the recovery detection process.

(Processing-Recovery switching process)
Finally, the recovery switching process will be described. FIG. 8 is a flowchart of the recovery switching process. This restoration switching process is activated by the overall control unit 50 in the restoration detection process. In this process, the overall control unit 50 controls the output switch of the switching target unit 20 to be ON (SD1). Thus, rebroadcasting of the channel of the switching target frequency is resumed via the switching target unit 20.

  Further, the overall control unit 50 controls the output switch of the spare unit 40 to be OFF (SD2). Thus, the spare unit 40 can be disconnected from the rebroadcast system. In addition, as a method of performing this separation, for example, the amplifier is controlled to stop, or the frequency of the spare unit 40 is changed to a frequency other than the frequency band targeted for broadcasting and not affecting the broadcasting. May be.

  Here, the overall control unit 50 takes over the setting information of the spare unit 40 to the switching target unit 20 when switching the spare unit 40 to the switching target unit 20 as described above. Specifically, the overall control unit 50 acquires the output level set in the level adjustment unit 32 of the backup unit 40 via the unit control unit 43 of the backup unit 40 (SD3). Then, the overall control unit 50 sets the output level of the level adjusting unit 32 of the switching target unit 20 to the output level acquired from the spare unit 40 via the unit control unit 38 of the switching target unit 20 (SD4). This completes the recovery switching process.

(effect)
As described above, according to the present embodiment, when the channel unit 20 in which the abnormality is detected is switched to the spare unit 40, the predetermined setting information in the channel unit 20 in which the abnormality is detected is acquired, and based on the setting information Since the spare unit 40 is set, the retransmission environment in the channel unit 20 in which an abnormality is detected can be taken over by the spare unit 40, and the stability of the broadcast environment can be improved. In particular, since the setting information of the channel unit 20 in which an abnormality is detected can be automatically transferred to the spare unit 40, it is not necessary for the maintenance staff to manually set the spare unit 40, and the spare unit 40 is manually set. No need for special techniques to do.

  Further, since the output level of the level adjustment unit 32 in the channel unit 20 in which the abnormality is detected is acquired and the output level is set in the level adjustment unit 32 of the standby unit 40, the level adjustment unit 32 in the channel unit 20 in which the abnormality is detected. The output level can be taken over by the spare unit 40, and the influence of the frequency characteristics of the coaxial cable 6 and the power amplifier 4 on the rear stage of the reception amplifying unit 3 can be canceled as before the occurrence of the abnormality.

  Further, when the restored channel unit 20 is switched to the spare unit 40, the setting information in the spare unit 40 is acquired, and the restored channel unit 20 is set based on the setting information. The re-transmission environment in 20 can be taken over to the restored channel unit 20 via the backup unit 40, and the stability of the broadcast environment can be improved. In particular, even when the channel unit 20 in which an abnormality is detected is repaired, even if the setting information is inadvertently changed or deleted, the setting information of the channel unit 20 is automatically updated when the abnormality occurs. Since it is possible to return to the setting information, it is not necessary for the maintenance staff to manually set the channel unit 20, and no special technique for manually setting the channel unit 20 is required.

  In addition, when the overall control unit 50 detects that the channel unit 20 that has detected the abnormality is restored, the overall control unit 50 outputs the restoration via the restoration lamp 36 and gives an instruction to perform restoration control to the restoration switch 37. The restored channel unit 20 is switched to the spare unit 40, so that the restoration detection is performed automatically and quickly, and the maintenance staff determines whether or not the switching to the restored channel unit 20 is possible. Careful implementation can improve the stability of the broadcast environment.

[III] Modifications to Embodiments Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention are within the scope of the technical idea of each invention described in the claims. Can be arbitrarily modified and improved. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved.

(Abnormality judgment method)
The abnormality determination of each channel unit 20 can be performed by other methods besides the determination based on the level of the input signal and the level of the output signal. For example, the unit control unit 38 monitors whether or not the control state of the reference frequency by the oscillator is within a predetermined control range. If not, the unit control unit 38 determines that an abnormality has occurred and controls the abnormality notification signal. You may make it output to the control part 50. FIG. Alternatively, the unit control unit 38 monitors whether the identification information (NIT: Network Information Table) included in the signal detected by the signal detection unit 11 in FIG. 2 matches the identification information of the predetermined channel, and does not match. In this case, it may be determined that an abnormality has occurred and an abnormality notification signal may be output to the overall control unit 50. In particular, the abnormality determination based on the identification information can also be performed after mixing the output signals from the channel units 20. Specifically, the overall control unit 50 determines the signal detected by the signal detection unit 11 for each channel. And the overall control unit 50 may determine whether there is an abnormality based on the identification information of each channel. In addition, for the abnormality determination, a known determination method in the rebroadcast device 1 can be adopted.

(About switching method)
In the above-described abnormality switching process and recovery switching process, switching is automatically performed by the unit control unit 38 and the overall control unit 50, but some of them may be performed manually. For example, in the abnormality switching process, when an abnormality is recognized in the level adjustment unit 32 of the switching target unit 20, it may be considered that the setting information of the level adjustment unit 32 is not desired to be taken over by the level adjustment unit 32 of the spare unit 40. In order to cope with such a case, the overall control unit 50 detects the abnormality of the switching target unit 20 and then transmits the setting information of the switching target unit 20 to the monitoring center, and the person in charge of the monitoring center instructs the takeover. The handover may be performed only when the instruction signal is output. Alternatively, in the restoration switching process, when the person in charge adjusts the setting information of the switching target unit 20 to the optimum state and the switching target unit 20 is attached to the rebroadcasting device 1, the setting information of the spare unit 40 is changed. There may be a case where it is not desired to take over the switching target unit 20. In order to deal with such a case, the overall control unit 50 detects the recovery of the switching target unit 20 and then transmits spare setting information to the monitoring center, and an instruction signal instructed by the person in charge of the monitoring center to take over. You may make it take over only when outputting. Conversely, in the recovery switching process, the standby unit 40 is switched to the switching target unit 20 after the recovery switch 37 is operated. However, the switching may be performed without waiting for this operation.

(About processing order)
The order in each process described above can be changed. For example, in the abnormal switching process of FIG. 6, after the output switch 33 of the standby unit 40 is controlled to ON (SB3), the output switch 33 of the switching target unit 20 is controlled to OFF (SB4). Or you may perform in reverse order. In particular, the acquisition of the output level set in the level adjustment unit 32 of the switching target unit 20 (SB5), and the setting of the output level of the level adjustment unit 32 of the backup unit 40 (SB6), the output switch 33 of the backup unit 40 It is preferable to carry out before controlling to ON. Similarly, in the restoration switching process of FIG. 8, the output level set in the level adjustment unit 32 of the standby unit 40 is acquired (SD3), and the output level setting of the level adjustment unit 32 of the switching target unit 20 is (SD4). ), Preferably before the output switch 33 of the switching target unit 20 is controlled to be ON.

(About output method)
In the embodiment described above, the abnormality notification signal is transmitted to the monitoring center by wire or wirelessly, but may be displayed on a display unit (for example, a liquid crystal panel) (not shown) provided in the rebroadcast device 1.

DESCRIPTION OF SYMBOLS 1,100 Rebroadcast apparatus 2,101 Reception antenna 3,102 Reception amplifier 4,103 Power amplifier 5,104 Transmission antenna 6,105 Coaxial cable 7 Input terminal 8 Divider 9 Mixer 10,22,31 Amplifier 11,34, 35 Signal Detection Unit 12 Output Terminal 20 Channel Unit 21, 27 Filter 23 AGC
24, 28 Frequency control unit 25, 29 Oscillator 26, 30 Frequency conversion unit 32 Level adjustment unit 33 Output switch 36 Recovery lamp 37 Recovery switch 38 Unit control unit 40 Spare unit 50 General control unit 106 Broadcast wave 107, 111, 112, 114 Output signal 108, 110 Frequency characteristics 109, 113 Input signal

Claims (4)

A broadcast transmission device that outputs a broadcast signal,
A channel unit that generates and outputs an output signal by performing predetermined processing on a broadcast input signal, and a plurality of channel units assigned to each of a plurality of channels;
A spare unit that generates an output signal by performing predetermined processing on the broadcast input signal and outputs the output signal as the broadcast signal;
When detecting any abnormality of the plurality of channel units, comprising a control means for switching the channel unit that detected the abnormality to the spare unit,
When the channel unit that has detected the abnormality is switched to the spare unit, the control unit acquires predetermined setting information in the channel unit that has detected the abnormality, and sets the spare unit based on the setting information. ,
Broadcast transmission device. Each of the plurality of channel units and the spare unit includes a level adjusting unit that adjusts the level of the output signal to a predetermined level,
The control means acquires, as the setting information, an output level of the level adjustment unit in the channel unit in which the abnormality is detected, and sets the output level in the level adjustment unit of the spare unit.
The broadcast transmission apparatus according to claim 1. The control means includes
When it is detected that the channel unit that has detected the abnormality is restored, the restored channel unit is switched to the spare unit,
When switching the restored channel unit to the spare unit, the setting information in the spare unit is acquired, and the restored channel unit is set based on the setting information.
The broadcast transmission apparatus according to claim 1 or 2. The control means includes
When it is detected that the channel unit that has detected the abnormality has been recovered, an output indicating that the channel unit has been recovered is output via a predetermined output unit, and an instruction to perform recovery control is received via a predetermined input unit And switching the restored channel unit to the spare unit,
The broadcast transmission apparatus according to claim 3.

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