JP2004297542A - Receiving system device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem that stable reception in receiving environment where transmission power is gradually increased and avoidance of performance degradation of other receiver by erroneous controlling a booster resulting from a cable failure, etc. can not be made compatible after starting the broadcast service. <P>SOLUTION: In a digital broadcast network, a receiving system capable of optimizing the input signal levels of each receiver connected with a receiving system at the time of increase of the transmission power and by which no erroneous control of the booster due to reduction of receiving signals of the cable failure is generated is provided by acquiring increase information of the transmission power beforehand and attenuating an input signal at a tuner part or a booster part of the receiver so as to correspond to increase of the receiving power in future based on the increase information. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a broadcast receiving system that receives a broadcast radio signal and outputs it as a video and audio signal, and particularly relates to a reception system including a booster and a receiver that amplifies a broadcast signal, that is, a broadcast radio signal, An object of the present invention is to maintain stable reception performance in a reception environment in which transmission power is gradually increased after the start of a broadcast service.
[0002]
[Prior art]
In an area where a broadcast wave with a weak received radio wave exists, a booster is generally used to amplify a broadcast signal and supply the amplified broadcast signal to a receiver (for example, see Patent Document 1).
[0003]
FIG. 9 is a block diagram for explaining the configuration of a conventional broadcast receiving system. Inside the receiver 10, a microcomputer 101 for control and information processing is connected to the microcomputer 101, and a VIF (video intermediate frequency) amplifier circuit and an SIF (sound intermediate frequency) are connected. A) a tuner 102 having an amplifying circuit, a video / audio output circuit 103 connected to the tuner 102 to output video and audio signals, and an external input device 104 for providing an external control signal to the microcomputer 101 from outside. The tuner 102 receives the detected output and automatically controls the gains of the high-frequency (RF) amplifier circuit, VIF amplifier circuit, and SIF amplifier circuit in order to prevent the detection output from fluctuating due to the strength of the broadcast wave. An AGC (automatic gain control) circuit is provided, and a detection circuit (RF-AGC circuit) 105 for outputting an RF-AGC voltage for controlling the gain of a high frequency (RF) amplifier circuit is provided in the AGC circuit.
[0004]
Further, an EEPROM 106 for storing control information is connected to the microcomputer 101. The receiver 10 includes a booster 20 for amplifying a broadcast signal and supplying the amplified signal to the tuner 102. The booster 20 amplifies the broadcast signal and a broadcast signal captured by the antenna 3 via the amplifier 201. A switch means 202 is provided to switch between an amplification path to be given to the tuner 102 and a through path to be given to the tuner 102 without passing through the amplifier 201. The microcomputer 101 controls the gain of the amplifier 201 and the switching of the switch 202.
[0005]
Note that the tuner 102 and the video / audio output circuit 103 that outputs a video signal and an audio signal can be replaced with a block compatible with digital broadcasting, and can also be used as a digital receiver.
[0006]
Next, the operation of the broadcast receiving device 100 will be described. The user operates the external input device 104 (such as a remote control device) to select a desired broadcast station. At the stage when the antenna 3 starts to capture a broadcast wave and start outputting it as a broadcast signal, the broadcast signal is supplied to the tuner 102 without amplification. The tuner 102 detects a given broadcast signal, automatically controls gains of a high-frequency (RF) amplifier circuit, a VIF amplifier circuit, and an SIF amplifier circuit by an AGC circuit, and outputs an RF-GC voltage from an RF-AGC circuit 105. It is output to the microcomputer 101.
[0007]
Here, the output characteristics of the detection circuit (RF-AGC circuit) 105 are shown in FIG. In FIG. 10, the horizontal axis represents the radio wave state of the broadcast radio wave, and the vertical axis represents the detection voltage (RF-AGC voltage). The detection circuit (RF-AGC circuit) 105 is a circuit that receives the detection output and outputs an RF-AGC control voltage for controlling the gain of the high-frequency (RF) amplification circuit. When the output is small, that is, when the radio wave condition of the broadcast radio wave is weak, the detection voltage (RF-AGC voltage) is kept high, and when the detection output increases, that is, when the radio wave condition of the broadcast radio wave becomes strong, the detection is performed. The voltage (RF-AGC voltage) is reduced. Therefore, if the detection voltage (RF-AGC voltage) serving as a reference is determined, the strength of the broadcast radio wave can be determined based on the intensity of the broadcast radio wave that achieves the voltage.
[0008]
The control of the booster by the microcomputer is as follows. If it is determined that the radio wave condition is strong, the switch unit 202 is kept connected to the through path. On the other hand, when it is determined that the radio wave condition is weak, the switch means 202 is switched to be connected to the amplification path side, the booster 20 is turned on, and the amplifier is set so as to become the reference detection voltage (RF-AGC voltage). The gain control of 201 is performed.
[0009]
[Patent Document 1]
JP-A-8-256077 (FIGS. 1 and 2 on page 9)
[0010]
[Problems to be solved by the invention]
It is assumed that a plurality of television receivers are connected in a receiving environment such as a detached house where a broadcast wave is received by an antenna and an antenna output signal is distributed to each room by a booster or a cable. When the receiving system described in the conventional example is used in this receiving environment (a booster and one of a plurality of TV receivers are the constituent elements), the antenna is changed due to a change in surrounding location conditions and the like. When the strength of the incoming radio wave to the receiver increases, the master TV receiver that controls the booster detects the increase in the received signal and controls the booster gain to decrease the received signal level. I do.
[0011]
According to the above-described operation, the input signal level of not only the master television receiver for controlling the booster but also the other television receivers is optimized, and stable reception performance can be maintained. On the other hand, the level of the received signal of the non-target TV receiver is stable, but if the level of the received signal of only the master target TV receiver that controls the booster becomes weak due to an obstacle such as cable damage, the TV reception The machine controls to amplify the booster gain to increase the received signal level. As a result, the received signal level of the TV receiver other than the master that controls the booster does not fluctuate and the received signal level increases more than necessary, and the receiver inside the receiver may become unsuccessful due to saturation. There is.
[0012]
This is because, in the indoor distribution system configured by the conventional receiving system, the gain of the booster is controlled according to the receiving condition of the master target receiver that controls the booster, so that the stable transmission environment in which the transmission power is stepwise increased. It is impossible to achieve both reception and avoidance of performance degradation of other receivers due to erroneous control of the booster due to a cable failure or the like.
[0013]
For example, in the digitalization of domestic terrestrial broadcasting, simultaneous broadcasting of digital broadcasting and existing analog broadcasting is carried out until complete digitalization. Measures are taken to gradually expand the reception area. During this transition period, a problem arises when a conventional receiving system is used and a plurality of analog and digital compatible television receivers are connected and used.
[0014]
[Means for Solving the Problems]
In order to solve the above problems, the receiving system of the present invention performs digital modulation on a transport stream in which control information such as the date and time when transmission power is increased, a target channel, and transmission power after the increase is multiplexed. In a receiving system used in a digital broadcasting network in which at least one or more broadcast wave channels exist, a booster capable of changing a gain under the control of a tuner, means for extracting control information related to the transmission power, and the booster , And the output signal of the booster is distributed to a plurality of receivers.
[0015]
According to the present invention, the booster control timing is set based on the transmission power boost information received in advance, and the execution of the booster control is determined based on the deterioration state of the reception quality. Thus, it is possible to provide a receiving system that can optimize the input signal level of each receiver and that does not cause erroneous control of the booster due to a decrease in the received signal due to a cable failure.
[0016]
Further, in order to solve the above problem, the receiving system of the present invention performs digital modulation on a transport stream in which control information such as transmission date and time when transmission power is increased, and transmission power after the increase is multiplexed. In a digital broadcasting network having at least one broadcast wave channel, a booster capable of changing a gain under control of a tuner, a unit for extracting control information regarding the transmission power, and a unit for controlling the booster are provided. It consists of a receiver, and the output signal of the booster has an output terminal for distribution to a plurality of receivers, and after acquiring information on the increase in the transmission output power, notifies the user of an operation instruction, and issues a user instruction. Optimizing the receiving system.
[0017]
According to the present invention, the booster control timing is set based on the transmission power boost information received in advance, and the execution of the booster control is determined based on the deterioration state of the reception quality. Thus, it is possible to provide a receiving system that can optimize the input signal level of each receiver and that does not cause erroneous control of the booster due to a decrease in the received signal due to a cable failure.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
A receiving system apparatus according to claim 1 of the present invention, in a receiving system used in a digital broadcasting network, acquires transmission power increase information in advance and responds to future increase in reception power based on the increase information. It is characterized by limiting the input signal strength of the tuner section or booster section of the receiver so that the booster control timing is set in advance based on the received transmission power boost information, and the booster control timing is set according to the deterioration of the reception quality. Judgment of control execution enables optimization of the input signal level of each receiver connected to the receiving system when the transmission power is increased, and a receiving system that does not cause erroneous control of the booster due to a decrease in the received signal due to cable failure. Can be provided.
[0019]
A receiving system according to a second aspect of the present invention is the receiving system according to the first aspect, wherein an output signal of the booster section is distributed to a plurality of receivers, and a transmission power received in advance. By setting the booster control timing based on the boost information and determining whether to execute the booster control based on the deterioration of the reception quality, the input signal level of each receiver connected to the receiving system can be optimized when the transmission power is boosted. In addition, it is possible to provide a receiving system in which erroneous control of a booster due to a decrease in a received signal due to a cable failure does not occur.
[0020]
According to a third aspect of the present invention, in the receiving system according to the first or second aspect, control information such as a date and time at which transmission power is increased, a target channel, and transmission power after the enhancement are multiplexed. In a receiving system used in a digital broadcasting network in which at least one or more broadcast wave channels obtained by digitally modulating a transport stream to be transmitted exist, a booster capable of changing a gain under the control of a tuner and the transmission power It is characterized by comprising a receiver having a means for extracting control information and a means for controlling the booster, and setting a control timing of the booster based on the boost information of the transmission power received in advance, according to a deterioration state of the reception quality. By judging the execution of booster control, the transmission power can be increased. Input signal level of each receiver connected to the receiving system can be optimized, and can be erroneous control of the booster by the reception signal decreases the cable failure to provide a receiving system does not occur.
[0021]
According to a fourth aspect of the present invention, in the receiving system according to the third aspect, the control unit is configured to control the reception signal quality of one or more channels obtained before and after a designated time when the transmission power is increased. When the received signal quality is degraded by a specified level or more after the transmission power is increased, the booster control is activated to operate normally so that the booster information is received in advance by the boost information of the transmission power. By setting the control timing and judging the execution of the booster control based on the reception quality deterioration status, it is possible to optimize the input signal level of each receiver connected to the reception system when the transmission power is increased, and to receive the cable failure It is possible to provide a receiving system in which erroneous control of the booster due to signal reduction does not occur.
[0022]
According to a fifth aspect of the present invention, in the receiving system according to the fourth aspect, the received signal quality uses at least one of a bit error rate, a received signal level, and a C / N ratio. The booster control timing is set based on the transmission power boost information received in advance, and the booster control execution is determined based on the deterioration state of the reception quality. It is possible to provide a receiving system that can optimize the input signal level of each of the receivers connected to the system and that does not cause erroneous control of the booster due to a decrease in the received signal due to the cable failure.
[0023]
According to a sixth aspect of the present invention, in the receiving system according to the first, second, third, fourth, and fifth aspects, a high-frequency signal received by an antenna is used as an input signal. A booster comprising an amplifying means capable of changing a gain by an external first control signal, and a first control means for generating the first control signal in response to an external second control signal Section, a channel selecting means for converting the output signal of the booster to a required baseband signal, a demodulating means for converting the baseband signal to digital data, and a digital stream for video and a digital stream for control information for converting the digital data. Data separating means for separating the digital stream for control information, control information extracting means for obtaining information on transmission output from the digital stream for control information, Decoding means for converting the video stream into digital video data for display, reception quality evaluation means for outputting a quality index of a received signal using an intermediate processing signal of the demodulation means, and controlling the booster based on the quality index. It is characterized by comprising a receiving unit composed of a second control means, setting the booster control timing based on the transmission power boost information received in advance, and judging the execution of the booster control based on the deterioration state of the reception quality. Accordingly, it is possible to provide a receiving system that can optimize the input signal level of each receiver connected to the receiving system when the transmission power is increased, and that does not cause erroneous control of the booster due to a decrease in the received signal due to a cable failure.
[0024]
The receiving system according to claim 7 of the present invention, in the receiving system according to claim 1, 2, 3, 4, 5, and 6, after acquiring the power output power increase information, It is characterized by notifying the user of the operation instruction for the optimization operation and indicating the corresponding operation procedure, setting the control timing of the booster based on the transmission power boost information received in advance, and executing the booster control according to the reception quality deterioration status. By making the above determination, it is possible to optimize the input signal level of each receiver connected to the receiving system when the transmission power is increased, and to provide a receiving system that does not cause erroneous control of the booster due to a decrease in the received signal due to a cable failure. be able to.
[0025]
A receiving system according to an eighth aspect of the present invention is the receiving system according to the seventh aspect, in which a telephone line or the like is provided for user support when the optimization operation of the receiving system is not performed according to a user's instruction. The feature is to notify the user information to the nearest service center by using the service.If a failure occurs in the receiving system when the transmission power is increased, it immediately starts support and minimizes user dissatisfaction A system can be provided.
[0026]
In the reception system according to the ninth aspect of the present invention, in the reception system according to the third aspect, the control unit may control reception signal quality of one or more channels acquired before and after a designated time when transmission power is increased. In comparison, if the received signal quality is degraded more than a specified value after the transmission power is increased, the fact that an adverse effect due to the enhancement of the transmission signal appears in the receiver is notified to the user, and the reception is performed when the transmission power is increased. When a system failure occurs, the user can specify the cause of the reception failure, and it is possible to provide a reception system in which subsequent support is efficiently performed.
[0027]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0028]
(Embodiment 1)
Hereinafter, embodiments of the present invention described in claim 1, claim 2, claim 3, claim 4, claim 5, and claim 6 of the present invention will be described with reference to FIGS. This will be described with reference to FIGS.
[0029]
FIG. 1 is a configuration diagram of a receiving system according to the present invention. The main configuration of the receiving system includes a booster 300 and a first receiver 400, and an output terminal of the booster 300 is connected to a second receiver 510 and a third receiver. The booster 300 includes an amplifying unit 310 and a first control unit 320. The amplifying unit 310 adjusts a gain of the high-frequency television signal received by the antenna by a control signal output from the first control unit 320, Output to the first receiver 400. At the same time, the signal is output to the second receiver 510 and the third receiver 500 connected by a cable. First control section 320 receives a control signal from second control section 470 in first receiver 400 and generates a control signal.
[0030]
The first receiver 400 receives a signal from the booster 300, tunes a signal of a desired channel and converts it to a baseband signal, and returns the baseband signal to a digital signal of a transport stream (TS). A demodulation unit 420, a TS separation unit 430 that separates a transport stream into packets according to types such as video / audio, data broadcasting, and control information, and a TS decoding unit that decodes a video / audio digital stream generated after separation. 440, a reception quality evaluation section 450 for generating a quality index of the reception signal using the intermediate processing signal of the demodulation section 420, and a control information extraction section 460 for extracting necessary PSI / SI information from an output signal of the TS separation section 430. And a storage unit 480 for storing necessary information, an operation of the first receiver and a gain control of the booster. Having a second control unit 470 performs. Further, the tuner unit 410, the reception quality evaluation unit 450, the control information extraction unit 460, the storage unit 480, and the second control unit 470 are connected by the same bus.
[0031]
Next, the operation of the second control unit will be described by taking as an example a domestic terrestrial digital broadcast in which the transmission output is stepwise increased as a reception environment. FIG. 7 shows a change in the magnitude of the transmission output at each broadcasting station in a time series. At the start of the broadcast (time A), the power is transmitted at 10 W output, and at the time when the boost is determined (time B), the notification information about the boost is multiplexed to the SI (service information) of each broadcast wave signal in the broadcast service area. .
[0032]
FIG. 8 is an explanatory diagram of the contents of transmission data of a broadcast station between time B and time C. The channel of the broadcast station A is 13ch, the channel of the broadcast station B is 14ch, and the channel of the broadcast station C is 15ch. During this period, the SI in which the notification information is described is multiplexed on the broadcast signals of all the channels.
[0033]
The contents of the notification information on the increase are the channel number (referred to as an engineering channel) for broadcasting the detailed information on the increase and the broadcast period. Here, for the sake of simplicity of description, the period is the same as the power increase notification period (time B to time C). In other words, the detailed information on the enhancement is multiplexed on the engineering channel whenever the notification of the enhancement is given. The detailed information on the boosting includes the channel number of the transmitting station to be boosted, the boosting ratio (or the transmission output before and after the boosting), the scheduled execution time of the boosting, and the like. Here, the target channel number is 13 ch, the boost ratio is 10 dB (10 W → 100 W), and the scheduled execution time of boost is time C. After the power is increased to 100 W at time C, the power is increased to 1 kW according to the same rule as that described above.
[0034]
The operation of the second control unit in the above reception environment will be described with reference to FIGS. 2, 3, and 4. FIG. FIG. 2 is an explanatory diagram of control in a period from time A to time C in FIG. In step 100, the channel of 15ch (or 13ch, 14ch) is selected. At this time, in the case from time A to time B, there is no plan to increase the transmission output, so in step 110, only branch to NO. If this is from time B to time C, the information of the boost notification is multiplexed on the broadcast wave, so the flow branches to YES in step 110, and if the current channel is the engineering channel (13ch), the flow goes to step 120. Then, the process proceeds to the boost information extraction processing of step 140 without changing the channel.
[0035]
On the other hand, if the current channel is other than the engineering channel (14 ch, 15 ch), the process branches at step 120 to select the target channel (= engineering channel), and the boost information is extracted. Then, in step 150, the extracted information is stored in a memory in preparation for a future increase in power. This process is executed during a time when the user is not watching the program.
[0036]
Next, a process in a period of time C after the boost information is stored in the memory in the above process will be described with reference to FIG. In step 200, when the vehicle enters the range of the first execution time, that is, in the period from the time C-α to the time C, a preliminary process for the increase in power is performed. In step 210, the channels to be boosted (13ch, 14ch, 15ch) are selected. Then, in step 220, the bit error rate and the reception electric field level of the target channel are measured, and in step 230, the bit error rate and the reception electric field level are stored in the memory in association with the target channel. Α representing the period is changed by the receiver designer as necessary. This process is executed during a time when the user is not watching the program.
[0037]
Next, processing in a period of time C + β after the above processing will be described with reference to FIG. In step 300, at time C when the boosting is performed, a process corresponding to the boosting is started. First, in step 310, the channel selected in step 210 is selected as a target channel, and in step 320, the bit error rate and the received electric field level are measured. In step 330, confirmation of increase in power is performed. Specifically, the method evaluates whether the relative value between the value of the received electric field level obtained in step 320 and the value of the received electric field level associated with the channel stored in step 230 is equivalent to the transmission power boost ratio. Can be determined.
[0038]
If the boost can be confirmed, the process branches to YES and proceeds to step 340 for checking the reception quality. Specifically, if the bit error rate measured in step 320 exceeds a value that cannot be decoded or exceeds a threshold set by the designer, it is determined that the reception quality is NG, and the process branches to YES. In the booster control process of step 350, the booster gain is controlled in steps of decreasing the gain of the booster, and each time the BER measurement is performed in step 370, the booster gain is reduced until the reception quality judgment in step 340 branches to NO. .
[0039]
If NO is determined in step 330, it is determined that power has not been increased, and the process ends. In this case, a retry is performed in consideration of the possibility that the radio wave may have been operated during the time when the radio wave is stopped. If NO is determined in step 340, the process is terminated after judging that there is no adverse effect on the reception quality due to the increased power. In the subsequent processing for increasing the power (increasing the power from 100 W to 1 kW), the same operation as described above is performed.
[0040]
In the reception quality determination in step 340, the relative ratio between the value of the bit error rate obtained in step 320 and the value of the bit error rate associated with the channel stored in step 230 is larger than the previous value. If possible, it is possible to determine that the reception quality is NG.
[0041]
Note that the power increase confirmation in step 330 and the reception quality confirmation in step 340 can improve control reliability by using information of a plurality of channels. In this case, it goes without saying that steps 210, 220, and 230 are performed for the number of target channels, and steps 310 and 320 are also performed for the target channels.
[0042]
(Embodiment 2)
Hereinafter, an embodiment of the invention described in claim 7 of the present invention will be described. The configuration of the receiver is the same as in the first embodiment. The operation of the second control unit is the same as the reception environment used in the description of the first embodiment. Only different points in the control operation will be described with reference to the drawings.
[0043]
FIG. 5 shows a process in a period from time C to time C + β after the pre-processing for increasing the power. In step 300, at time C when the boosting is performed, a process corresponding to the boosting is started. In step 400, an explanation of the change in the reception status accompanying the increase in power is displayed on the screen. After that, in step 410, the process waits for an instruction for automatic adjustment of the receiver for increasing the power. In the case of YES, the process transitions to step 310 to execute the same processing as in the first embodiment of the present invention. The description is omitted for the same processing. If NO, the process ends. The adjustment accompanying the increase in power will be handled by the user.
[0044]
For user support, it is possible to automatically notify the nearest service center of the user information by using a telephone line in cooperation with the end of the processing of step 360.
[0045]
(Embodiment 3)
Hereinafter, an embodiment of the invention described in claim 9 of the present invention will be described. The configuration of the receiver is the same as in the first embodiment. The operation of the second control unit is the same as the reception environment used in the description of the first embodiment. Only different points in the control operation will be described with reference to the drawings.
[0046]
FIG. 6 shows a process in a period from time C to time C + β after the pre-processing for increasing the power. In step 300, at time C when the boosting is performed, a process corresponding to the boosting is started. In the reception quality confirmation in step 340, the reception quality is poor and the process branches to YES and shifts to step 500. In step 500, the fact that the reception situation is degraded due to the influence on the increase in the power of the transmitting station is notified to the user, and the corresponding method is displayed on the screen. If the decision result in the step 340 is NO, the process ends. The adjustment accompanying the increase in power will be handled by the user.
[0047]
【The invention's effect】
As described above, according to the reception system of the present invention, the control timing of the booster is set based on the boost information of the transmission power received in advance, and the determination of the execution of the booster control is performed based on the deterioration state of the reception quality. It is possible to provide a receiving system that can optimize the input signal level of each receiver connected to the receiving system when the power is increased, and that does not cause erroneous control of the booster due to a decrease in the received signal due to a cable failure.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a receiving system according to claims 1 to 8;
FIG. 2 is an explanatory diagram of a control flow of a receiving system according to the first embodiment of the present invention.
FIG. 3 is an explanatory diagram of a control flow of the receiving system according to the first embodiment of the present invention.
FIG. 4 is an explanatory diagram of a control flow of the receiving system according to the first embodiment of the present invention.
FIG. 5 is an explanatory diagram of a control flow of a receiving system according to the second embodiment of the present invention.
FIG. 6 is an explanatory diagram of a control flow of the receiving system according to the third embodiment of the present invention.
FIG. 7 is a diagram illustrating a reception environment according to the first, second, and third embodiments of the present invention.
FIG. 8 is an explanatory diagram of a reception environment according to the first, second, and third embodiments of the present invention.
FIG. 9 is a configuration diagram of a conventional example.
FIG. 10 is a power detection characteristic diagram of a conventional example.
[Explanation of symbols]
3 Antenna
10 Receiver
20 boosters
101 microcomputer
102 Tuner
103 Video / audio output circuit
104 External input device
105 detection circuit
106 EEPROM
201 Amplifier
202 switch means
300 booster
310 amplifier
320 first control unit
400 first receiver
410 Tuner section
420 demodulation unit
430 TS separation unit
440 TS decoding unit
450 Receive quality evaluation unit
460 control information extraction unit
470 Second control unit
480 storage unit
500 Third receiver
510 second receiver

Claims (9)

In a receiving system used in a digital broadcasting network, information on the power increase of the transmission power is obtained in advance, and based on the information on the power increase, the input of the tuner section or the booster section of the receiver is input so that it can cope with a future increase in the reception power. A receiving system for limiting signal strength. The receiving system according to claim 1, wherein the output signal of the booster section is distributed to a plurality of receivers. A digital broadcast network in which at least one broadcast wave channel is obtained by digitally modulating a transport stream on which control information such as the date and time when transmission power is increased, a target channel, and transmission power after the increase is multiplexed. In the receiving system used in the above, a booster that can change the gain under the control of a tuner, a unit that extracts control information related to the transmission power, and a receiver that has a unit that controls the booster 3. The receiving system according to claim 1, wherein: The control unit compares the received signal quality of one or more channels obtained before and after the designated time at which the transmission power is increased, and activates the booster control when the received signal quality is deteriorated by a specified amount or more after the transmission power is increased. 4. The receiving system according to claim 3, wherein the receiving system operates so as to perform normal reception. The receiving system according to claim 4, wherein the received signal quality is evaluated using at least one of a bit error rate, a received signal level, and a C / N ratio. An amplifying means capable of using a high-frequency signal received by an antenna as an input signal and varying a gain by an external first control signal, and generating the first control signal according to an external second control signal A booster section comprising first control means, tuning means for converting an output signal of the booster to a required baseband signal, demodulation means for converting the baseband signal to digital data, Data separating means for separating a digital stream for video and a digital stream for control information, control information extracting means for obtaining information on transmission output from the digital stream for control information, and video digital data for display from the digital stream for video Decoding means for converting the received signal into a signal, and outputting a quality indicator of the received signal using the intermediate processing signal of the demodulating means. And Shin quality evaluation unit, receiving system of claims 1 to 5, wherein the consist receiving unit consisting of a second control means for controlling the booster on the basis of the quality index. The receiving system according to claim 1, wherein after acquiring the power increase information of the transmission output power, an operation instruction is notified to a user, and an optimization operation of the receiving system is performed according to the user instruction. 8. The method according to claim 7, wherein the user information is notified to a nearest service center using a telephone line or the like for user support when the receiving system optimization operation is not performed according to a user's instruction. The receiving system as described. The control unit compares the received signal quality of one or more channels obtained before and after the designated time when the transmission power is increased, and when the received signal quality is deteriorated by a specified amount or more after the transmission power is increased, the transmission signal is increased. 4. The receiving system according to claim 3, wherein the user is notified of the fact that an adverse effect due to is present on the receiver.

Images