JP4005839B2 - Reception status monitoring system, reception status monitoring method and monitoring receiver - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a reception state monitoring system, a reception state monitoring method, and a monitoring receiver for monitoring a reception state of a broadcast in a reception target area (service area) such as a television broadcast.
[0002]
[Prior art]
Broadcasting radio waves in terrestrial broadcasting are serviced over a wide area with high output by towers of radio waves (transmitting towers) represented by Tokyo Tower in large cities, but service areas are desired for local cities and villages. A relay broadcasting station is installed in a place with a good view, and it transmits from the transmitting antenna provided there.
[0003]
As is well-known, Japan is an island country with many mountains, and it is rich in undulations, and it is complicated. Therefore, the relay broadcasting station is often provided on a mountain or on a mountain overlooking the urban area, and is generally operated in an unmanned state. Due to topography, there are about 15000 relay stations in Japan. Many of them are relay broadcast stations with relatively small broadcast output.
[0004]
Broadcasting is positioned as one of the public services, so broadcast stations that have received national approval can receive broadcast radio waves with a reception quality exceeding the specified minimum in the reception target area. Must deliver.
[0005]
Therefore, it is necessary to monitor the broadcast status, but in a relay broadcasting station with a large output scale, a broadcast transmitter (satellite broadcast device) that is a transmission facility can be monitored and adjusted and operated by remote control (remote control) Equipment) is installed so that it can be monitored at all times. Since the relay broadcast station is unmanned, this monitoring is performed by laying a telephone line or a radio line and transmitting it to the center on the ground. However, since the cost of laying the line and the cost of the remote control device increase, the installation ratio is only about 20%.
[0006]
Therefore, the broadcast receiver is requested to monitor. For example, for each reception target area of each relay broadcasting station, a monitoring facility is installed in a general household such as an electric shop in the area, and commission monitoring is requested.
[0007]
In Japan, even in terrestrial digital broadcasting, where services will be started sequentially after the year 2003, satellite broadcasting devices for that purpose will be installed at relay broadcast stations, so in this case as well It is necessary to entrust the monitor at a general household. And since the monitoring is entrusted to a general household, a monitoring receiver is required so that even a person without specialized technology can easily monitor the broadcaster.
[0008]
Considering terrestrial digital broadcasting, a television receiver at home has a C / N (carrier / noise) value of received radio waves of 2 × 10. ^-4 It is known that when it becomes smaller, the situation becomes unbearable for viewing. The C / N value indicates the state of the transmission path and represents the error rate. The digital data of the broadcast content received as the television broadcast radio wave is decoded in real time and displayed on the television receiver. Even if the received data has an error, it is digital data because of the error correction function. It can be repaired. However, since the target is a TV image and a broadcast program, it is necessary to be able to restore in real time, and the limit value is the above-mentioned C / N value = 2 × 10. ^-4 It will be a value.
[0009]
Therefore, it is necessary to transmit a broadcast radio wave having a transmission quality that does not divide this value to the broadcast service area.
[0010]
[Problems to be solved by the invention]
In relay broadcasting stations that serve large-scale broadcast service areas with a large number of receiving households, a remote control device that can monitor the operation status and can be adjusted remotely is arranged. In the event that the situation requires adjustment while monitoring at the broadcasting station, a mechanism is provided to remotely adjust the broadcasting equipment of the relay broadcast station, but the equipment is expensive, so this Is installed only for relay broadcasting stations with a large output scale, accounting for about 20% of the total. For this reason, broadcasting is performed without being monitored at 80% of the relay stations, and there remains a problem in terms of quality of service.
[0011]
Broadcast equipment installed at a broadcast station may deteriorate in performance due to aging, etc., or may cause a broadcast failure due to a failure. Although it is regularly inspected, it is not sufficient.
[0012]
However, it is impossible to install expensive remote control devices at all broadcast stations. Therefore, in the broadcasting area to be serviced, the state of the broadcast wave transmitted by the broadcaster can be easily set. The establishment of a monitoring mechanism is envied.
[0013]
Accordingly, an object of the present invention is to provide a reception system that can grasp the transmission state of the relay broadcast station from the reception state in the actual receiving home in the cover area, and enables realistic and effective maintenance management. To provide a state monitoring system and a reception state monitoring method.
[0014]
In addition, it is possible to monitor in urban areas and villages where communication infrastructure such as telephone lines is established, and using this existing communication infrastructure, monitoring information can be transmitted to the center, and broadcast areas of each relay broadcasting station It is an object of the present invention to provide a reception state monitoring system and a reception state monitoring method that enable monitoring of reception states at a large number of monitoring points. In addition, a reception status monitoring system that can construct a monitoring network at low cost and can effectively monitor the broadcast status of a relay broadcast station, which is a broadcasting facility that is operated unattended in a remote and inconvenient location, and It is to provide a reception state monitoring method.
[0015]
[Means for Solving the Problems]
In order to achieve the above object, the present invention is configured as follows. That is, a server provided in the center, a plurality of monitoring receivers installed at each receiving point and observing an error rate with respect to a received broadcast radio wave at the installation point, and these monitoring receivers and the server are connected. A communication network,
The monitoring receiver is installed in a reception area of a broadcasting station that transmits a digital broadcast program, and receives a digital broadcast radio wave of the broadcast program and demodulates the demodulator, and is demodulated by the demodulator The error rate of the received broadcast signal is measured and stored in the storage means, and the error rate is compared with a predetermined reference value of the alarm at the reception point, so that the measured error rate value is the alarm comparison reference. Comprising a measuring means for generating an alarm when it becomes worse than the value, and a transmission means for transmitting the alarm and the value of the measurement error rate accumulated in the accumulating means as monitoring information via a communication network,
The server is provided with a function of collecting monitoring information transmitted from each monitoring receiver via a network and grasping a transmission state of a broadcast wave at each broadcasting station from the monitoring information. Features.
[0016]
In this system having such a configuration, a plurality of monitoring points (monitoring points) are provided in a receiving area of a broadcasting station that transmits a digital broadcast program, and monitoring receivers are provided and monitored respectively.
[0017]
That is, according to such a configuration, the monitoring receiver demodulates the digital broadcast radio wave at the reception point, measures the error rate, specifically the C / N value, and stores the demodulated received / transmitted signal. At the same time, the C / N value is compared with an alarm comparison reference value at a predetermined reception point, and an alarm is generated when the measured C / N value becomes worse than the alarm comparison reference value. It functions to transmit the / N value as monitoring information via the communication network.
[0018]
Monitoring points are monitor households (or include public facilities and offices) entrusted with monitoring. A monitoring receiver is installed there, and a server is prepared on the center side, and a network is connected from the monitoring receiver of each monitor household. The monitoring information sent via the network is collected, the transmission state of the broadcast radio wave at each broadcast station is known from the monitoring information, and the information is provided to the broadcast station corresponding to the broadcast radio wave.
[0019]
In this way, broadcast reception status information is collected for each monitor household so that the broadcast status can be monitored, so it is installed throughout the country, and it is inconvenient such as the summit that is good for the view but difficult for people to reach It is possible to grasp the status of broadcast relay broadcasters installed at many relay broadcast stations that are often installed at locations from the reception status in the actual receiving home, and realistic and effective maintenance In addition to being able to manage, communication areas such as telephone lines have been established in areas where people gather, and monitoring information can be transmitted to the center using this communication infrastructure. Broadcast status of relay broadcasters that are broadcast equipment that can be operated unattended in remote places such as monitoring status of reception at a number of monitoring points and building a monitoring network at low cost. Possible to provide a monitoring system capable of monitoring effectively.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
For example, in the terrestrial digital broadcasting, the present invention uses a C / N (carrier / noise) value of a received radio wave as a mechanism for monitoring the broadcast state of relay broadcast stations scattered in various places. / N value is measured and the situation is judged by collecting the measured C / N value at the home location from each monitor home via the communication network and monitoring its transition, and necessary instructions And commands are generated.
[0021]
Considering terrestrial digital broadcasting, in a television receiver at home, a C / N (carrier / noise) value, which is a data error rate included in received radio waves, is 2 × 10. ^-4 It is known that when it becomes smaller, the situation becomes unbearable for viewing. The C / N value indicates the state of the transmission path and represents the error rate. The digital data of the broadcast content received as the TV broadcast radio wave is decoded in real time and displayed on the television receiver. Since the received data is digital even if there is an error, the error correction function can Can be repaired. However, since the object is a TV image and a TV broadcast program, it is necessary to be able to restore in real time, and therefore the limit value is the above-mentioned C / N value = 2 × 10. ^-4 It will be a value.
[0022]
Therefore, it is necessary to transmit broadcast radio waves to the broadcast service area so as not to divide this value within the coverage area of each broadcast station. In analog broadcasting, a received image is seen to know the broadcasting state in the area, and a person judges the quality of the broadcasting state. It is not an objective judgment but a subjective judgment.
[0023]
However, in digital broadcasting, by measuring the C / N value, it is possible to determine the quality of the broadcast state based on that value. The present invention collects the C / N value against such a background and changes its state. By monitoring the above, the situation is judged and necessary instructions and commands are generated. Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
[0024]
FIG. 1 is a schematic diagram illustrating the overall system configuration of the present invention. 1, 10a, 10b,... Are broadcasting stations, 20a, 20b,... Are relay broadcasting stations, and 60a, 60b,... 60n are broadcasting stations installed in the relay broadcasting stations 20a, 20b,. It is a relay broadcaster for
[0025]
Reference numerals 30a, 30b, .about.30n are monitor households entrusted with reception monitoring, and monitoring receivers 40a, 40b, .about.40n provided by the system of the present invention will be described later in detail. . Each of the monitoring receivers 40a, 40b, to 40n can be connected to the server 51 of the center 50 using a network such as a public line.
[0026]
The center 50 is for each broadcasting channel obtained from the monitoring receivers 40a, 40b, to 40n in the monitoring homes 30a, 30b, to 30n in the broadcasting areas of the relay broadcasting stations 20a, 20b,. A function that collects, aggregates, and analyzes the monitoring information of the broadcast stations 20a, 20b,..., Grasps the broadcast status of each broadcast channel for each broadcast channel, and gives necessary instructions to the broadcast station in response to the situation. The server 51 has a function of performing business such as management of the monitor and the home. The server 51 is configured to handle this function.
[0027]
The center 50 is responsible for monitoring the transmission status of each relay broadcasting station in the jurisdiction based on information from each monitor household in the jurisdiction over a wide area. In the case of functioning as a monitoring / management agency service undertaken as a contractor, a function as a monitoring agency (for example, charging work for a broadcasting station entrusted with monitoring or payment of a monitoring commission fee to a monitor household) It is necessary to have a function for management.
[0028]
In addition to the server 51, the center 50 includes a monitor DB (database) 52, a relay broadcaster (broadcast station relay machine) DB 53, and a broadcast station DB 54.
[0029]
The monitor DB 52 is a database in which various information about each monitor home is registered. In addition to information about the monitor home, the monitor DB 52 collects information from the monitor receivers 30a, 30b, to 30n installed in the monitor home. This is a database to be stored. Here, the location (address, geographical location information), monitor receiver model information, installation date, management number (or equipment number), initial setting value (initial) Measurement C / N value), antenna type (performance information such as antenna model, antenna gain, number of stacks, number of elements, etc.), monitoring commission date, etc., as well as monitoring receivers 40a, 40b, 40n In this configuration, historical observation information (C / N value) and the like sent periodically (hourly, daily, weekly, etc.) are stored.
[0030]
The relay broadcaster DB 53 stores initial setting information (initial setting C / N values) and relaying station information (initial setting C / N values) of the relay broadcasting machines (broadcasting station relays) 60a, 60b, to 60n installed in each relay broadcasting station. This is a database in which information such as installation location, installation model, management number, installation date, maintenance inspection record book, broadcast target area information, and channel) is accumulated. Also, the broadcast station DB 54 stores various information of broadcast stations that have been commissioned for monitoring, report history information of monitoring results, and the like.
[0031]
<Configuration example of monitoring receiver>
FIG. 2 is a block diagram illustrating a configuration example of the monitoring receiver 40 (40a, 40b, to 40n), in which 41 is a noise generating unit, 42 is a noise adding unit, 43 is an OFDM receiving unit, and 44 is C / N error measurement unit, 45 is a control & information storage unit, 46 is an operation unit, and 47 is an information transmission unit.
[0032]
Among these, the operation unit 46 is for performing various settings and operations such as setting a reception C / N value for notifying an alarm or setting a reception channel of the OFDM reception unit 43. In addition, the control & information storage unit 45 performs necessary control of each unit in the monitoring receiver in correspondence with the mode at that time, accumulates the acquired C / N value and temporarily holds it as a history value, The initial setting C / N value and the C / N value serving as a reference value for the occurrence of an alarm, which are input through registration operation at the operation unit 46, are stored.
[0033]
In addition, by registering the operation unit 46 in the control & information storage unit 45, the machine number (manufacturing number, etc.) of the monitoring receiver 40 that has been input and the identification number of the monitor household are used as specific information. The information can be stored, and at the time of transmission of information, it is configured to control such that the machine number (manufacturing number and the like) of the monitoring receiver 40 and the identification number of the monitor household are transmitted together.
[0034]
In addition, the control & information storage unit 45 has a clock calendar function so that it can obtain time-by-day time information. Therefore, when storing information, the time at the time of generation of the information to be stored is stored. Stamps (date / time information) can be stored together. The control & information accumulating unit 45 functions to transmit information such as measured values accumulated so far for each preset period to the center, and receives a request upon receiving an information transmission request from the center side. For example, a function for controlling the information to be transmitted to the center and a function for receiving the setting information (for example, alarm reference value) from the center and registering the setting information.
[0035]
The noise generating unit 41 generates thermal noise corresponding to the received C / N value set by the operation unit 46, generates a thermal noise signal corresponding to the set value, and outputs it to the noise adding unit 42. Is.
[0036]
The noise adding unit 42 synthesizes and outputs the thermal noise signal output from the noise generating unit 41 and the broadcast radio wave input, and the OFDM receiving unit 43 outputs the combined output of the noise adding unit 42 to the OFDM ( It is for demodulating into an Orthogonal Frequency Division Multiplex signal. Here, OFDM is a transmission method as a transmission technology of digital terrestrial broadcasting adopted in Japan.
[0037]
The C / N error measurement unit 44 is a measurement unit that measures the C / N value of the signal from the OFDM signal output from the OFDM reception unit 43 and has an output function in the control & information storage unit 45. The C / N error measurement unit 44 compares the alarm reference value stored in the control & information storage unit 45 with the measured C / N value exceeding the alarm reference value (ie, measurement). A function of generating an alarm and giving it to the control & information storage unit 45 (when the C / N value is worse than the reference value).
[0038]
Therefore, when an alarm is generated from the C / N error measurement unit 44, the control & information storage unit 45 receives this and transmits the measured C / N value and alarm information to the center. It also has a function to make it.
[0039]
The information transmission unit 47 controls transmission to transmit information to the center under the control of the control & information storage unit 45, and the control & information storage unit 45 that has received the alarm receives the alarm information and its information. By instructing transmission of the measured C / N value at the time of the alarm occurrence, the information transmission unit 47 is connected to the center side via the network to which the information transmission unit 47 is connected, and then information about itself (this monitoring receiver), etc. In addition, it has a function of transmitting an alarm and a measured C / N value.
[0040]
<Operation example of monitoring receiver>
The operation of the monitoring receiver 40 (40a, 40b, ˜40n) shown in FIG. 2 will be described.
[0041]
When the monitoring receiver 40 is installed in a monitor home, the radio wave is taken into the noise adding unit 42 by drawing the antenna wire from the television antenna in the monitor home, and is given to the noise adding unit 42. The noise adder 42 receives the broadcast radio wave signal as an input, adds the thermal noise signal from the noise generator 41 as a noise component to the OFDM receiver 43.
[0042]
The noise generating unit 41 is a component as a noise source provided for testing, and the noise source is not used during normal operation. This is for testing whether the alarm operation is performed in the expected state when performing the initial setting. The operation mode of the control & information storage unit 45 is the “alarm test mode” in the “setting mode”. Only works in some cases. Therefore, when the operation mode is “operation mode”, no thermal noise signal is generated, and no noise addition is performed in the noise adding unit 42.
[0043]
The operation modes include “setting mode” and “operation mode”, which are selected by operating the operation unit 46. When the “setting mode” is selected by the operation of the operation unit 46, the control & information storage unit 45 receives this and operates in the “setting mode”. When “measurement” is selected by operating the operation unit 46, the control & information storage unit 45 receives this signal and causes the OFDM reception unit 43 to function, and the broadcast radio wave input obtained via the noise addition unit 42 is converted to OFDM (orthogonal). Demodulate to frequency division multiplexed) signal. Then, the demodulated OFDM signal is provided to the C / N error measurement unit 44. In this state, since there is no thermal noise signal from the noise generating unit 41, the demodulated OFDM signal for the broadcast radio wave signal received by the antenna is given to the C / N error measuring unit 44, and the C / N error is measured. The measuring unit 44 measures the C / N value of the received broadcast radio wave signal. The measurement value (measured C / N value) of the C / N error measurement unit 44 is given to the control & information storage unit 45. The control & information storage unit 45 holds the given measurement value as the C / N value of the currently received broadcast radio wave signal.
[0044]
The control & information accumulating unit 45 has a clock calendar function. Therefore, when the measured value is held, the current time stamp (date / time information) obtained by the function is stored together. To check the history and time of occurrence. When an average C / N value is obtained by measuring a plurality of times, the value is designated as an initial value to be registered, and the operation unit 46 is registered to perform control. In 45, the registered C / N value is registered and held as an initial value.
[0045]
If the initial value is determined, the alarm generation reference value is registered. In this case, the C / N value registered as the initial value is registered with a value lower by a desired standard. However, the C / N value which is the limit value of quality = 2 × 10 ^-4 The limit value is a value that does not fall below a certain value. C / N value = 2 × 10 ^-4 Is a value in the case of an error rate, and corresponds to 22 [dB] in dB.
[0046]
The relationship between error rate and dB is shown in FIG. This A relationship diagram shows values when the C / N value is taken as the error rate on the vertical axis, and values when the C / N value is taken as dB on the horizontal axis, which is parabolic. It has special characteristics. When the error rate increases beyond the limit, the dB value decreases rapidly, and when the error rate decreases, the dB value increases. However, the increase becomes smaller in the range of 22 [dB] or more.
[0047]
For example, if the measurement value is 30 [dB] in a normal reception state at a certain reception point, the initial value of 30 [dB] is registered in the monitoring receiver 40 installed at this point. However, the method for determining the reference value of the alarm at this point is a desired value lower than this. For example, if the set value as the initial value is 30 [dB], the alarm reference value for this is set to about 27 [dB]. The alarm reference value is appropriately determined based on the desired deterioration point value. However, a value equal to or lower than the limit value of 22 [dB] is not adopted, and therefore the alarm is 22 [dB] even at a point where the reception state is bad. Then, when the determined alarm reference value is input to the operation unit 46, the control & information storage unit 45 registers and holds the alarm reference value. In the above example, the set value as the initial value is 30 [dB], and the alarm reference value is 27 [dB]. In this way, the reference value of the alarm is determined to be good when the reception state is good and bad when it is bad. The alarm reference value can be set by the monitoring unit 40 alone by operating the operation unit 46, or can be implemented from the center 50 side via the network NW according to a command from the center 50 side.
[0048]
Once you have registered the alarm reference value, you want to check the alarm operation. In that case, the operation unit 46 is operated to issue a noise generation command. Noise generation can give the magnitude of noise as a C / N value. In the above example, the alarm generation is set at 27 [dB]. Therefore, 27 [dB] is instructed to perform the noise generation command operation.
[0049]
Upon receiving this command from the operation unit 46, the control & information storage unit 45 controls the noise generation unit 41 to generate noise.
[0050]
That is, since the control & information storage unit 45 controls the noise generation unit 41 so as to generate the noise having the command value, the noise generation unit 41 receives the received C / N value (example) set by the operation unit 46. Then, a thermal noise signal corresponding to 27 [dB]) is generated. The generated thermal noise signal is output to the noise adding unit 42. The noise adding unit 42 combines the thermal noise signal output from the noise generating unit 41 and the broadcast radio wave input from the antenna and outputs the synthesized signal to the OFDM receiving unit 43. The OFDM receiving unit 43 The combined output is demodulated into an OFDM signal and provided to the C / N error measurement unit 44.
[0051]
Then, the C / N error measurement unit 44 measures the C / N value of the signal from the OFDM signal output from the OFDM reception unit 43, outputs the C / N value to the control & information storage unit 45, and outputs the measurement value. If the measured C / N value reaches or exceeds this alarm reference value compared to the alarm reference value stored in the control & information storage unit 45 (that is, the measured C / N value is An alarm is generated and given to the control & information storage unit 45 (when the value is lower than or equal to the alarm reference value).
[0052]
Upon receipt of the alarm, the control & information accumulating unit 45 calculates the measured C / N value at that time, including the management number (or device number) of the monitoring receiver 40 and the specific information of the monitor household identification number. 50 is provided with a function to transmit to the center 50, control of transmission of alarm and C / N value to the center 50 is started for the information transmission unit 47. However, since the current mode is “setting mode”, the control & information storage unit 45 adds information indicating “test” to the alarm so that it can be distinguished that it is not a real alarm.
[0053]
As a result of starting control of transmission to the center 50 in this way, the information transmission unit 47 controls transmission of the information to the center 50 under the control of the control & information storage unit 45. It will be. That is, the information transmission unit 47 operates to connect the line to the center side via the network to which the information transmission unit 47 is connected, and then transmits an alarm and a measured C / N value together with information on the own (this monitoring receiver). Do something like that. Therefore, if an indicator or a display is provided in the monitoring receiver 40, the contents can be displayed here so that it can be confirmed that the alarm operation has functioned under the set conditions. become.
[0054]
Once the alarm is confirmed, the actual operation starts. For this purpose, the operation mode is set to “operation mode”. The operation mode is selected by operating the operation unit 46. When the “operation mode” is selected by the operation of the operation unit 46, the control & information storage unit 45 receives this and operates in the “operation mode”. In this state, no thermal noise signal is generated, and no noise addition is performed by the noise adding unit 42.
[0055]
In this mode, the control & information storage unit 45 causes the OFDM reception unit 43 to function, and demodulates the broadcast radio wave input obtained via the noise addition unit 42 into an OFDM (orthogonal frequency division multiplexing) signal (received broadcast by the demodulation means). Signal demodulation). Then, the demodulated OFDM signal is provided to the C / N error measurement unit 44. In this mode, since there is no thermal noise signal from the noise generating unit 41, the demodulated OFDM signal for the broadcast radio wave signal received by the antenna is supplied to the C / N error measuring unit 44. The error measuring unit 44 measures the C / N value of the received broadcast radio wave signal. Then, the measurement value (measured C / N value) of the C / N error measurement unit 44 is given to the control & information storage unit 45, and the control & information storage unit 45 receiving this gives the given measurement value to the current It is held as the C / N value of the received broadcast radio signal.
[0056]
Further, the C / N error measurement unit 44 compares the measured C / N value with the alarm reference value, and checks whether the measured C / N value is equal to or less than the alarm reference value.
[0057]
The C / N error measurement unit 44 repeats such an operation periodically or randomly. When the alarm reference value or less is reached, the C / N error measurement unit 44 generates an alarm and gives it to the control & information storage unit 45.
[0058]
In response to this, the control & information storage unit 45 reads the measured C / N value that is the target of the alarm generation, and transmits the alarm and the C / N to the information transmission unit 47 to transmit the alarm together with the time stamp. The N value and the management number (or device number) of the monitoring receiver 40 or the identification number of the monitor home are passed, and control of transmission to the center 50 is started.
[0059]
As a result of starting control of transmission to the center in this way, the information transmission unit 47 causes the center to receive an alarm, a C / N value when an alarm occurs, Therefore, transmission control is performed so that unique information and the like are transmitted including a time stamp and the like. In other words, the information transmission unit 47 operates to connect the line to the center 50 side through the network to which the information transmission unit 47 is connected, and thereafter, the alarm and the measured C / N value together with the specific information of the self (this monitoring receiver) are displayed. Send it with a time stamp. Therefore, the center side 50 receives these via the network and obtains the monitoring result at the monitor home.
[0060]
The configuration example and operation example of the monitoring receiver 40 (40a, 40b, to 40n) used in the present system have been described above. The overall flow of this system using such a monitoring receiver 40 (40a, 40b, to 40n) will be described next.
[0061]
<Operation of the entire system>
FIG. 3 is a sequence flow diagram showing an operation transition as an example of the present system. The operation of the present system of FIG. 1 will be described with reference to this figure. In this system, for each relay broadcast station, monitoring is performed for the broadcast area originally intended for the broadcast station (broadcast service area that is originally intended for viewing).
[0062]
In the broadcasting area, a plurality of points suitable for monitoring are selected, homes, offices, public facilities and the like that can ask for cooperation at each point are determined, and monitoring receivers 40 are respectively installed there. Each monitoring receiver 40 draws in a line using an existing network NW such as a public line and is connected thereto. The line does not need to be always captured, and it is sufficient if it can be connected and used when necessary. Therefore, it is sufficient if a line connection environment using a dial-up connection modem or the like is prepared.
[0063]
Each monitoring receiver 40 installed in each place can be connected to the server 51 of the center 50 by line connection using the network NW, and the server 51 can collect information transmitted from each monitoring receiver 40. . The center 50 may be one place in the whole country, may be an area unit of wide area such as East Japan, West Japan, or may be a relatively wide area area unit such as the metropolitan area, Kansai area, Tohoku area, You may take the installation form called a unit.
[0064]
In the monitor DB 52 in the center 50, a database that collects information on monitor homes is constructed. In addition to information on monitor homes, monitoring receivers 30a, 30b,. Information from 30n can be collected and accumulated. Once the monitor homes are determined, this database contains the location (address, geographical location information), monitor receiver model information, installation date, management number (or equipment number), and initial settings for each monitor home. Information such as value (initial C / N value), antenna type (performance information such as antenna model, antenna gain, number of stacks, number of elements, etc.), monitor home identification number and monitoring commission date are registered and managed Monitoring information (C) measured and sent by the monitoring receivers 40a, 40b, .about.40n in such a way that the correspondence can be ascertained based on the number (or device number) or the identification number of the monitor home and maintained. / N value and alarm) are accumulated.
[0065]
Programs broadcast from the broadcasting stations 10a, 10, and 10n are sent to the relay broadcasting stations 20a, 20b, and 20n, and the relay broadcasting stations 20a, 20n, and 20n are transmitted from the relay broadcasting stations 60a, 60b, and 60n for each station. Are transmitted as broadcast radio waves to the broadcast area of the relay broadcast stations 20a to 20n via the transmission antenna. In a viewing home in the area, the broadcast radio wave is received by a television receiver and a program is viewed. However, a monitoring receiver 40 is installed in the monitor home to monitor the reception state. The monitoring of the reception status determines the reference value of the alarm based on the normal reception status at the monitoring point, and the measured value (C / N value) of the received radio wave is measured every time using the reference value of the alarm as a comparison reference. This is done by comparing. Therefore, when monitoring the reception state, it is necessary to make initial settings first.
[0066]
Accordingly, the procedure will be described here from the initial setting stage. The initial C / N value is set by measuring broadcast radio waves in normal broadcasting transmitted from the relay broadcasting stations 20a to 20n in the respective areas. At the broadcast station 20a, 20n, the broadcast radio station receives its own broadcast radio waves and measures the C / N value multiple times, and the average value is used as the initial C / N value of the local broadcast station. The C / N value is sent to the server 51 of the center 50, and the server 51 receives it and registers it in the relay broadcaster DB 53 (S1, S2 in FIG. 3).
[0067]
In addition, in one monitor home of the monitor homes 30 (30a to 30n), a broadcast radio wave is received from a relay broadcast station, and C is received by a monitoring receiver 40 (40a, 40b, to 40n) installed in the home. The / N value is measured a plurality of times, and an average value is registered in the self-monitoring receiver 40 (40a, 40b, to 40n) as an initial setting C / N value. Also, a value that is lower than that value by a desired amount is set as a reference value for alarm, and registered in the self-monitoring receiver 40 (40a, 40b, to 40n) (S3, S2 in FIG. 3).
[0068]
Then, this registration value is sent to the server 51 of the center 50 via the network NW, and the server 51 receives it and registers it in the monitor DB 52 (S3, S2 in FIG. 3). The server 51 of the center 50 makes a determination based on the initial setting C / N value of the relay broadcasting station and the initial setting C / N value of the monitor home, and is an appropriate C that is several steps lower than the initial setting C / N value of the monitor home. / N value is determined and set as an alarm reference value (S4 in FIG. 3), and the alarm reference value is sent to the monitoring receiver 40 of the monitor home via the network NW, and the monitor home The monitoring receiver 40 receives this and registers it in the control & information storage unit 45 as an alarm reference value (S5 in FIG. 3). The alarm reference value may be set by operating the operation unit 46 in the monitoring receiver 40 on the monitor home side.
[0069]
In this way, if the alarm reference value is registered in the monitor receiver 40 of the monitor home, the process proceeds to monitoring. The monitoring receiver 40 of the monitor home receives the broadcast radio wave from the relay broadcast station, sequentially measures the C / N value, and holds it in the control & information storage unit 45 so that it can be grasped in time series. (S6 to S10 in FIG. 3).
[0070]
The control & information storage unit 45 reads the stored measured C / N value, compares it with the alarm reference value, and checks whether or not a state below the alarm reference value continues for a predetermined time or more ( S11 in FIG.
[0071]
As a result, the control & information storage unit 45 periodically measures the C / N value measured with respect to the center 50 when there is no state where the alarm is below the reference value for a predetermined time or longer. Is transmitted together with the specific information of the monitor home and the monitoring receiver 40 of the home (S20 in FIG. 3).
[0072]
In response to these, the server 51 of the center 50 collects C / N values, collates monitor homes by referring to the information in the monitor DB 52, specifies the relay broadcast station, and selects the relay broadcaster by referring to the relay broadcaster DB 53. The C / N values for each relay broadcaster are specified (S21 to S24 in FIG. 3).
[0073]
Then, the transition of the average C / N value is obtained from the aggregated C / N value history for each relay broadcaster, and the current average C / N value becomes the maintenance standard C / N value set in advance as the maintenance condition. On the other hand, it is determined (s25 in FIG. 3). As a result, when maintenance is not required, the process returns to S21, and the processes after S21 are repeated. However, if the result of determination in S25 is within the maintenance inspection condition range, it is determined that the corresponding relay broadcaster needs to be repaired, and the broadcast station operating the relay broadcaster needs maintenance inspection. Notification is made (S26 in FIG. 3). Upon receiving the notification, the broadcasting station activates and executes repair / inspection in the equipment maintenance management department (S18 in FIG. 3).
[0074]
In addition, as a result of the determination in S11, that is, in the control & information storage unit 45, the stored measurement C / N value is read out and compared with the alarm reference value, and the alarm reference value is set for a predetermined time or more. As a result of investigating whether or not the state below the threshold value continues (S11 in FIG. 3), if the state below the alarm reference value continues for a predetermined time or more, an abnormality notification is sent to the center 50 (S12 in FIG. 3).
[0075]
That is, in this case, the control & information storage unit 45 generates an alarm, sends it to the server 51 of the center 50 via the network NW, receives it on the server 51 side, registers it in the monitor DB 52 and Recognizing the abnormality (by receiving an alarm) by receiving the notification, identifying the broadcast station that is in charge of broadcasting in the area of the monitor home and which broadcast station, It is notified that an abnormality has occurred in the transmission state at the specified relay broadcast station (S12 to S15 in FIG. 3).
[0076]
At this time, the server 51 of the center 50 notifies the broadcasting station of the degree of abnormality, together with the history information of the measured C / N value and information such as the monitoring point. As a result, the broadcasting station can grasp how much the abnormality is.
[0077]
Based on this, the broadcast station can grasp the abnormality of the relay broadcaster at the relay broadcast station, and further determine whether the relay broadcaster needs to be repaired from the information provided from the server 51 of the center 50, If repair is necessary, the maintenance management department of the device activates and executes repair / inspection (S15 to S18 in FIG. 3).
[0078]
Deterioration factors of terrestrial digital broadcast signals include the occurrence of ghosts that exceed the guard interval, the Doppler effect, aging deterioration of relay broadcasters, deterioration of transmission antennas, and increase of environmental noise. Of these, in the case of the occurrence of ghost or the Doppler effect, it depends on the environment at the receiving point. Therefore, the C / C at the transmitting station (relay broadcast station) and each consigned receiving point (monitor home position) is the first. Each N value is measured and compared, a calibration table is created, and registered in the center 50. The calibration table is as shown in FIG. 4, which is obtained by measuring the change in the C / N value at the reception point (consignment point) with respect to the change in the transmission C / N value at the transmitting station. Yes, for example, when the transmitting station C / N value is “40” in the dB value, the C / N value at the consignment point M2 is 38 [dB], and the transmitting station C / N value is secured by x [dB]. In some cases, the C / N value at the consignment point M2 is y [dB], and what kind of change is exhibited is measured in advance and measured.
[0079]
Using this calibration table, an optimum alarm reference value at the reception point is determined, and is set in the monitoring receiver 40 (40a, 40b, .about.40n) as an actual alarm reference value.
[0080]
In the above embodiment, the digital broadcast radio wave at the reception point is demodulated, the C / N value is measured and stored for the demodulated received / transmitted signal, and the C / N value is determined in advance at the reception point. A function that generates an alarm when the measured C / N value becomes worse than the alarm comparison reference value compared to the alarm comparison reference value in the network, and transmits the alarm and the measured C / N value as monitoring information via the communication network. The monitoring receiver 40 is prepared, and the monitoring receiver 40 is installed in the monitor home outsourced for monitoring, and a server is prepared on the center side, and sent from the monitoring receiver 40 of each monitor home via the network. The monitoring information is collected, the transmission status of the broadcast radio wave at each transmitting station is known from the monitoring information, and the information is provided to the broadcast station corresponding to the broadcast radio wave. Monitors Broadcast reception status information for each household is collected so that the broadcast status can be monitored, so it is installed all over the country, and it is installed at inconvenient places such as the summit where the view is good but difficult for people to reach In addition to being able to grasp the status of a large number of broadcast stations for broadcasts from the actual reception status at the receiving home, it is possible to perform realistic and effective maintenance and management, as well as areas where people gather. Has established a communication infrastructure such as a telephone line, and can use this communication infrastructure to transmit monitoring information to the center, and monitor the reception status at a number of monitoring points in each broadcast broadcasting area. This makes it possible to monitor the broadcasting status of a relay broadcast station, which is a broadcasting facility that is operated unattended in a remote and inconvenient location. It is possible to provide a monitoring system.
[0081]
The present invention is not limited to the above-described embodiment, and can be implemented with various modifications. In the present invention, the above embodiment includes inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some constituent elements are deleted from all the constituent elements shown in the embodiment, at least one of the problems described in the column of the problem to be solved by the invention can be solved, and is described in the column of the effect of the invention. In the case where at least one of the effects is obtained, a configuration in which this configuration requirement is deleted can also be extracted as an invention.
[0082]
Moreover, although the method described in the embodiment of the present invention uses the C / N value, in addition to the C / N value, a delay may be considered as a factor.
[0083]
【The invention's effect】
As described above in detail, according to the present invention, the transmission status of a large number of broadcast broadcasting stations that are installed throughout the country and often installed at inconvenient places such as mountain peaks, It is possible to provide a monitoring system that makes it possible to grasp the reception status in the receiving home and enables realistic and effective maintenance management.
[0084]
In addition, because it can be monitored in urban areas and villages where communication infrastructure such as telephone lines is established, monitoring information can be transmitted to the center using this communication infrastructure, and there are many It is possible to provide a monitoring system that can monitor the reception status at a monitoring point. In addition, since monitoring points can be installed in urban areas and villages, it is possible to build a monitoring network at low cost, and to effectively monitor the broadcasting status of relay broadcasting stations that are unattended operation in remote and inconvenient locations. Can provide a monitoring system.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining the present invention, and is a schematic diagram for explaining the overall system configuration of the present invention.
FIG. 2 is a diagram for explaining the present invention, and is a block diagram showing a configuration example of a monitoring receiver 40 (40a, 40b, to 40n) according to an embodiment of the present invention.
FIG. 3 is an operation transition diagram for explaining the operation of the system of the present invention.
FIG. 4 is a diagram as an example in which the relationship between the C / N values with respect to the broadcast radio waves at the transmitting station and the consigned monitoring point (monitor home) is summarized as a calibration table.
[Explanation of symbols]
10a, 10b, ... Broadcast station
20a, 20b, ... Broadcasting station
30a, 30b, ~ 30n ... Monitor households entrusted with reception monitoring
40, 40a, 40b, ... 40n ... monitoring receiver
41 ... Noise generator
42 ... Noise adding unit
43 ... OFDM receiver
44 ... C / N error measurement section
45 ... Control & information storage unit
46 ... operation unit
47. Information transmission section
NW ... Network (for example, public line)
50 ... Center
51 ... Server
52 ... Monitor DB (database)
53. Relay broadcaster (broadcast station relay) DB,
54 ... Broadcasting station DB.
60a, 60b, .about.60n. Relay broadcaster for each broadcasting station.

Claims (7)

A server provided in the center;
Multiple monitoring receivers installed at each receiving point and observing the error rate for the broadcast radio waves received at the installation point;
It consists of a communication network that connects these monitoring receivers and the server,
The monitoring receiver is installed in a reception area of a broadcasting station that transmits a digital broadcast program, and receives a demodulated means that receives and demodulates a broadcast radio wave of the broadcast program, and a reception demodulated by the demodulating means. The error rate of the broadcast signal is measured and stored in the storage means, and the error rate is compared with a predetermined reference value of the alarm at the reception point, so that the measured error rate value is the alarm comparison reference value. It comprises a measuring means for generating an alarm when it gets worse, and a transmission means for transmitting the alarm and the value of the measurement error rate accumulated in the accumulating means as monitoring information via a communication network,
The server has a function of collecting monitoring information transmitted from each monitoring receiver via a communication network and grasping a transmission state of a broadcast wave at each broadcasting station from the monitoring information. A reception status monitoring system. A server provided in the center;
Multiple monitoring receivers installed at each receiving point and observing the error rate for the broadcast radio waves received at the installation point;
It consists of a communication network that connects these monitoring receivers and the server,
The monitoring receiver is installed in a reception area of a broadcasting station that transmits a digital broadcast program, and receives and demodulates the broadcast program by receiving a radio wave of the broadcast program and the demodulation means. While measuring the error rate for the broadcast signal and storing it as measurement information in the storage means, the measurement information stored in the storage means compares the error rate with a predetermined reference value of the alarm at the reception point, Comprising a measuring means for generating an alarm when the error rate value becomes worse than an alarm comparison reference value, and a transmission means for transmitting the measurement information stored in the storage means and the alarm as monitoring information via a communication network;
The server has a function of collecting monitoring information transmitted from each monitoring receiver via a communication network and grasping a transmission state of a broadcast wave at each broadcasting station from the monitoring information. A reception status monitoring system. A server provided in the center;
Multiple monitoring receivers installed at each receiving point and observing the error rate for the broadcast radio waves received at the installation point;
It consists of a communication network that connects these monitoring receivers and the server,
The monitoring receiver is installed in a reception area of a broadcasting station that transmits a digital broadcast program, and receives a broadcast radio wave of the broadcast program and demodulates the demodulation receiver, and is demodulated by the demodulation means The C / N value of the received broadcast signal is measured and accumulated in the accumulating means, and the C / N value accumulated in the accumulating means is compared with a predetermined reference comparison value of the alarm at the receiving point. Measuring means for generating an alarm when the N value becomes lower than an alarm comparison reference value, and transmitting means for transmitting the measured C / N value stored in the storing means and the alarm as monitoring information to the center via a communication network And consisting of
The server collects monitoring information transmitted from each monitoring receiver via a communication network, grasps the transmission state of the broadcast radio wave at each broadcast station from these monitoring information, and uses the information as the broadcast radio wave. A reception state monitoring system characterized by having a function to provide to a compatible broadcasting station. Demodulating means for receiving and demodulating digital broadcast radio waves, means for measuring an error rate for a received broadcast signal demodulated by the demodulating means, storing information on the measured error rate, and predetermining the error rate If the measurement error rate value is worse than the alarm comparison reference value compared to the alarm comparison reference value at the receiving point, an alarm is generated, and these alarm and measurement error rate values are monitored via the communication network. And a transmission means for transmitting to a server provided in the center. In the reception area of a broadcasting station that transmits a digital broadcast program, the broadcast radio wave of the broadcast program is received and demodulated, and the error rate is measured and stored for the demodulated received broadcast signal, and the error rate is determined in advance. When the measurement error rate value is worse than the alarm comparison reference value compared to the alarm comparison reference value at that reception point, an alarm is generated, and these alarms and measurement error rate values are monitored as information via a communication network. Install multiple monitoring receivers that have the function to transmit, prepare a server on the center side, collect monitoring information sent from each monitoring receiver via the communication network, and from each of these monitoring information broadcast stations A reception state monitoring method characterized by grasping the transmission state of broadcast radio waves on the Internet. In the reception area of the broadcasting station that transmits the digital broadcast program, the broadcast radio wave of the broadcast program is received and demodulated, the error rate of the demodulated received broadcast signal is measured and stored as measurement information, and the stored measurement information Is transmitted to the center via the network, and the measurement information is compared with an alarm comparison reference value at a predetermined reception point, and the measurement error rate value is compared with the alarm comparison reference value. An alarm is generated when it gets worse, and a plurality of monitoring receivers having a function of transmitting the alarm and measurement error rate values as monitoring information via a communication network are installed, and a server is prepared on the center side. Collect monitoring information sent from the network via the communication network, and grasp the transmission status of broadcast radio waves at each broadcasting station from these monitoring information Reception state monitoring method characterized by the. In the reception area of the broadcasting station that transmits the terrestrial digital broadcast program, the digital broadcast radio wave of the broadcast program is received and demodulated, and the C / N value is measured and stored for the demodulated received broadcast signal. An alarm is generated when the measured C / N value becomes worse than the alarm reference value by comparing the C / N value with a predetermined reference value of the alarm at the receiving point. Install multiple monitoring receivers that have the function of transmitting via the communication network as monitoring information, prepare a server on the center side, collect monitoring information sent from each monitoring receiver via the communication network, From this monitoring information, the transmission status of broadcast radio waves at each broadcasting station is known, and this information is provided to broadcast stations compatible with the broadcast radio waves. Method.

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