JP3992537B2 - Broadcast content monitoring device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a broadcast system, and in particular, when broadcasting via a relay line, a monitor screen that receives a broadcast wave is always used to monitor the broadcast start and end of the local station and the broadcast content being broadcast. A broadcast content monitoring device that can output a broadcast content monitoring signal only by a device system, even if it is not monitored by a human system.InRelated.
[0002]
[Prior art]
Conventionally, when broadcasting through a relay line, in order to monitor the broadcast start and end of its own station and the broadcast content being broadcast, for example, it actually receives a broadcast wave and displays it on a monitor screen, A method is used in which the video transmitted from the local station to the relay line is visually compared to confirm that the local station has started broadcasting and the broadcasting has ended.
[0003]
This method will be described with reference to FIG.
Fig. 2 conceptually shows a method for confirming the start and end of own station broadcasting in the prior art.
In FIG. 17, the broadcasting system is composed of equipment related to a broadcasting station, a key station, a relay line, and a program distribution line. For simplicity, there are three broadcasting stations and one key station. Yes.
In FIG. 17, the signal switch 26 provided in the broadcasting station a27 selects, for example, the VTR 20, the still picture device 22, the output signal of the studio 24, the signal received from the relay vehicle (not shown), or the like as necessary. To connect to the trunk line 28. In addition, the signal switching unit 26 displays the broadcast indicator lamp a21 when the output signal of the VTR 20 is selected and connected to the trunk line 28, and the broadcast indicator lamp b23 when the output signal of the still image device 22 is selected. When the output signal of the studio 24 is selected, the broadcasting indicator lamp c25 is turned on.
[0004]
  The relay line 28 transmits the output signal of the signal switch 26 of the broadcasting station a27 to the key station 29. In the key station 29, an appropriate timing is determined according to program transmission data or manually.GThen, the signal from the broadcast station a27,SuccessorA signal transmitted through a line or an output signal of its own station, for example, a VTR (not shown) is switched.
[0005]
Further, the output signal of the key station 29 is transmitted to the broadcast station a27 via the program distribution line a30, to the broadcast station b39 via the program distribution line b38, and to the broadcast station c41 via the program distribution line c40. . The broadcast station a27 will be described as an example. First, the signal of the program distribution line a30 is input to the control device 31. For example, the control device 31 switches a signal received from a relay vehicle or an output signal from the program distribution line a30 according to program transmission data or by manual operation at an appropriate timing, and uses the broadcast station relay line 32 to change to the broadcast station 33. Transmit to.
[0006]
The broadcasting station 33 modulates a carrier wave using a signal transmitted through the broadcasting station relay line 32 and transmits it to a general receiving household from the transmitting antenna 34. The broadcast station a27 is provided with a broadcast wave receiver 36 connected to a receiving antenna 35 for receiving the broadcast wave, and its output is connected to an in-station monitor 37. If necessary, broadcast wave video and audio are transmitted. Can be monitored. The program distribution line b38 and the broadcast station b39, and the program distribution line c40 and the broadcast station c41 have the same relationship.
The combination of the receiving antenna 35, the broadcast wave receiver 36, and the in-station monitor 37 performs the same operation as the combination of an antenna and a receiver in a general receiving household.
[0007]
For example, when broadcasting the output of the studio 24 of the broadcasting station a27 nationwide, the output of the studio 24 is first selected by the signal switch 26, connected to the relay line 28, and transmitted to the key station 29. Then, the key station 29 transmits the output of the relay line 28 to broadcast stations around the country, that is, the broadcast station a27, the broadcast station b39, and the broadcast station c41 using the program distribution line a30, the program distribution line b38, and the program distribution line c40. . Further, the broadcast station a27, the broadcast station b39, and the broadcast station c41 respectively output the output of the program distribution line a30, the program distribution line b38, and the program distribution line c40 by a control device (not shown for the broadcast station b39 and the broadcast station c41). Connect to the broadcaster's trunk line of the broadcast station and transmit to each broadcaster.
[0008]
Now, let t be the time difference between the input and output signals generated by the trunk line 28._d1The time difference between the input / output signals of the program distribution line a30, program distribution line b38, and program distribution line c40 is t._d2, The time difference between the input signal of the broadcasting station 33 and the signal that is actually converted into a broadcast wave by modulating the carrier wave by the signal t_d3, The time difference generated while the broadcast wave receiver 36 demodulates and outputs to the in-station monitor 37 is t._d4And
[0009]
By the way, the signal switch 26 has a function of turning on the on-broadcast indicator lamp c25 when the output of the studio 24 is selected. However, in general, the time when the key station 29 connects the signal of the broadcasting station a27 to the program distribution line a30, the program distribution line b38, and the program distribution line c40 is the time when the output of the studio 24 is selected by the signal switch 26. Is different.
[0010]
FIG. 18 shows the operation timing of each of the above signals, or of the indicator lamp and the in-station monitor.
18, (a) is an output signal of the studio 24 of the broadcasting station a27, (b) is an operation of the signal switch 26, (c) is an operation of the broadcasting indicator c25 of the studio 24, and (d) is a relay line. 28, (e) is the output signal of the key station 29, (f) is the output signal of the program distribution line a30, (g) is the content of the broadcast wave, (h) is the display on the in-station monitor 37, and (i) ) Indicates the time during which the output of the broadcasting station a27 is broadcast.
[0011]
Time difference t in FIG._d1, T_d2, T_d3And t_d4Is the time difference t described above, respectively._d1To t_d4It is shown in agreement with the definition up to.
The time difference t_d3Depends mainly on the encoding system and modulation system of the broadcaster, and the time difference t_d4Depends on the demodulation method of the broadcast wave receiver. Furthermore, these time differences t_d1, T_d2, T_d3And t_d4Are generally different numbers. In an actual system, a time difference also occurs between the output of the studio 24 and the input of the relay line 28, the input / output of the key station 29, and the output of the program distribution line a30 and the input of the broadcasting station 33. However, both of these time differences are t_d1, T_d2, T_d3And t_d4Ignored here because it is small compared to.
[0012]
In FIG. 18, the output of the studio 24 of the broadcasting station a27 is, for example, six cuts of cut 0 to cut 5, and the times when these cuts change are t.₁, T₂, T_Three, T_Four, T_Five(See FIG. 18A). Cut 0 and cut 5 are so-called discard cuts that are sent to the relay line 28 but are not used for actual broadcasting. Further, the time at which the output of the studio 24 is connected to the relay line 28 by the signal switcher 26 is, for example, t in the middle of the cut 0._onThe time to release the connection is t in the middle of cut 5_off(See FIG. 18 (b)), the broadcast indicator lamp c25 of the studio 24 is linked to the operation of the signal switch 26, so that the time t_onUntil the time t_onTo time t_offUntil the time t_offThereafter, the light is turned off (see FIG. 18C). On the other hand, the output of the trunk line 28 is time difference t._d1By
t_Ten= T_on+ T_d1 (1)
, Switch from no output to cut 0,
t₁₁= T_off+ T_d1 (2)
In FIG. 18, the state changes from cut 5 to no output (see FIG. 18D).
[0013]
Next, the key station 29, for example, initially transmits a signal of another station, and the time t when the output of the trunk line 28 changes to cut 1₆Switch to the output of the trunk line 28 at time t in the middle of the cut 4₇It is assumed that the signal is switched to the signal of the other station again (see FIG. 18 (e)). Where time t₆Is
t₆= T₁+ T_d1 (3)
Sought by.
[0014]
Here, the time difference t between the input and output of the program distribution line a30_d2The output of the program distribution line a30 is switched from the signal of the other station to the output of the studio 24 of the broadcasting station a27.
t₁₂= T₆+ T_d2= T₁+ T_d1+ T_d2 (4)
Time t₁₂(See FIG. 18 (f)), the output from the studio 24 of the broadcasting station a27 is switched to the signal of the other station.
t₁₃= T₇+ T_d2                                    (5)
Time t₁₃(See FIG. 18 (f)).
[0015]
Furthermore, the time difference t at the broadcasting station 33_d3, And the time difference t at the broadcast wave receiver 36_d4Considering time t₁When the broadcasting station a27 switches the output of the studio 24 to cut 1, the display on the in-station monitor 37 of the broadcasting station a27 switches to cut 1 at time t determined by the equation (6).₈(See FIGS. 18 (h) and (i)).
t₈= T₁+ T_d1+ T_d2+ T_d3+ T_d4 (6)
In addition, time t₇Even if the key station switches from the output of the studio 24 of the broadcasting station a27 to the signal of the other station, the display on the in-station monitor 37 of the broadcasting station a27 switches to the signal of the other station at time t determined in (7).₉(See FIGS. 18 (h) and (i)).
t₉= T₇+ T_d2+ T_d3+ T_d4 (7)
[0016]
  As above
t₈≠ t_on                                               (8)
  Also,
t₉≠ t_off                                              (9)
Therefore, it is impossible to know the time when the output of the studio 24 is broadcasted nationwide by turning on the broadcasting indicator light c25..Even if the broadcasting station a27 switches the output of the studio 24, the time difference t in the equation (10) is actually set._d10After the elapse, the display on the in-station monitor 37 is switched.
  t_d10= T_d1+ T_d2+ T_d3+ T_d4                          (10)
  Further, when the key station 29 switches from the output of the studio 24 of the broadcasting station a27 to the signal of the other station, the time difference t in the expression (11) is similarly applied._d11After the elapse, the display on the in-station monitor 37 is switched.
  t_d11= T_d2+ T_d3+ T_d4                                (11)
[0017]
  These time relationships also apply between the broadcasting station a27 and the receiving household. Usually, in such a case, a direct communication line provided between the key station 29 and the broadcast station 27 or a portable telephoneStoryThe switch timing is informed.
  However, when a relay vehicle is used from a place other than the studio 24 of the broadcasting station a27, such contact means may not be taken. Also, in order to ensure reliable operation even when a means of communication is secured, the station monitor 37 is always used for monitoring by a human system without relying solely on the broadcast indicator light c25, direct communication line, or mobile phone, and broadcast. A method of visually confirming that the wave content has been switched to the output of the studio 24 of the broadcasting station a27 and that the signal has been switched to the signal of another station is used. However, this method requires a lot of human labor and could cause a broadcast accident.
[0018]
[Problems to be solved by the invention]
As described above, a signal from a broadcasting station is once transmitted to a key station via a relay line, and the signal is transmitted from the key station to another broadcasting station via a program distribution line, and transmitted as a broadcast wave to a general receiving household. In doing so, there were the following first to third problems regarding the monitoring of the broadcast contents.
The first problem is that since the key station is in between, the output of the signal switch of the broadcasting station a is not transmitted as it is as a broadcast wave, but the time during which the broadcasting indicator lamp is lit and the broadcasting station The time during which the output of a is broadcast is not the same. Further, even when the output of the signal switch of the broadcasting station a is transmitted as it is as a broadcast wave without switching operation at the key station, the time difference between the time when the broadcasting station a operates the signal switch and the station The time when the monitor display changes does not match. Therefore, the broadcasting station a side does not know the timing of switching when monitoring the broadcast content, and must always keep an eye on the image.
[0019]
The second problem is that the relay line, the program distribution line, the broadcasting station, and the broadcast wave receiver each have a time difference between the input and output, so the output of the broadcast station a and the output of the in-station monitor that has received the actual broadcast wave Will have a time difference. For this reason, the broadcast station a must monitor the broadcast contents having a time difference from each other, and the larger the time difference, the more difficult it is to monitor the broadcast contents.
[0020]
The third problem is that, for example, when a broadcast station a receives a signal from a relay station outside the station and transmits the signal to the key station through a relay line for broadcasting, only the voice of the relay vehicle from the key station is transmitted. It is not always possible for the above-mentioned relay vehicle to always receive the return voice, i.e., so-called N-1, from which the signal is removed. In general, in this case, the sound of the broadcast wave will be monitored, but since the sound of the site is also included, the announcer will speak while listening to his / her voice with earphones, and may make an announcement. It may be very difficult, or the monitor sound of the broadcast wave may enter the microphone and cause howling.
[0021]
The object of the present invention is to solve the above-mentioned problems, and enables monitoring that the output of the own station is transmitted as the contents of the broadcast wave without always watching the in-station monitor of the broadcast station, Another object of the present invention is to provide a broadcast content monitoring apparatus and a return voice generation apparatus that can generate N-1 return voices obtained by removing the own station voice from broadcast waves.
[0022]
[Means for Solving the Problems]
In order to achieve the above object, the broadcast content monitoring apparatus of the present invention obtains, for each frame, a difference between a signal obtained by gradually delaying a broadcast station signal and a signal obtained by receiving and demodulating a broadcast wave, and the obtained difference is determined in advance. When it is within the set allowable range, it is determined that the broadcasting of the broadcasting station signal has started, and the time difference between the broadcasting station signal and the broadcasting wave is measured, and only the time difference obtained by the measurement is measured. The broadcast station signal is delayed, a difference between the delayed signal and the signal obtained by receiving and demodulating the broadcast wave is obtained, and when the obtained difference exceeds a predetermined allowable range, broadcasting of the broadcast station signal is performed. The present invention is characterized in that it is determined to be completed.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail based on an embodiment of the invention with reference to the accompanying drawings.
As described above, the broadcast content monitoring apparatus of the present invention performs the following processing after the time when the signal switch 26 connects the signal of its own station to the relay line 28 in the broadcasting station a27 in FIG. It is comprised so that it may perform.
[0027]
That is, first, a time difference in the delay direction is given to the output signal of the signal switch 26 of the broadcasting station a27 (see FIG. 17 for the reference sign), and compared with the output signal of the broadcast wave receiver 36. When it is determined that it is, information that the signal of the local station is output as a broadcast wave is extracted. Thereafter, the output signal of the signal switch 26 is observed in time series in units of frames, and when a large change is detected between frames, the signal of the frame and the detection time are stored in advance in the storage means. . Then, when the same signal as the signal of the frame is detected from the output signal of the broadcast wave receiver 36 after that time, the signal of the frame and the detection time are stored. The previously stored time is subtracted from the newly stored time to obtain a new time difference.
[0028]
After that, the signal obtained by delaying the output signal of the signal switch 26 by a new time difference is compared with the output signal of the broadcast wave receiver 36, and it is repeatedly determined whether or not they are the same signal. At that time, it is determined that the signal of the own station is not output on the broadcast wave, and the determined information is taken out. When the signal switch 26 disconnects its own signal from the relay line 28, the above operation is stopped.
[0029]
FIG. 1 is a block diagram showing the principle configuration of the broadcast content monitoring apparatus of the present invention.
In FIG. 1, 1 is an A / D converter, 2 is an image memory a, 3 is signal storage means, 4 is signal comparison means, 5 is determination means, 6 is control / processing means, 7 is a receiving antenna, and 8 is broadcast. A wave receiver, 9 is an A / D converter, and 10 is an image memory b.
[0030]
Next, the operation will be described.
The video output signal of the signal switch 26 of the broadcast station a27 shown in FIG. 17 is converted into a digital signal by the A / D converter 1 of FIG. 1 and input to the image memory a2. The image memory a2 can store data of a plurality of frames. The output of the image memory a2 is branched into two, one being input to the signal comparison means 4 via the signal storage means 3, and the other being directly input to the signal comparison means 4.
[0031]
The broadcast wave of the broadcast station a27 (see FIG. 17) is demodulated by the broadcast wave receiver 8 connected to the reception antenna 7 shown in FIG. 1, and a video signal is output. This video signal is converted into a digital signal by the A / D converter 9 and input to the image memory b10. The image memory b10 can store data of a plurality of frames in the same manner as the image memory a2. The output of the image memory b10 is input to the signal comparison means 4.
[0032]
The output of the signal comparison unit 4 is used for determination processing by the determination unit 5. The determination means 5 can take out the broadcast content monitoring signal from this. In-broadcast information of the signal switch 26 of the broadcasting station a27 is input to the control / processing means 6. The control / processing unit 6 is connected to each of the image memory a2, the image memory b10, the signal storage unit 3, the signal comparison unit 4, and the determination unit 5, and exchanges data, an operation based on the data, and an operation result Control of the entire device, such as delivery of broadcasts and output of broadcast content monitoring signals.
[0033]
Further, the circuit operation of FIG. 1 will be described in detail using a flowchart.
2 to 6 are flowcharts showing the operation of the broadcast content monitoring apparatus of the present invention.
First, a description will be given with reference to FIG.
First, after the flowchart starts, in order to determine whether or not a signal is sent from the broadcast station a27 (see FIG. 17) to the trunk line, the signal switch 26 (see FIG. 17) of the broadcast station a27 is used. It is determined by the control / processing means 6 whether or not broadcast information is output (step ST1). If not output, step ST1 is repeated. If output, the initial value t of the time difference between input and output is stored in the signal storage means 3._do1(Step ST2). Next, the initial value e of the allowable error is given to the signal comparison means 4.₀₁(Step ST3).
[0034]
Next, the output of the signal switch 26 of the broadcasting station a27 is A / D converted using the A / D converter 1 (step ST4). The A / D converted digital data is stored in the image memory a2 in time series (step ST5). The amount of data stored corresponds to a plurality of frames. Further, the signal storage means 3 applies t to the data of the image memory a2._d01Is given (step ST6). In parallel with the processing of steps ST4 to ST6, the output of the broadcast wave receiver 8 is A / D converted using the A / D converter 9 (step ST7). The A / D converted digital data is stored in time series in the image memory b10 (step ST8). Similar to the image memory a2, the amount of data stored in the image memory b10 corresponds to a plurality of frames.
[0035]
Hereinafter, a description will be given with reference to FIG.
After completion of step ST6 and step ST8, the output data of the signal storage means 3 and the output data of the image memory b10 are input to the signal comparison means 4 (step ST9). The signal comparison means 4 compares the data corresponding to the same pixel position on the screen of one frame using both data, and the difference is an allowable error e.₀₁It is determined whether the following is true (step ST10). Tolerance e₀₁If it exceeds the above, the process returns to step ST4 and step ST7 to repeat the above process. At this time, t_d01Is updated (step ST10-1 (see FIG. 2)).
[0036]
Tolerance e₀₁In the following cases, the control / processing means 6 determines whether or not broadcast information is output from the signal switch 26 of the broadcast station a27 (step ST11). If broadcast information is output, the determination means 5 outputs a broadcast content monitoring signal indicating that the broadcast content matches (step ST12). Further, at this time, the time t when the image memory b10 fetches the image.₃₀The time t when the image memory a2 captured the image from₃₆And subtract t_d01Is updated (step ST12-1). If the broadcast information is not output, the control / processing means 6 operates so as to return to the first step ST1.
[0037]
Hereinafter, a description will be given with reference to FIG.
After step ST12-1, the A / D converter 1 performs A / D conversion on the output of the signal switch 26 of the broadcasting station a27 (step ST13). The A / D converted digital data is stored in the image memory a2 in time series (step ST14). When the signal comparison unit 4 and the control / processing unit 6 detect that a large change has occurred between frames in the output of the image memory a2, that is, the difference in data between frames is an allowable value e.₁₁The time t₃₁Is obtained (step ST15). This tolerance e₁₁Is a value previously given to the signal comparison means 4 by the control / processing means 6. Thereafter, the control / processing means 6 sends an allowable error e to the signal comparison means 4.₀₃(Step ST16). In parallel with the processing of steps ST13 to ST16, the output of the broadcast wave receiver 8 is A / D converted by the A / D converter 9 (step ST17). Next, the A / D converted digital data is stored in time series in the image memory b10 (step ST18).
[0038]
Hereinafter, a description will be given with reference to FIG.
After step ST16 and step ST18, t calculated in step ST15₃₁Data in the image memory a2 and t₃₁The subsequent data in the image memory b10 is input to the signal comparison means 4 (step ST19). The signal comparison means 4 compares the data corresponding to the same pixel position on the screen of one frame from both data, and the difference between them is an allowable error e.₀₃It is determined whether or not the following is true (step ST20). Difference is tolerance e₀₃If it exceeds, return to step ST17 and time t₃₁Stored in the image memory a2 at time t₃₁The subsequent process of comparing the data in the image memory b10 is repeated.
[0039]
On the other hand, the difference is the tolerance e₀₃If it is less than or equal to tolerance e₀₃The first time t₃₂To find a new time difference t_d02Is defined by equation (12) (step ST21).
t_d02= T₃₂-T₃₁                                  (12)
Furthermore, t calculated by the equation (12)_d02Is an appropriate value according to equation (13) (step ST22).
0 <t_d02<T_dmax                                  (13)
Where t_dmaxIs the maximum input / output time difference that can occur in a broadcasting network in which the broadcasting station a27 constitutes a key station. t_d02Does not satisfy the expression (13), the process returns to step ST12-1, and the above-described processing is repeated. t_d02When the above equation (13) is satisfied, the control / processing means 6 causes the signal storage means 3 to input / output time difference t_d02(Step ST23). For the signal comparison means 4, an allowable error e₀₄(Step ST24).
[0040]
Hereinafter, a description will be given with reference to FIG.
Next, the A / D converter 1 converts the output of the signal switch 26 of the broadcasting station a27 into digital data (step ST25). Subsequently, the A / D converted digital data is stored in time series in the image memory a2 (step ST26). Further, the data in the image memory a2 is t_d02Is given (step ST27). In parallel with these processes, the output of the broadcast wave receiver 8 is converted into digital data by the A / D converter 9 (step ST28). The A / D converted digital data is stored in time series in the image memory b10 (step ST29).
[0041]
Next, the output data of the signal storage means 3 and the data of the image memory b10 are input to the signal comparison means 4 (step ST30). The signal comparison means 4 compares the data corresponding to the same pixel position on the screen of one frame using both data, and the difference between them is an allowable error e.₀₄It is determined whether the following is true (step ST31). Tolerance e₀₄If it exceeds, the determination means 5 determines that the broadcast part of the own station has ended, outputs a broadcast content monitoring signal indicating that the broadcast content does not match (step ST34), resets the state, and then operates. To stop the flowchart. On the other hand, tolerance e₀₄In the case of the following, the control / processing means 6 further determines whether broadcast information is being output from the signal switch 26 of the broadcast station a27 (step ST32). If broadcast information is not output, step ST34 is executed to set the flowchart to END. On the other hand, if broadcast information is output, the control / processing means 6 outputs a signal indicating that the broadcast contents match, and maintains the state (step ST33). Then, it returns to step ST25 and step ST28, and repeats the above-mentioned process.
[0042]
Furthermore, it demonstrates in detail using a time chart.
FIG. 7 is a time chart showing the operation of the broadcast content monitoring apparatus of the present invention.
In FIG. 7, (a) is the output of the signal switch 26 of the broadcast station a27, (b) is the broadcast information of the signal switch 26 of the broadcast station a27, and (c) is the output of the signal switch 26 of the broadcast station a27. (D) is the data acquisition time of the image memory a2, (e) is the output of the broadcast wave receiver 8, (f) is the data acquisition time of the image memory b10, and (g) is the time difference between input and output of the signal storage means 3. (H) shows the allowable error of the signal comparison means 4, and (i) shows the state of the broadcast content monitoring signal.
[0043]
The signal switch 26 of the broadcasting station a27_onTo time t_offUntil then, the output of the broadcasting station a27 is connected to the relay line (see FIG. 7A). Since the broadcast information of the signal switch 26 is linked to the operation of the signal switch 26, the time t is the same as the connection to the trunk line._onTo time t_offUntil then, the broadcast information is output to the broadcast content monitoring apparatus (see FIG. 7B). The output of the signal switch 26 of the broadcasting station a27 is at time t._onTo time t_offIt is assumed that there is a change from cut 1 to cut n in the time until (see FIG. 7C). The image memory a2 and the image memory b10_onThereafter, data obtained by A / D converting the output signal of the signal switch 26 of the broadcasting station a27 and data obtained by A / D converting the output of the broadcast wave receiver 8 (see FIG. 7 (e)), respectively, at a constant cycle. Capture is performed (see FIGS. 7D and 7F). Also, time t_onIn the signal storage means 3, the initial value t of the time difference between input and output is_d01(See FIG. 7 (g)), the signal comparison means 4 has an initial value e of allowable error.₀₁(See FIG. 7 (h)), and an allowable error e between frames of data in the image memory a2.₁₁Is given.
[0044]
The key station 29 initially sends the signal of the other station to the program distribution line, switches from the middle of the cut 1 of the signal from the broadcast station a27, and sends the signal of the broadcast station a27 to the program distribution line until the middle of the cut n. It is assumed that the signal of the other station is transmitted again. At this time, the output of the broadcast wave receiver is at time t.₃₄Until the time t₃₄Thereafter, time t₃₅Until the time of t₃₅After that, it becomes the signal of other stations.
[0045]
Time t_onThereafter, the data in the image memory a2 is converted to the above input / output time difference t._d01Compared with the data in the image memory b10 with a delay. And these differences are the tolerance e₀₁Time t determined to be₃₀A broadcast content monitoring signal indicating that the broadcast content matches is output (see FIG. 7 (i)). Time t₃₀Thereafter, the output maintains that state.
[0046]
Time t₃₀Thereafter, the process of measuring an accurate time difference from the output of the signal switch 26 of the broadcasting station a27 to the output of the broadcast wave receiver 8 is entered. First, a new allowable error e for the signal comparison means 4.₀₃give. Next, the difference between the frames of the data in the image memory a2 is the allowable error e.₁₁Time t when it was determined that the time exceeded₃₁And this time t₃₁The data for one frame in the image memory a2 is stored. This saved data and t₃₁The subsequent output of the broadcast wave receiver 8, that is, the data in the image memory b 10 is compared, and as a result of the comparison, the difference between them is an allowable difference e₀₃Time t determined to be₃₂Save. T obtained in this way₃₁And t₃₂From the time difference t using equation (12)_d02Ask for. Furthermore, when this numerical value satisfies the equation (13), t_d02Is an accurate time difference and the signal storage means 3 is t_d02Is given as the time difference between input and output. Further, a new allowable error e for the signal comparison means 4 is obtained.₀₄give.
[0047]
Time t₃₂Thereafter, the above-described time difference t between input and output_d02And tolerance e₀₄Make a determination using. The output of the signal storage means 3 and the output of the image memory b10 are compared, and the comparison result is e₀₄When the broadcast information is output from the signal switching unit 26 as described below, the output state of the broadcast content monitoring signal indicating that the broadcast content matches is maintained. The output of the broadcast wave receiver 8 is time t₃₅When the signal is switched to the signal of the other station at time t, the result of comparing the output of the signal storage means 3 and the output of the image memory b2 is the time t₃₃In the following, e₀₄Over. At this time, even if the broadcast information is output from the signal switch 26, the time t₃₃Thereafter, a broadcast content monitoring signal indicating that the broadcast content does not match is output. The allowable error e₀₄E does not determine that the broadcast content has been switched even if the key station 29 superimposes characters or the like on the signal of the broadcast station a27.₀₁, E₀₃Is set to a larger value.
[0048]
  FIG. 8 shows a time difference measuring circuit for measuring the time difference between the output signal of the signal switch of the broadcasting station a and the video signal obtained by demodulating the broadcast wave for constituting the broadcast content monitoring apparatus of the present invention. ing.
  In FIG. 8, 50 is an A / D converter, 51 is a synchronous separation / clock generation circuit, 52 is a frame memory a, 53 is a one-frame delay memory, 54 is a comparator, and 55 is an allowable value e.₁₁Setter 56, 1 frame memory, 57 comparator, 58 allowable value e₀₃Setter 59, inverter, 60 OR circuit, 61 AND circuit, 62 RS freeTsuPhu FroTsu63, a pulse length counter, 64, a decision circuit, 65, an allowable value 0, t_dmaxSetter 66, time difference measurement circuit 66, system clock generation circuit 67, frame memory b 68, A / D converter 69, synchronization separation / clock generation circuit 70, broadcast wave receiver 71, reception 72 It is an antenna.
[0049]
The operation will be described.
In FIG. 8, the video output signal of the signal switcher of the broadcasting station a is input to the A / D converter 50 and the synchronization separation / clock generation circuit 51, and based on the clock generated by the synchronization separation / clock generation circuit 51. A / D converted and read into the frame memory a52. The frame memory a52 can store video data of one frame or more, and reads data in synchronization with the system clock supplied from the system clock generation circuit 67.
[0050]
On the other hand, the broadcast wave received by the receiving antenna 72 is demodulated by the broadcast wave receiver 71, and the demodulated video signal is input to the A / D converter 69 and the synchronization separation / clock generation circuit 70, and the synchronization separation / clock is received. Based on the clock generated by the generation circuit 70, A / D conversion is performed and read into the frame memory b68. Similar to the frame memory a52, the frame memory b68 can store one or more frames of video data, and reads data in synchronization with the system clock supplied by the system clock generation circuit 67.
[0051]
The output data of the frame memory a52, the output data of the frame memory b68, the system clock, and the broadcasting information of the signal switcher of the broadcasting station a are input to the time difference measuring circuit 66. It is assumed that the in-broadcast information of the signal switch of the broadcasting station a becomes logic H while the output of the broadcasting station a is connected to the relay line.
[0052]
The output of the frame memory a52 is connected to a 1-frame delay memory 53, a comparator 54, and a 1-frame memory 56. The comparator 54 has an allowable value e.₁₁A setting device 55 is connected. The comparator 54 compares the output of the frame memory a52 between frames, and determines an allowable value e.₁₁Time t beyond₃₁The output becomes logic H. That is, the time t when the signal switch output of the broadcasting station a changes greatly.₃₁Is detected. Also, time t₃₁The data in the frame memory a52 is stored in the 1-frame memory 56.
[0053]
The 1-frame memory 56 and the frame memory b68 are connected to the comparator 57. Further, the comparator 57 has an allowable value e.₀₃A setting device 58 is connected. The comparator 57 receives the time t₃₁The data stored in the one frame memory 56 and the data sequentially read from the frame memory b68 are compared, and the difference between the two is e.₀₃Time t when₃₂The output becomes logic H. That is, the time t when the video signal output obtained by demodulating the broadcast wave changes greatly.₃₂Is detected.
[0054]
  Broadcasting information of the signal switching unit of the broadcasting station a is connected to the AND circuit 61 and the inverter 59, and the output of the inverter 59 is passed through the OR circuit 60 to the RS flip-flow.TsuThe output of the AND circuit 61 is connected to the R input of the group 62 and the S input. When the broadcast information is logic L, RS flip flowTsuThe output of the loop 62 keeps the logic L state, and when the broadcast information is logic H, the time t₃₁T₃₂RS only for the time untilTsuThe output of the flop 62 becomes logic H. Time t when the output of the RS flip-flop 62 is logic H_d02Is measured using a pulse length counter 63 and output to the determination circuit 64. The judgment circuit 64 has an allowable value 0, t_dmaxA setting device 65 is connected, and the result measured by the pulse length counter 63 satisfies the expression (13).PlaceTime difference t_dmaxOutput the data. In this way, it is possible to measure the time difference between the input of the trunk line, that is, the output of the signal switch of the broadcasting station a and the video signal obtained by demodulating the broadcast wave.
[0055]
  FIG. 9 is a block diagram showing a first embodiment of the broadcast content monitoring apparatus of the present invention.
  In FIG. 9, 80 is a frame memory c, 81 is a comparator, and 82 is an allowable error e.₀₁, E₀₄Setter 83, time difference t_d01, T_d02Setter, 84, inverter, 85, AND circuit, 86, OR circuit, 87, rise detection circuit, 88, inverter, 89, OR circuit, 90, RS freeTsuPhu FroUp, 91 is AND timesRoad, 92 is a sequence control circuit, and 120 is a broadcast content monitoring device. Other circuit elements are denoted by the same reference numerals as in FIG.
[0056]
The operation will be described.
The output of the frame memory a52, the output of the frame memory b68, the system clock, and the broadcasting information of the signal switch of the broadcasting station a are all input to the time difference measuring circuit 66, and as described with reference to FIG. Measure the time difference between the output of the switch and the video signal obtained by demodulating the broadcast wave. The inverter 84, the AND circuit 85, the OR circuit 86, the rising edge detection circuit 87, the inverter 88, the OR circuit 89, the RS flip-flop 90, and the AND circuit 91 are all logic circuits for outputting a broadcast content monitoring signal. It is composed.
[0057]
In addition to the time difference measuring circuit 66, the system clock includes a frame memory a52, a frame memory b68, a frame memory c80, and a time difference t._d01, T_d02It is supplied to the setting device 83 and the sequence control circuit 92, respectively. The data in the frame memory a52 is read according to the system clock and written into the frame memory c80. Time difference t_d01, T_d02The setter 83 has a time difference t between the input and output data of the frame memory c80 immediately after the broadcast information of the signal switcher of the broadcasting station a becomes logic H._d01A read clock is supplied so that Also, tolerance e₀₁, E₀₄The setter 82 has an allowable error e with respect to the comparator 81.₀₁Set. The output data of the frame memory c80 and the output data of the frame memory b68 are compared by the comparator 81, and the broadcast contents match and an allowable error e₀₁When it is determined that it is within the range, the logic H is output to the AND circuit 85. At this time, the broadcasting information of the signal switching unit of the broadcasting station a is logic H, and the allowable error e of the comparator 81₀₄Since the signal indicating the following is logic L, the RS flip-flop 90 is set, the output of the AND circuit 91, that is, the broadcast content monitoring signal changes from the logic L state to the logic H state, and the broadcast content matches. Indicates that
[0058]
  Thereafter, the time difference measuring circuit 66 performs the time difference t_d02And measure the time difference t_d01, T_d02Output to setting device 83.Time difference t_d02After the measurement is completed, the time difference t_d01, T_d02The setter 83 has a time difference t between input and output data of the frame memory c80._d02A read clock is supplied so that Also, tolerance e₀₁, E₀₄The setter 82 has an allowable error e with respect to the comparator 81.₀₄Set. The lighter 81 compares the output data of the frame memory c80 and the output data of the frame memory b68, and the broadcast contents match, and the allowable error e₀₄When it is determined that it is within the range, the logic H is output to the inverter 84 and the OR circuit 86. As a result, RS freeTsuThe flop / flop 90 is maintained in the set state, and the broadcast content monitoring signal maintains the logic H state.
[0059]
  On the other hand, the comparator 81 compares the output data of the frame memory c80 and the output data of the frame memory b68, and the allowable error e₀₄When it is determined that the signal exceeds the output, the output to the inverter 84 and the OR circuit 86 changes from logic H to logic L. The output of the inverter 84 is connected to the rising edge detection circuit 87, so that the RS flip-flow circuit is connected.Tsu, The broadcast content monitoring signal is changed to a logic L state, and it is output that the broadcast content does not match.
[0060]
FIG. 10 is a block diagram showing a second embodiment of the broadcast content monitoring apparatus of the present invention.
In FIG. 10, 100 is a CPU, 101 is a memory, and 102 is an input / output interface. Other circuit elements are denoted by the same reference numerals as in FIGS. 8 and 9.
[0061]
The operation will be described.
10, the main part of the broadcast content monitoring apparatus 120 is replaced with a CPU 100, a memory 101, and an input / output interface 102, and the same operation as the monitoring apparatus described with reference to FIG. 9 is realized using software. Also in this case, the broadcast content monitoring device receives the output signal of the signal switch of the broadcast station a, the broadcast wave, and the broadcast information of the signal switch of the broadcast station a, and outputs the broadcast content monitor signal.
In the present embodiment, the CPU 100 may be replaced with, for example, a high-speed DSP (Digital Signal Processor).
[0062]
FIG. 11 is a block diagram showing a third embodiment of the broadcast content monitoring apparatus of the present invention.
In FIG. 11, 130 is a falling detection circuit, 131 is a rising detection circuit, 132 is an inverter, 133 is an OR circuit, and 134 is an RS flip-flop. Other circuit elements are denoted by the same reference numerals as in FIGS.
[0063]
  The operation will be described.
  In the present embodiment, when the broadcast content monitoring device 120 described with reference to FIGS. 9 and 10 determines that the broadcast content matches, that is, the broadcast is in progress, a device use warning signal is generated. is there.
  In this embodiment, the time t when the output of the signal switch of the broadcasting station a is connected to the trunk line_onRS flip flow is detected by detecting that the broadcast information of the signal switcher has changed from logic L to H.Tsu, The device in-use warning signal is changed from logic L to H, and the state is maintained. At the same time, the broadcast content monitoring device 120 is activated to output a broadcast content monitoring signal. When the broadcast of the broadcast station a is finished and the broadcast content monitoring device 120 detects a mismatch, the broadcast content monitoring signal changes from logic H to logic L. This change is detected by the falling detection circuit 130, and the RS flip-flop 134 is reset to change the device in-use warning signal from logic H to L.
[0064]
FIG. 12 is a block diagram showing a fourth embodiment of the broadcast content monitoring apparatus of the present invention.
The reference numerals assigned to the constituent elements are the same as those given in FIGS.
In this embodiment, the broadcast content monitoring device 120 compares and monitors the output signal of the program distribution line a and the content of the broadcast wave of the broadcast station a. Here, the broadcast information on the program distribution line a of the broadcast station a becomes logic H at the time when the broadcast station a is broadcasting the output of the program distribution line a, and the broadcast content monitoring device 120 is operated. . As a result, it is possible to monitor whether the content of the program distribution line a matches the content of the broadcast wave.
[0065]
FIG. 13 is a block diagram showing a fifth embodiment of the broadcast content monitoring apparatus of the present invention.
The reference numerals assigned to the constituent elements are the same as those given in FIGS.
In this embodiment, the broadcast content monitoring device 120 compares and monitors the output signal of the control device of the broadcast station a and the content of the broadcast wave of the broadcast station a. Here, the broadcasting information of the control device of the broadcasting station a becomes the logic H at the time when the broadcasting station a is broadcasting a signal received from a device such as a studio, a VTR, or a relay vehicle in its own station. It is assumed that the monitoring device 120 is operated. As a result, it is possible to monitor whether or not the content of the broadcast station a sent from the own station to the broadcaster relay line matches the content of the broadcast wave implemented in the service area of the own station.
[0066]
In the first to fifth embodiments of the broadcast content monitoring apparatus of the present invention described above, both the output signal of the signal switch of the broadcasting station a and the output signal of the broadcast wave receiver 71 are analog signals. In the case where these are digital signals, the configuration shown in FIGS. 14A and 14B may be used as an example.
In FIG. 14, 110 is a video data extraction circuit, 111 is a clock recovery circuit, 112 is a buffer memory, 113 is a receiving antenna, 114 is a broadcast wave receiver, 115 is a clock recovery circuit, 116 is a video data extraction circuit, and 117 is Buffer memory.
[0067]
The operation will be described.
As shown in FIG. 14A, when a digital video signal and a digital audio signal are multiplexed and transmitted from a broadcasting station a by, for example, an SDl (Serial Digital Interface) signal, a clock is reproduced by a clock reproduction circuit 111. And the video data extraction circuit 110 is operated based on the reproduced clock, and only the digital video signal is extracted. After the extracted signal is read into the buffer memory 112, it is output as digital video data to the frame memory a52 of FIGS.
[0068]
Further, as shown in FIG. 14B, the broadcast wave received by the reception antenna 113 is demodulated by the broadcast wave receiver 114 to obtain a digital signal. The clock is regenerated from the digital signal by the clock regenerating circuit 115, the video data extracting circuit 116 is operated based on the regenerated clock, and only the digital video signal is extracted. The extracted signal is read into the buffer memory 117 and then output as digital video data to the frame memory b68 in FIGS.
Further, the case where a digital video signal is handled has been described above, but it goes without saying that the same processing can be performed on a digital audio signal and the same effect can be obtained.
[0069]
Next, the sending back voice generating apparatus of the present invention will be described.
FIG. 15 is a block diagram showing an embodiment of the sending back voice generating apparatus of the present invention.
In FIG. 15, 121 is an A / D converter, 122 is a memory d, 123 is an A / D converter, 124 is an AND circuit, 125 is a subtractor, 126 is a D / A converter, 127 is an audio monitor or earphone, 128 is a time difference corrector, and 129 is a weighting circuit. Other circuit elements are denoted by the same reference numerals as in FIGS.
[0070]
The operation will be described.
First, the sending back voice generating device of the present invention is configured using the above-described broadcasting content monitoring device 120 of the present invention.
In FIG. 15, the broadcast content monitoring device 120 receives the video output signal of the signal switch of the broadcast station a, the broadcast wave of the broadcast station a, and the broadcast information of the signal switch of the broadcast station a, and the time difference t_d02Data, an audio signal from the broadcast wave receiver 71 and a broadcast content monitoring signal are output.
[0071]
The audio output signal of the signal switcher at the broadcasting station a is converted into digital data by the A / D converter 121 and read into the memory d122. The time difference corrector 128 is a time difference t obtained from the video signal of the broadcast wave receiver._d02 And the time difference between the audio signal of the signal switcher of the broadcasting station a and the time difference of the audio signal are set in the memory d122. The audio signal obtained from the broadcast wave receiver 71 is converted into a digital signal by the A / D converter 123. The A / D converted digital signal and the broadcast content monitoring signal are input to the AND circuit 124, and the weighting circuit is used only when the broadcast station a is broadcasting and the broadcast content monitoring signal output from the broadcast content monitoring device 120 is logic H. The digital audio level is adjusted by 129 and input to the subtractor 125. The subtractor 125 subtracts the data read out from the memory d122 by giving the time difference after the above correction from the audio data of the broadcast wave. Then, the subtracted output is converted into an analog signal by the D / A converter 126, thereby outputting the sound from which the sound multiplication from the broadcasting station a is removed from the sound monitor or earphone 127.
[0072]
  The so-called N-1 sending back sound can be generated by the sending back sound generating apparatus described above. In FIG. 15, memory d122, time difference corrector 128, AND circuit 124, weighting timesRoadNeedless to say, 129 and the subtractor 125 are replaced with a combination of CPU, input / output interface, and memory as shown in FIG. This device can also be applied when relaying from outside the station using a relay vehicle. In this case, the audio signal of the relay car is used instead of the audio output signal of the signal switch of the broadcasting station a, and the logic H signal is used instead of the in-broadcast information of the signal switch of the broadcasting station a. The same effect can be obtained by inputting for the time that the signal is transmitted.
[0073]
In the embodiment of the present invention for generating a return audio according to the present invention, the output signal of the signal switch of the broadcasting station a and the output signal of the broadcast wave receiver 71 are both analog signals. In this case, as an example, the configuration may be as shown in FIGS. 16 (a) and 16 (b).
In FIG. 16, reference numeral 140 denotes an audio data extraction circuit, 141 denotes a clock reproduction circuit, 142 denotes a buffer memory, 143 denotes an audio data extraction circuit, 144 denotes a clock reproduction circuit, and 145 denotes a buffer memory. Other circuit elements are denoted by the same reference numerals as in FIG.
[0074]
The operation will be described.
As shown in FIG. 16A, the clock reproduction circuit 141 reproduces the clock from the digital signal output of the broadcasting station a, and the audio data extraction circuit 140 is operated based on the reproduced clock to extract only the digital audio signal. The extracted signal is read into the buffer memory 142 and then output to the memory d122 of FIG. 15 as digital audio data.
[0075]
Also, as shown in FIG. 16B, the broadcast wave received by the receiving antenna 113 is demodulated by the broadcast wave receiver 114 to obtain a digital signal. The clock is regenerated from the digital signal by the clock regenerating circuit 115, the video data extracting circuit 116 is operated based on the regenerated clock, and only the digital video signal is extracted. The extracted signal is read into the buffer memory 117 and then output as digital video data to a frame memory (not shown) in the broadcast content monitoring apparatus 120 of FIG.
[0076]
On the other hand, the audio data is reproduced by the clock reproduction circuit 144, and the audio data extraction circuit 143 is operated based on the reproduced clock to extract only the digital audio signal. The extracted signal is read into the buffer memory 145 and then output to the AND circuit 124 of FIG. 15 as digital audio data.
[0077]
As described above, according to the broadcast content monitoring apparatus of the present invention, the output of the signal switch of its own station, the broadcasting information of the signal switch of its own station, and the broadcast wave of its own station are input to the apparatus of the present invention. As a result, for example, even if a special control signal is not superimposed on the broadcast wave, it is possible to monitor the broadcast content while the signal of the local station is being output on the broadcast wave.
[0078]
The initial value t of the time difference between input and output given to the signal storage means 3 (see FIG. 1)._d01Is the above t_d02If the value is close to, extremely good operation can be obtained, but t_d01Of course, good operation can be obtained even when = 0. In addition, the time difference between input and output of the entire broadcasting network, that is, t in the above equation (10)._d10If you know t_d01, T_d02Instead of t_d10Needless to say, a good operation can be obtained by using. Or t calculated | required by step ST12-1 of FIG._d01Value is 0 <t_d01<T_dmaxIf t is satisfied, this t_d01T_d02Can be used instead of_.here_,t_dmaxIs_,This is the same as that shown in equation (13). In this case, it goes without saying that steps ST13 to ST21 (see FIGS. 4 and 5) can be omitted.
[0079]
Furthermore, the signal of the own station₅₀In the image memory a2 (see FIG. 1), the output of the broadcast wave receiver of the local station is taken in the image memory b10 (see FIG. 1) for each frame and compared. Allowable value e (see FIG. 1)₀₁You may use the time difference when it becomes the following. Further, the output signal of the signal switching unit of the local station is not limited to the output of the studio, but may be, for example, a VTR, a still image device, or a relay vehicle signal received by the local station.
[0080]
In addition to broadcasting nationwide via a key station, for example, broadcasting the studio output / VTR, still image device, and relay vehicle signals received by the local station only to the local service area. In this case, the output of the signal switch 26 is directly input to the control device, and then the signal is transmitted to the broadcasting station via the broadcasting station relay line to transmit the broadcast wave. Of course, the present invention is applicable even in such a case.
[0081]
In addition, the present invention can be applied to any case where a general terrestrial microwave line, communication satellite line, or optical fiber line is used as a relay line or a program distribution line. Furthermore, instead of a combination of a key station, program distribution line, control device, broadcast station relay line, broadcast station, and transmission antenna, a signal is sent directly from the key station to a broadcast satellite or communication satellite, and a broadcast wave is sent to each home. Of course, the present invention can also be applied to a broadcasting form.
[0082]
In the above description, the broadcast content monitoring apparatus of the present invention is configured using the video signal as an example, but it goes without saying that the same processing can be performed on the audio signal and the same effect can be obtained. Yes.
[0083]
Further, for example, in order to obtain a return voice in a relay car using the broadcast content monitoring apparatus of the present invention, the time difference t between input and output with respect to the voice output of the relay car._d02And subtracted from the audio signal obtained from the broadcast wave receiver.
[0084]
  In the above description, the signal comparison means calculates the difference between two input data in the time domain and compares it with an allowable error. For example, the signal comparison means performs DFT (Discrete Fourier Transform) calculation. Needless to say, the comparison in the frequency domain, the comparison performed by calculating the correlation coefficient, or the comparison of the two data can be performed by combining these methods. In addition to comparison and calculation for each pixel, all the pixels included in one frame are converted into a plurality of pixels composed of a plurality of pixels.TheOf course, it is possible to apply a method of calculating an average value, median value, standard deviation, etc. of a luminance signal, a color difference signal, etc., and comparing and calculating with a block of another frame in the block. It is. Furthermore, there is a method in which the signal comparison means compares two input data with an allowable error in one frame and outputs a comparison result, but the comparison with the allowable error is performed in a plurality of frames to increase the comparison accuracy. Of course it is possible.
[0085]
【The invention's effect】
According to the present invention, it is possible to measure the time difference between the input of the trunk line and the video signal obtained by demodulating the broadcast wave during the broadcast of the own station without using a special signal.
Furthermore, it is possible to monitor whether or not the broadcast contents match by comparing the signal transmitted from the own station with a signal obtained by delaying the measured time difference and demodulating the broadcast wave.
[0086]
Also, when the signal sent to the program distribution line is broadcast by appropriately selecting the input signal used for monitoring the broadcast content, or when the signal is broadcast from a relay vehicle, for example. Can be monitored in the same way.
In addition, it is possible to issue information that warns that the device is in use from the measured value of the time difference and the information indicating the state in which the signal is being sent from the device of the local station to the trunk line. It is possible to prevent an erroneous operation such as inadvertently stopping the device until the broadcast ends. As a result, it is possible to reduce the burden on the operating side and to provide a high-quality broadcasting service for the receiver.
[0087]
Further, by subtracting the signal obtained by adding the above time difference to the audio signal sent from the local station or the relay vehicle from the audio signal obtained by demodulating the broadcast wave, the local station or the relay vehicle, for example, It is possible to obtain a return voice from which the voice has been removed.
[Brief description of the drawings]
FIG. 1 is a block diagram showing the basic configuration of a broadcast content monitoring apparatus according to the present invention.
FIG. 2 is a flowchart showing the operation of the broadcast content monitoring apparatus of the present invention.
FIG. 3 is a flowchart showing the operation of the broadcast content monitoring apparatus of the present invention.
FIG. 4 is a flowchart showing the operation of the broadcast content monitoring apparatus of the present invention.
FIG. 5 is a flowchart showing the operation of the broadcast content monitoring apparatus of the present invention.
FIG. 6 is a flowchart showing the operation of the broadcast content monitoring apparatus of the present invention.
FIG. 7 is a time chart showing the operation of the broadcast content monitoring apparatus of the present invention.
FIG. 8 shows a time difference measuring circuit for measuring a time difference between an output signal of a signal switch of a broadcasting station a and a video signal obtained by demodulating a broadcast wave for constituting a broadcast content monitoring apparatus of the present invention. ing.
FIG. 9 is a block diagram showing a first embodiment of the broadcast content monitoring apparatus of the present invention.
FIG. 10 is a block diagram showing a second embodiment of the broadcast content monitoring apparatus of the present invention.
FIG. 11 is a block diagram showing a third embodiment of the broadcast content monitoring apparatus of the present invention.
FIG. 12 is a block diagram showing a fourth embodiment of the broadcast content monitoring apparatus of the present invention.
FIG. 13 A fifth embodiment of the broadcast content monitoring apparatus of the present invention is shown in a block diagram.
FIG. 14 shows a configuration example of the broadcast content monitoring apparatus of the present invention in the case where the output signal of the signal switch of the broadcasting station a and the output signal of the broadcast wave receiver are digital signals.
FIG. 15 is a block diagram showing an embodiment of the sending back voice generating device according to the present invention.
FIG. 16 shows an example of the configuration of the return audio generating device of the present invention when the output signal of the signal switcher of the broadcasting station a and the output signal of the broadcast wave receiver are digital signals.
FIG. 17 conceptually shows a method for confirming the start and end of own station broadcasting in the prior art.
FIG. 18 shows the timing at which each of the signals or the operation of the indicator lamp and the in-station monitor is performed.
[Explanation of symbols]
1,9 A / D converter
2 Image memory a
3 Signal storage means
4 signal comparison means
5 judgment means
6 Control and processing means
7 Receiving antenna
8 Broadcasting wave receiver
10 Image memory b
20 VTR
21 Broadcast indicator a
22 Still image equipment
23 Broadcast indicator b
24 Studio
25 Broadcast indicator c
26 Signal selector
27 Broadcasting station a
28 trunk lines
29 key stations
30 Program wiring line a
31 Control device
32 Broadcasting station trunk line
33 Broadcasting Station
34 Transmitting antenna
35 Receiving antenna
36 Broadcast wave receiver
37 Station monitor
38 Program wiring line b
39 Broadcasting station b
40 Program distribution line c
41 broadcasting station c
50,69 A / D converter
51,70 Sync separation / clock generation circuit
52 frame memory a
53 1 frame delay memory
54,57 comparator
55 Allowable value e₁₁Setting device
56 1 frame memory
58 Allowable value e₀₃Setting device
59 Inverter
60 OR circuit
61 AND circuit
62 RS FreeTsuPhu FroTsuThe
63 Pulse length counter
64 judgment circuit
65 Allowable value 0, t_dmaxSetting device
66 Time difference measurement circuit
67 System clock generator
68 frame memory b
71 Broadcast wave receiver
72 Receive Antenna
80 frame memory c
81 comparator
82 Tolerance e₀₁, E₀₄Setting device
83 time difference t_d01, T_d02Setting device
84,88 inverter
85, 91 AND circuit
86,89 OR circuit
87 Rise detection circuit
90 RS freeTsuPhu FroUp
92 Sequence control circuit
100 CPU
101 memory
102 I / O interface
110, 116 Video data extraction circuit
111,115 clock recovery circuit
112,117 Buffer memory
113 Receive antenna
114 Broadcast wave receiver
120 Broadcast content monitoring device
121,123 A / D converter
122 memory d
124 AND circuit
125 subtractor
126 D / A converter
127 Voice monitor or earphone
128 time difference corrector
129 Weighting circuit
130 Falling detection circuit
131 Rise detection circuit
132 Inverter
133 OR circuit
134 RS freeTsuPhu FroTsuThe
140 Voice data extraction circuit
141, 144 clock recovery circuit
142,145 Buffer memory
143 Voice data extraction circuit

Claims (1)

  The difference between the signal obtained by delaying the broadcast station signal stepwise and the signal obtained by receiving and demodulating the broadcast wave is obtained for each frame, and when the obtained difference falls within a predetermined allowable range, , The time difference between the signal of the broadcast station and the broadcast wave is measured, the signal of the broadcast station is delayed by the time difference obtained by the measurement, and the delayed signal and the broadcast A broadcast characterized in that a difference from a signal obtained by receiving and demodulating a wave is obtained, and when the obtained difference exceeds a predetermined allowable range, it is determined that the broadcast of the signal of the broadcast station is finished. Content monitoring device.

Images