JP3865643B2 - CATV system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a CATV system, and in particular, when a receiving terminal is connected to a branch signal cable branched from a cable network and an emergency broadcast signal is supplied to each receiving terminal through the branch signal cable, it is supplied at each receiving terminal. The present invention relates to a CATV system provided with means for reliably receiving an emergency broadcast signal.
[0002]
[Prior art]
In general, the CATV system is connected to a cable network to which a wired broadcast signal output from a broadcasting station is supplied, a number of tap-off and the same number of branch signal cables connected to the cable network, and an end of each branch signal cable. And a monitor composed of a television receiver or the like connected to each receiving terminal, and a wired broadcast signal branched from a cable network is supplied to each receiving terminal It is.
[0003]
Here, FIG. 5 is a block diagram showing a part of a main configuration of a known CATV system.
[0004]
As shown in FIG. 5, the CATV system includes a cable network 50, a tap-off 51, a branch signal cable 52, a protector 53, a receiving terminal 54, and a monitor 55. In FIG. 5, one tap-off 51, one branch signal cable 52, one protector 53, one receiving terminal 54, and one monitor 55 are shown. However, in an actual CATV system, many tap-offs 51, branch signals A cable 52, a protector 53, a receiving terminal 54, and a monitor 55 are provided.
[0005]
When a wired broadcast signal output from the broadcasting station is supplied to the cable network 50, the wired broadcast signal is branched by the tap-off 51, and the branched wired broadcast signal is supplied to the branched signal cable 52. The cable broadcast signal supplied to the branch signal cable 52 is supplied to the receiving terminal 54 through the protector 53.
[0006]
FIG. 6 is a block diagram showing an example of the internal configuration of the receiving terminal 54 shown in FIG.
[0007]
In FIG. 6, the same components as those shown in FIG.
[0008]
As shown in FIG. 6, the receiving terminal 54 includes a receiving unit 56 with a built-in tuner, a demodulating unit 57, a demultiplexer 58, an MPEG decoder 59, a graphic controller 60, an NTSC encoder 61, and activation control. Microcomputer 62, main control unit (main CPU) 63, main power switch (SW) 64, broadcast signal input terminal 65, video signal output terminal 66, audio signal output terminal 67, and remote control signal input terminal 68. And the power supply terminal 69. These components 56 to 69 are connected as shown in FIG. In addition, a monitor 70 such as a television receiver and an outlet plug 71 to be inserted into an AC power socket (not shown) are arranged. The monitor 70 is connected to the video signal output terminal 66 and the audio signal output terminal 67, and the outlet plug 71 is connected to the power supply terminal 69.
[0009]
The receiving terminal 54 configured as described above operates as follows.
[0010]
A wired broadcast signal supplied through a branch signal cable (not shown) is supplied to the receiving unit 56 through a broadcast signal input terminal 65. The receiving unit 56 selects a broadcast signal of a desired channel in the input wired broadcast signal, converts the selected broadcast signal into an intermediate frequency signal, and supplies the intermediate frequency signal to the subsequent demodulation unit 57. The demodulator 57 performs QAM (Quadrature Amplitude Modulation) demodulation or QPSK (Quadrature Phase ShiftKeying) demodulation or the like on the supplied intermediate frequency signal in accordance with the modulation form of the broadcast station to form a data string. This data string is restored by error correction processing and supplied to the demultiplexer 58 in the form of an MPEG transport stream in which a plurality of video data, audio data, and other data are multiplexed.
[0011]
The demultiplexer 58 selects the information content of the MPEG transport stream, transfers the video data and audio data to the MPEG decoder 59, and processes the data for receiving broadcast such as SI (Service Information) as processing of the main control unit 63. To make a table. The MPEG decoder 59 decompresses the compressed video data and audio data and converts them into a video signal and an audio signal. The video signal is supplied to the graphic controller 60, and the audio signal is supplied to the monitor 70 through the audio signal output terminal 67. The graphic controller 60 performs scaling of the supplied video signal and superimposition of an OSD (On Screen Display) image, and then supplies it to the NTSC encoder 61 where it is converted into an NTSC signal. The converted NTSC signal is supplied to the monitor 70 through the video signal output terminal 66. The operations of the components 56 to 61 in the receiving terminal 54 are controlled by the main control unit 63.
[0012]
The receiving terminal 54 includes a main power switch 64 connected to the power terminal 69, and AC power is supplied to the power terminal 69 from the outlet plug 71. In this case, the power supply state to the receiving terminal 54 has the following four types depending on the state of the main power switch 64 and the state of the outlet plug 71.
[0013]
The first is a state in which the main power switch 64 is on, power is supplied to almost all circuit parts, and video signals, audio signals, and the like are output to the monitor 70 (hereinafter referred to as a main function operating state). It is.
[0014]
The second is that the main power switch 64 is in an ON state, but power is supplied only to a part of the circuit portion such as the activation control microcomputer 62 and the like, and only the control by the remote control signal and the time reservation activation can be performed (hereinafter referred to as the following) It is called a standby state).
[0015]
The third is a state in which the main power switch 64 is in the off state but the outlet plug 71 is fitted in the AC power socket (hereinafter referred to as a main power off state).
[0016]
No. 4 is a state in which the outlet plug 71 is not fitted in the AC power socket (hereinafter referred to as AC power unconnected state).
[0017]
When the receiving terminal 54 is in a standby state, many circuit portions are not driven as much as possible in order to reduce power consumption. For this purpose, the activation control function and the remote control signal of the activation control microcomputer 62 are reduced. A reception function is provided, and only the activation control microcomputer 62 is always operated, so that a program reservation function and a remote control operation during standby can be supported.
[0018]
In the CATV system shown in FIG. 5, various wired broadcast signals are transmitted and supplied to the receiving terminal 54, and emergency broadcast signals are transmitted and supplied to the receiving terminal 54. This emergency broadcast signal avoids the occurrence of disasters due to earthquakes, typhoons, etc., and conveys necessary information to the viewers in the event of an emergency to alert the viewer. A receiving terminal equipped with an emergency broadcast receiver Received at 54.
[0019]
Since the receiving terminal 54 equipped with the emergency broadcast receiving unit does not know when the emergency broadcast signal is supplied, even if it is in a standby state, the receiving terminal 54 receives the information content indicating the supply of the emergency broadcast signal. The terminal 54 is automatically turned on to shift to the main function operating state, and provides necessary information to the viewer. That is, as will be described later, the receiving terminal 54 including the emergency broadcast receiving unit can confirm the supply of the emergency broadcast signal even when it is in a standby state. The part is always operating.
[0020]
Here, FIG. 7 is a block diagram showing an example of a circuit portion that is always in an operating state in a known receiving terminal 54.
[0021]
In FIG. 7, the same components as those shown in FIG.
[0022]
As shown in FIG. 7, the circuit portion that is always in an operating state includes a receiving unit 56 including a tuner, a demodulating unit 57, a demultiplexer 58, and a main control unit 63. In the example illustrated in FIG. 7, when broadcasting an emergency broadcast signal, a normal wired broadcast signal output from a broadcasting station includes a flag, a descriptor, or the like indicating the presence or absence of the emergency broadcast. When emergency broadcast is performed, the flag, descriptor, etc. are set to have emergency broadcast. After receiving and demodulating the wired broadcast signal, the receiving terminal 54 monitors a flag or descriptor included in the data, and detects that the emergency broadcast is performed. Operation, for example, forced channel selection of emergency broadcast signals, screen display of emergency broadcast signals, etc. is started.
[0023]
Next, FIG. 8 is a block diagram showing another example of a circuit portion that is always in an operating state in a known receiving terminal 54.
[0024]
In FIG. 8, the same components as those shown in FIG.
[0025]
As shown in FIG. 8, the circuit portion that is always in an operating state includes a receiving unit 56 including a tuner and a startup control microcomputer 62. In the example shown in FIG. 8, when broadcasting an emergency broadcast signal, a normal wired broadcast output from a broadcasting station is provided. The transmission signal includes a pilot signal having a specific frequency indicating the presence of emergency broadcasting. The receiving terminal 54 selects a pilot signal of the specific frequency, monitors the presence or absence of a carrier wave of the specific frequency, and detects that the emergency broadcast is performed, a predetermined operation of receiving the emergency broadcast, For example, forced channel selection of emergency broadcast signals and screen display of emergency broadcast signals are started.
[0026]
[Problems to be solved by the invention]
By the way, the known receiving terminal 54 is such that some circuit parts are always in an operating state in order to be able to receive an emergency broadcast signal. When in the state, the power consumption in the standby state cannot be significantly reduced.
[0027]
Therefore, in order to significantly reduce the power consumption in the receiving terminal, a part of the circuit that is always in an operating state is separated from the main body of the receiving terminal, and the part of the separated circuit is separated by an uninterruptible power source such as a CATV system. Means for drastically reducing the power consumption of the receiving terminal main body by driving (hereinafter referred to as first power reducing means), or the irregular signal monitoring device disclosed in Japanese Patent Laid-Open No. 58-88936 As described above, a means for significantly reducing the power consumption of the receiving terminal in the standby state (hereinafter referred to as “this”) is achieved by intermittently setting some circuit portions that are always in the operating state to the operating state at regular time intervals. Has been proposed).
[0028]
However, the first power reduction means and the second power reduction means are basically such that the receiving terminal main body is in a standby state, and some circuit parts such as a receiving unit, a demodulating unit, a demultiplexer, etc. are always in an operating state. If the main body of the receiving terminal is in the main power off state or the AC power source disconnected state, the emergency broadcast cannot be received, and such an emergency broadcast cannot be received. If the receiving terminal body is always set to the standby state in order to avoid the state, it is still difficult to achieve a significant reduction in power consumption.
[0029]
The present invention has been made in view of such a technical background, and its purpose is to supply direct current to a receiving terminal through each branch signal cable when performing emergency broadcasting, regardless of the power state of the receiving terminal. An object of the present invention is to provide a CATV system that enables a receiving terminal to be in an operating state.
[0030]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a broadcasting station. Output in normal time Cable broadcasting signal And emergency broadcast signals that are output when an emergency occurs Supplied to the cable network and connected to the cable network plural By tap-off Each broadcast signal Distribute to multiple branch signal cables, respectively at the end of those branch signal cables Each broadcast signal In the CATV system to which the receiving terminal to receive is connected, in the middle of each branch signal cable Transmit each broadcast signal Main broadcast signal transmission section Connected in parallel to it Connect a DC superimposition voltage generating amplifier consisting of a DC voltage superimposing unit, and before the broadcast station generates an emergency broadcast signal Specified frequency When the carrier voltage signal is output, the DC voltage superimposing amplifier receives the carrier signal of the specified frequency supplied through the branch signal cable by the DC voltage superimposing unit. AC-DC conversion And a means for supplying the output DC voltage to the receiving terminal connected to the end of the branch signal cable and performing activation or emergency notification of the receiving terminal.
[0031]
According to the above means, when the broadcasting station outputs the carrier signal of the specified frequency prior to generating the emergency broadcast signal, the carrier signal of the specified frequency drives the DC superimposed voltage generating amplifier to each branch signal cable. Since the DC voltage is generated and supplied to the corresponding receiving terminal, simply connecting a DC superimposed voltage generating amplifier to each branch signal cable, the cable broadcasting signal of each branch signal cable is connected. A DC voltage can be easily generated without affecting the transmission state.
[0032]
The main broadcast signal transmission unit has the DC superimposed voltage generating amplifier in the means. Each broadcast signal A band pass filter in which a DC voltage superimposing unit extracts a carrier signal of a specified frequency and a carrier signal of a specified frequency extracted by the band pass filter. AC-DC conversion A DC voltage generator for generating a DC voltage, and an adder for adding and outputting the output of the main broadcast signal transmitter and the output of the DC voltage superimposing unit.
[0033]
According to such a configuration, it is possible to easily configure a DC superimposed voltage generating amplifier by adding a bandpass filter having a general-purpose circuit configuration, a DC voltage generating unit, and an adding unit to the amplifying unit. it can.
[0034]
Further, the receiving terminal in the means determines the voltage value of the DC voltage supplied through the branch signal cable, and is a normal voltage value. Determined A voltage level determination means for outputting a determination signal sometimes, and an emergency broadcast signal in response to the supplied DC voltage The arrival When an emergency broadcast notification means for notification and a main control unit activation control means controlled by a determination signal are provided, and the operation state of the receiving terminal is in a standby state where the main power is on In When the voltage level determination means outputs a determination signal, the main control unit activation control means activates the main control unit in response to the determination signal, and shifts the receiving terminal from the standby state to the main function operating state. When the main power is off or the AC power is not connected. In Emergency broadcast notification means in response to the supplied DC voltage To the notification operation state The arrival of emergency broadcast signals Notification, for example, by driving a sounding body such as a buzzer I am doing so.
[0035]
According to such a configuration, when the operating state of the receiving terminal is the standby state in which the main power is on, when a DC voltage is supplied, the receiving terminal is shifted from the standby state to the main function operating state and receives the emergency broadcast. When the operating state of the receiving terminal is the main power off state where the main power source is off or the AC power source is not connected, when a DC voltage is supplied, the arrival of an emergency broadcast signal is notified, for example, by sounding Therefore, the viewer who hears the occurrence of the pronunciation can immediately shift the operating state of the receiving terminal to the main function operating state and receive the emergency broadcast. Especially, the operating state of the receiving terminal Even when the main power is off or the AC power is not connected, it is possible to know that a DC voltage has been supplied, and the receiving terminal can be connected to the main power off or AC power not connected. Contact By the state, it is possible to achieve a drastic reduction in power consumption in the receiving terminal.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0037]
FIG. 1 shows one embodiment of a CATV system according to the present invention, and is a block diagram showing a part of the configuration of the main part thereof.
[0038]
As shown in FIG. 1, this CATV system includes a cable network 1, a tap-off 2, a branch signal cable 3, a DC superimposed voltage generating amplifier 4, a protector 5, a receiving terminal 6, a monitor 7, and the like. It is made up of. In FIG. 1, tap-off 2, branch signal cable 3, DC superimposed voltage generating amplifier 4, protector 5, receiving terminal 6, and monitor 7 are shown one by one, but in an actual CATV system, A number of tap-offs 2, branch signal cables 3, DC superimposed voltage generating amplifiers 4, protectors 5, receiving terminals 6, and monitors 7 are provided. Between the cable network 1 and the receiving terminal 6, the tap-off 2, the branch signal cable 3, the DC superimposed voltage generating amplifier 4, the branch signal cable 3, and the protector 5 are connected in this order. Is connected to a monitor 7 composed of a television receiver or the like.
[0039]
FIG. 2 is a block diagram showing an example of the internal configuration of the DC superimposed voltage generating amplifier 4 shown in FIG.
[0040]
In FIG. 2, the same components as those shown in FIG.
[0041]
As shown in FIG. 2, the DC superimposed voltage generating amplifier 4 includes an amplifying unit 4a, a bandpass filter 4b, a DC voltage generating unit 4c, an adding unit 4d, an input terminal 4e, and an output terminal 4f. It is made up of. The amplifying unit 4a has an input terminal connected to the input terminal 4e and an output terminal connected to the first input terminal of the adding unit 4d. The bandpass filter 4b has an input terminal connected to the input terminal 4e and an output terminal connected to the input terminal of the DC voltage generator 4c. The output terminal of the DC voltage generator 4c is connected to the second input terminal of the adder 4d. The adder 4d has an output terminal connected to the output terminal 4f. In this case, the band-pass filter 4b selectively passes only a carrier wave signal having a specified frequency, which will be described later, and the DC voltage generator 4c has a DC voltage of a predetermined level when a carrier signal having a specified frequency is supplied. Is generated.
[0042]
Further, FIG. 3 is a block diagram showing an example of the internal configuration of the receiving terminal 6 shown in FIG.
[0043]
In FIG. 3, the same components as those shown in FIG.
[0044]
As shown in FIG. 2, the receiving terminal 6 includes a receiving unit 8 incorporating a tuner, a demodulating unit 9, a demultiplexer 10, an MPEG decoder 11, a graphic controller 12, an NTSC encoder 13, a DC level. A determination unit 14, a startup control microcomputer 15, a main control unit (main CPU) 16, a buzzer power supply unit 17, a buzzer 18, a main power switch (SW) 19, a broadcast signal input terminal 20, It consists of a video signal output terminal 21, an audio signal output terminal 22, a remote control signal input terminal 23, and a power supply terminal 24. In addition, a monitor 7 composed of a television receiver and an outlet plug 25 to be inserted into an AC power socket (not shown) are arranged.
[0045]
The receiving unit 8 has an input terminal connected to the broadcast signal input terminal 20 and an output terminal connected to the input terminal of the demodulating unit 9. The demultiplexer 10 has an input terminal connected to the output terminal of the demodulator 9 and an output terminal connected to the input terminal of the MPEG decoder 11. The MPEG decoder 11 has a video signal output terminal connected to the input terminal of the graphic controller 12 and an audio signal output terminal connected to the audio signal output terminal 22. The NTSC encoder 13 is connected to the output end of the graphic controller 12, and the output end is connected to the video signal output terminal 21. The DC level determination unit 14 has an input terminal connected to the broadcast signal input terminal 20 and an output terminal connected to the activation control microcomputer 15. The buzzer power supply unit 17 has an input terminal connected to the broadcast signal input terminal 20, an output terminal connected to the buzzer 18, and a control terminal connected to the activation control microcomputer 15. The activation control microcomputer 15 is connected to the main control unit 16 and the remote control signal input terminal 23. The main control unit 16 is connected to control terminals of the receiving unit 8, the demodulating unit 9, the demultiplexer 10, the MPEG decoder 11, the graphic controller 12, and the NTSC encoder 13. The main power switch 19 is connected to the power terminal 24. Further, the monitor 7 is connected to the video signal output terminal 21 and the audio signal output terminal 22, and the outlet plug 25 is connected to the power supply terminal 24 through a power supply lead (not shown).
[0046]
In this case, the DC level determination unit 14 and the buzzer power supply unit 17 are configured so that they can operate even when the main power switch 19 is off or the outlet plug 25 is disconnected from the AC power socket. It is configured to be driven by a power source different from the power source, for example, a built-in battery.
[0047]
The operation of the CATV system configured as described above will be described with reference to FIGS.
[0048]
First, the operation in a fixed state where a wired broadcast signal output from a broadcasting station is supplied to the cable network 1 will be described.
[0049]
When the wired broadcast signal output from the broadcasting station is supplied to the cable network 1, the wired broadcast signal is branched from the cable network 1 by the tap-off 2, supplied to the corresponding branch signal cable 3, and passed through the branch signal cable 3. This is supplied to the DC superimposed voltage generating amplifier 4. At this time, the DC superimposed voltage generating amplifier 4 amplifies the wired broadcast signal supplied to the input terminal 4e to a predetermined level by the amplifier 4a, and the amplified wired broadcast signal is branched from the output terminal 4f through the adder 4d. The signal cable 3 is supplied. Next, the wired broadcast signal is supplied to the receiving terminal 6 through the branch signal cable 3 and through the protector 5.
[0050]
If the receiving terminal 6 is in the main function operating state when the wired broadcast signal is supplied, the supplied wired broadcast signal is supplied to the receiving unit 8 through the broadcast signal input terminal 20. The receiving unit 8 selects a broadcast signal of a desired channel in the supplied wired broadcast signal, converts the selected broadcast signal into an intermediate frequency signal, and supplies the intermediate frequency signal to the subsequent demodulation unit 9. The demodulator 9 demodulates the supplied intermediate frequency signal to form a data string. This data string is restored by error correction processing and supplied to the demultiplexer 10 in the form of an MPEG transport stream in which a plurality of video data, audio data, and other data are multiplexed.
[0051]
Next, the demultiplexer 10 selects the information content of the MPEG transport stream and transfers the video data and audio data to the MPEG decoder 11. The MPEG decoder 11 decompresses the compressed video data and audio data and converts them into a video signal and an audio signal. The video signal is supplied to the graphic controller 12, and the audio signal is supplied to the monitor 7 through the audio signal output terminal 22. The graphic controller 12 scales the supplied video signal and superimposes the OSD image, and then supplies the video signal to the NTSC encoder 13 where it is converted into an NTSC signal. The converted NTSC signal is supplied to the monitor 7 through the video signal output terminal 21. As a result, an image is displayed on the monitor 7 and sound corresponding to the image is uttered.
[0052]
On the other hand, if the receiving terminal 6 is in a standby state, a main power off state, or an AC power supply unconnected state when the wired broadcast signal is supplied, the wired broadcast signal is supplied to the receiving terminal 6. However, some or all of the components that receive the cable broadcast signal and perform image display and sound utterance do not perform normal functions, and the monitor 7 does not perform image display or sound utterance as described above. .
[0053]
Next, an operation when an emergency broadcast signal output from a broadcasting station is supplied to the cable network 1 will be described.
[0054]
Prior to outputting the emergency broadcast signal to the cable network 1, the broadcast station outputs a carrier signal having a specified frequency. The carrier signal of the specified frequency output to the cable network 1 is branched from the cable network 1 by the respective tap-offs 2, transmitted through the corresponding branch signal cables 3, and supplied to the DC superimposed voltage generating amplifier 4. At this time, the DC superimposed voltage generating amplifier 4 selectively extracts the carrier signal of the specified frequency supplied to the input terminal 4e by the band pass filter 4b, and supplies the selected carrier signal of the specified frequency to the DC voltage generating unit 4c. To do. The DC voltage generator 4c generates a DC voltage of a predetermined level in response to the supply of the carrier wave signal of the specified frequency, and supplies the generated DC voltage to the output terminal 4f through the adder 4d. Thereafter, the DC voltage is transmitted through the corresponding branch signal cable 3 and further supplied to the receiving terminal 6 through the protector 5.
[0055]
First, if the receiving terminal 6 is in the main function operating state, that is, the power is supplied to all the components of the receiving terminal 6 when the DC voltage is supplied, the receiving terminal 6 operates normally. Is in a state. For this reason, when the emergency broadcast signal is supplied following the supply of the DC voltage, the reception terminal 6 selects the emergency broadcast signal by the reception unit 8, demodulates it by the demodulation unit 9, and transports it by the demultiplexer 10. When the service information (SI) of the stream is separated, the main controller 16 constantly monitors an identifier indicating arrival of an emergency broadcast signal included in the service information. And the main control part 16 will set the receiving terminal 6 to the reception mode of an emergency broadcast signal, if this identifier is detected. At this time, when the emergency broadcast signal is supplied, the main control unit 16 controls the graphic controller 12 to display the notification content of the emergency broadcast on the display screen of the monitor 7.
[0056]
In this case, when a DC voltage is supplied to the receiving terminal 6, the DC voltage is supplied to the DC level determination unit 14 and the buzzer power supply unit 17, and the DC voltage level of the DC voltage is equal to or higher than a predetermined value. The activation signal is supplied from the DC level determination unit 14 to the activation control microcomputer 15, and the buzzer drive signal is supplied from the buzzer power supply unit 17 to the buzzer 18. At this time, the activation control microcomputer 15 is already activated. Therefore, serial communication is performed between the activation control microcomputer 15 and the buzzer power supply unit 17, whereby the output of the buzzer drive signal from the buzzer power supply unit 17 is stopped and the buzzer 18 does not operate. .
[0057]
Next, if the receiving terminal 6 is in a standby state at the time when the DC voltage is supplied, that is, if only a part of the components of the receiving terminal 6 is supplied with power, the receiving terminal 6 operates normally. It needs to be in a state. For this reason, when the DC voltage is supplied, the receiving terminal 6 determines the DC voltage level of the DC voltage with the DC level determining unit 14, and the activation control is performed when the DC voltage level is equal to or higher than the predetermined value. A start signal is supplied to the microcomputer 15 for use. The activation control microcomputer 15 transmits an activation notification to the main control unit 16 in response to the supplied activation signal. The main control unit 16 immediately supplies power to all the components of the receiving terminal 6 by receiving the activation notification, and puts the receiving terminal 6 into a normal operation state. When the receiving terminal 6 is in a normal operation state, the main control unit 16 can determine an identifier indicating the arrival of an emergency broadcast signal included in the service information of the transport stream. When the emergency broadcast signal is supplied subsequent to the supply of the DC voltage, the reception terminal 6 performs the same operation as when the reception terminal 6 is in the main function operating state, and the emergency broadcast is displayed on the display screen of the monitor 7. Display the content of notifications by.
[0058]
In this case, when a DC voltage is supplied to the receiving terminal 6, the DC voltage is supplied to the DC level determination unit 14 and the buzzer power supply unit 17, and the DC voltage level of the DC voltage is equal to or higher than a predetermined value. The activation signal is supplied from the DC level determination unit 14 to the activation control microcomputer 15, and the buzzer drive signal is supplied from the buzzer power supply unit 17 to the buzzer 18. At this time, the activation control microcomputer 15 is activated. Therefore, serial communication is performed between the activation control microcomputer 15 and the buzzer power supply unit 17, whereby the output of the buzzer drive signal from the buzzer power supply unit 17 is stopped and the buzzer 18 does not operate.
[0059]
Next, if the receiving terminal 6 is in the main power off state, that is, the main power switch 19 is in the off state and the outlet plug 25 is fitted in the AC power socket when the DC voltage is supplied. As in the case where the receiving terminal 6 is in the standby state, even if the activation signal is supplied from the DC level determination unit 14 to the activation control microcomputer 15, power is not supplied to the activation control microcomputer 15. Cannot be supplied to the main control unit 16, and the receiving terminal 6 cannot be brought into a normal operation state. Therefore, when the DC voltage is supplied, the receiving terminal 6 supplies the DC voltage to the buzzer power supply unit 17, and when the DC voltage level of the DC voltage is equal to or higher than a predetermined value, A buzzer drive signal is supplied from the supply unit 17 to the buzzer 18. As a result, the buzzer 18 is driven to notify that an emergency broadcast signal arrives by sound generation. If the listener who hears this notification immediately turns on the main power switch 19 of the receiving terminal 6, the receiving terminal 6 enters a normal operating state. Then, if the receiving terminal 6 is in a normal operation state, the receiving terminal 6 is supplied with an emergency broadcast signal subsequent to the supply of the DC voltage, as in the case where the receiving terminal 6 is in the main function operating state. The content of notification by emergency broadcast is displayed on the display screen of the monitor 7.
[0060]
In this case, since the activation control microcomputer 15 is not activated when the DC voltage is supplied, serial communication is not performed between the activation control microcomputer 15 and the buzzer power supply unit 17, and the buzzer The output of the buzzer driving signal supplied from the power supply unit 17 to the buzzer 18 does not stop.
[0061]
Subsequently, when the DC voltage is supplied, it is assumed that the receiving terminal 6 is in an AC power supply unconnected state, that is, the main power switch 19 is in an OFF state and the outlet plug 25 is not fitted in the AC power supply socket. In this case, the receiving terminal 6 cannot be brought into a normal operation state as when the receiving terminal 6 is in the main power off state. Therefore, when the DC voltage is supplied, the receiving terminal 6 supplies the DC voltage to the buzzer power supply unit 17, and when the DC voltage level of the DC voltage is equal to or higher than a predetermined value, A buzzer drive signal is supplied from the supply unit 17 to the buzzer 18. As a result, the buzzer 18 is driven to notify that an emergency broadcast signal arrives by sound generation. If the listener who hears this notification immediately inserts the outlet plug 25 into the AC power socket and turns on the main power switch 19 of the receiving terminal 6, the receiving terminal 6 is in a normal operating state. Then, if the receiving terminal 6 is in a normal operation state, the receiving terminal 6 is supplied with an emergency broadcast signal subsequent to the supply of the DC voltage, as in the case where the receiving terminal 6 is in the main function operating state. The content of notification by emergency broadcast is displayed on the display screen of the monitor 7.
[0062]
Even in this case, since the activation control microcomputer 15 is not activated when the DC voltage is supplied, serial communication is not performed between the activation control microcomputer 15 and the buzzer power supply unit 17. The output of the buzzer driving signal supplied from the buzzer power supply unit 17 to the buzzer 18 does not stop.
[0063]
FIG. 4 is a circuit diagram showing an example of the configuration of the DC level determination unit 14 shown in FIG.
[0064]
As shown in FIG. 4, the DC level determination unit 14 includes a level detection grounded emitter transistor 14a, an input resistor 14b connected to the base of the transistor 14a, and a load resistor 14c connected to the collector of the transistor 14a. It has become.
[0065]
When a DC voltage is supplied to the base of the transistor 14a through the input resistor 14b, the DC level determination unit 14 does not turn on the transistor 14a if the DC voltage level is equal to or lower than a predetermined voltage level, and the collector of the transistor 14a. To output a level detection signal (positive logic detection signal) substantially equal to the power supply voltage. On the other hand, if the DC voltage level is equal to or higher than the predetermined voltage level, the transistor 14a is turned on, and a level detection signal (negative logic detection signal) substantially equal to the ground voltage is output from the collector of the transistor 14a. At this time, by using the negative logic detection signal as the activation signal of the activation control microcomputer 15, the voltage level of the input DC voltage can be determined and the activation signal can be generated.
[0066]
In the above-described embodiment, the example using the buzzer 18 that is a sound generation member as the emergency broadcast notification unit has been described. However, the emergency broadcast notification unit according to the present invention is not limited to the buzzer 18, and other than the buzzer 18. A sound generating member may be used, and a display member such as a light emitting element (LED) or a front panel may be used.
[0067]
【The invention's effect】
As described above, according to the first aspect of the present invention, when the broadcasting station outputs a carrier signal having a specified frequency prior to generating an emergency broadcast signal, the carrier signal having the specified frequency is used for generating a DC superimposed voltage. Since the amplifier is driven to generate a DC voltage on each branch signal cable and the DC voltage is supplied to the corresponding receiving terminal, simply connecting a DC superimposed voltage generating amplifier to each branch signal cable There is an effect that it is possible to easily generate a DC voltage without affecting the transmission state of the cable broadcasting signal of each branch signal cable.
[0068]
According to the second aspect of the present invention, a DC superimposed voltage generating amplifier can be easily obtained by adding a bandpass filter having a general-purpose circuit configuration, a DC voltage generating unit, and an adding unit to the amplifying unit. There is an effect that it can be configured.
[0069]
Further, according to the invention described in claim 3, when the operating state of the receiving terminal is a standby state in which the main power is on, when a DC voltage is supplied, the receiving terminal is shifted from the standby state to the main function operating state, When an emergency broadcast can be received and the operating state of the receiving terminal is the main power off state where the main power is off or the AC power source is not connected, the arrival of the emergency broadcast signal is notified when a DC voltage is supplied. Therefore, the viewer who perceived the notification can immediately shift the operating state of the receiving terminal to the main function operating state and receive the emergency broadcast. In particular, the operating state of the receiving terminal is Even when the main power supply is off or the AC power supply is not connected, it is possible to know that a DC voltage has been supplied, and the receiving terminal is connected to the main power supply off or the AC power supply is not connected. State A result, there is an effect that it is possible to achieve a drastic reduction in power consumption in the receiving terminal.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a part of the main configuration of an embodiment of a CATV system according to the present invention.
2 is a block diagram showing an example of the internal configuration of the DC superimposed voltage generating amplifier shown in FIG. 1; FIG.
FIG. 3 is a block diagram illustrating an example of an internal configuration of the receiving terminal illustrated in FIG. 1;
4 is a circuit diagram illustrating an example of a configuration of a DC level determination unit illustrated in FIG. 3;
FIG. 5 is a block diagram showing a part of a main configuration of a known CATV system.
6 is a block diagram illustrating an example of an internal configuration of the receiving terminal illustrated in FIG. 5. FIG.
FIG. 7 is a block diagram showing an example of a circuit portion that is always in an operating state in a known receiving terminal.
FIG. 8 is a block diagram showing another example of a circuit portion that is always in an operating state in a known receiving terminal.
[Explanation of symbols]
1 Cable network
2 Tap-off
3 Branch signal cable
4 DC superimposed voltage generating amplifier
4a Amplifier
4b Bandpass filter
4c DC voltage generator
4d adder
4e Input terminal
4f output terminal
5 protectors
6 Receiving terminal
7 Monitor
8 Receiver
9 Demodulator
10 Demultiplexer
11 MPEG decoder
12 Graphic controller
13 NTSC encoder
14 DC level judgment unit
15 Microcomputer for start control
16 Main control unit (main CPU)
17 Power supply unit for buzzer
18 Buzzer (emergency broadcast notification means)
19 Main power switch (SW)
20 Broadcast signal input terminal
21 Video signal output terminal
22 Audio signal output terminal
23 Remote control signal input terminal
24 Power supply terminal
25 Outlet plug

Claims (4)

Supplying a cable broadcast signal normally output from a broadcasting station and an emergency broadcast signal output in the event of an emergency to a cable network, and a plurality of branch signals for each broadcast signal by a plurality of tap-offs connected to the cable network In a CATV system in which receiving terminals that receive the respective broadcast signals are connected to the ends of the branch signal cables, the main broadcast signals are transmitted in the middle of the branch signal cables. When a DC superimposed voltage generating amplifier comprising a transmission unit and a DC voltage superimposing unit connected in parallel thereto is connected, and the broadcast station outputs a carrier wave signal of a specified frequency prior to generating an emergency broadcast signal, the DC The superimposed voltage generating amplifier receives the carrier signal of the specified frequency supplied from the DC voltage superimposing unit through the branch signal cable. AC receipt carrier wave signal - DC converter and outputs, and supplies an output DC voltage to said branch signal receiving terminal connected to an end of the cable, characterized in that the start or emergency notification of the receiving terminal is performed CATV system. The DC superimposed voltage generating amplifier includes an amplification unit that the main broadcast signal transmission unit amplifies the broadcast signals, and the DC voltage superposition unit extracts a carrier signal of the specified frequency and the band A DC voltage generator for generating a DC voltage by AC-DC conversion of the carrier signal of the specified frequency extracted by a pass filter, and further, an output of the main broadcast signal transmitter and an output of the DC voltage superimposing unit The CATV system according to claim 1, further comprising: an adding unit that adds and outputs.   The receiving terminal determines a voltage value of a DC voltage supplied through the branch signal cable, and outputs a determination signal when the voltage value is determined to be a normal voltage value; and the supplied DC voltage In response to the emergency broadcast notification means for notifying the arrival of an emergency broadcast signal, and a main control unit activation control means controlled by the determination signal, when the operating state of the receiving terminal is a standby state of the main power on When the voltage level determination means outputs a determination signal, the main control unit activation control unit activates the main control unit in response to the determination signal, and shifts the receiving terminal from the standby state to the main function operating state, When the operating state of the receiving terminal is a main power off state in which the main power is off or an AC power source unconnected state, the emergency broadcast notification means is informed in response to the supplied DC voltage. CATV system according to claim 1, driven, characterized by notifying the arrival of the emergency broadcast signal.   The CATV system according to claim 3, wherein the emergency broadcast notification means is a sounding body such as a buzzer.

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