JP2012175644A - Terminal side modem and communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a terminal side modem and a communication system that can solve abnormality such as a hangup of a monitor camera associated with software through remote control.SOLUTION: In a communication system in which a terminal-side modem 1 connected to a high order-side model 2 through a coaxial cable 3 is connected to a monitor camera 4 through a cable run 5 for digital communication and power supply, for example, the high order-side modem 2 is provided with a power supply control part 25 which functions to monitor abnormality of the monitor camera 4 and to output a power supply control command to a terminal-side modem 1 when detecting abnormality, and the terminal-side model 1 is provided with a communication part 101 through which the high order-side model 2 and monitor camera 4 transmit and receive communication signals to and from each other, and a power supply part 102 which supplies a power supply voltage to the monitor camera 4, and temporarily turns off the supply of the power supply voltage when the communication part 101 receives the power supply command.

Description

  The present invention relates to a communication system in which a host-side modem and a terminal-side modem are connected to each other via a coaxial line, and more particularly to a terminal-side modem for connecting a digital surveillance camera and a communication system including the terminal-side modem.

  In recent years, so-called IP (Internet Protocol) cameras have become widespread as digital surveillance cameras that have excellent image quality and can be incorporated into LANs (local area networks) in place of conventional analog surveillance cameras. ing. As a communication system targeting this IP camera, for example, if it is a relatively small store such as a convenience store, LAN cables connected to a plurality of IP cameras are aggregated in a hub and connected to an information processing apparatus. Thus, a monitoring system can be easily configured.

  However, since there is a limit to the length of the LAN cable that can be laid, for example, it is extremely difficult to configure a network connection using only a LAN cable in a large station or factory premises. In addition, it is a heavy burden to install a new cable. Therefore, a system using a coaxial modem has been proposed as a communication system suitable for longer-distance signal transmission (see, for example, Patent Document 1). In this case, the higher-order modem and the terminal-side modem are connected to each other via a coaxial cable, and communication between both modems is performed. An information processing apparatus such as a personal computer is connected to the upper modem, and an IP camera is connected to the terminal modem. The coaxial cable in such a communication system is applicable to a long distance that cannot be handled by a LAN cable. Further, when an analog surveillance camera is installed, a coaxial cable is already installed for connecting the camera, and there is no need to newly install a cable for introducing the IP camera.

JP 2010-258769 A

  Since the above IP camera is a digital device that operates by software, abnormalities in software such as hang-up may occur. When an IP camera is used for monitoring, monitoring cannot be performed while hung up, and it is not sufficient to simplify installation or enable communication using a coaxial modem. Furthermore, in the hang-up state, even if a reset command is sent to the IP camera, it cannot be normally received.

  In view of such a conventional problem, an object of the present invention is to provide a terminal-side modem and a communication system that can eliminate software abnormality such as hang-up of a surveillance camera by remote control.

(1) The present invention is a terminal-side modem that is connected to a higher-order modem via a coaxial cable and connected to a monitoring camera via an electric circuit for digital communication and power feeding.
A communication unit that transmits and receives communication signals between each of the higher-order modem and the monitoring camera, and supplies a power supply voltage to the monitoring camera. And a power supply unit having a function of temporarily turning off the supply of the power supply voltage when a power supply control command is received from the host side based on an abnormality in video transmission.

  In the terminal-side modem configured as described above, the power supply unit receiving the power supply control command from the upper side temporarily turns off the power supply voltage supplied to the monitoring camera (in this case, for a short time) After that, the surveillance camera that has fallen into software abnormality such as hang-up can be restarted by remote control. As a result, the abnormality of the monitoring camera that has become uncontrollable is resolved, and monitoring can be resumed early.

(2) In the terminal-side modem of (1), the electric circuit may be a shared circuit for digital communication and power supply, and the power supply unit may superimpose a power supply voltage on a digital communication signal.
In this case, the monitoring camera can be restarted by temporarily turning off the power supply voltage superimposed on the communication signal.

(3) Also, in the terminal-side modem of (1), the digital circuit and the power supply are provided independently from each other, and the power supply unit is provided on the power supply circuit with a predetermined number required for the monitoring camera. A power supply voltage may be output.
In this case, the surveillance camera having a dedicated power supply cord can be restarted by temporarily turning off the power supply voltage.

(4) On the other hand, the present invention is a terminal-side modem that is connected to the host modem via a coaxial cable and the host modem, and connected to the surveillance camera via a digital communication and power supply circuit. A communication system comprising:
Either the higher-order modem or an information processing apparatus provided above the higher-order modem monitors whether there is an abnormality in the monitoring camera or an abnormality in the video transmission, and when an abnormality is detected, the terminal-side modem Including a power supply control unit having a function of outputting a power supply control command to
The terminal-side modem supplies a communication voltage for transmitting and receiving a communication signal between the host modem and the monitoring camera, and supplies a power supply voltage to the monitoring camera. A power supply unit having a function of temporarily turning off the supply of the power supply voltage when receiving a command.

  In the communication system configured as described in (4) above, the power supply voltage supplied to the monitoring camera by the power supply unit that has received a power supply control command from the upper side is temporarily turned off (in this case, for a short time). Therefore, the camera for monitoring that has fallen into software abnormalities such as hang-up can be restarted by remote control by turning on thereafter. As a result, the abnormality of the monitoring camera that has become uncontrollable is resolved, and monitoring can be resumed early. In addition, since the power supply control unit monitors whether there is an abnormality in the monitoring camera or an abnormality in the video transmission, the monitoring camera can be turned off when an abnormality occurs.

(5) In the communication system of (4), the power supply control unit outputs a predetermined command for requesting a response to the monitoring camera, and outputs a power supply control command when there is no response. You may do it.
In this case, by issuing a predetermined command (for example, a ping command) and monitoring a response thereto, it is possible to easily monitor whether there is an abnormality in the monitoring camera.

(6) In the communication system of (4) above, the upper modem has a counter function for measuring traffic, and the power supply controller monitors when the traffic count value exceeds a predetermined amount within a predetermined time. If the monitoring camera is normal and the count value does not increase beyond a predetermined amount within a certain time, it is determined that the monitoring camera is abnormal, and if it is determined abnormal, a power supply control command may be output. Good.
In this case, under the assumption that if the surveillance camera is normal, the count value should increase correspondingly, if it does not increase accordingly, the surveillance camera has fallen into an abnormality such as a hang-up. It can be judged accurately.

(7) In the communication system of (4), the coaxial cable is branched in the middle, and a terminal-side modem is connected to each end of the plurality of coaxial cables after being branched. When the traffic exceeds a predetermined ratio with respect to the transmission capacity of the coaxial cable, the power supply control unit determines that the operation priority is ascending from the lowest order according to a predetermined operation priority. Alternatively, the power supply control command may be output for the required number of terminal-side modems, and the power supply voltage supplied to the monitoring camera may be turned off to reduce the traffic.
In this case, for example, all of the surveillance cameras are normal, but there is a problem in video transmission due to some abnormality in transmission through the coaxial cable (for example, ambient noise or a decrease in transmission capacity due to cable deterioration). When it is likely to occur, video data from a monitoring camera with a high operation priority can be reliably transmitted preferentially by turning off the power supply voltage from the one with the lower operation priority. In this case, the monitoring camera with a low operation priority is temporarily turned off until the transmission abnormality of the coaxial cable is resolved. In other words, the temporary turn-off in this case is not a short turn-off for restarting, but a relatively long time that is irregular in time.

  According to the terminal-side modem and the communication system of the present invention, software abnormalities such as a surveillance camera hang-up can be resolved by remote control.

It is a block diagram which shows the outline of the terminal side modem which concerns on 1st Embodiment of this invention, and the whole communication system containing this. FIG. 2 is a more detailed block diagram from an upper modem in FIG. 1 to a monitoring camera. It is a block diagram from a higher-order modem to a surveillance camera in a communication system according to a second embodiment of the present invention. It is a block diagram of the terminal side modem in the communication system which concerns on 3rd Embodiment of this invention. It is a block diagram which shows the state by which three sets (terminal side modem + surveillance camera) are connected with respect to a high-order side modem as a communication system which concerns on 4th Embodiment of this invention. It is a block diagram of the communication system which concerns on 5th Embodiment of this invention. It is a block diagram which shows the outline of the whole communication system which concerns on 6th Embodiment of this invention. FIG. 8 is a more detailed block diagram from the upper modem in FIG. 7 to the monitoring camera.

Embodiments of the present invention will be described below with reference to the drawings.
<< First Embodiment >>
FIG. 1 is a block diagram showing an outline of a terminal-side modem and a communication system including the terminal-side modem according to the first embodiment of the present invention. In the figure, a terminal-side modem 1 as a slave unit and a host-side modem 2 as a master unit are connected to each other via a coaxial cable 3 so that digital communication is possible between both modems. As a modem modulation method, OFDM (Orthogonal Frequency Division Multiplexing) similar to that of the PLC modem can be employed. As a use band, 2-28 MHz can be used, for example. In addition, when the communication system is introduced as an alternative model when an analog surveillance camera is installed, an existing coaxial cable can be used as it is.

  A monitoring camera 4, which is a so-called IP camera, is connected to the terminal-side modem 1 via an Ethernet (registered trademark) cable (UTP) 5. The terminal-side modem 1 is provided as close to the surveillance camera 4 as possible, and therefore the length of the cable 5 is relatively short. On the other hand, the host modem 2 is similarly connected to the network via an Ethernet (registered trademark) cable 6, and an information processing device 8 for monitoring is provided on the network 7.

  The terminal-side modem 1 has a function of supplying power to the monitoring camera 4 and also has a function of turning on / off the power supply. The upper modem 2 connects the plug 2a to an outlet (not shown) to obtain a commercial power supply voltage such as AC100V. The high-order modem 2 generates a predetermined DC voltage from this power supply voltage, uses it as its power supply, applies a DC voltage to the coaxial cable 3 (that is, superimposes it on the communication signal), and supplies power to the terminal-side modem 1 It has a function. Further, the host modem 2 outputs a command to turn off the power supply to the monitoring camera 4 to the terminal modem 1 when the abnormality of the monitoring camera 4 is detected. And a power supply control function for the terminal-side modem 1.

FIG. 2 is a more detailed block diagram from the high-order modem 2 to the monitoring camera 4 in FIG. In the figure, the upper modem 2 is provided with a filter 21, a signal processing unit 22, an Ethernet switch (Ethernet is a registered trademark) 23, an AC / DC conversion unit 24, and a power supply control unit 25, as shown in the figure. It is connected to the.
The host modem 2 includes a connection terminal 2c for the coaxial cable 3, a power supply terminal 2p for receiving commercial AC voltage, and a connection terminal 2e for connecting the cable 6 (FIG. 1).

  The filter 21 passes a communication signal having a certain frequency or higher in both directions. The signal processing unit 22 performs digital processing such as modulation and demodulation on the communication signal. The Ethernet (registered trademark) switch 23 is an interface with the upper network 6 (FIG. 1) and is a switch that enables signal exchange with the power supply control unit 25.

  Further, the filter 21 allows the direct current voltage from the AC / DC converter 24 to pass only to the lower side. The commercial AC voltage supplied to the power supply terminal 2p is converted into a predetermined DC voltage by the AC / DC converter 24 and provided to the terminal-side modem 1 from the filter 21 via the coaxial cable 3. That is, the power supply voltage sent to the terminal-side modem 1 is provided by being superimposed on the communication signal. Further, this DC voltage is also used as a power supply voltage in the upper modem 2.

  On the other hand, in the terminal-side modem 1, a filter 11, a signal processing unit 12, an Ethernet (registered trademark) switch 13, a PoE (Power Over Ethernet: Ethernet is a registered trademark) processing unit 14, a changeover switch 15, a control unit 16, and A power supply unit 17 is provided and connected as shown. The filter 11, the signal processing unit 12, the Ethernet (registered trademark) switch 13, and the PoE processing unit 14 constitute a communication unit 101 that transmits and receives communication signals to and from the host modem 2 and the monitoring camera 4. is doing. The changeover switch 15, the control unit 16, and the power supply unit 17 constitute a power supply unit 102 that obtains a power supply voltage from the outside and supplies power to the monitoring camera 4 based on the power supply voltage.

  The terminal-side modem 1 includes a connection terminal 1 c for the coaxial cable 3, a preliminary power supply terminal 1 p that is used when receiving a power supply voltage from other than the coaxial cable 3, and a connection terminal 1 e for the cable 5. . A monitoring camera 4 is connected to the connection terminal 1 e via a cable 5.

  The filter 11 allows only communication signals having a certain frequency or higher to pass in both directions. The signal processing unit 12 performs digital processing such as modulation and demodulation on the communication signal. The Ethernet (registered trademark) switch 13 is an interface with the monitoring camera 4 and is a switch that enables signal exchange with the control unit 16.

  On the other hand, since a DC power supply voltage is superimposed on the signal received from the connection terminal 1 c, this DC component is sent from the filter 11 to the changeover switch 15. The changeover switch 15 sends the voltage output from the filter 11 to the power supply unit 17. The power supply unit 17 provides a power supply voltage (for example, DC48V) to the PoE processing unit 14 according to the control of the control unit 16. Further, the power supply unit 17 has a switch 17s for turning on / off the voltage output. The PoE processing unit 14 performs processing for superimposing a DC power supply voltage on an Ethernet (registered trademark) signal. Note that PoE is a technology based on the provisions of IEEE 802.3af. Thus, the power supply voltage is supplied to the monitoring camera 4 by PoE.

  According to the above configuration, the terminal-side modem 1 is supplied with power by the power supply from the higher-order modem 2 via the coaxial cable 3, and the monitoring camera 4 is further supplied with power by PoE of the terminal-side modem 1. Is done. In this way, the terminal-side modem 1 and the monitoring camera 4 do not require a dedicated power supply cord. Therefore, the terminal-side modem 1 and the monitoring camera 4 can be installed even in places such as outdoors where there is no outlet nearby. Further, since the terminal-side modem 1 and the monitoring camera 4 do not require a power cord, the configuration on the appearance is simple, and handling such as the routing of the cord is easy.

  If there is an available outlet near the terminal-side modem 1, a commercial AC voltage can be supplied to the power supply unit 17 by an alternative switching function of the changeover switch 15. In this case, the power supply unit 17 generates a predetermined DC voltage from the commercial AC voltage and supplies it to the PoE processing unit 14. That is, the power supply path can be changed as appropriate according to the installation environment.

Next, a technique for controlling on / off of power supply from the terminal-side modem 1 to the monitoring camera 4 will be described.
First, the power supply control unit 25 of the upper modem 2 acquires in advance identification information (for example, an IP address or a MAC address) of the monitoring camera 4 and the terminal modem 1. As an acquisition method, the operator may store the information directly in the host modem 2 using the information processing apparatus 8, for example. In addition, since the identification information is included in the data transmitted from the monitoring camera 4 and the terminal-side modem 1, the power supply control unit 25 constantly monitors the data, and transmits the IP address and MAC address of the transmission source. If there is a new or changed item, the automatically updated identification information can be held by updating the held identification information.

  The power supply control unit 25 of the higher-order modem 2 periodically transmits a ping (Packet InterNet Groper) command for status confirmation to the monitoring camera 4. The transmission path of this ping command is from the power supply control unit 25 to the Ethernet (registered trademark) switch 23, the signal processing unit 22, the filter 21, the coaxial cable 3, the filter 11, the signal processing unit 12, the Ethernet (registered trademark) switch 13, It reaches the monitoring camera 4 via the PoE processing unit 14 and the cable 5.

  If the monitoring camera 4 is normal, a response to the ping command is returned. Therefore, the power supply control unit 25 determines that the response to the ping command is normal and that the response is not returned within a predetermined time, such as an abnormality such as a hang-up. Here, the power supply control unit 25 when determined to be normal does nothing. On the other hand, the power supply control unit 25 when determined to be abnormal transmits a power supply control command (off command) for turning off the power of the monitoring camera 4 to the terminal-side modem 1.

  The transmission path of the power supply control command is from the power supply control unit 25 to the Ethernet (registered trademark) switch 23, the signal processing unit 22, the filter 21, the coaxial cable 3, the filter 11, the number processing unit 12, and the Ethernet (registered trademark) switch 13. Then, the control unit 16 is reached. Note that the video data from the monitoring camera 4 is, for example, transmitted upstream to the higher-order modem 2 in a time-sharing manner, and a ping command or a power supply control command is sent from the higher-order modem 2 to the terminal-side modem 1 by sewing between these intervals. A time slot for downlink transmission is prepared.

  Receiving the power supply control command (off command), the control unit 16 turns off the switch 17s of the power supply unit 17. As a result, the power supply voltage is not output, and the monitoring camera 4 is turned off. After the elapse of a predetermined time for completely turning off the monitoring camera 4, the power supply control unit 25 outputs the next power supply control command (ON command) to the terminal-side modem 1. Receiving the power supply control command (ON command), the control unit 16 turns on the switch 17 s of the power supply unit 17. Thereby, the power supply from the power supply unit 17 to the monitoring camera 4 is resumed, and the monitoring camera 4 is restarted. As a result, the abnormality of the monitoring camera that has become uncontrollable is resolved, and monitoring can be resumed at an early stage. That is, according to the terminal-side modem 1 and the communication system, software abnormalities such as hang-up of the monitoring camera 4 can be resolved by remote control.

  In order to confirm whether or not the abnormality has been resolved, the power supply control unit 25 transmits a ping command to the monitoring camera 4 in a time when the restarting of the monitoring camera 4 is completed. Here, if the response is returned, it is possible to confirm that the abnormality has been resolved and the normal state has been restored. If there is no response within a predetermined time as usual, the surveillance camera 4 may be restarted again by the same remote control. When it is confirmed that there is no response after one or more restarts, a warning signal is sent from the host modem 2 to the information processing device 8 (FIG. 1), and the information processing device 8 is monitored. Display a warning or output a warning sound if necessary.

  As described above, in such a terminal-side modem 1 and a communication system including the terminal-side modem 1, the power supply voltage supplied to the monitoring camera 4 by the power supply unit 102 that has received a power supply control command from the upper side is temporarily (this Since it is turned off for a short time, the surveillance camera 4 that has fallen into software abnormality such as hang-up can be restarted by remote control. As a result, the abnormality of the monitoring camera that has become uncontrollable is resolved, and monitoring can be resumed early. Further, by issuing a predetermined command (here, a ping command) and monitoring a response thereto, it is possible to easily monitor whether there is an abnormality in the monitoring camera.

  In the first embodiment, the ping command is used. However, the command is not limited to ping as long as it is a command that can obtain a response to the monitoring camera 4.

<< Second Embodiment >>
FIG. 3 is a block diagram from the host modem to the monitoring camera in the communication system according to the second embodiment of the present invention. The block diagram showing the outline of the whole is the same as FIG. In FIG. 3, the terminal-side modem 1 and the monitoring camera 4 are the same as those in the first embodiment. Further, with respect to the higher-order modem 2, the apparent block elements are the same as those in the first embodiment, but the functions of the Ethernet (registered trademark) switch 23 and the power supply control unit 25 are different.

  In FIG. 3, an Ethernet (registered trademark) switch 23 has a built-in traffic counter function, and sends a count value of the number of packets to the power supply control unit 25. The count value increases when a video data packet is transmitted from the monitoring camera 4. However, the packet includes a control signal packet in addition to the video data, which is also counted. However, the number of video data packets is much larger than the number of control signal packets. Therefore, for example, if the count value per fixed time is equal to or greater than a predetermined threshold value, video data packets are transmitted one after another, and the monitoring camera 4 determines that the count value is normal, and conversely, the count value does not reach the threshold value. When it is estimated that the video data packet is not transmitted, the monitoring camera 4 determines that the packet is abnormal. The power supply control unit 25 determined to be abnormal executes the restart of the monitoring camera 4 as in the first embodiment.

  If the determination is made based on the count value of the traffic counter as in the second embodiment, it is confirmed whether or not video data is being transmitted from the monitoring camera 4, so that the determination is more reliable. Further, not only the abnormality of the monitoring camera 4 but also the presence or absence of abnormality in the video transmission can be monitored.

<< Third Embodiment >>
FIG. 4 is a block diagram of the terminal-side modem 1 in the communication system according to the third embodiment of the present invention. A block diagram showing an outline of the upper side of the coaxial cable 3 is the same as FIG. In FIG. 4, the same thing as 1st Embodiment (FIG. 2) or 2nd Embodiment (FIG. 3) is applicable about the high-order side modem 2. FIG.

  In FIG. 4, a filter 11, a signal processing unit 12, an Ethernet (registered trademark) switch 13, a changeover switch 15, a control unit 16, and a power supply unit 17 are provided in the terminal-side modem 1 in the third embodiment. They are connected as shown. The filter 11, the signal processing unit 12, and the Ethernet (registered trademark) switch constitute a communication unit 101 that transmits and receives communication signals to and from the host modem 2 and the monitoring camera 4. The changeover switch 15, the control unit 16, and the power supply unit 17 constitute a power supply unit 102 that obtains a power supply voltage from the outside and supplies power to the monitoring camera 4 based on the power supply voltage.

  The difference between the terminal-side modem 1 in the first and second embodiments is that there is no PoE processing unit, and the Ethernet (registered trademark) switch 13 is directly connected to the monitoring camera via the connection terminal 1e and the cable (UTP) 5e. 4 and the output voltage of the power supply unit 17 is connected to the monitoring camera 4 via the power supply terminal 1s and the power supply cord 5p. That is, the terminal-side modem 1 is not of the PoE type, and is provided with a signal cable 5e and a power supply cord 5p separately from each other. The power supply voltage output from the power supply unit 17 is a DC voltage or an AC voltage necessary for the monitoring camera 4. When an AC voltage is required, the power supply unit 17 may be equipped with an inverter function.

In this case, the control unit 16 turns off the switch 17 s of the power supply unit 17 in accordance with a power supply control command (off command) from the host modem 2. As a result, the power supply voltage is not output, and the monitoring camera 4 is turned off. Further, the control unit 16 turns on the switch 17 s of the power supply unit 17 in accordance with a power supply control command (ON command) from the host modem 2. As a result, the monitoring camera 4 is turned on.
Such a terminal-side modem 1 can be restarted by temporarily turning off the power supply voltage for the monitoring camera 4 having a dedicated power supply cord.

<< 4th Embodiment >>
As shown in FIG. 1, a system in which one terminal modem 1 and one surveillance camera 4 are connected to one host modem 2 has a basic and simple form. There may be a case where a plurality of sets (terminal modem 1 + monitoring camera 4) are connected to the host modem 2.

  FIG. 5 shows that three sets (terminal-side modems 1x, 1y, 1z + monitoring cameras 4x, 4y, 4z) are connected to the host modem 2 in the communication system according to the fourth embodiment as an example. It is a block diagram which shows the state performed. In this case, a mixer / distributor 9 is provided in the middle of the coaxial cable 3. The mixer / distributor 9 serves as a distributor for downstream signals and serves as a mixer for upstream signals. However, actually, when there are a plurality of terminal-side modems as described above, uplink signals from the respective terminal-side modems 1x, 1y, and 1z are transmitted, for example, in a time division manner.

The configuration of the upper modem 2 may be either the configuration of FIG. 2 or the configuration of FIG. 3, but the power supply control unit 25 of the upper modem 2 includes a plurality of sets of terminal side modems 1x, 1y, 1z and a monitoring camera 4x. , 4y, 4z, IP addresses and MAC addresses are stored as identification information.
In such a configuration, the power supply control command (off / on) output from the upper modem 2 is the terminal modem (1x, 4x, 4y, 4z) of the specific surveillance camera in which the abnormality is detected. Information (IP address or the like) specifying one of 1y and 1z) is included in the header or the like.

<< 5th Embodiment >>
FIG. 6 is a block diagram of a communication system according to the fifth embodiment. Note that the configuration above the upper modem 2 is the same as in FIG. In FIG. 6, the configuration other than the upper modem 2 is the same as that in FIG. For the higher-order modem 2, the apparent block elements and the functions of the Ethernet (registered trademark) switch 23 and the power supply control unit 25 that exchange the count value and the power supply control command with each other are the same. The relationship between the power supply control unit 22 and the power supply control unit 25 is different.

  That is, in the present embodiment, as in the other embodiments, in addition to the control of restarting in order to eliminate the abnormality of the monitoring camera 4, the relationship with traffic and the environment even if there is no abnormality in the monitoring camera 4. Thus, when trouble occurs in transmission of video data, control is performed to intentionally turn off one of the monitoring cameras 4.

  Specifically, in consideration of the importance of the plurality of monitoring cameras 4, for example, as shown in Table 1, the priority order is stored in the power supply control unit 25 together with identification information and the like.

  In FIG. 6, the signal processing unit 22 grasps the current transmission capacity of the coaxial cable 3. Although the transmission capacity can be said to be a constant value, it actually fluctuates (decreases) due to ambient noise. In addition, the transmission capacity also decreases due to the aging of the coaxial cable 3 itself. Therefore, the signal processing unit 22 gives the current transmission capacity to the power supply control unit 25 as information. The power supply control unit 25 monitors the traffic count value per unit time given from the Ethernet (registered trademark) switch 23, and when the transmission capacity exceeds 90% of the transmission capacity, for example, the priority 3 is the lowest priority. In order to turn off the camera 1z, a power supply control command (off command) is transmitted to the terminal-side modem 1z. If the traffic count value exceeds 100% of the transmission capacity, transmission delay and video degradation occur.

  By turning off the monitoring camera 1z having the lowest priority, video data is not transmitted from the monitoring camera 1z, so the traffic count value per unit time decreases. If the monitoring camera 1z is not stopped by merely stopping the monitoring camera 1z, the terminal-side modem 1x is requested to turn off the monitoring camera 1x having the next lowest priority. A power supply control command (off command) is transmitted.

  As described above, in the fifth embodiment, all of the monitoring cameras 4 are normal, but when there is a problem in transmission of the video due to some abnormality in transmission through the coaxial cable 3, the operation priority By turning off the power supply voltage from the lower one, it is possible to reliably and reliably transmit video data from the monitoring camera having a high operation priority. In this case, the monitoring camera having a low operation priority is temporarily turned off until the transmission abnormality of the coaxial cable 3 is resolved. In other words, the temporary turn-off in this case is not a short turn-off for restarting, but a relatively long time that is irregular in time.

<< 6th Embodiment >>
FIG. 7 is a block diagram showing an outline of the entire communication system according to the sixth embodiment of the present invention. The difference from FIG. 1 is that the host modem 2 does not have the function of the power supply control unit, and instead, the power supply control unit 81 on the network 6 performs the function. The power supply control unit 81 can be mounted as one function of the information processing apparatus 8, for example. However, apart from the information processing apparatus 8, a “power supply controller” having the function of a power supply control unit may be provided on the network 6.

FIG. 8 is a more detailed block diagram from the high-order modem 2 to the monitoring camera 4 in FIG. In FIG. 8, the host modem 2 is not provided with the function of the power supply control unit. The terminal-side modem 1 and the monitoring camera 4 are the same as in FIG.
In FIG. 8, a ping command and a power supply control command are sent to the upper modem 2 from a power supply control unit 81 on the network 6. The point that the surveillance camera 4 is restarted based on these is the same as in the first embodiment and the like, and thus the description thereof is omitted here.

<Others>
In each of the embodiments described above, the power supply control command includes an off command and a subsequent on command. However, in the first to fifth embodiments, it is only necessary that the monitoring camera 4 can be restarted. Only the command may be received, and the terminal-side modem 1 may be turned on and restarted after a certain time (short time). On the other hand, as in the case of the sixth embodiment, when the power of a specific monitoring camera 4 is turned off based on the relationship with the transmission capacity instead of restarting, the monitoring camera turned off according to the traffic situation A command to turn on the power source 4 again is necessary.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

1, 1x, 1y, 1z: Terminal-side modem 2: High-order modem 3: Coaxial cable 4, 4x, 4y, 4z: Monitoring camera 5, 5e: Cable 5p: Power cord 8: Information processing device 25, 81: Power supply Control unit 101: Communication unit 102: Power supply unit

Claims (7)

A terminal-side modem connected to a higher-order modem via a coaxial cable and connected to a surveillance camera via a digital communication and power line for power supply,
A communication unit that transmits and receives communication signals between the upper modem and the monitoring camera;
Supplying a power supply voltage to the monitoring camera and supplying the power supply voltage when the communication unit receives a power supply control command from a higher-order side based on an abnormality in the monitoring camera or an abnormality in video transmission. And a power supply unit having a function of temporarily turning off the terminal.   The terminal-side modem according to claim 1, wherein the electric circuit is a shared electric circuit for digital communication and power supply, and the power supply unit superimposes the power supply voltage on a digital communication signal.   2. The terminal side according to claim 1, wherein the electric circuit is provided independently for digital communication and for power supply, and the power supply unit outputs a predetermined power supply voltage required for the monitoring camera to the power supply circuit. modem. With the host modem,
A terminal-side modem connected to the host modem via a coaxial cable and connected to a monitoring camera via a digital communication and power supply line for power supply,
Either the higher-order modem or an information processing apparatus provided above the higher-order modem monitors whether there is an abnormality in the monitoring camera or an abnormality in the video transmission, and when an abnormality is detected, the terminal-side modem Including a power supply control unit having a function of outputting a power supply control command to
The terminal modem is
A communication unit that transmits and receives communication signals between the upper modem and the monitoring camera,
A power supply unit that supplies a power supply voltage to the monitoring camera and has a function of temporarily turning off the supply of the power supply voltage when the communication unit receives the power supply control command. A communication system.   The communication system according to claim 4, wherein the power supply control unit outputs a predetermined command for requesting a response to the monitoring camera, and outputs the power supply control command when there is no response. The upper modem has a counter function for measuring traffic,
When the traffic count value has increased by a predetermined amount or more within a predetermined time, the power supply control unit is normal, and when the count value does not increase to a predetermined amount or more within the predetermined time, the monitoring camera The communication system according to claim 4, wherein the power supply control command is output when the power supply control command is determined to be abnormal. The coaxial cable is branched in the middle, and the terminal-side modem is connected to the ends of the plurality of coaxial cables after being branched,
The upper modem has a counter function for measuring traffic,
When the traffic exceeds a predetermined ratio with respect to the transmission capacity of the coaxial cable, the power supply control unit has the required number of terminal-side modems in ascending order from the lowest order according to a predetermined operation priority. The communication system according to claim 4, wherein the traffic is reduced by outputting the power supply control command and turning off a power supply voltage supplied to the monitoring camera.

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