JP6993655B2 - Communication control methods, communication control devices, and communication control programs for network camera systems, including network cameras. - Google Patents

Description

The present invention relates to a communication control method, a communication control device, and a communication control program of a network camera system including a network camera.

This type of network camera system includes a plurality of network cameras and a single network camera recorder. Here, the network camera is a video camera having a wired or wireless LAN (Local Area Network) function, and is a kind of Web camera. The network camera includes a camera function capable of shooting moving images, a circuit for converting the camera function into a video signal, and a circuit for connecting the video signal to the transport layer or application layer of the LAN for data communication. On the other hand, a network camera recorder is a device that records video signals transmitted from each network camera.

Usually, in such a network camera system, a plurality of network cameras are connected to a network camera recorder via a relay device such as a hub device or a multicast router (see, for example, Patent Document 1 and Patent Document 2). ..

However, in such a configuration, since a relay device such as a hub device or a multicast router is required, there is a problem that the network camera system becomes large and the financial burden increases.

Therefore, a network camera system has been proposed in which a plurality of network cameras are connected to one network camera recorder without using a relay device.

One of the connection methods is a method of directly connecting a plurality of network cameras to one network camera recorder in parallel. Hereinafter, this connection method will be referred to as a "parallel connection method".

Another connection method is to connect a plurality of network cameras in series (connecting them in a row) to one network camera recorder. Hereinafter, this connection method will be referred to as a "series connection method".

For example, Patent Document 3 discloses a series connection method in which each network camera is connected and connected to a network digital video recorder via an Ethernet (registered trademark) network. The network camera disclosed in Patent Document 3 has a built-in hub having at least two input ports and an output uplink port. The uplink connection terminal of one network camera is connected to the input port of another adjacent network camera.

Further, Patent Document 4 discloses a surveillance camera system including a plurality of stereo cameras, a communication cable connecting two adjacent stereo cameras, a control device, a monitor, and an operation panel. The plurality of stereo cameras are connected in a daisy chain, which is a so-called string connection, and are connected to the control device by a communication cable at the end.

Japanese Unexamined Patent Publication No. 2006-287292 Japanese Unexamined Patent Publication No. 2007-158533 Japanese Unexamined Patent Publication No. 2004-274762 Japanese Unexamined Patent Publication No. 2012-011989

However, the parallel connection method has the following problems.

The network camera recorder requires a plurality of LAN ports for connecting the network camera. That is, the number of network cameras connected to the network camera recorder depends on the number of LAN ports mounted on the network camera recorder. In order to expand, it is necessary to prepare an extra LAN port in the network camera recorder from the beginning. Therefore, the miniaturization of the network camera recorder and the additional introduction of the network camera recorder are adversely affected. Further, regarding the installation work of the cable network, there is a problem that the cable network is complicated because it is necessary to connect one network camera recorder and a plurality of network cameras in parallel.

Further, the series connection method disclosed in Patent Documents 3 and 4 also has the following problems.

Suppose a network camera breaks down or a connection cable breaks down. In this case, there is a problem that it is not possible to acquire not only the network camera in which the failure occurred but also the video signal captured by the network camera connected in beads after the location where the failure occurred (network camera or connection cable). be.

An object of the present invention is to provide a communication control method, a communication control device, and a communication control program of a network camera system including a network camera that solves the above-mentioned problems.

The network camera system to which the present invention is applied is a network camera recorder having a first recorder port and a second recorder port; a first camera port and a second camera, each of which can be connected to a connection cable, respectively. A first to N (N is an integer of 3 or more) comprising a port; a port switching means connected to the first camera port and the second camera port and capable of switching the communication direction; With a network camera; from the first recorder port of the network camera recorder to the network camera recorder via the first camera port and the second camera port of the first to Nth network cameras. It is provided with a first to first (N + 1) connection cable that connects to the second recorder port in a ring shape in a string connection.

The communication control method of the present invention is a communication control method implemented by the network camera recorder in the network camera system described above, and is the first recorder for all of the first to Nth network cameras. The first instruction step for instructing forward communication from the port to the second recorder port; the first to Nth video signals sent from the first to Nth network cameras, respectively, are the first. A determination step of receiving as a received video signal at the recorder port 2 and determining whether or not all of the first to Nth video signals have been sent; in the determination step, the first to nth ( When it is determined that the video signal of 1 <n ≦ N) cannot be received, the first recorder port to the first to the first network cameras and the second recorder port to the first recorder port to the first to nth network cameras. A second instruction step for instructing reverse communication to the recorder port;

The communication control device of the present invention is the communication control device of the network camera recorder in the network camera system described above, and is the first to Nth video signals transmitted from the first to Nth network cameras, respectively. Is received as a received video signal, and a determination means for determining whether or not all of the first to Nth video signals have been transmitted; based on the determination result of the determination means, the first to first. It has a communication direction indicating means for instructing the network camera of N to communicate in the forward direction or the reverse direction.

The communication control program of the present invention is a communication control program for causing the computer of the network camera recorder in the above-mentioned network camera system to control communication, and sends the computer to the computer from the first to Nth network cameras, respectively. A determination procedure for receiving the incoming first to Nth video signals as a received video signal and determining whether or not all of the first to Nth video signals have been sent; Based on the determination result, the purpose is to cause the first to Nth network cameras to execute a communication direction instruction procedure for instructing forward or reverse communication.

According to the present invention, it is possible to continue the operation even if a failure or disconnection occurs while reducing the number of ports of the network camera recorder.

It is a figure which shows the structure of the network camera system which adopted the "parallel connection method" which is a related technology. It is a figure which shows the structure of the network camera system which concerns on 1st Embodiment of this invention. It is a block diagram which shows the internal structure of the network camera used in the network camera system shown in FIG. It is a block diagram which shows the internal structure of the network camera recorder used for the network camera system shown in FIG. It is a block diagram which shows the schematic structure of the communication control device used for the controller of the network camera recorder shown in FIG. It is a flowchart for demonstrating the operation of the communication control apparatus shown in FIG. It is a figure which shows the state which only the forward communication is performed in the network camera system shown in FIG. FIG. 2 is a diagram showing a state in which forward communication and reverse communication are performed after a failure or disconnection in the network camera system shown in FIG. 2. It is a block diagram which shows the schematic structure of the communication control device which showed an example of the judgment circuit part. It is a flowchart for demonstrating the operation of the communication control apparatus shown in FIG. It is a figure which shows the structure of the network camera system which concerns on the 2nd Embodiment of this invention. It is a block diagram which shows the internal structure of the network camera used in the network camera system shown in FIG. It is a block diagram which shows the internal structure of the network camera recorder used in the network camera system shown in FIG. It is a block diagram which shows the schematic structure of the communication control device used for the controller of the network camera recorder shown in FIG. It is a flowchart for demonstrating the operation of the communication control apparatus shown in FIG.

[Related technology]
In order to facilitate the understanding of the present invention, first, a related technique "parallel connection method" will be described with reference to FIG.

As shown in FIG. 1, the network camera system according to the related technology includes one network camera recorder 1 and N (N is an integer of 2 or more) network cameras 2. In this example, N is equal to 4.

Therefore, the illustrated network camera system includes first to fourth network cameras 2-1, 2-2, 2-3, and 2-4.

The network camera recorder 1 has a plurality of LAN ports. In the illustrated example, the network camera radar 1 has first to seventh LAN ports 1-1 to 1-7.

In the illustrated example, since the network camera system includes four network cameras 2-1 to 2-4, the network camera radar 1 has only the first to fourth LAN ports 1-1 to 1-4. I'm using it.

More specifically, the first LAN port 1-1 is connected to the first network camera 2-1 via the first LAN cable 3-1. The second LAN port 1-2 is connected to the second network camera 2-2 via the second LAN cable 3-2. The third LAN port 1-3 is connected to the third network camera 2-3 via the third LAN cable 3-3. The fourth LAN port 1-4 is connected to the fourth network camera 2-4 via the fourth LAN cable 3-4.

Since the illustrated network camera radar 1 has first to seventh LAN ports 1-1 to 1-7, a maximum of seven network cameras can be connected to the network camera recorder 1.

When the "parallel connection method" is adopted in this way, when the number of connected network cameras 2 connected to the network camera recorder 1 is multiple, the network camera recorder 1 has a plurality of LAN ports for connecting the network camera 2. You will need it. Further, it is necessary to connect the LAN cable 3 in parallel.

As described above, in the related technology, the number of network cameras 2 that can be connected to the network camera recorder 1 depends on the number of LAN ports mounted on the network camera recorder 1. Therefore, in order to expand, it is necessary to prepare an extra LAN port from the beginning, which has been an adverse effect on the miniaturization and additional introduction of the network camera recorder 1.

Further, regarding the installation work of the cable network, since the network camera recorder 1 and the network camera 2 need to be connected in parallel, there is a problem that the cable network is complicated.

[Characteristics of the invention]
Next, the features of the invention will be described.

The present invention is characterized in that a network camera recorder and a network camera are ring-wired in a string, and the network camera is provided with only two LAN ports to switch communication directions.

In the present invention, the network camera recorder and the network camera are provided with the following functions, respectively, to realize a cascade connection (ring-shaped bead connection).

The network camera recorder has a function of switching the communication direction between the forward direction and the reverse direction, and a function of performing communication in both the forward direction and the reverse direction.

Each network camera has two LAN ports and has a function of switching the communication direction between the LAN ports. Further, the network camera may have a function of raising an alarm to the network camera recorder when a failure occurs.

Next, the solution will be described.

Connect from the first LAN port of the network camera recorder to the first LAN port of the first network camera, and from the second LAN port of the first network camera to the first LAN of the second network camera. Connect as many network cameras as you need, such as connecting to a port, and finally connect to the second LAN port of the network camera recorder.

In the case of normal access, communication is performed in the forward direction, but in the event of a network camera failure, communication in both the forward and reverse directions is performed to maintain communication redundancy and realize a cascade connection. There is.

[Embodiment]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
The network camera system according to the first embodiment of the present invention will be described with reference to FIGS. 2 to 10.

FIG. 2 is a diagram showing a configuration of a network camera system according to the first embodiment.

The illustrated network camera system includes one network camera recorder 10, first to Nth network cameras 21 to 2N, and first to (N + 1) connection cables 31 to 3 (N + 1). In the illustrated example, N is equal to 4.

Therefore, the illustrated network camera system includes one network camera recorder 10, first to fourth network cameras 21 to 24, and first to fifth connection cables 31 to 35.

The network camera recorder 10 has a first recorder port 11 and a second recorder port 12. Each of the first and second recorder ports 11 and 12 consists of a LAN port. Each of the first to fifth connection cables 31 to 35 is composed of a LAN cable.

Each of the first to fourth network cameras 21 to 24 has a first camera port 201 and a second camera port 202 that can be connected to a connection cable, respectively. Each of the first and second camera ports 201 and 202 consists of a LAN port.

The first to fifth connection cables 31 to 35 are from the first recorder port 11 of the network camera recorder 10 to the first camera port 201 and the second camera port of the first to fourth network cameras 21 to 24. It is for connecting to the second recorder port 12 of the network camera recorder 10 via the 202 in a ring shape in a string.

More specifically, the first recorder port 11 of the network camera recorder 10 is connected to the first camera port 201 of the first network camera 21. The second camera port 202 of the first network camera 21 is connected to the first camera port 201 of the second network camera 22. The second camera port 202 of the second network camera 22 is connected to the first camera port 201 of the third network camera 23. The second camera port 202 of the third network camera 23 is connected to the first camera port 201 of the fourth network camera 24. The second camera port 202 of the fourth network camera 24 is connected to the second recorder port 12 of the network camera recorder 10.

With this configuration, the network camera recorder 10 can record the first to fourth video signals that are captured and transmitted by the first to fourth network cameras 21 to 24, respectively. Become.

FIG. 3 is a block diagram showing an internal configuration of a network camera used in the network camera system shown in FIG. FIG. 3 shows the internal configuration of the first network camera 21. Since the second to fourth network cameras 22 to 24 also have the same configuration as the first network camera 21, the illustration of the second to fourth network cameras 22 to 24 is omitted.

As described above, the first network camera 21 includes a first camera port 201 and a second camera port 202. As described above, the first and second camera ports 201 and 201 are for connecting the network camera recorder 10, the network cameras 21 and 24, and the network cameras 21 to 24 with LAN cables 31 to 35. be.

The first network camera 21 includes a LAN port switching hub 203 connected to the first camera port 201 and the second camera port 202. The LAN port switching hub 203 has a function of switching the communication direction of the two LAN ports 201 and 202 according to the instruction of the network camera recorder 10. That is, the LAN port switching hub 203 functions as a port switching means capable of switching the communication direction.

The LAN port switching hub 203 transfers the video signal sent from the first camera port 201 as it is to the second camera port 202, and the video signal sent from the second camera port 202 is used as it is. It has a function of transferring to the camera port 201 of 1.

The first network camera 21 includes a camera control unit 204. The camera control unit 204 has a camera recording function. The camera control unit 204 transmits the first video signal captured by the first network camera 21 from the first camera port 201 to the first connection cable 31 via the LAN port switching hub 203, or Transmission is performed from the second camera port 201 to the second connection cable 32.

FIG. 4 is a block diagram showing an internal configuration of the network camera recorder 10 used in the network camera system shown in FIG. 2.

The network camera recorder 10 includes the first and second recorder ports 11 and 12, the transceiver 13, the controller 15, and the storage device 17 described above.

The transceiver 13 is connected to the first and second recorder ports 11 and 12 and the controller 15. The transceiver 13 has a function of receiving a video signal received from the first recorder port 11 or the second recorder port 12 and transmitting the received video signal to the controller 15. Further, the transceiver 13 transmits an instruction signal (described later) from the controller 15 to the first connection cable 31 or the fifth connection cable 35 via the first recorder port 11 or the second recorder port 12. It also has a function to do.

The storage device 17 is composed of, for example, a hard disk drive (HDD). The storage device 17 has a function of recording a video signal sent from the controller 15. The storage device 17 may be composed of a solid state drive (SSD).

The controller 15 can be realized by a computer using a combination of hardware and software. In the illustrated example, the controller 15 has a memory 42, a program memory 44, and a communication control device 50 according to the present embodiment.

The memory 42 is composed of, for example, a RAM (random access memory) or the like. The memory 42 works as a working memory for temporarily storing the processing result of the communication control device 50.

The program memory 44 includes, for example, a ROM (read only memory) or a RAM. The program memory 44 stores a communication control program described later.

As will be described in detail later, the communication control device 50 controls the communication direction and controls the communication direction to be switched based on the received video signal.

The communication control device 50 can be realized by a processor such as a CPU (central processing unit) or an arithmetic processing unit. That is, the communication control device 50 can be realized as various means by operating hardware such as a CPU based on the communication control program stored in the program memory 44. Further, this communication control program is read into the program memory 44 via a wired, wireless, or recording medium itself, and operates the hardware of the communication control device 50. Examples of recording media include optical disks, magnetic disks, semiconductor memory devices, hard disks, and the like.

FIG. 5 is a block diagram showing a schematic configuration of the communication control device 50. The communication control device 50 includes a communication direction indicating circuit unit 52 and a determination circuit unit 54.

The determination circuit unit 54 receives the first to fourth video signals sent from the first to fifth network cameras 21 to 24 as received video signals, and the first to fourth video signals are described later. It is judged whether or not all of the video signals of are sent.

Based on the determination result of the determination circuit unit 54, the communication direction instruction circuit unit 52 instructs the first to fourth network cameras 21 to 24 to communicate in the forward direction or the reverse direction, as will be described later. ..

FIG. 6 is a flowchart for explaining the operation of the communication control device 50. FIG. 7 is a diagram showing a state in which only forward communication is performed in the network camera system shown in FIG. 2. FIG. 8 is a diagram showing a state in which forward communication and reverse communication are performed in the network camera system shown in FIG. 2 after a failure or disconnection.

Hereinafter, the schematic operation of the communication control device 50 shown in FIG. 5 will be described with reference to FIGS. 6 to 8. However, the flowchart of FIG. 6 describes an example of a general case in which the first to Nth network cameras 21 to 2N are connected to the network camera recorder 10 in a ring shape. Please be careful. Therefore, in the illustrated example, N is equal to 4.

First, the communication direction instruction circuit unit 52 instructs all of the first to fourth network cameras 21 to 24 to communicate in the forward direction from the first recorder port 11 to the second recorder port 12 ( Step S101). This instruction is called a "forward communication instruction".

The first instruction signal indicating this "forward communication instruction" is transmitted to the first connection cable 31 via the transceiver 13 and the first recorder port 11. As a result, in each of the first to fourth network cameras 21 to 24, the LAN port switching hub 203 receives the first instruction signal via the first camera port 201. In response to this first instruction signal, the LAN port switching hub 203 switches to transmit the video signal sent from the camera control unit 204 to the connection cable via the second camera port 202.

As a result, as shown in FIG. 7, the first to fourth video signals captured by the first to fourth network cameras 21 to 24 are forwardly communicated and are transmitted from the fifth connection cable 35 to the fifth. It is sent to the recorder port 12 of 2.

The determination circuit unit 54 receives the first to fourth video signals transmitted from the first to fourth network cameras 21 to 24 as received video signals on the second recorder port 12 in this way. , It is determined whether or not all of the first to fourth video signals have been sent (step S102).

When all of the first to fourth video signals have been sent (YES in step S102), the determination circuit unit 54 repeats the determination operation. As a result, forward communication as shown in FIG. 7 is continuously performed.

In this state, as shown in FIG. 8, a failure has occurred in the second network camera 22, the second camera port 202 of the second network camera 22 has been disconnected, or the third connection cable has been disconnected. It is assumed that a disconnection occurs at 33.

In this case, the determination circuit unit 54 determines that the first to second video signals have not been received (NO in step S102). In response to this determination result, the communication direction indicating circuit unit 52 has the second recorder port 12 to the first with respect to the first network camera 21 and the second network camera 22 from the first recorder port 11. Instructing communication in the reverse direction toward the recorder port 11 (step S103). This instruction is called a "reverse communication instruction".

Here, it is assumed that a failure has occurred in the second network camera 22. In this case, the second instruction signal indicating "reverse communication instruction" is transmitted to the first connection cable 31 via the transceiver 13, the first recorder port 11. As a result, in the first network camera 21, the LAN port switching hub 203 receives the second instruction signal via the first camera port 201. In response to this second instruction signal, the LAN port switching hub 203 of the first network camera 21 transmits the first video signal sent from the camera control unit 204 via the first camera port 201. Switch to transmit to the connection cable 31 of 1.

As a result, as shown in FIG. 8, the first video signal captured by the first network camera 21 is communicated in the reverse direction and sent from the first connection cable 31 to the first recorder port 11. ..

In the network camera recorder 10, the first video signal received at the first recorder port 11 is sent to the controller 15 via the transceiver 13.

In this way, in the network camera system of the first embodiment, when a camera failure occurs, the second network camera 22 in which the failure has occurred by performing both forward communication and reverse communication. Only can be removed and operation can be continued. In other words, the network system of the first embodiment has redundancy.

Next, it is assumed that the second camera port 202 of the second network camera 22 is disconnected, or the third connection cable 33 is disconnected. In this case, the second instruction signal indicating "reverse communication instruction" is transmitted to the first connection cable 31 via the transceiver 13, the first recorder port 11. As a result, in the first and second network cameras 21 and 22, the LAN port switching hub 203 receives the second instruction signal via the first camera port 201. In response to the second instruction signal, the LAN port switching hubs 203 of the first and second network cameras 21 and 22 receive the first and second video signals sent from the camera control unit 204, respectively. It is switched to transmit to the first and second connection cables 31 and 32 via the first camera port 201.

As a result, as shown in FIG. 8, the second and first video signals captured by the second and first network cameras 22 and 21 are communicated in the reverse direction, and the second and first connection cables are used. It is sent from 32 and 31 to the first recorder port 11.

In the network camera recorder 10, the second and first video signals received by the first recorder port 11 are sent to the controller 15 via the transceiver 13.

In this way, in the network camera system of the first embodiment, when the LAN port of the camera is disconnected or the cable is disconnected, both forward communication and reverse communication are performed. Operation can be continued. In other words, the network system of the first embodiment has redundancy.

On the other hand, it is assumed that the second connection cable 32 is disconnected or the second camera port 202 of the first network camera 21 is disconnected. In this case, the determination circuit unit 54 determines that the first video signal has not been received (NO in step S102). In response to this determination result, the communication direction indicating circuit unit 52 reverses the direction from the second recorder port 12 to the first recorder port 11 with respect to the first network camera 21 from the first recorder port 11. Communication is instructed (step S103).

As a result, as described above, the operation can be continued by performing both the forward communication and the reverse communication, so that it can be seen that the network system of the first embodiment has redundancy.

Next, the specifics of the determination circuit unit used in the communication control device will be described in more detail.

FIG. 9 is a block diagram showing a schematic configuration of the communication control device 50A showing an example of the determination circuit unit.

The illustrated communication control device 50A includes a communication direction indicating circuit unit 52 and a determination circuit unit 54A. The determination circuit unit 54A includes a camera identification number presence / absence detection circuit unit 541A.

More specifically, the first to fourth network cameras 21 to 24 are assigned first to fourth camera identification numbers, respectively. The camera control units 204 of the first to fourth network cameras 21 to 24 transmit the first to fourth video signals by adding the first to fourth camera identification numbers assigned to their own devices, respectively. do.

The camera identification number presence / absence detection circuit unit 541A determines whether or not a failure has occurred in the nth (1 <n ≦ N) network camera depending on the presence / absence of the first to Nth camera identification numbers in the received video signal. It is determined whether or not the (n + 1) th connection cable connected to the nth network camera is disconnected.

FIG. 10 is a flowchart for explaining the operation of the communication control device 50A. However, the flowchart of FIG. 10 also describes an example of a general case in which the first to Nth network cameras 21 to 2N are connected to the network camera recorder 10 in a ring shape. Please be careful. Therefore, in the illustrated example, N is equal to 4.

Hereinafter, the schematic operation of the communication control device 50A shown in FIG. 9 will be described with reference to FIG.

First, the communication direction instruction circuit unit 52 issues the above-mentioned "forward communication instruction" (step S101).

Next, the camera identification number presence / absence detection circuit unit 541A of the determination circuit unit 54A determines whether or not all of the first to fourth camera identification numbers are present in the received video signal (step S102A).

Here, as shown in FIG. 8, it is assumed that a failure occurs in the second network camera 22 or a disconnection occurs in the third connection cable 33.

In this case, the camera identification number presence / absence detection circuit unit 541A of the determination circuit unit 54A determines that there is no first or second camera identification number in the received video signal (NO in step S102A). In this case, in response to this determination result, the communication direction instruction circuit unit 52 issues the above-mentioned "reverse direction communication instruction" (step S103).

Next, the effect of the first embodiment will be described.

The first effect is that the network camera recorder 10 can be developed inexpensively and compactly. The reason is that the number of LAN ports of the network camera recorder 10 can be reduced.

The second effect is that the number of connected network cameras can be easily increased. The reason is that the network cameras 21 to 24 are connected in a row.

The third effect is that the labor of installing the cable network can be improved. The reason is that the network cameras 21 to 24 are similarly connected in a row.

The fourth effect is that it has redundancy so that the operation can be continued even when a camera failure occurs or the connection cable is disconnected. The reason is that normally only forward communication is performed, but when a camera failure occurs or the connection cable is disconnected, forward communication and reverse communication are performed to remove only the network camera 22 in which the failure has occurred.

[Second Embodiment]
The network camera system according to the second embodiment of the present invention will be described with reference to FIGS. 11 to 14.

FIG. 11 is a diagram showing a configuration of a network camera system according to a second embodiment.

The illustrated network camera system has the same configuration as the network camera system shown in FIG. 2, except that the internal configurations of the first to fourth network cameras and the internal configurations of the network camera recorder are different as described later. Have and operate. Therefore, the first to fourth network cameras are each designated with a reference code of 21A to 24A, and the network camera recorder is designated with a reference code of 10A. Those having the same function as the components of the first embodiment described above are designated by the same reference numerals. In the following, in order to simplify the explanation, mainly the differences from the first embodiment will be described in detail.

The illustrated network camera system includes one network camera recorder 10A, first to fourth network cameras 21A to 24A, and first to fifth connection cables 31 to 35.

FIG. 12 is a block diagram showing an internal configuration of a network camera used in the network camera system shown in FIG. FIG. 12 shows the internal configuration of the second network camera 22A. Since the first, third, and fourth network cameras 21A, 23A, and 24A also have the same configuration as the second network camera 22A, the first, third, and fourth network cameras 21A, 23A, And 24A are omitted.

The second network camera 22A has and operates in the same configuration as the first network camera 21 shown in FIG. 3, except that the fault detector 205 as described later is further provided.

The fault detector 205 detects whether or not a fault has occurred in its own device, and if the fault has been detected, the fault detector 205 generates a fault detection signal.

Therefore, the first to fourth fault detectors 205 of the first to fourth network cameras 21A to 24A each detect whether or not a fault has occurred in their own device, and when a fault occurs, they detect it. The first to fourth failure detection signals are generated.

The first to fourth camera control units 204 of the first to fourth network cameras 21A to 24A add the first to fourth failure detection signals to the first to fourth video signals and transmit them, respectively. .. Alternatively, the first to fourth camera control units 204 of the first to fourth network cameras 21A to 24A receive the first to fourth failure detection signals in place of the first to fourth video signals, respectively. You may send it.

FIG. 13 is a block diagram showing an internal configuration of the network camera recorder 10A used in the network camera system shown in FIG.

The network camera recorder 10A has and operates in the same configuration as the network camera recorder 10 shown in FIG. 4, except that the controller configuration differs as described later. Therefore, a reference code of 15A is attached to the controller.

The controller 15A has and operates in the same configuration as the controller 15 shown in FIG. 4, except that the configuration of the communication control device differs as described later. Therefore, a reference code of 50B is attached to the communication control device.

FIG. 14 is a block diagram showing a schematic configuration of the communication control device 50B. The communication control device 50B includes a communication direction indicating circuit unit 52 and a determination circuit unit 54B. The determination circuit unit 54B includes a failure detection signal detection circuit unit 541B.

The failure detection signal detection circuit unit 541B determines that a failure has occurred in the nth network camera by detecting the presence of the nth failure detection signal in the received video signal.

FIG. 15 is a flowchart for explaining the operation of the communication control device 50B. However, the flowchart of FIG. 15 also describes an example of a general case in which the first to Nth network cameras 21A to 2NA are connected to the network camera recorder 10A in a ring shape. Please be careful. Therefore, in the illustrated example, N is equal to 4.

Hereinafter, the schematic operation of the communication control device 50B shown in FIG. 14 will be described with reference to FIG.

First, the communication direction instruction circuit unit 52 issues the above-mentioned "forward communication instruction" (step S101).

Next, the failure detection signal detection circuit unit 541B of the determination circuit unit 54B determines whether or not the nth failure detection signal is present in the received video signal (step S102B).

Here, it is assumed that a failure occurs in the second network camera 22A as in the case shown in FIG.

In this case, the failure detection signal detection circuit unit 541B of the determination circuit unit 54B detects the second failure detection signal in the received video signal (YES in step S102B). In this case, in response to this determination result (detection result), the communication direction indicating circuit unit 52 issues the above-mentioned "reverse direction communication instruction" (step S103).

Next, the effect of the second embodiment will be described.

The first effect is that the network camera recorder 10A can be developed inexpensively and compactly. The reason is that the number of LAN ports of the network camera recorder 10A can be reduced.

The second effect is that the number of connected network cameras can be easily increased. The reason is that the network cameras 21A to 24A are connected in a row.

The third effect is that the labor of installing the cable network can be improved. The reason is that the network cameras 21A to 24A are similarly connected in a row.

The fourth effect is that it has redundancy so that the operation can be continued even when a camera failure occurs. The reason is that normally only forward communication is performed, but when a camera failure occurs, only the network camera 22A in which the failure has occurred is removed by performing forward communication and reverse communication.

Although the present invention has been described above with reference to the embodiments, the present invention is not limited to the above embodiments. Various modifications that can be understood by those skilled in the art can be made to the structure and details of the present invention within the scope of the present invention.

Some or all of the above embodiments may also be described, but not limited to:

(Appendix 1) The first camera port and the second camera port that can be connected to the connection cable, respectively.
A port switching means that is connected to the first camera port and the second camera port and can switch the communication direction.
Equipped with a network camera.

(Supplementary Note 2) The network camera according to Supplementary Note 1, wherein each of the first camera port and the second camera port comprises a LAN port.

(Appendix 3) The network camera according to Appendix 2, wherein the port switching means comprises a LAN port switching hub.

(Appendix 4) A network camera recorder having a first recorder port and a second recorder port,
A first to Nth (N is an integer of 3 or more) network cameras, each of which has the configuration described in any one of the appendices 1 to 3.
From the first recorder port of the network camera recorder to the second camera port of the network camera recorder via the first camera port and the second camera port of the first to Nth network cameras. The first to first (N + 1) connection cables that connect to the recorder port in a ring shape, and
A network camera system.

(Appendix 5) Each of the first recorder port and the second recorder port is composed of a LAN port.
Each of the first to (N + 1) connection cables comprises a LAN cable.
The network camera system according to Appendix 4.

(Appendix 6) A communication control method implemented by the network camera recorder in the network camera system according to the appendix 4.
A first instruction step for instructing all of the first to Nth network cameras to perform forward communication from the first recorder port to the second recorder port.
The first to Nth video signals sent from the first to Nth network cameras are received as received video signals at the second recorder port, and all of the first to Nth video signals are received. Judgment process to judge whether or not has been sent, and
When it is determined in the determination step that the first to nth (1 <n ≦ N) video signals cannot be received, the first to nth network cameras are referred to from the first recorder port. A second instruction step for instructing reverse communication from the second recorder port to the first recorder port, and
Communication control method including.

(Appendix 7) The first to Nth network cameras transmit the first to Nth video signals by adding the first to Nth camera identification numbers assigned to their own devices, respectively.
In the determination step, whether or not a failure has occurred in the nth network camera depending on the presence or absence of the first to Nth camera identification numbers in the received video signal, or is connected to the nth network camera. Determine if the first (n + 1) connection cable is disconnected,
The communication control method according to Appendix 6.

(Appendix 8) Each of the first to Nth network cameras detects whether or not a failure has occurred in its own device, and when the failure has been detected, the first to Nth failure detection signals are transmitted. It has a first to Nth fault detector to generate,
The first to Nth fault detection signals are transmitted in addition to or in place of the first to Nth video signals.
The determination step determines that a failure has occurred in the nth network camera by detecting the presence of the nth failure detection signal in the received video signal.
The communication control method according to Appendix 6.

(Appendix 9) The communication control device of the network camera recorder in the network camera system according to the appendix 4.
Whether or not all of the first to Nth video signals are transmitted by receiving the first to Nth video signals transmitted from the first to Nth network cameras as received video signals, respectively. As a means of judging whether or not
Based on the determination result of the determination means, the communication direction indicating means for instructing the first to Nth network cameras to communicate in the forward direction or the reverse direction,
Communication control device with.

(Appendix 10) The first to Nth network cameras transmit the first to Nth video signals by adding the first to Nth camera identification numbers assigned to their own devices, respectively.
The determination means is connected to the nth network camera or whether or not a failure has occurred in the nth network camera depending on the presence or absence of the first to Nth camera identification numbers in the received video signal. It comprises means for detecting the presence / absence of a camera identification number, which determines whether or not the first (n + 1) connection cable has been disconnected.
The communication control device according to Appendix 9.

(Appendix 11) Each of the first to Nth network cameras detects whether or not a failure has occurred in its own device, and when the failure has been detected, the first to Nth failure detection signals are transmitted. It has a first to Nth fault detector to generate,
The first to Nth fault detection signals are transmitted in addition to or in place of the first to Nth video signals.
The determination means comprises failure detection signal detection means for determining that a failure has occurred in the nth network camera by detecting the presence of the nth failure detection signal in the received video signal.
The communication control device according to Appendix 9.

(Appendix 12) A communication control program for causing the computer of the network camera recorder in the network camera system according to the appendix 4 to control communication, and the computer.
Whether or not all of the first to Nth video signals are transmitted by receiving the first to Nth video signals transmitted from the first to Nth network cameras as received video signals, respectively. Judgment procedure to judge whether
Based on the judgment result of the judgment procedure, the communication direction instruction procedure for instructing the first to Nth network cameras to communicate in the forward direction or the reverse direction, and
Communication control program for executing.

(Appendix 13) The first to Nth network cameras transmit the first to Nth video signals by adding the first to Nth camera identification numbers assigned to their own devices, respectively.
In the determination procedure, whether or not a failure has occurred in the nth network camera depending on the presence or absence of the first to Nth camera identification numbers in the received video signal in the computer, or the nth network camera. It consists of a camera identification number presence / absence detection procedure for determining whether or not the (n + 1) th connection cable connected to is disconnected.
The communication control program according to Appendix 12.

(Appendix 14) Each of the first to Nth network cameras detects whether or not a failure has occurred in its own device, and when the failure has been detected, the first to Nth failure detection signals are transmitted. It has a first to Nth fault detector to generate,
The first to Nth fault detection signals are transmitted in addition to or in place of the first to Nth video signals.
The determination procedure comprises a failure detection signal detection procedure that causes the computer to determine that a failure has occurred in the nth network camera by detecting the presence of the nth failure detection signal in the received video signal. ,
The communication control program according to Appendix 12.

10, 10A Network camera recorder 11, 12 LAN port 13 Transceiver 15, 15A Controller 17 Storage device 21 to 24 Network camera 21A to 24A Network camera 201, 202 LAN port 203 LAN port Switching hub 204 Camera control unit 205 Failure detector 31 to 35 LAN cable 42 Memory 44 Program memory 50, 50A, 50B Communication control device 52 Communication direction indicator circuit section 54, 54A, 54B Judgment circuit section 541A Camera identification number presence / absence detection circuit section 541B Failure detection signal detection circuit section

Claims (9)

A network camera recorder with a first recorder port and a second recorder port,
Port switching that is connected to the first camera port and the second camera port that can be connected to the connection cable, respectively, and the first camera port and the second camera port, and the communication direction can be switched. A first to Nth (N is an integer of 3 or more) network cameras comprising means and means.
From the first recorder port of the network camera recorder to the second camera port of the network camera recorder via the first camera port and the second camera port of the first to Nth network cameras. The first to first (N + 1) connection cables that connect to the recorder port in a ring shape, and
A communication control method implemented by the network camera recorder in a network camera system.
A first instruction step for instructing all of the first to Nth network cameras to perform forward communication from the first recorder port to the second recorder port.
The first to Nth video signals sent from each of the first to Nth network cameras are received as received video signals at the second recorder port, and the first to Nth video signals are received. Judgment process to judge whether everything has been sent, and
When it is determined in the determination step that the first to nth (1 <n ≦ N) video signals cannot be received, the first to nth network cameras are referred to from the first recorder port. A second instruction step for instructing reverse communication from the second recorder port to the first recorder port, and
Communication control method including. The first to Nth network cameras transmit the first to Nth video signals by adding the first to Nth camera identification numbers assigned to their own devices, respectively.
In the determination step, whether or not a failure has occurred in the nth network camera depending on the presence or absence of the first to Nth camera identification numbers in the received video signal, or is connected to the nth network camera. Determine if the first (n + 1) connection cable is disconnected,
The communication control method according to claim 1 . Each of the first to Nth network cameras detects whether or not a failure has occurred in its own device, and when the failure has been detected, the first to Nth network cameras generate the first to Nth failure detection signals. To have the Nth fault detector,
The first to Nth fault detection signals are transmitted in addition to or in place of the first to Nth video signals.
The determination step determines that a failure has occurred in the nth network camera by detecting the presence of the nth failure detection signal in the received video signal.
The communication control method according to claim 1 . A network camera recorder with a first recorder port and a second recorder port,
Port switching that is connected to the first camera port and the second camera port that can be connected to the connection cable, respectively, and the first camera port and the second camera port, and the communication direction can be switched. A first to Nth (N is an integer of 3 or more) network cameras comprising means and means.
From the first recorder port of the network camera recorder to the second camera port of the network camera recorder via the first camera port and the second camera port of the first to Nth network cameras. The first to first (N + 1) connection cables that connect to the recorder port in a ring shape, and
A communication control device for the network camera recorder in a network camera system.
Whether or not all of the first to Nth video signals are transmitted by receiving the first to Nth video signals transmitted from the first to Nth network cameras as received video signals, respectively. As a means of judging whether or not
Based on the determination result of the determination means, the communication direction indicating means for instructing the first to Nth network cameras to communicate in the forward direction or the reverse direction,
Communication control device with. Each of the first camera port and the second camera port consists of a LAN port.
The communication control device according to claim 4, wherein the port switching means comprises a LAN port switching hub. Each of the first recorder port and the second recorder port consists of a LAN port.
Each of the first to (N + 1) connection cables comprises a LAN cable.
The communication control device according to claim 4 or 5. The first to Nth network cameras transmit the first to Nth video signals by adding the first to Nth camera identification numbers assigned to their own devices, respectively.
The determination means is connected to the nth network camera or whether or not a failure has occurred in the nth network camera depending on the presence or absence of the first to Nth camera identification numbers in the received video signal. It comprises means for detecting the presence / absence of a camera identification number, which determines whether or not the first (n + 1) connection cable has been disconnected.
The communication control device according to any one of claims 4 to 6 . Each of the first to Nth network cameras detects whether or not a failure has occurred in its own device, and when the failure has been detected, the first to Nth network cameras generate the first to Nth failure detection signals. To have the Nth fault detector,
The first to Nth fault detection signals are transmitted in addition to or in place of the first to Nth video signals.
The determination means comprises failure detection signal detection means for determining that a failure has occurred in the nth network camera by detecting the presence of the nth failure detection signal in the received video signal.
The communication control device according to any one of claims 4 to 6 . A network camera recorder with a first recorder port and a second recorder port,
Port switching that is connected to the first camera port and the second camera port that can be connected to the connection cable, respectively, and the first camera port and the second camera port, and the communication direction can be switched. A first to Nth (N is an integer of 3 or more) network cameras comprising means and means.
From the first recorder port of the network camera recorder to the second camera port of the network camera recorder via the first camera port and the second camera port of the first to Nth network cameras. The first to first (N + 1) connection cables that connect to the recorder port in a ring shape, and
A communication control program for causing the computer of the network camera recorder in the network camera system to control communication.
Whether or not all of the first to Nth video signals are transmitted by receiving the first to Nth video signals transmitted from the first to Nth network cameras as received video signals, respectively. Judgment procedure to judge whether
Based on the judgment result of the judgment procedure, the communication direction instruction procedure for instructing the first to Nth network cameras to communicate in the forward direction or the reverse direction, and
Communication control program for executing.

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