JP2011259359A - Video recording system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video recording system by which an estimation for the number of recording dates can be accurately checked.SOLUTION: When damage is occurred on an imaging apparatus such as a camera but it is not complete failure and caused some kind of fault on video such as generating geometric patterns, consumption of recording capacity can be extremely increased due to the damage. Thus, video can not be recorded for the preliminarily predicted hours. In a video recording system of the present invention, recording capacity for a constant time interval can be periodically obtained during recording processing, and change in the recording capacity can be periodically checked to give an alarm.

Description

  The present invention relates to a video recording apparatus that records video obtained by an imaging device such as a camera, and in particular, periodically acquires a storage capacity of a video recorded in the video recording apparatus for a certain period and performs abnormal recording. The present invention relates to a video recording system for detecting a state.

An example of a recording capacity monitoring method in a conventional video recording system will be described with reference to FIGS.
FIG. 6 is a block diagram for explaining an example of the configuration of a conventional video recording system. 101 ′ is a video recording device, 104 is a communication channel such as a network or a dedicated line, and 105 ′ is an information terminal that monitors the status of the video recording device 101 ′. The information terminal 105 ′ may be a simple monitor or may be configured with a personal computer or the like, and has a display unit (not shown) that displays information using dedicated software or a WEB browser.

In the video recording apparatus 101 ′, reference numeral 106 denotes a storage unit, 102 denotes a recording area of the storage unit 106 for recording the video at point A, 103 denotes a recording area of the storage unit 106 for recording video at the point B, and 201 ′. Is a software processing unit in the video recording apparatus. In the recording areas 102 and 103, capacity allocation is performed for each camera video (for example, a video of a camera that images a point A and a video of a camera that images a point B) (see Patent Document 1). , May be managed collectively. The software processing unit 201 ′ performs a recording process, a response to an external control command, and the like. Predetermined software for performing the process is registered, and the processing operation is performed based on these softwares. Is going.
In the information terminal 105 ′, 202 ′ is a software processing unit that displays information such as dedicated software inside the information terminal 105 and a WEB browser. In the software processing unit 202 ′, dedicated software in the information terminal 105 ′, software for displaying information such as a WEB browser, and the like are registered, and processing operations are performed based on these software. These displays are displayed on a display unit (not shown) of the information terminal 105 ′ or an external display device.

  FIG. 5 is a diagram illustrating an example of the state of the recording area of the video recording apparatus 101 ′ displayed on the information terminal 105 ′ in FIG. 6. The storage unit 106 of the video recording apparatus 101 ′ is divided into two areas, a recording area 102 for storing the captured image of the point A and a recording area 103 for storing the captured image of the point B. For each of the divided recording areas In addition, the captured image of the point A and the captured image of the point B are stored respectively. At this time, as the information of the recording area at the point A, the allocated capacity “22000 MB”, the recorded video start point “A0 (start point address), XXX × year ×× month ×× day (start date), XX: × ×: ×× (time (hour: minute: second)) ”, recorded video end point“ A1 (end point address), XXX × year ×× month ×× day (start date), XX: ××: XX (time (hours: minutes: seconds)) and used capacity / recording time "A1-A0 (used capacity), XX month XX day, XX: XX: XX (month, day, Hour: minute: second) "is displayed. Similarly, as the information of the recording area at the B point, the allocated capacity “22000 MB”, the recording video start point “B0 (start point address), xxx year, xx month xx day (start date), xx: XX: XX (time (hours: minutes: seconds)) ", recorded video end point" B1 (end point address), XXXXXX year XX month XX day (start date), XX: XX : XX (time (hours: minutes: seconds)) and used capacity / recording time "B1-B0 (used capacity), XX month XX day, XX: XX: XX (month, day) , Hour: minute: second) "is displayed. Here, xx means that a numerical value is displayed, but does not mean that it is the same number.

  The addresses of the recording area 102 and the recording area 103 are configured so that the end point and the start point of the physical recording area are continuous. For example, in the recording area 102, when the first address is 0, the last address is 22000, the start address A0 is 2100, and the end address A1 is 15, the used capacity A1-A0 is , (2200− “A1”) + (“A0” −0) = (2200−2100) + (15−0) = 115.

The software processing unit 201 ′ of the video recording apparatus 101 ′ uses the information for displaying in FIG. 5 as a recording area in which the input camera video is designated by the recording area 102 of the storage unit 106 or a predetermined address of the storage area 103. And the display information of FIG. 5 is acquired. That is, the video recording apparatus 101 ′ acquires the recorded video and the display information thereof based on the control of the software processing unit 201 ′. The software processing unit 201 ′ transmits the acquired information to the information terminal 105 ′ via the communication path 104.
The software processing unit 202 ′ of the information terminal 105 ′ performs communication via the communication path 104, acquires the recorded video and the display information of FIG. 5, and displays it.

  Some video recording systems do not set the allocated capacity for each video (point A, point B) in the display of FIG. In such an unset system, each time an image is input, the recording capacity is used by recording processing, so that the influence of one image is exerted as a whole.

  As described above, in the prior art, as shown in FIG. 5, the recording video start point (data remains in each storage area 102 or 103 in which the video at each point (point A and point B) is recorded. The oldest address and time) and the end point (the latest address and time remaining in the data) are known, and the current recording time can be calculated from the difference. In the case of repeated recording settings (overwriting from the oldest data when the allocated capacity is full), the entire recording time can be calculated when the recording is completed or calculated at a general rate of the recording settings.

Japanese Patent Laid-Open No. 2002-300568

In the conventional system, the entire recording time cannot be determined unless the capacity is full (or if all recording areas are not used for video recording). Moreover, since there is a difference for each input video (for example, depending on a landscape, a scene, etc.) at a general recording rate, the recording time may be shifted.
Furthermore, an imaging device such as a camera may cause some failure including a power interruption. If the failure that has occurred is not a complete failure but some abnormality has occurred in the video image, a geometric pattern may be generated, and based on this, the recording capacity may be consumed abnormally. For this reason, there has been a problem that it is not possible to record video for an expected time.
In view of the above problems, an object of the present invention is to provide a video recording system capable of accurately confirming the number of recording days.

In order to solve the above-described problems, the video recording system of the present invention can periodically acquire a recording capacity at a certain time interval during the recording process, periodically check the fluctuation, and issue a warning. Is.
That is, the video recording system of the present invention includes a video recording device that records video distributed from an imaging device, and an information terminal that communicates with the video recording device via a communication path and monitors the status of the video recording device. In the configured video recording system, the video recording device includes a storage unit having a plurality of recording areas, and a first software processing unit that controls the storage unit to record and manage an input video. The information terminal communicates with a recording medium and the first software processing unit, acquires consumption capacity information within a predetermined period of the storage unit of the video recording device, stores the information in the recording medium, When the acquired consumption capacity information is abnormal, a second software processing unit for outputting an alert is provided.

  According to the present invention, since the video recordable time is calculated based on the recorded video data, the error between the actual video recordable time and the calculated video recordable time can be reduced. .

It is a figure which shows one Example at the time of displaying the state of the recording area of the video recording device of this invention on an information terminal. It is a block diagram for demonstrating the structure of one Example of the video recording system of this invention. It is a figure which shows the process sequence for demonstrating operation | movement of each software processing part 202 and 201 of the information terminal of one Example of the video recording system of this invention, and a video recording device. It is a flowchart for demonstrating operation | movement of the process procedure P308 of FIG. 3 and the procedure P311 of the information terminal of one Example of the video recording system of this invention, and a video recording device. It is a figure which shows an example at the time of displaying on the information terminal the state of the recording area of the conventional video recording device. It is a block diagram for demonstrating an example of a structure of the conventional video recording system.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In addition, the following description is for describing one embodiment of the present invention, and does not limit the scope of the present invention. Accordingly, those skilled in the art can employ embodiments in which these elements or all of the elements are replaced with equivalent ones, and these embodiments are also included in the scope of the present invention.
In this document, components having common functions are denoted by the same reference numerals in the following description of each drawing including FIG. 5 and FIG.

  An example of a recording capacity monitoring method in the video recording system of the present invention will be described with reference to FIGS. FIG. 2 is a block diagram for explaining the configuration of an embodiment of the video recording system of the present invention. The video recording system of the present invention shown in FIG. 2 uses the video recording apparatus 101 in place of the video recording apparatus 101 ', and uses the information terminal 105 in place of the information terminal 105'. In place of the software processing unit 201 ′ of the video recording apparatus 101 ′, the software processing unit 201 is provided in the video recording apparatus 101. Further, instead of the software processing unit 202 ′ of the information terminal 105 ′, a software processing unit 202 is provided in the information terminal 105, and a recording medium 107 for storing data acquired by the software processing unit 202 in the information terminal 105 ′. Is provided.

In the video recording apparatus 101 of FIG. 2, the recording area 102 and the recording area 103 of the storage unit 106 may be allocated capacity for each camera video, or may be managed collectively. The software processing unit 201 performs recording processing, response to an external control command, and the like in the video recording apparatus 101. Predetermined software for performing the processing is registered, and these software The processing operation is performed based on the wear.
The information terminal 105 in FIG. 2 is an information terminal that monitors the state of the video recording apparatus 101. In the case of a simple monitor, information may be displayed on a personal computer or the like using dedicated software or a WEB browser.
In the information terminal 105, 202 is a software processing unit that displays information such as dedicated software inside the information terminal 105 and a WEB browser. In the software processing unit 202, dedicated software inside the information terminal 105, software for displaying information such as a WEB browser, and the like are registered, and processing operations are performed based on these software. The software processing unit 202 communicates with the software processing unit 201 of the video recording apparatus 101 via the communication path 104 at a predetermined cycle, and acquires the states of the recording areas 102 and 103 of the video recording apparatus 101.
In addition, the software processing unit 202 stores the data of the state of each recording area 102 and recording area 103 in the recording medium 107 for the obtained storage unit 106 of the video recording apparatus 101.

FIG. 1 is a diagram showing an embodiment in which the state of the recording area of the video recording apparatus 101 is displayed on the information terminal 105 of FIG.
The video recording apparatus 101 records the input camera video in the address area defined in the recording area 102 or 103 by the operation of the software processing unit 201. In the information terminal 105, the software processing unit 202 communicates with the software processing unit 201 of the video recording apparatus 101 via the communication path 104, and acquires the display information of FIG. That is, the video recording apparatus 101 acquires the recorded video and the display information based on the control of the software processing unit 201. The software processing unit 201 transmits the acquired display information to the information terminal 105 via the communication path 104. The software processing unit 202 of the information terminal 105 acquires display information taken into consideration from the video recording apparatus 101 and stores it in the recording medium 107.

As an example, Fig. 1 shows the recording capacity for one day in advance by dividing it into time zones of morning (4: 00-12: 00), daytime (12: 00-20: 00), and night (20: 00-44: 00). Operates to get data.
At point A, from day 1 to day 4, a constant recording capacity is shown throughout the day.
At point B, from day 1 to day 3, the recording capacity tends to increase during the day.
On the fifth day of point A, the recording capacity is drastically reduced than usual. In this case, it is considered that the environment has changed and it has become a place that is usually almost dark and hardly monitored, or has become a flat image due to a failure and has been extremely reduced. However, with the data for one day, it is still early to draw a conclusion, so it is judged that attention is needed.

On the fourth day at point B, the recording capacity is extremely increased, and there is no tendency to increase the normal daytime. From this, it can be considered that (1) the environment has changed dramatically, or (2) a geometric pattern appears in the image due to the failure, and the image cannot be compressed. However, the former (1) is usually difficult to think, and the latter (2) is often the cause. In this case, the device failure has not yet been automatically determined, and some video can be acquired and recording continues. For this reason, it cannot be captured by a single device health check. Further, since the recording capacity becomes large, if left unattended, there is a possibility that there will be no recording area in which a video to be originally acquired should be recorded.
In such a case, it is detected from the comparison with the past state that the recording state has changed, and the information terminal 105 outputs an alarm. As an alarm to be output, for example, a warning sound or a warning sound is output from a speaker (not shown) attached to the information terminal 105, or an alert may be output as a display on the information terminal 105.
Note that the software processing unit 202 and the recording medium 107 can be incorporated into the video recording apparatus 101.

According to the first embodiment, it is possible to predict the number of recording days with high accuracy by periodically checking the recording capacity for a certain period. For one, failure diagnosis can prevent the recorded image from being affected in a situation where the device does not reach a complete failure. One is that it is possible to predict at an early point how much the recorded video will be affected by a change in the situation of the monitoring point.
At the start of video recording, it is possible to quickly cope with a shortage of recording time by following the observation for several days.

Next, an embodiment for calculating the recording capacity actually used in FIG. 2 will be described with reference to FIGS. In the present embodiment, the video recording apparatus 101 in FIG. 2 is, for example, a network digital recorder and the communication path 104 is an IP network line. However, the configuration of the video recording system, the video recording apparatus, and the information terminal are the same. The configuration may be the same. Also, the display example of the information terminal is the same as that shown in FIG. 2, or a recordable time may be added.
The communication method between the information terminal 105 and the video recording apparatus 101 is TCP / IP, and the control method is CGI (Common Gateway Interface).
Then, the main implementation means first sets the date and time range for checking the usage status, acquires the disk usage capacity at the set start and end date and time, and acquires the disk usage capacity within the acquired date and time range per second. The available disk capacity is calculated and the recordable time is calculated from the allocated disk capacity.

FIG. 3 is a diagram showing a processing procedure for explaining the operations of the software processing units 202 and 201 of the information terminal and the video recording apparatus of an embodiment of the video recording system of the present invention. Processing moves from top to bottom (time elapses). The processing sequence on the left shows processing on the information terminal 105 side, and the processing sequence on the right shows processing on the video recording apparatus 101 side.
In procedure P301, the IP address of the video recording apparatus 101 is acquired. Next, in procedure P302, the start point and end point date and time, that is, the date and time range for checking the usage status are set. In step P303, the disk allocation capacity acquisition CGI is transmitted from the information terminal 105 to the video recording apparatus 101. In step P304, a response is returned from the video recording apparatus 101 to the information terminal 105.

In procedure P305, the information terminal 105 holds the disk allocation capacity (referred to as disk capacity Q). Next, in procedure P306, the channel number acquisition CGI is transmitted from the information terminal 105 to the video recording apparatus 101. In procedure P307, a response is returned from the video recording apparatus 101 to the information terminal 105.
In step P308, the information terminal 105 performs start point frame ID acquisition processing (details will be described with reference to FIG. 4). In step P309, the information terminal 105 transmits a disk usage capacity acquisition aCGI to the video recording apparatus 101. Then, the response of the start frame address is returned from the video recording apparatus 101 to the information terminal 105.
In step P311, the information terminal 105 performs an end point frame ID acquisition process (details will be described with reference to FIG. 4). In step P312, the information terminal 105 transmits a disk usage capacity acquisition bCGI to the video recording apparatus 101. Then, the response of the address of the end point frame is returned from the video recording apparatus 101 to the information terminal 105.

In procedure P314, the information terminal 105 calculates the disk usage amount U in seconds for the date / time range (setting range) for checking the set usage status. That is, the used disk amount U is calculated from the start point address and the end point address.
In procedure P315, the information terminal 105 calculates the recordable time X (X = Q ÷ U). Here, Q is a disk capacity allocated to one video recording, and U is a disk capacity used for one second. For example, when Q = 1 [GB] and U = 40 [KB], X = 1 [GB] / 40 [KB / second] = 1000000 [KB] / 40 [KB / second] = 25000 [second] Thus, the recordable time X of this video is 25000 [seconds].
Thereafter, this operation is repeated at a predetermined cycle. If there is a different video recording device, the same calculation is performed for the video recording device.
Note that, as described in the first embodiment, the processing may be performed up to the procedure P314.

Next, details of the procedure P308 and the procedure P311 in FIG. 3 will be described with reference to FIG. FIG. 4 is a flowchart for explaining the operations of the processing procedure P308 and the procedure P311 of FIG. 3 of the information terminal and the video recording apparatus of the embodiment of the video recording system of the present invention.
In FIG. 4, procedure P402 to procedure P411 are flowcharts showing details of the processing procedure from procedure P308 to procedure P313 in FIG.
Therefore, at the start of the process of FIG. 4 in process P401, a date / time range (request date / time, start point frame ID, end point frame ID) for checking the usage status is set as the setting range.

First, in procedure P402, the information terminal 105 sets an intermediate frame ID between the start point and the end point. The intermediate frame ID represents an intermediate value between the start frame ID and the end frame ID. By using this value as a parameter, an inquiry is made to the network digital recorder, and the recording date and time at that time is acquired.
In step P403, the information acquisition CGI is transmitted from the information terminal 105 to the video recording apparatus 101. In step P404, a response is returned from the video recording apparatus 101 to the information terminal 105.
Next, in procedure P405, the information terminal 105 acquires the date and time from the responded data. In step P406, it is determined whether the request date and time (date and time requested by the information terminal 105 in step 403) is equal to the acquisition date and time (date and time when the video recording apparatus 101 responded in step P404). If they are equal, the process proceeds to procedure P407, and if not, the process proceeds to procedure P408.
In procedure P407, a return value is set, and the processing procedure in FIG. 4 ends (proceeds to procedure P314 in FIG. 3). The return value setting is a value to be returned at the end of the processing procedure of FIG. 4, and the value to be set is an intermediate frame ID set immediately after the start of the processing.

In step 408, it is determined whether or not the request date and time (date and time requested by the information terminal 105 in step 403) is earlier than the acquisition date and time (date and time when the video recording apparatus 101 responded in step P404). If it is early, the process proceeds to procedure P409, and if it is late, the process proceeds to procedure P411.
In step P409, the acquired frame ID is set as the end point frame, and the process proceeds to step P410.
In procedure P410, frame ID acquisition processing is performed, and the processing procedure of FIG.
In step P411, the acquired frame ID is set as the start point frame, and the process proceeds to step P410.

As described above, according to the second embodiment, since the recordable time is calculated based on the recorded data, the error between the actual recordable time and the calculated recordable time can be reduced.
Further, in the recording of surveillance video in the video surveillance system, it is often stored using video compression technology. However, video compression technology varies greatly depending on the landscape and scene of the video. Since the recording capacity is in a fixed state, it was operated in a state in which the originally planned recording time could not be satisfied without noticing the fluctuation. According to the second embodiment, the capacity of the recorded video is periodically checked, the progress data is acquired, and a warning is issued. Alternatively, it is possible to record the video data of the upstream device (camera or encoder) by automatically increasing the compression rate, thereby ensuring the recording capacity.

  101, 101 ′: Video recording device, 102, 103: Recording area, 104: Communication channel, 105, 105 ′: Information terminal, 106: Storage unit, 107: Recording medium, 201, 201 ′: 202, 202 ′: Software Processing part.

Claims (1)

In a video recording system comprising a video recording device that records video distributed from an imaging device, and an information terminal that communicates with the video recording device via a communication path and monitors the status of the video recording device,
The video recording apparatus includes a storage unit having a plurality of recording areas, and a first software processing unit that controls the storage unit to record and manage an input video.
The information terminal communicates with the recording medium and the first software processing unit, acquires consumption capacity information within a predetermined period of the storage unit of the video recording apparatus, stores the information in the recording medium, and acquires A video recording system comprising a second software processing unit that outputs an alert when the consumed capacity information is abnormal.

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