JP2006311521A - Information processing apparatus and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus aiming at recording an accidentally occurring event that can record video data for a long time. <P>SOLUTION: A communication control section 41 of an information processing apparatus 30 acquires video data expressing a photographed video image by a camera 11 from a monitor apparatus 10. An analysis section 45 analyzes the video data acquired from the monitor apparatus 10 by the communication control section 41 and detects a change in the photographed video image. On the other hand, when the analysis section dose not detects the change in the video image video data wrights in buffer 49, a recording control section 43 acquires video data with a prescribed amount stored in a buffer temporally before the video data whose change is detected together with the video data from which the change is detected and writes the acquired data to a hard disk unit 33. Further, the recording control section 34 writes video data received by the communication control section for a prescribed time to the hard disk unit after the detection. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an information processing apparatus that records video data.

  Conventionally, as an information processing apparatus that records video data, an information processing apparatus that converts a video signal input from a camera that captures a monitoring target into image data and stores the image data in a memory is known. In addition, this type of information processing device analyzes the image data stored in the memory, detects that an object has entered the camera's field of view, and turns on a warning light when the object has entered. Is known (see, for example, Patent Document 1).

Other known recording media include rewritable non-volatile memory such as volatile memory and flash memory, magnetic recording type hard disk devices, etc., and the information processing device records video data in volatile memory. And those that record video data on a hard disk drive are known. In addition, information processing devices for recording sudden events, such as recording evidence when a crime occurs, are known to record video data on a hard disk device and store the video data for a long time. It has been.
JP2005-50382

  However, in the conventional apparatus, since video data is continuously stored in the hard disk device in order to record sudden events, the user is stored in the hard disk device in order to selectively check only sudden events. It was necessary to find the video that needed confirmation from the video data. That is, conventionally, there has been a problem that a great deal of labor is required to find a necessary image.

  Another problem with the conventional apparatus is that video data cannot be recorded for a sufficiently long time due to storage capacity restrictions because video data is always recorded on the hard disk device in order to record sudden events. It was. In addition, when a large-capacity hard disk device is used, the recording time can be lengthened. However, in this case, there is a problem that the manufacturing cost of the product is high.

  The present invention has been made in view of these problems, and it is a first object of the present invention to provide a technique for recording video data so that a user can easily find a captured video of a sudden event. To do. It is a second object of the present invention to provide a technique that can improve the period during which video data can be recorded at low cost.

The information processing apparatus according to claim 1, which has been made to achieve the object,
Volatile storage means;
Non-volatile storage means capable of rewriting data;
Data acquisition means for acquiring video data representing video captured by the imaging device from the imaging device;
Storage means for temporarily storing the video data acquired by the data acquisition means in the volatile storage means;
Detection means for detecting a change in the video imaged by the imaging device based on the video data acquired by the data acquisition unit;
When the change in the video is detected by the detection means, the video data representing the video before the change stored in the volatile storage means is acquired from the volatile storage means, and the video data is A document for storing in the nonvolatile storage means, the video data representing the video captured by the data acquisition means and captured within the predetermined period after the change, in the nonvolatile storage means. Including
It is characterized by providing.

An information processing apparatus according to claim 2 is:
Non-volatile storage means capable of rewriting data;
Data acquisition means for acquiring video data representing video captured by the imaging device from the imaging device;
Detection means for detecting a change in the video imaged by the imaging device based on the video data acquired by the data acquisition unit;
Based on the detection result of the detection means, the video data acquired by the data acquisition means and representing video taken within a predetermined period from the time of change of the video is a predetermined first bit rate. And storing the video data representing the video captured by the data acquisition unit and out of the predetermined period, which is lower than the first bit rate. Writing means for storing in the non-volatile storage means at a bit rate of
It is characterized by providing.

An information processing apparatus according to claim 3 is:
Area setting means for setting a detection area of the change in the video in a frame constituting the video data based on an instruction from the user input from an operation means operable by the user;
With
The detection means detects a change in the video in a detection area set by the area setting means.

  A program according to claim 4 is a program for causing a computer to realize the functions as the data acquisition unit, the storage unit, the detection unit, and the writing unit in the information processing apparatus according to claim 1. It is.

  In addition, the program according to claim 5 is a program for causing a computer to realize the functions as the data acquisition unit, the detection unit, and the writing unit in the information processing apparatus according to claim 2.

  According to the information processing apparatus of the first aspect, the video data acquired from the photographing apparatus is temporarily stored, and when the video indicated by the video data changes, a predetermined amount of video data before and after the change is selectively nonvolatile. Since it is stored in the sex storage means, the user can easily find out the video of the sudden event when checking the video later. That is, in the conventional device, since the video data is continuously recorded, when confirming the video of the sudden event, it is necessary to find the corresponding video by fast-forwarding the video. In the information processing apparatus according to the present invention, since the video of the event that occurs suddenly can be selectively stored in the nonvolatile storage means, the above-described work of the user can be eased.

  Further, in the information processing apparatus of the present invention, video data representing a sudden event can be selectively stored in the nonvolatile storage means, so that the storage capacity of the nonvolatile storage means is not increased. The video recording time (the period during which video data can be recorded) can be made longer than in the past. Therefore, according to the present invention, a product capable of recording video data for a long time can be manufactured at a low cost with respect to an information processing apparatus for recording a sudden event.

  In the information processing apparatus according to claim 2, the video data is continuously recorded. However, the video data other than the predetermined period after the video change is obtained by adjusting the bit rate (for example, adjusting the number of frames per second). Therefore, the video data can be recorded for a long time compared to the conventional case without increasing the storage capacity of the storage means. Therefore, according to the present invention, a product capable of recording video data for a long time can be manufactured at a low cost with respect to an information processing apparatus for recording a sudden event.

  The detection means may be configured to detect a change in the image with the entire frame (the region captured by the imaging device) as a detection target, but when only a part of the region is detected. Convenient. According to the information processing apparatus of the third aspect, since only a partial area of the frame can be set as the detection area, a slight change in the image such as a swing due to the wind is detected by the detection means. Can be relaxed. Therefore, according to the present invention, it is possible to prevent a period in which video data can be recorded from being shortened by recording insignificant video data in the nonvolatile storage means.

  In addition, the program according to claim 4 can cause a computer to realize the function as the information processing apparatus according to claim 1, and according to the program according to claim 5, The function as an information processing apparatus can be realized. The program may be recorded on a recording medium such as a flexible disk, a CD-ROM, or a DVD and provided to the user.

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory diagram showing the configuration of a monitoring system 1 to which the present invention is applied.
The monitoring system 1 according to the present embodiment includes a monitoring device 10 that captures an image of a monitoring target, a video recording / output information processing device 30, and a wireless communication device 50 that is connected to the information processing device 30 via a communication cable LN. And consist of

  The monitoring device 10 is connected to a camera 11 that captures an object to be monitored, a digital conversion unit 13 that converts an analog video signal input from the camera 11 into digital video data, a communication control unit 15, and an information processing device 30. A wireless communication circuit unit 17 capable of wireless communication with the wireless communication device 50.

  The communication control unit 15 generates transmission data storing the digital video data input from the digital conversion unit 13 and the transmission destination information describing the address of the information processing device 30, and generates the transmission data as a wireless communication circuit unit 17 On the other hand, the radio communication circuit unit 17 outputs a radio signal on which transmission data input from the communication control unit 15 is superimposed, from the antenna. Note that a well-known IEEE 802.11x standard can be adopted as a wireless communication method, and an Internet protocol can be adopted as a communication protocol.

  Further, the digital conversion unit 13 is configured to encode an input signal from the camera 11 by a well-known MPEG (Moving Picture Expert Group) system, and generate and output digital video data having a predetermined frame size (resolution). Yes. As is well known, in the MPEG system, frames as still image data are arranged in time series to express a moving image and generate digital video data.

  The wireless communication device 50 is configured to be able to wirelessly communicate with the monitoring device 10. In addition, the information processing device 30 is connected to the wireless communication device 50 and can communicate with the wireless communication device 50, a hard disk device 33, a display unit 35 including a liquid crystal display, a user-operable keyboard, An input unit 37 including a pointing device and a control unit 40 including a CPU, a ROM, a RAM, and the like (not shown) are provided.

  The control unit 40 executes the program stored in the ROM by the CPU, thereby functioning as the communication control unit 41, the recording control unit 43, the analysis unit 45, the setting unit 47, and the reproduction processing unit 48. Realize. The function as the buffer 49 is realized by the memory control program and the RAM.

  The communication control unit 41 realizes exchange of digital video data between the information processing device 30 and the monitoring device 10, and data received from an external device via the wireless communication device 50 and the interface 31 is transmitted to the monitoring device. In the case where the digital video data transmitted from 10 is included, the digital video data is extracted from the received data and input to the recording control unit 43.

  On the other hand, the reproduction processing unit 48 performs reproduction processing on the digital video data stored in the hard disk device 33 by the operation of the recording control unit 43 (details will be described later) according to a reproduction instruction from the input unit 37, and converts the digital video data into the digital video data. The video based on this is output to the display unit 35.

  In addition, the analysis unit 45 analyzes the digital video data input from the recording control unit 43 by a known method, and detects the motion (motion) of the object displayed in the video represented by the digital video data. is there. Only when the motion of the object can be confirmed in a predetermined region (detection region) in the frame, the analysis unit 45 provides a “motion detection notification” indicating that a motion has been detected as an analysis result. In other cases, a “motion non-detection notification” indicating that a motion could not be detected is input to the recording control unit 43.

  In the information processing apparatus 30, when a setting screen display instruction is input from the user through the input unit 37, the setting unit 47 executes the detection position setting process illustrated in FIG. 2, and according to the instruction from the user, The setting information stored in the hard disk device 33 is updated. FIG. 2 is a flowchart showing the detection position setting process realized by the setting unit 47, and FIG. 3 is an explanatory diagram showing the configuration of the detection position setting screen displayed on the display unit 35.

  When starting the detection position setting process, the setting unit 47 reads the current setting information from the hard disk device 33 (S110), and displays a detection position setting screen reflecting the setting information on the display unit 35 (S120). .

  The setting information consists of a matrix with N rows and N columns. This setting information describes the value of the element corresponding to each section when the frame is divided into N squares in the vertical and horizontal directions. In this setting information, an element corresponding to a motion detection area is indicated by a value “1”, and an element corresponding to a non-detection area is indicated by a value “0”.

  Further, the detection position setting screen is a GUI configuration setting screen showing frames that are divided into N vertical and horizontal grids as shown in FIG. The detection position setting screen includes a completion button for inputting the completion of setting from the input unit 37. Further, on this detection position setting screen, a section which is a detection area is displayed in a filled expression.

  That is, in S120, the setting unit 47 displays the detection position setting screen reflecting the setting information by filling each section in the detection position setting screen corresponding to the element of the value “1” based on the read setting information. Displayed on the unit 35.

  When the processing in S120 is completed, the setting unit 47 waits until the operation information is input from the input unit 37 by the user operating the input unit 37. When the operation information is input, the setting unit 47 performs the operation. Based on the information, it is determined whether or not the user has pressed the completion button (S130). If it is determined that the pressing operation has not been performed (No in S130), the process proceeds to S140, and the detected position setting screen being displayed is updated according to the input operation information. That is, when the user selects and operates a section that is a detection area, the filling expression of the selected section is stopped, the section is indicated as a non-detection area, and the user selects and operates a section that is a non-detection area. In such a case, the section is filled and expressed, and the section selected by the user is indicated as a detection area. When the detection position setting screen is updated in this way, the setting unit 47 proceeds to S130 again.

  If it is determined that the user has pressed the completion button (Yes in S130), the setting unit 47 updates the setting information in the hard disk device 33 according to the display content of the current detection position setting screen (S150). . Specifically, the element corresponding to the section expressed by filling is changed to the value “1”, and the element corresponding to the section not expressed by filling is updated to the value “0”. Then, when the process in S150 is finished, the display of the detection position setting screen is finished (S160), and the detection position setting process is finished.

  Next, the analysis unit 45 will be described. FIG. 4 is a flowchart showing an analysis process realized by the analysis unit 45. When the digital video data is input from the recording control unit 43, the analysis unit 45 executes an analysis process for the digital video data.

  When analysis processing is started, the analysis unit 45 analyzes input data (digital video data) from the recording control unit 43 (S210), and the digital video data is digital video data representing a video obtained by photographing the motion of the object. Whether or not (S220). Specifically, each frame constituting the digital video data is compared with a frame representing the immediately preceding video, and a difference (difference between digital values constituting the pixel) is extracted. In this way, it is determined whether or not the photographed object is moving.

  Then, when it is determined that the input data from the recording control unit 43 is not digital video data representing a video obtained by photographing the motion of the object (No in S220), the analysis result indicates “motion non-detection” indicating that the motion could not be detected. “Notification” is input to the recording control unit 43 (S240). Thereafter, the analysis process ends.

  On the other hand, if it is determined that the input data from the recording control unit 43 is digital video data representing an image obtained by photographing the motion of the object (Yes in S220), the analysis unit 45 can confirm the motion of the object. It is determined whether or not the position is within the detection area indicated by the setting information stored in the hard disk device 33 (S230). If it is determined that the position is not within the detection area (No in S230), “motion non-detection notification” is displayed. The data is input to the recording control unit 43 (S240). On the other hand, if it is determined that the position where the movement of the object can be confirmed is within the detection region (Yes in S230), the process proceeds to S250, and “motion detection notification” indicating that the motion is detected as an analysis result. Is input to the recording control unit 43. Thereafter, the analysis process ends.

  Next, the operation of the recording control unit 43 will be described. FIG. 5 is a flowchart showing a recording control process realized by the recording control unit 43. When the received digital video data is input from the communication control unit 41, the recording control unit 43 executes the recording control process shown in FIG.

  When the recording control process is started, the recording control unit 43 inputs the digital video data input from the communication control unit 41 (digital video data received by the communication control unit 41) to the analysis unit 45, and as described above. The analysis unit 45 is made to analyze the digital video data. Then, it waits until a response is obtained from the analysis part 45 (S310).

  When the response is obtained, the recording control unit 43 determines whether the response from the analysis unit 45 is “motion detection notification” or “motion non-detection notification” (S320). If it is determined that the response is “motion non-detection notification” (No in S320), the digital video data input from the communication control unit 41 is written in the buffer 49 (S330). Thereafter, the recording control process ends. The buffer 49 is configured as a ring buffer capable of storing a predetermined amount of digital video data (digital video data corresponding to a video of several seconds to several minutes).

  On the other hand, if the recording control unit 43 determines that the response from the analysis unit 45 is “motion detection notification” (Yes in S320), the recording control unit 43 proceeds to S340 and extracts all of the digital video data stored in the buffer 49. Then, the digital video data representing the video of the motion of the object input to the analysis unit 45 is added to the extracted digital video data. Then, the added digital video data is written to the hard disk device 33 (S350).

  When the digital video data is written to the hard disk device 33 in the previous recording control process, the recording control unit 43 adds the current writing target to the end of the digital video data already recorded on the hard disk device 33. The digital video data to be written is written in the hard disk device 33 so that the digital video data is connected. On the other hand, if digital video data is not written to the hard disk device 33 in the previous recording control process, the digital video data to be written this time is written to the hard disk device 33 as a new data file.

  Further, when the processing in S350 is completed in this way, the recording control unit 43 sequentially receives the digital video data continuously input from the communication control unit 41 for a predetermined time (several seconds to several minutes) in S350. The digital video data written in the hard disk device 33 is connected to the hard disk device 33 so as to be connected (S360). Thereafter, the recording control process ends.

  Although the monitoring system 1 has been described above, in the present embodiment, the communication control unit 41 acquires digital video data representing video captured by the camera 11 from the monitoring device 10 and inputs this to the recording control unit 43. To do. Further, the analysis unit 45 analyzes the digital video data received from the monitoring device 10 by the communication control unit 41 and detects a change in the video taken by the camera 11. Specifically, when a video showing the motion of an object is confirmed within a preset detection area in a frame constituting the digital video data, a change in the video is detected, and a “motion detection notification” is sent to that effect. To the recording control unit 43.

  On the other hand, when the motion of the object is not detected in the detection area (No in S320), the recording control unit 43 stores the digital video data received by the communication control unit 41 in the buffer 49 as a volatile storage unit. Temporary storage is performed (S330).

  Further, when the motion of the object is detected within the detection area by the analysis unit 45 (Yes in S320), the recording control unit 43 is digital video data received by the communication control unit 41 in the past, and is stored in the buffer 49. The stored predetermined amount of digital video data is taken out from the buffer 49, and is stored in the hard disk device 33 as a nonvolatile storage means together with the digital video data in which the motion of the object is detected (S350). In addition, the digital video data received by the communication control unit 41 is stored in the hard disk device 33 for a predetermined time thereafter (S360).

  Thus, in the information processing apparatus 30 of the present embodiment, the digital video data acquired from the monitoring apparatus 10 is temporarily stored in the buffer 49, and a predetermined amount of video before and after the video indicated by the digital video data has changed. Since data is selectively written to the hard disk device 33, only digital video data representing sudden events necessary for the user can be selectively recorded on the hard disk device 33. Therefore, according to the present embodiment, digital video data can be efficiently stored in the hard disk device 33.

  For example, if the monitoring device 10 is installed for the purpose of monitoring an intruder from the outside, digital video data representing the image of the intruder from the outside taken by the monitoring device 10 is selectively stored in the hard disk device 33. Can be recorded.

  Therefore, according to the present embodiment, even if the storage capacity of the hard disk device 33 is not increased, the period during which digital video data can be recorded can be lengthened as compared with the conventional case, and sudden events are recorded. With respect to the target information processing apparatus, a product capable of recording digital video data for a long time can be manufactured at low cost.

  Further, in the information processing apparatus 30 of this embodiment, digital video data important for the user is selectively stored, so that the user can easily find the video that needs to be confirmed when the video is confirmed later. . In other words, since the conventional device continuously records video data, it was necessary to find the corresponding video by fast-forwarding the video, etc. when confirming the video of sudden events. According to the invention, such work can be eased.

  Further, in the information processing apparatus 30 according to the present embodiment, the setting unit 47 updates the setting information based on an instruction from the user input from the input unit 37 to detect a video change in a frame constituting the digital video data. Since the area is set (detection position setting process), it is possible to mitigate the detection of a change in the video that should not be detected (a slight change in the video).

  Therefore, according to the present invention, it is possible to prevent digital video data unnecessary for the user from being stored in the hard disk device 33 due to a slight change in video and shortening the period in which the digital video data can be recorded. it can. Also, since unnecessary digital video data is not stored, the user can easily find a video that needs to be confirmed when the video is confirmed later.

In this embodiment, when the “motion non-detection notification” is received from the analysis unit 45, the corresponding digital video data is stored in the buffer 49, and if not necessary, the digital video data is stored in the hard disk device 33. Although not stored, the corresponding digital video data may be stored in the hard disk device 33 even when the “motion non-detection notification” is received from the analysis unit 45. However, in this case, in order to reduce the storage amount of the corresponding digital video data, it is preferable to store the digital video data after performing the data thinning process (modified example).
[Modification]
FIG. 6 is a flowchart illustrating a recording control process executed by the recording control unit 43 according to the modification. The monitoring system of the modified example has a slightly different content of the recording control process from the above embodiment, and the other configuration is the same as that of the monitoring system 1. Therefore, the contents of the recording control process of the modified example will be described below. The description will be made with reference to FIG.

  When the recording control process shown in FIG. 6 is started, the recording control unit 43 inputs the digital video data input from the communication control unit 41 (digital video data received by the communication control unit 41) to the analysis unit 45, The analysis unit 45 is made to analyze the digital video data. Then, it waits until a response is obtained from the analysis part 45 (S410).

  When the response is obtained, the recording control unit 43 determines whether the response from the analysis unit 45 is “motion detection notification” or “motion non-detection notification” (S420). If it is determined that the response is “motion detection notification” (Yes in S420), the process proceeds to S430, and the digital video data representing the video of the motion of the object input to the analysis unit 45 is stored in the hard disk device 33. Write.

  In the previous recording control process, if it is determined Yes in S420, the digital video data to be written this time is connected to the end of the previous digital video data recorded in the hard disk device 33. The digital video data to be written is written in the hard disk device 33 (S430). On the other hand, if it is determined No in S420 in the previous recording control process, the digital video data to be written this time is written in the hard disk device 33 as a new data file (S430).

  When the processing in S430 is completed in this way, the recording control unit 43 sequentially receives the digital video data continuously input from the communication control unit 41 for a predetermined time (several seconds to several minutes) in S430. The digital video data written in the device 33 is connected to the hard disk device 33 so as to be connected (S440). Thereafter, the recording control process ends.

  On the other hand, if it is determined that the response from the analysis unit 45 is “motion non-detection notification” (No in S420), the recording control unit 43 proceeds to S450, and the digital video data input to the analysis unit 45 is received. , Thinning out. Specifically, digital video data is generated by removing a predetermined number of frames from the digital video data and reducing the number of frames per second. Then, the generated digital video data is written to the hard disk device 33 (S460).

  If it is determined No in S420 in the previous recording control process, the digital video data to be written this time is connected to the end of the previous digital video data recorded in the hard disk device 33. The digital video data to be written is written to the hard disk device 33 (S460). On the other hand, if it is determined Yes in S420 in the previous recording control process, the digital video data to be written this time is written in the hard disk device 33 as a new data file (S460). Thereafter, the recording control unit 43 ends the recording control process.

  Although the modification has been described above, in the modification, the digital video data for a predetermined time starting from the digital video data in which the motion of the object is detected in the detection area remains as received data (the bit rate is changed). The digital video data is stored in the hard disk device 33, and the other digital video data is subjected to a thinning process to reduce the bit rate by a predetermined amount from the received data. save.

  Therefore, according to this modification, it is possible to record video data for a long time as compared with the prior art without increasing the storage capacity of the hard disk device 33. In addition, it is possible to record video data in which the motion of the object is not detected while obtaining such an effect.

  The data acquisition unit of the present invention corresponds to the communication control unit 41, and the detection unit corresponds to the analysis unit 45. The storage means is realized by the processing of S330 executed by the recording control unit 43, and the writing means is the processing of S340 to S360 executed by the recording control unit 43, or S410 executed by the recording control unit 43. This is realized by the processing of S460. The area setting means corresponds to the setting unit 47, the first bit rate corresponds to the bit rate of the received data, and the second bit rate corresponds to the bit rate after the thinning process.

Further, the information processing apparatus and the program of the present invention are not limited to the above-described embodiments, and can take various forms.
For example, in the above embodiment, the entire region of the frame including the detection region is analyzed, and when the position where the motion of the object can be confirmed is the detection region, the recording control unit 43 is notified that the motion has been detected. However, the information processing apparatus 30 may be configured to analyze only the video in the detection area without analyzing the entire frame area.

  In addition, in the above embodiment, after the motion detection, the digital video data for a predetermined time is recorded in the hard disk device 33 in S360, but the information processing apparatus 30 is configured so as not to execute the process of S360. May be. Even when the process of S360 is not executed, when the motion is continuously detected, the process of S350 is repeatedly executed, so that the digital video data during that time can be recorded on the hard disk device 33. . However, when the information processing apparatus 30 is configured in this way, once the motion is no longer detected, the digital video data is not immediately recorded on the hard disk device 33, which may be inconvenient in some cases. .

  In the above-described embodiment, the information processing apparatus 30 that detects the movement of the object as the change in the image has been described. However, the information processing apparatus 30 may change the color other than the movement of the object as the change in the image, for example. It may be configured to detect.

  In addition, the information processing apparatus 30 may be configured to switch and execute the recording control process illustrated in FIG. 5 and the recording control process illustrated in FIG. 6 in accordance with an instruction input from the user.

It is explanatory drawing showing the structure of the monitoring system 1 to which this invention was applied. 7 is a flowchart showing detection position setting processing realized by a setting unit 47. 6 is an explanatory diagram illustrating a configuration of a detection position setting screen displayed on a display unit. FIG. 5 is a flowchart showing an analysis process realized by an analysis unit 45. 4 is a flowchart showing a recording control process realized by a recording control unit 43. It is a flowchart showing the recording control process of a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Monitoring system, 10 ... Monitoring apparatus, 11 ... Camera, 13 ... Digital conversion part, 15 ... Communication control part, 17 ... Wireless communication circuit part, 30 ... Information processing apparatus, 31 ... Interface, 33 ... Hard disk apparatus, 35 ... Display unit 37 ... Input unit 40 ... Control unit 41 ... Communication control unit 43 ... Recording control unit 45 ... Analysis unit 47 ... Setting unit 48 ... Reproduction processing unit 49 ... Buffer 50 ... Wireless communication device , LN ... Communication cable

Claims (5)

Volatile storage means;
Non-volatile storage means capable of rewriting data;
Data acquisition means for acquiring video data representing video captured by the imaging device from the imaging device;
Storage means for temporarily storing the video data acquired by the data acquisition means in the volatile storage means;
Detection means for detecting a change in the video imaged by the imaging device based on the video data acquired by the data acquisition unit;
When the change in the video is detected by the detection means, the video data representing the video before the change stored in the volatile storage means is acquired from the volatile storage means, and the video data is A document for storing in the nonvolatile storage means, the video data representing the video captured by the data acquisition means and captured within the predetermined period after the change, in the nonvolatile storage means. Including
An information processing apparatus comprising: Non-volatile storage means capable of rewriting data;
Data acquisition means for acquiring video data representing video captured by the imaging device from the imaging device;
Detection means for detecting a change in the video imaged by the imaging device based on the video data acquired by the data acquisition unit;
Based on the detection result of the detection means, the video data acquired by the data acquisition means and representing video taken within a predetermined period from the time of change of the video is a predetermined first bit rate. And storing the video data representing the video captured by the data acquisition unit and out of the predetermined period, which is lower than the first bit rate. Writing means for storing in the non-volatile storage means at a bit rate of
An information processing apparatus comprising: Area setting means for setting a detection area of the change in the video in a frame constituting the video data based on an instruction from the user input from an operation means operable by the user;
With
The information processing apparatus according to claim 1, wherein the detection unit detects a change in the video in a detection region set by the region setting unit.   The program for making a computer implement | achieve the function as the said data acquisition means in the information processing apparatus of Claim 1, the said storage means, the said detection means, and the said writing means. The program for making a computer implement | achieve the function as the said data acquisition means in the information processing apparatus of Claim 2, the said detection means, and the said writing means.