JP2015139064A - Imaging apparatus, imaging system, control method of imaging apparatus, control method of imaging system, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To also flexibly deal with a newly appearing encoding method.SOLUTION: An imaging apparatus includes: a storage part 1002 for storing distribution setting information that may include H.264 or H.265; a compression coding part 1004 for coding a captured image outputted from an imaging part 1003 on the basis of the encoding method included in the distribution setting information stored in the storage part 1002; a communication part 1005 for receiving from a client device 2000 a SetVEC command for including H.264 in the distribution setting information stored in the storage part 1002 or a SetVEC2 command for including H.265 in the distribution setting information; and a control part 1001 for including an encoding method to which the command received by the communication part 1005 corresponds, in the distribution setting information stored in the storage part 1002 in the case where the encoding method to which the command received by the communication part 1005 corresponds is different from the encoding method included in the distribution setting information stored in the storage part 1002.

Description

  The present invention relates to an imaging apparatus, an imaging system, an imaging apparatus control method, an imaging system control method, and a program. In particular, the present invention relates to a technique for setting an encoding method for image data output from an imaging apparatus.

  2. Description of the Related Art Conventionally, an imaging apparatus that encodes captured image data and outputs the encoded image data to the outside via a network is known (Patent Document 1). As encoding methods of such image data, JPEG (JPEG), MPEG4 (MPPEG4) for still images, and H.264 for moving images. H.264 (etched dot 264) and H.264. 265 (etched dots 265).

  For example, the network camera device has JPEG and H.264. H.264 is implemented, and image data is encoded by an encoding method designated by the client apparatus, and the encoded image data is streamed and distributed to the client apparatus via the network.

  A standard protocol for sharing a communication interface between a network camera device and a client device that communicates with the network camera device via a network is known. As an example of such a standard protocol, a common standard established by ONVIF (Open Network Video Interface Forum) is known. (Non-Patent Document 1)

JP 2012-227602 A

ONVIF Specification (http://www.ovnif.org/specs/DocMap.html)

  In the future, due to the growing needs for higher pixels, higher image quality, and higher compression, It is conceivable that a new version of a network camera that implements an encoding method such as H.265 will appear.

  However, the encoding methods defined by standard protocols such as ONVIF are JPEG for still images and MPEG4 and H.264 for moving images. H.264, and standard protocols such as ONVIF use JPEG2000 and H.264. 265 etc. were not assumed.

  The present invention has been made in view of the above points, and an object thereof is to be able to flexibly cope with a newly appearing encoding method.

  In order to achieve the above object, an imaging apparatus according to the present invention is an imaging apparatus that communicates with an external device via a network, the imaging means for imaging a subject, and the first encoding method or the first encoding. A storage control unit that stores in the storage unit distribution setting information that can include a second encoding method different from the method, and a distribution setting in which the captured image output from the imaging unit is stored in the storage unit An encoding means for encoding based on the encoding method included in the information, and a first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit Receiving means for receiving a second encoding method setting command for including the second encoding method in the distribution setting information from the external device via a network, and a code received by the receiving means Conversion The encoding received by the receiving means in the distribution setting information stored in the storage unit when the encoding method corresponding to the setting command is different from the encoding method included in the distribution setting information stored in the storage unit And control means for including an encoding method corresponding to the method setting command.

  According to the present invention, it is possible to flexibly cope with a newly appearing encoding method.

1 is a system configuration diagram for describing a configuration of an example of an imaging system according to Embodiment 1. FIG. 1 is a block diagram illustrating an internal configuration of a surveillance camera that constitutes an imaging system according to Embodiment 1. FIG. 1 is a block diagram illustrating an internal configuration of a client device that constitutes an imaging system according to Embodiment 1. FIG. 1 is a block diagram illustrating an internal configuration of a client device that constitutes an imaging system according to Embodiment 1. FIG. FIG. 3 is a parameter configuration diagram held by the monitoring camera according to the first embodiment. FIG. 6 is a command sequence diagram between the monitoring camera and the client device according to the first embodiment. FIG. 6 is a command sequence diagram between the monitoring camera and the client device according to the first embodiment. 6 is a flowchart for explaining a GetVideoEncoderConfigurationOptions transmission process of the monitoring camera according to the first embodiment. 6 is a flowchart for explaining SetVideoEncoderConfiguration reception processing of the monitoring camera according to the first embodiment. 6 is an example of a VideoEncoder setting window according to the first embodiment. 6 is an example of a VideoEncoder setting window according to the first embodiment. 6 is an example of a VideoEncoder setting window according to the first embodiment. 6 is an example of a VideoEncoder setting window according to the first embodiment. 12 is a flowchart for explaining Set Video Encoder Configuration reception processing of a monitoring camera according to a second embodiment. 12 is a flowchart for explaining SetVideoEncoderConfiguration2 reception processing of a monitoring camera according to a third embodiment. FIG. 10 is an example of a VideoEncoder setting window according to Embodiment 4. FIG. 10 is a flowchart for explaining a Play command reception process of a monitoring camera according to a fourth embodiment. FIG. 10 is a flowchart for explaining SetVideoEncoderConfiguration reception processing of a monitoring camera according to a fifth embodiment. It is a parameter block diagram which the monitoring camera which concerns on Example 5 hold | maintains. It is a parameter block diagram which the monitoring camera which concerns on Example 5 hold | maintains. FIG. 20 is a flowchart for explaining SetVideoEncoderConfiguration2 reception processing of a monitoring camera according to a sixth embodiment. FIG. 20 is a flowchart for explaining SetVideoEncoderConfiguration reception processing of a monitoring camera according to a seventh embodiment. It is a figure which shows an example of the definition of VideoEncoderConfiguration2 for setting the 2nd encoding system based on Example 1. FIG.

  Below, this invention is demonstrated in detail based on the suitable Example. The configurations shown in the following embodiments are merely examples, and the present invention is not limited to the illustrated configurations.

Example 1
FIG. 1 is a system configuration diagram of an imaging system including a monitoring camera 1000 corresponding to a transmission apparatus in the present embodiment. Reference numerals 2000 and 2010 denote client apparatuses corresponding to the receiving apparatus in this embodiment. The monitoring camera 1000 and the client apparatuses 2000 and 2010 are connected to each other via the IP network 1500 (in a state where they can communicate with each other).

  The imaging system in this embodiment is an example of a transmission / reception system. In addition, the monitoring camera 1000 in the present embodiment is an imaging device that captures moving images, and more specifically, is a network camera used for monitoring.

  The IP network 1500 is assumed to be composed of a plurality of routers, switches, cables, and the like that satisfy a communication standard such as Ethernet (registered trademark). However, in this embodiment, any communication standard, scale, and configuration may be used as long as communication between the monitoring camera 1000 and the client apparatuses 2000 and 2010 can be performed.

  For example, the IP network 1500 may be configured by the Internet, a wired LAN (Local Area Network), a wireless LAN (Wireless LAN), a WAN (Wide Area Network), or the like. Note that the monitoring camera 1000 in this embodiment may be compatible with, for example, PoE (Power Over Ethernet (registered trademark)), and may be supplied with power via a LAN cable.

  The client apparatuses 2000 and 2010 transmit various commands such as imaging parameter change, pan head drive, and video streaming start described later to the monitoring camera 1000. The monitoring camera 1000 transmits responses to these commands and video streaming to the client devices 2000 and 2010.

  Although FIG. 1 shows an example in which one monitoring camera 1000 and two client apparatuses 2000 and 2010 are connected to the IP network 1500, the present invention is not limited to this. For example, two or more surveillance cameras may be provided, and three or more client devices may be provided.

  Next, FIG. 2 is a block diagram illustrating an internal configuration of the monitoring camera 1000 in the present embodiment. In FIG. 2, reference numeral 1001 denotes a control unit that controls the entire monitoring camera 1000. The control unit 1001 is configured by, for example, a CPU (Central Processing Unit).

  Reference numeral 1002 denotes a storage unit. The storage unit 1002 is mainly used as a storage region for various data such as a program storage region executed by the control unit 1001, a work region during program execution, and a storage region for captured images generated by the imaging unit 1003 described later.

  Reference numeral 1003 denotes an imaging unit. The imaging unit 1003 converts an analog signal acquired by capturing an image of a subject formed by the imaging optical system of the monitoring camera 1000 into digital data, and outputs the digital data to the storage unit 1002 as a captured image. Reference numeral 1004 denotes a compression encoding unit. Note that the imaging unit 1003 in this embodiment includes an imaging sensor (imaging device) such as a CCD or a CMOS.

  The compression encoding unit 1004 generates image data by performing compression encoding processing on the captured image output from the imaging unit 1003 based on the encoding method specified by the client device 2000 or 2010. The processed image data is output to the storage unit 1002. At this time, the compression encoding unit 1004 generates a VIDEO transmission trigger to the control unit 1001 and notifies that the image data that can be distributed is output to the storage unit 1002.

  Here, the compression encoding unit 1004 of the monitoring camera 1000 in this embodiment includes JPEG, H.264, and the like. H.264, and H.H. Assume that three types of encoding schemes H.265 are implemented. Therefore, the surveillance camera 1000 in this embodiment is JPEG, H.264, etc. This corresponds to a SetVideoEncoderConfiguration command (hereinafter also referred to as a SetVEC command) corresponding to an existing encoding method setting such as H.264.

  Furthermore, the surveillance camera 1000 in this embodiment is JPEG, MPEG, H.264. H.264 other than H.264 It also supports the SetVideoEncoderConfiguration2 command that also supports encoding schemes such as H.265. That is, this SetVideoEncoderConfiguration2 command (SetVEC2 command) is H.264. H.265, JPEG, MPEG, H.264 H.264 is also supported.

  Reference numeral 1005 denotes a communication unit. The communication unit 1005 is used when receiving each control command from an external device, and when transmitting a stream including a response to each control command and image data to the external device. Note that the client apparatuses 2000 and 2010 in this embodiment are examples of external devices.

  Reference numeral 1006 denotes an imaging control unit. The imaging control unit 1006 is used to control the tilt mechanism, the pan mechanism, and the zoom mechanism according to the pan angle, tilt angle, and zoom magnification values input by the control unit 1001. Further, the imaging control unit 1006 periodically provides the current pan angle value, tilt angle value, and zoom magnification value as PTZ Position information to the control unit 1001 by setting a PTZ Position transmission flag.

  Further, the imaging control unit 1006 provides the current pan, tilt, and zoom mechanism (not shown) operating status as PTZ Status information to the control unit 1001 by setting a PTZStatus transmission flag.

  In this embodiment, each of the compression encoding unit 1004 and the imaging control unit 1006 is configured by a sub CPU, for example. In this embodiment, each of the pan mechanism, the tilt mechanism, and the zoom mechanism includes a stepping motor, a gear, and the like. Each of the pan mechanism, the tilt mechanism, and the zoom mechanism is an example of a changing unit that changes the position of the imaging unit 1003.

  Next, FIG. 3 is a block diagram illustrating an internal configuration of the client apparatus 2000 in the present embodiment. In FIG. 3, reference numeral 2001 denotes a control unit. The control unit 2001 is configured by a CPU, for example, and performs overall control of the client device 2000. Reference numeral 2002 denotes a storage unit. The storage unit 2002 is mainly used as a storage area for various data such as a program storage area executed by the control unit 2001 and a work area during program execution.

  Reference numeral 2003 denotes a display unit. The display unit 2003 is configured with, for example, an LCD, an organic EL display, and the like, and displays various setting screens, a viewer of video received from the monitoring camera 1000, various messages, and the like to the user of the client apparatus 2000. These various setting screens include a VideoEncoder setting window to be described later.

  Reference numeral 2004 denotes an input unit. The input unit 2004 includes, for example, a button, a cross key, a touch panel, a mouse, and the like, and notifies the control unit 2001 of the contents of the screen operation by the user. Reference numeral 2005 denotes a decoding unit. The decoding unit 2005 decodes the compressed and encoded image data received via the communication unit 2006 and expands the decoded image data in the storage unit 2002.

  In the decoding unit 2005 of the client device 2000 in this embodiment, JPEG and H.264 are used as image decoding methods. 264 is implemented. Therefore, the client apparatus 2000 in the present embodiment is configured to use JPEG and H.264. Only the SetVEC command corresponding to an existing encoding method such as H.264 is supported, and the SetVEC2 command is not supported.

  Similarly, the client apparatus 2000 according to the present exemplary embodiment has JPEG and H.264. Only the GetVideoEncoderConfiguration command corresponding to an existing encoding method such as H.264 is supported. That is, the client apparatus 2000 in the present embodiment does not support the GetVideoEncoderConfiguration2 command.

  Reference numeral 2006 denotes a communication unit. The communication unit 2006 is used when transmitting each control command to the monitoring camera 1000, and when receiving a response to each control command and a stream including image data from the monitoring camera 1000. In the present embodiment, the decoding unit 2005 is configured by, for example, a sub CPU.

  Next, FIG. 4 is a block diagram illustrating an internal configuration of the client apparatus 2010 in the present embodiment. Here, as shown in FIG. 4, the processing blocks of the client device 2010 are the same as those of the client device 2000 shown in FIG.

  That is, the control unit 2011 is the same as the control unit 2001, and the storage unit 2012 is the same as the storage unit 2002. The display unit 2013 is the same as the display unit 2003, and the input unit 2004 is the same as the input unit 2014. Further, the communication unit 2016 is the same as the communication unit 2006.

  In FIG. 4, reference numeral 2015 denotes a decoding unit. The decoding unit 2015 decodes the compressed and encoded image data received via the communication unit 2016 and develops the decoded image data in the storage unit 2012.

  In the present embodiment, the decoding unit 2015 uses JPEG, H.264 as an image decoding method. H.264, and H.H. 265 is implemented. Therefore, the client apparatus 2010 in this embodiment supports both the SetVEC command and the SetVEC2 command.

  Similarly, the client apparatus 2010 according to the present exemplary embodiment supports both the GetVideoEncoderConfiguration command and the GetVideoEncoderConfiguration2 command.

  The internal configuration of the monitoring camera 1000 and the client devices 2000 and 2010 has been described above with reference to FIGS. 1 to 4. However, the processing block shown in FIG. 2 is a preferred embodiment of the monitoring camera and client device according to the present invention. This is an explanation, not a limitation. For example, the monitoring camera and the client device can be variously modified and changed within the scope of the present invention, such as including a voice input unit or a voice output unit.

  Next, referring to FIG. 5, the names and contents of commands, parameters, etc. used in this embodiment will be described below. Here, FIG. 3 illustrates a structure of parameters held by the monitoring camera 1000 (the storage unit 1002) in the present embodiment.

  In FIG. 5, MediaProfile 3000, 3001, and 3002 are parameter sets for storing various setting items of the monitoring camera 1000 in association with each other. Each of the MediaProfiles 3000, 3001, and 3002 holds a ProfileToken that is an ID of the MediaProfile.

  Each of MediaProfile 3000, 3001, and 3002 holds links to various setting items. The various setting items include VideoSourceConfiguration 3011 and VideoEncoderConfiguration 3020 and 3021 described later. Further, the various setting items include VideoEncoderConfiguration2 3030, 3031, 3032 and the like.

  A video source 3010 in FIG. 5 is a set of parameters indicating the performance of one image capturing unit 1003 provided in the monitoring camera 1000. Here, the video source 3010 includes a parameter such as a video source token that is an ID of the video source 3010 and a resolution indicating the resolution of the captured image that can be output by the imaging unit 1003.

  Hereinafter, VideoSource may be abbreviated as VS. Further, VS in the present embodiment corresponds to image sensor setting information related to image sensor settings.

  The video source configuration 3011 includes a video source token of the VS 3010 and the like. Accordingly, it can be said that the VideoSourceConfiguration 3011 is a set of parameters for associating the VS 3010 included in the monitoring camera 1000 with the MediaProfile 3000, 3001, and 3002.

  Here, the VideoSourceConfiguration 3011 includes a Resolution indicating the resolution of the captured image that can be output by the imaging unit 1003. Further, the VideoSourceConfiguration 3011 includes Bounds for designating which part of the captured image output from the imaging unit 1003 is to be cut out and distributed to the client device 2000 or the like.

  Hereinafter, VideoSourceConfiguration is sometimes abbreviated as VSC.

  VideoEncoderConfigurations 3020 and 3021 are a collection of parameters for associating encoder settings related to compression encoding of image data with MediaProfile. VideoEncoderConfigurations 23030, 3031, and 3032 are also a set of parameters that associates encoder settings related to compression encoding of image data with MediaProfile.

  Hereinafter, VideoEncoderConfiguration may be abbreviated as VEC, and VideoEncoderConfiguration2 may be abbreviated as VEC2.

  The monitoring camera 1000 compresses and encodes the captured image output from the imaging unit 1003 based on the contents of the VS and VSC based on the VEC and VEC2, and the client devices 2000 and 2010 via the communication unit 1005 as image data. Deliver to.

  Here, the compression encoding unit 1004 encodes this captured image in accordance with parameters such as an encoding method (for example, JPEG, H.264 or H.265) set by VEC and VEC2, frame rate, or resolution. Thus, image data is generated.

  The VEC includes VECTToken, which is an ID of the VEC, Encoding that specifies the compression encoding method, and Resolution that specifies the resolution of the output image. Further, the VEC includes a quality for specifying the compression encoding quality, a framerate limit for specifying the maximum frame rate of the output image, and a bit rate limit for specifying the maximum bit rate.

  VEC2 includes VEC2Token that is an ID of VEC2, an encoding string (text information) that specifies a compression encoding method, and a Resolution that specifies the resolution of an output image. Furthermore, VEC2 also includes a Quality that specifies the compression encoding quality, a FramerateLimit that specifies the maximum frame rate of the output image, and a BitrateLimit that specifies the maximum bit rate.

  Here, among the encoding schemes implemented in the compression encoding unit 1004, JPEG and H.264. H.264 can hold the parameter in both VEC and VEC2 of the storage unit 1002. On the other hand, H. 265 is held only by VEC2.

  Next, FIG. 6 shows a typical command sequence for setting a MediaProfile necessary for distributing video between the monitoring camera 1000 and the client apparatus 2000. Here, the transaction refers to a pair of a command transmitted from the client apparatus 2000 to the monitoring camera 1000 and a response that the monitoring camera 1000 returns to the client apparatus 2000 in response thereto.

  4000 in FIG. 6 is a network device connection transaction. The client apparatus 2000 transmits a Probe command for connecting a network device to the IP network 1500 through unicast or multicast. The monitoring camera 1000 connected to the IP network 1500 returns a ProbeMatch response indicating that the command can be accepted to the client device 2000.

  Reference numeral 4001 denotes a subscribe transaction. With this transaction, the client apparatus 2000 can instruct the monitoring camera 1000 to perform event distribution.

  Reference numeral 4002 denotes a GetProfiles transaction. This transaction is a transaction for obtaining a MediaProfile corresponding to the distribution profile. Here, MediaProfile is a parameter set for storing various setting items of the monitoring camera 1000 in association with each other.

  These various setting items include ProfileToken, which is the ID of this MediaProfile, VSC, VEC, and an audio encoder. MediaProfile holds links to these various setting items.

  The client device 2000 transmits a GetProfiles command to the monitoring camera 1000. Upon receiving the GetProfiles command, the monitoring camera 1000 transmits a MediaProfile list to the client device 2000.

  As a result, the client device 2000 obtains a list of MediaProfiles currently usable in the monitoring camera 1000 together with ProfileToken corresponding to the distribution profile ID for identifying MediaProfile. Note that the client device 2000 identifies a MediaProfile, which is a distributable distribution profile setting existing in the monitoring camera 1000, using a distribution profile ID.

  Reference numeral 4003 denotes a transaction of the GetVideoSources command. With this command, the client apparatus 2000 acquires a list of VideoSources held by the monitoring camera 1000.

  Here, VideoSource is a set of parameters indicating the performance of one imaging unit 1003 provided in the monitoring camera 1000. The video source includes a video source token that is an ID of the video source and a resolution indicating the resolution of the captured image that can be output by the imaging unit 1003.

  The client apparatus 2000 transmits a GetVideoSources command to the monitoring camera 1000. Then, the monitoring camera 1000 that has received the GetVideoSources command returns a response to this command to the client device 2000.

  Reference numeral 4004 denotes a GetVideoSourceConfigurations transaction. This transaction is a transaction for obtaining a list of VideoSourceConfiguration held by the monitoring camera 1000.

  The client apparatus 2000 transmits a GetVideoSourceConfigurations command to the monitoring camera 1000. Then, the monitoring camera 1000 that has received the GetVideoSourceConfigurations command returns a list including the ID of the VSC held by the monitoring camera 1000 to the client device 2000.

  Reference numeral 4005 denotes a GetVideoEncoderConfigurations transaction. Through this transaction, the client apparatus 2000 acquires a list of VideoEncoderConfigurations held by the monitoring camera 1000.

  The client apparatus 2000 transmits a GetVideoEncoderConfigurations command to the monitoring camera 1000. The monitoring camera 1000 that has received this command returns a response to this command.

  In this response, as a list of image compression methods, JPEG, H.264. H.264 is included. On the other hand, this response includes H.264. 265 is not included. In addition, this response includes a list including IDs of encoding settings stored in the storage unit 1002.

  Reference numeral 4006 denotes a GetVideoEncoderConfigurationOptions transaction. With this transaction, the client apparatus 2000 can acquire the parameter options and setting value ranges that can be accepted by the monitoring camera 1000 for the VEC specified by the ID.

  The client apparatus 2000 transmits a GetVideoEncoderConfigurationOptions command to the monitoring camera 1000. The monitoring camera 1000 that has received this command returns a response to this command.

  With this transaction, the client apparatus 2000 acquires a list including the ID of the encoding setting stored in the storage unit 1002 from the monitoring camera 1000. This response includes JPEG and H.264. H.264 is included in the response. On the other hand, this response includes H.264. 265 is not included.

  Reference numeral 4007 denotes a CreateProfile transaction. This transaction is a transaction for requesting creation of a distribution profile. The client device 2000 transmits a CreateProfile command to the monitoring camera 1000. The monitoring camera 1000 that has received this command returns a response to this command.

  Through this transaction, the client apparatus 2000 can newly create a distribution profile in the monitoring camera 1000 and obtain the ID of the created distribution profile. The surveillance camera 1000 stores the newly created distribution profile.

  More specifically, the control unit 1001 newly creates a MediaProfile corresponding to the CreateProfile command received by the communication unit 1005, and executes storage control processing for storing the created MediaProfile in the storage unit 1002.

  After the command processing of this transaction, the monitoring camera 1000 transmits a MediaProfile change notification event to the client device 2000, thereby notifying the client device 2000 that some change has occurred in the MediaProfile.

  Reference numeral 4008 denotes an AddVideoSourceConfiguration transaction. This transaction is a transaction for requesting addition of VSC. The client device 2000 transmits an AddVideoSourceConfiguration command to the monitoring camera 1000. Upon receiving this command, the monitoring camera 1000 returns a response to this command to the client device 2000.

  In this transaction, the client apparatus 2000 designates the distribution profile ID acquired in 4007 and the VSC ID acquired in 4004. Accordingly, the client apparatus 2000 can associate a desired VSC corresponding to the specified VSC ID with the MediaProfile corresponding to the specified distribution profile ID.

  On the other hand, the monitoring camera 1000 stores a MediaProfile corresponding to the distribution profile ID specified by the client device 2000 and a desired VSC corresponding to the ID of the VSC specified by the client device 2000 in association with each other.

  Reference numeral 4009 denotes an AddVideoEncoderConfiguration transaction. This transaction is a transaction for requesting addition of VEC. The client device 2000 transmits an AddVideoEncoderConfiguration command to the monitoring camera 1000. The monitoring camera 1000 returns a response to this command to the client device 2000.

  In this transaction, the client apparatus 2000 designates the distribution profile ID acquired in 4007 and the VEC ID acquired in 4005. Thereby, the client apparatus 2000 can associate the VEC corresponding to the specified VEC ID with the MediaProfile corresponding to the specified distribution profile ID.

  On the other hand, the monitoring camera 1000 stores a MediaProfile corresponding to the distribution profile ID specified by the client device 2000 and a desired VEC corresponding to the VEC ID specified by the client device 2000 in association with each other.

  After processing the transactions 4008 and 4009, the monitoring camera 1000 transmits a MediaProfile change notification event to the client device 2000 to notify the client device 2000 that there has been some change in the MediaProfile.

  Reference numeral 4010 denotes a SetVideoEncoderConfiguration transaction. This transaction is a transaction for setting each parameter of VEC. The client apparatus 2000 transmits a SetVideoEncoderConfiguration command to the monitoring camera 1000.

  The monitoring camera 1000 that has received this command returns a response to this command. With this transaction, the client apparatus 2000 sets the contents of the VEC acquired in 4005 based on the option acquired in 4006. For example, the compression encoding method and the cutout size are changed. The monitoring camera 1000 stores the contents such as the set compression encoding setting.

  After processing this transaction, the monitoring camera 1000 sends a VEC change notification event to the client device 2000 to notify the client device 2000 that there has been some change in the VEC. Note that the SetVideoEncoderConfiguration command in this embodiment corresponds to the first encoding method setting command.

  Reference numeral 4011 denotes a GetStreamUri transaction. This transaction is a transaction for requesting acquisition of a delivery address. In this transaction, the client device 2000 specifies the distribution profile ID acquired in 4007, and acquires an address (URI) for acquiring image data or the like that is distributed by streaming based on the setting of the specified distribution profile.

  The monitoring camera 1000 returns to the client device 2000 an address for streaming delivery of the VSC associated with the distribution profile ID designated by the client device 2000 and the image data corresponding to the contents of the VEC.

  Reference numeral 4012 denotes a DESCRIBE transaction. This transaction is a transaction for requesting acquisition of distribution information. The client device 2000 transmits a DESCRIBE command to the monitoring camera 1000. Upon receiving this command, the monitoring camera 1000 returns a response to this command to the client device 2000.

  In this transaction, the client apparatus 2000 requests and obtains information on the content to be streamed by the monitoring camera 1000 by executing a DESCRIBE command using the URI obtained in 4011.

  Reference numeral 4013 denotes a SETUP transaction. This transaction is a transaction for requesting distribution setting. The client device 2000 transmits a SETUP command to the monitoring camera 1000. Upon receiving this command, the monitoring camera 1000 returns a response to this command to the client device 2000.

  In this transaction, the client apparatus 2000 causes the monitoring camera 1000 to prepare for streaming based on the detailed data regarding the distribution information acquired in 4012. By executing this command, the transmission method of the stream including the session number is shared between the client apparatus 2000 and the monitoring camera 1000.

  Reference numeral 4014 denotes a PLAY transaction. This transaction is a transaction for starting streaming distribution. The client apparatus 2000 transmits a PLAY command to the monitoring camera 1000. Upon receiving this command, the monitoring camera 1000 returns a response to this command to the client device 2000.

  When the client apparatus 2000 transmits a PLAY command to the monitoring camera 1000, the client apparatus 2000 can request the monitoring camera 1000 to start streaming by using the session number acquired in 4013.

  Reference numeral 4015 denotes a stream distributed from the monitoring camera 1000 to the client apparatus 2000. The stream requested to start in 4014 is distributed by the transmission method shared in 4013.

  Reference numeral 4016 denotes a TEARDOWN transaction. This transaction is a transaction for stopping distribution. The client apparatus 2000 transmits a TEARDOWN command to the monitoring camera 1000. The monitoring camera 1000 that has received this command returns a response to this command.

  In this transaction, the client apparatus 2000 can request the monitoring camera 1000 to stop streaming by specifying the session number acquired in 4013 and executing the TEDOWN command.

  Next, FIG. 7 shows a typical command sequence for setting a MediaProfile necessary for distributing video between the monitoring camera 1000 and the client apparatus 2010. Here, the transaction refers to a pair of a command transmitted from the client apparatus 2010 to the monitoring camera 1000 and a response that the monitoring camera 1000 returns to the client apparatus 2010 in response thereto.

  Here, as described above, the client apparatus 2010 has the H.264 format. A decoding unit 2015 corresponding to the decoder of H.265 is provided, and both VEC and VEC2 are supported. In the description of FIG. 7, the description of the same transaction as that of FIG. 6 is omitted, and the same reference numerals are given.

  Reference numeral 4055 denotes a GetVEC2 transaction. Here, FIG. 7 illustrates a case where the GetVECs2 command is used, but the client apparatus 2010 can use either GetVECs or GetVECs2.

  When the client apparatus 2010 transmits a GetVECs command request, the response returned from the monitoring camera 1000 includes JPEG and H.264 as settable encoding methods. H.264 is included. On the other hand, when the client apparatus 2010 transmits a GetVECs2 command request, the response sent back from the monitoring camera 1000 includes JPEG, H. H.264, and H.H. H.265.

  The monitoring camera 1000 can recognize that the client device 2010 is a client device having a new command set by receiving a command such as GetVECs2 described later. On the other hand, if the client device 2010 uses an existing system command such as GetVideoEncoderConfiguration, the monitoring camera 1000 cannot determine whether it is old or new.

  Reference numeral 4056 denotes a GetVideoEncoderConfigurationOptions2 transaction. With this transaction, the client apparatus 2010 can acquire the parameter options and setting value ranges that can be received by the monitoring camera 1000 for the VEC2 specified by the ID.

  The client apparatus 2010 transmits a GetVideoEncoderConfigurationOptions2 command to the monitoring camera 1000. The monitoring camera 1000 that has received this command returns a response to this command. With this transaction, the client apparatus 2010 acquires a list including the ID of the compression encoding setting stored in the storage unit 1002 from the monitoring camera 1000.

  4059 is a transaction of AddVideoEncoderConfiguration2. This transaction is a transaction for requesting addition of VEC2. The client apparatus 2010 transmits a command of AddVideoEncoderConfiguration2 to the monitoring camera 1000. The monitoring camera 1000 returns a response to this command to the client device 2010.

  In this transaction, the client apparatus 2010 designates the distribution profile ID acquired in 4007 and the VEC2 ID acquired in 4055. As a result, the client apparatus 2010 can associate the VEC2 corresponding to the designated VEC2 ID with the MediaProfile corresponding to the designated distribution profile ID.

  On the other hand, the monitoring camera 1000 stores a MediaProfile corresponding to the distribution profile ID specified by the client device 2010 and a desired VEC2 corresponding to the ID of the VEC2 specified by the client device 2010 in association with each other.

  Reference numeral 4060 denotes a SetVideoEncoderConfiguration2 transaction. This transaction is a transaction for setting each parameter of VEC2. The client apparatus 2010 transmits a SetVideoEncoderConfiguration2 command to the monitoring camera 1000.

  Note that SetVideoEncoderConfiguration2 in this embodiment corresponds to a second encoding method setting command.

  The monitoring camera 1000 that has received this command returns a response to this command. With this transaction, the client apparatus 2010 sets the content of VEC2 acquired in 4055 based on the option acquired in 4056. For example, the compression encoding method and the cutout size are changed. The monitoring camera 1000 stores the contents such as the set compression encoding setting.

  As described above, by using FIGS. A typical command sequence when the surveillance camera 1000 that implements H.265 and supports both VEC and VEC2 receives the VEC and VEC2 commands has been described.

  Next, FIG. 23 is a diagram for explaining an example of the definition of VideoEncoderConfiguration2 in the present embodiment. In the present embodiment, the XML Schema Definition language (hereinafter sometimes referred to as XSD) used in the ONVIF standard is used to define this VideoEncoderConfiguration2.

  FIG. 23A shows that VideoEncoderConfiguration2 is defined as ProfileExtension2.

  FIG. 23B shows the contents of VideoEncoderConfiguration2. In FIG. 23B, the sequence specifier specifies that the order of the elements in FIG. 23B appears as defined.

  In FIG. 23B, Encoding is a parameter for designating an encoding method. Resolution is a parameter for designating the resolution, and designates the screen horizontal pixel number and the screen vertical pixel number by each of the parameters designated by Width and Height.

  Quality is a parameter for designating image quality. RateControl is a parameter for designating the setting of the frame rate. FrameRateLimit included in the RateControl is a parameter that specifies an upper limit value of the frame rate.

  Also, EncodingInterval included in the RateControl is a parameter that specifies encoding and a transmission interval. Bitratelimit included in the RateControl is a parameter that specifies the upper limit bit rate of the video stream.

  Multicast is a parameter that specifies the number of multicast video streams. Further, SessionTimeout is a parameter for designating the timeout of the video stream. GovLength is a parameter for designating the I frame interval.

  Further, EncodingProfile is a parameter for designating a coding scheme profile. For example, the encoding method H.264. In H.265, Main, Main10, MainStillPicture, etc. are designated as this profile.

  A description will now be given of an embodiment for an event that occurs in an actual surveillance camera network system. First, it is assumed that the surveillance camera 1000 delivers a video stream encoded according to VEC2 set in the MediaProfile 3000 to the client apparatus 2010 in response to an encoding method request from the client apparatus 2010. This video stream is, for example, H.264. It is assumed that it is encoded by H.265.

  Next, processing when the monitoring camera 1000 receives an encoding method request from the client device 2000 will be described with reference to FIG. Here, FIG. 8 shows processing when the monitoring camera 1000 receives the above-described GetVEOptions command from the client apparatus 2000. Note that this processing is executed by the control unit 1001.

  In step S1500, the control unit 1001 acquires a list of compression methods supported by the VEC among the compression methods stored in the storage unit 1002. In other words, in the present embodiment, the control unit 1001 performs the H.264 operation. JPEG and H.264, except for H.265. H.264 is read from the storage unit 1002.

  In step S1501, the control unit 1001 acquires a list of supported output resolutions stored in the storage unit 1002. This list includes, for example, 1280 × 960, 1024 × 768, 640 × 480, 320 × 240, and the like.

  In step S <b> 1502, the control unit 1001 acquires a settable framerate range, image quality quality range, bitrate range, and encoding interval from the storage unit 1002. For example, the control unit 1001 reads 1 to 30 fps as the Framerate Limit, 1 to 5 as the Quality range, and 64 to 16384 bps as the Bitrate range from the storage unit 1002.

  In step S1503, the control unit 1001 includes the options and setting range acquired in steps S1500 to S1502 in a normal response and returns them to the client apparatus 2000 via the communication unit 1005.

  Next, FIG. 9 is a flowchart for explaining processing when the monitoring camera 1000 receives the above-described SetVEC command from the client device 2000. This process is executed by the control unit 1001.

  Here, the client apparatus 2000 cannot read the contents of VEC2. For this reason, the client device 2000 is configured such that, for example, the monitoring camera 1000 transmits the H.264 to the client device 2010. It is impossible to know that the video stream encoded by H.265 is being distributed.

  More specifically, the client apparatus 2000 cannot know the presence of the VEC2 parameter included in the MediaProfile acquired as a response when the GetProfiles transaction 4002 in FIG. 6 is executed. That is, from the client device 2000, it seems that only parameters such as VSC except VEC2 and AudioEncoderConfiguration (not shown) are held.

  Therefore, the client apparatus 2000 uses the SetVideoEncoderConfiguration command as an encoding method of the VEC3020 of the MediaProfile 3000, for example, H.264. The processing when H.264 has been set will be described with reference to FIG.

  In step S1600, the control unit 1001 determines whether or not VEC2 is set in the MediaProfile 3000 corresponding to the distribution setting information.

  If the control unit 1001 determines that VEC2 is set in the MediaProfile 3000, the control unit 1001 advances the process to step S1611. On the other hand, if the control unit 1001 determines that VEC2 is not set in the MediaProfile 3000, the process proceeds to step S1601.

  In step S1601, the control unit 1001 stores each setting value of Framerate, Quality, Bitrate, and EncodingInterval specified by the argument of the SetVEC command in the VEC of the storage unit 1002.

  In step S1602, the control unit 1001 determines whether the output resolution (Resolution) specified by the argument of the SetVEC command is supported.

  Specifically, the control unit 1001 determines whether or not the output resolution list (Resolution) specified by the argument of the SetVEC command is included in the list of output resolutions acquired in step S1501.

  Next, if the control unit 1001 determines that the output resolution specified by the argument of the SetVEC command is included in the list, the control unit 1001 determines that the output resolution is not supported. On the other hand, when it is determined that the output resolution specified by the argument of the SetVEC command is not included in this list, the control unit 1001 determines that this output resolution is not supported.

  If the control unit 1001 determines that the output resolution specified by the argument of the SetVEC command is supported, the control unit 1001 advances the process to step S1603. On the other hand, if the control unit 1001 determines that the output resolution specified by the argument of the SetVEC command is not supported, the control unit 1001 advances the process to step S1610.

  In step S1603, the control unit 1001 stores the output resolution (Resolution) specified by the argument of the SetVEC command in the VEC of the storage unit 1002.

  In step S1604, the control unit 1001 determines whether the compression method (Encoding) specified by the argument of the SetVEC command is supported.

  Specifically, the control unit 1001 determines whether or not the compression method list obtained in step S1500 includes the compression method (Encoding) specified by the argument of the SetVEC command.

  Next, when the control unit 1001 determines that the compression method specified by the argument of the SetVEC command is included in the list, the control unit 1001 advances the processing to step S1605. On the other hand, if the control unit 1001 determines that this list does not include the compression method specified by the argument of the SetVEC command, the control unit 1001 advances the process to step S1610.

  In step S1605, the control unit 1001 stores the compression method (Encoding) specified by the argument of the SetVEC command in the VEC of the storage unit 1002.

  In step S1606, the control unit 1001 returns a normal response to the client device 2000 via the communication unit 1005. Then, the control unit 1001 ends this process.

  In step S1610, the control unit 1001 returns an error response to the client device 2000 via the communication unit 1005. Then, the control unit 1001 ends this process.

  In step S1611, the control unit 1001 stores the setting values of Framerate, Quality, Bitrate, and EncodingInterval specified by the argument of the SetVEC command in the VEC and VEC2 of the storage unit 1002.

  As a result, the same parameter specified by the argument of the SetVEC command is set and held in VEC and VEC2 associated with the same MediaProfile (for example, in MediaProfile3000).

  In step S1612, the control unit 1001 determines whether the output resolution (Resolution) specified by the argument of the SetVEC command is supported.

  Specifically, the control unit 1001 determines whether or not the output resolution list (Resolution) specified by the argument of the SetVEC command is included in the list of output resolutions acquired in step S1501.

  Next, if the control unit 1001 determines that the output resolution specified by the argument of the SetVEC command is included in the list, the control unit 1001 determines that the output resolution is not supported. On the other hand, when it is determined that the output resolution specified by the argument of the SetVEC command is not included in this list, the control unit 1001 determines that this output resolution is not supported.

  If the control unit 1001 determines that the output resolution specified by the argument of the SetVEC command is supported, the control unit 1001 advances the process to step S1613. On the other hand, if the control unit 1001 determines that the output resolution specified by the argument of the SetVEC command is not supported, the control unit 1001 advances the process to step S1610.

  In step S1613, the control unit 1001 stores the output resolution (Resolution) specified by the argument of the SetVEC command in the VEC and VEC2 of the storage unit 1002.

  In step S1604, the control unit 1001 determines whether the compression method (Encoding) specified by the argument of the SetVEC command is supported.

  Specifically, the control unit 1001 determines whether or not the compression method list obtained in step S1500 includes the compression method (Encoding) specified by the argument of the SetVEC command.

  Next, if the control unit 1001 determines that the compression method specified by the argument of the SetVEC command is included in this list, the control unit 1001 advances the processing to step S1615. On the other hand, if the control unit 1001 determines that this list does not include the compression method specified by the argument of the SetVEC command, the control unit 1001 advances the process to step S1610.

  In step S1615, the control unit 1001 stores the compression method Encoding specified by the argument of the SetVEC command in the VEC and VEC2 of the storage unit 1002.

  Since step S1616 is the same as step S1606, the description thereof is omitted.

  Through the processing as described above, only one type of encoding method can be set in MediaProfile (for example, MediaProfile3000) that is one distribution setting information.

  After processing these commands, the monitoring camera 1000 transmits a MediaProfile change notification event to notify the client devices 2000 and 2010 on the network that some change has occurred in the MediaProfile.

  By this process, H. The monitoring camera 1000 that has distributed the video stream encoded by the H.265 system to the client apparatus 2010 transmits the MediaProfile change notification event, and then stops the transmission of this video stream.

  Next, the surveillance camera 1000 is connected to the H.264. The transmission of a video stream encoded by H.264 is started. It should be noted that the client device 2010 has an H.264 format. Since the decoding unit 2015 corresponding to the decoder of H.265 has backward compatibility, the video stream can be received and decoded.

  Next, FIG. 10 is a diagram showing a VideoEncoder setting window, which is a user interface for setting the VEC of the monitoring camera 1000 in the client device 2000 of the present embodiment.

  7000 in FIG. 10 is a LiveView area. When this window is opened, the client apparatus 2000 displays the image corresponding to the video stream obtained in the transaction 4015 on the LiveView window 7000 by executing the sequence shown in FIG.

  Further, the client device 2000 acquires a list of all VECs from the monitoring camera 1000 by transmitting a GetVECs command to the monitoring camera 1000. Then, the client device 2000 displays the VideoEncoder tabs 7001 and 7002 on the screen of FIG. 10 by using the obtained result (acquired list).

  In addition, the client apparatus 2000 acquires a selection and a setting range of each parameter of the VEC by transmitting a GetVEOptions command. Then, the client device 2000 uses the obtained results (acquired options and setting range) to update the options and setting ranges of each parameter of VideoEncoder on the screen of FIG.

  As a result, the client apparatus 2000 can provide the user with the VEC setting value options and setting ranges displayed on the display unit 2003.

  A VideoEncoder tab 7001 and a VideoEncoder tab 7002 are tabs for switching the VideoEncoder setting screen.

  For example, when the VideoEncoder tab 7001 is pressed by the user, the VideoEncoder1 setting screen is displayed in the VideoEncoder setting window of FIG. This screen is a screen for allowing the user to change the VEC 3021 associated with the MediaProfile 3001.

  On the other hand, when the VideoEncoder tab 7002 is pressed by the user, the VideoEncoder2 setting screen is displayed in the VideoEncoder setting window of FIG. This screen is a screen for allowing the user to change the VEC 3021 associated with the MediaProfile 3002.

  That is, VideoEncoder1 (setting screen) and VideoEncoder2 (setting screen) correspond to MediaProfile parameters (screen for setting) created in the monitoring camera 1000. Here, this MediaProfile is created in the monitoring camera 1000 by a CreateProfile command transmitted from an external device such as the client devices 2000 and 2010.

  In FIG. 10, two media profiles 3001 and 3002 are created in the monitoring camera 1000, and parameters corresponding to the created media profile are displayed on the setting screen of the client device 2000.

  Here, the value of ProfileToken of this MediaProfile 3001 is profile1. Also, the value of ProfileToken of this MediaProfile 3002 is profile2.

  Reference numeral 7010 denotes an EncoderType area that allows the user to select a compression encoding method for each VEC. In this area, choices of compression encoding (Encoding) obtained by transmitting a GetVEOptions command when the screen of FIG. 10 is opened are displayed.

  In this embodiment, this area includes JPEG and H.264 as compression encoding methods that can be currently selected by the user in the client apparatus 2000. H.264 is displayed.

  The radio button 7011 and the radio button 7012 are JPEG and H.264. A button for selecting any one of H.264. Here, when the radio button 7011 is pressed, JPEG is selected, and when the radio button 7012 is pressed, H.264 is selected. H.264 is selected. Note that in FIG. H.264 is not selected.

  When the radio button 7012 is pressed by the user in this unselected state, H. When H.264 is selected, the transaction 4010 in FIG. 6 is executed. With this execution, the encoding type is set, and the process proceeds to step S1600 of FIG. Here, FIG. 2 is a diagram illustrating an example of a display setting screen of the client apparatus 2000 in a state where H.264 is selected.

  In the screen of FIG. 11, the radio button 7012 is pressed by clicking on the screen with the mouse or by keyboard input, and H. H.264 is selected, and a black circle is displayed on the radio button 7012.

  7020 is a Detail area for allowing the user to select the parameters of FramerateLimit, BitrateLimit, and Quality included in the VEC 3021. The parameter setting ranges indicated by 7021, 7022, and 7023 reflect the contents of the parameter setting ranges obtained by executing the GetVEOptions command when the screen of FIG. 10 is opened.

  Reference numeral 7030 denotes an EncoderResolution area for selecting the resolution (Resolution) of the VEC3021. The drop-down list 7031 displays the contents of the VEC3021 resolution parameter choices obtained by executing the GetVEOptions command when the screen of FIG. 10 is opened.

  Reference numeral 7040 denotes a setting button. When the setting button 7040 is pressed by the user, the client apparatus 2000 transmits SetVEC to the monitoring camera 1000. As a result, the parameters selected in the Encoder Type area 7010, Detail area 7020, and Encoder Resolution area 7030 are reflected in the compression encoding unit 1004 of the monitoring camera 1000.

  After the transaction 4010 is processed by this transmission, the monitoring camera 1000 transmits a VEC change notification event to the client apparatuses 2000 and 2010 to notify the client apparatuses 2000 and 2010 that there has been some change in the VEC. When the monitoring camera 1000 receives the SetVEC command, the monitoring camera 1000 proceeds with the process according to the flowchart of FIG.

  Next, FIG. 12 is a diagram illustrating a VideoEncoder setting window, which is a user interface for causing the monitoring apparatus 1000 to perform VEC settings in the client device 2010 of the present embodiment.

  More specifically, the screen of FIG. 12 is the H.264 VideoEncoder setting screen of the client apparatus 2000. 6 is a VideoEncoder setting screen of the client apparatus 2010 in a state before H.264 is selected. In FIG. 12, the same components as those in FIG. 10 are denoted by the same reference numerals, and the description thereof may be omitted.

  The screen of FIG. 12 displays the settings of the monitoring camera 1000 such as encoding, framerate limit, bitrate limit, quality, and resolution parameters, options, and setting ranges.

  These parameter settings, options, setting ranges, and the like are acquired from the monitoring camera 1000 by transmitting the GetVECs2 command and the GetVEOptions2 command from the client apparatus 2010.

  In the EncoderType area 7050 in FIG. 12, the radio button 7053 is pressed by the user. H.265 is selected. As a result, the surveillance camera 1000 The image data encoded in H.265 is being streamed to the client device 2010.

  In the LiveView window 7000, an image corresponding to the image data decoded by the decoding unit 2015 is displayed. At this time, the communication unit 2016 is connected to the H.264. The image data encoded in H.265 is received. Further, the decoding unit 2015 decodes the image data received by the communication unit 2016.

  On the other hand, the client device 2000 is connected to the H.264 client. Since the video encoder setting screen of the client apparatus 2000 is not compatible with H.265, as shown in FIG. A radio button for selecting H.265 is not displayed.

  As described above, when the user presses the radio button 7012 on the VideoEncoder setting screen of the client apparatus 2000, the H. H.264 is selected and H.264 is assigned to VEC3021. Assume that H.264 is set. In such an assumption, the monitoring camera 1000 notifies the client apparatuses 2000 and 2010 that a change has been made to the MediaProfile associated with the VEC 3021.

  At this time, in the monitoring camera 1000, steps S1611 to S1616 in FIG. 9 are executed, and rewriting of the parameters of VEC and VEC2 is executed. If the display of the VideoEncoder setting screen of the client apparatus 2010 is updated in a state where this rewriting is executed, the radio button 7052 is pressed and H.264 is updated as shown in FIG. This setting screen with H.264 selected is displayed.

  Furthermore, the LiveView window 7000 on the screen of FIG. When the image data encoded by H.264 is decoded by the decoding unit 2015, an image corresponding to the decoded image data is displayed.

  As described above, the monitoring camera 1000 according to the present embodiment, when the SetVEC command is received by the communication unit 1005, overwrites the VEC2 associated with the MediaProfile corresponding to the received command with the contents of the received command.

  In the monitoring camera 1000 according to the present exemplary embodiment, only one image data can be distributed to the client device 2000 or 2010 by one MediaProfile.

  Here, it is assumed that the VEC is associated with the MediaProfile associated with VEC2 by the SetVEC command transmitted from the client apparatus 2000. Under such an assumption, the image data that can be distributed to the client apparatus 2000 or 2010 by this MediaProfile is only one image data corresponding to the associated VEC.

  For this reason, the client apparatus 2010 that has received the image data corresponding to the associated VEC2 may not be able to continue receiving this image data because the VEC is associated with this MediaProfile.

  Therefore, according to this embodiment, the image data corresponding to the associated VEC and the image data corresponding to the associated VEC2 can be made the same. As a result, even if there is only one image data that can be distributed by one MediaProfile, both the client apparatuses 2000 and 2010 can continuously receive the image data.

(Example 2)
In the first embodiment, the case where the monitoring camera 1000 receives the SetVEC command for updating the parameter of the VEC associated with the MediaProfile from the client apparatus 2000 has been described. Here, it is assumed that the VEC2 parameter has already been associated with this MediaProfile.

  Further, the monitoring camera 1000 overwrites the VEC2 parameters associated with the MediaProfile with the contents of the VEC updated by the received SetVEC command.

  In contrast, when the monitoring camera 1000 according to the second embodiment receives such a SetVEC command, the monitoring camera 1000 returns an error response to the client device 2000 without overwriting such VEC2 parameters. A second embodiment of the present invention considering the above points will be described below with reference to FIG. In the present embodiment, the same components as those in the first embodiment described above are denoted by the same reference numerals, and the description thereof may be omitted.

  Next, FIG. 14 is a flowchart for explaining processing when the monitoring camera 1000 receives a SetVEC command from the client device 2000 in the present embodiment. This process is executed by the control unit 1001.

  In step S1600, the control unit 1001 determines whether or not VEC2 is set in the MediaProfile 3000 corresponding to the distribution setting information.

  If the control unit 1001 determines that VEC2 is set in the MediaProfile 3000, the control unit 1001 advances the process to step S1610. On the other hand, if the control unit 1001 determines that VEC2 is not set in the MediaProfile 3000, the process proceeds to step S1601.

  As described above, when the communication unit 1005 receives the SetVEC command from the client apparatus 2000 and the VEC2 is associated with the MediaProfile, the monitoring camera 1000 according to the present embodiment transmits an error response to the client apparatus 2000.

  As a result, it is possible to prevent an unintended encoding method of the client apparatus 2010 corresponding to VEC2 from being associated with the MediaProfile associated with VEC2.

(Example 3)
In the second embodiment, the case where the monitoring camera 1000 receives the SetVEC command for updating the VEC parameter from the client apparatus 2000 has been described. Here, it is assumed that the MediaProfile of the monitoring camera 1000 is already associated with the VEC2 parameter. The monitoring camera 1000 returns an error response to the client device 2000 when receiving the SetVEC command.

  In contrast, in the third embodiment, a case where the monitoring camera 1000 receives a SetVEC2 command for updating the VEC2 parameter from the client apparatus 2010 will be described. Here, it is assumed that the MediaProfile of the monitoring camera 1000 is associated with a VEC parameter.

  The monitoring camera 1000 returns an error response to the client apparatus 2010 when receiving the SetVEC2 command. A third embodiment of the present invention considering the above points will be described below with reference to FIG. In the present embodiment, the same components as those in the first embodiment described above are denoted by the same reference numerals, and the description thereof may be omitted.

  Next, FIG. 15 is a flowchart for explaining processing when the monitoring camera 1000 receives a SetVEC2 command from the client apparatus 2010 in this embodiment. This process is executed by the control unit 1001.

  In step S1620, the control unit 1001 determines whether or not VEC is set in the MediaProfile 3000 corresponding to the distribution setting information.

  If the control unit 1001 determines that VEC is set in the MediaProfile 3000, the control unit 1001 advances the process to step S1627. On the other hand, if the control unit 1001 determines that VEC is not set in the MediaProfile 3000, the control unit 1001 advances the process to step S1621.

  In step S1621, the control unit 1001 stores the setting values of Framerate, Quality, Bitrate, and EncodingInterval specified by the argument of the SetVEC2 command in the VEC2 of the storage unit 1002.

  In step S1622, the control unit 1001 determines whether the output resolution (Resolution) specified by the argument of the SetVEC2 command is supported.

  Specifically, first, the control unit 1001 acquires a list of output resolutions supported by the VEC2 among the output resolutions stored in the storage unit 1002. Next, the control unit 1001 determines whether or not the acquired list includes the output resolution (Resolution) specified by the argument of the SetVEC2 command.

  When the control unit 1001 determines that the output resolution specified by the argument of the SetVEC2 command is included in the acquired list, the control unit 1001 determines that the output resolution is not supported. On the other hand, if the control unit 1001 determines that the output resolution specified by the argument of the SetVEC2 command is not included in the acquired list, the control unit 1001 determines that the output resolution is not supported.

  If the control unit 1001 determines that the output resolution specified by the argument of the SetVEC2 command is supported, the control unit 1001 advances the process to step S1623. On the other hand, if the control unit 1001 determines that the output resolution specified by the argument of the SetVEC2 command is not supported, the control unit 1001 advances the processing to step S1627.

  In step S <b> 1623, the control unit 1001 stores the output resolution (Resolution) specified by the argument of the SetVEC2 command in the VEC of the storage unit 1002.

  In step S1624, the control unit 1001 determines whether the encoding method (Encoding) specified by the argument of the SetVEC2 command is supported.

  Specifically, first, the control unit 1001 obtains a list of encoding methods supported by VEC2 among the encoding methods stored in the storage unit 1002. Next, the control unit 1001 determines whether or not the acquired list includes the encoding method specified by the argument of the SetVEC2 command.

  If the control unit 1001 determines that the encoding method specified by the argument of the SetVEC2 command is included in the list, the control unit 1001 advances the process to step S1625. On the other hand, if the control unit 1001 determines that the encoding method specified by the argument of the SetVEC2 command is not included in the list, the control unit 1001 advances the processing to step S1627.

  In step S1625, the control unit 1001 stores the encoding method (Encoding) specified by the argument of the SetVEC2 command in the VEC2 of the storage unit 1002.

  In step S1626, the control unit 1001 returns a normal response to the client apparatus 2010 via the communication unit 1005. Then, the control unit 1001 ends this process.

  In step S <b> 1627, the control unit 1001 returns an error response to the client device 2010 via the communication unit 1005. Then, the control unit 1001 ends this process.

  As described above, when the communication unit 1005 receives the SetVEC2 command from the client apparatus 2010 and VEC is set in the MediaProfile, the monitoring camera 1000 according to the present embodiment transmits an error response to the client apparatus 2010.

  Here, both VEC and VEC2 can be associated with the MediaProfile of the monitoring camera 1000 in the present embodiment. A case is assumed in which VEC2 is newly associated with the MediaProfile that is already associated with the VEC.

  Under such an assumption, even if the client apparatus 2000 receives image data corresponding to the MediaProfile with which VEC2 is newly associated, the received image data may not always be decoded. For example, the image data corresponding to this MediaProfile is H.264. In the case of the image data encoded by H.265, the client device 2000 cannot decode the image data.

  On the other hand, according to the monitoring camera 1000 of this embodiment, it is possible to prevent the encoding method that the client apparatus 2000 cannot decode from being associated with the MediaProfile associated with the VEC.

Example 4
In the first to third embodiments, the monitoring camera 1000 that can distribute only one video stream with one MediaProfile has been described. On the other hand, in the fourth embodiment, a monitoring camera 1000 capable of delivering a plurality of video streams with one MediaProfile will be described.

  A fourth embodiment of the present invention considering the above points will be described below with reference to FIGS. In the present embodiment, the same components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof may be omitted.

  Next, FIG. 16 is a diagram illustrating a VideoEncoder setting window, which is a user interface for causing the monitoring apparatus 1000 to perform VEC settings in the client apparatus 2010 of the present embodiment.

  This window is the same as H.264. VEC and H.264 for which encoding corresponding to H.264 is set. It is a VideoEncoder setting window when VEC2 for which encoding corresponding to H.265 is set is associated with the same MediaProfile.

  Note that this VEC encoding is performed in the Encoder Type area 7010 in the client device 2000. H.264 is set by the transmitted SetVEC. Also, the encoding of this VEC2 is performed in the Encoder Type area 7050 in the client apparatus 2010. This is set by SetVEC2 transmitted by selecting H.265.

  In the EncoderType area 7050 in FIG. 16, the radio button 7052 is pressed, and H.264 is set as EncoderType. H.264 is selected, and a black circle is displayed on the radio button 7052. Further, in the EncoderType area 7050, the radio button 7053 is pressed, and the H.264 is set as EncoderType. H.265 is selected, and a black circle is displayed on the radio button 7053.

  In such a case, in the VideoEncoder setting window in the client apparatus 2010, as shown in FIG. 11, the radio button 7012 in the EncoderType area 7010 is pressed. Further, in this EncoderType area 7010, a black circle is displayed on the radio button 7012.

  As described above, in the storage unit 1002 according to the present embodiment, as shown in FIG. 5, each Token of VEC and VEC2 is stored in one MediaProfile. That is, in this embodiment, VEC and VEC2 are associated with one MediaProfile.

  Further, the monitoring camera 1000 according to the present embodiment performs streaming distribution of the image data corresponding to the VEC associated with the MediaProfile to the client device 2000. In addition, the image data corresponding to VEC2 associated with this MediaProfile is also streamed to the client apparatus 2010.

  Next, FIG. 17 is a flowchart for explaining processing when the monitoring camera 1000 receives a Play command from the client device 2000 or 2010 in the present embodiment. This process is executed by the control unit 1001.

  In step S1200, the control unit 1001 reads from the storage unit 1002 the encoding method set in the VEC associated with the MediaProfile corresponding to the Play command received by the communication unit 1005. Then, the control unit 1001 temporarily stores the read encoding method in the storage unit 1002. Here, in the present embodiment, for example, the control unit 1001 performs the H.264 operation. H.264 is temporarily stored in the storage unit 1002.

  In step S1202, the control unit 1001 determines whether the VEC is associated with the MediaProfile corresponding to the Play command received by the communication unit 1005.

  If it is determined that the VEC is associated with the MediaProfile corresponding to the Play command received by the communication unit 1005, the control unit 1001 advances the process to step S1203. On the other hand, if it is determined that the VEC is not associated with the MediaProfile corresponding to the Play command received by the communication unit 1005, the control unit 1001 advances the process to step S1204.

  In the present embodiment, for example, the control unit 1001 advances the process to step S1203.

  In step S1203, the control unit 1001 compresses the captured image output from the imaging unit 1003 into the compression encoding unit 1004 using the VEC encoding method associated with the MediaProfile corresponding to the Play command received by the communication unit 1005. Encode. Then, the control unit 1001 instructs the communication unit 1005 to transmit the image data corresponding to the compression-encoded captured image to the outside.

  In the present embodiment, for example, the control unit 1001 instructs the communication unit 1005 to execute H.264. The image data compressed and encoded by H.264 is transmitted to the outside.

  In step S1204, the control unit 1001 determines whether or not VEC2 is associated with the MediaProfile corresponding to the Play command received by the communication unit 1005.

  If it is determined that VEC2 is associated with the MediaProfile corresponding to the Play command received by the communication unit 1005, the control unit 1001 advances the process to step S1205. On the other hand, if it is determined that the VEC is not associated with the MediaProfile corresponding to the Play command received by the communication unit 1005, the control unit 1001 advances the process to step S1206.

  In the present embodiment, for example, the control unit 1001 advances the process to step S1205.

  In step S1205, the control unit 1001 compresses the captured image output from the imaging unit 1003 into the compression encoding unit 1004 using the VEC2 encoding method associated with the MediaProfile corresponding to the Play command received by the communication unit 1005. Encode. Then, the control unit 1001 instructs the communication unit 1005 to transmit the image data corresponding to the compression-encoded captured image to the outside.

  In the present embodiment, for example, the control unit 1001 instructs the communication unit 1005 to execute H.264. The image data compressed and encoded at 265 is transmitted to the outside.

  In step S1206, the control unit 1001 determines whether or not a teardown command has been received by the communication unit 1005. If the control unit 1001 determines that a Teadonw command has been received by the communication unit 1005, the control unit 1001 ends the process of FIG. On the other hand, when the control unit 1001 determines that the teardown command is not received by the communication unit 1005, the control unit 1001 returns the process to step S1200.

  As described above, the compression encoding unit 1004 according to the present exemplary embodiment encodes the captured image output from the imaging unit 1003 using an encoding method corresponding to the VEC associated with the MediaProfile stored in the storage unit 1002. Further, the compression encoding unit 1004 in the present embodiment encodes this captured image with an encoding method corresponding to VEC2 associated with this MediaProfile.

  Thereby, even when the client apparatuses 2000 and 2010 use the same MediaProfile, the client apparatus 2000 can receive image data encoded by a desired encoding method. In addition, the client apparatus 2010 can also receive image data encoded by a desired encoding method.

  Note that the compression encoding unit 1004 in this embodiment, for example, uses a separate processor for the captured image output from the imaging unit 1003 to execute the H.264 encoding. H.264 encoding and H.264 encoding Each of the H.265 encodings may be configured to execute in parallel.

  In addition, the compression encoding unit 1004 in the present embodiment applies the same processor to the H.264 image with respect to the captured image output from the imaging unit 1003. H.264 encoding and H.264 encoding The encoding of 265 may be configured to be time-division processed.

  In this embodiment, H. H.264 encoded image data and H.264. The image data encoded by H.265 may be distributed as separate streams, or may be distributed as a single stream that is time-division multiplexed.

(Example 5)
In the second embodiment, the case where the monitoring camera 1000 receives the SetVEC command for updating the VEC parameter from the client apparatus 2000 has been described. Here, it is assumed that the MediaProfile of the monitoring camera 1000 is already associated with the VEC2 parameter. The monitoring camera 1000 returns an error response to the client device 2000 when receiving the SetVEC command.

  On the other hand, the monitoring camera 1000 according to the fifth embodiment creates a new MediaProfile without returning an error response to the client device 2000 when such a SetVEC command is received. A fifth embodiment of the present invention considering the above points will be described below with reference to FIGS. In the present embodiment, the same components as those in the second embodiment described above are denoted by the same reference numerals, and the description thereof may be omitted.

  Next, FIG. 18 is a flowchart for explaining processing when the monitoring camera 1000 receives a SetVEC command from the client device 2000 in the present embodiment. This process is executed by the control unit 1001.

  In step S1630, the control unit 1001 newly generates a MediaProfile different from the MediaProfile specified by the SetVEC command received by the communication unit 1005, and stores the generated MediaProfile in the storage unit 1002.

  Here, FIG. 19 illustrates a structure of parameters held by the monitoring camera 1000 (the storage unit 1002 thereof) before the generated MediaProfile is stored in the storage unit 1002 in the present embodiment.

  In FIG. 19, MediaProfile 3040, 3041, 3042, and 3043 are parameter sets for storing various setting items of the monitoring camera 1000 in association with each other. Each of the MediaProfiles 3040, 3041, 3042, and 3043 holds a ProfileToken that is an ID of the MediaProfile.

  The MediaProfile 3040 holds links to various setting items such as the VideoSourceConfiguration 3011 and the VEC23030. The MediaProfile 3041 holds links to various setting items such as the VideoSourceConfiguration 3011 and the VEC23031.

  Furthermore, the MediaProfile 3042 holds links to various setting items such as the VideoSourceConfiguration 3011 and the VEC23032. The MediaProfile 3043 holds links to various setting items such as the VideoSourceConfiguration 3011 and the VEC3020.

  Next, FIG. 20 illustrates a structure of parameters held by the monitoring camera 1000 (the storage unit 1002 thereof) after the generated MediaProfile is stored in the storage unit 1002 in the present embodiment.

  In FIG. 20, a MediaProfile 3044 is the MediaProfile generated in step S1630, and is a parameter set for storing various setting items of the monitoring camera 1000 in association with each other. This MediaProfile 3044 holds a ProfileToken whose value is “profile3”.

  The MediaProfile 3044 holds links to various setting items such as the VSC 3011 and VEC3021.

  Step S1631 is the same as step S1601 when it is determined in step S1600 that VEC2 is not set. On the other hand, if it is determined in step S1631 that VEC2 is set in step S1600, the control unit 1001 stores the MediaProfile stored in step S1630 with each setting value specified by the argument of the SetVEC command. Remember me.

  The setting items are Framerate, Quality, Bitrate, and EncodingInterval.

  Step S1633 is the same as step S1603 when it is determined in step S1600 that VEC2 is not set. On the other hand, in step S1633, if it is determined in step S1600 that VEC2 is set, the control unit 1001 stores the output resolution specified by the argument of the SetVEC command in the MediaProfile stored in step S1630. Remember.

  Step S1635 is the same as step S1605 if it is determined in step S1600 that VEC2 is not set. On the other hand, if it is determined in step S1635 that VEC2 is set in step S1600, the control unit 1001 sets the encoding method specified by the argument of the SetVEC command in the MediaProfile stored in step S1630. Remember.

  As described above, when the communication unit 1005 receives the SetVEC command and the VEC2 is associated with the MediaProfile corresponding to the received SetVEC command, the monitoring camera 1000 according to the present embodiment automatically generates a new MediaProfile. Then, the generated MediaProfile is associated with the VEC corresponding to the received SetVEC command.

  Accordingly, for example, in such a case, it is possible to prevent a complicated exchange between the monitoring camera 1000 and the client device 2000 such as the client device 2000 transmitting a CreateProfile command.

(Example 6)
In the third embodiment, the case where the monitoring camera 1000 receives the SetVEC2 command for updating the VEC2 parameter from the client apparatus 2010 has been described. Here, the MediaProfile of the monitoring camera 1000 is associated with a VEC parameter. The monitoring camera 1000 returns an error response to the client apparatus 2010 when receiving the SetVEC2 command.

  On the other hand, in the sixth embodiment, in such a case, only VEC2 stored in the storage unit 1002 or both VEC and VEC2 are updated according to the encoding method specified by SetVEC2 received from the client apparatus 2010. The surveillance camera 1000 will be described. A sixth embodiment of the present invention considering the above points will be described below with reference to FIG.

  In the present embodiment, the same components as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof may be omitted.

  Next, FIG. 21 is a flowchart for explaining processing when the monitoring camera 1000 receives a SetVEC2 command from the client device 2010 in the present embodiment. This process is executed by the control unit 1001.

  In step S1650, the control unit 1001 determines that the encoding method specified by the SetVEC2 command received by the communication unit 1005 is JPEG, MPEG, H.264. H.264 is determined. Then, the control unit 1001 determines that the encoding method specified by the SetVEC2 command received by the communication unit 1005 is JPEG, MPEG, H.264, or the like. If it is determined that any one of H.264, the process advances to step S1660.

  On the other hand, the control unit 1001 determines that the encoding method specified by the SetVEC2 command received by the communication unit 1005 is JPEG, MPEG, H.264. If it is determined that it is not any one of H.264, the process proceeds to step S1651. In this embodiment, JPEG, MPEG, H.264, etc. H.264 corresponds to a predetermined encoding method.

  Since steps S1651 to S1656 are the same as steps S1621 to S1626, the description thereof is omitted.

  In step S1660, the setting values of Framerate, Quality, Bitrate, and EncodingInterval specified by the argument of the SetVEC2 command are stored in the VEC and VEC2 of the storage unit 1002.

  For example, the control unit 1001 sets the encoding method of SetVEC2 to H.264. In the case of H.264, the encoding method for each of VEC and VEC2 of MediaProfile, which is distribution setting information, is H.264. H.264 is set.

  Since step S1661 is the same as step S1622, the description thereof is omitted.

  In step S1662, the control unit 1001 stores the output resolution specified by the argument of the SetVEC2 command in the VEC and VEC2 of the storage unit 1002.

  Since step S1663 is the same as step S1624, description thereof is omitted.

  In step S1664, the control unit 1001 stores the encoding method specified by the argument of the SetVEC command in the VEC and VEC2 of the storage unit 1002.

  Since step S1655 is the same as step S1626, description thereof is omitted.

  As described above, in the monitoring camera 1000 according to the present embodiment, the encoding method specified by the SetVEC2 command received by the communication unit 1005 is JPEG, MPEG, H.264. H.264 is determined. And the surveillance camera 1000 is JPEG, MPEG, H.264. When it is determined that it is H.264, both the VEC and VEC2 encoding methods associated with the MediaProfile corresponding to this command are changed to the encoding methods corresponding to this command.

  Normally, the client device 2000 that does not support VEC2 cannot recognize the encoding method set in MediaProfile with the SetVEC2 command.

  However, according to the monitoring camera 1000 of the present embodiment, both the client apparatuses 2000 and 2010 can grasp the encoding method set in MediaProfile by the SetVEC2 command.

(Example 7)
In the first embodiment, the case where the monitoring camera 1000 receives the SetVEC command for updating the parameter of the VEC associated with the MediaProfile from the client apparatus 2000 has been described. Here, it is assumed that the VEC2 parameter has already been associated with this MediaProfile.

  Further, the monitoring camera 1000 overwrites the VEC2 parameters associated with the MediaProfile with the contents of the VEC updated by the received SetVEC command.

  In contrast, in the seventh embodiment, the number of client devices that have transmitted the SetVEC command is compared with the number of client devices that have transmitted the SetVEC2 command. . A seventh embodiment of the present invention considering the above points will be described below with reference to FIG. In the present embodiment, the same components as those in the first embodiment described above are denoted by the same reference numerals, and the description thereof may be omitted.

  Next, FIG. 22 is a flowchart for explaining processing when the monitoring camera 1000 receives a SetVEC command from the client device 2000. This process is executed by the control unit 1001.

  In step S1670, the control unit 1001 determines whether there are more client devices that have transmitted the SetVEC command in the past than the number of client devices that have transmitted the SetVEC command in the past.

  If the control unit 1001 determines that the number of client devices that have transmitted the SetVEC2 command in the past is greater than the number of client devices that have transmitted the SetVEC command in the past, the control unit 1001 advances the process to step S1610.

  On the other hand, when the control unit 1001 determines that the number of client devices that have transmitted the SetVEC2 command in the past is not greater than the number of client devices that have transmitted the SetVEC command in the past, the control unit 1001 performs processing in step S1611. Proceed.

  As described above, in the monitoring camera 1000 according to the present embodiment, when the communication unit 1005 receives the SetVEC command, the number of client devices that have transmitted the SetVEC command in the past is larger than the number of client devices that have transmitted the SetVEC command in the past. Determine whether there are many.

  If the monitoring camera 1000 determines that this number is not large, both the VEC and VEC2 encoding methods associated with the MediaProfile corresponding to this command are set to the encoding methods corresponding to this command.

  Thereby, the encoding method of VEC2 associated with the MediaProfile can be set more effectively with the SetVEC command.

  In step S1670, the number of client devices that have transmitted the SetVEC command is compared with the number of client devices that have transmitted the SetVEC2 command, and the process branches. However, branch determination may be performed by other methods. For example, in step S1670, branch determination may be performed using event transmission from the client device as a trigger, or branch determination may be performed by setting a weighting factor for each client device and comparing the sums.

(Other examples)
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in the computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

1000 Monitoring Camera 1001 Control Unit 1002 Storage Unit 1004 Compression Coding Unit 1005 Communication Unit 2000 Client Device

Claims (27)

An imaging device that communicates with an external device via a network,
Imaging means for imaging a subject;
Storage control means for storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
Encoding means for encoding the captured image output from the imaging means based on the encoding method included in the delivery setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Receiving means for receiving a second encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received by the receiving means is different from the encoding method included in the distribution setting information stored in the storage unit, the distribution setting information stored in the storage unit Control means for including the encoding method corresponding to the encoding method setting command received by the receiving means,
An imaging apparatus comprising:   The imaging apparatus according to claim 1, wherein the delivery setting information including the encoding method by the control unit includes one of the first encoding method and the second encoding method. .   The imaging apparatus according to claim 1, wherein the delivery setting information including the encoding method by the control unit includes the first encoding method and the second encoding method.   The first encoding included in the distribution setting including the encoding method by the control unit when the encoding method corresponding to the encoding method setting command received by the receiving unit is a predetermined encoding method. The imaging apparatus according to claim 3, wherein both the system and the second encoding system are the predetermined encoding system.   The encoding unit encodes the captured image output from the imaging unit with the first encoding method included in the distribution setting information including the encoding method by the control unit, and the distribution setting. The imaging apparatus according to claim 3 or 4, wherein encoding is performed using a second encoding method included in the information. The external device is plural,
The control unit is different from the encoding method corresponding to the encoding method setting command received by the receiving unit and the encoding method included in the distribution setting information stored in the storage unit, and the encoding method setting command If the number of external devices that have transmitted in the past an encoding method setting command that is different from the encoding method setting command is greater than the number of external devices that have transmitted the past, the distribution setting information stored in the storage unit The imaging apparatus according to claim 1, wherein the encoding method setting command received by the receiving unit includes a corresponding encoding method. An imaging device that communicates with an external device via a network,
Imaging means for imaging a subject;
Storage control means for storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
Encoding means for encoding the captured image output from the imaging means based on the encoding method included in the distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit, and a second for including the second encoding method in the distribution setting information. Receiving means for receiving the encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received by the receiving unit is different from the encoding method included in the delivery setting information stored in the storage unit, an error response is sent to the external device via the network. A transmission means for transmitting;
An imaging apparatus comprising:   The transmission unit sends an error response to the external device when the first encoding method setting command is received by the receiving unit and the distribution setting information stored in the storage unit includes the second encoding method. The imaging apparatus according to claim 7, wherein the imaging apparatus transmits the information via a network.   The transmission unit sends an error response to the external device when the second encoding method setting command is received by the receiving unit and the distribution setting information stored in the storage unit includes the first encoding method. The imaging apparatus according to claim 8, wherein the imaging apparatus transmits the information via a network. An imaging device that communicates with an external device via a network,
Imaging means for imaging a subject;
Storage control means for storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
Encoding means for encoding the captured image output from the imaging means based on the encoding method included in the first distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Receiving means for receiving a second encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received by the receiving unit is different from the encoding method included in the delivery setting information stored in the storage unit, the first stored in the storage unit Generating means for generating second distribution setting information different from the distribution setting information;
An imaging apparatus comprising:   11. The imaging apparatus according to claim 10, wherein the second distribution setting information generated by the generating unit includes an encoding method corresponding to an encoding method setting command received by the receiving unit.   The first distribution setting information stored in the storage unit and the second distribution setting information generated by the generation unit are imaging element setting information related to the setting of the imaging element, and include the same imaging element setting information. The imaging apparatus according to claim 11. An imaging system comprising an imaging device and an external device that communicates with the imaging device via a network,
The imaging device
Imaging means for imaging a subject;
Storage control means for storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
Encoding means for encoding the captured image output from the imaging means based on the encoding method included in the delivery setting information stored in the storage unit;
With
The external device is
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. A transmission means for transmitting a second encoding method setting command to the imaging apparatus via a network;
The imaging device further includes:
The distribution setting information stored in the storage unit when the encoding method corresponding to the encoding method setting command transmitted by the transmission unit is different from the encoding method included in the distribution setting information stored in the storage unit. An imaging system comprising: a control unit that includes an encoding method corresponding to the encoding method setting command transmitted by the transmission unit. An imaging system comprising an imaging device and an external device that communicates with the imaging device via a network,
The imaging device
Imaging means for imaging a subject;
Storage control means for storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
Encoding means for encoding the captured image output from the imaging means based on the encoding method included in the delivery setting information stored in the storage unit;
With
The external device is
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit, and a second for including the second encoding method in the distribution setting information. Transmitting means for transmitting the encoding method setting command to the imaging apparatus via a network;
With
The imaging device further includes:
When the encoding method corresponding to the encoding method setting command transmitted by the transmission means is different from the encoding method included in the distribution setting information stored in the storage unit, an error response is sent to the external device via the network. An imaging system comprising notification means for notification. An imaging system comprising an imaging device and an external device that communicates with the imaging device via a network,
The imaging device
Imaging means for imaging a subject;
Storage control means for storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
Encoding means for encoding the captured image output from the imaging means based on the encoding method included in the first distribution setting information stored in the storage unit;
With
The external device is
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Transmitting means for transmitting a second encoding method setting command to the imaging apparatus via a network;
With
The imaging device further includes:
When the encoding method corresponding to the encoding method setting command transmitted by the transmission means is different from the encoding method included in the delivery setting information stored in the storage unit, the first stored in the storage unit An imaging system comprising: a generating unit that generates second distribution setting information different from distribution setting information. A method for controlling an imaging apparatus having an imaging unit for imaging a subject and communicating with an external apparatus via a network,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on an encoding method included in the distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Receiving a second encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received in the receiving step is different from the encoding method included in the distribution setting information stored in the storage unit, the distribution setting stored in the storage unit A control step of including in the information the encoding scheme corresponding to the encoding scheme setting command received in the reception step;
An image pickup apparatus control method comprising: A method for controlling an imaging apparatus having an imaging unit for imaging a subject and communicating with an external apparatus via a network,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding a captured image output from the imaging unit based on an encoding method included in distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit, and a second for including the second encoding method in the distribution setting information. A receiving step of receiving the encoding method setting command of the external device from the external device via a network;
When the encoding method corresponding to the encoding method setting command received in the receiving step is different from the encoding method included in the delivery setting information stored in the storage unit, an error response is sent to the external device via the network. Sending step to send in,
An image pickup apparatus control method comprising: A method for controlling an imaging apparatus having an imaging unit for imaging a subject and communicating with an external apparatus via a network,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on the encoding method included in the first distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Receiving a second encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received in the reception step is different from the encoding method included in the distribution setting information stored in the storage unit, the first stored in the storage unit Generating step of generating second distribution setting information different from the distribution setting information of
An image pickup apparatus control method comprising: An imaging system control method comprising: an imaging device having an imaging unit that images a subject; and an external device that communicates with the imaging device via a network.
In the imaging device,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on an encoding method included in the distribution setting information stored in the storage unit;
With
In the external device,
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. A transmission step of transmitting a second encoding method setting command to the imaging apparatus via a network;
In the imaging device,
When the encoding method corresponding to the encoding method setting command transmitted in the transmission step is different from the encoding method included in the distribution setting information stored in the storage unit, the distribution setting stored in the storage unit A control method for an imaging system, comprising: a control step for including in the information the encoding method corresponding to the encoding method setting command transmitted in the transmission step. An imaging system control method comprising: an imaging device having an imaging unit that images a subject; and an external device that communicates with the imaging device via a network.
In the imaging device,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on an encoding method included in the distribution setting information stored in the storage unit;
With
In the external device,
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit, and a second for including the second encoding method in the distribution setting information. A transmission step of transmitting the encoding method setting command of
With
In the imaging device,
When the encoding method corresponding to the encoding method setting command transmitted in the transmission step is different from the encoding method included in the distribution setting information stored in the storage unit, an error response is sent to the external device via the network. A control method for an imaging system, comprising a notification step of notifying in (1). An imaging system control method comprising: an imaging device having an imaging unit that images a subject; and an external device that communicates with the imaging device via a network.
In the imaging device,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on the encoding method included in the first distribution setting information stored in the storage unit;
With
In the external device,
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. A transmission step of transmitting a second encoding method setting command to the imaging apparatus via a network;
With
In the imaging device,
When the encoding method corresponding to the encoding method setting command transmitted in the transmission step is different from the encoding method included in the delivery setting information stored in the storage unit, the first stored in the storage unit An imaging system control method comprising: a generation step of generating second distribution setting information different from distribution setting information. A program for controlling an imaging device that has an imaging unit that images a subject and communicates with an external device via a network,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on an encoding method included in the distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Receiving a second encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received in the receiving step is different from the encoding method included in the distribution setting information stored in the storage unit, the distribution setting stored in the storage unit A control step of including in the information the encoding scheme corresponding to the encoding scheme setting command received in the reception step;
A program that causes a computer to execute. A program for controlling an imaging device that has an imaging unit that images a subject and communicates with an external device via a network,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding a captured image output from the imaging unit based on an encoding method included in distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit, and a second for including the second encoding method in the distribution setting information. A receiving step of receiving the encoding method setting command of the external device from the external device via a network;
When the encoding method corresponding to the encoding method setting command received in the receiving step is different from the encoding method included in the delivery setting information stored in the storage unit, an error response is sent to the external device via the network. Sending step to send in,
A program that causes a computer to execute. A program for controlling an imaging device that has an imaging unit that images a subject and communicates with an external device via a network,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on the encoding method included in the first distribution setting information stored in the storage unit;
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Receiving a second encoding method setting command from the external device via a network;
When the encoding method corresponding to the encoding method setting command received in the reception step is different from the encoding method included in the distribution setting information stored in the storage unit, the first stored in the storage unit Generating step of generating second distribution setting information different from the distribution setting information of
A program that causes a computer to execute. A program for controlling an imaging system including an imaging device having an imaging unit that images a subject and an external device that communicates with the imaging device via a network,
In the imaging device,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on an encoding method included in the distribution setting information stored in the storage unit;
To the computer,
In the external device,
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. Causing the computer to execute a transmission step of transmitting the second encoding method setting command to the imaging apparatus via a network;
In the imaging device,
When the encoding method corresponding to the encoding method setting command transmitted in the transmission step is different from the encoding method included in the distribution setting information stored in the storage unit, the distribution setting stored in the storage unit A program for causing a computer to execute a control step of including information in an encoding scheme corresponding to the encoding scheme setting command transmitted in the transmission step. A program for controlling an imaging system including an imaging device having an imaging unit that images a subject and an external device that communicates with the imaging device via a network,
In the imaging device,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on an encoding method included in the distribution setting information stored in the storage unit;
To the computer,
In the external device,
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit, and a second for including the second encoding method in the distribution setting information. A transmission step of transmitting the encoding method setting command of
To the computer,
In the imaging device,
When the encoding method corresponding to the encoding method setting command transmitted in the transmission step is different from the encoding method included in the distribution setting information stored in the storage unit, an error response is sent to the external device via the network. A program for causing a computer to execute a notification step for notification in the above. A program for controlling an imaging system including an imaging device having an imaging unit that images a subject and an external device that communicates with the imaging device via a network,
In the imaging device,
A storage control step of storing distribution setting information that can include a first encoding method or a second encoding method different from the first encoding method in a storage unit;
An encoding step of encoding the captured image output from the imaging unit based on the encoding method included in the first distribution setting information stored in the storage unit;
To the computer,
In the external device,
A first encoding method setting command for including the first encoding method in the distribution setting information stored in the storage unit; and a second encoding method for including the second encoding method in the distribution setting information. A transmission step of transmitting a second encoding method setting command to the imaging apparatus via a network;
To the computer,
In the imaging device,
When the encoding method corresponding to the encoding method setting command transmitted in the transmission step is different from the encoding method included in the delivery setting information stored in the storage unit, the first stored in the storage unit A program for causing a computer to execute a generation step of generating second distribution setting information different from distribution setting information.

Images