WO2020158093A1 - Control device and communication device - Google Patents

Abstract

This control device comprises: a reception unit that receives state information indicating a state pertaining to playback of a video represented by video data in a reception device that receives, from a distribution server, distribution data including video data; a generation unit that generates, on the basis of the state information received by the reception unit, designation information for designating a request for the data amount of the video data to be transmitted per unit time by the distribution server, said request being a request for the reception device to transmit to the distribution server; and a provision unit that provides, to the reception device, the designation information generated by the generation unit.

Description

Control device and communication device

The present invention relates to a control device and a communication device.

Patent Document 1 describes a distribution server that transmits video data to a receiving device. The distribution server described in Patent Document 1 determines the bit rate of moving image data based on the type of receiving device and the prediction of future communication band fluctuations.

International Publication No. 2008/108379

The distribution server described in Patent Document 1 determines the bit rate of video data regardless of the playback status of the video based on the video data in the receiving device. For this reason, even if there is a situation in which the receiving device cannot properly reproduce the moving image, the distribution server described in Patent Document 1 transmits moving image data of the moving image that cannot be properly reproduced by the receiving device. Therefore, when the distribution server described in Patent Document 1 is used, a problem may occur in the quality of moving image reproduction in the receiving device.

An object of the present invention is to provide a technique capable of suppressing the occurrence of a problem in the quality of moving image reproduction in a receiving device.

A control device according to an aspect of the present invention includes a receiving unit that receives status information indicating a status regarding reproduction of a moving image represented by the moving image data in a receiving device that receives distribution data including moving image data from a distribution server, and the receiving unit. Generating, based on the received status information, generation of specification information that specifies a request regarding the data amount of the moving image data that the distribution server should transmit per unit time, as a request that the reception device should transmit to the distribution server. And a providing unit that provides the designation information generated by the generating unit to the receiving device.

A communication device according to an aspect of the present invention is based on a reproduction executing unit that reproduces a moving image represented by moving image data included in distribution data transmitted from a distribution server, and a situation regarding reproduction of the moving image in the reproduction executing unit. A request determining unit that determines the content of the request regarding the data amount of the moving image data that the distribution server should transmit per unit time, and a request that transmits the request indicating the content determined by the request determining unit to the distribution server And a part.

According to an aspect of the present invention, it is possible to suppress a problem in the quality of playback of a moving image on the receiving device.

It is a figure which shows the whole structure of the delivery system 1 which concerns on 1st Embodiment. FIG. 6 is a sequence diagram for explaining an example of an operation of distribution system 1. It is a flow chart for explaining an example of Step S108. It is a flow chart for explaining an example of Step S108 in the 1st modification. It is a figure which shows the 2nd modification. It is a figure which shows an example of the learning model generation apparatus 50. It is a figure which shows the 3rd modification.

<A. First Embodiment>
FIG. 1 is a diagram showing the overall configuration of a distribution system 1 according to the first embodiment.

<A1. Delivery system 1>
As illustrated in FIG. 1, the distribution system 1 includes a distribution server 10, a user device 20, and a QoE (Quality of Experience) server 30. The distribution server 10, the user device 20, and the QoE server 30 can communicate with each other via the network NW. In the distribution system 1, the numbers of the distribution server 10, the user device 20, and the QoE server 30 are not limited to “1”. For example, the distribution system 1 may include a plurality of distribution servers 10, a plurality of user devices 20, and a plurality of QoE servers 30. The user device 20 is an example of a receiving device and a delivery destination device. The QoE server 30 is an example of a control device.

<A2. Distribution server 10>
The distribution server 10 transmits distribution data including moving image data indicating a moving image and sound data indicating sound to the user device 20. The distribution data is, for example, data representing a movie. The distribution data is not limited to data representing a movie, but may be data representing a television program, for example. Each of the moving image data and the audio data is encoded data. In the distribution data, the reproduction timing of the moving image based on the moving image data and the reproduction timing of the sound based on the audio data are defined in advance. The frame rate of the moving image indicated by the moving image data is fixed to the reference frame rate. The reference frame rate is, for example, 30 fps (Frames Per Second). The reference frame rate is not limited to 30 fps and may be higher or lower than 30 fps. The frame rate of the moving image indicated by the moving image data may be changed.

The distribution server 10 is composed of a computer system including a communication device 101, a storage device 102, and a processing device 103. In this specification, the term “device” in a communication device, a storage device, a processing device, an input device described below, and a display device described below may be replaced with another term such as a circuit, a device, or a unit. Each element of the distribution server 10 is mutually connected by one or two or more buses. Each element of the distribution server 10 is composed of a single device or a plurality of devices.

The communication device 101 communicates with another device, for example, the user device 20, via the network NW. The communication device 101 is also called, for example, a network device, a network controller, a network card, or a communication module.

The storage device 102 is a recording medium that can be read by the processing device 103. The storage device 102 stores a plurality of programs including a control program executed by the processing device 103, various data used by the processing device 103, and various distribution data. The storage device 102 is configured by at least one of a recording medium such as a ROM (Read Only Memory), an EPROM (Erasable Programmable ROM), an EEPROM (Electrically Erasable Programmable ROM), and a RAM (Random Access Memory).

The processing device 103 is a processor that controls the distribution server 10. The processing device 103 is composed of, for example, one or more chips. As an example, the processing device 103 includes an interface with peripheral devices and a central processing unit (CPU). The central processing unit includes an arithmetic unit, a register and the like. Even if some or all of the functions of the processing device 103 are executed by hardware such as DSP (Digital Signal Processor), ASIC (Application Specific Integrated Circuit), PLD (Programmable Logic Device), FPGA (Field Programmable Gate Array), etc. Good. The processing device 103 executes various processes in parallel or sequentially.

The processing device 103 reads the control program from the storage device 102. The processing device 103 functions as the distribution control unit 110 by executing the control program.

The delivery control unit 110 is an example of a functional block of the processing device 103. The distribution control unit 110 may be configured by hardware such as DSP, ASIC, PLD, or FPGA. The delivery control unit 110 controls transmission of delivery data. For example, the distribution control unit 110 transmits distribution data to the user device 20 in response to a request from the user device 20. Further, the distribution control unit 110 adjusts the bit rate of the moving image data included in the distribution data in response to the request from the user device 20. The bit rate of moving image data represents the amount of moving image data transmitted per second. One second is an example of unit time. The unit time is not limited to 1 second and may be longer or shorter than 1 second.

<A3. User device 20>
The user device 20 is, for example, a smartphone. The user device 20 is not limited to a smartphone. For example, the user device 20 may be a laptop computer, a wearable terminal, a tablet terminal, a desktop personal computer, or the like. The user device 20 receives the distribution data from the distribution server 10.

The user device 20 is configured by a computer system including an input device 201, a display device 202, a speaker 203, a communication device 204, a storage device 205, and a processing device 206. Each element of the user device 20 is connected to each other by one or more buses. Also, each element of the user device 20 is configured by one or more devices.

The input device 201 is a device for inputting information used by the user device 20 to the user device 20. The input device 201 receives user input such as instructions or questions from the user. For example, the input device 201 receives an operation for inputting codes such as numbers and letters to the user device 20, and an operation for selecting an icon displayed on the display device 202. The input device 201 is, for example, a touch panel that detects contact with the display surface of the display device 202. The input device 201 is not limited to the touch panel. For example, the input device 201 may be a keyboard, a mouse, a switch, a button, or the like.

The display device 202 displays various images under the control of the processing device 206. For example, the display device 202 displays the icon and the moving image based on the moving image data included in the distribution data at the same time or at mutually different timings. The display device 202 is, for example, a liquid crystal display panel. The display device 202 is not limited to a liquid crystal display panel. For example, the display device 202 may be an organic EL (Electro Luminescence) display panel or the like.

The speaker 203 outputs various sounds under the control of the processing device 206. For example, the speaker 203 outputs a sound based on the sound data included in the distribution data.

The communication device 204 communicates with other devices, for example, the distribution server 10 and the QoE server 30 via the network NW. The communication device 204 is also called, for example, a network device, a network controller, a network card, or a communication module.

The storage device 205 is a recording medium that can be read by the processing device 206. The storage device 205 stores a plurality of programs including a control program executed by the processing device 206, and various data used by the processing device 206. The storage device 205 includes, for example, a non-volatile memory and a volatile memory. The non-volatile memory is, for example, ROM, EPROM, or EEPROM. The volatile memory is, for example, a RAM. The volatile memory included in the storage device 205 is used as a working memory of the processing device 206.

The processing device 206 is a processor that controls the user device 20. The processing device 206 includes, for example, one or more chips. As an example, the processing unit 206 is configured by a central processing unit (CPU). Some or all of the functions of the processing device 206 may be realized by hardware such as DSP, ASIC, PLD, or FPGA. The processing device 206 executes various processes in parallel or sequentially.

The processing device 206 reads the control program from the storage device 205. The processing device 206 functions as the reproduction executing unit 210 and the operation control unit 220 by executing the control program.

The reproduction execution unit 210 and the operation control unit 220 are examples of functional blocks of the processing device 206. Both or a part of the reproduction execution unit 210 and the operation control unit 220 may be configured by hardware such as DSP, ASIC, PLD, or FPGA.

The reproduction execution unit 210 reproduces a moving image and a sound based on the distribution data. For example, the reproduction executing unit 210 decodes distribution data received from the distribution server 10 by the communication device 204, specifically, each of moving image data and audio data. The reproduction executing unit 210 provides the display device 202 with the image information that is the decoding result of the moving image data, thereby causing the display device 202 to display the moving image indicated by the moving image data. The reproduction executing unit 210 provides the speaker 203 with the audio information that is the decoding result of the audio data, so that the speaker 203 outputs the audio indicated by the audio data.

The operation control unit 220 controls the operation of the user device 20. For example, the operation control unit 220 transmits, from the communication device 204 to the QoE server 30, a reproduction log indicating a situation regarding reproduction of a moving image in the user device 20. The reproduction log is an example of status information.

The playback log indicates the status of the number of unplayed image frames (hereinafter referred to as “non-playback image frames”) among the consecutive image frames that make up the video based on the video data, as the status related to the video playback. The reproduction log indicates the number of non-reproduction image frames, for example, the number of continuous non-reproduction image frames (hereinafter referred to as “number of consecutive frame drops”). The number of consecutive frames dropped can also be referred to as “the number of consecutive unreproduced image frames”. As an example, if the image frames with index numbers “3” to “8” are not played back among the nine consecutive image frames with index numbers “1” to “9”, the playback log is "6" is shown as the number of drops.

In addition, the reproduction log indicates a situation regarding the reproduction of the moving image, further, a time difference between the reproduction timing of the sound to be reproduced together with the moving image (the sound reproduced based on the sound data) and the moving image (hereinafter referred to as “sound and moving image”). (Referred to as “deviation timing deviation time”). The discrepancy time between the reproduction timings of the audio and the moving image means the discrepancy time between the reproduction timing of the audio and the actual reproduction timing of the moving image to be reproduced in synchronization with the reproduction timing of the audio. The time difference between the reproduction timings of the sound and the moving image is an example of the situation of the difference between the reproduction timings of the sound and the moving image.

The status of the number of unplayed image frames, the number of consecutive frames dropped, the status of audio/video playback timing deviation, and the audio/video playback timing deviation time are each related to video playback disturbance. Is an example.

The operation control unit 220 receives, from the QoE server 30 via the communication device 204, designation information designating a request that the user device 20 should transmit to the distribution server 10. The designation information designates a request regarding the amount of moving image data that the distribution server 10 should transmit per unit time, as a request that the user device 20 should transmit to the distribution server 10. Specifically, the designation information is the content of the request that the user device 20 should transmit to the distribution server 10, that is, the content of the request regarding the data amount of the motion picture data that the distribution server 10 should transmit per unit time. Specify the bit rate of.

Note that if the frame rate of the moving image is fixed, the amount of moving image data transmitted by the distribution server 10 per unit time can be adjusted by adjusting the resolution of the moving image. Therefore, when the frame rate of the moving image is fixed, the resolution of the moving image may be designated as the content of the request that the user device 20 should transmit to the distribution server 10 in the designation information.

Further, when the resolution of the moving image is fixed, the amount of moving image data transmitted by the distribution server 10 per unit time can be adjusted by adjusting the frame rate of the moving image. Therefore, when the resolution of the moving image is fixed, the frame rate of the moving image may be designated as the content of the request that the user device 20 should transmit to the distribution server 10 in the designation information.

Upon receiving the designation information from the QoE server 30, the operation control unit 220 transmits the request designated in the designation information to the distribution server 10.

<A4. QoE server 30>
The QoE server 30 generates designation information, that is, designation information that designates a request that the user device 20 should transmit to the distribution server 10.

The QoE server 30 is composed of a computer system including a communication device 301, a storage device 302, and a processing device 303. Each element of the QoE server 30 is mutually connected by one or more buses. Each element of the QoE server 30 is composed of one or more devices.

The communication device 301 communicates with another device, for example, the user device 20, via the network NW. The communication device 301 is also called, for example, a network device, a network controller, a network card, or a communication module.

The storage device 302 is a recording medium that can be read by the processing device 303. The storage device 302 stores a plurality of programs including a control program executed by the processing device 303, and various data used by the processing device 303. The storage device 302 is configured by at least one of recording media such as ROM, EPROM, EEPROM, and RAM.

The processing device 303 is a processor that controls the QoE server 30. The processing device 303 is composed of, for example, one or more chips. As an example, the processing device 303 is configured by a central processing unit (CPU). Some or all of the functions of the processing device 303 may be realized by hardware such as DSP, ASIC, PLD, or FPGA. The processing device 303 executes various processes in parallel or sequentially.

The processing device 303 reads the control program from the storage device 302, for example. The processing device 303 implements the receiving unit 310, the generating unit 320, and the providing unit 330 by executing the control program. The receiving unit 310, the generating unit 320, and the providing unit 330 are examples of functional blocks of the processing device 303. All or part of the receiving unit 310, the generating unit 320, and the providing unit 330 may be configured by hardware such as DSP, ASIC, PLD, or FPGA.

The receiving unit 310 receives a reproduction log (a reproduction log indicating a status regarding reproduction of a moving image performed by the user device 20) from the user device 20. For example, the receiving unit 310 receives, via the communication device 301, the reproduction log voluntarily transmitted by the user device 20. Note that the receiving unit 310 transmits, via the communication device 301, a reproduction log request transmitted to the user device 20 via the communication device 301, and the reproduction log transmitted by the user device 20 in response to the reproduction log request. Good.

The generation unit 320 generates specification information that specifies a request that the user device 20 should send to the distribution server 10 based on the reproduction log received by the reception unit 310.

As illustrated in FIG. 1, the generation unit 320 includes a determination unit 321 and a determination unit 322. The determination unit 321 and the determination unit 322 are each an example of a functional block of the generation unit 320. All or part of the determination unit 321 and the determination unit 322 may be configured by hardware such as DSP, ASIC, PLD, or FPGA.

The determination unit 321 determines whether or not the data amount of moving image data that the user device 20 can process per unit time is equal to or larger than the reference data amount, based on the reproduction log received by the reception unit 310. The reference data amount is predetermined.

The amount of moving image data that the user device 20 can process per unit time is within the unit time, for example, while satisfying the reference condition that the time difference between the reproduction timings of the sound and the moving image is 0.1 second without generating a non-reproduced image frame. In addition, it means the maximum value of the amount of moving image data that can be processed by the user device 20. The standard conditions can be changed as appropriate. For example, the reference condition may be a condition that non-reproduced image frames do not occur consecutively and the time difference between the reproduction timings of the audio and the moving image is within 0.2 seconds.

In the following, a device in which the data amount of moving image data that can be processed per unit time is less than the reference data amount is referred to as a “problem device”.
When the word “problem device” is used, the operation of the determination unit 321 means “an operation of determining whether or not the user device 20 is a problem device based on the reproduction log received by the reception unit 310”.
Furthermore, if the determination unit 32 determines that the amount of moving image data that the user device 20 can process per unit time is less than the reference data amount, the determination unit determines that the user device 20 is a problem device. When 32 determines.”
Further, “when the determination unit 32 determines that the amount of moving image data that the user device 20 can process per unit time is equal to or greater than the reference data amount”, the determination unit 32 determines that the user device 20 is not a problem device. If you do.

The determination unit 322 determines the content of the request specified by the designation information, that is, the content of the request that the user device 20 should transmit to the distribution server 10, based on the determination result of the determination unit 321, and further, the distribution server 10 is a unit. The content of the request regarding the amount of moving image data to be transmitted per hour is determined.

When the determination unit 321 determines that the data amount of the moving image data that the user device 20 can process per unit time is less than the reference data amount, the determination unit 322 determines the moving image data that the distribution server 10 should transmit per unit time. The content of the request to make the data amount smaller than the reference data amount (the content of the bit rate of the moving image data) is determined.

When the determination unit 321 determines that the data amount of the moving image data that the user device 20 can process per unit time is equal to or larger than the reference data amount, the determination unit 322 causes the distribution server 10 to determine the moving image data to be transmitted per unit time. The content of the request to set the data amount to the data amount equal to or larger than the reference data amount (the content of the request for the bit rate of moving image data) is determined.
The determining unit 322 may change the data amount equal to or larger than the reference data amount according to the reproduction log. For example, the determining unit 322 may increase the data amount equal to or greater than the reference data amount as the number of consecutive frames dropped indicated by the reproduction log decreases. Further, the determination unit 322 may increase the data amount equal to or larger than the reference data amount as the time difference between the reproduction timings of the audio and the moving image decreases.

When the user device 20 determines the content of the request to be transmitted to the distribution server 10, the determination unit 322 generates designation information designating the request indicating the determined content.

The providing unit 330 provides the designation information generated by the generating unit 320 (specifically, the determining unit 322) from the communication device 301 to the user device 20.

<A5. Operation of distribution system 1>
FIG. 2 is a sequence diagram for explaining an example of the operation of the distribution system 1. Hereinafter, in order to simplify the description, in the communication in the distribution server 10, the user device 20, and the QoE server 30, the reference to the communication devices 101, 204, and 301 will be omitted.

When the user inputs a request for distribution data to the input device 201 of the user device 20, the operation control unit 220 transmits the request for distribution data to the distribution server 10 in response to the request from the user (step S100). The request for distribution data includes identification information of the distribution data.

Upon receiving the request for distribution data, the distribution control unit 110 of the distribution server 10 reads the distribution data corresponding to the request for distribution data from the storage device 102. The distribution data is encoded data as described above. Subsequently, the distribution control unit 110 starts transmitting the distribution data read from the storage device 102 to the user device 20 (step S102).

The reproduction execution unit 210 of the user device 20 starts reproduction of a moving image and audio based on the distribution data transmitted from the distribution server 10 (step S104).

An example of step S104 is as follows.
The reproduction execution unit 210 generates image information by decoding the moving image data included in the distribution data. Further, the reproduction executing unit 210 generates audio information by decoding the audio data included in the distribution data.

If the distribution data is encrypted by DRM (Digital Rights Management), the reproduction executing unit 210 first decrypts the distribution data. Subsequently, the reproduction executing unit 210 generates image information and audio information by decoding the decrypted distribution data.

Then, the reproduction executing unit 210 provides the image information to the display device 202. Upon receiving the image information, the display device 202 displays the moving image indicated by the moving image data based on the image information. In addition, the reproduction executing unit 210 provides audio information to the speaker 203. Upon receiving the voice information, the speaker 203 outputs the voice indicated by the voice data based on the voice information.
The above is an example of step S104.

Then, the operation control unit 220 outputs a reproduction log (hereinafter, referred to as “first reproduction log”) indicating a situation related to the reproduction of the moving image in a period from the start time of the reproduction of the moving image to the first time point after the start time. It is transmitted to the QoE server 30 (step S106). The first reproduction log is an example of first status information. The length of the period from the start point of the reproduction of the moving image to the first point (hereinafter referred to as “first period”) is, for example, 10 seconds. The length of the first period may be longer or shorter than 10 seconds. The first reproduction log indicates both the number of consecutive frame drops in the first period and the time difference between the reproduction timings of the audio and the moving image in the first period.

When the reception unit 310 of the QoE server 30 receives the first reproduction log from the user device 20 as the reproduction log, the determination unit 321 determines whether the user device 20 is the problem device based on the reproduction log. (Step S108). That is, the determination unit 321 determines whether the data amount of moving image data that the user device 20 can process per unit time is equal to or greater than the reference data amount, based on the reproduction log.

In step S108, the determination unit 321 determines that the user device 20 has a problem based on either or both of the number of consecutive frame drops indicated in the reproduction log and the time difference between the reproduction timings of the audio and the moving image indicated in the reproduction log. It is determined whether or not the device.

For example, the determination unit 321 determines that the user device 20 is the problem device when the number of consecutive frame drops exceeds the first determination value. The first determination value is “10”, for example. The first determination value is not limited to “10” and may be larger or smaller than “10”.

The determination unit 321 also determines that the user device 20 is the problem device when the time difference between the reproduction timings of the audio and the moving image exceeds the second determination value. The second determination value is “1 second”, for example. The second determination value is not limited to "1 second", and may be longer or shorter than "1 second".

When the number of dropped frames does not exceed the first determination value and the time difference between the playback timings of the audio and the moving image does not exceed the second determination value, the determination unit 321 determines that the user device 20 has the problem device. Determine not.

Note that an example of the above determination method in step S108 will be described later with reference to FIG.

Subsequently, the determination unit 322 determines the content of the request designated by the designation information, specifically, the bit rate of the moving image data that the user device 20 should request the distribution server 10 based on the determination result of the determination unit 321. To do.
When the user device 20 is determined to be the problem device, the determination unit 322 sets the data amount of the moving image data to be transmitted by the distribution server 10 per unit time to a data amount smaller than the reference data amount. The bit rate is determined as the content of the request designated by the designation information.
When it is determined that the user device 20 is not a problem device, the determining unit 322 sets the data amount of the moving image data to be distributed by the distribution server 10 per unit time to a data amount of the reference data amount or more. The bit rate is determined as the content of the request designated by the designation information.
The determination unit 322 determines the bit rate of moving image data to be determined when the user device 20 is determined to be a problem device, rather than the bit rate of moving image data to be determined when the user device 20 is determined to be not a problem device. make low.
Subsequently, the determining unit 322 generates designation information that designates the bit rate of the moving image data that the user device 20 should request from the distribution server 10 as the content of the request that the user device 20 should transmit to the distribution server 10 (step). S110).

Subsequently, the providing unit 330 provides the designation information generated by the determining unit 322 to the user device 20 (step S112).

Upon receiving the designation information, the operation control unit 220 of the user device 20 transmits the request designated by the designation information to the distribution server 10 (step S114).

Upon receiving the request from the user device 20, the distribution control unit 110 of the distribution server 10 transmits the moving image data to the user device 20 at the requested bit rate (step S116).
For example, when the distribution control unit 110 receives a request at the time when a part of the distribution data is transmitted, the distribution control unit 110 sets the bit rate of the moving image data included in a part of the distribution data to be transmitted to the requested bit data. To do.

Therefore, it is possible to adjust the data amount per unit time of the moving image data transmitted to the user device 20, depending on the situation regarding the reproduction of the moving image performed by the user device 20.

Therefore, for example, when the number of consecutive frames dropped exceeds the first determination value due to the low specifications (low processing performance) of the user device 20, the moving image data transmitted to the user device 20 per unit time The amount of data is less than the standard amount of data. Therefore, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20 having low specifications, that is, the user device 20 having low processing performance.

In addition, when the number of consecutive frames dropped exceeds the first determination value due to the occurrence of a defect in the user device 20, the data amount of moving image data transmitted to the user device 20 per unit time becomes smaller than the reference data amount. .. Therefore, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20 in which the malfunction has occurred.

Further, even when the number of dropped frames exceeds the first determination value due to the high processing load on the user device 20, the data amount of the moving image data transmitted to the user device 20 per unit time is smaller than the reference data amount. Become. Therefore, it is possible to suppress a problem in the quality of moving image reproduction in the user device 20 having a high processing load.

After step S116, a series of operations A from step S106 to step S116 is repeated regularly or irregularly during transmission of distribution data.

For example, the operation control unit 220 may generate a reproduction log indicating a situation regarding reproduction of a moving image in a period from the second time point after the start time point of the reproduction of the moving image performed by the user device 20 to the third time point after the second time point. , QoE server 30. Hereinafter, the period from the second time point to the third time point will be referred to as a “second time period”. The length of the second period is, for example, 10 seconds. The length of the second period may be longer or shorter than 10 seconds. The second time point is, for example, a time point 10 minutes after the start time point of the reproduction of the moving image performed by the user device 20. The second time point may be before or after the time point 10 minutes have elapsed from the start time point of the reproduction of the moving image performed by the user device 20. In the present embodiment, the second time point is a time point after the time point when the previous step S116 is completed. Hereinafter, the reproduction log indicating the situation regarding the reproduction of the moving image in the second period is referred to as a “second reproduction log”. The second reproduction log is an example of second status information. The receiving unit 310 receives the second reproduction log from the operation control unit 220 as the reproduction log.

Since a series of operations A is repeated during the transmission of the distribution data, the data per unit time of the moving image data may be changed depending on the situation regarding the reproduction of the moving image performed by the user device 20, even after the period for starting the reproduction of the moving image. The amount is adjusted. Note that the moving image reproduction start period is a period from the start time of step S102 to the end time of the first step S116.

Since a series of operations A is repeated during transmission of the distribution data, even if the processing load of the user device 20 increases after the start period of the reproduction of the moving image, for example, there is a problem in the quality of the reproduction of the moving image in the user device 20. Can be suppressed.

Further, when the processing load of the user device 20 is high during the start period of the playback of the moving image and low after the start period of the playback of the moving image is reached, per unit time of the moving image data after the start period of the playback of the moving image The amount of data can be increased. For this reason, when the user device 20 that has temporarily become the problem device ceases to be the problem device, the distribution server 10 can increase the data amount of the moving image data transmitted to the user device 20 per unit time to the reference data amount or more. ..

<A6. Example of step S108>
FIG. 3 is a flowchart for explaining an example of step S108.
The determination unit 321 determines that the user device 20 is the problem device (step S202) when the number of consecutive frame drops indicated in the reproduction log exceeds the first determination value (step S200: YES). When the reproduction log indicates the transition of the number of consecutive frames dropped, the determination unit 321 determines in step S200 that the user device 20 determines that the maximum number of consecutive frames dropped indicated in the reproduction log exceeds the first determination value. Determined to be the problem device.

Further, when the time difference between the reproduction timings of the sound and the moving image shown in the reproduction log exceeds the second determination value (step S204: YES), the determination unit 321 determines that the user device 20 is the problem device (step S202). ). When the reproduction log indicates the transition of the time difference between the reproduction timings of the audio and the moving image, the determination unit 321 determines in step S204 that the maximum value of the time difference between the reproduction timings of the audio and the moving image is the second. When it exceeds the determination value, it is determined that the user device 20 is the problem device.

On the other hand, when the number of dropped frames does not exceed the first determination value (step S200: NO) and the time difference between the reproduction timings of the audio and the moving image does not exceed the second determination value (step S204: NO), the determination unit 321 determines that the user apparatus 20 is not a problem apparatus (step S206).

In the process illustrated in FIG. 3, step S200 and step S204 may be interchanged with each other.

In the situation where the reproduction log indicates the number of consecutive frames dropped without indicating the time difference between the reproduction timing of the audio and the moving image, the determination unit 321 determines that the number of consecutive frames dropped exceeds the first determination value. Is determined to be the problem device. The determination unit 321 determines that the user device 20 is not a problem device when the number of consecutive frame drops does not exceed the first determination value.

In a situation where the reproduction log indicates the time difference between the reproduction timings of the audio and the video without indicating the number of consecutive frames dropped, the determination unit 321 determines that the time difference between the reproduction timings of the audio and the video exceeds the second determination value. It is determined that the user device 20 is the problem device. The determination unit 321 determines that the user device 20 is not a problem device when the time difference between the audio and the video does not exceed the second determination value.

<A7. Summary of First Embodiment>
In the first embodiment, the receiving unit 310 receives a reproduction log indicating a situation regarding reproduction of a moving image based on moving image data in the user device 20. Based on the reproduction log received by the receiving unit 310, the generating unit 320 requests the user device 20 to transmit to the distribution server 10 as a request regarding the data amount of moving image data that the distribution server 10 should transmit per unit time (for example, a request). , Bit information of moving image data) is generated. The providing unit 330 provides the designation information generated by the generating unit 320 to the user device 20.
Therefore, it is possible to adjust the data amount per unit time of the moving image data transmitted to the user device 20, based on the situation regarding the reproduction of the moving image in the user device 20. Therefore, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20.

The determination unit 321 determines whether or not the amount of moving image data that the user device 20 can process per unit time is equal to or larger than the reference data amount, based on the reproduction log received by the reception unit 310. The determination unit 322 determines the content of the request designated by the designation information (for example, the bit rate of the moving image data) based on the determination result of the determination unit 321.
Therefore, depending on whether or not the data amount of the moving image data that the user device 20 can process per unit time is greater than or equal to the reference data amount, that is, depending on whether or not the user device 20 is a problem device, The amount of data specified by information can be changed.

When the determination unit 321 determines that the data amount of the moving image data that the user device 20 can process per unit time is less than the reference data amount, the determination unit 322 determines the moving image data that the distribution server 10 should transmit per unit time. Setting the data amount to be smaller than the reference data amount is determined as the content of the request designated by the designation information.
Therefore, if the amount of moving image data that the user device 20 can process per unit time is less than the reference data amount, that is, if the user device 20 is a problem device, the processing load of reproduction on the user device 20 is suppressed. Therefore, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20.

The receiving unit 310 receives the first reproduction log as the reproduction log. The first reproduction log indicates a situation related to the reproduction of the moving image in the period from the start time of the reproduction of the moving image performed by the user device 20 to the first time point after the start time. Therefore, it is possible to provide moving image data of a data amount per unit time suitable for the ability of the user device 20 for reproducing moving images at the start stage of reproducing moving images.

The receiving unit 310 also receives the second reproduction log as the reproduction log. The second reproduction log indicates the situation regarding the reproduction of the moving image in the period from the second time point after the start time point of the reproduction of the moving image performed by the user device 20 to the third time point after the second time point. For this reason, it is possible to provide moving image data of a data amount per unit time suitable for the moving image reproducing capability of the user device 20 in the stage after the second time point.

Note that the receiving unit 310 may receive only one of the first reproduction log and the second reproduction log as the reproduction log.

-The situation regarding the playback of the video indicated by the playback log includes the situation regarding the disturbance in the playback of the video. Therefore, the data amount per unit time of the moving image data transmitted to the user device 20 can be adjusted according to the disturbance in the reproduction of the moving image performed by the user device 20. Therefore, the amount of moving image data transmitted per unit time when the disturbance is generated in the reproduction of the moving image performed by the user device 20 is calculated as the data amount of the moving image data transmitted per unit time when the disturbance is not generated. It can be smaller than the amount of data. Therefore, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20.

The status related to the playback of the video indicated by the playback log includes the status of the number of unplayed image frames. Therefore, for example, the amount of moving image data transmitted to the user device 20 per unit time can be adjusted according to the disturbance of the moving image caused by the non-reproduced image frame.

As an example of the situation of the number of unreproduced image frames, the number of consecutive frames dropped can be mentioned. The situation of the number of unreproduced image frames is not limited to the number of consecutive frames dropped. For example, the number of non-reproduction image frames in a unit time may be used as the number of non-reproduction image frames.

In addition, the situation regarding the reproduction of the moving image indicated by the reproduction log is such that the reproduction timing of the audio reproduced in the user device 20 based on the audio data and the moving image reproduced in the user device 20 based on the moving image data is deviated. In addition, it includes the time difference between the playback timings of audio and video. When the reproduction timing of the audio and the video is deviated, the synchronization between the audio and the video is disturbed. One of the causes of the discrepancy between the reproduction timing of the audio and the moving image is that the processing time for reproducing the moving image based on the moving image data is longer than the processing time for reproducing the audio based on the audio data. Occurs.
In the present embodiment, the data amount of the moving image data transmitted to the user device 20 per unit time is adjusted according to the difference between the reproduction timings of the sound and the moving image. For this reason, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20.

Note that the situation relating to the disorder in the playback of the video may include only one of the status of the number of non-playback image frames and the status of the timing difference between the playback timing of the audio and the video. In this case, the amount of information in the reproduction log can be reduced as compared with the case where the reproduction log shows both the situation of the number of non-reproduced image frames and the situation of deviation of the reproduction timing of audio and moving image.

<B. Modification>
A specific mode of modification of the above-exemplified mode will be described below. Two or more aspects arbitrarily selected from the following exemplifications may be appropriately merged as long as they do not conflict with each other.

<B1. First Modification>
In the first embodiment, the situation regarding the reproduction of the moving image indicated by the reproduction log is not only the situation regarding the disturbance in the reproduction of the moving image, but also the situation of the load of the reproducing apparatus that reproduces the moving image based on the moving image data included in the distribution data. May be included. Hereinafter, the load status of the playback device that plays back a video based on the video data is also referred to as “apparatus load status”.

The device load status indicates, for example, a decoding time required for the user device 20 to decode the distribution data (hereinafter, simply referred to as “decoding time”). Generally, since the decoding time of moving image data is longer than the decoding time of audio data, the time required for decoding moving image data is used as the decoding time included in the load status of the device.

The load status of the device further indicates the usage rate of the processing device (CPU) 206 during playback of the moving image (hereinafter, simply referred to as the “usage rate of the processing device 206”).

The load status of the device further indicates the usage rate of the working memory in the storage device 205 (hereinafter, simply referred to as the “working memory usage rate”) when the moving image is played back.

The load status of the device further indicates a descrambling time (hereinafter referred to as a “decrypt time”) required by the user device 20 for a decryption for canceling the encryption of the distribution data (for example, encryption using DRM). The encryption of distribution data is not limited to the encryption using DRM. Generally, since the decryption time of moving image data is longer than the decryption time of audio data, the decryption time of moving image data is used as the decryption time included in the load status of the device.

Note that the load status of the device may indicate only part of the decoding time, the usage rate of the processing device 206, the usage rate of the working memory, and the decryption time, instead of the whole.

Also, the status regarding the playback of the video indicated by the playback log may indicate the bit rate of the video data. The higher the bit rate of moving image data, the higher the load on the device.

In the following, the reproduction log shows the number of consecutive dropped frames, the time difference between the reproduction timings of audio and moving images, the bit rate of moving image data, the decoding time, the usage rate of the processing device 206, and the usage rate of the working memory. , Decryption time, will be described.

In the first modification, step S108 illustrated in FIG. 2 is executed, for example, as illustrated in FIG.
In FIG. 4, the same processing as the processing shown in FIG. 3 is given the same reference numeral as an example of step S108. Hereinafter, the processing illustrated in FIG. 4 will be mainly described with respect to differences from the processing illustrated in FIG.

When the time difference between the reproduction timing of the audio and the moving image does not exceed the second determination value in step S204, the determination unit 321 determines whether the bit rate of the moving image data exceeds the third determination value (step S300). .. The third determination value is a preset value. When the reproduction log indicates the transition of the bit rate of the moving image data, the determination unit 321 determines in step S300 whether the maximum bit rate of the moving image data shown in the reproduction log exceeds the third determination value. To judge.

When it is determined in step S300 that the bit rate of the moving image data exceeds the third determination value, the number of consecutive frame drops does not exceed the first determination value, and the time difference between the reproduction timings of the audio and the moving image is the second time. It has already been determined that the judgment value is not exceeded. That is, when a positive determination is made in step S300, even if the bit rate of the moving image data is higher than the third determination value, the number of consecutive dropped frames does not exceed the first determination value, and the audio and moving image The reproduction timing deviation time does not exceed the second determination value. Therefore, the determination unit 321 advances the process to step S206. That is, the determination unit 321 determines that the user device 20 is not the problem device.

If the bit rate of the moving image data does not exceed the third determination value in step S300, the determination unit 321 determines whether the decoding time exceeds the fourth determination value (step S302). The fourth determination value is a preset value. When the reproduction log shows the transition of the decoding time, the determination unit 321 determines in step S302 whether the maximum value of the decoding time shown in the reproduction log exceeds the fourth determination value.

If the decoding time exceeds the fourth judgment value in step S302, the judgment unit 321 advances the process to step S202. That is, since the bit rate of the moving image data is lower than the third determination value, but the decoding time exceeds the fourth determination value, the determination unit 321 determines that the user device 20 is the problem device.

If the decoding time does not exceed the fourth determination value in step S302, the determination unit 321 determines whether the decryption time exceeds the fifth determination value (step S304). The fifth determination value is a preset value. When the reproduction log shows the transition of the decryption time, in step S304, the determination unit 321 determines whether or not the maximum value of the decryption time shown in the reproduction log exceeds the fifth determination value.

If the decryption time exceeds the fifth judgment value in step S304, the judgment unit 321 advances the process to step S202. That is, since the decryption time exceeds the fifth determination value even though the bit rate of the moving image data is lower than the third determination value, the determination unit 321 determines that the user device 20 is the problem device.

If the decryption time does not exceed the fifth determination value in step S304, the determination unit 321 determines whether the usage rate of the processing device 206 exceeds the sixth determination value (step S306). The sixth determination value is a preset value. When the reproduction log indicates the transition of the usage rate of the processing device 206, in step S306, the determination unit 321 determines whether the maximum value of the usage rate of the processing device 206 indicated in the reproduction log exceeds the sixth determination value. Determine whether or not.

If the usage rate of the processing device 206 exceeds the sixth determination value in step S306, the determination unit 321 advances the process to step S202. That is, since the bit rate of the moving image data is lower than the third determination value, but the usage rate of the processing device 206 exceeds the sixth determination value, the determination unit 321 determines that the user device 20 is the problem device.

If the usage rate of the processing device 206 does not exceed the sixth determination value in step S306, the determination unit 321 determines whether the usage rate of the working memory exceeds the seventh determination value (step S308). The seventh determination value is a preset value. When the reproduction log shows the transition of the usage rate of the work memory, the determination unit 321 determines in step S308 whether the maximum value of the usage rate of the work memory shown in the reproduction log exceeds the seventh determination value. To judge.

If the usage rate of the working memory exceeds the seventh determination value in step S308, the determination unit 321 advances the process to step S202. That is, since the bit rate of the moving image data is lower than the third determination value, but the usage rate of the working memory exceeds the seventh determination value, the determination unit 321 determines that the user device 20 is the problem device.

If the usage rate of the working memory does not exceed the seventh determination value in step S308, the determination unit 321 advances the process to step S206. That is, the determination unit 321 determines that the user device 20 is not the problem device.

Of the processing illustrated in FIG. 4, all or part of steps S200, S204, and S300 may be omitted. Steps S200 and S204 may be replaced with each other. Step S300 may be moved before step S200 or between step S200 and step S204. The order of steps S302, S304, S306 and S308 can be changed. Part of steps S302, S304, S306 and S308 may be omitted.

According to the first modified example, the status regarding the playback of the video indicated by the playback log includes the load status of the device that is playing back the video based on the video data. Therefore, the data amount per unit time of the moving image data transmitted to the user device 20 can be adjusted according to the load condition of the user device 20 which is reproducing the moving image based on the moving image data. Therefore, it is possible to suppress the occurrence of a problem in the reproduction quality of the moving image in the user device 20 due to the load condition of the user device 20.

<B2. Second Modification>
In the first embodiment and the first modification, the determination unit 321 may execute the determination using the learning model 302a illustrated in FIG. 5, elements that are the same as or similar to the elements described in FIG. 1 are assigned the same reference numerals and detailed description thereof is omitted.

The learning model 302a is based on the situation regarding the reproduction of a moving image in a device that reproduces a moving image and sound based on distribution data (hereinafter referred to as “reproducing device”) and the amount of moving image data that the reproducing device can process per unit time. It is a learned model that has learned the relational data indicating the relation between the determination result indicating whether or not the data amount is equal to or more than the data amount. The learning model 302a is defined by a plurality of coefficients K specified by machine learning using teacher data, which is an example of relational data.

The playback device is, for example, a smartphone. The playback device is not limited to the smartphone, and may be, for example, a laptop computer, a wearable terminal, a tablet terminal, or a desktop computer.

Next, the learning model 302a and the learning model execution unit 321a will be described in detail.
The learning model execution unit 321a is a functional unit implemented by the processing device 303 that executes the learning model 302a. The learning model execution unit 321a is included in the determination unit 321. The learning model executing unit 321a may be generally referred to as a learning model.
The learning model 302a defines, for example, a neural network, typically a deep neural network. The plurality of coefficients K are specified by machine learning using teacher data. Based on the reproduction log received by the receiving unit 310, the learning model executing unit 321a determines whether or not the amount of moving image data that the user device 20 can process per unit time is equal to or greater than the reference data amount, that is, the user device 20. Is a problematic device. The reproduction log may be input to the learning model executing unit 321a by the receiving unit 310. The playback log includes the number of consecutive dropped frames, the time difference between the playback timings of audio and video, the bit rate of video data, the decoding time, the usage rate of the processing device 206, the usage rate of the working memory, and the decryption time. , Is shown.

Next, the learning model 302a and the learning model executing unit 321a will be described from different viewpoints.
The learning model execution unit 321a is a neural network realized by the processing device (exemplary computer) 303, or more specifically, a functional block. The learning model execution unit 321a generates an output B according to the input A.

The learning model 302a is used in a program (for example, a program module that constitutes artificial intelligence software) that causes the processing device 303 to execute an operation that specifies the output A from the input A. Specifically, the learning model 302a includes a plurality of coefficients K applied to the calculation. A predetermined response function is used for the calculation.

The multiple coefficients K are optimized by prior machine learning (deep learning) using relational data including multiple teacher data. In each of the plurality of teacher data, the input A and the output B are associated with each other. That is, the learning model 302a is a statistical model in which the relationship data indicating the relationship between the input A and the output B is learned.

The processing device 303 executes a calculation that applies a plurality of coefficients K and a predetermined response function to an unknown input A, and thereby tends to be extracted from a plurality of teacher data (between the input A and the output B). B), that is, a valid output B for the input A is generated.

In the learning model 302a, a “playback log” (information indicating the situation regarding playback of a moving image) is used as an input A, and an output B is “the amount of moving image data that the user device 20 can process per unit time is equal to or greater than a reference data amount The determination result of whether or not is used.

Note that the learning model execution unit 321a may be realized by a processor for a neural network such as a Tensor Processing Unit (tensor processing unit) and a Neural Engine (neural engine), for example.

FIG. 6 is a diagram showing an example of a learning model generation device 50 that generates a learning model 302a defined by a plurality of coefficients K. 6, elements that are the same as or similar to the elements described in FIG. 1 are given the same reference numerals, and detailed description thereof will be omitted.

The learning model generation device 50 generates teacher data for the learning model 302a and a plurality of coefficients K that define the learning model 302a. The teacher data for the learning model 302a may be generated by a device different from the learning model generation device 50. The learning model generation device 50 communicates with the information processing devices 41 to 4n (n is an integer of 1 or more) via the network NW.
The information processing devices 41 to 4n are examples of moving image playback devices. The information processing devices 41 to 4n have the same configuration as the user device 20 except that a reproduction log provided with reproduction information for reproducing a moving image and a sound is output. Hereinafter, each of the information processing devices 41 to 4n is referred to as an information processing device 4m (m is an integer of 1 to n).
The reproduction information is used to reproduce the moving image and sound reproduced by the information processing device 4m. The reproduction information includes identification information of the distribution data used for reproducing the sound and the moving image in the information processing device 4m. The reproduction information further includes, for each index number of the image frame forming the moving image, the image quality (resolution) of the image frame with the index number, whether or not the image frame is reproduced, and the audio to be synchronized with the image frame. The time difference between the playback timing and the moving image indicated by the image frame is shown.

The learning model generation device 50 is configured by a computer system including an input device 501, a display device 502, a speaker 503, a communication device 504, a storage device 505, and a processing device 506. Each element of the learning model generation device 50 is mutually connected by one or two or more buses. Further, each element of the learning model generation device 50 is configured by one or two or more devices.

The input device 501 is a device for inputting information used by the learning model generation device 50 to the learning model generation device 50. The input device 501 receives user input such as instructions or questions from the user. The input device 501 is, for example, a keyboard. Note that the input device 501 is not limited to the keyboard, and may be a touch panel, a mouse, a switch, a button, or the like that detects contact with the display surface of the display device 502.

The display device 502 displays various images under the control of the processing device 506. For example, the display device 502 displays a moving image based on the moving image data included in the distribution data. The display device 502 is, for example, a liquid crystal display panel, an organic EL display panel, or the like.

The speaker 503 outputs various sounds by being controlled by the processing device 506. For example, the speaker 503 outputs a sound based on the sound data included in the distribution data.

The communication device 504 communicates with other devices, for example, the information processing devices 41 to 4n, via the network NW. The communication device 504 is also called, for example, a network device, a network controller, a network card, or a communication module.

The storage device 505 is a recording medium that can be read by the processing device 506. The storage device 505 stores a control program executed by the processing device 506 and various data used by the processing device 506. The storage device 505 is composed of, for example, a non-volatile memory (for example, ROM, EPROM or EEPROM) and a volatile memory (for example, RAM).

The processing device 506 is a processor that controls the learning model generation device 50. The processing device 506 includes, for example, one or more chips. As an example, the processing device 506 is configured by a central processing unit (CPU). Some or all of the functions of the processing device 506 may be realized by hardware such as DSP, ASIC, PLD, or FPGA. The processing device 506 executes various processes in parallel or sequentially.

The processing device 506 reads the control program from the storage device 505. The processing device 506 functions as the receiving unit 510, the reproducing unit 520, the evaluation obtaining unit 530, the teacher data generating unit 540, and the learning model generating unit 550 by executing the control program.

The reception unit 510, the reproduction unit 520, the evaluation acquisition unit 530, the teacher data generation unit 540, and the learning model generation unit 550 are examples of functional blocks of the processing device 506. All or some of the receiving unit 510, the reproducing unit 520, the evaluation obtaining unit 530, the teacher data generating unit 540, and the learning model generating unit 550 may be configured by hardware such as DSP, ASIC, PLD, or FPGA.

The receiving unit 510 receives the reproduction log from the information processing device 4m via the communication device 504. Hereinafter, the reproduction log received from the information processing device 4m will be referred to as a "learning reproduction log". The playback log for learning includes the number of consecutive dropped frames, the time difference between the playback timings of audio and video, the bit rate of video data, the decoding time, the usage rate of the processing device 206, and the usage rate of the working memory. The situation of the decryption time is shown. Further, reproduction information is added to the learning reproduction log.
For example, the receiving unit 510 receives a learning reproduction log voluntarily transmitted by the information processing device 4m. The receiving unit 510 may receive a request for a learning reproduction log to the information processing apparatus 4m, and may receive a learning reproduction log that the information processing apparatus 4m transmits in response to the request for the learning reproduction log. ..

The reproduction unit 520 reproduces the reproduction status of the moving image and the audio in the information processing device 4m, using the display device 502 and the speaker 503, based on the reproduction information for each reproduction reproduction log for learning. For example, the reproduction unit 520 first acquires from the distribution server 10 the distribution data specified by the identification information of the distribution data indicated by the reproduction information. Specifically, the reproduction unit 520 acquires, from the distribution server 10, distribution data indicating a moving image having the highest image quality among the image quality indicated for each index number of the image frame in the reproduction information. The reproduction unit 520 may obtain the distribution data from a server different from the distribution server 10.

Subsequently, the reproducing unit 520 reproduces the reproduction status of the moving image and the audio indicated by the reproduction information using the display device 502 and the speaker 503 based on the distribution data and the reproduction information. Therefore, the image quality of each image frame, the presence or absence of reproduction of each image frame, and the time difference between the reproduction timing of the sound of each image frame and the sound are reproduced. Since the distribution data indicating the moving image having the highest image quality among the image quality indicated for each image frame index number is used, the conversion to any image quality indicated for each image frame index number is possible.

The determiner determines whether or not the information processing device 4m is the problem device, based on the situation of the reproduction of the moving image and sound reproduced by the reproduction unit 520, that is, of the moving image data that the information processing device 4m can process per unit time. It is determined whether the data amount is equal to or larger than the reference data amount. The determiner inputs the determination result into the input device 501.

The evaluation acquisition unit 530 receives, from the input device 501, the result of the judgment made by the judge for each reproduction log for learning.

The teacher data generation unit 540 generates teacher data for each learning reproduction log. The teacher data is a set of a learning reproduction log and a determination result (label) based on the reproduction of the moving image reproduced based on the learning reproduction log. Specifically, the teacher data generation unit 540 first deletes the reproduction information from the reproduction reproduction log for learning. Next, the teacher data generation unit 540 makes a determination based on the learning reproduction log and the reproduction of the moving image reproduced based on the learning reproduction log for each learning reproduction log in which the reproduction information is deleted. A set of the result and is generated as teacher data. Therefore, the teacher data indicates the relationship between the situation regarding the reproduction of the moving image (the situation indicated by the reproduction log) and the determination result.

The learning model generation unit 550 specifies a plurality of coefficients K defining the learning model 302a by performing machine learning (deep learning) using the teacher data generated by the teacher data generation unit 540. The plurality of coefficients K specified by the learning model generation unit 550 are stored in the storage device 302 illustrated in FIG. 1, for example, by the determiner. The QoE server 30 implements the learning model execution unit 321a based on the plurality of coefficients K stored in the storage device 302.

In the second modified example, the learning reproduction log and the reproduction log of the user device 20 include the number of consecutive frames dropped, the time difference between the reproduction timings of audio and video, the bit rate of video data, the decoding time, and the processing device. The usage rate of 206, the usage rate of the working memory, and the status of the decryption time are shown.

　The higher the number of consecutive frames dropped, the worse the playback quality of the video. The longer the time difference between the audio and video playback timing, the worse the video playback quality.

The longer the decoding time, the more likely the number of consecutive frames dropped and the longer the time difference between the audio and video playback timing. Therefore, the longer the decoding time, the worse the reproduction quality of the moving image.

The higher the usage rate of the processing device 206, the easier the processing in the processing device 206 is delayed. If processing is easily delayed, the number of consecutive frames dropped tends to increase. If the processing is easily delayed, the time difference between the playback timings of the audio and the video tends to be long. Therefore, the higher the usage rate of the processing device 206, the worse the reproduction quality of the moving image.

The higher the usage rate of the working memory, the more likely the processing in the processing device 206 will be delayed. Therefore, the higher the usage rate of the working memory, the worse the reproduction quality of the moving image.

-The longer the decryption time, the more likely the number of consecutive frames dropped. The longer the decryption time, the longer the time difference between the audio and video playback timing. Therefore, the longer the decryption time, the worse the reproduction quality of the moving image.

The higher the bit rate of the video data, the more likely the processing in the processing device 206 will be delayed. Therefore, the higher the bit rate of the moving image data, the worse the reproduction quality of the moving image.

As described above, various information indicated by the reproduction log of the user device 20 and the reproduction log for learning is considered to affect the reproduction quality of the moving image. In the learning model 302a, machine learning is performed based on teacher data using a reproduction log for learning. Therefore, the accuracy of the determination using the learning model 302a can be made higher than the accuracy of the determination using the learning model in which the machine learning based on the teacher data using the learning reproduction log is not performed.

The reproduction log of the user device 20 and the reproduction log for learning include the number of consecutive frames dropped, the time difference between the reproduction timings of audio and video, the bit rate of video data, the decoding time, and the usage rate of the processing device 206. , The working memory usage rate, and only a part of the decryption time may be shown.

For example, the reproduction log of the user device 20 and the reproduction log for learning include the number of consecutive frames dropped, the time difference between the reproduction timings of audio and video, the bit rate of video data, the decoding time, and the processing device 206. , The usage rate of the working memory, the number of consecutive dropped frames in the decryption time, and the time difference between the playback timings of audio and video, or only one of the two elements. Good.
The number of consecutive frames dropped and the time difference between the reproduction timings of the audio and the moving image directly contribute to the reproduction quality of the moving image, and therefore easily influences the judgment made by the judge. Therefore, in the case where the reproduction log of the user device 20 and the reproduction log for learning show at least one of the number of consecutive frames dropped and the time difference between the reproduction timings of the audio and the moving image, compared to the case where neither is shown. , The accuracy of the determination result using the learning model 302a can be improved.

In addition, the reproduction log of the user device 20 and the reproduction log for learning include the number of consecutive frames dropped and the time difference between the reproduction timings of the audio and the video, the bit rate of the video data, the decoding time, the usage rate of the processing device 206, and the work rate. Only part of the memory usage and decryption time may be shown.

In addition, the reproduction log of the user device 20 and the learning reproduction log include not only one of the number of consecutive dropped frames and the time difference between the reproduction timings of the audio and the video, but also the bit rate of the video data, the decoding time, and the processing time. All or only part of the utilization of device 206, the working memory utilization, and the decryption time may be shown.

As described above, the bit rate of video data, the decoding time, the usage rate of the processing device 206, the usage rate of the working memory, and the decryption time are considered to affect the playback quality of the video. For this reason, the reproduction log of the user device 20 and the reproduction log for learning are added to all or part of the number of continuous frame dropouts and the time difference between the reproduction timings of the audio and the video, the bit rate of the video data, the decoding time, and the processing. When the usage rate of the device 206, the usage rate of the working memory, and all or part of the decryption time are shown, the accuracy of the determination result using the learning model 302a can be increased.

The learning model 302a is not limited to the model represented by the neural network or the deep neural network. For example, the learning model 302a may be represented by SVM (Support Vector Machine) or HMM (Hidden Markov Model).

<B3. Third Modification>
In the first embodiment, the first modified example, and the second modified example, the QoE server 30 controls the data amount of the moving image data transmitted to the user device 20 per unit time, based on the reproduction log of the user device 20. Determine the content of the request to In the third modification, the user device 20 instead of the QoE server 30 makes a request for controlling the data amount of the moving image data transmitted to the user device 20 per unit time, based on the reproduction log of the user device 20. Determine the content.

FIG. 7 is a block diagram showing an example of the distribution system 1 according to the third modification. In FIG. 7, elements that are the same as or similar to the elements described using FIG. 1 are assigned the same reference numerals and detailed description thereof is omitted.

The distribution system 1 illustrated in FIG. 7 differs from the distribution system 1 illustrated in FIG. 1 in that the user device 20 does not include the QoE server 30 and includes the request determination unit 230 and the request unit 240.

The processing device 206 of the user device 20 reads the program stored in the storage device 205. The processing device 206 implements the reproduction execution unit 210, the operation control unit 220, the request determination unit 230, and the request unit 240 by executing the program.

The reproduction execution unit 210, the operation control unit 220, the request determination unit 230, and the request unit 240 are examples of functional blocks of the processing device 206. All or a part of the reproduction execution unit 210, the operation control unit 220, the request determination unit 230, and the request unit 240 may be configured by hardware such as DSP, ASIC, PLD, or FPGA.

In the distribution system 1 illustrated in FIG. 7, the operation control unit 220 provides the reproduction log to the request determination unit 230.

The request determination unit 230 determines the content of the request regarding the data amount of the moving image data to be transmitted by the distribution server 10 per unit time, based on the situation regarding the reproduction of the moving image in the reproduction execution unit 210 indicated by the reproduction log. The request determination unit 230 includes the determination unit 321 described above and the user device request determination unit 231.

The user device request determination unit 231 determines the content of the request that the user device 20 should transmit to the distribution server 10, based on the determination result of the determination unit 321, and more specifically, the moving image data that the distribution server 10 should transmit per unit time. Determine the content of the request regarding the amount of data. The operation in which the user device request determination unit 231 determines the content of the request is the same as the above-described operation in which the determination unit 322 determines the content of the request.

The request unit 240 transmits a request indicating the content determined by the request determination unit 230 to the distribution server 10.

According to the third modification, the user device 20 determines the content of the request to the distribution server 10 based on the reproduction log of the user device 20. Therefore, the QoE server 30 can be eliminated and the configuration can be simplified.

<B4. Fourth Modification>
In the first embodiment and the first modified example to the second modified example, the operation control unit 220 of the user device 20 may store the latest designation information in the storage device 205. In this case, when newly requesting the distribution data from the distribution server 10, the operation control unit 220 may transmit to the distribution server 10 the request indicated by the latest designated information stored in the storage device 205.

Further, in the third modification, the operation control unit 220 of the user device 20 may store request information indicating the latest determination result of the request determination unit 230 in the storage device 205. In this case, the operation control unit 220 may transmit a request indicated by the data amount information stored in the storage device 205 to the distribution server 10 when newly requesting distribution data from the distribution server 10.

According to the fourth modification, the user device 20 can reproduce a moving image from the start of transmission of distribution data, based on moving image data of a data amount per unit time according to the specifications of the user device 20. Therefore, it is possible to suppress the deterioration of the reproduction quality of the moving image.

<B5. Fifth Modification>
In the first embodiment and the first modification to the fourth modification, when the distribution server 10 receives a request for distribution data from the user device 20, the distribution server 10 uses the distribution data to which the advertisement moving image data indicating the advertisement is added at the beginning. It may be transmitted to the device 20.

For users, the reproduction quality of advertisements is likely to be less noticeable than the reproduction quality of videos that are reproduced after advertisements. Therefore, according to the fifth modified example, it is difficult for the user to recognize the deterioration of the quality of the moving image reproduction until the data amount of the moving image data per unit time is adjusted, and the moving image after the advertisement is reproduced. It is possible to suppress deterioration of reproduction quality.

<B6. Sixth Modification>
In the first embodiment, the first modified example, the second modified example, the fourth modified example, and the fifth modified example, there is a device (hereinafter, referred to as “first storage device”) that stores the reproduction log of the user device 20. In this case, the receiving unit 310 may receive the reproduction log of the user device 20 from the first storage device.

For example, the receiving unit 310 receives a reproduction log voluntarily transmitted by the first storage device. The receiving unit 310 may transmit a reproduction log request to the first storage device, and may receive a reproduction log transmitted by the first storage device in response to the reproduction log request.

Further, when there is a device (hereinafter, referred to as “second storage device”) that stores the reproduction log for learning of each of the information processing devices 41 to 4n, the receiving unit 510 outputs the learning log from the second storage device. You may receive a replay log.

For example, the receiving unit 510 receives the learning reproduction log voluntarily transmitted by the second storage device. The receiving unit 510 may send a request for a learning reproduction log to the second storage device, and may receive a learning reproduction log that the second storage device transmits in response to the request for the learning reproduction log.

<C. Other>
(1) In each of the first embodiment and the first to sixth modifications, the storage devices 102, 205 and 302 are flexible disks, magneto-optical disks (eg compact disks, digital versatile disks, Blu-disks). ray (registered trademark) disk, smart card, flash memory device (eg, card, stick, key drive), CD-ROM (Compact Disc-ROM), register, removable disk, hard disk, floppy (registered trademark) disk, magnetic It may include strips, databases, servers and other suitable storage media. Further, the program may be transmitted from the network via an electric communication line.

(2) In the first embodiment and each of the first to sixth modifications, LTE (Long Term Evolution), LTE-A (LTE-Advanced), SUPER 3G, IMT-Advanced, 4G, 5G, FRA ( Future Radio Access), W-CDMA (registered trademark), GSM (registered trademark), CDMA2000, UMB (Ultra Mobile Broadband), IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802.20. , UWB (Ultra-WideBand), Bluetooth (registered trademark), and other suitable systems, and/or may be applied to a next-generation system extended based on these systems.

(3) The information described in each of the first embodiment and each of the first modification to the sixth modification may be represented using any of various different technologies. For example, data, information, bits, chips, etc. that may be referred to throughout the above description may be represented by voltages, currents, electromagnetic waves, magnetic fields, magnetic particles, optical fields, photons, or any combination thereof. Good. Note that the terms described in the present specification and/or the terms necessary for understanding the present specification may be replaced with terms having the same or similar meanings.

(4) In each of the first embodiment and the first to sixth modifications, the input/output information and the like may be stored in a specific place (for example, a memory) or may be managed by a management table. Good. Information that is input/output may be overwritten, updated, or added. The output information and the like may be deleted. The input information and the like may be transmitted to another device.

(5) In each of the first embodiment and the first to sixth modified examples, the determination may be made based on the value (0 or 1) represented by 1 bit, or the true/false value. It may be performed based on (Boolean: true or false) or may be performed based on comparison of numerical values (for example, comparison with a predetermined value).

(6) The order of the processing procedures, sequences, flowcharts, and the like illustrated in each of the first embodiment and the first modification to the sixth modification may be changed as long as there is no contradiction. For example, the methods described herein present elements of the various steps in a sample order, and are not limited to the specific order presented.

(7) Each function illustrated in FIG. 1, FIG. 5, FIG. 6 and FIG. 7 is realized by an arbitrary combination of hardware and software. Further, each function may be realized by a single device, or may be realized by two or more devices that are configured separately from each other.

(8) Whether the program illustrated in each of the first embodiment and the first to sixth modifications is called software, firmware, middleware, microcode, hardware description language, or another name. , Instruction, instruction set, code, code segment, program code, subprogram, software module, application, software application, software package, routine, subroutine, object, executable file, execution thread, procedure or function, etc. It should be widely interpreted.
In addition, software, instructions, and the like may be transmitted and received via a transmission medium. For example, the software may use a wired technology such as coaxial cable, fiber optic cable, twisted pair and digital subscriber line (DSL) and/or wireless technology such as infrared, wireless and microwave to websites, servers, or other When transmitted from a remote source, these wireline and/or wireless technologies are included within the definition of transmission medium.

(9) In each of the first embodiment and the first to sixth modifications, the terms “system” and “network” are used interchangeably.

(10) In each of the first embodiment and the first modification to the sixth modification, the user equipment 20 may be a mobile station. Mobile stations are defined by those skilled in the art as subscriber stations, mobile units, subscriber units, wireless units, remote units, mobile devices, wireless devices, wireless communication devices, remote devices, mobile subscriber stations, access terminals, mobile terminals, wireless. It may also be referred to as a terminal, remote terminal, handset, user agent, mobile client, client, or some other suitable term.

(11) The term "determining" as used herein may encompass a wide variety of actions. "Decision" means, for example, judgment, calculation, computing, processing, deriving, investigating, looking up (eg, table, database or another). In the data structure of the above), ascertaining what has been confirmed (ascertaining), etc. may be included. “Decision” means receiving (eg, receiving information), transmitting (eg, transmitting information), input, output, accessing (accessing). For example, it may include that access to the data in the memory) is regarded as “determined”. Further, the “decision” may include the determination of what has been “resolved”, “selecting”, “choosing”, “establishing”, or “comparing”. That is, “decision” may include considering some action as “decided”.

(12) In each of the first embodiment and the first to sixth modifications, the description “based on” does not mean “based only on” unless otherwise specified. In other words, the phrase "based on" means both "based only on" and "based at least on."

(13) Any reference to elements using designations such as “first” and “second” as used herein does not generally limit the amount or order of those elements. These nomenclatures may be used herein as a convenient way to distinguish between two or more elements. Thus, references to the first and second elements do not mean that only two elements can be employed or that the first element must precede the second element in any way.

(14) In each of the first embodiment and the first modification to the sixth modification, the terms “including”, “comprising”, and the modifications thereof are included in the present specification or claims. As used in, the terms as well as the term "comprising" are intended to be inclusive. Further, the term "or" as used in the specification or claims is not intended to be an exclusive OR.

(15) Throughout this application, if articles are added by translation, such as a, an, and the in English, unless these contexts clearly indicate otherwise, then Including multiple.

(16) It will be apparent to those skilled in the art that the present invention is not limited to the embodiments described herein. The present invention can be implemented as modified and changed modes without departing from the spirit and scope of the present invention defined based on the description of the claims. Therefore, the description of the present specification is for the purpose of exemplifying description, and has no restrictive meaning to the present invention. In addition, a plurality of modes selected from the modes exemplified in this specification may be combined.

1... Delivery system, 10... Delivery server, 101... Communication device, 102... Storage device, 103... Processing device, 110... Delivery control unit, 20... User device, 201... Input device, 202... Display device, 203... Speaker, 204... Communication device, 205... Storage device, 206... Processing device, 210... Replay execution unit, 220... Operation control unit, 230... Request determination unit, 231... User device request determination unit, 240... Request unit, 30... QoE server , 301... Communication device, 302... Storage device, 302a... Learning model, 303... Processing device, 310... Receiving part, 320... Generation part, 321... Judgment part, 322... Determining part, 330... Providing part, 321a... Learning model Execution department.

Claims (8)

1. A receiving unit that receives status information indicating a status regarding reproduction of a moving image represented by the moving image data in a receiving device that receives distribution data including moving image data from a distribution server;
   Designation information for designating a request regarding the data amount of the moving image data to be transmitted by the distribution server per unit time, as a request to be transmitted by the receiving device to the distribution server, based on the status information received by the receiving unit. A generator that generates
   A providing unit that provides the receiving device with the designation information generated by the generating unit,
   Including a control device.
2. The generator is
   A determination unit that determines whether or not the data amount of the moving image data that the receiving device can process per the unit time is based on the status information received by the receiving unit, or more.
   A determination unit that determines the content of the request based on the determination result of the determination unit;
   including,
   The control device according to claim 1.
3. The determination unit is
   When the determination unit determines that the data amount of the moving image data that the receiving device can process per unit time is less than the reference data amount, the moving image data that the distribution server should transmit per unit time It is determined as the content of the request to make the data amount of the data amount smaller than the reference data amount,
   The control device according to claim 2.
4. The determination unit,
   A relationship between a situation regarding reproduction of a moving image in the moving image reproducing apparatus and a determination result indicating whether or not a data amount of the moving image data that can be processed by the moving image reproducing apparatus per unit time is equal to or more than the reference data amount is shown. Based on the situation information, it is determined whether the data amount of the moving image data that can be processed by the receiving device per unit time is equal to or more than the reference data amount, using a learning model that learned relational data. ,
   The control device according to claim 2 or 3.
5. The receiving unit is
   As the situation information,
   First situation information indicating a situation regarding reproduction of the moving image in a period from a start time point of reproduction of the moving image performed by the receiving device to a first time point after the start time point, or
   Receiving second status information indicating a status regarding reproduction of the moving image in a period from a second time point after the start time point to a third time point after the second time point,
   The control device according to any one of claims 1 to 4.
6. The status information is
   The situation regarding the disturbance in the reproduction of the video, and
   Indicating either or both of the load conditions of the playback device playing the video,
   The control device according to any one of claims 1 to 5.
7. The distribution data includes, in addition to the moving image data, sound data indicating a sound to be reproduced together with the moving image represented by the moving image data,
   The status information is
   A situation of the number of image frames that have not been reproduced among the consecutive image frames that form the moving image, and
   Indicating either or both of a situation of a reproduction timing difference between the sound reproduced in the receiving device based on the audio data and the moving image reproduced in the receiving device based on the moving image data,
   The control device according to any one of claims 1 to 5.
8. A reproduction execution unit that reproduces the video represented by the video data included in the distribution data transmitted from the distribution server,
   A request determination unit that determines the content of the request regarding the data amount of the moving image data that the distribution server should transmit per unit time, based on the situation regarding the reproduction of the moving image in the reproduction execution unit;
   A request unit that transmits the request indicating the content determined by the request determination unit to the distribution server;
   A communication device including.

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