JP2018160147A - Information processor and processing load distribution method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively suppress occurrence of inappropriate reproduction of contents even when other processing is executed in parallel with content reproduction.SOLUTION: An other processing load specification part 741 specifies a processing load of a processing part by the other processing before execution start of the other processing. Continuously, a mode transition control part 742 controls transition to a generation processing mode corresponding to the specified processing load for a content reproduction processing execution part 743. When the mode transition control part 742 receives completion report of the transition of the processing mode of the content reproduction processing execution part 743, a start command of execution of the other processing is sent to an other processing execution part 744. As a result, execution of the other processing in the other processing execution part 744 is started.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an information processing apparatus, a processing load distribution method, a processing load distribution program, and a recording medium on which the processing load distribution program is recorded.

  Conventionally, various technologies have been proposed regarding apparatuses capable of executing other processes in parallel with the content reproduction process. One of the proposed technologies is to execute other application programs at the same time when decompressing / playing compressed video data, and to display the video on the same display screen without the system malfunctioning. There is a system technology (refer to Patent Document 1: hereinafter referred to as “conventional example”).

  In the technology of this conventional example, a first content reproduction method having a relatively large CPU processing load and a second content reproduction method having a CPU processing load smaller than that of the first content reproduction method are prepared. Then, the load state of the CPU that executes the program is detected, and the content reproduction method is switched according to the detected load state of the CPU.

Japanese Patent No. 3133113

  In the conventional technique described above, the content reproduction method is switched according to the detection state of the load state of the CPU. For this reason, when the load on the CPU suddenly increases, there is a possibility that a situation in which the switching of the content reproduction method is not in time can occur. For example, in the case where the content is music, if such a situation occurs during audio reproduction, it may cause inappropriate reproduction such as noise or skipping.

  For this reason, there is a demand for a technology that can effectively suppress the occurrence of inappropriate reproduction of content even if other processing is executed in parallel with content reproduction. Meeting this requirement is one of the problems to be solved by the present invention.

  The invention according to claim 1 is an information processing apparatus including a processing unit capable of executing a generation process of content data for reproduction and a process other than the generation process in parallel. A plurality of processing modes having different processing loads from each other, and the processing unit specifies a processing load of the processing unit due to the other processing prior to the start of execution of the other processing; A mode transition control unit that controls the first transition to the processing mode according to the identified processing load.

  A tenth aspect of the present invention is a processing load distribution method used in an information processing apparatus including a processing unit capable of executing a reproduction content data generation process and a process other than the generation process in parallel. In addition, the generation process includes a plurality of processing modes in which the processing load of the processing unit is different from each other, and the processing unit is configured to process the processing load of the processing unit due to the other process prior to starting the execution of the other process. A process load distribution method for executing a process transition specifying process for performing a transition control to a process mode according to the specified process load.

  According to an eleventh aspect of the present invention, there is provided a processing load distribution program that causes a computer included in the information processing apparatus to execute the processing load distribution method according to the tenth aspect.

  The invention according to claim 12 is a recording medium on which the processing load distribution program according to claim 11 is recorded so as to be readable by a computer included in the information processing apparatus.

It is a figure which shows schematic structure of the information processing apparatus which concerns on one Embodiment of this invention. It is a figure which shows schematic structure of the information processing apparatus which concerns on 1st Example of this invention. It is a figure for demonstrating the structure of the process control unit of FIG. It is a figure for demonstrating the audio | voice reproduction | regeneration processing part of FIG. It is a figure for demonstrating the load information of FIG. It is a flowchart for demonstrating the execution control process by the execution process control of FIG. It is a flowchart for demonstrating the start process of the start designation | designated process of FIG. It is a flowchart for demonstrating the process end process of FIG. It is a figure for demonstrating the audio | voice reproduction | regeneration processing part in 2nd Example. It is a figure for demonstrating the mode transition process in the audio | voice reproduction | regeneration processing part of FIG. It is a figure for demonstrating the audio | voice reproduction | regeneration processing part in 3rd Example. It is a figure for demonstrating the mode transition process in the audio | voice reproduction | regeneration processing part of FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to FIG. In the following description and drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

[Constitution]
FIG. 1 shows a schematic configuration of an information processing apparatus 700 according to an embodiment. As shown in FIG. 1, a content presentation device 910 and another processing device 920 are connected to the information processing apparatus 700.

  In this embodiment, the information processing apparatus 700 performs audio reproduction processing as content reproduction processing, and generates output sound data as audio output content data. Then, the generated output sound data is sent to the content presentation device 910 (sound output device).

  In this embodiment, voice recognition processing, image generation processing, and the like are performed as processing other than voice reprocessing.

  The content presentation device 910 described above includes a speaker. The output sound data sent from the information processing apparatus 700 is received. Then, the content presentation device 910 outputs a sound according to the output sound data.

  The other processing device 920 is used for other processing (hereinafter simply referred to as “other processing”) than the audio reproduction processing executed in the information processing apparatus 700. For example, when the other process is a voice recognition process, the other processing device 920 is a sound input device including a microphone. For example, when the other processing is image display processing, the other processing device 920 is a display device.

<Configuration of Information Processing Device 700>
Next, the configuration of the information processing apparatus 700 will be described.

  As illustrated in FIG. 1, the information processing apparatus 700 includes a storage unit 710 and a pre-processing content data holding unit 720. Further, the information processing apparatus 700 includes an input unit 730 and a processing unit 740.

  The storage unit 710 includes a nonvolatile storage element. The storage unit 710 stores various information data used in the information processing apparatus 700. Such information data includes processing executed in the information processing apparatus 700, that is, processing load information (hereinafter also simply referred to as “load information”) of the above-described audio reproduction processing and other processing. Note that the processing unit 740 can access the storage unit 710.

  Note that the content reproduction processing execution unit 743 in the processing unit 740 to be described later can operate in a plurality of processing modes. In this embodiment, each processing load of the plurality of processing modes is the load described above. Registered in the information.

  The pre-processing content data holding unit 720 includes a nonvolatile storage element. The pre-processing content data holding unit 720 stores, for example, compressed audio data as pre-processing content data. In the present embodiment, the pre-processing content data includes time stamp information for each data block. Such pre-processing content data can be read by the processing unit 740. As the pre-processing content data holding unit 720, a portable recording medium such as a CD (Compact Disc) or a DVD (Digital Versatile Disc) can be used. In addition, the pre-processing content data can be stored in the storage unit 710.

  An input operation by the user is performed on the input unit 730. Then, the input unit 730 sends the operation input result to the processing unit 740 as input data. By using the input unit 730, the user can input a process start request, a process end request, and the like specifying the process type to the information processing apparatus 700.

<Configuration of Processing Unit 740>
Next, the configuration of the processing unit 740 will be described.

  The processing unit 740 includes another processing load specifying unit 741 and a mode transition control unit 742. The processing unit 740 includes a content reproduction processing execution unit 743 and another processing execution unit 744.

  The other processing load specifying unit 741 receives a processing start request for other processing (hereinafter, also referred to as “other processing start request”) sent from the input unit 730. Subsequently, the other process load specifying unit 741 refers to the load information in the storage unit 710 and specifies the process load for executing the process specified in the other process start request. Then, the other processing load specifying unit 741 sends the type of processing specified in the specifying result and the other processing start request to the mode transition control unit 742.

  When the other process load specifying unit 741 receives an end request for other processing (hereinafter, also referred to as “another process end request”) sent from the input unit 730, the other process load specifying unit 741 executes the end designation process in the other process end request. Is specified as “0”. Then, the other process load specifying unit 741 sends a process end instruction to the effect that the end specifying process should be ended to the other process executing unit 744, and changes the type of the process specified in the specifying result and the other process end request to the mode transition control. To part 742.

  Further, when receiving a report from the other process execution unit 744 that the execution of the other process has been voluntarily terminated, the other process load specifying unit 741 sets the processing load for executing the process that performed the report to “0”. Is specified. Then, the other processing load specifying unit 741 sends the specifying result to the mode transition control unit 742.

  The mode transition control unit 742 receives the specifying result sent from the other processing load specifying unit 741. Subsequently, the mode transition control unit 742 refers to the load information in the storage unit 710 and calculates a processing load that can be distributed to the content reproduction processing according to the specific result. Next, the mode transition control unit 742 determines a processing mode to be executed by the content reproduction processing execution unit 743 according to the calculated processing load. Then, the mode transition control unit 742 sends a mode transition command in which the determined processing mode is designated as the transition destination processing mode to the content reproduction processing execution unit 743.

  The mode transition control unit 742 receives the mode transition completion report sent from the content reproduction processing execution unit 743. When the mode transition completion report is received, the mode transition control unit 742 sends a process start command related to the process specified in the other process start request input to the input unit 730 to the other process execution unit 744.

  The content reproduction processing execution unit 743 has a plurality of processing modes in which at least one of sampling rate conversion, DSD (Direct Stream Digital) conversion, reverb processing, and the like are different from each other. Note that the processing load is higher in the processing mode in which the quality of the reproduced sound is higher.

  The content reproduction processing execution unit 743 receives the mode transition command sent from the mode transition control unit 742. Then, the content reproduction processing execution unit 743 sends a mode transition completion report to the mode transition control unit 742 after making a transition to the processing mode specified in the mode transition command. Subsequently, the content reproduction processing execution unit 743 performs content reproduction processing on the pre-processing content data in the post-transition processing mode to generate output sound data, and sends the generated output sound data to the content presentation device 910.

  Note that the content playback processing execution unit 743 uses time stamp information at the time of processing mode transition to perform processing for seamless playback from cross-processing mode audio to post-transition processing mode audio, cross-fade playback, and the like. Is supposed to do.

  The other process execution unit 744 receives the other process start command sent from the mode transition control unit 742. Then, the other process execution unit 744 starts executing the process specified in the other process start command.

  When the other process execution unit 744 voluntarily ends the process being executed, the other process execution unit 744 sends a report to that effect to the mode transition control unit 742.

[Operation]
Next, the operation of the information processing apparatus 700 configured as described above will be described mainly focusing on the other process load specifying process by the other process load specifying unit 741 and the mode transition control process by the mode transition control unit 742.

  Note that the content reproduction processing execution unit 743 executes the content reproduction processing, performs content reproduction processing on the pre-processing content data, generates output sound data, and sends the generated output sound data to the content presentation device 910. It shall be.

<Other processing load identification processing>
When the other process start request designating the start process is received from the input unit 730, the processing load for executing the process designated in the other process start request is specified with reference to the load information in the storage unit 710. Then, the other processing load specifying unit 741 sends the specifying result to the mode transition control unit 742.

  When receiving the other process end request sent from the input unit 730, the other process load specifying unit 741 first sends a process end instruction to the other process executing unit 744 to end the execution of the end specifying process. As a result, the other process execution unit 744 ends the execution of the end designation process.

  Subsequently, the other processing load specifying unit 741 specifies “0” as the processing load for executing the end specifying process. Then, the other process load specifying unit 741 sends a process end instruction to the effect that the execution of the end specifying process should be ended to the other process executing unit 744, and sends the specification result and the type of the end specifying process to the mode transition control unit 742. .

  In addition, when receiving a report from the other process execution unit 744 that the other process has been voluntarily terminated, the other process load specifying unit 741 sets the processing load for executing the process that performed the report to “0”. ". Then, the other processing load specifying unit 741 sends the specifying result and the type of the other processing that has ended to the mode transition control unit 742.

<Mode transition control processing>
Upon receiving the identification result sent from the other processing load identification unit 741, the mode transition control unit 742 refers to the load information in the storage unit 710 and can process the load that can be distributed to the content reproduction process according to the identification result. Is calculated. Next, according to the calculated processing load, the mode transition control unit 742 selects a processing mode that can achieve the highest playback quality among the processing modes within the processing load that can be distributed, and the content playback processing execution unit 743. Determines the processing mode to be executed. Then, the mode transition control unit 742 sends a mode transition command specifying the determined processing mode as the transition destination processing mode to the content reproduction processing execution unit 743.

  As a result, the content reproduction processing execution unit 743 sends a mode transition completion report to the mode transition control unit 742 after making a transition to the designated processing mode. Subsequently, the content reproduction processing execution unit 743 performs content reproduction processing on the pre-processing content data according to the post-transition processing mode, generates output sound data, and sends the generated output sound data to the content presentation device 910. Note that, as described above, the content reproduction processing execution unit 743 refers to the time stamp information included in the pre-processing content data during the transition of the processing mode, from the sound in the pre-transition processing mode to the sound in the post-transition processing mode. For seamless playback, crossfade playback, etc.

  Upon receiving the mode transition completion report sent from the content reproduction process execution unit 743 due to the other process start request, the mode transition control unit 742 sends a process start command specifying the process specified in the other process start request to the other process start command. The data is sent to the process execution unit 744. As a result, the other process execution unit 744 starts executing the process specified in the process start command.

  As described above, in the information processing apparatus 700 according to the present embodiment, the other processing load specifying unit 741 specifies the processing load of the processing unit 740 due to the other processing before starting the execution of the other processing. Subsequently, the mode transition control unit 742 controls the content reproduction processing execution unit 743 to control the transition to the processing mode according to the specified processing load. When the mode transition control unit 742 receives the completion report of the processing mode transition of the content reproduction processing execution unit 743, the mode transition control unit 742 sends a processing start command for executing the other processing to the other processing execution unit 744. As a result, execution of the other process in the other process execution unit 744 is started.

  Therefore, according to the present embodiment, it is possible to effectively suppress the occurrence of inappropriate reproduction of content even if other processing is executed in parallel with the execution of content reproduction processing.

  Further, in the present embodiment, when the other process ends, the mode transition control unit 742 controls the content reproduction process execution unit 743 to control the transition to the processing mode that is executed when the other process is not executed. . Therefore, among the processing modes within the processing load distributed to the execution of the content reproduction processing, the processing mode that can achieve the highest reproduction quality can be determined as the processing mode to be executed by the content reproduction processing execution unit 743. High-quality content can be played as much as possible at the time.

  Further, in the present embodiment, at the time of transition of the processing mode, the content reproduction processing execution unit 743 performs processing for seamless reproduction, crossfade reproduction, etc. using time stamp information included in the pre-processing content data. For this reason, a user's uncomfortable feeling at the time of the transition of a processing mode can be suppressed.

[Modification of Embodiment]
Various modifications can be made to the above embodiment.

  For example, in the above embodiment, the playback content is audio content, but the playback content may be content other than audio content.

  In the above embodiment, at the time of transition of the processing mode, processing for seamless reproduction, cross-fade reproduction, etc. using the time stamp information included in the pre-processing content data is performed. On the other hand, such processing may not be performed at the time of transition of the processing mode. Further, without using the time stamp information, the fade-out process may be performed after the fade-out process is performed before the process mode transition, and then the fade-in process may be performed. Furthermore, another process that can suppress the user's uncomfortable feeling may be performed during the transition of the process mode.

  In the above embodiment, the time stamp information is included in the pre-processing content data. On the other hand, the content reproduction processing execution unit may generate time stamp information. When generating such a time stamp, the content reproduction processing execution unit may generate time stamp information based on the metadata (INDEX information) of the pre-processing content data file, or the pre-processing content data may be PCM. In the case of (Pulse Code Modulation) data, time stamp information may be generated based on the sampling frequency and the number of quantization bits. Furthermore, the content reproduction process execution unit may generate time stamp information by combining these two methods.

  A part or all of the information processing apparatus 700 of the above embodiment is configured as a computer as a calculation unit including a central processing unit (CPU), and a program prepared in advance is executed by the computer. By executing this, a part or all of the functions of the information processing apparatus 700 may be performed. This program is recorded on a computer-readable recording medium such as a hard disk, CD-ROM, or DVD, and is loaded from the recording medium and executed by the computer. The program may be acquired in a form recorded on a portable recording medium such as a CD-ROM or DVD, or may be acquired in a form distributed via a network such as the Internet. Also good.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. In the following description and drawings, the same or equivalent elements including the above-described embodiment are denoted by the same reference numerals, and redundant description is omitted.

[First embodiment]
First, a first embodiment of the present invention will be described with reference to FIGS.

<Configuration>
FIG. 2 shows a schematic configuration of the information processing apparatus 100A according to the first embodiment. This information processing apparatus 100A is an aspect of the information processing apparatus 700 (see FIG. 1) of the above-described embodiment. The information processing apparatus 100A is arranged in a vehicle CR as a moving body.

  A speed detection unit 210 and a sound output unit 220 are disposed in the vehicle CR. In addition, a display unit 230, a position detection unit 240, and a sound collection unit 250 are disposed in the vehicle CR. These elements 210 to 250 are connected to the information processing apparatus 100A.

  The speed detection unit 210 includes a vehicle speed sensor, and detects the vehicle speed of the vehicle CR. The detection result by the speed detection unit 210 is sent to the information processing apparatus 100A as vehicle speed information.

  The sound output unit 220 receives the output sound data sent from the information processing apparatus 100A. Then, the sound output unit 220 outputs sound corresponding to the output sound data. The sound output unit 220 functions as the content presentation device 910 in the above-described embodiment.

  The display unit 230 receives display image data sent from the information processing apparatus 100A. Then, the display unit 230 displays an image corresponding to the display image data. The display unit 230 performs a part of the function of the other processing device 920 in the above-described embodiment.

  The position detection unit 240 includes a GPS (Global Positioning System) receiving unit. The position detection unit 240 calculates the current position of the vehicle CR based on reception results of radio waves from a plurality of GPS satellites. The calculated current position is sent to the information processing apparatus 100A as current position information. The position detection unit 240 performs a part of the functions of the other processing device 920.

  The sound collection unit 250 collects ambient sounds. The sound collection result by the sound collection unit 250 is sent to the information processing apparatus 100A. The sound collection unit 250 performs a part of the functions of the other processing device 920.

<< Configuration of Information Processing Apparatus 100A >>
The information processing apparatus 100A includes a processing control unit 110A and a storage unit 120, as shown in FIG. The information processing apparatus 100 </ b> A includes a wireless communication unit 130 and an input unit 140.

  The processing control unit 110A performs overall control of the entire information processing apparatus 100A. The processing control unit 110A includes a central processing unit (CPU), a DSP (Digital Signal Processor), and peripheral circuits. The CPU and DSP execute programs to perform various functions. Such functions include the functions of the processing unit 740 (that is, the other processing load specifying unit 741, the mode transition control unit 742, the content reproduction processing execution unit 743, and the other processing execution unit 744) in the above-described embodiment.

  The processing control unit 110A will be described later.

  The storage unit 120 includes a nonvolatile storage device such as a hard disk device, and stores various information data used in the information processing apparatus 100A. Such information data includes sound source data CND, map information MPI, and load information LDI corresponding to the above-mentioned content data before processing. The storage control unit 110A can access the storage unit 120.

  That is, the storage unit 120 performs the function of the storage unit 710 in the above-described embodiment.

  The sound source data CND is audio data to be subjected to content reproduction processing in the information processing apparatus 100A. In other words, the storage unit 120 also functions as the pre-processing content data holding unit 720 in the above-described embodiment.

  The map information MPI includes road data indicating road connection relationships, image data for displaying them, POI (Point of Interest) information, and the like. Here, the road data includes information on points (nodes) where a plurality of roads intersect, merge and branch, and roads (links) connecting the nodes. Specifically, position information of nodes and links (latitude and longitude) ), Shape pattern, standard travel time information, and an ID (Identifier) for uniquely identifying them. The POI information includes a facility name, a facility position, and the like.

  In the load information LDI, the processing load of processing executed by the processing control unit 110A is registered. The contents of the load information will be described later.

  The wireless communication unit 130 communicates with the data server 600 via the network 500. The data server 600 stores a lot of sound source data and map information update information. By using the wireless communication unit 130, the processing control unit 110A can acquire new sound source data and update information of the map information MPI.

  The input unit 140 includes a key unit provided in the main body of the information processing apparatus 100A and / or a remote input device including the key unit. Here, as a key part provided in the main body part, a touch panel provided in a display device of the display unit 230 can be used.

  When the user operates the input unit 140, the operation setting of the information processing apparatus 100A is performed. Such operation setting input includes a process start request, a process end request, and the like. That is, the input unit 140 performs the function of the input unit 730 in the above-described embodiment.

(Configuration of processing control unit 110A)
As shown in FIG. 3, the processing control unit 110A includes an execution control unit 111 and an audio reproduction processing unit 112A. The processing control unit 110A includes a map display processing unit 113, a voice recognition unit 114, and a wireless communication processing unit 115.

  The execution control unit 111 is always executed by the processing control unit 110A. The execution control unit 111 receives a process start request, a process end request, and the like sent from the input unit 140. Here, the processing start request includes specification of the start processing. Further, the process end request includes designation of the end process. Then, the execution control unit 111 controls execution start and execution end of each of the above-described elements 112A to 115. The execution control unit 111 functions as the other processing load specifying unit 741 and the mode transition control unit 742 in the above-described embodiment.

  Further, the execution control unit 111 receives vehicle speed information sent from the speed detection unit 210. For this reason, the execution control part 111 can grasp | ascertain the vehicle speed of the vehicle CR at the present time.

  The details of the execution control process executed by the execution control unit 111 will be described later.

  The audio reproduction processing unit 112A performs processing on the pre-processing audio data read from the sound source data CND in the storage unit 120 under the control of the execution control unit 111, and generates output sound data. . Here, the audio reproduction processing unit 112A has a plurality of processing modes in which at least one of sampling conversion, DSD conversion, reverb processing, and the like is different from each other. Note that the processing load is higher in the processing mode in which the quality of the reproduced sound is higher. Then, the sound reproduction processing unit 112A sends the generated output sound data to the sound output unit 220.

  When the sound reproduction processing unit 112A receives the sound reproduction processing start command sent from the execution control unit 111, the sound reproduction processing unit 112A starts executing the sound reproduction processing. In addition, when the audio reproduction processing unit 112A receives the audio reproduction processing end command sent from the execution control unit 111, the audio reproduction processing unit 112A ends the execution of the audio reproduction processing. Furthermore, when the voice reproduction processing unit 112A receives the mode transition command sent from the execution control unit 111, the voice reproduction processing unit 112A switches the processing mode of the voice reproduction processing.

  That is, the audio reproduction processing unit 112A performs the function of the content reproduction processing execution unit 743 in the above-described embodiment. Details of the configuration of the audio reproduction processing unit 112A will be described later.

  The map display processing unit 113 receives the current position information sent from the position detection unit 240. Then, the map display processing unit 113 refers to the map information MPI based on the current position of the vehicle CR, and generates map image data around the current position of the vehicle CR. The map image data generated in this way is sent to the display unit 230 as display image data.

  In addition, when the map display processing unit 113 receives the map display processing start command sent from the execution control unit 111, the map display processing unit 113 starts executing the map display processing. Further, when the map display processing unit 113 receives the map display processing end command sent from the execution control unit 111, the map display processing unit 113 ends the execution of the map display processing.

  The voice recognition processing unit 114 receives the sound collection result sent from the sound collection unit 250. Then, the voice recognition processing unit 114 performs voice recognition processing on the collected sound result. The voice recognition result by the voice recognition processing unit 114 is sent to the execution control unit 111. By such processing of the voice recognition processing unit 114, for example, the input unit 140 described above can be supplemented.

  When the voice recognition processing unit 114 receives the voice recognition process start command sent from the execution control unit 111, the voice recognition processing unit 114 starts executing the voice recognition process. In addition, when the voice recognition processing unit 114 receives the voice recognition processing end command sent from the execution control unit 111, the voice recognition processing unit 114 ends the execution of the voice recognition processing.

  The wireless communication processing unit 115 performs processing for communication with the data server 600 using the wireless communication unit 130. By the wireless communication processing by the wireless communication processing unit 115, new sound source data can be acquired and update information of the map information MPI can be acquired.

  In addition, when the wireless communication processing unit 115 receives the wireless communication process start command sent from the execution control unit 111, the wireless communication processing unit 115 starts executing the wireless communication process. In addition, when the wireless communication processing unit 115 receives the wireless communication processing end instruction sent from the execution control unit 111, the wireless communication processing unit 115 ends the execution of the wireless communication processing.

  Further, the wireless communication processing unit 115 voluntarily ends the execution of the wireless communication process when the target communication designated by the wireless communication process start command ends. Then, the wireless communication processing unit 115 sends an end report to the execution control unit 111.

<< Configuration of Audio Reproduction Processing Unit 112A >>
Next, the configuration of the audio reproduction processing unit 112A will be described.

As shown in FIG. 4, the audio reproduction processing unit 112A includes a signal processing unit 310A and buffer units 320 ₁ and 320 ₂ . In addition, the audio reproduction processing unit 112A includes a selection unit 330A.

  The signal processing unit 310A receives the sound reproduction processing start command sent from the execution control unit 111. Here, the audio reproduction processing start command includes designation of a processing mode to be executed.

Upon receiving the audio reproduction processing start command, the signal processing unit 310A reads the pre-processing audio data from the sound source data CND after clearing the buffer units 320 ₁ and 320 ₂ . Subsequently, the signal processing unit 310A performs processing corresponding to the designated processing mode on the read pre-processed audio data, and generates reproduction content data. Then, the signal processing section 310A is generated reproduction content data, i.e., the processing result data, sent to the buffer unit 320 _1.

  The signal processing unit 310 </ b> A receives the mode transition command sent from the execution control unit 111. Here, the mode transition command includes designation of the processing mode of the transition destination.

  Upon receiving the mode transition command, the signal processing unit 310A corresponds to the processing mode of the designated transition destination for the read pre-processing audio data while continuing to read the pre-processing audio data from the sound source data CND. The audio reproduction process for performing signal processing is started. As a result, the signal processing unit 310A sends the processing result data to a buffer unit different from the buffer unit that has sent the processing result data so far. When the mode transition is thus completed, the signal processing unit 310A sends a mode transition completion report to the execution control unit 111.

Note that the processing result data sent to the buffer units 320 ₁ and 320 ₂ includes the time stamp information included in the pre-processing audio data.

  Further, the signal processing unit 310 </ b> A receives the audio reproduction processing end command sent from the execution control unit 111. When receiving the audio reproduction process end command, the signal processing unit 310A ends the process.

The buffer units 320 ₁ and 320 ₂ have a FIFO (Fast-In Fast-0ut) function. The buffer units 320 ₁ and 320 ₂ receive the processing result data sent from the signal processing unit 310A and temporarily store it. The data stored in the buffer units 320 ₁ and 320 ₂ is sequentially read by the selection unit 330A.

Said selection part 330A receives the audio | voice reproduction | regeneration processing start command sent from the execution control part 111. FIG. When receiving the audio reproduction process start command, the selection unit 330A starts the sequential reading of the processing result data stored in the buffer unit 320 _1. Then, the time stamp information in the processing result data is removed, and output sound data is generated. The output sound data generated in this way is sent to the sound output unit 220.

  The selection unit 330 </ b> A receives the mode transition command sent from the execution control unit 111. Upon receiving the mode transition command, the selection unit 330A causes the time stamp information in the processing result data read from the buffer unit used in the processing mode before the mode transition and the buffer unit used in the processing mode after the mode transition. The time stamp information in the first data block is monitored.

  As a result of the monitoring, the selection unit 330A reads the processing result data from the buffer unit used in the processing mode before the mode transition until the seamless reproduction can be performed when the reading buffer unit is switched, and Continue generating output sound data. When seamless reproduction can be performed when the reading buffer unit is switched, the selection unit 330A switches the reading buffer, reads the processing result data from the switched reading buffer unit, and outputs the output sound data. Start generation. Subsequently, the selection unit 330A clears the buffer unit used in the processing mode before the mode transition.

  In addition, the selection unit 330 </ b> A receives the audio reproduction processing end command sent from the execution control unit 111. Upon receiving the sound reproduction process end command, the selection unit 330A ends the generation of the output sound data.

<< Contents of load information LDI >>
Next, the content of the load information LDI described above will be described. Note that the processing load described later registered in the load information LDI is predetermined based on experiments, simulations, and the like.

As shown in FIG. 5, the load information LDI includes an execution control unit load (LR _EC ), a voice reproduction processing unit load, a map display processing unit load, a voice recognition processing unit load (LR _SR ), and a wireless communication processing unit load. (LR _CM ) is registered. As the load of the audio playback processing unit, the load when the quality of the playback audio is high (LR _HQ ), the load when the quality of the playback audio is normal quality (LR _NQ ), and the quality of the playback audio are low quality. A load (LR _LQ ) in a case is registered. Here, the relationship between the loads LR _HQ , LR _NQ , and LR _LQ is LR _HQ > LR _NQ > LR _LQ .

In addition, a load LR _Vj (j = 1, 2,..., MAX) corresponding to the vehicle speed is registered as the map display processing unit load. Here, the relationship between the loads LR _VM and LR _VN (VM <VN) is LR _VM <LR _VN . This is because the map display processing section load increases as the vehicle speed increases.

Note that the sum load of the load LR _EC , the load LR _HQ and the load LR _CM does not become an overload for the processing control unit 110A. Further, the total load of the load LR _EC , the load LR _LQ , the load LR _VMAX , the load LR _SR, and the load LR _CM is not overloaded to the processing control unit 110A.

<Operation>
Next, the operation of the information processing apparatus 100A configured as described above will be described mainly focusing on the execution control processing (processing load distribution processing) by the execution control unit 111.

  Here, it is assumed that the detection result of the vehicle speed of the vehicle CR is sequentially sent from the speed detection unit 210 to the processing control unit 110A. Further, it is assumed that the current position information of the vehicle CR is sequentially sent from the position detection unit 240 to the processing control unit 110A. Furthermore, it is assumed that the sound collection results are sequentially sent from the sound collection unit 250 to the processing control unit 110A.

  In the execution control process, as shown in FIG. 6, first, in step S <b> 11, the execution control unit 111 determines whether or not a new process start request has been received from the input unit 140. If the result of the determination in step S11 is negative (step S11: N), the process proceeds to step S13 described later.

  When a new process start request is received and the result of determination in step S11 is affirmative (step S11: Y), the process proceeds to step S12. In step S12, the execution control unit 111 executes a start process of a process specified in the new process start request (hereinafter also referred to as “start specifying process”). The start process of the start designation process will be described later.

  Next, in step S <b> 13, the execution control unit 111 determines whether a new process end request or end report has been received from the input unit 140. If the result of the determination in step S13 is negative (step S13: N), the process returns to step S11.

  If a new process end request or report is received and the result of determination in step S13 is affirmative (step S13: Y), the process proceeds to step S14. In step S14, a process end process is performed. The process end process will be described later.

  When the process of step S14 ends, the process returns to step S11. Thereafter, the processes of steps S11 to S14 are repeated.

<< Start process of start specification process in step S12 >>
Next, the start process of the start designation process in step S12 will be described.

  In the start process, as shown in FIG. 7, first, in step S21, the execution control unit 111 determines whether or not the start designation process is an audio reproduction process. If the result of the determination in step S21 is affirmative (step S21: Y), the process proceeds to step S22.

  In step S22, the execution control unit 111 determines the processing mode of the audio reproduction process. In making this determination, the execution control unit 111 first calculates the processing load of the processing control unit 110A due to the processing currently being executed with reference to the load information LDI. Subsequently, the execution control unit 111 determines, based on the calculated processing load, a processing mode that can achieve the highest playback sound quality within a range in which the processing control unit 110A does not become overloaded, as a processing mode of the sound playback processing to be executed from now on. To do.

  Next, in step S23, the execution control unit 111 sends a sound reproduction processing start command specifying the determined processing mode to the sound reproduction processing unit 112A. As a result, the audio reproduction processing unit 112A starts audio reproduction processing in the designated processing mode.

  When the process in step S23 is completed in this way, the process in step S12 is completed. Then, the process proceeds to step S13 in FIG.

  If the result of the determination in step S21 is negative (step S21: N), the process proceeds to step S24. In step S24, the execution control unit 111 determines whether or not audio reproduction processing is in progress. If the result of the determination in step S24 is negative (step S24: N), the process proceeds to step S29 described later.

  If the result of the determination in step S24 is affirmative (step S24: Y), the process proceeds to step S25. In step S25, the execution control unit 111 specifies the processing load of the start designation process with reference to the load information LDI.

  Next, in step S26, the execution control unit 111 determines whether it is necessary to change the processing mode of the audio reproduction process based on the specified processing load. When making such a determination, the execution control unit 111 needs to change modes depending on whether or not the processing load when the processing load of the start designation process is added to the current processing load is an overload for the processing control unit 110A. It is determined whether or not. If the result of the determination in step S26 is negative (step S26: N), the process proceeds to step S29.

  If the result of the determination in step S26 is affirmative (step S26: Y), the process proceeds to step S27. In step S27, the execution control unit 111 determines the processing mode of the transition destination with reference to the load information LDI. At the time of such determination, the execution control unit 111 determines the processing mode that can achieve the highest playback sound quality as the transition destination processing mode within a range that does not overload the processing control unit 110A even if the processing load of the start designation processing is added. To do.

  Subsequently, in step S28, the execution control unit 111 sends a mode transition command designating the transition destination processing mode to the sound reproduction processing unit 112A. As a result, the audio reproduction processing unit 112A starts audio reproduction processing in the designated processing mode.

  Next, in step S29, the execution control unit 111 sends a process start command to the processing unit that executes the start designation process. The execution control unit 111 sends the process start command after receiving the mode transition completion report from the audio reproduction processing unit 112A.

  When the process of step S29 ends, the process of step S12 ends. Then, the process proceeds to step S13 in FIG.

<< Processing Completion Process in Step S14 >>
Next, the process end process in step S14 will be described.

  In the process end process, as shown in FIG. 8, first, in step S31, the execution control unit 111 determines whether or not a process end request has been received. If the result of the determination in step S31 is negative (step S31: N), the process proceeds to step S34 described later.

  If the result of the determination in step S31 is affirmative (step S31: Y), the process proceeds to step S32. In step S32, the execution control unit 111 sends a process end command to the processing unit that is executing the end specifying process specified in the process end request. As a result, the execution of the process in the processing unit that is executing the end specifying process is completed.

  Next, in step S33, it is determined whether or not an audio reproduction process is in progress. If the result of determination in step S33 is negative (step S33: N), the process of step S14 ends. Then, the process returns to step S11 in FIG.

  If the result of the determination in step S33 is affirmative (step S33: Y), the process proceeds to step S34. In step S34, the execution control unit 111 specifies the processing load of the end process with reference to the load information LDI.

  Next, in step S35, the execution control unit 111 determines whether it is possible to change the processing mode of the audio reproduction process based on the specified processing load. At the time of such determination, the execution control unit 111 determines the current sound reproduction process within a range in which the load of the process control unit 110A is not overloaded based on the process load obtained by subtracting the process load of the end designation process from the process load so far. By determining whether or not the transition to the processing mode with higher reproduction quality is possible, it is determined whether or not the processing mode transition of the audio reproduction processing is possible.

  If the result of the determination in step S35 is negative (step S35: N), the process of step S14 ends. Then, the process returns to step S11 in FIG.

  If the result of the determination in step S35 is affirmative (step S35: Y), the process proceeds to step S36. In step S36, the execution control unit 111 determines a processing mode of the transition destination audio reproduction processing with reference to the load information LDI. At the time of such determination, the execution control unit 111 sets a processing mode that can achieve the highest reproduction sound quality within a range that does not cause an overload to the processing control unit 110A even if the audio reproduction processing in the transition destination processing mode is executed. Determine the mode.

  Subsequently, in step S37, the execution control unit 111 sends a mode transition command designating the determined processing mode to the sound reproduction processing unit 112A. As a result, the audio reproduction processing unit 112A starts audio reproduction processing in the designated processing mode.

  When the process of step S37 ends, the process of step S14 ends. Then, the process returns to step S11 in FIG.

  As described above, in the information processing apparatus 100A according to the first embodiment, the execution control unit 111 of the processing control unit 110A starts executing other processes other than the audio reproduction process in parallel with the audio reproduction process during the audio reproduction process. Prior to this, the processing load of the processing control unit 110A by the other processing is specified. Subsequently, the execution control unit 111 controls the sound reproduction processing unit 112A to control the transition to the processing mode according to the specified processing load. When the execution control unit 111 receives the mode transition completion report from the audio reproduction processing unit 112A, the execution control unit 111 sends a processing start command for executing the other processing to the processing unit that executes the start designation processing. As a result, the execution of the start designation process is started.

  Therefore, according to the first embodiment, it is possible to effectively suppress the occurrence of inappropriate reproduction of audio even if other processing is executed in parallel with the execution of audio reproduction processing.

  Further, in the first embodiment, when the other process is completed, the execution control unit 111 controls the sound reproduction processing unit 112A to control the transition to the processing mode that is executed when the other process is not executed. For this reason, the processing mode in which the reproduction quality can be maximized among the processing modes within the processing load that can be distributed to the execution of the audio reproduction processing can be determined as the processing mode to be executed by the audio reproduction processing unit 112A. As long as possible, high-quality content can be played back.

  In the first embodiment, when the processing mode is changed, the audio reproduction processing unit 112A performs a process for seamless reproduction using time stamp information included in the sound source data. For this reason, a user's uncomfortable feeling at the time of the transition of a processing mode can be suppressed.

[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference mainly to FIGS.

  The information processing apparatus according to the second embodiment is different from the information processing apparatus 100A according to the first embodiment described above in that an audio reproduction processing unit 112B configured as illustrated in FIG. 9 is used instead of the audio reproduction processing unit 112A. The only difference is the provision. Hereinafter, this difference will be mainly described.

  In the following description, the processing control unit including the audio reproduction processing unit 112B is referred to as “processing control unit 110B”. The information processing apparatus according to the second embodiment including the processing control unit 110B is referred to as “information processing apparatus 100B”.

As shown in FIG. 9, the audio reproduction processing unit 112B includes a signal processing unit 310B and buffer units 320 ₁ and 320 ₂ . The audio reproduction processing unit 112B includes a blending unit 330B.

The signal processing unit 310B receives the sound reproduction processing start command sent from the execution control unit 111. When receiving the audio reproduction processing start command, the signal processing unit 310B clears the buffer units 320 ₁ and 320 ₂ and then reads the pre-processing audio data from the sound source data CND. Subsequently, as in the case of the signal processing unit 310A described above, the signal processing unit 310B performs processing corresponding to the processing mode specified in the audio reproduction processing start command on the read pre-processing audio data. Then, the signal processing section 310B sends the process result data to the buffer unit 320 _1.

  In addition, the signal processing unit 310B receives the mode transition instruction sent from the execution control unit 111. Upon receiving the mode transition instruction, the signal processing unit 310B continues to read the pre-processing audio data from the sound source data CND, and changes to the designated transition destination processing mode for the read pre-processing audio data. The audio reproduction process for applying the corresponding signal processing is started. Then, the signal processing unit 310B sends the processing result data to a buffer unit different from the buffer unit that has sent the processing result data so far. When the mode transition is thus completed, the signal processing unit 310B sends a mode transition completion report to the execution control unit 111.

  Note that the signal processing unit 310B includes processing result data stored in the buffer unit used before the mode transition and processing result data stored in the buffer unit used before the mode transition are time stamp information. At least one of them includes the same processing result data.

  In addition, the signal processing unit 310 </ b> B receives the audio reproduction processing end command sent from the execution control unit 111. When receiving the audio reproduction processing end command, the signal processing unit 310B ends the processing.

The blending unit 330B receives the sound reproduction processing start command sent from the execution control unit 111. When receiving the audio reproduction process start command, the blend unit 330B, as in the case of the selection section 330A described above, starts sequentially reading the processing result data stored in the buffer unit 320 _1. Then, the time stamp information in the processing result data is removed, and output sound data is generated. The output sound data generated in this way is sent to the sound output unit 220.

  The blending unit 330B receives the mode transition command sent from the execution control unit 111. Upon receiving the mode transition command, the blending unit 330B causes the time stamp information in the processing result data read from the buffer unit used in the processing mode before the mode transition and the buffer used in the processing mode after the mode transition. The time stamp information in the first data block in the section is monitored.

As a result of the monitoring, the time stamp information into two at time T _BS is identical, the blend unit 330B starts crossfading. Thereafter, crossfade processing is performed until time (T _BS −T _BE ) elapses and time T _BE is reached, and output sound data is generated.

During the cross-fade processing period, the data obtained by removing the time stamp information from the processing result data read from the buffer unit used in the processing mode before the mode transition is defined as X ₁ (T), and the processing mode after the mode transition Output data X (T) is generated by the following equation (1), where X ₂ (T) is the data obtained by removing the time stamp information from the processing result data read from the buffer used in FIG. .
X (T) = C ₁ (T) · X ₁ (T) + C ₂ (T) · X ₂ (T) (1)

Here, the coefficient C ₁ (T) changes from “1” to “0” during the cross-fade processing period. The coefficient C ₂ (T) changes from “0” to “1” during the cross-fade process. The sum of the coefficient C ₁ (T) and the coefficient C ₂ (T) is maintained at “1”.

The coefficient C ₁ (T) is set to “1” before the crossfade processing period and is set to “0” after the crossfade period. The coefficient C ₂ (T) is “0” before the cross-fade processing period, and is “1” after the cross-fade period.

An example of the time change of the coefficients C ₁ (T) and C ₂ (T) is shown in FIG.

  As described above, in the information processing apparatus 100B of the second embodiment, the execution control unit 111 of the processing control unit 110B performs the audio parallel to the audio reproduction process during the audio reproduction process, as in the first embodiment. Prior to the start of execution of other processes other than the reproduction process, the processing load of the process control unit 110B due to the other processes is specified. Subsequently, the execution control unit 111 controls the sound reproduction processing unit 112B to control the transition to the processing mode according to the specified processing load. When the execution control unit 111 receives the mode transition completion report from the audio reproduction processing unit 112B, the execution control unit 111 sends a start command for executing the other process to the processing unit that executes the start designation process. As a result, the execution of the start designation process is started.

  Therefore, according to the second embodiment, it is possible to effectively suppress the occurrence of inappropriate reproduction of audio even if other processing is executed in parallel with the execution of audio reproduction processing.

  Further, in the second embodiment, as in the case of the first embodiment, when the other process ends, the execution control unit 111 controls the transition to the processing mode that is executed when the other process is not executed. This is performed for the audio reproduction processing unit 112B. For this reason, the processing mode with the highest reproduction quality among the processing modes within the processing load that can be distributed to the execution of the audio reproduction processing can be determined as the processing mode to be executed by the audio reproduction processing unit 112B, As long as possible, high-quality content can be played back.

  In the second embodiment, the audio reproduction processing unit 112B performs a process for crossfading when the processing mode is changed. For this reason, a user's uncomfortable feeling at the time of the transition of a processing mode can be suppressed.

[Third embodiment]
Next, a third embodiment of the present invention will be described with reference mainly to FIGS.

  The information processing apparatus according to the third embodiment is different from the information processing apparatus 100A according to the first embodiment described above in that an audio reproduction processing unit 112C configured as shown in FIG. 11 is used instead of the audio reproduction processing unit 112A. The only difference is the provision. Hereinafter, this difference will be mainly described.

  In the following description, the processing control unit including the audio reproduction processing unit 112C is referred to as “processing control unit 110C”. The information processing apparatus according to the third embodiment including the processing control unit 110C is referred to as “information processing apparatus 100C”.

  The audio reproduction processing unit 112C includes a signal processing unit 310C and a buffer unit 320, as shown in FIG. In addition, the audio reproduction processing unit 112C includes an output unit 330C.

The buffer unit 320 has a FIFO (Fast-In Fast-0ut) function, similar to the buffer units 320 ₁ and 320 ₂ described above. The buffer unit 320 receives the processing result data sent from the signal processing unit 310C and temporarily stores it. Data stored in the buffer unit 320 is sequentially read by the output unit 330C. Then, the output unit 330C sends the data read from the buffer unit 320 to the sound output unit 220 as output sound data.

  The signal processing unit 310 </ b> C receives the sound reproduction processing start command sent from the execution control unit 111. When receiving the audio reproduction processing start command, the signal processing unit 310C clears the buffer unit 320 and then reads the pre-processing audio data from the sound source data CND. Subsequently, as in the case of the signal processing unit 310A described above, the signal processing unit 310C performs processing corresponding to the designated processing mode on the read pre-processing audio data. Then, the signal processing unit 310C sends the processing result data to the buffer unit 320.

  In the third embodiment, the processing result data does not include time stamp information.

In addition, the signal processing unit 310C receives a mode transition command sent from the execution control unit 111. Upon receiving the mode transition command, the signal processing unit 310C generates data Y (T) that has been subjected to signal processing in the processing mode before the mode transition while continuing to read the pre-processing audio data from the sound source data CND. After that, fade-out processing according to the following equation (2) is performed to generate output sound data X (T), and the generated output sound data is sent to the buffer unit 320.
X (T) = C (T) · Y (T) (2)

The coefficient C (T) changes with time from “1” to “0” in a fade-out period having a first predetermined period length from time _TFS to time _TSW . Here, the coefficient C (T) is “1” before the fade-out period.

  When the fade-out period ends, the signal processing unit 310C makes a transition to the processing mode specified in the mode transition command, and sends a mode transition completion report to the execution control unit 111. Then, the signal processing unit 310C generates the data Y (T) subjected to the signal processing process in the processing mode specified in the mode transition command, and then performs the fade-in process according to the above-described equation (2). Output sound data X (T) is generated, and the generated output sound data is sent to the buffer unit 320.

The coefficient C (T) changes over time from “0” to “1” in the fade-in period having the second predetermined period length from time T _SW to time T _FE . Here, the coefficient C (T) is set to “1” after the fade-in period.

  An example of the time change of the coefficient C (T) is shown in FIG.

  As described above, in the information processing apparatus 100C of the third embodiment, the execution control unit 111 of the processing control unit 110C performs the audio parallel to the audio reproduction process during the audio reproduction process, as in the first embodiment. Prior to the start of execution of other processes other than the reproduction process, the processing load of the process control unit 110C by the other process is specified. Subsequently, the execution control unit 111 controls the sound reproduction processing unit 112 </ b> C to control transition to the processing mode according to the specified processing load. When the execution control unit 111 receives the mode transition completion report from the sound reproduction processing unit 112C, the execution control unit 111 sends a start command for executing the other processing to the processing unit that executes the start designation processing. As a result, the execution of the start designation process is started.

  Therefore, according to the third embodiment, it is possible to effectively suppress the occurrence of inappropriate reproduction of audio even when other processing is executed in parallel with the execution of audio reproduction processing.

  Further, in the third embodiment, as in the case of the first embodiment, when the other process ends, the execution control unit 111 controls the transition to the processing mode executed when the other process is not executed. This is performed on the sound reproduction processing unit 112C. Therefore, among the processing modes within the processing load that can be distributed to the execution of the audio reproduction processing, the processing mode that can achieve the highest reproduction quality can be determined as the processing mode that the audio reproduction processing unit 112C should execute, As long as possible, high-quality content can be played back.

  In the third embodiment, the sound reproduction processing unit 112C sequentially performs a fade-out process and a fade-in process when the processing mode is changed. For this reason, a user's uncomfortable feeling at the time of the transition of a processing mode can be suppressed.

[Modification of Example]
Various modifications can be made to the first to third embodiments.

  For example, in the above first to third embodiments, the playback content is audio content, but the playback content may be content other than audio content.

  In the first to third embodiments, the processing for suppressing the user's uncomfortable feeling is performed at the time of transition of the processing mode. However, such processing may not be performed. In addition, a process different from the above first to third embodiments may be performed as a process capable of suppressing the user's uncomfortable feeling during the transition of the process mode.

  In the first to third embodiments, the sound source data is stored in the storage unit. On the other hand, the pre-processing audio data may be read from a portable recording medium such as a CD (Compact Disc) or a DVD (Digital Versatile Disc) on which sound source data is recorded.

  Moreover, you may employ | adopt changes other than the time change example of the coefficient shown to FIG.10 and FIG.12.

  Moreover, in said 1st-3rd Example, although the map display process and the speech recognition process were illustrated as another process, in addition to these or instead of these, another process is employ | adopted as another process. May be.

  In the first and second embodiments, the sound source data includes time stamp information. On the other hand, when the time stamp information is not included in the sound source data, the time stamp information may be generated using the method described in the modification of the above-described embodiment. In the case of the third embodiment, it goes without saying that the time stamp information does not have to be included in the sound source data.

  In the first to third embodiments, the process is performed prior to the start of execution of processes other than the audio reproduction process in parallel with the audio reproduction process until the transition to the processing mode in which the reproduction quality is deteriorated. The first transition time is the same as the second transition time until the transition to the processing mode in which the reproduction quality is improved when the other processes other than the audio reproduction process in parallel with the audio reproduction process are completed. . On the other hand, you may make it make 2nd transition time longer than 1st transition time. This is because it is necessary to shorten the first transition time as much as possible in order to start the execution of other processing quickly, but when the reproduction quality is improved, it is not always necessary to quickly transition to the processing mode. It is. For this reason, for example, the second transition time can be set to the time until the end of the music being played. In this case, since frequent changes in the processing mode do not occur, it is expected that the sense of incongruity that occurs during transition can be reduced.

  In the first to third embodiments, the process mode transition is performed after a process start request for processes other than the audio reproduction process in parallel with the audio reproduction process is input to the input unit. did. On the other hand, the processing mode may be changed when it is determined that the probability that a processing start request for other processing is input to the input unit has increased. For example, when the other process selection screen for inputting a process start request to the input unit is displayed, the other processing load is the highest among the other processes displayed on the other process selection screen. It is possible to change the processing mode according to the processing load of the processing.

  Moreover, in said 1st-3rd Example, although the information processing apparatus was arrange | positioned in the vehicle, you may make it arrange | position in mobile bodies other than a vehicle. Furthermore, it is needless to say that the present invention can be applied even when a moving body is not arranged.

100A to 100C ... Information processing apparatus 110A to 110C ... Processing control unit (processing unit, other processing load specifying unit,
Mode transition control unit)
700 ... Information processing device 740 ... Processing unit 741 ... Other processing load specifying unit 742 ... Mode transition control unit

Claims (12)

In an information processing apparatus including a processing unit capable of executing in parallel processing other than the generation processing of the content data for reproduction and the generation processing,
The generation process includes a plurality of processing modes having different processing loads of the processing unit,
Prior to the start of execution of the other processing, the processing unit,
Another processing load specifying unit for specifying the processing load of the processing unit due to the other processing;
A mode transition control unit that controls the first transition to the processing mode according to the identified processing load;
An information processing apparatus comprising:   The information processing apparatus according to claim 1, wherein the processing unit starts execution of the other processing after transition of the processing mode.   The said mode transition control part controls the 2nd transition to the process mode performed when the said other process is not performed, when the said other process is complete | finished. Information processing device.   The information processing apparatus according to claim 1, wherein the reproduction content data includes output sound data. The playback content data includes time stamp information,
The information processing apparatus according to any one of claims 1 to 4, wherein the processing unit performs a seamless reproduction process with reference to the time stamp information at the time of the first transition.   The processing unit generates the first reproduction content data generated in the first processing mode applied before the start of the mode transition and the second processing mode applied after the end of the mode transition in the first transition. The information processing apparatus according to any one of claims 1 to 4, wherein a cross-fade reproduction process based on the second reproduction content data is performed. The processing unit, during the first transition,
A fade-out process for the first reproduction content data generated in the first processing mode before the transition of the processing mode;
Transition processing from the first processing mode to the second processing mode after the fade-out processing is completed, and
A fade-in process for the second playback content data generated in the second processing mode;
The information processing apparatus according to claim 1, wherein the information processing is performed sequentially.   When the execution start request for the other process using the input unit connected to the processing unit is input, the other processing load specifying unit specifies the processing load of the processing unit due to the other process. The information processing apparatus according to claim 1, wherein the information processing apparatus is characterized. When the other processing is guidance guidance processing related to movement of a moving object that moves with the processing unit, the other processing load specifying unit performs processing of the processing unit by the other processing as the moving speed of the moving object increases. Identify high load,
The information processing apparatus according to claim 1, wherein the information processing apparatus is an information processing apparatus. A processing load distribution method used in an information processing apparatus including a processing unit capable of executing processing for generating content data for reproduction and processing other than the generation processing in parallel,
The generation process includes a plurality of processing modes having different processing loads of the processing unit,
Prior to the start of execution of the other processing, the processing unit,
Another processing load specifying step of specifying the processing load of the processing unit due to the other processing;
A mode transition control step of performing transition control to a processing mode according to the specified processing load;
Processing load distribution method to execute.   A processing load distribution program that causes a computer included in an information processing apparatus to execute the processing load distribution method according to claim 10.   12. A recording medium on which the processing load distribution program according to claim 11 is recorded so as to be readable by a computer included in the information processing apparatus.

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