JP5482676B2 - REPRODUCTION DEVICE, RECORDING DEVICE, REPRODUCTION METHOD, RECORDING METHOD, AND PROGRAM - Google Patents

Description

  The present invention relates to a playback apparatus that plays back content recorded on a medium, a recording apparatus that records content on a medium, a playback method, a recording method, and a program.

  Proposals have been proposed for reproducing content recorded on an optical disc such as a BD (Blue-ray Disc), DVD (Digital Versatile Disc), CD (Compact Disc), etc., and a recording device for recording content on an optical disc (for example, , See Patent Document 1).

  There are various standards for optical disks, and new standards are defined as needed. For example, in the case of BD, there are standards (profiles) such as Profile 1.1 and Profile 2.0. Profill 1.1 provides a function called Bonus View including Picture-in-Picture and Virtual Package. Profile2.0 provides a function called BD-Live including BD-J Network Access (Blu-ray Cis Java (registered trademark)) and Progressive Playlist.

  The playback device and recording device are manufactured so as to conform to the standard of the optical disc. However, in order to play back an optical disc in which content of a new standard is recorded, it is necessary to update the firmware held by the playback device. Similarly, in the case of a recording device, in order to record content on an optical disc in accordance with a new standard, it is necessary to update the firmware held by the recording device.

  For example, in the case of a BD playback apparatus, new firmware for dealing with a new profile is provided about twice a month. Some profiles, such as Profil 1.1 Virtual Package, must be handled. Therefore, it is essential to update about once a month. For updating the firmware of the BD playback apparatus, a method using a storage medium such as a CD, a DVD, or a flash memory may be employed. However, since the update frequency is high, a method via a network line is generally employed.

  In addition, in order to comply with a new standard, an addition or a change may be required to the configuration of the apparatus. More than a predetermined amount of memory is required to support the above-described Virtual Package. Therefore, in the case of a BD playback device that does not include the memory, it is necessary to add a memory inside or outside the BD playback device.

JP 2010-146695 A

  However, the BD profile includes functions that are practically unsuitable for use depending on the application of the BD playback apparatus, or functions that are considered to be less frequently used. For such a function, handling on software or hardware imposes an extra burden on the user or developer, and causes the structure or size of the BD playback device to become complicated. There is a problem.

  For example, when the application of the BD playback apparatus is for in-vehicle use, the display screen is smaller and the resolution is lower than that for home use. For this reason, even if Picture-in-Picture is used, characters and images displayed on the child screen are crushed, and the user cannot recognize them.

  In addition, when the BD playback apparatus is for in-vehicle use, it is considered that the Virtual Package is not used much. In order to support the virtual package, a large-capacity memory is required as described above. This increases the size of the BD playback device. In the in-vehicle BD playback device, it is difficult to secure a space for attaching the expansion memory to the outside.

  Furthermore, when dealing with complicated processing such as Picture-in-Picture and Virtual Package, processing executed in the firmware becomes complicated, and the file size becomes large. The cost required to update and develop such firmware is significant.

  In addition, in order to execute complicated processing, a BD equipped with a high-performance computing device, a large-capacity memory, a power source capable of responding to an increase in power consumption, a cooling fan for releasing an increasing amount of heat generation, etc. It is necessary to improve the specifications of the playback device. For this reason, the BD playback apparatus has a complicated structure or becomes large.

  The present invention has been made in view of the above circumstances, and provides a compact playback device that has a simple structure and does not require firmware update or reduces the frequency depending on the use of the device. For the purpose.

In order to achieve the above object, a playback apparatus according to the first aspect of the present invention provides:
Vibration detecting means for detecting vibration generated in the playback device and outputting vibration detection information including the detected number of vibrations;
The vibration detection information is acquired, and based on the number of vibrations included in the acquired vibration detection information, the reproduction apparatus is used for either a first application with a certain level of vibration or a second use without a certain level of vibration. Determining means for determining whether or not
To read the content information recorded on the medium in the first mode, which has a different function from the second mode suitable for reproduction in the second application when the determination means determines that the first application is used. A reproduction control means for executing the process of reading the content information and processing the read content information ;
Audio output means for outputting audio ,
The vibration detection means, if there is no sound output from the sound output unit to detect vibrations, characterized by also be output from the vibration detection information.

The reproduction control means outputs a servo signal in a process for reading content information from a medium,
The vibration detection unit may acquire a servo signal from the reproduction control unit, detect a vibration having a magnitude greater than a threshold value based on the acquired servo signal, and output vibration detection information including the detected number of vibrations. Good.

  The vibration detection means may include a sensor for detecting vibration, detect vibration having a magnitude greater than a threshold based on a signal from the sensor, and output vibration detection information including the detected number of vibrations. .

  The reproduction control means may perform control so that no sound is output from the sound output means when the vibration detection means detects vibration.

Furthermore, silence determination for acquiring audio information indicating audio included in the content from the reproduction control unit and determining whether or not the content being reproduced includes audio based on the acquired audio information. With means,
The vibration detection means may detect vibration and output vibration detection information when the silence determination means determines that no sound is included.

  The vibration detection unit may detect vibration and output the vibration detection information while the reproduction control unit executes processing for reading content information recorded on the medium.

Furthermore, it comprises reproduction determination means for obtaining reproduction information indicating whether or not the content is being reproduced from the reproduction control means, and determining whether or not the content is being reproduced based on the obtained reproduction information,
The vibration detection unit may detect vibration and output vibration detection information when the reproduction determination unit determines that the content is not being reproduced.

The discrimination means includes
Vibration number comparison means for acquiring the vibration detection information and comparing the threshold value with the number of vibrations included in the acquired vibration detection information;
If the number of vibrations is equal to or greater than a threshold value as a result of comparison by the vibration number comparison unit, use determination unit that determines that the first use is included may be provided.

The vibration detection means outputs vibration detection information including the detected number of vibrations and the number of samplings for detecting vibrations,
The discrimination means includes
A detection rate calculation means for calculating a vibration detection rate that is a ratio of detecting a vibration by dividing the number of vibrations included in the vibration detection information by the number of samplings, and outputting vibration detection rate information indicating the calculated vibration detection rate When,
Detection rate comparison means for acquiring the vibration detection rate information and comparing the acquired vibration detection rate with a threshold;
As a result of comparison by the detection rate comparison means, there may be provided application determining means for determining the first application when the vibration detection rate is equal to or greater than a threshold value.

A recording apparatus according to the second aspect of the present invention is
Vibration detection means for outputting vibration detection information relating to the vibration of the recording apparatus;
The vibration detection information is acquired, and based on the acquired vibration detection information, it is determined whether the use of the recording apparatus is a first use with a certain level of vibration or a second use without a certain level of vibration. Discriminating means to perform,
When it is determined by the determining means that the application is the first use, content information is generated in the first mode that is different from the second mode suitable for recording in the second application, and the generated content information is Recording control means for executing control for recording on a medium;
It comprises output means for acquiring the generated content information from the recording control means and recording the content information on a medium.

A reproduction method according to the third aspect of the present invention is as follows.
When there is no sound output from the playback device, the vibration generated in the playback device is detected, and vibration detection information including the detected number of vibrations is output,
The vibration detection information is acquired, and based on the number of vibrations included in the acquired vibration detection information, the reproduction apparatus is used for either a first application with a certain level of vibration or a second use without a certain level of vibration. Is determined,
When it is determined to be the first application, a process for reading the content information recorded on the medium is executed in the first mode, which is different from the second mode suitable for reproduction in the second application. Then, the content information is read, and the read content information is processed.

A recording method according to the fourth aspect of the present invention is
Output vibration detection information about the vibration of the recording device,
The vibration detection information is acquired, and based on the acquired vibration detection information, it is determined whether the use of the recording apparatus is a first use with a certain level of vibration or a second use without a certain level of vibration. And
When it is determined to be the first application, content information is generated in the first mode that is different from the second mode suitable for recording in the second application, and the generated content information is recorded on the medium. Control for and
The generated content information is acquired, and the content information is recorded on a medium.

A program according to the fifth aspect of the present invention is:
When there is no sound output from the playback device, the vibration generated in the playback device is detected, and vibration detection information including the detected number of vibrations is output,
The vibration detection information is acquired, and based on the number of vibrations included in the acquired vibration detection information, the reproduction apparatus is used for either a first application with a certain level of vibration or a second use without a certain level of vibration. Is determined,
When it is determined to be the first application, a process for reading the content information recorded on the medium is executed in the first mode, which is different from the second mode suitable for reproduction in the second application. Then, the content information is read, and the computer is caused to execute processing of the read content information.

A program according to the sixth aspect of the present invention is
Output vibration detection information about the vibration of the recording device,
The vibration detection information is acquired, and based on the acquired vibration detection information, it is determined whether the use of the recording apparatus is a first use with a certain level of vibration or a second use without a certain level of vibration. And
When it is determined to be the first application, content information is generated in the first mode that is different from the second mode suitable for recording in the second application, and the generated content information is recorded on the medium. Control for and
It is characterized by causing a computer to acquire the generated content information and record the content information on a medium.

  According to the present invention, the playback device or the recording device discriminates the use based on the vibration detection information related to the vibration, and when it is discriminated that the use is the first use with a certain level of vibration, Can play or record content in the first mode, which uses different functions.

  Since the function used in the first mode is different from that in the second mode, it is not necessary to update the firmware when the first mode is determined, or the frequency of updating the firmware is reduced. It becomes possible. Further, in the first mode, it can be set so that processing can be performed by a reproducing apparatus or recording apparatus having a lower specification than in the case of using the second mode. Therefore, the structure of the reproducing device or the recording device can be simplified and made compact.

It is a figure which shows the structure of the BD reproducing | regenerating apparatus concerning 1st Embodiment of this invention. It is a figure which shows an example of the mode information memorize | stored in the mode information storage part. It is a figure which shows the detailed structure of the vibration detection part which concerns on 1st Embodiment. It is a figure which shows the detailed structure of the discrimination | determination part concerning 1st Embodiment. It is a flowchart of the process which the BD reproducing | regenerating apparatus concerning 1st Embodiment performs. It is a flowchart which shows the detail of the vibration detection process which concerns on 1st Embodiment. It is a flowchart which shows the detail of the use determination process which concerns on 1st Embodiment. It is a figure which shows the structure of the BD reproducing | regenerating apparatus concerning 2nd Embodiment of this invention. It is a flowchart of the process which the BD reproducing | regenerating apparatus concerning 2nd Embodiment performs. It is a flowchart of the process which the BD reproducing | regenerating apparatus concerning 3rd Embodiment of this invention performs. It is a figure which shows the structure of the BD reproducing | regenerating apparatus concerning 4th Embodiment of this invention. It is a figure which shows the structure of the BD reproducing | regenerating apparatus concerning 6th Embodiment of this invention. It is a flowchart of the process which the BD reproducing | regenerating apparatus concerning 6th Embodiment performs. It is a figure which shows the structure of the BD reproducing | regenerating apparatus concerning 7th Embodiment of this invention. It is a figure which shows the detailed structure of the vibration detection part which concerns on 7th Embodiment. It is a figure which shows the detailed structure of the discrimination | determination part concerning 7th Embodiment. It is a flowchart of the process which the BD reproducing | regenerating apparatus concerning 7th Embodiment performs. It is a flowchart which shows the detail of the vibration detection process which concerns on 7th Embodiment. It is a flowchart which shows the detail of the application determination process which concerns on 7th Embodiment. It is a figure which shows an example of the structure with which the BD recording device which concerns on this invention is provided. It is a figure which shows an example of the physical structure of the BD reproducing | regenerating apparatus concerning this invention. It is a figure which shows an example of the physical structure of the BD recording device based on this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the same component and process throughout a figure. Moreover, the description which overlaps about the same component and process is abbreviate | omitted through all embodiment.

(First embodiment)
A BD (Blue-ray Disc) playback device 100 according to a first embodiment of the present invention will be described with reference to FIGS.

  The BD playback device 100 is a device that plays back content indicated by content information recorded on a BD as a medium, detects vibration using a servo signal generated when executing processing for reading content, The use is determined based on the detected number of vibrations.

  As shown in FIG. 1, the BD playback device 100 includes a discrimination information storage unit 101 and a mode information storage unit 102. Each of the storage units 101 and 102 is realized by a storage medium such as a hard disk or a flash memory.

  The discrimination information storage unit 101 stores discrimination information 101a. The discrimination information 101a is information indicating the use of the BD playback device 100 determined by the BD playback device 100. In the present embodiment, as applications, a description will be given of an example of conveyance (first application) that is an application involving a certain level of vibration and stationary (second application) that is an application that is not accompanied by a certain level of vibration.

  Here, the term “for stationary use” refers to an application in which the BD playback apparatus 100 is installed and used at a certain position in a general home or office. The term “for transportation” refers to an application for transportation and use such as portable or vehicle-mounted. In the case of in-vehicle use, the BD playback device 100 may be incorporated in a car navigation system or the like.

  FIG. 1 shows an example in which the discrimination information storage unit 101 stores information indicating “for transport” as discrimination information 101a.

  The mode information storage unit 102 stores mode information 102 a that indicates a content playback method (mode) suitable for the use of the BD playback device 100. The mode is determined in advance according to the use that is determined by the BD playback apparatus 100 by the user or the like, and is stored in advance in the mode information storage unit 102 as mode information 102a indicating the mode.

  As shown in FIG. 2, the mode information 102a of the present embodiment includes information indicating a transport mode (first mode) that is a playback method suitable for transport, and a stationary mode that is a playback method suitable for stationary. Information indicating (second mode).

  The stationary mode is a playback method that can use all the functions included in all profiles of the BD. The transport mode is an example of a playback method in which usable functions are limited as compared with the stationary mode, and is a playback method in which playback using the Bonus View is limited among the functions included in all profiles of the BD.

  Returning to FIG. 1, the BD playback apparatus 100 further includes a playback control unit 103, a vibration detection unit 104, a determination unit 105, and an input reception unit 106. Each processing unit 103 to 106 is realized by, for example, a processor that executes a computer program.

  The playback control unit 103 reads the content information by executing processing for reading the content information recorded on the BD 107 from the BD 107. Processing for reading content information from the BD 107 includes focus servo, tracking servo, rotation control of the BD 107, and the like.

  Further, the reproduction control unit 103 refers to the discrimination information 101a stored in the discrimination information storage unit 101 and the mode information 102a stored in the mode information storage unit 102, and specifies the mode information 102a corresponding to the discrimination information 101a. . The reproduction control unit 103 processes the read content information according to the mode indicated by the identified mode information 102a. The content information processing includes processing for generating information in a format that can be output by a monitor, a speaker, and the like from the content information, processing for controlling output of the generated information, and the like. A process for controlling the output of the generated information includes, for example, a volume adjustment process.

Vibration detection unit 104 acquires the servo signal from the reproduction control unit 103, detects a vibration generated in the BD playback apparatus 100 based on the obtained servo signals, including vibration number N _V detected in the vibration detection time VDT Outputs vibration detection information.

The vibration detection unit 104 includes a comparator, for example. The comparator acquires a servo signal, and outputs a signal indicating that the vibration is detected when the servo signal includes vibration exceeding the threshold value. The vibration detection unit 104 counts the number of times the above signal is output from the comparator during a predetermined vibration detection time VDT. Thus, the number of vibrations N _V is calculated.

The vibration detection unit 104 may further include, for example, a band-pass filter that passes a signal of several tens to several hundreds of hertz, and the comparator may acquire the servo signal via the band-pass filter. Thus, vibration of the range of frequencies is not included in the number of oscillations N _V, it is possible to calculate the number of vibrations N _V except for noise.

  The servo signal is a signal generated by the reproduction control unit 103 in order to read content information from the BD 107, and is, for example, a tracking error (TE) signal. The servo signal may be a focus error (FE) signal, a radio frequency (RF) signal during content reproduction, or the like.

  In terms of cost, it is preferable to detect vibration using a servo signal, but vibration may be detected using a separate vibration sensor (see the fourth to sixth embodiments).

FIG. 3 shows details of the vibration detection unit 104. The vibration detection unit 104 includes a vibration number storage unit 111. Vibration frequency storage unit 111 stores a vibration count information indicating the detected number of oscillations _{N V,} is realized by a RAM (Random Access Memory).

  The vibration detection unit 104 includes a timer 112, an initialization unit 113, a sampling unit 114, a signal comparison unit 115, and an increment unit 116.

  The timer 112 measures the vibration detection time VDT. The timer 112 is realized using, for example, a clock signal generated by a processor of the BD playback device 100 or the like.

  The initialization unit 113 starts the timer 112 and resets the vibration frequency information stored in the vibration frequency storage unit 111 as an initialization process for detecting vibration.

The sampling unit 114 acquires a servo signal from the reproduction control unit 103 for a time T ₁ (milliseconds) set in advance as the vibration detection time VDT, and generates a vibration detection signal T _SHOCK based on the acquired servo signal. To do.

The vibration detection signal T _SHOCK is generated, for example, by passing a servo signal for sampling time ST (milliseconds) out of the servo signal acquired at the vibration detection time VDT through a band-pass filter. In this case, the vibration detection signal T _SHOCK is a signal indicating the magnitude of the predetermined frequency component.

The signal comparison unit 115 compares the magnitude indicated by each vibration detection signal T _SHOCK with a preset threshold value TV ₁ (mV), and outputs information indicating the comparison result.

The increment unit 116 acquires information indicating the comparison result from the signal comparison unit 115. When the size of the vibration detection signal _{T SHOCK} is the threshold value TV ₁ or more, the increment unit 116 increments the number of vibrations _{N V} indicated by the oscillation frequency information stored in the vibration frequency storage unit 111. Thus, the number of vibrations N _V indicated by the oscillation frequency information will indicate the number of vibrations of the BD playback apparatus 100 detected in the vibration detection time VDT.

  Each processing unit 113 to 116 is realized by a processor or the like that executes a computer program.

  Next, the determination unit 105 illustrated in FIG. 1 acquires vibration frequency information from the vibration detection unit 104, and determines whether the use of the BD reproduction apparatus 100 is for stationary use or for conveyance based on the acquired vibration frequency information. Then, information indicating the discrimination result is output.

  As shown in FIG. 4, the determination unit 105 includes a vibration frequency comparison unit 121 and a use determination unit 122.

The number of vibrations comparison unit 121 acquires the number of vibrations information stored in the vibration frequency storage unit 111 from the increment unit 116 of the vibration detection unit 104, the obtained number of vibrations N _V with a preset threshold TV vibration times information indicates ₂ is output, and information indicating the comparison result is output.

The application determining unit 122 determines whether the application of the BD playback device 100 is “for stationary” or “for transport” based on the comparison result indicated by the information acquired from the vibration frequency comparing unit 121. Specifically, application determination unit 122, when the number of vibrations N _V is the threshold value TV ₂ or more, and determined to be a transport, when the number of vibrations N _V is less than the threshold TV _2, in a stationary Determine that there is. In addition, the usage determining unit 122 outputs information indicating the determination content to the discrimination information storage unit 101 and the reproduction control unit 103.

  Each processing unit 121 to 123 is realized by a processor or the like that executes a computer program.

From here, it returns to description of FIG. 1 again.
The input receiving unit 106 receives a signal input when a user or the like operates a button or the like (not shown) provided in the remote controller or the BD playback device 100, and outputs the received signal.

  The output unit 108 acquires content information processed by the playback control unit 103 from the playback control unit 103 and outputs the content. The output unit 108 includes, for example, a monitor as the image output unit 109 that outputs an image, and a speaker as the audio output unit 110 that outputs sound.

The thus configured BD playback apparatus 100, the vibration is detected and the application based on the detected number of vibrations N _V is to determine which of the conveyance and Stationary, in accordance to the determined application mode The content recorded on the BD 107 can be reproduced.

  From here, the process which BD reproducing | regenerating apparatus 100 performs is demonstrated with reference to FIGS. FIG. 5 shows an outline of processing executed by the BD playback device 100.

  The input receiving unit 106 receives a signal indicating a playback start instruction based on a user operation (step S101).

  Upon receiving an instruction from the input reception unit 106 that has received a signal indicating a reproduction start instruction, the reproduction control unit 103 executes processing for reading content information from the BD 107. Subsequently, the reproduction control unit 103 reads the content information and processes the read content information. At this time, the reproduction control unit 103 processes the content information so that the output unit 108 outputs the content without sound (silence reproduction processing, step S102).

  Here, any method may be used for outputting the content without sound. For example, there are a method for setting the volume to zero and a method for blocking the output of the audio signal to the audio output unit 110. By outputting the content without sound, it is possible to eliminate the influence of vibration caused by sound on vibration detection of the BD playback device 100.

The vibration detection unit 104 acquires a servo signal generated in the process for reading the content information from the BD 107 from the reproduction control unit 103, detects vibration based on the acquired servo signal, and is detected at the vibration detection time VDT. and it outputs a vibration detection information including the number of vibration times _{N V} (step S103).

  From here, with reference to FIG. 6, the detail of a vibration detection process (step S103) is demonstrated.

Initializing unit 113, the number of vibration times _{N V} indicated by the oscillation frequency information stored in the vibration frequency storage unit 111 is reset to 0 and starts the timer 112 (step S111).

The sampling unit 114 acquires the TE signal from the reproduction control unit 103 until the vibration detection time VDT reaches T ₁ (milliseconds) while referring to the timer 112 (step S112), and based on the acquired TE signal. Then, a vibration detection signal T _SHOCK is generated (step S113).

The vibration detection signal T _SHOCK is, for example, a signal of a specific frequency component included in the TE signal as described above, and allows the TE signal for a preset sampling time ST (milliseconds) to pass through the bandpass filter. Generated by.

Next, the signal comparison unit 115 compares the magnitude of the vibration detection signal T _SHOCK with a preset threshold value TV ₁ and outputs information according to the comparison result (step S114). Specifically, when the magnitude of the vibration detection signal T _SHOCK is greater than or equal to the threshold TV ₁ (step S114; Yes), the signal comparison unit 115 outputs information indicating the determination result to the increment unit 116. When the vibration detection signal T _SHOCK is less than the threshold TV ₁ (step S114; No), the sampling unit 114 outputs information for continuing the sampling process (step S113).

When the increment unit 116 obtains information indicating that the magnitude of the vibration detection signal T _SHOCK is greater than or equal to the threshold TV ₁ , the increment unit 116 obtains the vibration number information stored in the vibration number storage unit 111. Subsequently, the increment unit 116 adds one to the number of vibrations N _V indicated by the acquired vibration count information, (step of storing in the vibration frequency storage unit 111 information indicating the number of vibrations N _V after addition as the vibration frequency information S115).

In this way, until the oscillation detection time VDT is _{T 1,} the sampling process (step S113) is performed, based on the sampled TE signal, the signal comparison process (step S114) and increments the number of oscillations _{N V} Processing (step S115) is executed.

Subsequently, when the increment unit 116 acquires information indicating that the vibration detection time VDT has reached T ₁ from the timer 112 via the signal comparison unit 115, the increment unit 116 acquires vibration number information from the vibration number storage unit 111. The increment unit 116 outputs vibration detection information including the acquired vibration frequency information (step S116). Thereby, a vibration detection process (step S103) is complete | finished.

  Referring to FIG. 5 again, the determination unit 105 acquires vibration detection information including vibration frequency information from the increment unit 116 of the vibration detection unit 104, determines the use of the BD playback device 100 based on the acquired information, Information indicating the discrimination result is output (step S104).

  From here, with reference to FIG. 7, the detail of an application determination process (step S104) is demonstrated.

The number of vibrations comparison section 121 compares acquired vibration detection information from the increment unit 116 (step S121), and a threshold value TV ₂ which is set in advance as the number of vibrations N _V included in the acquired vibration detection information, the comparison result The information shown is output (step S122).

Application determination unit 122 compares the result to obtain information, when the number of vibrations _{N V} In comparison results contained in the information is the threshold value TV ₂ or more (step S122; Yes), the use of BD playback apparatus 100 is in a conveyance It is determined that there is (step S123). Also, if the application determination section 122 is less than the number of vibrations _{N V} threshold TV ₂ in the comparison result (step S122; No), the use of BD playback apparatus 100 is determined to be a stationary (step S124).

The usage determining unit 122 outputs discrimination information indicating the determined usage (step S125). That is, the application determination unit 122, if the number of vibration times _{N V} is the threshold value TV ₂ or more; the determination information indicating that is conveying (step S122 Yes), the number of vibrations _{N V} is less than the threshold value TV ₂ In the case (step S122; No), discrimination information indicating that the application is for stationary use is output to the reproduction control unit 103 and stored in the discrimination information storage unit 101.

From here, it returns to description of FIG. 5 again.
The reproduction control unit 103 acquires the discrimination information 101a from the discrimination unit 105 or the discrimination information storage unit 101, and acquires the mode information 102a corresponding to the acquired discrimination information 101a by referring to the mode information storage unit 102. The reproduction control unit 103 performs normal content reproduction processing according to the mode indicated by the acquired mode information 102a (step S105). Here, the normal reproduction process is different from the silent reproduction process (step S102), and means that the content information is processed so as to be accompanied by the sound output at the volume determined by the user.

  Based on the instruction from the input receiving unit 106, the playback control unit 103 determines whether a playback end instruction has been received (step S106).

  If the playback control unit 103 determines that the playback end instruction has not been received from the input receiving unit 106 (step S106; No), the playback control unit 103 continues the normal playback process (step S105).

  If the playback control unit 103 determines that a playback end instruction has been received from the input receiving unit 106 (step S106; Yes), the playback control unit 103 ends the process.

  The series of processes from the silent reproduction process (step S102) to the application determination process (step S104) may be executed at any timing as long as the servo signal can be acquired. The timing described is desirable.

  That is, as shown in FIG. 5, the BD playback device 100 immediately after the playback start instruction receiving process (step S101), the silence playback process (step S102), the vibration detection process (step S103), and the application determination process (step S104). ) Are executed sequentially. Immediately after the reproduction start instruction receiving process (step S101), a process for reading content information from the BD 107, such as a spin-up process of the BD 107, is executed. Therefore, no sound is output at this time. By executing a series of processes from the silence reproduction process (step S102) to the application determination process (step S104) at the timing of this embodiment, the sound of the content being reproduced is interrupted by the silence reproduction process (step S102). Can be prevented.

  As described so far, the BD playback apparatus 100 according to the present embodiment receives a command to play back the content of the BD 107 and detects vibration using a servo signal. The servo signal is a signal generated for reproducing content in a general BD reproducing apparatus. Therefore, the BD playback device 100 does not need to be provided with a new sensor or the like in order to detect vibration. Therefore, it is possible to realize the BD playback device 100 that can detect vibration and determine the application with a simple and compact configuration.

  In addition, since the BD playback device 100 detects vibration without sound output, it can detect vibration without being affected by vibration due to sound output. Therefore, it is possible to accurately detect the vibration of the BD playback device 100.

Further, even for stationary use, a slight vibration can occur. Since the BD playback apparatus 100 detects a vibration having a magnitude greater than or equal to the threshold TV ₁ as a vibration, it can prevent an application determination error due to a slight vibration.

Furthermore, even for stationary use, there is a possibility that a large vibration will occur to some extent when an earthquake occurs or the installation is unstable. However, large vibrations are rarely generated for stationary use. To determine the conveyance when the number of times the vibration is detected is the threshold value TV ₂ or more, it is possible to prevent erroneous determination by accidental vibration generated in the BD playback apparatus 100 for stationary.

  Furthermore, in this embodiment, after receiving an instruction to reproduce the content of the BD 107, a vibration detection process (step S103) and an application determination process (step S104) are executed. When the BD playback apparatus 100 is used, that is, when a user inputs an instruction to play back content, the transport BD playback apparatus 100 often generates vibrations associated with transport. On the other hand, the large vibration as described above hardly occurs in the stationary BD reproducing apparatus 100. Therefore, when inputting an instruction to reproduce content, it is possible to detect the vibration and determine the application, thereby making it possible to accurately determine the application.

  Furthermore, the BD playback device 100 according to the present embodiment determines whether the application is stationary or transport based on the vibration detection information, and determines the stationary mode and transport according to the determined use. The playback process of the BD 107 is performed in one of the modes for use. As described in the present embodiment, in the transfer mode, some of the functions that can be used in the stationary mode are limited.

  The transport BD reproduction apparatus 100 is used by being transported by being mounted on a car or being carried. Therefore, in general, the BD playback apparatus 100 for conveyance has a smaller screen and a smaller processing capability such as image processing than those for stationary use. Therefore, in the transfer mode, for example, Bonus View increases the processing load on the BD playback device 100, but restricts functions that do not have a substantial profit on a small screen. On the other hand, for stationary use such as home use, a mode that can handle all functions is desirable.

  Thus, according to the BD playback device 100 according to the present embodiment, it is possible to play back the content included in the BD 107 in a mode suitable for the application of the BD playback device 100.

  In the transfer mode with limited functions, it is not necessary to update the firmware related to at least the limited functions. Therefore, it is possible to eliminate or reduce the need to update the firmware of the transport BD playback apparatus 100. Since the playback process can be performed only with the basic simple playback function, the compatibility of disk playback is improved.

  Furthermore, in the transfer mode with a limited function, for example, it may be set so as not to correspond to a new profile. As a result, even if the content uses the new profile function, the use of the function is limited when the BD playback apparatus 100 according to the present embodiment is for conveyance. Therefore, it is possible to view content that uses the function of the new profile under a limited function without updating the firmware. Therefore, it is possible to eliminate or reduce the need to update the firmware of the transport BD playback apparatus 100.

  If the use of the BD playback device is set in advance, the BD playback device may erroneously try to play back in the stationary mode even though the actual use is for transportation. If the firmware does not support playback in the transport mode, content using the new profile function cannot be played back. In the BD playback apparatus 100 according to the present embodiment, the usage can be reliably determined, so that it is possible to accurately determine the actual usage and reproduce the content in a mode suitable for the usage.

(Second Embodiment)
Similar to the BD playback device 100 according to the first embodiment, the BD playback device 200 according to the second embodiment of the present invention is a BD playback device that detects a vibration and discriminates a use in the absence of an audio output. The BD playback device 200 executes silence determination processing instead of the silence playback processing executed by the BD playback device 100. That is, the BD playback device 200 determines whether or not there is silence during normal playback, and executes the vibration detection process and the application determination process when determining that there is no sound.

  As shown in FIG. 8, the BD playback device 200 according to the present embodiment has substantially the same configuration as the BD playback device 100, and includes a silence determination unit 201 in addition to the components included in the BD playback device 100. . The silence determination unit 201 acquires audio information indicating an audio part included in the content of the BD 107 from the reproduction control unit 103, and determines whether there is silence based on the audio information.

  Next, processing executed by the BD playback device 200 will be described with reference to FIG.

  The reproduction control unit 103 receives the signal output from the input receiving unit 106 and executes normal reproduction processing (step S105).

  The silence determination unit 201 acquires audio information of the content being reproduced from the reproduction control unit 103 (step S201). Subsequently, the silence determination unit 201 determines whether there is no sound (silence) included in the acquired sound information (step S202).

  When the silence determination unit 201 determines that there is no sound (step S202; Yes), the vibration detection unit 104 executes a vibration detection process (step S103). When the silence determination unit 201 determines that there is no silence (step S202; No), the reproduction control unit 103 performs a determination process (step S106) as to whether a reproduction end instruction has been accepted.

  Since the BD playback device 200 detects vibration while there is no sound being played back, the vibration can be detected without interrupting the sound of the content being played back by silence. Therefore, the sound to be reproduced is not reproduced, and comfortable viewing can be realized.

(Third embodiment)
Similar to the BD playback device 100 and the BD playback device 200, the BD playback device according to the third embodiment of the present invention is a BD playback device that detects vibrations and discriminates the application in the absence of audio output. The BD playback device according to the present embodiment has the same configuration as the BD playback device 100 according to the first embodiment. Therefore, a diagram illustrating the configuration of the BD playback apparatus according to the present embodiment and a description of the configuration are omitted.

  The BD playback device according to the present embodiment is characterized by the timing of executing the vibration detection process and the application determination process. Processing executed by the BD playback device according to the third embodiment will be described with reference to FIG.

  The playback control unit 103 executes a spin-up process (step S301), which is one of processes for reading content information from the BD 107. In the spin-up process (step S301), the reproduction control unit 103 controls the rotation of the BD 107 and generates and outputs a servo signal such as a TE signal.

  The spin-up process (step S301) may be executed at any timing such as when the BD playback apparatus is turned on or when the input receiving unit 106 receives a playback start instruction based on a user operation. Good.

  Subsequently, the vibration detection unit 104 executes a vibration detection process (step S103), the determination unit 105 executes an application determination process (step S104), and the reproduction control unit 103 executes a normal reproduction process (step S105). The reproduction control unit 103 executes a reproduction end instruction acceptance determination process (step S106).

  As described above, the BD playback apparatus according to the present embodiment executes the vibration determination process (step S103) and the application determination process (step S104) during the spin-up process (step S301). Since the spin-up process (step S301) is executed before processing the read content information, the output unit 108 does not output the content. Therefore, vibration can be detected in the absence of sound output, and vibration can be accurately detected without being affected by vibration caused by sound.

  According to the present embodiment, the process of eliminating the volume and the process of determining whether or not the sound is silence are not required, and the process for accurately detecting the vibration can be simplified.

(Fourth embodiment)
Similar to the BD playback device 100 according to the first embodiment, the BD playback device according to the fourth embodiment of the present invention is a device that discriminates a use and plays back a BD in a mode corresponding to the determined use. The BD playback device according to the present embodiment is different from the BD playback device according to the first embodiment in that it includes a sensor that detects vibration.

  As shown in FIG. 11, the BD playback device 400 includes a sensor 441 in addition to the components included in the BD playback device 100, and includes a vibration detection unit 404 instead of the vibration detection unit 104 according to the first embodiment. .

  The sensor 441 is a sensor capable of detecting vibration, and is, for example, an acceleration sensor or an angular velocity (gyro) sensor. The sensor 441 outputs a signal (sensor detection signal) indicating the magnitude of the detected vibration.

Vibration detecting unit 404 has the same configuration as the vibration detection unit 104 according to the first embodiment, to detect the vibration based on the signal, the vibration detection information including the number of vibrations N _V detected in the vibration detection time VDT Is output. Unlike the vibration detection unit 104 according to the first embodiment, the vibration detection unit 404 acquires a sensor detection signal from the sensor 441 and generates vibration frequency information based on the sensor detection signal.

  The processing executed by the BD playback device 400 is the same as the processing executed by the BD playback device 100 described with reference to FIGS. However, in the vibration detection process (step S103), the initialization unit (not shown) of the vibration detection unit 404 initializes the vibration detection using a signal from the reproduction control unit 103 that executes the silence reproduction process (step S102) as a trigger. A process (step S111) is executed. In the vibration detection process (step S103), the sampling unit of the vibration detection unit 404 performs the sampling process (step S113) based on the sensor detection signal acquired from the sensor 441.

  Thus, since the BD playback device 400 includes the sensor 441, vibration can be detected without using a signal from the playback control unit 103. In addition, by using a signal from the reproduction control unit 103 that executes the silent reproduction process (step S102) as a trigger, it is possible to detect vibration without sound output. As a result, vibration can be detected without being affected by vibration caused by the sound output.

(Fifth embodiment)
The BD playback device according to the fifth embodiment of the present invention includes a silence determination unit 201 of the BD playback device 200 according to the second embodiment in addition to the components included in the BD playback device 400 according to the fourth embodiment ( FIG. 8 and FIG. 11). Further, the BD playback device according to the present embodiment executes the same processing as the BD playback device 200 according to the second embodiment (see FIG. 9).

  That is, in the BD playback device according to the fifth embodiment, during the playback of the content, the silence determination unit (201) determines whether the content being played back is silent based on the audio information (step S202). When it is determined that there is no sound (step S202; Yes), the vibration detection unit (404) executes a vibration detection process (step S103).

  According to this embodiment, even a BD playback device including the sensor 441 can detect vibration while there is no sound being played back. For this reason, it is possible to detect the vibration without interrupting the sound of the content being reproduced by silence. Therefore, the sound to be reproduced is not reproduced, and comfortable viewing can be realized.

(Sixth embodiment)
Similar to the BD playback device 400 according to the fourth embodiment, the BD playback device according to the sixth embodiment of the present invention detects vibration based on the signal of the sensor, discriminates the use, and determines the use. This is a device for playing back a BD in a corresponding mode.

  A BD playback device 600 according to this embodiment will be described with reference to FIGS.

  As illustrated in FIG. 12, the BD playback device 600 includes a playback determination unit 651 in addition to the components included in the BD playback device 400 according to the fourth embodiment. The reproduction determination unit 651 determines whether or not the reproduction control unit 103 is reproducing the content of the BD 107.

  Processing executed by the BD playback device 600 will be described with reference to FIG.

  Based on the instruction from the input receiving unit 106, the reproduction determining unit 651 determines whether an instruction to turn on the power has been received (step S651). When it is determined that an instruction to turn on the power is not received from the input receiving unit 106 (step S651; No), the reproduction determining unit 651 waits.

  If it is determined that an instruction to turn on the power has been received from the input receiving unit 106 (step S651; Yes), the playback determining unit 651 displays playback information indicating whether or not the content of the BD 107 is being played back. And based on the acquired reproduction information, it is determined whether or not the content is being reproduced (step S652).

  The reproduction information may be information generated by the reproduction control unit 103 during content reproduction. For example, the reproduction information may be a specific signal indicating that the content is being reproduced, content information generated by the reproduction control unit 103, or the like.

  If it is determined that reproduction is in progress (step S652; Yes), the reproduction determination unit 651 waits.

  When it is determined that the reproduction is not being performed (step S652; No), the vibration detection unit 404 detects a vibration based on the sensor detection signal acquired from the sensor 441 using the signal from the reproduction determination unit 651 as a trigger, and the vibration frequency information. Is output (step S103).

  Subsequently, after the use determining process (step S104) is executed by the determining unit 105, the reproduction determining unit 651 determines whether an instruction to turn off the power has been received based on an instruction from the input receiving unit 106. (Step S653).

  If it is determined that an instruction to turn off the power has not been received (step S653; No), the playback determination unit 651 executes a determination process (step S652) as to whether or not content is being played back. If it is determined that an input for turning off the power has been received (step S653; Yes), the BD playback device 600 ends the process.

  According to this embodiment, since vibration is detected when the reproduction process is not executed, no sound is output when vibration is detected. Therefore, it is possible to accurately detect vibration without being affected by vibration due to audio output.

(Seventh embodiment)
Similar to the BD playback device 100 according to the first embodiment, the BD playback device according to the seventh embodiment of the present invention detects vibration based on the servo signal, determines the use, and according to the determined use. Is a device for playing back a BD in a different mode. BD playback apparatus according to the seventh embodiment, not the number of oscillations N _V, to determine the application by the rate of vibration is detected (vibration detection rate, VDR).

  The BD playback device 700 will be described with reference to FIGS.

  As shown in FIG. 14, the BD playback device 700 has substantially the same configuration as the BD playback device 100, and instead of the vibration detection unit 104 and the determination unit 105 of the BD playback device 100, a vibration detection unit 704 and a determination unit. 705.

  Similar to the vibration detection unit 104, the vibration detection unit 704 outputs vibration detection information regarding the detected vibration. As shown in FIG. 15, the vibration detection unit 704 has a detailed configuration different from that of the vibration detection unit 104 according to the first embodiment. The vibration detection unit 704 according to the present embodiment includes a sampling number storage unit 717 in addition to the components included in the vibration detection unit 104, and includes an initialization unit 713 and an increment unit 716 instead of the initialization unit 113 and the increment unit 116. Prepare.

Sampling count storage unit 717 stores a sampling count information indicating the number of times of sampling N _S is the number of times the sampling process is performed to generate a vibration detection signal T _SHOCK, it is realized by a RAM.

  The initialization unit 713 activates the timer 112 and resets the vibration number information and the sampling number information stored in the vibration number storage unit 111 as an initialization process for detecting vibration.

Increment unit 716 acquires information indicating the comparison result of the signal comparison unit 115 increments the sampling number N _S indicated by the number of sampling information stored in the sampling frequency storage unit 717. Also, the increment unit 716, according to the comparison result, increments the number of vibrations N _V indicated by the oscillation frequency information stored in the vibration frequency storage unit 111. Furthermore, the increment unit 116 outputs a vibration detection information including the number of vibration times _{N V} and the sampling number _{N S.}

  Returning to FIG. 14, the determination unit 705 acquires vibration detection information from the vibration detection unit 704, and determines whether the use of the BD reproduction device 700 is for stationary use or for conveyance based on the acquired vibration detection information. The information indicating the discrimination result is output. As illustrated in FIG. 16, the determination unit 705 has a detailed configuration different from that of the determination unit 105 according to the first embodiment. The determination unit 705 according to the present embodiment includes a detection rate calculation unit 723, a detection rate comparison unit 721, and an application determination unit 722.

Detection rate calculation section 723 refers to the vibration detection information obtained from the vibration detecting unit 704 calculates a value obtained by dividing the number of vibration times N _V at sampling times N _S as a vibration detection rate VDR.

The detection rate comparison unit 721 acquires vibration detection rate information indicating the vibration detection rate from the detection rate calculation unit 721, compares the vibration detection rate with a preset threshold TV _3, and outputs information indicating the comparison result. .

  The usage determining unit 722 determines whether the usage of the BD playback device 700 is “for stationary” or “for conveying” based on the comparison result indicated by the information acquired from the detection rate comparing unit 721. The information indicating is output.

  Processing executed by the BD playback device 700 will be described with reference to a flowchart.

  FIG. 17 shows an outline of processing executed by the BD playback device 700. As shown in the figure, the process executed by the BD playback apparatus 700 is substantially the same as the process executed by the BD playback apparatus 100, and details of the vibration detection process (step S703) and the application determination process (step S704) are described. Different. Each process will be described with reference to FIGS. 18 and 19.

  The vibration detection process (step S703) is a process executed by the vibration detection unit 704, and details thereof are shown in FIG.

Initializing unit 713, the number of vibration times N _V indicated by the oscillation frequency information stored in the vibration frequency storage unit 111 is reset to 0, the sampling number N _S contained in the stored sampled frequency information to the sampling frequency storage unit 717 Reset to 0 and start the timer 112 (step S711).

Sampling unit 114, with reference to the timer 112, until the vibration detection time VDT is _{T 1} (step S112), and the sampling process is performed (step S113). Subsequently, the signal comparison unit 115 executes a comparison determination process (step S114) of the vibration detection signal T _SHOCK .

If the vibration detection signal _{T SHOCK} is the threshold value TV ₁ or more (step S114; Yes), the increment unit 716 performs increment processing of the number of vibrations _{N V} a (step S115). Specifically, the increment unit 716 adds one to the number of vibrations N _V indicated by the oscillation frequency information stored in the vibration frequency storage unit 111, the vibration frequency storage unit 111 the number of vibrations N _V after addition as the vibration frequency information (Step S115).

If the vibration detection signal _{T SHOCK} is less than the threshold value TV ₁ (Step S114; No), or after the increment processing of the vibration number _{N V} (step S115), the increment unit 716, increment processing of the sampling number _{N S} ( Step S717) is executed. Specifically, the increment unit 716 adds 1 to the sampling number N _S indicated by the number of sampling information stored in the sampling frequency storage unit 717, a sampling frequency storage unit 717 the sampling number N _S after the addition as the sampling frequency information (Step S717).

Increment unit 716, the vibration detection time VDT via a signal comparator 115 acquires the information indicating that becomes T _1, the number of vibration times information and the sampling frequency information from the vibration frequency storage unit 111 and a sampling frequency storage unit 717 get. Subsequently, the increment unit 716 outputs the vibration detection information including the number of vibration times _{N V} and the sampling number _{N S} indicated by the acquired information group (step S116). Thereby, the vibration detection process (step S703) ends.

  The application determining process (step S704) is a process executed by the determining unit 705, and details thereof are shown in FIG.

Detection rate calculation section 723 acquires the vibration detection information from the increment unit 716 (step S721), by dividing the number of vibrations N _V included in the acquired vibration detection information at the sampling times N _S, calculates the vibration detection rate (Step S726).

Detection rate comparison unit 721 acquires the vibration detection rate information indicating a vibration detection rate from the detection rate calculation section 723 compares the threshold value TV ₃ set in advance and the vibration detection rate included in the acquired vibration detection rate information Then, information indicating the comparison result is output (step S722).

The use determining unit 722 acquires information indicating the comparison result, and when the vibration detection rate is equal to or higher than the threshold TV ₃ in the comparison result included in the information (step S722; Yes), the use determining unit 722 determines that the use is for conveyance. (Step S723). Further, when the vibration detection rate is less than the threshold TV ₃ in the comparison result (step S722; No), the use determining unit 722 determines that the use is for stationary use (step S724).

The usage determining unit 722 outputs discrimination information indicating the determined usage (step S725). In other words, the use determining unit 722 displays discriminating information indicating that it is for conveyance when the vibration detection rate is greater than or equal to the threshold TV ₃ (step S722; Yes), and the vibration detection rate is less than the threshold TV ₃ ( In step S122; No), discrimination information indicating that the application is for stationary use is output to the discrimination information storage unit 101 and the reproduction control unit 103.

  As described above, the BD playback device 700 according to the present embodiment determines the application based on the vibration detection rate. The present embodiment is an example in which the application determination method based on the vibration detection rate is applied to the BD playback device 100 according to the first embodiment. This application determination method is the BD playback device according to the second to sixth embodiments. It can also be applied to. As a result, the same effects as those of the embodiments can be obtained.

  The BD playback apparatus and method according to the embodiment of the present invention have been described above, but the present invention is not limited to the embodiment described so far.

(Modification 1)
In the embodiment, the BD playback device has been described as an example. However, each embodiment can also be applied to a BD recording device that records content information indicating content on a medium. For example, FIG. 20 shows a configuration example of a BD recording apparatus that detects vibrations by the same process as in the first embodiment and discriminates the application. As shown in the figure, the BD recording apparatus 800 includes a discrimination information storage unit 101, a mode information storage unit 102, a vibration detection unit 104, a discrimination unit 105, an input reception unit 106, an imaging unit 851, and a recording. A control unit 803 and an output unit 808 are provided.

  The discrimination information storage unit 101 and the mode information storage unit 102 store discrimination information 101a and mode information 102a, respectively, as in the first embodiment.

Vibration detection unit 104, similarly to the first embodiment, information indicating the number of vibrations N _V generated on BD recorder 800, and outputs as the vibration detection information regarding the vibration of the BD recorder 800.

Determination unit 105, similarly to the first embodiment, the vibration detection information acquires, based on the number of vibrations N _V included in the acquired vibration detection information, conveying the application of the BD recorder 800 is accompanied by certain more oscillating It is discriminated whether it is for use or stationary for a certain amount of vibration.

  As in the first embodiment, the input receiving unit 106 receives a signal input by an operation by a user or the like, and outputs the received signal.

  The imaging unit 851 captures an image and generates content information indicating the captured content. The imaging unit 851 includes, for example, a lens and an imaging element.

  When the discriminating unit 105 determines that the recording control unit 803 is for transport, the recording control unit 803 generates content information in a transport mode in which the function is limited compared to the stationary mode suitable for stationary playback. Control for recording the obtained content information on the BD 107 is executed.

  The output unit 808 acquires the content information generated by the recording control unit 803 and records the content information on the BD 107.

  The BD recording apparatus 800 according to the present modification is a modification of the BD playback apparatus 100 according to the first embodiment, but this modification can also be applied to the BD playback apparatus according to the second to seventh embodiments. .

(Modification 2)
In each embodiment, the case where the medium on which information to be reproduced or recorded is recorded is a BD, but the medium may be an optical disk such as a DVD or a CD.

  For example, the transport mode exemplified in each embodiment has a different reproduction (recording) method than the stationary mode, and preferably a BD reproduction (recording) device in the content reproduction (recording) process than the stationary mode. This is an example of a reproduction method with a small load on the.

  By adopting a mode that uses different functions, for example, in the first mode, which is a playback method suitable for the first application, it is not necessary to update the firmware, or the frequency of updating the firmware is reduced. Is possible. In addition, the first mode can be set so that it can be processed by a reproduction (recording) device having a lower specification than the second mode, which is a reproduction method suitable for the second application. Therefore, the structure of the reproducing (recording) apparatus can be simplified and made compact.

  Such an effect can be similarly obtained even when a mode in which a load applied to the BD playback (recording) apparatus is different is adopted in the content playback (recording) process. That is, in a mode with a small processing load, it is possible to eliminate the need to update the firmware, or to reduce the frequency of updating the firmware. Further, in a mode with a small processing load, processing can be performed with a reproduction (recording) apparatus having a lower specification than in a mode with a small processing load, and the structure of the reproduction (recording) apparatus can be simplified and made compact.

(Modification 3)
In each embodiment, the case where the content includes sound and a moving image has been described as an example. However, the content may include only one of the sound and the moving image.

(Modification 4)
In the embodiment, the case where the vibration detection unit outputs the vibration detection information based on the servo signal or the signal output from the sensor has been described as an example. However, examples of outputting the vibration detection information related to the vibration of the playback device are described here. Not limited to. For generation of the vibration detection information, a signal specific to the device provided with the BD playback or recording device may be used.

  For example, when the BD playback device is for in-vehicle use, the vibration detection unit uses a pulse signal generated by a pulse generator for detecting a vehicle speed provided in a general automobile in order to display the vehicle speed on a speedometer. Also good. In this case, the vibration detection unit outputs vibration detection information indicating that when a pulse signal is detected. A discrimination | determination part discriminate | determines a use for conveyance, when the vibration detection information which shows having detected the pulse signal is acquired.

  As a result, the configuration and processing for discriminating the application by the BD playback device can be simplified, and the usage can be discriminated while the BD playback device is made compact.

(Modification 5)
In each embodiment, although the case where a use is for conveyance and stationary use was demonstrated to the example, a use is not restricted to these, What is necessary is just the use which can discriminate | determine by a vibration. For example, in the case of a video camera as a recording apparatus, there are uses for fixing by using a tripod or the like and for hand-held use by hand. In addition, if the video camera has a playback function, the same video camera can record and play back images. Such a video camera is not only included in the recording device according to the present invention, but also in the playback device. Is also included.

(Modification 6)
In each embodiment, the result is updated every time the application determining process is performed. However, the determined result may be retained, and may be retained, for example, unless the user gives an update instruction. Further, after a certain period, time, or number of samplings, the determination unit may determine the use and update the determination information in the determination information storage unit. This modification can be applied to the apparatuses and methods described in the first to seventh embodiments and other modifications. According to this modification, it is possible to reduce the load applied to the apparatus by the discrimination process.

(Modification 7)
In each embodiment, the use is determined for each vibration detection time VDT. However, the use may be determined based on a sampling result for detecting vibrations over a certain period, time, or number of times.

  In the case of this modification, the apparatus according to the present invention includes a sampling history storage unit that stores sampling history information for vibration detection, and a sampling history of a certain period, time, or number of times based on the history information. And a history determination unit that determines whether or not is stored. The vibration history information includes information indicating whether vibration is detected, and further includes a sampling time or a sampling time as appropriate.

  In this case, when the history determination unit determines that a sampling history of a certain period, time, or number of times has been accumulated, the determination unit determines the use and updates the determination information in the determination information storage unit based on the determination result To do.

  When it is determined by the history determination unit that no sampling history is accumulated for a certain period, time, or number of times, the determination unit does not update the determination information in the determination information storage unit.

  This modification can be applied to the apparatuses and methods described in the first to seventh embodiments and other modifications. According to this modification, the use is determined based on the vibration history, so that the influence of accidental vibration on the determination is reduced. Therefore, it is possible to reduce discrimination errors.

(Modification 8)
An initial value may be set in advance in the discrimination information 101a. It is preferable that the initial value of the determination information 101a is set for conveyance. If stationary is set as the initial value, there is a possibility that the content cannot be reproduced because the firmware is not updated when the actual use is for transportation. By setting the value for conveyance as an initial value, the content is reproduced in the conveyance mode until at least the first use determination process is executed. Therefore, it is possible to prevent the content from being unable to be reproduced because the firmware has not been updated.

  The initial value of the discrimination information 101a may be set for conveyance immediately after receiving an instruction to turn on or off the power from the user. As a result, even if the apparatus is used for both stationary use and transfer use, it is possible to prevent the content from being unable to be reproduced because the firmware has not been updated.

(Physical configuration)
FIG. 21 shows an example of a physical configuration of the BD playback device 100, 200, 400, 600, 700 according to each embodiment of the present invention. The BD playback devices 100, 200, 400, 600, and 700 include a storage unit 901, sensors 441 (401, 402), a processor 902, and an output unit 108 (109, 110). Each element is communicably connected via an internal bus 903. In FIG. 21, each element is one, but each element may be divided into a plurality of elements.

  The storage unit 901 is a flash memory, a hard disk drive, or the like, corresponds to the storage units 101 and 102 according to each embodiment, and stores discrimination information 101a and mode information 102a. The storage unit 901 may store each threshold, a software program executed by the processor 902, and the like.

  The sensor 441 is an acceleration sensor, an angular velocity (gyro) sensor, or the like used in the fourth, fifth, and sixth embodiments. The sensor 441 may not be provided in the BD playback devices 100, 200, and 700 according to the first, second, third, and seventh embodiments.

  The processor 902 is an arithmetic processing device that executes a software program stored in the storage unit 901 and a program incorporated therein. The processor 901 exhibits the functions of the reproduction control unit 103, the vibration detection units 104, 404, and 704, the determination units 105 and 705, and the input reception unit 106 according to each embodiment by executing these programs.

  The output unit 108 includes a liquid crystal monitor that outputs an image, a plasma display (109), and a speaker (110) that outputs sound. The output unit 108 may be built in the BD playback device 100, 200, 400, 600, 700 as shown in FIG. 21, but is detachably provided outside the BD playback device 100, 200, 400, 600, 700. May be.

  Next, FIG. 22 shows an example of a physical configuration of a BD recording apparatus 800 according to an embodiment of the present invention. The BD recording apparatus 800 includes a storage unit 1001, a processor 1002, an output unit 808, and an imaging unit 851. Each element is communicably connected via an internal bus 1003. In FIG. 22, each element is one, but each element may be divided into a plurality of elements. In addition, sensors such as an acceleration sensor and an angular velocity (gyro) sensor may be provided as appropriate.

  The storage unit 1001 is a flash memory, a hard disk drive, or the like, corresponds to the storage units 101 and 102 according to the eighth embodiment, and stores discrimination information 101a and mode information 102a. The storage unit 1001 may store each threshold value, a software program executed by the processor 1002, and the like.

  The processor 1002 is an arithmetic processing unit that executes a software program stored in the storage unit 1001 and a program incorporated in the processor 1002. The processor 1002 performs the functions of the recording control unit 803, the vibration detection unit 104, the determination unit 105, and the input reception unit 106 according to the eighth embodiment by executing these programs.

  The output unit 808 is a part that acquires content information and records the content information on the BD 107, and includes an optical device such as a prism and a lens, a laser diode, and a control unit that controls the operation thereof.

  In addition, the present invention is arbitrarily combined with each embodiment and each modification as long as there is no contradiction, and further, each embodiment, each modification, and a combination thereof without departing from the gist of the present invention. Includes changes. In addition, the present invention may be realized as a program that causes a computer to execute steps included in a method according to each embodiment, each modification, and a combination thereof. Furthermore, the present invention may be realized as a storage medium in which such a program is recorded in a computer-readable manner.

100, 200, 400, 600, 700: BD playback device 101: Discrimination information storage unit 101a: Discrimination information 102: Mode information storage unit 102b: Mode information 104, 404, 704: Vibration detection unit 105, 705: Discrimination unit 103: Playback control unit 108,808: Output unit 110: Audio output unit 201: Silence determination unit 441: Sensor 651: Playback determination unit 800: BD recording device 803: Recording control unit

Claims (14)

Vibration detecting means for detecting vibration generated in the playback device and outputting vibration detection information including the detected number of vibrations;
The vibration detection information is acquired, and based on the number of vibrations included in the acquired vibration detection information, the reproduction apparatus is used for either a first application with a certain level of vibration or a second use without a certain level of vibration. Determining means for determining whether or not
To read the content information recorded on the medium in the first mode, which has a different function from the second mode suitable for reproduction in the second application when the determination means determines that the first application is used. A reproduction control means for executing the process of reading the content information and processing the read content information ;
Audio output means for outputting audio ,
The vibration detection means, if there is no sound output from the sound output unit, reproducing and wherein the detecting vibration, you outputs vibration detection information. The reproduction control means outputs a servo signal in a process for reading content information from a medium,
The vibration detection unit acquires a servo signal from the reproduction control unit, detects a vibration having a magnitude equal to or larger than a threshold based on the acquired servo signal, and outputs vibration detection information including the detected number of vibrations. The playback apparatus according to claim 1 , wherein The vibration detection means includes a sensor for detecting vibration, detects vibration having a magnitude greater than a threshold based on a signal from the sensor, and outputs vibration detection information including the detected number of vibrations. The playback apparatus according to claim 1 . The playback apparatus according to claim 1 , wherein the playback control unit performs control so that no sound is output from the audio output unit when the vibration detection unit detects vibration. Furthermore, silence determination for acquiring audio information indicating audio included in the content from the reproduction control unit and determining whether or not the content being reproduced includes audio based on the acquired audio information. With means,
The playback apparatus according to claim 1 , wherein the vibration detection unit detects vibration and outputs vibration detection information when the silence determination unit determines that no sound is included. The vibration detection means, while the regeneration control means executes a process for reading content information recorded in the medium, according to claim 1, characterized in that to detect the vibration and outputs a vibration detection information Playback device. Furthermore, it comprises reproduction determination means for obtaining reproduction information indicating whether or not the content is being reproduced from the reproduction control means, and determining whether or not the content is being reproduced based on the obtained reproduction information,
The playback apparatus according to claim 1 , wherein the vibration detection unit detects vibration and outputs vibration detection information when the playback determination unit determines that the content is not being played back. The discrimination means includes
Vibration number comparison means for acquiring the vibration detection information and comparing the threshold value with the number of vibrations included in the acquired vibration detection information;
The number of vibrations comparing means compares the result of the case the number of vibrations is equal to or greater than the threshold, to any one of claims 1 7, characterized in that it comprises a usage determining means for determining that the first application The reproducing apparatus as described. The vibration detection means outputs vibration detection information including the detected number of vibrations and the number of samplings for detecting vibrations,
The discrimination means includes
A detection rate calculation means for calculating a vibration detection rate that is a ratio of detecting a vibration by dividing the number of vibrations included in the vibration detection information by the number of samplings, and outputting vibration detection rate information indicating the calculated vibration detection rate When,
Detection rate comparison means for acquiring the vibration detection rate information and comparing the acquired vibration detection rate with a threshold;
Comparison of results of the detection rate comparison means, when the vibration detection rate is equal to or higher than the threshold, any one of claims 1 to 7, characterized in that it comprises a usage determining means for determining that the first application The playback device described in 1. Vibration detection means for outputting vibration detection information relating to the vibration of the recording apparatus;
The vibration detection information is acquired, and based on the acquired vibration detection information, it is determined whether the use of the recording apparatus is a first use with a certain level of vibration or a second use without a certain level of vibration. Discriminating means to perform,
When it is determined by the determining means that the application is the first use, content information is generated in the first mode that is different from the second mode suitable for recording in the second application, and the generated content information is Recording control means for executing control for recording on a medium;
A recording apparatus comprising: output means for acquiring the generated content information from the recording control means and recording the content information on a medium. When there is no sound output from the playback device, the vibration generated in the playback device is detected, and vibration detection information including the detected number of vibrations is output,
The vibration detection information is acquired, and based on the number of vibrations included in the acquired vibration detection information, the reproduction apparatus is used for either a first application with a certain level of vibration or a second use without a certain level of vibration. Is determined,
When it is determined to be the first application, a process for reading the content information recorded on the medium is executed in the first mode, which is different from the second mode suitable for reproduction in the second application. And reading the content information and processing the read content information. Output vibration detection information about the vibration of the recording device,
The vibration detection information is acquired, and based on the acquired vibration detection information, it is determined whether the use of the recording apparatus is a first use with a certain level of vibration or a second use without a certain level of vibration. And
When it is determined to be the first application, content information is generated in the first mode that is different from the second mode suitable for recording in the second application, and the generated content information is recorded on the medium. Control for and
A recording method characterized by acquiring the generated content information and recording the content information on a medium. When there is no sound output from the playback device, the vibration generated in the playback device is detected, and vibration detection information including the detected number of vibrations is output,
The vibration detection information is acquired, and based on the number of vibrations included in the acquired vibration detection information, the reproduction apparatus is used for either a first application with a certain level of vibration or a second use without a certain level of vibration. Is determined,
When it is determined to be the first application, a process for reading the content information recorded on the medium is executed in the first mode, which is different from the second mode suitable for reproduction in the second application. Then, the program causes the computer to read the content information and process the read content information. Output vibration detection information about the vibration of the recording device,
The vibration detection information is acquired, and based on the acquired vibration detection information, it is determined whether the use of the recording apparatus is a first use with a certain level of vibration or a second use without a certain level of vibration. And
When it is determined to be the first application, content information is generated in the first mode that is different from the second mode suitable for recording in the second application, and the generated content information is recorded on the medium. Control for and
A program for causing a computer to acquire generated content information and record the content information on a medium.

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