JP5008461B2 - Fault information storage device and fault information storage method - Google Patents

Description

  The present invention relates to a failure information storage device and failure information storage method, and is particularly suitable for use in a storage medium playback device that reads and plays back audio data for playback from a storage medium.

  In a storage medium playback device that plays back audio data stored on a CD (Compact Disk), it is possible to obtain seamless playback sound by playing back the audio data continuously during playback. However, if playback failure occurs due to scratches on the CD surface, external vibration, playback device malfunction, etc. during playback of audio data, the audio data cannot be played back seamlessly, skipping sound, noise, etc. Will occur.

In order to investigate the cause of such a malfunction, when a playback failure occurs during playback of audio data, information for specifying a storage medium in which the audio data is stored is associated with failure information related to the playback failure. A technique (information processing apparatus) that stores data in a storage unit has been proposed (see, for example, Patent Document 1). According to this technology, it is possible to grasp the storage medium used at the time of the playback failure and the state of the playback failure, and later when a failure analysis was performed in a reproduction failure reproduction test using the storage medium. This makes it easier to identify the cause of the regeneration failure.
Japanese Patent Laid-Open No. 2005-116028

  However, with the technique described in Patent Document 1, each time a playback failure occurs during playback of audio data, information for specifying the storage medium in which the playback failure has occurred and failure information related to the playback failure are additionally stored in the storage unit. Therefore, there is a problem that the storage unit needs a large memory capacity to leave the failure information. In addition, since the failure information that is directly connected to the cause of the reproduction failure and the other failure information are mixedly stored in the storage unit, the engineer who investigates the cause of the reproduction failure has There is a problem that it takes time to extract failure information that is directly connected to cause investigation, and it is difficult to quickly hit the cause of the reproduction failure.

  The present invention has been made to solve such a problem, and collects failure information of a playback failure with a small memory capacity, and easily analyzes the cause of the playback failure based on the reduced failure information. The purpose is to be able to.

In order to solve the above-described problems, in the present invention, a reproduction quality index value that is an index of reproduction quality when reproducing audio data from an external storage medium is obtained by calculation based on failure information related to reproduction failure, When there are a plurality of pieces of acquired failure information, a predetermined number of pieces of failure information are stored in the internal storage medium in order of increasing reproduction quality index value obtained from each piece of failure information.
Here, the failure information includes a plurality of types of event information obtained by quantifying the number of occurrences of a plurality of types of events related to the playback failure, and the numerical values of the plurality of types of event information are weighted. Each of the added values is added, and a value obtained by dividing the added value by the playback time of the external storage medium is output as a playback quality index value.

  According to the present invention configured as described above, a predetermined number of pieces of failure information are stored in the internal storage medium in the descending order of the reproduction quality index value. Therefore, a large memory capacity is required to leave the failure information. In addition, the user can easily acquire failure information that is particularly easily connected to investigation of the cause of the reproduction failure (poor reproduction quality). As a result, it is possible to collect the failure information of the reproduction failure with a small memory capacity and easily analyze the cause of the reproduction failure based on the collected small amount of failure information.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of a storage medium playback device 100 that implements the failure information storage device according to the present embodiment. In the present embodiment, the storage medium playback device 100 is mounted on a vehicle.

  In FIG. 1, reference numeral 120 denotes a disk (external storage medium) such as a CD or a DVD. Reference numeral 140 denotes a turntable on which the disk 120 is placed and rotated. A spindle motor 160 rotates the disk 120 at a constant speed. A spindle servo circuit 180 controls the speed of the spindle motor 160. An optical pickup 200 emits a laser beam to the disk 120 and detects a reflected beam. A sled motor 220 sends the optical pickup 200 in the radial direction of the disk 120.

  A sled servo circuit 240 performs sled servo control for tracking the track of the disk 120 with respect to the sled motor 220. An RF amplifier 260 amplifies the audio data signal read from the disk 120 by the optical pickup 200. Reference numeral 280 denotes a digital signal processing circuit which inputs the audio data signal amplified by the RF amplifier 260 and demodulates the audio data signal.

  A focus servo circuit 300 drives a focus actuator (not shown) provided in the optical pickup 200 to perform focus servo control. A servo driver 320 amplifies a control signal from the focus servo circuit 300 and drives the focus actuator. A tracking servo circuit 340 drives a tracking actuator (not shown) provided in the optical pickup 200 to perform tracking servo control. A servo driver 360 amplifies a control signal from the tracking servo circuit 340 to drive the tracking actuator. A servo controller 380 receives a command from the system controller 400, which will be described later, and starts up the pickup servo system and adjusts and sets automatic adjustment coefficients (focus gain, tracking gain, etc.) for the pickup servo system.

  Reference numeral 420 denotes an ACC on / off detector that detects the on / off state of the ACC associated with the operation of the engine key. A disk insertion detection unit 440 detects the insertion of the disk 120 into the storage medium playback apparatus 100. A loading unit 460 loads the disk 120 on the turntable 140 or unloads it from the turntable 140 under the control of the system controller 400.

  Reference numeral 480 denotes an operation unit, which allows the user to perform operations such as ejecting the disk 120 and switching the disk 120. Reference numeral 500 denotes an internal storage medium that stores various data such as TOC information of the disk 120 and failure information related to playback failure. In the present embodiment, the internal storage medium 500 is an EEPROM (Erasable Programmable Read-Only Memory), and the various data are stored even when the ACC is off.

  Reference numeral 400 denotes a system controller that performs overall control of the system necessary for reproducing audio data stored in the disk 120 and storing failure information related to a reproduction failure in the internal storage medium 500. . In this embodiment, the system controller 400 includes a TOC information acquisition unit 520, a reproduction control unit 540, a failure information acquisition unit 560, a reproduction quality index value calculation unit 580, a failure information storage unit 600, and a second failure information storage unit 620. It is prepared for.

  The TOC information acquisition unit 520 acquires TOC information related to audio data stored in the disk 120 during automatic adjustment of the pickup servo system. Specifically, the TOC information acquisition unit 520 is stored in the lead-in (data area given as an indication of the start of storage) of the disk 120 through the path of the optical pickup 200, the RF amplifier 260, and the digital signal processing circuit 280. TOC information is acquired and temporarily stored in a temporary storage memory (not shown) such as a RAM.

  The playback control unit 540 reads audio data stored on the disk 120 and plays or stops the music based on the read audio data. Specifically, the reproduction control unit 540 reproduces music based on the audio data demodulated through the path of the optical pickup 200, the RF amplifier 260, and the digital signal processing circuit 280, and outputs the music from a speaker (not shown).

  The failure information acquisition unit 560 acquires failure information related to the playback failure that occurs when the playback audio data is read from the disc 120 and played back. Based on the failure information acquired by the failure information acquisition unit 560, the playback quality index value calculation unit 580 calculates a playback quality index value that is an index of playback quality when the audio data from the disk 120 is being played back. Ask.

  When there are a plurality of pieces of failure information acquired by the failure information acquisition unit 560, the failure information storage unit 600 includes a failure history including failure information in descending order of reproduction quality index values calculated by the reproduction quality index value calculation unit 580. A predetermined number (three in this embodiment) of information is stored in the internal storage medium 500. When there are a plurality of pieces of failure information acquired by the failure information acquisition unit 560, the second failure information acquisition unit 620 stores a predetermined number (three in this embodiment) stored in ascending order of reproduction quality index values. Apart from the failure history information, a predetermined number (six in this embodiment) of the latest failure history information in time is stored in the internal storage medium 500.

  FIG. 2 is a diagram illustrating a data structure example of failure history information. Here, the failure history information is information stored in the internal storage medium 500 by the failure information storage unit 600 and the second failure information storage unit 620 at the timing when the currently reproduced disc 120 is changed. As shown in FIG. 2A, the failure information (Play Error Info) is stored in Bytes 6 to 12 of the failure history information. In the present embodiment, the failure information includes a plurality of types of event information obtained by quantifying the number of occurrences of a plurality of types of events related to the playback failure.

  Byte 6 stores an item “SubQ Err” indicating the number of occurrences of “Sub-Q Error” (the number of activations of the mirror surface protection processing of the disk 120). Specifically, in the item “SubQ Err”, the number of times when “subcode Q” cannot be read by the optical pickup 200 during reproduction of the audio data stored in the disc 120 is stored.

  Byte 7 stores an item “SPM Err” indicating the number of times SPM is forcedly connected. Specifically, the item “SPM Err” stores the number of times that audio data to be read from the disk 120 is not input to the shock proof memory after the number of retries set by the shock proof parameter.

  Byte 8 stores an item “Loop” indicating the number of occurrences of the scratch Loop avoidance process. Specifically, in the item “Loop”, the number of times that the next “subcode Q” cannot be read due to timeout due to the occurrence of many “SubQ Err” described above is stored.

  Bytes 9 and 10 store an item “C2 Err” indicating the number of C2 uncorrectable occurrences. Specifically, the item “C2 Err” is one of errors that occur in the error correction code used in the disk 120, and the number of times that error correction within the frame fails even if the error correction code is used. Remembered.

  Byte 11 stores an item “DRM” indicating the number of occurrences of DRM file detection. Specifically, the item “DRM” stores the number of times of attempting to reproduce the file when a copyright-protected file (eg, WMA file, MP3 file) is stored on the disk 120. .

  Byte 12 stores an item “Impossible Decode” indicating the number of occurrences of “Impossible Decode File” detection. Specifically, in the item “Impossible Decode”, for example, the number of times that the compressed audio data stored in the disk 120 could not be reproduced due to a scratch on the disk 120 is stored.

  Next, items other than the failure information included in the failure history information will be described. Bytes 0 and 1 store an item “Time Stamp” indicating a timer value that is updated every 10 minutes during playback of audio data read from the disk 120 after the storage medium playback device 100 is turned on. Is done. Bytes 2 to 5 store an item “TOC” indicating the TOC information of the disk 120 acquired by the TOC information acquisition unit 520. The item “TOC” includes an item “A0” indicating the first track number in which audio data is stored in the disc 120, an item “A1” indicating the last track number in which audio data is stored in the disc 120, and an audio An item “A2” indicating the time length (minute, second, frame) of data is stored.

  FIG. 2B shows a data structure example of the item “TOC”. As shown in FIG. 2B, in the item “TOC”, the item “A0” is stored in Bit7, and the item “A1” is stored in Bits 6 to 0. More specifically, in the item “A0”, 1 is stored when the head track number is 1, and 0 is stored when the head track number is other than 1. In the item “A1”, any binary value of 1 to 99 is stored as the last track number.

  Byte 13 stores “Play Time” indicating the time counted every 5 minutes from the start of reproduction of the audio data read from the disk 120. Specifically, the item “Play Time” stores a sampling time of the number of occurrences of each event stored in the item “Play Error Info”.

  Byte 14 stores an item “Play Quality Level” indicating an index value of the reproduction quality of audio data stored in the disc 120. Specifically, in the item “Play Quality Level”, a value obtained by weighting and adding the number of occurrences of each event described above and dividing the added value by a reproduction time (a value stored in the item “Play Time”). Remembered. A more detailed method for calculating the reproduction quality index value will be described later. Byte 15 stores an item “Check Sum” indicating the XOR value of Bytes 0 to 14 of the failure history information as an error detection code of the failure history information.

  Next, a method for calculating the reproduction quality index value stored in the Byte 14 of the failure history information will be described with reference to FIG. FIG. 3 shows an example of a method for calculating the reproduction quality index value. The reproduction quality index value calculation unit 580 weights the numerical values of the plurality of types of event information shown in Bytes 6 to 10 and 12 in FIG. 2, adds the weighted values, and calculates the added value. A value divided by the playback time of the disc 120 is output as a playback quality index value.

  Specifically, as shown in FIG. 3A, the reproduction quality index value calculation unit 580 is a value obtained by performing a 7-bit left shift operation on the value stored in the item “Loop” (number of times of starting the wound loop avoidance process). The value stored in the item “Impossible Decode” (number of occurrences of the Impossible Decode) is 6-bit left-shifted, and the value stored in the item “SPM Err” (number of occurrences of the SPM error) is left The value obtained by performing the shift operation and the value stored in the item “SubQ Err” (SubQ error occurrence number) left-shifted by 4 bits and the item “C2 Err” (the number of times C2 error cannot be corrected) are stored. Add the value obtained by shifting the value to the right by 8 bits (the lower 1 byte is discarded) and add the value (Play Quality S). Seek m). In the present embodiment, an event that has a high possibility of causing skipping or interruption of sound in reproduction of audio data stored in the disk 120 is weighted more heavily.

  Next, the reproduction quality index value calculation unit 580 divides the added value (Play Quality Sum) by the value stored in the item “Play Time” (reproduction time), thereby reproducing the reproduction quality index value per unit time. (Play Quality Level) is obtained. As shown in FIG. 3B, a small playback quality index value (Play Quality Level) indicates that the playback quality is high, and a large playback quality index value indicates that the playback quality is low. Yes.

  Next, a method for storing failure history information including failure information will be specifically described. FIG. 4 is a diagram illustrating an example of a storage method of failure history information. The failure information storage unit 600 and the second failure information storage unit 620 are configured to change the currently played disk 120, for example, when the user performs a disk switching operation, a disk ejection operation, or a forced ejection operation using the operation unit 480. At the same timing, failure history information including failure information related to a playback failure that has occurred since the start of playback of the disk 120 is stored in the internal storage medium 500. The failure information storage unit 600 and the second failure information storage unit 620 store the failure history information in the internal storage medium 500 only when the audio data stored in the disk 120 has reached the reproduction state at least once. .

  FIG. 4A shows a storage area of the internal storage medium 500 in which failure history information including failure information is stored. The storage area “Play Condition Information” is composed of a first storage area “Latest Condition Area” and a second storage area “Worst Condition Area”.

  As shown in FIG. 4A, the first storage area “Latest Condition Area” has a capacity capable of storing six pieces of failure history information, and is cyclically overwritten and stored from the oldest failure history information at the time of overflow. The That is, the second failure information storage unit 620 stores the failure history information in order from the storage area corresponding to the serial number 1, and stores the failure history information up to the storage area corresponding to the serial number 6; When the failure information is further acquired by the acquisition unit 560, the storage target position of the failure history information is returned to the storage area corresponding to the serial number 1, and the failure history information including the failure information is overwritten and stored.

  The second storage area “Worst Condition Area” has a capacity capable of storing three pieces of failure history information. The failure information storage unit 580 corresponds to each failure history information in which the reproduction quality index value obtained from the failure information acquired this time by the failure information acquisition unit 560 is stored in the second storage area “Worst Condition Area”. If the reproduction quality index value is greater than or equal to any reproduction quality index value, the failure history information including the failure information acquired this time is stored in the past failure history information stored in the second storage area. It is stored (overwritten and stored) instead of one (failure history information corresponding to the third place counted from the worst reproduction quality index value).

  Next, a method for storing failure history information will be described with a specific example. 4B and 4C, each failure history in which the reproduction quality index value corresponding to the failure information acquired this time by the failure information acquisition unit 560 is stored in the second storage area “Worst Condition Area”. The operation in the case where any reproduction quality index value is exceeded as compared with the reproduction quality index value corresponding to the information is shown.

  4B shows an internal RAM (not shown) before the failure information acquired this time by the failure information acquisition unit 560 is stored in the internal storage medium 500, and a first storage area in the internal storage medium 500. The state of the “Latest Condition Area” and the second storage area “Worst Condition Area” is shown.

  In the internal RAM, 0x02 (represents serial number 2) as a storage position (Play Condition Pointer) in the first storage area “Latest Condition Area” in which the failure information previously acquired by the failure information acquisition unit 560 is stored. The storage area “refer to the arrow position in“ Latest Condition Area ”) is stored.

  In addition, the internal RAM stores a reproduction quality index value (corresponding to the third rank counted from the worst among the reproduction quality index values corresponding to the failure history information stored in the second storage area “Worst Condition Area”) ( 0x8F is stored as the worst condition quality level.

  Further, the internal RAM stores, in the reproduction quality index value corresponding to the failure history information stored in the second storage area “Worst Condition Area”, the third highest reproduction quality index value (Worst Condition Index value) counted from the worst. 0x03 (third from the beginning of the second storage area and the serial number 9 is represented as the storage position in the second storage area “Worst Condition Area” in which failure history information corresponding to Quality Level) is stored. “See the arrow position in“ Worst Condition Area ”). Further, 0xA0 is stored in the internal RAM as a reproduction quality index value (Current Play Quality Level) obtained from the failure information acquired this time by the failure information acquisition unit 560.

  Here, the failure history information including the failure information acquired this time is stored in the first storage area (0x03) next to the location (0x02) where the failure history information including the previously acquired failure information is stored. Is overwritten and stored. Further, the reproduction quality index value (0xA0) corresponding to the failure information acquired this time is counted from the worse one of the reproduction quality index values corresponding to the failure history information stored in the second storage area so far. Since the reproduction quality index value (0x8F) corresponding to the failure information acquired this time is larger than the reproduction quality index value (0x8F) corresponding to the third place, the reproduction quality index value (0x8F) stored at the position of the serial number 9 Instead of being stored.

  In FIG. 4C, the internal RAM after the failure history information including the failure information acquired this time by the failure information acquisition unit 560 is stored in the internal storage medium 500, the first storage area “Latest Condition Area”, The state of the second storage area “Worst Condition Area” is shown.

  In the internal RAM, 0x03 (represents serial number 3) as a storage position (Play Condition Pointer) in the first storage area “Latest Condition Area” in which the failure information acquired this time by the failure information acquisition unit 560 is stored. The storage area “refer to the arrow position in“ Latest Condition Area ”) is stored.

  In addition, the internal RAM stores a reproduction quality index value (corresponding to the third rank counted from the worst among the reproduction quality index values corresponding to the failure history information stored in the second storage area “Worst Condition Area”) ( 0x95 is stored as the worst condition quality level. That is, the reproduction quality index value (0xA0) of this time is stored in place of the reproduction quality index value (0x8F) that has been ranked third from the worst, so that the reproduction ranked second from the worst is stored. It shows that the quality index value (0x95) has moved down to the third place from the worst.

  In addition, the internal RAM stores a reproduction quality index value (corresponding to the third rank counted from the worst among the reproduction quality index values corresponding to the failure history information stored in the second storage area “Worst Condition Area”) ( 0x02 (second from the beginning of the second storage area, representing the serial number 8) as the storage position in the second storage area “Worst Condition Area” in which the failure history information corresponding to the worst condition quality level is stored. Storage area “refer to the arrow position in the worst condition area”).

  In addition, after the reproduction quality index level (Current Play Quality Level) obtained from the failure information acquired this time by the failure information acquisition unit 560 is stored in the internal storage medium 500, the reproduction quality index value (Current Play) is stored in the internal RAM. The value (0xA0) stored until immediately before (Quality Level) is deleted.

  Next, the operation of the storage medium playback apparatus 100 that implements the failure information storage method according to this embodiment will be described. 5 and 6 are flowcharts showing an example of the operation of the storage medium playback apparatus 100 that implements the failure information storage method according to the present embodiment. Each process in FIGS. 5 and 6 shows the processing contents of the storage medium playback apparatus 100 when audio data is read from the disk 120 and played back, and starts when ACC is on.

  First, the disc insertion detection unit 440 determines whether or not the disc 120 has been inserted into the storage medium playback device 100 (step S100). If disc insertion detection unit 440 determines that disc 120 is not inserted into storage medium playback apparatus 100 (NO in step S100), the process transitions to step S100, and disc insertion detection unit 440 The determination process in step S100 is repeated until the disc 120 is inserted into the playback apparatus 100.

  On the other hand, when disc insertion detector 440 determines that disc 120 has been inserted into storage medium playback device 100 (YES in step S100), the process transitions to step S120. In step S120, the TOC information acquisition unit 520 acquires the TOC information stored in the lead-in of the disk 120 through the path of the optical pickup 200, the RF amplifier 260, and the digital signal processing circuit 280, and temporarily stores it in the internal RAM. Let Next, the playback control unit 540 searches the beginning of the first song with reference to the TOC information temporarily stored in the internal RAM (step S140), and starts playback of audio data (step S160). Thereafter, the playback control unit 540 acquires fault information related to the playback fault and temporarily stores it in the internal RAM (step S180).

  During the reproduction of the audio data stored on the disc 120, the system controller 400 determines whether or not the user has performed an ejection operation or a forced ejection operation with the operation unit 480 (step S200). If the system controller 400 determines that the user has performed an eject operation or a forced eject operation with the operation unit 480 (YES in step S200), the reproduction control unit 540 stops reproduction of audio data (step S220). . And a process changes to the failure information storage process in step S240. Details of the failure information storage process will be described later. After the failure information storage process ends, the process proceeds to step S100. Thereafter, when the user inserts another disk 120 (YES in step S100), storage medium playback apparatus 100 performs the processing from step S120 onward again, and starts playback of audio data stored in disk 120.

  On the other hand, when system controller 400 determines that the user is not performing an eject operation or a forced eject operation with operation unit 480 (NO in step S200), system controller 400 turns off the ACC by turning the engine key. It is determined whether or not the ACC on / off detection unit 240 has detected (step S260). If the system controller 400 determines that the ACC on / off detection circuit 420 has detected ACC off during playback of the audio data stored on the disc 120 (YES in step S260), the playback control unit 540 Stops the reproduction of the audio data (step S280). Thereafter, the failure information storage process in the storage medium playback apparatus 100 ends.

  On the other hand, when the system controller 400 determines that the ACC on / off detection circuit 420 has not detected ACC off during playback of the audio data stored on the disc 120 (NO in step S260), the system controller 400 determines whether or not the user has performed a disk switching operation on the operation unit 480 during reproduction of the audio data stored on the disk 120 (step S300). If the system controller 400 determines that the user has performed a disk switching operation with the operation unit 480 during reproduction of audio data stored in the disk 120 (YES in step S300), the reproduction control unit 540 The reproduction of the audio data is stopped (step S320). And a process changes to the failure information storage process in step S340. When a disk switching operation is performed after the failure information storage process is completed (step S360), the storage medium playback apparatus 100 performs the processes in and after step S120 again to reproduce the audio data stored in the switched disk 120. To start.

  Next, the failure information storage process will be described. FIG. 6 is a flowchart showing an example of failure information storage processing of the storage medium playback apparatus 100 according to the present embodiment. First, the failure information acquisition unit 560 reads out the playback audio data from the disc 120 and plays back the failure information related to the playback failure that occurred when the audio data was played back, that is, during the operation of the main flow in FIG. 5 (step S180). Fault information stored in the internal RAM is acquired (step S400). Similarly, the failure information acquisition unit 560 acquires TOC information stored in the internal RAM during the operation of the main flow of FIG. 5 (step S120) (step S420). Next, the reproduction quality index value calculation unit 580 is based on the failure information acquired by the failure information acquisition unit 560, and serves as a reproduction quality index value when reproducing audio data from the disc 120. Is obtained by calculation (step S440). Next, the failure information storage unit 600 obtains the current reproduction quality index value obtained by the failure information acquisition unit 560, and the worst third place (counted from the worst, third place) obtained in the past and stored in the internal RAM. The corresponding reproduction quality index value is compared (step S460).

  The failure information storage unit 600 determines whether or not the current reproduction quality index value is larger than the worst third reproduction quality index value obtained in the past and stored in the internal RAM (step S480). If the failure information storage unit 600 determines that the current reproduction quality index value is greater than the worst third reproduction quality index value obtained in the past and stored in the internal RAM (YES in step S480). The failure information storage unit 600 reproduces the failure history information including the failure information and the TOC information acquired this time in the past third worst stored in the second storage area “Worst Condition Area” of the internal storage medium 500. The history failure information corresponding to the quality index value is stored instead of being stored (step S500). Thereafter, the process proceeds to step S520. On the other hand, when the failure information storage unit 600 determines that the current reproduction quality index value is less than or equal to the worst third reproduction quality index value obtained in the past and stored in the internal RAM (NO in step S480). ), The process transitions to step S520.

  In step S520, the second failure information storage unit 620 includes the failure history including the failure information acquired this time by the failure information acquisition unit 560 separately from the storage of the failure history information in the second storage area of the internal storage medium 500. The information is stored in the first storage area “Latest Condition Area” of the internal storage medium 500. Thereafter, the failure information storage process ends.

  As described above in detail, in this embodiment, the reproduction quality index value calculation unit 580 reproduces audio data from the disc 120 based on the failure information acquired by the failure information acquisition unit 560. When there are a plurality of pieces of acquired failure information, the failure information storage unit 600 stores the three pieces of failure information in the order of worse playback quality index values obtained from the respective failure information. The information is stored in the storage medium 500.

  In this way, only three pieces of failure information are stored in the internal storage medium 500 in the order of worse reproduction quality index values, so that a large amount of memory capacity is not required to leave the failure information. Furthermore, the user can easily acquire failure information that is easily connected to investigation of the cause of reproduction failure (poor reproduction quality). As a result, it is possible to collect the failure information of the reproduction failure with a small memory capacity and easily analyze the cause of the reproduction failure based on the collected small amount of failure information.

  Further, in the present embodiment, when there are a plurality of pieces of failure information acquired by the failure information acquisition unit 560, the second failure information storage unit 620 stores the three pieces of failure information stored in order from the lowest reproduction quality index value. Separately, six pieces of failure information that is closest in time are stored in the internal storage medium 500. In this way, since the most recent failure information in time is stored in the internal storage medium 500, the cause analysis of the failure that has occurred recently may be performed in more detail based on the stored failure information. Can do.

  In the present embodiment, when there are a plurality of pieces of failure information acquired by the failure information acquisition unit 560, the failure information storage unit 600 has the 3 in ascending order of the playback quality index values calculated by the playback quality index value calculation unit 580. Although one piece of failure information is stored in the internal storage medium 500, the present invention is not limited to this. For example, four or more pieces of failure information may be stored in the internal storage medium 500 in ascending order of the reproduction quality index value as long as the relatively small storage capacity of the internal storage medium 500 allows.

  Further, in the present embodiment, when there are a plurality of pieces of failure information acquired by the failure information acquisition unit 560, the second failure information storage unit 620 stores the three pieces of failure information stored in ascending order of reproduction quality index values. Separately, six pieces of failure information that is closest in time are stored in the internal storage medium 500, but the present invention is not limited to this. For example, the latest failure information in terms of time may not be stored at all. On the other hand, in the range allowed by the relatively small storage capacity of the internal storage medium 500, the latest failure information in time is stored in the internal storage medium 500 in addition to the three pieces of failure information stored in ascending order of the reproduction quality index value. Two or more may be stored.

  In the present embodiment, the example in which the failure information storage unit 560 stores the failure history information illustrated in FIG. 2A in the internal storage medium 500 has been described. However, all items of information included in the failure history information are not necessarily stored. It is not necessary to memorize. That is, the failure information storage unit 560 may include only items that are particularly useful for failure analysis related to playback failures in the failure history information and store them in the internal storage medium 500.

  In addition, each of the above-described embodiments is merely an example of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed in a limited manner. In other words, the present invention can be implemented in various forms without departing from the spirit or main features thereof.

It is a figure which shows the structural example of the storage medium reproducing | regenerating apparatus which implemented the failure information storage device by this invention. It is a figure which shows the example of a data structure of the fault history information containing the fault information by this embodiment. It is a figure which shows the example of the calculation method of the reproduction | regeneration quality parameter | index value by this embodiment. It is a figure which shows the example of a memory | storage method of the fault history information containing the fault information by this embodiment. It is a flowchart which shows the failure log | history information storage operation example of the storage medium reproducing | regenerating apparatus by this embodiment. It is a flowchart which shows the failure log | history information storage operation example of the storage medium reproducing | regenerating apparatus by this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Storage medium reproduction apparatus 120 Disk 140 Turntable 160 Spindle motor 180 Spindle servo circuit 200 Optical pick-up 220 Thread motor 240 Thread servo circuit 260 RF amplifier 280 Digital signal processing circuit 300 Focus servo circuit 320 Focus servo driver 340 Tracking servo circuit 360 Tracking servo Driver 380 Servo controller 400 System controller 420 ACC on / off detection unit 440 Disc insertion detection unit 460 Loading unit 480 Operation unit 500 Internal storage medium 520 TOC information acquisition unit 540 Playback control unit 560 Fault information acquisition unit 580 Playback quality index value calculation unit 600 Failure information storage unit 620 Second failure information storage unit

Claims (3)

A failure information acquisition unit that acquires failure information related to a playback failure that occurs when playback audio data is read from an external storage medium inserted in the playback device and played back;
Based on the failure information acquired by the failure information acquisition unit, a playback quality index value for calculating a playback quality index value that is an index of playback quality when the audio data from the external storage medium is being played back An arithmetic unit;
When there are a plurality of pieces of failure information acquired by the failure information acquisition unit, a predetermined number of pieces of the failure information are stored in the internal storage of the playback device in the order of poor playback quality index values calculated by the playback quality index value calculation unit. A failure information storage unit to be stored in the medium ,
The failure information includes a plurality of types of event information obtained by quantifying the number of occurrences of a plurality of types of events related to the regeneration failure,
The reproduction quality index value calculating unit weights the numerical values of the plurality of types of event information, adds the weighted values, and divides the added value by the reproduction time of the external storage medium. the output to the fault information storage device according to claim Rukoto as reproduction quality index value. The failure information storage device according to claim 1,
When there are a plurality of pieces of failure information acquired by the failure information acquisition unit, apart from the predetermined number of pieces of the failure information stored in the first storage area of the internal storage medium in the order of poor reproduction quality index value, A second failure information storage unit for storing a predetermined number of pieces of failure information nearest in time in the second storage area of the internal storage medium ;
The reproduction quality index value obtained by the reproduction quality index value calculation unit for the failure information acquired by the failure information acquisition unit is based on a predetermined number of reproduction quality index values already stored in the first storage area. If bad, the failure information acquired by the failure information acquisition unit is stored in the first storage area by the failure information storage unit and the second failure information storage unit is stored in the second storage area. On the other hand, if it is not worse than a predetermined number of reproduction quality index values already stored in the first storage area, the failure information acquired by the failure information acquisition unit is stored in the second failure information storage. The failure information storage device, wherein the storage unit stores the second information in the second storage area. A first step of acquiring failure information related to a playback failure that occurs when audio data for playback is read from an external storage medium inserted in the playback device and played back;
A second step of calculating, based on the failure information acquired in the first step, a reproduction quality index value serving as an index of reproduction quality when reproducing the audio data from the external storage medium; When,
The current reproduction quality index value obtained in the second step is counted from the worse one compared with a predetermined number of reproduction quality index values obtained in the past and stored in the internal storage medium of the reproduction apparatus. The failure information corresponding to the current reproduction quality index value is stored in the internal storage medium in place of one of the previous failure information stored in the internal storage medium. With steps ,
The failure information includes a plurality of types of event information obtained by quantifying the number of occurrences of a plurality of types of events related to the regeneration failure,
In the second step, the numerical values of the plurality of types of event information are weighted, the weighted values are added, and a value obtained by dividing the added value by the reproduction time of the external storage medium is reproduced. failure information storage method characterized that you output as a quality indicator value.