JP3653281B2 - Signal recording method and apparatus using the same - Google Patents

Description

TECHNICAL FIELD The present invention relates to a technique for recording data on a medium such as a data recorder or a hard disk, and relates to a signal recording method capable of shortening ownership time, an apparatus using the same, and a recording medium recorded by the recording method or apparatus.
BACKGROUND ART Conventionally, there have been the following methods for recording data transmitted from an information processing system to an apparatus. FIG. 13 shows a flowchart thereof. The data is stored in the memory (FIG. 13C), the data is recorded on the medium (FIG. 13D), and the data is reproduced from the medium for error management (FIG. 13E). An error is detected by comparing the data in the memory (Fig. 13F), the error detection result is compared with the error threshold (Fig. 13G), and the threshold is fixed to a fixed value. If the value is satisfied, the recording is terminated, and if not satisfied, the recording is performed again in the order of returning to recording (FIG. 13D). Until the threshold is satisfied, the recording (FIG. 13D) to the comparison with the threshold (FIG. 13G) are repeated.
FIG. 14 shows details of the threshold comparison. Here, an error rate is used as a threshold for error comparison. The error rate is the ratio of errors to a certain number of recorded data. The solid line represents the fluctuation of the error rate along the time axis, and the broken line represents the threshold value. When the error rate becomes higher than a certain threshold value, that is, when the threshold value is not satisfied, the data is re-recorded.
Currently, an information processing system and devices connected to the information processing system are desired to be fast from the viewpoint of reliability and time efficiency. In addition, there are increasing opportunities to handle image data in information processing systems such as personal computers and workstations. Currently, still images are mainly used, but it is thought that opportunities to handle moving images will increase.
The amount of image data is larger than the amount of numerical data or program data. For example, a single black-and-white still image requires position information and luminance information for the number of pixels. Color information is added to a color image. If the image to be handled changes from a still image to a moving image, the amount of data further increases. From this, it is considered that the amount of data that must be processed in the information processing system that handles image data increases dramatically compared to the information processing system that handles only numerical data and program data. It is considered that the time required to record this data becomes longer due to the increase in the data amount, and this is a problem from the viewpoint of high speed.
In conventional error management using a threshold value fixed to a certain value, it is difficult to prevent this recording from being prolonged.
Accordingly, an object of the present invention is to provide a signal recording technique that prevents a long recording time of data having a large amount of data such as image data.
Disclosure of the Invention The present invention determines the type of data such as numerical data, program data, still image data, and moving image data, and sets a threshold value for error management of recorded data on the medium according to the data type. The data is stored in the memory, the data is recorded on the medium, the data is reproduced from the medium for error management, the error is detected by comparing the reproduced data and the data in the memory, and the error detection result and the error are detected. The threshold values are compared, and if the threshold value is satisfied, the process is terminated. This makes it possible to shorten the time required for error management due to the threshold value of the recording data on the medium, and to provide a signal recording method that prevents the recording time of image data having a large amount of data from being prolonged.
[Brief description of the drawings]
FIG. 1 is a diagram showing a flowchart of a recording method according to an embodiment of the present invention, FIG. 2 is a diagram showing threshold values and error rates along a time axis, and FIG. FIG. 4 is a diagram showing a flowchart of a recording method according to an embodiment of the present invention, FIG. 4 is a diagram showing an outline of the apparatus, and FIG. 5 is a flowchart of a recording method according to an embodiment of the present invention. FIG. 6 is a diagram showing a flowchart of a recording method according to an embodiment of the present invention, and FIG. 7 is a diagram showing a flowchart of a recording method according to an embodiment of the present invention. FIG. 8 is a diagram showing a data block, FIG. 9 is a diagram showing a tape and a helical scan type apparatus according to an embodiment of the present invention, and FIG. 10 is an embodiment of the present invention. FIG. 11 shows an example of a tape and a device for recording in the longitudinal direction, and FIG. FIG. 12 is a diagram showing a disk according to an embodiment of the present invention and a device using the same, FIG. 12 is a diagram showing a card according to an embodiment of the present invention, and FIG. 13 is a diagram showing conventional recording. FIG. 14 is a diagram showing a flowchart of the method, and FIG. 14 is a diagram showing a threshold value and an error rate along a conventional time axis.
BEST MODE FOR CARRYING OUT THE INVENTION To describe the present invention in more detail, the following description will be given with reference to the accompanying drawings.
FIG. 1 shows a flowchart of a recording method according to an embodiment. A) The type of data such as numerical data, program data, still image data, or moving image data is discriminated. B) A threshold value for error management of recorded data on the medium is set according to the data type. ) Store data in memory, D) record data on the medium, E) reproduce data from the medium for error management, F) detect errors by comparing the reproduced data with data in the memory, G) The error detection result is compared with the threshold value for error management of the recording data on the medium. If the threshold value is satisfied, the process ends. If the threshold value is not satisfied, D) returns to recording. However, B) may be performed before G), that is, after C), D), E), and F).
In the following, each of the recording methods will be described with reference to the respective examples by adding the symbols A) to G).
Three examples of A) data type discrimination classification and B) threshold setting based on the classification are shown below.
(1) Discriminate between non-image data and image data. When handling non-image data such as numerical data and program data, the threshold value is set to a. When image data such as still image data and moving image data is handled, the allowable amount of errors is larger than the above a. Is set to a threshold value b. A case where an error rate is used as the threshold will be described below. The error rate is the ratio of errors to a certain number of recorded data, and the error rate increases as the amount of errors increases. At this time, b is set to a high value with respect to a, that is, a <b.
(2) Discriminate between non-moving image data and moving image data. When handling non-moving image data such as numerical data, program data, and still image data, the threshold value is set to a. When moving image data is handled, the threshold of error tolerance is larger than a. Set to the value b. When an error rate is used as a threshold value, b is set to a high value with respect to a, that is, a <b.
(3) Discriminate between non-image data, still image data, and moving image data. When handling non-image data such as numerical data and program data, the threshold value is set to a, and when handling still image data, the threshold value b is set so that the error tolerance is larger than a. When handling moving image data, the threshold value c is set so that the error tolerance is larger than b. When an error rate is used as the threshold, a <b <c is set.
The reason why the threshold value of the image data is set to a value with a larger error tolerance with respect to the threshold value of the non-image data will be described below. The threshold used for error management is set to a value that allows the data processing system to handle the data without any problem. Error management based on the threshold value of the recording data on the medium is necessary from the viewpoint of reliability, but from the viewpoint of high speed, the speed of processing depends on the threshold setting value. . In other words, when the threshold value is set to a value that increases the error tolerance, the probability of satisfying the threshold value during recording increases, and the time required for error management by the threshold value is short, but the threshold value is high. When the value is set to a value with a smaller error tolerance, the probability of satisfying the threshold is lowered, and the time required for error management is increased. Here, attention is paid to the difference in quality of image data from non-image data such as numerical data and program data. Numerical data is single information, but image data is a collection of many numerical information. More specifically, if it is necessary information that how many people are shown on a certain screen, missing data of several pixels or tens of pixels does not cause a problem. For non-image data, setting the threshold value to a value that increases the allowable error is problematic from the reliability, but for image data, the threshold value is set to a value that increases the allowable value up to a certain value. But there is no practical problem.
In the following description, the case of discriminating between non-image data and image data will be described as an example. The same applies to the other classifications.
C) Data sent to the device is stored in memory. Extract a certain amount of unrecorded data from memory.
D) Recording is performed on the medium by the recording head.
Data is recorded on the medium in fixed amounts. This amount varies depending on the apparatus using the recording method. Hereinafter, a certain amount of data at the time of recording will be referred to as divided data.
E) Data read from the medium by the reproducing head is amplified by a preamplifier circuit, demodulated in a demodulating circuit through an equalizer circuit and a clock reproducing circuit.
F) Error detection will be described. An error is detected by comparing the reproduced data with data stored in the memory. This error is corrected by an error correction circuit, and an error flag is attached to the remaining error. The number of error flags is counted by the error number counter.
G) The threshold value and comparison will be described. Here, an error rate is used as a threshold for error comparison. The error rate is the ratio of errors to a certain number of recorded data. FIG. 2 shows the error rate variation along the time axis. The solid line represents the error rate variation along the time axis, and the broken line represents the threshold value. The threshold is set according to the data type. In contrast to the threshold for handling non-image data, the threshold is set to increase the allowable error when handling image data. As a result, even if the error rate deteriorates when handling image data, the probability of satisfying the threshold is increased, and the time required for error management by the threshold of the recording data on the medium can be shortened.
The following is after threshold comparison.
(1) When all the data is recorded when the threshold value is satisfied, the process ends. Otherwise, the process returns to the extraction of unrecorded data, and D) the recording and the like are performed in the same manner as described above.
(2) When the threshold value is not satisfied When the threshold value is not satisfied, the same data as that used for the previous recording is extracted from the memory, and D) the recording is performed in the same manner. Hereinafter, the recording position on the medium will be described. Attempts to record the same data at the same position on the medium up to the re-recording limit A. If the threshold is still not satisfied, the recording position on the medium is changed, and the same data is tried to be recorded at the same position on the medium up to the re-recording limit A. If the threshold value is not satisfied even if this is repeated up to the number of position changes B, the device user selects whether to continue or cancel the recording after displaying the information indicating the recording failure on the information processing system screen. Let When continuing, try to record the same data again. When canceling, the recording ends.
When recording is repeated at the same position on the medium, the head and the medium must be moved so that the head comes to the same position. When the tape shown in FIGS. 9 and 10 is used as a medium, the tape must be rewound by a certain amount.
In preparation for the case where the divided data are not continuously reproduced because the position is changed, the divided data is recorded together with a number or a symbol that can determine which part of which data belongs to which data.
FIG. 3 shows a flowchart of a recording method according to an embodiment. The threshold value can be changed after the device user selects to continue recording in the continue recording selection. After selecting to continue recording, the apparatus user is made to select whether to change the threshold value or not. When changing is selected, the apparatus user changes the threshold value using software or a switch or dial provided in the apparatus. At this time, by changing the threshold value to the threshold value b that increases the allowable amount of errors compared to the previous time, the probability that the threshold value is satisfied in re-recording can be increased. Alternatively, if change is selected, the device automatically changes the threshold to a value that satisfies the error rate that did not satisfy the previous threshold. For example, the threshold value b1 is changed so that b1> be with respect to the error rate be that did not satisfy the previous threshold value. Then, try to record the same data again.
Hereinafter, an apparatus using the above recording method will be described. FIG. 4 shows a schematic view of the apparatus. An apparatus records data using a head on a medium, reproduces data from the medium using a head, a data processing unit that processes recorded data and reproduced data, and behavior of the recording / reproducing unit It is comprised by the control processing part etc. which control. In addition, the apparatus can communicate data with the information processing system using a transmission unit. There are SCSI and the like as a transmission means. Data, file names, data type discrimination results, etc. are transmitted from the information processing system to the device using SCSI commands or the like. SCSI is an abbreviation for Small Computer System Interface, which is standardized by the American National Standards Institute (ANSI) as a standard interface for computers, and is used to connect information processing systems and devices. Here, the information processing system is a mainframe, a workstation, a personal computer, or the like. A) The data type discrimination method includes a method using data type discrimination software and a method not using this. And the method using software is further divided into two according to the signal form of the data type information transmitted from the information processing system to the apparatus. This signal form is a data type discrimination result and a threshold value. This will be described in detail below.
(1) Method without Using Data Type Discrimination Software FIG. 5 is a flowchart showing a system and an apparatus for performing each process of the recording method. In the information processing system, the user determines the type of data to be recorded, non-image data or image data, and adds a specific extension designated by the device manufacturer to the file name. As an example, assume that the extension of a specific file name indicating an image is designated as “AA”. When the device user transmits data of a file with the extension “AA” from the information processing system to the device, the device recognizes the data type of the transmitted data as image data with the extension “AA”. A threshold setting circuit in the apparatus sets a threshold by referring to a threshold stored in a storage device such as a ROM according to the data type. As for the threshold value to be referred to, an external switch or dial is provided in the apparatus, and the apparatus user can set the threshold value by these. Also, as an example, the device manufacturer can specify several extensions that indicate different reference thresholds. As an example, it is assumed that the extensions “AA1”, “AA2”, and “AA3” correspond to the reference threshold values x, y, and z, and have a relationship of x>y> z. By using this extension, the apparatus user can select a threshold value from several types of threshold values. (2.1) Method of discriminating using data type discriminating software and transmitting a data type discriminating signal FIG. 6 shows a flowchart showing a system and an apparatus for performing each process of the recording method. The software is activated and operable in the information processing system before sending data to the device. The software determines whether the data to be recorded is non-image data or image data from an extension of the file name, from a storage format such as PICT, or from information about a file held by the information processing system. Thus, the software has a data type determination result indicating whether the data is non-image data or image data. The data type determination result is transmitted from the information processing system to the apparatus together with the data. When the threshold value setting circuit in the apparatus receives the data type discrimination result, the threshold value setting circuit refers to the threshold value stored in the storage device such as the ROM and sets the threshold value. As for the threshold value to be referred to, an external switch or dial is provided in the apparatus, and the apparatus user can set the threshold value by these. (2.2) When discriminating using data type discriminating software and transmitting a threshold value FIG. 7 shows a flowchart showing a system and an apparatus for performing each process of the recording method. The software is activated and operable in the information processing system before sending data to the device. The software determines whether the data to be recorded is non-image data or image data from an extension of the file name, from a storage format such as PICT, or from information about a file held by the information processing system. Thus, the software has a data type determination signal indicating whether the data is non-image data or image data. Further, the user sets a threshold value from the data type discrimination result using software in the information processing system. The threshold value is transmitted together with the data from the information processing system to the apparatus. There are several methods for setting the threshold, and are shown below.
(2.2.1) A method in which a value is given as an initial value as a threshold value from the device manufacturer and is used as it is. (2.2.2) A method in which the device user selects a threshold value from several values using software. An instruction is displayed on the screen for selection by software, for example, what number is to be set and how many threshold values are set, and the icon or keyboard on the screen is selected accordingly.
(2.2.3) A method in which the device user sets the threshold value to any value using software. An instruction for setting by software is displayed on the screen, and a threshold value is input by using the keyboard accordingly.
In the apparatus, attached data such as headers and error correction codes (ECC) having various attribute information of data is added to the data and handled. That is, the attached data is stored or recorded together with the data. The attached data and the data form one data block. FIG. 8 shows an example. The threshold setting based on the data type described in the present invention has the following two application forms (1) and (2) for data and attached data.
(1) The threshold setting according to the data type is applied only to data, and is not applied to attached data such as a header and an error correction code. Therefore, threshold comparison must be performed separately for data and attached data.
(2) The threshold setting by data type is applied to all data and attached data.
As one embodiment, there is a method of recording a threshold value that is referred to when recording, by including it in this header, a device using this recording method, and a medium recorded by this recording method. According to this method, the apparatus user can know in which range the data has deteriorated with respect to the original data when reproducing the data.
As an embodiment, there is provided a method for recording a threshold value referenced at the time of recording and an actual error rate value to be compared in this header, a device using this recording method, and a medium recorded by this recording method. is there. For example, if image data is repeatedly recorded many times, deterioration is accumulated for each recording by the threshold value set to a value that increases the allowable error. In preparation for such a situation, if an error detection result such as an error rate for each recording with respect to the original data is stored, an accurate deterioration amount of the current data with respect to the original data can be obtained.
As one embodiment, the threshold value for the next recording is determined based on the range in which the original data can be degraded and the error rate of the current data. One of the determination methods is shown below.
L = MN
Where L: Error rate as a threshold for the next recording
M: Error rate as a threshold calculated based on the possible degradation range for the original data
N: Amount of error rate degradation with respect to the original data of the current data As an example, the apparatus user performs error management of recorded data using a single threshold value by software, or is set according to the type of data There is an apparatus configured to be able to select whether it is performed according to a threshold value. An instruction is displayed on the screen for selecting by software, for example, which method is used to select the number, and the icon or keyboard on the screen is selected accordingly.
Examples of the medium recorded by the recording method and the vicinity of the head of the apparatus are shown below.
As an example, tape 1 is used as a medium, which is recorded using magnetism. There are two types of devices for this medium. FIG. 9 shows one of them, the helical scan type. The tape 1 is wound around the rotary head device 3 by the tape guides 4 and 5, and is recorded and reproduced by the head 2 mounted on the rotary head device 3. FIG. 10 shows another type of recording in the longitudinal direction of the tape. The tape 1 is driven by a capstan 6 and a pinch roller 7 and is recorded and reproduced by a fixed head 2.
FIG. 11 shows an embodiment of an apparatus using a flat circular disk 8 as a medium. The disk is rotated and the head 2 is moved to perform recording and reproduction. The head is moved by sliding or rotating the arm 9. As a recording method, there are a recording method using magnetism and a recording method using light such as a laser beam. Each of the heads forms a magnetic field or irradiates light toward the medium.
There is an apparatus for recording in a recordable area 11 using a card 10 as a medium. FIG. 12 shows an embodiment of the card 10.
Industrial Applicability As described above, a recording method according to the present invention, an apparatus using the recording method, and a recorded medium are recorded using a medium such as a data recorder, a floppy disk drive, a hard disk, and the like. It is suitable for use in an apparatus using a recording method and a medium recorded by this recording method.

Claims (23)

Determine the type of data to be recorded and Set a threshold corresponding to the error tolerance according to the After saving the data in memory, the saved in the memory Data is recorded on the medium, and the recording is performed from the medium after the recording operation. Recording data is reproduced, and the reproduced data is stored in the memory. Error detection compared with the data in the And the detection result is compared with the threshold value. If you are dissatisfied with the previous value, the previous recording operation in the memory will be performed again. Re-record the data used for recording on the medium and store the re-recorded data. As above, playback, error detection, threshold ratio If the threshold is satisfied, If recorded data remains, unrecorded data in the memory The above-mentioned recording of the above is performed in the same manner and the threshold value is satisfied. If there is no unrecorded data left, A signal recording method characterized by that. In the above threshold setting, image data Threshold value for non-image data The scope of claims set to increase the tolerance for errors. The signal recording method according to claim 1. When setting the above threshold values, The threshold for non-moving image data. Billing set to allow more errors than values The signal recording method according to claim 1, wherein When setting the above threshold values, The threshold for the case of still image data. Set the error tolerance to be greater than the value, and The threshold for image data is the same as for non-image data. Set the error tolerance to be greater than the threshold. The signal recording method according to claim 1. The threshold value used as the recording condition is the medium. The signal recording according to claim 1, wherein the signal recording is performed on Method. The error results detected during recording are recorded on the medium. The signal recording method according to claim 1, wherein the signal is recorded. Determine the type of data to be recorded and Set a threshold corresponding to the error tolerance according to the After saving the data in memory, the saved in the memory Data is recorded on the medium, and the recording is performed from the medium after the recording operation. Recording data is reproduced, and the reproduced data is stored in the memory. Error detection compared with the data in the And the above threshold value is compared, and based on the comparison result, The set threshold value has a larger error tolerance than the set value. To the previous recording operation in the memory again. Re-record the data used in the work on the medium and re-record Replay, error detection, threshold for data as above It is characterized by comparing and discriminating with values Signal recording method. The above threshold setting is based on the data type That are automatically set based on the result of 9. A signal recording method according to claim 7, wherein: Discriminating means for discriminating the type of data to be recorded And a threshold corresponding to the error tolerance according to the determination result A setting means for setting the data, a memory for storing the data, Recorder for recording data stored in the memory on a medium And reproducing the recorded data from the medium after the recording operation. Reproducing means, and the reproduced data as data in the memory Detection means for comparing and detecting error, and error detection result And a comparing means for comparing the set threshold value with the set threshold value, If the error detection result does not satisfy the threshold, it is Re-record the data used for the previous recording operation in the memory on the medium. Recorded and re-recorded data in the same manner as described above. -Detection, comparison with threshold and discrimination If unrecorded data remains, Perform the above-mentioned recording of unrecorded data in the memory in the same way, When the threshold is satisfied, there is still unrecorded data Signal recording characterized in that it is configured to end if not Recording device. The setting means is connected to the output of the discrimination means. Therefore, the automatic setting of claim 9 The signal recording device according to item. Discriminator that determines the type of data to be recorded And a threshold corresponding to the error tolerance according to the determination result. Setting means for setting a value and memory for storing the data And recording the data stored in the memory on a medium. And recording means from the medium after the recording operation of the recording means Reproduction means for performing data reproduction operation, and Detection means for detecting errors by comparing with data in memory And the error detection result is compared with the set threshold value. Comparing means, and the setting means based on the comparison result The threshold value at which the error tolerance is larger than the set value To the previous recording operation in the memory again. The recorded data is re-recorded on the medium, and the re-recorded data is recorded. As above, playback, error detection, comparison with threshold A signal recording device characterized in that Place. The setting means is connected to the output of the discrimination means. Therefore, the claim 11 is automatically set. The signal recording device according to item. The setting means is connected to the output of the comparison means. Therefore, the scope of claims that are automatically reset Item 11. The signal recording device according to item 11 or 12. The discriminating means can discriminate the type of data 9. The configuration according to claim 9, wherein the configuration is provided with functional software. Signal recording device. The discriminating means can discriminate the type of data 12. The configuration according to claim 11, which is configured to include functional software Signal recording device. The setting means sets a threshold value to be set, 9. Claim according to claim 9 which is configured to be selectable from several values The signal recording device. The setting means sets a threshold value to be set, Claim 11 which can be selected from several values The signal recording device. The setting means sets a threshold value to be set, The claim 9 which is configured to be set to an arbitrary value. Signal recording device. The setting means sets a threshold value to be set, 11. The claim 11 which is configured to be set to an arbitrary value Signal recording device. The setting means sets a threshold value to be set, It has a configuration that can be set regardless of the output of the discrimination means The signal recording apparatus according to claim 9. The setting means sets a threshold value to be set, It has a configuration that can be set regardless of the output of the discrimination means 12. The signal recording apparatus according to claim 11, wherein: The recording means is detected by the detecting means. The error detection result can be recorded on the medium. The signal recording device according to claim 9. The recording means is detected by the detecting means. The error detection result can be recorded on the medium. 12. A signal recording device according to claim 11.

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