RU2016136820A - Waveform data structure, waveform data storage device, waveform data storage method, waveform data extraction device, waveform data extraction method and electronic musical instrument - Google Patents

Claims (107)

1. The data structure of the waveform, and: the waveform data structure is configured by a plurality of frame types having different data sizes; each of a plurality of frame types includes an auxiliary information area and a data area; the auxiliary information area includes an area for storing data on the total effective bit length for a segment of waveform samples and an area for storing an identifier for identifying one of a plurality of frame types; and the data area is an area for storing retrieved waveform samples that are retrieved from waveform samples based on the total effective bit length, and the number of retrieved waveform samples is determined based on the total effective bit length. 2. The waveform data structure according to claim 1, wherein: the data area is an area for storing retrieved waveform samples having a variable sound volume; and the auxiliary information area includes an area for storing a sound volume correction parameter for correcting the sound volume of the extracted waveform samples stored in the data area. 3. The data structure of the waveform, and: the waveform data structure is configured by at least the first and second frames, wherein the number of waveform samples to be stored in the first frame is different from the number of waveform samples to be stored in the second frame; each of the first and second frames includes an auxiliary information area and a data area; the auxiliary information area has frame attribute data including a region for storing data on the total effective bit length of waveform samples to be stored in the data region, and a region for storing data regarding the type of frame for identifying one of the first and second frames; and wherein in the data area, both numerous waveform samples and a number of samples are determined, determined in accordance with the first or second frame, identified by the frame type from the data of the frame attributes stored in the auxiliary data area and determined in accordance with the total effective bit length frame attribute data stored in the auxiliary information area. 4. The waveform data structure according to any one of paragraphs. 1-3, in which: total effective bit length is the maximum effective bit length of the effective bit lengths of a plurality of waveform samples to be stored in the data area. 5. The data structure of the waveform according to claim 3, in which: in the data area of the first frame, both numerous waveform samples and an integer obtained by dividing the data capacity of the first frame, with the exception of the auxiliary information area, by the total effective bit length are stored; and in the data region of the second frame, both numerous waveform samples and an integer obtained by dividing the data capacity of the second frame, with the exception of the auxiliary information area, by the total effective bit length are stored. 6. A device for storing waveform data, comprising: a determination unit that determines one of at least the first and second frames based on the change in effective bit lengths of the individual waveform samples to be stored, wherein the predetermined number of waveform samples to be stored in the first frame is different from the specified number of waveform samples to be saved in the second frame; an auxiliary information storage unit in which frame attribute data is stored including the total effective bit length of the waveform samples and the type of frame for identifying one of the first and second frames in the auxiliary information area of the first or second frame determined by the determining unit; and a waveform sample storage unit in which waveform samples are stored in the data region of the first or second frame determined by the determining unit based on a predetermined number of waveform samples in accordance with the total effective bit length of the frame attributes data stored in the auxiliary information area. 7. A device for storing waveform data according to claim 6, in which: in the case where the effective bit lengths of the individual waveform samples to be stored are changed, the determination unit determines a small-sized frame from the first and second frames; and in the case where the effective bit lengths of the individual waveform samples to be stored are not changed, the determining unit determines a large frame from the first and second frames. 8. A device for storing waveform data according to claim 6 or 7, in which: the determination unit in advance virtually identifies the first half of the frame and the second half of the frame; and the determination unit includes: a first half frame generation unit that extracts the maximum effective bit length from the effective bit lengths of the individual waveform samples to be stored as the first total effective bit length and which forms the first half of the frame when the number of waveform samples to be extracted reaches the stored amount samples of the waveform in the first half of the frame, while the stored number of samples of the waveform is determined based on the extracted first total effective length us in bits; a second half-frame generation unit that extracts the maximum effective bit length from the effective bit lengths of subsequent waveform samples to be stored, which are supplied after the waveform samples from the first half-frame generation unit, as the second total effective bit length and which generates the second half of the frame, when the number of extracted waveform samples reaches the stored number of waveform samples in the second half of the frame, while the number of mplov waveform determined based on the extracted second total effective length in bits; a first frame attribute data generating unit that generates frame attribute data including a frame type representing a large frame from the first and second frames and a second total effective bit length extracted by the second half frame generating unit in the case where the first common the effective bit length extracted by the block forming the first half of the frame coincides with the second total effective bit length extracted by the block forming the second half of the frame; and a second block attribute data generating unit, which generates frame attribute data including a frame type representing a small-sized frame from the first and second frames, and a first total effective bit length extracted by the first half frame generating unit, in the case where the first common the effective bit length extracted by the block forming the first half of the frame does not match the second total effective bit length extracted by the block forming the second half of the frame. 9. A device for storing waveform data according to claim 6 or 7, in which: the waveform sample storage unit stores compressed waveform samples obtained by encoding individual waveform samples based on the total effective bit length of the attribute data of the frame stored in the auxiliary information area in the data area of the first or second frame determined by the determination unit. 10. A device for storing waveform data, comprising: a determination unit that determines one frame from a plurality of frames based on a bit length of waveform samples that are supplied, while the sizes of frames from a plurality of frames to store waveform samples are different from each other; and a data storage unit that stores at least bit length data representing the bit length of the waveform samples and frame attribute data representing a frame for storing the determination determined by the block in the auxiliary information area formed in the storage device in which the area is formed data having a size based on frame attribute data stored in the auxiliary information area, and which stores waveform samples in a data area formed in a storage device ystv. 11. A device for storing waveform data according to claim 10, in which: the determination unit includes: a sequence determination unit that determines whether a predetermined or more consecutive samples have the same bit length equal to the quantization length in bits of prediction error data obtained by adaptive prediction of samples of the original waveform; and a size determining unit that determines a small size of the data area from at least different sizes of the data area in the case where the sequence determining unit determines that a predetermined or more consecutive samples do not have the same bit length, and which determines the large size of the data area in the case where the sequence determination unit determines that a predetermined or more consecutive samples have the same bit length. 12. A method of storing waveform data of a waveform storage device in which: A device for storing waveform data is configured to: determining one of at least the first and second frames based on the change in effective bit lengths of the individual waveform samples to be stored, wherein the number of waveform samples to be stored in the first frame is different from the number of waveform samples to be stored in the second frame; storing the data of the attributes of the frame, including the total effective bit length of the samples of the waveform and the type of frame for identifying one of the first and second frames, in the auxiliary information area of the specific first or second frame; and storing both multiple waveform samples and a number of samples in accordance with the total effective bit length of the frame attributes data stored in the auxiliary information area in the data area of a particular first or second frame. 13. The method of storing waveform data according to claim 12, wherein: A device for storing waveform data is configured to: determining a small-sized frame from the first and second frames in the case where the effective bit lengths of the individual waveform samples to be stored are changed; and determining a large frame from the first and second frames in the case where the effective bit lengths of the individual waveform samples to be stored are not changed. 14. A method for storing waveform data according to claim 12 or 13, wherein: A device for storing waveform data is configured to: leading designation of the first half of the frame and the second half of the frame; extracting the maximum effective bit length from the effective bit lengths of the individual waveform samples to be stored as the first total effective bit length and forming the first half of the frame when the number of waveform samples to be extracted reaches the stored number of waveform samples in the first half of the frame, wherein the stored number of waveform samples is determined based on the retrievable first total effective bit length; extracting the maximum effective bit length from the effective bit lengths of successive waveform samples to be stored, which are provided after the waveform samples of the first half of the frame, as the second total effective bit length and forming the second half of the frame when the number of waveform samples to be extracted reaches the stored number of waveform samples in the second half of the frame, while the stored number of waveform samples is determined based on the extracted second effective effective length in bits; the generation of frame attribute data, including a frame type representing a large frame from the first and second frames, and a second total effective bit length, extracted during the formation of the second half of the frame, in the case where the first total effective bit length, extracted in the formation time of the first half of the frame, coincides with the second total effective bit length extracted during the formation of the second half of the frame; and the formation of the frame attributes data, including the frame type representing a small-sized frame from the first and second frames, and the first total effective bit length extracted during the formation of the first half of the frame, in the case where the first total effective bit length extracted in the formation time of the first half of the frame does not coincide with the second total effective bit length extracted during the formation of the second half of the frame. 15. A method of storing waveform data associated with a storage device for waveform data, wherein: A device for storing waveform data is configured to: determining the size of the frame region for storing waveform samples based on the length in bits of the waveform samples that are supplied; storing at least bit length data representing the bit length of the waveform samples and data about the size of the data region representing the specific size of the region in the auxiliary information area formed in the storage device; and defining a data region having an area size represented by data on the size of the data region stored in the auxiliary information area, and storing waveform samples in the predetermined data region. 16. The method of storing waveform data according to claim 15, wherein: A device for storing waveform data is configured to: determining whether a predetermined or more consecutive samples have the same bit length equal to the quantization length in bits of prediction error data obtained by adaptive prediction of samples of the original waveform; determining a small size of the data region from at least different sizes of the data region if it is determined that a predetermined or more consecutive samples do not have the same bit length; and determining a large data size from at least different sizes of the data region in the case of determining that a predetermined or more consecutive samples have the same bit length. 17. A device for extracting waveform data that has access to a storage device having a waveform data structure according to claim 1, wherein the device for extracting waveform data comprises: an address data generation unit that generates address data based on the total effective bit length read from the auxiliary information area of the assigned frame stored in the storage device; an extraction unit that extracts waveform samples from the data area of the assigned frame in accordance with the address data generated by the address data generation unit; and a frame assignment unit that assigns the next frame to be extracted after the waveform samples are extracted by the extraction unit. 18. A device for extracting waveform data that has access to a storage device having a waveform data structure according to claim 3, wherein the device for extracting waveform data comprises: a reading unit that sequentially reads the waveform samples from the data area of the assigned frame in accordance with the address data based on the total effective bit length of the frame attributes data stored in the auxiliary information area of the assigned first or second frame stored in the storage device; and a next frame assignment unit that assigns one of the first and second frames as the next frame to be read after the waveform samples of the assigned frame are read by the read unit. 19. A method of extracting waveform data of a device for extracting waveform data, wherein: A device for extracting waveform data is configured to access a storage device having a waveform data structure according to claim 1, and wherein the method of extracting waveform data comprises the steps of: generate address data based on data on the length in bits read from the auxiliary information area of the assigned frame stored in the storage device; extracting waveform samples from the data area of the assigned frame in accordance with the generated address data; and designate the next frame to be extracted after extracting the waveform samples. 20. A method of extracting waveform data of a device for extracting waveform data, wherein: A device for extracting waveform data is configured to access a storage device having a waveform data structure according to claim 3, wherein the method of extracting waveform data comprises the steps of: sequentially reading the waveform samples from the data area of the assigned frame in accordance with the address data based on the total effective bit length of the frame attributes data stored in the auxiliary information area of the assigned first or second frame in the storage device; and designate one of the first and second frames as the next frame to be read after reading the waveform samples of the assigned frame. 21. An electronic musical instrument comprising: a storage device having a waveform data structure according to claim 1; a device for extracting waveform data; an input unit for the performance of the musical instrument, which generates information about the performance of the musical instrument in accordance with the playback operations; a processing unit that performs an instruction process for instructing the formation of music in accordance with reproduction operations and a control process for controlling a device for extracting waveform data, so that the device for extracting waveform data extracts necessary waveform samples from the storage device in response to the instruction process , and a sound generating unit that generates a musical sound based on waveform data obtained by decompressing waveform samples taken from the waveform data extraction apparatus, in which the device for extracting waveform data is configured to access a storage device having a waveform data structure according to claim 1, and A device for extracting waveform data includes: a sound generating unit that generates a musical sound based on waveform data obtained by decompressing waveform samples taken from the waveform data extraction apparatus; an address data generation unit that generates address data based on the total effective bit length read from the auxiliary information area of the assigned frame stored in the storage device; an extraction unit that extracts waveform samples from the data area of the assigned frame in accordance with the address data generated by the address data generation unit; and a frame assigning unit that assigns the next frame to be extracted after the waveform samples are extracted by the extraction unit. 22. An electronic musical instrument comprising: a storage device having a waveform data structure according to claim 3; a device for extracting waveform data; an input unit for the performance of the musical instrument, which generates information about the performance of the musical instrument in accordance with the playback operations; a processing unit that performs the instructing process for generating music in accordance with the reproduction operations and the control process of the device for extracting waveform data so that the device for extracting waveform data retrieves the necessary waveform samples from the storage device in response to the instructing process, and a sound generating unit that generates a musical sound based on waveform data obtained by decompressing waveform samples taken from the waveform data extraction apparatus, in which the device for extracting waveform data is configured to access a storage device having a waveform data structure according to claim 3, and A device for extracting waveform data includes: a reading unit that sequentially reads the waveform samples from the data area of the assigned first or second frame stored in the storage device, in accordance with the address data based on the total effective length in the data bits of the frame attributes stored in the auxiliary information area of the assigned first or second frame, stored in a storage device; and a next frame assignment unit that assigns one of the first and second frames as the next frame to be read after the waveform samples of the assigned frame are read by the read unit. 23. An electronic musical instrument according to claim 21 or 22, in which: the sound generating unit generates sound based on waveform samples reconstructed in accordance with the sound volume correction parameter when the waveform data extractor extracts the sound volume correction parameter from the auxiliary information area of the frame.