JP6526126B2 - Speech decoder - Google Patents

Description

  The present invention relates to a speech decoding apparatus.

  Speech coding technology that compresses the amount of data of speech signals and sound signals to a few tenths is a very important technology in signal transmission and storage. Code-Excited Linear Predictive Coding (CELP), which encodes a signal in the time domain, transform code excitation coding (TCX), which encodes a signal in the frequency domain, as examples of widely used speech coding techniques. Examples include "MPEG4 AAC" standardized by "ISO / IEC MPEG".

  As a method of further improving the performance of speech coding and obtaining high speech quality at a low bit rate, a band expansion technique for generating high frequency components using low frequency components of speech has been widely used in recent years. A representative example of the band extension technology is SBR (Spectral Band Replication) technology used in "MPEG4 AAC".

  In speech coding, the time envelope shape of a decoded signal obtained by decoding a coded sequence obtained by coding an input signal may be significantly different from the time envelope shape of the input signal and may be perceived as distortion. Also, in the case of using the band extension technology, in order to generate high frequency components using a signal obtained by encoding / decoding low frequency components of the speech signal by the above speech coding technology, The temporal envelope shape of high frequency components is also different and may be perceived as distortion.

  The following method is known as a solution to this problem (see Patent Document 1 below). That is, in order to generate a high frequency component, the high frequency component is divided into frequency bands in an arbitrary time segment, and energy of each frequency band is calculated and encoded. Are calculated and encoded for each time segment shorter than the above time segment. At this time, the bandwidth of each frequency band and the length of the short time segment can be flexibly set for the frequency band to be divided and the short time segment. Thereby, in the decoding device, in the time direction, the energy of the high frequency component can be controlled for each short time segment, that is, the temporal envelope of the high frequency component can be controlled for each short time segment.

U.S. Patent No. 7,191,121

  However, according to the method of Patent Document 1, in order to control the time envelope of high frequency components in detail, it is divided into very short time segments, energy information for each frequency band is calculated for each short time segment, and the code There is a problem that the amount of information concerned becomes very large and it becomes difficult to encode at a low bit rate.

  In view of the above problems, the present invention aims to correct the temporal envelope shape of a decoded signal with a small amount of information and reduce perceived distortion.

A speech decoding apparatus according to an embodiment of the present invention is a speech decoding apparatus that decodes a coded speech signal and outputs a speech signal, and a coded sequence including information of the coded low frequency signal A low frequency decoding unit for receiving and decoding to obtain a low frequency signal; a high frequency decoding unit for receiving the first information from the low frequency decoding unit and generating a high frequency signal based on the first information; And a time determined by the high frequency time envelope shape determination unit, which determines the time envelope shape of the generated high frequency signal based on the second information transmitted from the information processing apparatus. A high frequency time envelope correction unit that corrects and outputs a time envelope shape of the generated high frequency signal based on an envelope shape, and a low frequency signal is received from the low frequency decoding unit, and the high frequency time envelope correction unit A low frequency / high frequency signal combining unit for obtaining an audio signal to be output by receiving a high frequency signal whose envelope shape has been corrected, and combining the low frequency signal and the high frequency signal whose time envelope shape has been corrected; And the high frequency time envelope correction unit determines that the time envelope shape is flat in the high frequency time envelope shape determination unit, the high frequency time envelope correction unit determines that the high frequency signal is generated in the same time segment as the generated high frequency signal. The generated high frequency signal is used to correct and output the time envelope shape, and when correcting the time envelope shape of the encoded voice signal , the high frequency signal generated by the high frequency decoding unit is used. The time envelope information of the high frequency signal determined by the power is used, and the time envelope information of the low frequency signal obtained from the low frequency decoding unit is not used .

  According to the present invention, it is possible to correct the temporal envelope shape of the decoded signal with less amount of information and reduce the perceived distortion.

It is a figure which shows the structure of the audio | voice decoding apparatus 10 which concerns on 1st Embodiment. It is a flowchart which shows operation | movement of the audio | voice decoding apparatus 10 which concerns on 1st Embodiment. It is a figure which shows the structure of the speech coding apparatus 20 which concerns on 1st Embodiment. 5 is a flowchart showing an operation of the speech to digital converter 20 according to the first embodiment. It is a figure showing the composition of the 1st modification 10A of the speech decoding device concerning a 1st embodiment. It is a flow chart which shows operation of the 1st modification 10A of the speech decoding device concerning a 1st embodiment. It is a figure which shows the structure of the 2nd modification 10 B of the speech decoding apparatus which concerns on 1st Embodiment. It is a figure which shows the structure of the 3rd modification 10C of the speech decoding apparatus which concerns on 1st Embodiment. It is a figure showing the composition of the 1st modification 20A of the speech to digital converter concerning a 1st embodiment. It is a flowchart which shows operation | movement of the 1st modification 20A of the speech to digital converter based on 1st Embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 11 which concerns on 2nd Embodiment. It is a flowchart which shows operation | movement of the audio | voice decoding apparatus 11 which concerns on 2nd Embodiment. It is a figure which shows the structure of the speech coding apparatus 21 which concerns on 2nd Embodiment. It is a flowchart which shows operation | movement of the speech coding apparatus 21 which concerns on 2nd Embodiment. It is a figure showing the composition of the 1st modification 21A of the speech to digital converter concerning a 2nd embodiment. It is a flowchart which shows operation | movement of the 1st modification 21A of the speech to digital converter which concerns on 2nd Embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 12 which concerns on 3rd Embodiment. It is a flowchart which shows operation | movement of the audio | voice decoding apparatus 12 which concerns on 3rd Embodiment. It is a figure which shows the structure of the speech coding apparatus 22 which concerns on 3rd Embodiment. It is a flowchart which shows operation | movement of the speech coding apparatus 22 which concerns on 3rd Embodiment. It is a figure showing the composition of the 1st modification 22A of the speech to digital converter concerning a 3rd embodiment. It is a flowchart which shows the operation | movement of the 1st modification 22A of the speech to digital converter which concerns on 3rd Embodiment. It is a figure which shows the structure of the 2nd modification 22 B of the speech to speech encoding apparatus which concerns on 3rd Embodiment. It is a flowchart which shows the operation | movement of the 1st modification 22 B of the speech to digital converter which concerns on 3rd Embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 13 which concerns on 4th Embodiment. It is a flowchart which shows operation | movement of the audio | voice decoding apparatus 13 which concerns on 4th Embodiment. It is a figure which shows the structure of the speech coding apparatus 23 which concerns on 4th Embodiment. It is a flowchart which shows operation | movement of the speech coding apparatus 23 which concerns on 4th Embodiment. It is a figure which shows the structure of the 1st modification 13A of the speech decoding apparatus which concerns on 4th Embodiment. [Fig. 28] It is a flow chart showing the operation of the first modification 13A of the speech decoding device according to a 4th embodiment. It is a figure which shows the structure of the 2nd modification 13 B of the speech decoding apparatus which concerns on 4th Embodiment. It is a figure which shows the structure of the 3rd modification 13C of the speech decoding apparatus which concerns on 4th Embodiment. It is a figure which shows the structure of the 1st modification 23A of the speech coding apparatus which concerns on 4th Embodiment. [Fig. 28] It is a flow chart showing the operation of the first modification 23A of the speech to digital converter according to a 4th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 14 which concerns on 5th Embodiment. It is a flowchart which shows operation | movement of the audio | voice decoding apparatus 14 which concerns on 5th Embodiment. It is a figure which shows the structure of the speech coding apparatus 24 which concerns on 5th Embodiment. It is a flowchart which shows operation | movement of the speech coding apparatus 24 which concerns on 5th Embodiment. It is a figure which shows the structure of the 1st modification 14A of the speech decoding apparatus which concerns on 5th Embodiment. [Fig. 68] It is a flow chart showing the operation of the first modification 14A of the speech decoding device according to a 5th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 15 which concerns on 6th Embodiment. It is a flowchart which shows operation | movement of the audio | voice decoding apparatus 15 which concerns on 6th Embodiment. It is a figure which shows the structure of the speech coding apparatus 25 which concerns on 6th Embodiment. It is a flow chart which shows operation of speech coding unit 25 concerning a 6th embodiment. It is a figure which shows the structure of the 1st modification 15A of the speech decoding apparatus which concerns on 6th Embodiment. [Fig. 68] It is a flow chart showing the operation of the first modification 15A of the speech decoding device according to a sixth embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 16 which concerns on 7th Embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 7th Embodiment. It is a figure which shows the structure of the speech coding apparatus 26 which concerns on 7th Embodiment. It is a flowchart which shows operation | movement of the speech to digital converter 26 concerning 7th Embodiment. It is a figure which shows the structure of the 1st modification 16A of the speech decoding apparatus based on 7th Embodiment. [Fig. 132] It is a flow chart showing the operation of the first modification 16A of the speech decoding device according to a 7th embodiment. [Fig. 28] It is a figure showing the configuration of the first modification 26A of the speech to digital converter according to a seventh embodiment. [Fig. 68] It is a flow chart showing the operation of the first modification 26A of the speech to digital converter according to a seventh embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 17 which concerns on 8th Embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 8th Embodiment. It is a figure which shows the structure of the speech coding apparatus 27 which concerns on 8th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech to digital converter 27 according to an eighth embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 18 which concerns on 9th Embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 9th Embodiment. It is a figure which shows the structure of the speech coding apparatus 28 which concerns on 9th Embodiment. It is a flow chart which shows operation of speech coding unit 28 concerning a 9th embodiment. It is a figure which shows the structure of the 1st modification 18A of the speech decoding apparatus which concerns on 9th Embodiment. [Fig. 156] It is a flow chart showing the operation of the first modification 18A of the speech decoding device according to a ninth embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 1 which concerns on 10th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech decoding device according to a 10th embodiment. It is a figure which shows the structure of the speech coding apparatus 2 which concerns on 10th Embodiment. [Fig. 34] It is a flow chart showing the operation of the speech to digital converter 2 according to a 10th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 100 concerning 11th Embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 11th Embodiment. It is a figure which shows the structure of the speech coding apparatus 200 which concerns on 11th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech to digital converter 200 according to an 11th embodiment. It is a figure showing the composition of the 1st modification 100A of the speech decoding device concerning an 11th embodiment. [Fig. 132] It is a flow chart showing the operation of the first modification 100A of the speech decoding device according to an 11th embodiment. [Fig. 102] It is a figure showing the configuration of the first modification 100A of the speech to digital converter according to an 11th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 110 which concerns on 12th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech decoding device according to a 12th embodiment. It is a figure which shows the structure of the speech coding apparatus 210 which concerns on 12th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech to digital converter 210 according to a 12th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 120 which concerns on 13th Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device 120 according to a 13th embodiment. It is a figure which shows the structure of the speech coding apparatus 220 which concerns on 13th Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech to digital converter 220 according to a 13th embodiment. [Fig. 126] It is a figure showing the configuration of the first modification 120A of the speech decoding device according to a 13th embodiment. [Fig. 328] It is a flow chart showing the operation of the first modification 120A of the speech decoding device according to a 13th embodiment. [Fig. 34] It is a figure showing the configuration of the second modification 120B of the speech decoding device according to a 13th embodiment. [Fig. 328] It is a flow chart showing the operation of the second modification 120B of the speech decoding device according to a 13th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 130 which concerns on 14th Embodiment. [Fig. 126] It is a flow chart showing the operation of the speech decoding device according to a 14th embodiment. It is a figure which shows the structure of the speech coding apparatus 230 which concerns on 14th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech to digital converter 230 according to a 14th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 140 which concerns on 15th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech decoding device according to a 15th embodiment. It is a figure which shows the structure of the speech coding apparatus 240 which concerns on 15th Embodiment. [Fig. 68] It is a flow chart showing the operation of a speech to digital converter 240 according to a 15th embodiment. FIG. 54 is a diagram showing the configuration of the first modification 140A of the speech decoding device according to the fifteenth embodiment. [Fig. 316] It is a flow chart showing the operation of the first modification 140A of the speech decoding device according to a 15th embodiment. It is a figure which shows the structure of the 2nd modification 140 B of the speech decoding apparatus which concerns on 15th Embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 150 which concerns on 16th Embodiment. [Fig. 166] It is a flow chart showing the operation of the speech decoding device according to a 16th embodiment. It is a figure which shows the structure of the speech coding apparatus 250 which concerns on 16th Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech to digital converter 250 concerning a 16th embodiment. [Fig. 160] It is a figure showing the configuration of the first modification 150A of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a flow chart showing the operation of the first modification 150A of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a figure showing the configuration of the second modification 150B of the speech decoding device according to a 16th embodiment. It is a figure showing the composition of the speech decoding device 160 concerning a 17th embodiment. [Fig. 172] It is a flow chart showing the operation of the speech decoding device according to a 17th embodiment. It is a figure which shows the structure of the speech coding apparatus 260 which concerns on 17th Embodiment. [Fig. 68] It is a flow chart showing the operation of a speech to digital converter 260 according to a 17th embodiment. [Fig. 160] It is a figure showing the configuration of the first modification 160A of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the first modification 160A of the speech decoding device according to a 17th embodiment. It is a figure which shows the structure of the 2nd modification 160 B of the speech decoding apparatus based on 17th Embodiment. It is a figure which shows the structure of the speech decoding apparatus 170 which concerns on 18th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech decoding device according to an 18th embodiment. It is a figure which shows the structure of the speech coding apparatus 270 which concerns on 18th Embodiment. [Fig. 68] It is a flow chart showing the operation of the speech to digital converter 270 according to an 18th embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 180 which concerns on 19th Embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 19th Embodiment. It is a figure which shows the structure of the speech coding apparatus 280 which concerns on 19th Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech to digital converter 280 according to a 19th embodiment. It is a figure showing the composition of the speech decoding device 190 concerning a twentieth embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 20th Embodiment. It is a figure which shows the structure of the speech coding apparatus 290 which concerns on 20th Embodiment. [Fig. 28] It is a flow chart showing the operation of a speech to digital converter 290 according to a twentieth embodiment. It is a figure which shows the structure of the audio | voice decoding apparatus 300 which concerns on 21st Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device according to a 21st embodiment. It is a figure which shows the structure of the speech coding apparatus 400 which concerns on 21st Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech to digital converter 400 according to a 21st embodiment. It is a figure showing the composition of the speech decoding device 310 concerning a 22nd embodiment. [Fig. 222] It is a flow chart showing the operation of the speech decoding device according to a 22nd embodiment. It is a figure which shows the structure of the speech coding apparatus 410 which concerns on 22nd Embodiment. It is a flowchart which shows operation | movement of the speech coding apparatus 410 based on 22nd Embodiment. It is a figure showing the composition of the speech decoding device 320 concerning a 23rd embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device according to a 23rd embodiment. It is a figure which shows the structure of the speech coding apparatus 420 which concerns on 23rd Embodiment. [Fig. 28] It is a flow chart showing the operation of a speech to digital converter 420 according to a 23rd embodiment. [Fig. 284] This is a figure showing the configuration of the speech decoding device 320A according to the first modification of the twenty-third embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device 320A according to a first modification of the twenty-third embodiment. It is a figure showing the composition of the speech decoding device 330 concerning a 24th embodiment. It is a flowchart which shows operation | movement of the speech decoding apparatus based on 24th Embodiment. It is a figure which shows the structure of the speech coding apparatus 430 which concerns on 24th Embodiment. [Fig. 28] It is a flow chart showing the operation of a speech to digital converter 430 according to a 24th embodiment. It is a figure showing the composition of the speech decoding device 340 concerning a 25th embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device according to a 25th embodiment. It is a figure showing the composition of the speech to digital converter 440 concerning a 25th embodiment. [Fig. 28] It is a flow chart showing the operation of a speech to digital converter 440 according to a 25th embodiment. It is a figure showing the composition of the speech decoding device 350 concerning a 26th embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device according to a 26th embodiment. It is a figure showing the composition of the speech to digital converter 450 concerning a 26th embodiment. [Fig. 68] It is a flow chart showing the operation of a speech to digital converter 450 according to a 26th embodiment. It is a figure showing the composition of the speech decoding device 350A concerning the 1st modification of a 26th embodiment. [Fig. 260] It is a flow chart showing the operation of the speech decoding device 350A according to a first modification of the twenty-sixth embodiment. It is a figure which shows the structure of the 2nd modification 16 B of the speech decoding apparatus which concerns on 7th Embodiment. [Fig. 132] It is a flow chart showing the operation of the second modification 16B of the speech decoding device according to a 7th embodiment. It is a figure which shows the structure of the 3rd modification 16 C of the speech decoding apparatus which concerns on 7th Embodiment. [Fig. 160] It is a flow chart showing the operation of the 3rd modification 16C of the speech decoding device according to a 7th embodiment. It is a figure which shows the structure of 4th modification 16D of the speech decoding apparatus based on 7th Embodiment. [Fig. 126] It is a flow chart showing the operation of the 4th modification 16D of the speech decoding device according to a 7th embodiment. It is a figure which shows the structure of the 5th modification 16E of the speech decoding apparatus which concerns on 7th Embodiment. [Fig. 156] It is a flow chart showing the operation of the fifth modification 16E of the speech decoding device according to a seventh embodiment. FIG. 33 is a diagram showing the configuration of the first modification 17A of the speech decoding device according to the eighth embodiment. [Fig. 174] It is a flow chart showing the operation of the first modification 17A of the speech decoding device according to an 8th embodiment. It is a figure which shows the structure of the 2nd modification 17 B of the speech decoding apparatus which concerns on 8th Embodiment. [Fig. 28] It is a flow chart showing the operation of the second modification 17B of the speech decoding device according to an 8th embodiment. It is a figure which shows the structure of the 3rd modification 17 C of the speech decoding apparatus which concerns on 8th Embodiment. [Fig. 174] It is a flow chart showing the operation of the 3rd modification 17C of the speech decoding device according to an 8th embodiment. It is a figure which shows the structure of 4th modification 17 D of the speech decoding apparatus which concerns on 8th Embodiment. [Fig. 174] It is a flow chart showing the operation of the 4th modification 17D of the speech decoding device according to an 8th embodiment. It is a figure which shows the structure of the 2nd modification 18 B of the speech decoding apparatus based on 9th Embodiment. [Fig. 156] It is a flow chart showing the operation of the second modification 18B of the speech decoding device according to a ninth embodiment. It is a figure which shows the structure of the 3rd modification 18C of the speech decoding apparatus which concerns on 9th Embodiment. [Fig. 186] It is a flow chart showing the operation of the 3rd modification 18C of the speech decoding device according to a 9th embodiment. It is a figure which shows the structure of 4th modification 18D of the speech decoding apparatus which concerns on 9th Embodiment. [Fig. 174] It is a flow chart showing the operation of the 4th modification 18D of the speech decoding device according to a 9th embodiment. It is a figure which shows the structure of the 5th modification 18E of the speech decoding apparatus which concerns on 9th Embodiment. [Fig. 156] It is a flow chart showing the operation of the 5th modification 18E of the speech decoding device according to a 9th embodiment. It is a figure which shows the structure of the 6th modification 18F of the speech decoding apparatus which concerns on 9th Embodiment. [Fig. 156] It is a flow chart showing the operation of the sixth modification 18F of the speech decoding device according to a ninth embodiment. It is a figure which shows the structure of the 7th modification 18 G of the speech decoding apparatus which concerns on 9th Embodiment. [Fig. 174] It is a flow chart showing the operation of the seventh modification 18G of the speech decoding device according to a 9th embodiment. It is a figure showing the configuration of the eighth modification 18H of the speech decoding device according to the ninth embodiment. [Fig. 174] It is a flow chart showing the operation of the eighth modification 18H of the speech decoding device according to a ninth embodiment. [Fig. 160] It is a figure showing the configuration of the ninth modification 18I of the speech decoding device according to a 9th embodiment. [Fig. 186] It is a flow chart showing the operation of the ninth modification 18I of the speech decoding device according to a 9th embodiment. [Fig. 130] It is a figure showing the configuration of the third modification 120C of the speech decoding device according to a 13th embodiment. [Fig. 328] It is a flow chart showing the operation of the 3rd modification 120C of the speech decoding device according to a 13th embodiment. It is a figure which shows the structure of 4th modification 120 D of the speech decoding apparatus which concerns on 13th Embodiment. [Fig. 316] It is a flow chart showing the operation of the 4th modification 120D of the speech decoding device according to a 13th embodiment. [Fig. 126] It is a figure showing the configuration of the fifth modification 120E of the speech decoding device according to a 13th embodiment. [Fig. 328] It is a flow chart showing the operation of the fifth modification 120E of the speech decoding device according to a 13th embodiment. [Fig. 160] It is a figure showing the configuration of the sixth modification 120F of the speech decoding device according to a 13th embodiment. [Fig. 316] It is a flow chart showing the operation of the sixth modification 120F of the speech decoding device according to a 13th embodiment. [Fig. 130] It is a figure showing the configuration of the seventh modification 120G of the speech decoding device according to a 13th embodiment. [Fig. 316] It is a flow chart showing the operation of the seventh modification 120G of the speech decoding device according to a 13th embodiment. [Fig. 160] It is a figure showing the configuration of the eighth modification 120H of the speech decoding device according to a 13th embodiment. [Fig. 316] It is a flow chart showing the operation of the eighth modification 120H of the speech decoding device according to a 13th embodiment. [Fig. 160] It is a figure showing the configuration of the ninth modification 1201 of the speech decoding device according to a 13th embodiment. [Fig. 328] It is a flow chart showing the operation of the ninth modification 1201 of the speech decoding device according to a 13th embodiment. [Fig. 160] It is a figure showing the configuration of the 10th modification 120J of the speech decoding device according to a 13th embodiment. [Fig. 246] It is a flow chart showing the operation of the 10th modification 120J of the speech decoding device according to a 13th embodiment. [Fig. 120] It is a figure showing the configuration of the eleventh modification 120K of the speech decoding device according to a 13th embodiment. [Fig. 328] It is a flow chart showing the operation of the eleventh modification 120K of the speech decoding device according to a 13th embodiment. [Fig. 120] It is a figure showing the configuration of the twelfth modification 120L of the speech decoding device according to a 13th embodiment. [Fig. 316] It is a flow chart showing the operation of the twelfth modification 120L of the speech decoding device according to a 13th embodiment. It is a figure which shows the structure of the 13th modification 120 M of the speech decoding apparatus which concerns on 13th Embodiment. [Fig. 316] It is a flow chart showing the operation of the 13th modification 120M of the speech decoding device according to a 13th embodiment. [Fig. 160] It is a figure showing the configuration of the 14th modification 120N of the speech decoding device according to a 13th embodiment. [Fig. 246] It is a flow chart showing the operation of the 14th modification 120N of the speech decoding device according to a 13th embodiment. It is a figure which shows the structure of the 3rd modification 140C of the speech decoding apparatus which concerns on 15th Embodiment. [Fig. 316] It is a flow chart showing the operation of the 3rd modification 140C of the speech decoding device according to a 15th embodiment. It is a figure which shows the structure of 4th modification 140D of the audio | voice decoding apparatus concerning 15th Embodiment. [Fig. 316] It is a flow chart showing the operation of the 4th modification 140D of the speech decoding device according to a 15th embodiment. It is a figure which shows the structure of the 5th modification 140E of the speech decoding apparatus based on 15th Embodiment. [Fig. 316] It is a flow chart showing the operation of the fifth modification 140E of the speech decoding device according to a 15th embodiment. [Fig. 160] It is a figure showing the configuration of the sixth modification 140F of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a flow chart showing the operation of the sixth modification 140F of the speech decoding device according to a 15th embodiment. It is a figure which shows the structure of the 7th modification 140 G of the speech decoding apparatus which concerns on 15th Embodiment. [Fig. 156] It is a flow chart showing the operation of the seventh modification 140G of the speech decoding device according to a 15th embodiment. [Fig. 284] This is a figure showing the configuration of the eighth modification 140H of the speech decoding device according to a fifteenth embodiment. [Fig. 316] It is a flow chart showing the operation of the eighth modification 140H of the speech decoding device according to a 15th embodiment. [Fig. 160] It is a figure showing the configuration of the ninth modification 140I of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a flow chart showing the operation of the ninth modification 1401 of the speech decoding device according to a 15th embodiment. [Fig. 160] It is a figure showing the configuration of the 10th modification 140J of the speech decoding device according to a 15th embodiment. [Fig. 246] It is a flow chart showing the operation of the 10th modification 140J of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a figure showing the configuration of the eleventh modification 140K of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a flow chart showing the operation of the eleventh modification 140K of the speech decoding device according to a 15th embodiment. [Fig. 126] It is a figure showing the configuration of the 12th modification 140L of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a flow chart showing the operation of the twelfth modification 140L of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a figure showing the configuration of the 13th modification 140M of the speech decoding device according to a 15th embodiment. [Fig. 316] It is a flow chart showing the operation of the 13th modification 140M of the speech decoding device according to a 15th embodiment. [Fig. 160] It is a figure showing the configuration of the 14th modification 140N of the speech decoding device according to a 15th embodiment. [Fig. 246] It is a flow chart showing the operation of the 14th modification 140N of the speech decoding device according to a 15th embodiment. [Fig. 160] It is a figure showing the configuration of the third modification 150C of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the 3rd modification 150C of the speech decoding device according to a 16th embodiment. It is a figure which shows the structure of 4th modification 150D of the speech decoding apparatus based on 16th Embodiment. [Fig. 166] It is a flow chart showing the operation of the 4th modification 150D of the speech decoding device according to a 16th embodiment. It is a figure which shows the structure of the 5th modification 150E of the speech decoding apparatus which concerns on 16th Embodiment. [Fig. 316] It is a flow chart showing the operation of the fifth modification 150E of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a figure showing the configuration of the sixth modification 150F of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the sixth modification 150F of the speech decoding device according to a 16th embodiment. It is a figure which shows the structure of the 7th modification 150 G of the speech decoding apparatus which concerns on 16th Embodiment. [Fig. 156] It is a flow chart showing the operation of the seventh modification 150G of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a figure showing the configuration of the eighth modification 150H of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the eighth modification 150H of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a figure showing the configuration of the ninth modification 150I of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the ninth modification 1501 of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a figure showing the configuration of the tenth modification 150J of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a flow chart showing the operation of the 10th modification 150J of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a figure showing the configuration of the eleventh modification 150K of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the eleventh modification 150K of the speech decoding device according to a 16th embodiment. [Fig. 126] It is a figure showing the configuration of the twelfth modification 150L of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the twelfth modification 150L of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a figure showing the configuration of the 13th modification 150M of the speech decoding device according to a 16th embodiment. [Fig. 316] It is a flow chart showing the operation of the 13th modification 150M of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a figure showing the configuration of the 14th modification 150N of the speech decoding device according to a 16th embodiment. [Fig. 160] It is a flow chart showing the operation of the 14th modification 150N of the speech decoding device according to a 16th embodiment. [Fig. 166] It is a figure showing the configuration of the third modification 160C of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the 3rd modification 160C of the speech decoding device according to a 17th embodiment. It is a figure which shows the structure of 4th modification 160D of the speech decoding apparatus based on 17th Embodiment. [Fig. 174] It is a flow chart showing the operation of the 4th modification 160D of the speech decoding device according to a 17th embodiment. It is a figure which shows the structure of the 5th modification 160 E of the speech decoding apparatus which concerns on 17th Embodiment. [Fig. 174] It is a flow chart showing the operation of the fifth modification 160E of the speech decoding device according to a 17th embodiment. [Fig. 160] It is a figure showing the configuration of the sixth modification 160F of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the sixth modification 160F of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a figure showing the configuration of the seventh modification 160G of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the seventh modification 160G of the speech decoding device according to a 17th embodiment. [Fig. 166] It is a figure showing the configuration of the eighth modification 160H of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the eighth modification 160H of the speech decoding device according to a 17th embodiment. [Fig. 160] It is a figure showing the configuration of the ninth modification 160I of the speech decoding device according to a 17th embodiment. [Fig. 160] It is a flow chart showing the operation of the ninth modification 1601 of the speech decoding device according to a 17th embodiment. [Fig. 160] It is a figure showing the configuration of the tenth modification 160J of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the tenth modification 160J of the speech decoding device according to a 17th embodiment. It is a figure which shows the structure of the 11th modification 160 K of the speech decoding apparatus based on 17th Embodiment. [Fig. 174] It is a flow chart showing the operation of the eleventh modification 160K of the speech decoding device according to a 17th embodiment. It is a figure which shows the structure of the 12th modification 160L of the speech decoding apparatus based on 17th Embodiment. [Fig. 270] It is a flow chart showing the operation of the twelfth modification 160L of the speech decoding device according to a 17th embodiment. [Fig. 160] It is a figure showing the configuration of the thirteenth modification 160M of the speech decoding device according to a 17th embodiment. [Fig. 328] It is a flow chart showing the operation of the 13th modification 160M of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a figure showing the configuration of the 14th modification 160N of the speech decoding device according to a 17th embodiment. [Fig. 174] It is a flow chart showing the operation of the 14th modification 160N of the speech decoding device according to a 17th embodiment. [Fig. 160] It is a figure showing the configuration of the first modification 170A of the speech decoding device according to an 18th embodiment. [Fig. 186] It is a flow chart showing the operation of the first modification 170A of the speech decoding device according to an 18th embodiment. [Fig. 174] It is a figure showing the configuration of the second modification 170B of the speech decoding device according to an 18th embodiment. [Fig. 186] It is a flow chart showing the operation of the second modification 170B of the speech decoding device according to an 18th embodiment. [Fig. 166] It is a figure showing the configuration of the third modification 170C of the speech decoding device according to an 18th embodiment. [Fig. 186] It is a flow chart showing the operation of the 3rd modification 170C of the speech decoding device according to an 18th embodiment. It is a figure which shows the structure of 4th modification 170D of the speech decoding apparatus based on 18th Embodiment. [Fig. 186] It is a flow chart showing the operation of the 4th modification 170D of the speech decoding device according to an 18th embodiment. [Fig. 202] It is a figure showing the configuration of the first modification 180A of the speech decoding device according to a 19th embodiment. [Fig. 190] It is a flow chart showing the operation of the first modification 180A of the speech decoding device according to a 19th embodiment. It is a figure which shows the structure of the 2nd modification 180 B of the speech decoding apparatus based on 19th Embodiment. [Fig. 246] It is a flow chart showing the operation of the second modification 180B of the speech decoding device according to a 19th embodiment. It is a figure showing the configuration of the third modification 180C of the speech decoding device according to a nineteenth embodiment. [Fig. 190] It is a flow chart showing the operation of the 3rd modification 180C of the speech decoding device according to a 19th embodiment. It is a figure which shows the structure of 4th modification 180 D of the audio | voice decoding apparatus based on 19th Embodiment. [Fig. 246] It is a flow chart showing the operation of the 4th modification 180D of the speech decoding device according to a 19th embodiment. FIG. 55 is a diagram showing the configuration of the first modification 190A of the speech decoding device according to the twentieth embodiment. [Fig. 202] It is a flow chart showing the operation of the first modification 190A of the speech decoding device according to a twentieth embodiment. It is a figure which shows the structure of the 2nd modification 190 B of the speech decoding apparatus based on 20th Embodiment. [Fig. 246] It is a flow chart showing the operation of the second modification 190B of the speech decoding device according to a twentieth embodiment. It is a figure showing the configuration of the third modification 190C of the speech decoding device according to the twentieth embodiment. [Fig. 190] It is a flow chart showing the operation of the 3rd modification 190C of the speech decoding device according to a twentieth embodiment. It is a figure showing the configuration of the fourth modification 190D of the speech decoding device according to the twentieth embodiment. [Fig. 292] It is a flow chart showing the operation of the 4th modification 190D of the speech decoding device according to a twentieth embodiment. FIG. 55 is a diagram showing the configuration of the fifth modification 190E of the speech decoding device according to the twentieth embodiment. [Fig. 186] It is a flow chart showing the operation of the fifth modification 190E of the speech decoding device according to a twentieth embodiment. FIG. 55 is a diagram showing a configuration of a sixth modified example 190F of the speech decoding device according to the twentieth embodiment. [Fig. 292] It is a flow chart showing the operation of the sixth modification 190F of the speech decoding device according to a twentieth embodiment. It is a figure showing the configuration of the seventh modification 190G of the speech decoding device according to the twentieth embodiment. [Fig. 270] It is a flow chart showing the operation of the seventh modification 190G of the speech decoding device according to a twentieth embodiment. It is a figure showing the configuration of the eighth modification 190H of the speech decoding device according to the twentieth embodiment. [Fig. 186] It is a flow chart showing the operation of the eighth modification 190H of the speech decoding device according to a twentieth embodiment. [Fig. 160] It is a figure showing the configuration of the ninth modification 190I of the speech decoding device according to a twentieth embodiment. [Fig. 190] It is a flow chart showing the operation of the ninth modification 1901 of the speech decoding device according to a twentieth embodiment. FIG. 54 is a diagram showing a configuration of a first modified example 300A of the speech decoding device according to a twenty-first embodiment. [Fig. 260] It is a flow chart showing the operation of the first modification 300A of the speech decoding device according to a 21st embodiment. [Fig. 28] It is a figure showing the configuration of the second modification 300B of the speech decoding device according to a 21st embodiment. [Fig. 260] It is a flow chart showing the operation of the second modification 300B of the speech decoding device according to a 21st embodiment. [Fig. 28] It is a figure showing the configuration of the third modification 300C of the speech decoding device according to a 21st embodiment. [Fig. 328] It is a flow chart showing the operation of the 3rd modification 300C of the speech decoding device according to a 21st embodiment. It is a figure which shows the structure of 4th modification 300D of the audio | voice decoding apparatus based on 21st Embodiment. [Fig. 260] It is a flow chart showing the operation of the 4th modification 300D of the speech decoding device according to a 21st embodiment. [Fig. 28] It is a figure showing the configuration of the first modification 310A of the speech decoding device according to a 22nd embodiment. [Fig. 292] It is a flow chart showing the operation of the first modification 310A of the speech decoding device according to a 22nd embodiment. [Fig. 292] It is a figure showing the configuration of the second modification 310B of the speech decoding device according to a 22nd embodiment. [Fig. 292] It is a flow chart showing the operation of the second modification 310B of the speech decoding device according to a 22nd embodiment. It is a figure which shows the structure of the 3rd modification 310 C of the speech decoding apparatus which concerns on 22nd Embodiment. [Fig. 260] It is a flow chart showing the operation of the 3rd modification 310C of the speech decoding device according to a 22nd embodiment. It is a figure which shows the structure of 4th modification 310 D of the speech decoding apparatus based on 22nd Embodiment. [Fig. 260] It is a flow chart showing the operation of the fourth modification 310D of the speech decoding device according to a 22nd embodiment. [Fig. 28] It is a figure showing the configuration of the second modification 320B of the speech decoding device according to a 23 rd embodiment. [Fig. 246] It is a flow chart showing the operation of the second modification 320B of the speech decoding device according to a 23rd embodiment. [Fig. 34] It is a figure showing the configuration of the third modification 320C of the speech decoding device according to a 23rd embodiment. [Fig. 328] It is a flow chart showing the operation of the 3rd modification 320C of the speech decoding device according to a 23rd embodiment. [Fig. 34] It is a figure showing the configuration of the fourth modification 320D of the speech decoding device according to a 23rd embodiment. [Fig. 246] It is a flow chart showing the operation of the 4th modification 320D of the speech decoding device according to a 23rd embodiment. [Fig. 284] This is a figure showing the configuration of the fifth modification 320E of the speech decoding device according to a twenty-third embodiment. [Fig. 246] It is a flow chart showing the operation of the fifth modification 320E of the speech decoding device according to a 23rd embodiment. [Fig. 284] This is a figure showing the configuration of the sixth modification 320F of the speech decoding device according to a twenty-third embodiment. [Fig. 246] It is a flow chart showing the operation of the sixth modification 320F of the speech decoding device according to a 23rd embodiment. [Fig. 268] This is a figure showing the configuration of the seventh modification 320G of the speech decoding device according to a twenty-third embodiment. [Fig. 246] It is a flow chart showing the operation of the seventh modification 320G of the speech decoding device according to a 23rd embodiment. [Fig. 284] This is a figure showing the configuration of the eighth modification 320H of the speech decoding device according to a twenty-third embodiment. [Fig. 246] It is a flow chart showing the operation of the eighth modification 320H of the speech decoding device according to a 23rd embodiment. [Fig. 292] It is a figure showing the configuration of the ninth modification 320I of the speech decoding device according to a 23rd embodiment. [Fig. 292] It is a flow chart showing the operation of the ninth modification 3201 of the speech decoding device according to a 23rd embodiment. [Fig. 28] It is a figure showing the configuration of the first modification 330A of the speech decoding device according to a 24th embodiment. [Fig. 246] It is a flow chart showing the operation of the first modification 330A of the speech decoding device according to a 24th embodiment. [Fig. 28] It is a figure showing the configuration of the second modification 330B of the speech decoding device according to a 24th embodiment. [Fig. 246] It is a flow chart showing the operation of the second modification 330B of the speech decoding device according to a 24th embodiment. [Fig. 284] This is a figure showing the configuration of the third modification 330C of the speech decoding device according to a twenty-fourth embodiment. [Fig. 328] It is a flow chart showing the operation of the 3rd modification 330C of the speech decoding device according to a 24th embodiment. It is a figure which shows the structure of 4th modification 330D of the speech decoding apparatus which concerns on 24th Embodiment. [Fig. 324] It is a flow chart showing the operation of the 4th modification 330D of the speech decoding device according to a 24th embodiment. [Fig. 28] It is a figure showing the configuration of the first modification 340A of the speech decoding device according to a 25th embodiment. [Fig. 292] It is a flow chart showing the operation of the first modification 340A of the speech decoding device according to a 25th embodiment. It is a figure which shows the structure of the 2nd modification 340 B of the audio | voice decoding apparatus based on 25th Embodiment. [Fig. 292] It is a flow chart showing the operation of the second modification 340B of the speech decoding device according to a 25th embodiment. It is a figure showing the configuration of the third modification 340C of the speech decoding device according to a twenty-fifth embodiment. [Fig. 328] It is a flow chart showing the operation of the 3rd modification 340C of the speech decoding device according to a 25th embodiment. It is a figure which shows the structure of 4th modification 340D of the audio | voice decoding apparatus based on 25th Embodiment. [Fig. 246] It is a flow chart showing the operation of the 4th modification 340D of the speech decoding device according to a 25th embodiment. It is a figure which shows the structure of the 2nd modification 350 B of the audio | voice decoding apparatus based on 26th Embodiment. [Fig. 260] It is a flow chart showing the operation of the second modification 350B of the speech decoding device according to a 26th embodiment. It is a figure which shows the structure of the 3rd modification 350 C of the speech decoding apparatus based on 26th Embodiment. [Fig. 328] It is a flow chart showing the operation of the 3rd modification 350C of the speech decoding device according to a 26th embodiment. It is a figure which shows the structure of 4th modification 350D of the audio | voice decoding apparatus based on 26th Embodiment. [Fig. 246] It is a flow chart showing the operation of the 4th modification 350D of the speech decoding device according to a 26th embodiment. [Fig. 260] It is a figure showing the configuration of the fifth modification 350E of the speech decoding device according to a 26th embodiment. [Fig. 246] It is a flow chart showing the operation of the fifth modification 350E of the speech decoding device according to a 26th embodiment. It is a figure showing the configuration of the sixth modification 350F of the speech decoding device according to a 26th embodiment. [Fig. 292] It is a flow chart showing the operation of the sixth modification 350F of the speech decoding device according to a 26th embodiment. It is a figure which shows the structure of the 7th modification 350 G of the audio | voice decoding apparatus based on 26th Embodiment. [Fig. 246] It is a flow chart showing the operation of the seventh modification 350G of the speech decoding device according to a 26th embodiment. It is a figure which shows the structure of the 8th modification 350 H of the audio | voice decoding apparatus based on 26th Embodiment. [Fig. 246] It is a flow chart showing the operation of the eighth modification 350H of the speech decoding device according to a 26th embodiment. It is a figure showing the configuration of the ninth modification 3501 of the speech decoding device according to the twenty-sixth embodiment. [Fig. 292] It is a flow chart showing the operation of the ninth modification 3501 of the speech decoding device according to a 26th embodiment. It is a figure showing the composition of the speech decoding device 360 concerning a 27th embodiment. [Fig. 27] It is a flow chart showing the operation of the speech decoding device 360 according to a 27th embodiment. [Fig. 28] It is a figure showing the configuration of the first modification 360A of the speech decoding device according to a 27th embodiment. [Fig. 270] It is a flow chart showing the operation of the first modification 360A of the speech decoding device according to a 27th embodiment. It is a figure which shows the structure of the speech decoding apparatus 370 which concerns on 28th Embodiment. [Fig. 28] It is a flow chart showing the operation of the speech decoding device 370 according to a 28th embodiment. [Fig. 28] It is a figure showing the configuration of the first modification 370A of the speech decoding device according to a 28th embodiment. [Fig. 328] It is a flow chart showing the operation of the first modification 370A of the speech decoding device according to a 28th embodiment. It is a figure showing the composition of the speech decoding device 380 concerning a 29th embodiment. [Fig. 292] It is a flow chart showing the operation of the speech decoding device 380 according to a 29th embodiment. [Fig. 292] It is a figure showing the configuration of the first modification 380A of the speech decoding device according to a 29th embodiment. [Fig. 292] It is a flow chart showing the operation of the first modification 380A of the speech decoding device according to a 29th embodiment. [Fig. 28] It is a figure showing the configuration of the speech decoding device 390 according to a thirtieth embodiment. [Fig. 292] It is a flow chart showing the operation of the speech decoding device 390 according to a thirtieth embodiment.

  Various embodiments of the present invention will be described with reference to the accompanying drawings. Where possible, the same parts will be denoted by the same reference symbols, without redundant description.

First Embodiment
FIG. 1 is a diagram showing the configuration of the speech decoding apparatus 10 according to the first embodiment. The communication device of the speech decoding device 10 receives the multiplexed coded sequence output from the speech coding device 20 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 1, the speech decoding apparatus 10 functionally includes a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 10d, and a low frequency time envelope shape. A determination unit 10e, a low frequency time envelope correction unit 10f, a high frequency signal generation unit 10g, a decoding / inverse quantization unit 10h, a frequency envelope adjustment unit 10i, and a synthesis filter bank unit 10j. The function and operation of each part will be described below.

  FIG. 2 is a flowchart showing an operation of the speech decoding device 10 according to the first embodiment.

  The coded sequence demultiplexing unit 10a determines a coded sequence as a core coding portion obtained by coding a low frequency signal, a band extension portion for generating a high frequency signal from the low frequency signal, and a low frequency time envelope shape determination. The information is divided into information necessary for the part 10e (information related to the low frequency time envelope shape) (step S10-1).

  The coded sequence analysis unit 10d analyzes the band extension part of the coded sequence divided by the coded sequence demultiplexing unit 10a, and information necessary for the high frequency signal generation unit 10g and the decoding / dequantization unit 10h. (Step S10-2).

  The core decoding unit 10b receives the core coding part of the coding sequence from the coding sequence demultiplexing unit 10a and decodes it to generate a low frequency signal (step S10-3).

  The analysis filter bank unit 10c divides the low frequency signal into a plurality of sub-band signals (step S10-4).

  The low frequency temporal envelope shape determination unit 10e receives the information on the low frequency temporal envelope shape from the coding sequence analysis unit 10d, and determines the temporal envelope shape of the low frequency signal based on the information (step S10-5). For example, the time envelope shape of the low frequency signal is determined to be flat, the time envelope shape of the low frequency signal is determined to be rising, and the time envelope shape of the low frequency signal is determined to be falling.

  The low frequency time envelope correction unit 10 f is based on the time envelope shape determined by the low frequency time envelope shape determination unit 10 e, the shape of the time envelope of a plurality of subband signals of the low frequency signal output from the analysis filter bank unit 10 c. Is corrected (step S10-6).

により得られるX’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として出力する。 For example, the low frequency time envelope correction unit 10 f may set a plurality of sub-band signals X _{dec, LO} (k, i) (0 ≦ k <k _x , t _E (l) ≦ of the low frequency signal in an arbitrary time segment). For i <t _E (l + 1), the following equation (1) is obtained using a predetermined function F (X _{dec, LO} (k, i))

And X ′ _{dec, LO} (k, i) obtained by the above are output as sub-band signals of a low frequency signal whose temporal envelope shape is corrected.

として、X’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として出力する。
また別の例によれば、所定の関数F(X_dec,LO(k,i))を、サブバンド信号X_dec,LO(k,i)に対して平滑化フィルタ処理を施す

(N_filt≧1)で定義して、X’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として出力する。さらに、前記B_dec,LO(m)を用いて境界が表される各周波数帯域内で、フィルタ処理前後のサブバンド信号のパワーをあわせるように処理できる。
また別の例によれば、サブバンド信号X_dec,LO(k,i)を前記B_dec,LO(m)を用いて境界が表される各周波数帯域内で周波数方向に線形予測して線形予測係数α_p(m) (m=0,…,M_LO-1)を得て、所定の関数F(X_dec,LO(k,i))を、サブバンド信号X_dec,LO(k,i)に対して線形予測逆フィルタ処理を施す

(N_pred≧1)で定義して、X’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として出力する。 For example, when the temporal envelope shape of the low frequency signal is determined to be flat, the temporal envelope shape of the low frequency signal can be corrected by the following process.
For example, the sub-band signal X _{dec, LO} (k, i) is B _{dec, LO} (m) (m = 0, ..., M _LO , M _LO 1 1) (B _{dec, LO} (0) 0, 0, B A subband signal X _{dec, LO} (k, i) (B _LO which is divided into M _LO frequency bands represented by _{dec, LO} (M _LO ) <k _x ) and included in the m th frequency band (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)), a predetermined function F (X _{dec, LO} (k, i)) is obtained ,

As, X ′ _{dec, LO} (k, i) is output as a sub-band signal of the low frequency signal whose temporal envelope shape is corrected.
According to another example, the predetermined function F (X _{dec, LO} (k, i)) is subjected to smoothing filter processing on the subband signal X _{dec, LO} (k, i)

As defined by (N _filt 1 1), X ′ _{dec, LO} (k, i) is output as a sub-band signal of a low frequency signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using B _{dec and LO} (m), processing can be performed to match the power of the sub-band signal before and after filtering.
According to another example, the subband signal X _{dec, LO} (k, i) is linearly predicted in the frequency direction within each frequency band where the boundary is expressed using the B _{dec, LO} (m) to be linear. The prediction coefficient α _p (m) (m = 0, ..., M _LO -1) is obtained, and a predetermined function F (X _{dec, LO} (k, i)) is obtained by the subband signal X _{dec, LO} (k, Apply linear predictive inverse filter to i)

As defined by (N _pred 11), X ′ _{dec, LO} (k, i) is output as a sub-band signal of a low frequency signal whose temporal envelope shape is corrected.

  The example of the process which corrects said time envelope shape flatly can be implemented combining each, respectively. The low frequency time envelope correction unit 10 f performs processing for correcting the shape of the time envelope of the plurality of sub band signals of the low frequency signal to be flat, and is not limited to the above example.

で定義して、X’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として出力する。さらに、前記B_dec,LO(m)を用いて境界が表される各周波数帯域内で、時間包絡形状の修正前後のサブバンド信号のパワーをあわせるように処理できる。 Furthermore, for example, when the temporal envelope shape of the low frequency signal is determined to be rising, the temporal envelope shape of the low frequency signal can be corrected by the following processing.
For example, using a function incr (i) that monotonously increases a predetermined function F ( _{X.sub.dec, LO} (k, i)) with respect to i.

And X ′ _{dec, LO} (k, i) is output as a sub-band signal of a low frequency signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using B _{dec and LO} (m), processing can be performed to match the power of the sub-band signal before and after the correction of the time envelope shape.

  The low frequency time envelope correction unit 10 f performs a process of correcting the shape of the time envelope of the plurality of sub band signals of the low frequency signal to rise, and is not limited to the above example.

で定義して、X’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として出力する。さらに、前記B_dec,LO(m)を用いて境界が表される各周波数帯域内で、時間包絡形状の修正前後のサブバンド信号のパワーをあわせるように処理できる。 Furthermore, for example, when the temporal envelope shape of the low frequency signal is determined to be falling, the temporal envelope shape of the low frequency signal can be corrected by the following processing.
For example, using a function decr (i) which monotonically decreases a predetermined function F (X.sub.dec _{, LO} (k, i)) with respect to i.

And X ′ _{dec, LO} (k, i) is output as a sub-band signal of a low frequency signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using B _{dec and LO} (m), processing can be performed to match the power of the sub-band signal before and after the correction of the time envelope shape.

  The low frequency time envelope correction unit 10 f performs processing to correct the shape of the time envelope of the plurality of sub band signals of the low frequency signal to fall, and is not limited to the above example.

  The decoding / inverse quantization unit 10 h determines the design of the scale factor band and the length of the time segment in the generation / adjustment processing of the high frequency signal from the information of the time / frequency resolution output from the coding sequence analysis unit 10 d Further, information on gain and information on noise signal to be added to the high frequency signal generated by the high frequency signal generation unit 10 g are received from the coding sequence analysis unit 10 d and decoded / dequantized The gain and noise signal magnitude for high frequency signals are acquired (step S10-7). When the design of the scale factor band and the length of the time segment are determined in advance, it is not necessary to determine.

  The high frequency signal generation unit 10 g generates information from the input low frequency signal sub-band signal, output information from the coding sequence analysis unit 10 d, design of scale factor band output from the decoding / inverse quantization unit 10 h, time A high frequency signal is generated based on at least one of the segment lengths (step S10-8). In the present embodiment, the sub-band signal of the low frequency signal divided by the analysis filter bank unit 10 c is input.

  The frequency envelope adjustment unit 10i performs gain adjustment and noise signal generation on the high frequency signal generated by the high frequency signal generation unit 10g based on the gain and noise signal magnitude acquired by the decoding / inverse quantization unit 10h. To adjust the frequency envelope of the high frequency signal (step S10-9). Furthermore, a sine wave signal may be added, and the addition of the sine wave signal may be based on the information included in the band extension part of the coding sequence.

  The synthesis filter bank unit 10 j synthesizes a time signal from the subband signal of the low frequency signal output from the low frequency time envelope correction unit 10 f and the subband signal of the high frequency signal output from the frequency envelope adjustment unit 10 i The output audio signal is output (step S10-10).

  The processes of steps S10-1 to S10-4 and S10-7 to S10-10 can be handled by the processes of “SBR” and “Low Delay SBR” defined in “ISO / IEC 14496-3”.

  FIG. 3 is a diagram showing the configuration of the speech to digital converter 20 according to the first embodiment. The communication device of speech coding apparatus 20 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 3, the speech encoding apparatus 20 functionally includes a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, a control parameter encoding unit 20d, an envelope calculation unit 20e, A quantization / coding unit 20f, a time envelope information coding unit 20g, a coding sequence multiplexing unit 20h, a subband signal power calculation unit 20j, and a core decoded signal generation unit 20i. The function and operation of each part will be described below.

  FIG. 4 is a flowchart showing the operation of the speech to digital converter 20 according to the first embodiment.

  The downsampling unit 20a downsamples the input speech signal to obtain a downsampled input speech signal corresponding to the low frequency signal of the input speech signal (step S20-1).

  The core encoding unit 20b encodes the downsampled signal obtained by the downsampling unit 20a to generate a coded sequence of low frequency signals (step S20-2).

  The analysis filter bank unit 20c divides the input speech signal into a plurality of sub-band signals (step S20-3).

  The control parameter encoding unit 20d encodes control parameters necessary to generate a high frequency signal in the speech decoding apparatus 10 (step S20-4). The parameters include, for example, time / frequency resolution information. For example, it includes the design of a scale factor band in the decoding / inverse quantization unit 10 h of the speech decoding apparatus 10 and information used to determine the length of a time segment.

  The envelope calculation unit 20 e is a gain and noise signal magnitude for high frequency signals decoded / dequantized by the decoding / inverse quantization unit 10 h of the speech decoding device 10 from the subband signals obtained by the analysis filter bank unit 20 c. Is calculated (step S20-5).

  The quantization / coding unit 20 f quantizes and codes the gain and the magnitude of the noise signal for the high frequency signal calculated by the envelope calculation unit 20 e (step S 20-6).

  The core decoded signal generation unit 20i generates a core decoded signal using the information encoded by the core encoding unit 20b (step S20-7). The said process may be implemented similarly to the core decoding part 10b of the audio | voice decoding apparatus 10. FIG. Also, the core decoded signal may be generated using quantized information before being coded in the core coding unit 20b. Further, part of the information may be different from that of the core decoding unit 10b of the speech decoding apparatus 10. For example, in the case of CELP coding, the signal held in the adaptive codebook in the decoding apparatus is an excitation signal decoded in the past or It is a signal that has been subjected to predetermined processing, but the core decoded signal generation unit 20i may be a residual signal after linear prediction of the input speech signal.

  The analysis filter bank unit 20c1 divides the core decoded signal generated by the core decoded signal generation unit 20i into a plurality of sub-band signals (step S20-8). In the processing, the resolution at the time of dividing the core decoded signal into the subband signals may be the same as that of the analysis filter bank unit 20c.

  The subband signal power calculation unit 20j calculates the power of the subband signal of the core decoded signal obtained by the analysis filter bank unit 20c1 (step S20-9). The said process is implemented similarly to calculation of the power of the sub-band signal of the low frequency signal in the envelope calculation part 20e.

  The time envelopment information encoding unit 20g calculates the time envelopment of the low frequency signal using the power of the sub band signal of the low frequency signal calculated by the envelope calculation unit 20 e, and similarly the power of the sub band signal of the core decoded signal The temporal envelope of the core decoded signal is calculated using the above equation, and temporal envelope information is calculated from the temporal envelope of the low frequency signal and the core decoded signal and encoded (step S20-10). In the process, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal may be calculated by the time envelopment information encoding unit 20g. It is not limited where the power of the subband signal is calculated.

同様に、コア復号信号の時間包絡E_dec,LO(k,i)を前記時間セグメント及び周波数帯域内で正規化した当該コア復号信号のサブバンド信号X_dec,LO(k,i)のパワーとして算出できる。

低周波数信号及びコア復号信号のサブバンド信号の時間包絡は、低周波数信号及びコア復号信号のサブバンド信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, B _LO (m) (m = 0,..., M _LO , M _LO 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _LO (0) ≧ Subband signal X _LO (k, i) of a low frequency signal that is divided into M _LO frequency bands, which are bounded by 0, B _LO (M _LO ) <k _x ), and included in the m th frequency band The temporal envelope E _LO (k, i) of (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1) is the time segment and the frequency It can be calculated as the power of the sub-band signal X _LO (k, i) of the low frequency signal normalized in the band.

Similarly, the time envelope E _{dec, LO} (k, i) of the core decoded signal is the power of the sub-band signal X _{dec, LO} (k, i) of the core decoded signal normalized in the time segment and frequency band. It can be calculated.

The temporal envelope of the low frequency signal and the sub-band signal of the core decoding signal may be any parameter that can indicate the temporal variation of the magnitude of the sub-band signal of the low frequency signal and the core decoding signal, and is not limited to the above example.

For example, the temporal envelope information encoding unit 20g calculates information representing a degree of flatness as temporal envelope information. For example, the dispersion of the time envelope of the low frequency signal and the sub-band signal of the core decoded signal or a parameter according to it is calculated. In still another example, the ratio of the arithmetic mean to the geometric mean or the parameter corresponding thereto of the temporal envelope of the low frequency signal and the subband signal of the core decoded signal is calculated. In this case, the time envelope information encoding unit 20g may calculate information indicating the flatness of the time envelope of the sub-band signal of the low frequency signal as the time envelope information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value of the said parameter of a low frequency signal and a core decoding signal or its absolute value is encoded. Furthermore, for example, the value or absolute value of the parameter of the low frequency signal is encoded. For example, if the flatness of the temporal envelope is expressed as flat or not, it can be encoded by one bit, for example, the information is encoded by M _LO bits for each of the M _LO frequency bands in the arbitrary time segment. it can. The encoding method of temporal envelope information is not limited to the above example.

さらには、式（９）において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最大値を算出できる。 Furthermore, for example, the time envelopment information encoding unit 20g calculates information representing the degree of rising as time envelopment information. For example, in any time segment t _E (l) ≦ i <t _E (l + 1), the maximum value of the time-wise difference value of the time envelope of the sub-band signal of the low frequency signal is calculated.

Furthermore, it is possible to calculate the maximum value of the difference value in the time direction of the parameter obtained by smoothing the time envelope in the time direction instead of the time envelope in Expression (9).

In this case, the time envelope information encoding unit 20g may calculate information indicating the degree of rise of the time envelope of the sub-band signal of the low frequency signal as the time envelope information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value of the said parameter of a low frequency signal and a core decoding signal or its absolute value is encoded. For example, if the degree of rising of the time envelopment is expressed by whether it is rising or not, it can be encoded by 1 bit. For example, the information can be encoded by M _LO bits for every M _LO frequency bands in the arbitrary time segment. Can be The encoding method of temporal envelope information is not limited to the above example.

さらには、式（１０）において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最小値を算出できる。 Furthermore, for example, the time envelopment information encoding unit 20g calculates information indicating the degree of fall as time envelopment information. For example, within any time segment t _E (l) ≦ i <t _E (l + 1), the minimum value of the time-wise difference value of the time envelope of the sub-band signal of the low frequency signal is calculated.

Furthermore, in equation (10), it is possible to calculate the minimum value of the difference values in the time direction of parameters obtained by smoothing the time envelope in the time direction instead of the time envelope.

In this case, the time envelope information encoding unit 20g may calculate information indicating the degree of fall of the time envelope of the sub-band signal of the low frequency signal as the time envelope information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value of the said parameter of a low frequency signal and a core decoding signal or its absolute value is encoded. For example, if the degree of falling of the time envelopment is expressed by whether it is falling or not, it can be encoded by one bit, for example, the information may be M _LO bits for every M _LO frequency bands in the arbitrary time segment. Can be encoded with The encoding method of temporal envelope information is not limited to the above example.

  In the example of calculating information representing the degree of flatness, the degree of rise, and the degree of fall as the time envelope information, when only one of the low frequency signal and the time envelope of the core decoded signal is used, the other time is used. Each part and each processing which concern only on calculation of an envelope can be omitted.

  The coded sequence multiplexing unit 20h multiplexes the input one or more coded sequences or the coded information or the coded parameters, and outputs the multiplexed data as a coded sequence (step S20-11). Here, the coded sequence of the low frequency signal is received from the core coding unit 20b, the control parameter coded by the control parameter coding unit 20d is received, and the high frequency signal coded by the quantization / coding unit 20f. And the size of the noise signal, the encoded time envelope information is received from the time envelope information encoding unit 20g, these are multiplexed and output as an encoded sequence.

  The processes of steps S20-1 to S20-6 and S20-80 can be handled by the processes of the "SBR" and "Low Delay SBR" encoders defined in "ISO / IEC 14496-3".

First Modification of Speech Decoding Device According to First Embodiment
FIG. 5 is a diagram showing a configuration of a first modification 10A of the speech decoding device according to the first embodiment. In the following, characteristic functions and operations in the modification and the embodiment will be described, and redundant description will be omitted as much as possible.

  The coding sequence demultiplexing unit 10aA divides the coding sequence into a core coding portion obtained by coding a low frequency signal, and a band extension portion for generating a high frequency signal from the low frequency signal (step S10-1a). ).

  FIG. 6 is a flowchart showing an operation of the first modification 10A of the speech decoding device according to the first embodiment.

  The low frequency temporal envelope shape determination unit 10eA receives the low frequency signal from the core decoding unit 10b, and determines the temporal envelope shape of the low frequency signal (step S10-5a).

For example, the time envelope shape of the low frequency signal is determined to be flat. For example, the power of the low frequency signal x _dec (t) or a parameter according to it is calculated, and the dispersion of the parameter or a parameter according to it is calculated. The calculated parameter is compared with a predetermined threshold to determine whether the temporal envelope shape is flat or not, or the degree of flatness. In yet another example, the power of the low frequency signal x _dec (t) or the ratio of the arithmetic mean to the geometric mean or a parameter according to it or the parameter according to it is calculated, and the time envelope shape is flat when compared with a predetermined threshold Determine the degree of flatness or not. The method of determining that the time envelope shape of the low frequency signal is flat is not limited to the above example.

Furthermore, for example, the time envelope shape of the low frequency signal is determined to be rising. For example, the power of the low frequency signal x _dec (t) or a parameter based thereon is calculated, the difference value in the time direction of the parameter is calculated, and the maximum value in any time segment of the difference value is calculated. The maximum value is compared with a predetermined threshold value to determine whether the time envelopment shape is rising or not, or the degree of rising. The method of determining the time envelope shape of the low frequency signal as rising is not limited to the above example.

Furthermore, for example, the time envelope shape of the low frequency signal is determined to be falling. For example, the power of the low frequency signal x _dec (t) or a parameter corresponding thereto is calculated, the difference value in the time direction of the parameter is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated. The minimum value is compared with a predetermined threshold value to determine whether the temporal envelope shape is falling or not, or the degree of falling. The method of determining the time envelope shape of the low frequency signal as falling is not limited to the above example.

Second Modification of Speech Decoding Device According to First Embodiment
FIG. 7 is a diagram showing the configuration of a second modification 10B of the speech decoding device according to the first embodiment.

  The difference with the first modification of the speech decoding apparatus according to the first embodiment is that the low frequency time envelope shape determination unit 10eB receives a plurality of subband signals of the low frequency signal from the analysis filter bank unit 10c, This is a point to determine the time envelope shape of the low frequency signal (processing corresponding to step S10-5a).

For example, the time envelope shape of the low frequency signal is determined to be flat. For example, B _LO (m) (m = 0,..., M _LO , M _LO 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _LO (0) ≧ 0, B _LO (M _LO ) <k _x ) A subband signal X _{dec, LO} (k, k) of a low frequency signal included in the m th frequency band divided into M _LO frequency bands represented by i) Temporal envelope E _{dec, LO} (k, i) of (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)) The parameters are determined and compared to a predetermined threshold to determine if the temporal envelope shape is flat or not, or the degree of flatness. The temporal envelope E _{dec, LO} (k, i) can be calculated by, for example, Equation (8), but is not limited thereto. In yet another example, a low frequency signal sub-band signal X _{dec, LO} (k, i) (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E ( Calculate the ratio of the arithmetic mean to the geometric mean or the parameter average according to the temporal envelope E _{dec, LO} (k, i) of l + 1)) or the parameter according to it, compare with a predetermined threshold, and the time envelope shape is Determine if flat or not flat. The temporal envelope E _{dec, LO} (k, i) can be calculated by, for example, Equation (8), but is not limited thereto. The method of determining that the time envelope shape of the low frequency signal is flat is not limited to the above example.

Furthermore, for example, the time envelope shape of the low frequency signal is determined to be rising. For example, in any time segment t _E (l) ≦ i <t _E (l + 1), the sub-band signal X _{dec, LO} (k, i) (B _LO (m) ≦ k <B) of the low frequency signal The maximum value of the difference value of the time envelope E _{dec, LO} (k, i) of _LO (m + 1), t _E (l) ≦ i <t _E (l + 1) is calculated. For example, it can be calculated by equation (9). The maximum value of the difference value is compared with a predetermined threshold value to determine whether the time envelope shape is rising or not, or the degree of rising. Furthermore, instead of the temporal envelope, parameters obtained by smoothing the temporal envelope in the temporal direction can be used. The method of determining the time envelope shape of the low frequency signal as rising is not limited to the above example.

Furthermore, for example, the time envelope shape of the low frequency signal is determined to be falling. The subband signals X _{dec, LO} (k, i) of the low frequency signal (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)) The minimum value of the difference value of the time envelope E _{dec, LO} (k, i) is calculated. For example, it can be calculated by equation (10). The minimum value of the difference value is compared with a predetermined threshold value to determine whether the temporal envelope shape is falling or not, or the degree of falling. Furthermore, instead of the temporal envelope, parameters obtained by smoothing the temporal envelope in the temporal direction can be used. The method of determining the time envelope shape of the low frequency signal as falling is not limited to the above example.

Third Modification of Speech Decoding Device According to First Embodiment
FIG. 8 is a diagram showing a configuration of a third modification 10C of the speech decoding device according to the first embodiment.

  The low frequency temporal envelope shape determination unit 10eC includes information on the low frequency temporal envelope shape from the coding sequence analysis unit 10d, a low frequency signal from the core decoding unit 10b, and a plurality of sub-ranges of low frequency signals from the analysis filter bank unit 10c. At least one of the band signals is received, and the time envelope shape of the low frequency signal is determined (corresponding to step S10-5 in FIG. 2).

  For example, the time envelope shape of the low frequency signal is determined to be flat. In this case, in combination with at least one of the method for determining the temporal envelope shape of the low frequency signal as flat in the first and second modifications of the speech decoding apparatus according to the first embodiment and the decoding apparatus. Determine the temporal envelope shape as flat. The method of determining that the time envelope shape of the low frequency signal is flat is not limited to the above.

  For example, the time envelope shape of the low frequency signal is determined to be rising. In this case, the speech decoding apparatus according to the first embodiment and the method for determining the time envelopment shape of the low frequency signal described in the first and second variants of the decoding apparatus in combination are at least one or more in combination. Determine the time envelopment shape as rising. The method of determining the time envelope shape of the low frequency signal as rising is not limited to the above.

  For example, the time envelope shape of the low frequency signal is determined to be falling. In this case, the speech decoding apparatus according to the first embodiment and at least one method of determining the time envelope shape of the low frequency signal as falling according to the first and second modified examples of the decoding apparatus are combined. And determine that the time envelopment shape is falling. The method of determining the time envelope shape of the low frequency signal as falling is not limited to the above.

[First Modification of Speech Encoding Device of First Embodiment]
FIG. 9 is a diagram showing the configuration of a first modification 20A of the speech to digital converter according to the first embodiment.

  FIG. 10 is a flowchart showing an operation of the first modification 20A of the speech to digital converter according to the first embodiment.

  The time envelopment information encoding unit 20gA calculates the time envelopment of the low frequency signal using the power of the sub band signal of the low frequency signal calculated by the envelop calculation unit 20e, and encodes the time envelopment information from the time envelopment (Step S20-10a). In the process, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal may be calculated by the time envelopment information encoding unit 20gA. It is not limited where the power of the subband signal is calculated.

For example, as time envelope information, information representing the degree of flatness of the time envelope shape is calculated. For example, B _LO (m) (m = 0,..., M _LO , M _LO 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _LO (0) ≧ Subband signal X _LO (k, i) of a low frequency signal that is divided into M _LO frequency bands, which are bounded by 0, B _LO (M _LO ) <k _x ), and included in the m th frequency band The time envelope E _LO (k, i) of (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)) is calculated by equation (7) Do. Further, the method of calculating the time envelope E _LO (k, i) is not limited to Formula (7). A parameter corresponding to the variance of the temporal envelope E _LO (k, i) or the like is calculated, and the parameter is encoded. In yet another example, the ratio of the arithmetic mean to the geometric mean of the temporal envelope E _LO (k, i) or a parameter corresponding thereto is calculated, and the parameter is encoded. The method of calculating information representing the degree of flatness of the time envelope shape of the low frequency signal is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of rising of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (k, i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of rising of the time envelopment shape of the low frequency signal is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of fall of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (k, i) is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of falling of the time envelope shape of the low frequency signal is not limited to the above example.

Second Embodiment
FIG. 11 is a diagram showing the configuration of the speech decoding device 11 according to the second embodiment. The communication device of the speech decoding device 11 receives the multiplexed coded sequence output from the speech coding device 21 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 11, the speech decoding apparatus 11 functionally has a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 10d, and a low frequency time envelope shape. A determination unit 10e, a low frequency time envelope correction unit 10f, a high frequency signal generation unit 10g, a decoding / inverse quantization unit 10h, a frequency envelope adjustment unit 10i, and a synthesis filter bank unit 10j.

  FIG. 12 is a flowchart showing an operation of the speech decoding device 11 according to the second embodiment.

  The difference between the operation of the high frequency signal generation unit 10 g and the high frequency signal generation unit 10 g of the speech decoding apparatus 11 according to the first embodiment is that the low frequency temporal envelope correction unit 10 f corrects the time envelope shape. It is a point which generates a high frequency signal from the sub-band signal of a signal.

  FIG. 13 is a diagram showing the configuration of the speech to digital converter 21 according to the second embodiment. The communication device of the speech coding device 21 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 13, the speech encoding apparatus 21 functionally includes a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, a control parameter encoding unit 20d, an envelope calculation unit 20e, A quantization / coding unit 20f, a time envelope information coding unit 21a, a coding sequence multiplexing unit 20h, a subband signal power calculation unit 20j, and a core decoded signal generation unit 20i.

  FIG. 14 is a flowchart showing the operation of the speech to digital converter 21 according to the second embodiment.

  The temporal envelope information encoding unit 21a uses the power of the sub-band signal of the low frequency signal and the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20e to generate a temporal envelope of the low frequency signal and the high frequency signal. The temporal envelope is calculated, and the temporal envelope of the core decoded signal is calculated using the power of the subband signal of the core decoded signal similarly calculated by the subband signal power calculation unit 20j, and the temporal envelope of the low frequency signal The temporal envelope information is encoded from the temporal envelope of the high frequency signal and the temporal envelope of the core decoded signal (step S 21-1). In the process, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal may be calculated by the time envelopment information encoding unit 21a. It is not limited where the power of the subband signal is calculated. In the process, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal may be calculated by the time envelopment information encoding unit 21a. It is not limited where the power of the subband signal is calculated.

高周波数信号のサブバンド信号の時間包絡は、高周波数信号のサブバンド信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 Specifically, for example, B _LO (m) (m = 0,..., M _LO , M _LO 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B Subband signal X _LO of low frequency signals divided into M _LO frequency bands bounded by _LO (0) ≧ 0, B _LO (M _LO ) <k _x ), and included in the m th frequency band Temporal envelope E _LO (k, i) of (k, i) (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)), and Of the sub-band signal X _{dec, LO} (k, i) (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)) of the core decoded signal Temporal envelope E _{dec, LO} (k, i) is calculated using Formula (7) and Formula (8), respectively. Similarly, B _HI (m) (m = 0,..., M _HI , M _HI 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _HI (0) A subband signal X _HI (k, k) of a high frequency signal which is divided into M _HI frequency bands bounded by k k _x , B _HI (M _HI ) <k _h ) and included in the m th frequency band i) Calculate a temporal envelope E _HI (k, i) of (B _HI (m) ≦ k <B _HI (m + 1), t _E (l) ≦ i <t _E (l + 1)).

The temporal envelope of the sub-band signal of the high frequency signal may be a parameter that can be seen in the temporal variation of the magnitude of the sub-band signal of the high frequency signal, and is not limited to the above example.

For example, the time envelopment information encoding unit 21a calculates information representing the degree of flatness as time envelopment information. For example, the dispersion of the time envelope of the low frequency signal, the core decoded signal and the sub-band signal of the high frequency signal, or a parameter according to it is calculated. In yet another example, the ratio or equivalent of the arithmetic mean and the geometric mean of the temporal envelope of the low frequency signal, the core decoded signal, and the sub-band signal of the high frequency signal is calculated. In this case, the time envelopment information encoding unit 21a may calculate, as the time envelopment information, information representing the flatness of the time envelopment of at least one or more sub-band signals of the low frequency signal and the high frequency signal. It is not limited to the example of. Then, the parameters are encoded. For example, the difference value of the said parameter of a low frequency signal and a core decoding signal or its absolute value is encoded. Furthermore, for example, the values or absolute values of the parameters of the low frequency signal and the high frequency signal are encoded. For example, if the flatness of the temporal envelope is expressed as flat or not, it can be encoded by one bit, for example, the information is encoded by M _LO bits for each of the M _LO frequency bands in the arbitrary time segment. it can. The encoding method of temporal envelope information is not limited to the above example.

さらには、式（１２）において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最大値を算出できる。この場合、時間包絡情報符号化部21aは、時間包絡情報として当該低周波数信号及び高周波数信号のうち少なくとも1つ以上のサブバンド信号の時間包絡の立ち上がりの程度を表す情報を算出すればよく、前記の例に限定されない。そして、前記パラメータを符号化する。例えば、低周波数信号とコア復号信号の当該パラメータの差分値またはその絶対値を符号化する。さらに、例えば、低周波数信号と高周波数信号の当該パラメータの値を符号化する。例えば、時間包絡の立ち上がりの程度を立ち上がりか否かで表現すれば1ビットで符号化でき、例えば、前記任意の時間セグメント内において前記M_LO個の周波数帯域毎に当該情報をM_LOビットで符号化できる。時間包絡情報の符号化方法は前記の例に限定されない。 Furthermore, for example, the time envelopment information encoding unit 21a calculates, as time envelopment information, information representing the degree of rising. For example, in any time segment t _E (l) ≦ i <t _E (l + 1), the maximum value of the difference value in the time direction of the time envelope of the sub-band signal of the low frequency signal Calculate using. Similarly, for example, within any time segment t _E (l) ≦ i <t _E (l + 1), the maximum value of the time-direction difference value of the time envelope of the sub-band signal of the high frequency signal is calculated.

Furthermore, it is possible to calculate the maximum value of the difference value in the time direction of the parameter obtained by smoothing the time envelope in the time direction instead of the time envelope in Expression (12). In this case, the time envelopment information encoding unit 21a may calculate, as time envelopment information, information representing the degree of rise of the time envelopment of at least one or more sub-band signals of the low frequency signal and the high frequency signal. It is not limited to the above example. Then, the parameters are encoded. For example, the difference value of the said parameter of a low frequency signal and a core decoding signal or its absolute value is encoded. Furthermore, for example, the values of the parameters of the low frequency signal and the high frequency signal are encoded. For example, if the degree of rising of the time envelopment is expressed by whether it is rising or not, it can be encoded by 1 bit. For example, the information can be encoded by M _LO bits for every M _LO frequency bands in the arbitrary time segment. Can be The encoding method of temporal envelope information is not limited to the above example.

さらには、式（１３）において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最小値を算出できる。この場合、時間包絡情報符号化部21aは、時間包絡情報として当該低周波数信号及び高周波数信号のうち少なくとも1つ以上のサブバンド信号の時間包絡の立ち下がりの程度を表す情報を算出すればよく、前記の例に限定されない。そして、前記パラメータを符号化する。例えば、低周波数信号とコア復号信号の当該パラメータの差分値またはその絶対値を符号化する。さらに、例えば、低周波数信号と高周波数信号の当該パラメータの値を符号化する。。例えば、時間包絡の立ち下がりの程度を立ち下がりか否かで表現すれば1ビットで符号化でき、例えば、前記任意の時間セグメント内において前記M_LO個の周波数帯域毎に当該情報をM_LOビットで符号化できる。時間包絡情報の符号化方法は前記の例に限定されない。 Furthermore, for example, the time envelope information encoding unit 21a calculates information indicating the degree of fall as time envelope information. For example, in any time segment t _E (l) ≦ i <t _E (l + 1), the minimum value of the time difference of the time envelope of the sub-band signal of the low frequency signal Calculate using. Similarly, for example, in any time segment t _E (l) ≦ i <t _E (l + 1), the minimum value of the time-wise difference value of the time envelope of the sub-band signal of the high frequency signal is calculated.

Furthermore, in equation (13), it is possible to calculate the minimum value of the difference values in the time direction of the parameters obtained by smoothing the time envelope in the time direction, instead of the time envelope. In this case, the time envelopment information encoding unit 21a may calculate information indicating the degree of fall of the time envelopment of at least one or more sub-band signals of the low frequency signal and the high frequency signal as time envelopment information. Not limited to the above examples. Then, the parameters are encoded. For example, the difference value of the said parameter of a low frequency signal and a core decoding signal or its absolute value is encoded. Furthermore, for example, the values of the parameters of the low frequency signal and the high frequency signal are encoded. . For example, if the degree of falling of the time envelopment is expressed by whether it is falling or not, it can be encoded by one bit, for example, the information may be M _LO bits for every M _LO frequency bands in the arbitrary time segment. Can be encoded with The encoding method of temporal envelope information is not limited to the above example.

[First Modification of Speech Encoding Device of Second Embodiment]
FIG. 15 is a diagram showing the configuration of a first modification 21A of the speech to digital converter according to the second embodiment.

  FIG. 16 is a flowchart showing an operation of the first modification 21A of the speech to digital converter according to the second embodiment.

  The time envelopment information encoding unit 21aA calculates the time envelopment of the input sound signal using the power of the sub-band signal of the input sound signal calculated by the envelop calculation unit 20e, and encodes the time envelopment information from the time envelopment (Step S21-1a). In the process, when the power of the sub-band signal of the input voice signal is not calculated, the time envelope information coding unit 21aA may calculate the power of the sub-band signal of the input voice signal. It is not limited where the power of the subband signal is calculated.

For example, as time envelope information, information representing the degree of flatness of the time envelope shape is calculated. For example, B _LO (m) (m = 0,..., M _LO , M _LO 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _LO (0) ≧ Subband signal X _LO (k, i) of a low frequency signal that is divided into M _LO frequency bands, which are bounded by 0, B _LO (M _LO ) <k _x ), and included in the m th frequency band The time envelope E _LO (k, i) of (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)) is calculated by equation (7) Do. Further, the method of calculating the time envelope E _LO (k, i) is not limited to Formula (7). Similarly, B _HI (m) (m = 0,..., M _HI , M _HI 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _HI (0) A subband signal X _HI (k, k) of a low frequency signal that is divided into M _HI frequency bands bounded by k k _x , B _HI (M _HI ) <k _h ) and included in the m th frequency band i) The time envelope E _HI (k, i) of (B _HI (m) ≦ k <B _HI (m + 1), t _E (l) ≦ i <t _E (l + 1)) Calculated by Moreover, the calculation method of time envelope _EHI (k, i) is not limited to Formula (11). At least one or more of the variance of the temporal envelope E _LO (k, i) or the parameter according to it and the variance of the temporal envelope E _HI (k, i) or the parameter according to it are calculated, and the parameters are separately or combined Encoding. In yet another example, the ratio of the arithmetic mean to the geometric mean of the temporal envelope E _LO (k, i) or a parameter according thereto, and the ratio of the arithmetic mean to the geometric mean of the temporal envelope E _HI (k, i) At least one or more corresponding parameters are calculated, and the parameters are encoded separately or in combination. The method of calculating information representing the degree of flatness of the temporal envelope shape is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of rising of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (k, i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated. Similarly, the difference value in the time direction of the time envelope E _HI (k, i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated. The parameters are encoded separately or in combination. The method of calculating information representing the degree of rising of the time envelopment shape of the low frequency signal is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of fall of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (k, i) is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated. Similarly, the difference value in the time direction of the time envelope E _HI (k, i) is calculated, and the minimum value in any time segment of the difference value is calculated. The parameters are encoded separately or in combination. The method of calculating information representing the degree of falling of the time envelope shape of the low frequency signal is not limited to the above example.

  It is obvious that the first, second and third variants of the first embodiment of the present invention can be applied to the low frequency time envelope shape determination unit 10e of the second embodiment.

  The speech decoding device 11 according to the second embodiment decodes the coded sequence encoded by the speech coding device 20 according to the first embodiment of the present invention and the speech coding device 20A according to the first modification. it can.

Third Embodiment
FIG. 17 is a diagram showing the configuration of the speech decoding device 12 according to the third embodiment. The communication device of the speech decoding device 12 receives the multiplexed coded sequence output from the speech coding device 22 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 17, the speech decoding apparatus 12 functionally has a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 10d, and a low frequency time envelope shape. A determination unit 10e, a low frequency time envelope correction unit 12a, a high frequency signal generation unit 10g, a decoding / inverse quantization unit 10h, a frequency envelope adjustment unit 10i, and a synthesis filter bank unit 10j.

  FIG. 18 is a flowchart showing an operation of the speech decoding device 12 according to the third embodiment.

  The low frequency temporal envelope correction unit 12a corrects the shape of the temporal envelope of the low frequency signal output from the core decoding unit 10b based on the temporal envelope shape determined by the low frequency temporal envelope shape determination unit 10e (step S12- 1).

により得られるx’_dec,LO(i)を時間包絡形状が修正された低周波数信号として出力する。 For example, the low frequency time envelope correction unit 12a _{applies to the} low frequency signal x _{dec, LO} (i) in an arbitrary time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1)). Then, using the predetermined function F _t (x _{dec, LO} (i)), the following equation (14)

And x ′ _{dec, LO} (i) obtained by the above are output as a low frequency signal whose time envelope shape is corrected.

として、x’_dec,LO(i)を時間包絡形状が修正された低周波数信号として出力する。
また別の例によれば、所定の関数F_t(x_dec,LO(i))を、低周波数信号x_dec,LO(i)に対して平滑化フィルタ処理を施す

(N_filt≧1)で定義して、x’_dec,LO(i)を時間包絡形状が修正された低周波数信号として出力する。上記の時間包絡形状を平坦に修正する処理の例は、それぞれを組み合わせて実施できる。低周波数時間包絡修正部10fは、低周波数信号の複数のサブバンド信号の時間包絡の形状を平坦に修正する処理を実施し、上記の例に限定されない。 For example, when the temporal envelope shape of the low frequency signal is determined to be flat, the temporal envelope shape of the low frequency signal can be corrected by the following process. For example, for the low frequency signal x _{dec, LO} (i), a predetermined function F _t (x _{dec, LO} (i))

Output x ′ _{dec, LO} (i) as a low frequency signal whose time envelope shape is corrected.
According to another example, the predetermined function F _t (x _{dec, LO} (i)) is subjected to smoothing filter processing on the low frequency signal x _{dec, LO} (i)

As defined by (N _filt 11), x ′ _{dec, LO} (i) is output as a low frequency signal whose temporal envelope shape is corrected. The example of the process which corrects said time envelope shape flatly can be implemented combining each, respectively. The low frequency time envelope correction unit 10 f performs processing for correcting the shape of the time envelope of the plurality of sub band signals of the low frequency signal to be flat, and is not limited to the above example.

で定義して、x’_dec,LO(i)を時間包絡形状が修正された低周波数信号として出力する。低周波数時間包絡修正部10fは、低周波数信号の複数のサブバンド信号の時間包絡の形状を立ち上がりに修正する処理を実施し、上記の例に限定されない。 Furthermore, for example, when the temporal envelope shape of the low frequency signal is determined to be rising, the temporal envelope shape of the low frequency signal can be corrected by the following processing. For example, a predetermined function F _t (x _{dec, LO} (i)) is used with a function incr (i) which monotonically increases with respect to i.

Define x ′ _{dec, LO} (i) as a low frequency signal whose time envelope shape is corrected. The low frequency time envelope correction unit 10 f performs a process of correcting the shape of the time envelope of the plurality of sub band signals of the low frequency signal to rise, and is not limited to the above example.

で定義して、x’_dec,LO(i)を時間包絡形状が修正された低周波数信号として出力する。低周波数時間包絡修正部10fは、低周波数信号の複数のサブバンド信号の時間包絡の形状を立ち下がりに修正する処理を実施し、上記の例に限定されない。 Furthermore, for example, when the temporal envelope shape of the low frequency signal is determined to be falling, the temporal envelope shape of the low frequency signal can be corrected by the following processing. For example, using a function decr (i) which decreases monotonically with respect to i, a predetermined function F _t (x _{dec, LO} (i))

Define x ′ _{dec, LO} (i) as a low frequency signal whose time envelope shape is corrected. The low frequency time envelope correction unit 10 f performs processing to correct the shape of the time envelope of the plurality of sub band signals of the low frequency signal to fall, and is not limited to the above example.

により得られるX’_dec,LO(k)を時間包絡形状が修正された低周波数信号の周波数領域の変換係数として出力する。 According to another example, low-frequency signals are transformed by frequency domain transform coefficients X _{dec, LO} (k) (0 ≦ k <k) by time-frequency transform represented by discrete Fourier transform, discrete cosine transform, and modified discrete cosine transform. When it is represented by _x ), using a predetermined function F _f (X _{dec, LO} (k))

And X ′ _{dec, LO} (k) obtained by the above are output as the transform coefficients of the frequency domain of the low frequency signal whose temporal envelope shape is corrected.

(N_pred≧1)で定義して、X’_dec,LO(k,i)を時間包絡形状が修正された低周波数信号の変換係数として出力する。 For example, when the temporal envelope shape of the low frequency signal is determined to be flat, the temporal envelope shape of the low frequency signal can be corrected by the following process.
M _LO arbitrary pieces of boundary represented by B _LO (m) (m = 0,..., M _LO , M _LO 1 1) (B _LO (0) 0, 0, B _LO (M _LO ) <k _x ) frequency band B _dec, in the _LO (m), the linear prediction coefficient _{α p (m) (m =} 0, ..., M LO -1) by linear prediction in the frequency direction to obtain a predetermined function F _t ( X _{dec, LO} a (k)), performs linear prediction inverse filtering transform coefficients X _dec, with respect to _LO (k)

As defined by (N _pred 11), X ′ _{dec, LO} (k, i) is output as a transform coefficient of a low frequency signal whose temporal envelope shape is corrected.

  FIG. 19 is a diagram showing the configuration of the speech to digital converter 22 according to the third embodiment. The communication device of the speech coding device 22 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 19, the speech encoding apparatus 22 functionally includes a downsampling unit 20a, a core encoding unit 20b, an analysis filter bank unit 20c, a control parameter encoding unit 20d, an envelope calculation unit 20e, and quantization. / Coding unit 20 f, time envelope calculation units 22 a and 22 a 1, time envelope information coding unit 22 b, coded sequence multiplexing unit 20 h, and core decoded signal generation unit 20 i.

  FIG. 20 is a flowchart showing the operation of the speech to digital converter 22 according to the third embodiment.

  The time envelope calculation unit 22a calculates the time envelope of the downsampled signal obtained from the downsampling unit 20a (step 22-1).

ダウンサンプル信号の時間包絡は、ダウンサンプル信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, the temporal envelope E _LO (i) of the downsampled signal x _LO (i) in any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1) It can be calculated as the power of the downsampled signal normalized by.

The temporal envelope of the down-sampled signal may be a parameter that shows the temporal variation of the magnitude of the down-sampled signal, and is not limited to the above example.

  The time envelope calculation unit 22a1 calculates the time envelope of the core decoded signal generated by the core decoded signal generation unit 20i (step 22-2). The temporal envelope of the core decoded signal can be calculated in the same manner as the temporal envelope of the downsampled signal.

コア復号信号の時間包絡は、コア復号信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, the time envelope E _{dec, LO} (i) of the core decoded signal x _{dec, LO} (i) in any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1)) , It can be calculated as the power of the core decoding signal normalized within the time segment.

The temporal envelope of the core decoded signal may be a parameter that can be seen in the temporal variation of the magnitude of the core decoded signal, and is not limited to the above example.

  The temporal envelope information encoding unit 22b uses temporal envelope of the downsampled signal calculated by the temporal envelope calculation unit 22a and temporal envelope of the core decoded signal calculated by the temporal envelope calculation unit 22a1 to obtain temporal envelope information. The time envelope information is calculated based on the time envelope (step S22-3).

  For example, the time envelopment information encoding unit 22b calculates information representing a degree of flatness as the time envelopment information. For example, the distribution of the time envelope of the downsampled signal and the core decoded signal or a parameter according to it is calculated. In still another example, the ratio of the arithmetic mean to the geometric mean or the parameter corresponding thereto of the temporal envelope of the down-sample signal and the sub-band signal of the core decoded signal is calculated. In this case, the time envelopment information encoding unit 22b may calculate information representing the flatness of the time envelopment of the downsampled signal as the time envelopment information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value or the absolute value of the parameter of the downsampled signal and that of the core decoded signal are encoded. Furthermore, for example, the value or absolute value of the parameter of the downsampled signal is encoded. For example, if the flatness of the temporal envelope is expressed as flat or not, it can be encoded with one bit, for example, it can be encoded with one bit for the arbitrary time segment. The encoding method of temporal envelope information is not limited to the above example.

さらには、式（２３）において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最大値を算出できる。この場合、時間包絡情報符号化部22bは、時間包絡情報として当該ダウンサンプル信号の時間包絡の立ち上がりの程度を表す情報を算出すればよく、前記の例に限定されない。そして、前記パラメータを符号化する。例えば、ダウンサンプル信号とコア復号信号の当該パラメータの差分値またはその絶対値を符号化する。例えば、時間包絡の立ち上がりの程度を立ち上がりか否かで表現すれば1ビットで符号化でき、例えば、前記任意の時間セグメントについては1ビットで符号化できる。時間包絡情報の符号化方法は前記の例に限定されない。 Furthermore, for example, the time envelope information encoding unit 22b calculates information indicating the degree of rising as time envelope information. For example, within any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1), the maximum value of the difference value in the time direction of the time envelope of the down-sampled signal is calculated.

Furthermore, in equation (23), it is possible to calculate the maximum value of the difference value in the time direction of the parameter obtained by smoothing the time envelope in the time direction instead of the time envelope. In this case, the time envelope information encoding unit 22b may calculate information indicating the degree of rising of the time envelope of the down-sample signal as time envelope information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value or the absolute value of the parameter of the downsampled signal and that of the core decoded signal are encoded. For example, if the degree of rising of the time envelopment is expressed by whether it is rising or not, it can be encoded by one bit, for example, it can be encoded by one bit for the arbitrary time segment. The encoding method of temporal envelope information is not limited to the above example.

さらには、式（２４）において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最小値を算出できる。この場合、時間包絡情報符号化部22bは、時間包絡情報として当該ダウンサンプル信号の時間包絡の立ち下がりの程度を表す情報を算出すればよく、前記の例に限定されない。そして、前記パラメータを符号化する。例えば、ダウンサンプル信号とコア復号信号の当該パラメータの差分値またはその絶対値を符号化する。例えば、時間包絡の立ち下がりの程度を立ち下がりか否かで表現すれば1ビットで符号化でき、例えば、前記任意の時間セグメントについては1ビットで符号化できる。時間包絡情報の符号化方法は前記の例に限定されない。 Furthermore, for example, the time envelopment information encoding unit 20g calculates information representing the degree of fall as time envelopment information. For example, in any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1), the minimum value of the time difference of the time envelope of the sub-band signal of the low frequency signal is calculated. .

Furthermore, in equation (24), it is possible to calculate the minimum value of the difference values in the time direction of parameters obtained by smoothing the time envelope in the time direction instead of the time envelope. In this case, the time envelopment information encoding unit 22b may calculate information representing the degree of fall of the time envelopment of the downsampled signal as time envelopment information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value or the absolute value of the parameter of the downsampled signal and that of the core decoded signal are encoded. For example, if the degree of falling of the temporal envelope is expressed as falling or not, it can be encoded in one bit, and for example, it can be encoded in one bit for the arbitrary time segment. The encoding method of temporal envelope information is not limited to the above example.

  In the example of calculating information representing the degree of flatness, the degree of rising, and the degree of falling as the time envelope information, when only one of the time envelopes of the down sample signal and the core decoded signal is used, the other time is used. Each part and each processing which concern only on calculation of an envelope can be omitted.

First Modification of Speech Encoding Device of Third Embodiment
FIG. 21 is a diagram showing the configuration of a first modification 22A of the speech to digital converter according to the third embodiment.

  FIG. 22 is a flowchart showing an operation of the first modification 22A of the speech to digital converter according to the third embodiment.

  The temporal envelope information coding unit 22bA calculates temporal envelope information from the temporal envelope of the downsampled signal calculated by the temporal envelope calculation unit 22a, and encodes the temporal envelope information (step S22-3a).

For example, as time envelope information, information representing the degree of flatness of the time envelope shape is calculated. For example, down-sampled signal x _LO (i) (t _{t, E} (l) ≦ i <t _{t, E} within any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1) The time envelope E _LO (i) of (l + 1) is calculated by equation (21). Moreover, the calculation method of time envelope E _LO (i) is not limited to Formula (21). A parameter corresponding to the variance or its equivalent of the temporal envelope E _LO (i) is calculated, and the parameter is encoded. In yet another example, the ratio of the arithmetic mean to the geometric mean of the time envelope E _LO (i) or a parameter equivalent thereto is calculated, and the parameter is encoded. The method of calculating information representing the degree of flatness of the time envelope shape of the downsampled signal is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of rising of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of rising of the time envelope shape of the downsampled signal is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of fall of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (i) is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of falling of the time envelope shape of the downsampled signal is not limited to the above example.

Second Modification of Speech Encoding Device of Third Embodiment
FIG. 23 is a diagram showing the configuration of a second modification 22B of the speech to digital converter according to the third embodiment.

  FIG. 24 is a flowchart showing an operation of the second modification 22B of the speech to digital converter according to the third embodiment.

  The time envelope calculation unit 22aB calculates the time envelope of the input speech signal (step 22-1b).

入力信号の時間包絡は、入力信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, the time envelope E (i) of the input signal x (i) in any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1)) is normalized within the time segment It can be calculated as the power of the converted input signal.

The temporal envelope of the input signal may be any parameter that can indicate temporal variation of the magnitude of the input signal, and is not limited to the above example.

  The temporal envelope information coding unit 22bB calculates temporal envelope information from the temporal envelope of the input speech signal calculated by the temporal envelope calculation unit 22aB, and encodes the temporal envelope information (step S22-3b).

For example, as time envelope information, information representing the degree of flatness of the time envelope shape is calculated. For example, an input signal x (i) (t _{t, E} (l) ≦ i <t _{t, E} (l) in any time segment t _{t, E} (l) ≦ i <t _{t, E} (l + 1) The temporal envelope E (i) of +1)) is calculated by equation (25). Moreover, the calculation method of time envelope E (i) is not limited to Formula (25). A parameter corresponding to the variance or its equivalent of the temporal envelope E (i) is calculated, and the parameter is encoded. In yet another example, the ratio of the arithmetic mean to the geometric mean of temporal envelope E (i) or the parameter corresponding thereto is calculated, and the parameter is encoded. The method of calculating the information representing the degree of flatness of the time envelope shape of the input signal is not limited to the above example.

  Furthermore, for example, as time envelope information, information representing the degree of rising of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E (i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of rising of the time envelopment shape of the input signal is not limited to the above example.

  Furthermore, for example, as time envelope information, information representing the degree of fall of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E (i) is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of falling of the time envelope shape of the input signal is not limited to the above example.

  It is obvious that the first, second and third variants of the first embodiment of the present invention can be applied to the low frequency time envelope shape determination unit 10e of the third embodiment.

Fourth Embodiment
FIG. 25 is a diagram showing the configuration of the speech decoding device 13 according to the fourth embodiment. The communication device of the speech decoding device 13 receives the multiplexed coded sequence output from the speech coding device 23 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 25, the speech decoding apparatus 13 functionally has a coded sequence demultiplexing unit 10aA, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a high frequency time envelope shape. A determination unit 13a, a time envelope correction unit 13b, a high frequency signal generation unit 10g, a decoding / inverse quantization unit 10h, a frequency envelope adjustment unit 10i, and a synthesis filter bank unit 10j.

  FIG. 26 is a flowchart showing the operation of the speech decoding device 13 according to the fourth embodiment.

  The coding sequence analysis unit 13c analyzes the band extension part of the coding sequence divided by the coding sequence demultiplexing unit 10aA, and the high frequency signal generation unit 10g, the decoding / inverse quantization unit 10h, and the high frequency time envelope The information is divided into necessary information by the shape determination unit 13a (step S13-3).

  The high frequency temporal envelope shape determination unit 13a receives the information on the high frequency temporal envelope shape from the coding sequence analysis unit 13c, and determines the temporal envelope shape of the high frequency signal based on the information (step S13-1). For example, the time envelope shape of the high frequency signal is determined to be flat. Furthermore, for example, the time envelope shape of the high frequency signal is determined to be rising. Furthermore, for example, the time envelope shape of the high frequency signal is determined to be falling.

  The time envelope correction unit 13b is output from the analysis filter bank unit 10c based on the time envelope shape determined by the high frequency time envelope shape determination unit 13a, and is used to generate a high frequency signal in the high frequency signal generation unit 10g. The shape of the time envelope of the plurality of sub-band signals of the low frequency signal is corrected (step S13-2).

  For example, when the temporal envelope shape of the high frequency signal is determined to be flat, for example, the low frequency temporal envelope correction unit 10 f may generate the temporal envelope of the low frequency signal with respect to the low frequency signal used to generate the high frequency signal. Similar to the process for flattening the shape, the time envelope shape of the low frequency signal used to generate the high frequency signal can be corrected.

  Furthermore, for example, when the time envelopment shape of the high frequency signal is determined to be rising, for example, the low frequency time envelopment correction unit 10f performs the same process as the process of making the time envelopment shape of the low frequency signal rise. The temporal envelope shape of the low frequency signal used to generate the frequency signal can be corrected.

  Furthermore, for example, when the time envelope shape of the high frequency signal is determined to be falling, for example, the low frequency time envelope correction unit 10f performs the same processing as the processing of making the time envelope shape of the low frequency signal fall. The time envelope shape of the low frequency signal used to generate the high frequency signal can be corrected.

  The process of correcting the time envelope shape of the low frequency signal used to generate the high frequency signal is not limited to the above example.

  FIG. 27 is a diagram showing the configuration of the speech to digital converter 23 according to the fourth embodiment. The communication device of the speech coding device 23 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 27, the speech coding apparatus 23 functionally includes a downsampling unit 20a, a core coding unit 20b, analysis filter bank units 20c and 20c1, a control parameter coding unit 20d, an envelope calculation unit 20e, A quantization / coding unit 20f, a time envelope information coding unit 23a, a coding sequence multiplexing unit 20h, a subband signal power calculation unit 20j, and a core decoded signal generation unit 20i.

  FIG. 28 is a flowchart showing the operation of the speech to digital converter 23 according to the fourth embodiment.

  The time envelopment information encoding unit 23a calculates at least one of the time envelopment of the low frequency signal and the time envelopment of the high frequency signal to be used for generation of the high frequency signal, and further, the sub band signal power calculation unit 20j. The time envelope of the core decoded signal is calculated using the calculated power of the subband signal of the core decoded signal, and at least one of the time envelope of the low frequency signal and the time envelope of the high frequency signal and the core decoded signal The time envelope information is encoded from the time envelope (step S23-1). The temporal envelope of the low frequency signal is calculated using the power of the sub-band signal of the low frequency signal calculated by the envelope calculation unit 20 e. The temporal envelope of the high frequency signal is calculated using the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20 e. In the processing, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal can be calculated by the time envelopment information coding unit 23a, and the sub band signal of the low frequency signal It is not limited where the power of is calculated. Furthermore, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal can be calculated by the time envelopment information encoding unit 23a. It is not limited where the power is calculated.

  For example, the time envelope of the low frequency signal used to generate the high frequency signal can be calculated by the same process as the process of the time envelope information encoding unit 20 g calculating the time envelope of the low frequency signal. The time envelope of the sub-band signal of the low frequency signal used to generate the high frequency signal may be a parameter that can be seen in the time direction variation of the magnitude of the sub band signal of the low frequency signal, and is not limited to the above example .

  Further, for example, the time envelope of the high frequency signal can be calculated by the same process as the process of the time envelope information encoding unit 21a calculating the time envelope of the high frequency signal. The temporal envelope of the sub-band signal of the high frequency signal may be a parameter that can be used to indicate the temporal variation of the magnitude of the sub-band signal of the high frequency signal, and is not limited to the above example.

  For example, in processing in which the time envelopment information encoding unit 20g calculates information representing a degree of flatness as time envelopment information, a low used for generating the high frequency signal instead of the time envelopment of the low frequency signal sub-band signal. By using the temporal envelope of the sub-band signal of the frequency signal, it is possible to calculate information representing the degree of flatness as temporal envelope information and to encode the temporal envelope information. Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates the information representing the degree of flatness as the time envelopment information, the subband of the high frequency signal instead of the temporal envelope of the low frequency signal subband signal By using the temporal envelope of the signal, it is possible to calculate information representing the degree of flatness as temporal envelope information, and to encode the temporal envelope information. For example, if the degree of flatness of the temporal envelope is expressed as flat or not, it can be encoded with one bit.

  Furthermore, for example, in processing in which the time envelopment information encoding unit 20g calculates information representing the degree of rising as time envelopment information, it is used for generation of the high frequency signal instead of the time envelopment of the low frequency signal sub band signal. By using the time envelope of the sub-band signal of the low frequency signal, it is possible to calculate information indicating the degree of rising as time envelope information, and to code the time envelope information. Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates information representing the degree of rising as time envelopment information, a subband of the high frequency signal instead of the temporal envelope of the low frequency signal subband signal. By using the temporal envelope of the signal, it is possible to calculate information indicating the degree of rising as temporal envelope information, and to encode the temporal envelope information. For example, if it expresses whether the rising degree of the time envelope is rising or not, it can be encoded by 1 bit.

  Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates information representing the degree of fall as time envelopment information, instead of the time envelopment of the low frequency signal sub band signal, generation of the high frequency signal By using the time envelope of the sub-band signal of the low frequency signal to be used, it is possible to calculate information indicating the degree of fall as time envelope information, and to code the time envelope information. Furthermore, for example, in the processing in which the time envelope information encoding unit 20g calculates information indicating the degree of fall as time envelope information, a sub-frame of the high frequency signal is used instead of the time envelope of the low frequency signal sub-band signal. By using the temporal envelope of the band signal, it is possible to calculate information indicating the degree of fall as temporal envelope information, and to encode the temporal envelope information. For example, if the degree of falling of the time envelopment is expressed by whether it is falling or not, it can be encoded in one bit.

  Note that the method of calculating time envelope information and the encoding method are not limited to the above examples.

First Modification of Speech Decoding Device According to Fourth Embodiment
FIG. 29 is a diagram showing the configuration of the first modification 13A of the speech decoding device according to the fourth embodiment.

  FIG. 30 is a flowchart showing an operation of the first modification 13A of the speech decoding device according to the fourth embodiment.

  The high frequency temporal envelope shape determination unit 13aA receives the low frequency signal from the core decoding unit 10b, and determines the high frequency temporal envelope shape based on the low frequency signal (step S13-1a).

  For example, the temporal envelope of the low frequency signal is calculated, and the high frequency temporal envelope shape is determined based on the shape of the low frequency temporal envelope. Furthermore, for example, a temporal envelope of a signal obtained by applying predetermined processing to a low frequency signal is calculated, and a high frequency temporal envelope shape is determined based on the shape of the temporal envelope of the processed low frequency signal. The predetermined process is, for example, a high pass filter process, but is not limited thereto.

  For example, the time envelope shape of the high frequency signal is determined to be flat. For example, the time envelope shape of the high frequency signal can be determined to be flat, as in the process in which the low frequency time envelope shape determination unit 10eA determines that the time envelope shape of the low frequency signal is flat. Furthermore, in the processing in which the low frequency temporal envelope shape determination unit 10eA determines that the temporal envelope shape of the low frequency signal is flat, the temporal envelope of the processed low frequency signal is used instead of the temporal envelope of the low frequency signal. The temporal envelope shape of the high frequency signal can be determined to be flat. The process of determining that the temporal envelope shape of the high frequency signal is flat is not limited to the above example.

  Furthermore, for example, the time envelope shape of the high frequency signal is determined to be rising. For example, the time envelope shape of the high frequency signal can be determined to be rising, as in the process in which the low frequency time envelope shape determination unit 10eA determines the time envelope shape of the low frequency signal to be rising. Furthermore, in the processing in which the low frequency time envelope shape determination unit 10eA determines that the time envelope shape of the low frequency signal is rising, using the time envelope of the processed low frequency signal instead of the time envelope of the low frequency signal. The time envelope shape of the high frequency signal can be determined to be rising. The process of determining the time envelope shape of the high frequency signal as rising is not limited to the above example.

  Furthermore, for example, the time envelope shape of the high frequency signal is determined to be falling. For example, the time envelope shape of the high frequency signal can be determined to be falling, similar to the processing in which the low frequency time envelope shape determining unit 10eA determines the time envelope shape of the low frequency signal to be falling. Furthermore, in the processing in which the low frequency temporal envelope shape determination unit 10eA determines the temporal envelope shape of the low frequency signal as falling, the temporal envelope of the processed low frequency signal is used instead of the temporal envelope of the low frequency signal. Thus, the time envelope shape of the high frequency signal can be determined to be falling. The process of determining the time envelope shape of the high frequency signal as falling is not limited to the above example.

Second Modification of Speech Decoding Device According to Fourth Embodiment
FIG. 31 is a diagram showing the configuration of the second modification 13B of the speech decoding device according to the fourth embodiment.

  The difference with the first modification 13A of the speech decoding device according to the fourth embodiment is that the high-frequency time envelope shape determination unit 13aB receives a plurality of subband signals of a low frequency signal from the analysis filter bank unit 10c. The time envelope shape of the high frequency signal is determined based on a plurality of sub-band signals of the low frequency signal (processing equivalent to step S13-1a).

  For example, the temporal envelope of at least one or more sub-band signals of the low frequency signal is calculated, and the high frequency temporal envelope shape is determined based on the shape of the low frequency sub-band signal temporal envelope.

For example, the time envelope shape of the high frequency signal is determined to be flat. For example, the time envelope shape of the high frequency signal can be determined to be flat in the same manner as the low frequency time envelope shape determination unit 10eB determines that the time envelope shape of the low frequency signal is flat. In this case, B _LO representative of the boundary of the frequency band (m) is, for example, as such defines only the frequency band of relatively high frequencies, may be different from the low-frequency time envelope shape determination unit 10eB. The process of determining that the temporal envelope shape of the high frequency signal is flat is not limited to the above example.

Furthermore, for example, the time envelope shape of the high frequency signal is determined to be rising. For example, the time envelope shape of the high frequency signal can be determined to be rising in the same manner as the low frequency time envelope shape determination unit 10eB determines the time envelope shape of the low frequency signal to be rising. In this case, B _LO representative of the boundary of the frequency band (m) is, for example, as such defines only the frequency band of relatively high frequencies, may be different from the low-frequency time envelope shape determination unit 10eB. The process of determining the time envelope shape of the high frequency signal as rising is not limited to the above example.

Furthermore, for example, the time envelope shape of the high frequency signal is determined to be falling. For example, the time envelope shape of the high frequency signal can be determined as falling in the same manner as the low frequency time envelope shape determining unit 10eB determines the time envelope shape of the low frequency signal as falling. In this case, B _LO representative of the boundary of the frequency band (m) is, for example, as such defines only the frequency band of relatively high frequencies, may be different from the low-frequency time envelope shape determination unit 10eB. The process of determining the time envelope shape of the high frequency signal as falling is not limited to the above example.

Third Modification of Speech Decoding Device According to Fourth Embodiment
FIG. 32 is a diagram showing the configuration of the third modification 13C of the speech decoding device according to the fourth embodiment.

  The high frequency temporal envelope shape determination unit 13aC receives information on the high frequency temporal envelope shape from the coding sequence analysis unit 13c, a plurality of subband signals of the low frequency signal from the core decoding unit 10b, and the low frequency signal from the analysis filter bank unit 10c. At least one is received to determine the time envelope shape of the high frequency signal (processing equivalent to step S13-1).

  For example, the temporal envelope of at least one or more sub-band signals of the low frequency signal is calculated, and the high frequency temporal envelope shape is determined based on the shape of the low frequency sub-band signal temporal envelope.

  For example, the time envelope shape of the high frequency signal is determined to be flat. In this case, the speech decoding apparatus according to the fourth embodiment, in combination with at least one method for determining the temporal envelope shape of the high frequency signal as described in the first and second modifications of the decoding apparatus, is flat. Determine the temporal envelope shape as flat. The method of determining that the temporal envelope shape of the high frequency signal is flat is not limited to the above.

  Also, for example, the time envelope shape of the high frequency signal is determined to be rising. In this case, the speech decoding apparatus according to the fourth embodiment and the method for determining the time envelopment shape of the high frequency signal as the rise described in the first and second variants of the decoding apparatus are combined in combination with at least one or more. Determine the time envelopment shape as rising. The method of determining the time envelope shape of the high frequency signal as rising is not limited to the above.

  Furthermore, for example, the time envelope shape of the high frequency signal is determined to be falling. In this case, the speech decoding apparatus according to the fourth embodiment, at least one method of determining the time envelope shape of the high frequency signal as falling according to the first and second modified examples of the decoding apparatus is combined. And determine that the time envelopment shape is falling. The method of determining the time envelope shape of the high frequency signal as falling is not limited to the above.

[First Modification of Speech Encoding Apparatus of Fourth Embodiment]
FIG. 33 is a diagram showing the configuration of the first modification 23A of the speech to digital converter according to the fourth embodiment.

  FIG. 34 is a flowchart showing an operation of the first modification 23A of the speech to digital converter according to the fourth embodiment.

  The time envelopment information encoding unit 23aA calculates at least one or more of the time envelopment of the low frequency signal and the time envelopment of the high frequency signal, and at least one or more of the time envelops of the low frequency signal and the high frequency signal. The time envelope information is calculated and encoded (step S23-1a). The temporal envelope of the low frequency signal is calculated using the power of the sub-band signal of the low frequency signal calculated by the envelope calculation unit 20 e. The temporal envelope of the high frequency signal is calculated using the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20 e. In the process, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal may be calculated by the time envelopment information encoding unit 23aA. It is not limited where the power of the subband signal is calculated. Furthermore, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal may be calculated by the time envelopment information coding unit 23aA. It is not limited where the power of the band signal is calculated.

For example, as time envelope information, information representing the degree of flatness of the time envelope shape is calculated. For example, B _LO (m) (m = 0,..., M _LO , M _LO 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _LO (0) ≧ Subband signal X _LO (k, i) of a low frequency signal that is divided into M _LO frequency bands, which are bounded by 0, B _LO (M _LO ) <k _x ), and included in the m th frequency band The time envelope E _LO (k, i) of (B _LO (m) ≦ k <B _LO (m + 1), t _E (l) ≦ i <t _E (l + 1)) is calculated by equation (7) Do. Further, the method of calculating the time envelope E _LO (k, i) is not limited to Formula (7). A parameter corresponding to the variance of the temporal envelope E _LO (k, i) or the like is calculated, and the parameter is encoded. In yet another example, the ratio of the arithmetic mean to the geometric mean of the temporal envelope E _LO (k, i) or a parameter corresponding thereto is calculated, and the parameter is encoded. Furthermore, for example, B _HI (m) (m = 0,..., M _HI , M _H 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _HI ( 0) A subband signal X _HI of high frequency signals included in the m-th frequency band by dividing it into M _HI frequency bands bounded by k k _x , B _HI (M _HI ) <k _h ) The time envelope E _HI (k, i) of (k, i) (B _HI (m) ≦ k <B _HI (m + 1), t _E (l) ≦ i <t _E (l + 1) Calculated by 11). Moreover, the calculation method of time envelope _EHI (k, i) is not limited to Formula (11). A parameter corresponding to the variance of the temporal envelope E _HI (k, i) or the like is calculated, and the parameter is encoded. In yet another example, a parameter corresponding to the ratio of arithmetic mean to geometric mean or time average of temporal envelope E _HI (k, i) or the like is calculated, and the parameter is encoded. The method of calculating information representing the degree of flatness of the temporal envelope shape is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of rising of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (k, i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated and encoded. Furthermore, for example, the difference value in the time direction of the time envelope E _HI (k, i) is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated and encoded. The method of calculating information representing the degree of rising of the time envelopment shape is not limited to the above example.

Furthermore, for example, as time envelope information, information representing the degree of fall of the time envelope shape is calculated. For example, the difference value in the time direction of the time envelope E _LO (k, i) is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated and encoded. Furthermore, for example, the difference value in the time direction of the time envelope E _HI (k, i) is calculated, and the minimum value in an arbitrary time segment of the difference value is calculated and encoded.

  Note that the method of calculating the information indicating the degree of falling of the time envelopment shape is not limited to the above example. In the example of calculating information representing the degree of flatness, the degree of rising, and the degree of falling as the time envelope information, in the case where only one of the time envelopes of the sub-band signals of the low frequency signal and the high frequency signal is used Each part and each processing only concerning calculation of the other time envelope can be omitted.

Fifth Embodiment
FIG. 35 is a diagram showing the configuration of the speech decoding device 14 according to the fifth embodiment. The communication device of the speech decoding device 14 receives the multiplexed coded sequence output from the speech coding device 24 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 35, the speech decoding apparatus 14 functionally includes a coded sequence demultiplexing unit 10aA, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a high frequency signal generation unit. 10g, a high-frequency time envelope shape determination unit 13a, a time envelope correction unit 14a, a decoding / inverse quantization unit 10h, a frequency envelope adjustment unit 10i, and a synthesis filter bank unit 10j.

  FIG. 36 is a flowchart showing an operation of the speech decoding device 14 according to the fifth embodiment.

  The time envelope correction unit 14a determines the shape of the time envelope of the plurality of sub-band signals of the high frequency signal output from the high frequency signal generation unit 10g based on the time envelope shape determined by the high frequency time envelope shape determination unit 13a. It corrects (step S14-1).

により得られるX’_gen,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。 For example, B _{gen, HI} (m) (m = 0, ..., M _{gen, HI} , M _{gen, HI} 1 1) within any time segment t _E (l) ≦ i <t _E (l + 1) Divide into M _HI frequency bands bounded by B _{gen, HI} (0) k k _x , B _{gen, HI} (M _{gen, HI} ) <k _h ), and include the high in the m th frequency band Subband signal X _{gen, HI} (k, i) of high frequency signal outputted from the frequency signal generation unit 10 g (B _HI (m) ≦ k <B _HI (m + 1), t _E (l) ≦ i < For t _E (l + 1), using the predetermined function F (X _{gen, HI} (k, i)), the following equation (26)

The _{X'gen, HI} (k, i) obtained by the above is output as a sub-band signal of a high frequency signal whose time envelopment shape is corrected.

（これらを式（２７）という。）
として、X’_gen,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。
また別の例によれば、所定の関数F(X_gen,HI(k,i))を、サブバンド信号X_gen,HI(k,i)に対して平滑化フィルタ処理を施す

(N_filt≧1)で定義して、X’_gen,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。さらに、前記B_gen,HI(m)を用いて境界が表される各周波数帯域内で、フィルタ処理前後のサブバンド信号のパワーをあわせるように処理できる。
また別の例によれば、前記B_gen,HI(m)を用いて境界が表される各周波数帯域内で、サブバンド信号X_gen,HI(k,i)を周波数方向に線形予測して線形予測係数α_p(m) (m=0,…,M_HI-1)を得て、所定の関数F(X_gen,HI(k,i))をサブバンド信号X_gen,HI(k,i)に対して線形予測逆フィルタ処理を施す

(N_pred≧1)で定義して、X’_gen,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。 For example, when the temporal envelope shape of the high frequency signal is determined to be flat, the temporal envelope shape of the high frequency signal can be corrected by the following processing. For example, the sub-band signal X _{gen, HI} (k, i) may be B _{gen, HI} (m) (m = 0, ..., M _HI , M _HI 1 1) (B _{gen, HI} (0) k k _x , A subband signal X _{gen, HI} (k, i) (B is divided into M _HI frequency bands defined by B _{gen, HI} (M _HI ) <k _h ) and included in the m th frequency band. _{For HI} (m) _gen k <B _HI (m + 1), t _E (l) i i <t _E (l + 1), the predetermined function F (X _{gen, HI} (k, i)) ,

(These are called equation (27).)
As X ′ _{gen, HI} (k, i) is output as a sub-band signal of the high frequency signal whose temporal envelope shape is corrected.
According to another example, the predetermined function F ( _{Xgen, HI} (k, i)) is subjected to smoothing filter processing on the subband signal _{Xgen, HI} (k, i)

As defined by (N _filt 1 1), X ′ _{gen, HI} (k, i) is output as a sub-band signal of a high frequency signal whose temporal envelope shape is corrected. Furthermore, processing can be performed to match the power of the sub-band signal before and after filtering within each frequency band whose boundary is represented using _{B.sub.gen, HI} (m).
According to another example, the subband signal X _{gen, HI} (k, i) is linearly predicted in the frequency direction within each frequency band bounded by the B _{gen, HI} (m). Linear prediction coefficients α _p (m) (m = 0, ..., M _HI -1) are obtained, and a predetermined function F (X _{gen, HI} (k, i)) is obtained as a subband signal X _{gen, HI} (k, i) Apply linear predictive inverse filter to i)

As defined by (N _pred 11), X ′ _{gen, HI} (k, i) is output as a sub-band signal of a high frequency signal whose temporal envelope shape is corrected.

  The example of the process which corrects said time envelope shape flatly can be implemented combining each, respectively. The time envelope correction unit 14a performs processing for correcting the shape of the time envelope of the plurality of sub-band signals of the high frequency signal to be flat, and is not limited to the above example.

で定義して、X’_gen,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。さらに、前記B_gen,HI(m)を用いて境界が表される各周波数帯域内で、時間包絡形状の修正前後のサブバンド信号のパワーをあわせるように処理できる。 Furthermore, for example, when the temporal envelope shape of the high frequency signal is determined to be rising, the temporal envelope shape of the high frequency signal can be corrected by the following processing. For example, using a function incr (i) that monotonously increases a predetermined function F (X _{gen, HI} (k, i)) with respect to i

Define X ′ _{gen, HI} (k, i) as a sub-band signal of a high frequency signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using _{B.sub.gen and HI} (m), processing can be performed to match the power of the sub-band signal before and after the correction of the temporal envelope shape.

  The time envelope correction unit 14a performs a process of correcting the shape of the time envelope of a plurality of sub-band signals of the high frequency signal into a rising edge, and is not limited to the above example.

で定義して、X’_gen,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。さらに、前記B_gen,HI(m)を用いて境界が表される各周波数帯域内で、時間包絡形状の修正前後のサブバンド信号のパワーをあわせるように処理できる。 Furthermore, for example, when the temporal envelope shape of the high frequency signal is determined to be falling, the temporal envelope shape of the high frequency signal can be corrected by the following processing. For example, using a function decr (i) which decreases monotonically with respect to i, a predetermined function F ( _{X.sub.gen, HI} (k, i))

Define X ′ _{gen, HI} (k, i) as a sub-band signal of a high frequency signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using _{B.sub.gen and HI} (m), processing can be performed to match the power of the sub-band signal before and after the correction of the temporal envelope shape.

  The time envelope correction unit 14a performs a process of correcting the shape of the time envelope of the plurality of sub-band signals of the high frequency signal into falling, and is not limited to the above example.

の算出は、前記“HF adjustment”において算出されるために省略できる。さらに、前記“HF adjustment”にて“interpolation”を利用しない場合（すなわち、bs_interpol_freq=0の場合）は、式（２７）内の高周波数信号のサブバンド信号のパワーの周波数方向の和

の算出は、前記“HF adjustment”において算出されるため、さらに省略できる。 In the case where the frequency envelope adjustment unit 10i in the present embodiment is realized by "HF adjustment" in "SBR" and "Low Delay SBR" defined in "ISO / IEC 14496-3", time envelope correction is performed. The calculation amount can be reduced by performing the processing of the unit 14a in the frequency envelope adjustment unit 10i. Specifically, for example, when correcting the time envelope shape according to equation (27), the power of the sub-band signal of the high frequency signal in equation (27)

The calculation of can be omitted because it is calculated in the above "HF adjustment". Furthermore, when “interpolation” is not used in the “HF adjustment” (ie, when bs_interpol_freq = 0), the sum in the frequency direction of the power of the subband signal of the high frequency signal in Equation (27)

Since the calculation of is calculated in the above-mentioned "HF adjustment", it can be further omitted.

が算出される場合には、上記和を、前記“HF adjustment”において算出される

の代替量、あるいは近似量として用いることができ、上記和の算出を省略することにより演算量が削減できる。 On the other hand, the sum in the time direction using the “interpolation” in the “HF adjustment”,

Is calculated in the "HF adjustment".

It can be used as an alternative amount or an approximate amount, and the calculation amount can be reduced by omitting the calculation of the sum.

  Furthermore, it is obvious that in the other examples of the time envelope correction unit 14a, some operations can be omitted as well.

  In addition, the first, second, and third modified examples of the speech decoding device according to the fourth embodiment of the present invention are compared with the high frequency time envelope shape determination unit 13a of the speech decoding device 14 according to the present embodiment. It is obvious that it is applicable.

  FIG. 37 is a diagram showing the configuration of the speech to digital converter 24 according to the fifth embodiment. The communication device of the speech coding device 24 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 37, the speech encoding apparatus 24 functionally includes a downsampling unit 20a, a core encoding unit 20b, an analysis filter bank unit 20c, a control parameter encoding unit 20d, an envelope calculation unit 20e, and quantization. / Coding unit 20 f, pseudo high frequency signal generation unit 24 a, subband signal power calculation unit 24 b, time envelope information coding unit 24 c, and coding sequence multiplexing unit 20 h.

  FIG. 38 is a flowchart showing the operation of the speech to digital converter 24 according to the fifth embodiment.

  The pseudo high frequency signal generation unit 24 a controls the sub-band signal of the low frequency signal of the input speech signal obtained by the analysis filter bank unit 20 c and the control necessary to generate the high frequency signal obtained by the control parameter coding unit 20 d. A pseudo high frequency signal is generated based on the parameters (step S24-1). The generation process of the pseudo high frequency signal is performed in the same manner as the process in the high frequency signal generation unit 10g, but in the high frequency signal generation unit 10g, it is generated from the sub-band signal of the low frequency signal decoded by the core decoding unit 10b. On the other hand, the pseudo high frequency signal generation unit 24a is different from that generated from the sub-band signal of the low frequency signal of the input speech signal. In the pseudo high frequency signal generation unit 24a, part of the processing in the high frequency signal generation unit 10g can be omitted for the purpose of reducing the amount of calculation. For example, the adjustment process of the tonality of the generated high frequency signal can be omitted.

  The subband signal power calculator 24b calculates the power of the subband signal of the pseudo high frequency signal generated by the pseudo high frequency signal generator 24a (step S24-2).

  The time envelope information encoding unit 24c calculates the time envelope of the high frequency signal using the power of the sub band signal of the high frequency signal calculated by the envelope calculating unit 20 e, and the calculation is performed by the sub band signal power calculation unit 24 b. The temporal envelope of the pseudo high frequency signal is calculated using the power of the subband signal of the pseudo high frequency signal, and the temporal envelope information is calculated and encoded from the temporal envelope of the high frequency signal and the temporal envelope of the pseudo high frequency signal ( Step S24-3). In the process, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal can be calculated by the time envelopment information coding unit 24c, and the sub band signal of the high frequency signal It is not limited where the power of is calculated.

  For example, the time envelope of the high frequency signal can be calculated by the same process as the process of the time envelope information encoding unit 21a calculating the time envelope of the high frequency signal. The temporal envelope of the sub-band signal of the high frequency signal may be a parameter that can be used to indicate the temporal variation of the magnitude of the sub-band signal of the high frequency signal, and is not limited to the above example.

擬似高周波数信号のサブバンド信号の時間包絡は、擬似高周波数信号のサブバンド信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, B _{sim, gen, HI} (m) (m = 0, ..., M _{sim, gen, HI} , M _{sim, gen} ) within any time segment t _E (l) i i <t _E (l + 1) _{, HI} 1 1) M _{sim, gen, HI} pieces whose boundaries are represented by (B _{sim, gen, HI} (0) k k _x , B _{sim, gen, HI} (M _{sim, gen, HI} ) <k _h ) Subband signal X _{sim, gen, HI} (k, i) (B _{sim, gen, HI} (m) ≦ k <B _sim, Temporal envelope E _{sim, gen, HI} (k, i) of _{gen, HI} (m + 1), t _E (l) ≦ i <t _E (l + 1) is calculated.

The temporal envelope of the sub-band signal of the pseudo high frequency signal may be any parameter as long as the variation in the time direction of the magnitude of the sub band signal of the pseudo high frequency signal can be understood, and is not limited to the above example.

For example, in the processing in which the time envelope information encoding unit 20g calculates information indicating the degree of flatness as time envelope information, the time of the subband signal of the high frequency signal instead of the time envelope of the subband signal of the low frequency signal By using the envelope and further using the time envelope of the subband signal of the pseudo high frequency signal instead of the time envelope of the subband signal of the core decoded signal, it is possible to calculate information representing the degree of flatness as time envelope information, Also, the time envelope information can be encoded. For example, if the degree of flatness of the time envelopment is expressed by whether it is flat or not, it can be encoded with one bit, for example, the information may be M for every M _{sim, gen, HI} frequency bands in the arbitrary time segment. _It can be encoded with _{sim, gen and HI} bits.

Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates information representing the degree of rising as time envelopment information, the sub band signal of the high frequency signal instead of the time envelopment of the sub band signal of the low frequency signal. Calculating the information indicating the degree of rising as time envelope information by using the time envelope of the core decoded signal and using the time envelope of the subband signal of the pseudo high frequency signal instead of the time envelope of the subband signal of the core decoded signal And the time envelope information can be encoded. For example, if the degree of rising of the time envelopment is expressed by whether it is rising or not, it can be encoded by one bit, for example, the information may be M for every M _{sim, gen, HI} frequency bands in the arbitrary time segment. _It can be encoded with _{sim, gen and HI} bits.

Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates information representing the degree of fall as time envelopment information, the subband of the high frequency signal instead of the temporal envelope of the subband signal of the low frequency signal. Information indicating the degree of fall as time envelope information by using the time envelope of the signal and further using the time envelope of the sub band signal of the pseudo high frequency signal instead of the time envelope of the sub band signal of the core decoded signal Can be calculated and the time envelope information can be encoded. For example, if the degree of falling of the time envelopment is expressed as falling or not, it can be encoded by one bit, for example, the information for each of the M _{sim, gen and HI} frequency bands in the arbitrary time segment Can be encoded with M _{sim, gen, HI} bits.

  Note that the method of calculating time envelope information and the encoding method are not limited to the above examples. Further, it is apparent that the first modification of the speech to digital converter according to the fourth embodiment of the present invention can be applied to the speech to digital converter according to the present embodiment.

First Modification of Speech Decoding Device According to Fifth Embodiment
FIG. 39 is a diagram showing the configuration of the first modification 14A of the speech decoding device according to the fifth embodiment.

  FIG. 40 is a flowchart showing an operation of the first modification 14A of the speech decoding device according to the fifth embodiment.

  The high frequency temporal envelope shape determination unit 14b receives information on the high frequency temporal envelope shape from the coding sequence analysis unit 13c, a low frequency signal from the core decoding unit 10b, a plurality of subband signals of low frequency signals from the analysis filter bank unit 10c, At least one of the plurality of sub-band signals of the high frequency signal is received from the frequency signal generation unit 10g, and the time envelope shape of the high frequency signal is determined (step S14-2). For example, the time envelope shape of the high frequency signal is determined to be flat. Furthermore, for example, the time envelope shape of the high frequency signal is determined to be rising. Furthermore, for example, the time envelope shape of the high frequency signal is determined to be falling. The difference with the high frequency time envelope shape determination unit 13aC of the third modification 13C of the speech decoding device according to the fourth embodiment of the present invention is that the high frequency signal generation unit 10g receives a plurality of sub A band signal is also acceptable, and the high frequency time envelope shape can be determined from the high frequency signal sub band signal in the same manner as the low frequency signal sub band signal.

Sixth Embodiment
FIG. 41 is a diagram showing the configuration of the speech decoding device 15 according to the sixth embodiment. The communication device of the speech decoding device 15 receives the multiplexed coded sequence output from the speech coding device 25 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 41, the speech decoding apparatus 15 functionally includes a coded sequence demultiplexing unit 10aA, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a high frequency signal generation unit. 10g, a decoding / inverse quantization unit 10h, a frequency envelope adjustment unit 10i, a high frequency time envelope shape determination unit 13a, a time envelope correction unit 15a, and a synthesis filter bank unit 10j.

  FIG. 42 is a flowchart showing an operation of the speech decoding device 15 according to the sixth embodiment.

  The time envelope correction unit 15a corrects the shape of the time envelope of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i based on the time envelope shape determined by the high frequency time envelope shape determination unit 13a. (Step S15-1).

により得られるX’_adj,HI(k,i)を時間包絡形状が修正された高周波数信号のサブバンド信号として出力する。 For example, B _HI (m) (m = 0,..., M _HI , M _HI 11) in any time segment t _E (l) ≦ i <t _E (l + 1) (B _HI (0) ≧ The high frequency signal output from the frequency envelope adjustment unit 10i is divided into M _HI frequency bands represented by k _x , B _HI (M _HI ) <K _h ), and included in the m th frequency band Subband signals X _{adj, HI} (k, i) (B _{adj, HI} (m) ≦ k <B _{adj, HI} (m + 1), t _E (l) ≦ i <t _E (l + 1)) In contrast, the following equation (37) is obtained using a predetermined function F ( _{X.sub.adj, HI} (k, i)).

And X ′ _{adj, HI} (k, i) obtained by the above are output as sub-band signals of a high frequency signal whose temporal envelope shape is corrected.

For example, when the temporal envelope shape of the high frequency signal is determined to be flat, the temporal envelope shape of the high frequency signal can be corrected by the following processing. For example, in the process of correcting the time envelope shape in the time envelope correction unit 14a to be flat, the frequency envelope adjustment unit 10i is output instead of the sub-band signal of the high frequency signal output from the high frequency signal generation unit 10g. high frequency signals of the sub-band signals X _adj, by using _HI (k, i), the high frequency signal of the sub-band signals X _adj output from the frequency envelope adjuster _10i, the time envelope of _HI (k, i) The shape can be corrected flat. The time envelope correction unit 15a performs processing for correcting the shape of the time envelope of the plurality of sub-band signals of the high frequency signal to be flat, and is not limited to the above example.

Furthermore, for example, when the time envelope shape of the high frequency signal is determined to be rising, the time envelope shape of the high frequency signal can be corrected by the following processing. For example, in the process of correcting the time envelopment shape in the time envelopment correction unit 14a to rise, the frequency envelope adjustment unit 10i is output instead of the sub-band signal of the high frequency signal output from the high frequency signal generation unit 10g. high frequency signals of the sub-band signals X _adj, by using _HI (k, i), the high frequency signal of the sub-band signals X _adj output from the frequency envelope adjuster _10i, the time envelope of _HI (k, i) The shape can be corrected to stand up. The time envelope correction unit 15a performs a process of correcting the shape of the time envelope of the plurality of sub-band signals of the high frequency signal into a rising edge, and is not limited to the above example.

Furthermore, for example, when the temporal envelope shape of the high frequency signal is determined to be falling, the temporal envelope shape of the high frequency signal can be corrected by the following processing. For example, in the process of correcting the time envelope shape in the time envelope correction unit 14a to fall, the frequency envelope adjustment unit 10i is output instead of the sub-band signal of the high frequency signal output from the high frequency signal generation unit 10g. high frequency signals of the sub-band signals X _{adj that,} by using _HI (k, i), the frequency envelope adjuster 10i high frequency signal of the sub-band signals X _adj output _{from, HI} (k, i) of the time The envelope shape can be corrected to fall. The time envelope correction unit 15a performs a process of correcting the shape of the time envelope of the plurality of sub-band signals of the high frequency signal to fall, and is not limited to the above example.

  In addition, the first, second, and third modified examples of the speech decoding apparatus according to the fourth embodiment of the present invention with respect to the high frequency time envelope shape determination unit 13a of the speech decoding apparatus 15 according to the present embodiment. And it is obvious that the first modification of the speech decoding device of the fifth embodiment of the present invention can be applied.

  FIG. 43 is a diagram showing the configuration of the speech to digital converter 25 according to the sixth embodiment. The communication apparatus of the speech coding apparatus 25 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 43, the speech encoding apparatus 25 functionally includes a downsampling unit 20a, a core encoding unit 20b, an analysis filter bank unit 20c, a control parameter encoding unit 20d, an envelope calculation unit 20e, and quantization. / Coding unit 20f, pseudo high frequency signal generation unit 24a, subband signal power calculation unit 24b, frequency envelope adjustment unit 25a, time envelope information coding unit 25b, and coding sequence multiplexing unit 20h.

  FIG. 44 is a flowchart showing the operation of the speech to digital converter 25 according to the sixth embodiment.

  The frequency envelope adjustment unit 25a is a control parameter necessary for adjusting the frequency envelope of the high frequency signal obtained by the control parameter coding unit 20d, and a gain and noise signal for the high frequency signal quantized by the quantization / coding unit 20f. The frequency envelope of the pseudo high frequency signal generated by the pseudo high frequency signal generation unit 24a is adjusted based on the magnitude of (step S25-1). The frequency envelope adjustment processing of the pseudo high frequency signal is performed in the same manner as the processing in the frequency envelope adjustment unit 10i, but in the frequency envelope adjustment unit 10i, a subband signal of the high frequency signal generated by the high frequency signal generation unit 10g. However, the frequency envelope adjustment unit 25a is different from that performed on the sub-band signal of the pseudo high frequency signal generated by the pseudo high frequency signal generation unit 24a. In the frequency envelope adjustment unit 25a, part of the processing in the frequency envelope adjustment unit 10i can be omitted for the purpose of reducing the amount of calculation. For example, the process of adding a sine wave signal can be omitted. Furthermore, for example, the process of adding a noise signal can be omitted. In this case, the process of adjusting the magnitude of the noise signal can also be omitted.

  The time envelopment information encoding unit 25b calculates the time envelopment of the high frequency signal using the power of the sub band signal of the high frequency signal calculated by the envelope calculation unit 20 e, and the calculation is performed by the sub band signal power calculation unit 24 b. The time envelope of the pseudo high frequency signal is calculated using the power of the sub band signal of the pseudo high frequency signal whose frequency envelope has been adjusted, and the time envelope information is encoded from the time envelope of the high frequency signal and the time envelope of the pseudo high frequency signal Step S25-2). In the processing, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal can be calculated by the time envelopment information encoding unit 25b, and the sub band signal of the high frequency signal It is not limited where the power of is calculated.

  For example, the time envelope of the high frequency signal can be calculated by the same process as the process of the time envelope information encoding unit 21a calculating the time envelope of the high frequency signal. The temporal envelope of the sub-band signal of the high frequency signal may be a parameter that can be used to indicate the temporal variation of the magnitude of the sub-band signal of the high frequency signal, and is not limited to the above example.

擬似高周波数信号のサブバンド信号の時間包絡は、擬似高周波数信号のサブバンド信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, B _{sim, adj, HI} (m) (m = 0, ..., M _{sim, adj, HI} , M _{sim, adj} ) within any time segment t _E (l) i i <t _E (l + 1) _{, HI} 1 1) M _{sim, adj, HI} pieces whose boundaries are represented by (B _{sim, adj, HI} (0) k k _x , B _{sim, adj, HI} (M _{sim, adj, HI} ) <k _h ) Subband signal X _{sim, adj, HI} (k, i) (B _{sim, adj, HI} (m) k k <B _sim, divided into frequency bands and included in the m th frequency band) Temporal envelope E _{sim, adj, HI} (k, i) of _{adj, HI} (m + 1), t _E (l) ≦ i <t _E (l + 1) is calculated.

The temporal envelope of the sub-band signal of the pseudo high frequency signal may be any parameter as long as the variation in the time direction of the magnitude of the sub band signal of the pseudo high frequency signal can be understood, and is not limited to the above example.

For example, in the processing in which the time envelope information encoding unit 20g calculates information indicating the degree of flatness as time envelope information, the time of the subband signal of the high frequency signal instead of the time envelope of the subband signal of the low frequency signal By using the envelope and further using the time envelope of the subband signal of the pseudo high frequency signal instead of the time envelope of the subband signal of the core decoded signal, it is possible to calculate information representing the degree of flatness as time envelope information, Also, the time envelope information can be encoded. For example, if the degree of flatness of the temporal envelope is expressed by whether it is flat or not, it can be encoded with one bit. For example, the information may be M for every M _{sim, adj, HI} frequency bands in the arbitrary time segment. _It can be encoded with _{sim, adj, HI} bits.

Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates information representing the degree of rising as time envelopment information, the sub band signal of the high frequency signal instead of the time envelopment of the sub band signal of the low frequency signal. Calculating the information indicating the degree of rising as time envelope information by using the time envelope of the core decoded signal and using the time envelope of the subband signal of the pseudo high frequency signal instead of the time envelope of the subband signal of the core decoded signal And the time envelope information can be encoded. For example, if the degree of rising of the time envelopment is expressed by whether it is rising or not, it can be encoded with one bit, for example, the information may be M for every M _{sim, adj, HI} frequency bands in the arbitrary time segment. _It can be encoded with _{sim, adj, HI} bits.

Furthermore, for example, in the processing in which the time envelopment information encoding unit 20g calculates information representing the degree of fall as time envelopment information, the subband of the high frequency signal instead of the temporal envelope of the subband signal of the low frequency signal. Information indicating the degree of fall as time envelope information by using the time envelope of the signal and further using the time envelope of the sub band signal of the pseudo high frequency signal instead of the time envelope of the sub band signal of the core decoded signal Can be calculated and the time envelope information can be encoded. For example, if the degree of falling of the time envelope is expressed by whether it is falling or not, it can be encoded with one bit, for example, the information for every M _{sim, adj, HI} frequency bands within the arbitrary time segment. Can be encoded with M _{sim, adj, HI} bits.

  Note that the method of calculating time envelope information and the encoding method are not limited to the above examples. Further, it is apparent that the first modification of the speech to digital converter according to the fourth embodiment of the present invention can be applied to the speech to digital converter according to the present embodiment.

First Modification of Speech Decoding Device According to Sixth Embodiment
FIG. 45 is a diagram showing the configuration of the first modification 15A of the speech decoding device according to the sixth embodiment.

  FIG. 46 is a flowchart showing an operation of the first modification 15A of the speech decoding device according to the sixth embodiment.

  In the present modification, the frequency envelope adjustment unit 10i separates and outputs at least one or more of the components constituting the high frequency signal. For example, the components constituting the high frequency signal are a high frequency signal component generated from the low frequency signal, a noise signal component, and a sine wave signal component.

  The time envelope correction unit 15aA generates at least one of the components constituting the high frequency signal output in a separated form from the frequency envelope adjustment unit 10i based on the time envelope shape determined by the high frequency time envelope shape determination unit 13a. The above time envelope shape is corrected, and a high frequency signal is synthesized from each component of the high frequency signal including the component whose time envelope shape is corrected (step S15-1a).

により、前記高周波数信号のうち任意の成分の信号のサブバンド信号X_shp,dj,HI(k,i)の時間包絡形状を修正した成分のサブバンド信号X’_shp,adj,HI(k,i)を得る。そして、当該時間包絡形状を修正した成分のサブバンド信号と時間包絡形状の修正が施されない他の成分の信号とで高周波数信号を合成し、高周波数信号を出力する。 For example, a sub-band signal X _{shp, dj, HI} (k, i) (B _{shp, adj, HI} (m) of an arbitrary component signal of high frequency signals separated and output from the frequency envelope adjustment unit 10i) For a predetermined function F (X _{shp, adj, HI} (k, i) for ≦ k <B _{shp, adj, HI} (m + 1), t _E (l) ≦ i <t _E (l + 1) The following equation (39) using))

The sub-band signal X ' _{shp, adj, HI} (k, i (k, i) is a component obtained by correcting the temporal envelope shape of the sub-band signal X _{shp, dj, HI} (k, i) of the signal of any component of the high frequency signal. i) get. Then, a high frequency signal is synthesized with the sub-band signal of the component in which the time envelopment shape is corrected and the signal of the other component in which the time envelopment shape is not corrected.

  In addition, when the component by which a time envelope shape is corrected is multiple, each or some of that can be corrected to a different time envelope shape. Furthermore, the signal of the component whose temporal envelope shape is to be corrected may be a signal of the sum of the signals of a plurality of components, for example, the sum of a high frequency signal component generated from a low frequency signal and a noise signal component it can.

  In addition, the first, second, and third modified examples of the speech decoding device according to the fourth embodiment of the present invention with respect to the high-frequency time envelope shape determining unit 13a of the speech decoding device 15A according to the present modification. And it is obvious that the first modification of the speech decoding device of the fifth embodiment of the present invention can be applied.

Seventh Embodiment
FIG. 47 is a diagram showing the configuration of the speech decoding device 16 according to the seventh embodiment. The communication device of the speech decoding device 16 receives the multiplexed coded sequence output from the speech coding device 26 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 47, the speech decoding apparatus 16 functionally has a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a low frequency time envelope shape. Decision unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, time envelope correction unit 13b, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, and synthesis A filter bank unit 10 j is provided.

  FIG. 48 is a flowchart showing an operation of the speech decoding apparatus according to the seventh embodiment.

  The first, second, and third variants of the speech decoding apparatus according to the first embodiment of the present invention are the same as the low frequency time envelope shape determination unit 10e of the speech decoding apparatus 16 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding apparatus 16 according to the present embodiment, the first, second, and third modified examples of the speech decoding apparatus according to the fourth embodiment of the present invention It is obvious that is applicable.

  FIG. 49 is a diagram showing the configuration of the speech to digital converter 26 according to the seventh embodiment. The communication device of the speech coding device 26 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 49, the speech encoding apparatus 26 functionally includes a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, a control parameter encoding unit 20d, an envelope calculation unit 20e, A quantization / coding unit 20f, a core decoded signal generation unit 20i, a subband signal power calculation unit 20j, a time envelope information coding unit 26a, and a coding sequence multiplexing unit 20h are provided.

  FIG. 50 is a flowchart showing an operation of the speech to digital converter 26 according to the seventh embodiment.

  The time envelopment information encoding unit 26a calculates at least one or more of the time envelopment of the low frequency signal and the time envelopment of the high frequency signal, and further, the core decoded signal calculated by the sub band signal power calculation unit 20j. The time envelope of the core decoded signal is calculated using the power of the subband signal, and the time envelope information is calculated from the time envelope of the low frequency signal and the time envelope of the high frequency signal and the time envelope of the core decoded signal Encoding is performed (step S26-1).

  The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information.

  The temporal envelope of the low frequency signal is calculated using the power of the sub-band signal of the low frequency signal calculated by the envelope calculation unit 20 e. The temporal envelope of the high frequency signal is calculated using the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20 e. In the processing, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal can be calculated by the time envelopment information encoding unit 26a, and the sub band signal of the low frequency signal It is not limited where the power of is calculated. Furthermore, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal can be calculated by the time envelopment information encoding unit 26a. It is not limited where the power is calculated.

  For example, low frequency temporal envelope information can be calculated and encoded in the same manner as the operation of the temporal envelope information coding unit 20g, and high frequency temporal envelope information can be calculated and the code in the same manner as the operation of the temporal envelope information coding unit 23a. Can be The calculation coding of the low frequency time envelope information and the high frequency time envelope information is not limited to the above example.

  The low frequency temporal envelope information and the high frequency temporal envelope information may be separately encoded or may be encoded together, and in the present invention, a code of the low frequency temporal envelope information and the high frequency temporal envelope information The method of conversion is not limited.

  For example, the low frequency temporal envelope information and the high frequency temporal envelope information can be treated as a vector and encoded by vector quantization. Furthermore, for example, the vector can be entropy coded.

  Furthermore, the low frequency time envelope information and the high frequency time envelope information may be set as the same time envelope information. In this case, the same time envelope information from the coding sequence analysis unit 10d of the speech decoding device 16 has a low frequency. It is output as temporal envelope information and high frequency temporal envelope information. In the present invention, the forms of the low frequency time envelope information and the high frequency time envelope information are not limited.

[First Modification of Speech Decoding Device of Seventh Embodiment]
FIG. 51 is a diagram showing the configuration of the first modification 16A of the speech decoding apparatus according to the seventh embodiment.

  FIG. 52 is a flowchart showing an operation of the first modification 16A of the speech decoding apparatus according to the seventh embodiment.

  The high frequency temporal envelope shape determination unit 16a receives information on the high frequency temporal envelope shape from the coding sequence analysis unit 13c, a low frequency signal from the core decoding unit 10b, and a plurality of subband signals of low frequency signals from the analysis filter bank unit 10c, At least one of the plurality of sub-band signals of the low frequency signal whose time envelope shape has been corrected is received from the frequency time envelope correction unit 10f, and the time envelope shape of the high frequency signal is determined (step S16-1). For example, there may be a case where the time envelope shape of the high frequency signal is determined to be flat, a case where the time envelope shape of the high frequency signal is determined to be rising, and a case where the time envelope shape of the high frequency signal is determined to be falling. The difference with the high-frequency time envelope shape determination unit 13aC of the third modification 13C of the speech decoding device according to the fourth embodiment is that the time envelope shape is corrected low from the low-frequency time envelope correction unit 10f as an input. A plurality of sub-band signals of the frequency signal is also acceptable, and from the sub-band signal of the low-frequency signal, high frequency time is also obtained by the same method as the sub-band signal of the low frequency signal from the analysis filter bank unit 10c. The envelope shape can be determined.

[Second Modification of Speech Decoding Device of Seventh Embodiment]
FIG. 153 is a diagram showing the configuration of the second modification 16B of the speech decoding apparatus according to the seventh embodiment.

  FIG. 154 is a flowchart showing an operation of the second modification 16B of the speech decoding device according to the seventh embodiment.

  In the present modification, the difference between the low frequency time envelope shape determination unit 16b and the low frequency time envelope shape determination unit 10eC is that the determined low frequency envelope shape is also notified to the time envelope correction unit 16c. The determination of the temporal envelope shape in the low frequency temporal envelope shape determination unit 16b may be based on, for example, the frequency power distribution of the low frequency signal, in addition to the above example.

  Furthermore, it is apparent that the same modification can be applied to the low frequency time envelope shape determination units 10e, 10eA and 10eB.

  The difference between the time envelope correction unit 16c and the time envelope correction unit 13b is the time envelope shape and the low frequency time envelope shape determination received from the high frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, 13aB may be used) The shape of the time envelope of a plurality of subband signals output from the analysis filter bank unit 10c and used to generate high frequency signals in the high frequency signal generation unit 10g based on at least one or more of the time envelope shapes received from the unit 16b (S16-2).

  For example, when the information of the time envelope shape that is flat is received from the low frequency time envelope shape determination unit 16b, the analysis filter bank unit 10c does not depend on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. Correct the shape of the time envelope of the plurality of sub-band signals output from B. Furthermore, for example, when the information of the time envelope shape that is not flat is received from the low frequency time envelope shape determination unit 16b, the analysis filter bank unit 10c does not depend on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. The shape of the temporal envelope of the plurality of sub-band signals output from V.2 is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

[Third Modification of Speech Decoding Device of Seventh Embodiment]
FIG. 155 is a diagram showing a configuration of the third modification 16C of the speech decoding device according to the seventh embodiment.

  FIG. 156 is a flowchart showing an operation of the third modification 16C of the speech decoding device according to the seventh embodiment.

  In this modification, the difference between the high frequency time envelope shape determination unit 16 d and the high frequency time envelope shape determination unit 13 a C is that the determined high frequency envelope shape is also notified to the low frequency time envelope correction unit 16 e. is there.

  The determination of the temporal envelope shape in the high frequency temporal envelope shape determination unit 16d may be based on, for example, the frequency power distribution of the low frequency signal, in addition to the above example. Furthermore, it is possible to use, for example, the frame length at the time of generation of the high frequency signal obtained from the coded sequence analysis unit 13c. For example, it can be determined that the frame length is flat when the frame length is long, and rising or falling when the frame length is short. As an example of the frame length at the time of generation of the high frequency signal, a length of "time segment" which can be determined by "time border" defined in "ISO / IEC 14496-3" can be mentioned. Furthermore, it is apparent that the same modification can be applied to the high frequency time envelope shape determination units 13a, 13aA, and 13aB.

  The difference between the low frequency time envelope correction unit 16e and the low frequency time envelope correction unit 10f is the time envelope shape and high frequency received from the low frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA, 10eB may be used) The point is to correct the shape of the time envelope of the plurality of subband signals output from the analysis filter bank unit 10c based on at least one or more of the time envelope shapes received from the time envelope shape determination unit 16d (S16-3 ).

  For example, when the information on the time envelope shape that is flat is received from the high frequency time envelope shape determination unit 16d, the analysis filter bank unit 10c does not depend on the time envelope shape received from the low frequency time envelope shape determination unit 10eC. Correct the shape of the time envelope of the plurality of sub-band signals output from B. Furthermore, for example, when the information of the time envelope shape not flat is received from the high frequency time envelope shape determination unit 16d, the analysis filter bank unit does not depend on the time envelope shape received from the low frequency time envelope shape determination unit 10eC. The shape of the temporal envelope of the plurality of subband signals output from 10c is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

Fourth Modification of Speech Decoding Device of Seventh Embodiment
FIG. 157 is a diagram showing the configuration of the fourth modification 16D of the speech decoding device according to the seventh embodiment.

  FIG. 158 is a flowchart showing an operation of the fourth modification 16D of the speech decoding device according to the seventh embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 16c, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fifth Modification of Speech Decoding Device of Seventh Embodiment]
FIG. 159 is a diagram showing a configuration of the fifth modification 16E of the speech decoding device according to the seventh embodiment.

  FIG. 160 is a flowchart showing the operation of the fifth modification 16E of the speech decoding device according to the seventh embodiment.

  The difference between the present modification and the speech decoding apparatus 16 according to the seventh embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

  The time envelopment shape determination unit 16f includes information on the low frequency time envelopment shape from the coding sequence demultiplexing unit 10a, a low frequency signal from the core decoding unit 10b, and a plurality of sub-ranges of low frequency signals from the analysis filter bank unit 10c. The temporal envelope shape is determined based on at least one or more of the band signal and the information on the high frequency temporal envelope shape from the coding sequence analysis unit 13c (S16-4). The determined time envelope shape is notified to the low frequency time envelope correction unit 10 f and the time envelope correction unit 13 b.

  For example, it is determined that the time envelope shape is flat. Further, for example, it is determined that the time envelope shape is rising. Furthermore, for example, it is determined as falling as the time envelope shape. The temporal envelope shape to be determined is not limited to the above example.

  In the time envelope shape determination unit 16f, for example, similar to the low frequency time envelope shape determination units 10e, 10eA, 10eB, 10eC, and 16b, and the high frequency time envelope shape determination units 13a, 13aA, 13aB, 13aC, and 16d. The time envelope shape can be determined. The method of determining the temporal envelope shape is not limited to the above example.

[First Modification of Speech Encoding Apparatus of Seventh Embodiment]
FIG. 53 is a diagram showing the configuration of the first modification 26A of the speech encoding device according to the seventh embodiment.

  FIG. 54 is a flowchart showing an operation of the first modification 26A of the speech to digital converter according to the seventh embodiment.

  The time envelopment information encoding unit 26aA calculates at least one of the time envelopment of the low frequency signal and the time envelopment of the high frequency signal, and at least one of the time envelops of the low frequency signal and the high frequency signal. Time envelope information is calculated and encoded (step S26-1a).

  The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information. Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of encoding the low frequency time envelope information and the high frequency time envelope information is not limited.

  The temporal envelope of the low frequency signal is calculated using the power of the sub-band signal of the low frequency signal calculated by the envelope calculation unit 20 e.

  The temporal envelope of the high frequency signal is calculated using the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20 e.

  In the process, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal may be calculated by the time envelopment information encoding unit 26aA. It is not limited where the power of the subband signal is calculated.

  Furthermore, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal may be calculated by the time envelopment information encoding unit 26aA. It is not limited where the power of the band signal is calculated.

  For example, low frequency temporal envelope information can be calculated and encoded in the same manner as the operation of the temporal envelope information coding unit 20gA, and high frequency temporal envelope information can be calculated and the code in the same manner as the operation of the temporal envelope information coding unit 23aA Can be The calculation coding of the low frequency time envelope information and the high frequency time envelope information is not limited to the above example.

  Furthermore, the low frequency temporal envelope information and the high frequency temporal envelope information can be the same temporal envelope information as in the operation of the temporal envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment. .

Eighth Embodiment
FIG. 55 is a diagram showing the configuration of the speech decoding device 17 according to the eighth embodiment. The communication device of the speech decoding device 17 receives the multiplexed coded sequence output from the speech coding device 27 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 55, the speech decoding apparatus 17 functionally includes a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a low frequency time envelope shape. Decision unit 10e, low frequency time envelope correction unit 10f, high frequency signal generation unit 10g, high frequency time envelope shape determination unit 13a, time envelope correction unit 14a, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, and synthesis A filter bank unit 10 j is provided.

  FIG. 56 is a flowchart showing an operation of the speech decoding apparatus according to the eighth embodiment.

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low frequency time envelope shape determination unit 10e of the speech decoding device 17 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 17 according to the present embodiment, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 57 is a diagram showing the configuration of the speech to digital converter 27 according to the eighth embodiment. The communication device of the speech coding device 27 externally receives a speech signal to be coded, and further outputs the coded coded sequence to the outside. As shown in FIG. 57, the speech encoding apparatus 27 functionally includes a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, a control parameter encoding unit 20d, an envelope calculation unit 20e, The quantization / coding unit 20f, the pseudo high frequency signal generation unit 24a, the core decoded signal generation unit 20i, the subband signal power calculation units 20j and 24b, the time envelope information coding unit 27a, and the coding sequence multiplexing unit 20h Prepare.

  FIG. 58 is a flowchart showing the operation of the speech to digital converter 27 according to the eighth embodiment.

  The time envelopment information encoding unit 27a calculates at least one or more of the time envelopment of the low frequency signal of the input speech signal, the time envelopment of the high frequency signal, the time envelopment of the core decoded signal, and the time envelopment of the pseudo high frequency signal The time envelope information is encoded from the calculated time envelope (step S27-1).

  The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information.

  The temporal envelope of the low frequency signal is calculated using the power of the sub-band signal of the low frequency signal calculated by the envelope calculation unit 20 e. The temporal envelope of the high frequency signal is calculated using the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20 e. In the processing, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal can be calculated by the time envelopment information encoding unit 27a, and the sub band signal of the low frequency signal It is not limited where the power of is calculated. Furthermore, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal can be calculated by the time envelopment information coding unit 27a. It is not limited where the power is calculated.

  The time envelope of the core decoded signal is calculated using the power of the sub-band signal of the core decoded signal calculated by the sub-band signal power calculation unit 20j.

  The temporal envelope of the pseudo high frequency signal is calculated using the power of the sub band signal of the pseudo high frequency signal calculated by the sub band signal power calculation unit 24b.

  For example, the time envelope information of the low frequency signal can be calculated and encoded in the same manner as the operation of the time envelope information coding unit 20g, and the time of the high frequency signal can be calculated as in the operation of the time envelope information coding unit 24c. Envelope information can be calculated and encoded.

  Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of calculating and encoding the low frequency time envelope information and the high frequency time envelope information is not limited.

  Furthermore, low-frequency temporal envelope information and high-frequency temporal envelope information can be the same temporal envelope information as in the temporal envelope information coding unit 26a of the speech to digital converter 26 of the seventh embodiment.

  It is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 27 according to the present embodiment.

First Modification of Speech Decoding Device According to Eighth Embodiment
FIG. 161 is a diagram showing the configuration of the first modification 17A of the speech decoding apparatus according to the eighth embodiment.

  FIG. 162 is a flowchart showing an operation of the first modification 17A of the speech decoding device according to the eighth embodiment.

  In this modification, the difference between the time envelope correction unit 17a and the time envelope correction unit 14a is the time envelope shape received from the high frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, 13aB may be used) Based on at least one or more of time envelope shapes received from low frequency time envelope shape determination unit 16b, the shape of the time envelope of a plurality of sub-band signals of the high frequency signal output from high frequency signal generation unit 10g is corrected It is a point (S17-1).

  For example, when the information of the time envelope shape that is flat is received from the low frequency time envelope shape determination unit 16b, the high frequency signal generation unit is not based on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. The shape of the temporal envelope of a plurality of subband signals output from 10g is corrected to be flat. Furthermore, for example, when the information of the time envelope shape that is not flat is received from the low frequency time envelope shape determination unit 16b, the high frequency signal generation unit is not based on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. The shape of the temporal envelope of a plurality of subband signals output from 10g is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

Second Modification of Speech Decoding Device According to Eighth Embodiment
FIG. 163 is a diagram showing the configuration of the second modification 17B of the speech decoding device according to the eighth embodiment.

  FIG. 164 is a flowchart showing an operation of the second modification 17B of the speech decoding device according to the eighth embodiment.

  The difference between the present modification and the speech decoding apparatus 17 according to the eighth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of Eighth Embodiment]
FIG. 165 is a diagram showing the configuration of the third modification 17C of the speech decoding device according to the eighth embodiment.

  FIG. 166 is a flowchart showing an operation of the third modification 17C of the speech decoding device according to the eighth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 17a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

Fourth Modification of Speech Decoding Device of Eighth Embodiment
FIG. 167 is a diagram showing the configuration of the fourth modification 17D of the speech decoding device according to the eighth embodiment.

  FIG. 168 is a flowchart showing an operation of the fourth modification 17D of the speech decoding device according to the eighth embodiment.

  The difference between the present modification and the speech decoding apparatus 17 according to the eighth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

The ninth embodiment
FIG. 59 is a diagram showing the configuration of the speech decoding device 18 according to the ninth embodiment. The communication device of the speech decoding device 18 receives the multiplexed coded sequence output from the speech coding device 28 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 59, the speech decoding apparatus 18 functionally includes a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a low frequency time envelope shape. Decision unit 10e, low frequency time envelope correction unit 10f, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, high frequency time envelope shape determination unit 13a, time envelope correction unit 14a, and synthesis A filter bank unit 10 j is provided.

  FIG. 60 is a flowchart showing the operation of the speech decoding apparatus according to the ninth embodiment.

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding device 18 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 18 according to the present embodiment, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 61 is a diagram showing the configuration of the speech to digital converter 28 according to the ninth embodiment. The communication device of the speech coding device 28 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 61, the speech encoding apparatus 28 functionally includes a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, a control parameter encoding unit 20d, an envelope calculation unit 20e, Quantization / coding unit 20f, pseudo high frequency signal generation unit 24a, frequency envelope adjustment unit 25a, core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, time envelope information coding unit 27a, and coding A sequence multiplexing unit 20h is provided.

  FIG. 62 is a flowchart showing the operation of the speech to digital converter 28 according to the ninth embodiment.

  The temporal envelope information encoding unit 28a performs at least one of the temporal envelope of the low frequency signal of the input speech signal, the temporal envelope of the high frequency signal, the temporal envelope of the core decoding signal, and the temporal envelope of the pseudo high frequency signal whose frequency is adjusted. One or more are calculated, and time envelope information is encoded from the calculated time envelope (step S28-1).

  The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information. Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of encoding the low frequency time envelope information and the high frequency time envelope information is not limited.

  The temporal envelope of the low frequency signal is calculated using the power of the sub-band signal of the low frequency signal calculated by the envelope calculation unit 20 e. The temporal envelope of the high frequency signal is calculated using the power of the sub-band signal of the high frequency signal calculated by the envelope calculation unit 20 e. In the processing, when the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal can be calculated by the time envelopment information encoding unit 28a, and the sub band signal of the low frequency signal It is not limited where the power of is calculated. Furthermore, when the power of the sub-band signal of the high frequency signal is not calculated, the power of the sub-band signal of the high frequency signal can be calculated by the time envelope information encoding unit 28a, and It is not limited where the power is calculated.

  The time envelope of the core decoded signal is calculated using the power of the subband signal of the core decoded signal calculated by the subband signal power calculation unit 20 j.

  The time envelope of the pseudo high frequency signal subjected to the frequency envelope adjustment is calculated using the power of the sub band signal of the pseudo high frequency signal calculated by the sub band signal power calculation unit 24b.

  For example, the time envelope information of the low frequency signal can be calculated and encoded in the same manner as the operation of the time envelope information encoding unit 20g, and the time of the high frequency signal can be calculated in the same manner as the operation of the time envelope information encoding unit 25b. Envelope information can be calculated and encoded.

  Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of calculating and encoding the low frequency time envelope information and the high frequency time envelope information is not limited.

  Furthermore, low-frequency temporal envelope information and high-frequency temporal envelope information can be the same temporal envelope information as in the temporal envelope information coding unit 26a of the speech to digital converter 26 of the seventh embodiment.

  It is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 28 according to this embodiment.

[First Modification of Speech Decoding Device of Ninth Embodiment]
FIG. 63 is a diagram showing the configuration of the first modification 18A of the speech decoding device according to the ninth embodiment.

  FIG. 64 is a flowchart showing an operation of the first modification 18A of the speech decoding device according to the ninth embodiment.

  The first, second, and third variants of the speech decoding apparatus according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding apparatus 18A according to the present modification. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 18A according to the present modification, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

Second Modification of Speech Decoding Device of Ninth Embodiment
FIG. 169 is a diagram showing the configuration of the second modification 18B of the speech decoding device according to the ninth embodiment.

  FIG. 170 is a flowchart showing an operation of the second modification 18B of the speech decoding device according to the ninth embodiment.

  In this modification, the difference between the time envelope correction unit 18a and the time envelope correction unit 15a is the time envelope shape received from the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, 13aB may be used) Correct the shape of the time envelope of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i based on at least one or more of the time envelope shapes received from the low frequency time envelope shape determination unit 16b (S18-1).

  For example, when the information on the time envelope shape that is flat is received from the low frequency time envelope shape determination unit 16b, the frequency envelope adjustment unit 10i is not based on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. Correct the shape of the time envelope of the plurality of sub-band signals output from B. Furthermore, for example, when the information of the time envelope shape that is not flat is received from the low frequency time envelope shape determination unit 16b, the frequency envelope adjustment unit 10i is not based on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. The shape of the temporal envelope of the plurality of sub-band signals output from V.2 is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

[Third Modification of Speech Decoding Device of Ninth Embodiment]
FIG. 171 is a diagram showing a configuration of the third modification 18C of the speech decoding device according to the ninth embodiment.

  FIG. 172 is a flowchart showing an operation of the third modification 18C of the speech decoding device according to the ninth embodiment.

  The difference between the present modification and the speech decoding apparatus 18 according to the ninth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

Fourth Modification of Speech Decoding Device of Ninth Embodiment
FIG. 173 is a diagram showing the configuration of the fourth modification 18D of the speech decoding device according to the ninth embodiment.

  FIG. 174 is a flowchart showing an operation of the fourth modification 18D of the speech decoding device according to the ninth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fifth Modification of Speech Decoding Device of Ninth Embodiment]
FIG. 175 is a diagram showing a configuration of the fifth modification 18E of the speech decoding device according to the ninth embodiment.

  FIG. 176 is a flowchart showing an operation of the fifth modification 18E of the speech decoding device according to the ninth embodiment.

  The difference between the present modification and the speech decoding apparatus 18 according to the ninth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

Sixth Modification of Speech Decoding Device of Ninth Embodiment
FIG. 177 is a diagram showing a configuration of the sixth modification 18F of the speech decoding device according to the ninth embodiment.

  FIG. 178 is a flowchart showing an operation of the sixth modification 18F of the speech decoding device according to the ninth embodiment.

  In this modification, the difference between the time envelope correction unit 18aA and the time envelope correction unit 15aA is the time envelope shape received from the high frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, 13aB may be used) Based on at least one or more of the time envelope shapes received from the low frequency time envelope shape determination unit 16b, at least one or more of the components constituting the high frequency signal separately output from the frequency envelope adjustment unit 10i The time envelope shape is corrected, and a high frequency signal is synthesized from each component of the high frequency signal including the component whose time envelope shape is corrected (S18-1a).

  For example, when the information on the time envelope shape that is flat is received from the low frequency time envelope shape determination unit 16b, the frequency envelope adjustment unit 10i is not based on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. The temporal envelope shape of at least one or more of the components constituting the high frequency signal output in a more separated form is corrected to be flat. Furthermore, for example, when the information of the time envelope shape that is not flat is received from the low frequency time envelope shape determination unit 16b, the frequency envelope adjustment unit 10i is not based on the time envelope shape received from the high frequency time envelope shape determination unit 13aC. The temporal envelope shape of at least one or more of the components constituting the high frequency signal output in a more separated form is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

Seventh Modification of Speech Decoding Device of Ninth Embodiment
FIG. 179 is a diagram showing a configuration of a seventh modification 18G of the speech decoding device according to the ninth embodiment.

  FIG. 180 is a flowchart showing an operation of the seventh modification 18G of the speech decoding device according to the ninth embodiment.

  The difference between the speech decoding apparatus 18A according to this modification and the first modification of the ninth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), and low. It is a point provided with the high frequency time envelope shape determination unit 16 d and the low frequency time envelope correction unit 16 e instead of the frequency time envelope correction unit 10 f.

Eighth Modification of Speech Decoding Device of Ninth Embodiment
FIG. 181 is a diagram showing the configuration of the eighth modification 18H of the speech decoding device according to the ninth embodiment.

  FIG. 182 is a flowchart showing an operation of the eighth modification 18H of the speech decoding device according to the ninth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18aA, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Ninth Modification of Speech Decoding Device of Ninth Embodiment]
FIG. 183 is a diagram illustrating the configuration of a ninth modification 18I of the speech decoding device according to the ninth embodiment.

  FIG. 184 is a flowchart showing an operation of the ninth modification 18I of the speech decoding device according to the ninth embodiment.

  The difference between the present modification and the speech decoding apparatus 18A according to the first modification of the ninth embodiment is that the time envelope shape is determined instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point equipped with the part 16f.

Tenth Embodiment
FIG. 65 is a diagram showing the configuration of the speech decoding device 1 according to the tenth embodiment. The communication device of the speech decoding device 1 receives the multiplexed encoded sequence output from the speech coding device 2 below, and further outputs the decoded speech signal to the outside. As shown in FIG. 65, the speech decoding apparatus 1 functionally includes a coded sequence analysis unit 1a, a speech decoding unit 1b, a time envelope shape determination unit 1c, and a time envelope correction unit 1d.

  FIG. 66 is a flowchart showing an operation of the speech decoding device 1 according to the tenth embodiment.

  The coded sequence analysis unit 1a analyzes the coded sequence and divides it into information on the speech coding portion and the time envelope shape (step S1-1).

  The speech decoding unit 1b decodes the speech coding part of the coded sequence to obtain a decoded signal (step S1-2).

  The temporal envelope shape determination unit 1c determines the temporal envelope shape of the decoded signal based on at least one or more of the information on the temporal envelope shape divided by the coding sequence analysis unit 1a and the decoded signal obtained by the speech decoding unit 1b. Are determined (step S1-3).

  For example, the temporal envelope shape of the decoded signal is determined to be flat. For example, the power of the decoded signal or a parameter according to it is calculated, and the variance of the parameter or a parameter according to it is calculated. The calculated parameter is compared with a predetermined threshold to determine whether the temporal envelope shape is flat or not, or the degree of flatness. In yet another example, the arithmetic mean of the power of the decoded signal or the parameter according to it or the ratio of the arithmetic mean or the parameter according to it is calculated, the temporal envelope shape is flat or not or flat according to the comparison with a predetermined threshold Determine the degree of The method of determining that the temporal envelope shape of the decoded signal is flat is not limited to the above example.

  Furthermore, for example, the time envelope shape of the decoded signal is determined to be rising. For example, the power of the decoded signal or a parameter corresponding thereto is calculated, the difference value in the time direction of the parameter is calculated, and the maximum value in an arbitrary time segment of the difference value is calculated. The maximum value is compared with a predetermined threshold value to determine whether the time envelopment shape is rising or not, or the degree of rising. The method of determining the time envelope shape of the decoded signal as rising is not limited to the above example.

  Furthermore, for example, the time envelope shape of the low frequency signal is determined to be falling. For example, the power of the decoded signal or a parameter equivalent thereto is calculated, the difference value in the time direction of the parameter is calculated, and the minimum value in any time segment of the difference value is calculated. The minimum value is compared with a predetermined threshold value to determine whether the temporal envelope shape is falling or not, or the degree of falling. The method of determining the time envelopment shape of the decoded number signal as falling is not limited to the above example.

  The above example can be applied even when the decoded signal is output as a time domain signal from the speech decoding unit 1b, and can be applied even when the decoded signal is output as a plurality of subband signals.

  The temporal envelope correction unit 1d corrects the shape of the temporal envelope of the decoded signal output from the speech decoding unit 1b based on the temporal envelope shape determined by the temporal envelope shape determination unit 1c (step S1-4).

により得られるX’_dec(k,i)を時間包絡形状が修正された復号信号のサブバンド信号として算出し，当該サブバンド信号より時間領域の信号を合成して出力する。 For example, when the decoded signal is represented by a plurality of subband signals, the time envelope correction unit 1 d is configured to generate a plurality of subband signals X _dec (k, i) (0 ≦ k) of the decoded signal in an arbitrary time segment. With respect to <k _h , t (l) ≦ i <t (l + 1), the following equation (40) is obtained using a predetermined function F (X _dec (k, i)):

The X ′ _dec (k, i) obtained by the above is calculated as a sub-band signal of the decoded signal whose time envelopment shape has been corrected, and a signal in the time domain is synthesized and output from the sub-band signal.

として、X’_dec(k,i)を時間包絡形状が修正された復号信号のサブバンド信号として算出する。
また別の例によれば、所定の関数F(X_dec(k,i))をサブバンド信号X_dec(k,i)に対して平滑化フィルタ処理を施す

(N_filt≧1)で定義して、X’_dec(k,i)を時間包絡形状が修正された復号信号のサブバンド信号として算出する。さらに、前記B_dec(m)を用いて境界が表される各周波数帯域内で、フィルタ処理前後のサブバンド信号のパワーをあわせるように処理できる。
また別の例によれば、サブバンド信号をX_dec(k,i)を前記B_dec(m)を用いて境界が表される各周波数帯域内で周波数方向に線形予測して線形予測係数α_p(m) (m=0,…,M_dec-1)を得て、所定の関数F(X_dec(k,i))をサブバンド信号X_dec(k,i)に対して線形予測逆フィルタ処理を施す

(N_pred≧1)で定義して、X’_dec(k,i)を時間包絡形状が修正された復号信号のサブバンド信号として算出する。 For example, when the temporal envelope shape of the decoded signal is determined to be flat, the temporal envelope shape of the decoded signal can be corrected by the following process. For example, the sub-band signal X _dec (k, i) can be _expressed as B _dec (m) (m = 0,..., M _dec , M _dec 1 1) (B _dec (0) 0, 0, B _dec (M _dec ) < A subband signal X _dec (k, i) (B _dec (m) ≦ k <B _dec (m), which is divided into M _dec frequency bands represented by k _h ) and included in the m th frequency band A predetermined function F (X _dec (k, i)) is obtained for +1), t (l) ≦ i <t (l + 1)),

Then, X ′ _dec (k, i) is calculated as a sub-band signal of the decoded signal in which the time envelope shape is corrected.
According to another example, the predetermined function F (X _dec (k, i)) is subjected to smoothing filter processing on the subband signal X _dec (k, i)

By defining (N _filt 1 1), X ′ _dec (k, i) is calculated as a sub-band signal of the decoded signal whose temporal envelope shape has been corrected. Furthermore, in each frequency band whose boundary is represented using B _dec (m), processing can be performed to match the power of the sub-band signal before and after filtering.
According to another example, the linear prediction coefficient α is obtained by linearly predicting the subband signal in the frequency direction within each frequency band whose boundary is represented using X _dec (k, i) using the B _dec (m). Obtain _p (m) (m = 0, ..., M _dec -1), and linearly predict the predetermined function F (X _dec (k, i)) with respect to the subband signal X _dec (k, i) Apply filter processing

By defining (N _pred 11), X ′ _dec (k, i) is calculated as a sub-band signal of the decoded signal whose temporal envelope shape is corrected.

  The example of the process which corrects said time envelope shape flatly can be implemented combining each, respectively.

  The time envelope correction unit 1d carries out the process of correcting the shape of the time envelope of the decoded signal to be flat, and is not limited to the above example.

で定義して、X’_dec(k,i)を時間包絡形状が修正された復号信号のサブバンド信号として算出する。さらに、前記B_dec(m)を用いて境界が表される各周波数帯域内で、時間包絡形状の修正前後のサブバンド信号のパワーをあわせるように処理できる。 Furthermore, for example, when the temporal envelope shape of the decoded signal is determined to be rising, the temporal envelope shape of the decoded signal can be corrected by the following process.
For example, using a function incr (i) that monotonously increases a predetermined function F ( _X.sub.dec (k, i)) with respect to i.

Define X ′ _dec (k, i) as a sub-band signal of the decoded signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using B _dec (m), processing can be performed to match the power of the sub-band signal before and after the correction of the time envelopment shape.

  The time envelope correction unit 1d performs a process of correcting the shape of the time envelope of the plurality of sub-band signals of the decoded signal into a rising edge, and is not limited to the above example.

で定義して、X’_dec(k,i)を時間包絡形状が修正された低周波数信号のサブバンド信号として算出する。さらに、前記B_dec(m)を用いて境界が表される各周波数帯域内で、時間包絡形状の修正前後のサブバンド信号のパワーをあわせるように処理できる。 Furthermore, for example, when the temporal envelope shape of the decoded signal is determined to be falling, the temporal envelope shape of the decoded signal can be corrected by the following processing.
For example, the predetermined function _{F (X dec (k, i} )) using a monotone decreasing function decr (i) with respect to the i

Define X ′ _dec (k, i) as a sub-band signal of a low frequency signal whose temporal envelope shape is corrected. Furthermore, in each frequency band whose boundary is represented using B _dec (m), processing can be performed to match the power of the sub-band signal before and after the correction of the time envelopment shape.

  The time envelope correction unit 1d performs processing for correcting the shape of the time envelope of the plurality of sub-band signals of the decoded signal into falling, and is not limited to the above example.

により得られるx’_dec(i)を時間包絡形状が修正された復号信号として出力する。 For example, when the decoded signal is represented by a signal in the time domain, the time envelope correction unit 1d determines that the decoded signal x _dec (i) (t (l) ≦ i <t (l + 1) in an arbitrary time segment. ), Using the given function F _t (x _dec (i))

And x ′ _dec (i) obtained by the above is output as a decoded signal in which the time envelope shape is corrected.

として、x’_dec(i)を時間包絡形状が修正された復号信号として出力する。 For example, when the temporal envelope shape of the decoded signal is determined to be flat, the temporal envelope shape of the decoded signal can be corrected by the following process.
For example, with respect to the decoded signal x _dec (i), a predetermined function F _t (x _dec (i))

Output x ' _dec (i) as a decoded signal whose time envelope shape is corrected.

(N_filt≧1)で定義して、x’_dec(i)を時間包絡形状が修正された復号信号として出力する。 According to another example, the predetermined function F _t (x _dec (i)) is subjected to smoothing filter processing on the decoded signal x _dec (i)

As defined by (N _filt 1 1), x ′ _dec (i) is output as a decoded signal whose temporal envelope shape is corrected.

  The example of the process which corrects said time envelope shape flatly can be implemented combining each, respectively.

で定義して、x’_dec(i)を時間包絡形状が修正された復号信号として出力する。 Furthermore, for example, when the temporal envelope shape of the decoded signal is determined to be rising, the temporal envelope shape of the decoded signal can be corrected by the following process.
For example, using a function incr (i) that monotonically increases with respect to i, a predetermined function F _t (x _dec (i))

, And outputs x ′ _dec (i) as a decoded signal whose time envelope shape is corrected.

  The time envelope correction unit 1d performs a process of correcting the shape of the time envelope of the decoded signal into a rising edge, and is not limited to the above example.

で定義して、x’_dec(i)を時間包絡形状が修正された復号信号として出力する。時間包絡修正部1dは、復号信号の時間包絡の形状を立ち下がりに修正する処理を実施し、上記の例に限定されない。 Furthermore, for example, when the temporal envelope shape of the decoded signal is determined to be falling, the temporal envelope shape of the decoded signal can be corrected by the following processing.
For example, using a function decr (i) that decreases monotonically with respect to i using a predetermined function F _t (x _dec (i))

, And outputs x ′ _dec (i) as a decoded signal whose time envelope shape is corrected. The time envelope correction unit 1d performs a process of correcting the shape of the time envelope of the decoded signal to fall, and is not limited to the above example.

により得られるX’_dec(k)を時間包絡形状が修正された復号信号の周波数領域の変換係数として算出し、所定の周波数間変換により時間領域の信号に変換して出力する。 For example, when the decoded signal is represented by a transform coefficient X _dec (k) (0 ≦ k <k _h ) in the frequency domain by time-frequency transform represented by discrete Fourier transform, discrete cosine transform, modified discrete cosine transform , The following formula (51) using a predetermined function F _f (X _dec (k))

The X ′ _dec (k) obtained by the above is calculated as a transform coefficient of the frequency domain of the decoded signal whose temporal envelope shape has been corrected, converted into a signal of the time domain by conversion between predetermined frequencies, and output.

(N_pred≧1)で定義して、X’_dec(k,i)を時間包絡形状が修正された復号信号の変換係数として算出する。 For example, when the temporal envelope shape of the decoded signal is determined to be flat, the temporal envelope shape of the decoded signal can be corrected by the following process.
M _dec arbitrary boundaries whose boundaries are represented by B _dec (m) (m = 0,..., M _dec , M _dec 1 1) (B _dec (0) 0, 0, B _dec (M _dec ) <k _h ) In the frequency band B _dec (m), linear prediction is performed in the frequency direction to obtain linear prediction coefficients α _p (m) (m = 0,..., M _dec -1), and a predetermined function F _f (X _dec apply linear predictive inverse filtering to (k)) with respect to the transform coefficient X _dec (k)

By defining (N _pred 11), X ′ _dec (k, i) is calculated as a transform coefficient of the decoded signal whose temporal envelope shape has been corrected.

  The time envelope correction unit 1d carries out the process of correcting the shape of the time envelope of the decoded signal to be flat, and is not limited to the above example.

  FIG. 67 is a diagram showing the configuration of the speech to digital converter 2 according to the tenth embodiment. The communication device of the speech coding device 2 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. The speech encoding apparatus 2 functionally includes a speech encoding unit 2a, a temporal envelope information encoding unit 2b, and a coded sequence multiplexing unit 2c, as shown in FIG.

  FIG. 68 is a flowchart showing an operation of the speech to digital converter 2 according to the tenth embodiment.

  The speech encoding unit 2a encodes the input speech signal (step S2-1).

  The temporal envelope information encoding unit 2b calculates temporal envelope information based on at least one or more of information obtained in the encoding process including the input speech signal and the encoding result of the input speech signal in the speech encoding unit 2a. Coding (step S2-2).

さらに、例えば、音声符号化部2aにおいて前記入力音声信号が複数のサブバンドの信号X(k,i)が算出される場合、入力音声信号の時間包絡として、任意の時間セグメントt(l)≦i<t(l+1))内でB(m) (m=0,…,M, M≧1) (B(0)≧0, B(M)<k_h)で境界を表されるM個の周波数帯域に分割され、m番目の周波数帯域に含まれる当該入力音声信号のサブバンド信号X(k,i) (B(m)≦k<B(m+1), t(l)≦i<t(l+1))の時間包絡E(k,i)を、当該時間セグメント内で正規化した入力音声信号のサブバンド信号のパワーとして算出できる。

入力音声信号の時間包絡は、入力音声信号の大きさの時間方向の変動がわかるパラメータであれば良く、前記の例に限定されない。 For example, the time envelope E _t (i) of the input speech signal x (i), which is a time domain signal within any time segment t (l) ≦ i <t (l + 1), is It can be calculated as the power of the decoded signal normalized by.

Furthermore, for example, when the speech encoding unit 2a calculates the signals X (k, i) of a plurality of sub-bands of the input speech signal, arbitrary time segment t (l) ≦ as a time envelope of the input speech signal The boundary is expressed by B (m) (m = 0,..., M, M ≧ 1) (B (0) ≧ 0, B (M) <k _h ) in i <t (l + 1)) Subband signal X (k, i) of the input speech signal that is divided into M frequency bands and included in the mth frequency band (B (m) B k <B (m + 1), t (l) A temporal envelope E (k, i) of ≦ i <t (l + 1) can be calculated as the power of the sub-band signal of the input speech signal normalized within the time segment.

The temporal envelope of the input speech signal may be any parameter as long as the variation in the time direction of the magnitude of the input speech signal is known, and is not limited to the above example.

さらに、例えば、音声符号化部2aにおける前記入力音声信号の符号化過程で、または符号化結果に基づいて復号信号のサブバンド信号X_dec(k,i)が算出される場合、復号信号の時間包絡として、任意の時間セグメントt(l)≦i<t(l+1))内でB(m) (m=0,…,M, M≧1) (B(0)≧0, B(M)<k_h)で境界を表されるM個の周波数帯域に分割され、m番目の周波数帯域に含まれる当該入力音声信号のサブバンド信号X_dec(k,i) (B(m)≦k<B(m+1), t(l)≦i<t(l+1))の時間包絡E_dec(k,i)を、当該時間セグメント内で正規化した入力音声信号のサブバンド信号のパワーとして算出できる。

例えば、時間包絡情報符号化部2bは時間包絡情報として平坦の程度を表す情報を算出する。例えば、入力音声信号及び復号信号の時間包絡の分散またはそれに準ずるパラメータのうち少なくとも一つ以上を算出する。さらに別の例では、入力音声信号及び復号信号の時間包絡の相加平均と相乗平均の比またはそれに準ずるパラメータのうち少なくとも一つ以上を算出する。この場合、時間包絡情報符号化部2bは、時間包絡情報として当該入力音声信号の時間包絡の平坦さを表す情報を算出すればよく、前記の例に限定されない。そして、前記パラメータを符号化する。例えば、入力音声信号と復号信号の当該パラメータの差分値またはその絶対値を符号化する。さらに、例えば、入力音声信号の当該パラメータの値または絶対値のうち少なくとも一つ以上を符号化する。例えば、時間包絡の平坦さを平坦か否かで表現すれば1ビットで符号化でき、例えば、前記時間領域の入力音声信号については前記任意の時間セグメント内において1ビットで符号化でき、さらに例えば、前記入力音声信号のサブバンド信号の前記M個の周波数帯域毎に当該情報を符号化する際にはMビットで符号化できる。時間包絡情報の符号化方法は前記の例に限定されない。 Furthermore, for example, the decoded signal x _dec (i) is calculated based on the encoding result of the input speech signal in the speech encoding unit 2a, and any time segment t (l) ≦ i <t (l + 1)) The temporal envelope E _{dec, t} (i) of the decoded signal x _dec (i) in the above can be calculated as the power of the decoded signal normalized within the time segment.

Furthermore, for example, when the sub-band signal X _dec (k, i) of the decoded signal is calculated in the encoding process of the input audio signal in the audio encoding unit 2 a or based on the encoding result, the time of the decoded signal As an envelope, B (m) (m = 0,..., M, M ≧ 1) in any time segment t (l) ≦ i <t (l + 1)) (B (0) ≧ 0, B ( M) <k _h) is divided into M frequency bands represented the boundary in the subband signals of the input audio signal included in the m-th frequency band _{X dec (k, i) (} B (m) ≦ Subband signal of the input speech signal obtained by normalizing the time envelope E _dec (k, i) of k <B (m + 1), t (l) ≦ i <t (l + 1) in the time segment It can be calculated as the power of

For example, the time envelopment information encoding unit 2b calculates information representing a degree of flatness as time envelopment information. For example, at least one or more of the variance of the time envelope of the input speech signal and the decoded signal or parameters corresponding thereto are calculated. In yet another example, at least one or more of the ratio of the arithmetic mean to the geometric mean of the temporal envelope of the input speech signal and the decoded signal or the parameter corresponding thereto is calculated. In this case, the time envelopment information encoding unit 2b may calculate information representing the flatness of the time envelopment of the input audio signal as the time envelopment information, and is not limited to the above example. Then, the parameters are encoded. For example, the difference value of the said parameter of an input audio | voice signal and a decoding signal or its absolute value is encoded. Furthermore, for example, at least one or more of the value or the absolute value of the parameter of the input speech signal is encoded. For example, if the flatness of the temporal envelope is expressed as flat or not, it can be encoded in one bit, for example, the input speech signal in the time domain can be encoded in one bit in the arbitrary time segment, When encoding the information for each of the M frequency bands of the sub-band signal of the input audio signal, the information can be encoded with M bits. The encoding method of temporal envelope information is not limited to the above example.

さらには、これらの式において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最大値を算出できる。 Furthermore, for example, the time envelope information encoding unit 2b calculates information indicating the degree of rising as time envelope information. For example, within any time segment t (l) ≦ i <t (l + 1), the maximum value of the difference value in the time direction of the time envelope of the input speech signal is calculated.

Furthermore, in these formulas, it is possible to calculate the maximum value of the difference value in the time direction of the parameter obtained by smoothing the time envelope in the time direction instead of the time envelope.

  In this case, the time envelope information encoding unit 2b may calculate information indicating the degree of rise of the time envelope of the input audio signal as time envelope information, and is not limited to the above example. Then, the parameters are encoded. For example, at least one of the difference value of the parameter of the input speech signal and the decoded signal or the absolute value thereof is encoded. For example, it can be encoded with one bit if it is expressed by whether or not the rise of the temporal envelope is a rise, for example, the input speech signal in the time domain can be encoded in one bit in the arbitrary time segment, When encoding the information for each of the M frequency bands of the sub-band signal of the input audio signal, the information can be encoded with M bits. The encoding method of temporal envelope information is not limited to the above example.

さらには、これらの式において、時間包絡に代えて当該時間包絡を時間方向に平滑化したパラメータの時間方向の差分値の最小値を算出できる。この場合、時間包絡情報符号化部2bは、時間包絡情報として当該入力音声信号のサブバンド信号の時間包絡の立ち下がりの程度を表す情報を算出すればよく、前記の例に限定されない。そして、前記パラメータを符号化する。例えば、入力音声信号と復号信号の当該パラメータの差分値またはその絶対値のうち少なくとも一つ以上を符号化する。例えば、時間包絡の立ち下がりを立ち下がりか否かで表現すれば1ビットで符号化でき、例えば、前記時間領域の入力音声信号については前記任意の時間セグメント内において1ビットで符号化でき、さらに例えば、前記入力音声信号のサブバンド信号の前記M個の周波数帯域毎に当該情報を符号化する際にはMビットで符号化できる。時間包絡情報の符号化方法は前記の例に限定されない。 Furthermore, for example, the time envelope information encoding unit 2b calculates, as time envelope information, information indicating the degree of fall. For example, in any time segment t (l) ≦ i <t (l + 1), the minimum value of the difference value in the time direction of the time envelope of the input speech signal is calculated.

Furthermore, in these equations, it is possible to calculate the minimum value of the difference value in the time direction of the parameter obtained by smoothing the time envelope in the time direction instead of the time envelope. In this case, the time envelopment information encoding unit 2b may calculate information indicating the degree of fall of the time envelopment of the sub-band signal of the input audio signal as time envelopment information, and is not limited to the above example. Then, the parameters are encoded. For example, at least one of the difference value of the parameter of the input speech signal and the decoded signal or the absolute value thereof is encoded. For example, it can be encoded with one bit if it is expressed by whether it falls or not, and for example, the input speech signal in the time domain can be encoded in one bit in the arbitrary time segment, and further For example, when encoding the information for each of the M frequency bands of the sub-band signal of the input audio signal, the information can be encoded with M bits. The encoding method of temporal envelope information is not limited to the above example.

  In the above example, in place of the temporal envelope of the input speech signal, in the speech encoding unit 2a, the power of the time segment shorter than the time segment within an arbitrary time segment t (l) ≦ i <t (l + 1) Coding parameters that are correlated (eg, codebook gain in CELP coding) can be used.

  The coding sequence multiplexing unit 2c receives the coding sequence of the input speech signal from the speech coding unit 2a, receives the time envelope shape information coded from the time envelopment information coding unit 2b, and multiplexes it for coding sequence Output as (step S2-3).

Eleventh Embodiment
FIG. 69 is a diagram showing the configuration of the speech decoding apparatus 100 according to the eleventh embodiment. The communication apparatus of the speech decoding apparatus 100 receives the multiplexed coded sequence output from the speech coding apparatus 200 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 69, the speech decoding apparatus 100 functionally includes a coded sequence demultiplexing unit 100a, a low frequency decoding unit 100b, a low frequency time envelope shape determination unit 100c, and a low frequency time envelope correction unit 100d, A high frequency decoding unit 100e and a low frequency / high frequency signal combining unit 100f are provided.

  FIG. 70 is a flowchart showing the operation of the speech decoding apparatus according to the eleventh embodiment.

  The coding sequence demultiplexing unit 100a divides the coding sequence into a low frequency coding portion obtained by coding a low frequency signal and a high frequency coding portion obtained by coding a high frequency signal (step S100-1).

  The low frequency decoding unit 100b decodes the low frequency coding part divided by the coding sequence demultiplexing unit 100a to obtain a low frequency signal (step S100-2).

  The low frequency temporal envelope shape determination unit 100c performs at least one or more of the information on the low frequency temporal envelope shape divided by the coding sequence demultiplexing unit 100a and the low frequency signal obtained by the low frequency decoding unit 100b. Based on the above, the time envelope shape of the low frequency signal is determined (step S100-3).

  For example, the time envelope shape of the low frequency signal is determined to be flat, the time envelope shape of the low frequency signal is determined to be rising, and the time envelope shape of the low frequency signal is determined to be falling.

  For the determination of the time envelope shape of the low frequency signal, for example, in the determination process of the time envelope shape of the decoded signal in the time envelope shape determination unit 1c, the low frequency decoding unit 100b obtains the decoded signal obtained in the speech decoding unit 1b. It can be realized by replacing with a low frequency signal.

  The low frequency temporal envelope correction unit 100d corrects the shape of the temporal envelope of the low frequency signal output from the low frequency decoding unit 100b based on the temporal envelope shape determined by the low frequency temporal envelope shape determination unit 100c (step S100). -Four).

  The correction of the time envelopment shape of the low frequency signal is obtained by, for example, the low frequency decoding unit 100b obtaining the decoded signal obtained by the speech decoding unit 1b in the correction process of the time envelopment shape of the decoded signal in the time envelopment correction unit 1d. It can be realized by substituting low frequency signals.

  The high frequency decoding unit 100e decodes the high frequency coding portion divided by the coding sequence demultiplexing unit 100a to obtain a high frequency signal (step S100-5).

  The decoding of the high frequency signal by the high frequency decoding unit 100e is performed by encoding a high frequency signal encoded by the signal of at least one or more of the time domain signal, the subband signal, and the frequency domain signal. It can be realized by a method of decoding.

  Furthermore, for example, as in the speech decoding devices according to the first to ninth embodiments, a high frequency signal is generated by a band expansion method of generating a high frequency signal using the decoding result obtained by the low frequency decoding unit. Can be generated. At this time, when the information necessary for generating the high frequency signal in the band extension method is included in the coding sequence, the portion of the coding sequence which includes the information becomes the high frequency coding portion. Then, the high frequency coding portion divided by the coding sequence demultiplexing unit 100a is decoded to obtain information necessary for the band expansion method, and a high frequency signal is generated. On the other hand, when the information required to generate a high frequency signal is not included in the coded sequence by the band expansion method, there is no input to the high frequency decoding unit 100e from the coded sequence demultiplexing unit 100a, and predetermined processing is performed. Alternatively, a high frequency signal is generated by processing using the decoding result obtained by the low frequency decoding unit.

  The low frequency / high frequency signal synthesis unit 100 f combines the low frequency signal whose time envelope shape is corrected by the low frequency time envelope correction unit 100 d with the high frequency signal obtained by the high frequency decoding unit 100 e to obtain a low frequency. An audio signal including the component and the high frequency component is output (step S100-6).

  FIG. 71 is a diagram showing the configuration of the speech to digital converter 200 according to the eleventh embodiment. The communication device of speech coding apparatus 200 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 65, the speech encoding apparatus 200 functionally includes a low frequency encoding unit 200a, a high frequency encoding unit 200b, a low frequency temporal envelope information encoding unit 200c, and a coded sequence multiplexing unit. It has 200d.

  FIG. 72 is a flowchart showing an operation of the speech to digital converter 200 according to the eleventh embodiment.

  The low frequency encoding unit 200a encodes the low frequency signal corresponding to the low frequency component of the input speech signal (step S200-1).

  The high frequency encoding unit 200b encodes the high frequency signal corresponding to the high frequency component of the input speech signal (step S200-2).

  The low frequency temporal envelope information coding unit 200c is low based on at least one of the information obtained in the process of coding including the input speech signal and the coding result of the input speech signal in the low frequency coding unit 200a. Frequency time envelope shape information is calculated and encoded (step S200-3).

  The calculation of low frequency temporal envelope shape information and the encoding process are performed, for example, in the calculation of temporal envelope information of the input speech signal in the time envelope information coding unit 2b, and in the encoding process, instead of the input speech signal. The frequency signal can be realized in the same manner by using a low frequency decoded signal obtained by decoding the coding result in the low frequency coding unit 200a instead of the decoded signal.

  The coding sequence multiplexing unit 200d receives the coding sequence of the low frequency speech signal from the low frequency coding unit 200a, receives the coding sequence of the high frequency speech signal from the high frequency coding unit 200b, and receives low frequency time envelope information The low frequency temporal envelope shape information encoded by the encoding unit 200c is received, multiplexed, and output as an encoded sequence (step S200-4).

First Modification of Speech Decoding Device According to Eleventh Embodiment
FIG. 73 is a diagram showing the configuration of the first modification 100A of the speech decoding device according to the eleventh embodiment.

  FIG. 74 is a flowchart showing an operation of the first modification 100A of the speech decoding device according to the eleventh embodiment.

  The high frequency decoding unit 100 e A decodes the high frequency coding part divided by the coding sequence demultiplexing unit 100 a to obtain a high frequency signal (step S 100-5 A).

  The high frequency decoding unit 100eA uses the low frequency decoded signal obtained by the low frequency decoding unit in the high frequency signal decoding, the low frequency signal with the time envelope shape corrected by the low frequency time envelope correction unit 100d. The point of use is a point different from the high frequency decoding unit 100e.

Second Modification of Speech Decoding Device According to Eleventh Embodiment
FIG. 75 is a diagram showing the configuration of the first modification 100A of the speech decoding device according to the eleventh embodiment.

  The difference with the first modification of the speech decoding apparatus according to the eleventh embodiment is that the low frequency signal input to the low frequency / high frequency signal synthesis unit 100 f is an output from the low frequency time envelope correction unit 100 d. The point is the output from the low frequency decoding unit 100b.

Twelfth Embodiment
FIG. 76 is a diagram showing the configuration of the speech decoding device 110 according to the twelfth embodiment. The communication device of the speech decoding device 110 receives the multiplexed coded sequence output from the speech coding device 210 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 76, the speech decoding apparatus 110 functionally includes a coded sequence demultiplexing unit 110a, a low frequency decoding unit 100b, a high frequency decoding unit 100e, a high frequency time envelope shape determining unit 110b, and a high frequency A time envelope correction unit 110c and a low frequency / high frequency signal synthesis unit 100f are provided.

  FIG. 77 is a flowchart showing an operation of the speech decoding apparatus according to the twelfth embodiment.

  The coded sequence demultiplexing unit 110a divides the coded sequence into information on the low frequency coding part, the high frequency coding part, and the high frequency temporal envelope shape (step S110-1).

  The high frequency temporal envelope shape determination unit 110b obtains information on the high frequency temporal envelope shape divided by the coding sequence demultiplexing unit 110a, the high frequency signal obtained by the high frequency decoding unit 100e, and the low frequency decoding unit 100b. The time envelope shape of the high frequency signal is determined based on at least one or more of the low frequency signals (step S110-2).

  For example, there may be a case where the time envelope shape of the high frequency signal is determined to be flat, a case where the time envelope shape of the high frequency signal is determined to be rising, and a case where the time envelope shape of the high frequency signal is determined to be falling.

  For the determination of the time envelope shape of the high frequency signal, for example, in the determination process of the time envelope shape of the decoded signal in the time envelope shape determination unit 1c, the high frequency decoding unit 100e obtains the decoded signal obtained by the speech decoding unit 1b. It can be realized by replacing it with a high frequency signal. In addition, it can be realized by replacing the decoded signal obtained by the audio decoding unit 1b with the low frequency signal obtained by the low frequency decoding unit 100b.

  The high frequency temporal envelope correction unit 110c corrects the shape of the temporal envelope of the high frequency signal output from the high frequency decoding unit 110e based on the temporal envelope shape determined by the high frequency temporal envelope shape determination unit 110b (step S110). -3). For example, when the temporal envelope shape of the high frequency signal is determined to be flat, the temporal envelope shape of the high frequency signal can be corrected by the following processing.

  The correction of the temporal envelope shape of the high frequency signal is obtained, for example, by the high frequency decoding unit 100 e of the decoded signal obtained by the speech decoding unit 1 b in the correction process of the temporal envelope shape of the decoded signal in the time envelope correction unit 1 d. It can be realized by replacing it with a high frequency signal.

  FIG. 78 is a diagram showing the configuration of the speech to digital converter 210 according to the twelfth embodiment. The communication device of speech coding apparatus 210 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 78, the speech encoding apparatus 210 functionally includes a low frequency encoding unit 200a, a high frequency encoding unit 200b, a high frequency temporal envelope information encoding unit 210a, and a coded sequence multiplexing unit. 210 b is provided.

  FIG. 79 is a flowchart showing an operation of the speech to digital converter 210 according to the twelfth embodiment.

  The high frequency temporal envelope information coding unit 210a is an information obtained in the process of coding including the input speech signal and the coding result of the input speech signal in the low frequency coding unit 200a, and the input speech in the high frequency coding unit 200b. The high frequency temporal envelope shape information is calculated and encoded based on at least one or more of the information obtained in the process of encoding including the signal encoding result (step S210-1).

  The calculation of high-frequency temporal envelope shape information, the encoding process, for example, the calculation of temporal envelope information of the input speech signal in the time envelope information encoding unit 2b, the encoding process, instead of the input speech signal, the high-level input speech signal A frequency signal can be realized in the same manner by using a high frequency decoded signal obtained by decoding the coding result in the high frequency coding unit 200b instead of the decoded signal.

  The coding sequence multiplexing unit 210b receives the coding sequence of the low frequency speech signal from the low frequency coding unit 200a, receives the coding sequence of the high frequency speech signal from the high frequency coding unit 200b, and receives high frequency time envelope information The encoded high frequency temporal envelope shape information is received from the encoding unit 210a, multiplexed, and output as an encoded sequence (step S210-2).

Thirteenth Embodiment
FIG. 80 is a diagram showing the configuration of the speech decoding apparatus 120 according to the thirteenth embodiment. The communication apparatus of the speech decoding apparatus 120 receives the multiplexed coded sequence output from the speech coding apparatus 220 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 80, the speech decoding apparatus 120 functionally includes a coded sequence demultiplexing unit 120a, a low frequency decoding unit 100b, a low frequency time envelope shape determination unit 100c, and a low frequency time envelope correction unit 100d, A high frequency decoding unit 100e, a high frequency time envelope shape determination unit 120b, a high frequency time envelope correction unit 110c, and a low frequency / high frequency signal combining unit 100f.

  FIG. 81 is a flowchart showing an operation of the speech decoding device 120 according to the thirteenth embodiment.

  The coding sequence demultiplexing unit 120a divides the coding sequence into a low frequency coding part, a high frequency coding part, information on a low frequency temporal envelope shape, and information on a high frequency temporal envelope shape (step S120-1). ).

  In this case, a code including, for example, information on separately encoded low frequency time envelope shape and information on high frequency time envelope shape, for information division on low frequency time envelope shape and information on high frequency time envelope shape It is possible to divide from the coded sequence, or to divide it from the coded sequence including information on the combined frequency-time envelope shape and information on the high-frequency temporal envelope shape. Furthermore, for example, information on the low frequency temporal envelope shape and information on the high frequency temporal envelope shape may be divided from a coded sequence including the information represented and encoded by a single piece of information.

  The high frequency temporal envelope shape determination unit 120b includes information on the high frequency temporal envelope shape divided by the coding sequence demultiplexing unit 120a, the low frequency signal obtained by the low frequency decoding unit 100b, and the low frequency temporal envelope correction unit 100d. The temporal envelope shape of the high frequency signal is determined based on at least one or more of the low frequency signals whose temporal envelope shape has been corrected (step S120-2).

  For example, there may be a case where the time envelope shape of the high frequency signal is determined to be flat, a case where the time envelope shape of the high frequency signal is determined to be rising, and a case where the time envelope shape of the high frequency signal is determined to be falling.

  In the determination process of the high frequency temporal envelope shape in the high frequency temporal envelope shape determination unit 120b, when based on the low frequency signal whose temporal envelope shape is corrected in the low frequency temporal envelope correction unit 100d, decoding in the temporal envelope shape determination unit 1c In the process of determining the time envelopment shape of the signal, it can be realized by replacing the decoded signal obtained by the speech decoding unit 1b with a low frequency signal whose time envelopment shape is corrected by the low frequency time envelopment correction unit 100d.

  FIG. 82 is a diagram showing the configuration of the speech to digital converter 220 according to the thirteenth embodiment. The communication device of speech coding apparatus 220 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 82, the speech coding apparatus 220 functionally includes a low frequency coding unit 200a, a high frequency coding unit 200b, a low frequency time envelope information coding unit 200c, and a high frequency time envelope information coding. And a coding sequence multiplexing unit 220b.

  FIG. 83 is a flowchart showing an operation of the speech to digital converter 220 according to the thirteenth embodiment.

  The high frequency temporal envelope information coding unit 220a is an information obtained in the process of coding including the input speech signal and the coding result of the input speech signal in the low frequency coding unit 200a, and the input speech in the high frequency coding unit 200b. At least among the information obtained in the process of coding including the coding result of the signal, the information obtained in the process of coding including the coding result of the low frequency time envelope information in the low frequency time envelope information coding unit 200 c The high frequency temporal envelope shape information is calculated and encoded based on one or more (step S220-1).

  The calculation of the high frequency temporal envelope shape information and the encoding process can be realized, for example, in the same manner as the calculation of the temporal envelope information of the high frequency signal and the encoding process in the high frequency temporal envelope information coding unit 210a. Furthermore, for example, it may be based on the coding result of low frequency time envelope information. For example, only if the result of coding the low frequency time envelope is flat as a result of coding the low frequency time envelope information, it is coded whether the high frequency time envelope is flat as high frequency time envelope information can do.

  The coding sequence multiplexing unit 220b receives the coding sequence of the low frequency speech signal from the low frequency coding unit 200a, receives the coding sequence of the high frequency speech signal from the high frequency coding unit 200b, and receives low frequency time envelope information It receives low-frequency temporal envelope shape information encoded by the encoding unit 200c, receives high-frequency temporal envelope shape information encoded by the high-frequency temporal envelope information encoding unit 210a, multiplexes it, and outputs it as a coded sequence. (Step S220-2).

  At this time, for example, information on the separately encoded low frequency temporal envelope shape and information on the high frequency temporal envelope shape are received with respect to encoding of the information regarding the low frequency temporal envelope shape and the information regarding the high frequency temporal envelope shape It is also possible to receive information on the combined encoded frequency-time envelope shape and information on the high-frequency time envelope shape. Furthermore, it is also possible to receive, for example, information on the low frequency temporal envelope shape represented and encoded by a single piece of information and information on the high frequency temporal envelope shape.

First Modification of Speech Decoding Device According to Thirteenth Embodiment
FIG. 84 is a diagram showing the configuration of the first modification 120A of the speech decoding device according to the thirteenth embodiment. The difference with the speech decoding apparatus 120 of the thirteenth embodiment is that the high frequency decoding unit 100eA uses a low frequency signal whose time envelope shape is corrected by the low frequency temporal envelope correction unit 100d for decoding a high frequency signal. It is a point to

  FIG. 85 is a flowchart showing an operation of the first modification 120A of the speech decoding device according to the thirteenth embodiment. In Step 100-5A of FIG. 85, when the low frequency decoded signal obtained by the low frequency decoding unit 100b is used in decoding of the high frequency signal, the low frequency temporal envelope correction unit 100d corrects the time envelope shape. Use frequency signal.

Second Modification of Speech Decoding Device According to Thirteenth Embodiment
FIG. 86 is a diagram showing the configuration of the second modification 120B of the speech decoding device according to the thirteenth embodiment. The difference with the first modification of the speech decoding apparatus according to the thirteenth embodiment is that the low frequency signal input to the low frequency / high frequency signal synthesis unit 100 f is the output from the low frequency time envelope correction unit 100 d. The point is the output from the low frequency decoding unit 100b.

  FIG. 87 is a flowchart showing an operation of the second modification 120B of the speech decoding device according to the thirteenth embodiment. In step S100-6 in FIG. 87, the low frequency signal from the low frequency decoding unit 100b and the high frequency signal from the high frequency time envelope correction unit 110c are combined.

[Third Modification of Speech Decoding Device of Thirteenth Embodiment]
FIG. 185 is a diagram showing a configuration of the third modification 120C of the speech decoding device according to the thirteenth embodiment.

  FIG. 186 is a flowchart showing an operation of the third modification 120C of the speech decoding device according to the thirteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 120 according to the thirteenth embodiment is that the low-frequency time envelope shape determination unit 120c is replaced with the low-frequency time envelope shape determination unit 100c and the high-frequency time envelope correction unit 110c. , High frequency time envelope correction unit 120d.

  In this modification, the difference between the low frequency time envelope shape determination unit 120c and the low frequency time envelope shape determination unit 100c is that the determined time envelope shape is also notified to the high frequency time envelope correction unit 120d. .

  The difference between the high frequency time envelope correction unit 120d and the high frequency time envelope correction unit 110c is determined by the time envelope shape determined by the high frequency time envelope shape determination unit 120b and the low frequency time envelope shape determination unit 120c. The shape of the temporal envelope of the high frequency signal output from the high frequency decoding unit 100 e is corrected based on at least one or more of the temporal envelope shapes (S 120-3).

  For example, when the low-frequency temporal envelope shape determination unit 120c determines that the temporal envelope shape is flat, high-frequency decoding is performed regardless of the temporal envelope shape determined by the high-frequency temporal envelope shape determination unit 120b. The shape of the temporal envelope of the high frequency signal output from the unit 100e is corrected to be flat. Furthermore, for example, when the low-frequency temporal envelope shape determination unit 120c determines that the temporal envelope shape is not flat, high-frequency decoding is performed regardless of the temporal envelope shape determined by the high-frequency temporal envelope shape determination unit 120b. The shape of the temporal envelope of the high frequency signal output from the unit 100e is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

Fourth Modification of Speech Decoding Device of Thirteenth Embodiment
FIG. 187 is a diagram showing the configuration of the fourth modification 120D of the speech decoding device according to the thirteenth embodiment.

  FIG. 188 is a flowchart showing an operation of the fourth modification 120D of the speech decoding device according to the thirteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 120 according to the thirteenth embodiment resides in that the high-frequency time envelope shape determination unit 120b is replaced with the high-frequency time envelope shape determination unit 120b and the low-frequency time envelope correction unit 100d. , Low frequency time envelope correction unit 120e.

  In this modification, the difference between the high frequency time envelope shape determination unit 120bA and the high frequency time envelope shape determination unit 120b is that the determined time envelope shape is also notified to the low frequency time envelope correction unit 120e. .

  The determination of the temporal envelope shape in the high frequency temporal envelope shape determination unit 120bA may be based on, for example, the frequency power distribution of the low frequency signal, in addition to the above example. Furthermore, it is possible to use, for example, the frame length in decoding of the high frequency signal obtained from the coded sequence demultiplexing unit 120a. For example, if the frame length is long, it can be determined to be flat, and if the frame length is short, it can be determined to be rising or falling, and the high frequency temporal envelope shape determination unit 120b can also determine similarly.

  The difference between the low frequency time envelope correction unit 120e and the low frequency time envelope correction unit 100d is determined by the time envelope shape determined by the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120bA. The shape of the temporal envelope of the low frequency signal output from the low frequency decoding unit 100b is corrected based on at least one or more of the temporal envelope shapes (S120-4).

  For example, when the high-frequency temporal envelope shape determination unit 120bA determines that the temporal envelope shape is flat, low-frequency decoding is performed regardless of the temporal envelope shape determined by the low-frequency temporal envelope shape determination unit 100c. The shape of the time envelope of the low frequency signal output from the unit 100b is corrected to be flat. Furthermore, for example, when the high-frequency temporal envelope shape determination unit 120bA determines that the temporal envelope shape is flat, the low-frequency temporal envelope shape determination unit 100c does not depend on the temporal envelope shape determined by the low-frequency temporal envelope shape determination unit 100c. The shape of the temporal envelope of the low frequency signal output from the decoding unit 100b is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

[Fifth Modification of Speech Decoding Device of Thirteenth Embodiment]
FIG. 189 is a diagram showing a configuration of the fifth modification 120E of the speech decoding device according to the thirteenth embodiment.

  FIG. 190 is a flowchart showing an operation of the fifth modification 120E of the speech decoding device according to the thirteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 120d, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Sixth Modification of Speech Decoding Device According to Thirteenth Embodiment
FIG. 191 is a diagram showing the configuration of the sixth modification 120F of the speech decoding device according to the thirteenth embodiment.

  FIG. 192 is a flowchart showing an operation of the sixth modification 120F of the speech decoding device according to the thirteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 120 according to the thirteenth embodiment is that the time envelope shape determination unit 120f is provided instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. It is a point to do.

  The time envelopment shape determination unit 120f includes information on the low frequency time envelopment shape from the coding sequence demultiplexing unit 120a, information on the high frequency time envelopment shape, a low frequency signal from the low frequency decoding unit 100b, and a high frequency decoding unit 100e. The temporal envelope shape is determined based on at least one or more of the high frequency signals from S. (S120-5). The determined time envelope shape is notified to the low frequency time envelope correction unit 100 d and the high frequency time envelope correction unit 110 c.

  For example, it is determined that the time envelope shape is flat. Further, for example, it is determined that the time envelope shape is rising. Furthermore, for example, it is determined as falling as the time envelope shape. The temporal envelope shape to be determined is not limited to the above example.

  The time envelope shape determination unit 120f can determine the time envelope shape, for example, in the same manner as the low frequency time envelope shape determination units 100c and 120c and the high frequency time envelope shape determination unit 120b and 120bA. The method of determining the temporal envelope shape is not limited to the above example.

Seventh Modification of Speech Decoding Device of Thirteenth Embodiment
FIG. 193 is a diagram showing a configuration of a seventh modification 120G of the speech decoding device according to the thirteenth embodiment.

  FIG. 194 is a flowchart showing an operation of the seventh modification 120G of the speech decoding device according to the thirteenth embodiment.

  The difference between this modification and the first modification 120A of the speech decoding apparatus according to the thirteenth embodiment is the low-frequency time envelope shape determination unit 100c and the high-frequency time envelope correction unit 110c. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 120d.

Eighth Modification of Speech Decoding Device According to Thirteenth Embodiment
FIG. 195 is a diagram showing the configuration of the eighth modification 120H of the speech decoding device according to the thirteenth embodiment.

  FIG. 196 is a flowchart showing an operation of the eighth modification 120H of the speech decoding device according to the thirteenth embodiment.

  The difference between this modification and the first modification 120A of the speech decoding apparatus according to the thirteenth embodiment is the high frequency time envelope shape determination unit 120b and the low frequency time envelope correction unit 100d. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

[Ninth modified example of speech decoding apparatus according to thirteenth embodiment]
FIG. 197 is a diagram showing the configuration of the ninth modification 1201 of the speech decoding device according to the thirteenth embodiment.

  FIG. 198 is a flowchart showing the operation of the ninth modification 1201 of the speech decoding device according to the thirteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 120d, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Tenth Modified Example of Speech Decoding Device According to Thirteenth Embodiment
FIG. 199 is a diagram showing a configuration of a tenth modification 120J of the speech decoding device according to the thirteenth embodiment.

  FIG. 200 is a flowchart showing the operation of the tenth modification 120J of the speech decoding device according to the thirteenth embodiment.

  The difference between this modification and the first modification 120A of the speech decoding apparatus according to the thirteenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Eleventh Modified Example of the Speech Decoding Device According to the Thirteenth Embodiment
FIG. 201 is a diagram showing the configuration of the eleventh modification 120K of the speech decoding device according to the thirteenth embodiment.

  FIG. 202 is a flowchart showing an operation of the eleventh modification 120K of the speech decoding device according to the thirteenth embodiment.

  The difference between this modification and the second modification 120B of the speech decoding apparatus according to the thirteenth embodiment is the low-frequency time envelope shape determination unit 100c and the high-frequency time envelope correction unit 110c. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 120d.

[Twelfth modified example of the speech decoding device according to the thirteenth embodiment]
FIG. 203 is a diagram showing the configuration of a twelfth modification 120L of the speech decoding device according to the thirteenth embodiment.

  FIG. 204 is a flowchart showing an operation of the twelfth modification 120L of the speech decoding device according to the thirteenth embodiment.

  The difference between this modification and the second modification 120B of the speech decoding apparatus according to the thirteenth embodiment resides in that the high frequency time envelope shape determination unit 120b and the low frequency time envelope correction unit 100d are replaced with a high frequency. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

Thirteenth Modification of Speech Decoding Device According to Thirteenth Embodiment
FIG. 205 is a diagram showing a configuration of a thirteenth modification 120M of the speech decoding device according to the thirteenth embodiment.

  FIG. 206 is a flowchart showing an operation of the thirteenth modification 120M of the speech decoding device according to the thirteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 120d, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

[Seventeenth modified example of speech decoding apparatus according to the thirteenth embodiment]
FIG. 207 is a diagram showing a configuration of a fourteenth modification 120N of the speech decoding device according to the thirteenth embodiment.

  FIG. 208 is a flowchart showing an operation of the fourteenth modification 120N of the speech decoding device according to the thirteenth embodiment.

  The difference between this modification and the second modification 120B of the speech decoding apparatus according to the thirteenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Fourteenth Embodiment
FIG. 88 is a diagram showing the configuration of the speech decoding apparatus 130 according to the fourteenth embodiment. The communication device of the speech decoding device 130 receives the multiplexed coded sequence output from the speech coding device 230 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 88, the speech decoding apparatus 130 functionally includes a coded sequence demultiplexing unit 110a, a low frequency decoding unit 100b, a high frequency time envelope shape determination unit 110b, a high frequency time envelope correction unit 130a, A high frequency decoding unit 130 b and a low frequency / high frequency signal combining unit 100 f are provided.

  FIG. 89 is a flowchart showing an operation of the speech decoding apparatus according to the thirteenth embodiment.

  The high frequency temporal envelope correction unit 130a corrects the shape of the temporal envelope of the low frequency signal input to the high frequency decoding unit 130b based on the temporal envelope shape determined by the high frequency temporal envelope shape determination unit 110b (step S130). -1). The correction of the temporal envelope shape in the high frequency temporal envelope correction unit 130a is performed by, for example, the low frequency decoding unit 100b in the processing for correcting the temporal envelope shape of the decoded signal in the temporal envelope correction unit 1d. It can be realized by replacing with the low frequency signal obtained in

  The high frequency decoding unit 130 b decodes the high frequency coding part divided by the coding sequence demultiplexing unit 100 a to obtain a high frequency signal (step S 130-2).

  The high frequency decoding unit 130 b uses the low frequency decoded signal obtained by the low frequency decoding unit in decoding the high frequency signal, the low frequency signal whose temporal envelope shape has been corrected by the high frequency temporal envelope correction unit 130 a The point to be used is a point different from the high frequency decoding unit 100e.

  FIG. 90 is a diagram showing the configuration of speech encoding apparatus 230 according to the fourteenth embodiment. The communication device of speech coding apparatus 230 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 90, the speech encoding apparatus 230 functionally includes a low frequency encoding unit 200a, a high frequency encoding unit 200b, a high frequency temporal envelope information encoding unit 230a, and a coded sequence multiplexing unit. 210 b is provided.

  FIG. 91 is a flowchart showing an operation of the speech to digital converter 230 according to the fourteenth embodiment.

  The high frequency temporal envelope information coding unit 230a is an information obtained in the process of coding including the input speech signal and the coding result of the input speech signal in the low frequency coding unit 200a, and the input speech in the high frequency coding unit 200b. The high-frequency temporal envelope shape information is calculated and encoded based on at least one or more of the information obtained in the encoding process including the signal encoding result (step S230-1).

  The calculation of the high frequency temporal envelope shape information and the encoding process can be realized, for example, in the same manner as the calculation and the encoding process of the temporal envelope information of the low frequency signal in the low frequency temporal envelope information coding unit 200c. However, the calculation of the high-frequency time envelope shape information and the coding process can also use information obtained in the process of coding including the coding result of the input speech signal in the high-frequency coding unit 200b. This is different from the calculation of the time envelope information of the low frequency signal using the low frequency decoded signal of the input speech signal and the encoding process.

Fifteenth Embodiment
FIG. 92 is a diagram showing the configuration of the speech decoding device 140 according to the fifteenth embodiment. The communication device of the speech decoding device 140 receives the multiplexed coded sequence output from the speech coding device 240 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 92, the speech decoding apparatus 140 functionally includes the coding sequence demultiplexing unit 120a, the low frequency decoding unit 100b, the low frequency time envelope shape determination unit 100c, and the low frequency time envelope correction unit 100d, The high frequency temporal envelope shape determination unit 120b, the high frequency temporal envelope correction unit 130a, the high frequency decoding unit 130b, and the low frequency / high frequency signal combining unit 100f.

  FIG. 93 is a flowchart showing an operation of the speech decoding apparatus according to the fifteenth embodiment. The coded sequence demultiplexing unit 120a and the high frequency time envelope shape determining unit 120b perform the same operations as the coded sequence demultiplexing unit 120a and the high frequency time envelope shape determining unit 120b in the thirteenth embodiment (steps S120-1, S120-2). The high frequency time envelope correction unit 130a and the high frequency decoding unit 130b perform the same operation as the high frequency time envelope correction unit 130a and the high frequency decoding unit 130b in the fourteenth embodiment (steps S130-1 and S130-2). .

  FIG. 94 is a diagram showing the configuration of speech encoding apparatus 240 according to the fifteenth embodiment. The communication device of speech coding apparatus 240 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 94, the speech encoding apparatus 240 functionally includes a low frequency encoding unit 200a, a high frequency encoding unit 200b, a low frequency temporal envelope information encoding unit 200c, and a high frequency temporal envelope information encoding. And a coding sequence multiplexing unit 220b.

  FIG. 95 is a flowchart showing an operation of the speech to digital converter 240 according to the fifteenth embodiment.

[First Modification of Speech Decoding Device According to Fifteenth Embodiment]
FIG. 96 is a diagram showing the configuration of the first modification 140A of the speech decoding apparatus according to the fifteenth embodiment.

  FIG. 97 is a flowchart showing an operation of the first modification 140A of the speech decoding device according to the fifteenth embodiment.

  The high frequency temporal envelope correction unit 140a is configured to correct the temporal envelope shape of the low frequency signal with the low frequency temporal envelope correction unit 100d based on the temporal envelope shape determined by the high frequency temporal envelope shape determination unit 120b. The shape is corrected (step S140-1). The difference from the high frequency temporal envelope correction unit 130a is that the input signal is a low frequency signal whose temporal envelope shape has been corrected by the low frequency temporal envelope correction unit 100d.

[Second Modification of Speech Decoding Device of the Fifteenth Embodiment]
FIG. 98 is a diagram showing the configuration of the second modification 140B of the speech decoding apparatus according to the fifteenth embodiment.

  The difference with the first modification of the speech decoding apparatus according to the embodiment is that the low frequency signal used for the combining process in the low frequency / high frequency signal combining unit 100 f is temporally enveloped in the low frequency time envelope correcting unit 100 d. Instead of the low frequency signal whose shape is corrected, it is a low frequency signal decoded by the low frequency decoding unit 100b.

Third Modification of Speech Decoding Device According to Fifteenth Embodiment
FIG. 209 is a diagram showing the configuration of the third modification 140C of the speech decoding device according to the fifteenth embodiment.

  FIG. 210 is a flowchart showing an operation of the third modification 140C of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the speech decoding apparatus 140 according to the fifteenth embodiment is that the low frequency temporal envelope shape determination unit 120c is replaced with the low frequency temporal envelope correction unit 130a. , High frequency time envelope correction unit 140b.

  The difference between the high frequency time envelope correction unit 140b and the high frequency time envelope correction unit 130a is determined by the time envelope shape determined by the high frequency time envelope shape determination unit 120b and the low frequency time envelope shape determination unit 120c. The shape of the temporal envelope of the low frequency signal input to the high frequency decoding unit 130b is corrected based on at least one or more of the temporal envelope shapes (S140-2).

  For example, when the low-frequency temporal envelope shape determination unit 120c determines that the temporal envelope shape is flat, high-frequency decoding is performed regardless of the temporal envelope shape determined by the high-frequency temporal envelope shape determination unit 120b. The shape of the temporal envelope of the low frequency signal input to the unit 130b is corrected to be flat. Furthermore, for example, when the low-frequency temporal envelope shape determination unit 120c determines that the temporal envelope shape is not flat, high-frequency decoding is performed regardless of the temporal envelope shape determined by the high-frequency temporal envelope shape determination unit 120b. The shape of the temporal envelope of the low frequency signal input to the unit 130 b is not corrected flat. The same applies to rising and falling, and the time envelope shape is not limited.

[Fourth Modification of Speech Decoding Device According to Fifteenth Embodiment]
FIG. 211 is a diagram showing the configuration of the fourth modification 140D of the speech decoding device according to the fifteenth embodiment.

  FIG. 212 is a flowchart showing an operation of the fourth modification 140D of the speech decoding device according to the fifteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 140 according to the fifteenth embodiment is that the high-frequency time envelope shape determination unit 120b is replaced with the high-frequency time envelope shape determination unit 120b and the low-frequency time envelope correction unit 100d. , Low frequency time envelope correction unit 120e.

[Fifth Modification of Speech Decoding Device According to Fifteenth Embodiment]
FIG. 213 is a diagram showing the configuration of the fifth modification 140E of the speech decoding device according to the fifteenth embodiment.

  FIG. 214 is a flowchart showing the operation of the fifth modification 140E of the speech decoding device according to the fifteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 140b, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Sixth Modification of Speech Decoding Device According to Fifteenth Embodiment
FIG. 215 is a diagram showing the configuration of the sixth modification 140F of the speech decoding device according to the fifteenth embodiment.

  FIG. 216 is a flowchart showing an operation of the sixth modification 140F of the speech decoding device according to the fifteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 140 according to the fifteenth embodiment is that the time envelope shape determination unit 120f is provided instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. It is a point to do.

Seventh Modification of Speech Decoding Device According to Fifteenth Embodiment
FIG. 217 is a diagram showing a configuration of a seventh modification 140G of the speech decoding device according to the fifteenth embodiment.

  FIG. 218 is a flowchart showing an operation of the seventh modification 140G of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the first modification 140A of the speech decoding apparatus according to the fifteenth embodiment resides in that the low frequency time envelope shape determination unit 100c and the high frequency time envelope correction unit 140a are replaced with a low frequency. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 140b.

  In the present modification, the high frequency temporal envelope correction unit 140b performs at least one of the temporal envelope shape determined by the high frequency temporal envelope shape determination unit 120b and the temporal envelope shape determined by the low frequency temporal envelope shape determination unit 120c. Based on one or more, the shape of the temporal envelope of the low frequency signal whose temporal envelope shape has been corrected input to the high frequency decoding unit 130b is corrected (S140-2).

Eighth Modification of Speech Decoding Device According to Fifteenth Embodiment
FIG. 219 is a diagram showing the configuration of the eighth modification 140H of the speech decoding device according to the fifteenth embodiment.

  FIG. 220 is a flowchart showing an operation of the eighth modification 140H of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the first modification 140A of the speech decoding apparatus according to the fifteenth embodiment resides in that the high-frequency time envelope shape determination unit 120b and the low-frequency time envelope correction unit 100d are replaced with a high frequency. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

[Ninth modified example of speech decoding apparatus according to fifteenth embodiment]
FIG. 221 is a diagram showing the configuration of the ninth modification 1401 of the speech decoding device according to the fifteenth embodiment.

  FIG. 222 is a flowchart showing the operation of the ninth modification 1401 of the speech decoding device according to the fifteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 140b, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Tenth Modified Example of Speech Decoding Device According to Fifteenth Embodiment
FIG. 223 is a diagram showing the configuration of the tenth modification 140J of the speech decoding device according to the fifteenth embodiment.

  FIG. 224 is a flowchart showing an operation of the tenth modification 140J of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the first modification 140A of the speech decoding apparatus according to the fifteenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Eleventh Modified Example of the Speech Decoding Device According to the Fifteenth Embodiment
FIG. 225 is a diagram showing the configuration of an eleventh modification 140K of the speech decoding device according to the fifteenth embodiment.

  FIG. 226 is a flowchart showing an operation of the eleventh modification 140K of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the second modification 140B of the speech decoding apparatus according to the fifteenth embodiment is the low frequency time envelope shape determination unit 100c and the high frequency time envelope correction unit 140a. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 140b.

[Twelfth modified example of the speech decoding device according to the fifteenth embodiment]
FIG. 227 is a diagram showing a configuration of a twelfth modification 140L of the speech decoding device according to the fifteenth embodiment.

  FIG. 228 is a flowchart showing an operation of the twelfth modification 140L of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the second modification 140B of the speech decoding apparatus according to the fifteenth embodiment resides in that the high-frequency time envelope shape determination unit 120b and the low-frequency time envelope correction unit 100d are replaced with a high frequency. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

[Thirteenth modified example of the speech decoding device according to the fifteenth embodiment]
FIG. 229 is a diagram showing a configuration of a thirteenth modification 140M of the speech decoding device according to the fifteenth embodiment.

  FIG. 230 is a flowchart showing an operation of the thirteenth modification 140M of the speech decoding device according to the fifteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 140b, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

[Seventeenth modified example of speech decoding apparatus according to the fifteenth embodiment]
FIG. 231 is a diagram showing the configuration of a fourteenth modification 140N of the speech decoding device according to the fifteenth embodiment.

  FIG. 232 is a flowchart showing an operation of the fourteenth modification 140N of the speech decoding device according to the fifteenth embodiment.

  The difference between this modification and the second modification 140B of the speech decoding apparatus according to the fifteenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Sixteenth Embodiment
FIG. 99 is a diagram showing the configuration of a speech decoding apparatus 150 according to the sixteenth embodiment. The communication device of the speech decoding device 150 receives the multiplexed coded sequence output from the speech coding device 250 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 99, the speech decoding apparatus 150 functionally includes a coding sequence demultiplexing unit 150a, a switch group 150b, a low frequency decoding unit 100b, a low frequency time envelope shape determining unit 100c, and a low frequency time envelope A correction unit 100d, a high frequency decoding unit 100e, a high frequency time envelope shape determination unit 120b, a high frequency time envelope correction unit 110c, and a low frequency / high frequency signal synthesis unit 150c.

  FIG. 100 is a flowchart showing the operation of the speech decoding apparatus according to the sixteenth embodiment.

  The coding sequence demultiplexing unit 150a divides the coding sequence into high frequency signal generation control information, low frequency coding part, and information on temporal envelope shape (step S150-1).

  Whether or not to generate a high frequency signal is determined based on the high frequency signal generation control information obtained by the coded sequence demultiplexing unit 150a (step S150-2).

  When generating a high frequency signal, the coded sequence demultiplexing unit 150a extracts a high frequency coded portion from the coded sequence (step S150-3). Then, a high frequency signal portion of the coded sequence is used to generate a high frequency signal, and further, the temporal envelope shape of the high frequency signal is determined to correct the temporal envelope shape of the high frequency signal.

  The order of performing the processes in steps S150-2 and S150-3 may be determined before the process of determining the high-frequency temporal envelope shape and the high-frequency encoding part before the process of decoding, and is limited to the order of the flowchart in FIG. I will not.

  When it is determined that the low frequency / high frequency signal synthesis unit 150c generates the high frequency signal based on the high frequency signal generation information, the low frequency signal whose temporal envelope shape is corrected and the high frequency whose temporal envelope shape is corrected The output speech signal is synthesized from the signal, and when it is judged that the high frequency signal is not generated based on the high frequency signal generation information, the output speech signal is synthesized from the low frequency signal whose temporal envelope shape is corrected (step S150- Four). However, if it is determined that the high frequency signal is not generated, and if the low frequency / high frequency signal synthesis unit 150 c is input in a state where the low frequency signal whose temporal envelope shape is corrected can be output, the input low frequency It is also possible to output the signal as it is.

  FIG. 101 is a diagram showing the configuration of a speech to digital converter 250 according to the sixteenth embodiment. The communication device of speech coding apparatus 250 receives a speech signal to be coded from the outside, and further outputs the coded coded sequence to the outside. As shown in FIG. 101, the speech encoding apparatus 250 functionally includes a high frequency signal generation control information encoding unit 250 a, a low frequency encoding unit 200 a, a high frequency encoding unit 200 b, and a low frequency time envelope information code. A coding unit 200c, a high frequency temporal envelope information coding unit 220a, and a coding sequence multiplexing unit 250b are provided.

  FIG. 102 is a flowchart showing the operation of the speech to digital converter 250 according to the sixteenth embodiment.

  The high frequency signal generation control information coding unit 250a determines whether to generate the high frequency signal based on at least one of the input voice signal and the high frequency signal generation control instruction signal, and the high frequency signal generation control information Are encoded (step S250-1). For example, when the input speech signal includes a signal of a frequency band to be encoded by the high frequency encoding unit 200b, it can be determined to generate a high frequency signal. Furthermore, for example, when generation of a high frequency signal is instructed by the high frequency signal generation control instruction signal, it can be determined to generate a high frequency signal. Furthermore, for example, the two methods may be combined, and it may be determined that the high frequency signal is to be generated, for example, when it is determined that the high frequency signal is to be generated by at least one of the two methods.

  The high frequency signal generation control information can be encoded, for example, by representing whether to generate a high frequency signal with one bit.

  However, the determination as to whether or not to generate the high frequency signal, and the encoding method of the high frequency signal generation control information are not limited.

  When it is determined that the high frequency signal is generated by the high frequency signal generation control information encoding unit 250a, the high frequency encoding unit 200b encodes the high frequency signal corresponding to the high frequency component of the input speech signal, and the high frequency time envelope The information encoding unit 220a calculates and encodes high frequency time envelope shape information. On the other hand, when it is determined that the high frequency signal generation control information coding unit 250a does not generate the high frequency signal, the coding of the high frequency signal and the calculation and coding of the high frequency time envelope shape information are not performed (step S250). -2).

  The coded sequence multiplexing unit 250c receives the high frequency signal generation control information encoded by the high frequency signal generation control information coding unit 250a, and receives the coded sequence of the low frequency speech signal from the low frequency coding unit 200a. When it is determined that the low frequency time envelope shape information encoded by the low frequency time envelope information coding unit 200c is received and added to these, the high frequency signal generation control information coding unit 250a generates a high frequency signal. Receives the coded sequence of the high frequency speech signal from the high frequency coding unit 200b and the high frequency time envelope shape information coded from the high frequency time envelope information coding unit 210a, and multiplexes it to output as a coded sequence (Step S250-3).

  When it is determined to generate the high frequency signal in the high frequency signal generation control information encoding unit 250a, for example, the code separately regarding the information on the low frequency time envelope shape and the information on the high frequency time envelope shape It is also possible to receive information on the generalized low frequency temporal envelope shape and information on the high frequency temporal envelope shape, and a form encoded by combining the information on the low frequency temporal envelope shape and the information on the high frequency temporal envelope shape You can also receive Furthermore, it is also possible to receive, for example, information on the low frequency temporal envelope shape represented and encoded by a single piece of information and information on the high frequency temporal envelope shape.

First Modification of Speech Decoding Device According to Sixteenth Embodiment
FIG. 103 is a diagram showing the configuration of the first modification 150A of the speech decoding device according to the sixteenth embodiment.

  FIG. 104 is a flowchart showing an operation of the first modification 150A of the speech decoding device according to the sixteenth embodiment. The difference with the speech decoding apparatus 150 of the sixteenth embodiment is that the high frequency decoding unit 100 eA uses a low frequency signal whose temporal envelope shape has been corrected by the low frequency temporal envelope correction unit 100 d for decoding a high frequency signal. It is a point to do. In Step 100-5A of FIG. 104, when the low frequency decoded signal obtained by the low frequency decoding unit 100b is used in decoding of the high frequency signal, the low frequency temporal envelope correction unit 100d corrects the time envelope shape. Use frequency signal.

  Note that the order of performing the processes of steps S150-2 and S150-3 may be determined before the process of determining the high-frequency temporal envelope shape and the high-frequency encoding part before the process of decoding, and is limited to the order of the flowchart in FIG. I will not.

[Second Modification of Speech Decoding Device of Sixteenth Embodiment]
FIG. 105 is a diagram showing the configuration of the second modification 150B of the speech decoding device according to the sixteenth embodiment. The difference with the first modification of the speech decoding apparatus according to the sixteenth embodiment is that the low frequency signal input to the low frequency / high frequency signal synthesis unit 150c is the output from the low frequency time envelope correction unit 100d. The point is the output from the low frequency decoding unit 100b.

[Third Modification of Speech Decoding Device of Sixteenth Embodiment]
FIG. 233 is a diagram showing the configuration of the third modification 150C of the speech decoding device according to the sixteenth embodiment.

  FIG. 234 is a flowchart showing an operation of the third modification 150C of the speech decoding device according to the sixteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 150 according to the sixteenth embodiment is that the low frequency temporal envelope shape determination unit 120c is replaced with the low frequency temporal envelope shape determination unit 100c and the high frequency temporal envelope correction unit 110c. , High frequency time envelope correction unit 120d.

[Fourth Modification of Speech Decoding Device of Sixteenth Embodiment]
FIG. 235 is a diagram showing the configuration of the fourth modification 150D of the speech decoding device according to the sixteenth embodiment.

  FIG. 236 is a flowchart showing an operation of the fourth modification 150D of the speech decoding device according to the sixteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 150 according to the sixteenth embodiment resides in that the high frequency time envelope shape determination unit 120b is replaced with the high frequency time envelope shape determination unit 100d. , Low frequency time envelope correction unit 120e.

[Fifth Modification of Speech Decoding Device of Sixteenth Embodiment]
FIG. 237 is a diagram showing the configuration of the fifth modification 150E of the speech decoding device according to the sixteenth embodiment.

  FIG. 238 is a flowchart showing an operation of the fifth modification 150E of the speech decoding device according to the sixteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 120d, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

[Sixth Modified Example of Speech Decoding Device of Sixteenth Embodiment]
FIG. 239 is a diagram showing the configuration of the sixth modification 150F of the speech decoding device according to the sixteenth embodiment.

  FIG. 240 is a flowchart showing an operation of the sixth modification 150F of the speech decoding device according to the sixteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 150 according to the sixteenth embodiment is that the time envelope shape determination unit 120f is provided instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. It is a point to do.

[Seventh Modified Example of Speech Decoding Device of Sixteenth Embodiment]
FIG. 241 is a diagram showing the configuration of a seventh modification 150G of the speech decoding device according to the sixteenth embodiment.

  FIG. 242 is a flowchart showing an operation of the seventh modification 150G of the speech decoding device according to the sixteenth embodiment.

  The difference between this modification and the first modification 150A of the speech decoding apparatus according to the sixteenth embodiment is the low frequency time envelope shape determination unit 100c and the high frequency time envelope correction unit 110c, instead of the low frequency. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 120d.

Eighth Modification of Speech Decoding Device According to Sixteenth Embodiment
FIG. 243 is a diagram showing the configuration of the eighth modification 150H of the speech decoding device according to the sixteenth embodiment.

  FIG. 244 is a flowchart showing an operation of the eighth modification 150H of the speech decoding device according to the sixteenth embodiment.

  The difference between this modification and the first modification 150A of the speech decoding apparatus according to the sixteenth embodiment lies in the high frequency time envelope shape determination unit 120b and the low frequency time envelope correction unit 100d. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

[Ninth Modification of Speech Decoding Device of Sixteenth Embodiment]
FIG. 245 is a diagram showing the configuration of the ninth modification 1501 of the speech decoding device according to the sixteenth embodiment.

  FIG. 246 is a flowchart showing an operation of the ninth modification 150I of the speech decoding device according to the sixteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 120d, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Tenth Modified Example of Speech Decoding Device of Sixteenth Embodiment
FIG. 247 is a diagram showing the configuration of the tenth modification 150J of the speech decoding device according to the sixteenth embodiment.

  FIG. 248 is a flowchart showing an operation of the tenth modification 150J of the speech decoding device according to the sixteenth embodiment.

  The difference between this modification and the first modification 150A of the speech decoding apparatus according to the sixteenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

[Eleventh Modification of Speech Decoding Device of Sixteenth Embodiment]
FIG. 249 is a diagram showing the configuration of an eleventh modification 150K of the speech decoding device according to the sixteenth embodiment.

  FIG. 250 is a flowchart showing the operation of the eleventh modification 150K of the speech decoding device according to the sixteenth embodiment.

  The difference between this modification and the second modification 150B of the speech decoding apparatus according to the sixteenth embodiment resides in the low frequency time envelope shape determination unit 100c and the high frequency time envelope correction unit 110c. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 120d.

Twelfth Modified Example of Speech Decoding Device According to Sixteenth Embodiment
FIG. 251 is a diagram showing a configuration of a twelfth modification 150L of the speech decoding device according to the sixteenth embodiment.

  FIG. 252 is a flowchart showing an operation of the twelfth modification 150L of the speech decoding device according to the sixteenth embodiment.

  The difference between this modification and the second modification 150B of the speech decoding apparatus according to the sixteenth embodiment resides in that the high-frequency time envelope shape determination unit 120b and the low-frequency time envelope correction unit 100d are replaced with a high frequency. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

[Thirteenth modified example of the speech decoding device according to the sixteenth embodiment]
FIG. 253 is a diagram showing the configuration of the thirteenth modification 150M of the speech decoding device according to the sixteenth embodiment.

  FIG. 254 is a flowchart showing an operation of the thirteenth modification 150M of the speech decoding device according to the sixteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 120d, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

[Seventeenth modified example of speech decoding apparatus according to the sixteenth embodiment]
FIG. 255 is a diagram showing the configuration of a fourteenth modification 150N of the speech decoding device according to the sixteenth embodiment.

  FIG. 256 is a flowchart showing an operation of the fourteenth modification 150N of the speech decoding device according to the sixteenth embodiment.

  The difference between this modification and the second modification 150B of the speech decoding apparatus according to the sixteenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Seventeenth Embodiment
FIG. 106 is a diagram showing the configuration of the speech decoding device 160 according to the seventeenth embodiment. The communication device of the speech decoding device 160 receives the multiplexed coded sequence output from the speech coding device 260 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 106, the speech decoding apparatus 160 functionally includes a coded sequence demultiplexing unit 150a, a switch group 150b, a low frequency decoding unit 100b, a low frequency time envelope shape determining unit 100c, and a low frequency time envelope A correction unit 100d, a high frequency time envelope shape determination unit 120b, a high frequency time envelope correction unit 130a, a high frequency decoding unit 130b, and a low frequency / high frequency signal synthesis unit 150c.

  FIG. 107 is a flowchart showing an operation of the speech decoding apparatus according to the seventeenth embodiment. The order of performing the processes of steps S150-2 and S150-3 may be determined before the process of determining the high-frequency time envelope shape and the high-frequency encoding part before the process of decoding, and is limited to the order of the flowchart of FIG. I will not.

  FIG. 108 is a diagram showing the configuration of the speech to digital converter 260 according to the seventeenth embodiment. The communication device of speech coding apparatus 260 receives from the outside a speech signal to be coded, and further outputs the coded coded sequence to the outside. As shown in FIG. 108, speech encoding apparatus 260 functionally includes high frequency signal generation control information encoding section 250 a, low frequency encoding section 200 a, high frequency encoding section 200 b, and low frequency time envelope information code. A coding unit 200c, a high frequency temporal envelope information coding unit 220a, and a coding sequence multiplexing unit 250b are provided.

  FIG. 109 is a flowchart showing the operation of the speech to digital converter 260 according to the seventeenth embodiment.

[First Modification of Speech Decoding Device of Seventeenth Embodiment]
FIG. 110 is a diagram showing the configuration of the first modification 160A of the speech decoding device according to the seventeenth embodiment.

  FIG. 111 is a flowchart showing an operation of the first modification 160A of the speech decoding device according to the seventeenth embodiment.

  The difference from the speech decoding apparatus 160 of the present embodiment is that the high frequency time envelope correction section 140a described in the first modification of the speech decoding apparatus of the fifteenth embodiment is replaced with the high frequency time envelope correction section 130a. The point is that

  The order of performing the processes in steps S150-2 and S150-3 may be determined before the process of determining the high-frequency time envelope shape and the high-frequency encoding part before the process of decoding, and is limited to the order of the flowchart in FIG. I will not.

[Second Modification of Speech Decoding Device of Seventeenth Embodiment]
FIG. 112 is a diagram showing the configuration of the second modification 170B of the speech decoding device according to the seventeenth embodiment.

  The difference with the first modification 160A of the speech decoding device according to this embodiment is the same as in the second modification of the speech decoding device according to the fifteenth embodiment, in the low frequency / high frequency signal combining unit 150c. The low frequency signal used for the combining process is a low frequency signal decoded by the low frequency decoding unit 100 b instead of the low frequency signal whose temporal envelope shape has been corrected by the low frequency time envelope correction unit 100 d.

[Third Modification of Speech Decoding Device of Seventeenth Embodiment]
FIG. 257 is a diagram showing the configuration of the third modification 160C of the speech decoding device according to the seventeenth embodiment.

  FIG. 258 is a flowchart showing an operation of the third modification 160C of the speech decoding device according to the seventeenth embodiment.

  The difference between the present modification and the speech decoding apparatus 160 according to the seventeenth embodiment is that the low frequency temporal envelope shape determination unit 120c is replaced with the low frequency temporal envelope correction unit 130a. , High frequency time envelope correction unit 140b.

[Fourth Modification of the Speech Decoding Device of the Seventeenth Embodiment]
FIG. 259 is a diagram showing the configuration of the fourth modification 160D of the speech decoding device according to the seventeenth embodiment.

  FIG. 260 is a flowchart showing an operation of the fourth modification 160D of the speech decoding device according to the seventeenth embodiment.

  The difference between the present modification and the speech decoding apparatus 160 according to the seventeenth embodiment resides in that the high frequency temporal envelope shape determination unit 120b is replaced with the high frequency temporal envelope correction unit 100d. , Low frequency time envelope correction unit 120e.

[Fifth Modification of Speech Decoding Device According to Seventeenth Embodiment]
FIG. 261 is a diagram showing the configuration of the fifth modification 160E of the speech decoding device according to the seventeenth embodiment.

  FIG. 262 is a flowchart showing an operation of the fifth modification 160E of the speech decoding device according to the seventeenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 140b, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Sixth Modification of Speech Decoding Device According to Seventeenth Embodiment
FIG. 263 is a drawing showing the configuration of the sixth modification 160F of the speech decoding device according to the seventeenth embodiment.

  FIG. 264 is a flowchart showing an operation of the sixth modification 160F of the speech decoding device according to the seventeenth embodiment.

  The difference between the present modification and the speech decoding apparatus 160 according to the seventeenth embodiment is that the time envelope shape determination unit 120f is provided instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. It is a point to do.

[Seventh Modified Example of Speech Decoding Device of Seventeenth Embodiment]
FIG. 265 is a diagram showing the configuration of a seventh modification 160G of the speech decoding device according to the seventeenth embodiment.

  FIG. 266 is a flowchart showing an operation of the seventh modification 160G of the speech decoding device according to the seventeenth embodiment.

  The difference between this modification and the first modification 160A of the speech decoding apparatus according to the seventeenth embodiment is that the low frequency time envelope shape determination unit 100c and the high frequency time envelope correction unit 140a are replaced with a low frequency. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 140b.

  In the present modification, the high frequency temporal envelope correction unit 140b performs at least one of the temporal envelope shape determined by the high frequency temporal envelope shape determination unit 120b and the temporal envelope shape determined by the low frequency temporal envelope shape determination unit 120c. Based on one or more, the shape of the temporal envelope of the low frequency signal whose temporal envelope shape has been corrected input to the high frequency decoding unit 130b is corrected (S140-2).

Eighth Modification of Speech Decoding Device According to Seventeenth Embodiment
FIG. 267 is a diagram showing a configuration of the eighth modification 160H of the speech decoding device according to the seventeenth embodiment.

  FIG. 268 is a flowchart showing an operation of the eighth modification 160H of the speech decoding device according to the seventeenth embodiment.

  The difference between this modification and the first modification 160A of the speech decoding apparatus according to the seventeenth embodiment is the high frequency time envelope shape determination unit 120b and the low frequency time envelope correction unit 100d. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

[Ninth modified example of speech decoding apparatus according to the seventeenth embodiment]
FIG. 269 is a diagram showing the configuration of the ninth modification 1601 of the speech decoding device according to the seventeenth embodiment.

  FIG. 270 is a flowchart showing an operation of the ninth modification 1601 of the speech decoding device according to the seventeenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 140b, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

Tenth Modified Example of Speech Decoding Device of Seventeenth Embodiment
FIG. 271 is a drawing showing the configuration of the tenth modification 160J of the speech decoding device according to the seventeenth embodiment.

  FIG. 272 is a flowchart showing an operation of the tenth modification 160J of the speech decoding device according to the seventeenth embodiment.

  The difference between this modification and the first modification 160A of the speech decoding apparatus according to the seventeenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Eleventh Modified Example of the Speech Decoding Device According to the Seventeenth Embodiment
FIG. 273 is a drawing showing the configuration of the eleventh modification 160K of the speech decoding device according to the seventeenth embodiment.

  FIG. 274 is a flowchart showing an operation of the eleventh modification 160K of the speech decoding device according to the seventeenth embodiment.

  The difference between this modification and the second modification 160B of the speech decoding apparatus according to the seventeenth embodiment is the low frequency time envelope shape determination unit 100c and the high frequency time envelope correction unit 140a. This is a point provided with a time envelope shape determination unit 120c and a high frequency time envelope correction unit 140b.

[Twelfth modified example of the speech decoding device according to the seventeenth embodiment]
FIG. 275 is a diagram showing the configuration of a twelfth modification 160L of the speech decoding device according to the seventeenth embodiment.

  FIG. 276 is a flowchart showing an operation of the twelfth modification 160L of the speech decoding device according to the seventeenth embodiment.

  The difference between this modification and the second modification 160B of the speech decoding apparatus according to the seventeenth embodiment is that the high-frequency time envelope shape determination unit 120b and the low-frequency time envelope correction unit 100d are replaced with a high frequency. This is a point provided with a time envelope shape determination unit 120bA and a low frequency time envelope correction unit 120e.

Thirteenth Modification of Speech Decoding Device According to Seventeenth Embodiment
FIG. 277 is a diagram showing a configuration of a thirteenth modification 160M of the speech decoding device according to the seventeenth embodiment.

  FIG. 278 is a flowchart showing an operation of a thirteenth modification 160M of the speech decoding device according to the seventeenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 120c, the high frequency time envelope correction unit 140b, the high frequency time envelope shape determination unit 120bA, and the low frequency time envelope correction unit 120e are provided.

[Seventeenth modified example of speech decoding apparatus according to the seventeenth embodiment]
FIG. 279 is a diagram showing the configuration of the fourteenth modification 160N of the speech decoding device according to the seventeenth embodiment.

  FIG. 280 is a flowchart showing an operation of the fourteenth modification 160N of the speech decoding device according to the seventeenth embodiment.

  The difference between this modification and the second modification 160B of the speech decoding apparatus according to the seventeenth embodiment is the time envelope instead of the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 120b. This is a point provided with the shape determination unit 120f.

Eighteenth Embodiment
FIG. 113 is a diagram showing the configuration of a speech decoding apparatus 170 according to the eighteenth embodiment. The communication device of the speech decoding device 170 receives the multiplexed coded sequence output from the speech coding device 270 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 113, the speech decoding apparatus 170 functionally includes a coded sequence demultiplexing unit 170a, a switch group 170b, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, Frequency time envelope shape determination unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, time envelope correction unit 13b, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i and a synthesis filter bank unit 170c.

  FIG. 114 is a flowchart showing an operation of the speech decoding apparatus according to the eighteenth embodiment.

  The coded sequence demultiplexing unit 170a includes information on the time envelopment shape required by the high frequency signal generation control information, the core coding portion obtained by coding the low frequency signal, and the low frequency time envelope shape determination unit 10e. (Step S170-1).

  Whether or not to generate a high frequency signal is determined based on the high frequency signal generation control information obtained by the coded sequence demultiplexing unit 170a (step S170-2).

  When generating a high frequency signal, the coding sequence demultiplexing unit 170a extracts a band extension part for generating a high frequency signal from the low frequency signal from the coding sequence, and the coding sequence analysis unit 13c generates a code The band extension part of the coded sequence extracted by the coded sequence demultiplexing unit 170a is analyzed, and information necessary for the high frequency signal generation unit 10g and the decoding / inverse quantization unit 10h, the high frequency time envelope shape determination unit 13a And the information on the time envelope shape required in step S170-3 (step S170-3). Then, a high frequency signal portion of the coded sequence is used to generate a high frequency signal, and further, the temporal envelope shape of the high frequency signal is determined to correct the temporal envelope shape of the high frequency signal.

  The order of performing the processes of steps S170-2 and S170-3 may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / dequantizing the band expansion part, and the flowchart of FIG. Not limited to the order of

  When it is determined that the synthesis filter bank unit 170c generates the high frequency signal based on the high frequency signal generation information, the low frequency subband signal whose temporal envelope shape is corrected and the high frequency subband whose temporal envelope shape is corrected The output speech signal is synthesized from the signal, and when it is determined not to generate the high frequency signal based on the high frequency signal generation information, the output speech signal is synthesized from the low frequency sub-band signal whose time envelope shape is corrected (step S170-4).

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding device 170 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding apparatus 170 according to the present embodiment, the first, second, and third modifications of the speech decoding apparatus according to the fourth embodiment of the present invention It is obvious that the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention is applicable.

  FIG. 115 is a diagram showing the configuration of the speech to digital converter 270 according to the eighteenth embodiment. The communication device of speech coding apparatus 270 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 115, the speech encoding apparatus 270 functionally includes a high frequency signal generation control information encoding unit 270a, a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, and control. Parameter coding unit 20d, envelope calculation unit 20e, quantization / coding unit 20f, core decoded signal generation unit 20i, subband signal power calculation unit 20j, time envelope information coding unit 270b, and coding sequence multiplexing unit 270c Equipped with

  FIG. 116 is a flowchart showing an operation of the speech to digital converter 270 according to the eighteenth embodiment.

  The high frequency signal generation control information encoding unit 270a determines whether to generate the high frequency signal based on at least one of the input voice signal and the high frequency signal generation control instruction signal, and the high frequency signal generation control information Are encoded (step S270-1). For example, when the input speech signal includes a signal of a frequency band generated by band expansion which performs quantization / coding in the quantization / coding unit 20 f, it can be determined to generate a high frequency signal. Furthermore, for example, when generation of a high frequency signal is instructed by the high frequency signal generation control instruction signal, it can be determined to generate a high frequency signal. Furthermore, for example, the two methods may be combined, and it may be determined that the high frequency signal is to be generated, for example, when it is determined that the high frequency signal is to be generated by at least one of the two methods.

  The high frequency signal generation control information can be encoded, for example, by representing whether to generate a high frequency signal with one bit.

  However, the determination as to whether or not to generate the high frequency signal, and the encoding method of the high frequency signal generation control information are not limited.

  When it is determined that the high frequency signal is to be generated by the high frequency signal generation control information encoding unit 270a, information necessary for generating the high frequency signal is calculated and encoded by band extension. On the other hand, when it is determined that the high frequency signal generation control information coding unit 270 a does not generate the high frequency signal, calculation / coding of information necessary to generate the high frequency signal is not performed (step S 270-2) ).

  When it is determined that the high frequency signal generation control information coding unit 270 a generates the high frequency signal, the time envelope information coding unit 270 b performs at least one of the time envelope of the low frequency signal and the time envelope of the high frequency signal. The above is calculated, and the time envelope of the core decoded signal is calculated using the power of the subband signal of the core decoded signal calculated by the subband signal power calculation unit 20j, and the time envelope and high frequency of the low frequency signal are calculated. Temporal envelope information is encoded from at least one or more of the temporal envelopes of the signal and the temporal envelope of the core decoded signal. The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information. Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of encoding the low frequency time envelope information and the high frequency time envelope information is not limited. On the other hand, when it is determined that the high frequency signal generation control information encoding unit 270a does not generate the high frequency signal, the time envelope of the low frequency signal is calculated, and the core calculated by the subband signal power calculation unit 20j. The time envelope of the core decoded signal is calculated using the power of the subband signal of the decoded signal, and the time envelope information on the low frequency signal is encoded from the time envelope of the low frequency signal and the time envelope of the core decoded signal (steps S270-3). Here, if it is determined that the high frequency signal generation control information encoding unit 270 a does not generate the high frequency signal, the envelope calculation unit 270 d can calculate only the power of the sub band signal of the low frequency signal, and further Can also send the sub-band signal of the low frequency signal to the time envelope information encoding unit 270 b without calculating the power of the sub-band signal of the low frequency signal. When the power of the sub-band signal of the low frequency signal is not calculated, the power of the sub-band signal of the low frequency signal may be calculated by the time envelopment information encoding unit 270b. It is not limited where the power is calculated.

  The coded sequence multiplexing unit 270c receives the high frequency signal generation control information encoded by the high frequency signal generation control information coding unit 270a, receives the coded sequence of the low frequency signal from the core coding unit 20b, When it is determined that the high-frequency signal generation control information coding unit 270a generates the high-frequency signal in the high-frequency signal generation control information coding unit 270a, it is encoded by the control parameter coding unit 20d. The control parameter is further received, the gain and noise signal magnitude for the high frequency signal encoded by the quantization / encoding unit 20 f are further received, and these are multiplexed and output as an encoded sequence (step S 270-4) ).

First Modification of Speech Decoding Device According to Eighteenth Embodiment
FIG. 281 is a diagram showing the configuration of the first modification 170A of the speech decoding device according to the eighteenth embodiment.

  FIG. 282 is a flowchart showing an operation of the first modification 170A of the speech decoding device according to the eighteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 170 according to the eighteenth embodiment is the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), and the temporal envelope correction unit 13b. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 16c.

[Second Modification of Speech Decoding Device of Eighteenth Embodiment]
FIG. 283 is a diagram showing the configuration of the second modification 170B of the speech decoding device according to the eighteenth embodiment.

  FIG. 284 is a flowchart showing an operation of the second modification 170B of the speech decoding device according to the eighteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 170 according to the eighteenth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of Eighteenth Embodiment]
FIG. 285 is a diagram showing the configuration of the third modification 170C of the speech decoding device according to the eighteenth embodiment.

  FIG. 286 is a flowchart showing an operation of the third modification 170C of the speech decoding device according to the eighteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 16c, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fourth Modification of Speech Decoding Device of Eighteenth Embodiment]
FIG. 287 is a diagram showing the configuration of the fourth modification 170D of the speech decoding device according to the eighteenth embodiment.

  FIG. 288 is a flowchart showing an operation of the fourth modification 170D of the speech decoding device according to the eighteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 170 according to the eighteenth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

Nineteenth Embodiment
FIG. 117 is a diagram showing the configuration of a speech decoding apparatus 180 according to the nineteenth embodiment. The communication device of the speech decoding device 180 receives the multiplexed coded sequence output from the speech coding device 280 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 117, the speech decoding apparatus 180 functionally has a coded sequence demultiplexing unit 170 a, a switch group 170 b, a core decoding unit 10 b, an analysis filter bank unit 10 c, a coded sequence analysis unit 13 c, Frequency time envelope shape determination unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, high frequency signal generation unit 10g, time envelope correction unit 14a, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i and a synthesis filter bank unit 170c.

  FIG. 118 is a flowchart showing the operation of the speech decoding apparatus according to the nineteenth embodiment. The order in which the processes of steps S170-2 and S170-3 are performed may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / dequantizing the band expansion part, and the flowchart of FIG. Not limited to the order of

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding device 180 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding apparatus 180 according to the present embodiment, the first, second, and third modifications of the speech decoding apparatus according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 119 is a diagram showing the configuration of the speech to digital converter 280 according to the nineteenth embodiment. The communication device of speech coding apparatus 280 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 119, the speech encoding apparatus 280 functionally includes a high frequency signal generation control information encoding unit 270a, a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, and control. Parameter coding unit 20d, envelope calculation unit 270d, quantization / coding unit 20f, core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, pseudo high frequency signal generation unit 24a, time envelope information coding unit 280a and a coded sequence multiplexing unit 270c.

  FIG. 120 is a flowchart showing the operation of the speech to digital converter 280 according to the nineteenth embodiment.

  When it is determined to generate a high frequency signal in the high frequency signal generation control information encoding unit 270a, information necessary for generating the high frequency signal is calculated and encoded by band extension, and a pseudo high frequency signal is further generated. It generates and calculates the time envelope of the said pseudo | simulation high frequency signal. On the other hand, when it is determined that the high frequency signal generation control information coding unit 270a does not generate the high frequency signal, the information necessary for generating the high frequency signal in the band extension is calculated / coded, and the pseudo The generation of the high frequency signal and the calculation of the time envelope are not performed (step S280-1).

  When it is determined that the high frequency signal generation control information coding unit 270 a generates the high frequency signal, the time envelope information coding unit 280 a may time envelope of the low frequency signal of the input speech signal, time envelope of the high frequency signal, At least one of the temporal envelope of the core decoded signal and the temporal envelope of the pseudo high frequency signal is calculated, and temporal envelope information is encoded from the calculated temporal envelope. The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information. Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of encoding the low frequency time envelope information and the high frequency time envelope information is not limited. On the other hand, when it is determined that the high frequency signal generation control information coding unit 270a does not generate the high frequency signal, at least one of the time envelope of the low frequency signal of the input speech signal and the time envelope of the core decoding signal is selected. Based on the calculated and calculated time envelope, time envelope information related to the low frequency signal is encoded (step S280-2).

  It is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 280 according to the present embodiment.

[First Modification of Speech Decoding Device of the Nineteenth Embodiment]
FIG. 289 is a diagram showing the configuration of the first modification 180A of the speech decoding device according to the nineteenth embodiment.

  FIG. 290 is a flowchart showing an operation of the first modification 180A of the speech decoding device according to the nineteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 180 according to the nineteenth embodiment is the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA and 10eB may be used), and the temporal envelope correction unit 14a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 17a.

[Second Modification of Speech Decoding Device of Nineteenth Embodiment]
FIG. 291 is a diagram showing the configuration of the second modification 180B of the speech decoding device according to the nineteenth embodiment.

  FIG. 292 is a flowchart showing an operation of the second modification 180B of the speech decoding device according to the nineteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 180 according to the nineteenth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of the Nineteenth Embodiment]
FIG. 293 is a diagram showing the configuration of the third modification 180C of the speech decoding device according to the nineteenth embodiment.

  FIG. 294 is a flowchart showing an operation of the third modification 180C of the speech decoding device according to the nineteenth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 17a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fourth Modification of the Speech Decoding Device of the Nineteenth Embodiment]
FIG. 295 is a diagram showing the configuration of the fourth modification 180D of the speech decoding device according to the nineteenth embodiment.

  FIG. 296 is a flowchart showing an operation of the fourth modification 180D of the speech decoding device according to the nineteenth embodiment.

  The difference between the present modification and the speech decoding apparatus 180 according to the nineteenth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

20th Embodiment
FIG. 121 is a diagram showing the configuration of the speech decoding device 190 according to the twentieth embodiment. The communication device of the speech decoding device 190 receives the multiplexed coded sequence output from the speech coding device 290 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 121, the speech decoding apparatus 190 functionally has a coded sequence demultiplexing unit 170a, a switch group 170b, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, Frequency time envelope shape determination unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, time envelope correction unit 15a and a synthesis filter bank unit 170c.

  FIG. 122 is a flowchart showing an operation of the speech decoding apparatus according to the twentieth embodiment. The order of performing the processes of steps S170-2 and S170-3 may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / dequantizing the band expansion part, and the flowchart of FIG. Not limited to the order of

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low frequency time envelope shape determination unit 10e of the speech decoding device 190 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 190 according to the present embodiment, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 123 is a diagram showing the configuration of speech encoding apparatus 290 according to the twentieth embodiment. The communication device of speech coding apparatus 290 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 123, speech encoding apparatus 290 functionally includes high frequency signal generation control information encoding section 270a, downsampling section 20a, core encoding section 20b, analysis filter bank sections 20c and 20c1, and control. Parameter coding unit 20d, envelope calculation unit 270d, quantization / coding unit 20f, core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, pseudo high frequency signal generation unit 24a, time envelope information coding unit 280a and a coded sequence multiplexing unit 270c.

  FIG. 124 is a flowchart showing an operation of the speech to digital converter 290 according to the twentieth embodiment.

When it is determined that the high frequency signal generation control information coding unit 270 a generates the high frequency signal, the time envelope information coding unit 290 a may time envelope of the low frequency signal of the input speech signal, time envelope of the high frequency signal, At least one of the temporal envelope of the core decoded signal and the temporal envelope of the frequency envelope-adjusted pseudo high frequency signal is calculated, and temporal envelope information is encoded from the calculated temporal envelope. The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information. Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of encoding the low frequency time envelope information and the high frequency time envelope information is not limited.
On the other hand, when it is determined that the high frequency signal generation control information coding unit 270a does not generate the high frequency signal, at least one of the time envelope of the low frequency signal of the input speech signal and the time envelope of the core decoding signal is selected. Based on the calculated and calculated time envelope, time envelope information related to the low frequency signal is encoded (step S290-1).

  It is obvious that the first modification of the speech to digital converter of the seventh embodiment of the present invention can be applied to the speech to digital converter 290 according to the present embodiment.

[First Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 297 is a diagram showing the configuration of the first modification 190A of the speech decoding device according to the twentieth embodiment.

  FIG. 298 is a flowchart showing an operation of the first modification 190A of the speech decoding device according to the twentieth embodiment.

  The difference between the present modification and the speech decoding apparatus 190 according to the twentieth embodiment is that a time envelope correction unit 15aA is provided instead of the time envelope correction unit 13a.

[Second Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 299 is a diagram showing the configuration of the second modification 190B of the speech decoding device according to the twentieth embodiment.

  FIG. 300 is a flowchart showing the operation of the second modification 190B of the speech decoding device according to the twentieth embodiment.

  The difference between the present modification and the speech decoding apparatus 190 according to the twentieth embodiment is that the low-frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), and the time envelope correction unit 15a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 18a.

[Third Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 301 is a diagram showing the configuration of the third modification 190C of the speech decoding device according to the twentieth embodiment.

  FIG. 302 is a flowchart showing an operation of the third modification 190C of the speech decoding device according to the twentieth embodiment.

  The difference between the present modification and the speech decoding apparatus 190 according to the twentieth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Fourth Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 303 is a diagram showing the configuration of the fourth modification 190D of the speech decoding device according to the twentieth embodiment.

  FIG. 304 is a flowchart showing an operation of the fourth modification 190D of the speech decoding device according to the twentieth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fifth Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 305 is a diagram showing the configuration of the fifth modification 190E of the speech decoding device according to the twentieth embodiment.

  FIG. 306 is a flowchart showing an operation of the fifth modification 190E of the speech decoding device according to the twentieth embodiment.

  The difference between the present modification and the speech decoding apparatus 190 according to the twentieth embodiment is that the low-frequency time envelope shape determination unit 10e and the high-frequency time envelope shape determination unit 13a are replaced by a time envelope shape determination unit 16f. It is a point to do.

[Sixth Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 307 is a diagram showing the configuration of the sixth modification 190F of the speech decoding device according to the twentieth embodiment.

  FIG. 308 is a flowchart showing an operation of the sixth modification 190F of the speech decoding device according to the twentieth embodiment.

  The difference between the present modification and the speech decoding apparatus 190A according to the first modification of the twentieth embodiment is that the low-frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), time This is a point provided with a low frequency time envelope shape determination unit 16b and a time envelope correction unit 18aA instead of the envelope correction unit 15aA.

Seventh Modification of Speech Decoding Device of Twentieth Embodiment
FIG. 309 is a diagram showing the configuration of a seventh modification 190G of the speech decoding device according to the twentieth embodiment.

  FIG. 310 is a flowchart showing an operation of the seventh modification 190G of the speech decoding device according to the twentieth embodiment.

  The difference between the speech decoding apparatus 190A according to this modification and the first modification of the twentieth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), and low. It is a point provided with the high frequency time envelope shape determination unit 16 d and the low frequency time envelope correction unit 16 e instead of the frequency time envelope correction unit 10 f.

Eighth Modification of Speech Decoding Device of Twentieth Embodiment
FIG. 311 is a diagram showing the configuration of the eighth modification 190H of the speech decoding device according to the twentieth embodiment.

  FIG. 312 is a flowchart showing an operation of the eighth modification 190H of the speech decoding device according to the twentieth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18aA, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Ninth Modification of Speech Decoding Device of Twentieth Embodiment]
FIG. 313 is a diagram showing the configuration of the ninth modification 1901 of the speech decoding device according to the twentieth embodiment.

  FIG. 314 is a flowchart showing the operation of the ninth modification 1901 of the speech decoding device according to the twentieth embodiment.

  The difference between the present modification and the speech decoding apparatus 190A according to the first modification of the twentieth embodiment is that the time envelope is changed to the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. This is a point provided with the shape determination unit 16f.

21st Embodiment
FIG. 125 is a diagram showing the configuration of the speech decoding apparatus 300 according to the twenty-first embodiment. The communication device of the speech decoding apparatus 300 receives the multiplexed coded sequence output from the speech coding apparatus 400 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 125, the speech decoding apparatus 300 functionally includes a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a low frequency time envelope shape. Decision unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, time envelope correction unit 300a, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, and synthesis A filter bank unit 10 j is provided.

  FIG. 126 is a flowchart showing an operation of the speech decoding apparatus according to the twenty-first embodiment.

  The time envelope correction unit 300a is output from the low frequency time envelope correction unit 10f based on the time envelope shape determined by the high frequency time envelope shape determination unit 13a, and generates a high frequency signal in the high frequency signal generation unit 10g. The shape of the temporal envelope of the plurality of sub-band signals of the low frequency signal whose temporal envelope shape has been corrected is corrected (step S300-1). The difference from the time envelope correction unit 13b is that the time at which the input signal is output from the low frequency time envelope correction unit 10f instead of the plurality of sub-band signals of the low frequency signal output from the analysis filter bank unit 10c. It is a point which is a plurality of sub-band signals of a low frequency signal whose envelope shape has been corrected. In the time envelope correction processing in time envelope correction unit 13b, the plurality of sub-band signals of the low frequency signal output from analysis filter bank unit 10c are corrected for the time envelope shape output from low frequency time envelope correction unit 10f. This can be realized by converting to a plurality of sub-band signals of the low frequency signal.

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding device 300 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 300 according to the present embodiment, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is obvious that the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention is applicable.

  FIG. 127 is a diagram showing the configuration of speech encoding apparatus 400 according to the twenty-first embodiment. The communication device of speech coding apparatus 400 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 127, the speech encoding apparatus 400 functionally includes a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, a control parameter encoding unit 20d, an envelope calculation unit 20e, A quantization / coding unit 20f, a core decoded signal generation unit 20i, a subband signal power calculation unit 20j, a time envelope information coding unit 400a, and a coding sequence multiplexing unit 20h are provided.

  FIG. 128 is a flowchart showing an operation of the speech to digital converter 400 according to the twenty-first embodiment.

  The time envelopment information encoding unit 400a calculates at least one or more of the time envelopment of the low frequency signal and the time envelopment of the high frequency signal, and further calculates the sub of the core decoded signal calculated by the sub band signal power calculation unit 20j. The time envelope of the core decoded signal is calculated using the power of the band signal, and the time envelope information is encoded from the time envelope of the core decoded signal and at least one of the time envelope of the low frequency signal and the time envelope of the high frequency signal Step S400-1). The temporal envelope information includes low frequency temporal envelope information and high frequency temporal envelope information. Similar to the operation of the time envelope information encoding unit 26a of the speech encoding apparatus 26 according to the seventh embodiment, the method of encoding the low frequency time envelope information and the high frequency time envelope information is not limited. The difference with the time envelopment information encoding unit 26a is that, when calculating time envelopment information on a high frequency signal, at least one of time envelopment information on a core decoded signal and time envelopment information on a low frequency signal is used. The time envelope shape can be used to correct the time envelope of the core decoded signal. The time envelope information of the high frequency signal can be generated based on the time envelope information of the low frequency signal.

[First Modification of Speech Decoding Device of the Twenty-first Embodiment]
FIG. 315 is a diagram showing the configuration of the first modification 300A of the speech decoding device according to the twenty-first embodiment.

  FIG. 316 is a flowchart showing an operation of the first modification 300A of the speech decoding device according to the twenty-first embodiment.

  The difference between the present modification and the speech decoding apparatus 300 according to the twenty-first embodiment is the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA and 10eB may be used), and the temporal envelope correction unit 300a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 300aA.

  In this modification, the difference between the time envelope correction unit 300aA and the time envelope correction unit 300a is the time envelope shape received from the high frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, 13aB may be used) Based on at least one or more of the time envelope shapes received from the low frequency time envelope shape determination unit 16b, output from the low frequency time envelope correction unit 10f and use it to generate high frequency signals in the high frequency signal generation unit 10g The point is to correct the shape of the temporal envelope of the plurality of sub-band signals of the low frequency signal whose temporal envelope shape has been corrected (S300-1a).

[Second Modification of Speech Decoding Device of Twenty-first Embodiment]
FIG. 317 is a diagram showing the configuration of the second modification 300B of the speech decoding device according to the twenty-first embodiment.

  FIG. 318 is a flowchart showing an operation of the second modification 300B of the speech decoding device according to the twenty-first embodiment.

  The difference between the present modification and the speech decoding apparatus 300 according to the twenty-first embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of Twenty-first Embodiment]
FIG. 319 is a diagram showing the configuration of the third modification 300C of the speech decoding device according to the twenty-first embodiment.

  FIG. 320 is a flowchart showing an operation of the third modification 300C of the speech decoding device according to the twenty-first embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 300aA, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fourth Modification of the Speech Decoding Device of the Twenty-first Embodiment]
FIG. 321 is a diagram showing the configuration of the fourth modification 300D of the speech decoding device according to the twenty-first embodiment.

  FIG. 322 is a flowchart showing an operation of the fourth modification 300D of the speech decoding device according to the twenty-first embodiment.

  The difference between the present modification and the speech decoding apparatus 300 according to the twenty-first embodiment is that the low-frequency time envelope shape determination unit 10e and the high-frequency time envelope shape determination unit 13a are replaced by a time envelope shape determination unit 16f. It is a point to do.

Twenty-Second Embodiment
FIG. 129 is a diagram showing the configuration of a speech decoding apparatus 310 according to the twenty-second embodiment. The communication device of the speech decoding device 310 receives the multiplexed coded sequence output from the speech coding device 410 below, and further outputs the decoded speech signal to the outside. As shown in FIG. 129, the speech decoding apparatus 310 functionally includes a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a low frequency time envelope shape. Decision unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, high frequency signal generation unit 10g, time envelope correction unit 14a, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, and synthesis A filter bank unit 10 j is provided.

  FIG. 130 is a flowchart showing the operation of the speech decoding apparatus according to the twenty-second embodiment.

  The difference with the speech decoding apparatus 17 according to the eighth embodiment of the present invention is that the high frequency signal generation unit 10 g substitutes for a plurality of sub-band signals of the low frequency signal output from the analysis filter bank unit 10 c. The point is that a high frequency signal is generated using a plurality of sub-band signals of the low frequency signal whose temporal envelope shape is corrected and which is output from the temporal envelope correction unit 10 f.

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low frequency time envelope shape determination unit 10e of the speech decoding device 310 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding apparatus 310 according to the present embodiment, the first, second, and third modifications of the speech decoding apparatus according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 131 is a diagram showing the configuration of the speech to digital converter 410 according to the nineteenth embodiment. The communication device of speech coding apparatus 410 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 131, the speech coding apparatus 410 functionally includes a downsampling unit 20a, a core coding unit 20b, analysis filter bank units 20c and 20c1, a control parameter coding unit 20d, an envelope calculation unit 270d, A quantization / coding unit 20f, a core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, a pseudo high frequency signal generation unit 410b, a time envelope information coding unit 410a, and a coded sequence multiplexing unit 270c. Prepare.

  FIG. 132 is a flowchart showing the operation of the speech to digital converter 410 according to the twenty-second embodiment.

  The temporal envelope information encoding unit 410a calculates at least one or more of the temporal envelope of the low frequency signal of the input speech signal and the temporal envelope of the core decoding signal, and temporal envelope information on the low frequency signal from the calculated temporal envelope. Are encoded (step S410-1).

  The pseudo high frequency signal generation unit 410 b controls the sub-band signal of the low frequency signal of the input speech signal obtained by the analysis filter bank unit 20 c and the control necessary to generate the high frequency signal obtained by the control parameter coding unit 20 d. A pseudo high frequency signal is generated based on the parameters (step S410-2). The difference from the pseudo high frequency signal generation unit 24a is that, when generating the pseudo high frequency signal, analysis filter bank using the time envelope information on the low frequency signal encoded by the time envelope information encoding unit 410a. The point is that the sub-band signal of the low frequency signal of the input speech signal obtained by the unit 20c can be corrected.

  The temporal envelope information encoding unit 410a calculates at least one or more of the temporal envelope of the high frequency signal of the input speech signal and the temporal envelope of the pseudo high frequency signal, and the temporal envelope of the high frequency signal is calculated from the calculated temporal envelope. The information is encoded (step S410-3).

  Note that the temporal envelope information encoding unit 410a can output temporally encoded information on the low frequency signal and temporal envelope information on the high frequency signal separately as an encoded sequence, and further, the time associated with the low frequency signal The envelope information and the temporal envelope information related to the high frequency signal may be combined and output as a coded sequence, and the format of the coded sequence of the temporal envelope information is not limited in the present invention. Further, as with the operation of the time envelopment information encoding unit 26a of the speech to digital converter 26 according to the seventh embodiment, the method of encoding the low frequency time envelopment information and the high frequency time envelopment information is not limited.

  When the pseudo high frequency signal generation unit 410 b generates the pseudo high frequency signal, the time envelope information is not used when the low frequency signal encoded by the time envelope information encoding unit 410 a is not used. The encoding unit 410a can perform the processes of steps S410-1 and S410-3 together. For example, at least one of the time envelope of the low frequency signal of the input speech signal, the time envelope of the high frequency signal, the time envelope of the core decoded signal, and the time envelope of the pseudo high frequency signal The time envelopment information can be encoded from the calculated time envelopment.

  It is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 410 according to the present embodiment. Also, temporal envelope information of the high frequency signal can be generated based on temporal envelope information of the low frequency signal.

[First Modification of Speech Decoding Device According to Twenty-Second Embodiment]
FIG. 323 is a diagram showing the configuration of the first modification 310A of the speech decoding device according to the twenty-second embodiment.

  FIG. 324 is a flowchart showing an operation of the first modification 310A of the speech decoding device according to the twenty-second embodiment.

  The difference between the present modification and the speech decoding apparatus 310 according to the twenty-second embodiment is that the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA and 10eB may be used), and the temporal envelope correction unit 14a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 17a.

[Second Modification of Speech Decoding Device of Twenty-Second Embodiment]
FIG. 325 is a diagram showing the configuration of the second modification 310B of the speech decoding device according to the twenty-second embodiment.

  FIG. 326 is a flowchart showing an operation of the second modification 310B of the speech decoding device according to the twenty-second embodiment.

  The difference between the present modification and the speech decoding apparatus 310 according to the twenty-second embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of Twenty-Second Embodiment]
FIG. 327 is a diagram showing the configuration of the third modification 310C of the speech decoding device according to the twenty-second embodiment.

  FIG. 328 is a flowchart showing an operation of the third modification 310C of the speech decoding device according to the twenty-second embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 17a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fourth Modification of Speech Decoding Device According to Twenty-Second Embodiment]
FIG. 329 is a diagram showing the configuration of the fourth modification 310D of the speech decoding device according to the twenty-second embodiment.

  FIG. 330 is a flowchart showing the operation of the fourth modification 310D of the speech decoding device according to the twenty-second embodiment.

  The difference between the present modification and the speech decoding apparatus 310 according to the twenty-second embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

Twenty-Third Embodiment
FIG. 133 is a diagram showing the configuration of the speech decoding apparatus 320 according to the twenty-third embodiment. The communication device of the speech decoding device 320 receives the multiplexed coded sequence output from the speech coding device 420 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 133, the speech decoding apparatus 320 functionally has a coded sequence demultiplexing unit 10a, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, and a low frequency time envelope shape. Decision unit 10e, low frequency time envelope correction unit 10f, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, high frequency time envelope shape determination unit 13a, time envelope correction unit 14a, and synthesis A filter bank unit 10 j is provided.

  FIG. 134 is a flowchart showing an operation of the speech decoding apparatus according to a twenty-third embodiment.

  The difference from the speech decoding apparatus 18 according to the ninth embodiment is that the high frequency signal generation unit 10g substitutes a plurality of sub-band signals of the low frequency signal output from the analysis filter bank unit 10c for low frequency time. The point is that a high frequency signal is generated using a plurality of sub-band signals of the low frequency signal whose temporal envelope shape is corrected and which is output from the envelope correction unit 10 f.

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low frequency time envelope shape determination unit 10e of the speech decoding device 320 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 320 according to the present embodiment, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 135 is a diagram showing the configuration of the speech to digital converter 420 according to the twenty-third embodiment. The communication device of speech coding apparatus 420 externally receives a speech signal to be coded, and further outputs the coded coded sequence to the outside. As shown in FIG. 135, the speech coding apparatus 420 functionally includes a downsampling unit 20a, a core coding unit 20b, analysis filter bank units 20c and 20c1, a control parameter coding unit 20d, an envelope calculation unit 20e, Quantization / coding unit 20f, pseudo high frequency signal generation unit 410b, frequency envelope adjustment unit 25a, core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, time envelope information coding unit 420a, and coding A sequence multiplexing unit 20h is provided.

  FIG. 136 is a flowchart showing the operation of the speech to digital converter 420 according to the twenty-third embodiment.

  The time envelopment information encoding unit 420a calculates at least one of the time envelopment of the high frequency signal of the input speech signal and the time envelopment of the pseudo high frequency signal subjected to the wave number envelopment adjustment, and is higher than the calculated time envelop The time envelope information on the frequency signal is encoded (step S420-1).

  Note that the temporal envelope information encoding unit 420a can output temporally encoded information on the low frequency signal and temporal envelope information on the high frequency signal separately as an encoded sequence, and further, the time associated with the low frequency signal The envelope information and the temporal envelope information related to the high frequency signal may be combined and output as a coded sequence, and the format of the coded sequence of the temporal envelope information is not limited in the present invention. Further, as with the operation of the time envelopment information encoding unit 26a of the speech to digital converter 26 according to the seventh embodiment, the method of encoding the low frequency time envelopment information and the high frequency time envelopment information is not limited.

  Similar to the speech encoding apparatus 410 according to the twenty-second embodiment, the time envelope information encoding unit 420a can perform the processes of steps S410-1 and S420-1 together. Further, it is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 420 according to the present embodiment. Also, temporal envelope information of the high frequency signal can be generated based on temporal envelope information of the low frequency signal.

[First Modification of Speech Decoding Device According to Twenty-Third Embodiment]
FIG. 137 is a diagram showing the configuration of a speech decoding apparatus 320A according to a first modification of the twenty-third embodiment.

  FIG. 138 is a flowchart showing an operation of the speech decoding device 320A according to the first modified example of the twenty-third embodiment.

  The difference from the speech decoding apparatus 320 according to the twenty-third embodiment is that a time envelope correction unit 15aA is used instead of the time envelope correction unit 15a.

  The first, second, and third variants of the speech decoding apparatus according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding apparatus 320A according to the present modification. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 320A according to the present modification, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

[Second Modification of Speech Decoding Device According to Twenty-Third Embodiment]
FIG. 331 is a diagram showing the configuration of the second modification 320B of the speech decoding device according to the twenty-third embodiment.

  FIG. 332 is a flowchart showing an operation of the second modification 320B of the speech decoding device according to a twenty-third embodiment.

  The difference between the present modification and the speech decoding apparatus 320 according to the twenty-third embodiment is that the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA and 10eB may be used), and the temporal envelope correction unit 15a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 18a.

[Third Modification of Speech Decoding Device of Twenty-Third Embodiment]
FIG. 333 is a diagram showing the configuration of the third modification 320C of the speech decoding device according to the twenty-third embodiment.

  FIG. 334 is a flowchart showing an operation of the third modification 320C of the speech decoding device according to the twenty-third embodiment.

  The difference between the present modification and the speech decoding apparatus 320 according to the twenty-third embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Fourth Modification of Speech Decoding Device According to Twenty-Third Embodiment]
FIG. 335 is a diagram showing the configuration of the fourth modification 320D of the speech decoding device according to the twenty-third embodiment.

  FIG. 336 is a flowchart showing an operation of the fourth modification 320D of the speech decoding device according to a twenty-third embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fifth Modification of Speech Decoding Device According to Twenty-Third Embodiment]
FIG. 337 is a diagram showing the configuration of the fifth modification 320E of the speech decoding device according to the twenty-third embodiment.

  FIG. 338 is a flowchart showing an operation of the fifth modification 320E of the speech decoding device according to a twenty-third embodiment.

  The difference between the present modification and the speech decoding apparatus 320 according to the twenty-third embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

[Sixth Modified Example of Speech Decoding Device According to Twenty-Third Embodiment]
FIG. 339 is a drawing showing the configuration of the sixth modification 320F of the speech decoding device according to the twenty-third embodiment.

  FIG. 340 is a flowchart showing an operation of the sixth modification 320F of the speech decoding device according to the twenty-third embodiment.

  The difference between the present modification and the speech decoding apparatus 320A according to the first modification of the twenty-third embodiment is that the low-frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), time This is a point provided with a low frequency time envelope shape determination unit 16b and a time envelope correction unit 18aA instead of the envelope correction unit 15aA.

[Seventh modified example of speech decoding apparatus according to the twenty-third embodiment]
FIG. 341 is a diagram showing the configuration of a seventh modification 320G of the speech decoding device according to the twenty-third embodiment.

  FIG. 342 is a flowchart showing an operation of the seventh modification 320G of the speech decoding device according to the twenty-third embodiment.

  The difference between the present modification and the speech decoding apparatus 320A according to the first modification of the twenty-third embodiment is that the high-frequency time envelope shape determination unit 13aC (13a, 13aA, and 13aB may be obvious), low It is a point provided with the high frequency time envelope shape determination unit 16 d and the low frequency time envelope correction unit 16 e instead of the frequency time envelope correction unit 10 f.

Eighth Modification of Speech Decoding Device According to the Twenty-Third Embodiment
FIG. 343 is a drawing showing the configuration of the eighth modification 320H of the speech decoding device according to the twenty-third embodiment.

  FIG. 344 is a flowchart showing an operation of the eighth modification 320H of the speech decoding device according to a twenty-third embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18aA, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Ninth modified example of speech decoding apparatus according to the twenty-third embodiment]
FIG. 345 is a diagram showing the configuration of the ninth modification 3201 of the speech decoding device according to the twenty-third embodiment.

  FIG. 346 is a flowchart showing an operation of the ninth modification 3201 of the speech decoding device according to a twenty-third embodiment.

  The difference between the present modification and the speech decoding apparatus 320A according to the first modification of the twenty-third embodiment is the time envelope instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. This is a point provided with the shape determination unit 16f.

Twenty-Fourth Embodiment
FIG. 139 is a diagram showing the configuration of the speech decoding apparatus 330 according to the twenty-fourth embodiment. The communication device of the speech decoding device 330 receives the multiplexed coded sequence output from the speech coding device 430 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 139, the speech decoding apparatus 330 functionally includes a coded sequence demultiplexing unit 170a, a switch group 170b, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, Frequency time envelope shape determination unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, time envelope correction unit 300a, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i and a synthesis filter bank unit 170c.

  FIG. 140 is a flowchart showing the operation of the speech decoding apparatus according to the twenty-fourth embodiment. The order in which the processes of steps S170-2 and S170-3 are performed may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / dequantizing the band expansion part, and the flowchart of FIG. Not limited to the order of

  The first, second, and third variants of the speech decoding apparatus according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding apparatus 330 according to the present modification. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 330 according to the present modification, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is obvious that the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention is applicable.

  FIG. 141 is a diagram showing the configuration of the speech to digital converter 430 according to the twenty-fourth embodiment. The communication device of speech coding apparatus 430 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 141, speech encoding apparatus 430 functionally includes high frequency signal generation control information encoding section 270a, downsampling section 20a, core encoding section 20b, analysis filter bank sections 20c and 20c1, and control. Parameter coding unit 20d, envelope calculation unit 20e, quantization / coding unit 20f, core decoded signal generation unit 20i, subband signal power calculation unit 20j, time envelope information coding unit 400a, and coding sequence multiplexing unit 270c Equipped with

  FIG. 142 is a flowchart showing the operation of the speech to digital converter 430 according to the twenty-fourth embodiment. At step S400-1, the time envelope information encoding unit 400a calculates and encodes time envelope information. The time envelope information of the high frequency signal can be generated based on the time envelope information of the low frequency signal.

[First Modification of Speech Decoding Device of the Twenty-fourth Embodiment]
FIG. 347 is a diagram showing the configuration of the first modification 330A of the speech decoding device according to the twenty-fourth embodiment.

  FIG. 348 is a flowchart showing an operation of the first modification 330A of the speech decoding device according to a twenty-fourth embodiment.

  The difference between the present modification and the speech decoding apparatus 330 according to the twenty-fourth embodiment is the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), and the temporal envelope correction unit 300a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 300aA.

[Second Modification of Speech Decoding Device of the Twenty-fourth Embodiment]
FIG. 349 is a diagram showing the configuration of the second modification 330B of the speech decoding device according to the twenty-fourth embodiment.

  FIG. 350 is a flowchart showing the operation of the second modification 330B of the speech decoding device according to the twenty-fourth embodiment.

  The difference between the present modification and the speech decoding apparatus 330 according to the twenty-fourth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of the Twenty-fourth Embodiment]
FIG. 351 is a diagram showing the configuration of the third modification 330C of the speech decoding device according to the twenty-fourth embodiment.

  FIG. 352 is a flowchart showing an operation of the third modification 330C of the speech decoding device according to the twenty-fourth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 300aA, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fourth Modification of Speech Decoding Device of the Twenty-fourth Embodiment]
FIG. 353 is a diagram showing the configuration of the fourth modification 330D of the speech decoding device according to the twenty-fourth embodiment.

  FIG. 354 is a flowchart showing an operation of the fourth modification 330D of the speech decoding device according to the twenty-fourth embodiment.

  The difference between the present modification and the speech decoding apparatus 330 according to the twenty-fourth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

Twenty-Fifth Embodiment
FIG. 143 is a diagram showing the configuration of the speech decoding device 340 according to the twenty-fifth embodiment. The communication device of the speech decoding device 340 receives the multiplexed coded sequence output from the speech coding device 440 below, and further outputs the decoded speech signal to the outside. As shown in FIG. 143, the speech decoding apparatus 340 functionally has a coded sequence demultiplexing unit 170a, a switch group 170b, a core decoding unit 10b, an analysis filter bank unit 10c, a coded sequence analysis unit 13c, Frequency time envelope shape determination unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, time envelope correction unit 14a, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i and a synthesis filter bank unit 170c.

  FIG. 144 is a flowchart showing the operation of the speech decoding apparatus according to the twenty-fifth embodiment. The order of performing the processes of steps S170-2 and S170-3 may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / dequantizing the band expansion part, and the flowchart of FIG. Not limited to the order of

  The first, second, and third variants of the speech decoding apparatus according to the first embodiment of the present invention are compared to the low-frequency time envelope shape determination unit 10e of the speech decoding apparatus 340 according to the present modification. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding apparatus 340 according to the present modification, the first, second, and third modifications of the speech decoding apparatus according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 145 is a diagram showing the configuration of the speech to digital converter 440 according to the twenty-fifth embodiment. The communication device of speech coding apparatus 440 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 145, the speech encoding apparatus 440 functionally includes a high frequency signal generation control information encoding unit 270a, a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, and control. Parameter coding unit 20d, envelope calculation unit 20e, quantization / coding unit 20f, core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, pseudo high frequency signal generation unit 410b, time envelope information coding unit 410a, and a coding sequence multiplexing unit 270c.

  FIG. 146 is a flowchart showing an operation of the speech to digital converter 440 according to the twenty-fifth embodiment. It is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 440 according to the present embodiment. Also, temporal envelope information of the high frequency signal can be generated based on temporal envelope information of the low frequency signal.

[First modified example of speech decoding apparatus according to the twenty-fifth embodiment]
FIG. 355 is a diagram showing the configuration of the first modification 340A of the speech decoding device according to the twenty-fifth embodiment.

  FIG. 356 is a flowchart showing an operation of the first modification 340A of the speech decoding device according to the twenty-fifth embodiment.

  The difference between the present modification and the speech decoding apparatus 340 according to the twenty-fifth embodiment is that the low-frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA and 10eB may be used), and the temporal envelope correction unit 14a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 17a.

[Second Modification of Speech Decoding Device of the Twenty-fifth Embodiment]
FIG. 357 is a diagram showing the configuration of the second modification 340B of the speech decoding device according to the twenty-fifth embodiment.

  FIG. 358 is a flowchart showing an operation of the second modification 340B of the speech decoding device according to a twenty-fifth embodiment.

  The difference between the present modification and the speech decoding apparatus 340 according to the twenty-fifth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Third Modification of Speech Decoding Device of the Twenty-fifth Embodiment]
FIG. 359 is a diagram showing the configuration of the third modification 340C of the speech decoding device according to the twenty-fifth embodiment.

  FIG. 360 is a flowchart showing an operation of the third modification 340C of the speech decoding device according to the twenty-fifth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 17a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fourth Modification of the Speech Decoding Device of the Twenty-fifth Embodiment]
FIG. 361 is a diagram showing the configuration of the fourth modification 340D of the speech decoding device according to the twenty-fifth embodiment.

  FIG. 362 is a flowchart showing an operation of the fourth modification 340D of the speech decoding device according to the twenty-fifth embodiment.

  The difference between the present modification and the speech decoding apparatus 340 according to the twenty-fifth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

Twenty-Sixth Embodiment
FIG. 147 is a diagram showing the configuration of the speech decoding apparatus 350 according to the twenty-sixth embodiment. The communication device of the speech decoding device 350 receives the multiplexed coded sequence output from the speech coding device 450 described below, and further outputs the decoded speech signal to the outside. As shown in FIG. 147, the speech decoding apparatus 350 functionally includes the coding sequence demultiplexing unit 170a, the switch group 170b, the core decoding unit 10b, the analysis filter bank unit 10c, and the coding sequence analysis unit 13c. Frequency time envelope shape determination unit 10e, low frequency time envelope correction unit 10f, high frequency time envelope shape determination unit 13a, high frequency signal generation unit 10g, decoding / inverse quantization unit 10h, frequency envelope adjustment unit 10i, time envelope correction unit 15a and a synthesis filter bank unit 170c.

  FIG. 148 is a flowchart showing the operation of the speech decoding apparatus according to the twenty-sixth embodiment. The order in which the processes of steps S170-2 and S170-3 are performed may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / inverse quantization of the band expansion part, and the flowchart of FIG. Not limited to the order of

  In addition, the first, second, and third modified examples of the speech decoding device according to the first embodiment of the present invention are compared with the low-frequency time envelope shape determination unit 10e of the speech decoding device 350 according to the present embodiment. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 350 according to the present embodiment, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

  FIG. 149 is a diagram showing the configuration of speech encoding apparatus 450 according to the twenty-sixth embodiment. The communication device of speech coding apparatus 450 receives a speech signal to be coded from the outside, and further outputs a coded coded sequence to the outside. As shown in FIG. 149, the speech encoding apparatus 450 functionally includes a high frequency signal generation control information encoding unit 270a, a downsampling unit 20a, a core encoding unit 20b, analysis filter bank units 20c and 20c1, and control. Parameter coding unit 20d, envelope calculation unit 270d, quantization / coding unit 20f, core decoded signal generation unit 20i, subband signal power calculation units 20j and 24b, pseudo high frequency signal generation unit 410b, time envelope information coding unit 420a, and a coding sequence multiplexing unit 270c.

  FIG. 150 is a flowchart showing the operation of the speech to digital converter 450 according to the twenty-sixth embodiment. It is apparent that the first modification of the speech to digital converter according to the seventh embodiment of the present invention can be applied to the speech to digital converter 450 according to the present embodiment. Also, temporal envelope information of the high frequency signal can be generated based on temporal envelope information of the low frequency signal.

[First Modification of Speech Decoding Device of Twenty-sixth Embodiment]
FIG. 151 is a diagram showing the configuration of a speech decoding apparatus 350A according to the first modification of the twenty-sixth embodiment.

  FIG. 152 is a flowchart showing an operation of the speech decoding device 350A according to the first modified example of the twenty-sixth embodiment. The order of performing the processes of steps S170-2 and S170-3 may be before the process of determining the time envelope shape of the high frequency signal and the process of decoding / inverse quantization of the band expansion part, and the flowchart of FIG. Not limited to the order of

  The difference from the speech decoding apparatus 350 according to the twenty-sixth embodiment is that a time envelope correction unit 15aA is used instead of the time envelope correction unit 15a.

  The first, second, and third variants of the speech decoding apparatus according to the first embodiment of the present invention are the same as the low-frequency time envelope shape determination unit 10e of the speech decoding apparatus 350A according to the present modification. It is obvious that it is applicable.

  Furthermore, with respect to the high-frequency time envelope shape determination unit 13a of the speech decoding device 350A according to the present modification, the first, second, and third modifications of the speech decoding device according to the fourth embodiment of the present invention It is apparent that the first modification of the speech decoding apparatus according to the fifth embodiment of the present invention and the first modification of the speech decoding apparatus according to the seventh embodiment of the present invention can be applied.

[Second Modification of Speech Decoding Device of Twenty-sixth Embodiment]
FIG. 363 is a diagram showing the configuration of the second modification 350B of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 364 is a flowchart showing an operation of the second modification 350B of the speech decoding device according to the twenty-sixth embodiment.

  The difference between the present modification and the speech decoding apparatus 350 according to the twenty-sixth embodiment is the low-frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), the time envelope correction unit 15a. This is a point provided with the low frequency time envelope shape determination unit 16b and the time envelope correction unit 18a.

[Third Modification of Speech Decoding Device of Twenty-sixth Embodiment]
FIG. 365 is a diagram showing the configuration of the third modification 350C of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 366 is a flowchart showing an operation of the third modification 350C of the speech decoding device according to the twenty-sixth embodiment.

  The difference between the present modification and the speech decoding apparatus 350 according to the twenty-sixth embodiment is that the high-frequency time envelope shape determination unit 13aC (it is apparent that 13a, 13aA, and 13aB may be used), the low-frequency time envelope correction unit 10f Instead, a high frequency time envelope shape determination unit 16d and a low frequency time envelope correction unit 16e are provided.

[Fourth Modification of Speech Decoding Device According to Twenty-sixth Embodiment]
FIG. 367 is a diagram showing the configuration of the fourth modification 350D of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 368 is a flowchart showing an operation of the fourth modification 350D of the speech decoding device according to the twenty-sixth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18a, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Fifth Modification of Speech Decoding Device of Twenty-sixth Embodiment]
FIG. 369 is a diagram showing the configuration of the fifth modification 350E of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 370 is a flowchart showing an operation of the fifth modification 350E of the speech decoding device according to the twenty-sixth embodiment.

  The difference between the present modification and the speech decoding apparatus 350 according to the twenty-sixth embodiment is that the time envelope shape determination unit 16f is provided instead of the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. It is a point to do.

Sixth Modification of Speech Decoding Device According to Twenty-sixth Embodiment
FIG. 371 is a diagram showing the configuration of the sixth modification 350F of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 372 is a flowchart showing an operation of the sixth modification 350F of the speech decoding device according to the twenty-sixth embodiment.

  The difference between the present modification and the speech decoding apparatus 350A according to the first modification of the twenty-sixth embodiment is that the low-frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA, and 10eB may be used), time This is a point provided with a low frequency time envelope shape determination unit 16b and a time envelope correction unit 18aA instead of the envelope correction unit 15aA.

[Seventh modified example of speech decoding apparatus according to the twenty-sixth embodiment]
FIG. 373 is a diagram showing a configuration of a seventh modification 350G of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 374 is a flowchart showing an operation of the seventh modification 350G of the speech decoding device according to the twenty-sixth embodiment.

  The difference between this modification and the speech decoding apparatus 350A according to the first modification of the twenty-sixth embodiment is that the high-frequency time envelope shape determination unit 13aC (13a, 13aA, and 13aB may be obvious), low It is a point provided with the high frequency time envelope shape determination unit 16 d and the low frequency time envelope correction unit 16 e instead of the frequency time envelope correction unit 10 f.

[Eighth Modification of Speech Decoding Device According to Twenty-sixth Embodiment]
FIG. 375 is a diagram showing a configuration of the eighth modification 350H of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 376 is a flowchart showing an operation of the eighth modification 350H of the speech decoding device according to the twenty-sixth embodiment.

  In this modification, the low frequency time envelope shape determination unit 16b, the time envelope correction unit 18aA, the high frequency time envelope shape determination unit 16d, and the low frequency time envelope correction unit 16e are provided.

[Ninth modified example of speech decoding apparatus according to the twenty-sixth embodiment]
FIG. 377 is a diagram showing the configuration of the ninth modification 3501 of the speech decoding device according to the twenty-sixth embodiment.

  FIG. 378 is a flowchart showing an operation of the ninth modification 3501 of the speech decoding device according to the twenty-sixth embodiment.

  The difference between the present modification and the speech decoding apparatus 350A according to the first modification of the twenty-sixth embodiment lies in that the time envelope is changed to the low frequency time envelope shape determination unit 10e and the high frequency time envelope shape determination unit 13a. This is a point provided with the shape determination unit 16f.

Speech Decoding Device of Twenty-seventh Embodiment
FIG. 379 is a diagram showing the configuration of the speech decoding device 360 according to the twenty-seventh embodiment.

  FIG. 380 is a flowchart showing the operation of the speech decoding device 360 according to the twenty-seventh embodiment.

  The time envelope correction unit 360a may receive the time envelope shape received from the low frequency time envelope shape determination unit 10eC (10e, 10eA or 10eB may be obvious) and the high frequency time envelope shape determination unit 13aC (13a, 13aA, 13aB) It is obvious that the plurality of sub-band signals of the low frequency signal output from the analysis filter bank unit 10c and the high frequency signal output from the frequency envelope adjustment unit 10i based on at least one or more of the time envelope shape received from The shape of the time envelope of the plurality of sub-band signals is corrected (S360-1).

  In the correction of the temporal envelope shape of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i, at least one of the components constituting the high frequency signal output separately from the frequency envelope adjustment unit 10i One or more temporal envelope shapes may be modified.

  Temporal envelope shape received from low frequency temporal envelope shape determination unit 10eC (can be 10e, 10eA, 10eB is obvious) and temporal envelope received from high frequency temporal envelope shape determination unit 13aC (apparent that it may be 13a, 13aA, 13aB) The shapes may be the same or different.

[First Modification of Speech Decoding Device of Twenty-Seventh Embodiment]
FIG. 381 is a diagram showing the configuration of the first modification 360A of the speech decoding device according to the twenty-seventh embodiment.

  FIG. 382 is a flowchart showing an operation of the first modification 360A of the speech decoding device according to a twenty-seventh embodiment.

  The difference between the present modification and the speech decoding apparatus 360 according to the twenty-seventh embodiment is the low frequency temporal envelope shape determination unit 10eC (it is apparent that 10e, 10eA, 10eB may be used) and the high frequency temporal envelope shape determination unit The point is that the time envelope shape determination unit 360b is provided instead of 13aC (it is obvious that 13a, 13aA, 13aB may be used).

  The temporal envelope determination unit 360b is configured to receive information on the low frequency temporal envelope shape from the coding sequence demultiplexing unit 10a, a low frequency signal from the core decoding unit 10b, and a plurality of subbands of the low frequency signal from the analysis filter bank unit 10c. A temporal envelope shape is determined based on at least one of the signal and the information on the high frequency temporal envelope shape from the coding sequence analysis unit 13c (S360-2).

  The temporal envelope shape to be determined may be different for each of the low frequency signal and the high frequency signal, and may be the same single temporal envelope shape for the low frequency signal and the high frequency signal.

  Based on the time envelope shape received from the time envelope shape determination unit 360b, the time envelope correction unit 360aA outputs a plurality of sub-band signals of the low frequency signal output from the analysis filter bank unit 10c and the frequency envelope adjustment unit 10i. The shape of the temporal envelope of the plurality of sub-band signals of the high frequency signal is corrected (S360-1a).

  In the correction of the temporal envelope shape of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i, at least one of the components constituting the high frequency signal output separately from the frequency envelope adjustment unit 10i One or more temporal envelope shapes may be modified.

Speech Decoding Device of Twenty-Eighth Embodiment
FIG. 383 is a diagram showing a configuration of the speech decoding device 370 according to a twenty-eighth embodiment.

  FIG. 384 is a flowchart showing an operation of the speech decoding device 370 according to a twenty-eighth embodiment.

  The time envelope correction unit 370a may receive the time envelope shape received from the low frequency time envelope shape determination unit 10eC (10e, 10eA, 10eB may be obvious) and the high frequency time envelope shape determination unit 13aC (13a, 13aA, 13aB) It is obvious that the high frequency signal is corrected based on at least one or more of the time envelope shape received from the analysis filter bank unit 10c, the shape of the time envelope of the plurality of sub-band signals of the low frequency signal If it is determined based on the generated information that a high frequency signal is to be generated, the shape of the temporal envelope of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i is also corrected (S370-1).

  In the correction of the temporal envelope shape of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i, at least one of the components constituting the high frequency signal output separately from the frequency envelope adjustment unit 10i One or more temporal envelope shapes may be modified.

[First Modification of Speech Decoding Device According to Twenty-eighth Embodiment]
FIG. 385 is a drawing showing the configuration of the first modification 370A of the speech decoding device according to the twenty-eighth embodiment.

  FIG. 386 is a flowchart showing an operation of the first modification 370A of the speech decoding device according to a twenty-eighth embodiment.

  The difference between this modification and the speech decoding apparatus 370 according to the twenty-eighth embodiment is the low frequency time envelope shape determination unit 10eC (it is apparent that 10e, 10eA and 10eB may be used) and the high frequency time envelope shape determination unit The point is that the time envelope shape determination unit 360b is provided instead of 13aC (it is obvious that 13a, 13aA, 13aB may be used).

  The time envelope correction unit 370aA corrects the shape of the time envelope of the plurality of sub-band signals of the low frequency signal output from the analysis filter bank unit 10c based on the time envelope shape received from the time envelope shape determination unit 360b. If it is determined that the high frequency signal is to be generated based on the high frequency signal generation information, the shape of the temporal envelope of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i is corrected (S360-1a) .

  In the correction of the temporal envelope shape of the plurality of sub-band signals of the high frequency signal output from the frequency envelope adjustment unit 10i, at least one of the components constituting the high frequency signal output separately from the frequency envelope adjustment unit 10i One or more temporal envelope shapes may be modified.

[Voice decoding apparatus according to the twenty-ninth embodiment]
FIG. 387 is a diagram showing the configuration of the speech decoding apparatus 380 according to the twenty-ninth embodiment.

  FIG. 388 is a flow chart showing the operation of the speech decoding device 380 according to the twenty-ninth embodiment.

  The time envelope correction unit 380a is low based on at least one of the time envelope shape determined by the low frequency time envelope shape determination unit 100c and the time envelope shape determined by the high frequency time envelope shape determination unit 110b. The shape of the time envelope of the low frequency signal output from the frequency decoding unit 100b and the high frequency signal output from the high frequency decoding unit 100e is corrected (S380-1).

  The time envelope shape determined by the low frequency time envelope shape determination unit 100c and the time envelope shape determined by the high frequency time envelope shape determination unit 110b may be the same or different.

[First Modification of Speech Decoding Device of Twenty-ninth Embodiment]
FIG. 389 is a diagram showing the configuration of the first modification 380A of the speech decoding device according to the twenty-ninth embodiment.

  FIG. 390 is a flowchart showing the operation of the first modification 380A of the speech decoding device according to the twenty-ninth embodiment.

  The difference between the present modification and the speech decoding apparatus 380 according to the twenty-ninth embodiment is that the time envelope shape determination unit 120f is replaced with the low frequency time envelope shape determination unit 100c and the high frequency time envelope shape determination unit 110b. The point is that a time envelope correction unit 380aA is provided instead of the time envelope correction unit 380a.

  The time envelope correction unit 380aA generates the low frequency signal output from the low frequency decoding unit 100b and the high frequency output from the high frequency decoding unit 100e based on the time envelope shape determined by the time envelope shape determination unit 120f. The shape of the time envelope of the signal is corrected (S380-1a).

Speech Decoding Device of Thirtieth Embodiment
FIG. 391 is a diagram showing the configuration of the speech decoding device 390 according to the thirtieth embodiment.

  FIG. 392 is a flowchart showing an operation of the speech decoding device 390 according to the thirtieth embodiment.

  In the present modification, the time envelope correction unit 380aA corrects the shape of the time envelope of the low frequency signal output from the low frequency decoding unit 100b based on the time envelope shape determined by the time envelope shape determination unit 120f. If it is determined that a high frequency signal is to be generated based on the high frequency signal generation information, the shape of the temporal envelope of the high frequency signal output from the high frequency decoding unit 100e is also corrected (S380-1a).

  The applicant has invented a speech decoding apparatus according to the following first to fourth aspects in order to achieve the above object.

  The speech decoding apparatus according to the first aspect is a speech decoding apparatus that decodes a coded speech signal and outputs a speech signal, wherein the coding includes analyzing a coded sequence including the coded speech signal. A sequence analysis unit; a speech decoding unit that receives a coded sequence including the encoded speech signal from the coding sequence analysis unit and decodes the speech sequence to obtain a speech signal; the coding sequence analysis unit; and the speech decoding unit A time envelope shape determination unit that receives information from at least one of the above and determines a time envelope shape of the decoded speech signal based on the information, and a time envelope shape determined by the time envelope shape determination unit And a temporal envelope correction unit that corrects and outputs a temporal envelope shape of the decoded speech signal.

  A speech decoding apparatus according to a second aspect is a speech decoding apparatus for decoding a coded speech signal and outputting a speech signal, wherein at least a coded sequence including the coded speech signal is encoded. A coded sequence demultiplexing unit for dividing into a coded sequence including information of the low frequency signal of the voice signal and a coded sequence including information of the high frequency signal of the voice signal encoded; A low frequency decoding unit that receives a coded sequence including information of the low frequency signal that has been coded from the coded sequence demultiplexing unit and decodes it to obtain a low frequency signal; the coded sequence demultiplexing unit; A high frequency decoding unit that receives first information from at least one of the low frequency decoding units and generates a high frequency signal based on the first information; the coded sequence demultiplexing unit; and the low frequency Few of the decryption units A low frequency temporal envelope shape determining unit that receives the second information from one of the two and determines a temporal envelope shape of the decoded low frequency signal based on the second information; and the low frequency temporal envelope shape determining unit A low frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the decoded low frequency signal based on the temporal envelope shape determined in step; and a low whose temporal envelope shape is corrected from the low frequency temporal envelope correction unit Low frequency / high frequency to obtain an audio signal to be output by receiving a frequency signal, receiving a high frequency signal from the high frequency decoding unit, and combining the low frequency signal with the time envelope shape corrected and the high frequency signal And a frequency signal synthesis unit.

  A speech decoding apparatus according to a third aspect is a speech decoding apparatus for decoding a coded speech signal to output a speech signal, wherein at least a coded sequence including the coded speech signal is encoded. A coded sequence demultiplexing unit for dividing into a coded sequence including information of the low frequency signal of the voice signal and a coded sequence including information of the high frequency signal of the voice signal encoded; A low frequency decoding unit that receives a coded sequence including information of the low frequency signal that has been coded from the coded sequence demultiplexing unit and decodes it to obtain a low frequency signal; the coded sequence demultiplexing unit; A high frequency decoding unit that receives first information from at least one of the low frequency decoding units and generates a high frequency signal based on the first information; the coded sequence demultiplexing unit; A decryption unit, and the high cycle A high frequency time envelope shape determining unit that receives second information from at least one of the number decoding units and determines a time envelope shape of the generated high frequency signal based on the second information; and the high frequency A high frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the generated high frequency signal based on the temporal envelope shape determined by the temporal envelope shape determination unit, and a low frequency signal from the low frequency decoding unit An audio signal to be output by receiving a high frequency signal whose time envelope shape has been corrected from the high frequency time envelope correction unit, and combining the low frequency signal and the high frequency signal whose time envelope shape has been corrected; Obtaining a low frequency / high frequency signal synthesis unit.

  A speech decoding apparatus according to a fourth aspect is a speech decoding apparatus for decoding a coded speech signal and outputting a speech signal, wherein at least a coded sequence including the coded speech signal is encoded. A coded sequence demultiplexing unit for dividing into a coded sequence including information of the low frequency signal of the voice signal and a coded sequence including information of the high frequency signal of the voice signal encoded; A low frequency decoding unit that receives a coded sequence including information of the low frequency signal that has been coded from the coded sequence demultiplexing unit and decodes it to obtain a low frequency signal; the coded sequence demultiplexing unit; A high frequency decoding unit that receives first information from at least one of the low frequency decoding units and generates a high frequency signal based on the first information; the coded sequence demultiplexing unit; and the low frequency Few of the decryption units A low frequency temporal envelope shape determining unit that receives the second information from one of the two and determines a temporal envelope shape of the decoded low frequency signal based on the second information; and the low frequency temporal envelope shape determining unit A low frequency time envelope correction unit that corrects and outputs a time envelope shape of the decoded low frequency signal based on the time envelope shape determined in step d, a coding sequence demultiplexing unit, the low frequency decoding unit, and A high frequency time envelope shape determining unit that receives third information from at least one of the high frequency decoding units and determines a time envelope shape of the generated high frequency signal based on the third information; A high frequency time envelope correction unit that corrects and outputs a time envelope shape of the generated high frequency signal based on the time envelope shape determined by the high frequency time envelope shape determination unit; and the low frequency time envelope correction A low frequency signal whose time envelopment shape is corrected from the part, and a high frequency signal whose time envelopment shape is corrected from the high frequency time envelopment correction unit, the low frequency signal whose time envelopment shape is corrected and the time And a low frequency / high frequency signal synthesis unit for obtaining an audio signal to be output by synthesizing the high frequency signal whose envelope shape has been corrected.

  In the speech decoding apparatus according to the second or fourth aspect, the high frequency decoding unit is at least one of the coding sequence demultiplexing unit, the low frequency decoding unit, and the low frequency time envelope correction unit. More information may be received and a high frequency signal may be generated based on the information.

  Further, in the speech decoding apparatus according to the first to fourth aspects, the high frequency time envelope correction unit is configured to calculate the high frequency decoding unit based on the time envelope shape determined by the high frequency time envelope shape determination unit. Correcting the temporal envelope shape of the intermediate signal when generating the high frequency signal, and the high frequency decoding unit generates the remaining high frequency signal using the intermediate signal whose temporal envelope shape is corrected. Processing may be performed.

  Here, the high frequency decoding unit receives the low frequency signal decoded by the low frequency decoding unit, and divides the signal into sub-band signals, and at least a sub divided by the analysis filter unit. A high frequency signal generation unit that generates a high frequency signal using a band signal; and a frequency envelope adjustment unit that adjusts a frequency envelope of the high frequency signal generated by the high frequency signal generation unit; The high frequency signal generated by the high frequency signal generation unit may be used.

  The invention of the speech decoding apparatus according to the first to fourth aspects described above can be understood as an invention of a speech decoding method, and can be described as follows.

  A speech decoding method according to a first aspect is a speech decoding method performed by a speech decoding device that decodes a speech signal encoded and outputs the speech signal, the speech decoding method including the speech signal encoded as described above. A coded sequence analyzing step of analyzing a coded sequence, a voice decoding step of receiving a coded sequence including the coded voice signal after analysis and decoding it to obtain a voice signal, the coded sequence analyzing step, A time envelope shape determining step of receiving information obtained in at least one of the voice decoding steps and determining a time envelope shape of the decoded voice signal based on the information; And D. correcting the time envelope shape of the decoded speech signal based on the determined time envelope shape and outputting the corrected time envelope shape.

  A speech decoding method according to a second aspect is a speech decoding method performed by a speech decoding apparatus that decodes a speech signal encoded and outputs the speech signal, the speech decoding method including the coded speech signal A code for dividing a coded sequence into at least a coded sequence including information of a low frequency signal of the voice signal encoded and a coded sequence including information of a high frequency signal of the voice signal encoded. A low frequency decoding step of receiving a coded sequence including information of the coded low frequency signal obtained by division, a low frequency decoding step of obtaining a low frequency signal, and the coded sequence reverse step; A high frequency decoding step of receiving first information obtained in at least one of the multiplexing step and the low frequency decoding step, and generating a high frequency signal based on the first information; Receiving second information obtained in at least one of a coded sequence demultiplexing step and the low frequency decoding step, and determining a time envelope shape of the decoded low frequency signal based on the second information A low frequency time envelope shape determining step, and a low frequency time envelope correcting step of correcting and outputting a time envelope shape of the decoded low frequency signal based on the time envelope shape determined in the low frequency time envelope shape determining step And receiving the low frequency signal having the time envelope shape corrected in the low frequency time envelope correcting step, receiving the high frequency signal obtained in the high frequency decoding step, and correcting the time envelope shape. Combining a low frequency signal and the high frequency signal to obtain an audio signal to be output; Characterized in that it obtain.

  A speech decoding method according to a third aspect of the present invention is a speech decoding method performed by a speech decoding apparatus that decodes an encoded speech signal and outputs the speech signal, the speech decoding method including the encoded speech signal. A code for dividing a coded sequence into at least a coded sequence including information of a low frequency signal of the voice signal encoded and a coded sequence including information of a high frequency signal of the voice signal encoded. A low frequency decoding step of receiving a coded sequence including information of the coded low frequency signal obtained by division, a low frequency decoding step of obtaining a low frequency signal, and the coded sequence reverse step; A high frequency decoding step of receiving first information obtained in at least one of the multiplexing step and the low frequency decoding step, and generating a high frequency signal based on the first information; Receiving the second information obtained in at least one of the coded sequence demultiplexing step, the low frequency decoding step, and the high frequency decoding step, and generating the high frequency based on the second information A high frequency temporal envelope shape determining step of determining a temporal envelope shape of the signal, and a temporal envelope shape of the generated high frequency signal are corrected based on the temporal envelope shape determined in the high frequency temporal envelope shape determining step. Receiving the low frequency signal obtained in the high frequency temporal envelope correction step and the low frequency decoding step, and receiving the high frequency signal having the temporal envelope shape corrected in the high frequency temporal envelope correction step, Low frequency / high to obtain an audio signal to be output by combining a low frequency signal and a high frequency signal whose time envelope shape is corrected Characterized in that it comprises a wavenumber signal synthesis step.

  A speech decoding method according to a fourth aspect of the present invention is a speech decoding method performed by a speech decoding apparatus that decodes an encoded speech signal and outputs the speech signal, the speech decoding method including the coded speech signal. A code for dividing a coded sequence into at least a coded sequence including information of a low frequency signal of the voice signal encoded and a coded sequence including information of a high frequency signal of the voice signal encoded. A low frequency decoding step of receiving a coded sequence including information of the coded low frequency signal obtained in the coded sequence demultiplexing step and the coded sequence demultiplexing step to obtain a low frequency signal A high frequency circuit that receives first information obtained in at least one of the coded sequence demultiplexing step and the low frequency decoding step, and generates a high frequency signal based on the first information. Receiving the second information obtained in at least one of the number decoding step, the coding sequence demultiplexing step and the low frequency decoding step, and based on the second information, the decoded low frequency signal Modifying the time envelope shape of the decoded low frequency signal based on the time envelope shape determined in the low frequency time envelope shape determining step of determining the time envelope shape of the step and the low frequency time envelope shape determining step Receiving third information from at least one of a low frequency time envelope correction step, the coding sequence demultiplexing step, the low frequency decoding step, and the high frequency decoding step, and based on the third information A high frequency time envelope shape determining step of determining a time envelope shape of the generated high frequency signal; and the high frequency time envelope shape determining step A high frequency temporal envelope correction step of correcting and outputting a temporal envelope shape of the generated high frequency signal based on the temporal envelope shape determined in step h, and the temporal envelope obtained in the low frequency temporal envelope correction step Receiving the shape-corrected low frequency signal, receiving the time envelope shape corrected high frequency signal obtained in the high frequency time envelope correction step, and correcting the time envelope shape corrected low frequency signal and the time And a low frequency / high frequency signal synthesis step of obtaining an audio signal to be output by synthesizing the envelope shape with the corrected high frequency signal.

  The invention of the speech decoding apparatus according to the first to fourth aspects described above can be understood as an invention of a speech decoding program, and can be described as follows.

  An audio decoding program according to a first aspect of the present invention includes a computer provided in an audio decoding apparatus that decodes an encoded audio signal and outputs an audio signal, a coded sequence including the encoded audio signal. A coded sequence analysis unit to analyze, a speech decoding unit that receives a coded sequence including the coded speech signal from the coded sequence analysis unit and decodes it to obtain a speech signal; the coded sequence analysis unit; A time envelopment shape determination unit that receives information from at least one of the speech decoding units and determines a time envelopment shape of a decoded speech signal based on the information, and is determined by the time envelopment shape determination unit It is characterized in that it functions as a time envelope correction unit that corrects and outputs the time envelope shape of the decoded speech signal based on the time envelope shape.

  A speech decoding program according to a second aspect of the present invention is a speech decoding apparatus for decoding a coded speech signal and outputting a speech signal, a computer provided in the speech decoding apparatus comprising: a coded sequence including the coded speech signal A coded sequence demultiplexing step of dividing into at least a coded sequence including information of the low frequency signal of the coded voice signal and a coded sequence including the information of the high frequency signal of the coded voice signal A low frequency decoding unit for receiving a coded sequence including information on the low frequency signal encoded from the coded sequence demultiplexing unit, and obtaining the low frequency signal by decoding; A high frequency decoding unit that receives first information from at least one of a multiplexing unit and the low frequency decoding unit and generates a high frequency signal based on the first information; and the coded sequence demultiplexing unit And the above A low frequency time envelope shape determining unit that receives second information from at least one of the frequency decoding units and determines a time envelope shape of the decoded low frequency signal based on the second information; A low frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the decoded low frequency signal based on the temporal envelope shape determined by the temporal envelope shape determination unit, and a temporal envelope shape from the low frequency temporal envelope correction unit Receiving the high frequency signal from the high frequency decoding unit, and combining the low frequency signal with the time envelope shape corrected with the high frequency signal to output an audio signal to be output. It is characterized in that it functions as a low frequency / high frequency signal synthesis unit to be obtained.

  A speech decoding program according to a third aspect of the present invention is a speech decoding apparatus for decoding a coded speech signal and outputting a speech signal, a computer provided in the speech decoding apparatus, a coded sequence including the coded speech signal A coded sequence demultiplexing step of dividing into at least a coded sequence including information of the low frequency signal of the coded voice signal and a coded sequence including the information of the high frequency signal of the coded voice signal A low frequency decoding unit for receiving a coded sequence including information on the low frequency signal encoded from the coded sequence demultiplexing unit, and obtaining the low frequency signal by decoding; A high frequency decoding unit that receives first information from at least one of a multiplexing unit and the low frequency decoding unit and generates a high frequency signal based on the first information; and the coded sequence demultiplexing unit , Said low A high frequency time envelope shape which receives second information from at least one of a wave number decoding unit and the high frequency decoding unit, and determines a time envelope shape of the generated high frequency signal based on the second information. A high frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the generated high frequency signal based on the temporal envelope shape determined by the high frequency temporal envelope shape determination unit; Receiving a low frequency signal from the unit, receiving a high frequency signal whose time envelope shape is corrected from the high frequency time envelope correction unit, and combining the low frequency signal and the high frequency signal whose time envelope shape is corrected. , And functions as a low frequency / high frequency signal synthesis unit for obtaining an audio signal to be output.

  A voice decoding program according to a fourth aspect of the present invention is a voice decoding apparatus that decodes a coded voice signal and outputs a voice signal, and a computer provided in a coded sequence including the coded voice signal. A coded sequence demultiplexing step of dividing into at least a coded sequence including information of the low frequency signal of the coded voice signal and a coded sequence including the information of the high frequency signal of the coded voice signal A low frequency decoding unit for receiving a coded sequence including information on the low frequency signal encoded from the coded sequence demultiplexing unit, and obtaining the low frequency signal by decoding; A high frequency decoding unit that receives first information from at least one of a multiplexing unit and the low frequency decoding unit and generates a high frequency signal based on the first information; and the coded sequence demultiplexing unit And the above A low frequency time envelope shape determining unit that receives second information from at least one of the frequency decoding units and determines a time envelope shape of the decoded low frequency signal based on the second information; A low frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the decoded low frequency signal based on the temporal envelope shape determined by the temporal envelope shape determination unit; the coding sequence demultiplexing unit; A high frequency time envelope shape for receiving third information from at least one of a frequency decoding unit and the high frequency decoding unit, and determining a time envelope shape of a generated high frequency signal based on the third information. A high frequency time envelope correction unit that corrects and outputs a time envelope shape of the generated high frequency signal based on the determination unit and the time envelope shape determined by the high frequency time envelope shape determination unit Receiving a low frequency signal whose time envelope shape has been corrected from the low frequency time envelope correction unit, and receiving a high frequency signal whose time envelope shape has been corrected from the high frequency time envelope correction unit; It is characterized in that it functions as a low frequency / high frequency signal combining unit for obtaining an audio signal to be output by combining the low frequency signal and the high frequency signal in which the time envelopment shape is corrected.

  In order to achieve the above object, the applicant has invented a speech coding apparatus according to the following first to fourth aspects.

  The speech encoding apparatus according to the first aspect is a speech encoding apparatus that encodes an input speech signal and outputs a coded sequence, comprising: a speech coding unit that encodes the speech signal; A temporal envelope information coding unit that calculates and encodes temporal envelope information of a signal, a coding sequence including the audio signal obtained by the audio coding unit, and temporal envelope information obtained by the temporal envelope information coding unit And a coded sequence multiplexing unit that multiplexes the coded sequence with the coded sequence.

  A speech encoding apparatus according to a second aspect of the present invention is a speech encoding apparatus that encodes an input speech signal and outputs a coded sequence, and low frequency coding that encodes a low frequency component of the speech signal. , A high frequency encoding unit encoding high frequency components of the audio signal, the audio signal, an encoding result of the low frequency encoding unit, and at least information obtained in the low frequency encoding process A low frequency temporal envelope information encoding unit that calculates and encodes temporal envelope information of low frequency components based on one or more, and a coding sequence including the low frequency components obtained by the low frequency encoding unit; Coding that multiplexes a coding sequence including the high frequency component obtained by the high frequency coding unit and a coding sequence of time envelope information of a low frequency component obtained by the low frequency time envelope information coding unit Sequence multiplexing Characterized in that it comprises a and.

  A speech encoding apparatus according to a third aspect of the present invention is a speech encoding apparatus that encodes an input speech signal and outputs a coded sequence, and low frequency coding that encodes low frequency components of the speech signal. A high frequency encoding unit encoding high frequency components of the audio signal, the audio signal, an encoding result of the low frequency encoding unit, information obtained in the low frequency encoding process, the high frequency A high frequency temporal envelope information encoding unit that calculates and encodes temporal envelope information of high frequency components based on at least one of the encoding result of the encoding unit and the information obtained in the high frequency encoding process. A coding sequence including the low frequency component obtained by the low frequency coding unit, a coding sequence including the high frequency component obtained by the high frequency coding unit, and the high frequency temporal envelope information coding In the department A coded sequence multiplexing unit for multiplexing the coded sequence of the time envelope information of the high frequency components that, characterized in that it comprises a.

  A speech encoding apparatus according to a fourth aspect of the present invention is a speech encoding apparatus that encodes an input speech signal and outputs a coded sequence, and low frequency coding that encodes a low frequency component of the speech signal. , A high frequency encoding unit encoding high frequency components of the audio signal, the audio signal, an encoding result of the low frequency encoding unit, and at least information obtained in the low frequency encoding process A low frequency temporal envelope information encoding unit that calculates and encodes temporal envelope information of low frequency components based on one or more, the speech signal, the encoding result of the low frequency encoding unit, the low frequency encoding Calculating and encoding temporal envelope information of high frequency components based on at least one of information obtained in the process, the encoding result of the high frequency encoding unit, and information obtained in the high frequency encoding process High A wave number time envelope information coding unit, a coding sequence including the low frequency component obtained by the low frequency coding unit, a coding sequence including the high frequency component obtained by the high frequency coding unit, and A coding sequence of time envelope information of low frequency components obtained by the low frequency time envelope information coding unit and a coding sequence of time envelope information of high frequency components obtained by the high frequency time envelope information coding unit are multiplexed And a coding sequence multiplexing unit.

  The invention of the speech encoding apparatus according to the first to fourth aspects described above can be understood as an invention of a speech encoding method, and can be described as follows.

  A speech coding method according to a first aspect is a speech coding method for coding an input speech signal and outputting a coded sequence, comprising the steps of: encoding the speech signal A speech coding step, a time envelope information coding step of calculating and coding time envelope information of the speech signal, a coding sequence including the speech signal obtained in the speech coding step, and the time envelope information And D. a coded sequence multiplexing step of multiplexing with the coded sequence of temporal envelope information obtained in the coding step.

  A speech coding method according to a second aspect is a speech coding method for coding an input speech signal and outputting a coded sequence, comprising: a low frequency of the speech signal; Low frequency coding step of coding a component, high frequency coding step of coding a high frequency component of the speech signal, the speech signal, coding result of the low frequency coding step, and the low frequency code A low frequency temporal envelope information encoding step of calculating and encoding temporal envelope information of a low frequency component based on at least one or more of information obtained in a coding process; and the low frequency obtained in the low frequency encoding step A coding sequence including a frequency component, a coding sequence including the high frequency component obtained in the high frequency coding step, and a low frequency temporal envelope information coding step Characterized in that it and a coded sequence multiplexing step for multiplexing the coded sequence of the time envelope information of the low-frequency components.

  A speech encoding method according to a third aspect of the present invention is a speech encoding method performed by encoding an input speech signal and outputting a coded sequence, wherein the low frequency of the speech signal is low. Low frequency encoding step of encoding the component, high frequency encoding step of encoding the high frequency component of the audio signal, the audio signal, encoding result of the low frequency encoding step, the low frequency encoding Calculating and encoding temporal envelope information of high frequency components based on at least one of information obtained in the process, the encoding result of the high frequency encoding step, and information obtained in the high frequency encoding process A high frequency temporal envelope information coding step, a coding sequence including the low frequency component obtained in the low frequency coding step, and a high frequency coding step Providing a coding sequence multiplexing step of multiplexing a coding sequence including the high frequency component and a coding sequence of time envelope information of the high frequency component obtained in the high frequency time envelope information coding step; It is characterized by

  A speech coding method according to a fourth aspect is a speech coding method for coding an input speech signal and outputting a coded sequence, comprising: a low frequency of the speech signal; Low frequency coding step of coding a component, high frequency coding step of coding a high frequency component of the speech signal, the speech signal, coding result of the low frequency coding step, and the low frequency code Low-frequency temporal envelope information encoding step of calculating and encoding temporal envelope information of low-frequency components based on at least one or more of information obtained in an encoding process, the voice signal, and the low-frequency encoding step At least one of the encoding result, the information obtained in the low frequency encoding process, the encoding result of the high frequency encoding step, and the information obtained in the high frequency encoding process A high frequency temporal envelope information encoding step of calculating and encoding temporal envelope information of a high frequency component based on one or more, and a coding sequence including the low frequency component obtained in the low frequency coding step; A coding sequence including the high frequency component obtained in the high frequency coding step, a coding sequence of time envelope information of a low frequency component obtained in the low frequency time envelope information coding step, and the high frequency time envelope And D. a coded sequence multiplexing step of multiplexing the coded sequence of time envelope information of high frequency components obtained in the information coding step.

  The inventions of the speech coding apparatuses according to the first to fourth aspects described above can be understood as inventions of speech coding programs and can be described as follows.

  A speech encoding program according to a first aspect of the present invention is a speech encoding unit for encoding a speech signal, comprising: a computer provided in a speech encoding device that encodes an input speech signal and outputs a coded sequence. A time envelopment information encoding unit for calculating and encoding time envelopment information of the audio signal; an encoded sequence including the audio signal obtained by the audio encoding unit; and a time envelopment information encoding unit It is characterized in that it functions as a coding sequence multiplexing unit that multiplexes with the coding sequence of time envelope information to be encoded.

  A speech encoding program according to a second aspect of the present invention encodes a low frequency component of the speech signal in a computer provided in a speech coding apparatus that encodes an input speech signal and outputs a coded sequence. A low frequency coding unit, a high frequency coding unit coding a high frequency component of the voice signal, the voice signal, a coding result of the low frequency coding unit, and the low frequency coding process A low frequency temporal envelope information encoding unit that calculates and encodes temporal envelope information of low frequency components based on at least one or more of information, and a code including the low frequency components obtained by the low frequency encoding unit A coded sequence, a coded sequence including the high frequency component obtained by the high frequency coding unit, and a coded sequence of time envelope information of a low frequency component obtained by the low frequency time envelope information coding unit; Coding sequence multiplexing unit for duplicating the function as an characterized.

  A speech encoding program according to a third aspect of the present invention encodes a low frequency component of the speech signal in a computer provided in a speech coding apparatus that encodes an input speech signal and outputs a coded sequence. A low frequency coding unit, a high frequency coding unit for coding high frequency components of the voice signal, the voice signal, a coding result of the low frequency coding unit, information obtained in the low frequency coding process A high frequency time envelope for calculating and encoding temporal envelope information of high frequency components based on at least one of the coding result of the high frequency coding unit and the information obtained in the high frequency coding process. An information coding unit, a coding sequence including the low frequency component obtained by the low frequency coding unit, a coding sequence including the high frequency component obtained by the high frequency coding unit, and the high frequency Coding sequence multiplexing unit for multiplexing the coded sequence of the time envelope information of the high frequency component obtained among envelope information encoding unit, characterized in that to function as a.

  A speech encoding program according to a fourth aspect of the present invention encodes a low frequency component of the speech signal in a computer provided in a speech coding apparatus that encodes an input speech signal and outputs a coded sequence. A low frequency coding unit, a high frequency coding unit coding a high frequency component of the voice signal, the voice signal, a coding result of the low frequency coding unit, and the low frequency coding process A low frequency temporal envelope information encoding unit that calculates and encodes temporal envelope information of low frequency components based on at least one or more of information, the speech signal, and the encoding result of the low frequency encoding unit, Based on at least one or more of the information obtained in the low frequency coding process, the coding result of the high frequency coding unit, and the information obtained in the high frequency coding process, a time envelope of high frequency components is obtained. A high frequency temporal envelope information coding unit that calculates and codes information, a coding sequence including the low frequency component obtained by the low frequency coding unit, and the high frequency component obtained by the high frequency coding unit , A coded sequence of temporal envelope information of a low frequency component obtained by the low frequency temporal envelope information coding unit, and a temporal envelope of a high frequency component obtained by the high frequency temporal envelope information coding unit It is characterized in that it functions as a coding sequence multiplexing unit that multiplexes with a coding sequence of information.

  The applicant has invented a speech decoding apparatus according to the following fifth and sixth aspects in order to achieve the above object.

  A speech decoding apparatus according to a fifth aspect of the present invention is a speech decoding apparatus for decoding a coded speech signal and outputting a speech signal, wherein at least the coding sequence including the coded speech signal is encoded. A coded sequence including the information of the low frequency signal of the voice signal, a coded sequence demultiplexing unit for dividing the coded sequence into a coded sequence including the information of the high frequency signal of the voice signal, and the code A low frequency decoding unit which receives a coded sequence including information of the coded low frequency signal from a coded sequence demultiplexing unit and decodes it to obtain a low frequency signal; the coded sequence demultiplexing unit; A high frequency decoding unit that receives information from at least one of the frequency decoding units and generates a high frequency signal based on the information, the coded sequence demultiplexing unit, the low frequency decoding unit, and the high frequency decoding Out of department A time envelopment shape determination unit that receives information from at least one and determines a time envelopment shape of the decoded low frequency signal and the generated high frequency signal; a time envelopment shape determined by the time envelopment shape determination unit And a low frequency time envelope correction unit that corrects and outputs a time envelope shape of the decoded low frequency signal based on the time domain shape determined by the time envelope shape determination unit; A high frequency time envelope correction unit that corrects and outputs a time envelope shape, and a low frequency signal whose time envelope is corrected from the low frequency time envelope correction unit receives the time envelope corrected from the high frequency time envelope correction unit And a low-frequency / high-frequency signal synthesis unit for receiving a high frequency signal and synthesizing an audio signal to be output.

  A speech decoding apparatus according to a sixth aspect of the present invention is a speech decoding apparatus for decoding a coded speech signal to output a speech signal, wherein at least the coding sequence including the coded speech signal is coded. A coded sequence including the information of the low frequency signal of the voice signal, a coded sequence demultiplexing unit for dividing the coded sequence into a coded sequence including the information of the high frequency signal of the voice signal, and the code A low frequency decoding unit which receives a coded sequence including information of the coded low frequency signal from a coded sequence demultiplexing unit and decodes it to obtain a low frequency signal; the coded sequence demultiplexing unit; A high frequency decoding unit that receives information from at least one of the frequency decoding units and generates a high frequency signal based on the information, the coded sequence demultiplexing unit, the low frequency decoding unit, and the high frequency decoding Out of department And at least one time envelope shape determining unit for determining information on a low frequency signal decoded and a time envelope shape of the generated high frequency signal, and a low frequency signal decoded from the low frequency decoding unit Receiving the high frequency signal generated from the high frequency decoding unit, and based on the time envelope shape determined by the time envelope shape determination unit, a time of the decoded low frequency signal and the time of the generated high frequency signal A time envelope correction unit that corrects and outputs an envelope shape, and a low frequency / high frequency signal synthesis unit that combines an audio signal that receives and outputs a low frequency signal and a high frequency signal whose time envelope has been corrected from the time envelope correction unit And.

  In the speech decoding apparatus according to the fifth aspect, the high frequency decoding unit is configured to receive information from at least one of the coding sequence demultiplexing unit, the low frequency decoding unit, and the low frequency time envelope correction unit. It may be received and a high frequency signal may be generated based on the information.

  Further, in the speech decoding apparatus according to the fifth aspect, the high frequency time envelope correction unit is configured to calculate a high frequency signal in the high frequency decoding unit based on the time envelope shape determined by the time envelope shape determination unit. Correcting the time envelope shape of the intermediate signal when generating the high frequency signal, and the high frequency decoding unit performs processing for generating the remaining high frequency signal using the intermediate signal whose time envelope shape is corrected. It is also good.

  Further, in the speech decoding apparatus according to the sixth aspect, the high frequency decoding unit receives information from at least one of the coding sequence demultiplexing unit and the low frequency decoding unit, and the high frequency decoding unit performs high on the basis of the information. A frequency signal may be generated.

  Further, in the speech decoding apparatus according to the sixth aspect, the time envelope correction unit generates a high frequency signal at the high frequency decoding unit based on the time envelope shape determined by the time envelope shape determination unit. May modify the time envelope shape of the intermediate signal at the time of performing, and the high frequency decoding unit may perform processing to generate the remaining high frequency signal using the intermediate signal whose time envelope shape is corrected. .

  Here, the high frequency decoding unit receives the low frequency signal decoded by the low frequency decoding unit, and divides the signal into sub-band signals, and at least a sub divided by the analysis filter unit. A high frequency signal generation unit that generates a high frequency signal using a band signal; and a frequency envelope adjustment unit that adjusts a frequency envelope of the high frequency signal generated by the high frequency signal generation unit; The high frequency signal generated by the high frequency signal generation unit may be used.

  The invention of the speech decoding apparatus according to the fifth and sixth aspects described above can be understood as an invention of a speech decoding method, and can be described as follows.

  A speech decoding method according to a fifth aspect of the present invention is a speech decoding method performed by a speech decoding apparatus that decodes an encoded speech signal and outputs the speech signal, the speech decoding method including the coded speech signal. A coded sequence for dividing a coded sequence into a coded sequence including at least information of a low frequency signal of the voice signal encoded, and a coded sequence including information of a high frequency signal of the voice signal encoded. A low frequency decoding step of receiving a coded sequence including information of the coded low frequency signal obtained by division, and demultiplexing to obtain a low frequency signal; and the coded sequence demultiplexing A high frequency decoding step of receiving information obtained in at least one of the step and the low frequency decoding step, and generating a high frequency signal based on the information; A time envelope that receives information obtained in at least one of: an encoding step, the low frequency decoding step, and the high frequency decoding step, and determines a temporal envelope shape of the decoded low frequency signal and the generated high frequency signal A low frequency temporal envelope correction step of correcting and outputting a temporal envelope shape of the low frequency signal decoded based on the temporal envelope shape determined in the temporal envelope shape determination step; Correcting the time envelope shape of the high frequency signal generated based on the time envelope shape determined in the step and correcting the time envelope obtained in the low frequency time envelope correction step; Received high frequency signal and correcting the time envelope obtained in the high frequency time envelope correction step. It receives several signals, characterized in that it comprises a low-frequency / high-frequency signal synthesis step of synthesizing a speech signal to be output.

  A speech decoding method according to a sixth aspect is a speech decoding method performed by a speech decoding apparatus that decodes a speech signal encoded and outputs the speech signal, the speech decoding method including the coded speech signal A coded sequence for dividing a coded sequence into a coded sequence including at least information of a low frequency signal of the voice signal encoded, and a coded sequence including information of a high frequency signal of the voice signal encoded. A low frequency decoding step of receiving a coded sequence including information of the coded low frequency signal obtained by division, and demultiplexing to obtain a low frequency signal; and the coded sequence demultiplexing A high frequency decoding step of receiving information obtained in at least one of the step and the low frequency decoding step, and generating a high frequency signal based on the information; A time envelope that receives information obtained in at least one of: an encoding step, the low frequency decoding step, and the high frequency decoding step, and determines a temporal envelope shape of the decoded low frequency signal and the generated high frequency signal Receiving the decoded low frequency signal obtained in the shape determining step and the low frequency decoding step; receiving the generated high frequency signal obtained in the high frequency decoding step; determining in the time envelope shape determining step Correcting the time envelope shape of the decoded low frequency signal and the generated high frequency signal based on the determined time envelope shape, and outputting the time envelope obtained in the time envelope correction step. A low frequency / high frequency signal that receives the modified low frequency signal and the high frequency signal and synthesizes the output speech signal Forming a step, characterized in that it comprises a.

  The invention of the speech decoding apparatus according to the fifth and sixth aspects described above can be understood as an invention of a speech decoding program, and can be described as follows.

  According to a fifth aspect of the present invention, there is provided an audio decoding program comprising: an audio decoding device that decodes an encoded audio signal and outputs the audio signal; and a computer provided in the encoded sequence including the encoded audio signal A coded sequence demultiplexing unit for dividing a coded sequence including at least information of a low frequency signal of the voice signal coded and a coded sequence including information of a high frequency signal of the voice signal coded; A low frequency decoding unit for receiving a coded sequence including information of the low frequency signal encoded from the coded sequence demultiplexing unit and decoding the coded sequence to obtain a low frequency signal; and the coded sequence demultiplexing A high frequency decoding unit that receives information from at least one of the low frequency decoding unit and the low frequency decoding unit, and generates a high frequency signal based on the information, the coded sequence demultiplexing unit, the low frequency decoding unit, A time envelope shape determination unit that receives information from at least one of the high frequency decoding units and determines a time envelope shape of the decoded low frequency signal and the generated high frequency signal; A low frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the decoded low frequency signal based on the determined temporal envelope shape; and the generation based on the temporal envelope shape determined by the temporal envelope shape determination unit A high frequency time envelope correction unit that corrects and outputs a time envelope shape of the high frequency signal, and a low frequency signal whose time envelope is corrected from the low frequency time envelope correction unit is received from the high frequency time envelope correction unit It is characterized in that it functions as a low frequency / high frequency signal synthesis unit that receives a high frequency signal whose temporal envelope has been corrected and synthesizes an audio signal to be output.

  According to a sixth aspect of the present invention, there is provided an audio decoding program comprising: an audio decoding device that decodes an encoded audio signal and outputs the audio signal; and a computer provided in the encoded sequence including the encoded audio signal. A coded sequence demultiplexing unit for dividing a coded sequence including at least information of a low frequency signal of the voice signal coded and a coded sequence including information of a high frequency signal of the voice signal coded; A low frequency decoding unit for receiving a coded sequence including information of the low frequency signal encoded from the coded sequence demultiplexing unit and decoding the coded sequence to obtain a low frequency signal; and the coded sequence demultiplexing A high frequency decoding unit that receives information from at least one of the low frequency decoding unit and the low frequency decoding unit, and generates a high frequency signal based on the information, the coded sequence demultiplexing unit, the low frequency decoding unit, A time envelope shape determining unit that receives information from at least one of the high frequency decoding units and determines a time envelope shape of the decoded low frequency signal and the generated high frequency signal; Receiving the low frequency signal and receiving the high frequency signal generated from the high frequency decoding unit, and based on the time envelope shape determined by the time envelope shape determination unit, the decoded low frequency signal and the generated A time envelope correction unit that corrects and outputs a time envelope shape of the high frequency signal, and a low frequency that combines a low frequency signal and a high frequency signal whose time envelope has been corrected from the time envelope correction unit and outputs the signal And a high frequency signal synthesis unit.

を使って得られる信号を、時間包絡形状が修正された高周波数信号として出力する。 The speech decoding apparatus according to the present invention is a speech decoding apparatus that decodes a coded speech signal and outputs a speech signal, and receives and decodes a coded sequence including information of the coded low frequency signal. A low frequency decoding unit for obtaining a low frequency signal; a high frequency decoding unit for receiving the first information from the low frequency decoding unit and generating a high frequency signal based on the first information; A high frequency time envelope shape determination unit that determines a time envelope shape of the generated high frequency signal based on the second information, and the time envelope shape determined by the high frequency time envelope shape determination unit; A high frequency time envelope correction unit that corrects and outputs a time envelope shape of the generated high frequency signal, and a low frequency signal from the low frequency decoding unit, and corrects the time envelope shape from the high frequency time envelope correction unit A low frequency / high frequency signal synthesis unit for obtaining an audio signal to be output by receiving the high frequency signal and combining the low frequency signal with the high frequency signal having the time envelope shape corrected. If the high frequency time envelope shape determination unit determines that the time envelope shape is flat, the high frequency time envelope correction unit generates any of the generated high frequency signals in the time segment. The high frequency signal is used to correct the time envelope shape, and the high frequency time envelope correction unit determines that the high frequency time envelope shape determination unit determines that the time envelope shape is flat. (I) When (t (l) ≦ i <t (l + 1)) is a high frequency signal in an arbitrary time segment,

Is output as a high frequency signal whose time envelope shape is corrected.

  In the speech decoding apparatus according to the present invention, a coded sequence including the coded voice signal is coded at least a coded sequence including information of a low frequency signal of the coded voice signal. The signal processing apparatus may further include a coding sequence demultiplexing unit that divides the speech signal into a coding sequence including information of a high frequency signal.

を

で除した結果に基づいて得られる信号を、時間包絡形状が修正された高周波数信号として出力することとしてもよい。 Further, in the speech decoding apparatus according to the present invention, when the high frequency temporal envelope correction unit determines that the temporal envelope shape is flat in the high frequency temporal envelope shape determination unit, xdec (i) (t (l (t (l)) When ≦ i <t (l + 1)) is a high frequency signal in any time segment,

The

The signal obtained on the basis of the result divided by may be output as a high frequency signal whose time envelope shape is corrected.

  1, 10, 11, 12, 13, 14, 15, 15A, 16, 17, 18, 18A, 100, 110, 120, 130, 140, 150, 160, 170, 180, 190, 190A, 300, 310, 320, 320A, 330, 340, 350, 350A, 360, 370, 380, 390 ... Speech decoding device, 1a, 10d, 13c ... Coding sequence analysis unit, 1b ... Speech decoding unit, 1c, 16f, 120f, 360b ... Temporal envelope shape determination unit 1d, 13a, 13b, 14a, 15a, 16a, 17a, 18a, 18a, 300a, 360a, 360a, 370a, 370a, 380a, 380aA, ..., 20, 20 , 20A, 21, 22, 23, 24, 25, 26, 27, 28, 200, 220, 230, 240, 250, 260, 270, 280, 290, 400, 410, 420, 430, 440, 450 ... speech coding apparatus, 2a: speech coding unit, 2b, 20g, 20gA, 21a, 21aA, 22b, 22bA, 22bB, 23a, 23aA, 24c, 25b, 26a, 26aA, 27a, 28a, 270b, 280a, 290a , 400a, 410a, 420a ... time envelopment information coding unit, 2c, 20h, 200d, 210b, 220b, 250b, 250c, 270c ... coded sequence multiplexing unit, 10a, 10aA, 100a, 110a, 120a, 150a, 170a, 170a ... Decoding sequence demultiplexing unit 10b: core decoding unit 10c, 20c, 20c1 analysis filter bank unit 10e, 10eA, 10eB, 10eC, 16b, 100c, 120c ... low frequency time envelope shape determining unit 10f, 12a 16e, 100d, 120e: low frequency time envelope correction unit, 10g: high frequency signal generation unit, 10h: decoding / inverse quantization unit, 10i, 25a ... frequency envelope adjustment unit, 10j, 170c ... synthesis filter bank unit, 13a 13aA, 13aB, 13aC, 14b, 16a, 16d, 110b, 120bA ... high frequency time envelope shape determination unit 20a ... downsampling unit 20b ... core encoding unit 20d ... control parameter encoding unit 20e, 270d ... envelope calculation unit, 20f ... quantization / coding unit, 20i ... core decoded signal generation unit, 20j, 24b ... subband signal power calculation unit, 22a, 22a1, 22aB ... time envelope calculation unit, 24a, 410b ... pseudo High frequency signal generation unit, 100b: low frequency decoding unit, 100e, 110e, 130b ... high frequency decoding unit, 100f, 150c ... low frequency / high frequency signal High frequency time envelope correction unit 150b, 170b Switch group 200a Low frequency coding unit 200b High frequency coding unit 200c Low frequency time envelope information Encoding unit 210a, 220a, 230a high frequency signal generation control information encoding unit 250a, 270a high frequency signal generation control information encoding unit 360b time envelope determination unit.

Claims (1)

A speech decoding apparatus that decodes an encoded speech signal and outputs the speech signal, comprising:
A low frequency decoding unit which receives a coded sequence including information of the coded low frequency signal and decodes it to obtain a low frequency signal;
A high frequency decoding unit that receives the first information from the low frequency decoding unit and generates a high frequency signal based on the first information;
A high frequency temporal envelope shape determining unit that determines a temporal envelope shape of the generated high frequency signal based on the second information transmitted from the encoding device;
A high frequency temporal envelope correction unit that corrects and outputs a temporal envelope shape of the generated high frequency signal based on the temporal envelope shape determined by the high frequency temporal envelope shape determination unit;
The low frequency signal is received from the low frequency decoding unit, and the high frequency signal whose temporal envelope shape is corrected is received from the high frequency time envelope correction unit, and the low frequency signal and the high frequency signal whose temporal envelope shape is corrected Low-frequency / high-frequency signal synthesis unit for obtaining an audio signal to be output by synthesizing
Equipped with
The high frequency time envelope correction unit may generate the generated high frequency signal within the same time segment as the generated high frequency signal if the high frequency time envelope shape determination unit determines that the time envelope shape is flat. It uses the frequency signal to correct and output the time envelope shape,
When correcting the time envelope shape of the encoded voice signal , the time envelope information of the high frequency signal obtained by the power of the high frequency signal generated by the high frequency decoding unit is used, and the low frequency decoding unit An audio decoding device that does not use temporal envelope information of a low frequency signal obtained .

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