ES2635212T3 - Procedure and device for switching audio signals - Google Patents

Abstract

A method of switching the bandwidth of voice or audio signals, characterized in that it comprises: when switching from a broadband voice or audio signal to a narrow frequency band voice or audio signal, weight (101) a first high frequency band signal of a current voice or audio signal frame and a second high frequency band signal of a previous voice or audio signal frame to obtain a first high frequency band signal processed; and synthesizing (102) the first processed high frequency band signal and a first low frequency band signal of the current voice or audio signal frame into a broad frequency band signal.

Description

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Step 405: Reduce the second weight 1 as in the first weight stage, and increase the second weight 2 as in the first weight stage.

Specifically, when the voice or audio signals are transmitted, the impact of the broadband voice or audio signals before switching on the subsequent narrow frequency band voice or audio signals is gradually reduced. In order to calculate the first envelope information more precisely, an adaptive adjustment is necessary in the second weight 1 and the second weight 2. Since the impact of the L-frame broadband voice or audio signals before the switching on subsequent voice or audio signals gradually decreases, the value of the second weight 1 is gradually reduced, while the value of the second weight 2 gradually increases, which weakens the impact of the envelope information before switching on the First envelope information. In step 405, the second weight 1 and the second weight 2 can be modified according to the following formulas: Second new weight 1 = Second old weight 1 - First weight stage; Second new weight 2 = Second old weight 2 + First weight stage, where the first weight stage is a fixed value.

Step 406: Determine if a third fixed weight 1 is greater than the first weight 1.

Specifically, the third weight 1 refers to the weighting value of the transient envelope information. The impact of the transient envelope information on the first envelope information of the current frame can be determined by comparing the third weight 1 with the second weight 1. The transient envelope information is calculated according to the envelope information of previous M frames and the information of envelope before switching. Therefore, the third weight 1 actually represents the degree of impact that the first envelope information suffers with respect to the envelope information before switching.

Step 407: If the third weight 1 is not greater than the first weight 1, weigh according to the first weight set 1 and the first weight 2 to calculate the first envelope information.

Specifically, when it is determined that the third weight 1 is less than or equal to the first weight 1 in step 406, this indicates that the current voice or audio signal frame is somewhat far from the L frames of voice or audio signals before switching, and that the first envelope information is mainly affected by the envelope information of previous M frames. Therefore, the first envelope information of the current frame can be calculated according to the first set weight 1 and the first weight 2.

Step 408: If the third weight 1 is greater than the first weight 1, weigh according to the third weight set 1 and the third weight 2 to calculate the first envelope information. The third weight 1 refers to the weighting value of the transient envelope information, and the third weight 2 refers to the weighting value of the predicted envelope information.

Specifically, if it is determined that the third weight 1 is greater than the first weight 1 in step 406, this indicates that the current voice or audio signal frame is closer to the L frames of voice or audio signals before the switching, and that the first envelope information is significantly affected by the envelope information before switching. Therefore, the first envelope information of the current frame has to be calculated according to the transient envelope information. The third weight 1 refers to the weighting value of the transient envelope information, and the third weight 2 refers to the weighting value of the predicted envelope information. In this case, the product of the transient envelope information and the third weight 1 is added to the product of the predicted envelope information and the third weight 2, and the weighted value is the first envelope information.

Step 409: Reduce the third weight 1 as in the second weight stage, and increase the third weight 2 as in the second weight stage until the third weight 1 is equal to 0.

Specifically, the objective of modifying the third weight 1 and the third weight 2 in step 409 is the same as modifying the second weight 1 and the second weight 2 in step 405, that is, the objective is to make an adaptive adjustment in the third weight 1 and the third weight 2 to calculate the first envelope information more accurately when the impact of the L frames of voice or audio signals before switching on the voice signals

or audio transmitted later is gradually reduced. Since the impact of the L frames of voice or audio signals before switching on subsequent voice or audio signals gradually decreases, the value of the third weight 1 gradually decreases, while the value of the third weight 2 gradually increases, which weakens the impact of the envelope information before switching on the first envelope information. In step 409, the third weight 1 and the third weight 2 can be modified according to the following formulas: Third new weight 1 = Third old weight 1 - Second weight stage; Third new weight 2 = Third old weight 2 + Second weight stage, where the second weight stage is a fixed value.

The sum of the first weight 1 and the first weight 2 is equal to 1; the sum of the second weight 1 and the second weight 2 is equal to 1; the sum of the third weight 1 and the third weight 2 is equal to 1; the initial value of the third weight 1 is greater than the initial value of the first weight 1; and the first weight 1 and the first weight 2 are fixed constants. Specifically, weight 1

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envelope before switching, which corresponds to the high frequency band signal of the previous voice or audio signal frame before switching.

Specifically, if c1 <corr <c2, the degree of the impact of the envelope information before switching and the previous frame envelope information in the first envelope information of the current frame can be obtained by comparing the second weight 1 with the first weight 1.

Step 505: If the second weight 1 is not greater than the first weight 1, weigh according to the first fixed weight 1 and the first fixed weight 2 to calculate the first envelope information.

Specifically, when it is determined that the second weight 1 is less than the first weight 1 in step 504, this indicates that the current voice or audio signal frame is somewhat far from the previous voice or audio signal frame before the switching, and that the first envelope information is slightly affected by the previous frame envelope information before switching. Therefore, the first envelope information of the current frame can be calculated according to the first set weight 1 and the first weight 2. In this case, step 505 can be represented by the following formula: cur_fenv = pre_fenv x a1 + fenv x b1 .

Step 506: If the second weight 1 is greater than the first weight 1, weigh according to the second weight 1 and the second weight set 2 to calculate the first envelope information. The second weight 2 refers to the weighting value of the predicted envelope information. For example, the second weight 1 can be represented as a2, and the second weight 2 can be represented as b2.

Specifically, when it is determined that the second weight 1 is greater than the first weight 1 in step 504, this indicates that the current frame of voice or audio signal is closer to the first voice or audio signal of frequency band of the previous frame before switching, and that the first envelope information is significantly affected by the envelope information before the switching corresponding to the previous frame of voice or audio signal before switching. Therefore, the first envelope information of the current frame can be calculated according to the second fixed weight 1 and the second weight 2. In this case, the product of the predicted envelope information and the second weight 2 is added to the product of the envelope information before switching and the second weight 1, and the weighted sum is the first envelope information of the current frame. The envelope information before switching can be represented as con_fenv. In this case, step 506 can be represented by the following formula: cur_fenv = con_fenv x a2 + fenv x b2.

Step 507: Reduce the second weight 1 as in the second weight stage, and increase the second weight 2 as in the second weight stage.

Specifically, when voice or audio signals are transmitted, the impact of a voice or audio signal before switching on the subsequent frame of voice or audio signal is gradually reduced. In order to calculate the first envelope information more precisely, an adaptive adjustment in the second weight 1 and the second weight 2 is necessary. The impact of the voice or audio signal before switching on the subsequent frame of the voice signal or audio is gradually reduced, while the impact of the previous voice or audio signal frame near the current voice or audio signal frame gradually increases. Therefore, the value of the second weight 1 decreases gradually, while the value of the second weight 2 gradually increases. In this way, the impact of the envelope information before switching on the first envelope information is weakened, while the impact of the envelope information predicted on the first envelope information improves. In step 507, the second weight 1 and the second weight 2 can be modified according to the following formulas: Second new weight 1 = Second old weight 1 - First weight stage; Second new weight 2 = Second old weight 2 + First weight stage, where the first weight stage is a fixed value.

The sum of the first weight 1 and the first weight 2 is equal to 1; the sum of the second weight 1 and the second weight 2 is equal to 1; The initial value of the second weight 1 is greater than the initial value of the first weight 1.

Step 303: Generate a first high frequency band signal processed according to the first envelope information and the predicted accurate structure information.

Specifically, after the first envelope information of the current frame is obtained in step 302, the first processed high frequency band signal can be generated according to the first envelope information and the predicted accurate structure information, so that the Second high frequency band signal can smoothly switch to the first processed high frequency band signal.

Using the method of switching voice or audio signals in this embodiment, in the process of switching a voice or audio signal from a broadband voice or audio signal to a voice or band audio signal of narrow frequency, the first processed high frequency band signal of the current frame is obtained according to the predicted precise structure information and the first envelope information. In this way, the second high frequency band signal of the broadband voice or audio signal before switching can smoothly switch to the first high frequency band signal.

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processed corresponding to the narrow frequency band voice or audio signal, which improves the quality of the audio signals received by the user.

According to the prior technical solution, step 202 shown in FIG. 6 includes the following stages:

Step 601: Determine if the first processed high frequency band signal has to be attenuated according to the current voice or audio signal frame and the previous voice or audio signal frame before switching.

Specifically, the first high frequency band signal of the narrowband voice or audio signal is null. In the process of switching the broadband voice or audio signal to the narrow frequency voice or audio signal, to prevent the negative effect of the first processed high frequency band signal corresponding to the voice signal or restored narrow frequency band audio, the energy of the first processed high frequency band signal is attenuated by frames until the attenuation coefficient reaches a given threshold after the number of frames of the wide frequency band signal extended from the narrow frequency band voice or audio signal reach a given number of frames. The interval between the current voice or audio signal frame and the voice or audio signal of a frame before switching can be obtained according to the current voice or audio signal frame and the voice or audio signal of the frame before the switching For example, the number of frames of the narrow frequency voice or audio signal may be recorded using a counter, where the number of frames may be a predetermined value greater than or equal to 0.

Step 602: If the first processed high frequency band signal does not have to be attenuated, synthesize the first processed high frequency band signal and the first low frequency band signal into a broad frequency band signal.

Specifically, if it is determined that the first processed high frequency band signal does not have to be attenuated in step 601, the first processed high frequency band signal and the first low frequency band signal are synthesized directly into a band signal. Wide frequency

Step 603: If the first processed high frequency band signal has to be attenuated, determine whether the attenuation factor corresponding to the first processed high frequency band signal is greater than the threshold.

Specifically, the initial value of the attenuation factor is 1, and the threshold is greater than or equal to 0 and less than 1. If it is determined that the first processed high frequency band signal has to be attenuated in step 601, in the stage 603 it is determined if the attenuation factor corresponding to the first processed high frequency band signal is greater than a given threshold.

Step 604: If the attenuation factor is not greater than the given threshold, multiply the first high frequency band signal processed by the threshold, and synthesize the product and the first low frequency band signal in the frequency band signal wide

Specifically, if it is determined that the attenuation factor is not greater than the threshold given in step 603, this indicates that the energy of the first processed high frequency band signal has already been attenuated to some extent and that the first signal of High frequency band processed may not generate negative effects. In this case, this attenuation ratio can be maintained. Then, the first processed high frequency band signal is multiplied by the threshold, and then the product and the first low frequency band signal are synthesized into a broad frequency band signal.

Step 605: If the attenuation factor is greater than the given threshold, multiply the first high frequency band signal processed by the attenuation factor, and synthesize the product and the first low frequency band signal in the band signal of broad frequency

Specifically, if the attenuation factor is greater than the threshold given in step 603, this indicates that the first processed high-frequency band signal can generate a bad listening on the attenuation factor and has to be further attenuated until it reaches the threshold dice. Then, the first processed high frequency band signal is multiplied by the attenuation factor, and then the product and the first low frequency band signal are synthesized into a broad frequency band signal.

Step 606: Modify the attenuation factor to reduce the attenuation factor.

Specifically, when voice or audio signals are transmitted, the impact of voice or audio signals before switching on subsequent narrowband voice or audio signals is gradually reduced, and the attenuation factor is also gradually reduced.

Optionally, depending on the prior technical solution, when switching from a narrow frequency band voice or audio signal to a broad frequency band voice or audio signal, a form

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In order to obtain the first frequency band signal processed through step 201, it includes the following steps, as shown in FIG. 7:

Step 701: Weigh according to the fourth set weight 1 and the fourth weight 2 to calculate a first processed high frequency band signal. The fourth weight 1 refers to the weighting value of the second high frequency band signal, and the fourth weight 2 refers to the weighting value of the first high frequency band signal of the current voice or audio signal frame .

Specifically, in the process of switching the narrow frequency voice or audio signal from the narrow frequency band to the voice or audio signal, because the high frequency band signal of the voice or band audio signal Wide frequency is not zero but the high frequency band signal corresponding to the narrow frequency voice or audio signal is null, the energy of the high frequency band signal of the voice or band audio signal Wide frequency must be attenuated to ensure that the narrow frequency band voice or audio signal can switch smoothly to the broad frequency band voice or audio signal. The product of the second high frequency band signal and the fourth weight 1 is added to the product of the first high frequency band signal and the fourth weight 2; The weighted value is the first processed high frequency band signal.

Step 702: Reduce the fourth weight 1 as in the third weight stage, and increase the fourth weight 2 as in the third weight stage until the fourth weight 1 is equal to 0. The sum of the fourth weight 1 and the fourth weight 2 is equal to 1.

Specifically, when voice or audio signals are transmitted, the impact of narrow frequency band voice or audio signals prior to switching on subsequent broadband voice or audio signals is gradually reduced. Therefore, the fourth weight 1 is gradually reduced, while the fourth weight 2 gradually increases until the fourth weight 1 is equal to 0 and the fourth weight 2 is equal to 1. That is, the transmitted voice or audio signals they are always voice signals or broadband audio.

Also, as shown in FIG. 8, another embodiment for obtaining the first high frequency band signal processed through step 201 may also include the following steps:

Step 801: Weigh according to the fifth weight set 1 and the fifth weight 2 to calculate a first processed high frequency band signal. The fifth weight 1 is the weighting value of an established fixed parameter, and the fifth weight 2 is the weighting value of the first high frequency band signal of the current voice or audio signal frame.

Specifically, since the first high frequency band signal of the narrow frequency band voice or audio signal is null, a fixed parameter can be set to replace the high frequency band signal of the voice or band audio signal. narrow frequency, where the fixed parameter is a constant greater than or equal to 0 and is less than the energy of the first high frequency band signal. The product of the fixed parameter and the fifth weight 1 is added to the product of the first high frequency band signal and the fifth weight 2; The weighted value is the first processed high frequency band signal.

Stage 802: Reduce the fifth weight 1 as in the fourth weight stage, and increase the fifth weight 2 as in the fourth weight stage until the fifth weight 1 is equal to 0. The sum of the fifth weight 1 and the fifth weight 2 is equal to 1.

Specifically, when voice or audio signals are transmitted, the impact of narrow frequency band voice or audio signals prior to switching on subsequent broadband voice or audio signals is gradually reduced. Therefore, the fifth weight 1 is gradually reduced, while the fifth weight 2 gradually increases until the fifth weight 1 is equal to 0 and the fifth weight 2 is equal to 1. That is, the transmitted voice or audio signals they are always real voice signals or broadband audio.

Using the method of switching voice or audio signals in this embodiment, in the process of switching a voice or audio signal from a narrow frequency voice or audio signal to a voice or band audio signal Wide frequency, the high frequency band signal of the broadband voice or audio signal is attenuated to obtain a processed high frequency band signal. In this way, the high frequency band signal corresponding to the narrow frequency band voice or audio signal before switching can smoothly switch to the processed high frequency band signal corresponding to the voice or band audio signal. Wide frequency, which helps improve the quality of the audio signals received by the user.

In this embodiment, the envelope information can also be replaced by other parameters that may represent the high frequency band signal, for example, a linear predictive coding parameter (LPC) or an amplitude parameter.

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voice or audio signal The prediction module 1011 is further adapted to predict the precise structure information and envelope information corresponding to the first low frequency band signal of the current voice or audio signal frame.

In the voice or audio signal switching apparatus of this embodiment, the prediction module predicts the precise structure information and envelope information corresponding to the first high frequency band signal, so that the first signal of Processed high frequency band can be precisely generated by the first generation module and the second generation module. In this way, the first high frequency band signal can smoothly switch to the first processed high frequency band signal, which improves the quality of the voice or audio signals received by the user. In addition, the classification module classifies the first low frequency band signal of the current voice or audio signal frame; The prediction module obtains the predicted accurate structure information and the predicted envelope information according to the type of signal. In this way, the predicted precise structure information and the predicted envelope information are more precise, which improves the quality of the voice or audio signals received by the user.

Optionally, according to the prior technical solution, the first synthesis module 102 includes the following modules, as shown in FIG. 10 and in FIG. 12:

a first determination module 1021, adapted to determine whether the first processed high frequency band signal has to be attenuated according to the current voice or audio signal frame and the previous voice or audio signal frame before switching; a third synthesizing module 1022, adapted to synthesize the first processed high frequency band signal and the first low frequency band signal into a broad frequency band signal when the first determination module 1021 determines that the first band signal High frequency processing does not have to be attenuated; a second determination module 1023, adapted to determine whether the attenuation factor corresponding to the first processed high frequency band signal is greater than the threshold given when the first determination module 1021 determines that the first processed high frequency band signal a fourth synthesization module 1024 must be attenuated, adapted to: if the second determination module 1023 determines that the attenuation factor is not greater than the given threshold, multiply the first high frequency band signal processed by the threshold, and synthesize the product and the first low frequency band signal into a broad frequency band signal; a fifth synthesis module 1025, adapted to: if the second determination module 1023 determines that the attenuation factor is greater than the given threshold, multiply the first high frequency band signal processed by the attenuation factor, and synthesize the product and the first low frequency band signal in a broad frequency band signal; and a first modification module 1026, adapted to modify the attenuation factor to reduce the attenuation factor.

The initial value of the attenuation factor is 1, and the threshold is greater than or equal to 0 and less than 1.

The first processed high frequency band signal is attenuated using the voice or audio signal switching apparatus, so that the broadband signal obtained by processing the current voice or audio signal frame is more accurate, which improves the quality of the audio signals received by the user.

Optionally, according to the prior technical solution, when a switching occurs from a narrow frequency band voice or audio signal to a broad frequency band voice or audio signal, the processing module 101 of this embodiment includes the following modules, as shown in FIG. 10 and in FIG. 13a:

a first calculation module 1011a, adapted to perform a weighting according to a fourth fixed weight 1 and a fourth weight 2 to calculate the first processed high frequency band signal, where the fourth weight 1 refers to the weighting value of the second signal high frequency band, and the fourth weight 2 refers to the weighting value of the first high frequency band signal; and a second modification module 1012a, adapted to reduce the fourth weight 1 as in the third weight stage, and increase the fourth weight 2 as in the third weight stage until the fourth weight 1 is equal to 0, where the sum of the fourth weight 1 and the fourth weight 2 is equal to 1.

Also, when switching from a narrow frequency band voice or audio signal to a broad frequency band voice or audio signal, the processing module 101 of this embodiment may also include the following modules, such as is shown in FIG. 10 and in FIG. 13b:

a second calculation module 1011b, adapted to perform a weighting according to a fifth set weight 1 and a fifth weight 2 to calculate the first processed high frequency band signal, where the fifth

weight 1 refers to the weighting value of an established fixed parameter, and the fifth weight 2 refers to the weighting value of the first high frequency band signal; and a third modification module 1012b, adapted to reduce the fifth weight 1 as in the fourth weight stage, and increase the fifth weight 2 as in the fourth weight stage until the fifth weight 1 is equal to

5 0, where the sum of the fifth weight 1 and the fifth weight 2 is equal to 1, where the fixed parameter is a fixed constant greater than or equal to 0 and less than the energy value of the first high frequency band signal.

Using the voice or audio signal switching apparatus of this embodiment, in the process of switching a voice or audio signal from a narrow frequency voice or audio signal to a voice or audio signal of Wide frequency band, the high frequency band signal of the broadband voice or audio signal is attenuated to obtain a processed high frequency band signal. In this way, the high frequency band signal corresponding to the narrow frequency band voice or audio signal before switching can smoothly switch to the processed high frequency band signal corresponding to the voice or band audio signal. wide frequency, which helps improve the quality of

15 audio signals received by the user.

Claims (1)

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