WO2007102674A1 - Method, medium, and system synthesizing a stereo signal - Google Patents
Method, medium, and system synthesizing a stereo signal Download PDFInfo
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- WO2007102674A1 WO2007102674A1 PCT/KR2007/001066 KR2007001066W WO2007102674A1 WO 2007102674 A1 WO2007102674 A1 WO 2007102674A1 KR 2007001066 W KR2007001066 W KR 2007001066W WO 2007102674 A1 WO2007102674 A1 WO 2007102674A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R5/00—Stereophonic arrangements
- H04R5/02—Spatial or constructional arrangements of loudspeakers
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10L—SPEECH ANALYSIS OR SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING; SPEECH OR AUDIO CODING OR DECODING
- G10L19/00—Speech or audio signals analysis-synthesis techniques for redundancy reduction, e.g. in vocoders; Coding or decoding of speech or audio signals, using source filter models or psychoacoustic analysis
- G10L19/008—Multichannel audio signal coding or decoding using interchannel correlation to reduce redundancy, e.g. joint-stereo, intensity-coding or matrixing
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S1/00—Two-channel systems
- H04S1/002—Non-adaptive circuits, e.g. manually adjustable or static, for enhancing the sound image or the spatial distribution
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S3/00—Systems employing more than two channels, e.g. quadraphonic
- H04S3/002—Non-adaptive circuits, e.g. manually adjustable or static, for enhancing the sound image or the spatial distribution
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S3/00—Systems employing more than two channels, e.g. quadraphonic
- H04S3/02—Systems employing more than two channels, e.g. quadraphonic of the matrix type, i.e. in which input signals are combined algebraically, e.g. after having been phase shifted with respect to each other
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04R—LOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
- H04R5/00—Stereophonic arrangements
- H04R5/033—Headphones for stereophonic communication
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S2420/00—Techniques used stereophonic systems covered by H04S but not provided for in its groups
- H04S2420/01—Enhancing the perception of the sound image or of the spatial distribution using head related transfer functions [HRTF's] or equivalents thereof, e.g. interaural time difference [ITD] or interaural level difference [ILD]
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S2420/00—Techniques used stereophonic systems covered by H04S but not provided for in its groups
- H04S2420/07—Synergistic effects of band splitting and sub-band processing
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04S—STEREOPHONIC SYSTEMS
- H04S3/00—Systems employing more than two channels, e.g. quadraphonic
Definitions
- One or more embodiments of the present invention relate to audio coding, and more particularly, to a method, medium, and system generating a 3-dimensional (3D) signal in a decoder by using a surround data stream.
- FIG. 1 illustrates a conventional apparatus for generating a stereo signal.
- a quadrature mirror filter (QMF) analysis filterbank 100 receives an input of a downmixed signal and transforms the time domain signal to the QMF domain.
- the downmixed signal is a signal that previous to encoding included one or more additional signals/channels, but which now represents all of the signals/channels with less signals/channels.
- An upmixing would be the conversion or expanding the downmixed signals/channels into a multi-channel signal, e.g., similar to its original channel form previous to encoding.
- a surround decoding unit 110 decodes the downmixed signal, to thereby upmix the signal.
- a QMF synthesis filterbank 120 then inverse transforms the resultant multi-channel signal in the QMF domain to the time domain.
- a Fourier transform unit 130 further applies a faster Fourier transform (FFT) to this resultant time domain multi-channel signal.
- FFT faster Fourier transform
- a binaural processing unit 140 then downmixes the resultant frequency domain multi-channel signal, transformed to the frequency domain in the Fourier transform unit 130, by applying a head related transfer function (HRTF) to the signal, to generate a corresponding stereo signal with only two channels based on the multi-channel signal.
- HRTF head related transfer function
- an inverse Fourier transform unit 150 inverse transforms the frequency domain stereo signal to the time domain.
- surround decoding unit 110 processes an input signal in the QMF domain, while the HRTF function is generally applied in the frequency domain in the binaural processing unit 140. Since the surround decoding unit 110 and the binaural processing unit 140 operate in different respective domains, the input downmix signal must be transformed to the QMF domain and processed in the surround decoding unit 110, and then, the signal must be inverse transformed to the time domain, and then, again transformed to the frequency domain. Only then, is an HRFT applied to the signal in the binaural processing unit, followed by the inverse transforming of the signal to the time domain. Accordingly, since transform and inverse transform are separately performed with respect to each of the QMF domain and the frequency domain, when decoding is performed in a decoder, the complexity increases.
- one or embodiments of the present invention provide a method, medium, and system for applying a head related transfer function (HRTF) within the quadrature mirror filter (QMF) domain, thereby generating a simplified 3-dimensional (3D) signal by using a surround data stream.
- HRTF head related transfer function
- QMF quadrature mirror filter
- an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal into a sub-band filter domain, and generating and outputting the upmixed signal from the transformed signal based on spatial information for the downmixed signal and a head related transfer function (HRTF) parameter in the sub-band filter domain.
- HRTF head related transfer function
- an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal into a sub-band filter domain, generating the upmixed signal from the transformed signal based on spatial information for the downmixed signal and a head related transfer function (HRTF) parameter, inverse transforming the upmixed signal from the sub-band filter domain to a time domain, and outputting the inverse transformed upmixed signal.
- HRTF head related transfer function
- an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal into a sub-band filter domain, generating a decorrelated signal from the transformed signal by using spatial information, generating the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and an HRTF parameter, inverse transforming the upmixed signal from the sub-band filter domain to a time domain, and outputting the inverse transformed upmixed signal.
- an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal to a sub-band filter domain, transforming a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, generating the upmixed signal from the transformed signal based on spatial information and the sub-band filter domain HRTF parameter, and outputting the upmixed signal.
- an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal to a sub-band filter domain, transforming a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, generating a decorrelated signal from the transformed signal by using spatial information, generating the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the sub-band HRTF parameter, and outputting the upmixed signal.
- an embodiment of the present invention includes a least one medium including computer readable code to control at least one processing element to implement at least an embodiment of the present invention.
- an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and an HRTF parameter in the sub-band filter domain.
- an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and an HRTF parameter, and a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain.
- an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information, a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and an HRTF parameter, and a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain.
- a domain transform unit to transform the downmixed signal to a sub- band filter domain
- a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information
- a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and an HRTF parameter
- a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain.
- an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, an HRTF parameter transform unit to transform a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and the sub-band filter domain HRTF parameter.
- an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, an HRTF parameter transform unit to transform a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information, and a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the sub-band filter domain HRTF parameter.
- FIG. 2 illustrates a method of generating a stereo signal, according to an embodiment of the present invention.
- a surround data stream including a downmix signal and spatial parameters (spatial cues) may be received and demultiplexed, in operation 200.
- the downmix signal can be a mono or stereo signal that was previously compressed/downmixed from a mulit-channel signal.
- the demultiplexed downmix signal may then be transformed from the time domain to the quadrature mirror filter (QMF) domain, in operation 210.
- QMF quadrature mirror filter
- the QMF domain downmix signal may then be decoded, thereby upmixing the QMF domain signal to a multi-channel signal by using the provided spatial information, in operation 220.
- the corresponding downmixed signal can be upmixed to back into the corresponding decoded 5.1 multi-channel signal of 6 channels, including a front left (FL) channel, a front right (FR) channel, a back left (BL) channel, a back right (BR) channel, a center (C) channel, and a low frequency enhancement (LFE) channel, in operation 220.
- the upmixed multi-channel signal may be used to generate a 3- dimnesional (3D) stereo signal, in operation 230, by using a head related transfer function (HRTF) that has been transformed for application in the QMF domain.
- HRTF head related transfer function
- the transformed QMF domain HRTF may also be preset for use with the upmixed multi-channel signal.
- an HRTF parameter that has been transformed for application in the QMF domain is used.
- the time-domain HRTF parameter/transfer function can be transformed into the QMF domain by transforming the time response of an HRTF to the QMF domain, and, for example, by calculating an impulse response in each sub-band.
- Such a transforming of the time-domain HRTF parameter may be also referred to as an HRTF parameterizing in the QMF domain, or as filter morphing of the time-domain HRTF filters, for example.
- the QMF domain can be considered as falling within a class of sub-band filters, since sub bands are being filtered.
- such application of the HRTF parameter in the QMF domain permits for selective upmixing, with such HRTF filtering, of different levels of QMF domain sub-band filtering, e.g., one, some, or all sub-bands depending on the available of processing/battery power, for example.
- the LFE channel may not be used in operation 230. Regardless, such a 3D stereo signal corresponding to the QMF domain can be generated using the below equation 1 , for example.
- x_left[sb][timeslot] is the L channel signal expressed in the QMF domain
- x_right[sb][timeslot] is the R channel signal expressed in the QMF domain
- a11 , a12, a13, a14, a15, a16, a21 , a22, a23, a24, a25, and a26 may be constants
- x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain
- x_FR[sb][timeslot] is the FR channel signal expressed in the QMF domain
- x_BL[sb][timeslot] is the BL channel signal expressed in the QMF domain
- x_C[sb][timeslot] is the C channel signal expressed in the QMF domain
- x_LFE[sb][timeslot] is the LFE channel signal expressed in the QMF domain
- HRTF1 [sbpmeslot] is the
- the generated 3D stereo signal can be inverse transformed from the QMF domain to the time domain, in operation 240.
- this QMF domain method embodiment may equally be available as operating in a hybrid sub-band domain or other sub-band filtering domains known in the art, according to an embodiment of the present invention.
- FIG. 3 illustrates a system for generating a stereo signal, according to an embodiment of the present invention.
- the system may include a demultiplexing unit 300, a domain transform unit 310, an upmixing unit 320, a stereo signal generation unit 330, and a domain inverse transform unit 340, for example.
- the demultiplexing unit 300 may receive, e.g., through an input terminal IN 1 , a surround data stream including a downmix signal and a spatial parameter, e.g., as transmitted by an encoder, and demultiplex and output the surround data stream.
- the domain transform unit 310 may then transform the demultiplexed downmix signal from the time domain to the QMF domain.
- the upmixing unit 320 may, thus, receive a QMF domain downmix signal, decode the signal, and upmix the signal into a multi-channel signal. For example, in the case of a 5.1 -channel signal, the upmixing unit upmixes the QMF domain downmix signal to a multi-channel signal of 6 channels, including FL, FR, BL, BR 1 C, and LFE channels.
- the stereo signal generation unit 330 may thereafter generate a 3D stereo signal, in the QMF domain, with the upmixed multi-channel signal. In the generation of the stereo signal, the stereo signal generation unit 330 may thus use a QMF applied HRTF parameter, e.g., received through an input terminal IN 2.
- the stereo generation unit 330 may further include a parameter transform unit 333 and a calculation unit 336, for example.
- the parameter transform unit 333 may receive a time- domain HRTF parameter, e.g., through the input terminal IN 2, and transform the time- domain HRTF parameter for application in the QMF domain. In one embodiment, for example, the parameter transform unit 333 may transform the time response of the HRTF to the QMF domain and, for example, calculate an impulse response with respect to each sub-band, thereby transforming the time-domain HRTF parameter to the QMF domain.
- a preset QMF domain HRTF parameter may be previously stored and read out when needed.
- alternative embodiments for providing a QMF domain HRTF parameter may equally be implemented
- the spatial synthesis unit 336 may generate a 3D stereo signal with the upmixed multi-channel signal, by applying the QMF domain HRTF parameter or by applying the above mer.ioned preset stored QMF domain HRTF parameter, for example. As noted above, in one embodiment, the spatial synthesis unit 336 may not use the LFE channel in order to reduce complexity. Regardless, the spatial synthesis unit 336 may generate a 3D stereo signal corresponding in the QMF domain by using the below Equation 2, for example.
- x_left[sb][timeslot] is the L channel signal expressed in the QMF domain
- x_right[sb][timeslot] is the R channel signal expressed in the QMF domain
- a11 , a12, a13, a14, a15, a16, a21, a22, a23, a24, a25, and a26 may be constants
- x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain
- x_FR[sb][timeslot] is the FR channel signal expressed in the QMF domain
- x_BL[sb][timeslot] is the BL channel signal expressed in the QMF domain
- x_C[sb][timeslot] is the C channel signal expressed in the QMF domain
- x_LFE[sb][timeslot] is the LFE channel signal expressed in the QMF domain
- HRTF1 [sbpmeslot] is the HR
- the domain inverse transform unit 340 may thereafter inverse transforms the QMF domain 3D stereo signal into the time domain, and may, for example, output the L and R channel signals through output terminals OUT 1 and OUT 2, respectively.
- the domain transform unit 310 may equally be available to operate in a hybrid sub-band domain as know in the art, according to an embodiment of the present invention.
- FIG. 4 illustrates a method of generating a stereo signal, according to another embodiment of the present invention.
- a surround data stream including a downmix signal and spatial parameters (spatial cues), may be received and demultiplexed, in operation 400.
- the downmix signal can be a mono or stereo signal that was previously compressed/downmixed from a multi-channel signal.
- the demultiplexed downmix signal output may then be transformed from the time domain to the QMF domain, in operation 410.
- the QMF domain downmix signal may then be decoded, thereby upmixing the QMF domain signal to a number of channel signals by using the provided spatial information, in operation 420.
- all available channels may not be upmixed.
- only 2 channels among the 6 available multi-channels may be output, and as another example, in the case of 7.1 channels, only 2 channels among the available 8 multi-channels may be output, noting that embodiments of the present invention are not limited to the selection of only 2 channels or the selection of any two particular channels. More particularly, in this 5.1 channels signal example, only FL and FR channel signals may be output among the available 6 multi-channel signals of FL, RF, BL, BR, C, and LFE channel signals.
- a 3D stereo signal may be generated from the selected 2 channel signals, in operation 430.
- the QMF domain HRTF parameter may be preset and applied to the select channel signals.
- the QMF domain HRTF parameter may be obtained by transforming the time response of the HRTF to the QMF domain, and calculating an impulse response in each sub-band.
- the LFE channel in order to reduce complexity, the LFE channel may not be used.
- a 3D stereo signal may be generated using the below equation 3, for example.
- x_left[sb][timeslot] is the L channel signal expressed in the QMF domain
- x_right[sb][timeslot] is the R channel signal expressed in the QMF domain
- a11, a12, a13, a14, a15, a16, a21 , a22, a23, a24, a25, and a26 may be constants
- x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain
- CLD 3, CLD 4 and CLD 5 are channel level differences specified in an MPEG surround specification
- HRTF1[sb][timeslot] is the HRTF parameter with respect to the FL channel expressed in the QMF domain
- HRTF2[sb][timeslot] is the HRTF parameter with respect to the FR channel expressed in the QMF domain
- HRTF3[sb][timeslot] is the HRTF parameter with respect to the BL channel expressed in the QMF domain
- HRTF4[sb][timesiot] is the HRTF parameter with respect to the BR channel expressed in the QMF domain
- HRTF5[sb][timeslot] is the HRTF parameter with respect to the C channel expressed in the QMF domain
- HRTF6[sb][timeslot] is the HRTF parameter with respect to the LFE channel expressed in the QMF domain.
- the generated 3D stereo signal generated may be inverse transformed from the QMF domain to the time domain, in operation 440.
- this QMF domain method embodiment may equally be available as operating in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
- FIG. 5 illustrates a system for generating a stereo signal, according to another embodiment of the present invention.
- the system may include a demultiplexing unit 500, a domain transform unit 510, an upmixing unit 520, a stereo signal generation unit 530, and a domain inverse transform unit 540, for example.
- the demultiplexing unit 500 may receive, e.g., through an input terminal IN 1 , a surround data stream including a downmix signal and spatial parameters, e.g., as transmitted by an encoder, and demultiplex and output the surround data stream.
- the domain transform unit 510 may then transform the demultiplexed downmix signal from the time domain to the QMF domain.
- the upmixing unit 520 may receive a QMF domain downmix signal, decode the signal, and by using spatial information, upmix the signal to select channels, which does not have to include all available channels that could have been upmixed into a multichannels signal.
- the upmixing unit 520 may output only 2 select channels among the 6 available channels in the case of 5.1 channels, and may output only 2 select channels among 8 available channels in the case of 7.1 channels, in one example, in the case of 5.1 multi-channel signals, the upmixing unit 520 may output only select FL and FR channel signals among the 6 available multichannel signals, including FL, RF, BL, BR, C, and LFE channel signals, again noting that embodiments of the present invention are not limited to these particular example select channels or only two select channels.
- stereo signal generation unit 530 may generate a QMF 3D stereo signal with the 2 select channel signals, e.g., output from the upmixing unit 520.
- the stereo signal generation unit 530 may use the spatial information output, e.g., from the demultiplexing unit 500, and a time-domain HRTF parameter, e.g., received through an input terminal IN 2.
- the stereo generation unit 530 may include a parameter transform unit 533 and a calculation unit 536, for example.
- the parameter transform unit 533 may receive the time-domain HRTF parameter, and transform the time-domain HRTF parameter for application in the QMF domain.
- the parameter transform unit 533 may transform the time-domain HRTF parameter by transforming the time response of the HRTF into a hybrid sub-band domain, for example, and then calculate an impulse response in each sub-band.
- a preset QMF domain HRTF parameter may be previously stored and read out when needed.
- alternative embodiments for providing a QMF domain HRTF parameter may equally be implemented.
- the spatial synthesis unit 536 may generate a 3D stereo signal with the 2 select channel signals output from the upmixing unit 520, by using the spatial information and the QMF domain HRTF parameter.
- a FL channel signal and a FR channel signal from the upmixing unit 520 may be received by the spatial synthesis unit 536, for example, and a QMF 3D stereo signal may be generated by using the spatial information and the QMF domain HRTF parameter using the below Equation 4, for example.
- x_left[sb][timeslot] is the L channel signal expressed in the QMF domain
- x_right[sb][timeslot] is the R channel signal expressed in the QMF domain
- a11, a12, a13, a14, a15, a16, a21 , a22, a23, a24, a25, and a26 may be constants
- x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain
- CLD 3, CLD 4 and CLD 5 are channel level differences specified in an MPEG surround specification
- HRTF1[sb][timeslot] is the HRTF parameter with respect to the FL channel expressed in the QMF domain
- HRTF2[sb][timeslot] is the HRTF parameter with respect to the FR channel expressed in the QMF domain
- HRTF3[sb][timeslot] is the HRTF parameter with respect to the BL channel expressed in the QMF domain
- HRTF4[sb][timeslot] is the HRTF parameter with respect to the BR channel expressed in the QMF domain
- HRTF5[sb][timeslot] is the HRTF parameter with respect to the C channel expressed in the QMF domain
- HRTF6[sb][timeslot] is the HRTF parameter with respect to the LFE channel expressed in the QMF domain
- the domain inverse transform unit 540 may further inverse transform the QMF domain 3D stereo signal to the time domain, and, in one embodiment, output the L channel signal and the R channel signal through output terminals OUT 1 and OUT 2, respectively, for example.
- the current embodiment may equally be available to operate in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
- FIG. 6 illustrates a method of generating a stereo signal, according to another embodiment of the present invention.
- a surround data stream including a downmix signal and spatial parameters (spatial cues), may be received and demultiplexed, in operation 600.
- the downmix signal can be a mono signal, for example, that was previously compressed/downmixed from a multi-channel signal.
- the demultiplexed mono downmix signal may be transformed from the time domain to the QMF domain, in operation 610.
- a decorrelated signal may be generated by applying the spatial information to the QMF domain mono downmix signal, and in operation 620.
- the spatial information may be transformed to a binaural 3D parameter, in operation 630.
- the binaural 3D parameter is expressed in QMF domain, and is used in a process in which the mono downmix signal and the decorrelated signal are input and calculation is performed in order to generate a 3D stereo signal.
- a 3D stereo signal may be generated by applying the binaural 3D parameter to the mono downmix signal and the decorrelated signal, in operation 640.
- the generated 3D stereo signal may then be inverse transformed from the QMF domain to the time domain, in operation 650.
- this QMF domain method embodiment may equally be available as operating in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
- FIG. 7 illustrates a system for generating a stereo signal, according to another embodiment of the present invention.
- the system may include a demultiplexing unit 700, a domain transform unit 710, a decorrelator 720, a stereo signal generation unit 730, and a domain inverse transform unit 740, for example.
- the demultiplexing unit 700 may receive, e.g., through an input terminal IN 1 , a surround data stream including a downmix signal and spatial parameters, e.g., as transmitted by an encoder, and demultiplex the surround data stream.
- the downmix signal may be a mono signal, for example.
- the domain transform unit 710 may then transform the mono downmix signal from the time domain to the QMF domain.
- the decorrelator 720 may then generate a decorrelated signal by applying the spatial information and the QMF domain mono downmix signal.
- the stereo signal generation unit 730 may further generate a QMF domain 3D stereo signal from the QMF domain mono downmix signal decorrelated signal. In the generation of the 3D stereo signal, the stereo signal generation unit 730 may use the spatial information and an HRTF parameter, e.g., as received through an input terminal IN 2.
- the stereo generation unit 730 may include a parameter transform unit 733 and a calculation unit 736.
- the parameter transform unit 733 transforms the spatial information to a binaural 3D parameter by using the HRTF parameter.
- the binaural 3D parameter is expressed in QMF domain, and is used in a process in which the mono downmix signal and the decorrelated signal are input and calculation is performed in order to generate a 3D stereo signal.
- the calculation unit 736 receives the QMF domain mono downmix signal and the decorrelated signal, and through calculation by applying the QMF domain binaural 3D parameter, generates a 3D stereo signal.
- the domain inverse transform unit 740 may inverse transform the QMF domain 3D stereo signal to the time domain, and output the L channel signal and the R channel signal through output terminals OUT 1 and OUT 2, respectively, for example.
- one or more embodiments of the present invention include a method, medium, and system generating a stereo signal by applying a QMF domain HRTF to generate a 3D stereo signal.
- a compressed/downmixed multi-channel signal can be upmixed through application of an HRTF without requiring repetitive transforming or inverse transforming for application of the HRTF, thereby reducing the complexity and increasing and the quality of the implemented system.
- embodiments of the present invention can also be implemented through computer readable code/instructions in/on a medium, e.g., a computer readable medium, to control at least one processing element to implement any above described embodiment.
- a medium e.g., a computer readable medium
- the medium can correspond to any medium/media permitting the storing and/or transmission of the computer readable code.
- the computer readable code can be recorded/transferred on a medium in a variety of ways, with examples of the medium including magnetic storage media (e.g., ROM, floppy disks, hard disks, etc.), optical recording media (e.g., CD-ROMs, or DVDs), and storage/transmission media such as carrier waves, as well as through the Internet, for example.
- the medium may further be a signal, such as a resultant signal or bitstream, according to embodiments of the present invention.
- the media may also be a distributed network, so that the computer readable code is stored/transferred and executed in a distributed fashion.
- the processing element could include a processor or a computer processor, and processing elements may be distributed and/or included in a single device.
- FIG. 1 illustrates a conventional apparatus for generating a stereo signal
- FIG. 2 illustrates a method of generating a stereo signal, according to an embodiment of the present invention
- FIG. 3 illustrates a system for generating a stereo signal, according to an embodiment of the present invention
- FIG. 4 illustrates a method of generating a stereo signal, according to another embodiment of the present invention
- FIG. 5 illustrates a system for generating a stereo signal, according to another embodiment of the present invention
- FIG. 6 illustrates a method of generating a stereo signal, according to another embodiment of the present invention.
- FIG. 7 illustrates a system for generating a stereo signal, according to another embodiment of the present invention.
Abstract
A method, medium, and system generating a 3-dimensional (3D) stereo signal in a decoder by using a surround data stream. According to such a method, medium, and system, a head related transfer function (HRTF) is applied in a quadrature mirror filter (QMF) domain, thereby generating a 3D stereo signal by using a surround data stream.
Description
Description METHOD, MEDIUM5 AND SYSTEM SYNTHESIZING A STEREO SIGNAL
Technical Field
[1] One or more embodiments of the present invention relate to audio coding, and more particularly, to a method, medium, and system generating a 3-dimensional (3D) signal in a decoder by using a surround data stream.
Background Art
[2] FIG. 1 illustrates a conventional apparatus for generating a stereo signal. Here, a quadrature mirror filter (QMF) analysis filterbank 100 receives an input of a downmixed signal and transforms the time domain signal to the QMF domain. The downmixed signal is a signal that previous to encoding included one or more additional signals/channels, but which now represents all of the signals/channels with less signals/channels. An upmixing would be the conversion or expanding the downmixed signals/channels into a multi-channel signal, e.g., similar to its original channel form previous to encoding. Thus, after transforming of the time domain signal to the QMF domain, a surround decoding unit 110 decodes the downmixed signal, to thereby upmix the signal. A QMF synthesis filterbank 120 then inverse transforms the resultant multi-channel signal in the QMF domain to the time domain. A Fourier transform unit 130 further applies a faster Fourier transform (FFT) to this resultant time domain multi-channel signal. A binaural processing unit 140 then downmixes the resultant frequency domain multi-channel signal, transformed to the frequency domain in the Fourier transform unit 130, by applying a head related transfer function (HRTF) to the signal, to generate a corresponding stereo signal with only two channels based on the multi-channel signal. Thereafter, an inverse Fourier transform unit 150 inverse transforms the frequency domain stereo signal to the time domain.
[3] Again, surround decoding unit 110 processes an input signal in the QMF domain, while the HRTF function is generally applied in the frequency domain in the binaural processing unit 140. Since the surround decoding unit 110 and the binaural processing unit 140 operate in different respective domains, the input downmix signal must be transformed to the QMF domain and processed in the surround decoding unit 110, and then, the signal must be inverse transformed to the time domain, and then, again transformed to the frequency domain. Only then, is an HRFT applied to the signal in the binaural processing unit, followed by the inverse transforming of the signal to the time domain. Accordingly, since transform and inverse transform are separately performed with respect to each of the QMF domain and the frequency domain, when
decoding is performed in a decoder, the complexity increases. With such complexity, such an arrangement may not be suitable for a mobile environment, for example. In addition to the complexity, sound quality is also degraded in the processes of transforming or inverse transforming a domain representation, such as transforming a QMF domain representation to a time domain representation, transforming a time domain representation to a frequency domain representation, and inverse transforming a frequency domain representation to a time domain representation.
Disclosure of Invention
Technical Solution
[4] Accordingly, one or embodiments of the present invention provide a method, medium, and system for applying a head related transfer function (HRTF) within the quadrature mirror filter (QMF) domain, thereby generating a simplified 3-dimensional (3D) signal by using a surround data stream.
[5] Additional aspects and/or advantages of the invention will be set forth in part in the description which follows and, in part, will be apparent from the description, or may be learned by practice of the invention.
[6] According to an aspect of the present invention, an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal into a sub-band filter domain, and generating and outputting the upmixed signal from the transformed signal based on spatial information for the downmixed signal and a head related transfer function (HRTF) parameter in the sub-band filter domain.
[7] According to another aspect of the present invention, an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal into a sub-band filter domain, generating the upmixed signal from the transformed signal based on spatial information for the downmixed signal and a head related transfer function (HRTF) parameter, inverse transforming the upmixed signal from the sub-band filter domain to a time domain, and outputting the inverse transformed upmixed signal.
[8] According to another aspect of the present invention, an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal into a sub-band filter domain, generating a decorrelated signal from the transformed signal by using spatial information, generating the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and an HRTF parameter, inverse transforming the upmixed signal from the sub-band filter domain to a time domain, and outputting the inverse transformed upmixed signal.
[9] According to another aspect of the present invention, an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal to a sub-band filter domain, transforming a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, generating the upmixed signal from the transformed signal based on spatial information and the sub-band filter domain HRTF parameter, and outputting the upmixed signal.
[10] According to another aspect of the present invention, an embodiment of the present invention includes a method of generating an upmixed signal from a downmixed signal, including transforming the downmixed signal to a sub-band filter domain, transforming a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, generating a decorrelated signal from the transformed signal by using spatial information, generating the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the sub-band HRTF parameter, and outputting the upmixed signal.
[11] According to another aspect of the present invention, an embodiment of the present invention includes a least one medium including computer readable code to control at least one processing element to implement at least an embodiment of the present invention.
[12] According to another aspect of the present invention, an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and an HRTF parameter in the sub-band filter domain.
[13] According to another aspect of the present invention, an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and an HRTF parameter, and a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain.
[14] According to another aspect of the present invention, an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information, a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the
spatial information and an HRTF parameter, and a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain.
[15] According to another aspect of the present invention, an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, an HRTF parameter transform unit to transform a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and the sub-band filter domain HRTF parameter.
[16] According to another aspect of the present invention, an embodiment of the present invention includes a system generating an upmixed signal from a downmixed signal, including a domain transform unit to transform the downmixed signal to a sub- band filter domain, an HRTF parameter transform unit to transform a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter, a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information, and a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the sub-band filter domain HRTF parameter.
Advantageous Effects
[17] Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. Embodiments are described below to explain the present invention by referring to the figures.
[18] FIG. 2 illustrates a method of generating a stereo signal, according to an embodiment of the present invention.
[19] A surround data stream including a downmix signal and spatial parameters (spatial cues) may be received and demultiplexed, in operation 200. Here, as noted above, the downmix signal can be a mono or stereo signal that was previously compressed/downmixed from a mulit-channel signal.
[20] The demultiplexed downmix signal may then be transformed from the time domain to the quadrature mirror filter (QMF) domain, in operation 210.
[21] The QMF domain downmix signal may then be decoded, thereby upmixing the QMF domain signal to a multi-channel signal by using the provided spatial information, in operation 220. For example, in the case of a pre-encoded 5.1 multi-channel signal, the corresponding downmixed signal can be upmixed to back into the corresponding decoded 5.1 multi-channel signal of 6 channels, including a front left (FL) channel, a front right (FR) channel, a back left (BL) channel, a back right (BR) channel, a center
(C) channel, and a low frequency enhancement (LFE) channel, in operation 220.
[22] Thereafter, the upmixed multi-channel signal may be used to generate a 3- dimnesional (3D) stereo signal, in operation 230, by using a head related transfer function (HRTF) that has been transformed for application in the QMF domain. At this time the transformed QMF domain HRTF may also be preset for use with the upmixed multi-channel signal. Thus, here, in operation 230, rather than using an HRTF parameter that is generally expressed in the time domain, an HRTF parameter that has been transformed for application in the QMF domain is used. Here, the time-domain HRTF parameter/transfer function can be transformed into the QMF domain by transforming the time response of an HRTF to the QMF domain, and, for example, by calculating an impulse response in each sub-band. Such a transforming of the time-domain HRTF parameter may be also referred to as an HRTF parameterizing in the QMF domain, or as filter morphing of the time-domain HRTF filters, for example. Similarly, the QMF domain can be considered as falling within a class of sub-band filters, since sub bands are being filtered. Thus, such application of the HRTF parameter in the QMF domain permits for selective upmixing, with such HRTF filtering, of different levels of QMF domain sub-band filtering, e.g., one, some, or all sub-bands depending on the available of processing/battery power, for example. In some embodiments, in order to reduce complexity, the LFE channel may not be used in operation 230. Regardless, such a 3D stereo signal corresponding to the QMF domain can be generated using the below equation 1 , for example.
[23] Equation 1 :
( x_FL[sb][timeslot] ® HRTFl [sb][timeslot] x_FR[sb][ϋmeslot] ® HRTF2[sb][timeslot] f x_left[sb][timeslot] λ fall all αl3 αl4 al5 al6^ x_BL[sb][timeslot] ® HRTF3[sb][timeslot] , x_right[sb][timeslot]J~l α21 a22 α23 α24 a25 a26) xJ3R[sb][timeslot] ® HRTF4[sb][timeslot] x_C[sb][timeslot] ® HRTF5[sb][timeslot] l^x_LFE[sb][timeslot] ® HRTF6[sb][timeslot] )
[24] Here, x_left[sb][timeslot] is the L channel signal expressed in the QMF domain, x_right[sb][timeslot] is the R channel signal expressed in the QMF domain, a11 , a12, a13, a14, a15, a16, a21 , a22, a23, a24, a25, and a26 may be constants, x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain, x_FR[sb][timeslot] is the FR channel signal expressed in the QMF domain, x_BL[sb][timeslot] is the BL channel signal expressed in the QMF domain, x_C[sb][timeslot] is the C channel signal expressed in the QMF domain, x_LFE[sb][timeslot] is the LFE channel signal expressed in the QMF domain, HRTF1 [sbpmeslot] is the HRTF parameter with respect to the FL channel expressed
in the QMF domain, HRTF2[sb][timeslot] is the HRTF parameter with respect to the FR channel expressed in the QMF domain, HRTF3[sb][timeslot] is the HRTF parameter with respect to the BL channel expressed in the QMF domain, HRTF4[sb][timeslot] is the HRTF parameter with respect to the BR channel expressed in the QMF domain, HRTF5[sb][timeslot] is the HRTF parameter with respect to the C channel expressed in the QMF domain, and HRTF6[sb][timeslot] is the HRTF parameter with respect to the LFE channel expressed in the QMF domain,
[25] In operation 230, although an embodiment where a HRTF parameter that has been transformed for application in the QMF domain has been used, in other embodiments, a separate operation for transforming a time domain, for example, HRTF parameter to the QMF domain may also be performed.
[26] Further to operation 230, the generated 3D stereo signal can be inverse transformed from the QMF domain to the time domain, in operation 240.
[27] Here, by transforming the downmix signal by using a QMF analysis filterbank in operation 210, and by inverse transforming the stereo signal generated in operation 230 by using a QMF synthesis filterbank in operation 240, this QMF domain method embodiment may equally be available as operating in a hybrid sub-band domain or other sub-band filtering domains known in the art, according to an embodiment of the present invention.
[28] FIG. 3 illustrates a system for generating a stereo signal, according to an embodiment of the present invention. The system may include a demultiplexing unit 300, a domain transform unit 310, an upmixing unit 320, a stereo signal generation unit 330, and a domain inverse transform unit 340, for example.
[29] The demultiplexing unit 300 may receive, e.g., through an input terminal IN 1 , a surround data stream including a downmix signal and a spatial parameter, e.g., as transmitted by an encoder, and demultiplex and output the surround data stream.
[30] The domain transform unit 310 may then transform the demultiplexed downmix signal from the time domain to the QMF domain.
[31] The upmixing unit 320 may, thus, receive a QMF domain downmix signal, decode the signal, and upmix the signal into a multi-channel signal. For example, in the case of a 5.1 -channel signal, the upmixing unit upmixes the QMF domain downmix signal to a multi-channel signal of 6 channels, including FL, FR, BL, BR1 C, and LFE channels.
[32] The stereo signal generation unit 330 may thereafter generate a 3D stereo signal, in the QMF domain, with the upmixed multi-channel signal. In the generation of the stereo signal, the stereo signal generation unit 330 may thus use a QMF applied HRTF parameter, e.g., received through an input terminal IN 2. Here, the stereo generation unit 330 may further include a parameter transform unit 333 and a calculation unit 336, for example.
[33] In one embodiment, the parameter transform unit 333 may receive a time- domain HRTF parameter, e.g., through the input terminal IN 2, and transform the time- domain HRTF parameter for application in the QMF domain. In one embodiment, for example, the parameter transform unit 333 may transform the time response of the HRTF to the QMF domain and, for example, calculate an impulse response with respect to each sub-band, thereby transforming the time-domain HRTF parameter to the QMF domain.
[34] In another embodiment, a preset QMF domain HRTF parameter may be previously stored and read out when needed. Here it is noted that alternative embodiments for providing a QMF domain HRTF parameter may equally be implemented
[35] Referring to FIG. 3, the spatial synthesis unit 336 may generate a 3D stereo signal with the upmixed multi-channel signal, by applying the QMF domain HRTF parameter or by applying the above mer.ioned preset stored QMF domain HRTF parameter, for example. As noted above, in one embodiment, the spatial synthesis unit 336 may not use the LFE channel in order to reduce complexity. Regardless, the spatial synthesis unit 336 may generate a 3D stereo signal corresponding in the QMF domain by using the below Equation 2, for example.
[36] Equation 2:
xjeft[sb][timeslot] ") (all all αl3 αl4 αl5 x_right[sb][timeslot ]J [ all aTl aZ3 α24 a25
[37]
[38] Here, x_left[sb][timeslot] is the L channel signal expressed in the QMF domain, x_right[sb][timeslot] is the R channel signal expressed in the QMF domain, a11 , a12, a13, a14, a15, a16, a21, a22, a23, a24, a25, and a26 may be constants, x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain, x_FR[sb][timeslot] is the FR channel signal expressed in the QMF domain, x_BL[sb][timeslot] is the BL channel signal expressed in the QMF domain, x_C[sb][timeslot] is the C channel signal expressed in the QMF domain, x_LFE[sb][timeslot] is the LFE channel signal expressed in the QMF domain, HRTF1 [sbpmeslot] is the HRTF parameter with respect to the FL channel expressed in the QMF domain, HRTF2[sb][timeslot] is the HRTF parameter with respect to the FR channel expressed in the QMF domain, HRTF3[sb][timeslot] is the HRTF parameter with respect to the BL channel expressed in the QMF domain, HRTF4[sb][timeslot] is the HRTF parameter with respect to the BR channel expressed
in the QMF domain, HRTF5[sb][timeslot] is the HRTF parameter with respect to the C channel expressed in the QMF domain, and HRTF6[sb][timeslot] is the HRTF parameter with respect to the LFE channel expressed in the QMF domain.
[39] The domain inverse transform unit 340 may thereafter inverse transforms the QMF domain 3D stereo signal into the time domain, and may, for example, output the L and R channel signals through output terminals OUT 1 and OUT 2, respectively.
[40] Here, by transforming a demultiplexed downmix signal by the domain transform unit 310 by using a QMF analysis filterbank, and by inverse transforming the QMF domain 3D stereo signal generated in the spatial synthesis unit 336 by using a QMF synthesis filterbank, the domain transform unit 310 may equally be available to operate in a hybrid sub-band domain as know in the art, according to an embodiment of the present invention.
[41] FIG. 4 illustrates a method of generating a stereo signal, according to another embodiment of the present invention.
[42] A surround data stream, including a downmix signal and spatial parameters (spatial cues), may be received and demultiplexed, in operation 400. Here, as noted above, the downmix signal can be a mono or stereo signal that was previously compressed/downmixed from a multi-channel signal.
[43] The demultiplexed downmix signal output may then be transformed from the time domain to the QMF domain, in operation 410.
[44] The QMF domain downmix signal may then be decoded, thereby upmixing the QMF domain signal to a number of channel signals by using the provided spatial information, in operation 420. Unlike the above embodiment where all available channels of the multi-channel signal may be upmixed, in operation 420, all available channels may not be upmixed. For example, in the case of 5.1 channels, only 2 channels among the 6 available multi-channels may be output, and as another example, in the case of 7.1 channels, only 2 channels among the available 8 multi-channels may be output, noting that embodiments of the present invention are not limited to the selection of only 2 channels or the selection of any two particular channels. More particularly, in this 5.1 channels signal example, only FL and FR channel signals may be output among the available 6 multi-channel signals of FL, RF, BL, BR, C, and LFE channel signals.
[45] By using the spatial information and the QMF domain HRTF, a 3D stereo signal may be generated from the selected 2 channel signals, in operation 430. In operation 430, the QMF domain HRTF parameter may be preset and applied to the select channel signals. As noted above, the QMF domain HRTF parameter may be obtained by transforming the time response of the HRTF to the QMF domain, and calculating an impulse response in each sub-band. In one embodiment,, in operation 430, in order to
reduce complexity, the LFE channel may not be used. Regardless, in an embodiment in which the FR and FR channel signals are the select two channels signals, by using the spatial information and the QMF domain HRTF parameter, a 3D stereo signal may be generated using the below equation 3, for example.
[46] Equation 3: [47]
[48] Here, x_left[sb][timeslot] is the L channel signal expressed in the QMF domain, x_right[sb][timeslot] is the R channel signal expressed in the QMF domain, a11, a12, a13, a14, a15, a16, a21 , a22, a23, a24, a25, and a26 may be constants, x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain,
[49] In addition, the described CLD 3, CLD 4 and CLD 5 are channel level differences specified in an MPEG surround specification, HRTF1[sb][timeslot] is the HRTF parameter with respect to the FL channel expressed in the QMF domain, HRTF2[sb][timeslot] is the HRTF parameter with respect to the FR channel expressed in the QMF domain, HRTF3[sb][timeslot] is the HRTF parameter with respect to the BL channel expressed in the QMF domain, HRTF4[sb][timesiot] is the HRTF parameter with respect to the BR channel expressed in the QMF domain, HRTF5[sb][timeslot] is the HRTF parameter with respect to the C channel expressed in the QMF domain, and HRTF6[sb][timeslot] is the HRTF parameter with respect to the LFE channel expressed in the QMF domain.
[50] Thereafter, the generated 3D stereo signal generated may be inverse transformed from the QMF domain to the time domain, in operation 440.
[51] Here, by transforming the downmix signal by using a QMF analysis filterbank in operation 410, and by inverse transforming the stereo signal generated in operation 430 by using a QMF synthesis filterbank in operation 440, this QMF domain method embodiment may equally be available as operating in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
[52] FIG. 5 illustrates a system for generating a stereo signal, according to another embodiment of the present invention. The system may include a demultiplexing unit 500, a domain transform unit 510, an upmixing unit 520, a stereo signal generation unit 530, and a domain inverse transform unit 540, for example.
[53] The demultiplexing unit 500 may receive, e.g., through an input terminal IN 1 , a surround data stream including a downmix signal and spatial parameters, e.g., as transmitted by an encoder, and demultiplex and output the surround data stream.
[54] The domain transform unit 510 may then transform the demultiplexed downmix
signal from the time domain to the QMF domain.
[55] The upmixing unit 520 may receive a QMF domain downmix signal, decode the signal, and by using spatial information, upmix the signal to select channels, which does not have to include all available channels that could have been upmixed into a multichannels signal. Thus, here, unlike the aforementioned embodiment, the upmixing unit 520 may output only 2 select channels among the 6 available channels in the case of 5.1 channels, and may output only 2 select channels among 8 available channels in the case of 7.1 channels, in one example, in the case of 5.1 multi-channel signals, the upmixing unit 520 may output only select FL and FR channel signals among the 6 available multichannel signals, including FL, RF, BL, BR, C, and LFE channel signals, again noting that embodiments of the present invention are not limited to these particular example select channels or only two select channels.
[56] Thereafter, stereo signal generation unit 530 may generate a QMF 3D stereo signal with the 2 select channel signals, e.g., output from the upmixing unit 520. In the generation of the QMF 3D stereo signal, the stereo signal generation unit 530 may use the spatial information output, e.g., from the demultiplexing unit 500, and a time-domain HRTF parameter, e.g., received through an input terminal IN 2. Here, the stereo generation unit 530 may include a parameter transform unit 533 and a calculation unit 536, for example.
[57] The parameter transform unit 533 may receive the time-domain HRTF parameter, and transform the time-domain HRTF parameter for application in the QMF domain. Thus, the parameter transform unit 533 may transform the time-domain HRTF parameter by transforming the time response of the HRTF into a hybrid sub-band domain, for example, and then calculate an impulse response in each sub-band.
[58] However, similar the above, a preset QMF domain HRTF parameter may be previously stored and read out when needed. Here, it is again noted that alternative embodiments for providing a QMF domain HRTF parameter may equally be implemented.
[59] Referring to FIG. 5, the spatial synthesis unit 536 may generate a 3D stereo signal with the 2 select channel signals output from the upmixing unit 520, by using the spatial information and the QMF domain HRTF parameter.
[60] In one embodiment in which a FL channel signal and a FR channel signal from the upmixing unit 520 may be received by the spatial synthesis unit 536, for example, and a QMF 3D stereo signal may be generated by using the spatial information and the QMF domain HRTF parameter using the below Equation 4, for example.
[61] Here, x_left[sb][timeslot] is the L channel signal expressed in the QMF domain, x_right[sb][timeslot] is the R channel signal expressed in the QMF domain, a11, a12, a13, a14, a15, a16, a21 , a22, a23, a24, a25, and a26 may be constants,
x_FL[sb][timeslot] is the FL channel signal expressed in the QMF domain,
[62] In addition, the described CLD 3, CLD 4 and CLD 5 are channel level differences specified in an MPEG surround specification, HRTF1[sb][timeslot] is the HRTF parameter with respect to the FL channel expressed in the QMF domain, HRTF2[sb][timeslot] is the HRTF parameter with respect to the FR channel expressed in the QMF domain, HRTF3[sb][timeslot] is the HRTF parameter with respect to the BL channel expressed in the QMF domain, HRTF4[sb][timeslot] is the HRTF parameter with respect to the BR channel expressed in the QMF domain, HRTF5[sb][timeslot] is the HRTF parameter with respect to the C channel expressed in the QMF domain, and HRTF6[sb][timeslot] is the HRTF parameter with respect to the LFE channel expressed in the QMF domain,
[63] The domain inverse transform unit 540 may further inverse transform the QMF domain 3D stereo signal to the time domain, and, in one embodiment, output the L channel signal and the R channel signal through output terminals OUT 1 and OUT 2, respectively, for example.
[64] Here, by disposing a QMF analysis filterbank as the domain transform unit 510 and a QMF synthesis filterbank as the domain inverse transform unit 540, the current embodiment may equally be available to operate in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
[65] FIG. 6 illustrates a method of generating a stereo signal, according to another embodiment of the present invention.
[66] A surround data stream, including a downmix signal and spatial parameters (spatial cues), may be received and demultiplexed, in operation 600. Here, as noted above, the downmix signal can be a mono signal, for example, that was previously compressed/downmixed from a multi-channel signal.
[67] The demultiplexed mono downmix signal may be transformed from the time domain to the QMF domain, in operation 610.
[68] Thereafter, a decorrelated signal may be generated by applying the spatial information to the QMF domain mono downmix signal, and in operation 620.
[69] By using an HRTF parameter, the spatial information may be transformed to a binaural 3D parameter, in operation 630. Here, the binaural 3D parameter is expressed in QMF domain, and is used in a process in which the mono downmix signal and the decorrelated signal are input and calculation is performed in order to generate a 3D stereo signal.
[70] Then, a 3D stereo signal may be generated by applying the binaural 3D parameter to the mono downmix signal and the decorrelated signal, in operation 640.
[71] The generated 3D stereo signal may then be inverse transformed from the QMF domain to the time domain, in operation 650.
[72] Here, by transforming the downmix signal by using a QMF analysis filterbank in operation 610, and by inverse transforming the 3D stereo signal generated in operation 640 by using a QMF synthesis filterbank in operation 650, this QMF domain method embodiment may equally be available as operating in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
[73] FIG. 7 illustrates a system for generating a stereo signal, according to another embodiment of the present invention. The system may include a demultiplexing unit 700, a domain transform unit 710, a decorrelator 720, a stereo signal generation unit 730, and a domain inverse transform unit 740, for example.
[74] The demultiplexing unit 700 may receive, e.g., through an input terminal IN 1 , a surround data stream including a downmix signal and spatial parameters, e.g., as transmitted by an encoder, and demultiplex the surround data stream. As noted above, the downmix signal may be a mono signal, for example.
[75] The domain transform unit 710 may then transform the mono downmix signal from the time domain to the QMF domain.
[76] The decorrelator 720 may then generate a decorrelated signal by applying the spatial information and the QMF domain mono downmix signal.
[77] The stereo signal generation unit 730 may further generate a QMF domain 3D stereo signal from the QMF domain mono downmix signal decorrelated signal. In the generation of the 3D stereo signal, the stereo signal generation unit 730 may use the spatial information and an HRTF parameter, e.g., as received through an input terminal IN 2. Here, the stereo generation unit 730 may include a parameter transform unit 733 and a calculation unit 736.
[78] The parameter transform unit 733 transforms the spatial information to a binaural 3D parameter by using the HRTF parameter. Here, the binaural 3D parameter is expressed in QMF domain, and is used in a process in which the mono downmix signal and the decorrelated signal are input and calculation is performed in order to generate a 3D stereo signal.
[79] Thus, the calculation unit 736 receives the QMF domain mono downmix signal and the decorrelated signal, and through calculation by applying the QMF domain binaural 3D parameter, generates a 3D stereo signal.
[80] Thereafter, the domain inverse transform unit 740 may inverse transform the QMF domain 3D stereo signal to the time domain, and output the L channel signal and the R channel signal through output terminals OUT 1 and OUT 2, respectively, for example.
[81] Here, by disposing a QMF analysis filterbank as the domain transform unit 710 and a QMF synthesis filterbank as the domain inverse transform unit 740, the current embodiment may equally be available to operate in a hybrid sub-band domain as known in the art, for example, according to an embodiment of the present invention.
[82] Accordingly, one or more embodiments of the present invention include a method, medium, and system generating a stereo signal by applying a QMF domain HRTF to generate a 3D stereo signal.
[83] In this way, a compressed/downmixed multi-channel signal can be upmixed through application of an HRTF without requiring repetitive transforming or inverse transforming for application of the HRTF, thereby reducing the complexity and increasing and the quality of the implemented system.
[84] In addition to the above described embodiments, embodiments of the present invention can also be implemented through computer readable code/instructions in/on a medium, e.g., a computer readable medium, to control at least one processing element to implement any above described embodiment. The medium can correspond to any medium/media permitting the storing and/or transmission of the computer readable code.
[85] The computer readable code can be recorded/transferred on a medium in a variety of ways, with examples of the medium including magnetic storage media (e.g., ROM, floppy disks, hard disks, etc.), optical recording media (e.g., CD-ROMs, or DVDs), and storage/transmission media such as carrier waves, as well as through the Internet, for example. Here, the medium may further be a signal, such as a resultant signal or bitstream, according to embodiments of the present invention. The media may also be a distributed network, so that the computer readable code is stored/transferred and executed in a distributed fashion. Still further, as only an example, the processing element could include a processor or a computer processor, and processing elements may be distributed and/or included in a single device.
[86] Although a few embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.
Description of Drawings
[87] These and/or other aspects and advantages of the invention will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
[88] FIG. 1 illustrates a conventional apparatus for generating a stereo signal;
[89] FIG. 2 illustrates a method of generating a stereo signal, according to an embodiment of the present invention;
[90] FIG. 3 illustrates a system for generating a stereo signal, according to an embodiment of the present invention;
[91] FIG. 4 illustrates a method of generating a stereo signal, according to another embodiment of the present invention;
[92] FIG. 5 illustrates a system for generating a stereo signal, according to another embodiment of the present invention;
[93] FIG. 6 illustrates a method of generating a stereo signal, according to another embodiment of the present invention; and
[94] FIG. 7 illustrates a system for generating a stereo signal, according to another embodiment of the present invention.
Claims
[I] L A method of generating an upmixed signal from a downmixed signal, comprising: transforming the downmixed signal into a sub-band filter domain; and generating and outputting the upmixed signal from the transformed signal based on spatial information for the downmixed signal and a head related transfer function (HRTF) parameter in the sub-band filter domain.
[2] 2. The method of claim 1, further comprising inverse transforming the upmixed signal to a time domain.
[3] 3. The method of claim 1, wherein the sub-band filter domain is a QMF domain.
[4] 4. The method of claim 1, wherein the sub-band filter domain is a hybrid sub- band domain.
[5] 5 . The method of claim 1, wherein the generating of the upmixed signal comprises: upmixing the transformed signal based on the spatial information; and generating the upmixed signal from select signals among signals of the upmixed transformed signal by using the spatial information and the HRTF parameter.
[6] 6 . The method of claim 6 , wherein, in the generating of the upmixed signal, a low frequency enhancement signal among the signals of the upmixed transformed signal is not used as one of the select signals.
[7] 7 . The method of claim 1, wherein the generating of the upmixed signal comprises: upmixing the transformed signal based on the spatial information; and generating the upmixed signal from select signals among signals of the upmixed transformed signal by using the HRTF parameter.
[8] 8 . The method of claim 7 , wherein, in the generating of the upmixed signal, a low frequency enhancement signal among the signals of the upmixed transformed signal is not used as one of the select signals.
[9] 9 . The method of claim 1, further comprising transforming a corresponding
HRTF parameter into the sub-band filter domain.
[10] 1 0 . The method of claim 9 , wherein the HRTF parameter is transformed into the sub-band filter domain by transforming a time response of a corresponding HRTF to the sub-band filter domain and calculating an impulse response with respect to each sub-band.
[I I] 1 1 . The method of claim 1, wherein the generating of the upmixed signal further comprises: generating a decorrelated signal from the transformed signal by using the spatial
information; and generating the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the HRTF parameter.
[12] 1 2 . A method of generating an upmixed signal from a downmixed signal, comprising: transforming the downmixed signal into a sub-band filter domain; generating a decorrelated signal from the transformed signal by using spatial information; generating the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and an HRTF parameter; inverse transforming the upmixed signal from the sub-band filter domain to a time domain; and outputting the inverse transformed upmixed signal.
[13] 1 3 . The method of claim 1 2 , wherein the HRTF parameter is transformed into the sub-band filter domain before the using of the HRTF parameter in the generating of the upmixed signal.
[14] 1 4 . The method of claim 1 3 , wherein the HRTF parameter is transformed into the sub-band filter domain by transforming a time response of a corresponding
HRTF into the sub-band filter domain and calculating an impulse response with respect to each sub-band.
[15] 1 5 . A method of generating an upmixed signal from a downmixed signal, comprising: transforming the downmixed signal to a sub-band filter domain; transforming a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter; generating the upmixed signal from the transformed signal based on spatial information and the sub-band filter domain HRTF parameter; and outputting the upmixed signal.
[16] 1 6 . The method of claim 1 5 , further comprising inverse transforming the upmixed signal from the sub-band filter domain to a time domain.
[17] 17 . A method of generating an upmixed signal from a downmixed signal, comprising: transforming the downmixed signal to a sub-band filter domain; transforming a non-sub-band filter domain HRTF parameter into a sub-band filter domain HRTF parameter; generating a decorrelated signal from the transformed signal by using spatial information; generating the upmixed signal from the transformed signal and the generated
decorrelated signal by using the spatial information and the sub-band HRTF parameter; and outputting the upmixed signal.
[18] 18 . The method of claim 17 , further comprising inverse transforming the upmixed signal to a time domain.
[19] 19 . At least one medium comprising computer readable code to implement the method of claim 1.
[20] 20 . At least one medium comprising computer readable code to control at least one processing element to implement the method of claim 1 2 .
[21] 2 1 . At least one medium comprising computer readable code to control at least one processing element to implement the method of claim 15 .
[22] 2 2 . At least one medium comprising computer readable code to control at least one processing element to implement the method of claim 17 .
[23] 2 3 . A system generating an upmixed signal from a downmixed signal, comprising: a domain transform unit to transform the downmixed signal to a sub-band filter domain; and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and an HRTF parameter in the sub-band filter domain.
[24] 2 4 . The system of claim 2 3 , further comprising a domain inverse transform unit to inverse transform the upmixed signal to a time domain.
[25] 2 5 . The system of claim 2 3 , wherein the sub-band filter domain is a QMF domain.
[26] 26 . The system of claim 2 3 , wherein the sub-band filter domain is a hybrid sub- band domain.
[27] 27 . The system of claim 2 3 , wherein the signal generation unit comprises: an upmixing unit to upmix the transformed signal based on the spatial information; and a signal generation unit to generate the upmixed signal from select signals among signals of the upmixed transformed signal by using the spatial information and the HRTF parameter.
[28] 28 . The system of claim 2 3, wherein, in the generating of the upmixed signal by the signal generation unit, a low frequency enhancement signal among the signals of the upmixed transformed signal is not used as one of the select signals.
[29] 29 . The system of claim 2 3 , wherein the signal generation unit comprises: an upmixing unit to upmix the transformed signal based on the spatial information; and
a signal generation unit to generate the upmixed signal from select signals among signals of the upmixed transformed signal by using the HRTF parameter. [30] 3 0 . The system of claims 29 , wherein, in the generating of the upmixed signal by the signal generation unit, a low frequency enhancement signal among the signals of the upmixed transformed signal is not used as one of the select signals. [31] 3 1 . The system of claim 2 3 , wherein the signal generation unit further transforms a corresponding HRTF parameter into the sub-band filter domain. [32] 3 2 . The system of claim 3 1 , wherein the HRTF parameter is transformed by transforming a time response of the corresponding HRTF to the sub-band filter domain and calculating an impulse response with respect to each sub-band. [33] 3 3 . The system of claim 2 3 , wherein the signal generation unit further comprises: a decorrelator to generate a decorrelated signal from the transformed signal by using the spatial information, wherein the signal generation unit generates the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the HRTF parameter. [34] 34 . A system generating an upmixed signal from a downmixed signal, comprising: a domain transform unit to transform the downmixed signal to a sub-band filter domain; a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information; a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and an HRTF parameter; and a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain. [35] 35 . The system of claim 34 , wherein the HRTF parameter is transformed into the sub-band filter domain before the using of the HRTF parameter in the generating of the upmixed signal. [36] 36 . The system of claim 34 , wherein the HRTF parameter is transformed into the sub-band filter domain by transforming a time response of a corresponding
HRTF into the sub-band filter domain and calculating an impulse response with respect to each sub-band. [37] 37 . A system generating an upmixed signal from a downmixed signal, comprising: a domain transform unit to transform the downmixed signal to a sub-band filter
domain; an HRTF parameter transform unit to transform a non-sub-band filter domain
HRTF parameter into a sub-band filter domain HRTF parameter; and a signal generation unit to generate the upmixed signal from the transformed signal based on spatial information and the sub-band filter domain HRTF parameter. [38] 38 . The system of claim 37 , further comprising a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain. [39] 39 . A system generating an upmixed signal from a downmixed signal, comprising: a domain transform unit to transform the downmixed signal to a sub-band filter domain; an HRTF parameter transform unit to transform a non-sub-band filter domain
HRTF parameter into a sub-band filter domain HRTF parameter; a decorrelator to generate a decorrelated signal from the transformed signal by using spatial information; and a signal generation unit to generate the upmixed signal from the transformed signal and the generated decorrelated signal by using the spatial information and the sub-band filter domain HRTF parameter. [40] 40 . The system of claim 39, further comprising: a domain inverse transform unit to inverse transform the upmixed signal from the sub-band filter domain to a time domain.
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US9479871B2 (en) | 2016-10-25 |
EP1991984B1 (en) | 2016-06-22 |
EP2495722A1 (en) | 2012-09-05 |
EP2495723A1 (en) | 2012-09-05 |
EP1991984A1 (en) | 2008-11-19 |
KR20070091586A (en) | 2007-09-11 |
US20140105404A1 (en) | 2014-04-17 |
KR20070091517A (en) | 2007-09-11 |
KR101029077B1 (en) | 2011-04-18 |
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