The invention relates to a method and to an apparatus for compressing and decompressing a Higher Order Ambisonics representation for a sound field.
Higher Order Ambisonics denoted HOA offers one way of representing three-dimensional sound. Other techniques are wave field synthesis (WFS) or channel based methods like 22.2. In contrast to channel based methods, the HOA representation offers the advantage of being independent of a specific loudspeaker set-up. This flexibility, however, is at the expense of a decoding process which is required for the playback of the HOA representation on a particular loudspeaker set-up. Compared to the WFS approach where the number of required loudspeakers is usually very large, HOA may also be rendered to set-ups consisting of only few loudspeakers. A further advantage of HOA is that the same representation can also be employed without any modification for binaural rendering to head-phones.
HOA is based on a representation of the spatial density of complex harmonic plane wave amplitudes by a truncated Spherical Harmonics (SH) expansion. Each expansion coefficient is a function of angular frequency, which can be equivalently represented by a time domain function. Hence, without loss of generality, the complete HOA sound field representation actually can be assumed to consist of O time domain functions, where O denotes the number of expansion coefficients. These time domain functions will be equivalently referred to as HOA coefficient sequences in the following.
The spatial resolution of the HOA representation improves with a growing maximum order N of the expansion. Unfortunately, the number of expansion coefficients O grows quadratically with the order N, in particular O=(N+1)2. For example, typical HOA representations using order N=4 require O=25 HOA (expansion) coefficients. According to the above considerations, the total bit rate for the transmission of HOA representation, given a desired single-channel sampling rate fS and the number of bits Nb per sample, is determined by O·fS·Nb. Transmitting an HOA representation of order N=4 with a sampling rate of fS=48 kHz employing Nb=16 bits per sample will result in a bit rate of 19.2 MBits/s, which is very high for many practical applications, e.g. streaming. Therefore, compression of HOA representations is highly desirable.
The existing methods addressing the compression of HOA representations (with N>1) are quite rare. The most straight forward approach pursued by E. Hellerud, I. Burnett, A Solvang and U. P. Svensson, “Encoding Higher Order Ambisonics with AAC”, 124th AES Convention, Amsterdam, 2008, is to perform direct encoding of individual HOA coefficient sequences employing Advanced Audio Coding (AAC), which is a perceptual coding algorithm. However, the inherent problem with this approach is the perceptual coding of signals which are never listened to. The reconstructed playback signals are usually obtained by a weighted sum of the HOA coefficient sequences, and there is a high probability for unmasking of perceptual coding noise when the decompressed HOA representation is rendered on a particular loudspeaker set-up. The major problem for perceptual coding noise unmasking is high cross correlations between the individual HOA coefficient sequences. Since the coding noise signals in the individual HOA coefficient sequences are usually uncorrelated with each other, there may occur a constructive superposition of the perceptual coding noise while at the same time the noise-free HOA coefficient sequences are cancelled at superposition. A further problem is that these cross correlations lead to a reduced efficiency of the perceptual coders.
In order to minimise the extent of both effects, it is proposed in EP 2469742 A2 to transform the HOA representation to an equivalent representation in the discrete spatial domain before perceptual coding. Formally, that discrete spatial domain is the time domain equivalent of the spatial density of complex harmonic plane wave amplitudes, sampled at some discrete directions. The discrete spatial domain is thus represented by O conventional time domain signals, which can be interpreted as general plane waves impinging from the sampling directions and would correspond to the loudspeaker signals, if the loudspeakers were positioned in exactly the same directions as those assumed for the spatial domain transform.
The transform to discrete spatial domain reduces the cross correlations between the individual spatial domain signals, but these cross correlations are not completely eliminated. An example for relatively high cross correlations is a directional signal whose direction falls in-between the adjacent directions covered by the spatial domain signals.
A main disadvantage of both approaches is that the number of perceptually coded signals is (N+1)2, and the data rate for the compressed HOA representation grows quadratically with the Ambisonics order N.
To reduce the number of perceptually coded signals, patent publication EP 2665208 A1 proposes decomposing of the HOA representation into a given maximum number of dominant directional signals and a residual ambient component. The reduction of the number of the signals to be perceptually coded is achieved by reducing the order of the residual ambient component. The rationale behind this approach is to retain a high spatial resolution with respect to dominant directional signals while representing the residual with sufficient accuracy by a lower-order HOA representation.
This approach works quite well as long as the assumptions on the sound field are satisfied, i.e. that it consists of a small number of dominant directional signals (representing general plane wave functions encoded with the full order N) and a residual ambient component without any directivity. However, if following decomposition the residual ambient component is still containing some dominant directional components, the order reduction causes errors which are distinctly perceptible at rendering following decompression. Typical examples of HOA representations where the assumptions are violated are general plane waves encoded in an order lower than N. Such general plane waves of order lower than N can result from artistic creation in order to make sound sources appearing wider, and can also occur with the recording of HOA sound field representations by spherical microphones. In both examples the sound field is represented by a high number of highly correlated spatial domain signals (see also section Spatial resolution of Higher Order Ambisonics for an explanation).
A problem to be solved by the invention is to remove the disadvantages resulting from the processing described in patent publication EP 2665208 A1, thereby also avoiding the above described disadvantages of the other cited prior art. The invention improves the HOA sound field representation compression processing described in patent publication EP 2665208 A1. First, like in EP 2665208 A1, the HOA representation is analysed for the presence of dominant sound sources, of which the directions are estimated. With the knowledge of the dominant sound source directions, the HOA representation is decomposed into a number of dominant directional signals, representing general plane waves, and a residual component. However, instead of immediately reducing the order of this residual HOA component, it is transformed into the discrete spatial domain in order to obtain the general plane wave functions at uniform sampling directions representing the residual HOA component. Thereafter these plane wave functions are predicted from the dominant directional signals. The reason for this operation is that parts of the residual HOA component may be highly correlated with the dominant directional signals.
That prediction can be a simple one so as to produce only a small amount of side information. In the simplest case the prediction consists of an appropriate scaling and delay. Finally, the prediction error is transformed back to the HOA domain and is regarded as the residual ambient HOA component for which an order reduction is performed.
Advantageously, the effect of subtracting the predictable signals from the residual HOA component is to reduce its total power as well as the remaining amount of dominant directional signals and, in this way, to reduce the decomposition error resulting from the order reduction.
In principle, the inventive compression method is suited for compressing a Higher Order Ambisonics representation denoted HOA for a sound field, said method including the steps:
In principle the inventive compression apparatus is suited for compressing a Higher Order Ambisonics representation denoted HOA for a sound field, said apparatus including:
In principle, the inventive decompression method is suited for decompressing a Higher Order Ambisonics representation compressed according to the above compression method, said decompressing method including the steps:
In principle the inventive decompression apparatus is suited for decompressing a Higher Order Ambisonics representation compressed according to the above compressing method, said decompression apparatus including:
Exemplary embodiments of the invention are described with reference to the accompanying drawings, which show in:
The compression processing according to the invention includes two successive steps illustrated in
D(k):=[d((kB+1)TS)d((kB+2)TS) . . . d((kB+B)TS)], (1)
where TS denotes the sampling period.
In
A
{circumflex over (Ω)}(k): =[{circumflex over (Ω)}DOM,1(k) . . . (k)] (2)
It is implicitly assumed that the direction estimates are appropriately ordered by assigning them to the direction estimates from previous frames. Hence, the temporal sequence of an individual direction estimate is assumed to describe the directional trajectory of a dominant sound source. In particular, if the d-th dominant sound source is supposed not to be active, it is possible to indicate this by assigning a non-valid value to {circumflex over (Ω)}DOM,d(k). Then, exploiting the estimated directions in A{circumflex over (Ω)}(k), the HOA representation is decomposed in a decomposing step or stage 12 into a number of maximum dominant directional signals XDIR(k−1), some parameters ζ(k−1) describing the prediction of the spatial domain signals of the residual HOA component from the dominant directional signals, and an ambient HOA component DA(k−2) representing the prediction error. A detailed description of this decomposition is provided in section HOA decomposition.
In
It is noted that, compared to the approach in patent publication EP 2665208 A1, the reduced order NRED may in general be chosen smaller, since the total power as well as the remaining amount of directivity of the residual ambient HOA component is smaller. Therefore the order reduction causes smaller errors as compared to EP 2665208 A1.
In a following decorrelation step or stage 14, the HOA coefficient sequences representing the order reduced ambient HOA component DA,RED (k−2) are decorrelated to obtain the time domain signals WA,RED(k−2), which are input to (a bank of) parallel perceptual encoders or compressors 15 operating by any known perceptual compression technique. The decorrelation is performed in order to avoid perceptual coding noise unmasking when rendering the HOA representation following its decompression (see patent publication EP 2688065 A1 for explanation). An approximate decorrelation can be achieved by transforming DA,RED (k−2) to ORED equivalent signals in the spatial domain by applying a Spherical Harmonic Transform as described in EP 2469742 A2.
Alternatively, an adaptive Spherical Harmonic Transform as proposed in patent publication EP 2688066 A1 can be used, where the grid of sampling directions is rotated to achieve the best possible decorrelation effect. A further alternative decorrelation technique is the Karhunen-Loeve transform (KLT) described in patent application EP 12305860.4. It is noted that for the last two types of de-correlation some kind of side information, denoted by α(k−2), is to be provided in order to enable reversion of the decorrelation at a HOA decompression stage.
In one embodiment, the perceptual compression of all time domain signals XDIR(k−1) and WA,RED(k−2) is performed jointly in order to improve the coding efficiency.
Output of the perceptual coding is the compressed directional signals X̆DIR(k−1) and the compressed ambient time domain signals W̆A,RED(k−2).
The decompression processing is shown in
In
In case the perceptual compression of all time domain signals XDIR(k−1) and WA,RED (k−2) was performed jointly in order to improve the coding efficiency, the perceptual decompression of the compressed directional signals X̆DIR(k−1) and the compressed time domain signals W̆A,RED (k−2) is also performed jointly in a corresponding manner.
A detailed description of the recomposition is provided in section HOA recomposition.
A block diagram illustrating the operations performed for the HOA decomposition is given in
Before going into detail, it is mentioned that the changes of the directions between successive frames can lead to a discontinuity of all computed signals during the composition. Hence, instantaneous estimates of the respective signals for overlapping frames are computed first, which have a length of 2B. Second, the results of successive overlapping frames are smoothed using an appropriate window function. Each smoothing, however, introduces a latency of a single frame.
The computation of the instantaneous dominant direction signals in step or stage 30 from the estimated sound source directions in A{circumflex over (Ω)}(k) for a current frame D (k) of HOA coefficient sequences is based on mode matching as described in M. A. Poletti, “Three-Dimensional Surround Sound Systems Based on Spherical Harmonics”, J. Audio Eng. Soc., 53(11), pages 1004-1025, 2005. In particular, those directional signals are searched whose HOA representation results in the best approximation of the given HOA signal.
Further, without loss of generality, it is assumed that each direction estimate {circumflex over (Ω)}DOM,d(k) of an active dominant sound source can be unambiguously specified by a vector containing an inclination angle θDOM,d(k)ϵ[0, π] and an azimuth angle ϕDOM,d(k)ϵ[0,2π] (see
{circumflex over (Ω)}DOM,d(k):=({circumflex over (θ)}DOM,d(k),{circumflex over (ϕ)}DOM,d(k))T. (3)
First, the mode matrix based on the direction estimates of active sound sources is computed according to
In equation (4), DACT (k) denotes the number of active directions for the k-th frame and dACT,j(k), 1≤j≤DACT(k) indicates their indices. Snm(⋅) denotes the real-valued Spherical Harmonics, which are defined in section Definition of real valued Spherical Harmonics.
Second, the matrix {tilde over (X)}DIR(k)ϵ×2B containing the instantaneous estimates of all dominant directional signals for the (k 1)-th and k-th frames defined as
{tilde over (X)}
DIR(k):=[{tilde over (x)}DIR(k,1){tilde over (x)}DIR(k,2) . . . {tilde over (x)}DIR(k,2B)] (6)
with {tilde over (x)}DIR(k,l):=[{tilde over (x)}(k,l),xDIR,2(k,l), . . . , {tilde over (x)}DIR,D(k,l)]TΣ,1≤l≤2B (7)
is computed. This is accomplished in two steps. In the first step, the directional signal samples in the rows corresponding to inactive directions are set to zero, i.e.
{tilde over (x)}
DIR,d(k,l)=0 ∀1≤l≤2B,if dΞACT(k), (8)
where ACT(k) indicates the set of active directions. In the second step, the directional signal samples corresponding to active directions are obtained by first arranging them in a matrix according to
This matrix is then computed to minimise the Euclidean norm of the error
ΞACT(k){tilde over (X)}DIR,ACT(k)−[D(k−1)D(k)]. (10)
The solution is given by
{tilde over (X)}
DIR,ACT(k)=[ΞACTT(k)ΞACT(k)]−1ΞACTT(k)[D(k−1)D(k)]. (11)
For step or stage 31, the smoothing is explained only for the directional signals {tilde over (X)}DIR(k), because the smoothing of other types of signals can be accomplished in a completely analogous way. The estimates of the directional signals {tilde over (x)}DIR,d(k,l), 1≤d≤, whose samples are contained in the matrix {tilde over (X)}DIR(k) according to equation (6), are windowed by an appropriate window function w(l):
{tilde over (x)}DIR,WIN,d(k,l):={tilde over (x)}DIR,d(k,l)·w(l),1≤l≤2B. (12)
This window function must satisfy the condition that it sums up to ‘1’ with its shifted version (assuming a shift of B samples) in the overlap area:
w(l)+w(B+l)=1∀1≤l≤B. (13)
An example for such window function is given by the periodic Hann window defined by
The smoothed directional signals for the (k−1)-th frame are computed by the appropriate superposition of windowed instantaneous estimates according to
x
DIR,d((k−1)B+l)={acute over (x)}DIR,WIN,d(k−1,B+1)+{tilde over (x)}DIR,WIN,d(k,l). (15)
The samples of all smoothed directional signals for the (k 1)-th frame are arranged in
the matrix XDIR(k−1):= (16)
[xDIR((k−1)B+1)xDIR((k−1)B+2) . . . xDIR((k−1)B+B)]ϵ×B1
with xDIR(l)=[xDIR,1(l),xDIR,2(l), . . . ,xDIR,D(l)]Tϵ. (17)
The smoothed dominant directional signals XDIR,d(l) are supposed to be continuous signals, which are successively input to perceptual coders.
From XDIR(k−1) and A{circumflex over (Ω)}(k), the HOA representation of the smoothed dominant directional signals is computed in step or stage 32 depending on the continuous signals xDIR,d (l) in order to mimic the same operations like to be performed for the HOA composition. Because the changes of the direction estimates between successive frames can lead to a discontinuity, once again instantaneous HOA representations of overlapping frames of length 2B are computed and the results of successive overlapping frames are smoothed by using an appropriate window function. Hence, the HOA representation DDIR(k−1) is obtained by
From DDIR(k−1) and D(k−1) (i.e. D(k) delayed by frame delay 381), a residual HOA representation by directional signals on a uniform grid is calculated in step or stage 33. The purpose of this operation is to obtain directional signals (i.e. general plane wave functions) impinging from some fixed, nearly uniformly distributed directions {circumflex over (Ω)}GRID,o, 1≤o≤0 (also referred to as grid directions), to represent the residual [D(k−2) D(k−1)]−[DDIR(k−2) DDIR(k−1)].
First, with respect to the grid directions the mode matrix ΞGRID is computed as
ΞGRID:=[SGRID,1SGRID,2 . . . SGRID,O]ϵO×O (21)
with
S
GRID,o:=[S00({circumflex over (Ω)}GRID,o),S1−1({circumflex over (Ω)}GRID,o),S10({circumflex over (Ω)}GRID,o), . . . ,SNN({circumflex over (Ω)}GRID,o)]Tϵ0. (22)
Because the grid directions are fixed during the whole compression procedure, the mode matrix ΞGRID needs to be computed only once.
The directional signals on the respective grid are obtained as {tilde over (X)}GRID,DIR(k−1)=(23) ΞGRID−1([D(k−2) D (k−1)]−[DDIR(k−2) DDIR(k−1)]).
Predicting Directional Signals on Uniform Grid from Dominant Directional Signals
From {tilde over (X)}GRID,DIR(k−1) and XDIR(k−1), directional signals on the uniform grid are predicted in step or stage 34. The prediction of the directional signals on the uniform grid composed of the grid directions {circumflex over (Ω)}GRID,O, 1≤o≤0 from the directional signals is based on two successive frames for smoothing purposes, i.e. the extended frame of grid signals {tilde over (X)}GRID,DIR(k−1) (of length 2B) is predicted from the extended frame of smoothed dominant directional signals
{tilde over (X)}
DIR,EXT(k−1):=[XDIR(k−3)XDIR(k−2)XDIR(k−1)]. (24)
First, each grid signal {tilde over (x)}GRID,DIR,o (k−1, l), 1≤o≤0, contained in {tilde over (X)}GRID,DIR(k−1) is assigned to a dominant directional signal {tilde over (x)}DIR,EXT,d (k−1, l), 1≤d≤, contained in {tilde over (X)}DIR,EXT(k−1). The assignment can be based on the computation of the normalised cross-correlation function between the grid signal and all dominant directional signals. In particular, that dominant directional signal is assigned to the grid signal, which provides the highest value of the normalised cross-correlation function. The result of the assignment can be formulated by an assignment function ,q,k−1: {1, . . . , 0}→{1, . . . , } assigning the o-th grid signal to the ,k−1(o)-th dominant directional signal.
Second, each grid signal {tilde over (x)}GRID,DIR,o (k−1, l) is predicted from the assigned dominant directional signal ,k−1(o)(k−1, l). The predicted grid signal {tilde over ({circumflex over (x)})}GRID,DIR,o (k−1, l) is computed by a delay and a scaling from the assigned dominant directional signal ,k−1(o)(k−1, l) as
{tilde over ({circumflex over (x)})}GRID,DIR,o(k−1,l)=Ko(k−1)·,k−1(o)(k−1,l−Δo(k−1)), (25)
where K0(k−1) denotes the scaling factor and Δo(k−1) indicates the sample delay. These parameters are chosen for minimising the prediction error.
If the power of the prediction error is greater than that of the grid signal itself, the prediction is assumed to have failed. Then, the respective prediction parameters can be set to any non-valid value.
It is noted that also other types of prediction are possible. For example, instead of computing a full-band scaling factor, it is also reasonable to determine scaling factors for perceptually oriented frequency bands. However, this operation improves the prediction at the cost of an increased amount of side information.
All prediction parameters can be arranged in the parameter matrix as
All predicted signals {tilde over ({circumflex over (x)})}GRID,DIR,o(k−1, l), 1≤o≤0, are assumed to be arranged in the matrix {tilde over ({circumflex over (X)})}GRID,DIR(k−1).
The HOA representation of the predicted grid signals is computed in step or stage 35 from {tilde over ({circumflex over (X)})}GRID,DIR(k−1) according to
{tilde over ({circumflex over (D)})}GRID,DIR(k−1)=ΞGRID{tilde over ({circumflex over (X)})}GRID,DIR(k−1) (27)
From {circumflex over (D)}GRID,DIR(k−2), which is a temporally smoothed version (in step/stage 36) of {tilde over ({circumflex over (D)})}GRID,DIR(k−1), from D(k−2) which is a two-frames delayed version (delays 381 and 383) of D(k), and from DDIR(k−2) which is a frame delayed version (delay 382) of DDIR(k−1), the HOA representation of the residual ambient sound field component is computed in step or stage 37 by
D
A(k−2)=D(k−2)−{circumflex over (D)}GRID,DIR(k−2)−DDIR(k−2). (28)
Before describing in detail the processing of the individual steps or stages in
A{circumflex over (Ω)}(k) and {circumflex over (X)}DIR(k−1) are input to a step or stage 41 for determining an HOA representation of dominant directional signals. After having computed the mode matrices ΞACT(k) and ΞACT(k−1) from the direction estimates A{circumflex over (Ω)}(k) and A{circumflex over (Ω)}(k−1), based on the direction estimates of active sound sources for the k-th and (k−1)-th frames, the HOA representation of the dominant directional signals {circumflex over (D)}DIR(k−1) is obtained by
Predicting Directional Signals on Uniform Grid from Dominant Directional Signals
{circumflex over (ζ)}(k−1) and {circumflex over (X)}DIR(k−1) are input to a step or stage 43 for predicting directional signals on uniform grid from dominant directional signals. The extended frame of predicted directional signals on uniform grid consists of the elements {tilde over ({circumflex over (x)})}GRID,DIR,o(k−1, l) according to
which are predicted from the dominant directional signals by
{tilde over ({circumflex over (x)})}GRID,DIR,o(k−1,l)=Ko(k−1)·k−1(o)((k−1)B+l−Δo(k−1)). (33)
In a step or stage 44 for computing the HOA representation of predicted directional signals on uniform grid, the HOA representation of the predicted grid directional signals is obtained by {tilde over ({circumflex over (D)})}GRID,DIR(k−1)=ΞGRID{tilde over ({circumflex over (X)})}GRID,DIR(k−1), (34)
where ΞGRID denotes the mode matrix with respect to the predefined grid directions (see equation (21) for definition).
From {circumflex over (D)}DIR(k−2) (i.e. {circumflex over (D)}DIR(k−1) delayed by frame delay 42), {circumflex over (D)}GRID,DIR(k−2) (which is a temporally smoothed version of {tilde over ({circumflex over (D)})}GRID,DIR(k−1) in step/stage 45) and {circumflex over (D)}A(k−2), the total HOA sound field representation is finally composed in a step or stage 46 as
{circumflex over (D)}(k−2)={circumflex over (D)}DIR(k−2)+{circumflex over (D)}GRID,DIR(k−2)+{circumflex over (D)}A(k−2). (35)
Higher Order Ambisonics is based on the description of a sound field within a compact area of interest, which is assumed to be free of sound sources. In that case the spatiotemporal behaviour of the sound pressure p(t,x) at time t and position x within the area of interest is physically fully determined by the homogeneous wave equation. The following is based on a spherical coordinate system as shown in
It can be shown (see E. G. Williams, “Fourier Acoustics”, volume 93 of Applied Mathematical Sciences, Academic Press, 1999) that the Fourier transform of the sound pressure with respect to time denoted by t(⋅), i.e.
P(ω,x)=t(p(t,x))=∫−∞∞p(t,x)e−i⋅tdt (36)
with ω denoting the angular frequency and i denoting the imaginary unit, may be expanded into a series of Spherical Harmonics according to
P(ω=kcs,r,θ,ϕ)=Σn=0NΣm=−nnAnm(k)jn(kr)Snm(θ,ϕ) (37)
where cs denotes the speed of sound and k denotes the angular wave number, which is related to the angular frequency ω by
denotes the spherical Bessel functions of the first kind, and Snm(θ, ϕ) denotes the real valued Spherical Harmonics of order n and degree which are defined in section Definition of real valued Spherical Harmonics. The expansion coefficients Anm(k) are depending only on the angular wave number k. Note that it has been implicitly assumed that sound pressure is spatially band-limited. Thus the series is truncated with respect to the order index n at an upper limit N, which is called the order of the HOA representation.
If the sound field is represented by a superposition of an infinite number of harmonic plane waves of different angular frequencies ω and is arriving from all possible directions specified by the angle tuple (θ, ϕ), it can be shown (see B. Rafaely, “Plane-wave Decomposition of the Sound Field on a Sphere by Spherical Convolution”, J. Acoust. Soc. Am., 4(116), pages 2149-2157, 2004) that the respective plane wave complex amplitude function D (ω, θ, ϕ) can be expressed by the Spherical Harmonics expansion
D(ω=kcs,θ,ϕ)=Σn=0NΣm=−nnDnm(k)Snm(θ,ϕ), (38)
where the expansion coefficients Dnm(k) are related to the expansion coefficients Anm(k) by Anm(k)=4πinDnm(k). (39)
Assuming the individual coefficients Dnm(k=ω/cs) to be functions of the angular frequency ω, the application of the inverse Fourier transform (denoted by t−1(⋅)) provides time domain functions
for each order n and degree m, which can be collected in a single vector d(t)=
The position index of a time domain function dnm(t) within the vector d(t) is given by n(n+1)+1+m.
The final Ambisonics format provides the sampled version of d(t) using a sampling frequency fS as
{d(lTS)}lϵN={d(TS),d(2TS),d(3TS),d(4TS), . . . }, (42)
where TS=1/fS denotes the sampling period. The elements of d(lTS) are referred to as Ambisonics coefficients. Note that the time domain signals dnm(t) and hence the Ambisonics coefficients are real-valued.
The real valued spherical harmonics Snm(θ,ϕ) are given by
The associated Legendre functions Pn,m(x) are defined as
with the Legendre polynomial Pn(x) and, unlike in the above mentioned E. G. Williams textbook, without the Condon-Short-ley phase term (−1)m.
A general plane wave function x(t) arriving from a direction Ω0=(θ0, ϕ0)T is represented in HOA by
d
n
m(t)=x(t)Snm(Ω0),0≤n≤N,|m|≤n. (46)
The corresponding spatial density of plane wave amplitudes d(t,Ω):=t−1(D(ω,Ω)) is given by
It can be seen from equation (48) that it is a product of the general plane wave function x(t) and a spatial dispersion function vN(Θ), which can be shown to only depend on the angle Θ between Ω and Ω0 having the property
cos Θ=cos θ cos θ0+cos(ϕ−ϕ0)sin θ sin θ0. (49)
As expected, in the limit of an infinite order, i.e. N→∞, the spatial dispersion function turns into a Dirac delta δ(⋅), i.e.
However, in the case of a finite order N, the contribution of the general plane wave from direction Ω0 is smeared to neighbouring directions, where the extent of the blurring decreases with an increasing order. A plot of the normalised function vN(Θ) for different values of N is shown in
It is pointed out that any direction Ω of the time domain behaviour of the spatial density of plane wave amplitudes is a multiple of its behaviour at any other direction. In particular, the functions d(t,Ω1) and d(t,Ω2) for some fixed directions Ω1 and Ω2 are highly correlated with each other with respect to time t.
If the spatial density of plane wave amplitudes is discretised at a number of 0 spatial directions Ω0, 1≤o≤0, which are nearly uniformly distributed on the unit sphere, 0 directional signals d(t,Ω0) are obtained. Collecting these signals into a vector
d
SPAT(t):=[d(t,Ω1) . . . d(t,Ω0)]T, (51)
it can be verified by using equation (47) that this vector can be computed from the continuous Ambisonics representation d(t) defined in equation (41) by a simple matrix multiplication as dSPAT(t)=ΨHd(t), (52)
where (⋅)H indicates the joint transposition and conjugation, and Ψ denotes the mode-matrix defined by Ψ:=[S1 . . . S0] (53)
with
S
0:=[S00(Ω0)S1−1(Ω0)S10(Ω0)S11(Ω0) . . . SNN−1(Ω0)SNN(Ω0)]. (54)
Because the directions Ω0 are nearly uniformly distributed on the unit sphere, the mode matrix is invertible in general. Hence, the continuous Ambisonics representation can be computed from the directional signals d(t, Ω0) by
d(t)=Ψ−HdSPAT(t). (55)
Both equations constitute a transform and an inverse transform between the Ambisonics representation and the spatial domain. In this application these transforms are called the Spherical Harmonic Transform and the inverse Spherical Harmonic Transform. Because the directions Ω0 are nearly uniformly distributed on the unit sphere, ΨHΨ≈−1, (56) which justifies the use of Ψ−1 instead of ΨH in equation (52). Advantageously, all mentioned relations are valid for the discrete-time domain, too.
At encoding side as well as at decoding side the inventive processing can be carried out by a single processor or electronic circuit, or by several processors or electronic circuits operating in parallel and/or operating on different parts of the inventive processing.
The invention can be applied for processing corresponding sound signals which can be rendered or played on a loudspeaker arrangement in a home environment or on a loudspeaker arrangement in a cinema.
Number | Date | Country | Kind |
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12306569.0 | Dec 2012 | EP | regional |
This application is a continuation of U.S. patent application Ser. No. 16/828,961, filed Mar. 25, 2020, which is division of U.S. patent application Ser. No. 16/276,363, filed Feb. 14, 2019, now U.S. Pat. No. 10,609,501; which is division of U.S. patent application Ser. No. 16/019,256, filed Jun. 26, 2018, now U.S. Pat. No. 10,257,635, which is division of U.S. patent application Ser. No. 15/435,175, filed Feb. 16, 2017, now U.S. Pat. No. 10,038,965, which is continuation of U.S. patent application Ser. No. 14/651,313, filed Jun. 11, 2015, now U.S. Pat. No. 9,646,618, which is United States National Application of International Application No. PCT/EP2013/075559, filed Dec. 4, 2013, which claims priority to European Patent Application No. 12306569.0, filed Dec. 12, 2012, each of which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 16276363 | Feb 2019 | US |
Child | 16828961 | US | |
Parent | 16019256 | Jun 2018 | US |
Child | 16276363 | US | |
Parent | 15435175 | Feb 2017 | US |
Child | 16019256 | US |
Number | Date | Country | |
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Parent | 16828961 | Mar 2020 | US |
Child | 17532246 | US | |
Parent | 14651313 | Jun 2015 | US |
Child | 15435175 | US |