Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04S—STEREOPHONIC SYSTEMS 
  • H04S7/00—Indicating arrangements; Control arrangements, e.g. balance control
  • H04S7/30—Control circuits for electronic adaptation of the sound field
  • H04S7/302—Electronic adaptation of stereophonic sound system to listener position or orientation
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04S—STEREOPHONIC SYSTEMS 
  • H04S5/00—Pseudo-stereo systems, e.g. in which additional channel signals are derived from monophonic signals by means of phase shifting, time delay or reverberation 
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04S—STEREOPHONIC SYSTEMS 
  • H04S2400/00—Details of stereophonic systems covered by H04S but not provided for in its groups
  • H04S2400/01—Multi-channel, i.e. more than two input channels, sound reproduction with two speakers wherein the multi-channel information is substantially preserved

Definitions

• This invention relates to a method of processing a single channel audio signal to provide an audio signal having left and right channels corresponding to a sound source at a given direction in space relative to a preferred position of a listener in use, the information in the channels including cues for perception of the direction of said single channel audio signal from said preferred position, the method including the steps of: a) providing a two channel signal having the same single channel signal in the two channels; b) modifying the two channel signal by modifying each of the channels using one of a plurality of head response transfer functions to provide a right signal in one channel for the right ear of a listener and a left signal in the other channel for the left ear of the listener; and c) introducing a time delay between the channels corresponding to the inter-aural time difference for a signal coming from said given direction, the inter-aural time difference providing cues to perception of the direction of the sound source at a given time.
• Figure 1 shows the head of a listener and a co-ordinate system
• Figure 2 shows a plan view of the head and an arriving sound wave
• Figure 3 shows the locus of points having an equal inter-aural or inter-aural time delay
• Figure 4 shows an isometric view of the locus of Figure 3
• Figure 5 shows a plan view of the space surrounding a listener's head
• Figure 6 shows further plan views of a listener's head showing paths for use in calculations of distance to the near ear
• Figure 7 shows further plan views of a listener's head showing paths for use in calculations of distance to the far ear
• Figure 8 shows a block diagram of a prior art method.
• Figure 9 shows a block diagram of a method according to the present invention
• Figure 10 shows a plot of near ear gain as a function of azimuth and distance
• Figure 11 shows a plot of far ear gain as a function of azimuth and distance.
• the present invention relates particularly to the reproduction of 3D-sound from two-speaker stereo systems or headphones.
• This type of 3D-sound is described, for example, in EP-B-0689756 which is incorporated herein by reference.
• HRTFs Head-Response Transfer Functions
• These sound cues are introduced naturally by the head and ears when we listen to sounds in real life, and they include the inter-aural amplitude difference (IAD), inter-aural time difference
• the loudspeaker in order to have the effects of these loudspeaker signals representative of a point source, the loudspeaker must be spaced at a distance of around 1 metre from the artificial head. Secondly, it is usually required to create sound effects for PC games and the like which possess apparent distances of several metres or greater, and so, because there is little difference between HRTFs measured at 1 metre and those measured at much greater distances, the 1 metre measurement is used.
• HF HF
• the present invention comprises a means of creating near-field distance effects for 3D-sound synthesis using a "standard" 1 metre HRTF set.
• the method uses an algorithm which controls the relative left-right channel amplitude difference as a function of (a) required proximity, and (b) spatial position.
• the algorithm is based on the observation that when a sound source moves towards the head from a distance of 1 metre, then the individual left and right-ear properties of the HRTF do not change a great deal in terms of their spectral properties. However, their amplitudes, and the amplitude difference between them, do change substantially, caused by a distance ratio effect.
• the expression "near-field” is defined to mean that volume of space around the listener's head up to a distance of about 1 - 1.5 metre from the centre of the head.
• a “closeness limit” For practical reasons, it is also useful to define a "closeness limit", and a distance of 0.2 m has been chosen for the present purpose of illustrating the invention. These limits have both been chosen purely for descriptive purposes, based respectively upon a typical HRTF measurement distance (1 m) and the closest simulation distance one might wish to create, in a game, say.
• the distance ratio (left-ear to sound source vs. right-ear to sound source) becomes greater.
• the intensity of a sound source diminishes with distance as the energy of the propagating wave is spread over an increasing area.
• the wavefront is similar to an expanding bubble, and the energy density is related to the surface area of the propagating wavefront, which is related by a square law to the distance travelled (the radius of the bubble).
• the intensity level would simply increase according to the inverse square law.
• Figure 1 shows a diagram of the near-field space around the listener, together with the reference planes and axes which will be referred to during the following descriptions, in which P-P' represents the front-back axis in the horizontal plane, intercepting the centre of the listener's head, and with Q-Q' representing the corresponding lateral axis from left to right.
• the inter-aural time-delay represents a very close approximation of the relative acoustic path length difference between a sound source and each of the ears
• the next stage is to find out a means of determining the value of the signal gains which must be applied to the left and right-ear channels when a "close" virtual sound source is required. This can be done if the near- and far-ear situations are considered in turn, and if we use the 1 metre distance as the outermost reference datum, at which point we define the sound intensity to be 0 dB.
• Figure 5 shows a plan view of the listener's head, together with the near- field area surrounding it.
• Figure 7 shows a plan view of the listener's head, together with the near- field area surrounding it.
• the path between the sound source and the far-ear comprises two serial elements, as is shown clearly in the right hand detail of Figure 7.
• the distance from the sound source to the centre of the head is d, and the head radius is r.
• the angle subtended by the tangent point and the head centre at the source is angle R.
• the gain is expressed in dB units with respect to the 1 metre distance reference, defined to be 0 dB.
• the gain, in dB is calculated according to the inverse square law from path length, d (in cm), as:
• the 100 cm line is equal to 0 dB at azimuth
• the 20 cm distance line shows a gain of 13.4 dB at azimuth 0°, because, naturally, it is closer, and, again, the level increases as the sound source moves around to the 90° position, to 18.1: a much greater increase this time.
• the other distance lines show intermediate properties between these two extremes.
• the 100 cm line is equal to 0 dB at azimuth 0° (as one expects), but here, as the sound source moves around to the 90 position, away from the far-ear, the level decreases to -0.99 dB.
• the 20 cm distance line shows a gain of 13.8 dB at azimuth 0°, similar to the equidistant near- ear, and, again, the level decreases as the sound source moves around to the 90 position, to 9.58: a much greater decrease than for the 100 cm data.
• the other distance lines show intermediate properties between these two extremes.
• each HRTF can be used as an index for selecting the appropriate L and R gain factors. Every inter-aural time-delay is associated with a horizontal plane equivalent, which, in turn, is associated with a specific azimuth angle. This means that a much smaller look-up table can be used.
• An HRTF library of the above resolution features horizontal plane increments of 3°, such that there are 31 HRTFs in the range 0° to 90°. Consequently, the size of a time-delay-indexed look-up table would be 31 x 4 x 2 elements (248 elements), which is only 2.8% the size of the
• Time-delay based look-up table for determining near-ear gain factor as function of distance between virtual sound source and centre of the head.
• Time-delay based look-up table for determining far-ear gain factor as function of distance between virtual sound source and centre of the head. Note that the time-delays in the above tables are shown in units of sample periods related to a 44.1 kHz sampling rate, hence each sample unit is 22.676 ⁇ s.
• Figure 8 shows the conventional means of creating a virtual sound source, as follows.
• the HRTF comprises a left-ear function, a right-ear function and an inter-aural time- delay value.
• the HRTF data will generally be in the form of FIR filter coefficients suitable for controlling a pair of FIR filters (one for each channel), and the time-delay will be represented by a number.
• a monophonic sound source is then transmitted into the signal- processing scheme, as shown, thus creating both a left- and right-hand channel outputs. (These output signals are then suitable for onward transmission to the listener's headphones, or crosstalk-cancellation processing for loudspeaker reproduction, or other means).
• the invention shown in Figure 9, supplements this procedure, but requires little extra computation.
• the signals are processed as previously, but a near-field distance is also specified, and, together with the time-delay data from the selected HRTF, is used to select the gain for respective left and right channels from a look-up table; this data is then used to control the gain of the signals before they are output to subsequent stages, as described before.
• the left channel output and the right channel output shown in Figure 9 can be combined directly with a normal stereo or binaural signal being fed to headphones, for example, simply by adding the signal in corresponding channels.
• the two output signals should be added to the corresponding channels of the binaural signal after transaural crosstalk compensation has been performed.
• the magnitudes may be set before such signal processing if desired, so that the order of the steps in the described method is not an essential part of the invention.
• the position of the virtual sound source relative to the preferred position of a listener's head in use is constant and does not change with time, by suitable choice of sucessive different positions for the virtual sound source it can be made to move relative to the head of the listener in use if desired.
• This apparent movement may be provided by changing the direction of the virtual souce from the preferred position, by changing the distance to it, or by changing both together.

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• Physics & Mathematics (AREA)
• Engineering & Computer Science (AREA)
• Acoustics & Sound (AREA)
• Signal Processing (AREA)
• Stereophonic System (AREA)

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• 1997
  • 1997-12-13 GB GBGB9726338.8A patent/GB9726338D0/en not_active Ceased
• 1998
  • 1998-12-11 DE DE69841097T patent/DE69841097D1/de not_active Expired - Fee Related
  • 1998-12-11 WO PCT/GB1998/003714 patent/WO1999031938A1/en not_active Ceased
  • 1998-12-11 EP EP98960002A patent/EP0976305B1/en not_active Expired - Lifetime
  • 1998-12-11 US US09/367,153 patent/US7167567B1/en not_active Expired - Fee Related
  • 1998-12-11 JP JP53218199A patent/JP4633870B2/ja not_active Expired - Lifetime
• 2008
  • 2008-09-04 JP JP2008227614A patent/JP4663007B2/ja not_active Expired - Lifetime

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