WO2004098053A2 - Volume and compression control in movie theaters - Google Patents
Volume and compression control in movie theaters Download PDFInfo
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- WO2004098053A2 WO2004098053A2 PCT/US2004/012629 US2004012629W WO2004098053A2 WO 2004098053 A2 WO2004098053 A2 WO 2004098053A2 US 2004012629 W US2004012629 W US 2004012629W WO 2004098053 A2 WO2004098053 A2 WO 2004098053A2
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03G—CONTROL OF AMPLIFICATION
- H03G9/00—Combinations of two or more types of control, e.g. gain control and tone control
- H03G9/005—Combinations of two or more types of control, e.g. gain control and tone control of digital or coded signals
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03G—CONTROL OF AMPLIFICATION
- H03G7/00—Volume compression or expansion in amplifiers
- H03G7/002—Volume compression or expansion in amplifiers in untuned or low-frequency amplifiers, e.g. audio amplifiers
- H03G7/004—Volume compression or expansion in amplifiers in untuned or low-frequency amplifiers, e.g. audio amplifiers using continuously variable impedance devices
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03G—CONTROL OF AMPLIFICATION
- H03G9/00—Combinations of two or more types of control, e.g. gain control and tone control
- H03G9/02—Combinations of two or more types of control, e.g. gain control and tone control in untuned amplifiers
- H03G9/04—Combinations of two or more types of control, e.g. gain control and tone control in untuned amplifiers having discharge tubes
- H03G9/10—Combinations of two or more types of control, e.g. gain control and tone control in untuned amplifiers having discharge tubes for tone control and volume expansion or compression
Definitions
- the invention relates generally to the processing of audio signals. More particularly, the invention relates to control of the loudness of motion picture soundtracks when reproduced. BACKGROUND ART
- Dolby Laboratories introduced a calibration recommendation for monitor levels in movie soundtracks ("Dolby” is a trademark of Dolby Laboratories, Inc.).
- Dolby is a trademark of Dolby Laboratories, Inc.
- a pink noise reference signal was used in the record chain to adjust the audio monitor level to 85 dBc. All theatres equipped for playback of the new stereo optical soundtracks were set up such that an equivalent pink noise signal in a soundtrack channel generated the same 85 dBc with the playback volume control (fader) set to the calibrated setting.
- the maximum sound pressure level in a theater is also a function of the number of soundtrack channels. For example, five channels can deliver 2.5 times as much power as two channels, resulting in an increase of 4 dB in sound pressure level. Thus, in the case of five or seven channel digital soundtrack reproduction, for example, the increase in peak sound pressure level is even greater than that shown in FIG. 1.
- the "non-associative" loudness of effects and music has risen to fill the available headroom space.
- loud sounds like explosions are often 20 dB or more louder (explosions reach full scale peak level of 25 dB above dialogue level), and some quiet sounds, which are intended to be heard by all listeners, such as leaves rustling, may be 50 dB quieter.
- audience complaints that movies are too loud many theatres are playing films substantially below the calibrated level.
- Some cinemas have their volume control permanently turned down to such settings because projectionists operating multiplexes with many screens showing different movies simultaneously don't have the time or cannot be bothered to set the controls differently for different movies. If the volume control is turned down to avoid complaints of excessive loudness, the dialogue is quieter than the mixer intended, and audiences may complain instead that some dialogue is not intelligible in the presence of other sounds in the film and/or general background noise of the theater (popcorn eating, air-conditioning, people talking, etc.).
- Theatre playback levels are often set by complaints generated by the loudest (and earliest) element of the show. If the playback level is set in response to the loudest trailer (preview), which is often louder than the feature film, the feature often plays at the same reduced level. The result is that the dialogue level of the feature is lowered by the same level deemed necessary to attenuate the trailer.
- a feature film played with a loudness 6 dB below the calibrated level may have serious dialogue intelligibility problems and veiy quiet sounds may become inaudible.
- the volume control was a mechanical potentiometer, often with a click-stop or detent at the standard setting. More recent (digital) equipment uses a shaft encoder or a pair of up-down buttons (with a numeric display for the setting), delivering a control signal that operates on multipliers (either digital or voltage-controlled amplifiers) to affect the gain applied to all channels of the reproduced soundtracks.
- the volume control varies the gain gradually and relatively uniformly over a range of settings from about "4" to "10,” with the gain falling more rapidly at setting below about “4,” allowing a fade to inaudibility.
- the present invention provides a motion picture soundtrack reproduction system, the system having a plurality of soundtrack channels.
- An estimator of the loudness of the channels when reproduced provides a loudness estimation level in response to the soundtrack channels or data associated with the soundtrack channels.
- a control for adjusting both gain and compression applied to the channels has a range of settings from a minimum to a maximum including a standard setting at which a signal having a respective reference level in each channel is reproduced at a respective standard acoustic level. At the standard setting, the gain applied to each of the channels is substantially constant for all loudness estimation levels and substantially no compression is applied.
- the gain of each channel is substantially constant at each control setting and substantially no compression is applied for loudness estimation levels up to a threshold higher than the standard acoustic level and, for loudness esthnation levels above the threshold, compression is applied to one or more channels, the threshold decreasing as the control setting decreases.
- the range of control settings less than the standard setting extends down to the minimum control setting, or, alternatively, the range of control settings less than the standard setting extends down to a further setting above the minimum control setting.
- the gain of each channel may remain substantially constant as the control setting decreases.
- the gains of all the channels may decrease as the control setting decreases.
- the threshold may remain substantially constant.
- the gain of each channel may decrease as the setting decreases at a rate less than the decrease in gain as the control setting decreases for settings below about the further setting.
- substantially no compression may be applied and the gain of the channels may increase as the control setting increases.
- the standard acoustic level provides a standard acoustic level for dialogue. Consequently, the threshold may be above a loudness estimation level that results in the compression of dialogue, so that dialogue is not compressed.
- compression When compression is applied, it may be applied to all channels or only to some channels and not to all channels. When applied to all channels, it may be applied uniformly or non-unifo ⁇ nly. When applied only to some channels and not to all channels, it may be applied unifoiinly or non-unifonnly to channels to which it is applied.
- the plurality of soundtrack channels includes a plurality of front soundtrack channels and a plurality of surround soundtrack channels
- less compression may be applied to the surround soundtrack channels than to the front soundtrack channels.
- the compression applied to one or more channels may have a linear limiting characteristic.
- compression may be applied to the one or more channels.
- the loudness estimated by the estimator may be an estimation of the subjective loudness of the channels that would result if the control were set at its standard setting.
- the loudness estimated by the estimator may be a measure of subjective loudness of the plurality of soundtiacks as a function of an estimated acoustic level of some or all the reproduced channels, their frequency content, and tune.
- the estimator may provide a loudness estimation level in response to soundtrack channel signal voltage levels.
- the estimator may provide a loudness estimation level in response to a summation of the frequency-weighted and squared soundtrack channel signal voltage levels for all soundtrack channels.
- the frequency weighting may be A-weighting, CCIR-weighting (also known as ITU/R weighting), or some other suitable weighting.
- the estimator may provide a loudness estimation level in response to metadata associated with the soundtrack channels.
- the invention provides for a single control to determine both volume and the degree of compression in the reproduction of motion picture soundtracks. For some settings of the control, compression or limiting reduces the highest levels on a movie soundtrack, leaving the dialogue level substantially unchanged, thus removing the reason for complaints from the audience without the danger of making the dialogue too quiet for intelligibility.
- the compressor threshold is a function of the setting of the "volume control.” At a standard setting and above, the compressor is disabled (it is of no significance whether it is actually disabled or whether the threshold is raised so far that signals cannot reach it). Over a limited range of settings below the standard setting, the contiol reduces the overall gain by less than would normally be expected of a conventional volume contiol (or by nothing at all), but the compressor threshold is placed within the possible range of estimated loudness levels so that the compressor will operate if and when the estimated loudness is sufficient to reach that threshold. Turning the control down moves the threshold down, affecting lesser levels of estimated loudness.
- the compression characteristic may be maintained substantially fixed and further reduction in the control setting introduces conventional volume reduction.
- the "volume control” there is one and one only threshold value. For example, when the cinema volume control is at a standard setting (e.g., "7" on many type of current equipment and "0.0" on certain others), the compressor is inactive.
- low-level signals may be subject to compression (boost), in order to maintain their level so that they are not overcome by background noise of the cinema.
- This option may be implemented so that below yet a further setting, low-level compression reaches a maximum degree, and further lowering of the control setting decreases gain in the channels, allowing the sound to be faded to inaudibility.
- An aspect of the present invention is that it is an estimation of the level of the reproduced loudness exceeding a threshold that leads to compression.
- the estimation is derived from signal levels in some or all of the soundtrack channels, applying appropriate time constants, as is discussed further below.
- Level and “threshold” parameters have been measured and defined in many ways.
- the “level” is generally the peak of the waveform (often die greatest of as many channels as there are), or perhaps a smoothing of the peak over a few hundreds of microseconds or a few milliseconds.
- the level is quite commonly the power measured over a few tens of milliseconds (sometimes described loosely as rms), or perhaps the mean amplitude measured over the same period.
- the threshold is in the same "units.”
- the measure used to control the compressor may consist of an estimate of subjective loudness or annoyance.
- Various techniques for estimating subjective loudness may be employed, as are described further below.
- FIG. 1 shows maximum sound pressure level versus frequency for four photographic soundtrack formats, Academy mono, Dolby A-type, Dolby SR and Dolby Digital.
- FIG. 2 is an idealized set of the loudness output versus audio input relationships of several compressors.
- FIG. 3 is an idealized set of the gain (vertical axis) versus audio input (horizontal axis) relationships of several compressors.
- FIG. 3 conveys the same information as that of FIG. 2 but does so in a different format with the vertical scale representing gain rather than output loudness.
- FIG. 4 is an idealized set of the gain applied to the reproduced sound (vertical axis) versus the subjective loudness (horizontal axis) (more precisely, an estimate of the subjective loudness with respect to the loudest sounds the motion picture soundtrack reproduction system is capable of reproducing with no compression and the volume control at the standard setting) for an embodiment of the invention.
- FIG. 4 is an idealized set of the gain applied to the reproduced sound (vertical axis) versus the subjective loudness (horizontal axis) (more precisely, an estimate of the subjective loudness with respect to the loudest sounds the motion picture soundtrack reproduction system is capable of reproducing with no compression and the volume control at the standard setting) for an embodiment of the invention.
- FIG. 5 is an idealized set of the gain applied to the reproduced sound (vertical axis) versus the subjective loudness (horizontal axis) (more precisely, an estimate of the subjective loudness with respect to the loudest sounds the motion picture soundtrack reproduction system is capable of reproducing with no compression and the volume control at the standard setting) for an alternative embodiment of the invention.
- FIG. 6 is an idealized set of the gain applied to the reproduced sound (vertical axis) versus the subjective loudness (horizontal axis) (more precisely, an estimate of the subjective loudness with respect to the loudest sounds the motion picture soundtrack reproduction system is capable of reproducing with no compression and the volume control at the standard setting) for a further alternative embodiment of the invention.
- FIG. 7 is a simplified functional block diagram showing an arrangement for controlling the gain or loss applied to audio signals in response to a control signal derived from a loudness estimation of the audio signals and a control setting.
- FIG. 8 is a simplified functional block diagram showing the generation of an estimate of loudness in response to multiple channels of audio.
- FIG. 9 show an A-weighting curve with respect to a CCIR-weighting curve (also known as an ITU-R weighting curve).
- the implementation of the present invention may be viewed as involving an audio compressor in which the compressor has a family of input/output response characteristics that are selected by the setting of a single control, conventionally a "volume" control, but in the context of the invention a control that selects not only a volume characteristic, but for some control settings, a compression response for very loud reproduced audio and, optionally, for both veiy loud and veiy quiet reproduced audio.
- FIG. 2 is an idealized set of the loudness output versus audio input relationships of several compressors.
- the axes represent levels on decibel scales, with 0 dB being arbitrary but frequently representing the highest achievable level without overload.
- a portion of a characteristic where the slope of the line is unity i.e., at 45 degrees
- a constant gain or loss i.e., no change in dynamics. If this portion, or its projection, passes through 0 dB on both axes, it represents unity gain (unity gain is provided in a motion picture sound system when the volume control setting is at its standard setting).
- Any line at 45 degrees lower represents a (fixed) loss, on higher up, a (fixed) gain or boost.
- a conventional volume control could be portrayed as a family of lines at 45 degrees, one for each setting.
- a portion of a characteristic where the slope is shallower than unity represents signal-dependent varying gain providing compression (reduction in dynamic changes).
- a portion of a characteristic with a slope greater than unity represents expansion (increase in dynamic changes).
- Curve A shows a compression characteristic with a constant slope over the whole range of audio input levels; in this example, a 1 dB change in input results in a 0.5 dB change in the output.
- Curve B shows what is generally known as a limiter (a compressor with an infinite compression ratio, sometimes referred to as a linear limiter to emphasize that there is no clipping involved); in this example, up to a predetermined input threshold, the output is exactly equal to the input, but once that threshold is exceeded, the limiter introduces loss equal to the degree by which the input has gone over the threshold, with the result that the output level remains at and does not rise significantly above the threshold value.
- a limiter a compressor with an infinite compression ratio, sometimes referred to as a linear limiter to emphasize that there is no clipping involved
- linear limiter usually refers to a device controlled by the peak of the audio waveform. Its usual function is to avoid overload by preventing the peaks from exceeding a well-defined maximum (for instance, 100% modulation of an AM tiansmitter, digital full-scale in an analog to digital converter or the maximum legal modulation of an FM transmitter).
- a best mode of the present invention uses a compression characteristic that looks like a conventional linear limiter, but differs in that the parameter being measured is estimated loudness, not peaks.
- Curve C shows a more complicated compression characteristic, similar to that employed in Dolby noise reduction systems and known as a bilinear characteristic, in which there are two thresholds, known as the start and the finish points.
- FIG. 3 is also an idealized set of the gain versus audio input relationships of several compressors.
- FIG. 3 conveys the same information as that of FIG.
- FIG. 3 format is uncommon, it is believed to indicate more clearly the compressor action and is used in FIGS. 4-6 that illustrate exemplary aspects of the present invention.
- the axes represent levels on decibel scales, with 0 dB on the horizontal axis being arbitrary but frequently representing the highest achievable level without overload.
- a portion of a characteristic where slope of the line is zero represents a constant gain or loss (i.e. no change in dynamics). If this portion, or its projection, passes through 0 dB on the vertical axis, it represents unity gain. If it is lower, it is a loss, if higher, a boost.
- a portion of a characteristic where the slope is negative represents signal-dependent varying gain providing compression (reduction in dynamic changes). For completeness, but not significant for this invention, a portion of a characteristic with a positive slope represents expansion (increase in dynamic changes).
- Curve A shows a constant slope compressor, where over the whole range of input levels, a 1 dB increase in input results in a 0.5 dB decrease in gain and hence an increase in the output of only 0.5 dB.
- Curve B shows what is generally known as a limiter (sometimes, linear limiter to emphasize that there is no clipping involved); in this example, up to a predetermined input threshold, the gain is 0 dB so the output is exactly equal to the input, but once that threshold is exceeded, the limiter introduces attenuation equal to the degree by which the input has gone over the threshold, as shown explicitly in FIG. 3, with the result that the output level remains at and does not rise significantly above the threshold value.
- a limiter sometimes, linear limiter to emphasize that there is no clipping involved
- Curve C shows a more complicated compression characteristic, similar to that employed in Dolby noise reduction systems and known as a bilinear characteristic, in which there are two thresholds, known as the start and the finish points. Below the start point, the gain is constant (say 10 dB) so the output follows the input but is consistently 10 dB larger. Above the finish point, the gain is constant but less than 10 dB; in this example, it is 0 dB, so the output is equal to the input. Between the start and finish points, the slope is negative, representing dynamic compression, and FIG. 3 a shows how the gain falls with increasing input level.
- Curve D shows a compressor that affects low-level signals only. Above a -40 dB threshold the gain is constant at 0 dB, but below the threshold, positive level-dependent gain boosts the quiet signals.”
- FIG. 4 shows the gain applied to the reproduced sound versus the subjective loudness (more precisely, an estimate of the subjective loudness with respect to the loudest sounds the motion picture soundtrack reproduction system is capable of reproducing with no compression and the volume control at the standard setting) for various control settings, in accordance with an embodiment of the present invention.
- the gain characteristics for certain control settings provide high- level compression/lhniting. For settings of "7," the standard setting, and above, there is no compression and the overall gain varies conventionally with the control setting.
- the gain over most of the dynamic ranges varies more slowly than for a conventional volume control (e.g., 2 dB per "setting unit” instead of approximately 4 dB per setting unit in this part of the range in standard motion picture sound systems), but high-level limiting attenuates the loudest sounds more for such control settings, with a threshold that moves down with decreasing control settings. Below settings of about “5.5,” the threshold ceases to move and overall attenuation of the (limited) signal occurs.
- a conventional volume control e.g., 2 dB per "setting unit” instead of approximately 4 dB per setting unit in this part of the range in standard motion picture sound systems
- FIG. 5 One useful variation of the characteristics shown in FIG. 4 is shown in FIG. 5, wherein for settings between “7,” the standard settmg, and about “5.5,” the gain does not vary but the threshold decreases with decreasing control settings.
- FIG. 6 shows representative relationships between the gain applied to the reproduced sound and the subjective loudness (more precisely, an estimate of the subjective loudness with respect to the loudest sounds the motion picture soundtrack reproduction system is capable of reproducing with no compression and the volume control at the standard setting) with both high-level limiting and low-level compression.
- a setting of "5,” for example the result is the same as in FIG. 3.
- the gain over most of the range is turned down modestly (e.g., 2 dB per division), but the limiting threshold falls so the loudest sounds are turned down more.
- the gain may remain constant as in the FIG. 5 alternative.
- characteristic responses can be realized in many ways, but may be most easily achieved using some form of look-up table, where each volume control setting has associated with it an overall gain value, a threshold of limiting and, if low-level compression is used, the start and finish points and the compression ratio between those points.
- each volume control setting has associated with it an overall gain value, a threshold of limiting and, if low-level compression is used, the start and finish points and the compression ratio between those points.
- FIGS. 4-6 While the characteristic responses shown in the examples of FIGS. 4-6 are practical and useful ones, the precise characteristics are not critical. The characteristics shown in the figures are just one example of suitable characteristics that fall within the scope of the invention.
- the maximum possible loudness of a system is typically not well defined, depending among other things on the relative powers of the amplifiers, the sensitivities of the loudspeakers, their overload levels and the frequency dependence of these parameters. Practical embodiments need not take all such parameters into account with any rigor. A rough estimate of maximum possible loudness in an installation might be made at the time of installation time in accordance with the equipment in use and the size of the room.
- the equipment is underpowered, it might be desirable to enable the compression more abruptly as the control setting is turned down from its standard setting.
- the extent to which the threshold moves into the active range for a paiticular control setting below “7” might not be the same from installation to installation.
- the characteristic curves resulting from the control settings labeled "4" to "6.5” in FIG. 4 might actually occur instead over the range of settings from "4.5” to "6.9,” so that moving the control setting from “6.9” to "7” would have the effect of moving abruptly from something close to the curve labeled "6.5” to that labeled "7” (in the manner of a push-button switch).
- FIG. 7 is a simplified functional block diagram showing an arrangement for controlling the gain or loss applied to audio signals in response to a control signal derived from a subjective loudness estimation of the audio signals and a control setting.
- any number of multiple motion picture soundtrack channels may have their loudness modified.
- the figure shows three channels, as an example.
- the gain applied to each of a plurality of motion picture soundtrack channels is controlled, for example, by a multiplier (or multiplier function) or voltage-controlled amplifier (VCA) 102, 104, 106, responding to a control signal from a control signal generator or generator function 108.
- the characteristic response of the control signal is selected by the control setting of a single control 110 in the manner of the FIG. 4 through FIG. 6 examples, discussed above.
- An estimated subjective loudness signal derived by a loudness estimator or loudness estimation function 112 responsive to the motion picture soundtrack channels, or from a data signal associated with the channels, provides the input to the control signal generator or generator function 108 from which the control signal output is generated.
- the control for the gain in each channel is derived from two inputs, the "volume control" setting and the estimated loudness.
- the gain is detennined solely by the control setting. When the signals are very loud, exceeding a threshold that depends on the control setting, the gain is reduced to provide compression, as is explained above.
- the same gain control signal is applied to all soundtrack channels in response to an estimated loudness signal derived from all of the soundtrack channels.
- the gain of less than all soundtrack channels is controlled and/or in which the estimated loudness signal is derived from less than all of the soundtrack channels.
- any changes in relative gains applied to the front channels could result in movement of the apparent position or direction of sound sources (a veiy few dB change can lead to major shifts in position).
- any changes in relative gains might alter the center of gravity of that ambience, so instead of being symmetrical (neither to left nor right), it might acquire a bias to one side.
- it would be an unusual sound that would be falsified by a modest difference in gain between front and surround.
- rapidly recovering compression on a reverberant decay apparently extends the reverberation. If the surround channels were principally carrying reverberation, it would be preferable to apply compression to the front channels only, leaving the reverberant decay from the surrounds uncompressed and hence, unextended.
- FIG. 7 shows the control signal being derived from what may be considered to be the input of a compressor.
- the loudness estimation can be derived from the input (from the soundtrack channels prior to volume adjustment and/or compression) as shown in FIG. 7, or from the output (from the audio soundtracks after volume adjustment and/or compression) or from an acoustic measurement in the listening area.
- the first two alternatives require some combination of the channels to assess their total loudness.
- the listening area does the combination so only one microphone would be necessary.
- the compression and volume adjustment would interact differently if one derived control from after, rather than before, the VCA or multiplier.
- FIG. 8 is a simplified functional block diagram showing the generation of an estimate of loudness in response to multiple channels of audio.
- the figure shows three channels, as an example.
- the horizontal axes in FIGS. 4-6 represent acoustic levels if those signals were reproduced without compression and with the volume control at the standard setting.
- a preferred measure for this memepose is one that correlates with subjective loudness and/or subjective annoyance.
- this requires measurement of a combination of all channels, such as the sum of their energies, a way of ensuring that the frequency-dependence of subjective loudness and/or annoyance is taken into account (by weighting or, alternatively, by employing multiband methods), and a way to take into account that loudness depends on the duration of a sound as well as on its sound pressure level ( . e., suitable time-constants). It is believed that a frequency dependence that places a greater emphasis on low treble (e.g., an approximate range of 2 to 6 kHz) would tend to take annoyance into consideration.
- the electiical signal in each soundtrack channel is frequency weighted by a frequency weighting function or frequency weighting filter 202, 204, 206, such as an A-weighting or a CCIR-weighting as described in the Dolby Model 737 Soundtrack Loudness Meter ⁇ Leq(m) Users Manual and shown here in FIG. 9.
- CCIR weighting is also known as ITU/R weighting.
- Each weighted signal is squared in a squaring function or device 208, 210, 212 to provide an energy measurement of each channel.
- the weighted energy signals are then additively combined in a summation function or device 214.
- a summation of the energies of all the channels over a suitable time period such as few tens or hundreds of milliseconds, delivers a single estimation of loudness waveform that is a function of time.
- soundtracks yield different loudness values when assessed with different frequency weightings.
- the low-frequency roll- off of A-weighting results in a reduction in the loudness estimation level when the material has a substantial bass content. Placing heavier emphasis on the 2 to 6 kHz region may better match how people react to soundtrack loudness.
- the CCIR- weighting curve also known as the ITU/R weighting curve, originally intended to measure low-level recording medium noise may more closely match subjective annoyance criteria than does the A-weighting curve.
- subjective loudness is a function not only of acoustic level and frequency content but also of duration. Complaints from the audience are not just because the movie soundtracks are uncomfortably loud but that discomfort is sustained. If a sound has a very high sound pressure but only lasts for a few or a few tens of milliseconds, it does not give the subjective impression of being very loud. There is a finite rate of build-up of the impression of loudness. Thus, it is preferred to apply smoothing over at least tens of milliseconds, so that a brief high-level signal in the soundtracks does not cause the loudness esthnation level to exceed a threshold and cause compression.
- sustained loudness should generate a control signal that exceeds a threshold and causes compression.
- attack times of a few tens of milliseconds (corresponding roughly to the buildup of subjective loudness) but a recoveiy rather longer, hundreds of milliseconds or seconds, may be suitable.
- a loudness esthnation control signal derived from very short-term measurements (such as waveform peak) is undesirable.
- program responsive time constants may be employed. For example, an isolated loud sound, enough to actuate the compression, may benefit from a fast recovery, so that by the time hearing sensitivity has recovered, gain is back to normal.
- the need to minimize compression artifacts by optimizing time constants may not be particularly important because the high-level compression aspect of the invention operates only on the loudest few dB of the soundtrack range (when the sounds are so loud that some degradation may be acceptable, or at least preferable to the sounds getting louder still) rather than at dialogue loudness levels.
- the control signal generated by an arrangement such as in FIG. 8 is an estimation of loudness because a real loudness measure would require a microphone in the listening area.
- the FIG. 8 arrangement makes electiical measurements at a point in the chain where signal voltage levels have a known relationship to acoustic sound pressure levels when the soundtiacks are reproduced (the relationship is known when the contiol is at its standard setting).
- the estimate of loudness may be provided by metadata associated with the motion picture soundtracks.
- the metadata carries the estimate of subjective loudness, avoiding the need to calculate it within the loudness estimator or loudness esthnation function 112 (FIG. 7).
- the metadata may be encoded into one or more of the soundtracks or carried separately but in association with one or more of the soundtracks.
- association with is meant that the metadata is related to the soundtrack information and is carried by the motion picture along with the soundtracks whether in a traditional context on a motion picture film snip (or on a disc carrying motion picture soundtiacks synchronized to the film) or in a digital cinema context as digital data constituting part of a digital motion picture.
- metadata By employing metadata, the entire motion picture could be analyzed in advance and suitable control signals generated and recorded on the motion picture. If a sound is in fact very loud, but it only lasts a few seconds or represents a very small part of the duration of a motion picture, the audience is unlikely to object. The best way of dealing with such sounds may be to employ metadata to provide the loudness estimation control signal.
- the present invention and its various aspects may be implemented in analog circuitry, or as software functions performed in digital signal processors, programmed general-purpose digital computers, and/or special purpose digital computers, or some combination of such devices and functions. Interfaces between analog and digital signal streams may be perfonned in appropriate hardware and/or as frinctions in software and/or firmware.
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Application Number | Priority Date | Filing Date | Title |
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AT04760365T ATE518302T1 (en) | 2003-04-24 | 2004-04-22 | VOLUME AND COMPRESSION CONTROL IN FILM THEATER |
AU2004234745A AU2004234745B2 (en) | 2003-04-24 | 2004-04-22 | Volume and compression control in movie theaters |
EP04760365A EP1616386B1 (en) | 2003-04-24 | 2004-04-22 | Volume and compression control in movie theaters |
JP2006513271A JP2006524968A (en) | 2003-04-24 | 2004-04-22 | Volume and compression control in cinemas |
CA2520118A CA2520118C (en) | 2003-04-24 | 2004-04-22 | Volume and compression control in movie theaters |
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US10/423,487 | 2003-04-24 | ||
US10/423,487 US7551745B2 (en) | 2003-04-24 | 2003-04-24 | Volume and compression control in movie theaters |
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EP (1) | EP1616386B1 (en) |
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AT (1) | ATE518302T1 (en) |
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Also Published As
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US7551745B2 (en) | 2009-06-23 |
JP2006524968A (en) | 2006-11-02 |
EP1616386B1 (en) | 2011-07-27 |
CN1774861A (en) | 2006-05-17 |
CA2520118A1 (en) | 2004-11-11 |
CN100514853C (en) | 2009-07-15 |
AU2004234745B2 (en) | 2008-10-30 |
CA2520118C (en) | 2013-09-24 |
WO2004098053A3 (en) | 2005-02-10 |
US20040213420A1 (en) | 2004-10-28 |
ATE518302T1 (en) | 2011-08-15 |
EP1616386A2 (en) | 2006-01-18 |
AU2004234745A1 (en) | 2004-11-11 |
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