US3614320A

US3614320A - Stereophonic sound enhancement system with reverberation chamber

Info

Publication number: US3614320A
Application number: US783618A
Authority: US
Inventors: John E Volkmann
Original assignee: RCA Corp
Current assignee: RCA Licensing Corp
Priority date: 1968-12-13
Filing date: 1968-12-13
Publication date: 1971-10-19
Anticipated expiration: 1988-10-19

Abstract

The reverberation characteristics of an auditorium or music hall are improved by picking up the sound originating in the auditorium with microphones, and reproducing the sound in a second room having a more optimal reverberation characteristic. A second set of microphones in the second room picks up the sound and its reverberations for transmission to a group of loudspeakers in the auditorium, where it is blended with the original sound.

Description

limited [72] Inventor John E. Volhmann Princeton, NJ.

[21] Appl.No. 783,618 [22] Filed Dec. 13, 1960 [45] Patented Oct. 19, 1971 [73] Assignee RCA Corporation [54] STEEEOPHONIIC SOUND ENHANCEMENT SYSTEM WITH REVEIRBERATIION CHAMBER 6 Claims, 2 Drawing Figs.

[52] IU.S.CI 179/1J [51] int. Cl llll04r 5/02 [50] Field of Search 179/1.6,

[56] References Cited UNITED STATES PATENTS 1,853,286 4/1932 Round et a1. 179/1 (.6) 2,421,424 6/1947 Kreuzer 179/1 (.6)

[ 1 3,0lldfi20 2,017,153 10/1935 Kellogg 179/100.1

2,107,804 2/1938 Roux et al.... 179/L6 3,024,309 3/1962 Kleis 179/1.6 OTHER REFERENCES Stereophonic Localization: An Analysis of Listener Reactions to Current Techniques; Eargle, John M.; lRE Transactions on Audio; September- October, 1960; pp. 174- 177.

Primary Examiner-Kathleen H. Claffy Assistant Examiner-Randall P. Myers Attorney-Eugene M. Whitacre a! Mama/ M/www STERIEUIPIHIQNIC SOUND ENHANCEMENT SYSTEM Wll'llill REVERBIERATION CHAMBER SOUND ENHANCEMENT This invention relates to sound reproducing systems and more particularly to a system to provide for the enchancement of the reverberation characteristics of a music hall or auditori- A problem common to many music halls and auditoriums is that the reverberation time of the hall auditorium may be too short. Reverberation time is defined as the time it takes for a given sound intensity to decrease a fixed amount. A hall with too short a reverberation time has been referred to as a dry hall and such a hall does not provide the appropriate acoustical characteristics for optimum presentation and recording of music. Various methods and systems to solve this problem have been attempted.

One system known in the prior art consists of transmitting sound from an auditorium to an acoustical chamber of small dimensions relative to the auditorium and then transmitting the reverberated sound from the acoustical chamber back to the auditorium. Such a system is disclosed in boux et al., US. Pat. No. 2,107,804. The disadvantages of this system are that it provides the listener with a feeling that the sound is artificially reverberated or altered instead of naturally reverberated. This may be caused by the reverberated sound lacking spatial distribution and directional illusion, or by the reverberated sound having an effective mean free path which is considerably different than the natural mean free path of the music hall. Mean free path is defined as the average distance sound travels between successive reflections in a chamber.

An object of this invention is to provide an improved system for presenting or recording a sound program, such as music, in

'an auditorium with a given reverberation characteristic in a manner such that the auditorium appears to have enhanced reverberation characteristics.

A further object of this invention is to enhance the reverberation characteristics of a hall or chamber without significantly changing other acoustical characteristics of the hall or chamber.

In accordance with the invention, the natural reverberation characteristics of a secondary chamber is superimposed on the reverberation characteristics of a primary chamber in such a manner that the reverberation characteristics of both chambers are naturally integrated or blended together in the primary chamber with respect to time sequencing, spatial distribution, direction illusion, and amplitude levels, and without amplifying the direct orchestral sounds or detrimentally altering the inherent good acoustics (clarity, definition, blending, socalled presence, intimacy, etc.) of the early sound reflections in the primary chamber. The dimensions of the secondary chamber are such that the effective mean free path of the reverberated sound is of the order of that of the primary chamber.

Various other objects and advantages will appear from the following description of the several embodiments of the invention, and the novel features will be particularly pointed out hereinafter in connection with the appended claims.

The drawings diagrammatically represent different examples of means for carrying out the invention.

FIG. l is a schematic diagram of a system for recording sound in an auditorium with enhanced reverberations; and

FIG. 2 is a schematic diagram of another embodiment of a system for recording sound in an auditorium with enhanced reverberations.

Referring now to the drawings and in particular to FIG. 1, the music hall or primary chamber which has a reverberation time characteristic that is not regarded as sufficiently long for the presentation or recording of music comprises a stage portion 12 and an audience portion M. At least two pick-up devices or microphones 16, 18 are located in the area of the audience portion 114 adjacent the stage portion 12 in a position to pick up the direct sound wave fronts of the music presentation from the stage portion 112.

It will be understood that the

microphones

116, 118 could also be located on the stage portion 112, the exact location of the microphone being dependent on the location of the sound source (orchestra). A pair of microphones I6, 18 are connected to the respective input terminals 20), 22 of a pair of

amplifiers

24, 26 which may be located in the music hall 110 or exterior thereof. The output signals from the amplifiers 2d, 26 are then respectively coupled to a pair of

loudspeakers

28, 30 located in a secondary chamber or room 32 which is separate from the primary chamber 110. The loudspeakers 2b, 30 are distributed in the secondary chamber 32 so as to reproduce stereophonically therein the sound wave fronts as they are picked up in the primary stage 110. This is accomplished by distributing loudspeakers 2b, 30 in the secondary chamber 32 in a similar or corresponding spatial relationship to the positioning of microphones I6 and 28 in the primary chamber 110. The secondary chamber 32 has a reverberation time characteristic which is preferably longer than that of the primary chamber, and is of a time duration considered desirable for superposition in the primary chamber 10 during the presentation of sound therein as will be hereinafter described. The effective mean free path of the reverberated sound in the secondary chamber 32 is of the same order as that of the primary chamber lltl. In other words, the average distance that a sound wave travels between reflections in the secondary chamber, with or without supplementary acoustic delay, is of the same order of magnitude as that in the primary chamber. This aids in effecting a spatial distribution and directional illustration in the reverberated sound waves produced in the secondary chamber 32. The total sound produced in the secondary chamber 32, which comprises the original sound introduced therein along with its increased reverberation, are picked up by a plurality of microphones 3 1, 36, 38, M], 42, and M positioned within the secondary chamber 32 in an arcuate array as shown in FIG. I. The outputs from each of the microphones 3 are coupled via respective amplifiers to, W, St), 52, 5d, 56 to respective loudspeakers 5d, 60, '52, 64, 66 and 68, said loudspeakers being located in the primary chamber lit] and within the audience portion M of the primary chamber 10 so as to reproduce therein the reverberation sound wave fronts as they are picked up in the secondary chamber 32.

In operation of the system, the microphones l6 and lb pick up primarily the direct sound wave fronts from the stage area B2. The spacing of the microphones l6 and lb permits the sound to be transduced in stereophonic relation so that similar sound wave fronts can be recreated in the secondary chamber 32 by loudspeakers 23 and 30. The direct and reverberated sound picked up by the microphones .3 in the secondary chamber 32 is amplified and reproduced by their associated loudspeakers in the primary chamber 10 at a level such that the sound appears to come from the stage area 112, and the reverberated sound from the secondary chamber 32 is smoothly blended with the natural reverberant sound in the primary chamber lit).

For recording purposes, additional microphones 70, I2, 74$, 76, 78 and 80 may be located on the stage l2 and audience M portions of the primary chamber lit). These microphones may be connected to respective input terminals of a suitable recording apparatus indicated by the block at $2. Recording apparatus 82 may comprise means for transcribing the sound audible in the primary chamber 20 and picked up by the microphones 70-30 on to recording tape or phonograph records for commercial purposes.

The amplifiers shown in the drawing may include equalizers, filters and acoustic delay means. Equalizers may be pro vided to selectively vary the phase and/or amplitude of the signals processed therethrough. Filters may be used to filter out or attenuate certain frequencies as desired. Acoustic delay means which may be electronic, mechanical, or acoustical may be employed to add additional time to delay to the system.

The secondary chamber may be any size or shape so long as the effective mean free path, with or without supplementary acoustic delay of the reverberated sound is comparable to or of the same order of magnitude as that of the primary chamber. Also, two or more secondary chambers may be connected in series in order to further modify the reverberation characteristics of the primary chamber.

Referring now to the embodiment of FIG. 2, the system shown therein was used to increase the reverberation time of the auditorium in the Academy of Music in Philadelphia, Pa. This auditorium, when used for recording, was though to have a dry sound and had a reverberation time of about 1.4 seconds. With the system shown in FIG. 2, the reverberation time of the auditorium was increased to about 2.2 seconds. Specifically, with reference to FIG. 2, four

microphones

90, 92, 94 and 96 were arranged on stage 99 of the Academy auditorium 100, in a position to pick up the direct sound wave fronts of the music presentation from the stage. Sound picked up by the

microphones

90, 92, 94 and 96 was respectively coupled to amplifiers 102, 104, 106 and 108. The outputs from amplifiers 102 and 104 were combined and fed to a first loudspeaker 110, and the outputs from amplifiers 106 and 108 combined and fed to a second loudspeaker 112, both of said loudspeakers being located in the main ballroom of the Academy which was used as the secondary chamber 114. Four

microphones

116, 118, 120 and 122 located in the secondary chamber 114 were respectively coupled to

amplifiers

124, 126, 128 and 130, the outputs of which were combined as shown in FIGURE to provide four signals for driving respective loudspeakers 132, 134, 136 and 138 in the audience portion 98 of the Academy auditorium 100. For recording purposes, four

microphones

140, 142, 144 and 146, located on the stage portion 99 of the auditorium, were coupled to a recording apparatus 148. It was found that the size and acoustical characteristics of the ballroom, along with the arrangement of the loudspeakers and microphones in the auditorium, and the ballroom, were such as to produce a realistic reproduction in the auditorium with an enhanced reverberation effect. The blending or integration of the sound originating in the auditorium with its reverberations in the ballroom was accomplished without affecting the time sequence, spatial distribution, and directional illustration of the music. The enchancement process was carried out without increasing the effective loudness of the direct orchestral sound and without altering the inherent good acoustical characteristics of the auditorium. The sound was transmitted from the auditorium to the ballroom and back again to be blended with the original sound so as to reinforce and enhance the sound as it was heard and recorded throughout the auditorium.

In addition to the embodiments shown, a variation of the present invention may comprise the use of plurality of secondary chambers along with means for selecting which secondary chambers are to be used to enhance the sound in the primary chamber. The reverberation characteristics of the total sound originating in the primary chamber may be varied by selecting a different secondary chamber into which this sound is to be fed. The microphones in the primary chamber may be so arranged with the selecting means so that the various sound transduced by the individual microphones may be fed to different secondary chambers. The sounds reverberated in the secondary chambers may be selectively fed to various loudspeakers arranged in the primary chamber. This embodiment will allow the reverberation of a particular sound in the primary to be altered without changing the reverberation of the other sounds.

What is claimed is:

l. A sound enchancement system comprising:

a primary chamber,

a secondary chamber having selected physical dimensions such that the mean free path of sound in said secondary chamber is of the same order of magnitude as the mean free path of sound in said primary chamber,

means for transmitting electrical signals representative of chamber and converting said electrical signals into sound,

said means for transmitting electrical signals representative of sound in said primary chamber to said second chamber comprising a plurality of stereophonically related channels, and

means for transmitting electrical signals representative of the sound along with its reverberations from said secondary chamber to said primary chamber and converting said electrical signals into sound, said means for transmitting electrical signals representative of said sound along with its reverberations from said secondary chamber to said primary chamber comprising a plurality of stereophonically related channels, thereby to enhance the acoustical characteristics of said primary chamber.

2. A sound enchancement system as defined in claim 1 wherein,

said secondary chamber has a reverberation time which is longer than the reverberation time of said primary chamber.

3. A sound enchancement system as defined in claim 1 wherein,

said means for transmitting electrical signals representative of said sound in said primary chamber to said secondary chamber further includes pickup means in said primary chamber located near to where the sound originates from so as to pick up a direct sound wave front.

4. A sound enchancement system comprising:

a primary chamber;

a secondary chamber, having a reverberation time longer than the reverberation time of said primary chamber and having selected physical dimensions such that the mean free path of sound in said secondary chamber is of the same order of magnitude as the means free path of sound in said primary chamber;

first means for transmitting electrical signals representative of sound is said primary chamber to said secondary chamber comprising a plurality of stereophonically related channels and including pickup means, located in said primary chamber near to where the sound originates, for picking up a direct sound wave front, said first means further including reproducing means, located near wall in said secondary chamber corresponding in spatial array to the positioning of said pickup means in said primary chamber, for reproducing said sound-wave front of said primary chamber in said secondary chamber; and

second means for transmitting electrical signals representa tive of the sound along with its reverberations from said secondary chamber to said primary chamber and converting said electrical signals into sound, thereby to enhance the acoustical characteristics of said primary chamber, said second means comprising a plurality of stereophonically related channels.

5. A sound enchancement system as defined in claim 4 wherein,

said means for transmitting electrical signals representative of said sound along with its reverberations from said secondary to said primary chamber further includes in said secondary chamber, pickup means located near walls other than from where said sound wave front is originally introduced therein.

6. A sound enhancement system as defined in claim 5 wherein,

said means for transmitting electrical signals representative of said sound along with its reverberations from said secondary to said primary chamber further includes in said primary chamber reproducing means located near walls other than from where said sound wave front originates.

UNITED STATES PATENT OFFICE CERTlFlCATE ()F CORRECTION Patent 3,614,320 Dated October 19, 1971 Inventor(s) John Volkmann It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:

In Column 1, line 1.0, following "hall" insert or line 23, delete "boux" and insert Roux Column 2, line 17, delete "28" and insert 18 line 29, delete "illustration" and insert illusion line 62, delete "20" and insert 10 line 71, that portion reading "time to delay should read time delay Column 3, line B, delete "though" and insert thought line 26, that portion reading "in FIGURE" should read in the FIGURE line delete "illustration" and insert mm illusion Column 4, line 34, delete "means" and insert mean """u Signed and sealed this 11th day of April 1972.

(SEAL) Attestr EDWARD I LFLETCHEQ, JR. ROBERT GOTI'SCHALK Attesting Officer Commissioner of Patents RM poqoso H0459) usgoMM-oc sows-pe U 5 GOVERNMENT PRINYING OFFICE I969 0-366-334

Claims

1. A sound enchancement system comprising: a primary chamber, a secondary chamber having selected physical dimensions such that the mean free path of sound in said secondary chamber is of the same order of magnitude as the mean free path of sound in said primary chamber, means for transmitting electrical signals representative of sound in said primary chamber to said secondary chamber and converting said electrical signals into sound, said means for transmitting electrical signals representative of sound in said primary chamber to said second chamber comprising a plurality of stereophonically related channels, and means for transmitting electrical signals representative of the sound along with its reverberations from said secondary chamber to said primary chamber and converting said electrical signals into sound, said means for transmitting electrical signals representative of said sound along with its reverberations from said secondary chamber to said primary chamber comprising a plurality of stereophonically related channels, thereby to enhance the acoustical characteristics of said primary chamber.

2. A sound enchancement system as defined in claim 1 wherein, said secondary chamber has a reverberation time which is longer than the reverberation time of said primary chamber.

3. A sound enchancement system as defined in claim 1 wherein, said means for transmitting electrical signals representative of said sound in said primary chamber to said secondary chamber further includes pickup means in said primary chamber located near to where the sound originates from so as to pick up a direct sound wave front.

4. A sound enchancement system comprising: a primary chamber; a secondary chamber, having a reverberation time longer than the reverberation time of said primary chamber and having selected physical dimensions such that the mean free path of sound in said secondary chamber is of the same order of magnitude as the means free path of sound in said primary chamber; first means for transmitting electrical signals representative of sound is said primary chamber to said secondary chamber comprising a plurality of stereophonically related channels and including pickup means, located in said primary chamber near to where the sound originates, for picking up a direct sound wave front, said first means further including reproducing means, located near wall in said secondary chamber corresponding in spatial array to the positioning of said pickup means in said primary chamber, for reproducing said sound-wave front of said primary chamber in said secondary chamber; and second means for transmitting electrical signals representative of the sound along with its reverberations from said secondary chamber to said primary chamber and convertIng said electrical signals into sound, thereby to enhance the acoustical characteristics of said primary chamber, said second means comprising a plurality of stereophonically related channels.

5. A sound enchancement system as defined in claim 4 wherein, said means for transmitting electrical signals representative of said sound along with its reverberations from said secondary to said primary chamber further includes in said secondary chamber, pickup means located near walls other than from where said sound wave front is originally introduced therein.

6. A sound enhancement system as defined in claim 5 wherein, said means for transmitting electrical signals representative of said sound along with its reverberations from said secondary to said primary chamber further includes in said primary chamber reproducing means located near walls other than from where said sound wave front originates.