As WG Group under Organization of JAS(Japan Audio Society)
Mick M.Sawaguchi
Shinji Koyano
Kazuhiko Terui
Satoshi Suzuki
Atsushi Marui
Bike H.Suzuki
Surround sound is normally produced with the loudspeakers
arranged according to the recommendation ITU-R BS.775-2. However, in ordinary
homes, especially in Japan, the produced surround sound is not necessarily enjoyed
with the same loudspeaker arrangement. Investigation and research was performed
to study the tolerance of surround speaker arrangement for listeners at home to
enjoy the surround sound with the quality level as close as possible to what
the original production intended for.
The goal was to develop and propose a practical guideline for surround loudspeaker placement in designing a good home-theater.
1. INTRODUCTION
It
is normally recommended that surround loudspeakers of a home-theater audio system
should be placed according to the ITU-R Recommendation BS.775-2, Multichannel
stereophonic sound system with and without accompanying picture. (Fig.1)The
recommendation is based on the agreement on the results of evaluation tests of
surround loudspeaker placements performed globally in the 1990’s. Most rooms specifically
for surround sound production have the surround loudspeakers placed right
according to the ITU-R recommendation.
If the same loudspeaker placement can be installed at ordinary homes, users would be able to enjoy the sound as it was intended in the production field.
If the same loudspeaker placement can be installed at ordinary homes, users would be able to enjoy the sound as it was intended in the production field.
However,
in Japan rooms at homes are forced to have several restrictions in terms of
room size and shape. Many home-theater owners must be content with a
loudspeaker placement which is very different from the one recommended by ITU.
The
research presented here was performed to clarify the torelance of surround
loudspeaker placement for Acceptable
perception of reproduced sound.
The research consisted of investigation of actual loudspeaker placement at homes, and auditory impression evaluation test, which made comparisons of the auditory impression between the ITU-R Recommendation and actual domestic placements.
2. SURVEYS ON LOUDSPEAKER PLACEMENT IN HOME-THEATERS
The research consisted of investigation of actual loudspeaker placement at homes, and auditory impression evaluation test, which made comparisons of the auditory impression between the ITU-R Recommendation and actual domestic placements.
2. SURVEYS ON LOUDSPEAKER PLACEMENT IN HOME-THEATERS
2.1 Gathering and Analysis of Samples of Loudspeaker
Placement
Home
theater installers and individual home-theater owners offered a total of 82
samples of data on loudspeaker placement in home theaters. The samples of data
included:
1.
Locations of surround loudspeakers on a plane: distance from the listening
position in meters, relative position to the listening position, and position
of display or screen.
2.
Height of each loudspeaker (from floor to the physical center of the
loudspeaker)
3.
Sketch drawings or pictures of loudspeaker placement
From
the data above the following parameters were calculated:
1.
The plane-projected distance and the real distance from the listening position
at a height of 1.2m, for each loudspeaker except for a subwoofer.
2.
Plane-projected angles between loudspeakers:
Left Ch. (L) to Center Ch. (C)
Right Ch. (R) to Center Ch. (C)
Left Surround Ch. (LS) to Center Ch. (C)
Right Surround Ch. (RS) to Center Ch. (C)
3.
Slant angle (upward or downward) from the listening position, for each
loudspeaker.
2.2 Typical Loudspeaker
Placement Patterns Extracted
Of
82 samples, 69 samples which deal with 5 surround loudspeakers were subjected
to cluster analysis with three parameters: (1) plane-projected distance of each
loudspeaker, (2) plane-projected angles between loudspeakers, and (3) slant angles
(upward or downward) from the listening position.
As
a result, the 69 samples of loudspeaker placement were grouped into the following
five patterns:
Pattern 1:
All loudspeakers are positioned higher than the listening position.
Pattern
2: Only rear loudspeakers are
positioned higher than the listening position.
Pattern 3:
Front loudspeakers are narrower angled, rear wider angled.
Pattern 4: Similar to the placement by ITU-R
recommendation
Pattern 5: Rear
loudspeakers are positioned right at the sides of the listener
Fig.2 Five Typical Patterns of Loudspeaker Placement
3. Perceptual
Audio Evaluation Test
3.1 Selection of loudspeaker
placement patterns for evaluation test
 |
| Sample recording room under IEC Spec |
Two more patterns were added to the
five (5) patterns for the auditory impression evaluation test. The additional
two patterns allow for the growing trend in Japan to place loudspeakers in the
ceiling of home theaters.
The seven (7) patterns are:
Pattern 1: Rear
loudspeakers are angled excessively wide from the listening position
Pattern 2: Rear loudspeakers are
positioned higher than the listening point. It is assumed that many home
theaters have rear loudspeakers installed on the walls.
Pattern 3: The front center loudspeaker is positioned lower
than Left, Right loudspeakers and the listening point. The pattern corresponds
to a case where front center loudspeaker is positioned below a large screen.
Pattern 4: Rear loudspeakers are
positioned right at the sides of the listener, and the listening point is very
close to the rear wall.
Pattern 5: The three front loudspeakers are positioned lower
than the listening point. The pattern accounts for home theater products called
“Theater Rack.”
Pattern6: Assumed is a case where the rear
loudspeakers are installed in the ceiling
Pattern 7: Assumed is a case where all
the loudspeakers are installed in the ceiling.
Fig.3 Loudspeaker Placement Patterns
 |
| Evaluation test sample recording with 7 deferent SP patterns by Dummy Head |
3.2 Evaluation Attributes and Sound Samples
From the viewpoint of evaluating expressly and clearly
fields of surround sound, three (3) evaluation attributes were selected: (1) Listener
Envelopment (Sensation of being embraced by sounds), (2) Sound Image Localization,
and (3) Sensation of movement.
For each evaluation attribute, the following three sound
samples were prepared:
(1) Sounds recorded in a natural outdoor environment (for Listener
Environment)
Early in the morning, in a wood. Birds are singing all around over 360
degrees.
(2) Instrumental Music (for Sound Image Localization)
Main Vocal in the center. Instruments positioned all over around 360
degrees.
(3) Sound Effect
(for Sensation of movement)
A single sound source rotates around the listener in increasing speeds
on a horizontal plain.
Editing was made so that the duration
of each sound sample is one minute.
3.3 Preparation of sound samples for evaluation
It is impractical to set up all the seven
loudspeaker placement patterns for each evaluation because of the time and
labor encountered: subjects must wait for a certain time before a new pattern
of loudspeaker placement is set up, and tend to forget the impression of the
sound presented in the preceding pattern.
In order to reduce the load on subjects
and implement higher evaluation precision by presenting sound samples freely
and instantly, the evaluation test was designed to use a method of presenting the
sound samples, which are recorded by a dummy head. In preparation for this,
binaural recordings of the sound samples described in 3.2 were made in a
reference listening room, which is in conformity with the ITU-R BS.1161-1, through
a dummy head to produce sound samples for the evaluation test.
3.4 Evaluation Method
Subjects of the evaluation were 25 adults in their twenties
to fifties who are audio specialists with aurally normal ears. The 5-point rating
scale method was used in the evaluation test: Subjects evaluate each sound
sample for (1) listener environment (sensation of being embraced by sounds),
(2) sound image localization, and (3) sensation of movement, by marking a level
in five levels with “3” as the level which means that the evaluated quality of
a sound sample is equal to that of the reference sound sample. Since the
ratings were made in comparison to the reference stimulus, which is set to 3.0
on the rating scales, an average rating beyond 3.0 for a given stimulus shows
that the stimulus has higher sense of envelopment, localization, or movement
than the reference. However, in
order to state that the difference between the stimulus and the reference is
significant, statistical tests such as analysis of variance and t-test are
often used. In our study, a “rule of thumb” [9] was employed to simplify the
statistical inference. Namely, in
comparing average ratings of two stimuli, the two averages are statistically
significantly different (at alpha=. 05 level) if the average value of a
stimulus is not within the 95% confidence interval about the average value of
another stimulus. Also, a stimulus is perceived significantly different from
the reference on a given rating scale if the 95% confidence interval about the
average rating of the stimulus does not include 3.0 in between the edges.
3.5 Sound
Sample Presentation
Subjects were, for preliminary audition, presented with a15-second
duration each of the reference sound sample and seven sound samples of Pattern
1 to Pattern 7 with 5-second intervals in between. Then during the actual
evaluation test, subjects listened to the reference sound sample, which was
recorded in compliance with the ITU-R loudspeaker placement, and subsequently to
randomly present 30-sec durations of 7 patterns of sound samples with 5-sec
intervals in between. To check for a correct evaluation, subjects were able to
listen to each presentation as many times as they wanted.
3.6
Results
The result of evaluation by 25 subjects
of 7 loudspeaker placement patterns is shown in Fig.4.
3.7 Discussion
Following are the review of results of
the evaluation listening test for the seven (7) -loudspeaker placements
patterns:
Pattern 1:
Evaluation score for Listener Envelopment (Sensation of
being embraced by sounds) is as low as 2.0. This is ascribed to the weaker sound
link between the front and rear loudspeakers, which are at too great a distance
from one another.
Pattern 2:
The result shows that rear loudspeakers can be installed
higher than the listening point without inferior aural impressions. Greater
heights of rear loudspeakers do not lead to lower evaluation scores. The
allowable height and vertical angle slant for rear loudspeakers, as proposed by
the production side, should be within 30% of the reference height and within
15degrees of the horizontal position, respectively.
Pattern 3:
For the three evaluation attributes, good evaluation scores are
obtained.
Pattern 4:
Lower evaluation score is observed for sound image localization,
and sensation of movement. This can be ascribed to the rear sound field, which
is rather narrow and small compared with the reference sound field.
Pattern 5:
Lower evaluation score is marked for sound image localization.
This is due to the stronger reflections from the floor.
Pattern 6:
Evaluation is low for sensation of movement. It is estimated
that sense of smooth movement is difficult to
achieve because sound images move at a slanted angle.
Pattern 7:
Evaluation score is low for sound image localization. This
could be ascribed to the greater deviation of loudspeaker directivity axis from
the listening position.
For Patterns 5, 6, and 7, loudspeaker directivity axis orientation
must also be taken into consideration.
3.8
Supplementary Experiments
As described in the above, with Patterns 5 and 7, the
influence of the deviation of loudspeaker directivity axis orientation is not
negligible on the perceived sound at the listening position. To study in detail
the influence of deviated directivity axis, supplementary experiments were made
for Patterns 5 and 7, with the directivity axis orientation varied. Evaluation
was made on five (5) loudspeaker placement patterns shown in Table 2.
Patterns 1, 2, 3
All loudspeakers are placed as high as the ceiling. This
placement corresponds to a case in a home-theater where all loudspeakers are
mounted recessed in the ceiling.
Patterns 4, 5
Front loudspeakers are positioned closer to the floor, with rear
loudspeakers closer to the ceiling. This placement allows for a case where a “rack
theater” system is used.
The distance of each loudspeaker from the listening position
is 2000 mm.
The angle between the center and front L or R loudspeakers
is 30°, between
the center and rear L or R loudspeaker 120°. The reference placement
was in accordance with the ITU-R recommendation.
Pattern
|
Height
F/C/R (mm)
|
TiltAngle
F/C/R(°)
|
1
|
2300/2300/2300
|
25/25/25
|
2
|
2365/2365/2365
|
0/0/0
|
3
|
2220/2200/2245
|
90/90/90
|
4
|
460/460/2245
|
0/0/90
|
5
|
530/530/2245
|
12/12/90
|
Table 2.
Supplemental Loudspeaker Placement Patterns
3.9
Results of Supplemental Listening Tests
Results of supplemental listening tests are shown in Fig. 5.
 |
Fig.5 Results of Supplemental Listening Tests
Patterns
1,2, and 3
With front and rear loudspeakers placed in the same setting
in terms of height, angle of separation, and directivity orientation, the aural
impression is not greatly different from that obtained with the reference ITU-R
placement. With Pattern 1, where directivity axis orientation is right toward
the listening position, the aural impression comes closer to that of the
reference ITU-R placement. With the directivity axis oriented right toward the
floor of the room, the evaluation scale is slightly lower than 3.0, but with
small variation in evaluation for the three evaluation attributes, suggesting evaluation
is little relevant to what contents is reproduced.
Patterns
4 and 5
Patterns 4 and 5 correspond to the cases where rear
loudspeakers are installed in the ceiling, with the directivity axis oriented
right down to the floor. Front loudspeakers were placed, with tilt angle at 0 (Pattern
4) and 12 degrees (Pattern 5). As seen in Fig.5, the tilted placement of
Pattern 5 gives better evaluation than Pattern 4 in terms of “Listener
Envelopment (Sensation of being embraced by sounds)” and “Sound Image Localization.”
4. Conclusions
1. Cluster analysis of samples of surround loudspeaker
placement in home theaters resulted in deriving five typical placement patterns.
2. Since more and more home theaters are expected to have
surround loudspeakers installed in the ceiling, two placement patterns were
added to the five patterns for evaluation test.
Listening evaluation was made of seven loudspeaker placement
patterns against the ITU-R recommendation placement pattern for (1) Listener
Envelopment (Sensation of being embraced by sounds), (2) Sound Image Localization,
and (3) Sensation of movement.
The results are:
(1) Too wide angles between rear loudspeakers produce
inferior Listener Envelopment (Sensation of being embraced by sounds.)
(2) With only rear loudspeakers installed in the ceiling,
evaluation is lower for Sensation of movement.
(3) With all the loudspeakers installed in the ceiling,
evaluation is lower for Sound Image Localization.
(4) With rear loudspeakers installed higher than front
loudspeakers , or the center loudspeaker installed lower than front L and R
loudspeakers、the evaluation score is comparable to that with the
reference (ITU-R recommendation) placement pattern.
The results of supplemental experiments support the
estimation obtained from the preliminary experiments.
The results of the listening experiments have led to the proposal
of the following guidelines for surround loudspeaker placement in home
theaters.
1. Angle
between Rear Loudspeakers L, and R
A recommended angle is between 100 degrees and 135 degrees.
The angle allows a good surround field without listener envelopment and sound
image localization lost.
(ITU-R recommends 110±10
degrees.)
2. Height of Front Center Loudspeaker
If the three front loudspeakers cannot be placed at the same
height, the center loudspeaker is allowed to be placed lower than L and R
loudspeakers. The vertical slant angle from L and R should be within 20
degrees. The ITU-R recommends the placement at the same height as the listening
position.
3. Slant
Angles of Loudspeakers Installed in Wall
For loudspeakers installed higher in the walls, the upward
slant angle should be within 20 degrees. The ITU-R recommends a degree within
15 degrees.
4. Distance
of Rear Loudspeakers from Listening Position Relative to Front Loudspeakers.
The distance of rear loudspeakers from the listening
position should be ±10% of the distance of front loudspeakers. (The ITU-R recommends the equal
distance from the listening position for each loudspeaker.)
5. Sound
Field Compensation Tool Utilization
Proper use of automatic sound field compensation features
built in AV amplifiers combined with good loudspeaker placement allow general
users to enjoy the surround sounds as originally intended at production.
ACKNOWLEDGEMENTS
A working group in the Digital Home-theater Committee of the
Japan Audio Society carried out the research and investigation by the listening
tests. It has been worked from 2010-2013.
Deep gratitude goes to those who provided the loudspeaker placement information, offered the experiment equipment and facilities, and participated in the experiments as subjects.
REFERENCES
[1] Rec. ITU-R BS.775-2, Multichannel stereophonic sound
system with and without accompanying picture, ITU, 2006
[2] M. Sawaguchi et al, Surround Sound Handbook, Tokyo
Geidai Press, 2010
[3] M. Sawaguchi, Current Topics on Surround Sound,
Pioneer Corporation R&D No18, 2008
[4] A.Fukada, Surround Sound viewed from the perspective of
playback environment, InterBEE Forum, 2006
[5] Recommendations For Surround Sound Production, NARAS,
2004
[6] S.Yoshikawa et al, Proposal for the Specification of
Control Rooms for HDTV Multichannel Sound Program Production, 100th AESConvention,
1996
[7] H. Suzuki et al, Study on Optimum Rear Loudspeaker
Height for 3-1 Reproduction HDTV Audio, 95th AES Convention, 1993
[8]Olive Sean et al., Interaction between Loudspeakers and Room
Acoustics Influences Loud Speakers
Preferences in Multichannel Audio Reproduction, 123rd AES
Convention, 2007
[9]Geoff Cumming and Sue Finch. "Inference by Eye:
Confidence Intervals and How to Read Pictures of Data" American
Psychologist. 2005.
BIO of WG Member
Currently, He is funder of Hi-Res Music Label UNAMAS to product Hi-Res surround/stereo music. http://unamas-label.net/.
Mick (Masaki) Sawaguchi graduated in 1971 in electronics from the Chiba Institute of Technology and joined the Broadcasting Engineering Department of NHK (Japan Broadcasting Corporation) as an engineer. By the 80’s, he was already a highly respected figure, both within NHK and in the audio engineering industry. He was an officer of the AES Japan section until 2010. Currently, he is president of Mick Sound Lab, which is a HD surround sound production. Also, he has a surround sound design class at TOKYO UNIVERCITY of the Arts and Nagoya University of the Arts. He has had many books on surround sound production published in Japan, China and Korea. He has contributed to many AES Conferences by presenting several technical papers on surround sound mixing and microphone techniques since 1991. He is a Vice-Chairman of the AES Studio Practices and Production Committee. In 2002 he was awarded an AES Fellowship Award for his outstanding contributions to the fields of surround sound recording and mixing for broadcasting. Other awards he has been honored to receive include: ABU Best Paper at 2004 as surround broadcasting program production, a Surround Master Award by JAS, 2005, an AES JAPAN Award for his Contribution of Surround Terakoya activity, 2009, a JAS Award for a study of evaluation of home theater surround, 2012. He has chaired or participated as panelist in several workshops or sessions at AES Conventions/Conferences, SMPTE Conferences, IBS/IBC Conferences, and INTERBEE. He has also delivered lectures on surround sound recording in countries all over the world.
Shinji Koyano graduate from Electronics Engineering
Department of Tokyo Denki University in 1975, and joined Pioneer Corporation. At
the Loudspeaker Engineering Department of the corporation he designed and
developed loudspeaker systems. In 1993 he got engaged in research on
loudspeaker system and audio signal processing as manager of Acoustic Research
Section of the Corporate Research and Development Department. Since 2005, he
has been engaged in activities related to education and promotion of audio
engineering, in and out of Pioneer. He is a member of Acoustic Transducer
Standards Group, JEITA (Japan Electronics and Information Technology Industries
Association), the head of the Surround Sound Working Group, JAS (Japan Audio
Society), the secretary of 1-bit Audio Consortium.
His contribution in activity to AES includes: the Paper
Chair in the 11th AES Tokyo Convention, 2003, the Paper Chair in the AES Japan
Conference, 2006, the Convention Chair of the 13th AES Tokyo Convention, and
the Chair of the AES Japan Section from 2007 to 2008. He was awarded a Board of
Governors Award in 2009 for his successful presiding over 13th AES Tokyo Convention. He is also a member of ASJ (Acoustical Society
of Japan).
Masami “Sam” Toyoshima graduated from Waseda University in
1964 with a Master Degree of Engineering. On graduation, he joined JVC’s Audio
Lab. At JVC in 1977 he started designing recording studios, along with his
colleague Hiroaki “Bike” Suzuki. In addition to JVC’s Studio, he designed major
studios throughout Japan including Warner Music, Onkio Haus, Roland, On Air,
West Side, etc. Meanwhile, in UK in 1985, he established Acoustics Design Group
with an architect, John Flynn, Bike Suzuki and a producer/engineer, Hugh
Padgham. He designed major studios in London, including
Abbey Road, Town House, Olympic, Metropolis, Sarm West, and so on. He has done
more than 250 music-recording facilities worldwide. From 2001 he has been
teaching acoustics, as Professor at Yokkaichi University. He received an AES
Fellowship Award in 2011 in London. He is a member of the AES, Acoustic Society
of Japan, Institute of Electronics, Information and Communication Engineers,
The Virtual Reality Society of Japan, and is an advisor to the Japan APRS. He
presented some technical papers at the past AES Conventions and Conferences.
Kazuhiko Terui joined Sony Corporation in 1978. He was
engaged in designing AVsurround amplifiers and tuners at the Audio Component
Design Division. In 1990, he was transferred temporarily to CBS Sony
Corporation to have some experience in the field of music production through
working in the Japanese music division. After getting back to Sony, he worked
in the Product Promotion Division, Overseas Sales Division, then was deeply
involved in the strategy of promoting SACD, and worked aggressively to enrich
the list of SACD titles. Currently he is the Chairman of the Audio Network
Business Committee, JEITA (Japan Electronics and Information Technology
Industries Association).
Bike Hiroaki Suzuki graduated from Tohoku University with a
bachelor degree in electrical engineering in 1970, and joined JVC to get
involved in the field of architectural acoustic design. Design projects he
worked on with his boss, Sam Toyoshima, includes Townhouse Studio, Abbey Road
Studios, and Metropolis Studios which are all located in London. In 1997 he was
appointed as Chairman of WG-4 of DVD Forum, which was responsible for producing
the new audio format, DVD-Audio Specifications. In 2001 he was awarded an AES
Fellowship Award in recognition of continued contribution to acoustics and
studio design as well as his leading role in the development of DVD-Audio.
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