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1. |
Calculation of the Loudness of Complex Noise |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 807-832
S. S. Stevens,
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摘要:
Charts and formulas are presented for the calculation of the loudness of noises having approximately continuous spectra. By means of direct loudness matches it is shown that the loudnesses in octave bands can be combined according to the formulaSt = Sm+0.3(ΣS − Sm), whereStis the loudness (in sones) of the total noise,Smis the loudness of the loudest band, and ΣSis the sum of the loudnesses of all the bands. The loudnesses of the octave bands can be determined from measurements of their sound pressure levels by means of a chart based upon a new determination of the equal loudness contours for bands of noise. Other charts and formulas are presented for half‐ and third‐octave band widths.Measurements were also made of the dependence of loudness on such factors as (a) separation between noncontiguous bands, (b) width of very narrow bands, and (c) rate and level of square wave modulation.
ISSN:0001-4966
DOI:10.1121/1.1908487
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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2. |
Criteria for Office Quieting Based on Questionnaire Rating Studies |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 833-852
Leo L. Beranek,
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摘要:
In order to discover what are the maximum noise levels that office personnel find acceptable and what their reactions are to noisy offices, a survey was carried out at a large air base. A questionnaire composed of 15 rating scales was administered to 190 people scattered over 17 different locations on the base. The rating scales allowed the workers to assess such things as the “noisiness” of their environment and to appraise the effect of noise on various aspects of their work, such as their ability to converse or to use the telephone.The results obtained with the rating scales were compared with various physical measures of the noise. A high correlation was found between perceived noisiness and the measure called “speech interference level” SIL, which is the average of the sound pressure levels measured in the three octave bands between 600 and 4800 cycles per second. An even higher correlation was found between the ratings of noisiness and a computed measure of loudness level. More than two‐thirds of those questioned stated that speech communication was an essential part of their activities and that the more intense noises in their offices interfered with it. These correlations provide a basis for setting criteria for the maximum noise acceptable in terms of SIL and of loudness level. These results, plus those from a previous study, suggest that the maximum continuous noise levels acceptable for office spaces in which speech communication is important should not exceed an SIL of 40 db. Office employees are accustomed to a noise spectrum of a form that yields a loudness level of about 22 units higher than the SIL. Complaints are encountered when the loudness level exceeds the SIL by 30 or more units. Thus, with an SIL of 40 db the loudness level should preferably not exceed about 62 phons. Only under special conditions with this SIL would it be advisable to exceed a loudness level of 70 phons.For intermittent noises, such as the noises produced by aircraft operations, evidence is presented to show that the mean (average) value of the SIL and loudness level should not exceed the numbers for steady noises if the work of office employees is not to be disturbed.
ISSN:0001-4966
DOI:10.1121/1.1908489
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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3. |
Onset and Growth of Aural Harmonics in the Overloaded Ear |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 852-858
Merle Lawrence,
Phillip A. Yantis,
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摘要:
The threshold of overload and the growth in intensity of the aural harmonics are determined by the exploring tone method for frequencies of 100, 350, 1000, 2000, and 5000 cps. It is found that the level of a test tone at which it first overloads the ear can be quite accurately determined and that the range of beats between the second harmonic and the exploring tone, as the latter is changed in intensity, is considerably narrower at the overload threshold level than at higher levels. As the test tone is raised in intensity the loudness of the harmonic increases rapidly.Overloading occurs at approximately the same sound pressure level for all frequencies so that the range of linear response is around 8 db at 100 cps, 30 db at 350 cps, and 50 db at 1000, 2000, and 5000 cps. All harmonics are detected when they reach a certain consistent level above threshold for that frequency. The exact level depends upon the subject.These results are considered as additional evidence that distortion in the ear takes place within the sensory cells as part of the electromechanical process and is not due to any nonlinearity of the mechanical response of the ear.
ISSN:0001-4966
DOI:10.1121/1.1908491
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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4. |
Some Measurements of Interaural Time Difference Thresholds |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 859-860
R. G. Klumpp,
H. R. Eady,
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摘要:
Thresholds for the detection of interaural time difference were determined by ten listeners (1) for band‐limited random noise (150–1700 cps), (2) for a 1000‐cps tone, and (3) for a 1‐millisecond click. The average interaural time differences corresponding to 75% correct detection in the symmetrical two‐alternative tests were (1) 9 microseconds, (2) 11 microseconds, and (3) 28 microseconds. Ranges of individual thresholds and group psychometric functions are presented.
ISSN:0001-4966
DOI:10.1121/1.1908493
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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5. |
Just Noticeable Differences in Dichotic Phase |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 860-864
J. Zwislocki,
R. S. Feldman,
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摘要:
The just noticeable difference in dichotic phase, as a function of sensation level and of frequency, has been determined on a number of listeners with normal hearing. The test tones were transmitted by earphones, and the phase difference between the ears was varied by means of an electronic phase shifter. The psychophysical method used combined paired comparisons and forced choice. The first tone pulse of each pair presented was kept at a constant phase difference at which the subject localized the sound source as equidistant from his ears. The dichotic phase difference of the second pulse was varied irregularly (“randomly”). The results show that the sensitivity to dichotic phase difference is highest (2° of phase) at medium sensation levels, and that the jnd increases with positive acceleration as the sound frequency increases. Around 1300 cps the jnd becomes so great that it cannot be measured. The dichotic time difference calculated from the measured jnd in phase has a minimum near 800 cps.
ISSN:0001-4966
DOI:10.1121/1.1908495
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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6. |
Loudness Adaptation for Bands of Noise |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 865-871
Edward C. Carterette,
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摘要:
Loudness adaptation may be measured by a simultaneous loudness balance, or, as in the two experiments reported below, by a median plane localization of a dichotically presented acoustic stimulus. The loudness of a steady auditory stimulus generally decreases with time. That is, the intensity of a comparison stimulus in the rested ear is ordinarily set below the intensity in the stimulated ear.Two experiments were done on loudness adaptation for bands of noise. In Experiment 1, using 36 subjects, loudness adaptation for a wide‐band thermal noise of 100–5000 cps was studied as a function of five SPL's: 40, 70, 90, 100, and 105 db over all. The mean maximum loudness adaptation obtained was 2.3, 9.9, 11.4, 14.4, and 16.3 db, respectively. The mean standard deviation for all measures was 6.1 db, and the distributions of the sets of measures tended to be skewed toward greater adaptation.In Experiment 2 (12 subjects), the loudness adaptation for a 1500‐cps tone was compared with that for bands of noise whose centers (mel scale) were at 1500 cps, and whose over‐all SPL's were equal to the SPL of the pure tone. The band limits in cycles per second were 1280–1120, 1075–1950, 720–2600, and 100–4900. For each band, adaptation was measured for 50, 70, and 90 db SPL over all. The essential results are: (1) Loudness adaptation for 1500 cps is about 8.5 db greater than the maximum adaptation for any noise band at any SPL; (2) Adaptation is small (4.5 db) at 50 db for all bands of noise; it is complete within one minute and is about equal for all band widths; (3) At 70 and 90 db, time taken for complete adaptation increases and the two widest bands give greater adaptation than the two narrowest bands. At 90 db a trend becomes clear: the wider the band, the greater the degree of adaptation and the longer the time required for maximum adaptation to be attained.
ISSN:0001-4966
DOI:10.1121/1.1908497
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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7. |
Annoyance Threshold Judgments of Bands of Noise |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 872-877
Walter Spieth,
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摘要:
Annoyance threshold judgments were obtained by exposing an individual to noise for three minutes and asking him to adjust the intensity to the level which, if any louder, would annoy him if it were present most of the time where he was working.In one experiment, 21 people made judgments about 13 bands of noise which covered the frequency range of 50 to 13 000 cps, and subsequently made sets of equal loudness matches. No differences were found between annoyance threshold curves and equal loudness curves. In a second experiment, each of 162 people made one annoyance judgment. When these annoyance thresholds were transformed into equivalent loudness terms, the resultant annoyance threshold curve varied reliably with frequency only in that the threshold on the highest band (6600–9000 cps) was reliably lower than those on lower frequency bands.Office workers who had once worked in noisy situations as well as those working in noisy situations at the time of the experiment gave thresholds about 15 db higher than did people who had only worked in office‐type situations.Within a group who had worked only in quiet situations, those who tried to imagine themselves in an actual working situation gave thresholds that averaged about 15 db higher than the thresholds of those who did not.
ISSN:0001-4966
DOI:10.1121/1.1908499
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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8. |
Neurological Theory of Beat Tones |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 877-881
Max F. Meyer,
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摘要:
Tartini pitches and beat tones behave differently and must have different physiological origins. Tartini pitches are heard only if the primary tones remain below 2000 cycles per second, preferably for clear observance below 1000. The cochlea is essential for hearing them. Beat tones are not so limited. Their observation is easiest (least confusing) when the primaries are chosen in the region from 3000 to 5000 cycles per second. But lower tones may be used (although there may then be an overlapping of Tartini pitches and beat tones). The cochlea need not exist for the existence of beat tones.
ISSN:0001-4966
DOI:10.1121/1.1908502
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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9. |
Theory of Recognition |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 882-888
Wilson P. Tanner,
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摘要:
The theory of statistical decision has previously been applied to the problem of sensory detection of signals. In this paper, the theory is expanded to treat a simple recognition problem. While the data supporting the expansion have been collected in auditory experiments, the theory applies generally to all human sensory behavior.
ISSN:0001-4966
DOI:10.1121/1.1908504
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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10. |
“Human ‘Cross‐Correlator’”—A Technique for Measuring Certain Parameters of Speech Perception |
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The Journal of the Acoustical Society of America,
Volume 28,
Issue 5,
1956,
Page 889-895
E. Colin Cherry,
Bruce Mc A. Sayers,
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摘要:
A human listener is here regarded as a “cross‐correlator”; his two ears are treated as “input terminals,” stimulated with the acoustic input signalsf1(t) andf2(t+τ), while his vocal responses are treated as the output “correlation function.” The two signals are, respectively, pure and distorted versions of the same signal (perhaps speech). The delay τ is randomly set and the listener answersrightorleft, as the source of sound appears to him to lie. The “correlation function” then corresponds to the probability distribution of his correct judgments. Such functions represent the degree of aural fusion, and show up strikingly the invariants of speech signals which are significant in aural perception.
ISSN:0001-4966
DOI:10.1121/1.1908506
出版商:Acoustical Society of America
年代:1956
数据来源: AIP
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