Author: C. R Greene (Jr)
Publisher:
ISBN:
Category :
Languages : en
Pages : 15
Book Description
The outputs of a pair of hydrophones suspended beneath the ice and separated sometimes vertically (210 feet) and sometimes horizontally (359 feet) were tape recorded. In order to measure directional properties of the ambient noise so recorded, the tapes were analyzed using polarity coincidence crosscorrelation. The results showed low frequency correlation as high as 34 percent and some high frequency correlation, probably resulting from marine life and strumming antenna wires in camp, as high as 6 percent. The correlation was generally stable over a period of minutes and often hours. Selected correlation functions are shown. (Author).
Directional Properties of Under-ice Ambient Acoustic Noise
Author: C. R Greene (Jr)
Publisher:
ISBN:
Category :
Languages : en
Pages : 15
Book Description
The outputs of a pair of hydrophones suspended beneath the ice and separated sometimes vertically (210 feet) and sometimes horizontally (359 feet) were tape recorded. In order to measure directional properties of the ambient noise so recorded, the tapes were analyzed using polarity coincidence crosscorrelation. The results showed low frequency correlation as high as 34 percent and some high frequency correlation, probably resulting from marine life and strumming antenna wires in camp, as high as 6 percent. The correlation was generally stable over a period of minutes and often hours. Selected correlation functions are shown. (Author).
Publisher:
ISBN:
Category :
Languages : en
Pages : 15
Book Description
The outputs of a pair of hydrophones suspended beneath the ice and separated sometimes vertically (210 feet) and sometimes horizontally (359 feet) were tape recorded. In order to measure directional properties of the ambient noise so recorded, the tapes were analyzed using polarity coincidence crosscorrelation. The results showed low frequency correlation as high as 34 percent and some high frequency correlation, probably resulting from marine life and strumming antenna wires in camp, as high as 6 percent. The correlation was generally stable over a period of minutes and often hours. Selected correlation functions are shown. (Author).
Directional, Spectral, and Statistical Properties of the Under-ice Noise in the Arctic
Author: C. R. Greene
Publisher:
ISBN:
Category :
Languages : en
Pages : 23
Book Description
Results of the analysis of ambient noise recordings are presented. The average pressure spectrum level observed over the 15-day period was about 5 db over Knudsen's sea state zero extended. As a function of time, the pressure spectrum level correlated significantly with wind speed. There was little difference in ambient noise received by vertical seismometers in thick ice or thin ice. Crosscorrelation of horizontally spaced hydrophones showed that the noise was anisotropic in azimuth, and that the degree of anisotropy was correlated with wind speed delayed by one day. The amplitude probability density function was found to be non-normal by virtue of higher probabilities for high amplitude noise, although this was less for periods of low noise or deep hydrophones than for high noise or shallow hydrophones. (Author).
Publisher:
ISBN:
Category :
Languages : en
Pages : 23
Book Description
Results of the analysis of ambient noise recordings are presented. The average pressure spectrum level observed over the 15-day period was about 5 db over Knudsen's sea state zero extended. As a function of time, the pressure spectrum level correlated significantly with wind speed. There was little difference in ambient noise received by vertical seismometers in thick ice or thin ice. Crosscorrelation of horizontally spaced hydrophones showed that the noise was anisotropic in azimuth, and that the degree of anisotropy was correlated with wind speed delayed by one day. The amplitude probability density function was found to be non-normal by virtue of higher probabilities for high amplitude noise, although this was less for periods of low noise or deep hydrophones than for high noise or shallow hydrophones. (Author).
A Study of the Spectral and Directional Properties of Ambient Noise in Pugent Sound
Author: David R. Dall'Osto
Publisher:
ISBN:
Category : Marine mammals
Languages : en
Pages : 77
Book Description
Publisher:
ISBN:
Category : Marine mammals
Languages : en
Pages : 77
Book Description
Ambient Noise in the Sea
Author: Robert J. Urick
Publisher:
ISBN:
Category : Noise
Languages : en
Pages : 208
Book Description
Publisher:
ISBN:
Category : Noise
Languages : en
Pages : 208
Book Description
U.S. Government Research Reports
Deep Water Studies of the Directional Properties of Ambient Noise
Technical Paper
Some Directional Properties of Deep-Water Ambient Noise
Author: R. J. Urick
Publisher:
ISBN:
Category : Naval research
Languages : en
Pages : 20
Book Description
Publisher:
ISBN:
Category : Naval research
Languages : en
Pages : 20
Book Description
Technical Paper - Arctic Institute of North America
Author: Arctic Institute of North America
Publisher:
ISBN:
Category : Arctic regions
Languages : en
Pages : 184
Book Description
Publisher:
ISBN:
Category : Arctic regions
Languages : en
Pages : 184
Book Description
Ambient Noise in the Sea
Author: Robert J. Urick
Publisher:
ISBN:
Category : Science
Languages : en
Pages : 216
Book Description
Ambient noise may be loosely said to be unwanted sound emanating from the sea itself. Its constituents typically come from a variety of somewhat diffusely combined sources: pressure changes and hydrostatic effects of tides and waves, oceanic turbulence, seismic disturbances, distant ship traffic, wind, rainfall, collapse of bubbles created by wave action, thermal agitation, marine animals and biological activity, breaking ice, and man-made noise such as distant oil rigs. Depending on locations in the ocean space, the times of day, season and year, and the happenstance of events and nature, the aforecited sources may or may not be contribute to the totality of ambient noise at any given time and place; and it may or may not exist as broad or narrow bands of energy in different regions of the frequency spectrum. More exactly defined, ambient noise is that part of the total noise background observed by an omnidirectional hydrophone in the sea which is: (1) not due to the hydrophone system's self-noise such as the noise of current flow around the measurement hydrophone and all forms of electrical noise; ambient noise is independent of the means used to observe it; and (2) not due to other identifiable localized sources of noise. Ambient noise is what is "left over" after all identifiable noise sources are accounted for. Ambient noise is an especially important consideration in detecting and identifying targets - be the targets submarines, underwater vehicles, floating mines, or fish-- in relatively quiet ocean environments and situations. In the case of active sonar, ambient noise typically becomes the dominant background against which the sonar receiver is trying to detect, and possibly identify, targets in the ocean space (not addressing search of the ocean floor) when it is greater than self noise and after the relatively loud reverberation noise created by the active sonar pings has died down in the sonar cycle. In the case of passive sonar, after taking into account self noise and possible extraneous noise from identifiable sources, ambient noise is the background against which the sonar receiver seeks to detect and identify targets. This book, AMBIENT NOISE IN THE SEA by Robert Urick, summarizes the main features of the ambient noise and gives the reader an easy to read, understandable entry in to its unclassified literature. This book is a must for engineers in the fields of active and passive sonars, underwater sensor and weapons systems, and underwater signal processing.
Publisher:
ISBN:
Category : Science
Languages : en
Pages : 216
Book Description
Ambient noise may be loosely said to be unwanted sound emanating from the sea itself. Its constituents typically come from a variety of somewhat diffusely combined sources: pressure changes and hydrostatic effects of tides and waves, oceanic turbulence, seismic disturbances, distant ship traffic, wind, rainfall, collapse of bubbles created by wave action, thermal agitation, marine animals and biological activity, breaking ice, and man-made noise such as distant oil rigs. Depending on locations in the ocean space, the times of day, season and year, and the happenstance of events and nature, the aforecited sources may or may not be contribute to the totality of ambient noise at any given time and place; and it may or may not exist as broad or narrow bands of energy in different regions of the frequency spectrum. More exactly defined, ambient noise is that part of the total noise background observed by an omnidirectional hydrophone in the sea which is: (1) not due to the hydrophone system's self-noise such as the noise of current flow around the measurement hydrophone and all forms of electrical noise; ambient noise is independent of the means used to observe it; and (2) not due to other identifiable localized sources of noise. Ambient noise is what is "left over" after all identifiable noise sources are accounted for. Ambient noise is an especially important consideration in detecting and identifying targets - be the targets submarines, underwater vehicles, floating mines, or fish-- in relatively quiet ocean environments and situations. In the case of active sonar, ambient noise typically becomes the dominant background against which the sonar receiver is trying to detect, and possibly identify, targets in the ocean space (not addressing search of the ocean floor) when it is greater than self noise and after the relatively loud reverberation noise created by the active sonar pings has died down in the sonar cycle. In the case of passive sonar, after taking into account self noise and possible extraneous noise from identifiable sources, ambient noise is the background against which the sonar receiver seeks to detect and identify targets. This book, AMBIENT NOISE IN THE SEA by Robert Urick, summarizes the main features of the ambient noise and gives the reader an easy to read, understandable entry in to its unclassified literature. This book is a must for engineers in the fields of active and passive sonars, underwater sensor and weapons systems, and underwater signal processing.