Energy Propagation and Coupling Studies for Line Transducers.

This program is an investigation of the effect of various soil compositions and frost conditions on performance of buried line transducers. The program encompasses theoretical modeling of transfer function of a MILES-type line transducer, controlled experiments in loam, clay and sand soils for vario...

Full description

Bibliographic Details
Main Author: Starr,J B
Other Authors: HONEYWELL INC HOPKINS MINN GOVERNMENT AND AERONAUTICAL PRODUCTS DIV
Format: Text
Language:English
Published: 1976
Subjects:
Soil Mechanics
Snow
Ice and Permafrost
Seismic Detection and Detectors
*SIGNAL PROCESSING
*SEISMIC DETECTION
*TRANSDUCERS
*FROST
*PERIMETERS(DEFENSE)
*LINEAR ARRAYS
*AREA DEFENSE
*ANTIINTRUSION DEVICES
COUPLING(INTERACTION)
PROPAGATION
LOADS(FORCES)
SECURITY
ENERGY
SAND
CLAY
IMPULSE LOADING
LOAMS
Miles transducers
Line transducers
Ice
permafrost
Online Access:http://www.dtic.mil/docs/citations/ADA031741
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA031741
Description
Summary:This program is an investigation of the effect of various soil compositions and frost conditions on performance of buried line transducers. The program encompasses theoretical modeling of transfer function of a MILES-type line transducer, controlled experiments in loam, clay and sand soils for various frost conditions, and correlations between theory and experiment. Experiments were conducted in an indoor test facility where frost conditions could be produced. Response of transducers was measured with vertical cyclic and impulse loads of defined magnitude applied at the soil surface. Experimental data indicates that as long as frost does not penetrate below the burial depth of the transducer, often there is no significant attenuation of line sensitivity; such cases occur when the frozen layer above the transducer does not form a continuous shelf of frozen ground. When a continuous shelf forms, or when frost penetrates below the transducer burial depth, some upward gain adjustment is necessary for satisfactory performance. Several approaches to minimizing performance problems in frozen ground are identified. Lines may be buried as significantly greater depths. Frost penetration may be artificially limited by insulating materials. Adaptive gain control may be introduced based on either frequency domain information or soil temperature measurements. (Author)

Similar Items