Difference between revisions of "Instruments for bed level detection"

From Coastal Wiki
Jump to: navigation, search
(External links)
 
(9 intermediate revisions by 4 users not shown)
Line 5: Line 5:
  
 
==Mechanical bed level detection in combination with DGPS==
 
==Mechanical bed level detection in combination with DGPS==
In coastal environments the bed level soundings are often performed by use of a vehicle moving through the surf zone. Rijkwaterstaat (The Netherlands) uses the WESP in combination with DGPS. The CRAB vehicle is in use at the Duck site (USA). The WESP is an approximately 15 m high amphibious 3-wheel vehicle, which can be used for bed level soundings in the surf zone in depths up to -6 m with waves up to 2 m. It is equipped with a DGPS positioning system. Small vehicles with DGPS can be used on the dry beach.
+
[[image:Wesptripod.jpg|thumb|300px|right|Figure 1: WESP tripod]]
 +
In coastal environments the bed level soundings are often performed by use of a vehicle moving through the surf zone. Rijkwaterstaat (The Netherlands) uses the WESP in combination with DGPS. The CRAB vehicle is in use at the Duck site (USA). The WESP is an approximately 15 m high amphibious 3-wheel vehicle, which can be used for bed level soundings in the surf zone in depths up to -6 m with waves up to 2 m (see Figure 1). It is equipped with a DGPS positioning system. Small vehicles with DGPS can be used on the dry beach.
  
==Acoustic bed level detection (Echo-sounding instruments)==
+
==Acoustic bed level detection (echo-sounding instruments)==
 
The most common system for measuring water depth is the single-beam echo sounder. This sonar instrument uses a transducer that is usually mounted on the bottom of a ship. Sound pulses (usually 210 KHz for surface detection) are sent from the transducer straight down into the water. The sound reflects off the seafloor and returns to the transducer. Acoustic penetration into the bed increases with decreasing frequency (usually 10 to 15 KHz for subsurface detection). The time the sound takes to travel to the bottom and back is used to calculate the distance to the seafloor. Water depth is estimated by using the speed of sound through the water (approximately 1500 meters per second) and a simple calculation: distance = speed x time. The faster the sound pulses return to the transducer from the ocean floor, the shallower the water depth is and the higher the elevation of the sea floor. The sound pulses are sent out regularly as the ship moves along the surface, which produces a line showing the depth of the ocean beneath the ship. This continuous depth data is used to create bathymetry maps of the survey area.
 
The most common system for measuring water depth is the single-beam echo sounder. This sonar instrument uses a transducer that is usually mounted on the bottom of a ship. Sound pulses (usually 210 KHz for surface detection) are sent from the transducer straight down into the water. The sound reflects off the seafloor and returns to the transducer. Acoustic penetration into the bed increases with decreasing frequency (usually 10 to 15 KHz for subsurface detection). The time the sound takes to travel to the bottom and back is used to calculate the distance to the seafloor. Water depth is estimated by using the speed of sound through the water (approximately 1500 meters per second) and a simple calculation: distance = speed x time. The faster the sound pulses return to the transducer from the ocean floor, the shallower the water depth is and the higher the elevation of the sea floor. The sound pulses are sent out regularly as the ship moves along the surface, which produces a line showing the depth of the ocean beneath the ship. This continuous depth data is used to create bathymetry maps of the survey area.
  
Multibeam bathymetry sonar (Figure 2) is the relatively recent successor to single-beam echo sounding. About 30 years ago, a new technology has been developed that uses many beams of sound at the same time to cover a large fan-shaped area of the ocean floor rather than just the small patch of seafloor that echo sounders cover. These multibeam systems can have more than 100 transducers, arranged in precise geometrical patterns, sending out a swath of sound that covers a distance on either side of the ship that is equal to about two times the water depth. All of the signals that are sent out reach the seafloor and return at slightly different times. These signals are received and converted to water depths by computers, and then automatically plotted as bathymetric maps.
+
Multi-beam [[bathymetry]] sonar (Figure 2) is the relatively recent successor to single-beam echo sounding. About 30 years ago, a new technology has been developed that uses many beams of sound at the same time to cover a large fan-shaped area of the ocean floor rather than just the small patch of seafloor that echo sounders cover. These multi-beam systems can have more than 100 transducers, arranged in precise geometrical patterns, sending out a swath of sound that covers a distance on either side of the ship that is equal to about two times the water depth. All of the signals that are sent out reach the seafloor and return at slightly different times. These signals are received and converted to water depths by computers, and then automatically plotted as bathymetric maps.
  
One of the best systems for imaging large areas of the ocean floor is side scan sonar (Figure 3A), either ship-mounted or bottom-mounted. The basic concept is much the same as the basic echo sounder; however, side scan sonar instruments are towed behind ships and often called towfish or tow vehicles. This technology uses a specially shaped acoustic beam, which pulses out 90 degrees from the path that it is towed, and also out to each side. Each pulse provides a detailed image of a narrow strip directly below and to either side of the instrument.
+
One of the best systems for imaging large areas of the ocean floor is side scan sonar (Figure 3A), either ship-mounted or bottom-mounted. The basic concept is much the same as the basic echo sounder; however, side scan sonar instruments are towed behind ships and often called tow fish or tow vehicles. This technology uses a specially shaped acoustic beam, which pulses out 90 degrees from the path that it is towed, and also out to each side. Each pulse provides a detailed image of a narrow strip directly below and to either side of the instrument.
  
Seismic reflection uses a stronger sound signal and lower sound frequencies than echosounding. The sound pulse is often sent from an airgun towed behind the ship. An airgun uses the sudden release of compressed air to form bubbles. The bubble formation produces a loud sound. The sound from the airgun travels down to the seafloor. Some of the sound reflects off the seafloor but some of the sound penetrates the seafloor. The sound that penetrates the seafloor may also reflect off layers of material within the seafloor. The reflected sounds travel back up to the surface. The ship also tows a number of hydrophones (called a towed array or streamer) which detects the reflected sound signal when it reaches the surface. The time it takes the sound to return to the ship can be used to find the thickness of the layers in the seafloor and their position (sloped, level, etc). It also gives some information about the composition of the layers.
+
Seismic reflection uses a stronger sound signal and lower sound frequencies than echo-sounding. The sound pulse is often sent from an airgun towed behind the ship. An airgun uses the sudden release of compressed air to form bubbles. The bubble formation produces a loud sound. The sound from the airgun travels down to the seafloor. Some of the sound reflects off the seafloor but some of the sound penetrates the seafloor. The sound that penetrates the seafloor may also reflect off layers of material within the seafloor. The reflected sounds travel back up to the surface. The ship also tows a number of hydrophones (called a towed array or streamer) which detects the reflected sound signal when it reaches the surface. The time it takes the sound to return to the ship can be used to find the thickness of the layers in the seafloor and their position (sloped, level, etc). It also gives some information about the composition of the layers.
 +
 
 +
See also: [[General principles of optical and acoustical instruments]]
  
 
==Optical bed level detection==
 
==Optical bed level detection==
Line 43: Line 46:
 
===Other internal links===
 
===Other internal links===
 
* [[Instruments and sensors to measure environmental parameters]]
 
* [[Instruments and sensors to measure environmental parameters]]
 +
* [[Satellite-derived nearshore bathymetry]]
 
* [[Use of aerial photographs for shoreline position and mapping applications]]
 
* [[Use of aerial photographs for shoreline position and mapping applications]]
* [[Hyperspectral seafloor mapping and direct bathymetry calculation in littoral zones]]
+
* [[HyMap: Hyperspectral seafloor mapping and direct bathymetry calculation in littoral zones]]
 +
* [[Use of X-band and HF radar in marine hydrography]]
  
===External links===
 
* [http://www.wldelft.nl/rnd/intro/fields/morphology/pdf/HH_10_Bed_level_detection.pdf  Chapter 10 of the manual: Bed level detection (pdf; 1,8 Mb)]
 
  
 
==References==
 
==References==
 
<references/>
 
<references/>
  
{{author
+
{{2Authors
|AuthorID=13226  
+
|AuthorID1=13226  
|AuthorFullName= Rijn, Leo van
+
|AuthorFullName1= Rijn, Leo van
|AuthorName=Leovanrijn}}
+
|AuthorName1=Leovanrijn
 
+
|AuthorID2=12969  
{{author
+
|AuthorFullName2= Roberti, Hans
|AuthorID=12969  
+
|AuthorName2=Robertihans}}
|AuthorFullName= Roberti, Hans
 
|AuthorName=Robertihans}}
 
  
[[Category:Theme_9]]
+
[[Category:Coastal and marine observation and monitoring]]
[[Category:Manual sediment transport measurements]]
+
[[Category:Observation of physical parameters]]
[[Category:Geomorphological processes and natural coastal features]]
 
[[Category:Techniques and methods in coastal management]]
 

Latest revision as of 12:16, 7 December 2023

This article is a summary of chapter 10 of the Manual Sediment Transport Measurements in Rivers, Estuaries and Coastal Seas[1]. This article describes three types of instruments which can be used to produce bathymetric maps: mechanical, acoustic and optical instruments.

Introduction

The management of rivers, estuaries and coastal seas always involves the production of bathymetric maps for evaluation of navigationable depths, shoaling and erosion volumes, etc. Hence, accurate measuring instruments for bed level detection are required. Herein, the following methods and accuracy involved are discussed: mechanical bed level detection in combination with DGPS; acoustic bed level detectors (single and multi-beam echo sounders); and optical bed level detection.

Mechanical bed level detection in combination with DGPS

Figure 1: WESP tripod

In coastal environments the bed level soundings are often performed by use of a vehicle moving through the surf zone. Rijkwaterstaat (The Netherlands) uses the WESP in combination with DGPS. The CRAB vehicle is in use at the Duck site (USA). The WESP is an approximately 15 m high amphibious 3-wheel vehicle, which can be used for bed level soundings in the surf zone in depths up to -6 m with waves up to 2 m (see Figure 1). It is equipped with a DGPS positioning system. Small vehicles with DGPS can be used on the dry beach.

Acoustic bed level detection (echo-sounding instruments)

The most common system for measuring water depth is the single-beam echo sounder. This sonar instrument uses a transducer that is usually mounted on the bottom of a ship. Sound pulses (usually 210 KHz for surface detection) are sent from the transducer straight down into the water. The sound reflects off the seafloor and returns to the transducer. Acoustic penetration into the bed increases with decreasing frequency (usually 10 to 15 KHz for subsurface detection). The time the sound takes to travel to the bottom and back is used to calculate the distance to the seafloor. Water depth is estimated by using the speed of sound through the water (approximately 1500 meters per second) and a simple calculation: distance = speed x time. The faster the sound pulses return to the transducer from the ocean floor, the shallower the water depth is and the higher the elevation of the sea floor. The sound pulses are sent out regularly as the ship moves along the surface, which produces a line showing the depth of the ocean beneath the ship. This continuous depth data is used to create bathymetry maps of the survey area.

Multi-beam bathymetry sonar (Figure 2) is the relatively recent successor to single-beam echo sounding. About 30 years ago, a new technology has been developed that uses many beams of sound at the same time to cover a large fan-shaped area of the ocean floor rather than just the small patch of seafloor that echo sounders cover. These multi-beam systems can have more than 100 transducers, arranged in precise geometrical patterns, sending out a swath of sound that covers a distance on either side of the ship that is equal to about two times the water depth. All of the signals that are sent out reach the seafloor and return at slightly different times. These signals are received and converted to water depths by computers, and then automatically plotted as bathymetric maps.

One of the best systems for imaging large areas of the ocean floor is side scan sonar (Figure 3A), either ship-mounted or bottom-mounted. The basic concept is much the same as the basic echo sounder; however, side scan sonar instruments are towed behind ships and often called tow fish or tow vehicles. This technology uses a specially shaped acoustic beam, which pulses out 90 degrees from the path that it is towed, and also out to each side. Each pulse provides a detailed image of a narrow strip directly below and to either side of the instrument.

Seismic reflection uses a stronger sound signal and lower sound frequencies than echo-sounding. The sound pulse is often sent from an airgun towed behind the ship. An airgun uses the sudden release of compressed air to form bubbles. The bubble formation produces a loud sound. The sound from the airgun travels down to the seafloor. Some of the sound reflects off the seafloor but some of the sound penetrates the seafloor. The sound that penetrates the seafloor may also reflect off layers of material within the seafloor. The reflected sounds travel back up to the surface. The ship also tows a number of hydrophones (called a towed array or streamer) which detects the reflected sound signal when it reaches the surface. The time it takes the sound to return to the ship can be used to find the thickness of the layers in the seafloor and their position (sloped, level, etc). It also gives some information about the composition of the layers.

See also: General principles of optical and acoustical instruments

Optical bed level detection

This instrument consists of a steel pole (diameter of 32 or 40 mm; lengths of 1.8, 2.4 and 2.9 m), which can be driven into the bed. The pole is supplied with many infra-red light sources/receivers (backscattering sensors) at spacings of 10 mm (100 sensors per meter; sampling volume of 0.5 cm3).

The instrument measures:

  • vertical distribution of the turbidity levels in the water column;
  • transition from water column to bed based on the scattering of light from the suspended particles and the bed material particles;
  • transition from water column to air (if pole end is above the water surface).

See also: light fields and optics in coastal waters and optical remote sensing.

See also

Summaries of the manual

Other internal links


References

  1. Rijn, L. C. van (1986). Manual sediment transport measurements. Delft, The Netherlands: Delft Hydraulics Laboratory
The main authors of this article are Rijn, Leo van and Roberti, Hans
Please note that others may also have edited the contents of this article.

Citation: Rijn, Leo van; Roberti, Hans; (2023): Instruments for bed level detection. Available from http://www.coastalwiki.org/wiki/Instruments_for_bed_level_detection [accessed on 24-11-2024]