System and method for an improved device for measuring water...

Acoustics – Echo system – Altitude or depth detection

Reexamination Certificate

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Details

C073S29000R, C367S908000, C340S612000

Reexamination Certificate

active

06345683

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates generally to determining the surface level of a given body and, more particularly, relates to a method and apparatus for determining the surface level of a given body using acoustic ranging.
BACKGROUND OF THE INVENTION
Using acoustic ranging to find the level of a liquid or solid body is well known to those practiced in the art. The general approach is to transmit a pulse of sound, listen to the echo, compute the time between transmission and reception, and convert this to a distance by multiplying the time by the speed of sound. An example of present capabilities is embodied in the EZQ River Flow Monitor, manufactured by Nortek AS of Oslo, Norway. The EZQ measures stage (surface level) with a vertical echo sounder that finds the strong echo of the water surface. The surface level or depth can be a very important commodity. For example, it can be very important in determining flow rates of water channels, which can be critical knowledge for a variety of reasons. Often, however, multiple echoes are received due to interference with the acoustic signal by debris. Additionally, multiple bounces of the echo where the depth is shallow can create added echoes, as can echoes generated from strong reflectors outside the acoustic beam or due to imperfect beam design. The additional echoes compete with the surface echo and make it hard to determine which echo actually corresponds to the surface. An issue not addressed by conventional systems is the problem of identifying a specific echo to associate with the surface being measured. There are many circumstances in which spurious echoes compete with the surface echo. The problem is to discern between the desired surface echo and any spurious echoes that may exist.
For example, because there is no control over natural water flows, debris within a flow is a rich source of spurious echoes. At the same time, water level at such sites is an important and economically valuable parameter to measure, as it forms a key element in measuring flow rates. Spurious echoes in rivers can come from debris, bubbles, fish, and plants, to name a few. Spurious echoes also arise from obstacles outside of the main acoustic beam due to imperfect beam design or because the obstacles are particularly strong reflectors.
Properly implemented acoustic sensors will find the surface most of the time. But spurious echoes can introduce spikes and dropouts into the measurement. Cleaning up this noisy data requires human intervention, which increases cost and delays the availability of good data. Consequently, the value of the data for use in automated processes and for automated data reporting is limited. With appropriate visual displays, a human being is easily able to discern echoes from the water surface and to filter out spurious echoes. This is because a human being is able to detect patterns and history within the information displayed, can include prior knowledge of measurement results, and can weigh evidence within the real world and within the results obtained. What is needed is an automated apparatus and method that incorporates processes natural to human beings, to improve identification of the surface echo in environments in which it might otherwise be overshadowed by spurious echoes.
SUMMARY OF THE INVENTION
The present invention is directed toward a method and apparatus for determining the surface level of a given body using acoustic ranging. In order to determine the surface level of a given body, whether the body is a solid or a liquid, an acoustic pulse is sent through the body. The pulse bounces off the surface of the particular body being investigated and returns toward the source, thus forming an echo. When the echo arrives back at the source, it is received and processed into data relating the strength of the echo and the roundtrip time from transmission to reception. The time is then converted into a distance by multiplying the time by the speed of sound within the body.
The surface level or depth can be a very important commodity. For example, it can be very important in determining flow rates of water channels, which can be critical knowledge for a variety of reasons. Often, however, multiple echoes are received due to interference with the acoustic signal by debris. Additionally, multiple bounces of the echo where the depth is shallow can create added echoes, as can echoes generated from strong reflectors outside the acoustic beam or due to imperfect beam design. The additional echoes compete with the surface echo and make it hard to determine which echo actually corresponds to the surface. The claimed invention overcomes this problem and enables an instrument to automatically select the echo corresponding to the surface reflection.
As such, a method for determining the surface level of a given body using acoustic ranging is presented. First, an acoustic pulse is transmitted through the liquid or solid body. In one embodiment, an electric signal is converted into an acoustic pulse, which is transmitted in an upward direction through the solid or liquid. The acoustic pulse travels vertically toward the surface where it is reflected. Any debris within the path of the pulse, as well as strong reflectors outside the path, may also reflect the acoustic pulse. For example, if the body is a liquid body in a channel, the pulse may reflect off silt, or other debris traveling in the channel. Additionally, imperfect beam design may allow generation of spurious echoes and, in shallow bodies, the echo may bounce up and down multiple times creating multiple spurious echoes.
As a result, the echo from the surface as well as spurious echoes is received. In one embodiment, the surface echo and multiple spurious echoes are converted into electric receive signals. The received signals are then filtered and processed for analysis and display to a user. The processed signals are then evaluated by locating peaks within the data, which represent strong echoes that may correlate to the surface echo. The peaks are then evaluated according to a variety of criteria to arrive at a measurement of the quality of each peak. The higher the quality, the more likely the peak represents the surface echo, as opposed to a strong spurious echo. Finally, the peak with the highest quality measurement is determined to represent the surface echo and the roundtrip time associated with the peak is converted to a distance representing the depth of the body.
In one embodiment, the evaluation criteria involves measuring the amplitude of the received echo, in order to determine the echo's signal strength, measuring the signal to noise ratio of the echo, and measuring the width of the received echo. These measurements are then converted into a quality measurement for the echo. The higher the quality measurement, the more likely the echo corresponds to the surface. Sometimes, however, the surface echo may be weaker than a particularly strong spurious echo or echoes, or the surface echo may not be present at all. Therefore, additional evaluation criteria may be required to select the correct echo or to enable ignoring a particular echo.
For example, in one embodiment, a first echo is looked at in relation to subsequent echoes to determine if the subsequent echoes are multiple bounces of the first echo. This can occur when the depth of the body is relatively shallow. The transmitted acoustic pulse will bounce off the surface and return to the source with relatively strong signal strength. When it arrives back at the source, it is reflected back toward the surface and the process starts over. The result of this phenomenon is the reception of several echoes evenly spaced in time. By looking at the time relationship of subsequent echoes with respect to a first echo, it can be determined if the subsequent echoes are multiple bounces of the first. The subsequent echoes that appear to be multiple bounces of a first echo can then be given lower quality measurements to account for this likelihood.
In one embodiment, an independent input device is u

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