This application claims priority to Chinese Patent Application No. 200610088838.6 filed on Jul. 19, 2006, the contents of which are incorporated herein by reference.
1. Field of the Invention
The invention relates to an apparatus for measurement of posture, and particularly to an apparatus for measurement of floating body posture of a person wearing a life jacket.
2. Description of the Related Art
Posture of a person wearing a life jacket in water is an important factor in evaluating performance of a life jacket, and how to accurately obtain various posture parameters is of great importance for the evaluation. Conventionally, posture parameters of a person wearing a life jacket in water are obtained by expert evaluation and static testing. Safety standards of various countries define that when a person wearing a life jacket is in a balance state, the distance between the person's mouth and the water surface is measured first, the overturn time of the person is calculated using a stopwatch, and then a float angle is obtained via a protractor. However, this method is too simplistic to accurately reflect the dynamics of a movement of the person's body in water and the quasi-static parameters associated therewith.
In view of the above-described problems, it is one objective of the invention to provide a system that is capable of reflecting a movement of a person's body wearing a life jacket in water and the quasi-static parameters thereof.
To achieve the above objectives, one embodiment of the invention provides an apparatus for measurement of floating body posture of a person wearing a life jacket, comprising a backpack frame having a plurality of reference points, an image collecting system, and an image processing system; wherein the image collecting system collects image sequence information of the person wearing a life jacket from the reference points; the image processing system processes the image sequence information, so as to obtain a dynamics of a movement of the person and the quasi-static parameters associated therewith.
In certain classes of this embodiment, the image collecting system comprises a pair of cameras, and a pair of image collecting cards connected to the cameras via a pair of data lines.
In certain classes of this embodiment, the backpack frame is located in an overlapping view field of the cameras.
In certain classes of this embodiment, the image processing system comprises software for performing image processing and a computer (incl. CPU).
In certain classes of this embodiment, the backpack frame comprises a plurality of bellows, a plurality of supporting plates, a plurality of reference points, a shoulder armor plate, a plurality of aluminum pipes, a haunch armor plate, a plurality of steel bars, a plurality of rivets, a waistband, a plurality of welding spot, a first connector and a second connector.
In certain classes of this embodiment, the bellows are jointly connected to the aluminum pipes via the shoulder armor plate.
In certain classes of this embodiment, the haunch armor plate is connected to the steel bar via the rivet.
In certain classes of this embodiment, the aluminum pipe is connected to the bellows via the first connector.
In certain classes of this embodiment, the aluminum pipe is connected to the supporting plates and the reference point via the second connector.
In certain classes of this embodiment, a surface of the supporting plate is coated with one or more low-reflectivity materials.
In certain classes of this embodiment, the supporting plate is fixed to the first connector via a screw thread.
In certain classes of this embodiment, the reference point is fixed to the first connector with glue.
In certain classes of this embodiment, the shoulder armor plate operates to fix the backpack frame to a shoulder of the person wearing the life jacket.
Compared with prior art, the invention has the following advantages: (1) The backpack frame features strong and flexible characteristics, high rigidity, small weight, convenient and reliable connection, compatibility with various devices, adaptability to different postures, along with no effects on movement of a person in water, which meet the testing requirements and enhance flexibility; (2) An image recognition algorithm of the reference point makes it possible to accurately locate the center of a circle even if the reference point is partly shaded, which greatly improves reliability of the system. The supporting plate coated with low-reflectivity materials is disposed at the bottom of the reference point, and helps to overcome the light reflection effect in a complex circumstance, which bring great convenience and reliability for object recognition; (3) The body movement posture in water is optically measured via reference points in a non-contacting manner, which transforms the body posture into a spacial position of a reference point. In this way, an expected dynamic movement of any time duration can be obtained, and the limitation of manual sampling is overcome; (4) A fast and precise circular object recognition algorithm based on a reference point recognition algorithm and a curvature scale-space technique is provided; (5) The precision of the circular object recognition algorithm is higher than that of a classical Hough transform, and it is more reliable than a block-based processing and recognition algorithm. The circular object robust recognition algorithm overcomes problems caused by shading of the reference point and a complex background, and reduces time spent on calculation.
The invention is described hereinafter with reference to accompanying drawings, in which:
As shown in
To obtain a relationship between a two-dimensional plane coordinate of the reference point on the backpack frame 7 and a three-dimension space coordinate thereof, the cameras 3 and 5 need to be calibrated, which comprises collecting moving sequence images on a calibration plate as shown in
As shown in
The bellows 13 are jointly connected to the aluminum pipes 17 via the shoulder armor plate 16, and the haunch armor plate 18 is connected to the steel bars 19 via the rivets 20. The aluminum pipe 17 is connected to the bellows 13 via the connector 32, and to the supporting plates 14 and the reference point 7′ via the connector 32 with a length of about 20 cm. A surface of the supporting plate 14 is coated with low-reflectivity materials, and the supporting plate 14 is fixed to the connector 31 via a screw thread. The reference point 29 is a standard ping pong ball, and is fixed to the connector 31 with glue. The shoulder armor plate 16 operates to fix the backpack frame to a shoulder of the person wearing the life jacket.
As shown in
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As shown in
The process of measuring of floating body posture of a person wearing a life jacket comprises: starting the computer and powering on the cameras; activating the image collecting software; selecting the option “two way real-time display”; adjusting the cameras to appropriate positions as described above, and determining a testing region; implementing software-assisted image collecting and data processing; displaying and analyzing results; saving the results in a database in the form of data and diagrams; and reading and/or displaying analysis results via the “show result” interface option.
While particular embodiments of the invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention.
Number | Date | Country | Kind |
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2006 1 0088838 | Jul 2006 | CN | national |
Number | Name | Date | Kind |
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7627139 | Marks et al. | Dec 2009 | B2 |
20040120774 | Courtney et al. | Jun 2004 | A1 |
Number | Date | Country | |
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20080019570 A1 | Jan 2008 | US |