SE533874C2 - Device and method for calculating body fat mass - Google Patents

Description

533 874 BMI thus changes naturally over time and is only partially dependent on body fat mass.

EP 1, 269,917 A1 describes the measurement of skin fold thickness, related to body fat mass, on a living body by placing a protruding part mainly on the area at the navel of the living body and irradiating it with light from a light source and detecting the di reiistically reflected the light with a photodetector.

The disadvantages of this methodology include the discomfort the person is exposed to when measured by, for example, the protruding part, which of necessity temporarily deforms the person's skin, and by the holders applied by e.g. a string or belt that is wrapped around the person's body.

EP 1,629,772 A1 contains a child body composition meter in the form of a platform comprising a bioelectrical impedance measuring section, a weight network section and a programmed microcomputer. The data generated by the first two is related to body fat mass. The disadvantages of this platform include the inability to obtain quantitative data related to the local body mass on different parts of the body, and the advanced electronics needed to measure, convert and present the generated data. Furthermore, the child being measured needs to stand actively and potentially uncomfortable and barefoot on the platform to e.g. an electric current, necessary for the bioelectrical impedance measurement, must pass the loop.

EP 1, 583.09 A2 contains a system and a method for managing growth and development in a child. The system includes, as in EP 1,629,772 A1, a module for measuring biological information, which is based on the principles of e.g. the measurement of bioelectrical impedance, related to body fat mass. The disadvantages of the system included in EP 1,583,019 A2 include the disadvantages of the child body composition network in EP 1,629,772 A1.

EP 1, 645,223 A2 describes a device and a method for measuring fat thickness in a target body part of a person, based on the principles of absorption and reaction of near infrared rays. The disadvantages of this method include the necessity of a calculator and of complicated analysis and conversion of the generated raw data, in order to obtain measurement values related to the body fat mass. Furthermore, the long-term health effects of penetrating electromagnetic radiation are widely debated and have not yet been fully understood.

Thus, there is room for improvement, namely a new technology for measuring or estimating the body fat mass and the degree of obesity in a person, where the technology involves limited discomfort and limited health risks the person dares, while limiting the need for advanced electronics and for current passage through the person's body, or exposure of the same to penetrating electromagnetic radiation.

SUMMARY It is an object of the present invention, in view of the disadvantages mentioned above, to create a simple and mobile device and a system to be used for the collection of relevant data which reflects a person's body proportions in a cost effective manner, and which causes minimal discomfort and minimal risk to the person.

It is another object of the present invention to provide a method for using the device and system of the invention, for the collection of two-dimensional coordinates, which reflect a person's body proportions and the body fat mass of the same.

These and other objects, which will appear from the following description, have now been achieved by a device and a system according to the present invention, which comprises a first and a second rib, said first rib created to be movable along said second rib and where said first rib is perpendicular to said second rib; first coupling device for coupling said first rib to said second rib; and a light emitting device created to emit light in a direction perpendicular to the plane formed by the first and second bars and to said person.

Additional features of the invention and its embodiments are set forth in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS These and other aspects, features and advantages to which the invention is capable will be elucidated and clarified in the following description of non-limiting embodiments of the present invention, in which reference will be made to the accompanying drawings, of which Fig. 1 gives a schematic perspective view of a device, placed with a first rib in the vertical direction and a second rib in the horizontal direction and with a person P placed horizontally with a sagittal plane of the body facing the device, according to an embodiment of the present invention.

Fig. 2 illustrates an embodiment of the present invention, showing the left side, i.e. sagittal perspective, of the body of a person P, lying on his back on a flat, horizontal surface, seen from the z-direction of the device; Fig. 3 provides a schematic perspective view of a device comprising an integrated bench, a set of light beams illuminating light sensing means placed on a third rib and a plane of light illuminating an extension unit provided with light sensing means. , according to an embodiment of the present invention; and Fig. 4 provides a schematic perspective view of a device comprising an interconnecting rib provided with a light emitting device consisting of a number of lasers which emit a number of light rays towards an integrated bench, according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS Several embodiments of the present invention will be described in more detail below with reference to the accompanying drawings, in order that a person skilled in the art may make the invention. However, the invention may have many different embodiments and should not be construed as limited to the embodiments presented herein. These embodiments are described in such a way that this report is thorough and complete and will fully express the scope of the invention to those skilled in the art. The embodiments do not limit the heating, but the heating is only limited by the appended claims. Furthermore, the terminology used in the detailed description of the specific embodiments illustrated in the accompanying drawings is not intended to limit the invention.

It is well known that the x-y-z coordinate system, where the constituent x, y, z axes are all perpendicular to each other, is widely used to describe Lex. points, lines and planes in three dimensions. In the description, embodiments and requirements of the present invention, the xyz coordinate system is used with reference to device 100, so that the x-axis of the xyz-coordinate system is always parallel to the direction of the second rib 102, the y-axis of the same is always parallel to the first rib 101 and the corresponding z-axis are always perpendicular to the plane defined by the first and second ribs 101, 102, unless otherwise indicated. Thus, e.g. "X-direction" is understood as a direction in space parallel to, or along, the extension of the second rib 102, and by "x-position" is meant a point in a plane intersecting the same position on the second rib 102 or the relative the position of the second rib 102, unless otherwise indicated.

In the description, embodiments and claims of the present invention, the well-known terms "horizontal" and "vertical", or derivative forms of these 533 874, are used, for the description of e.g. points, lines and planes in the room, so that the vertical direction is always parallel to the direction of the gravitational crane, unless otherwise stated.

Embodiments of the present invention will now be described below with reference to Figs. 1 to 4.

According to one embodiment of the invention, there is provided an apparatus 100 and a method for measuring and determining two-dimensional coordinates of a person P, including substantially a straight first rib 101, a straight second rib 102 and a light riveting device 104.

The first rib 101 is connected to the second rib 102 by first interconnecting means 105, so that a user can move the first rib 101 to a position in the x-direction of the second rib 102, as desired by the user and limited only by the effective length of the second rib 102. The angle between the first rib 101 and the second rib 102 is substantially 90 ° independent of the x-position of the former.

The first rib 101 and the second rib 102 may be made of the same or different materials, preferably selected from materials known in the art to be constituents of ribs, such as wood, plastic, aluminum or suitable joint assemblies.

More preferred are materials that are inexpensive, lightweight and environmentally friendly, to keep the overall cost of device 100 relatively low, the transportability of device 100 relatively high, and device 100 largely recyclable.

The second rib 102 is preferably made of a heavier material or has a larger total mass than the first rib, for stabilization reasons for device 100 when it is placed with the first rib 101 and the second rib 102 oriented in the vertical and horizontal directions, respectively.

When the first rib 101 has been moved to a desired x-position, it remains in that position by first interconnecting means 105 in the coupling between the first and second ribs 101, 102, until a user moves it to another desired x-position.

A first slider 103 is coupled to the first rib 101 by second interconnecting means 106, so that a user can move the first slider 103 to a position in the y-direction of the first rib 101, as desired by the user and limited only by the effective length. of the first bar 101.

When the first slider 103 has been moved to a desired y-position, it remains in that position by second interconnecting means 106 in the coupling between the first rib 101 and the first slider 103, until a user fl moves it to a arman desired y-position.

First and second interconnecting means 105, 106 include e.g. a tightening bolt, a natural action element or a socket suitable for coupling a first rib to a second rib and a barrel which is well known to those skilled in the art. One or both of the first and second interconnecting means 105, 106 are preferably of a user-friendly type, so that a user of device 100 intuitively understands their function and proper handling.

The x-position of the first rib 101 is equivalent to its, at that time, relative position on the second rib 102, which is determined by x-position determining means 107, such as a visual reading of a scale placed on the second rib 102. position determining means 107 may also be, as is well known in the art, an electrical, magnetic and / or mechanical sensor determining means, started by a user when appropriate, on the second rib 102.

The Y-position of the first slider 103 is equivalent to its, at that time, relative position on the first rib 101, which is determined by y-position determining means 108, such as a visual reading of a scale placed on the first rib 101. position determining means 108 may also be, as is well known in the art, an electrical, magnetic and / or mechanical sensor determining means, started by a user when appropriate, on the first rib 101.

Visual reading of a scale placed on the first or second bar 101, 102 is intuitive to a user and prevents common errors that are otherwise associated with more complicated data collection systems.

A light emitting device 104 is connected to the first sliding device 103, it having, at all times, the same x-position as the first sliding device 103 and in such a way that the emitted light beam 109 is substantially perpendicular, i.e. normal to the plane defined by the first and second ribs 101, 102, i.e. the plane they are fi niered by the y-axis and the x-axis, respectively. The emitted light may also be a plane of light, traveling in a plane substantially perpendicular to the plane defined by the first and second ribs 101, 102. The light beam 109, or the center of the plane of light, may have a direction with an error margin of t .ex. 0 to 3 °, relative to an irrigation line perpendicular to the plane as they are av niered by the first and second ribs 101, 102. Thus, the center of the light beam 109, or the center of the corresponding plane of light, , practically the same y- and x-coordinates along an axis (z) perpendicular to the plane as they are fi niered by the y- and x-axis.

Validation of the precision and accuracy of the light beam 109, and thus the setting of the device 100, can be easily done by pointing it towards reference points, e.g. on a wall, and then the corresponding x and y positions can be compared with exact reference values. This validation method is comparatively simpler than the validation of many other instruments or systems used for the calculation of body fat mass.

Means 104a for coupling the light emitting device 104 to the first sliding device 103, include e.g. bolts or screws or suitable fasteners.

The light emitting device 104 can also be connected to the first sliding device 103, by means 104a of a suitable gyro stabilizer known in the art, for e.g. stabilize the direction of the emitted light beam 109 against e.g. temporary dislocations or vibrations of device 100.

In the case that the direction of light beam 109 is, after being started by the user as desired, periodically varying in a plane, as in the y-plane or in the x-plane, an imaginary line is drawn from the center of the resulting projection in the xy-plane to the light emitting device 104 substantially parallel to the z-axis of the xyz coordinate system.

To prevent e.g. unintentional inclination or dislocation of device 100, which when the first rib 101 is placed in a vertical direction and the second rib 102 is placed on a horizontal surface, which would cause the light beam 109 to no longer be perpendicular to the vertical-horizontal plar in this example, the shape of the second rib 102 may be such that it securely supports the device 100 from inclination or dislocation. This can be accomplished by providing the second rib 102 with a flat bottom side with a large surface area and this may optionally be relatively thin, to provide a good support when the device 100 is placed horizontally on a flat surface, such as on the floor of the room or a table. . Furthermore, the second rib 102 can be provided with separate means for securing the device 100 at the surface on which it is placed, and these can be constituted by e.g. screws, straps, magnets, fasteners or a holder of the type commonly used to secure table lamps on a table.

The device 100 can be positioned in a direction towards, and at a distance from, a person P, so that, when the light beam 109 exposes the same or an extension unit 110 immediately in the vicinity (see Fig. 2), the resulting reflected light is clearly visible. 533 874 detectable by a user of the device 100, or detectable by other suitable means such as a photodetector well known in the art. The distance between the light emitting device 104 of the device 100 and the person P during the measurements is preferably 0.01 to 10 m, and more preferably 0.01 to 2 m.

Examples of said immediately adjacent extension unit 110 include a piece of material, such as wood, plastic or metal, which is not larger in size or weight than can be placed on a person P without unacceptable discomfort to the same.

Extension unit 110 functions as an extension of a person Pz's body by creating range for the light beam 109 when placed on body parts not easily reached by the light beam 109 in the position in which person P is placed. Extension unit 110 can e.g. placed on. the sternum of a person P, lying horizontally on his back with the light beam 109 directly coming from either the left or the right side, i.e. perpendicular to the sagittal plane of the body. Extension unit 110 may further be provided with one or more light sensing means, which may be selectively sensitive to the light emitted from the light emitting device 104, so that a signal is transmitted from the object upon exposure to that light. Light sensing means, selectively started for transmitting a light signal of a particular wavelength, are well known in the art. The signal may be a radio signal which may be cut through by a receiver, as a receiver integrated in or with a computer or control unit 1 l 1, or an audio signal from electronics which is optionally integrated with the object and which may be heard by the user of device 100, all well known in the art. The signal may also be a fluorescent light easily seen by the user of device 100 and be due to the object being covered with a fluorescent material, well known in the art.

The light emitting device 104 from which the light beam 109 comes is preferably a laser, e.g. of the same kind used in pen lasers which are used in public presentations, or a suitable sight laser, often used for weapons and which e.g. can be purchased from Laser Devices Inc. The light emitting device 104 may also be, either by selecting such a position by a user or constantly, a laser in which the emitted light beam periodically changes direction in the x- or y-plane, i.e. the plane of the second rib 102 and the first rib 101, respectively, at such a speed that the user of device 100 gets the visual impression of a line on the object, as a person P, which the beam is training. The user is thus guided in the identification of which parts of the object are placed along the current e.g. the x or y direction. To make the visual impression possible, the light emitting device 104 may alternatively emit a plane of light generated by optics and / or one or more lenses integrated in the light emitting device 104 and well known in the art. , and which diffuses an initially generated light beam into a plane of light format such as the letter "V". The plane of light is optionally initiated by selection by the user, by switching between different positions of the light emitting device 104, such as "beam mode" and "layer mode". The plane of light generates the visual impression of a line on the object, which is preferably in the frontal plane or cross-section of a person P, or an extension unit 110 which the plane of light strikes.

During the measurements, a person P, who may be a child or adolescent, may be placed lying horizontally on his back in front of the device 100, preferably in a comfortable manner such as on a suitable bed or table with a flat surface, with an imaginary line along the spine substantially parallel with the x-axis, i.e. the second rib 102, and the same imaginary line substantially perpendicular to the z-axis, i.e. the direction of the light beam 109.

During the measurements, a person P can also stand up on his feet in an upright horizontal direction, with the device arranged so that the light beam 109 or the central axis of the corresponding plane of light, i.e. The z-direction of the device is perpendicular to the sagittal plate or the cross-section of the person P.

During the measurements, preferably a person P, who may be a child or a young person, lies down horizontally on his back because this position is very comfortable and the person P can even sleep.

The placement of a person P and the device 100 can be in the order that feels comfortable and the person P is preferably naked or dressed in tight, thin clothing, on the body parts from which the coordinates are to be collected.

A user of device 100, which may be a nurse, doctor, physician, teacher, parent, or anyone else with a desire to collect relevant data about a person Pz's condition regarding body fat mass, may independently and as desired move the first bar 101 and the first the sliding device 103 for positioning the light beam 109, or the center thereof, at any x- and y-coordinate, within the limits set by the effective length of the second and first ribs 102, 101, which is preferably such that a person P can be exposed on any part of the body and more preferably on the body area between the neck and the upper part of the thigh, by the light beam 109. When a desired relative position of a person P and the device 100 has been arranged as described above, such as the arrangement of Fig. 1, the user of the device 100 can select a first x-position of the person P's body by surface, simultaneously or one at a time, the first rib web 101 and the first slider 103 until the reflection of the light beam 109, which can be visually detected by the user as a dot or line on the person P's body, corresponds to the first x-position. The first rib 101 can then be secured at the first x-position by means of the first interconnecting member 105 and its relative position on the second rib 102, i.e. corresponding x-coordinate of the person P, can be noted or otherwise registered by the user.

When the first rib 101 is secured at the first x-position, a user can move the first slider 103 from a position where the reaction of the light beam 109 from the body P's body is detectable, to a position where the same reaction from the body is no longer detectable. or the light beam 109 hits an object behind the body or the reaction distinctly changes character, which occurs when the light beam 109 completely misses the body or hits it at a low angle. The light beam 109 can also be moved away from the body and reach the extension unit 110. At that time, a user can note or record the relative location of the first slider 103 on the first rib 101, equivalent to the "limited y-coordinate" of person P, at the selected first x-position, equivalent to "the contiguous x-coordinate" of said limiting y-coordinate of the person P.

When the light beam 109: gnashes person P's body, the detection of the light beam 109 with the same kind of light sensing means, selectively sensitive to the emitted light from the previously mentioned light riveting device 104, can facilitate the user in the choice of x and y positions. For example. For example, a suitable screen or wall, located on the opposite side of person P in relation to device 100 and in the direction of the light beam 109, may be provided with said light sensing means and thereby transmit an indicative signal when the light beam 109 hits the same. Preferably, the extension unit 110 and the screen or wall are provided with various light-blocking means, to facilitate discernment of the times when the light beam 109 hits the former or later.

Then a second x-position can be selected and the same procedure performed for the first x-position can be repeated to collect the corresponding, limiting y-coordinates of the second x-position, ie. other contiguous x-coordinates.

Any number of x-positions, ie. contiguous x-coordinates, can be selected for the collection of corresponding limiting y-coordinate (s). In general, the choice and the determination of the corresponding limiting y-coordinate (s) at two different x-positions, i.e. corresponding contiguous x-coordinates, to be preferred.

The first sliding device 103 can be moved by a user in two directions, i.e. against the second rib 102 or away from it, to allow registration of e.g. two limiting y-coordinates of a person P, at any selected x-position, i.e. contiguous x-coordinate. A limiting y-coordinate can correspond to the intersection between person P's body and the surface where person P is located, Lex. lying on its back, and constitutes a useful, vertical reference line in the case that said surface is horizontal, or towards the lower end of the person P's body if this is not in contact with the underlying surface.

Furthermore, an experienced user of device 100 may collect xy-coordinates corresponding to different parts of a person P's body, such as the highest point on the right leg and the lowest point on the ribs, and xy-coordinates corresponding to the extension unit 1 10, which may represent the height of the sternum from a vertical reference line.

Different data sets, each consisting of one or fl your limiting y-coordinates together with the respective contiguous x-coordinate (s), as well as with xy-coordinate (s) for different body parts and / or extension unit 110 and / or the y-coordinates as corresponds to said vertical reference line, can be assembled as described above by different arrangements of a person P in relation to the device 100. E.g. the person P can be placed horizontally with the back down so that one of the sides of the person P is facing device 100, i.e. a sagittal perspective, or with the side down so that the front of the person P is facing the device 100, i.e. a frontal perspective. These arrangements will, after collecting data as described above, result in two data sets: one corresponding to a sagittal projection of a person P lying horizontally on the back and one corresponding to a frontal projection of a person P lying horizontally on the side.

During the collection of the data sets, the light beam 109 can advantageously not be felt by the person P and the light beam 109 is preferably of an impermeable wavelength, thus counteracting that the person P is exposed to a minimal health risk.

Furthermore, the x-y coordinates can be collected in the same way from e.g. the sagittal and frontal plane of a person A standing up vertically, by arranging the device 100 with the second rib 102 horizontally, the first rib 101 vertically, and with the light beam 109 directed towards the person P.

The data sets, as described and collected as described and the method above by the use of device 100, generated at different times, as times with an interval between them from fl your days to a few months, can be further mathematically handled and analyzed by those skilled in the art and are valuable for the generation of measurement values and anthropometric measurements and for the timely monitoring of health conditions, with respect to Lex. body fat mass, in a person P.

According to an embodiment of the invention, there is provided a control unit 111 coupled to the device 100, in which a user can record data or from which a user can read data fi other than the device 100, such as the xy coordinates of the light beam 109 or data from someone (s) related sensor (s), such as light sensing means, or through which a user can initiate calculations' from stored data and, optionally, via which a user can control the device 100. The control unit 11 may store data from the device 100, as data from xyz position determination means and perform calculations based on the same, as calculated indices and / or metrics known in the art. The control unit 11 1 enables reading of output for a user of device 100, such as the current x-position of the first rib 101, the current y-position of the first slider 103, and calculated index or metric, and storage of relevant information, which patient records including patient data and related two-dimensional coordinates, e.g. x-y and x-z coordinates, and calculated indices and / or metrics. Patient data may include e.g. the name, address, weight and height, medical history and date of birth of a person P. A user of the device 100 may optionally check the placement of the first ribbed band 101 and the first sliding device 103 via the control unit 111 which it can check devices known in the art, which servomotors, which automatically fl move the first rib 101 and the first slider 103 to positions desired by the user. A user of the device can optionally control the position of the light emitting device 104, or the corresponding one, via the control unit 11 1, e.g. switch between "beam mode" and "layer mode", as desired. The control unit may be a personal computer (PC) provided with suitable software and input / output hardware, or any other suitable control unit known in the art.

According to an embodiment of the invention, there is provided a device 100 for collecting two-dimensional coordinates of a growing child or adolescent lying horizontally on the back, said coordinates being coordinates of the sagittal plane of the body.

According to an embodiment of the invention, the device 100 is provided with an integrated bench 12 which can be stationary in, or (foldable up) in, the x-z plare, i.e. The plane perpendicular to the plane as they are av is driven by the first rib 101 and the second rib 102. The integrated bench 112 has a flat upper surface located at, either permanently or when it is (folded up) into , a predetermined y-coordinate corresponding to the reference line L3, so that a user of the device does not have to separately determine the y-coordinate of the reference line L3 since it is known. The integrated bench 112 can be connected to the second rib 102 by suitable interconnecting means known in the art, such as the hinge joints 126. Means for facilitating the folding and unfolding of the integrated bench 11 are known in the art. The integrated bench 112 can e.g. consist of separate parts interconnected with the hinge joints 126 in a teachable manner known in the art, a flat, comfortable surface in the xz plane being formed when the bench is (folded up) by a user who sets the device for measuring two-dimensional coordinates of a person P. When the integrated bench 112 is set for use with the device 100 with the first and second ribs 101, 102 arranged in vertical and horizontal directions, respectively, i.e. that it is (up) folded in the xz plane, its upper surface preferably located at a level lower than any level of the light beam of the device 100 traveling in the z-direction, or within the lower 10% of the y-direction of the total possible the range of such rays. The integrated bench 12 is preferably of a type which allows the device 100 to be foldable in a format such as the "briefcases", the device 100 being highly movable and easily transportable between different locations for measurements.

According to one embodiment of the invention, the light emitting device 104 may emit a plurality of rays and / or the plane of light, preferably a plurality of light rays 113 and a plane of light 114. Thus, the light emitting device 104 may comprise a plurality of light emitting sources, preferably lasers, placed at a short distance, as 0.1 to 5 mm from each other. The light emitting sources can be placed in a row in the y-direction, ie. in the same direction as the first rib 101, and the distance between the first and the last in the row is preferably greater than the distance between M4 or M5 and L3, i.e. the largest vertical distance in the sagittal plane of a person P, lying on his back on a horizontal, flat bench. The light riveting device 104 can optionally be placed directly on the first rib 101 (as illustrated in Figs. 3 and 4), i.e. without the need for a coupling to a first slider 103.

According to an embodiment of the invention, the light sensing sensor 115 may consist of a set of photoelectric sensors, i.e. a number of photoelectric sensors, preferably selectively sensitive to the light emitting from the light emitting device 104, as is known in the art. The photoelectric sensors are preferably located at a distance of 0.1 to 5 mm from each other, in a row in the y-direction and may be of an integrated type, as is known in the art.

According to an embodiment of the invention, light shielding means 115 may consist of an array of photoelectric sensors, i.e. a number of photoelectric sensors, synchronized by suitable means known in the art, mechanically or electrically, with a number of light beams 113, each of these sensors being capable of detecting illumination caused by the corresponding individual light beam emitted from the corresponding light source placed directly fi -Compare it. In such detection of illumination, each individual sensor may be capable of generating a positive light indication signal. Such signals and their use are well known in the art and include e.g. an analog electrical signal which can be converted into a digital signal (eg "1" by "1" or "0"), which can be transmitted further as input to a computer or control unit 111, for automatic calculation of y coordinates must be able to be implemented. Should e.g. a single given light beam among the number of photoelectric light beams 113 reach the corresponding sensor among the number of photoelectric light beams, a digital “1” is generated. If, on the other hand, this individual light beam does not reach the corresponding sensor, as in the case of interruption of a person's body, the corresponding digital "0" is generated.

According to one embodiment of the invention, light sensing means 115 consists of a single photoelectric sensor, the illumination of the light sensing means 115 with one or more of the number light beams 113 resulting in a positive light indicating signal.

According to one embodiment, the device 100 is provided with an interconnecting rib 117, extending in the z-direction, which connects the first and third ribs 101, 116 to keep them parallel in the yz-plane, independent of the relative position of the first rib 101 The interconnecting bar 117 is preferably detachable and replaceable so that easy mounting of the device 100 can take place when a person P is placed in its immediate vicinity or e.g. on an integrated bench 112 thereof, for measurements.

According to one embodiment, the interconnecting rib 11 is provided with a second light riveting device, 120 or 123, from which one or more light beams radiate out in the y-direction and towards a person P.

According to one embodiment, the second light riveting device is a single laser 123 which is superficial along the co-coupling rib 117 and which emits a single light beam 124. Furthermore, the individual laser 123 or the co-coupling rib 117 can be provided with means for determining relative z-position. well known in the art, as a scale 125 on the interconnecting bar 117. 10 15 20 25 30 35 533 874 1.5 According to one embodiment, the second light emitting device consists of a plurality of lasers 120, placed at a distance of 0.1 to 5 mm from each other and placed in a row on and along the interconnecting rib 117, and emitting a plurality of light beams 121.

According to one embodiment, the integrated bench 12 is provided with laser selective shielding means 127, the light emitted from the second light emitting device 120 or 123 being detectable. When illuminating the laser selective sensing means 127 with one or more light beams 121, or with a single light beam 124, the laser selective means 127 may result in a positive light indicating signal, analogous to the positive light indicating signal from light sensing means 1, which may be further transmitted. a computer or to a control unit 1 1 1. The laser selective means 127 preferably covers the entire surface of the integrated bench 112 on the same side as a person P is located, the surface of the bench outside the sagittal plane area of a person Pz's body being covered with laser selective sensing means 127 Thus, laser selective sensing means 127 can detect the nearest light beam, relative to the knob, from the second light emitting device, 120 or 123, which is outside the sagittal plane area of the person P's body. Suitable laser selective sensing means 127 is known in the art and includes any suitable photosensitive detector, which may consist of an array of photosensitive semiconductors capable of generating an electrical excitation signal at illumination, which is layered and preferably foldable to allow easy placement on it. 1 12, in combination with a light-filtering layer, so that only light of the same wavelength as the emitted light from the second light-emitting device, 120 or 123, can reach the photosensitive detector.

According to one embodiment, control unit 111 may (a) read input in the form of one or more positive light indicator signals) from the light sensing means 15, or from the laser selective sensing means 127, (b) send output signals in the form of signals to the light emitting device 104, or to the plurality of lasers 120, or to the individual laser 123, each of which may be individually turned on or off by any of said device or laser emitted beam (s) of light in accordance with an algorithm stored in the control unit. ll 1.

According to one embodiment, the device 100 comprises (a) a plurality of lasers 120, emitting a plurality of light beams 121, (b) a light emitting device 104, emitting a plurality of light beams 113, (c) light sensing means 115 consisting of a single light source. 533 B74 16 photoelectric sensor, capable of transmitting a positive light indicating signal to control unit 1 1 1, (d) laser selective sensing means 127, capable of transmitting a positive light indicating signal to control unit 11, and (e) control unit III, wherein a suitable control algorithm and recording and calculating data at / from the device 100 is stored.

Thus, after placing a person P horizontally, as described herein, and so that the frontal plane of the body is covered by the number of light rays 121 and, at least, the upper part of the sagittal plane of the body is covered by the number of light rays 13, two-dimensional coordinates of person P gather, in the sagittal and fi-ontal plane, at the present x-position of the first rib 101 by: (i) Turning on, each and every one at a time, the rays of fl ertal light rays 121, (ii) Registering the presence or absence of a positive light indicating signal from the laser selective sensing means 127 for each light beam during the period of time it is on; (iii) calculating the distance, corresponding to the frontal width of the body, from the first to the last light beam associated with the absence of a positive light indicating signal; to “ii”, with fl number of light rays 113 in combination with light sensing means 115, for an estimate of the upper y-coordinate of the body in the sagittal plane , which corresponds to the uppermost light beam associated with the absence of a positive light indicating signal.

An additional set of two-dimensional coordinates can then be assembled at another x-position by moving the first bar 101 to a new position and repeating steps “i” to “iv”.

Thus, a user can easily collect two-dimensional coordinates from both the frontal and sagittal planes of the body of a person P, without the need for person P to change position or be touched in any way.

According to an embodiment of the invention, the device 100 comprises a light emitting device 104 which emits a number of rays and / or planes of light, as described above, and light sensing means 115 in the form of a series of a number of photoelectric sensors in the y-direction, according to description above. The plurality of light beams 113 and the photoelectric sensors are synchronized so that each beam is detected by a corresponding sensor, regardless of the position of the first rib 101, given that no object, for example a person P, obstructs said beam or rays. Means for the synchronization comprise, for example, a third rib arranged in the y-direction, on which the sensors are placed, which are mechanically connected, known in the field, to the first rib 101 by e.g. an interconnected rib 117. Limiting y-coordinates can thus be determined by registration, automatically by a control unit 111 or manually by a user, for example by the lowest detected light beam (for an upper limiting y-coordinate ) at the corresponding x-coordinate on which the first bar 101 is located. The distance between the first rib 101 and the third rib 16 may be such that a person P can be placed, lying horizontally on his back, easily between these ribs, and preferably between 0.5 to 1.5 m.

According to one embodiment, the light riveting device 104 comprises a plurality of lasers located at a distance of 0.1 to 5 mm from each other, these lasers being placed in a row in the direction of the first rib 101 and emitting a plurality of light beams 13 in one direction. perpendicular to the plane defined by the first rib 101 and the second rib 102.

According to one embodiment, the device 100 comprises a third rib 116 extending in the y-direction and in front of the light beams 13.

The third rib 116 may be placed in front of the light beams 113 manually or by other means, for example mechanically synchronized with the first rib 101 known in the art.

According to one embodiment, the device 100 is provided with a fourth rib 122. The movement of the third rib 116 in the x-direction can be facilitated by means of this fourth rib 122, which extends in the x-direction and optionally integrated with the device 100, via for example hinges 126 or other suitable means known in the art. This fourth rib 122 acts as a support by allowing the third rib 116 to slide thereby by means known in the art, for example a low friction section, and helps to hold it in front of the light beams 113 while the first and third ribs 101, 16 are moved in x the direction.

According to an embodiment of the invention, the device 100 simultaneously comprises a light emitting device 104, which emits a number of rays and / or planes of light and is placed on the first rib 101, a third rib 116 provided with light sensing means 115 in the form of photoelectric sensors, and an integrated foldable bench 112. The third rib 116 and the photoelectric sensors are mechanically synchronized with the first rib 101 and the number of beams 113. The bench, foldable in the x-z plane and configured, known in the art, for convenient placement of a person P lying down on the back.

According to one embodiment of the invention, the light emitting device 104 emits a plane of light 114 in the xz plane, and the extension unit 110 is formed as a rod and provided with light sensing means 118 in the form of a row of a 533 874 18 a plurality of photoelectric sensors, located at a distance of preferably 0.1 to 5 mm from each other along the door extension 110. The plane of light is directed towards a point just above the sternum of a person P lying horizontally on his back on a flat surface and from which two-dimensional coordinates must be collected. The rod-shaped dry extension unit 110 is placed in a vertical direction on the sternum of said person P, the individual sensor 119, of the number of photoelectric sensors located at the same y-coordinate as the plane of light 11, detecting the plane of light 114.

Thus, the distance from the reference line L3 to the top of the sternum can be calculated based on the y-coordinate of the plane of light 114 and the distance from the sternum to the individual sensor 119 which detects the plane of light 114.

According to an embodiment of the invention, the rod-shaped door extension unit 110 is provided with a wireless connection to the control unit 111 and with a button, whereby a user can turn on and off the plane of light 114 with the button, and a signal from the individual sensor 119 can be sent to the control unit. 1 l 1 for subsequent identification of the same and calculation of the coordinates dares for example the sternum of person P. The user thus does not have to be close to the control unit lll for measuring the coordinates of for example the sternum, but only has to activate the button on dorsal extension unit 1 10.

According to an embodiment of the invention, device 100 may be placed above, for example hanging from the ceiling, a person P lying horizontally on his back on a flat surface, the first rib 101 being positioned horizontally, the second rib 102 being positioned horizontally, and the light beam 109 or corresponding rays or planes of light are directed at person P, thus enabling the collection of two-dimensional coordinates from a person P from the front, i.e. in the frontal plane, while the person P is lying on his back.

According to an embodiment of the invention, there is provided a method of using a device 100 for estimating the body fat mass of a person P, the method comprising (a) placing a person P on his back on a flat surface in the horizontal plane with one side of the body, i.e. sagittal plane, towards the device 100, the person P is naked on that part of the body from the neck to the upper part of the thigh, (b) registering at least two limiting y-coordinates of the person P's body, and (c) using said limiting y-coordinates for estimation of the body fat mass of the person P. According to an embodiment of the invention, the light emitting device 104 of device 100 is a laser which can optionally be set to periodically change direction of the emitted light beam 109 in xz-, or the yz plane.

According to an embodiment of the invention, the light riveting device 104 has built-in optics, said device riveting a plane of light format as the letter "V".

According to an embodiment of the invention, the y-position of the first sliding device 103, and the x-position of the first rib 101, are determined by visually reading the y- and x-scales 108, 107, respectively.

According to one embodiment, the device 100 is provided with means for relative x-position determination 107 of the first rib 101 along the second rib 102, for example a scale printed on the second rib 102.

An embodiment of the invention is illustrated by the following examples which describe the collection of xy coordinates, useful for determining measures related to body fat mass known in the art, for example F-index (F lodrnark index): A person P, who is a child or disabled, lies comfortable on the back on a horizontal flat bench, naked on the upper part of the body above the right leg. A user places the device 100, in accordance with the description herein, so that the light beam 109, which is a laser, is perpendicular to the side of the person P, i.e. the sagittal plane of the body. The user registers there, in any order and in accordance with the description herein, (i) the xy coordinates (or alternatively only the x-coordinates thereof) of the upper part of the right leg M1, (ii) the xy-coordinates (or alternatively only x the coordinate thereof) of the lower part of the ribs M2, (iii) the y-coordinate M3 (or alternatively any xy-coordinate along the reference line L3) for the reference line L3 corresponding to the intersection between the body and the bench, (iv) xy-coordinates (or alternatively only the y-coordinate thereof) of the uppermost point of the body M4 of person P along vertical line L1 vertically extending from the center of an imaginary line between M1 and M2, and (v) xy-coordinates M5 (or alternatively only the y-coordinate thereof) of extension unit 110 located on the sternum of person P or at an equivalent position thereof. The vertical distance between M5 and L3 is related to the height of the person Pz. The vertical distance between M4 and L3, equivalent to the distance between the horizontal lines L2 and L3, is related both to the height and to the body fat mass of person P. It is known in the art that the ratio between the two distances is indicative of the relative body fat mass of person P at time dare measurement. An embodiment of the invention is illustrated by the following examples, which describe the combination of xy coordinates useful for determining values related to body fat mass known in the art: (i) positioning the device 100 with the first rib 101 extending in a vertical direction and the second and third ribs 102, 16 extending in a horizontal direction, and the interconnecting rib 117 extending in a direction perpendicular to the plane defined by the first and second ribs 101, 102, the interconnecting rib 117 connected to the first and third ribs 101, 116, the emitted light from the light emitting source 104 and a number of lasers 120 or individual laser 123 are directed towards the intended location for measuring person P, (ii) placing the person P on the back of the integrated bench 1 12 arranged in the horizontal plane with the sagittal plane of the body towards and parallel to the plane de fi niered by the first rib 101 and the second a rib 102, and with the frontal plane of the body perpendicularly accessible by the plurality of light beams 121 or said individual light beam 124, and (iii) recording at least two limiting y-coordinates in the sagittal plane and at least two limiting z-coordinates in the frontal plane of person P.

According to an embodiment of the invention, device 100 is provided with calculation means, for example calculation means of the control unit 11, and optionally with automatic moving means, for example means integrated with the first interconnecting means 105, of the first bar 101, the x-coordinate corresponding to the center of two of users selected x-coordinates, for example M1 and M2, are calculated and presented to the user, or to which the first bar 101 is automatically fl when user selects the two respective x-coordinates. Said calculating means and said automatic moving means are well known in the art.

The requirements do not exclude the term “include / include” the presence of other elements or steps. Furthermore, even if they are listed individually, a number of means, elements or method steps can be implemented by, for example, an individual unit or processor. Furthermore, although individual features may be included in different claims, these may possibly be advantageously combined and the inclusion in different claims does not imply that a combination of features is not possible and / or advantageous. Furthermore, references in the singular do not exclude a number.

Reference numerals in the claims are provided for illustrative purposes only and shall not be construed as limiting the scope of the claims in any way.

Claims (1)

1. 0 15 20 25 30 533 874 21 PATENT REQUIREMENTS. A device for estimating body fat mass using anthropometric measurements as a proxy measurement for the degree of obesity of a person (P) by determining two-dimensional coordinates in at least one plane of said person (P) using said device, said two-dimensional coordinates is used to generate said anthropometric measurements, comprising: - a first and a second rib (101, 102), said first rib (101) being configured to be movable along said second rib (102) and said first rib (101) being perpendicular to said second rib (102), - first interconnecting means (105) for coupling said first rib (101) to said second rib (102), and ~ a light riveting device (104) configured to emit light in a direction perpendicular to the plane de fi niered by the first and second bars (101, 102) and against said person (P); wherein - said light emitting device (104) is connected to a first sliding device (103), said first sliding device (103) is connected to said first rib (101) and is configured to be superficial along said first rib (101), and configured to emit the light beam (109), the reflection of which is visually detectable to enable a user of said device to determine x- and y-coordinates; or - said light emitting device (104) is configured to emit a plurality of light beams (13) to a light sensing means (11), said light sensing means (11) which is at least one photoelectric sensor; and wherein said light emitting device (104) is a laser emitting light whose response is visually detectable. . The device of claim 1, wherein said light sensing means (115) is a series of a plurality of photoelectric sensors in the direction of said first rib (101), synchronized so that each said beam of light (11 13) is detected by a corresponding sensor given that a person P does not obstruct said beam or rays. . The device according to claim 1, wherein said light sensing means (115) is a single photoelectric sensor, wherein the illumination of said light sensing means (11) with one or näm era of said fl number of light beams (11 13) results in a positive light indicating signal. . The device of claim 1, further comprising: - means for relative x-position determination (107) of said first rib (101) along said second rib (102), and - means for relative y-position determination (108) of said first sliding device (103 ), along said second rib (102). . The device according to any one of claims 1 to 4, wherein the light emitting device (104) is a laser or comprises a plurality of lasers. . The device according to any one of claims 1 to 5, further comprising a control unit (111). . The device according to any one of claims 1 to 6, further comprising an integrated bench (11) which is stationary or foldable in a plane perpendicular to the plane defined by the first rib (101) and the second rib ( 102). . The device according to any one of claims 1 to 2 or 5 to 7, further comprising light shielding means (115) consisting of a plurality of photoelectric sensors, and wherein the light emitting device (104) is positioned directly on the first rib (101) and comprises a ljus a number of light emitting sources located at a distance of 0.1 to 5 mm from each other, and wherein said light emitting sources are located in a row in the direction of the first rib (101) and emitting a fl number of light beams (113) in a direction perpendicular to the plane defined by the first rib (101) and the second rib (102), and wherein said light beams (13) are directed towards said fl number of photoelectric sensors. . The device according to any one of claims 1 to 3, wherein the light emitting device (104) comprises a plurality of lasers located at a distance of 0.1 to 5 mm from each other, said lasers being placed in a row in the direction of the first rib (101) and emits a plurality of light beams (113) in a direction perpendicular to the plane defined by the first rib (101) and the second rib (102), and said device further comprises: - a third rib (116) extending in the y-direction and in front of said plurality of light beams (113), - light sensing means (115) located on said third rib (116) being accessible by each of said plurality of light beams (113), - an interconnecting rib (117) extending in the z-direction and configured to interconnect said first and third ribs (101, 116), said first and third ribs (101, 116) being kept parallel and in the yz plane independent of the relative position of said first rib (101) , - an integrated bench (1 12) which is interconnected with the second rib (102) by interconnecting means (126) and which is stationary or foldable in a plane perpendicular to the plane as they are av niered by the first rib 10 (20) and the second rib (102), - a second light emitting device (120 or 123) located on the interconnecting rib (117) and which consists of (a) a single laser (123), said single laser (123) being superficial along said interconnecting rib (117) and emitting a single light beam (124) and provided with means for relative z-position determination (125), or (b) a number of lasers (120) located at a distance of 0.1 to 5 mm from each other, said number of lasers (120) are placed in a row along said interconnecting rib (17) and emit a number of light beams (121), the direction of said individual light beam (124) or number of light beams (121) being parallel to the direction of the first rib (101) and towards said person ( P). The device according to claim 9, wherein the light sensing means (115) consists of (a) a fl number of photoelectric sensors, said photoelectric sensors being synchronized with said str number of light beams (13), each of said sensors being capable of detecting information caused by corresponding light beam resulting in an individual positive light indication signal, or (b) an individual sensor wherein the illumination of said light sensing means (1 15) with one or fl era of said fl number of light needles (1 13) results in a positive light indication signal, wherein said device further comprises: - laser selective sensing means (127) provided on said integrated bench (112) configured to provide a positive light indication signal when illuminated by one or more of said number of light beams (121) or said individual light beam (124), and - a control unit (11); 1), configured to (a) read input that includes one or more positives (a) 10 15 20 25 30 ll. 12. 533 874 'light indicator signal (s) å- from said light sensing means (1) or from said laser selective sensing means (127), (b) provide excitation signals including signals to said light sensing device (104) or said fl number of lasers (120) or said individual laser (123) wherein each of the fi- of any of said device or laser emitted light beam (s) can be individually turned on or off in accordance with an algorithm. A system for estimating body fat mass and degree of obesity in a person (P) by determining two-dimensional coordinates, comprising a device according to any one of claims 1 to 8, and an extension unit (1 10) for placement on a person (P), so that said extension unit (l 10) functions as an extension of the body of said person (P). The system of claim 11, wherein said extension unit (l10) is rod-shaped and further comprising: - light cutting means (118) in the form of a series of a number of photoelectric sensors along said extension unit (l 10), and wherein - the light riveting device (104 ) emits a plane of light configured to illuminate said extension unit (110) when placed on a person (P). A method for estimating body fat mass by using anthropometric measurements as a proxy measurement for the degree of obesity in a person (P), and by determining two-dimensional coordinates from the sagittal plane of a person (P), using a device or system according to any of claims 1 to 8 or 11 to 12, comprising the steps of: (i) placing the device (100) with the first rib (101) extending in a vertical direction and the second rib (102) extending in a horizontal direction; 14. 15. 533 874 Zb direction and the emitted light from the light emitting source (104) is directed towards the intended place of measurement of said person (P), (ii) placing said person (P) on his back on a flat surface in the horizontal plane with the sagittal plane of the body towards and parallel to the plane defined by the first bar (101) and the second bar (102) of the device (100), and (iii) registering at least two limiting y-coordinates of said person ( P ). A method for estimating body fat mass by using anthropometric measurements as a proxy measurement for the degree of obesity of a person (P), and for determining two-dimensional coordinates from the fi ontal plane of a person (P), using a device or system according to any of claims 1 to 8 or 11 to 12, comprising the steps of: (i) positioning the device (100) with the first rib (101) extending in a horizontal direction and the second rib (102) extending in a horizontal direction and the light being emitted from the light emitting source (104) is directed to the intended place of measurement of said person (P), (ii) placing said person (P) on his back on a flat surface in the horizontal plane with the frontal plane of the body towards and parallel to the plane defined by the first bar (101) and the second bar (102) of the device (100), and (iii) registering at least two limiting y-coordinates of said person (P). A method for estimating body fat mass by using anthropometric measurements as a proxy measurement for the degree of obesity of a person (P), and for determining two-dimensional coordinates from the frontal and sagittal plaries of a person (P), using a device or a system according to any one of claims 9 or 11, comprising the steps of: (i) placing the device (100) with the first rib (101) extending in a vertical direction and the second and third ribs ( 102, 116) extending in a horizontal direction and the interconnecting rib (117) extending in a direction perpendicular to the plane defined by said first and second ribs (101, 102) and interconnected with said first and third ribs (101, 116) , the emitted light from the light emitting source (104) and tal ertal of lasers (120) or individual laser (123) are directed towards the intended location for measurement of said person (P), (ii) placing said person (P) on the back on said i integrated bench (112) arranged in the horizontal plane with the sagittal plane of the body against and parallel to the plane as they are av niered by the first rib (101) and the second rib (102) and the fi ontal plane of the body being perpendicular to said fl number of light rays (121) or said individual light beam (124), and (iii) registering at least two limiting y-coordinates in the sagittal plane and at least two limiting z-coordinates in the frontal plane of said person (P). A method for estimating body fat mass by determining the two-dimensional coordinate plane of the sagittal plane of a person (P) from which said body fat mass is subsequently estimated, using a device or system according to any one of claims 1 to 12, comprising the steps of: - placing a person (P) on the back on a flat surface in the horizontal plane, - record the x, y coordinates of the upper part of the right leg (M1) of said person (P), - record the ray coordinates of the lower part of the ribs (M2 ) of the approached person (P), - record the y-coordinate of a horizontal reference line (L3), where said reference line (L3) corresponds to the intersection between the body of said person (P) and said flat surface, and - record the y-coordinate of the uppermost point of the body (M4) of said person (P) along a vertical line (L1) extending vertically from the center of an imaginary line between the upper part of the right leg (M1) and the lower part of the ribs (M2) , - register the y-coordinate (M5) of the top of the sternum of said Person (P), - calculate the vertical distance between said uppermost point of the body (M4) and said horizontal reference line (L3), and - calculate the vertical distance between said top of the sternum and said horizontal reference line (L3).