ES2232315B1 - NEW DIGITAL PHOTOOPTOMETRIC PODOMETER APPLICABLE TO THE STUDY OF THE MORPHOLOGICAL FORM, CUTANEOUS MAP AND TWO-DIMENSIONAL PRESSURE MAP OF THE FOOTPRINT FOOTPRINT OR POSTURAL BRAND OF A PART, OR THE WHOLE, OF THE BODY OF A HUMAN BEING, ANIMAL, VETO MATERIAL. - Google Patents

Abstract

New Digital Photooptometric Pedometer applicable to the study of the morphological shape, cutaneous map and two-dimensional map of pressures of the footprint of the plantar foot or postural mark of a part, or of the whole, of the body of a human, animal, plant or material object. It comprises a transducer (10, 11), transparent (18) or translucent (19, 20) (24) multiple layer, mounted on an Optical Unit (3) where a sensor zone (11) is defined that is read, by means of a unit mobile linear CCD reader (4, 5), which moves along guides (12) so that an image of the object to be studied is obtained according to the pressure, shape, profile and cutaneous aspect of said object or body structure . The capture of the map of information points or image of the footprint is processed by obtaining an image of the object or analysis that incorporates information related to the cutaneous map of the foot, pressure map and structural map of the vault of the foot.

Description

New applicable Digital PhotoOptoMetric Pedometer to the study of morphological form, cutaneous map and map two-dimensional pressures of the plantar footprint or mark postural of a part, or of the whole, of the body of a human being, animal, vegetable or material object.

Technical sector

This New PhotoOptoMetric Pedometer has its actual application within the following fields: Podiatry, Podiatry or similar; Orthopedics; Traumatology; Surgery Traumatological; Rehabilitation; Pediatrics; Physiotherapy; Medicine of Sports and any health, sports or social field in the that this Pedometer is feasible to be used as it appears from its actual operating possibilities described in this document.

It is also applicable to the fields of Systems security; Access Control or Presence; Forensic Medicine e Criminal and Police Investigation.

Its function is the capture of snapshots of High precision of the Cutaneous Map of the object under study, (foot, hand, finger), which allows assessing the degree of pathology of the individual and avoid deteriorating people's quality of life affected.

Its function is to capture Pressure Maps of high reliability that enable the assessment of the degree of plantar biomechanical pathology and facilitate the competent professional the information necessary to mitigate damage, or improve quality of your patient's life.

Its function is to prevent detection of anomalies where these could be of sufficient value to avoid the appearance of foreseeable pathologies in the course of The life of an individual.

Its function is measurement, qualification colorimetric and numerical quantification of the object under study that allow a structural and morphological assessment of the foot, hand or part of the human body that allows assessing the degree of pathology of the individual and avoid deteriorating the quality of life of people affected by the construction of appropriate braces to each case and function based on the information that the new Pedometer can facilitate.

State of the art

For a better understanding of the capabilities of the New Pedometer, which is presented in this report, has been considered that the study of the pressures of the human foot on the ground is more clarifying than the study of hand pressures, or of a finger or that of any other structure could represent. This exhibition has didactic purposes and cannot be considered as limiting or restrictive of the applications or functions that the New Pedometer can perform.

From the beginning of human ambulation, the sustenance of balance is effected on the soles of the feet and its biomechanical structure completes the fruit of evolution, which does not always follow a single response pattern, before modifications structural that the human body presents to adapt to a new biomechanical and energy saving body scheme.

From this evolution, intuited by our ancestors, the need to understand the reason for the structure of the foot, its footprint and its pathological evolution.

For this, a study was initiated, a consequence of the means of each moment, which are broadly outlined in the following lines:

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in first the direct observation of the foot by the human eye and its manual palpation were surely the work tools of The first doctors.

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then a system of impression of the footprint on soft clay bases to study the different depths that the foot presented.

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Plus forward, seeing the importance of the shape of the footprint in support, devices were designed to register it and be able to Compare the various footprints over time. To this period simple machines belong that allow obtaining a tracing or copy of the human footprint. Among these teams are they can point to the Ink-Based Impression; or the taking of printing using fats and oils; Impression taking by dyes in general.

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The later evolution led to combine in another machine the system of ink printing on paper with elastic elements creating the Ink photopodogram of Scholl and others of similar function.

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Other similar attempt was to use photography systems, impressions of  ink and liquid photographic developer on paper than the time Current has given us.

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With the advent of the electronic technique machines were developed that  by means of electroinductive, piezoelectric sensor arrays or piezoresistive attempts to assess different pressure points and from this data an image similar to the map is simulated planting of pressures of one foot with the help of a system computer annex. Unfortunately they don't have much resolution currently, so, the images that are obtained, although Useful, they are not complete. In the 1980-1990s the density of sensors was one per square centimeter of useful platform In the decade of 1990-2000 the sensor density was two to four per centimeter of useful platform While the technology is advanced, the prospects are not very good because with the current technology, the increase in sensor density, implies a higher density of printed circuits and this leads to energy losses in the form of heat that exponentially increases the noise of the signal read by the sensor. Fact that significantly hinders accuracy and effectiveness of these new machines.

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Other interesting attempt to read the plantar map has been the optical platform, (which from the beginning of the podoscope of crystal that displays, without registering, the plantar supports from of the reflection that occurs in a mirror), has improved so spectacular the possibility of the study of the foot since it has built-in a depressive tapestry on a transparent surface illuminated with tangential or transverse fluorescent light, (light fluorescent which is not stable or constant in its emission), and a dark camera that incorporates a filming system that captures the footprint with a resolution in information points that exceeds a lot to all the equipment and machines that have previously been commented. This machine is described in the invention patent requested in Spain with the number 8703571, which describes a "Pedometer, by video-pneumatic procedure for the study of plantar pressures and simultaneous obtaining of the mold for making corrective templates. " applicant makes special mention of this patent because it is the one that It is closer to the biomechanical reality of the foot. While in it I know they mention two different machines, one for the study of footprint, (mentioned above), and a different one with components tires for obtaining the mold, in load, of plaster of the foot.

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The previous invention patent has had, (in its objectives and some of its elements), some variants embodied in other patents of invention such as the one with the number 009800933, "New pedometer applicable to the study of the plantar footprint of a person ", and utility models embodied in application number U 9401359, "Device for the distribution analysis of pressures ", of which the applicant for this report has knowledge. These new attempts have not brought an advance significant in terms of the resolution of the data obtained, nor in terms of the ability to correct the optical distortion that is inherent to the optics that film systems entail short distances, nor have they been able to provide reliability to the making the real size of the plantar footprint, nor have they got get visual information of the structure of the plantar vault at real scale for owning opaque bodies to the vision between the camera of video that records the image and foot of the subject to study.

All these machines have served to bring us closer more to the study of the plantar footprint, but all give a version of the same subject that suffers from one or another important characteristic, to know: Some equipment, the electronics, prevail the mathematical calculation of pressure at one point of the foot but neglect the density of sensors leaving important dark areas that they cannot capture and they may be vital in the injuries or difficulties that the foot presents; Other equipment, the optics, prevails the resolution but they cannot quantify foot pressures because they are based in fluctuating and non-stable lighting systems such as tubes of fluorescent light that they state in their descriptions. Likewise, they cannot by design obtain readings from areas that are not in contact with the sensor, so that aerial structures, such as the arch and the plantar vault of the foot cannot detect them if they do not they are in contact with the ground and also have pressure significant.

In the same way all the equipment described, electronic and optical, obviate skin surface analysis of the foot, affecting only the attempt to study the pressure that this one supports in the process of the human march if to consider that the cutaneous surface is closely related to the aggressions caused by the force vectors that originate the overpressures on the sole of one foot.

While there are currently machines that are able to photograph an object, and even a foot, such as traditional or digital photo cameras; also exist office equipment that is capable of copying an image from a paper or a photographic negative, such as scanners desktop or office. But none of the previous teams noted in this paragraph are able to capture the footprint under load, that is, exerting pressure. A camera captures depths and visual perspectives, but it is impossible to capture the pressure that exists at one point of the foot without the help of others mechanisms or devices An office or desktop scanner you can digitize a photo, a drawing or a thin body as a sheet of paper, but is unable to capture volumes, distances from soil to the plantar vault and much less bear the weight of a adult individual The crystal that you use as the base of the sheet a Scan is thin and brittle. It can't be thicker because that the resulting image is distorted in size, resolution and color gradient This glass thickness is a character limitative.

That is why before the existing vacuum created by previous machines and systems it was designed, developed, built and verified a prototype of the New Pedometer Digital PhotoOptoMetric that allows the study of the footprint planting, handprint, fingerprint and fingerprint or postural mark, of part or all, of the body of a being human, of a non-human animal being, of a plant entity or of a inanimate object.

This New Digital PhotoOptoMetric Pedometer allows within the human species, the study of the form Foot morphology, the study of the biomechanical structure of foot, the study of the cutaneous map of the foot, the study of the map two-dimensional pressure exerted by the foot in load, both in static posture as in dynamic posture, and the study of the map three-dimensional structural of the plantar vault, retropie, mediopie, antepie and support of the fingers or pulp of the same on the wandering sign in human march.

The New Digital PhotoOptoMetric Pedometer that proposes this memory solves and overcomes the previous obstacles. Therefore, and for these characteristics, we state that the applicant is not aware of the existence currently of an invention that is endowed with the characteristics indicated previously as the most suitable in the study, function and application of the study of the plantar footprint, footprint of the hand, fingerprint of a finger and the fingerprint or postural mark, of a part or all of the body of a human being, of an animal being non-human, a plant entity or an inanimate object.

Explanation of the invention.

The large number of attempts in the search for media, machines and systems that allow the study of the footprint plant from the point of view of the pressures that are exerted on the ground demonstrates the great importance it has, for the human population, being able to properly treat problems support biomechanics, function pathologies, injury and evolution that presents the foot.

It is consistent to believe that a new medium, machine or system, which allows to assess, measure and analyze objectively the concrete state of an individual's feet will be a tool more than the healthcare professional (doctor, podiatrist, orthopedic or similar) will be available to alleviate injuries, correct trajectories of foreseeable evolution and especially prevent in child populations the appearance of pathologies that could invalidate the individual personally and increase the social cost by Been unnecessarily.

The purpose of this specification, in This patent application refers to the New Pedometer Digital PhotoOptoMetric applicable to the study of the form morphological, biomechanical structure, cutaneous map, map  two-dimensional pressure exerted on a smooth surface or curve, (be it hard or soft), and to the three-dimensional map structural that follows from said applicable form and structure to any part of the human body, (which can comprise a foot, a hand or a finger), of an animal, a vegetable or an object material.

The New Digital PhotoOptoMetric Pedometer, where more incidence may have as a consequence of the quality of the information that can be obtained, (among many other fields of possible study), is within the field of Orthotics Podiatric, Orthopedic or Traumatological, within the species human, in relation to the study of the morphological form of the foot, to study of the biomechanical structure of the foot, to the study of the map of the foot, to the study of the two-dimensional map of pressures that exerts the foot in load, both in static posture and in posture dynamics, and the study of the three-dimensional structural map of the plantar vault, retropie, mediopie, forefoot and finger support or pulps of the same on the wandering sign on the march human

One of the objectives of this New Digital PhotoOptoMetric Pedometer is to obtain an information map relative to the pressures exerted by the foot on the surface of the Pedometer, or an information map relative to the heights that can be seen in the arc, vault and base of the foot, or, a map of cutaneous information that incorporates, with a great resolution, the details that can indicate to a medical or sanitary professional the state of said structure, so that it allows him to decide on the degree of injury , pathology or damage that presents or may present in the future, or even, the remains of the lesions that would have suffered in a past time at the time of the study with said new
pedometer.

The invention has as one, not the only one, of its fundamental characteristics the capture of the pressures, in the case study of the foot, in position called Static, (standing or single operation), of relative rest; in position called Dynamic, (heel entry, half foot support, support forefoot and toe take off), in motion; If from the study of the hand, the collection of pressures is carried out in support position with the base of the hand, fingers, knuckles, being able to be open, semi-open or closed at the moment that the palm pressure map is read, or in the moment of reading its biomechanical, structural structure or cutaneous

This information can be monitored in a display screen (digital or analog television), system IT or similar. The information provided by the New Digital PhotoOptoMetric Pedometer is conducted to a system computer external to the Pedometer, where it is digitally processed or analogically until the images are obtained from the maps set forth in previous paragraphs.

With appropriate computer application programs such information is analyzed and obtained, with precision unprecedented to date pressure maps, skin maps, structural maps and three-dimensional maps of the object, plant, animal, foot or hand or part of the human body analyzed.

With this information, obtained through New Pedometer is able to colorimetrically qualify the alterations presented by the object under study, be they pressures plantar, plantar vault structure, or alterations or injuries Cutaneous foot. A quantification of: plantar pressures, of their centers of gravity on each foot, of center of gravity of the human body, of displacement in the space of said centers of gravity in both support positions Static as Dynamic, whether in the unipodal phase of support as in Bipodal support phase.

Description of the invention

The new Digital Optometric Pedometer that is invention proposes for the study of the footprint of the plantar foot, handprint, fingerprint of a finger and fingerprint or mark postural, of a part or of the whole, of the body of a human being, of a non-human animal being, a plant entity or an inanimate object, it comprises a series of units differentiated by their function that together properly allow to obtain the results that in other sections of this report are stated, described or comment.

For a better understanding of the invention it will be used, just as an example, (and can never be a limitation of possibility, application, composition or function), the study of the foot human; always remembering that what is described below is also applicable to everything stated in the first paragraph of This section Description of the invention.

The new Pedometer listed includes a Unit Positioning of the foot or object under study; a unit Transducer of the load, structure, or cutaneous appearance thereof; An optical unit; a Light Energy Generating Unit within of a specific range of the electromagnetic spectrum; a unit Reader; a Motor Unit; a Unit of Filtering, Adjustment and Rebalanced; A Structural Unit supporting all units or previous modules and a Communication and Transmission Unit of the information with other external equipment for the purpose of this invention.

The Positioning Unit is usually in the Upper part of the Pedometer and can be a mesh, a printed reference frame or similar, or an area that delimits the Useful area sensor pedometer. Indicates the user, operator or Handler of the same where you must place the object under study or foot of the person for the Transducer Unit to enter functioning.

The Transducer Unit, is formed by a set of elements that cover the optical unit. This elements they can be transparent to the light energy that will be used to Perform readings or feedback. They can also be from translucent nature and even opaque nature to the transmission of light energy used. In the case described as transparent, the transducer can even be obviated but the quality of reading the information that is obtained, although effective, is significantly smaller than if said transducer is used. So in some cases, such as the cutaneous reading of the foot, its morphology, its vault structure, and the pressure map can be carried out directly on the optical unit. It doesn't happen the same form in the reading of plantar pressures where, although the image Morphological foot is obtained with excellent quality, and the plantar pressures with good quality without the transducer unit, plantar pressures significantly improve if a flexible and slightly depressing transducer. Both mechanisms are perfectly valid. The existence or not of the Transducer Unit It will be defined by the use or application that at any given time is want to give the New Pedometer, said Transducer Unit being fixed or removable, whether reusable or not. The composition of the Transducer It can be monolayer or multilayer. The most common is the multilayer since it allows to combine depressive, elastic and semi-rigid, with controlled elastic memory, and even with meshes  that have differential density cells to simulate the signaling of areas and / or disjoint and discrete points of Pressure.

The optical unit consists of a transparent prism to the light energy emitted by the Power Generating Unit which has parallel, upper and lower face, being able to be the lateral faces at an angle of 90 degrees, or even at an angle different depending on the function or application you want to obtain or get. Its function is to channel the reflection of light with significant information of the object (read foot) to the sensor reading. It also has a function of supporting the dough body of the object or individual under study.

The Light Energy Generating Unit can be of three types according to the location where it is installed, namely: 1: it can be located under the prism and be mobile; or 2: it can be located on one or more of the sides of the prism and be mobile or 3: it can be located on one or more of the sides of the prism and being fixed in space. The light emission must be such that the prism does not absorb it, nor deflect in its entirety, so that the foot interaction, or object under study, when exerting pressure on the Transducer Unit and through it the forces on the prism generate a map of points, (each of they will represent a pressure), of very high definition, consequence of combined refraction and reflection phenomena, which the Reading Unit internal to the global structure of the New Pedometer will capture for further processing, transmission and stored.

The Reading Unit consists of a row of sensors photosensitive to the spectrum of light that the optical unit filters and use to form the information points at the bottom base of said optical unit. The photosensitive sensors can be arranged in flat or curved matrices, with provisions of N. Rows and M. Columns, where N and M can adopt integer values Strict majors of zero, such as 1, 2, 3, ..., etc; being the one-step reading unit, (with a sweep it get the image generated by the pressure transducer), or three steps, (a sweep is needed for each of the three colors basic components that make up a Red, Green and Blue image), with which said Reading Unit may not represent a limitation to the New Pedometer. The sensors used can be of different types, ways, technologies and work with limited or extensive ranges of radiation, both in signal emission and reception of wavelengths The most sensitive sensors are facilitating are those of the CCD type (Load Attached Device -electric-) that receives the light that is sent from the image to through the prism and converts it into controlled electrical signals for the intensity and color of the image, in the same way in That one eye works. It should be noted that this radiation used electromagnetic is always outside the spectrum of the radiation considered harmful or considered dangerous for beings humans.

The Reading Unit uses the principle of flatbed scanners in which the light source and the CCD sensor, are found coupled in a mobile arm that slides through the Motor unit by guides and below the prism that supports The transparent or translucent pressure transducer.

The sensors used can be of different types, form, function and nature to which they are currently described being able to incorporate to the Reading Unit other different than not they alter the function for which said unit has been designed. The Reader Unit can use sensors of type CIS (Image Sensor Contact) with a simple quality; PMT (Photomultiplier tube) Higher quality or CMOS (Metal Oxide Semiconductor Complementary) of lower quality and low cost, but usually better result the CCD sensor.

The Motor Unit comprises a band located under the Prism that is included in the Optical Unit, which supports the Reading Unit, (and in some variants or embodiments the own Light Generating Unit). This band can go subject to a displacement system along one of the axes of the prism, so that the combination of the width of the band  sensor, of the Reading Unit, together with the displacement that carried out along said axis allows the reading of each and every one of the information points that the right combination of Units described above have created, such as the cutaneous map of the foot, or its structural plantar map (vault plant), either the morphological map of the foot, or the map of plantar pressures of the foot.

The Filtering, Adjustment and Rebalancing Unit refers to the treatment of the information that the Unit Reader has captured. The Reader Unit captures light signal, inside of a segment of the specific electromagnetic radiation spectrum, and this is transformed into an electrical signal for transmission or driving to computer devices, or vision devices external to New Pedometer This Unit is responsible for filtering the possible electrical noise, adjust the signal for optimal transmission and rebalance the electrical, magnetic and optical fluctuations that The current state of technology provides. As the electronic elements, parts or devices evolve this Filtering, Adjustment and Rebalancing Unit will ensure that the New Pedometer be able to communicate with new devices information processing that we hope will arise from minds restless and forward looking.

The Communication and Transmission Unit of the information establishes the channel for sending information up to Information processing unit external to the New Pedometer, (currently it can be a simple screen or TV monitor, or either a sophisticated image processing system, or a current and operational computer system in the market). The communication of the New Pedometer with said external unit of Information processing cannot be considered a limitation of same, since the New Pedometer allows a cable communication physical, (such as parallel port, serial port, USB port, or any communications port deemed reliable), or well it allows a communication by means of the emission of waves of electromagnetic nature, (infrared, telemetry, etc.), waves radio, sound and photooptic and any means that the state of the technique allow in every moment.

The Structural Unit supports all previous units or modules sustains, integrates, correlates, connect and protect the different Units from external agents described above for the New PhotoOptoMetric Pedometer Digital. It consists of a parallelepiped-shaped structure, which supports inside the Motor Unit, which in turn supports the Reading Unit The movement guides of the motor unit they can be protected with a second housing, (housing that can be optional), and be enclosed in a space protected by a rigid rigid material plate that prevents contact with elements outside the New Pedometer, (especially plaster powder or organic powder as skin peels so common in Orthopedics, Podiatry and Traumatology consultations), and guarantee constant operation of the same for periods of time acceptably long.

The Structural Unit also supports the Unit Power generator that can be mounted on the same band mobile that supports the Sensor and Sensor Unit, or it can be in some lateral cavities available to the main prism of the optical unit, as the case may be. The prism The main optical unit is supported by the sides of the chassis using a band of sufficient width to support the pressure to which the prism will be subjected during use and Pedometer function. The main prism can present in a of their faces the Positioning Unit in printed form, silkscreen, painted or lacquered, fixed or removable.

The top finish, in a metal, steel, frame Polycarbonate or plastic derivative, guarantees the stability of all internal mechanisms and units, as well as a protection against possible injuries that such mechanisms could cause patient if these were not protected.

The collection of the map of information points or Image of the footprint, or generic imprint, can be: 1) by physical contact with the Positioning Unit and exercising pressure on the pressure transducer; 2) by contact physical with the transducer but without exerting significant pressure; or well 3) no physical contact when using a transducer transparent to the light beams that circulate through the optical prism; the three previous points being relative to distance existing between the surface of the reading transducer and the surface to read (for example foot base). This allows the obtaining the cutaneous map of the foot with the pressure map to real size integrated in it; or, the cutaneous map of the foot with the morphological footprint of the foot in load and / or discharge .; O well, the three-dimensional structure of the plantar vault and the thickness of the plantar arch that is in contact with the ground.

So the New PhotoOptoMetric Pedometer Digital combines the potential of the CCD readers used in a Flatbed scanner, with an optical prism, or additional lens, superimposed that filters the points of light that result from the shape, structure, significant pressure and support that the foot or hand exerts on the transducer tapestry that integrates the Transducer Unit. The presence of the crystalline prism of the optical drive is crucial for the reading of the pressures given that it supports the weight of the individual to study, stabilizes the flow of light that affects the part Transparent or translucent lower transducer, and allows capture the depths and heights that the vault of the foot has without apparent distortion. Three features that flatbed scanners desktop or office do not allow or own.

Description of the drawings

For a better understanding of the New Pedometer Digital Optometric proposed by this invention, and only by way of For example, some drawings integrated in the figures are attached 1, 2, 3, 4, 5, and, 6, which complement the explanation description of the invention.

In the figure no. 1 describes the structure global that the New Digital Optometric Pedometer presents in its reading mode in Din A4 format that specifically applied the human foot allows the reading of one foot or one hand in an adult It also allows reading the information of a plant, animal or object.

In the figure no. 1 you can see a frame upper external (1) that protects the internal parts and that supports the Positioning Unit (2).

In the figure no. 1 the Unit is also observed Transducer (3) that is available to the Shape, Surface, Structure and Pressure (4) than the different objects under study can present; such as the human foot (9), the human hand (10), an animal such as a worm (11), a vegetable such as a sheet (12) or even an inanimate object such as a key (13).

In the figure no. 1 different ones are appreciated important elements such as vents and aeration (5), the connection base (7) to the supply source energy and digital connection base (6) for the transmission of the information to an external computer unit to this one New Pedometer.

In the figure no. 5 describes the exploded view of the structure that the New Digital Optometric Pedometer presents in its reading mode in Din A4 format that applied specifically the human foot allows the reading of a single foot or of One hand in an adult. An external framework can be seen upper (1) that protects the internal parts and that supports the Positioning Unit (10).

In the figure no. 5 the Unit is also observed Transducer (2) that is segmented into two disjoint zones, one opaque to light (2) and another that is the area sensitive to measurement (11) by the Reading Unit located just below. Under Transducer Unit (11) is the Optical Unit (3) that It acts like a giant lens. This lens has a prism shape and is transparent to the frequency of electromagnetic radiation generated by the Light Energy Generating Unit (4).

In the figure no. 5, just below the prism that acts as a lens, is located the Motor Unit that supported by some rails (6) allow the displacement, in a Cartesian axis, of the structure that supports the Light Energy Generating Unit (4) and of the Reading Unit (5). The power generating unit light emits the light beams that after a refraction process and of reflection combined in concrete sequence and affections for a Repeatability factor will affect the Reading Unit (5). He combined displacement along the rails (6) of the Generating Unit of light energy and the Reading Unit which is formed by photosensitive sensors to emitted radiation, enable reading the information points related to the provision of the Shape, Surface, Structure and Pressure that the different objects to study may present; as they are: the human foot, the human hand, an animal like a worm, a vegetable like it can be a sheet or even an inanimate object such as a key.

In the figure no. 5 also appreciate the Structural Unit (8) support of different important elements such as the ventilation and aeration grilles (16), the connection base (15) to the power supply source and the digital connection base (16) for the transmission of information to an external computer unit to this New Pedometer.

In the figure no. 5 is detailed, inside the Structural Unit, the Filtering, Adjustment and Rebalanced (7), and the Communication and Transmission Unit (9) of the information to other teams external to this one New Pedometer.

In the figure no. 5 a reference to a Light Energy Generating Unit (17) alternative to the described above (4). This new unit can coexist with the first described but for the measurement of the pressure of a Any body enhances the accuracy of the pressure map. This unit (17) is formed by a closed housing (27) completely and wrapped in a dark chamber (28) that does not allow the escape of the light generated by the main source (29). Light rays generated by the source (29) are imprisoned within the dark chamber (27) and are channeled to the side of the prism or lens (3). The prism or lens (3) incorporates two zones of filtering and conduction (30) (31) of the light beams by both faces. The material of these areas is attached to the wall molecular prism or lens so that it is inert to changes thermal sources that the light source itself causes due to its proximity. The light beams (32) thus filtered are imprisoned within the prism or lens awaiting interaction with the Unit Transducer, which when activated by the pressures made by the object under study, issues the points that will generate the map of pressures of it.

In the figure no. 5 is detailed, so schematic the different basic modalities that the Unit Transducer (11) can adopt according to the desired function Activate. If the cutaneous map reading is desired, the transparent transducer (18) although to obtain said map Cutaneous can be missed by losing some quality; if you want the reading of the plantar pressures or the biomechanical structure of the foot can be used bilayer transducer (19,20), trilayer (21, 22, 23) or the multicellular mat (24). The transducers are formed by homogeneous materials that have properties of transparency, ductility, elasticity and the so-called elastic memory concrete for the application that has been designed the New Pedometer described. By interacting with the various materials between yes, combined with the firm that presents the lens or prism by a side, and the pressure exerted by the other side of the Unit Transducer get depressed, change size, color and density acting as agents modifying the light intensity of proportional to the pressure exerted by the object, foot or hand causing such action. The result is a difference of light intensity, which filtered from background noise, is captured by the Reading Unit, processed and sent to the Unit of Communication and transmission of information to a system external computer Image that will be translated as convenient computer programs for analysis and simulation to transfer the information captured by the New Pedometer in a format that is readable and easily interpretable by the human eye of Sanitary professional.

In the figure no. 6 one is appreciated, not the only one, of the novelties included in the New Pedometer: A mat cell (2), which is part of the Transducer Unit located in the figure no. 5, located above the firm that presents the prism or lens that forms the optical unit (1). Said cell mat it is formed by a mosaic of equal cells arranged in rows and columns forming an array of discrete points. These cells (3) they are physical sensors that react to pressure by modifying their length, thickness and also the color and density, although these two Latest features are not essential. The cells are integrated into a matrix that supports them and defines the pressure point reading resolution per square centimeter of transducer surface. Being 1, 4, 9. 16 and 25 values usual per square centimeter that the New Pedometer gets with this new cell transducer.

Figure no. 6 presents the different strain gradients (10) that the cell (3) can adopt (4, 5 and 7) according to the intensity (6) of the applied force (8, 9) on The surface of the physical sensor. The base of the sensor or cell rest on the prism firm (1) that integrates the optical unit of the New Pedometer.

Embodiments of the Invention

Although a mode of realization in the Description of the Invention section considers it pertinent to describe externally and globally different embodiments of the invention to shape Clear and unambiguous the possibilities posed by the New Pedometer. All these embodiments comprise the same structure, composition and function that the example embodiment outlined in the figure no. 5 and described in the Description section of the Invention. It varies only its shape, size and function but maintains its constant principles.

In the figure no. 2 is described, as a possible realization different from the first, the overall structure that a the New Digital Optometric Pedometer presents in its modality of reading in Din A3 format that specifically applied to the human foot allows the reading of both feet or both hands at the same time an adult. You can see a superior external frame (1) that protects the internal parts and that sustains the Unit of Positioning (2).

In the figure no. 2 the Unit is also observed Transducer (3) that is available to the Shape, Surface, Structure and Pressure (4) than the different objects under study can present; such as the human foot (9), the human hand (10), an animal, a vegetable or even an object.

In the figure no. 2 different ones are appreciated important elements such as vents and aeration (5), the connection base (7) to the supply source energy and digital connection base (6) for the transmission of the information to an external computer unit to this one New Pedometer.

In the figure no. 3 is described as another possible realization different from the previous ones, the global structure that the New Digital Optometric Pedometer presents in its reading mode in stretcher format that specifically applied the human body allows the reading, at the same time, of the whole body which is in the reading plane of the Transducer Unit (3). Be can appreciate a superior external framework (1) that supports the internal parts and which supports the Positioning Unit (2).

In the figure no. 3 the Unit is also observed Transducer (3) that is available to the Shape, Surface, Structure and Pressure (4) than the different objects under study can present; such as the human foot (9), the human hand, a animal, a vegetable or even an object.

In the figure no. 3 are appreciated different important elements such as vents and aeration (5), the connection base (7) to the supply source energy and digital connection base (6) for the transmission of the information to an external computer unit to this one New Pedometer.

While in figures numbers 1, 2 and 3 it is pose different formats of the same New Pedometer, in all they the force applied on the surface of the Unit Transducer is always perpendicular. In the figure no. 4 se describes, as another possible embodiment different from the previous ones, the global structure that a the New Digital Optometric Pedometer presents in its reading mode in Din A3 format and in a plane inclined, acting the force applied on the Unit Transducer at an angle other than 90 degrees, which applied specifically the human foot allows the reading, at the same time, of the two  feet or both hands in an adult. With what you can get information on pressure differences and map appearance cutaneous existing between two different readings at times consecutive. You can see a superior external frame (1) that protects the internal parts and that sustains the Unit of Positioning (2).

The drawings expressed in figures number 1, 2 3 and 4 describe the same New Pedometer in different ways, provisions and functions that allow the static study of the tread and the dynamic study of human gait among others.

In the figure no. 4 the Unit is also observed Transducer (3) that is available to the Shape, Surface, Structure and Pressure (4) than the different objects under study can present; such as the human foot (9), the human hand (10), an animal, a vegetable or even an object.

In the figure no. 4 different ones are appreciated important elements such as vents and aeration (5), the connection base (7) to the supply source energy and digital connection base (6) for the transmission of the information to an external computer unit to this one New Pedometer.

Industrial application

The new Digital PhotoOptoMetric Pedometer is feasible to develop and manufacture it industrially because all the elements are tangible and locatable in the industrial sector current. It is the combination of all of them properly for obtain the functions and benefits set forth in the title itself of this memory what gives the new pedometer its features of world novelty and that make it different from all the equipment and machines that have been built, as far as it has knowledge of the applicant, for the study of all functions that this new pedometer allows.

This New Digital PhotoOptoMetric Pedometer has been designed to have a low economic cost and to arrive easily to the entire population; to provide a support service to the medical professional, graduate, graduate, researcher and teacher; so that all citizens can benefit from the information you provide about the state of your skin pathology or biomechanics; and so that risk populations such as diabetics, child populations, practitioner populations Sports, professional and amateur, know how to preventive what is its cutaneous and biomechanical plantar state and avoid health problems, unnecessary costs, (for the subject and for the State), and sufferings associated with pathologies that may be treated if its evolution is known in time.

Its application is clear and concise, reading the plantar pressure map, reading the cutaneous map of the foot with the supports included and reading of the morphological structure of the foot.

Your presence in hospital centers, consultations of traumatology, podiatry, orthopedic centers, centers Sports and sports medicine centers will allow you to find, treat and prevent everyday health problems that affect The generality of the population.

Its presence in pediatric centers will allow apply prevention effectively and economically for the State and the particular population Since in children's and youth stadiums the incipient problems will be detected from the population and may initiate a long and medium term treatment by rehabilitation  postural first, and then with orthotic treatments or insoles If these were necessary. Avoiding in this way reach deteriorated biomechanical situations that can only be alleviated through surgery, absolute rest or a motor disability that It often involves the use of a wheelchair or similar. Biomechanically considered terminal situations that many sometimes they cause a serious psychic breakdown in the individual that suffer

The New Pedometer has been designed so that staff with limited computer skills can use them with minimal learning, with which the auxiliary staff at medical professional, or specialized professional, may perform the foot information collection, while the doctor focuses on  the personal assessment of the patient and instantly assess the results that the New Pedometer facilitates, and thus not slow down the work dynamics of medical centers.

The cost of manufacturing, marketing and maintenance is estimated well below the commercial cost that they own other machines or systems that read the plantar pressures such as optical equipment and electronic equipment. By what follows that the access of this New Pedometer to the general population should not involve more difficulties than usual to normal commercial exploitation.

Also for its technical characteristics, its size, its design and immediate application possibilities can be Hopefully, this New Digital PhotoOptoMetric Pedometer can enter the export market of goods without major difficulty.

Claims (13)

1. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural that follows from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating a Positioning Unit of the foot or object under study; a Transducer Unit of the load, structure, or cutaneous aspect thereof; An optical unit; a Light Energy Generating Unit within a specific range of the electromagnetic spectrum; a Reading Unit; a Motor Unit; a Filter, Adjust and Rebalance Unit; A Structural Unit supporting all previous units or modules and a Communication and Transmission Unit of information with other external equipment for the purpose of this invention. 2. New Digital PhotoOptoMetric Pedometer applicable to the study of morphological form, biomechanical structure, cutaneous map, two-dimensional map of pressures exerted on a smooth or curved surface, (whether hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating an optical Unit that comprises a prism transparent to light energy, emitted by the Energy Generating Unit, which has the parallel, upper and lower face, the lateral faces being able to be at an angle of 90 degrees, or even at a different angle depending on the function or application that one wishes to obtain or achieve. The pressure transducer unit supporting the upper face of said prism and exerting its lower face the function of channeling the light reflection with significant information of the object (read foot) to the optical reading sensor of the type used in the scanners, (no being a scanner object of claim for this New Digital PhotoOptoMetric Pedometer) and, said prism exercising a function of supporting the body mass of the object or individual under study. 3. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating a Light Energy Generating Unit that may be located under the prism, which is part of the Optical Unit, and be mobile being its linear and parallel arrangement to one of the Cartesian axis of the prism by its lower face 4. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object body characterized by integrating a Light Energy Generating Unit that may be located on one or more of the prism sides, which is part of the Optical Unit, and being mobile being its precise and parallel arrangement to one of the Cartesian axis of the prism by its lateral faces. The said light unit being inside a sealed and opaque housing that prevents the entry of external light emissions and also channels the flow of light emissions towards the optical prism. 5. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object body characterized by integrating a Light Energy Generating Unit that may be located on one or more of the prism sides, which is part of the optical unit, and be fixed being its linear arrangement and parallel to one of the Cartesian axes of the prism by its lateral faces. The said light unit being inside a sealed and opaque housing that prevents the entry of external light emissions and also channels the flow of light emissions towards the optical prism. 6. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating Reading Unit comprising a row of photosensitive sensors to the spectrum of light that the Optical Unit filters and uses to form the information points in the lower base of said Optical Unit. The photosensitive sensors can be arranged in flat or curved matrices, with provisions of N. Rows and M. Columns, where N and M can adopt strict integer values greater than zero. Said matrix of sensors occupying in length one of the Cartesian axes comprising the lower face of the prism integrated in the optical unit. 7. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating Motor Unit comprising a mobile band located under the Prism that is included in the Optical Unit, which supports the Reading Unit , (and in some variants the Light Generating Unit itself). It can be subject to a system of displacement along one of the axes of the prism, by means of two routing rails that ensure the stability and linearity of the movement of the Reading Unit, so that the combination of the width of the sensor band , of the Reading Unit, together with the displacement that it carries out along said axis allows the reading of each and every one of the information points that are generated in the inferior face of the optical prism. 8. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural that emerges from said form and structure applicable to any part of the human, animal, plant or material object body characterized by integrating Transducer Unit, from pressure to light intensity, comprising a combination of elements, arranged in mono and multilayer, of different degrees of elasticity and transparency, which are supported by a prism transparent to light and that by emitting beams of light of constant intensity that impact through the prism and by means of combined reflection-refraction processes convert discrete points of pressure on the surface of the transducer at discrete points of an image on the underside of an optical prism or lens 9. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object body characterized by integrating in one of its embodiments a special Transducer Unit, from pressure to light intensity, comprising a multicellular mat located above of the firm that presents the prism or lens that makes up the optical unit. Said cell mat is formed by a mosaic of equal cells arranged in rows and columns forming a matrix of discrete points. Being these physical sensor cells that react to pressure by modifying their length, thickness and also color and density, although these last two characteristics are not essential. The cells are integrated in a matrix that supports them and that defines the resolution of reading pressure points per square centimeter of transducer surface. Being 1, 4, 9. 16 and 25 the usual values per square centimeter that the New Pedometer achieves with this new cellular transducer. 10. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating in one of its embodiments a special Transducer Unit transparent, from pressure to light intensity, which allows the reading of the cutaneous map of the human foot in real size and with pressure and overload points incorporated into said cutaneous map 11. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating in one of its embodiments a special Transducer Unit transparent, from pressure to light intensity, which allows the reading of the Real-sized cutaneous map of the human foot and its morphological form. 12. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating in one of its embodiments a special Transducer Unit transparent, for reading distances or heights of the plantar vault at intensity of light, which allows reading the three-dimensional map of the plantar vault and the biomechanical arrangement of the human foot in real size. 13. New Digital PhotoOptoMetric Pedometer applicable to the study of the morphological form, the biomechanical structure, its cutaneous map, the two-dimensional map of pressures that it exerts on a smooth or curved surface, (whether it is hard or soft), and the three-dimensional map structural structure that emerges from said form and structure applicable to any part of the human, animal, plant or material object characterized by integrating in one of its embodiments a transparent Transducer Unit that allows, in loading position, to read the area aerial of the foot that is not in contact with the optical prism, the perimeter of the plantar footprint, the areas of significant pressure and the cutaneous two-dimensional map of the foot; being all these readings carried out at the same time and in an integrated way.