HRP20020483A2 - Diagnostic device - Google Patents

Abstract

The invention relates to a diagnostic device (1) for testing human organs using current frequency measurement. The inventive device comprises two parallelly interspaced, vertically erected plate-shaped component parts (3, 4), which are electrically connected to a sensor (10) that can be inserted therebetween. One of the plate-shaped component parts (3) is electrically connected to a measuring element (8), which can be brought into contact with the body of an individual to be tested, and the other plate-shaped component part (4) is electrically connected to a computer-controlled evaluation unit (15). The diagnostic device (1) can be economically manufactured, has a long serviceable life, and yields reliable test results.

Description

The invention relates to a diagnostic device for testing human organs using current frequency measurements.

There is a well-known diagnostic procedure using current frequency for testing human organs, which is especially used by homeopaths and health practitioners. In doing so, the measuring electrode is placed on certain meridian points to the left or right of the finger of the person being tested, and the frequency in Hertz is measured at the measuring points using ultrasound.

Measuring points are empirically found points of reaction of the skin and deeper tissue strains and form the place of transfer of excitation to local segmentally-determined, vegetatively-determined and neuro-endocrine-determined areas. Characteristic of a large number of measuring points is their linear order, as a thin line of points, the so-called meridians. These thin points tend in the border region of the two segments, presumably along the passage of the meridian, for example, on the extremities, where the projections of the dermatome, myotome and sclerotome can be most clearly recognized one above the other. These measuring points can be found at their topographical position on the human skin by measuring the skin resistance, i.e. the frequency of the current.

The found result of the measured frequency can be determined in the person on whom the search is performed, so it is then tested whether the frequency measured by this procedure of the tested organ of the person on whom the test is performed deviates from the already known frequency range of that organ or does not deviate. If the found ultrasound frequency of the organ lies within the known frequency range of the organ, as a rule, it can be concluded that the organ is healthy. If, on the other hand, the measured ultrasound frequency deviates from the known frequency range of the organ of the person being examined, this indicates a disease of the examined organ.

Furthermore, when testing human organs, a large number of test substances are used, which, when using electricity as a means of measurement, also provide certain information regarding the frequency. In order to obtain a more accurate or reliable test result of the tested organ, the result of measuring the frequency of the substance to be tested is compared with the result of measuring the frequency on the body of the person being tested and then it is placed at the position of the organ being tested. When measuring test substances, these are placed in test tubes and subjected to the measurement procedure.

If the person being tested complains of a disease of a certain organ, for example heart disease, this person usually takes one or more courses prescribed by the doctor. These flows can, like the previously mentioned test substances, be subsequently tested to see if they are suitable for treating the subject organ of the person being tested.

This procedure, which is based on frequency measurement, and which extracts from point locations the results of the energy state of points and meridians onto the surface of the frequency measured skin or tissue, is conditioned by the great variety of skin resistance and the magnitudes of disturbances that are often non-uniform or difficult to reproduce. These interferences are based, for example, on the moisture of the skin, the fat of the upper layer of the skin, the state of the vegetative nervous system of the person being tested, the pressure of the tip of the measuring electrode on the measurement point, and so on, and can significantly affect the measurement results. So, for example, wet skin gives a different frequency than dry skin. Therefore, the measurement results can be completely wrong due to the smallest changes, such as moving the body, taking stimulants such as coffee or tea, excitement, eating food, room temperature, loud noise and so on.

A further disadvantage of this procedure is that an enormous number of test substances for various organs and medications as well as test tubes, which are very expensive, must be constantly available. Test substances usually only have a limited shelf life and must be disposed of at the end of their shelf life and new test substances must be procured.

The task of this invention is to create a diagnostic device, which has properties as they are known at the beginning, which can be cheaply and permanently in operation and at the same time give reliable measurement results that can be used for the therapy of the tested person.

According to the invention, the task will be solved using two parallel, vertically oriented elements that have the shape of plates and are spaced from each other, and which are electrically connected to a sensor that can be placed between these plates, whereby one plate-shaped element is electrically connected to the measuring an element that can be brought into contact with the body of the person being tested, and another plate-shaped element is electrically connected to the evaluation unit, which is controlled by a computer. It is useful that the plate-shaped elements consist of an electrically conductive material.

The measuring element, which can be brought into contact with the person being tested, gives a result based on the frequency of the skin or tissue, which is transmitted to the plate-shaped element. Furthermore, the evaluation unit, controlled by the computer, will transfer to the second element, which has the shape of a plate, a known frequency, or frequency range from the computer program, which is known in advance. In this way, an electromagnetic field will be produced between both plate-shaped elements that are spaced apart from each other. Depending on whether the obtained measurement result, obtained from the measuring element that is brought into contact with the body of the person being tested, coincides with the supplied frequency from the evaluation unit controlled by the computer or significantly deviates from it, there is an electromagnetic field between the plate-shaped elements different voltage characteristic. Using the measuring probe, which can be placed between the plate-shaped elements, fine current measurement is achieved. In doing so, the actual difference in the electric field between the two plate-shaped elements is measured and transferred to the evaluation unit controlled by the computer, so that this data can then be used. With the help of a special computer program, it is possible to check that the examined organ of the person being tested is sick and how sick it is.

Based on this, a computer program can be used to suggest therapeutic measures and/or the possibility of taking suitable medications. In this way, the measurement procedure, which is carried out in accordance with the invented diagnostic device, can be repeated arbitrarily many times. Therefore, very accurate results can be achieved by equating the measured value with the predetermined values of the evaluation unit, which is controlled by a computer. Since the supply of test substances and test tubes no longer needs to be carried out, the diagnostic device can be put into operation an unlimited number of times and can be operated without major costs.

To achieve a stable overall performance of the diagnostic device, which is in accordance with the invention, elements having a plate shape are attached to the base support. This base support can be, for example, a base plate. In this way, the diagnostic device can be placed in various places and can be easily transported. In addition, it can be ensured that the distance between both elements, which have a plate shape, is always the same, in order to achieve the most unique test conditions and accurate measurement results as possible.

In accordance with a further extension of the invention, the measuring sensor is shaped like an antenna and is intended to be placed to measure the current frequency between two elements that have a plate shape. At the same time, if necessary or desired, the person handling the person being tested can place the measuring sensor manually between two plate-shaped elements, so that it is movable, or place it rigidly between two plate-shaped elements.

In order to ensure the most accurate possible measurement of the organ under test of the person being tested, it is advantageous to place the measuring member in contact with the hand of the person being tested, since it is known that the fingertips are the most suitable for frequency measurement due to their sensitivity and due to the multiplicity of measurement points on the meridians.

Accordingly, the value of the frequency transmitted from the measuring element, which is placed against the body of the person being tested, lies in the range of frequencies determined in advance, for the organs being searched, by the evaluation unit controlled by the computer, it is known that the antenna, which is between two plate-shaped elements, placed in a vertical position. This is a sign that the searched organ of the person being tested is healthy. When the value of the frequency obtained from the measuring element on the body of the person being tested tends to be outside the range of frequencies or frequency values determined by the computer-controlled evaluation unit, the antenna is placed in a horizontal position between the plate-shaped elements. This means that the searched organ of the person being tested is sick.

In order to enable frequency measurement on the body, i.e. on the measuring point of the meridian of one finger of the person being tested, and so that the measurement result could be transferred to the associated element that has the shape of a plate, there is a measuring element that can be brought into contact with the body of the person being tested and which is made of electrically conductive material.

For alternating transmission, i.e. teaching of measured values, the measuring element which can be in contact with the body of the person being tested via an electric line, can be put in contact with a plate-shaped element, and the other plate-shaped element can be connected to the evaluation unit that it controls computer. It is advantageous that the evaluation unit is such a device, which can perform electronic data processing. Furthermore, the measuring sensor can be connected via electrical lines to each of the plate-shaped elements. Therefore, each plate-shaped element has a connection box for electrical lines.

On the other hand, it is possible to deviate from the electrical lines that come from the measuring sensor to the plate-shaped elements. Since an electromagnetic field is created between the plate-shaped elements, during the time that the evaluation unit is switched on and thus the diagnostic device is supplied with voltage, the contact of the measuring element with the person being tested will be the antenna of the measuring sensor measuring the frequency of the electromagnetic field and the measured value transferred to the unit for evaluation.

After further development of the diagnostic device according to the invention, the evaluation unit is connected to the therapy unit. The evaluation unit uses the measured value obtained from the person being tested and then simultaneously finds, by means of an internal computer program, favorable values for the therapy that follows, of the person being tested, that is, for the person on whom the therapy is carried out. The preset values are transmitted to the therapy unit and determine the course of therapy for the person undergoing therapy.

By means of an additional computer program, or a partial program integrated into the diagnostic program in the evaluation unit of the diagnostic device, the measured and previously obtained measurement values, and the resulting values, are transmitted to the therapy unit of the person undergoing therapy, which therapy is then applied to that person.

Furthermore, the therapy unit can be placed in contact with the person undergoing therapy. During this, the electrodes are placed on the part of the body undergoing therapy and the resulting voltage frequency is transferred from the favorable values to the person undergoing therapy.

Often, there is a long period of time between diagnosis and therapy, or only one therapy session on a person undergoing therapy is not enough, so there are certain time intervals between sessions. In order to therapeutically bridge these time spaces, the software of the evaluation unit can therefore find support with certain medications, which can be assigned to the person to whom the therapy is applied in view of his illness, which this person should take in these time spaces. After each therapy session, a new diagnosis should be undertaken with the diagnostic device, since the original measurement values have usually changed over time.

It is understood that the previously mentioned characteristics as well as those that will be explained later apply not only to all mentioned combinations, but also to other combinations or individual cases, without leaving the scope of the above mentioned invention.

The idea underlying the subject invention will be described in the following description on the basis of one embodiment, which is presented in the drawing. Here they show:

Figure 1. Schematic view of the diagnostic device according to the invention, in a floor plan, with connection to the evaluation unit and the therapy unit,

Figure 2. Schematic side view of the diagnostic device according to point 1.

The diagnostic device 1 has, in accordance with Figures 1 and 2, a base plate 2. On the base plate, at a certain distance from each other, there are two elements 3 and 4, which have the shape of plates and are placed parallel to each other, whereby they protrude vertically from the base plate 2, as is especially visible on the joint 2. Each of the plate-shaped elements 3 and 4 is attached by means of a plate holder 5 or another suitable means of attachment to the base plate 2. In this way, it is ensured that the plate-shaped elements elements 3 and 4 always have the same distance from each other. In addition, each of these plate-shaped elements 3 and 4 has a connection box 6 and 7, respectively, for connecting electrical lines.

The diagnostic device also includes a measuring element 8, which has the shape of a handle and is made of electrically conductive material. This measuring element 8 is connected via an electric line 9 to the terminal box 6 of the plate-shaped element 3. Furthermore, the diagnostic device 1 includes a measuring sensor 10, which has the shape of a handle, and which is connected on one side via an electric line 11 to the plate-shaped terminal box 6 of the shaped element 3 and on the other side via the electrical line 12 with the connection box 7 of the plate-shaped element 4. The measuring sensor 10 has an antenna 13, the front end of which is shaped like a spiral, and is made of an electrically conductive metal wire.

The diagnostic device 1 is connected via an electrical line 14 to the computer-controlled evaluation unit. This evaluation unit 15 consists of a computer 16 and a screen 17. The computer contains a special computer program, which provides certain known information about the frequency via the lines 14 to the plate-shaped element 4.

The measuring element 8 is in contact with the hand or finger of the person being tested, and who needs to be tested to see if a certain organ is sick or not.

The measuring element 8 transmits through the lines 9 to the plate-shaped element 3 the frequency of the skin, i.e. the tissue layer of a certain measuring point of a meridian, which is responsible for a certain organ, at the same time, from the evaluation unit 15, which is controlled by the computer, it is given to the plate-shaped element 4 in advance a given value of a certain frequency range or a frequency value for the organ being tested in the person being tested. This creates an electric field between the plate-shaped elements 3 and 4. By means of the measuring sensor 10, which has the shape of a handle and its antenna 13, which is handled by the examiner, the possible difference in the field characteristic between both plate-shaped elements 3 and 4 will be measured and via lines 13 and 14 it will be transferred to the evaluation unit 15 controlled by the computer. The computer 16 of the evaluation unit 15 establishes, by means of the computer program, from the received information a therapy plan or a plan for the administration of medication for dealing with the diseased organ of the person being tested.

The evaluation unit 15 is connected by a line 18 to the therapy unit 19. At the same time, the evaluation unit 15 supplies the therapy unit 19 with values obtained in advance from the computer program for the therapy of a certain part of the body for the person on whom the therapy is performed. Through connections 20 and 21, which are brought to the person on whom the therapy is carried out, and to the part of the body on which the therapy is carried out, the corresponding voltage frequency, which is determined on the basis of the previously given value of the evaluation unit 15, is transmitted from the therapy unit 1 to the part of the body undergoing therapy of the person undergoing therapy.

List of associated tags

1. a diagnostic device

2. base plate

3. plate-shaped element

4. plate-shaped element

5. plate holder

6. connection box

7. connection box

8. measuring element

9th platoon

10. measuring sensor

11th platoon

12th platoon

13. antenna

14th platoon

15th evaluation unit

16. computer

17. screen

18th platoon

19. therapeutic unit

20. connection

21. connection

Claims (10)

1. Diagnostic device for testing human organs using current frequency measurement, indicated by the fact that two parallel and mutually spaced, vertically placed elements (3, 4) that have the shape of plates are electrically connected to each other via a measuring sensor (10) that can be placed between them, whereby one of the elements (3) which has the shape of a plate is connected to the measuring element (8), which can be brought into contact with the body of the person undergoing testing, and the other element (4) which has the shape of a plate is electrically connected to the evaluation unit (15), controlled by a computer. 2. Diagnostic device according to patent claim 1, characterized in that the elements (3, 4) having the shape of plates are made of electrically conductive material. 3. Diagnostic device according to claim 1 or 2, characterized in that the elements (3, 4) having the shape of plates are attached to the base support (2). 4. Diagnostic device according to one of the patent claims 1 to 3, characterized in that the measuring sensor (10) is shaped like an antenna (13) and is designed to measure the current frequency between two elements (3, 4), which have the shape of plates and can be manually moved between two elements (3, 4), which have the shape of plates or it is rigidly placed between two elements (3, 4) which have the shape of plates. 5. Diagnostic device according to one of the patent claims 1 to 4, characterized in that the measuring element (8) can be advantageously brought into contact with the hand of the person undergoing testing. 6. A diagnostic device according to one of claims 1 to 5, characterized in that the measuring element (8), which can be brought into contact with the body of a person undergoing therapy, is made of electrically conductive material. 7. Diagnostic device according to one of the patent claims 1 to 6, characterized in that the measuring element (8), which can be brought into contact with the body of the person undergoing therapy, is connected via an electric line (9) to one of plate-shaped elements (3), and another plate-shaped element (4) is connected via an electric line (14) to the evaluation unit (15), which is controlled by a computer. 8. A diagnostic device in accordance with one of claims 1 to 7, characterized in that the measuring sensor (10) is connected by electrical lines (11, 12) to each of the plate-shaped elements (3, 4). 9. Diagnostic device according to one of claims 1 to 8, characterized in that the evaluation unit (15) is connected to the therapy unit (19). 10. A diagnostic device according to one of claims 1 to 9, characterized in that the therapy unit (19) can be brought into contact with a person undergoing therapy.