DE19713584C2 - Method and device for measuring the state of decay of solid, liquid and gaseous matter by means of photon reflection and absorption - Google Patents

Description

The invention relates to a method and a device for measurement the state of decay of solid, liquid and gaseous matter by means of photon reflection and absorption.

The state of the art is not only based on measurements on matter, but also marked on intangible systems, since a with decay in accordance with the laws of nature always must have the same typical characteristics.

All organizational and information systems are immaterial Systems.

A correct input instruction, verbally or as a data set, is changed along the way by interactive influence, that the information at the system output does not match the Input information must match.

This is what the term "information entropy" stands for.
(SELBACH, Gerd: Up-to-date inventory management taking into account the inventory structure and order scheduling, p. 9; Fig . 1-2. AWF Rationalization Congress PPS 82).

In contrast to radiocarbon dating when measuring decay state are photon emissions in biophotonics Intensity and cooldowns are measured, with the intensities are either of natural origin or by laser radiation be stimulated.

Show special events, such as germinating seeds correlating photon emissions as well as cancerous degeneracies of cellular tissue.

The statement of biophotonics is always qualitative in relation to one Anomaly.

The high apparatus complexity of the method, together with this limitation, has meant that this technique has not yet gone beyond laboratory status.
(POPP, Fritz-Albert, QIAO Gu, KE-HSUEH Li, Biophoton Emission: Experimental Background and Theoretical Approaches, International Institute of Biophysics, Kaiserslautern 1994; p. 1292, Modern Physics Letter B, Vol. 8, Nos 21 & 22 ( 1994) 1269-1296).

In 1973 the quality of an industrial became the first Organization shown as liquidity-related distribution. This Distribution was obtained at the warehouse-manufacturing interface and showed itself to be extremely sensitive to wrong decisions of management as well as systemic weaknesses.

The inventory is the result of setting a certain goal Deliver the quantity on time. There is a material supply for this required, which is made up of the order quantity and existing stock composed, both under the article number in the parts master record guided.

This parts master record manages all movements and is therefore an object a distinctive interactive data processing with high human error rate.

This resulted in 50% incorrect stocks within 6 months, to be corrected by the intermediate inventory. From the associated unavailability to the demand point priority shifts and high stocks arise.

The cause research showed that the data set with 50 digits was not structured to minimize errors. It turned out that a human error rate of 1-9% could be reduced to 0.4-1% by changing the structure of the codes.
(SELBACH, Gerd; PFEIL, W.-D .; PROCHNIO, E .: The determination of the formation of errors in integrated data systems in production control with manual data entry, University of Duisburg 1979, pp. 5-7).

This frequency of errors is based on the correctness of the codes, inappropriate batch sizes and fatigue on the screen, reinforced by chaotic connections in the system.
(SELBACH, Gerd; BANDUHN, O .: Determination of a procedure for the calculation of the optimal occupancy occupancy based on the job file of the production program, University of Duisburg, 1985, pp. 2-3).

All of these individually non-quantifiable relationships are shown in a curve:
The cumulative curve of the coverslipping time distribution!
(STEINHART, A .; NEFF, M .: Determination of the correlation between the increase in the mounting time distribution in the parts warehouse and the spread of the throughput time as a tool for scheduling orders in unlinked batch production or one-parameter inventory management, FH Konstanz 1989. pp. 5- 7, 10-13, 18, 20).

The coverslipping time distribution is based on a single parameter, the Covering time as a quotient of inventory and consumption.

This showed for the first time a categorization based on typical distributions:
The Gaussian distribution as typical for program-controlled manufacturing,
the Poisson distribution as typical for order-controlled manufacturing,
provided that the specifications for both quantity and time were met.

Any deviation from these specifications resulted in the extension of the respective distributions, with growing rectangular parts up to to the chaotic, the rectangular distribution.

In the course of this, an algorithm was developed that allows the curves typical of a production program to be calculated as limits for the feasible operating profit.
(STEINHART, A .; NEFF, M .: Determination of the correlation between the increase in the mounting time distribution in the parts warehouse and the spread of the throughput time as an instrument for scheduling orders in unlinked batch production or one-parameter stock management, EH Konstanz 1989, p. 113 -114).

In 1981, the newly gained knowledge was able to make a statement by means of distributions for the first time on the representation more typical Distributions in pathologically normal and cancerous tissues will wear.

These findings correlate with those of biophotonics insofar as an anomaly there is defined by mathematically Structures can be suspected here.

Therefore: The laws of nature, like these in the second law thermodynamics and the nuclear decay law come are general.

A method for measuring the state of decay of matter must determine the meaningful parameters together with the measuring method.

The definition of a generally applicable measurement standard becomes necessary agile.

State of Science - Definitions and Natural Laws:
Entropy S: Description of a state whose course is unidirectional and irreversible.
dS = -dQ / dt, where Q can be not just heat, but any other type of condition.

Law of natural (organic) growth - Gauss -:
y = ln x or e ^y = x, describes processes whose development process is geared towards a target state.
The state parameters are Gaussian-distributed.

Law of natural (organic) decay:
N / N ₀ = e ^-1 * ^t describes processes whose development processes end in "disorder", which are characterized by chaotic, ie rectangular distributions of the state parameters.
It is the law of nuclear decay.
This means: N number of intact "event carriers" such as atoms, data sets, photon densities per unit area at time tN ₀ corresponds to time t = 0.
l as lambda: material constant.

Definitions: The continuum is a mass phenomenon characterized by irregularity and insensitive to selection. It is represented by the Gaussian distribution and its special forms.
The discontinuum is a mass phenomenon, characterized by irregularity and sensitive to choice. (Norbert Wiener).
It is represented by the rectangular distribution.

Phenomena under laser light:
A laser beam reflected from a surface shows:

• - Cold-rolled or drawn metals have a strongly curved course of reflection, the apex of which touches the horizontal when the laser beam strikes in the rolling / pulling direction.
  The energy distribution in the vertical is Gauss and thus corresponds to the energy distribution in the incoming laser beam.
• - A less strongly curved course, the vertex of which touches the vertical when the laser beam strikes at right angles to the rolling / pulling direction.
  The vertical energy distribution is largely chaotic.

Here the law of organic growth reveals itself as with the preferred direction of the development process.

If these materials are annealed at the transition temperature, then ver these characteristics disappear.

Normally annealed rolled material, descaled, shows from the beginning chaotic distributions in all directions.

The same applies to all kinds of plastics.

In all cases, therefore, before measuring the energy distribution to assess the state of decay, determine the direction of measurement become.

Body tissue, pathologically normal, reflects the incident Laser beam with Gaussian distributed energy.

Cancerously degenerate tissue reflects the incident laser beam chaotic.

The work of the International Intitute of Biophysic shows that cell poisons introduced into organic, living matter Change photon emission, resulting in correlations conclude is that such an event also with the decay structures becomes visible.  

Fig. 1 shows the results of measurements of the energy distributions in the reflection carried out on aluminum samples.

The distributions recorded in the rolling direction - longitudinal symbols - are clear Gaussian distributions, the maxima of which reflectivity depend on the surfaces.

The flatter curves became transverse to the rolling direction - transverse symbols - measured and provide evidence that the Objective of the growth process weaker across the rolling direction is.

The development towards rectangular distribution is unmistakable.

Fig. 2 shows the results of samples measured with a comparator on paper and cellulose.

The thickness of the comparator was insufficient for the separation of the two reflections, so that a mixed collective was created by superimposition. The comparator 10 is shown symbolically with the beam path.

The curves also show Gaussian character on the material side Reflection as an indication of the calendering process at Manufacturing, albeit less pronounced because of the structure than with metals.

The following generally apply:
The basic span, mean value and standard deviation determine the distribution form and are dependent on the inner state of the tested material, which is manifested in the energy distribution of the reflection of a Gaussian-distributed incident laser beam.

The mean and standard deviation, measured over time in a dynamic decay process, therefore meet

N / N ₀ = e ^- * ¹ * ^t .

The ratio N / N ₀ is a measure of the state of decay.

At time t = 0, each distribution shows the greatest differences between maximum and minimum value, thus the maximum value of the standard deviation.

At time t = i, however, this difference is smaller than in t = 0.

The rectangular distribution as a characteristic of advanced decay shows a standard deviation of approximately zero, from which follows:
The minima of mean and standard deviation, each expressed by N / N ₀ , correspond to the total loss of the functionality of the measured material.

The invention is based, a method and a task To design a device which determines the state of decay of matter to measure against general criteria and to interpret clearly animals allowed.

It stands to reason, as does the high resolving power of the laser to use as its systemic Gaussian energy distribution as To use the measurement standard.

It is also obvious to use this energy distribution as a reference to use for measured energy distributions, because the well-known world view is not deterministic, but stochastic.

In terms of process technology, it is advantageous that laser light is emitted Optical fiber can be transmitted, because a comparator is nothing other than a light guide with a special length / through knife ratio.

The end faces are parallel to the center line and information can be be introduced on the media side at each location of the extension.

This object is achieved by the features of claims 1 and 3. Advantageous refinements result from the subclaims for the:  

• - measurement of material fatigue on materials with Hook's curve,
• - Measurement of material hardness soft, hard and semi-hard Rolled material,
• - measurement of the structure of pulp and paper,
• - measurement of cancerous and pathologically normal tissue,
• - Measurement of heavy metal and drug effects on cellular structure doors.

An embodiment of the device, which represents a further development of the device specified in DE 195 43 444 A1 ( Fig. 3), is explained below with reference to Fig. 4:
In the common housing 1, a diode laser 2 emits radiation via optics 3 , which causes reflection at the focal point, the focal area of which represents a sample of the material to be tested. This reflection strikes a focusing screen 4 with an integrated sensor 5 , the slit aperture of which, together with the scanning performed by a stepping motor 6 with variable interval control, determines the distribution form.

The focusing screen 4 is used to align the direction to be measured.

The measurement of liquid and gaseous matter is served by a comparator 10 , which projects the input reflection directly onto the focusing screen 4 , so that it can be compared and measured with the reflection projected through the matter on the focusing screen.

For measurements with very high gains, the loss of passage through the comparator 10 is measured by means of a surface mirror 11 as a deflection unit on the material side.

Amplifier 8 and writing device 9 record the distributions obtained sequentially.

Claims (5)

1.Method for measuring the state of decay of solid, liquid and gaseous matter by means of photon reflection and absorption, in which the energy distribution of a photon beam of a laser ( 2 ) reflected or partially reflected by the matter by means of a from a matt screen ( 4 ), a sensor ( 5 ) and a stepper motor ( 6 ) with guardrail ( 7 ) and with a housing ( 1 ) and the laser ( 2 ) connected sensor module depending on the speed of the stepper motor ( 6 ) and the width ( 5 b) of a slit diaphragm of the sensor ( 5 ) scanned step-by-step above the focusing screen and the type of energy distribution is used to infer the state of decay of matter. 2. The method according to claim 1, characterized in that between the laser ( 2 ) and the material, adjacent to the latter, a plane-parallel glass or plastic plate is arranged, which as a comparator ( 10 ) both from the boundary layer of the plate to enter The photon beam and the energy distribution reflected by the boundary layer between plate and matter are projected onto the focusing screen ( 4 ). 3. Device for measuring the state of decay of solid, liquid and gaseous matter,
full

• - a housing ( 1 ),
• - A laser connected to the housing ( 2 ) for emitting a photon beam and
• - Also connected to the housing ( 1 ), from a focusing screen, ( 4 ), a sensor ( 5 ) with slit aperture ( 5 b) and a stepper motor ( 6 ) with guide rail ( 7 ) existing sensor module for step-by-step scanning of the energy distribution of the photon beam reflected or partially reflected by matter,
• - an amplifier ( 8 ),
• - A writing instrument ( 9 ).

4. The device according to claim 3, characterized in that it further comprises a plane-parallel glass or plastic plate as a comparator ( 10 ). 5. The device according to claim 3, characterized in that it further comprises a surface mirror ( 11 ) as a deflection unit.