DE102013113348A1 - Device for measuring DNA quantum states and use thereof - Google Patents

Abstract

The invention relates to a device for measuring quantum states in a DNA preparation (2). According to the invention, the device includes a tuned to one or more resonant frequencies of the DNA preparation resonator (5), which is adapted to receive the DNA preparation (2) and a sensor as close as possible to the DNA preparation (2) arranged (14) for detecting resonances and / or signals of the DNA preparation (2).

Description

The invention relates to a device for measuring quantum states of DNA preparations and a use of this device for living thing identification and / or device control.

A device for measuring quantum states of DNA is known from EP 1 684 064 A2 a quantum resonance analyzer which is also said to be useful for reading the nucleotide sequence of DNA molecules. For the analysis, it is necessary to direct shaped pulses to the molecules to be examined and to measure the then changing absorption or emission spectrum. In order for there to be quantum resonance effects, the molecules to be examined must be arranged in a resonant structure, e.g. In a pattern of quantum dots (Q-Dots) or as a multi-layer interference filter. Possible applications include the identification of certain types of molecules in living cells.

In contrast, the invention is based on the object to provide a device for measuring DNA quantum states, which is easier to implement and also opens up other applications.

This object is achieved according to the invention by a device having the features specified in claim 1. Advantageous developments of the device according to the invention are specified in the dependent claims. Preferred uses of the device according to the invention are specified in claims 8 and 9.

The tuned resonator makes it possible to amplify and detect resonances of the DNA preparations without requiring much excitation energy. In the best case, certain random field fluctuations from natural or artificial sources are sufficient to produce or amplify quantum resonance effects. If necessary, these can be additionally stimulated, but then you come out with very little energy, since you do not have to couple more energy into the device than has to be decoupled for detection again.

Since the resonator provides a regular structure to generate or amplify quantum resonance effects, the DNA preparations to be measured themselves need not necessarily be ordered in any regular structure.

The detection of the resonances takes place by means of a sensor which is arranged as close as possible to the preparation. The resonator is formed in a preferred embodiment by a resonance space which is delimited by a total reflecting reflector and a partially reflecting reflector. The sensor may be a planar array of many sensor cells, which extends on the back of the partially reflecting reflector in order to perform a large number of measurements in a short time and, if necessary, to be able to distinguish resonances according to their frequency and / or location.

The sensor provides complex signal patterns which may be individually different for the DNA of each animal. The decisive factor is the exclusive coupling between the DNA preparation and the target organism (DNA donor). In the following, only the term DNA donor is used, which however is interchangeable with the term target animal. The device of the invention may be used to uniquely identify the DNA preparation as derived from a particular animal, e.g. From a person or an animal. This does not require any nucleotide sequences to be determined, which would result in unnecessary overidentification, but will suffice for certain characteristic signal patterns, which also need not be known what they mean in detail. This characteristic signal pattern can only be generated by an exclusive, quantum-mechanically entangled remote coupling to the DNA preparation of the donor itself in the quantum field resonance sensor, nobody else.

An entirely new application of the invention is to use it for non-contact device control. Systems for the non-contact control of devices such. As computers or machines by means of thoughts are known, for. B. from the DE 10 2010 003 230 A1 or the US Pat. No. 3,830,064 However, their reliability leaves much to be desired, because of a limited coupling sharpness and corresponding error rate. The inaccurate assignment of the signals lowers the speed of operation.

The utility of the device control device of the present invention is based on the effect of deliberate intentions on human DNA, see the publication "Effect of conscious intention on human DNA" by Dr. med. Glen Rein, in 'Proceeds of the International Forum on New Science, Denver, Colorado, October 1996,' especially pages 6 and 7 and the bibliography ( http://item-bioenergy.com/infocenter/consciousintentiononDNA.pdf ).

• – http://mikephilbin.blogspot.de/2012/01/cleve-backter-quantum-biocommunication.html
• – http://www.theepochtimes.com/n3/164582-primary-perception-the-secret-life-of-life-part-1/
• – http://www.raymongraceprojects.com/pdf/cellcommunicationarticle.pdf
• – http://www.societyforunderstanding.co.uk/selected-articles/three-experiments-that-change-everything/

In addition, according to various other publications, there is evidence that the DNA molecules of all the cells of the same body are in some coherence with each other, even with DNA molecules in cells taken from the body and at a certain distance from it, see, for. B .:

• - http://mikephilbin.blogspot.de/2012/01/cleve-backter-quantum-biocommunication.html
• - http://www.theepochtimes.com/n3/164582-primary-perception-the-secret-life-of-life-part-1/
• - http://www.raymongraceprojects.com/pdf/cellcommunicationarticle.pdf
• - http://www.societyforunderstanding.co.uk/selected-articles/three-experiments-that-change-everything/

Such coherence can be explained by the fact that DNA can be regarded as a sequence of quantum dots, either as very many tiny quantum dots or as quantum dots, each formed by groups of adjacent base pairs, cf. z. B. the publication "Direct measurement of electrical transport through DNA molecules" in Nature, Vol. 403, February 2000, p. 635 ff. In addition, there are various interactions with longer reach in DNA molecules, cf. z. B. the publication Chemistry (2004) 236: 139-161, Springer-Verlag Berlin Heidelberg 2004 "The mechanism of long-distance radial cationic transport in duplex DNA: Ion-gated hopping of polaron-like distortions" ,

Because of their properties and interactions, adjacent DNA molecules in the body of a living entity may be quantum mechanically entangled, and such entanglement is known to be maintained as the molecules are spatially separated. As a result of the entanglement, state changes of a DNA molecule are transferred to other entangled DNA molecules, even if they are far away. Here, in a practical sense, the non-locality of quantum effects discovered at Einstein's time has an effect. According to Professor Meyl, the communication between DNA and cells is due to scalar waves that can not be shielded and are transferable lossless over long distances (see Meyl K., "DNA and cell resonance: magnetic waves enable cell communication", DNA Cell Biol., Apr. 2012 ). Similarly, it can be imagined that neuronal events in the brain are somewhat entangled with states and state changes of DNA molecules because neuron arrays also form quantum mechanical systems.

That said, research has made it believable that human DNA taken from a donor body can still communicate with the donor and in some way respond to its thoughts and emotions. This type of communication is believed to be about 90% of the DNA that is not used for the synthesis of amino acids in the body.

The device of the invention forms a quantum field resonance sensor, a labile quantum system that can be contactlessly influenced by a person's thoughts and emotions by responding to effects that the person's thoughts have on the DNA preparation. That is, the quantum field resonance sensor connects to a dedicated operator of a device and thus provides a coupling between the operator and the device. After optional signal conversion and preprocessing, the data in an evaluation unit is transformed into computer commands or screen signals. These are connected via a conventional interface to devices such. B. machines or computers to be controlled.

The quantum field resonance sensor consists of at least one unstable quantum system, which is influenced by the observer (operator). The sensor, which itself is a part of this quantum system, measures, so to speak, the coherence between the operator and the possible control commands with which the device can be operated by detecting resonances in the response signal of the quantum system. The quantum system can be any labile quantum system in which entangled quantum states occur uniformly distributed and their measurement is physically possible. Examples are the polarization of photons, spontaneous photon emission, electron spin measurement, unstable Q-bits, effects in Bose-Einstein condensates, entangled magnetic resonance systems, DNA photon emission, DNA potential differences, quantum resonators, noise diodes, random number generators, etc.

The incorporation of human DNA preparations into an electrical or photonic sensor can thus establish a direct connection to a person and ensure a clear resonance accuracy for the operation by a special person. As stated in claim 10, the DNA preparation acts as a public key in a cryptosystem, so to speak, and the operator's awareness as a secret key. This connection is absolutely secure against tampering and can therefore be used for security systems of all kinds, eg. Replacement of chip cards, ID systems, encryption, computer security, etc. The exclusive connection of the DNA with the consciousness of the person from whom the DNA originates means that no password is needed anymore. By coupling with the DNA, it is not necessary to calculate deviations in random signals, as in the case of known systems for the contactless control of devices. As a result, the device according to the invention and its preferred uses are safe from manipulation.

The quantum system is preferably optically and / or electrically coupled to a semiconductor chip. The coupling can z. B. via a photodiode, a FET transistor, a Q-dot or a bipolar transistor. The sensor is constructed as a microsystem and integrated together with the transmitter as a hybrid system. Preferably, many such labile quantum systems are arranged in a matrix in order to be able to perform a large number of measurements in a short time. This allows fast processing and correlation with numerous control options. The high-frequency processing of thought impulses ensures a short reaction time of the system and control in thought.

It is expedient to construct the matrix of the quantum field resonance sensor directly on a semiconductor chip. An FPGA or an individually configured ASIC can also be integrated on this chip. In order to avoid interference by electromagnetic radiation, the chip is preferably provided with a shield. The measurement of the quantum systems can take place with frequencies of approx. 1 kHz up to a few MHz.

In order to ensure that only the commands of the dedicated operator reach the control of the device, a personalization of the sensor can be performed. The personalization can take place both in the quantum field resonance sensor itself, in the signal conversion, in the preprocessing and in the evaluation unit. Any combination of these possibilities is also conceivable. In addition, the DNA preparation of the user is integrated. With the aid of a learning algorithm / learning program, the quantum field resonance sensor is trained on a new target person as an operator. An embodiment of the personalization as a chip card is conceivable.

Patterns that uniquely identify the operator and his commands can be recognized by the use of mathematical algorithms, as known in the art of signal processing. In this case, a spectrum analysis or a conversion into the frequency space or other mathematical spaces can take place, with subsequent pattern analysis in these rooms. Neural networks are ideal for learning patterns and then responding to them. This is very close to the way the brain works and is therefore also well-suited for the processing of thought signals.

For signal conversion, an electronic or photonic circuit can be integrated into the quantum field resonance sensor. This includes the use of an analog-to-digital converter that converts to digital data. In matrix arrangements, the signal conversion is connected for each element of the matrix.

As a further intermediate step, signal preprocessing can be carried out for each quantum field resonator. This preprocessing can z. B. take over a DSP processor. A neural network can also be used here. Subsequently, a signal evaluation takes place, preferably by a microcontroller and / or FPGA or ASIC, which contains various algorithms for evaluating the quantum field thought signals and undertakes the communication with the target system.

So that the quantum field resonance sensor can be used for the identification of many different thoughts, a selection of the possible actions for a specific application must be made. So that the translation into control of user programs can be accomplished comfortably, the programmer is provided with a software interface with a learning function.

A particular development of the invention is to let the quantum field resonance sensor interact with a quantum computer. Here, the quantum states of the sensor could be introduced directly into the processing as Q-bits.

According to yet another embodiment of the invention, not only the data input into a device such. For example, a computer may be speeded up, but also feedback from data that may be audible or visual not only in a conventional manner, but possibly directly as speech or thought, by providing appropriate feedback from the controlled device to the preparation in the device.

• – Texterfassung in Gedankengeschwindigkeit
• – Direkte und vollständige Steuerung von Programmen mittels Gedankenbefehlen, womit das lästige Suchen von Menüpunkten ein Ende hat
• – Interaktive Übersetzungshilfe, sobald an ein Wort gedacht wird
• – Schnelles Zeichnen mit Gedankenkraft
• – Interaktive Erstellung und Bearbeitung von Bildern in Gedankenschnelle
• – Darstellung von imaginierten Bildern.
• – Sehr schnelle Bearbeitung von Korrespondenz und Kontakten in sozialen Netzwerken.

The invention thus provides a non-contact human machine interface that uniquely identifies an operator, thus providing strong human-machine coupling and detecting coherence therebetween, enhancing the security, reliability, and speed of operation of devices such as personal computers. As computers and machines revolutionized. Only the operation of a computer in thought makes the user in the position to fully exploit the capacity of today's computers. The advantages of this technique include:

• - Text capture at thought speed
• - Direct and complete control of programs by means of thought commands, whereby the annoying search of menu items has an end
• - Interactive translation assistance as soon as a word is thought of
• - Fast drawing with thought force
• - Interactive creation and editing of images in thought
• - Presentation of imagined pictures.
• - Very fast processing of correspondence and contacts in social networks.

The following is a description of embodiments with reference to the drawings. Their sole figure shows a schematic diagram of a quantum field resonance sensor and its evaluation circuit.

The quantum field resonance sensor shown is a device for measuring quantum states in a DNA preparation 2 that is in the top of a stick 4 which also has an NFC or RFID chip or contact chip 6 may contain. Drug 2 can be configured differently depending on the desired safety requirement and resonance sharpness: in the simplest case, with low resonance sharpness and safety, the preparation consists of a substance or an object in connection with the target person, which represents a partial representation of the DNA. Furthermore, the preparation may be represented by a hand or other body part of the target person near the sensor. Examples of highly safe and highly resonant specimen preparations are: a saliva sample, leukocytes or other body cells or cell aggregates on a support, separated DNA, or a DNA solution or cells in a glass jar or other hermetically sealed volume. DNA could be particularly suitable between ITO electrodes so that it can be subjected to bias and can be frequency-excited. The ITO electrodes can, for. B. arranged in a spatial correspondence to the sensor array described later and also be galvanically connected thereto. Alternatively, the preparation could consist of an image, provided that the required resonance sharpness resulting from the low coupling is sufficient.

A housing 8th of the quantum field resonance sensor includes a shield against noise, z. B. by being designed as Faraday cage, and has an opening through which the stick 4 in the case 8th can be introduced so that the drug 2 in the center of a resonator 5 located. The resonator 5 can be configured differently depending on the desired safety requirement and resonance sharpness: in the simplest case, with low resonance sharpness and safety, it can by the approximation of the DNA preparation 2 be formed on the sensor. It acts z. B. already a cell through the dimensions of its cell membrane as a resonator for the DNA. In a preferred embodiment, the resonator 5 a resonance space between two reflectors 10 . 12 namely a totally reflecting reflector 10 and a partially reflecting, ie partially reflective and partially transmissive reflector 12 , In a further embodiment, the partially reflecting reflector 12 be formed by a suitable coating or a layer system on the sensor itself. The stick 4 is removable and can also take the form of a chip card. Even the quantum field resonance sensor itself is constructed as compact as possible, for. B. as a smart card reader, or possibly even has the form of a chip card into which an even smaller in-chip stick 4 can be introduced.

The reflectors 10 . 12 are at least reflective of vibrations that are resonant frequencies of DNA molecules, and those through the reflectors 10 . 12 formed resonant space is tuned to at least one such resonant frequency or a multiple thereof, which is primarily due to the distance between the reflectors 10 . 12 is determined.

In the exemplary embodiment, the resonance space is similar to an open laser resonator. But it could also be a closed resonator, z. B. a cavity resonator.

The vibrations are in particular vibrations of electromagnetic fields including electrical and magnetic vibrations. Candidate frequencies may be radio frequencies or microwaves, possibly also frequencies of infrared, visible or ultraviolet light. The vibrations may possibly also be non-electromagnetic nature, z. B. due to exchange interactions or Casimirkräften, if suitable reflectors and sensors can be realized.

On the drug 2 opposite side of the partially reflecting reflector 12 there is a sensor 14 , which is a flat array of 8 × 8 sensor cells in this example 14a each sensitive to vibrations at the resonant frequency or one of the resonant frequencies. Depending on the need, the number of sensor cells 16 also be bigger or smaller. The sensor cells 14a form together with the preparation 2 and the resonator, a plurality of labile quantum systems in a matrix to be able to perform a variety of measurements in a short time.

For light frequencies, the sensor 14 z. B. a highly sensitive photo chip (CCD / CMOS). The distance between the sensor 14 and the drug 2 should be small, preferably less than a few centimeters, even more preferably less than 1 mm, and more preferably less than 0.1 mm.

The quantum field resonance sensor can also be a pathogen 16 included, which generates a bias voltage and / or bias in the resonance space and / or radio frequency or light waves coupled with at least one predetermined frequency in the resonance space, such as. As a maser or laser. The germ 16 may also be located outside the resonant cavity and couple the generated energy into it in any manner.

An evaluation circuit 18 , which may include one or more microcontrollers, digital signal processors, FPGAs, ASICs, etc., receives signals from the sensor 14 ,

The evaluation circuit 18 contains a preprocessing 18a by means of a digital signal processor for transformations such. FFT transform, Discrete Cos transform, Discrete wavelet transform, Laplace transform, etc.

The evaluation circuit 18 also contains a neural network 18b which converts the complex patterns of preprocessed signals into commands that it selects from a database.

The evaluation circuit 18 also contains an interface 18c , which may be a conventional computer interface, e.g. For example, to a standard such as USB, SATA, Firewire, RFID, NFC or any future standard.

the interface 18c leads the determined commands to a target system 20 to, the z. As a computer, a portable data terminal such. As a mobile phone, a machine, a landline phone, a heater, a home system, a motor vehicle, an elevator, a vending machine or ATM can be.

If the target system 20 z. B. is a computer running on the appropriate software, the neural network 18b through learning coupling 22 with a person from whom the DNA molecules of the preparation 2 come, be trained. The feedback required for this is based on interactions between the thoughts of the person and their body's own DNA as well as between the body's own DNA and the DNA taken from the body in the preparation 2 and the sensor 14 , So the person z. For example, on a screen of the computer, observe what effects its intentions and emotions have on the result of the signal evaluation and, as a result, the person can learn to give targeted commands and / or the neural network 18b can learn what kind of command the person intends to give when they recognize a particular signal pattern. The person can tell the system via a defined conventional interface (eg keyboard), which command should trigger a particular thought pattern.

The procedure is as follows: 1. The user thinks of a desired action / command. 2. The quantum field resonance sensor detects a significant new signal pattern. 3. The user assigns the desired command to the detected signal pattern. 4. The user deepens the command through repeated training. The order of the steps can also be varied according to need.

After appropriate training, the person is able to achieve a desired target system 20 to control without contact.

The complex signal patterns that the evaluation circuit 18 are different for the DNA of every living thing. Therefore, the evaluation circuit 18 the DNA in the preparation 2 identify as being from a particular person. The identification is facilitated or the safety is increased when the evaluation circuit 18 In addition, you can read personal identification data on the NFC or RFID chip 6 are stored and can compare them with the complex signal patterns or the data derived therefrom. Besides, it is beneficial to have the signal patterns and personal training data on the stick 4 or the chip card. This allows the operator to operate different systems without having to train again.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1684064 A2 [0002]
• DE 102010003230 A1 [0009]
• US 3830064 A [0009]

Cited non-patent literature

• "Effect of conscious intention on human DNA" by Dr. med. Glen Rein, in 'Proceeds of the International Forum on New Science, Denver, Colorado, October 1996,' especially pages 6 and 7 [0010]
• http://item-bioenergy.com/infocenter/consciousintentiononDNA.pdf [0010]
• http://mikephilbin.blogspot.de/2012/01/cleve-backter-quantum-biocommunication.html [0011]
• http://www.theepochtimes.com/n3/164582-primary-perception-the-secret-life-of-life-part-1/ [0011]
• http://www.raymongraceprojects.com/pdf/cellcommunicationarticle.pdf [0011]
• http://www.societyforunderstanding.co.uk/selected-articles/three-experiments-that-change-everything/ [0011]
• "Direct measurement of electrical transport through DNA molecules" in Nature, Vol. 403, February 2000, p. 635 ff. [0012]
• "The mechanism of long-distance radial cationic transport in duplex DNA: ion-gated hopping of polaron-like distortions" in 'Top Curr Chem (2004) 236: 139-161, Springer-Verlag Berlin Heidelberg 2004 " [0012]
• Meyl K., "DNA and cell resonance: magnetic waves enable cell communication", DNA Cell Biol., Apr. 2012 [0013]

Claims (13)

Device for measuring quantum states in a DNA preparation ( 2 ), characterized in that the device is at one or more resonance frequencies of the DNA preparation ( 2 ) tuned resonator ( 5 ), which is adapted to the DNA preparation ( 2 ) and as close as possible to the preparation ( 2 ) arranged sensor ( 14 ) for detecting resonances and / or signals of the DNA preparation ( 2 ). Device according to claim 1, characterized in that the resonator ( 5 ) is formed by a resonance space through a totally reflecting reflector ( 10 ) and a partially reflecting reflector ( 12 ) and that the sensor ( 14 ) is arranged outside the resonance space to detect resonances and / or signals formed in the resonance space. Device according to claim 1 or 2, characterized in that the sensor ( 14 ) a planar array with many sensor cells ( 14a ) located on the back of the partially reflecting reflector ( 12 ). Device according to one of the preceding claims, characterized in that it also has an evaluation circuit ( 18 ), the signals of the sensor ( 14 ) and converts it into one or more instructions that it selects from a plurality of stored instructions. Device according to one of the preceding claims, characterized in that the preparation ( 2 ) in an elongated object ( 4 ) adapted to be inserted into and removed from the device. Device according to claim 5, characterized in that in the elongate object ( 4 ) also a chip ( 6 ) is accommodated for short-range wireless communication and / or for data storage. Device according to one of the preceding claims, characterized in that the DNA molecules in the preparation ( 2 ) come from a particular human or animal. Device according to one of the preceding claims, characterized in that it is designed to receive scalar waves and / or to send. Use of the device according to claim 1 or any one of claims 2 to 8 for living thing identification. Use of the device according to claim 1 or any one of claims 2 to 8 for non-contact device control. Use of the device according to claim 1 or any one of claims 2 to 8, wherein the DNA preparation ( 2 ) serves as a public key in a cryptosystem and wherein the resonance of the DNA preparation ( 20 ) or the resulting signals serve as the private key of the cryptosystem. A method of programming the device of claim 1 or any one of claims 2 to 8 for non-contact control of this device, comprising the steps of: Recognizing a significant signal pattern by the device, wherein the significant signal pattern originates from the user and corresponds to a desired action or command of the user; user-assigned the action to the detected significant signal pattern; and user deepening of the action or command through repetitive training to optimize the detection probability of the device. A method of non-contact control of a device using the device programmed according to claim 12, wherein the device responds to the detected, significant signal patterns.

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