EP1495338A2 - Verfahren und einrichtung zum aufnehmen und aufbereiten von störfeldern und störstrahlen - Google Patents
Verfahren und einrichtung zum aufnehmen und aufbereiten von störfeldern und störstrahlenInfo
- Publication number
- EP1495338A2 EP1495338A2 EP03714593A EP03714593A EP1495338A2 EP 1495338 A2 EP1495338 A2 EP 1495338A2 EP 03714593 A EP03714593 A EP 03714593A EP 03714593 A EP03714593 A EP 03714593A EP 1495338 A2 EP1495338 A2 EP 1495338A2
- Authority
- EP
- European Patent Office
- Prior art keywords
- frequency
- measuring
- ring antenna
- signals
- pulse
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q7/00—Loop antennas with a substantially uniform current distribution around the loop and having a directional radiation pattern in a plane perpendicular to the plane of the loop
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
- G01R29/00—Arrangements for measuring or indicating electric quantities not covered by groups G01R19/00 - G01R27/00
- G01R29/08—Measuring electromagnetic field characteristics
- G01R29/0864—Measuring electromagnetic field characteristics characterised by constructional or functional features
- G01R29/0871—Complete apparatus or systems; circuits, e.g. receivers or amplifiers
Definitions
- the invention relates to a device for recording and processing radiation emissions from technical high-frequency sources with a ring antenna pickup, furthermore a method for recording and processing interference fields and interference beams as emissions from technical high-frequency sources with a ring antenna pickup and a measuring circuit.
- the measuring devices should be designed in such a way that they influence the existing field as little as possible. Reading out the measurement results should be possible via an optical interface. In this way, an influence on the field by the operating personnel or a risk to the operating personnel can be excluded.
- the measuring devices should have the largest possible dynamic range, since the range of the existing and expected limit values is very large.
- the probes consist of one or more E-field or H-field sensors with downstream rectifiers. The output voltages of the rectifiers are sent to the basic device, where they are processed.
- One of the monocontrollers also handles the processing of measured values.
- the voltage values U ADC sampled by ADCs are read into the processor every 400 ms.
- the characteristic curve equation is calculated for each measuring channel.
- the substitute field strength is calculated from the individual spatial components of the field strength.
- the rms value averaged over the last 6 minutes (AVERAGE), the greatest field strength value since switching on (MAX) and the largest mean value since switching on (AVERAGE & MAX) are calculated from the current replacement field strength.
- the current or averaged measured value can appear in the numerical display.
- the current measured value is always shown in the display. It is a logarithmic level display with a resolution of 3.01 dB and a right-hand stop shortly before a possible overload of the device.
- the units V / m, A / m, W / m 2 and mW / m 2 can be selected for the numerical display.
- the conversion is based on the assumption of a flat wave in a vacuum.
- the bidirectional, serial optical interface is used for remote control of the device and for reading the measured values on an external computer. This also enables measurements where it is not permissible or possible for operating personnel to be near the probe. In addition, the optical interface makes calibration of the device considerably easier. "(End of quote)
- the best known standard value is the so-called thermal immission limit. This is around 41 to 59 V / m for mobile communications.
- the lowest measuring sensitivity is usually 1 V / m, rarely 0.1 V / m. This means that the device manufacturers are about 100 times lower than the official limit values.
- the second approach is that of "electrobiologists”. Today, the professional branch should rather be “bioelectronic engineer”, since many biological processes come very close to those of electronics.
- the new invention is based on bioelectronic sensitivity (BES): a search is made for parallels between the biological processes or regulations and the technically generated interference fields and interference pulses.
- BES bioelectronic sensitivity
- the new invention is based on the solution shown in WO 00/29859 and supplements the older solution in some areas, which is why WO00 / 29859 is explained as an integral part of the present application.
- This shows a procedure for the practical measurement or house measurement of technical interference fields in relation to the living environment, in particular humans, animals and plants using battery-powered measuring devices, preferably with digital display, characterized by the following features: a) the interference-effective field is measured by a voltage (in Volts, mVolt, // volts), wherein b) the antenna voltage and at least one additional disturbing parameter are determined in the high-frequency range.
- the optimum antenna voltage is determined via a high-frequency receiver and that the at least one additional interference-influencing parameter is the type of signal technology and / or the magnetic field component and / or the specific ELF frequencies and / or the respective peak values of the ELF frequencies, be it figuratively or acoustically.
- WO00 / 29859 started from the discovery of surprisingly strong magnetic field agglomerations, the so-called hot spots in rooms. It has been suggested.
- the inventor proceeded from the following three findings, according to which the body's own bioelectronics and their potential for interference must be the starting point and standard for any measuring activity, especially with regard to cyclical processes, especially if a biological process is regulated by changing or reducing and increasing the pulse frequency becomes.
- the body tries to optimally adapt a large number of processes, such as heart rate, active and passive brain activity, fast or slow nerve transmission, cell metabolism, to the current need (rest / movement) through the pulse rate.
- Voltage fluctuations of the body's own functions It is known from medical literature that within the framework of body functions, voltages in the range from a fraction of a millivolt (mV) to 100/200 mV prevail.
- mV millivolt
- the question of the penetration depth and the magnetic field Apart from the frequency / pulse question, the question of the penetration depth is absolutely central. If external radiation with interference pulses cannot penetrate the brain, it is not necessary to influence the brain.
- a) Thermal model In the thermal model, a piece of meat serves as a model. The whole piece of meat is irradiated with the piece of meat and the temperature is measured in layers inside the piece of meat. The result is a curve for the penetration depth of the radiation in the meat portion and a second for the fat portion. The result can be reproduced and confirmed in every laboratory in the world. This method is quite plausible if only the heat effect of the radiation is of interest as a criterion.
- Athermal model In the athermal or non-thermal model, as can be seen from the literal sense, no temperature change can be measured. The question of the penetration depth is already answered in the case of microwave beams by physics, namely the formation of magnetic field agglomerations. The primary measure is the magnetic field component. This penetrates the human body almost without obstacles and with it the entire information of the microwave transmission technology.
- interference pulse sequences must be large enough to penetrate the body and overlay the body's own pulse sequences.
- the new device is characterized in that the connections of the ring antenna pickup for processing the immissions are connected to a corresponding signal line via at least one diode with opposite blocking direction and the two signal lines are connected to a measuring device via a capacitor device after the output of the diodes, or that Ring antenna pickup has at least two or more, preferably concentrically and annularly arranged loops which are connected to a measuring device via a resistance network.
- the new method is characterized in that the signals picked up via the ring antenna are processed via at least one diode each with the opposite blocking direction with the corresponding signal line and the two signal lines after the output of the diodes are processed via a capacitor device, or that the ring antenna pickup is more than one, preferably Has concentrically and annularly arranged conductor track, the signals recorded via the more than one conductor track being processed with a resistance network via at least two signal lines with a measuring device.
- the high-frequency transmission activity generates pulse frequencies in the area of nerve transmission, the metabolic cycle of cells (cell pump), the heart and brain activity.
- a very particularly advantageous embodiment of the method is characterized in that the measurement processing of signals within the framework of bioelectronic sensitivity (BES) for the assessment of electrosmog immissions from technical high-frequency sources is carried out with a passive measuring probe with at least one shielded or unshielded ring antenna and a measuring circuit , whereby the signals are processed in the measuring circuit.
- the signals from the transducer are rectified for a broadband determination, in particular the peak sequences of the high-frequency field strength.
- the processed signal is processed and evaluated via the measuring circuit, in particular as low-frequency peak sequences.
- the measuring circuit is preferably designed for the metrological detection of various parameters, in particular also in the athermal, the so-called lowest dose range, with field strengths of less than 0.1 V / m or less than 0.3 mA / m.
- a further advantageous design idea is characterized in that the measurement is taken over a broadband over more than four, in particular ten to one hundred, preferably twenty to fifty, concentrically arranged conductor tracks, the resistor network particularly preferably being designed symmetrically and at least approximately corresponding to the optimized internal resistance of the measuring device.
- the measuring sensor with storage devices can be designed as a logger for long-term recording, whereby load maxima from pulsed and non-pulsed (analog) immissions can be recorded and displayed.
- a central idea of the new invention is that a) the. total high-frequency field strength is determined to assess a possible biological disturbance in the energetic or genotoxic range (0.1 to 10 V / m); b) the low-frequency pulse sequences are recorded in relation to possible disturbances in the biological processes and especially the biological regulation in the toxic range (below 0.1 V / m).
- Electrosmog emissions are recorded and processed in relation to low-frequency pulse effects, with at least the pulse peaks being recorded and processed in the biologically relevant range from 0.1 Hz to 10 kHz and the temporal course of the pulse sequences being able to be represented in selectable frequency ranges.
- the low-frequency, in particular pulsed, signals are processed electronically for frequency-specific storage and / or determination of the LF pulse sequences with respect to the strength, the pulse profile and for graphic display in a desired form.
- the electro-smog emissions are recorded with a shielded ring antenna or measuring probe and the pulse sequences are recorded in biology-specific frequency bands, for example in relation to cell metabolism, human heart activity, the nervous system or brain activity.
- the high-frequency field load is measured over a broad band and the specific, low-frequency pulse effects are depicted graphically and / or acoustically and / or electronically.
- the high-frequency signals and the LF signals are particularly preferably recorded simultaneously and, in particular, evaluated in relation to one another and printed out.
- the low-frequency range is from 0 to 100 kHz, preferably 0 to 10 kHz, and the high-frequency range is from 10 kHz to the gigahertz range.
- the high-frequency signals and the low-frequency signals be recorded simultaneously and evaluated, in particular printed out, in relation to one another. It is very clear if the RF and LF signals are printed out over time as field strength (V / m) or as power in (W / m 2 etc. or A / m 2 ) with different identification, for example blue and red become. You get the load situation or the load history over a whole day at a glance. 0-100 kHz, preferably 0-10 kHz, and 10 kHz to 20 GHz are recorded as the low-frequency range. The distinction is very interesting because it covers both the entire range of electrical / electronic devices with processing frequencies in the medium frequency range and all types of transmission technology with carrier frequencies in the classic high frequency range.
- Another design idea is that the differences between the HF and LF signals are evaluated and analogously in relation to the HF and LF signals. Values to be printed out.
- Another important aspect of the new solution is that the low-frequency peak sequences or peak or effective values are recorded and evaluated both from low-frequency sources and from HF sources.
- the RF signals of more than 10 kHz are preferably recorded with a passive measuring probe with a sensor with at least one ring antenna and a measuring circuit via two parallel signal lines, corresponding to the two connections of the ring antenna.
- the measuring sensor has storage devices for long-term recording, whereby load maxima from pulsed and non-pulsed (analog) immissions are recorded and displayed, the recording and processing of the electrosmog immissions, in particular in relation to low-frequency pulse effects, with at least the peak sequences in the biological relevant range from 0.1 Hz to 10 kHz can be recorded and processed and the simultaneous course of the peak sequences can be displayed in selectable frequency ranges.
- the new data logger shows the extreme peak fluctuations, which are a result of low-frequency power peaks over an entire daily routine.
- the object on which the invention is based is achieved and can be implemented in practice in the form of inexpensive handheld measuring devices or larger and more expensive portable laboratory devices.
- the new measurement technology enables further in-depth knowledge regarding the effect of electrosmog emissions in pulsed wireless transmission technology, especially in the microwave frequency range.
- the object on which the invention is based is achieved and can be implemented in practice in the form of inexpensive handheld measuring devices.
- the new measurement technology allows further, in-depth knowledge regarding the effect of electrosmog immissions in the pulsed wireless transmission technology, especially in the microwave frequency range.
- the new invention allows a number of particularly advantageous configurations, for which reference is made to claims 2 to 16 and 18 to 32.
- the processed signals are rectified for the broadband determination of the high-frequency field strength.
- the entire high-frequency range was measured by frequency analysis and was often printed out on paper.
- no one has been able to appropriate frequency analysis with regard to the interference effects of the individual RF frequencies on biological systems.
- the harmfulness or non-harmfulness can be assessed with a certain total RF field strength of, for example, more than 0.1 V / m in the case of analog technology, or with an LF magnetic field strength of more than 0.3 ⁇ l.
- the processed signal is evaluated via the measuring circuit, in particular as a low-frequency pulse signal.
- the measuring circuit should be designed for the metrological detection of various parameters, also in the athermal, in particular in the so-called toxic range or the lowest dose range, with field strengths of less than 0.1 V / m or less than 0.3 mA / m, and one Have measurement sensitivity for peak values in the microvolt and millivolt range, in the area in which the electrobiological processes take place.
- the real "elk test" for the new measuring probe is that low-frequency signals, especially pulsed signals, can be made audible via headphones without amplification.
- This experiment must be seen as a small quantum leap in passive measurement technology. From the point of view of biology and medicine, this test must be recognized as a shocking fact.
- the human being is surrounded by intensities of electrosmog, which are sufficient that headphones can be operated via a mere passive probe and the signal, e.g. a DECT cordless phone, is clearly recognizable. This may be the most obvious example for the explanation of increasing tinnitus.
- the low-frequency, in particular pulsed, signals are processed electronically for frequency-specific storage and / or determination of the LF pulse sequences with respect to the strength of the pulse profile and for graphic display in a desired form.
- magnetic electromagnetic emissions in particular are recorded with a ring antenna or measuring probe and the pulse sequences are recorded in biology-specific frequency bands, e.g. in relation to cell metabolism, human cardiac activity, the nervous system or brain activity, but also for the corresponding ones Processes in animals and plants.
- a simple wire loop is usually sufficient, which, for reasons of convenience, can have an oval shape when pressed together.
- an unshielded wire loop is used as a ring antenna, then in addition to the magnetic field, the electric field is also partially detected. This is even advantageous because, for example, the skin of the body and the eye are independent the possible penetration depth can be disturbed. This applies in particular to the immense number of nerve endings, for example on human skin.
- the heart of the device is that the device is designed as a circuit, in particular with a symmetrical circuit, with two signal outlets in the signal line.
- the capacitor device preferably has one or two capacitors, the outer “capacitor plates” being connected to the corresponding signal line and, in the case of two capacitors, the inner capacitor plates being connected to earth or ground.
- the device can be designed as a sensor or measuring probe as a separate passive unit with at least one built-in or plug-in ring antenna with at least two diodes on the ring antenna connections and a capacitor device connecting the two signal lines and one connection point for each of the two signal lines.
- a signal amplifier unit can be assigned to the measuring transducer during the setup, which can be connected to a handheld or memory oscilloscope, an oscilloscope, a recorder or a computer with or without a signal amplifier. This takes into account the fact that there are many evaluation and display devices for every level of perfection, but that a passive sensor with the desired sensitivity has not yet existed.
- a third device type is characterized in that it is designed as a measuring device unit with one or more displays for the high-frequency field strength or corresponding corresponding values, the measuring device preferably having a connection for the acoustic reproduction of the low-frequency pulsation, in particular via headphones, and particularly preferably at least has a further connection for an oscilloscope and / or a recorder and / or a computer.
- a fourth type of device for professional use is characterized in that it is designed as an oscilloscope unit with a search, selection and display device for the high-frequency field strength and the low-frequency signals, in particular pulse sequences, with means for selective selection for displaying special biologically relevant parameters.
- the new invention relates to a device with memory / computer means for long-term detection, for example over several hours or days, possibly over weeks, of biologically relevant technical interference parameters, in particular the broadbanding detected RF field strength and the frequency of the LF signals or Peak sequences from the continuously fluctuating field loads.
- the new solution also allows a 6-minute averaging over 6 minutes and an analysis of the 6 minutes at the same time.
- the low-frequency modulations in particular pulsed signals, are analyzed in terms of frequency, peak values and signal curve.
- the local magnetic field load is recorded with a shielded or unshielded ring antenna.
- the primary search criteria with regard to frequency and peak values are the frequencies for the biological processes in humans, animals and plants.
- the measurement recording and processing must have a sensitivity to the possibly audible bioelectrical processes, e.g. are in the milli- and microvolt range.
- the sensor must be passive so that maximum dynamics can be achieved and the measurement recording is not falsified by active components, and must then be corrected again.
- a ring antenna pickup with diode and capacitor device a ring antenna pick-up with a resistance mechanism
- a variant of Figure 2 with a preamplifier between the ring antenna pickup and measuring device a further embodiment of Figure 1 with a second signal output, for example for a spectrum analyzer; nd 5b two classic antenna types for spectral analyzers; a new sensor as a size comparison to Figures 5a and 5b;
- Different variations with a large number of concentric and ring-shaped conductor tracks on a printed circuit board an example of a preferred embodiment of the invention with transducers and a measuring circuit without power supply and acoustic reproduction of the LF signals; a shielded loop antenna; different configurations of the measuring circuit; a data logger; and FIG.
- Fig. 8b a sensor with an oscilloscope with a cylindrical protective housing for the printed circuit board;
- Fig. 8b is a section IIIb-IIIb of Fig. 8a; an oscilloscope with attached sensor; a transducer with cable connection; a broadband transducer with a data logger; and 10b two printouts of the data logger with artificially switched on and off electronic devices; and 12 two long-term recordings with a data logger; a form example for the respective setup of the logger; a transducer with a handheld oscilloscope; a to 14c a recording of the determined pulsed frequency sequences from the mobile radio operation; a to 1 5d and 16a to 1 6c further examples of frequency sequences; a concrete example of a recording with computer / data storage, laptop and printer; a sensor according to the invention with a storage oscilloscope and an example of the display; a to 19h different printouts of the storage oscilloscope of the pulse sequences in different frequency ranges;
- FIG. 1 represents the new solution. Purely physically, this consists of a broadband transducer, a module 2 with a housing for the measuring circuit, signal lines 3 and 4 and a preamplifier 5.
- the broadband transducer is shown as a ring antenna 1 or as a simple wire loop.
- the central components of the measuring circuit 7 are two diodes 8 and 9 (HF germanium or Schottky diode, e.g. AA1 1 2) and two capacitors 10 and 1 1 (e.g. 1 - 100 nF).
- the capacitors are described as plates.
- the capacitor 10 thus has an inner plate 10 ', an outer plate 10 ", an inner plate 11' and an outer plate 11".
- the two inner plates 10 'and 11' are electrically connected to ground or earth E.
- the ring antenna has two separate connections, a connection 12 on the left and a connection 13 on the right.
- the left connection 1 2 is connected directly to the diode 8, and via the diode 8 to the signal line 4 and the outer plate 10 ′ of the capacitor 10.
- the right connection 13 is connected directly to the diode 9 and via the diode 9 to the signal line 3 and the outer plate 11 '' of the capacitor 11.
- the reverse blocking direction of the diodes is shown in the diagram. forms the ring antenna 1, the diode 8, the capacitor 10 and 11 and the diode 9 a symmetrical circuit with a signal outlet 14, which is denoted by the minus sign - and a signal outlet 1 5 by the plus sign +
- a signal amplifier 5 was necessary for the oscilloscope head.
- a classic circuit 6 is shown in the signal amplifier 5 with a + - (plus / minus) connection to the signal line 3 and a - (minus) connection point to the signal line 4.
- the ring antenna is designed as a broadband pickup, the broadband nature of FIG. 1 still being limited in the solution according to FIG. 2, however, has increased to a level not previously possible. The wide range can be increased at will by a large number of conductor tracks.
- FIG. 2 shows the heart of the sensor, a second solution with a printed circuit board 78. shown on an enlarged scale.
- 20 annular, concentric conductor tracks 79 are applied to the circuit board, each of which has a loop or represent a magnetic field antenna.
- the geometry of the concentric arrangement results in 20 different antenna lengths.
- Each of the conductor tracks 79 is connected via a miniaturized resistance network 80 on one side to the conductor 82 and on the other end side to the conductor 81.
- One conductor goes to the mass of the device, the other to the electronic measuring device.
- the downsized sensor has a large number of individual antennas, so that the measured value recording is not only broadband, but is carried out in almost the highest quality over an extreme width.
- the bandwidth can range from the lowest Hertz range to the Gigahertz range.
- the application is particularly suitable for the detection of interference parameters within the scope of bioelectronic sensitivity, but also in general industrial practice, especially when troubleshooting in the laboratory.
- FIG. 3 shows a further possibility in which a preamplifier 94 is interposed from DC to the HF range between the broadband sensor 1 and the structural unit 2.
- FIG. 4 shows a third possibility, two signal lines 30 and 31 being able to be led away from the circuit 7 of the measuring sensor before the diodes 8 and 9. It can be used as a measuring receiver e.g. a spectrum analyzer or an oscilloscope for FFt analysis in the HF / LF range can be connected.
- the sensor 1 with measuring circuit is connected directly to a logger 20 according to FIG. 9.
- FIGS. 5a and 5b show two conventional antennas of the prior art and FIG. 6a shows a sensor 1 according to the invention in the sense of a size comparison.
- FIG. 6b shows different pickups 1, 1 ", 1" ', 1 "" with different numbers of pickup loops.
- FIG. 7a shows a test device 34, consisting of the structural unit 2, with a measuring circuit 7, a ring antenna 1 as a wire loop of approximately 4 cm in diameter and headphones 35.
- the completely surprising thing is that there are no active elements in the measuring circuit, in particular no power supply (for example with a battery). At a distance of one meter from a DECT telephone, the power of the recorded signal via the wire loop is sufficient to make the headphone membrane vibrate. The 100 Hz pulse signal can be clearly recognized as immission from the DECT telephone 36. This experiment is very important, since it enables the basic functions of the new measuring circuit to be represented and proven very convincingly.
- the low-frequency signal is transmitted in maximum strength and unadulterated.
- FIG. 7b shows a shielded magnetic field antenna only as an example.
- the general antenna theories are not dealt with in detail. It is known per se that dozens of variations are possible and can be used.
- FIG. 2d is in top form when the magnetic field is primarily in demand.
- the ring or loop antenna or magnetic field antenna 40 has three characteristic sizes: the total effective length AL of the "antenna wire" or the core 41 of the shielded cable 42, the loop length SL and the loop width SB. In the case of a circle, the SL and SB are the same size.
- a circle in the shielded cable is shown with a circle Ax.
- a shrink tube 43 is attached, which is pulled over an insulating layer or directly over a shielding jacket 44.
- the core 41 is the receiving antenna and, on the one hand, by means of the shield and the loop shape, emphasizes or exclusively the magnetic field component.
- the core is led to the electronics as a measurement input via the right connection AE, whereas the shield 44 is connected to the device ground.
- the antenna is connected to a measuring device.
- the core 41 is connected directly to the device ground via the left connection AM. This results in an effective antenna length AL, as shown.
- the solution shown is only an example.
- the interference field agglomerations have any kind of rays and clubs, from needles to ball shapes and larger shapes. large majority is common to the local agglomerations that the magnetic field component dominates. What has been completely overlooked to date is the fact that magnetic amplitude modulation dominates very often. The "music" from the headphones or the loudspeaker immediately shows the type of interference signal technology.
- FIG. 7c shows different circuits 7 instead of the circuit according to FIG. 7a.
- the left figures show two configurations which are currently considered to be the best. In special cases, additional modules can be advantageous. In the case of the figures on the left, a bridge rectifier circuit is used and in the case of the figure on the right, a two-way rectifier circuit is used.
- FIG. 7d shows a data logger in a concrete structural configuration.
- the broadband transducer 1 is designed in a spherical shape.
- the ball preferably as a hollow plastic ball, primarily has a protective function for the antenna circuitry, which is designed as a circuit board as for electronic circuitry.
- the broadband transducer 1 is arranged on a base 31 via a fixed connection in the form of a support 30. All components except the broadband sensor 1 are arranged in the base 31.
- the data logger is designed in analogy to a bedside lamp and is intended to be placed at the respective measuring locations for the desired time.
- the data logger can have an internal battery power supply in low voltage 32 or a connection 33 to the network with a corresponding voltage transformer.
- the data logger contains the necessary computers and memory for the gigantic amount of data to be processed. Because the data logger has a very specific limited function, the software for programming, especially for the exact time the logger was recorded and the customer's specific data, can be built into the logger or arranged or used via an independent PC or laptop.
- the data logger can have any shape, in particular can be combined with or integrated into common oscilloscopes, e.g. is shown in Figure 9.
- FIGS. 8a to 8d show an oscilloscope 50, combined with a commercially available measuring device, in which all functions of the new solution are installed. Evaluation devices such as memories / computers, printers, etc. can be connected via various outputs 51, 52, 53.
- the great value of the solution according to FIGS. 8a to 8d is that all central information:
- the low-frequency signal display as a signal curve and signal strength
- the solutions according to FIGS. 8a to 8d have the great advantage that they have combined both the logger function and all the essential oscilloscope functions in one light device as a hand-held measuring device with battery supply.
- the transducer can have a disk shape 54 or a spherical shape 55 with a fixed support 55 or with a flexible connection 57.
- the antenna is designed as a printed circuit board 58.
- FIG. 9 shows a complete data logger for the recording of HF / NF interference fields and interference beams.
- the sensor corresponds to the solution according to FIG. 1.
- the signal line 3 is connected on the one hand to the electronics 26 of a peak value detector 27 and on the other hand directly to the data logger 28, as indicated by the two thickly drawn signal lines 3 'and 17.
- the RF field strength 18 and the corresponding LF peak value field strength 19 are correspondingly stored in the data logger 15 over a longer period of time.
- the two values can be changed during a programmed logger time of e.g. 24 hours of the entire measurement time can be recorded or printed out simultaneously.
- the entire logger unit 20 can additionally have a differential amplifier 21 and an effective value rectifier 22, so that a crest factor (HF / NF) 24 and an effective value HF / NF 23 are also stored accordingly. All stored values can be shown subtracted via a computer interface 25 and printed out via a printer.
- the operation and computing programs of the data logger 28, e.g. from pure low-frequency loggers are assumed to be known.
- Figures 10a and 10b show examples of artificially generated NF peaks by switching various devices on and off. It is an application relating to the radiation effects of devices in the home, office and manufacturing plants.
- Figure 1 1 shows the light (gray) lines, the low-frequency peaks and the dark (black) lines, the high-frequency base and peak loads. The two curves are very revealing and show that the basic load in the first part (bedroom) oscillates between 0.1 and 0.3 V / m and the peak load between 0.5 and 1.0 V / m.
- the bedroom is heavily exposed to external influences from mobile communications.
- the bedroom is no longer usable for highly electrosensitive people.
- the middle section has a relatively low base load because the room is shielded.
- the peaks (gray curve) are only slightly weakened.
- the right part was taken in an air-raid shelter. The burden is clearly lower.
- FIG. 12 shows a further example of a long-term recording in a residential house.
- FIG. 13 shows a hint for the respective location or change of location over time.
- the crest factor shows the extreme field fluctuations very clearly and is an important indicator for the load, especially with pulsating immissions.
- other corresponding measured values can also be recorded and displayed, e.g. effective values instead of peak values.
- a 1-D representation was described. Two dimensions, in particular three dimensions (isotropic recorders), can easily be recorded. It is possible to use three separate transducers or one transducer with loop antennas lying in the three spatial directions.
- FIGS. 14, 15 and 16 show individual interference pulse patterns in the low-frequency range from 0 to 1000 Hertz.
- Figures 14a, 14b and 14c show Ozsilloskopf on recorded as a small selection of "interference pulse patterns", which were recorded in a house.
- the first two examples show pronounced clock sequences in the frequencies 0.9 kHz and 454 Hz. Both the clear timing and the peak value curve are typical of a technical source. In addition to the actual clock frequencies that are currently active, it may also be decisive how the peak curve is, whether increasing or decreasing, suddenly starting, etc.
- the characteristic feature of the oscilloscope display is the snapshot.
- the interference pulse patterns shown are typical of the control signal technology used in the organization of mobile radio.
- a third display world can be selected with storage oscilloscopes.
- the new invention makes it possible for the first time to display low-frequency pulse sequences of less than 100 Hz from high and extremely high-frequency sources of interference.
- FIG. 17 shows a possible practical implementation of the new solution.
- the measuring device 37 in which a printer 39 can be operated via a connection 38 and a computer / memory 91 can be operated via a connection 90.
- the measuring circuit can either be arranged in the ring antenna 1 or else in the measuring device 30, as indicated by 7, 7 '.
- the ring antenna is connected to the measuring device on a stand 93 via a measuring line 92.
- Figure 9 shows the new solution with a ring antenna on a tripod and connection to a computer and a printer.
- FIG. 10 shows an oscilloscope 60 as a commercially available measuring device, in which all functions of the new solution are installed. Evaluation devices such as memory / computer, printer, etc. can be connected via various outputs. The great value of the solution according to the figure is that all central information:
- the low-frequency signal display as a signal curve and signal strength
- FIG. 18 shows an oscilloscope 76 from LeCroy, Geneva and USA, which also has the lowest frequency range with the new transducer from 0.1 to 100 Hz, for example, can process almost in real time. With an enormous amount of computing power, it is possible to use the new broadband transducer to record in short time intervals, for example individual frequency spectra down to the deepest range, and at the same time to display pulse sequences, as shown above the oscilloscope. With regard to the technical information, reference is made to the manufacturer's documents.
- FIGS. 19a to 19h show typical recordings of the storage oscilloscope in the lowest frequency range.
- FIGS. 19a and 19b prove the existence of brain and heart-active interference pulse sequences in the range from 0 to 80 Hz.
- FIG. 19d shows an extreme massing of interference frequencies below 1000 Hz with a strongly increasing strength below 200 Hz.
- a DECT cordless telephone was switched on. It is very interesting that not only a basic disturbance (1 hump) occurs, but in a weakened form up to 100 kHz repetitions of the disturbance pulse sequences.
- the functionality, particularly of the transducer can be demonstrated.
- the megahertz frequency range can also be reproduced with classic spectrum analyzers.
- FIG. 20 shows the currently most widespread measurement method for the high-frequency range by means of an RF spectrum analyzer 61.
- a typical recording antenna 48 which is connected to an RF spectrum analyzer via a connecting line 49.
- the antenna measures broadband. It is known that each antenna only records correctly in a central area. The measured value coincides in the manner of a Gaussian curve in the upper and lower areas.
- FIG. 21 shows a typical antenna circuit in the prior art.
- FIG. 22a to 22c show different designs for a complete sensor.
- FIG. 22a digitally shows the HF and LF values, the corresponding signals being recognizable via headphones, insofar as it is audible.
- Figure 22b shows an extremely inexpensive embodiment with analog display of NF and HF.
- FIG. 22c shows a further example of a digital display of the high-frequency field strength and of the acoustic reproduction via a loudspeaker.
- FIG. 23 shows the three effective model areas and the measurement criteria for mobile radio and microwave radiation exposure.
- the new invention is a complete replacement for measuring devices and opens up completely new territory in terms of measurement technology, be it for bioelectronic measurement or for industrial measurement.
- the new sensor At the center is the new sensor.
- converters in particular also oscilloscopes as spectral analyzers.
- the aim is to use selective or broadband high-frequency measurement over a long-term measurement to show the biologically relevant effects of both RF exposure and NF peak exposure.
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- Physics & Mathematics (AREA)
- Electromagnetism (AREA)
- General Physics & Mathematics (AREA)
- Measurement And Recording Of Electrical Phenomena And Electrical Characteristics Of The Living Body (AREA)
Abstract
Description
Claims
Applications Claiming Priority (7)
Application Number | Priority Date | Filing Date | Title |
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CH6572002 | 2002-04-18 | ||
CH657022002 | 2002-04-18 | ||
CH20132002 | 2002-11-30 | ||
CH201302 | 2002-11-30 | ||
CH782003 | 2003-01-20 | ||
CH78032003 | 2003-01-20 | ||
PCT/CH2003/000260 WO2003087857A2 (de) | 2002-04-18 | 2003-04-17 | Verfahren und einrichtung zum aufnehmen und aufbereiten von störfeldern und störstrahlen |
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EP1495338A2 true EP1495338A2 (de) | 2005-01-12 |
Family
ID=29254772
Family Applications (1)
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EP03714593A Withdrawn EP1495338A2 (de) | 2002-04-18 | 2003-04-17 | Verfahren und einrichtung zum aufnehmen und aufbereiten von störfeldern und störstrahlen |
Country Status (3)
Country | Link |
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EP (1) | EP1495338A2 (de) |
AU (1) | AU2003218847A1 (de) |
WO (1) | WO2003087857A2 (de) |
Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
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DE102006052539A1 (de) * | 2006-11-06 | 2008-05-15 | Deutsche Bahn Ag | Verfahren zur großflächigen Erfassung stark schwankender niederfrequenter magnetischer Felder, insbesondere im Rahmen der Ermittlung einer elektromagnetischen Verträglichkeit im Bereich stromführender Einrichtungen |
WO2016178042A1 (es) * | 2015-05-01 | 2016-11-10 | Noxtak Technologies Vba. | Sistema de monitoreo y evaluación del electrosmog |
Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2000041268A1 (en) * | 1999-01-05 | 2000-07-13 | Tevca Technologies, Inc. | Box-kite uhf/vhf television and radio communications antenna |
Family Cites Families (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2235163A (en) * | 1938-12-15 | 1941-03-18 | Rca Corp | Broad band antenna |
US4320402A (en) * | 1980-07-07 | 1982-03-16 | General Dynamics Corp./Electronics Division | Multiple ring microstrip antenna |
JPS57142002A (en) * | 1981-02-27 | 1982-09-02 | Toshiba Corp | Small-sized loop antenna |
DE9115582U1 (de) * | 1991-12-16 | 1992-12-17 | Siemens AG, 80333 München | Leiterplattenantenne |
US5300885A (en) * | 1992-06-05 | 1994-04-05 | Flam & Russell, Inc. | Field probe for measuring vector components of an electromagnetic field |
US5936594A (en) * | 1997-05-17 | 1999-08-10 | Raytheon Company | Highly isolated multiple frequency band antenna |
US5959815A (en) * | 1998-03-17 | 1999-09-28 | Gateway 2000, Inc. | Method and apparatus for detecting potentially damaging electrical fields |
WO2000029859A1 (de) * | 1998-11-18 | 2000-05-25 | Ackermann Patent Gmbh | Verfahren zur praxismessung und spannungs-messeinrichtung |
KR100338057B1 (ko) * | 1999-08-26 | 2002-05-24 | 황 철 주 | 유도 결합형 플라즈마 발생용 안테나 장치 |
EP1094322A1 (de) * | 1999-10-21 | 2001-04-25 | Heinrich Kehlbeck | Messvorrichtung zur Messung der Intensität von schwacher elektromagnetischer Strahlung, Plasmafeldern, Ionenfeldern, Photonenfelder und/oder Elektrosmog |
-
2003
- 2003-04-17 EP EP03714593A patent/EP1495338A2/de not_active Withdrawn
- 2003-04-17 WO PCT/CH2003/000260 patent/WO2003087857A2/de not_active Application Discontinuation
- 2003-04-17 AU AU2003218847A patent/AU2003218847A1/en not_active Abandoned
Patent Citations (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2000041268A1 (en) * | 1999-01-05 | 2000-07-13 | Tevca Technologies, Inc. | Box-kite uhf/vhf television and radio communications antenna |
Also Published As
Publication number | Publication date |
---|---|
AU2003218847A1 (en) | 2003-10-27 |
AU2003218847A8 (en) | 2003-10-27 |
WO2003087857A2 (de) | 2003-10-23 |
WO2003087857A3 (de) | 2004-02-26 |
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