#gdvsputnik

СИСТЕМА БЕСКОНТАКТНОЙ РЕГИСТРАЦИИ РЕАКЦИИ ЧЕЛОВЕКА-ОПЕРАТОРА И ГРУППЫ ЛЮДЕЙ НА ИНФОРМАЦИОННО-ПСИХОЛОГИЧЕСКИЕ ВОЗДЕЙСТВИЯ Орлов Д.В.1,2, Коротков К.Г. 1,2, Гатчин Ю.А. 1, Сухостат В.В. 1, Гришенцев А.Ю. 1 1 Санкт-Петербургский национальный исследовательский университет информационных технологий, механики и оптики 2 Федеральное государственное бюджетное учреждение «Санкт-Петербургский научно- исследовательский институт физической культуры», Метод газоразрядной визуализации (ГРВ) используется во множестве научных и практических областей . Одним из новых направлений является регистрация реакции группы людей на различные информационно-психологические воздействия . Для проведения таких измерений авторами совместно с компанией ООО "КТИ" были разработаны и запущены в серийное производство прибор «ГРВ Эко-Тестер» и антенна «ГРВ Спутник», которые обеспечивают необходимую чувствительность и стабильность измерительной системы. Прибор «ГРВ Эко-Тестер» был спроектирован в соответствии с рекомендациями по анализу и коррекции дестабилизирующих факторов в процессе измерений методом ГРВ . Была разработана стандартная процедура проведения измерений и обработки результатов . В случае регистрации реакции человека-оператора или групп операторов на различные виды информационно-психологических воздействий возможна реализация двух подходов: 1) мониторинг состояния окружающего операторов пространства по всевозможным характеристикам с целью своевременного выявления факторов, способных оказать влияние на функциональное состояние человека; 2) мониторинг функционального состояния самих операторов. В случае осуществления первого подхода необходима установка множества датчиков, регистрирующих уровни шумового давления, вибрации, инфразвука, ультразвука, электромагнитных полей промышленных частот, электростатических полей, магнитных полей, радиации, микроклимата, концентрации легких аэроионов, химический состав воздуха. Кроме этого необходимо специальное программное обеспечение, позволяющее централизованно контролировать сигналы от всех вышеперечисленных датчиков и приборов. С технической и коммерческой точек зрения данная задача является нетривиальной. В случае же реализации второго подхода обычно проводится измерение различных физиологических характеристик (вариабельность сердечного ритма, артериальное давление, проводимость кожи, движения глаз, выражение лица, виброизображение) каждого человека-оператора в реальном времени. В подобном случае кроме сложности осуществления подобной задачи (особенно в случае бесконтактной регистрации) добавляется некомфортность для человека-оператора наличия множества датчиков на теле (контактная регистрация), что сказывается на продуктивности и эффективности работы. Вариантом решения данной проблемы является использование бесконтактных датчиков и технологий, позволяющих неинвазивно получать информацию о функциональном состоянии человека. Однако на данный момент разработаны системы, позволяющие определять функциональную психофизиологическую активность лишь отдельного человека. Следовательно, для контроля состояния группы людей требуется большое количество бесконтактных систем, кратное количеству человек в группе, что означает большие финансовые затраты, хотя и даёт возможность отслеживать состояние каждого члена группы в отдельности. Принимая во внимание трудности реализации традиционных подходов, возникает потребность в новых методах, позволяющих осуществлять неселективный мониторинг характеристик окружающей среды и неинвазивную оценку функционального состояния группы людей в реальном времени. Таким подходом является метод газоразрядной визуализации, а именно прибор «ГРВ Эко-Тестер» с антенным датчиком «ГРВ Спутник». Целью данной работы является экспериментальное тестирование прибора «ГРВ Эко- Тестер» для определения адекватности получаемых данных поставленным задачам: возможность выявления физических и химических воздействий, влияющих на состояние оператора, и точность реакции на изменение функционального состояния человека- оператора. Методы исследований Принцип формирования газоразрядный изображений Принцип формирования газоразрядных изображений (ГРИ) описан в . Процедура формирования ГРИ с помощью прибора «ГРВ Эко-Тестер» заключается в следующем. Металлический цилиндр (тест-объект) помещается на прозрачный кварцевый электрод, на обратную сторону которого нанесено прозрачное токопроводящее покрытие, на которое в течение заданного промежутка времени подаются импульсы напряжения от генератора. Мощность импульсов и длительность воздействия задаются программно на персональном компьютере. При высокой разности потенциалов между тест-объектом и пластиной из металлического цилиндра выбиваются электроны и фотоны, которые, сталкиваясь с молекулами воздуха, ионизируют их, что в итоге приводит к развитию лавинного и/или скользящего газового разряда. Характеристики газового разряда определяются свойствами внешней цепи – то есть тест-объекта, провода, подключенного к нему, антенны «ГРВ Спутник» и пространства между антенной и землей. Пространственное распределение разряда фиксируется специализированной видеокамерой на базе ПЗС-матрицы, расположенной непосредственно под прозрачным электродом. Видеопреобразователь осуществляет оцифровку изображения и передачу его на компьютер для дальнейшей обработки. ГРИ обрабатываются в специально разработанном программном комплексе, где осуществляется расчет параметров изображений, таких как энергия свечения, площадь засветки, средняя интенсивность разряда и др. Параметры ГРИ зависят от физических характеристик внешней цепи, в частности, электрической емкости и сопротивления .

GDV Sputnik distant influence Также существует техническая возможность обработки ГРИ в реальном времени на сервере, на котором установлено специально разработанное программное обеспечение BioDeck. Прибор ГРВ через Интернет посылает каждое снятое ГРИ на сервер, где рассчитываются необходимые параметры. Рассчитанные данные в виде графиков пересылаются с сервера на пользовательский компьютер, на котором установлена пользовательская версия программного обеспечения BioDeck, позволяющая получать числовые значения рассчитанных параметров ГРИ в реальном времени.

GDV Sputnik distant influence

Full text, PDF: GDV Sputnik distant influence

GDV for earthquake forecasting

The Energy of Space Method and device for earthquake forecasting https://youtu.be/pnXGbwYLlYE Abstract FIELD: seismology. SUBSTANCE: invention relates to seismology and can be used to predict earthquakes. Essence: in the controlled area, a device is installed to ensure the recording of gas-discharge air imaging on the surface of the medium. Device comprises an optically transparent electrode, a gas discharge glow detection means, means for creating an electromagnetic field between the electrode and gas-discharge glow detection means, and a gas-discharge glow parameter processing unit. Record the parameters of gas-discharge glow. Forthcoming earthquake is judged by reducing the area of gas-discharge luminescence by less than 20 %, while at the same time increasing the intensity of the gas-discharge glow by at least 1.5 %.EFFECT: simplification of forecasting of medium and strong earthquakes.12 cl, 2 dwg 1. A method of predicting an earthquake zone, characterized in that the controlled area is set the device, ensuring registration discharge air visualization on the medium surface, comprising an optically transparent electrode, gas discharge detection means, means for creating an electromagnetic field between the electrode and the gas-discharge means for registering the luminescence connected to a conductive electrode portion, and a block parameter processing gas discharge, the gas discharge spark recorded parameters Nia, with the impending earthquake is judged by the reduction gas discharge area of ​​less than 20% while increasing the gas-discharge luminescence intensity not less than 1.5%. 2. A method according to claim 1, characterized in that the gas discharge glow is generated by supplying high-voltage pulses at a repetition frequency electrode 1000 ± 100 Hz. 3. A method according to claim 1, characterized in that the gas discharge parameters were recorded continuously. 4. A method according to claim 1, characterized in that the gas discharge parameters were recorded periodically. 5. A method according to claim 1, characterized in that the electrode is mounted on outdoors. 6. A method according to claim 1, characterized in that the time measuring unit is less than 10 microseconds. 7. A method according to claim 1, characterized in that the voltage supplied to the electrode with single pulses once per 60 seconds. 8. Apparatus prediction earthquake zones, characterized in that it comprises an optically transparent electrode, gas discharge detection means, means for creating an electromagnetic field between the electrode and the gas-discharge means for registering the luminescence that is connected to the conductive portion of the electrode, processing parameters and block gas discharge. 9. The apparatus according to claim 8, characterized in that the optically transparent electrode is a dielectric plate coated with a layer of conductive material, said conductive layer facing toward the gas discharge recording means. 10. The apparatus according to claim 8, characterized in that the detection means is a gas discharge CCD. 11. The apparatus according to claim 8, characterized in that the means for creating an electromagnetic field of high intensity is a pulse generator with a frequency of 1000 ± 100 Hz. 12. The apparatus according to claim 8, characterized in that the processing means of gas discharge parameter is a personal computer with appropriate software. Description GDV for earthquake forecasting translated from Russian The invention relates to the field of geophysics, and can be used to predict earthquakes. Earthquakes are tremors and fluctuations in the Earth's surface. The most dangerous of them arise due to offsets and tectonic fractures in the earth's crust and upper mantle portion. Fluctuations from them in the form of elastic seismic waves are transmitted over long distances, and in the vicinity of the centers of earthquakes, they can become a cause of damage to buildings and loss of life. Earthquakes and related phenomena is studying a special science - seismology, which conducts research in the following areas: 1. The study of the nature of earthquakes, in other words, looking for an answer to the question: why, how and where they occur. 2. Application of knowledge about earthquakes to protect them by forecasting possible in one place or another seismic shock for the construction resistant to the effects of their designs and constructions. 3. Study of the Earth's interior structure and exploration of mineral deposits using seismic waves from earthquakes and artificial seismic sources. Nowadays range of devices that register vibrations of the earth, is quite high. There is an opportunity to learn about what happened the earthquake, literally "without leaving home" - opening a page on the Internet. For the year recorded more than a million different earthquakes, the strength of the Earth wobble usually poses no threat to the life of the population. Earthquakes are known, generally, for the destruction which they are applied. At the same time dangerous not only the underground vibrations, as well as many other phenomena associated with them, such as tsunamis, lava emissions of volcanic gas and ash to the surface. Unfortunately, their popularity is higher, the longer they take human victims. This occurs most often in areas of high seismic activity, and these areas are known to mankind. Using the equipment, which may signal an impending earthquake in advance, can help to avoid human casualties, as well as man-made accidents. Is known (RU, patent 2453871, publ. 20.06.2012) a method for predicting earthquakes by predicting it by forerunner. According to the known method produces a local compensation of the geomagnetic field well before the earthquake by creating compensating magnetic field of opposite tension geomagnetic field and monitoring the spontaneous violation of the compensated magnetic field, wherein a precursor earthquake occurrence determined by the occurrence of the violation and the appearance of an additional component of the magnetic field strength that violates the local payment geomagnetic fields, and produce a bearing on several Dalen apart places expected epicenter of the earthquake observation in the direction of the vector component of the additional magnetic field. To implement this method, an apparatus, comprising a rack mounted on the base with a magnetic compass arrow on the needle, the azimuth compass scale with possibility of adjusting its rotation around the magnetic needle of a compass. It is further provided a fortified on racks turntable circular wire frame - the solenoid, the center of symmetry of which coincides with the center of the magnetic compass needle, and its diameter is disproportionately greater than the length of the magnetic needle of a compass, with the possibility of adjusting the rotation of wire frames around a diametral horizontal axis and, together with the turntable , about a vertical axis, the circular wire frame included in the electric circuit comprising a source of steady dc voltage inverter detecting current, switch, normally closed button and control the current. The disadvantage of this technical solution is the need for, and a large amount of pre-preparatory work, the dependence of the results from external magnetic fields, and the complexity of the method used in the equipment. Also known (RU, patent 2489736. publ. 08.10.2013) a method for detecting the possibility of occurrence of catastrophic events. According to the known method the measurement is a parameter geophysical field in a controlled area and a judgment from the data of the possibility of catastrophic events, wherein the measurement is carried out continuously, reveal fluctuations measured value and exhibit sinusoidal oscillations increasing frequency having an amplitude significantly different from the background for the controlled area, and a period of from 100 to 1,000,000 with, the simultaneous recording is performed in the pressurized atmosphere and evap s, the determination of each selected point of a sum of increments of the amplitude function of pressure and temperature versus time, identifying the values ​​of said parameter area not equal to zero, the judgment about the time of occurrence of an earthquake on the time of appearance of these bands, the place of the earthquake is judged by the spatial position of such zones, Thus in one of claims seismic regions further diagnose atmosphere changes wave mode from regular measurements of the total content of ozone in the atmosphere in the sliding time window m Tod Fourier analysis, comparing the variation of seismic frequency ranges in the data RAM ozonometers, predetermined according to archival data, with reference seismogenic trends activation treble amid recession low frequencies emit seismic dangerous periods and specify the time of occurrence of the earthquake, but by definition manifestations of these effects and their duration is set approximate force of the earthquake, according to the peculiarities of the spatial structure of the spectral effects set position epicyte tral zone. In this further operate regular deep seismic sounding in the bottom ground in a controlled area, the measurement of the sea ground vibrations operate on discrete areas of the sea waters at different times so that the measurement obtained at each measurement point have different values ​​of time intervals relative to the nearest to the moment of measurement of the last points in the upper culmination of the moon on a fixed geographic meridian, for the analysis of microseismic waves operate for I transverse microseismic waves, while for all the emitting portion microseismic discrete points are selected from all the harmonics of the two broadband seismic receivers reflected simultaneously with substantially equal amplitudes and lying in the redistribution of the angle of arrival of the reflected waves. The above method is technically complicated and time-consuming, is mainly designed for the prediction of earthquakes on the seabed. GDV for earthquake forecasting Is known (RU, patent 2282220, publ. 20.08.2006) a method for determining the time, place and magnitude of earthquakes, comprising identifying seismogenerating zones potentially base structures for various purposes, placement in these zones a set of points of measurement of geophysical quantities measurements and in their result of the detection of anomalies due to rock deformation zones above holding space-time mapping analysis anomalies allocation precursors (foreshocks) earthquakes Zateev definition of the epicenter, time and magnitude of strong earthquakes. The disadvantage of this method is that the basis of the method is the assumption of the existence of a common co-directional tangential stress axes to outbreak foreshocks - weak earthquakes precede the main event, whereas the directions of these axes may form a considerable angle during large area preparation of strong earthquakes. In addition, the method is not sufficient criteria and selection procedure foreshocks clearly described from the whole set of seismic events in this region. All this reduces the reliability and accuracy of the method and the accuracy of determining the position of the predicted epicenter of a strong earthquake. In this case, possible ambiguity in determining the location, time and magnitude of an earthquake that could have an impact on the base of designed or existing facilities. The technical problem solved by using the developed method and apparatus is to provide the prediction zone (chamber) of medium and strong earthquakes. The technical result achieved when implementing the developed method and apparatus is their simplification. To achieve said technical result suggested to use the developed method earthquake prediction zone. According to the developed method airside mounted device providing registration discharge visualization of air on the surface of the medium and containing the optically transparent electrode, the detection means gas discharge, means for creating an electromagnetic field between the electrode and means for registering gas discharge connected to the conductive portion of the electrode, and a block parameter processing gas discharge, and record the parameters of gas discharge glow generated electromagneti bubbled pulses, wherein the impending earthquake is judged by the reduction gas discharge area by at least 20% while increasing the gas-discharge luminescence intensity not less than 1.5%. Experimentally observed that over the hearth quake for a few hours before it starts infrasonic vibrations are generated in the range up to 6 Hz, which leads to a change in electrical characteristics of the air above the region of the earthquake. The presence of these infrasonic vibrations that cause discomfort to the condition of animals and birds, has long been used to predict future earthquakes. It has been experimentally established that changes the character before the eruption of gas discharge air luminescence over future earthquake zone. Presumably electromagnetic radiation caused by the processes occurring within the earth to earth vibrations inscribed sensor is amplified by gas discharge, which makes it possible to visualize this electromagnetic radiation. This was the basis for the development of these technical solutions. Preferably, the gas discharge glow is generated by supplying to the electromagnetic field pulses of high tension electrode (duration roughly 10 ms with a repetition rate of 1000 ± 100 Hz.). The electrode is preferably mounted on outdoors. Advantageously, the measurement time unit is less than 10 microseconds. Typically, high voltage is applied to the electrode with single pulses once per 60 seconds (exposure may vary from 0.5 seconds to 30 seconds). To achieve said technical result, to use the requested zone designed earthquake prediction device.It comprises an optically transparent electrode, gas discharge detection means, means for creating an electromagnetic field between the electrode and the registering means connected to the conductive portion of the electrode, and a processing unit for the gas discharge parameters. Preferably, the optically transparent electrode is a dielectric plate (glass) coated with a layer of conductive material (tin or titanium oxide), wherein the conductive layer is facing towards the means of recording parameters gas discharge. Registration means is a gas discharge CCD or formed at its base camcorder. Means for creating a high intensity electromagnetic field is a high voltage pulse generator with a frequency of 1000 ± 100 Hz. Gas discharge means for processing parameters is the program a personal computer with appropriate software. Experimental test developed technical solutions conducted between mid-December 2015 to April 2016 (inclusive). The venue of the Republic of Moldova was chosen as an experiment, Taraclia district. This area has a sufficient seismic activity.

GDV for earthquake forecasting

Method and device for earthquake forecasting fig.1 It was used to design a device whose block diagram is shown in FIG. 1, the following symbols are used: object of study 1 (air), an optically transparent electrode 2, the gas discharge 3, emission region 4, generator 5, the optical system 6, the video converter 7, 8, 9, parameter processing means. The equipment was in non-residential, isolated room, without any additional heating. Diurnal measurements were performed, the shooting mode - 30 seconds. We considered only with the vibrations of an earthquake above 2.8 points and a source of up to 200 km away from the installation area. Geographically, this mainly European earthquake epicenter - Eastern the Carpathians, Physician zone, Romania (Zona seismica Vrancea, judetul Buzau, Zona seismica Vrancea, judetul Vrancea).

GDV for earthquake forecasting fig.2 FIG. 2 is a typical view taken options in a graphical form. More than 6 million charts was obtained. The following conclusions were reached: 1. In most cases, for about 8-14 hours before the earthquake signal changes have been recorded;The most informative and sensitive parameters are area and average intensity. 2. There were three types of change, it is believed that it may be associated with different types of earthquakes, sources of which are different tectonic plates. For example: 03/14/2015 00-31, the platform 3, 9 points, 118 km, Buzau The decrease in the glow area before the earthquake 22.36% The increase of the luminescence intensity before the earthquake 2.25% 03/16/2015 17-49, 4, 6 points, 115 km, Buzau The decrease in the glow area before the earthquake 29.95% The increase of the luminescence intensity before the earthquake 2.83% 3. There were also documented other parameter changes, probably related to the regular weather events. This invention will allow to predict the imminent fluctuation earth's surface within a radius of 100-150 km from the epicenter, for 4-5 hours before the earthquake. Also, the data will indicate the strength of future earthquakes. Presumably electromagnetic radiation caused by the processes occurring within the earth to earth vibrations inscribed sensor is amplified by gas discharge, which makes it possible to visualize this electromagnetic radiation.

GDV for earthquake forecasting

Patent RU2655027C1 GDV Sputnik and The Energy of Space

GDV for earthquake forecasting

The Energy of Space Project – Consciousness and Environmental Research

Teotihuacan pyramids GDVCAMERA Bio-Well measurements 02.11.2019 we were privileged to visit tunnels, recently excavated under Sun and Quetzalcoatl pyramids. Both tunnels have 105 meters and end exactly under the center of a pyramid. Sun pyramid tunnel is narrow, curvy and the walls left unprocessed, while Quetzalcoatl tunnel is strait, wide and all the walls are processed. Both tunnels were filled with earth to the top about 2000 years ago (according to carbon dating of wood samples). To define the time of construction of tunnels is impossible. We did measurements in tunnels with Bio-Well Sputnik sensor, as well as at the top of Quetzalcoatl pyramid. Result are presented at Fig.1. At the same graph presented results of 2012 measurements.

Teotihuacan pyramids measurements

Teotihuacan pyramids measurements Conclusion GDV Sputnik (Bio-Well Sputnik) measurements confirm high Energy values at the top of pyramids and low Energy in the tunnels. The higher values was recorded only at the top of Bosnian pyramids (see results in Korotkov K. Mysterious Mummies of Nazca. 2019).

Teotihuacan pyramids measurements 2019

See also: The Energy of Space Department at IUMAB Library

Evaluation of the environmental parameters in several places of Moscow with Electrophotonic Imaging technique

Korotkov Konstantin, PhD Mannspeiser Ruben

Introduction As part of the plan to conduct experimental studies with the Bio-Well and "Sputnik" sensor, a series of experiments to measure the parameters of space in a number of places in Moscow city was carried out on April 17 to 19, 2016. Methods April 17, 2016: With the blessings of Father Abbot Nicholas, a series of measurements was carried out at the Church of St. Nicholas in Tolmachy. In this temple is preserved the holy Vladimir icon of the Mother of God, brought to Russia from Constantinople at the time of the Grand Duke of Kiev, Yuri Dolgoruky (1090–1157). The histories of Moscow and of the icon of Vladimir Mother of God are eternally inseparable. How many times did the Mother of God save the capital city from enemies through the grace of her holy icon? This icon has linked Apostolic times to Byzantium, Kievan Rus to Vladimir Rus, and later to Muscovy, the Third Rome; as it is said, “there will be no Fourth.” The kingdom of Moscow was formed by divine Providence and embraced the mystical ties of ancient empires, historical experience and traditions of other Orthodox peoples. The miracle-working Vladimir icon became a symbol of unity and succession. The icon survived centuries of wars and unrest in Russia, and for many centuries, it was a symbol of God's protection of the Russian land. Since the mid-1930s, the icon has been kept in the Tretyakov Gallery exhibition in Moscow, and was later transferred to the Church of St. Nicholas. On the morning of April 17, we were given permission to mount the sensor "Sputnik" near the Vladimir icon of the Mother of God, with the back of her hand at a distance of about one meter from the icon. The sensor operated in a continuous mode, parameters were recorded every 5 seconds, we were unable to control data before final processing, and so, the experiment was conducted in double-blind mode. During the whole time, there were over 200 people in the Temple. At the end of the Sunday service in the Temple, the registration of parameters was carried out with the same device at the entrance to the Temple, and at the exit of the Temple. The temperature was in the range of 250C, humidity about 50%. Data analysis was carried out later on the Bio-Well server, when we connected to the internet. On the evening of the same day, “Sputnik” parameters were recorded by the same device indoors of the Evangelical Lutheran Cathedral of Sts. Peter and Paul during the concert of organ music, with participation of duduk and tenor. April 18: “Sputnik” parameters were recorded at Novodevichy Cemetery near the grave of Anton Chekhov, and on April 19 at Perepechinsky cemetery near the grave of an unknown person. On both days, the weather was clear and sunny, with a temperature of 11–120C, humidity 50–60% in the absence of wind. Results In data processing, we are interested both in the value of environmental parameters and in the dynamic response of the “Sputnik” sensor to the events taking place in this environment. In the Temple of St. Nicholas, the recording was held before and during the Sunday service, which was reflected in the change in the parameters. Fig. 1 shows the dynamic curve of the energy parameter within 140 minutes. The first 10 minutes of recording were carried out before the service. When the reading of the Psalter started, with the choir joining after 40 minutes, the signal was reduced; however, with the beginning of the service, it began to increase; about an hour after the beginning of the service, the signal reached a stable level, and remained there for another 40 minutes till the end of the recording, slightly decreasing by the end (Fig. 1). The “Environment Activity" index (see description in the Discussion section) was within the range of the minimum values, slightly changing during the service (Fig. 2).

Environmental parameters in Moscow

Full text PDF: Environmental parameters in Moscow

The Energy of Space Project – Consciousness and Environmental Research

Teotihuacan pyramids GDVCAMERA Bio-Well measurements 02.11.2019 we were privileged to visit tunnels, recently excavated under Sun and Quetzalcoatl pyramids. Both tunnels have 105 meters and end exactly under the center of a pyramid. Sun pyramid tunnel is narrow, curvy and the walls left unprocessed, while Quetzalcoatl tunnel is strait, wide and all the walls are processed. Both tunnels were filled with earth to the top about 2000 years ago (according to carbon dating of wood samples). To define the time of construction of tunnels is impossible. We did measurements in tunnels with Bio-Well Sputnik sensor, as well as at the top of Quetzalcoatl pyramid. Result are presented at Fig.1. At the same graph presented results of 2012 measurements.

Teotihuacan pyramids measurements

Teotihuacan pyramids measurements Conclusion GDV Sputnik (Bio-Well Sputnik) measurements confirm high Energy values at the top of pyramids and low Energy in the tunnels. The higher values was recorded only at the top of Bosnian pyramids (see results in Korotkov K. Mysterious Mummies of Nazca. 2019).

Teotihuacan pyramids measurements 2019

See also: The Energy of Space Department at IUMAB Library

The Energy of Space Project – Consciousness and Environmental Research

Teotihuacan pyramids GDVCAMERA Bio-Well measurements 02.11.2019 we were privileged to visit tunnels, recently excavated under Sun and Quetzalcoatl pyramids. Both tunnels have 105 meters and end exactly under the center of a pyramid. Sun pyramid tunnel is narrow, curvy and the walls left unprocessed, while Quetzalcoatl tunnel is strait, wide and all the walls are processed. Both tunnels were filled with earth to the top about 2000 years ago (according to carbon dating of wood samples). To define the time of construction of tunnels is impossible. We did measurements in tunnels with Bio-Well Sputnik sensor, as well as at the top of Quetzalcoatl pyramid. Result are presented at Fig.1. At the same graph presented results of 2012 measurements.

Teotihuacan pyramids measurements

Teotihuacan pyramids measurements Conclusion GDV Sputnik (Bio-Well Sputnik) measurements confirm high Energy values at the top of pyramids and low Energy in the tunnels. The higher values was recorded only at the top of Bosnian pyramids (see results in Korotkov K. Mysterious Mummies of Nazca. 2019).

Teotihuacan pyramids measurements 2019

See also: The Energy of Space Department at IUMAB Library