Professional instruments for measuring subtle fields, ultra-weak interactions, and torsion field structures. Based on 20+ years of pioneering research.
The Torsion Field Detector project represents a breakthrough in the field of subtle field measurement and analysis. Led by Viktor Shkatov and Pavel Shkatov, our research team has developed a series of sophisticated instruments capable of detecting and measuring torsion fields, ultra-weak interactions, and information fields.
Our research spans from direct contact measurements to remote monitoring using photo intermediaries, enabling the detection of events across vast distances - from Earth-based phenomena to cosmic events millions of kilometers away.
Access past events through static images and time-shifted measurements
Monitor objects at distances from kilometers to millions of kilometers
Ultra-sensitive detection with equivalent sensitivity to 10E-6K, 10E-9V
Based on G.I. Shipov's theoretical framework, the Physical Vacuum represents a fundamental level of existence from which all material phenomena emerge. This theory predicts the existence of primary torsion fields as ideal information carriers.
Torsion fields correspond to rotation at all levels of existence. The manifestations of subtle fields (SF-SI) are connected with spin-torsion fields as fields of rotation, creating a real causal chain in the appearance of material objects.
The Global Information Field (GIF) or Global Consciousness (GC) provides a framework for understanding non-local interactions. This field enables remote monitoring, retrospective analysis, and prospective detection of events.
The vacuum medium exhibits unique properties for TF-signal propagation, including variable propagation speeds and direct connection between speed, distance, and material density. This leads to the principle of wave invariance in interacting objects.
Professional-grade instruments for subtle field measurement and analysis
The first torsimeter using a magnetized but not saturated magnetic medium as the torsion field sensitive element. Features comparison with reference frequency and LCD display of results.
Orthogonal and differential design with two capacitive TF sensors on high-permeable ceramics. Features controlled torsion gates UTZ-2 and laser communicator.
Temperature-controlled sensor on CD4011A chip at 5 MHz. Features optical laser circuit with multi-mirror periscope and adjustable beam positioning. Triple frequency conversion.
Dual-beam differential torsion contrast meter with step-scan unit for circular laser beam movement. Enables measurement of field periphery without touching the center. USB connectivity and PC control.
Features a 3D block of piezoelectric sensors. Detects slow rotation of physical objects, determines position behind barriers, diagnoses dangerous substances. Successfully used for pipeline damage detection.
Revolutionary design where the operator's heart serves as the TF sensor. Uses heart rate variability (HRV) and RMSSD analysis. The device forms requests and analyzes R-R interval dynamics, representing a return to human beings as ultra-sensitive measurement components.
Registered earthquakes in Italy (06.04.09 and 11.03.11). The first was recorded in real-time with precursor signals, the second using retro+1 day mode with exact time alignment.
Detected underground nuclear explosions in North Korea (23.05.09 and 06.01.16). The first in real-time showing characteristic bell-shaped precursor, the second using retro+1 mode with multi-country synchronous detection.
Registered the Istanbul terrorist attack (29.06.16) using virtual retrospective with time reversal - information read from the Information Field in reverse time mode.
Successfully located hidden defects in Chile pipeline systems from Tomsk, Russia, using terrain photos and maps. Location error was about 1 meter, limited only by map resolution.
Registered the process of destruction of the MIR space station on 23.03.2001 in real-time using a newspaper photo as intermediary.
Detected the collision of Rosetta space station with comet 67P Churyumov-Gerasimenko on 30.09.16 at 720 million km distance using retro+1 mode. Signal delay accounted for 40 minutes propagation time.
Successful one-way TF communication from Perth, Australia to Tomsk, Russia on 22.05.11, with synchronous response recorded in Buenos Aires using 3D magnetometry.
TF communication session between New York (SEVA device by M. Krinker) and Tomsk (AUREOLE-01M1 by V. Shkatov) on 23.06.11, demonstrating intercontinental subtle field transmission.
Demonstrated that all events are automatically recorded in the Information Field. Using appropriate techniques, desired records can be restored and read - including time reversal modes.
First-ever virtual TF monitoring of the future - a 20-minute session monitored a 22-day process of pregnancy, birth, and rehabilitation, with 1 day of real life compressed into 1 minute of scanning.
Interested in our technology? Reach out to discuss research collaboration, product inquiries, or technical questions.