WO2011108957A1

WO2011108957A1 - Method for creating spatial disorientation in an individual and device for carrying out said method

Info

Publication number: WO2011108957A1
Application number: PCT/RU2010/000387
Authority: WO
Inventors: Леонид Андреевич КОСИК
Original assignee: Kosik Leonid Andreevich
Priority date: 2010-03-01
Filing date: 2010-07-12
Publication date: 2011-09-09
Also published as: RU2425667C1

Abstract

The invention relate to medicine. The method for creating spatial disorientation in an individual comprises stimulating the visual and auditory analyzers synchronously and in harmony with one another. The remaining sense organs are not stimulated in a manner equal to the visual and auditory analyzers, nor synchronously, and are mismatched with one another, which results in the mismatching of the cortical and subcortical functional systems of the brain that respond to perception of space and, as a consequence, causes spatial disorientation. In the device for carrying out the method, the base is in the form of a rectangular plate and is provided with telescopic supports which are mounted vertically at the corners of the plate and have extensible rods. The supporting element comprises a rectangular platform, an electric drive, a driving roller and a displacement mechanism. The device is also provided with an inflatable pneumatic foot rest which is arranged on the platform, a compressor and a biaxial horizon sensor which is mounted on the platform, and is also electrically connected to a power supply unit, a commutator and computer. The computer is electrically connected by an input to the biaxial horizon sensor and by an output to the commutator, the outputs of which are electrically connected to electric drives of a longitudinal and transverse carrier, respectively.

Description

DESCRIPTION OF THE INVENTION

METHOD FOR CREATING SPATIAL DISORIENTATION IN

TERMINAL AND DEVICE FOR ITS IMPLEMENTATION

Technical field

The invention relates to medicine, namely to the field of psychophysiological research.

State of the art

A known method for assessing the functional state of the central nervous system of a person and a device for its implementation (RU 2153847 C2, 08/10/2000).

A known method of reducing the negative impact of the gravitational field of the Earth on the human body (RU 2215512 CI, 1

November 0, 2003).

A well-known rehabilitation psychophysical complex for training using biofeedback, an audio tactile therapeutic device and a touch chair RU 2289311 C2, 12.20.2006).

However, the above patent documents in part of the method determine the general level of technology and are not particularly relevant. Thus, analogues of the proposed method are not found in published patent and non-patent sources of information.

A device is known for reducing the negative effect of the gravitational field of the Earth on the human body, comprising a base, a supporting structure, movably mounted on the base, and a chair with a seat and back mounted on a supporting structure, an object of work and peripheral equipment RU 2215512 C1, 11/10/2003). A device is also known for reducing the negative effect of the Earth's gravitational field on the human body (RU 2290157 C2, 12/27/2006).

The device, known from patent RU 2290157, is selected as a prototype because it contains the maximum number of features similar to those of the proposed technical solution.

The device according to patent RU 2290157 contains, as claimed, a base and a support structure movably mounted on the base, including a support element equipped with guide rollers, a support element made in the form of a ring mounted on the guide rollers with the possibility of rotation relative to the central axis of the ring, and a chair with a seat and back fixed to the ring, a visual object and equipment.

Disclosure of invention

Under ordinary conditions, the perception of space and spatial assessments of reality are formed under the influence of the constant gravitational field of the Earth and are based on mutually agreed information from receptors of the sensory organs to the brain. Reflection of reality, control of the location and movement of a person in space is carried out by the cortical and subcortical functional systems of the brain. External and internal stimuli arrive through afferent flows from receptors to anatomical and physiological systems - analyzers (analyzers include all sensory organs). The functional systems of the brain continuously analyze the intensity and mutual coordination of stimuli emanating from sensory receptors. Cortical centers of the head brain, compare the data obtained with previous experience and evaluate the surrounding reality as real - familiar and calm, unusual and disturbing or dangerous.

With a sharp change in afferentation (intensity of excitations) on the part of any of the above analyzers, as well as inconsistency of information from various analyzers, a mismatch in the functional systems of perception of space develops and, as a result, a violation of spatial orientation. The brain assesses this situation as dangerous, and the functional systems of the brain activate control over other analyzers in order to confirm the correspondence of the surrounding reality with inadequate afferentation. In the absence of inadequate signals from the rest of the analyzers, their signals (signals from the rest of the analyzers) become dominant, since they do not contradict previous experience and therefore inadequate afferentation is not perceived as real reality.

When viewing a dynamic video sequence (film, computer game), the brain receives a powerful stream of visual information from the screen (monitor), but without receiving adequate annoying signals from other analyzers (vestibular apparatus, proprioreceptors, tactile receptors, visceral receptors, auditory analyzer) does not perceive this information as events actually occurring with a person. Peripheral receptors of various senses provide information about the parameters of the surrounding reality.

The visual analyzer perceives emitted and reflected light and is a highly differentiated source of information on spatial relative positioning and movement of objects. At In this central - focused vision differentiates objects, determines their relative position, location relative to the observer, and also tracks their relative movement and movement relative to the observer. Peripheral vision differentiates the direction and speed of movement of objects relative to the observer. The human vestibular system perceives changes in the position of the head relative to the gravitational vertical and consists of three mutually perpendicular semicircular canals on the left and right, which play the role of angular acceleration sensors, and two pairs of otolith organs, which respond to linear accelerations and head movements relative to gravitational vertical.

The vestibular system is closely related to the peripheral field of vision in the cortical representations of the central nervous system. It is essentially a complement and continuation of the peripheral vision of a person, providing a spatial orientation relative to the plane of the earth's surface. With inadequate perturbations of the vestibular system, preference (control) in determining the spatial position and movement of a person is given to peripheral vision.

The proprioreceptors of muscles, bones, joints and internal organs perceive the action of the gravitational field, inform the brain about the pressure force of the body on the support under the influence of the gravitational field of the Earth or under the influence of acceleration (when moving the body in space). Tactile skin receptors perceive the presence of contact with surrounding objects, inform the brain about the location and area of contact. Proprioreceptors and tactile receptors are closely related in cortical representations of the central nervous system and complement each other.

The auditory analyzer perceives air vibrations caused by moving objects, determines the localization and direction of movement of sounding objects, the intensity of the general sound background.

Visceral receptors perceive low-frequency vibrations and vibration, inform the brain about their intensity, and form a general undifferentiated perception of the surrounding reality. Depending on the intensity of afferentation, the brain determines the degree of danger of the surrounding space (environment). With the appearance of low-frequency oscillations in the range of 3–20 hertz, a person has an unmotivated sense of anxiety, the danger of which exacerbates the other senses.

The work of the proposed device is aimed at the formation of artificial mismatched and contradictory stimulation of all senses (analyzers - visual, vestibular, auditory, tactile, proprioceptive, visceral) to create spatial disorientation.

Thus, the objective of the invention was to use the features of the brain to control the position of a person in space to create violations of this function, with the aim of creating a realistic perception of the artificial visual-sound series.

The technical result, both for the method and for the device, is to create spatial disorientation in humans with the aim of creating a realistic perception of artificial visual sound series by using the features of the brain to control the position of a person in space.

The indicated technical result in the method of creating spatial disorientation in a person is achieved by the fact that a person artificially using visual objects and equipment stimulates all the senses that are responsible for the perception of space and form spatial assessments of reality. Moreover, the stimulation of visual and auditory analyzers is carried out synchronously and mutually coordinated with each other. Stimulation of the other senses, namely the vestibular apparatus, tactile, proprioceptive and visceral receptors, is not carried out adequately with respect to the visual and auditory analyzers, not synchronously and mismatched with respect to each other, which leads to mismatch of the cortical and subcortical functional systems of the brain, responsible for the perception of space, and, as a result, causes spatial disorientation.

In addition, a person’s position is periodically changed along with visual objects and equipment from a sitting position to a supine position at a speed of 1–2 degrees per second.

In the part of the device, the indicated technical result is achieved in that in the device for creating spatial disorientation in a person, comprising a base and a supporting structure movably mounted on the base, including a supporting element equipped with guide rollers, a supporting element made in the form of a ring mounted on guide rollers rotatably relative to the central axis of the ring, and a chair with a seat and back fixed to the ring, a visual object and equipment, according to the invention In the current year, the base is made in the form of a rectangular plate and equipped with telescopic supports vertically mounted at the corners of the plate with extendable rods. The supporting element includes a rectangular platform placed on the upper ends of the pull-out rods, and at least two racks, the lower end of each of which is rigidly fixed on the platform, and a guide roller is installed on the upper end, an electric drive mounted on the upper surface platforms, a driving roller kinematically connected with the electric drive, interacting with the ring, and a movement mechanism consisting of an elastic element, a support interacting with the surface of the base through an elastic element, transversely electric carriage mounted on a support, a longitudinal electric carriage mounted on a transverse carriage and rigidly fixed to the lower surface of the platform. The composition of the visual object includes a central monitor and at least two side monitors. The equipment includes at least two loudspeakers fixed on the ring, a low-frequency amplifier and a subwoofer located behind the back of the chair, and a source of low-frequency oscillations located under the chair seat. In this case, the device is equipped with an inflatable pneumatic footrest located on the platform, a compressor mounted on the platform and connected by an air line to the footrest, a two-axis horizon sensor mounted on the platform, and an electrically connected power supply unit, a switch and a computer. Moreover, the computer is electrically connected to a two-axis horizon sensor by an input, and an output with a switch, the outputs of which are electrically connected to electric drives of the longitudinal and transverse carriages, respectively. In addition, the elastic element of the movement mechanism can be made in the form of a spring.

It is recommended that each telescopic support be equipped with an electric drive to move the extendable rod along the vertical axis and lock in place.

It is envisaged that the power supply, switch, and computer can be installed on the base.

Brief Description of the Drawings

Figure 1 shows a device for creating spatial disorientation in humans (side view).

Figure 2 shows a device for creating spatial disorientation in a person in dynamics (side view and rear).

Fig. 3 shows a change in a person’s position together with visual objects and equipment from a sitting position to a lying position when using the method.

The best embodiment of the invention

The proposed method for creating spatial disorientation in humans is as follows. Using visual objects and equipment, a person is artificially stimulated by all the senses responsible for the perception of space and forming spatial assessments of reality. Stimulation of visual and auditory analyzers is carried out synchronously and mutually coordinated with each other. Stimulation of the other sensory organs, namely the vestibular apparatus, tactile, proprioceptive and visceral receptors, is carried out inadequately with respect to the visual and auditory analyzers, and the mismatch with respect to each other is not synchronous. it leads to a mismatch of the cortical and subcortical functional systems of the brain responsible for the perception of space, and, as a result, causes spatial disorientation. Also periodically change the position of a person along with visual objects and equipment from a sitting position to a supine position at a speed of 1 to 2 degrees per second (Fig. 3).

Initially, the user forms the initial spatial assessment of reality (in the zone of subsequent events). For this, the user is placed in a chair (4) in front of the central monitor (15) in the zone of focused vision and side monitors (16) located on the sides, in the zone of peripheral vision, (Fig. 1). Around the user are placed sound sources - front on the sides and in the center, behind on the sides, bottom on the sides, behind the back a source of low-frequency sound vibrations (subwoofer) 30-3000 Hz, under the seat a source of low-frequency (3 -20 Hz) oscillations ( 19). The user's feet are placed on a pneumatic footrest (20). In this case, the platform (7) is fixed motionless relative to the base (1), there is no image on the monitors, no sound and low-frequency vibrations, the pneumatic stand is not filled with air. In this initial spatial reality, the sensory organs inform the brain that the surrounding space is familiar and calm (the organs of vision and hearing testify to this), the chair (4) in which the person sat, is stable (this testimony - organs of the vestibular apparatus), the area of support for a stable position of the body is sufficient (tactile receptors of the skin of the hands, back, buttocks, thighs, feet testify to this), a solid stable support under the feet (this is indicated by proprioreceptors of the feet), - alarming low-frequency vibrations are absent. Then the user is formed inadequate (relative to visual and auditory afferentypii) afferentations from the side of the vestibular apparatus. For this, the user turns on the source of visual-audio information and proceeds to its perception. When the dynamic visual range and sound appear on the monitors, the platform with the equipment located on it (armchair, image sources, sound, low-frequency oscillations, pneumatic stand) is moved from a stationary stable position to an unstable equilibrium position on an elastic element ( eleven). In this case, any user movements cause arbitrary swinging of the platform (7) in three-dimensional space (in three planes) with different amplitudes - from 0 to 30 degrees along the X and Y axes, and moving up and down along the Z axis from 0 to 50 mm and rotation to the left to the right from 0 to 10 degrees. As a result, the user experiences inadequate (with respect to visual and auditory afferentation) afferentions from the side of the vestibular apparatus, which do not fit into the logical picture of the spatial position of a person (based on previous experience) and are replaced in the cortical representations of the central nervous system with information coming from peripheral vision, currently receiving visual information from the side monitor screens (16).

For artificial, inadequate stimulation of skin tactile receptors, a subwoofer (18) is switched on through a low-frequency amplifier, low-frequency sound vibrations from which are mechanically transmitted through the chair structure (4) to the skin surface (in places of contact with the chair surface). In this case, the cortical representation of the central the nervous system is not able to adequately characterize the localization and contact area of the human body with the surface of the support.

For artificial, inadequate stimulation of proprioreceptors, a pneumatic footrest is filled with air (20). With inadequate afferentation from the tactile receptors, a person reflexively seeks support under his legs and increases pressure on the feet. Feet, resting on a soft pad filled with air (20), do not cause sufficient irritation to the proprioreceptors of the legs. In the absence of firm support under the feet, a person experiences the effect of “failing”. This afferentation exacerbates the spatial disorientation of the user.

For artificial stimulation of visceral receptors, a source of low-frequency vibrations is activated (19), mounted under the seat of a chair, which creates low-frequency vibrations in the range of 3–20 Hz, which are transmitted to the visceral receptors. As a result of this afferentation, the user has an unmotivated sense of anxiety, danger, which enhances spatial disorientation and exacerbates the other senses. To reduce the effect of getting used to inadequate sensory stimulations, the user’s position (along with visual objects and equipment) is periodically changed from a sitting position to a lying position at a speed of 1-2 degrees per second (Fig. 3). At the same time, the above-described stimulations are retained.

Thus, when using this method, the cortical and subcortical functional systems of the brain responsible for the perception of space and spatial assessments of reality receive a flow of conflicting information from all sensory organs and turn out to be completely disoriented. The only logical source of space perception is artificial visual and sound information.

A device for creating spatial disorientation in humans, contains a base (1) and a load-bearing structure movably mounted on the base, including a support element equipped with guide rollers (2), a bearing element made in the form of a ring (3), mounted on the guide rollers (2) with the possibility of rotation relative to the central axis of the ring (3), and a chair (4) with a seat and back mounted on the ring, a visual object and equipment. The base (1) is made in the form of a rectangular plate and equipped with telescopic supports (5) vertically mounted at the corners of the plate with extendable rods (6). The support element includes a rectangular platform (7) located at the upper ends of the extension rods (6), and at least two racks (8), the lower end of each of which is rigidly fixed to the platform. A guide roller (2) is installed on the upper end of the uprights. The support element also has an electric drive (9), which is mounted on the upper surface of the platform (7), a drive roller (10), kinematically connected with the electric drive and interacting with the ring (3), and a movement mechanism. The movement mechanism consists of an elastic element (11), a support (12) interacting with the surface of the base (1) through an elastic element (11), a transverse carriage

(13) with electric drive (27) mounted on a support, longitudinal carriage

(14) with an electric drive (26) mounted on the transverse carriage and rigidly fixed to the lower surface of the platform. The visual object includes a central monitor (15) and two side monitors (16). The equipment includes loudspeakers (17) fixed to the ring (3), a low-frequency amplifier and a subwoofer (18) located behind the back of the chair, and a source of low-frequency oscillations (19) located under the chair seat. In addition, the device is equipped with an inflatable pneumatic footrest (20) located on the platform (7), a compressor (21) with a drive mounted on the platform and connected by an air line to the footrest, and a two-axis horizon sensor mounted on the platform ( 22) to determine the position of the supporting structure in three-dimensional space, as well as electrically connected power supply unit (23), switch (24) and computer (25). It is envisaged that the power supply, switch, and computer can be installed on the basis of (1). Computer (25) is electrically connected to a biaxial horizon sensor (22) by an input and an output to a switch (24), the outputs of which are electrically connected to electric drives (26, 27) of the longitudinal and transverse carriages (14,13), respectively. The elastic element (11) of the movement mechanism can be made in the form of a spring. It is envisaged that each telescopic support (5) is equipped with an electric drive for moving the extendable rod (6) along the vertical axis and fixing it in a predetermined position.

A device for creating spatial disorientation in humans works as follows.

The device’s work is aimed at creating an artificial, mismatched and contradictory stimulation of all sensory organs (analyzers - visual, vestibular, auditory, tactile, proprioceptive, visceral) to create spatial disorientation. Starting position: the device is installed on a horizontal surface. The user sits in a chair (4). It should be noted that the X, Y, and Z axes correspond to the center of the total mass of the moving part of the structure and the operator located on it. Retractable rods (6) of telescopic supports (5) are in the upper position and motionlessly fix the platform (7). At the same time, the ring (3) holds the chair (4) in a sitting position (Figure 1), the pneumatic footrest (20) is not filled with air, the image, sound and low-frequency vibrations are absent.

The user (operator) turns on the computer and proceeds with the work.

To artificially stimulate central - focused vision, the user is located in front of the central monitor (15), and to artificially stimulate peripheral vision, side monitors are activated (16). It should be noted that all visual information from the monitor screens moves with the user on the platform (7).

In order to artificially stimulate the vestibular analyzer, the mobile part of the device, together with the user, is moved from a stable (initial) position to an unstable equilibrium position. For this, when a dynamic visual series appears on the monitors, the on-board computer (25) (according to the attached program), via the switch (24), turns on the electric drives of the telescopic supports (5) and puts the sliding rods (6) to the lower position and thereby brings the circuit board - form (7) from an immovable stable position to a position of unstable equilibrium on an elastic element (11). As a result of this, when With all the movements of the user, the supporting structure movably mounted on the base (1), including the supporting element and the supporting element made in the form of a ring (3), and a visual object and equipment fixed on the ring chair (4), goes out of equilibrium and - randomly swinging in three planes (Fig.1 and 2). The computer (25) generates the output signals coming from the biaxial horizontal sensor (22), which, through the switch (24), drive the corresponding electric drives (26.27), respectively, of the longitudinal and transverse carriages (14.13) (movement mechanism ), which move the supporting structure together with the operator (user) in three-dimensional space (in three planes) relative to the vector of the Earth's gravitational field.

When the user is shifted anterior or posterior, the center of mass (the moving part of the device plus the user) is shifted to the corresponding side along the X axis. In this case, the two-axis horizontal sensor (22) is activated and switches on the electric drive (26) via a longitudinal carriage, which moves the longitudinal carriage (14) in the opposite direction until the equilibrium of the moving part of the structure on the elastic element (11) is restored.

While the user is shifting left or right, the center of mass is shifted in the corresponding direction along the axis (Y) and the two-axis horizontal sensor (22) through the switch (24) turns on the electric drive (27) of the transverse carriage, which moves the transverse carriage (13) to opposite side until equilibrium is restored. The movement of the supporting structure along the X and Y axes initiates its movement along the vertical Z axis - up, down and rotational movements to the left, to the right. So at the same time, as a result of the user's physical activity, the system — the mobile part of the device (load-bearing structure) plus the user — leaves the state of equilibrium, while the electronic part and the device’s electric drives constantly return the system to the equilibrium position. Inadequate (inappropriate visual information) signals from the vestibular apparatus, caused by the above movements, are replaced in the cortical representations of the central nervous system by afferentation coming from peripheral vision, which is currently receiving visual information from the side monitor screens (16).

For artificial mismatched and contradictory stimulation (with respect to the vestibular analyzer) of the auditory analyzer, multichannel sound is switched on through the low-frequency amplifier. With the help of loudspeakers (17), sound signals are generated synchronized with the visual range (the soundtrack always corresponds to the events occurring in the film, video game). This afferentation does not correspond to stimuli coming from the side of the vestibular apparatus, which additionally violates the spatial orientation.

For artificial, inadequate stimulation of skin tactile receptors, a subwoofer (18) is switched on through a low-frequency amplifier, low-frequency sound vibrations from which are mechanically transmitted through the chair structure (4) to the skin surface (in places of contact with the chair surface).

For artificial, inadequate stimulation of proprioreceptors, the compressor (21) fills the air with a pneumatic stand for feet (20). In the absence of firm support under the feet, a person experiences the effect of “failing”. This afferentation exacerbates the spatial disorientation of the user.

For artificial stimulation of visceral receptors, the source of low-frequency vibrations (19), mounted under the seat of a chair (4), creates low-frequency vibrations in the range of 3–20 Hz, which are transmitted to visceral receptors. As a result of this afferentation, the user has an unmotivated sense of anxiety and danger, which enhances spatial disorientation and exacerbates the rest of the senses.

Thus, when using this device, the cortical and subcortical functional systems of the brain, which are responsible for the perception of space and spatial assessments of reality, receive a stream of conflicting information from all the senses and are completely disoriented. The only logical source of space perception is artificial visual and sound information.

Industrial applicability

The present invention can be applied to create real feelings by users of a home computer when used in games, in game modules and flight simulators, as well as in medicine for conducting psychophysiological studies.

Claims

CLAIM

1. A method of creating spatial disorientation in humans, characterized in that a person is artificially stimulated by visual objects and equipment with all the senses responsible for the perception of space and forming spatial assessments of reality, moreover, the stimulation of visual and auditory analyzers carry out synchronously and mutually associated with each other, stimulate the rest of the senses, namely the vestibular apparatus, tactile, proprioceptive and visceral receptors, they are not adequate with respect to visual and auditory analyzers, not synchronously and mismatched with respect to each other, which leads to a mismatch of the cortical and subcortical functional systems of the brain responsible for the perception of space, and, as a result, causes spatial disorientation.

2. The method according to claim 1, characterized in that the person’s position is periodically changed along with visual objects and equipment from a sitting position to a lying position at a speed of 1 to 2 degrees per second.

3. A device for creating spatial disorientation in a person, comprising a base and a supporting structure movably mounted on the base, including a support element equipped with guide rollers, a bearing element made in the form of a ring mounted on the guide rollers with the possibility of rotation relative to the central axis of the ring, and a chair with a seat and back fixed to the ring, a visual object and equipment, characterized in that the base is made in the form of a rectangular plate and equipped with telescopic supports with extendable rods vertically mounted at the corners of the slab, the support element includes a rectangular platform placed at the upper ends of the extendable rods, and at least two racks, the lower end of each of which is rigidly fixed on the platform, and on the upper at the end there is a guide roller, an electric drive mounted on the upper surface of the platform, a driving roller interacting with the ring kinematically connected with the electric drive, and a movement mechanism consisting of an elastic electric of a support, interacting with the base surface through an elastic element, a transverse electric carriage mounted on a support, a longitudinal electric carriage mounted on a transverse carriage and rigidly fixed to the lower surface of the platform, the central monitor is included in the visual object and at least two side monitors, and the equipment includes at least two loudspeakers mounted on a ring, a low-frequency amplifier and a subwoofer located behind the back of the chair, and sources low-frequency vibrations located under the seat of the chair, the device is equipped with an inflatable pneumatic footrest located on the platform, a compressor mounted on the platform and connected by an air line to the footrest, a two-axis horizon sensor mounted on the platform, and electrically connected unit power supply, a switch and a computer, the computer being connected electrically to a biaxial horizon sensor, and an output to a switch whose outputs are electrically connected to an electric poles, respectively, of the longitudinal and transverse carriage.

4. The device according to claim 3, characterized in that the elastic element of the movement mechanism is made in the form of a spring.

5. The device according to claim 3, characterized in that each telescopic support is equipped with an electric drive for moving the sliding rod along the vertical axis and fixing in a predetermined position.

6. The device according to claims 3 or 4, or 5, characterized in that the power supply unit, switch and computer are installed on the base.