RO127615B1 - Electronic equipment and method for quickly determining a psychological profile - Google Patents

Abstract

The invention relates to an electronic equipment and to a method for a rapid determination of psychological profile, meant to be used in psychological testing laboratories. According to the invention, the electronic equipment consists of a frequency divider (1), a signal generator (2) with eight stage inputs, two distribution blocks (3 and 3'), two signal access blocks (4 and 4'), two silver sensor grids (5 and 5'), a four-channel logger (6) and a computer (7). The method claimed by the invention is based on the projective testing of cerebral functions with a view to establishing a set of variables which, upon correlative interpretation, provide an objective psychological profile of the person to be assessed, said profile arising from an assembly of voltage levels determined through the use of the described electronic equipment, based on which, by applying on the skin of the palms a stage voltage signal, a set of response signals will be measured and converted first, by means of a specialized software, into parameters describing the functionality of seven energy centres, and then, by successively processing and correlating them to a scale and a data base allotting them an identity, will be used in computing the set of indicators of psychological significance required for establishing the activity levels projectively associated to emotional and mental intelligence, the behaviour style, the vocation and temperamental proportion, the abilities, aptitudes and motivations, hence the professional compatibility and compatible activity profile, the final results of said operations being presented in a quality report of the psychological profile.

Description

The invention relates to an electronic equipment and a method for the rapid determination of the psychological profile, which can be used in psychological testing laboratories, for the evaluation of students and students, in the recruitment companies, for identifying professional compatibilities, in the framework of security and protection companies, for the initial and periodic evaluation of the parameters and performance indicators of the employed personnel, within the sports clubs for the daily monitoring of the sports performance indicators, etc.

To identify the psychological profile, classical methods of investigation or methods and direct measurement equipment are used. The classical methods use questionnaire tests, written or interactive, self-assessment tests on the computer.

These methods have the disadvantage of the long participation of the person tested in the evaluation process, the installation of fatigue in time, the reserve of subjectivity that routine can induce, through the possibility of preparing the solutions, the inability that can not qualify with certainty that a person has a certain type of psychological profile, but also the relationship with the author of the evaluation test, which limits the scale of his intelligence coefficient to the extent to which the applied test can reveal the intelligence of the investigated person.

A number of methods and equipment by direct measurement highlight certain psycho-physiological parameters, which can be interpreted to establish a psychological profile, they function on the principle of determining the levels of conductivity of the epidermis of type SCL - basal conductance and SCR - conductance. response, by using two electrodes subjected to a very small electric potential difference, between which a measurable electric current is established. According to Edelberg's exocrine model, one of the most accepted models of skin conductance, phasic changes in skin conductance occur when the skin glands fill, and the skin conductance returns to basal values when this moisture is reabsorbed by the glands. In this model, in fact, exocrine glands are resistance. The conductance increases (resistance decreases) when these glands are filled. The amplitude of the conductance change derives from the amount of solution contained in the glands, as well as the number of exocrine glands activated by simutan. Activation of the exocrine glands is neurally regulated, being controlled by the brainstem. This is part of the phenomenology of exodermal manifestations of the brain, the electrodermal activity being a projection of the action of the reticular formation of the brainstem, hypothalamus, limbic system and motor cortex ("LAROIISSE The Big dictionary of psychology", Trei Publishing House, Bucharest, 2006, 407). It is also known that the electrical activity of the skin is correlated with the blood flow in the peripheral areas, depending directly on the heartbeat.

There are known various devices and devices associated with methods that, based on the electrodermal activity and the correspondence between the measurement points, located on the areas of the palm extremities and the psycho-physiological variables:

- it measures the psychogalvanic reflex - US patent 3841316;

- monitors the psycho-physiological state of a person - US patent 6067468;

- Measures the aura of the human body and its system - US Patent 6746397;

- visualize the energy centers and the aura of the human body, using a multimedia system with bioreaction, interactive assisted by computer - US patent 5720619.

The disadvantages of these devices, devices and associated methods consist either in the complexity and size of the device or devices, or in the limited destination of the method or use of the devices, providing insufficient data for the outline of a psychological profile.

RO 127615 Β1

There is also known an alternative therapy method, in which an important weight 1 during the stages is the determination, respectively the establishment of psycho-physiological aspects of the person - the patent application US 20040059184. This method 3 reveals the descriptive diagram of the centers energetics that govern both physiological and psychological aspects - identified and used in the practice of traditional physicians (patent application 5 US 20040059184 A1, published March 25, 2004, pp. 6-16, fig. 3), as well as the correspondence diagram between the areas located on the palms and the organs and psycho-physiological functions 7 (US patent application 20040059184 A1, published on March 25, 2004, pp. 6 -16, fig. 9B), diagram correlated with the map of the reflexogenic points of the palm, corresponding to the system 9 human psycho-physiological (Map B, page 44 of “Reflexolpgie palmară”, authors Mildred Carter and Tammy Weber, Polirom Publishing House, Bucharest, 2007). In agreement with this method, the empirical determinations 11 from the practice of traditional medicine reveal the functional correspondence between the energy centers and seven distinct areas, located at the palm level, as follows: first center 13 - palm base; second center - thumb; third center - middle finger; fourth center - little finger; fifth center - index finger; the sixth center - the ring finger; 15th center - palm center (http://www.adishakti.org/ subtle_system / mooladhara_chakra.htm). 17

The disadvantage of this method is the cumbersome data collection procedure, which involves an a priori preparation of both the specialist and the person tested, 19 drawing up records of the psycho-physiological state of the patient and their relationship with specialized documentation. 21

The technical problem consists in the development of an electronic equipment and a method that allows the rapid establishment of the psychological profile, consisting of indicators of mental intelligence 23, emotional intelligence, vocation, temperament and behavioral style, motivations, abilities, aptitudes, professional and profile compatibilities. of activity. 25

The electronic equipment for the rapid determination of the psychological profile, according to the invention, solves the technical problem by being composed of a cascade frequency divider 27, which, starting from a base frequency of a quartz-controlled oscillator, provides a signal with a tactile frequency of an eight-step signal generator, 29 made in the configuration of a digital-analog converter, which, after completing a step-by-step signal formatting sequence, transmits a switching impulse, necessary for a block 31, distributed on the structure of a displacement register capable of opening, within a signal access block, eight paths, one of which a separation, through which the 33 voltage signals formed in the signal generator are directed to the palm areas at the level of some silver sensor grids, mounted in an arrangement according to the anatomical shape of the 35 palms on the top of the box they to the electronic assembly, being transmitted at the same time to a four-channel logger, able to record the variations of conductance as variations 37 voltage level correspondents, during a number of measurement cycles, with a specialized program for data acquisition, installed on a PC that can view the form of an excitation signal 39, but also the response signal form, while also reading and storing the voltage values of these signals in a data file on the computer, prepared 41 in a special format for it could be used by another dedicated program, which identifies the psychological profile of the measured person. 43

The method for the rapid determination of the psychological profile, according to the invention, solves the technical problem by relying on the projective probing of brain functions, in order to establish a set of variables that, interpreted correlatively, provide an objective psychological profile of the evaluated person, which profile derives from a set of 47 voltage levels, determined by using the specialized electronic equipment described above, with

EN 127615 Β1 which is applied to the palms, at the level of the epidermis, a voltage signal in the step and a set of response signals is measured, which will be converted with a computer program into parameters that describe the functionality of seven energy centers, then , by successive processing and relating to a scale and to a database that attributes their identity, they serve to calculate the set of indicators with psychological significance, necessary to identify the activity levels associated projectively with emotional and cognitive intelligence, behavioral style, vocation and temperament ratio, skills, aptitudes and motivations, respectively professional compatibility and compatible activity profile, operations whose final results are presented in a qualitative report of the psychological profile.

The advantages of using the invention are the following:

- the electronic equipment can quickly measure the electrodermal parameters, due to the very short scanning time, the simplicity of the data acquisition software used and the very suggestive distribution of the sensors on the top of the scanning unit housing, without requiring specialized training for handling saddle;

- the scanning unit is made in a peripheral equipment configuration for the PC computers and communicates with them on the USB2 interface, which no longer requires its own power supply, being extremely reliable and offering the possibility of long use;

- the electronic equipment takes the electrodermal information with a very low working frequency, which eliminates the possibility of interference with any source close to the radioelectric signal;

- the method is fast and autonomous, it allows to establish the psychological profile in a very short time, on a flexible and simple to use software, implemented with great ease with the help of the Office tools of any PC computer, being able to reproduce quickly and to generate anytime from its database explicit, intelligible and formative reports of the persons whose biodata were processed, providing complex information with important role in the individual development;

- the method is precise, because with the help of the electronic equipment and the related program objective data are taken and the intervention of the human factor cannot alter the results of the evaluation;

- the electronic equipment and the related method constitute an open, flexible and effective system, programmable for a large number of professions and activity profiles, a special feature that makes any field of activity can be characterized and investigated with great efficiency.

The following is an example of embodiment of the invention, in connection with FIG. 1 ... 3, which represents:

FIG. 1, the block diagram of the electronic equipment for the rapid determination of the psychological profile, according to the invention;

FIG. 2, the diagram of the excitation and response signals;

FIG. 3, the flow chart of the method for the rapid determination of the psychological profile, according to the invention.

The electronic equipment for the rapid determination of the psychological profile, presented in the block diagram of fig. 1 is made up of a frequency divider 1, a signal generator 2 with eight states, two distribution blocks 3 and 3 ', two access blocks sign 4 and 4', two sensor grids 5 and 5 'of silver, a four-channel logger 6 and a computer 7 that provides USE52 port and power supply for the entire assembly.

In order to determine the working frequencies, it was taken into account that the heart beats at a rate normally between 70 and 100 beats per minute, meaning an average number

RO 127615 Β1

Nmb = 85 beats per minute, the duration of a cardiac pulse being, on average, Tpc = 0.7 s. In order to have at least one pulse of the signal sent to the measurement area, at least one heartbeat can be intercepted, the pulse duration, Ti, must be greater than or equal to at least 3 the duration of the heart rate. The excessive increase of the duration of the impulse can lead, however, to the decrease of the number of readings, respectively to the decrease of the resolution of the measurement, being conditioned 5 by the time base of the logger with which the recording is made, reason for which, according to the invention, the condition was adopted: Ti = Tpc, respectively Ti = 0.7 s, a condition that required the use of 7 a frequency of switching the access paths to the measurement areas through the distribution blocks 3 and 3 ', with a value deduced by the formula Fi = 1 / Ti, resulting Fi = 1.43 Hz, 9 frequency provided by the eight pulse loaded in signal generator 2. From Fi is deduced the tact frequency for the eight-step signal generator, Fo, according to the formula Fo 11 = 8 Fi, resulting Fo = 11,44Hz.

Considering that the total reading time allocated by the logger used is Ttc = 85 s, 13 and seven read-only pulse pulses corresponding to the seven measurement zones are required for the reading cycle, as well as a separation pulse. , so a total of 15 pulses / cycle, the reading duration of a cycle is calculated according to the formula: Tc = 8xTi, resulting in Tc = 5.6 s and the number of reading cycles, Nc = Ttc / Tc, resulting in Nc = 15, 2 cycles at a complete reading 17, a number large enough for the duration of the signal pulse in the step to be the same size as that of the pulse wave. 19

The frequency divider 1 is made using two 14-bit asynchronous binary counters with oscillator, placed in cascade. The oscillator of the first counter is piloted with a 21 quartz whose oscillation frequency is 3MHz. The tactical frequency Fo = 11.44 Hz is obtained by a division of the order 18, respectively 218 = 262.144 times from the 23 base frequency of the oscillator.

The signal generator in step 2 is designed on the structure of an analog-to-digital converter 25 and consists of two four-state displacement registers, with serial input and parallel output, four integrated areas with eight Darlington transistors with 27 common emitters and four voltage divider networks, corresponding to each area of ports, made with low power resistors. The shift registers are loaded one by one, serially, 29 with pulses starting from the frequency Fo = 11.44 Hz, so that, after charging the pulse eight, it resets the cascade of registers, preparing it for a new load, 31 being constituted. at the same time as a control pulse for the 3 and 3 'distribution blocks, with a frequency Fi = 1.43 Hz. The parallel outputs of the registers send the pulse sequence through the 33 two areas integrated with Darlington transistor ports to the voltage divider network of each area, each signal traveling through a resistor to a common point, separated by 35 masses with another resistor, where the currents charged by the Darlington ports are summed, a signal consisting of step voltage levels being realized, 37 of which measured values are presented in table 1. Two of the voltage level signals thus obtained are transmitted to the blocks. signal access 4 and 4 'and to the inputs of 39 channels CH1 and CH4 of the logger, where the response signals will be recorded as a result of the opening of the measurement paths and the establishment of the useful signal. The other two signals are 41 transmitted to the inputs of the other channels CH2 and CH3 of the logger and will be recorded as excitation control signals. 43

Table 1

Signal step 1 2 3 4 5 6 7 8 Excitation voltage level (V) 0 0.188 0.282 .341 0.376 0.4 0.424 0.435

RO 127615 Β1

The 3 and 3 'partition blocks contain a four-bit asynchronous counter.

The frequency pulse Fi = 1.43 Hz, provided by the signal generator, controls the binary counter on the tact input of the eight-sequence splitting sequence, to produce eight binary control sequences for the 4 and 4 'signal access blocks. .

The signal access blocks 4 and 4 'are made on the structure of two multiplexers with eight channels, ordered simultaneously in three bits using the binary sequences, provided by the distribution blocks 3 and 3'. The first seven binary sequences will simultaneously open four groups of seven paths, selectable with the frequency pulse Fi = 1.43 Hz provided by the signal generator 2, corresponding to the four multiplexers placed in the pair, in a signal access block to the signal areas. measure constituted by the 5 and 5 'sensor grids. The eighth sequence (1, 1,1) will simultaneously activate the eighth channel, through which the common input of a multiplexer, respectively the inputs CH1, CH4 and CH2, CH3 of the logger are set to "1 logic" by a resistance connected to the supply voltage + Vcc, state that will be recorded as a separating impulse for the set of seven useful signals, intercepted by the two groups of measurement paths, corresponding to CH1 and CH4, respectively by the two groups of excitation signal, corresponding to CH2 and CH3.

The sensor grids 5 and 5 'contain a number of 19 silver sensors, grouped into seven lines of measure, arranged according to the anatomical shape of the palms on the upper part of the electronic mounting box, according to the invention, according to the correspondence rule between centers and areas. of measurement, as follows: the first center towards the base of the palm, the second center towards the thumb, the third center towards the middle finger, the fourth center towards the little finger, the fifth center towards the index finger, the sixth center towards the ring finger, and the seventh center towards the center of the palm.

Logger 6 is a universal data acquisition tool for low frequency signals, communicating with the computer 7 through a USB2 port, which also receives the supply voltage + Vcc = 5V for the entire installation. It contains four measurement inputs CH1, CH2, CH3 and CH4 with amplification and a microcontroller controlled by a program capable of recording and storing the measured values in a data file, on the computer.

After the scanning cycle is started, four identical signals will be generated at generator 2, which will be sent to the four logger inputs. Of these, the signals from the CH1 and GH4 inputs will also be directed to the common inputs of the 4 and 4 'signal access blocks. The distribution blocks 3 and 3 'receive the tactile impulse from the generator 2 and will command the signal access blocks 4 and 4', which simultaneously open the selectable measurement paths with the frequency pulse Fi = 1.43Hz, to the sensor grids, from where variations in the conductance of the epidermis at the level of the palms, intercepted on the silver sensors, are intercepted. The conductance variations are viewed and recorded as corresponding voltage variations, according to the following relation: conductance G = 1 / R; epidermal resistance R = U / l, where U is the applied voltage, respectively G - l / U. Thus, the small measured voltage values reveal a high conductance of the epidermis, and the high voltage values reveal a reduced conductance of the epidermis, as long as the current remains constant throughout the measuring chain. The shape of the excitation and response signals at the level of the two inputs are shown in fig. 2.

The method for rapidly determining the psychological profile, according to the invention, has the following characteristics:

- provides a projective probing of brain functions, in order to identify a set of variables that, interpreted correlatively, provide an objective psychological profile of the person

RO 127615 Β1 evaluated, carrying out a number of queries of the measurement areas, by applying at the epidermis level 1 a step excitation signal, simultaneously recording and storing the response signals as variations of the epidermal conductance, expressed in corresponding variations. of voltage, on each query cycle, together with the excitation signal, in an input data report file; 5

- establishes a number of parameters regarding the activity of the energy centers, manifested in information of opening of the centers and of their coherence (efficiency), 7

- formatting a set of scale parameters, corresponding to the activity levels of the energy centers, in order to identify a set of intermediate parameters;

- determines a passive potential and a set of active potentials of the coherence levels, in order to establish a yield for each of the seven energy centers; 11

- identifies a set of useful parameters, respectively a set of indicators with psychological significance; 13

- determines the activity levels projectively associated with PE-IQ cognitive intelligence and PE-EQ emotional intelligence, according to the invention, indicating the level of operation of the cognitive and emotional areas, information relevant to the intelligence aspects;

- identifies a compatible vocation, two behavioral styles corresponding to that vocation, a temperamental proportion, the abilities, aptitudes and motivations of the person 19 evaluated;

- identifies a compatible activity profile of the evaluated person and a compatible profession 21, by accurately establishing the psychological aspects that differentiate the people; 2. 3

- generates a qualitative report of the psychological profile in a very short time, very precise, autonomous, explicit, intelligible and formative, easy to secure and accessible with the help of 25 Office tools of any PC computer.

Fig. 3 presents the organizational chart of the method of rapidly determining the psychological profile. 27 The evaluation is initiated, after placing the person's palms on the sensor grids of the electronic equipment and after triggering the scan sequence, a number of 29 interrogations of the measurement areas are performed, by applying at the epidermis an excitation signal in the form of a voltage signal in step, recording and storing the response signals 31 of the variation of the epidermal conductance, as corresponding variations of voltage level on each query cycle and for each channel separately, together with the excitation signal 33, in a file of input data report, with the possibility of visualizing them on the computer, using data acquisition software. After performing the 35 scan sequence, the input data report is subjected to a comparison process, which validates the format of the acquired data. If the format is incorrect, the sequence of 37 scans will be repeated, and if the format is correct, the data will be filtered, in order to determine the signals with maximum voltage level, corresponding to the minimum conductance levels 39 of SCR type, respectively SCL, taken at the end. interrogation of the measurement zones, according to the relation U = l / G, where U is the applied voltage, G = 1 / R is the conductance of the epidermis, the resistance 41 of the epidermis is deduced from Ohm's law, R = U / l, and I is the considered electrical current constant in the chain of measurement. 43

After filtering, from the preliminary data results, according to the invention, the openings of the energy centers C _{x are determined} , by identifying the maximum voltage level, 45 corresponding to the minimum conductivity level of the SCR response signal between all the query cycles, for each center, establishing , according to the invention, that a high voltage level of 47, corresponding to a low level of conductance of the SCR response signal

RO 127615 Β1 reflects a large opening of center C, and a small level reflects a small opening. According to the invention, the variation of the opening of the energy center C is set between 0 and 100 units. Also, from the preliminary data, we identify the F _y coherences of the energy centers, associated with the difference between the supply voltage level + Vcc and the maximum voltage level, corresponding to the minimum conductivity level of the SOL type signal, measured at the end of the query of the correspondence zones, establishing, also according to the invention, that a small value of this difference reveals a high coherence of that center, whereas a high value represents its poor coherence. Also, the variation of the coherence level F is established between 1 and 150 units And, depending on the measurement channel and their grouping on four levels, it means the coherence of the level y = F, F _P for the first and second centers; coherence of the bearing y = E, F _e for the third and fourth centers; consistency of bearing y = M, F _M for fifth and sixth centers and coherence of bearing y = I, F, for center of seventh.

The information regarding the coherence of the centers will be used to identify a scale parameter l _sx , using a scale factor F _s and the width of a range L _ix for each parameter C _x of the opening of the energy centers. The width of the interval L _ix is calculated by the relation:

L. = 150-F _x , where 150 represents the upper end of the coherence scale, and F _x is the scale value corresponding to the coherence level of the center represented by parameter C _x for which the scale parameter is identified. The scale factor F _s , according to the invention, is calculated in relation to a scale of S = 190 units, in which the useful parameters from which the final psychological profile indicators are composed are identified. It is given by the formula F _s = S / âF, where âF = 149, resulting from the difference between the scales of the coherence values, resulting in F _s = 1,275. The final shape of the scale parameter, according to the invention, will be l _sx = 1.275 (150 -F _x )

The scale parameter l _sx and parameter C _x will be used to determine the values of the intermediate parameters according to the formula:

I = c I ¹ ix ^w x'sx where _ix becomes the intermediate parameter corresponding to the parameter C _x . Also, the parameter C _x is used for the evaluation of the yield p. For the yield, the passive potential P _p of the energy potentials assembly is calculated, according to the relation:

»Η, = ι which represents the arithmetic mean of the value of all the openings of the energy centers, as well as the active potential P _a , also evaluated according to the invention as follows: for the first and second centers, P _aF = (C-! + C ₂ ) / 2; for the third and fourth centers, P _3E = (C ₃ + C ₄ ) / 2; for the fifth and sixth centers, P _aM = (C _s + C ₆ ) / 2; for the seventh center, P _al = C ₇ . The yield is evaluated for each level y based on the relationship:

Py = Pay> PP

RO 127615 Β1

Using the intermediate parameters _ix and the yield p _y determine the useful parameters 1 after the relation: l _bxy = p _xy l _1x .

After establishing the useful parameters, they are reported to a database containing all 3 possible identities of them, with which, according to the function of the parameters C _x and the type of bearing, they are assigned the identity. After the attribution of the identity, they acquire a psychological significance l _pxy and will be related to the lower end value of scale V, = 75, according to the formula l _pxy = V, + The value of the indicator with psychological significance thus 7 determines the openness and coherence of the energy center, from which it was identified and expresses, according to the invention, the activity level of the cognitive, affective or volitional function 9 that it represents projectively.

In order to evaluate the intelligence aspects, the ones corresponding to mental intelligence are extracted from the indicators with 11 psychological significance: general intelligence, visual-spatial intelligence, practical intelligence, verbal intelligence, mathematical intelligence, 13 intuition and clarity of reasoning, which will be distributed on a scale. with the length S = 190 units, divided into three zones, corresponding to insufficiency, efficiency and performance. The activity level 15 projectively associated with cognitive intelligence, PE-IQ, is evaluated as an arithmetic mean of the values of the distributed indicators and, according to the invention, represents the operational level 17 of the cognitive area. At the same time, from the indicators with psychological significance, the ones corresponding to the emotional intelligence are extracted: introspective emotional intelligence, 19 relational (empathic) emotional intelligence, self-image, inner comfort, integrative adaptability and stress response, which will be distributed along a scale. S = 190 units, 21 divided into three areas, corresponding to insufficiency, efficiency and performance. The activity level associated projectively with emotional intelligence, PE-EQ, is evaluated as an arithmetic mean 23 of the values of the distributed indicators and, according to the invention, represents the operational level of the emotional area, 25

Then the relation between a set of 16 vocations is established ^ ... V ^, a set of 8 behavioral styles S -, ... S ₈ and a set of 4 temperaments T ₁ , T ₂ , T ₃ , T ₄ according to the rules presented 27 in table 2, where l _a , l _b , O _a , O _b , D _a , D _b , R _a and R _b are behavioral style bipolar indicators, for which weights will be evaluated, extracting from the indicators with 29 psychological significance four sets of indicators, corresponding to the behavioral functions: understanding, organization, decision and relationship, whose psychological significance is distributed bipolar 31 by assigning a weight, so that the understanding receives as a weight for the set of psychological indicators analyzed only, one of the values l _a and _{b b} , respectively 33 or intuitive; the organization receives as a weight for the set of psychological indicators always analyzed, only one of the values O _a and Q _b , respectively cautious or spontaneous; decision 35 receives, as a weight for the set of psychological indicators always analyzed, only one of the values D _a and D _b , respectively affective or reflective; and the relation receives as a weight 37 for the set of indicators analyzed, always, only one of the values R _a and R _b , respectively reserved or open. To determine these weights, each set of indicators 39 corresponding to the behavioral functions was organized into two groups of indicators with antagonistic psychological significance. The value of a bipolar indicator is given by the arithmetic mean 41 of the values of the indicators corresponding to a group. By comparing the values of the pair of behavioral style bipolar indicators, the highest value is selected, 43 which will constitute the weight of the set of indicators corresponding to each behavioral function. 45

RO 127615 Β1

Table 2

T1 82 S6 31 33 db Rb Yes Rb a Ib Ib ob V1 32 S1 V2 S2 33 V5 S6 31 V6 S6 33 T2 32 S6 S4 S5 db Rb Yes Rb to a to ob V3 S2 S4 V4 S2 85 V7 36 34 V8 S6 85 S1 37 S8 83 a Ib R db Yes R Ib ob T3 V9 S7 AND V10 37 33 V13 38 S1 V14 S8 S3 T4 34 S7 S8 S5 to a R db Yes R to ob V11 S7 S4 V12 37 35 V15 38 34 V16 S8 35

For example, the decision receives a set of 4 indicators: fL, l ₃ and l ₄ , where D _a = (f + l ₄ ) / 2 represents the weight of affectivity, and D _b = (l ₂ + l ₃ ) / 2 represents the weight reflexivity. If the MAX function (D _a , D _b ) identifies the highest value for D _b , then the decision is reflective. If the highest value identified is D _a , then the decision is affective. Likewise, the understanding can be practical or intuitive, the organization can be cautious or spontaneous, and the relationship, reserved or open.

In order to determine the vocation, a set of 16 weightings Fv1>Pv2>> P v16> corresponding to the 16 vocations is evaluated. The evaluation of these weights is done, according to the invention, by comparing the corresponding amounts realized with the values of the behavioral style bipolar indicators, identified according to table 3. The highest weight of these amounts is given by the MAX function (P _v1 , P _v2 , ..., P _v16 ). The vocation corresponding to this value represents the basic vocation of the person evaluated.

RO 127615 Β1

Table 3

weight Behavioral style bipolar indicators ^Pv i db Rb a Ib Pv ₂ db Rb Ib ob Pv ₅ Yes Rb a Ib Pv ₆ Yes Rb Ib ob Pv ₃ db Rb to a Pv ₄ db Rb to ob Pv ₇ Yes Rb to a Pv ₈ Yes Rb to ob PVG R db ga Ib Pv ₁₀ R db Ib ob PV13 Yes R a Ib PV14 Yes R Ib ob ^Pv n R db to a PVi ₂ R db to ob PV15 Yes R to a Yes R to ob

The behavioral styles S _T ..... S ₈ are assigned to each vocation according to the correspondence presented in table 2, so that each vocation corresponds to a number of two behavioral styles 23, and each behavioral style corresponds to two bipolar indicators in the set of eight. 25

Temperatures T _1; T ₂ , T ₃ , T ₄ each group 4 vocations. The grouping mode is presented in table 2. In order to determine the temperamental proportion, the 16 27 weights P _v1 , P _v2 , ..., P _v16 corresponding to the 16 vocations are ordered. Each vocation is identified by temperamental belonging. From the analysis of the first 5 temperaments identified for the 29 first 5 vocations, it is established, according to the invention, the temperamental proportion in percentages.

For example, if T ₁ is identified 3 times and T ₃ is identified 2 times 31 in the first 5 positions, then its proportion is 60%, and the proportion of T ₃ is 40%.

In order to establish the abilities and aptitudes, a set of 7 indicators with meanings related to abilities and aptitudes are extracted from the indicators with psychological significance 33, whose values are introduced in a level discriminator. The discriminator, according to the invention, 35 sorts all the indicators whose values exceed the level established by the formula ΜI N (l _a1 , l _a2 , .....

l _a7 ) + (MAX (l _a1 , l _a2 , ... I _a7 ) -MIN (l _a1 , l _a2 , ... l _a7 )) / 2. After identifying the most important values, the information is constituted in a set of indicators of abilities and aptitudes.

In order to identify the motivations, a set of 7 indicators with meanings related to the motivations whose values, as in the previous situation, are introduced in a level discriminator are extracted from the psychological significance indicators 39. The discriminator, according to the invention, sorts all the indicators whose values exceed the level established according to the formula MIN (l _m1 , l _m2 , ... l _m7 ) + (MAX (l _m1 , l _m2 , ... I _m7 ) - MIN ( l _m1 , i _ffl2 , ... i _ffl7 )) / 2. After identifying the 43 most important values, the information is constituted in a set of motivational indicators.

In order to establish the profession compatible with the evaluated person, a set of 40 indicators is extracted from the indicators 45 with psychological significance, whose values are l _p1 , l _p2 , ... l _p40 which, according to the invention, will be arranged in a matrix scale with eight steps in which for each 47

RO 127615 Β1 location, we calculate the weight of the real value of each indicator, P _jpx . The scale has a length calculated for all indicators according to the formula L = MAX (l _p1 , l _p2 , ... l _p40 ) - MIN (l _p1 , l _p2 , ... l _p40 ), and the scale rate r _t is deduce from the formula r _t = L / 8. The weight of the real value of each indicator, P _pi ⁿ is identified by following the position of the value l _pj of the indicator on position n on the scale.

For example, if the position of the value l _pj is in the third step of the scale, n = 3, for the third location of the scale, P _pj ³ = lpi, for the fourth location, the weight is Ppj ⁴ = lpi + r _t , for the second location, the weight is P _pi ² = lpi- rt, for the first location, the weight is Ppi ¹ = lpi- 2r _t , respectively for the eighth location, the weight is P _pi ⁸ = l _pi + 5r _t .

A professional theme trainer is then used, so as to contain 24 professional themes out of a maximum of 40 ⁸ possible ones. The profession theme is formatted, according to the invention, on the structure of an identical matrix, as the number of lines and columns, with the matrix identifying the position weight on a scale, described above. Thus, each indicator with psychological significance receives a reference theme for its value. The reference theme is established by entering the number 1 in the corresponding location in the theme matrix, meaning, for the value of the indicator, a minimum or maximum mark. By comparing the theme matrix with the weight identification matrix, according to the invention, all the locations in which the maximum or minimum reference subjects were registered will be identified and the real values of the weights of those locations will be reproduced in the position weighting matrix on scale.

For example, if the position of the value l _pi is in the third step of the scale, and the reference in the reference topic is one of maximum, then the actual value of the weight corresponding to the value indicator l _pi is the one marked on the maximum, that is the weight from the eighth location of the scale, respectively P _p ⁸ = l _pi + 5r _t . The arithmetic mean of all the weights thus identified by the matrix comparator represents for each reference topic, the real way of mirroring the indicators with psychological significance in the profession topic. The hierarchy of the 24 artistic environments (Μ _υ M ₂ , ..., M ₂₄ ), corresponding to the programmed themes, gives for the maximum value, compatibility with the profession. Thus, the MAX function (M ₄ , M ₂ , ..., M ₂₄ ) indicates the profession most suited to the person evaluated.

Similarly, in order to establish the activity profile compatible with the evaluated person, a set of 7 indicators with psychological significance is extracted from the indicators with psychological significance, whose values are l _p1 , l _p2 , ... I _p7 , which according to the invention , will be arranged matrix in an eight-step scale in which, for each location, the weight of the real value of each indicator P _ipx is calculated. The scale has a length calculated for all indicators, according to the formula L = MAX (l _p1 , l _p2 , ... 1 ₇ ) - MIN (l _p1 , l _p2 , ... I _p7 ), and the scale rate r _t is deduced from the formula r _t = L / 8. As in the previous case, the weight of the real value of each indicator, P _pj ⁿ is identified by following the position of the value l _pi of the indicator at position n on the scale.

Similar to the previous step, an activity profile theme trainer is used, so that it contains a number of 12 activity profile themes out of the maximum 7 ⁸ possible. The theme of the activity profile is formatted, according to the invention, on the structure of an identical matrix as the number of lines and columns, with the matrix identifying the scale position weight, described above. Thus, each indicator with psychological significance receives a reference theme for its value. The reference theme is established by entering the number 1 in the corresponding location in the theme matrix, meaning, for the value of the indicator, a landmark on any of the steps of the scale.

By comparing the theme matrix with the weight identification matrix, according to the invention, all the locations in which the maximum or minimum type reference subjects have been registered will be identified and the real values of the weights of those locations will be reproduced in the position weighting matrix on scale.

RO 127615 Β1

For example, if the position of the value l _pi is in the third step of the scale, and the reference in the reference theme is one located on the fourth step, then the real value of the weight corresponding to the value indicator l _pj is given by the weight of the location on step four, respectively P _pi ⁴ = l _pi + r _t . the arithmetic mean of all the weights thus identified by the matrix comparator represents, for each reference topic, the real way of mirroring the indicators with psychological significance, in the activity profile theme. The hierarchy of the 12 arithmetic environments (Μ _υ M ₂ , ..., M ₁₂ ), corresponding to the programmed themes, gives for the maximum value, the compatibility with the activity profile. Thus, the MAX function (M _r , M ₂ ....... M _i2 ) indicates the profile most suited to the person evaluated. An example of a calculation is shown in Table 4.

Table 4

Table 5 presents the values evaluated for a number of 12 persons, for which the aspects of the real profession were also exposed.

Table 5

Nr. REAL PROFESSIONAL ASPECTS COMPATIBILITY DETERMINATIONS PROFESSION REAL THE REAL PROFILE OF ACTIVITY VOCATION ASSESSED COMPATIBILITY THE PROFESSIONAL COMPATIBLE ACTIVITY PROFILE 1 PROFESSOR UNIV. PSYCHOLOGIST EDUCATION UNIV. PROMOTER EXPERTISE EDUCATION ADMINISTRATIVE PROFILE ACT PROFILE. OFFICE 2 NOTARY PUBLIC LEGAL INSPECTOR ATTORNEY FREELANCER ACT PROFILE. OFFICE PROFILE COMMUNICATION 3 MANAGER, ELECTRONIC ENGINEER ST BUSINESS, RESEARCH MANAGER FREELANCER RESEARCH PROFILE craftsman PROFILE TECHNOLOGICAL 4 PRIEST RELIGION MANAGER RELIGION CHARITY ACADEMIC PROFILE SCIENTIFIC PROFILE

RO 127615 Β1

Table 5 (continued)

Nr. REAL PROFESSIONAL ASPECTS COMPATIBILITY DETERMINATIONS 5 ENGINEER PHYSICIST RESEARCH ANALYST INDUSTRY RESEARCH PROFILE craftsman PROFILE TECHNOLOGICAL 6 PROFESSOR UNIV: ECONOMIST finance VISIONARY RESEARCH PUBLIC FINANCES, BANKS SOCIAL PROFILE ACADEMIC PROFILE 7 PROFESSOR gymnasium SPORTS EXECUTOR SPORTS FREELANCER PROFILE craftsman PROFILE TECHNOLOGICAL 8 SURGEON HEALTH EXPERT HEALTH, PUBLIC SERVICES PROFILE TECHNOLOGICAL PROFILE craftsman 9 BANK DIRECTOR, ECONOMIST FINANCE VISIONARY PUBLIC FINANCE, BANKING, JUSTICE SOCIAL PROFILE ACADEMIC PROFILE 10: DOCTOR PEDIATRICIAN RESEARCH, HEALTH EXPLORER HEALTH RESEARCH PROFILE. craftsman PROFILE TECHNOLOGICAL 11 DIRECTOR TRUST MEDIA MEDIA PROFESSOR POLITICAL ANALYSIS MEDIA CRAFTSMAN PROFILE PROFILE TECHNOLOGICAL 12 ACADEMICIAN RESEARCH EXPLORER RESEARCH POLITICAL ANALYSIS PROFILE craftsman PROFILE TECHNOLOGICAL

In order to elaborate the qualitative report of the psychological profile, a descriptive register of the psychological profile elements is used, according to the invention, which contains all the meanings of form and background for each psychological profile element. The substantive meanings are expressed by a general description of the psychological indicator. This description can be found on the left side of the table in the final psychological report. Form meanings are described as attributes corresponding to the value determined by the evaluation method. The description accompanies the indicator evaluated in the structure of the presentation table in the final psychological report.

In order to format the report sequence, the information from the descriptive register of the psychological profile elements is taken and placed on a formatted structure, together with the scale areas, appropriately assigning the background and form significance, to the values determined for the evaluated indicators. The report sequence will thus contain a calibrated scale, divided into three areas: insufficiency, efficiency and performance and the evaluated indicator, placed on the scale, corresponding to its value described both as background and as form.

For example, the report on PE-IQ and PE-EQ activity levels will contain seven, respectively five report sequences, in which each intermediate indicator is described in general and particular way, in the scale sequence in which it is distributed. At the same time, the report also presents the total value of each intelligence indicator.

To assign the meanings of form and background to the vocation, behavioral style, temperaments, abilities, aptitudes, motivations, compatible profession and compatible activity profile, a correspondence register is used.

RO 127615 Β1

Both the report sequences regarding the structure of the PE-IQ and PE-EQ levels, as well as the 1 correspondence table form a qualitative report of the psychological profile, made within a Word file, which, once generated, can be archived, displayed or printed. 3 presentation in the final personality report of the activity level associated with the mental intelligence project PE-IQ is presented in table 6. 5

Table 6 7

DEVELOPMENT STAGE INSUFFICIENCY EFFICIENCY '9 PERFORMANCE Total PE-IQ IQ index value 1. General intelligence indicator value 1 general description of the indicator 1 description of indicator form 1 2. Visual-spatial intelligence general description of indicator 2 description of indicator form 2 3. Practical intelligence general description of the indicator 3 description of indicator shape 3 4. Verbal intelligence general description of the indicator 4 description of indicator shape 4 5. mathematical intelligence general description of the indicator 5 description of indicator shape 5 6. Intuition general description of the indicator 6 description of indicator shape 6 7. Clarity of reasoning general description of the indicator 7 description of indicator shape 7

RO 127615 Β1

Claims (8)

1. Electronic equipment for the rapid determination of the psychological profile, characterized in that it consists of a frequency divider (1), made with the help of two 14-bit asynchronous binary counters with oscillator, placed in cascade, the oscillator of the first counter is piloted with a quartz whose oscillation frequency is 3 MHz, from which a tactile frequency F _o = 11.44 Hz is obtained, taking into account that the duration of a heartbeat is on average T _pc = 0.7 s and that this duration must be equal to the duration of a signal pulse Ti = 8 / Fo, formed in a step signal generator (2) designed on the structure of a digital-analog converter which consists of two four-state displacement registers , with serial input and parallel output and using the tact frequency, generates the step signal and also provides control pulse with a frequency Fi = 1.43 Hz for two blocks dividers (3 and 3 '), each containing a binary asynchronous counter, by means of which a number of eight three-bit binary control sequences are realized for some signal access blocks (4 and 4'), each made up of the two eight-channel multiplexers, capable of simultaneously opening one signal separation pot to a voltage supply resistance (+ Vcc) and a seven-way group, selectable with the frequency pulse Fi - 1.43 Hz provided by the signal generator (2) to some measuring areas arranged on two sensor grids (5 and 5 '), to which an excitation voltage level signal is obtained, obtained from one of the first two outputs from the level of the first two of the four integrated areas of the signal generator (2), constituted, after the opening of the measurement paths, in response signal, which, together with an excitation control signal, produced on the other there are two outputs from the other two of the four integrated areas of the signal generator, will be recorded through the inputs (CH1, CH4, respectively, CH2, CH3) of a universal acquisition instrument given for low frequency signals, also called logger ( 6), which communicates with a personal computer (7) through a USB2 port and is capable of recording and storing in a file the values of the conductance variations of the epidermis in the palms of an evaluated person, expressed in corresponding voltage values, after the relation U = l / G, given that the current remains constant throughout the entire measurement chain. 2. Electronic equipment, according to claim 1, characterized in that the grid sensors (5 and 5 ') are grouped into seven measuring lines, arranged according to the anatomical shape of the palms on the upper part of the electronic mounting box, according to the following correspondence rule between centers. and the measuring areas: the first center towards the palm, the second center to the thumb, the third center to the middle finger, the fourth center to the small finger, the fifth center to the index finger, the sixth center to the ring finger, and the seventh center to the center of the palm 3. Method for the rapid determination of the psychological profile, characterized in that it provides a projective probing of the brain functions by identifying a set of variables capable of providing an objective psychological profile of the evaluated person, performing a number of queries of measurement areas with the help of the electronic equipment described in claim 1, by applying, at the level of the epidermis, an excitation signal in the form of a voltage level in the step and simultaneous recording of the response signals on each query cycle, for each channel, together with the signal of excitation, in an input data report file, data which are then filtered to extract the signals with maximum voltage level, corresponding to minimum levels of response conductance (BCR type), respectively basal (SCL type) , taken at the end of the zone query RO 127615 Β1, for determining the opening of energy centers (CJ and their coherences (F _y ) 1), according to the criterion that a high voltage level of the signal corresponding to the response conductance level (SCR type) reflects a large opening of the center (C), and a small level 3 reflects a small opening, respectively a small difference between the supply voltage level (+ Vcc) and the maximum voltage level corresponding to the basal conductance (SCL type), 5 measured at the end of the query of the measurement zones for each center in part, it shows a high coherence of that center, and a high value of this difference represents its weak coherence 7 and which coherences, depending on the measurement channel and their grouping on four levels, means the coherence of the bearing y = F (FJ for the first and second centers, the coherence 9 of the level y = E (F _E ) for the third and fourth centers, the coherence of the level y = M (F _M ) for the fifth and sixth centers and the coherence of the bearing y = I (F,) for the 11th center. Method according to claim 3, characterized in that 13 - a parameter of Isx scale is identified, according to the formula: l _sx = F _s (150 - FJ, where F _s = 1,275 is a scale factor, and F _x is the coherence level of the center represented by the 15 parameter C _x , then - a set of intermediate parameters l _ix , following the formula l _ix = C _x l _{ex and 17} - a yield p is evaluated, for which it is calculated - a passive potential P _p as an arithmetic mean of the values of all the openings of the 19 energy centers, and - an active potential P _a , evaluated according to the coherence level, respectively, 21 for the first and second centers, P _aF = (Ci + CJ / 2, for the third and fourth centers, P _aE = (C ₃ + CJ / 2, for the fifth and sixth centers, P _aM = (C ₅ + Cj / 2, for the 23rd center, P _a = C ₇ , resulting the evaluated yield for each energy level y after the relation: 25 o = P / P Hy ¹ ay ' ¹ p' with which and together with the intermediate parameters l _ix , 27 - some useful parameters are determined, according to the relation l _uxy = p ^, which are related to a database containing all their possible identities with which, according to the function 29 of the parameters C _x and the coherence level, they are assigned the identity by acquiring a psychological significance l _pxy and is related to the value of a lower end of scale V, = 75, 31 according to the formula l _pxy = V, + Ι _ϋχγ , the value of the indicator with psychological significance thus determined signifies the openness and coherence of the energy center from which it was identified , 33 expressing the level of activity of the cognitive, affective or volitional function that it designates. 35 5. Method according to claim 3, characterized in that, in order to evaluate the intelligence aspects, the indicators with psychological significance are extracted, the indicators 37 corresponding to the mental intelligence, respectively the indicators corresponding to the emotional intelligence, which are then distributed in an intermediate sequence of reports. from the composition 39 of a qualitative report of the psychological profile, on a scale with length S = 190 units, divided into three areas, corresponding to insufficiency, efficiency and performance, an activity level 41 associated with cognitive intelligence (PE-IQ) is evaluated as an arithmetic mean of the values of the distributed indicators and indicate the operational level of the cognitive area, and an activity level 43 associated projectively with emotional intelligence (PE-EQ) is evaluated as an arithmetic mean of the values of the distributed indicators and indicates the operational level of the emotional area. 45 RO 127615 Β1 6. Method according to claim 3, characterized in that it establishes the relationship between a set of 16 vocations, a set of 8 behavioral styles and a set of 4 temperaments, using a number of bipolar behavioral style indicators for which 16 weights are evaluated (P _v1 , P _v2 , P _v16 ), corresponding to the 16 vocations, determined by organizing a set of indicators corresponding to the behavioral functions understanding, organization, decision and relationship, in two groups of indicators with antagonistic psychological significance, having the value for a bipolar indicator. the arithmetic mean of the indicators corresponding to a group, which, by comparing the values of a pair of behavioral style bipolar indicators, lead to the selection of the largest value, which will constitute the weight of the set of indicators corresponding to each behavioral function, of which the highest weight, identified with MAX function (P _v1 , P _v2 , .. ., P _v16 ), indicates the basic vocation, respectively two corresponding behavioral styles, as well as the temperamental distribution in percent of the evaluated person, extracted from the structure of temperaments corresponding to the first 5 vocations hierarchized according to the corresponding weights, information distributed in a correspondence register, from the composition of the qualitative report of the psychological profile. 7. Method according to claim 3, characterized in that, in order to establish the abilities, aptitudes and motivations, a set of 7 indicators with meanings related to abilities, aptitudes and motivations, whose values are introduced in a discriminator, is extracted from the indicators with psychological significance. level, which sort all the indicators whose values exceed the level established by the formula MIN ^, l ₂ , ..., I ₇ ) + (ΜΑΧ (Ι _υ l ₂ , ..., I ₇ ) - MIN ^, l ₂ , ..., I ₇ )) / 2, which identifies the most important values, corresponding to the set of indicators of abilities, aptitudes and motivations of the evaluated person, information distributed in a correspondence register from the composition of the qualitative report of the psychological profile . 8. Method according to claim 3, characterized in that, in order to establish the compatible profession and the compatible activity profile of the evaluated person, a set of m indicators is extracted from the indicators with psychological significance, for the profession m = 40 indicators, and for the profile of activity m = 7 indicators, whose values (l _p1 , l _p2 , .... I _pm ) will be arranged matrix in an eight-step scale in which, for each location, the weight of the real value is calculated (P _pi ⁿ ) of each indicator, for a length of scale evaluated for all indicators according to the formula: L = MAX (lp1, | p2, ... Ipm) - MIN (lp1, lp2, ... | pm), for which a scale rate rt, according to the formula rt = L / 8, and the weight of the real value (Ppi ⁿ ) of each indicator is identified by showing the position of the value (lpi) of the indicator at position n on the scale, using a trainer of reference topics, to which they are related, according to the weightings pos ions on the scale, indicators with psychological significance, for which 24 arithmetic means (Μ _υ M ₂ , ..., M ₂₄ ) are hierarchized, to which the MAX function is applied (M., M ₂ , ..., M ₂₄ ) for establishing the compatible profession, respectively 12 arithmetic means (Μ _υ M ₂ , ..., M ₁₂ ), to which the function MAXiM ^ M ₂ , ..., M ₁₂ ) is applied to identify the activity profile best suited to the person evaluated, also recorded in a correspondence register from the composition of the qualitative report of the psychological profile.