JPS62148645A - Apparatus for processing route-organ functional information - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a meridian-organ function information processing device, and in particular to a meridian-organ function information processing device for diagnosing the functional status of the meridian-hawk machine and the balance state of the autonomic nervous system in a living body. It relates to an information processing device.

[Prior art and its problems] In Oriental medicine, especially in acupuncture and moxibustion, the existence of a system called "meridians" (which can be perceived as a stimulus-sensing system or a reaction system) throughout the body has been known through clinical experience, and the oral organs with these meridians have been known through clinical experience. By confirming that there is a close relationship with tissues and the autonomic nerves that control them, and identifying abnormal conditions at reaction points (acupuncture points, commonly referred to as acupuncture points) in these meridians, we can identify the abnormal conditions associated with the reaction points. Treatment is performed to diagnose the presence or absence of disease in each organ tissue, or to adjust the abnormal state by applying physical stimulation using needles, heat, electricity, etc. to the reaction points in the abnormal state. There is.

Identifying a reaction point in an abnormal state from among a large number of reaction points is determined by the sense of the examiner's fingertips and the patient's perception, but this depends on the examiner's many years of experience and skill. and requires. Therefore, a machine has been created that uses the fact that electrical resistance abnormalities are noticeable in the skin at reaction points (acupoints) to electrically detect acupuncture points and diagnose them without requiring experience or skill. . Conventionally, such a device was manufactured by Japanese Patent Publication No. 52-4
There is a viscera-autonomic nerve function diagnostic device No. 878. However, since the functional parameters of the living body detected by this device are only static impedance in response to electrical signals applied through the valve holes of the living body, sufficient biological information cannot necessarily be obtained from the functional parameters. In addition, diagnostic parameters obtained by calculating and analyzing functional parameters are difficult to use because they are expressed as numerical information, and accurate diagnosis still requires the experience and skill of experts.

[Purpose of the Invention] The present invention has been made in view of the above-mentioned drawbacks of the prior art, and its purpose is to visually and intuitively understand the relationship between the various quantities of the determined diagnostic parameters. An object of the present invention is to provide a meridian-organ function information processing device that can be provided as information. Preferably, it is an object to provide a meridian-organ function information processing device that can provide information without losing any information on the relationship between various points and with unimportant parts effectively excluded from the visual sense.

Another object of the present invention is to provide a meridian-organ function information processing device that can provide information in the form of a bar graph that allows easy understanding of the relationship between various quantities of the determined diagnostic parameters.

[Summary of the Invention] In order to achieve the above-mentioned purpose, the meridian-organ function information processing device of the present invention includes a data input means for inputting dynamic functional information related to the meridian-organ function; A parameter calculation/analysis means calculates and analyzes the functional information to obtain a predetermined diagnostic parameter, and a circular pattern of a predetermined diameter is calculated from the center by N etc. The various quantities are made to correspond to the length from the center on the divided line segment, and the various points determined by this are edited and outputted to a radar chart connected by the line segment. The outline thereof is to include a pattern that overlaps circular patterns having a diameter smaller than the predetermined diameter.

Preferably, the length of the diameter of the small circle corresponds to a threshold value set for a predetermined diagnostic parameter.

Further, in order to achieve the above object, the meridian-1 organ function information processing device M of the present invention includes a data input means for inputting dynamic functional information related to the meridian-organ function, and a data input means for inputting the functional information inputted by the data input means.・parameter calculation/analysis means for analyzing and obtaining predetermined diagnostic parameters; and data editing/output means for editing and outputting the various quantities of the diagnostic parameters obtained by the parameter calculation/analysis means in a bar graph;
Is it possible to edit various quantities of the diagnostic parameter into a bar graph using characters or symbols representing the meaning of the diagnostic parameter as units? The outline of this is as follows.

Furthermore, in order to achieve the above object, the meridian-organ function information processing training of the present invention includes a data input means for inputting dynamic functional information related to the meridian-organ function, and a data input means for inputting the functional information inputted by the data input means. A parameter calculation/analysis means for analyzing and obtaining predetermined diagnostic parameters, and a data editing/output means for editing and outputting the various amounts of the diagnostic parameters obtained by the parameter calculation/analysis means in a bar graph, and the various amounts of the diagnostic parameters are The outline is to have something to edit the relative meaning expressed in a bar graph in a specific arrangement.

DESCRIPTION OF THE PREFERRED EMBODIMENTS [First Embodiment] Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram of a meridian-organ function information/information processing device according to a first embodiment. In the figure, reference numeral 1 captures the dynamic changes in the current sequentially passed through the living body through 28 wells of both hands and feet of the subject, and from the measured values predetermined meridian-organ function parameters BP and AP.

A meridian-organ function parameter measuring device (hereinafter referred to as the measuring device) that calculates and outputs TC, IQ, and θ (hereinafter referred to as functional parameters), 2 is the main body of the meridian-organ function information processing device of the embodiment (hereinafter referred to as , information processing device), 3 is an external storage device M (cassette device, disk device, etc.) provided for the purpose of auxiliary storage means, and 4 is various diagnostic parameters and treatment points of the subject calculated and determined in the information processing device 2. Data output device (printer, CRT display device, L
ED matrix, audio output device, etc.), 5 instructs the progress of the test subject's diagnosis processing by the system of the embodiment, and also indicates various parameters necessary for diagnosis (measurement date and time, test subject's name, gender, age, medical history, This is a keyboard for inputting information (current symptoms, etc.).

Furthermore, although not shown, the information processing device 2 described above actually has the following functions:
For example, a ROM or RAM containing various diagnostic processing programs of the embodiments shown in FIGS. 5 to 10 and various dictionary information to be referred to for diagnosis, and temporarily stores data necessary for the diagnostic processing. Peripheral IO for outputting various processing data between RAM and external connection devices
It includes a central processing unit (CPU) housed on the same board together with circuits, etc., and the blocks of the information processing device 2 include functional blocks of the CPU realized by executing the various processing programs described above. ing.

Briefly explaining these functional blocks, 6 is a buffer means for temporarily storing the functional parameters BP-IQ inputted from the measuring device 1, and further θ if necessary, and the functional parameters stored in the buffer means 6 are BP~I
Q, etc. are normally processed immediately, but are sent to the external storage device 3 via line 101 for the purpose of batch processing multiple people later.
It is also possible to evacuate to 7 calculates and calculates the function parameters 8P to IQ read out from the buffer means 6.
Analyze and obtain parameters useful for diagnosis (systemic diagnostic parameters AD, intra-individual diagnostic parameters AD', etc.), output them, and obtain systemic diagnostic parameters AD, intra-individual diagnostic parameters AD', etc. 8 is a reference value table that stores a table of common reference values NS prepared in advance for comparison with the determined systemic diagnostic parameters AD. A storage means 9 is a diagnostic dictionary storage means that stores systemic diagnostic information DJ in a location that is accessed based on the comparison result with the common reference value NS; Obtained intra-individual diagnostic parameters AD
A treatment point determining means 11 determines and outputs an appropriate treatment point for the subject based on the individual diagnostic parameter AD'; A treatment point dictionary storage means 12 stores point information TJ, and 12 specifies the subject's systemic diagnostic parameters AD, personal diagnostic parameters 〇', systemic diagnostic information DJ, appropriate stimulation treatment point information TJ, etc. format and save them to the data output device 4 or external storage device 3.
This is a data editing means for outputting to.

FIG. 2 is a diagram illustrating one usage mode of the measuring device 1.

When measuring functional parameters such as BP to IQ, first attach two (-) side electrodes to both wrists, then attach 28 multi-point (+) side TL electrodes to the 28 wells at the ends of both hands and toes. Attach them to each hole. Figure 3(a).

For reference, 14 holes at the tips of the fingers and toes are shown in (b). Including the left and right sides, there are a total of 28 wells. (
The reason for attaching the -) side electrodes to both wrists is that each (+) side TL
This is to eliminate measurement errors due to the electrode mounting surface by balancing the electrical resistance path of the living body from the pole to the (-) side electrode.

After installing the electrodes in this way, each (
A positive pulse voltage (3 V) is sequentially applied to the (+) side electrode in an electronic scanning manner, and dynamic changes in the current flowing through each well of the living body are measured.

FIGS. 4(a) and 4(b) are diagrams for explaining the principles of measurement and calculation of functional parameters BP-IQ, etc. At time t, as shown in FIG. 4(a). When a DC voltage of 3cm is applied locally to the skin, the body's defense and homeostatic functions work to cancel out the electrical stimulation, and as a result, the voltage rises at time t as shown in FIG. 4(b). 200μsec after instantaneous current flows to
There is a phenomenon in which the value settles down to a constant value before and after. In this example, this rising current value is defined as the pre-polarization current BP (bef
The current that shows a constant value after polarization is called the after-polarization current AP (after polarization).
polarization), and the shaded area is the total polarization charge IQ (integrated pol
polarization charge), and the speed of polarization is called polarization rate TC (time constant).
The angle between the current axis and the line T in the figure is called the polarization angle θ. These functional parameters BP to IQ, etc. have the following properties.

70% of fBP (pre-polarization current) flows through the dermis and is determined by the specific resistance of living skin tissues, including the epidermis and dermis. This is a parameter that indicates the functional status of meridians. In summer, there is a lot of water in the body and the 8P value is high, and in winter, there is little water and the BP value is low. Healthy people with a good flow of body fluids have a high BP value, while elderly, seriously ill, and frail people have a poor flow of body fluids and have a low IP value.

rlQ (total polarized charge @) J Indicates a M of charges moved due to polarization. It is thought to indicate the homeostatic function of the body (metabolism, biological defense function).

IQ values are known to be extremely low in terminally ill cancer patients and those nearing death, and are observed to be higher than normal in cases of inflammation.

8P (post-polarization current) J flows mainly through the epidermis.It is formed when ions flow freely even after polarization because the ion permeability of the barrier membrane is still high.The AP value is a nervous response (GSR). The skin resistance level is measured as , and is thought to reflect autonomic nervous function. A high AP value indicates a sympathetic nervous function excitation type, and a low AP value indicates a parasympathetic nervous function excitation type.

FT(:(polarization speed)J Represents the speed of polarization.

“θ (polarization angle) J The speed of polarization is expressed in degrees.

In FIG. 4(a), the measuring device 1 captures the dynamically changing current change with the current detecting means A, and uses the detected current value at a predetermined sampling period (for example, 1μ5ec).
A/D conversion is performed. Therefore, this A/D converted series of current values ID includes dynamic functional information related to meridian-organ functions. The measuring device 1 further calculates the above five functional parameters based on this current value ID. The pre-polarization current BP is the peak value of the current at or near time t0. Furthermore, time t. The term "near" means that, for example, the first two data points are likely to be due to mechanical errors, so they are excluded, and the next three data points are calculated theoretically. Therefore, in the embodiment, for example, the time of three data points is set. '. The post-polarization current AP shows a constant value after polarization, but is, for example, an average value. The total polarized charge IQ is at time t. Or time t. It is the time-integrated result of subtracting the value of the post-polarization current AP from the current value of each data point starting from ' and until the current waveform stabilizes (about 200 μsec). For example, as shown in Figure 4(b), This corresponds to the area indicated by diagonal lines. Time t.

Nearby data contributes significantly to the integral, so it may not be possible to ignore it uniformly. Therefore, the operator can make a judgment and select one of them. The polarization speed TC is the time until AP is reached, and is the time t0 or time t until the first data 10 where the data IDs have the same value a predetermined number of times. ’ is the time since. Or, if you want to find it simply, time t up to the point where the tangent T of the current waveform at time to' intersects the time axis. Or time t. ’ is the time since.

This can be selected for the same reason as above. The polarization angle θ is the angle between the current axis and the tangent line T in the figure.

In this way, the numerical data sent from the measuring device 1 to the information processing device 2 includes the polarization charge current value BP measured and calculated at the tip of the limb 28, the post-polarization TL flow value AP, and the polarization speed T.
There are four functional parameters of C1 polarization charge total IQ, or five functional parameters including polarization angle θ.

Line 100 in FIG. 1 indicates a data connection line between measuring device 1 and information processing device 2. Line 100 in FIG. Various methods are possible for this data connection method.

For example, when the measurement device 1 and the information processing device 2 are directly connected and used, a simple direct connection interface is used. For example, by directly connecting a small measuring section 1' having a single-point electrode to an information processing section 2' configured on one chip,
It is possible to construct a portable device that can be operated by the subject himself, such as the sphygmomanometer of -112. Further, when connecting a plurality of measurement devices 1 and information processing device 2 online, it is configured by, for example, a GP-I B (IEEE-488) interface or an R3232C interface.

In this way, the functional parameters BP-IQ, etc. of multiple subjects sent from remote locations can be collected online, and the diagnosis results can be diagnosed in real time and returned immediately, or they can be stored temporarily in the external storage device 3 and then stored later. It is also possible to perform batch processing. Furthermore, the line 100 may be a simple wireless communication system used in hospitals.

Further, although the processing program of this embodiment is stored in the ROM, the present invention is not limited to this. The processing program PD and necessary dictionary information may be loaded via line 102 from an external storage device.

...Calculation of systemic diagnostic parameters...FIG. 5 is a flowchart showing the calculation and analysis process of the subject's systemic diagnostic parameters AD. In order to diagnose a subject's systemic function, it is effective to compare it with reference values determined for a large number of healthy people. However, since the measurement data for the functional parameters BP to IQ, etc. is 4×28 in., an effective comparison cannot be made as it is. Therefore, first, a systemic diagnostic parameter AD useful for comparison is determined. These are each average value (8VE) of functional parameters such as BP-IQ, each normalized standard deviation (SD), each limb ratio (F/T), each left and right ratio (L/It), and , the normalized functional parameters L% and R% of each left and right meridian, and the normalized value D% of each left-right difference.

In FIG. 5, the parameter analysis/diagnosis means 7 calculates each average value 1]PA""IOA of the functional parameters UP-IQ, etc. of the 28 meridians in step S51, for example, [IPA=
1/28x Σ1 bar '81'.

and store the result in the output area.

In step S52, each normalized standard deviation BPs
o”IQso, for example, BPso=1/[lPA・128×Σ+=i B
h Obtain by IIPA and store the result in the output area.

In step S53, the ratio BPFT of each limb ~■
death. is determined by, for example, BPPT=hand average value BPAF/foot average value BPAa, and the result is stored in the output area. Here, the average value BPAF of the hand is the parameter Bj+ of the 14 meridians of the left and right hands.
Therefore, BPAF=1/14XΣl='i' [IPI is obtained. The same applies to the bar average value IIFAT.

In step S54, each left and right ratio BPLR~
IQLR, for example, BPLR=left average value B P A 1. / right average value B
Obtain by AR and store the result in the output area. Here, the left average value BPAL is calculated from the parameters flP of the 14 meridians of the left limb, [1PAL = 1/14XΣ18' and B
It is determined by P. The same applies to the right average value BPAll.

In step S55, the measured functional parameters BP~I
For Q, etc., normalized functional parameters L% and R% of each left and right meridian are calculated. Now, if Ll and R are the left and right measured values, respectively, such as by parameter analysis, then the left normalized value L% can be found as L%=L1/xLR. Also, the normalized value R% on the right is R% = RI/X
It is determined by LR. Here, XLR is the average value of the left and right sum, and
+).

In step S56, the normalized L% and R% of the functional parameters OP to IQ, etc. are numbered in descending order of numerical value and stored in the output area of the determined L% and R%.

In step S57, the normalized value D% of the left-right difference is similarly calculated as D%=lLl-R1l/DA. Here, DA is the average value of the left-right difference, and D
A = 1/14XΣI! 'Determined by ILIRI+. It should be noted that numerical values obtained in the middle of the above-mentioned arithmetic processing, such as values such as the left-right difference D+=1L+R+1, are stored in a predetermined area for use in later diagnostic processing.

...Diagnosis of systemic function...Next, the parameter analysis/diagnosis means 7 compares the above-determined systemic diagnostic parameters 8VE~D% with a common standard value NS (normal 5 standard) prepared in advance. Diagnosis of the subject's systemic function is performed. For this purpose, reference value notation (, Q means 8 is 4 functional parameters BP-IQ measured in advance on a large number (N) of healthy people)
A common reference value NS created based on the above is stored for each month. Since functional parameters have seasonal variations, we decided to store them for each month. The relationship between the subject's systemic diagnostic parameter AD and its common reference value NS is as follows.

VE (average) For each average value BPA to IQA such as JBP to IQ, BPA is a parameter that mainly determines the meridian function of the entire body and the normality/abnormality of Qi energy, and APA is the parameter that determines the normality/abnormality of autonomic nervous function. IOA, a parameter for determining abnormality, is a parameter for determining normality/abnormality of the homeostasis function, metabolism, and defense function against exterior (bacteria, viruses, etc.) of the living body.The common reference value NS is determined as follows. It will be done.

■BP for each month of one year for N healthy subjects.
- Average value of IQ etc. BPA - IOA, for example, BPA =
l/N XΣhaτBP.

Find it with Here, BP is the average value of BP of 24 (or 28) meridians for one person.

■ Next, the average deviation BPD for each average value BPA ~ IQA
~IQo, for example, BP, = 1/N
Find it with 1.

(2) Next, the value obtained by subtracting the average deviation 11P from the obtained average value BPA is set as the lower limit of the normal range NS, and the value obtained by adding the average deviation BPD to the average value PA is set as the upper limit of the normal range 111NS.

Therefore, the range NS between the upper and lower limits is a normal range with a certain extent, and the average value BPA (average value of 28 meridians) obtained by measuring one subject later is the BPA
<Abnormal range of NS, normal range included in NS, and BP
It is evaluated in three classes: A>NS abnormality range.

r Normalized standard deviation SD (Standard Devi
It is a parameter that measures the degree of stability, deflection, excitement, and relaxation of meridian function, homeostatic function, and autonomic nervous function throughout the whole body. The common reference value NS is obtained using the same idea as above.

Ratio of two limbs F/T (Fingers/Toes) J
It is a parameter that measures the balance/imbalance in the upper and lower body, such as meridian function, homeostatic function, and autonomic nervous function.

``Left/Right Ratio L/R (Left/Right) This is a parameter that measures the balance/imbalance between the left and right sides of the J meridian function, homeostatic function (metabolic function), and autonomic nervous function.

r Normalized functional parameter analysis and R%J In particular, the L% and R% of the functional parameters BP have a deep correlation with the meridian function,
It is useful for discovering abnormal meridians. It is also extremely important as a personal diagnostic parameter, which will be described later.

r Normalized value of left-right difference D%1 This is a parameter that measures the left-right balance/imbalance of each meridian.

FIG. 6 is a flowchart showing a process for diagnosing systemic functions. The parameter analysis/diagnosis means 7 performs step S61.
Systemic diagnostic parameters AVE-L/R and reference values are shown in ↑,! l! The size is compared with each common reference NS read from the means 8. In step S62, it is determined whether the comparison result is within the normal range. If the systemic diagnostic parameters AVE-L/R are within the range of the corresponding common reference value NS, it is within the normal range, and the processes of steps S63 and S64 are skipped. In addition, the common standard riN
If it is not within the range of S, the process advances to step S63, where the common reference value NS used for the comparison and information indicating the magnitude relationship (
A symbol 〉 or 〉) and a symbol representing an abnormality are stored in the output ramp of the corresponding systemic diagnostic parameter AD. In step S64, the diagnostic dictionary storage means 9 is referred to in accordance with information representing the types of systemic diagnostic parameters AVE to L/R and their magnitude relationships, and appropriate diagnostic information DJ is read out and stored in a predetermined output area. In step S65, each normalization parameter L%, R% of each function parameter
and D% are compared in magnitude with the respective common bases 4NS read from the base value notation f, 11 means 8. In step S66, it is determined whether the comparison result is within the normal range. If the normalization parameter is within the range of the corresponding common reference value NS, it is within the normal range, and the process of step S67 is skipped. If it is not within the range of the common reference value NS, the process proceeds to step S'67, and the common reference value NS used for the comparison and information (symbols) indicating the magnitude relationship.
and a symbol representing the abnormality is stored in the output area of the corresponding normalization parameter. In step 368, the data m-th power means 12 calculates the function parameter BP-IQ
etc., and the determined systemic diagnostic parameters AV
E-L/R, normalization parameters L% to D%, information DJ of the diagnosis results, etc. are formed into a table and output to the data output device 4.

FIG. 11 shows an example of an output list of systemic diagnostic parameters. In the average value AVE, AP is the common reference value NS
It is indicated by the symbol 〉 and the common reference value NS. Therefore, abnormal trends in functional parameters compared to healthy others can be immediately seen. Furthermore, since L% and R% are shown normalized, it is easy to compare the relative relationships for each meridian. That is, the closer these values are to 1.0, the closer they are to the average value.

Furthermore, since L% and R% are assigned rank numbers in descending order of value, it is possible to easily grasp phenomena such as falsity, actuality, and reversal due to intra-individual diagnostic parameters, which will be described later.

Note that the process in step S64 is not necessarily necessary. This is because a specialist can make a sufficient diagnosis and determine treatment points simply by using the list data shown in FIG. However, if the subject manages his or her own health, step S64
processing provides useful and easy-to-understand diagnostic information.

Examples of diagnostic information DJ output in various cases are shown below. The message from the diagnostic information DJ is Step S
In step 62, the systemic diagnostic parameters determined to be abnormal are outputted to a predetermined diagnostic column along with the type AV-D% and the like.

? Average value AVE J BP> NS: Advanced meridian function BP< NS: Decreased meridian function AP> NS: Sympathetic nerve dominant AP<NS: Parasympathetic nerve dominant IQ> NS: Acute stage of disease/chronic disease/allergy integrated quality IQ<NS: Decreased metabolic and biological defense functions BP-IQ > NS: Acute stage of disease BP-IQ < NS: Generalized debilitation state "Normalized standard deviation 5 DJ AP, BP, IQ > NS: Advanced AP of each function, B
P, IQ <NS: Ratio of relaxation of each function per limb F/T J AP> NS: Current mood is high, anger, hot flashes, autonomic nervous symptoms appear.

AP< NS: Current Qi is falling BP> NS: Physically, there is a lot of Qi energy in the upper body. Harukita is empty and hasty.

BP<NS: Physically, there is a lot of Qi energy in the lower body. Depressive tendencies.

Both BP-IQ <NS: Depressed mood, decrease in vital energy, left-right ratio L/RJ, left-right difference BP of two people, left-right difference AP-BP-IQ both <NS : There is functional decline in the left side of the body.
...Calculation of intra-individual diagnostic parameters...

FIG. 7 is a flowchart showing the process of creating personal diagnostic parameters 0' based on the functional parameters BP. The intra-individual diagnostic parameters AD' are created for the purpose of making the diagnosis of the subject more accurate, and are not based on comparisons with healthy others using the above-mentioned Ido standard value NS. It is used to see. For this purpose, the functional parameters BP are used in particular as source data. The functional parameter [lPc′) value is different from that of other APs.
, Unlike IQ, etc., there is an old myth (the meridian function is weakened and weak, and the Qi energy is not flowing sufficiently), or it is proven (the meridian function is more active than normal, and the Qi energy is normal). This is because it shows a deep correlation with the state of gastric fluid flow (or gastric stagnation). What is particularly interesting is that meridians that have a so-called yin and yang relationship show a reversal in BP value, such as (value of yang meridian) < (value of yang meridian) when there is an abnormality such as disease in the internal organs related to them. It is.

To the personal diagnostic parameters shown below
, the average value on the right side is 11 PAR, and the il iB emitted from the hand
The average value of 8PA, and the average value of meridians emanating from the feet BPA
T, the normalized standard deviation BPSL on the left, the normalized standard deviation on the right These are the hand ratio BPLRF, the left and right foot ratio BPLIIT, the left limb ratio BPFTL, and the right limb ratio BI'FTR. In addition to this, some of the whole-body diagnostic parameters (average value, normalized standard deviation, ratio of limbs, left-right ratio) obtained by the process shown in FIG. 5 are used as intra-individual diagnostic parameters.

In step S71, the parameter analysis/diagnosis means 7 calculates the left side average value PAL for the functional parameter BP from the 8e value of the left limb.
The right side average value BPAR is determined by IIPI, and the right side average value BPAR is determined from the BP value of the right hand and foot by 8PAll = 1/14
From the P value, calculate BPAF = 1/+4 Store in.

In step S72, similarly, the left side normalized standard deviation BPsL is calculated from the 1 value of the left limb and the left side average value BPAL as follows: SL=1/[lPAL-l 14×Σ
1.11-' BPI -BPAL) 2, and the normalized standard deviation BPSR on the right side is
From P value and right side average value BPAR, BPSR = 1/BP
ARH114×Σl='l BPI BPAR)
2, the normalized standard deviation of the meridians emanating from the hands [1
1' s, the BP value of both hands and the average value of both hands [IPA, and 11 SF = 1 / II P A r・
l 14 X Σ , :□i” BP+
[]PAF) 2, the normalized standard deviation Or', T of the meridians originating from the feet is calculated from the Bl' values of both feet and the average value of both feet 8PAT = l/[1PAT-f-■gate4X Σ+= '? (BP+BFAT) 2
and store those results in the output area.

In step S73, the left and right hand ratio BP L is similarly determined.
II F from the []P value of the left hand and the BP value of the right hand B
P L RF = left hand average value BPALF / right hand average value B Calculated by A11F, and the left and right foot ratio BPLRT is determined from the left foot llP value and right foot BP value BPLRT = left foot average value (IPALT / right foot average value B ART , the left limb ratio BPFTL is calculated from the [IP value of the left hand and the [IP value of the left foot] BPPTL = left hand average value BPALF / left foot average value B
Calculate the right limb ratio BPFTR by ALT from the BP value of the right hand and the BP value of the right foot.
The results are obtained by ART and stored in the output area.

In step S74, the data editing means 12 converts each value of the intra-individual diagnostic parameters into the meanings of those parameters (
The bar graph is converted into a bar graph using the symbol that most intuitively represents the type (type), and is output to the data output device 4.

FIGS. 12(a) to 12(c) are diagrams showing examples of bar graphs of intra-individual diagnostic parameters. The average value in Figure 12(a) (
AVERAGE) Odor"'C1 left ff1ll average value BIIAL (LEFT) and right average value 81"AR
As shown in the (RIGHT) shelf, these bar graphs convert the meaning on the left side with L and the meaning on the right side with R. Therefore, the viewer has the advantage of being able to immediately understand the meaning and size of the graph just by looking at the bar graph itself, without having to refer to the name in the left column of the bar graph. This conversion method is 1
It is preferable to use a letter or a single symbol, but the invention is not limited to this. For example, if there are many bar graph types, °゛word°
You can also convert it in degrees. Also, the balance in Figure 12(c) (
As shown in the bar graph of B to LANCE), these bar graphs are converted with the symbol 〉 when the ratio exceeds 1.0, and with the symbol 〉 when the ratio does not exceed 1.0. Therefore, the viewer has the advantage of being able to immediately read the nature of size from these symbols. In short, it should be expressed in a way that connects with the viewer's intuition depending on the purpose and state of use.

...Diagnosis using intra-individual diagnostic parameters...FIG. 8 is a flowchart showing diagnostic processing using intra-individual diagnostic parameters. As mentioned above, functional parameter analysis values have a strong correlation with false theories, demonstrations, etc., and there is an advantage that diagnosis can be made using traditional methods based on these. The following process further defines the states of imaginary, most imaginary, actual, most fruitful, reversed, and unstable based on the intra-individual diagnostic parameters obtained as described above,
This is added as a new intra-individual diagnostic parameter.

In step S81, the parameter analysis/diagnosis means 7 calculates the 10th
A meridian showing a magnitude of 1st to 12th (for example, in the case of using the 12th meridian from the top in Figure 11, the same applies hereinafter) is diagnosed as a left-sided imaginary. In step S82, for each measured value Ri (or its normalized parameter R%, the same applies hereinafter) on the right side of the functional parameter BP, the meridian showing the 10th to 12th magnitude is diagnosed as a right-side imaginary. In step S83, for Li and Ri of the functional parameters BP, (t, i+Ri)/2
If the value does not indicate the magnitude of the 10th to 12th place, the meridian is diagnosed as imaginary, and the meridian showing the lowest value among them is diagnosed as the most imaginary. In step S84, the function parameter [IP L]
The meridian showing the 1st to 3rd largest size for i is diagnosed as the fruit on the left. Step 385 is the function parameter [1
The meridian showing the 1st to 3rd largest size for R1 of 1' is diagnosed as the fruit on the right side. In step S86, regarding Ll and Ri of the functional parameters BP (L i + Ri)
The meridian showing the value of /2 or the first to third largest size is diagnosed as fruit, and the meridian showing the highest value among them is diagnosed as fruit. In step S87, Li of the functional parameter BP is
and Ri have a relationship of (circle continuation) < (yang meridian), and if the value of the difference shows the first to third largest magnitude, the meridian is diagnosed as reversed. In step S88, the meridian in which the left and right difference Di (=ILi-Ri l, or its normalized parameter D%, the same applies hereinafter) of the functional parameter BP is the first to third largest is diagnosed as unstable. In step S89, the data editing means 12 converts the information of the above-mentioned diagnosis results into a bar graph in the order that best represents the characteristics of each diagnosis result and outputs it, and also compares it with the reference value and, if there is an abnormality, displays the bar graph. Outputs the diagnosis result.

FIGS. 13(a) to 13(e) are diagrams showing examples of bar graphs of diagnosis results based on personal diagnosis parameters. For example, the first
In Figure 3(a), the BPs of the 12 meridians are shown in order from 1st to 12th. This corresponds to the order of Li in the functional parameter UP described above. Therefore, it can be seen at a glance that the 1st to 3rd meridians are real, and the 10th to 12th meridians are imaginary. Similarly, you can see at a glance whether the meridian is unstable from Figure 13 (C). These bar graphs provide useful information in determining treatment points in a very easy to understand manner.

FIG. 9 is a flowchart showing radar chart editing processing. In step S91, the data editing means 12 creates a circular pattern with a predetermined diameter by 12 (or 1
4) Draw a line segment going outward from the center and make 12 (or 14) meridian names correspond to each other at the intersection of the line segment and the circumference. In step S92, the values of the parameters Li and Ri determined for each meridian are made to correspond to the length from the center of the circle, and the respective points are connected with a straight line. In step S93,
The value of the left-right difference obtained for each meridian is made to correspond to the length from the center of the circle, and a triangle extending outward from the center of the circle is formed with each point as a vertex. In step S94, the area from the center of the circle is filled with a circle having a predetermined radius set as a threshold value. In step S95, divide the other circle into 12 (or 14) equal parts from the center, and similarly divide the other circle into 12 (or 14) equal parts.
(or 14) Match meridian names. In step S96, the left and right average values obtained for each meridian are made to correspond to the length from the center of the circle, and the points are connected with a straight line. Step S97
Now, the inversion value obtained for each meridian is made to correspond to the length from the center of the circle, and a triangle extending outward from the center of the circle is formed with each point as a vertex. Step S98
Now, the area from the center of the circle is overlaid with a circle of a predetermined radius set as a threshold value.

FIGS. 14(a) and 14(b) are diagrams showing an example of a radar chart. Radar charts have the advantage of being able to read more comparative information at a glance. In the radar chart of the embodiment, the plates obtained for each meridian correspond to the lengths from the center of the circle, so the area around the center of the circle tends to be somewhat complicated. However, since it is usually not very important to know the details of this part of the data, I decided to fill it in with a small circle. This makes the radar chart even easier to read. Furthermore, by making the radius of the small circle correspond to a certain threshold value, it is easy to give the impression that the information protruding from the small circle has important meaning.

...Determination of the stimulation treatment point... Deficiency (DEFIC) obtained for the functional parameter BP,
EXCES, left/right difference (IMBAL), reversal (
INVER) Intra-individual diagnostic parameters are closely related to the determination of stimulation treatment points. The following processing is for automatically and safely carrying out complex judgments made by specialists.

FIG. 10 is a flowchart showing treatment point diagnosis processing. The treatment point determining means 10, in step 5IOI,
Regarding the functional parameter BP, imaginary (DELIC), real (
EXCES), left/right difference (IMBAL), inversion (INV)
The meridians indicating Et() are found, and the top three meridians for each are identified. In step 5102, the appropriate treatment point information TJ is read out by referring to the treatment point dictionary storage means 11 according to the above-determined imaginary, real, left-right difference, and reverse meridian information. The treatment point dictionary storage means 11 stores the meridian? 1. ? Regarding the relationship between i information and stimulation treatment points, dictionary information established through long clinical experience is recorded (,Q), and appropriate treatment point information TJ is output with the following relationship, for example.

(1) Treatment of the false meridian: Stimulating the original person of the real meridian (2) Treatment of the reversed meridian: Stimulating the original person of the real meridian (3) Treatment of the real meridian: Stimulating the grave of the false meridian (4) Treatment of unstable meridians. (5) Activation and balancing treatment of 28 meridians in the whole body - Activate the gold holes of the imaginary meridians with grave hole stimulation. - With the tiger hole stimulation of the real meridians. Decline (6) Treatment of the relative decline of the 14th meridian in the upper body - Grave stimulation of the imaginary meridian (7) Treatment of the relative decline of the 14th meridian in the lower body - Tiger hole stimulation of the imaginary meridian (8) The relationship between the imaginary meridian and the three yin and three yang When a certain meridian is imaginary and the difference between left and right is large, the gap in the gap stimulates the original person of the imaginary meridian. 10) Unstable meridians and yin and yang, two meridians that have a three yin and three yang relationship treat the false one and stab the grave of the unstable meridian. (11) Real meridians and conflict relationship. Stimulation of the meridian of the tiger hole (12) Treatment of a meridian or false meridian that is in a mutualistic relationship with an unstable meridian - Stimulate the original person with an unstable meridian (13) When a meridian that is in a conflicting relationship with an unstable meridian is actually unstable, In step 5103, the data editing means 12 performs the following steps in step 5103:
2 (or! 4) meridian names and the ranking of the top three individual pelvic examination parameters corresponding to each meridian name and indicating the above-mentioned imaginary to reversal by the number of corresponding symbols. and the hominid corresponding to each of the above meridian names,
The names of the stimulation points such as the grave and the gold hole, and the points to be treated are expressed by adding symbols to the names of the stimulation points, and are outputted in a table. In step 5104, the treatment points are added to a predetermined human body diagram pattern and output.

FIG. 15 is a diagram showing an example of table information of treatment points. Here, for example, in order to treat the false meridian (A) (increase L% to R%), it is shown that the original person (Taien) of the real meridian (High) should be stimulated. The treatment point for the meridian of reversal (Shin) is also the same original human (Taien). Conversely, for the treatment of the actual meridian (high) (reduction of L% to R%),
It is indicated to stimulate the grave of the false meridian (I). According to this treatment point information, it is easy to clear the false and real meridians and restore balance. Moreover, the table is very easy to read because it shows the numbers of similar symbols to indicate the imaginary, real, reversal, etc. of each of the first to third places.

FIG. 16 is a diagram showing an example of information on treatment points shown in a human body diagram. Since only the necessary treatment points are displayed, there is no chance of mistaken recognition and it is safe.

[Second Embodiment] In 9) and 9 of the first embodiment, an information processing device 2 including all the functional blocks of the embodiment is shown.

However, the information processing apparatus according to the present invention can be provided as an information/A processing apparatus that can produce its own unique effects by combining optimal functional blocks according to its intended use.

In FIG. 1, the information processing device of the second embodiment includes a buffer means 6 for temporarily storing functional parameters [lP to IQ, etc. input from the measuring device 1, and functional parameters BP to IQ read out from the buffer means 6. a parameter analysis/diagnosis means 7 which calculates and analyzes the systemic diagnostic parameters AD useful for diagnosis, and outputs them; and a data editing means 12 for outputting the data to the data output device 4.

As a result, the information processing device of the second embodiment is realized with a simple configuration and processing, and is useful for medical specialists as shown in the numerical table of FIG. 11 and FIGS. 12(a) to (c). Diagnostic information is available.

[Third Embodiment] In FIG. 1, the information processing device of the third embodiment includes a buffer means 6 for temporarily storing functional parameters BP to IQ, etc. inputted from the measuring device 1, and a Functional parameters BP-IQ, etc. are calculated and analyzed to obtain systemic diagnostic parameters AD useful for diagnosis, and these are compared with the common reference value NS, and the eight systemic diagnostic parameters and their common A table of common reference values NS prepared in advance for comparison between the parameter analysis/diagnosis means 7 that outputs the results of comparison with the reference value NS and the systemic diagnostic parameter AD is shown in ↑5Q. Reference value notation f, Q means 8, and the systemic diagnostic parameter AD
and a data editing means 12 for editing the data into a predetermined format and outputting them to the data output device 4.

Therefore, the information processing device of the third embodiment is realized with a simple configuration and processing, and for example, as shown in FIGS. 11 and 12, specialists can receive useful systemic diagnostic information as well as the comparison results with the common reference value NS. can get.

[Fourth Actual Eyebrow Example] In FIG. Calculate and analyze the read 1 geometric parameters BP~10, etc. to obtain a systemic diagnostic parameter 80 useful for diagnosis, compare it with the common standard value NS, and make a predetermined diagnosis based on the comparison result. A standard value table in which a table of common standard values NS provided in advance for comparison between the parameter analysis/diagnosis means 7 that outputs the conclusion information DJ and the above-mentioned systemic diagnostic parameter 80 is arranged and zeroed. a storage means 8; a diagnostic dictionary storage means 9 storing systemic diagnostic information DJ in a location accessed based on the comparison result with the common reference value NS; and editing the diagnostic result information DJ into a predetermined format. and a data editing means 12 for outputting them to the data output device 4.

Therefore, the information processing device of the fourth embodiment can automatically provide diagnostic results even to a person who has no knowledge. Suitable for health checkups.

U Fifth Embodiment The information processing bag U of the fifth embodiment is shown in FIG. Parameter analysis/diagnosis means 7 that calculates and analyzes the parameter BP to obtain personal diagnostic parameters D' useful for diagnosis and outputs them, and edits the personal diagnostic parameters D' etc. into a predetermined format. death,
Data editing means 1 that outputs them to the data output device 4
It consists of 2.

As a result, the information processing apparatus of the fifth embodiment can be realized with a simple configuration and processing, and for example, it is useful for medical specialists as shown in FIGS.
Useful intra-individual diagnostic information can be obtained as shown in e) and FIGS. 14(a) and 14(b).

[Sixth Embodiment] The □ln information processing device of the sixth embodiment is shown in FIG.
A buffer means 6 for temporarily storing at least the machine parameter OP inputted from the Rη determining device 1, and a function parameter BP read out from the buffer means 6 to calculate and analyze the individual diagnostic parameter AD' useful for diagnosis. a parameter analysis/diagnosis means 7 for calculating and outputting them; a treatment point determining means IO for determining and outputting an appropriate treatment point for the subject based on the personal diagnostic parameters; Appropriate stimulation treatment point information TJ for primitive people, graves, and gold holes in the locations accessed based on D'.
), edits the treatment point dictionary storage means 11, the subject's personal diagnosis parameters, appropriate stimulation treatment point information TJ, etc. into a predetermined format, and outputs them to the data output device 4. A data editing means 12 is provided.

As a result, the information processing apparatus of the sixth embodiment can be realized with a simple configuration and processing, and useful treatment point information can be provided as shown in FIGS. 15 and 16, for example.

In addition, in the above-mentioned first to sixth embodiments, the numerical data sent from the measuring device 1 to the information processing device 2 is ΩH: 32 B.
The polarization charge current (IiBP,
Polarization return current value AP, polarization speed TC1 polarization electrical quantity IQ 4
The case where there are five functional parameters including the functional parameter or the polarization angle θ has been described.

However, the invention is not limited to this, and for example, the numerical data sent from the measuring device 1 to the information processing device 2 may be a series of current value IDs themselves that have been A/D converted by the measuring device 1.

This is because the calculation of the five functional parameters as described above can be easily performed in the information processing device 2 using the same calculation method as in the measuring device 1. Furthermore, by performing such calculations in the information processing device 2, all complex calculations related to digital processing can be performed at once in the information processing device 2, and the measuring device 1 can be made smaller and simpler.

[Effects of the Invention] As described above, according to the present invention, it is possible not only to visually and intuitively understand the relationship between the various quantities of the obtained diagnostic parameters using a radar chart, but also preferably to obtain information on the relationship between the various quantities. Since diagnostic information is provided without losing any information and by effectively excluding unimportant parts from the visual field, important information can be easily grasped.

Further, according to the present invention, it is possible to provide diagnostic information that allows the user to easily understand the meaning and content of the bar graph by using characters or symbols displayed on the bar graph itself without referring to the item column.

Further, according to the present invention, by representing bar graphs in a specific arrangement according to the various quantities determined, diagnostic information that allows a predetermined meaning and content to be easily grasped from the arrangement can be provided.

[Brief explanation of drawings]

FIG. 1 is a block configuration diagram of the meridian-organ function information processing device of the first embodiment, FIG. 2 is a diagram explaining one usage mode of the measuring device 1, and FIG. 3 (a) and (b) are fingers and toes. Reference diagram showing the 14 wells at the tip. Figures 4 (a) and (b) are diagrams explaining the principles of measurement and calculation of functional parameters such as BP-IQ. Figure 5 is a general diagnosis of the subject. FIG. 6 is a flowchart showing the process for diagnosing the parameter AD; FIG. 7 is a flowchart showing the process for creating the personal diagnosis parameter AD' based on the functional parameter BP; FIG. 9 is a flowchart showing the radar chart editing process. FIG. 10 is a flowchart showing the treatment point diagnosis process. FIG. 11 is the output list 1 of systemic diagnostic parameters. Figures 12(a) to (C) are diagrams showing examples of bar graphs of personal diagnostic parameters. Figures 13(a) to (e) are bar graphs of diagnostic results based on personal diagnostic parameters. A diagram showing an example of FIG. 14(a),
(b) is a diagram showing an example of a radar chart, FIG. 15 is a diagram showing an example of table information of treatment points, and FIG. 16 is a diagram showing an example of information of treatment points displayed on a human body diagram. In the figure, 1... meridian-organ function parameter measuring device, 2
. . . Main body of meridian-organ function information processing device, 3. External storage device, 4. Data output device, 5. Keyboard, 6. Buffer means, 7. Parameter analysis. Diagnosis means, 8... Reference value notation means, 9... Diagnosis memory means, 10... Treatment point determination means, 11...
・Method cooking dictionary t0 means, 12...Data editing means. Figure 3 Figure 4 (b) Figure 13 (cL) (e) 1------Oki ■---Ryoichi --÷-11111-
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Claims (4)

[Claims] (1) a data input means for inputting dynamic functional information related to meridian-organ functions; a parameter calculation/analysis means for calculating and analyzing the functional information inputted by the data input means to obtain predetermined diagnostic parameters; Regarding the various amounts of diagnostic parameters determined by the parameter calculation/analysis means,
Data that is edited and output on a radar chart in which the various quantities correspond to the lengths from the center on line segments that divide a circular pattern of a predetermined diameter into N equal parts from the center, and points determined by this are connected by line segments. A meridian characterized in that the editing output means includes a means for overlapping circular patterns having a diameter smaller than the predetermined diameter on the center of the radar chart.
Organ function information processing device. (2) The meridian-organ function information processing device according to claim 1, wherein the length of the diameter of the small circle corresponds to a threshold value set for a predetermined diagnostic parameter. (3) a data input means for inputting dynamic functional information related to meridian-organ functions; a parameter calculation/analysis means for calculating and analyzing the functional information input by the data input means to obtain predetermined diagnostic parameters; A data editing/output means for editing and outputting the various amounts of the diagnostic parameters obtained by the parameter calculation/analysis means into a bar graph, and editing the various amounts of the diagnostic parameters into a bar graph using characters or symbols representing the meaning of the diagnostic parameters as units. What is claimed is: 1. A meridian-organ function information processing device comprising: (4) a data input means for inputting dynamic functional information related to meridian-organ functions; a parameter calculation/analysis means for calculating and analyzing the functional information inputted by the data input means to obtain predetermined diagnostic parameters; The data editing/outputting means edits and outputs the quantities of the diagnostic parameters obtained by the parameter calculation/analysis means in a bar graph, and includes means for editing the relative meanings expressed by the quantities of the diagnostic parameters in a bar graph in a specific arrangement. A meridian-organ function information processing device characterized by: