Evaluative Method of Effect of Adjustment Measures on Human Body's Physiological and Psychological States

1. Evaluative method of effect of adjustment measures on human body'"'"'s physiological and psychological states by means of using Thermal Texture Maps Technology (TTM), comprising the following steps:

• (1) Before certain adjustment measures are applied, conducting a scanning on the human body surface for a record of a thermal radiation mapping, taking a maximum value of the thermal radiation of each part, organs and tissues as its representative F_i⁰, i=1, 2, . . . , I, in an unit of °
  
  C.;
  
  I is the total number of the parts, organs and tissues, from which corresponding thermal radiation numerical values are measured by means of using TTM technology;
  
  thereby obtaining the thermal radiation intensity of the respective parts organs and tissues F_i⁰, i=1, 2, . . . , I;
  
  (2) Taking the thermal radiation numerical values of the lips, navel, and each endocrine glands, which are marked respectively as F_lips⁰, F_navel⁰, F_glandl⁰, l=1, . . . L, L is the number of the endocrine glands to be tested;
  
  these F_lips⁰, F_navel⁰, F_glandl⁰, l=1, . . . L are used to evaluate human body'"'"'s original physiological states of human body as a whole before application of any adjustment measure;
  
  a healthy human body should has F_lips⁰=0±
  
  0.2, F_navel⁰=2.0±
  
  0.2, F_glandl⁰≦
  
  0.1, l=1, . . . L;
  
  (3) Obtaining the nine thermal radiation values, marking them as F_r⁰, r=1, 2, . . . , 9, from the nine regional indicative windows, that is, two clavicle pit, two axillae and two inguina ditches on the left and right side of the body'"'"'s centre axis respectively, and from the upper, middle and lower sector of the back spinal;
  
  Each parameter respectively stands for the original thermal radiation intensity of certain zone as follows;
  
  F₁⁰left clavicle pit;
  
  F₂⁰right clavicle pit;
  
  F₃⁰left axilla;
  
  F₄⁰right axilla;
  
  F₅⁰left inguina ditch;
  
  F₆⁰right nguina ditch;
  
  F₇⁰upper sector of the spinalF₈⁰middle sector of the spinalF₉⁰lower sector of the spinal;
  
  and figuring out the following 5 absolute differential values of the five symmetric pairs from the corresponding nine thermal radiation numerical values;
  
  
  Δ
  
  F₁⁰=|F₁⁰−
  
  F₂⁰|
  Δ
  
  F₂⁰=|F₃⁰−
  
  F₄⁰|
  Δ
  
  F₃⁰=|F₅⁰−
  
  F₆⁰|
  Δ
  
  F₄⁰=|F₇⁰−
  
  F₈⁰|
  Δ
  
  F₅⁰=|F₈⁰−
  
  F₉⁰|if any one among Δ
  
  F_k⁰, k=1, . . . , 5 is larger than or equal to 0.2, it then needs to further analyze and obtain, with help of TTM technology, the thermal radiation intensity of each and all parts, organs and tissues represented by the zone(s) having higher thermal radiation numerical value(s), so as to find out the parts organs and tissues having abnormal function, and to figure out the thermal radiation numerical values F_ot⁰, t=1, 2, . . . , T;
  
  T is the number of the abnormal parts, organs and tissues;
  
  (4) Letting a human body accept one or more adjustment measures;
  
  (5) In J time intervals, conducting scanning on human body surface for J records of the thermal radiation mapping with help of TTM technology, thereby obtaining J batches of the thermal radiation intensity of the respective parts
  F^j, F^j, F_z,902 ^j, I=1, . . . , L;
  
  
  Δ
  
  F₁^j, Δ
  
  F₂^j, Δ
  
  F₃^j, Δ
  
  F₄^j, Δ
  
  F₅^j;
  
  And
  F_i^j, i=1, 2, . . . , I;
  
  
  j=1, 2, . . . , J;
  
  (6) Figuring out the followings;
  
  
  Δ
  
  F_lips^j=F_lips^j−
  
  F_lips⁰;
  
  
  Δ
  
  F_navel^j=F_navel^j−
  
  F_navel⁰;
  
  
  Δ
  
  F_glandl^j=F_glandl^j−
  
  F_glandl⁰, l=1, 2, . . . , L;
  
  
  Δ
  
  (Δ
  
  F_k)^j=Δ
  
  F_k^j−
  
  Δ
  
  F_k⁰, k=1, 2, 3, 4, 5;
  
  And
  Δ
  
  F_ot^j=F_ot^j−
  
  F_ot⁰, t=1, 2, . . . , T;
  
  
  j=1, 2, . . . , J;
  
  (7) As for the newly found Q parts having abnormal function clued by obviously increased Δ
  
  (Δ
  
  F_k)^j, k=1, 2, 3, 4, 5;
  
  j=1, 2, . . . J in step (6), conducting TTM analysis and determining the followings;
  
  
  Δ
  
  F_q^j=F_q^j−
  
  F_q⁰, q=1, 2, . . . , Q;
  
  j=1, 2, . . . , J;
  
  (8) Using the differential values of thermal radiation intensity Δ
  
  F^j and Δ
  
  (Δ
  
  F)^j, j=1, . . . J, obtained in steps (6) and (7), for the purpose of determining the positive and side effect of the adjustment measures applied onto the human body as a whole, onto regional zones and individual organs, tissues, and determining the starting time point and the lasting period of the effectuation, according to the criteria below;
  
  0≦ and
  
  ≦
  
  0.1 having side effect, but not obvious >
  
  0.1 and ≦
  
  0.2, obvious side effect >
  
  0.2 and ≦
  
  0.3, strong side effect >
  
  0.3 and ≦
  
  0.4, very strong side effect ≧
  
  0.5 poison;
  
  ≦
  
  0 and ≧
  
  −
  
  0.1, positive effect, not clear <
  
  −
  
  0.1 and ≧
  
  −
  
  0.2, obvious positive effect <
  
  −
  
  0.2 and ≧
  
  −
  
  0.3, strong positive effect <
  
  −
  
  0.3 and ≧
  
  −
  
  0.4, very strong positive effect <
  
  −
  
  0.5 best effect.