DEFINITION GENERATOR -- CONTINUED
Revised Apr. 07, 2006
Third Edition
THE ALPHABET
An additional "letter" has been added to the alphabet, making 27 letters. This is "TH" which is levels 5-5. Also the order of i-j has been reversed, to j-i.
Each letter is represented by a digit pair d1-d2. The d1 body in the shape of the letter interacts with similarly shaped inverted d2 body above resulting in a cavity of shape and orientation of the letter. For example, the 6 body in the shape of the letter A interacts with similarly shaped inverted 1 body above resulting in a cavity of shape and orientation A.
Letters A to F are belt-like 6 letters because the crossbar or curved shape enables the letter to be held securely by the hand without the fingers sliding up and down. This grip enables the point of the letter to act tangentially to the environment surface in the same way that a machine belt would slide or pull.
A=6-1. Force opposing the motion of A is independent of the speed. Energy dissipated is proportional to distance tangential to the crystalline 1 body.
A moves forward strongly and sharply forward with its sharp point on the environment surface. The sharp top breaks off projecting crystalline corners. Long A and short A are similar but short A has a more rounded top.
B=6-2. The operator body functions as a tensioned 6 belt, the environment body functions as 2 liquid. The operator body 6 rises and flattens stiffly and presses up into the environment body 2 against surface tension and then flips out and rubs against the liquid. There is no opposing force until a minimum speed is reached at which turbulence breakdown occurs.
C= 6-3. The shape is specialized to encourage shallow depths of fluid 3. The cursive increases local gradient and thus breakdown and also senses depth. For short C more pressure is obtained by a rubbing action flat on the 3 environment body. Short C action lasts a shorter time because of greater pressure from a stronger portion of the operator body and the thinner fluid layer which results in faster temperature buildup and consequent faster 3 breakdown. At breakdown both long and short C release the operator body into free motion, as a consequence of the conversion of 3 into 2 which has zero viscosity. This release is an important part of the C action.
D=6-4. The flat or nearly flat top enables maximum contact area on the environment 4 surface. The operator body moves slowly forward against the elastic surface 4 of the environment body and draws it along and suddenly is released and jerks forward as 4 breaks down to 3 fluid. The D motion before breakdown tends to slow down because the increasing force requires an increase in power at constant velocity. The operator is forced to slow down in order to be able to supply the power. At breakdown the opposing force is proportional to speed.
E=6-5. The flat top is specialized for precise abrasion on a curved rigid 5 surface. The strongly tensed operator body section 6 slides a centimeter or two forward along the environment body 5 so as to break it down. The opposing breakdown force is independent of speed. The right angle is maintained during sliding. The short E involves the same configuration but with less tension, force and speed.
F=6-6. The flat top of F is specialized for precise power transfer. Input motion is tangential to the environmental surface. No breakdown occurs in the two 6 bodies. Opposing force is entirely dependent on the environmental background of the environmental 6. Breakdown may occur in the environmental background of the environmental 6 body.
For letters G to K d1-d2=5-d2 the operator performs a collision action on the 5 body which does not involve the environment. Then the action continues with a translation followed by a collision between 5 and d2.
G=5-1. The curved top is specialized for collision with a hard approximately flat crystal 1 surface buildup. The cursive is designed for destruction of particular features. Long G is a slow speed large mass action. Short G is a high velocity low mass action.
H=5-2. The operator body is thrown upward ballistically so that the top edges of it 5 gently strike the soft environment body 2 squarely, breaking it down to 1. 5 is required to have a minimum impact speed to achieve turbulence. Surface tension of 2 slowly ejects H after the H has lost its momentum.
J=5-3. The operator body moves upward causing it to strike the environment body ballistically. 5 must have a minimum impact velocity sufficient to result in breakdown of 3. The top of the J impacts the environment body 3, progressively slowing down. Temperature buildup causes the breakdown of 3 after which momentum carries the operator body forward freely. The overall action is that of a jerk.
I = 5-4. The operator body strikes the environment body ballistically. 5 must have the minimum impact velocity sufficient to result in breakdown of elastic 4. Long I impact has a separating or cutting effect. This means that the long I action can last only a short time, that required to produce a separation. Short I impact has an imprinting effect. Short I is the result of an infinite mass moving infinitely slowly but having a finite amount of kinetic energy. It compresses a limited depth of 4 with a finite pressure over an infinite amount of time. Structural and chemical changes may take place in the impacted elastic over the long length of time under pressure.
?=5-5. The operator body 5 impacts the environment body 5 in a controlled manner so as not to break down the structure of either body. The shape is specialized for displacing masses in the environment.
K=5-6. The K shape is specialized for grabbing the 6 body of the environment and producing displacement of it by collision. The flexibility of the arm helps prolong the contact so that appreciable kinetic energy can be transferred. It lengthens the action of the letter and makes the bounce less violent and gentler and more controlled thus preventing breakdown of the K.
L=4-1. The operator body flexes to a straight shape against the environment body. Crystalline matter of the environment body is broken, smoothed and made level. The crystal edges are rounded so that leveling can take place.
M=4-2. The construction of M is such as to maximize the use of 4 to produce turbulence. The mixture of stiff and flexible sections in M causes M to move so that patterns of flow are broken up, eddies are broken up into finer disturbances. M may stay in 2 with little motion as a whole, whipping back and forth causing continuous turbulence. This accounts for the hum action of the letter. 2 bulges under pressure from 4 because the volume of a liquid cannot change. There is turbulence and swirling action in 2.
N=4-3. For N the force is a function of pressure and velocity. The operator body is cupped against the environment body. The operator body is slid forward on the environment body 3 causing a temperature increase. The impedance 3 then zeroes due to breakdown of 3 to 2 and the speed increases with a sudden jerk of the operator body forward and upward. This motion ends due to elastic tension increase.
O = 4-4. For the long O the operator compresses the flexible material of the operator body so it pushes up against the environment body so as to compress it. For the short O the operator body is stretched wide so that the operator body in turn stretches the environment body wider. Breakdown of the two 4 bodies does not occur.
P = 4-5. The operator body moves upward quickly and strikes and compresses against the environment body, stops and expands, moving the environment body upward. The operator body lingers in the vicinity of the environment body before contacting it, as a precaution. The flexing is light and quick to avoid breakdown of the operator body elasticity. The operator should be well aware of the feeling of displacement of the environment body. This may require considerable displacement of the environment body.
Q=4-6. The top of the operator body 4 is flexed lightly on the environment body 6 at an angle to its surface, resulting in tangential motion of 6. The tails provide help in sensing the motion. Breakdown of the operator body must be avoided. Elastic 4 has the capability of making light or zero force contact. This enables it to avoid damage from powerful and unpredictable 6 action generated by the environment of 6.
R=3-1. The stem of the operator body is placed perpendicular to the top of the environment body 1 and touching. The prong of the operator body is a detector of motion, and not a part of direct 3-1 interaction. As the 3 slides on 1 at sufficient speed breakdown produces a random effect on resistance to operator body motion. The prong is vibrated by this random breakdown and amplifies the action.
S=3-2. The operator body 3 first slips forward quickly without resistance on the environment body liquid 2 with increasing speed until the speed is sufficient to cause 2 to break down to 1. Breakdown results in sliding resistance which is sensed by the operator. The operator terminates the action by first decreasing the speed to eliminate the turbulence resistance. He then stops the freely moving 3 body.
T=3-3. The top of the operator body 3 is slid lightly and slowly in a controlled deliberate manner on the top of the environment body 3. The operator body has a balanced contact with the environment body. This improves control. Symmetry improves uniformity of shear flow so as to avoid inadvertent extremes of flow which might cause breakdown. The T action does not include the breaking of contact between 3 and 3. This is transition action, and involves a slight breakdown of 3.
U = 3-4. The U shape, consisting of viscous matter 3, will collapse on its right side but not on the left because the right side is thin. As the U moves forward oriented vertically it causes increasing elastic 4 flexing of the environment body. This causes it to start moving at an angle to the vertical. The stability and gripping power of 3 on 4 increases. U is controlled carefully to avoid breakdown of 3.
V=3-5. The operator fluid body 3 touches and accelerates the environment body mass 5 to the right. The environment body does not change shape but merely moves to the right and may veer upward. The operator body undergoes shear with resulting change of shape in the forward direction. V is controlled carefully to avoid breakdown of the 3 material.
W=3-6. The W is shown as two overlapping V shapes. This is intended to represent two V shaped fluid 3 bodies aligned perpendicular to the page but at an acute angle to each other, and moving to the right and toward each other in unison. They act on similar shaped and arranged 6 bodies, above and inverted, which are really considered as a single 6 body or belt. The environment body or belt is dragged to the right with the operator bodies moving in toward each other. The operator bodies act on the environment body the same as two V bodies (see description of V action above).
X=2-1. The operator body presses the rear prong of the crystalline body backward followed by a forward pressing on the front prong of the crystalline environment body. The result is a breaking apart of the crystalline X shape.
Y = 2-2. For the long vowel Y the operator body is initially spherical but becomes Y shaped during contact. It flattens first. The operator tends to go toward the environment so that most of the 2 tends to remain in the backward branch. Care is taken that turbulent breakdown does not occur. During action, or in position for it, the operator body can be freely moved to neighboring positions in all directions.
The vowel short Y is performed by careful balancing of the operator body on the environment body. There is a constant balancing motion required and this makes up the action of the Y. This corresponds to keeping one liquid sphere pressed on another sphere without flattening. If there is no breakdown the contact is frictionless so that any non perpendicular force will cause inertial acceleration forward. The velocity and pressure must be kept low enough that breakdown does not occur.
For the consonant Y the operator body is thrust up very slowly and carefully with increasing force perpendicular to the surface of the environment body. The operator body is allowed to shift to one side in a "yaw" effect.
Z=1-1. The operator body 1 top section has a rigid perfectly flat shape and slides without resistance on the top of the environment body 1. The action is performed with care and gentleness so that there is no breakdown. The action is pure motion since no forces are present.
AN EXAMPLE WORD:
RAKE. The environment body 1 consists of a layer of leaves that have fallen on a lawn. The specialized rake is better composed of wood rather than metal. The leaves have crimped down edges which gives them an approximate R shape. The upper side of a leaf will correspond to the top of an R. At the beginning of the raking motion the rake is at a low angle with the ground so that the bent prong functions as the top of the R with respect to the leaves. The action is approximately like the tops of two R's being rubbed together. The result of the action is an R shaped cavity in the leaf layer with the bottom of the R shape at the surface of the layer. Vibration of the prongs helps to find crevices between leaves. The R action results in penetration of the prong tips to the grass. The prongs act as a shape A in contact with the edges of the leaves 1 having less definite shape A. The results of leaf removal action are "cavities" in the lawn fallen leaf structure. A K shaped accumulation 6 of leaves is formed ahead of the rake. The bent prong tips and crossbar of the rake function as a K shape. This shape brings out the 6 aspect of the raked leaves, rather than the leaves having so much 6 aspect themselves. Momentum 5 of the rake acts on the raked leaf surface 6 so as to move it upward forming a pile. Then the rake prongs 6 act as a shape E to smooth the surface 5 of the pile, removing projecting leaves which might blow away.
Copyright 2006. Norman H. Smith.
All rights reserved.
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