System and method for relating electromagnetic waves to sound waves
DCFirst Claim
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1. A method for relating electromagnetic waves to harmonic sound waves, comprising the steps of:
- assigning one fundamental color of a color spectrum of twelve analogous colors to one of twelve fundamental tones of a musical 5th relationship, wherein the tones are represented by notes; and
consecutively associating the remaining analogous colors to the tones.
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Abstract
A system for relating electromagnetic waves to harmonic sound waves that includes a memory with logic, and a processor configured with the logic to assign one fundamental color of a color spectrum of twelve analogous colors to one of twelve fundamental tones of a musical 5th relationship, wherein the tones are represented by notes, wherein the processor is further configured with the logic to consecutively associate the remaining analogous colors to the tones.
118 Citations
104 Claims
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1. A method for relating electromagnetic waves to harmonic sound waves, comprising the steps of:
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assigning one fundamental color of a color spectrum of twelve analogous colors to one of twelve fundamental tones of a musical 5th relationship, wherein the tones are represented by notes; and
consecutively associating the remaining analogous colors to the tones. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71)
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2. The method of claim 1, wherein relating electromagnetic waves to harmonic sounds waves includes the step of relating the properties of electromagnetic waves to harmonic sound waves by relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave.
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3. The method of claim 2, wherein relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave, includes the steps of:
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assigning a fundamental frequency and its consecutive octaves to consecutive nodes of the harmonic energy wave;
assigning a third harmonic frequency and its consecutive octaves to consecutive anti-nodes of the harmonic energy wave;
assigning a fifth harmonic frequency and its consecutive octaves to consecutive maximum amplitudes of first-half wave cycles of the harmonic energy wave;
assigning a seventh harmonic frequency and its consecutive octaves to consecutive maximum amplitudes of second half wave cycles of the harmonic energy wave; and
assigning each newly defined harmonic to equidistant positions between previously defined harmonic energy wave positions.
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4. The method of claim 3, wherein the step of relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave, including the node, anti-node, and amplitude positions, further comprises the step of relating the color and tone of each harmonic wave position to at least one of individual harmonic energy waves, energy levels, and measurements.
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5. The method of claim 1, further comprising the step of positioning twelve equidistant points on a circle representing twelve equal angle divisions of a circle, twelve directional vectors, twelve analogous colors and twelve equal tempered musical 5ths based on roots of 2.
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6. The method of claim 5, wherein the step of positioning twelve equidistant points include the steps:
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starting an overtone harmonic series and an undertone harmonic series at a defined position;
starting a second overtone harmonic series and a second undertone harmonic series at a second position related to the first position by the square root of 2;
tempering the differences generated between the overtone and undertone harmonic positions resulting in new positions based on roots of 2;
repeating the steps of starting, starting, and tempering until all 12 equidistant points on a circle defined by roots of 2 are generated.
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7. The method of claim 1, further comprising the step of defining the color of frequency by defining the color of a chromatic frequency cycle.
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8. The method of claim 7, wherein the step of defining the color of frequency includes the steps of:
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assigning an equidistant analogous color pattern between consecutive chromatic frequency positions which represents the anologous color pattern, wherein the consecutive chromatic frequency positions are microtones;
defining the microtones as being separated by multiples of 2^( 1/84), wherein the separation of 2^( 1/84) is approximately 14.28 cents;
locating the relative position of the frequency to the at least one of one of the twelve equidistant points on the chromatic frequency circle and the one of six equidistant microtone points between consecutive equidistant chromatic points on the chromatic frequency circle;
locating at least one of the color, chroma, and gray of the relative position on the chromatic frequency circle; and
assigning the at least one of the located color, chroma, and gray to the frequency.
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9. The method of claim 1, further comprising the step of relating the properties of electromagnetic waves and harmonic sound waves by relating the electromagnetic properties of positive and negative charge to the properties of a harmonic energy wave, wherein the flow of energy of a reference harmonic energy level, having an overtone energy orientation, is related to the energy flow and type properties of one of a positive and negative electromagnetic charge, and by default assigning the same-reference undertone harmonic energy level and orientation to the remaining electromagnetic charge property.
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10. The method of claim 9, wherein the step of relating the electromagnetic properties of positive and negative charge to the energy level and the harmonic orientation of the harmonic energy wave further comprises the step of assigning a reference electromagnetic charge property to represent the harmonic energy orientation of a first-half harmonic wave cycle and assigning its opposition electromagnetic charge property to represent the harmonic energy orientation of a second-half harmonic wave cycle, wherein the step of assigning the positive and the negative electromagnetic charge properties to the first and second half harmonic energy wave cycles includes the steps of:
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assigning the reference electromagnetic charge property to the first-half cycle of an overtone harmonic energy wave located at one of defined equidistant positions on a color circle;
assigning an opposition electromagnetic charge property to the second-half cycle of the chosen overtone harmonic energy wave;
assigning the opposition electromagnetic charge property to the first-half cycle of an undertone harmonic energy wave beginning at the same frequency; and
assigning the reference electromagnetic charge property to the second-half cycle of the undertone harmonic energy wave.
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11. The method of claim 1, further comprising the step of bonding overtone and undertone harmonic energy wave half-wave and quarter-wave cycles to form a current loop having at least one of a neutral charge, a charge as defined by the position of the current loop within a current loop wave within an overtone defined wave structure, and a charge as defined by the position of the current loop within a current loop wave within an undertone defined wave structure.
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12. The method of claim 11, further comprising the step of forming a current loop wave.
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13. The method of claim 12, wherein the step of forming a current loop wave includes the steps of:
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assigning at least one of a prime spin and a retrograde spin to two current loops;
assigning a first-half cycle to the first current loop and a second-half cycle to the second current loop; and
assigning the order of the two current loops in order to determine inversion and retrograde-inversion spins.
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14. The method of claim 13, further comprising the step of defining the color of the current loops by the square of the harmonic series 12, 22, 32, to infinity based on the total harmonic distance between the overtone and the undertone harmonic positions.
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15. The method of claims 1, further comprising the step of relating the properties of electromagnetic waves and harmonic sound waves by bonding and relating the energy states, properties, and order of the harmonic energy wave with the electromagnetic wave properties of a harmonic current loop and its system of order and organization, represented by measurements and frequencies.
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16. The method of claim 15, wherein the step of bonding and relating the energy states, properties, and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization, represented by measurements and frequencies, includes the energy organization steps of:
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bonding a harmonic energy wave node of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies;
bonding a harmonic energy wave anti-node of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies; and
bonding a harmonic energy wave maximum amplitude of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies.
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17. The method of claim 16, wherein the step of relating the energy states, properties, and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system or order and organization, represented by measurements and frequencies, is further comprised of the step of forming a vector wave, wherein the electromagnetic properties of the current loops within the vector waves are related to the properties of the harmonic energy wave.
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18. The method of claim 17, wherein the step of forming a vector wave to relate the properties of electromagnetic current loop with the properties of harmonic energy wave includes the steps of:
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forming a charged first octave harmonic energy wave of a current loop at a specified energy level and assigning it a specific charge property defining energy flow and type;
bonding an octave harmonic energy wave of a current loop using a node-to-node bond; and
assigning a neutral charge property, exhibiting no external energy flow and type, to a third harmonic position of a second octave harmonic energy wave of a current loop, wherein the vector wave is represented by at least one of integer numbers, inversion of the integer numbers or fractions, and octaves.
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19. The method of claim 17, wherein the step of relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization further comprises forming a vector set wave that includes three vector waves bonded with anti-node-to-node bonds, wherein the vector set defines and relates the properties of the electromagnetic waves and current loops with properties of the harmonic sound waves and harmonic energy waves represented within it.
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20. The method of claim 19, wherein the step of forming a vector set wave includes the steps of:
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changing the third harmonic position of the first vector wave from an electromagnetically neutral charged to an electromagnetically charged position;
using the electromagnetically charged third harmonic position of the first vector wave as the starting position of the second vector wave; and
repeat the steps of changing and using for bonding a third vector wave to the second vector wave, wherein the total vector set is represented by at least one of the numbers 1, 2, 3, 6, 9, 18, 27 and the corresponding octaves, and the inversions of 1, 2, 3, 6 9, 18, 27 and the corresponding octaves.
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21. The method of claim 20, wherein the step of bonding a third vector wave to form a vector set wave includes the step of changing the electromagnetic charge properties of the third harmonic of the third vector set from a neutral to one of a positive and negative electrical charge.
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22. The method of claim 19, wherein the step of relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization further comprises the step of forming a 3-vector set wave that includes three vector waves bonded with anti-node-to-node bonds, wherein the 3-vector set wave defines and relates the 12 stable electromagnetic energy positions to 12 unique colors, musical 5ths, numbers, frequencies, and measurements.
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23. The method of claim 22, wherein the step of forming a 3-vector set wave includes the steps of:
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bonding the second vector set wave to the first vector set wave using an amplitude to node bond, wherein the first position of the second vector set bonds to the amplitude represented by harmonic 5 and the corresponding octaves of the first vector set wave, wherein the first position of the second vector set wave is defined by the number 5 and the corresponding octaves relative to the first vector set wave;
repeating the step of bonding for the third vector set wave to the second vector set wave, wherein the first position of the third vector set is defined by the number 5 and its octaves relative to the second vector set wave, and by the number 25 and its octaves relative to the first vector set wave.
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24. The method of claim 22, wherein the step of relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization further comprises the step of bonding an overtone 3-vector set wave to an undertone 3-vector set wave, wherein the relationship between the first position of the overtone 3-vector set wave and the first position of the undertone 3-vector set wave are related by the square root of 2 and the corresponding octaves, wherein the resulting energy structure relates the overtone associated properties of electromagnetic waves and harmonic energy waves with the undertone associated properties of electromagnetic waves and harmonic energy waves.
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25. The method of claim 24, wherein the relationship between the first position of the overtone 3-vector set wave and the first position of the undertone 3-vector set wave are related by the number 729 and the corresponding octaves.
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26. The method of claim 24, wherein the step of bonding an overtone 3-vector set wave to an undertone 3-vector set wave includes the steps of at least partly using charged positions and bonding two 3-vector set waves through amplitude-to-node bonds with the first position of the second 3-vector set wave relating to the first position of the first 3-vector set wave by 225 and the corresponding octaves.
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27. The method of claim 24, wherein the step of bonding an overtone 3-vector set wave to an undertone 3-vector set wave includes the step of at least partly using neutral positions and bonding two 3-vector set waves through amplitude-to-node bonds with the first position of the second 3-vector set wave relating to the first position of the first 3-vector set wave by 225 and the corresponding octaves.
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28. The method of claim 4, wherein the step of bonding an overtone 3-vector set wave to an undertone 3-vector set wave includes the steps of at least partly using charged positions and neutral positions and bonding two 3-vector set waves through amplitude-to-node bonds with the first position of the second 3-vector set wave relating to the first position of the first 3-vector set wave by 225 and the corresponding octaves.
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29. The method of claims 2, wherein the step of relating the properties of electromagnetic waves to harmonic sound waves by relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave includes a relation simplification step of applying a constantly changing time reference to at least one of a harmonic energy wave and the representatives of the harmonic energy wave resulting in a representation of a harmonic energy sine wave.
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30. The method of claim 1, further comprising the step of describing mixtures of frequencies, harmonic energy waves, current loop waves, energy levels, and measurements as mixtures of at least one of color, chroma, and gray.
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31. The method of claim 1, further comprising the step of displaying on a medium consecutive chromatic colors to define consecutive chromatic notes in a twelve note based musical notation system that comprises a ledger line and five staff lines and spaces between the lines and the ledger line and the lines, wherein the ledger lines are separated by octaves, wherein the twelve fundamental colors are representative of at least one of selected colors, chromas, and grays, wherein the consecutive chromatic notes are applied consecutively to consecutive lines and spaces.
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32. The method of claim 31, further comprising the step of displaying on the medium one-word color names for notes on the staff line and the ledger line, and two-word color names for the spaces between the staff lines and the ledger lines, wherein one-word color names are yellow, green, blue, violet, red, and orange, and two-word color names are yellow-green, blue-green, blue-violet, red-violet, red-orange, and yellow-orange, wherein the defined one-word and two-word color names are representative of at least one of selected colors, chromas, and grays.
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33. The method of claim 31, further comprising the step of displaying on the medium two-word color names for notes on the staff line and the ledger line, and one-word color names for the spaces between the staff lines and the ledger lines, wherein one-word color names are yellow, green, blue, violet, red, and orange, and two-word color names are yellow-green, blue-green, blue-violet, red-violet, red-orange, and yellow-orange, wherein the defined one-word and two-word color names are representative of at least one of selected colors, chromas, and grays.
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34. The method of claim 31, wherein the twelve chromatic colors are repeated for every octave.
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35. The method of claim 31, wherein the space between two lines and the space between a line and a ledger line are further divided by six lines generating a total of seven lines and spaces from one chromatic tone to the next, wherein the analogous microtone colors are applied to the additional consecutive lines and spaces between chromatic tones, wherein the ledger line is represented every fourteen microtone tones or two chromatic tones.
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36. The method of claim 31, further comprising the step of connecting tones in a vertical and horizontal placement by a line representing a harmonic energy wave, further comprising the step of passing a straight line through node and anti-node positions of the represented harmonic energy wave.
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37. The method of claim 36, wherein a line representing at least one of a first half wave cycle and a second half wave cycle connects consecutive harmonic wave designations.
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38. The method of claim 37, further comprising representing the first-half wave cycle as a strong beat and the second-half wave cycle as a weak beat.
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39. The method of claims 38, further comprising the step of connecting two same type beats using a connecting line.
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40. The method of claims 39, further comprising the step of describing an amplitude to node connection between the harmonic wave designations by a connecting line.
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41. The method of claims 40, further comprising the step of representing the extension of a note through multiple harmonic wave designations by at least one of a bar of the same color and a description stretching the length of the extension.
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42. The method of claim 41, further comprising the step of representing a perceptual wave by diagonal lines.
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43. The method of claim 42, farther comprising the step of representing the connection between perceptual wave nodes and harmonic wave nodes or perceptual wave amplitudes and harmonic wave amplitudes by a gray connecting bar.
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44. The method of claim 31, further comprising the step of relating the properties of electromagnetic waves and harmonic sound waves by relating the measurable volume properties of an harmonic sound wave to the pitch properties of an harmonic sound wave and the properties of an electromagnetic wave and displaying on a medium consecutive chromatic colors to define consecutive chromatic volume notes in a twelve volume note based musical notation system that comprises a ledger line and five staff lines and spaces between the lines and the ledger line and the lines, wherein the ledger lines are separated by octaves, wherein the twelve fundamental colors are representative of at least one of selected colors, chromas, and grays, wherein the consecutive chromatic volume notes are applied consecutively to consecutive lines and spaces.
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45. The method of claim 44, further comprising the step of describing the volume levels of measurable volume properties by chromatic intensities based on roots of 2, further comprising the step of grouping twelve chromatic volumes by octaves.
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46. The method of claim 31, further comprising the step of relating the properties of electromagnetic waves and harmonic sound waves by relating the measurable rhythm properties of an harmonic sound wave to the pitch properties of an harmonic sound wave and the properties of an electromagnetic wave and displaying on a medium consecutive chromatic colors to define consecutive chromatic rhythm notes in a twelve rhythm note based musical notation system that comprises a ledger line and five staff lines and spaces between the lines and the ledger line and the lines, wherein the ledger lines are separated by octaves, wherein the twelve fundamental colors are representative of at least one of selected colors, chromas, and grays, wherein the consecutive chromatic rhythm notes are applied consecutively to consecutive lines and spaces.
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47. The method of claim 46, further comprising the step of relating the rhythm properties of harmonic sound waves with the pitch properties of harmonic sound waves and harmonic energy waves and electromagnetic waves by connecting rhythm positions of a particular rhythm device with a line representing a rhythm harmonic energy wave or a rhythm sine wave.
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48. The method of claim 31, further comprising the step of dividing the staff by units of time representing the length of a harmonic octave in at least one of a given time, given times, and constantly changing time.
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49. The method of claim 48, further comprising the step of describing the start of the unit of time with a vertical line on the staff and the end of the unit of time with a vertical line on the staff, wherein the space in between the defined start and end is absolutely defined by at least one of time, times, and constantly changing times applied to the unit of time.
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50. The method of claim 49, further comprising the step of placing a tempo above the unit of time as at least one of the number of beats per minute, a fraction of a reference tempo, and a multiple of the reference tempo.
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51. The method of claim 50, further comprising the step of describing a continuously changing tempo between two points with a wavy line connecting two defined tempos.
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52. The method of claim 48, further comprising the step of dividing the unit of time into twelve hundred equal time units called ticks.
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53. The method of claim 48, further comprising the step of dividing the unit of time by harmonic and other time divisions represented by notes, wherein a stem of the note absolutely marks the starting position of the represented time value within the unit of time.
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54. The method of claim 53, further comprising the step of describing the division of the unit of time into three equal units by at least one of a triangle note head and a representative number.
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55. The method of claim 53, further comprising the step of describing the division of the unit of time into four equal units by at least one of a square note head and a representative number.
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56. The method of claim 53, further comprising the step of describing the division of the unit of time into five equal units by at least one of a pentagram note head and a representative number.
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57. The method of claim 53, further comprising the step of describing the division of the unit of time by seven equal units by at least one of a seven point star and a representative number.
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58. The method of claim 53, further comprising the step of describing the division of the unit of time by twelve equal units by at least one of a circle and a representative number.
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59. The method of claim 53, further comprising the step of describing with a note head the division of the unit of time into an assignable number of equal divisions, wherein the assignable number is placed above the note.
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60. The method of claim 53, further comprising the step of describing with a note head the division of the unit of time into an assignable number of equal divisions, wherein the assignable number replaces the note.
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61. The method of claim 60, further comprising the step of describing the division of the fundamental note time value by a flag attached to the stem of the note, wherein a line flag represents the zero power of 2, and each additional flag represents an additional power of two, wherein a box flag with a number defines the number of flags, wherein a number placed above the flags changes the fundamental division number of 2, wherein the highest represented flag number is the divisor of the fundamental note time value.
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62. The method of claim 61, further comprising the step of multiplying the fundamental note time value and flag alterations by placing at least one of the multiplying number and the fraction next to the note head.
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63. The method of claim 62, further comprising the step of placing dots next to the note head, wherein each dot represents a value in a series, wherein the base value of the series is the fundamental note value after flag and multiplier operations, wherein the fundamental dot division is 2, wherein the fundamental dot division is alterable by placing at least one of a number and fraction next to the dot, wherein the number of dots defines the number of positions in the series, wherein the number of dots can be represented by a single dot followed by a number, wherein a dot representing a number other than 2 is placed inside parentheses with the altering number followed by a number representing the total number of dots, wherein the time value of the note is the sum of the value of each represented dot.
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64. The method of claim 63, further comprising the step of placing at least one of a number and fraction below the flag representing a time value to be added to the note after all other time manipulations are accounted for.
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65. The method of claim 64, further comprising the step of using a wavy flag attached to a particular note value to describe a time value which is an approximation of the note value to which the flag is attached, including the implication that the flags represent normal flags and are included in the value of the approximated note.
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66. The method of claim 65, further comprising the step of using a geometric shape to represent note time values which extend beyond the unit of time, wherein the end of the note extension beyond a unit of time or units of time is represented by half of the defined geometric shape attached to a vertical line, wherein the line marks the absolute position with the unit of time which defines the end of the note time value.
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67. The method of claim 66, further comprising the step of grouping notes by at least one of a mathematical series and equation, wherein the step of grouping includes:
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marking the positions of at least one of the series and the defined positions of the equation by vertical lines;
joining the vertical lines with at least one of an overarching and underarching curved line;
placing the notes which begin at positions defined by the series or equation on the vertical lines;
describing the series and equation and the starting and ending points within the series and the equation; and
placing at least one of the description of the series and the equation and a reference of the series and the equation above the joining line.
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68. The method of claim 67, further comprising the step of describing a group of consecutive notes, each of which represents points along a complex, constantly changing time value, with a black connecting bar, wherein a description of at least one of the note time values and a reference of the note time values is placed near the black connecting bar.
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69. The method of claim 31, further comprising the step of forming two spirals, wherein the first spiral consists of secondary color relationships of one-word color names and the second spiral consists of secondary color relationships of two-word color names, wherein the two spirals are merged to form an analogous color pattern with octaves found along radial lines, wherein the radial lines alternated between black and white patterns with an optional gray section representing the lines, ledger lines, and spaces of the staff, wherein the colors define at least one of tones, microtones, any defined group of colors, chromas, gray, and deviations from tones.
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70. The method of claim 69, further comprising the step of representing the spirals in a linear format, wherein multiple two-word color lines and one-word color lines of undefined length are vertically arrayed with vertical positions representing consecutive octaves.
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71. The method of claim 1, further comprising the step of representing the consecutive analogous colors as consecutive note positions on a musical instrument.
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2. The method of claim 1, wherein relating electromagnetic waves to harmonic sounds waves includes the step of relating the properties of electromagnetic waves to harmonic sound waves by relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave.
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72. A system for relating electromagnetic waves to harmonic sound waves, comprising:
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means for assigning one fundamental color of a color spectrum of twelve analogous colors to one of twelve fundamental tones of a musical 5th relationship, wherein the tones are represented by notes; and
means for consecutively associating the remaining analogous colors to the tones. - View Dependent Claims (73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86)
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73. The system of claim 72, further comprising means for relating the properties of electromagnetic waves to harmonic sound waves by relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave.
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74. The system of claim 72, further comprising means for positioning twelve equidistant points on a circle representing twelve equal angle divisions of a circle, twelve directional vectors, twelve analogous colors and twelve equal tempered musical 5ths based on roots of 2.
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75. The system of claim 72, further comprising means for defining the color of frequency by defining the color of a chromatic frequency circle.
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76. The system of claim 72, further comprising means for relating the properties of electromagnetic waves and harmonic sound waves including means for relating the electromagnetic properties of positive and negative charge to the properties of an harmonic energy wave, wherein the means for relating charge properties includes means for relating the flow of energy of a reference harmonic energy level, having an overtone energy orientation to the energy flow and type properties of one of a positive and negative electromagnetic charge, and means for assigning by default the same-reference undertone harmonic energy level and orientation to the remaining electromagnetic charge property.
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77. The system of claim 76, further comprising means for relating the electromagnetic properties of positive and negative charge to the energy level and harmonic orientation of an harmonic energy wave by the means for assigning the reference chosen electromagnetic charge property to represent the harmonic energy orientation of the first-half harmonic wave cycle and the means for assigning its opposition electromagnetic charge property to represent the harmonic energy orientation of the second-half harmonic wave cycle, wherein the means for assigning the positive and the negative electromagnetic charge properties to first and second half harmonic energy wave cycles includes:
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means for assigning a reference electromagnetic charge property to the first-half cycle of an overtone harmonic energy wave located at one of defined equidistant positions on a color circle;
means for assigning an opposition electromagnetic charge property to the second-half cycle of the chosen overtone harmonic energy wave;
means for assigning the opposition electromagnetic charge property to the first-half cycle of an undertone harmonic energy wave beginning at the same frequency; and
means for assigning the reference electromagnetic charge property to the second-half cycle of the undertone harmonic energy wave.
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78. The system of claim 77, further comprising means for bonding overtone and undertone harmonic energy wave half-wave and quarter-wave cycles to form a current loop having at least one of neutral charge, a charge as defined by the position of the current loop within a current loop wave within an overtone defined wave structure, and a charge as defined by the position of the current loop within a current loop wave within an undertone defined wave structure.
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79. The system of claim 78, further comprising means for forming a current loop wave, including:
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means for assigning at least one of a prime spin and a retrograde spin to two current loops;
means for assigning a first-half cycle to the first current loop and a second-half cycle to the second current loop; and
means for assigning the order of the two current loops in order to determine inversion and retrograde-inversion spins.
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80. The system of claim 79, further comprising means for relating the properties of electromagnetic waves and sound waves within the current loop, the means for relating including means for defining the color of the current loops by the square of the harmonic series 12, 22, 32, to infinity based on the total harmonic distance between the overtone and the undertone harmonic positions.
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81. The system of claim 72, further comprising means for relating the properties of electromagnetic waves and harmonic sound waves by the means for bonding and the means for relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization, represented by measurements and frequencies, including:
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means for bonding a harmonic energy wave node of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies;
means for bonding a harmonic energy wave anti-node of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies; and
means for bonding a harmonic energy wave maximum amplitude of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies.
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82. The system of claim 81, further comprising means for relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization, represented by measurements and frequencies, by the means for forming a vector wave, wherein the electromagnetic properties of the current loops within the vector wave are related to the properties of the harmonic energy wave, wherein the means for forming a vector wave includes:
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means for forming a first octave harmonic energy wave of a current loop at a specified energy level and means for assigning it a specific charge property defining energy flow and type;
means for bonding an octave harmonic energy wave of a current loop using a node-to-node bond; and
means for assigning a neutral charge property, exhibiting no external energy flow and type, to the third harmonic energy position of a second octave harmonic energy wave of a current loop, wherein the vector wave is represented by at least one of integer numbers, inversion of the integer numbers or fractions, and octaves.
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83. The system of claim 82, further comprising means for relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization by the means for forming a vector set wave that includes three vector waves bonded with anti-node-to-node bonds, wherein the vector set defines and relates the properties of the electromagnetic waves and current loops with properties of the harmonic sound waves and harmonic energy waves represented within it, wherein the means for forming a vector set includes:
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means for changing the third harmonic position of the first vector wave from an electromagnetically neutral charged to an electromagnetically charged position;
means for using the electromagnetically charged third harmonic position of the first vector wave as the starting position of the second vector wave;
means for repeating the steps of changing and using for bonding a third vector wave to the second vector wave, wherein the total vector set is represented by at least one of the numbers 1, 2, 3, 6, 9, 18, 27 and the corresponding octaves, and the inversions of 1, 2, 3, 6, 9, 18, 27 and the corresponding octaves; and
means for changing the electromagnetic charge properties of the third harmonic of the third vector set from neutral to one of positive or negative electrical charge.
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84. The system of claim 83, further comprising means for relating the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization by the means for forming a 3-vector set wave that includes three vector waves bonded with anti-node-to-node bonds, wherein the 3-vector set wave defines and relates the 12 stable electromagnetic energy positions to 12 unique colors, musical 5ths, numbers, frequencies, and measurements, wherein the means for forming a 3-vector set wave includes:
means for bonding the second vector set wave to the first vector set wave using an amplitude to node bond, wherein the first position of the second vector set bonds to the amplitude represented by harmonic 5 and the corresponding octaves of the first vector set wave, wherein the first position of the second vector set wave is defined by the number 5 and the corresponding octaves relative to the first vector set wave; and
means for repeating the step of bonding for the third vector set wave to the second vector set wave, wherein the first position of the third vector set is defined by the number 5 and its octaves relative to the second vector set wave, and by the number 25 and its octaves relative to the first vector set wave.
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85. The system of claim 73, further comprising means for relating the properties of electromagnetic waves to harmonic sound waves by the means for relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of an harmonic energy wave, wherein the means for relating includes means for applying a constantly changing time reference to at least one of a harmonic energy wave and the representatives of the harmonic energy wave which results in a representation of a harmonic energy sine wave.
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86. The system of claim 72, further comprising means for relating the properties of electromagnetic waves and sound waves by means for describing mixtures of frequencies, harmonic energy waves, current loop waves, energy levels, and measurements as mixtures of at least one of color, chroma, and gray.
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73. The system of claim 72, further comprising means for relating the properties of electromagnetic waves to harmonic sound waves by relating the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave.
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87. A system for relating electromagnetic waves to harmonic sound waves, comprising:
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a memory with logic; and
a processor configured with the logic to assign one fundamental color of a color spectrum of twelve analogous colors to one of twelve fundamental tones of a musical 5th relationship, wherein the tones are represented by notes, wherein the processor is further configured with the logic to consecutively associate the remaining analogous colors to the tones. - View Dependent Claims (88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101)
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88. The system of claim 87, wherein the processor is further configured with the logic to relate the properties of electromagnetic waves to harmonic sound waves by being further configured to relate the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave.
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89. The system of claim 87, wherein the processor is further configured with the logic to position twelve equidistant points on a circle representing twelve equal angle divisions of a circle, twelve directional vectors, twelve analogous colors and twelve equal tempered musical 5ths based on roots of 2.
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90. The system of claim 88, wherein the processor is further configured with the logic to relate a color to a sound frequency and associated numeric descriptions by being further configured with the logic relating the frequencies of a chromatic sound frequency circle with colors as defined by the relationship between a 12 analogous color circle and the musical circle of 5ths, and produce in a colorized chromatic frequency circle, the processor configured with the logic to:
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assign an equidistant analogous color pattern between consecutive chromatic frequency positions which represents the analogous color pattern, wherein the consecutive chromatic frequency positions are microtones;
define the microtones as being separated by multiples of 2^( 1/84), wherein the separation of 2^( 1/84) is approximately 14.28 cents;
locate the relative position of the frequency to the at least one of one of the twelve equidistant points on the chromatic frequency circle and the one of six equidistant microtone points between consecutive equidistant chromatic points on the chromatic frequency circle;
locate at least one of the color, chroma, and gray of the relative position on the chromatic frequency circle; and
assign the at least one of the located color, chroma, and gray to the frequency.
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91. The system of claim 87, wherein the processor is further configured with the logic to relate the directional properties of overtone and undertone harmonic orientations to the directional properties of positive and negative charge, wherein the processor is further configured with the logic to relate the properties of electromagnetic waves and harmonic sound waves by relating the electromagnetic properties of positive and negative charge to the properties of an harmonic energy wave, wherein the flow of energy of a reference harmonic energy level, having an overtone energy orientation, is related to the energy flow and type properties of one of a positive and negative electromagnetic charge, wherein the processor is further configured with the logic to assign by default the same-reference undertone harmonic energy level and orientation to the remaining electromagnetic charge property.
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92. The system of claim 91, wherein the processor is further configured with the logic to assign the directional properties of positive and negative charge to directional properties of first-half and second-half cycles of a harmonic energy wave, wherein the processor is further configured with the logic to relate the positive and negative charge properties of electromagnetic waves to the overtone and undertone properties of harmonic sound waves by being further configured to assign the reference chosen electromagnetic charge property to represent the harmonic energy orientation of the first-half harmonic wave cycle and by being further configured to assign its opposition electromagnetic charge property to represent the harmonic energy orientation of the second-half harmonic wave cycle, the processor configured with the logic to:
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assign a reference electromagnetic charge property to the first-half cycle of an overtone harmonic energy wave located at one of defined equidistant positions on a color circle;
assign an opposition electromagnetic charge property to the second-half cycle of the chosen overtone harmonic energy wave;
assign the opposition electromagnetic charge property to the first-half cycle of an undertone harmonic energy wave beginning at the same frequency; and
assign the reference electromagnetic charge property to the second-half cycle of the undertone harmonic energy wave.
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93. The system of claim 87, wherein the processor is further configured with the logic to bond overtone and undertone harmonic energy wave half-wave and quarter-wave cycles to form a current loop, wherein the processor is further configured with the logic to assign the electromagnetic properties of neutral, positive, and negative charge to the half-wave cycles, quarter wave cycles, and bonded current loops, and assign a dependency to the associated electromagnetic properties of neutral, positive and negative charge based upon the position of the current loop within an overtone or undertone defined wave structure.
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94. The system of claim 93, wherein the processor is further configured with the logic to form a current loop wave, the processor configured with the logic to:
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assign at least one of a prime spin and a retrograde spin to two current loops;
assign a first-half cycle to the first current loop and a second-half cycle to the second current loop; and
assign the order of the two current loops in order to determine inversion and retrograde-inversion spins.
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95. The system of claim 94, wherein the processor is further configured with the logic to relate the chromatic properties of color to the analogous color properties of the current loops by the square of the harmonic series 12, 22, 32, to infinity based on the total harmonic distance between the overtone and the undertone harmonic positions.
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96. The system of claim 87, wherein the processor is further configured with the logic to further relate the properties of electromagnetic waves and harmonic sound waves by bonding and relating the energy states, properties, and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization, wherein the processor is further configured with the logic to represent the positions and properties of the harmonic energy wave and the harmonic current loop by measurements and frequencies, the processor configured with the logic to:
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bond a harmonic energy wave node of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies;
bond a harmonic energy wave anti-node of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies; and
bond a harmonic energy wave maximum amplitude of a current loop to a harmonic energy wave node of a current loop, wherein said bonding points are represented by measurements and frequencies.
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97. The system of claim 96, wherein the processor is further configured with the logic to further relate the energy states, properties, and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization, represented by measurements and frequencies, wherein the processor is further configured with the logic to form a vector wave and relate the electromagnetic properties of the current loops within the vector wave to the properties of the harmonic energy wave, the processor configured with the logic to:
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form a first octave harmonic energy wave of a current loop at a specified energy level and assigning it a specific charge property defining energy flow and type;
bond an octave harmonic energy wave of a current loop using a node-to-node bond; and
assigning a neutral charge property, exhibiting no external energy flow and type, to the third harmonic energy position of a second octave harmonic energy wave of a current loop; and
represent the vector wave is by at least one of integer numbers, inversion of the integer numbers or fractions, and octaves.
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98. The system of claim 97, wherein the processor is further configured with the logic to relate the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization by forming a vector set wave that includes three vector waves bonded with anti-node-to-node bonds, wherein the processor is further configured with the logic to define and relate the properties of the electromagnetic waves and current loops with properties of the harmonic sound waves and harmonic energy waves as defined within the confines of the vector set, wherein the processor configured with the logic to:
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change the third harmonic position of the first vector wave from an electromagnetically neutral charged to an electromagnetically charged position;
use the electromagnetically charged third harmonic position of the first vector wave as the starting position of the second vector wave;
repeat the steps of changing and using for bonding a third vector wave to the second vector wave, wherein the total vector set is represented by at least one of the numbers 1, 2, 3, 6, 9, 18, 27 and the corresponding octaves, and the inversions of 1, 2, 3, 6, 9, 18, 27 and the corresponding octaves; and
change the electromagnetic charge properties of the third harmonic of the third vector set from neutral to one of a positive or negative electrical charge.
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99. The system of claim 87, wherein the processor is further configured with the logic to further relate the energy states, properties and order of the harmonic energy wave with the electromagnetic wave properties of the harmonic current loop and its system of order and organization by forming a 3-vector set wave that includes three vector waves bonded with anti-node-to-node bonds, wherein the processor is further configured with the logic to relate the 12 stable electromagnetic energy positions of the 3-vector set wave to 12 unique colors, musical 5ths, numbers, frequencies, and measurements, the processor configured with the logic to:
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bond the second vector set wave to the first vector set wave using an amplitude to node bond, wherein the first position of the second vector set bonds to the amplitude represented by harmonic 5 and the corresponding octaves of the first vector set wave, wherein the first position of the second vector set wave is defined by the number 5 and the corresponding octaves relative to the first vector set wave; and
repeat the step of bonding for the third vector set wave to the second vector set wave, wherein the first position of the third vector set is defined by the number 5 and its octaves relative to the second vector set wave, and by the number 25 and its octaves relative to the first vector set wave.
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100. The system of claim 87, wherein the processor is further configured with the logic to apply a constantly changing time reference to at least one of a harmonic energy wave and the representatives of the harmonic energy wave resulting in a representation of a harmonic energy sine wave.
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101. The system of claim 87, wherein the processor is further configured with the logic to describe mixtures of frequencies, harmonic energy waves, current loop waves, energy levels, and measurements as mixtures of at least one of color, chroma, and gray.
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88. The system of claim 87, wherein the processor is further configured with the logic to relate the properties of electromagnetic waves to harmonic sound waves by being further configured to relate the individual harmonic sound waves, and their association to color by musical 5ths, to the positions of a harmonic energy wave.
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102. A notation system on a recordable medium, comprising:
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logic configured to display a ledger line and five staff lines and spaces between the lines and the ledger line and the lines; and
logic configured to display twelve consecutive chromatic notes representing consecutive tones of a musical 5th relationship, wherein the consecutive chromatic notes are applied consecutively to the lines and spaces, wherein the twelve consecutive notes are configured with consecutive chromatic colors, wherein the colors are twelve fundamental colors representative of at least one of selected colors, chromas, and grays. - View Dependent Claims (103, 104)
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103. The system of claim 102, wherein the logic is further configured to display ledger lines separated by octaves, such that the twelve consecutive chromatic notes are repeated for every octave.
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104. The system of claim 102, wherein the logic is further configured to display one-word color name notes positioned on the staff line and the ledger line, and two-word color name notes positioned on the spaces between the staff lines and the ledger lines, wherein the one-word color names include yellow, green, blue, violet, red, and orange, and the two-word color names include yellow-green, blue-green, blue-violet, red-violet, red-orange, and yellow-orange.
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103. The system of claim 102, wherein the logic is further configured to display ledger lines separated by octaves, such that the twelve consecutive chromatic notes are repeated for every octave.
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Specification
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Current AssigneeMS Squared
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Original AssigneeMS Squared
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InventorsSandborn, Mark D., Sandborn, Michael T.
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Primary Examiner(s)Donels, Jeffrey W
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Application NumberUS10/099,336Publication NumberTime in Patent Office1,251 DaysField of Search844/70.R, 844/71.R, 84472-475, 844/77.R, 844/78, 84479-480, 844/831, 844/832, 844/84, 844/85.SRUS Class Current84/483.2CPC Class CodesG09B 15/02 Boards or like means for pr...