GB2350447A - Time system - Google Patents
Time system Download PDFInfo
- Publication number
- GB2350447A GB2350447A GB9907127A GB9907127A GB2350447A GB 2350447 A GB2350447 A GB 2350447A GB 9907127 A GB9907127 A GB 9907127A GB 9907127 A GB9907127 A GB 9907127A GB 2350447 A GB2350447 A GB 2350447A
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- GB
- United Kingdom
- Prior art keywords
- time
- computer
- time clock
- year
- timing system
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- G—PHYSICS
- G09—EDUCATION; CRYPTOGRAPHY; DISPLAY; ADVERTISING; SEALS
- G09D—RAILWAY OR LIKE TIME OR FARE TABLES; PERPETUAL CALENDARS
- G09D3/00—Perpetual calendars
- G09D3/12—Perpetual calendars electrically operated
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- Physics & Mathematics (AREA)
- General Physics & Mathematics (AREA)
- Engineering & Computer Science (AREA)
- Theoretical Computer Science (AREA)
- Complex Calculations (AREA)
Abstract
A timing system has been devised which overcomes the problems associated with the Gregorian, Chinese lunar and Islamic calendars. The time clock of a computer set to Greenwich Standard Time is converted to vector time and is linked to the core calendar of the computer time clock by a He Tu positioner to produce a timing system which can carry digit-adding automatically from one century to the next. The timing system according to the invention not only solves problems associated with the millennium bug but will also solve other time problems such as those associated with the year 3322 and the Muslim solar year 86400 plus and minus problem.
Description
2350447 Title: TINIE SYSTEM The present invention relates to a time system
to overcome the problems associated with time calculated using the known Gregorian, Chinese lunar and Hijri (Islamic) calendars.
The developing trend of modem computer technology has stepped forward to the bounds of computer of light speed but, in the meantime, its algorithm and its data structure is relatively primitive. In the domain of artificial intelligence, a basic algorithm for computer is "Gauss's equation", which solutions are binary values of mathematical logic. Many kinds 10 of algorithms have been used in recent decades such as: probability, conditional probability, ambiguous probability and multiambiguous probabilities to resolve the problem in the interval 0-1, but the result shows that it is not as good as it should be in several modern important applications. The computer's super high speed of operation and its lower level of intelligence, the variety of algorithm and 15 the state of vector operation, these are the regrettable current state of development of computers and basic theory of artificial intelligence. Is there a solution to the algorithm of the "Gauss's Equation" of degree n, of degree 2, or not? There is one phenomenon in the ideological history of the human race that the solution of modem difficult problem often draws great 20 inspiration from early primitive natural philosophy. Also this interesting phenomenon happens again in the solution of "Equation of Gauss". Now if we study the difficult problem of "Equation of Gauss" together with "Zhou Yi San Tu" - one of Chinese primitive natural philosophies and "Albert Einstein's Theory of Relativity", a wonderful world may occur before us. There has never 25 been a solution to "He TO of "Zhou Yi San Tu" in history, but if we remove its five upper points, and its five lower points, out of the centre of "He Tu", then the "He Tu" becomes a regular matrix table. If we regard this matrix table as a point 2 of the "speed of the light U in Einstein's Theory of Relativity", and regard the five upper points and the five lower points of the "He TJ as the "Rigid Frame of Reference", then it may be possible for us to find a solution of 'Unstein's Theory of Relativity", and of the difficult problem of "Gauss' Equation" of mathematical logic; and of the points number of the "He TJ (including "Zhou Yi San TJ).
There are several hypotheses, viz:- a. Each point 1 to 9 in the matrix table of the "He TJ has its own relevant "Time & Space Position", and its respective property (attribute); and their relationship established with each other respectively. This type of three10 dimensional state (time and space, attribute, relationship) exists in every "Static" object of the natural word and universe. We use this logic to explain them, to give them a meaning; this is exactly 'lmaginary Mathematical Logic" or it may be called "Static Mode Of Imaginary Mathematical LogiC. It is also exactly the basic logic mode of systematic 15 analysis on the "Equation of Gauss' of degree 2, and degree N. b. In the matrix table of the "He TJ each point 1 to 9 (time and space position, attribute, relationship) is also the basic program of the 2 values or 3 values operation of mathematical logic "True- False". The "Rigid Frame of Reference" (expressed in the "He TJ by its five upper points and five 20 lower points) is the condition (0 dimension) of which the result of 3 values operation can be determined. This process of operation is exactly the operational process of 2 values of "Mathematical Logic"; and that of 3 values of 1maginary Mathematical Logic"; and that of N values (under the rigid frame of reference). The appearance (beginning, start of life) and 25 disappearance (ending) of the object (the operating engineering body) expressed in this process of operation, and a new start of a new object's process, we define this whole process as the process of '1maginary Mathematical Logic".
3 C. The 2 values, 3 values, N values (under the rigid frame of reference) of mathematical logic operation and also the '1maginary Mathematical Logic" which describe the whole process (including its happening, its ending, its new start) are the intersections in the artificial intelligence field 5 of the three theories; "Equation of Gauss"; Einstein's Theory of Relativity", "The General Theory of Relativity"; and "The Uncompleted General Theory of Relativity"; and "Zhou Yi San TJ, (especially the points number of the "He TJ). Consequently, this is one possible solution to the algorithm of degree 1, degree 2, degree N of the "Equation of 10 Gauss". d. By adopting '1maginary Mathematical Logic" and its algorithm to solve: (1) A permanent solution of the changing computer time clock beyond the present century; (2) The mathematical description and control engineering of process of 15 multi-dimensional data (including Information Data). (3) The bottleneck problem of machine translation {"[pattern control] and [self-study system] supported by an enlightening expert's systen'}.
The current "problem of exchanging computer time clocV is not a technical oversight. That is to say no matter two digits are used at present to represent the year or four digits are to be used after 1999 the crux of "time clock' problem is the barrier of Newton's classical physics on the basic theory of "Time- Space".
The concept of "Time" in Einstein's theory of relativity is a quantification of self motion (including rotation) of space object (including celestial body-in- itself) under the "rigid frame of reference". And the concept of "Space" is a mathematical expression of angle formed by space object (including celestial body-in-itself) and the "Frame of Reference' in the accelerating movement.
4 The exchanging time clock plan under the "Time-Space" concept of Einstein's theory of relativity, must be applicable at any place on the earth. Also it can be applicable as well in the computer of spacecraft (under the first, second and third cosmic velocity). This is also a precondition of stepping forward to a new stage in the field of a computer's artificial intelligence.
The 21" century is only the preliminary stage of computer times. If the present problem cannot be resolved then, by the year 9999, the computer time clock problem will bring disaster of astronomical figures to mankind.
The technical difficulties of solving the modem computer's changing time clock beyond the present century are:
(1) Turning the presently used time clock into "Vector Time" of the new time clock (i.e. "Computer Life Time"), (2) The concentrated algorithm of "Computer Core Calendar" comes from three international commonly used calendars (the Gregorian Calendar, the 15 Traditional Chinese Calendar and the Muslim Lunar Calendar). (3) To link up the "Vector Time" with "Core Calendar", a scientific carrier is needed with a calendar which we define as <<He Tu Positioner>>. With these three kinds of technology, the computer will never have a problem of being unable to carry digit-adding automatically when the year 1900 or 20 9999 (or the end of any other year) occurs.
As for "Einstein's theory of relativity", "The general theory of relativity" and "Einstein's uncompleted general field theory", if one regards the "Einstein's uncompleted theory of relativity" as a starting point, the velocity of point "C":
The new computer time clock used in the spacecraft must be a core of self positioning of which a flying object's space and position can be made, and also a core of time self-description (including in the speed of light-year). This theory is based on the "Einstein's special theory of relativity" and the "General theory of relativity" and the "Uncompleted general field theory".
(1) Point "C" is "vibrating", which is defined as point "C" of light speed.
Under the rigid frame of reference it is of zero cosmic velocity (n, and the "space-time" concept of T' velocity.
(2) Point "C" is accelerating (under the frame of reference or departing from the orbit of "General Field") i.e. the "Space-Time" concept under the first, second and third cosmic velocity.
(3) In the cosmic mode, Space, Time, Velocity (of attribute) are the keys to 10 solve the problem of computer time clock of modern three dimensional state (and the fourth dimension of "field" under the frame of reference).
The plan to solve the "Problem of computer time clock" permanently is a basic condition (or premise) for the computer to march forward up to a new step in the field of artificial intelligence.
is Two new concepts introduced from the "Time Clock" plan:
(1) Computer "Life Time" (set according to Greenwich Standard Time).
(2) The core calendar of "computer time clock" (including under the third cosmic velocity).
The permanent solution of changing computer time clock beyond the present century make it possible that the "time clocV problem will never happen again in the scientific history of computer. There are three solutions as follows:
6 (1) New time clock, including three core technologies:
a>. computer "Life Time"; b>. the "Core Calenda?' of computer time clock; c>. "He Tu Positione?'.
(2) As for the time clock of the presently used old CPU "Resuscitator of changing computer time clock beyond the present century" should be adopted.
(3) If the presently used computer has got the problem of millennium bug and cannot be paused to add "Resuscitator", "New time clock prograin' should be used to carry out "soft landinj plan in the operational system "including network server).
The accompanying drawings and charts further clarify the invention, the chart of sheet 2 continuing on sheet 3. Sheet 4 shows a 60-year cycle starting at year A.D.4 and continuing up to year 3723 in terms of the known calendar.
"Ma Liang Time Clock" in developing computer science history has for the first time resolved once and for all the so-called "Time Leakinj problem which has haunted the contemporary "Y2W' bug and post year-2000 problems. The signification of "Ma Liang Time Clock": a. The "Real Time Clock RTW of computer "Life Time" to be set according 20 to Greenwich Standard Time base on "Vector time" concept.
b. New time clock "Core Calenda?' efficiently resolves the plus or n-dnus of problem beyond the present century besides resolving the same for the first post 400 year at year 3322 problem as well as to eliminate the "Muslim Solar Calenda?' year 86400's plus and minus problem.
7 C. The implementation of "Three Dimension Stepwise Calculation" by new clock system will be able to calculate the infinity year in galaxy which is equivalent to astronomical "Speed of Light Year". The system based on the new time clock will be useable for accurate aircraft and 5 sPacecraft navigation.
8
Claims (2)
1. A timing system having a time clock which is not constrained by conventional temporal time, wherein the time clock is converted from Greenwich Standard Time into vector time and the vector time is linked to the core calendar by a He Tu positioner to produce a timing system which can carry digit- adding automatically from one century to the next.
2. A timing system substantially as described herein with reference to the drawings.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB9907127A GB2350447A (en) | 1999-03-26 | 1999-03-26 | Time system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB9907127A GB2350447A (en) | 1999-03-26 | 1999-03-26 | Time system |
Publications (2)
Publication Number | Publication Date |
---|---|
GB9907127D0 GB9907127D0 (en) | 1999-05-19 |
GB2350447A true GB2350447A (en) | 2000-11-29 |
Family
ID=10850513
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
GB9907127A Withdrawn GB2350447A (en) | 1999-03-26 | 1999-03-26 | Time system |
Country Status (1)
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GB (1) | GB2350447A (en) |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3792541A (en) * | 1972-10-16 | 1974-02-19 | R Engle | Electronic perpetual calendar |
JPS59224590A (en) * | 1983-06-03 | 1984-12-17 | Sanyo Electric Co Ltd | Detecting method of leap year |
GB2312060A (en) * | 1996-12-31 | 1997-10-15 | Erasoft Tech Inc | Detecting year 2000 date problems |
-
1999
- 1999-03-26 GB GB9907127A patent/GB2350447A/en not_active Withdrawn
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3792541A (en) * | 1972-10-16 | 1974-02-19 | R Engle | Electronic perpetual calendar |
JPS59224590A (en) * | 1983-06-03 | 1984-12-17 | Sanyo Electric Co Ltd | Detecting method of leap year |
GB2312060A (en) * | 1996-12-31 | 1997-10-15 | Erasoft Tech Inc | Detecting year 2000 date problems |
Also Published As
Publication number | Publication date |
---|---|
GB9907127D0 (en) | 1999-05-19 |
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Legal Events
Date | Code | Title | Description |
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WAP | Application withdrawn, taken to be withdrawn or refused ** after publication under section 16(1) |