Tracking Tumours into Number Community? – Yes, How and Why
W B Bozegha*
Numeration Science Literature, Development Research project, Department of Combinatorial Computation, Nigeria
Submission: March 12, 2019; Published: August 12, 2019
*Corresponding Address: Yimesgen Tarekegn Abeka, Jimma university, college of agriculture and veterinary medicine, Ethiopia
How to cite this article:W B Bozegha. Tracking Tumours into Number Community? – Yes, How and Why. Canc Therapy & Oncol Int J. 2019; 14(4): 555896. DOI:10.19080/CTOIJ.2019.14.555896
Abstract
Statement of the Problem: Tumours are growths (of quantity) in humans with medical science literature. Isodigitals produced by pre-emptive multiplication are also growths (of quantity) in numbers with slight numeration science literature for now. The developer of inchoate numeration science literature somehow acquainted with the literature of tumours, upon encountering isodigitals would be prompted to surmise isodigitals as phenotypes (lookalikes) of tumours and be urged to explore their literatures for prospects of relationship between the two.
Methodology and theoretical Orientation: Tumours and isodigitals are subjected to pentadic characterization with the five parameters of identity, structure, function, operation and application for methodology. The theoretical orientation of the method is that tumours and isodigitals as growths of quantity are classic examples of quantity which is defined as the phenomenal medium of manifestation of all things, whether material or non-material. So, the two can be compared and contrasted at will in the interest of science.
Findings:Numeration science literature on isodigitals can borrow mode of classification of tumours from medical science literature on tumours, while medical science literature on tumours can borrow verbal formulary for the description of pattern of growth of tumours from numeration science literature on isodigitals.
Conclusion and Significance:Tumours in humans and isodigitals in numbers are seen as phenotypes subsisting on manifestation of quantity. The peculiarities of one can serve as clues to the probing of the other for more light.
Recommendations:The ideal of insight on quantity should be brought to bear on scientific engagements.
Keywords: Tumours, Isodigitals,Borrowing, Classification, Literature
Introduction
Pre-emptive Multiplication in Numeration Science Literature Produces isodigitals (numbers with repeated digits at one or more sites in individual numbers) rather selectively from sudit family lineages in some spectacular architectural design as shown in Charts 1 & 2 that is easily described. The isodigital sites of such numbers look swollen and resemble swollen tissues in humans, which are called tumours in medical science. So the look-alikes (phenotypes) of tumours identified as isodigitals are encountered in some number communities. These isodigitals and tumours are subjected to comparison on this occasion on the ground that both are examples of QUANTITY which is defined in Numeration Science as phenomenal medium of manifestation of all things, whether material or non-material. The comparison includes pentadic characterization with as many as five parameters viz identity, structure, function, operation and application as rungs for exploring the ladder of similarity between the two as shown in Table 1.
Materials and Methods
Materials
The materials are digital and consist of the nine counting digits 1,2,3,4,5,6,7,8,9 distributed in the three Sudit Family Lineages of 1, 4, 7 in Family 1, 2, 5, 8 in Family 2; and 3,6,9 in Family 3 as shown in Chart 1 and the numeral 11 in Chart 2.
Methods
The methods are three: first Isodigital Square Multiplication (ISM). In Sudit family lineages under progressively increasing Digitality Level Arrangement (DLA) levels Chart 1 and the second of Base 11 Potentiation Multiplication under progressively increasing power (n) Chart 2, and the third of Base 10 digibreed construction involving Successive Collateral Posting (SCP), ref. Chart 3 are done as shown in Charts 1 and 2 respectively. The contents of the two charts are studied and regularities in the results of ISM of Family 3 in Chart 1 and that of potentiation multiplication of isodigital base 11 Chart 2 are discovered and identified as examples of pre-emptive multiplication, which is a newly invented brand of multiplication in inchoate micromathematics being developed by this author.
The construction is continued by transferring 10 -19 in row 2 to the second segment of the corridor as shown in Chart 3. The nine rows thus filled carry the digibreed to 99 preceded by 0-9 in the panel. Counting, however, starts at 1 and not 0 as 0 is not a counting digit. Step 1 requires the placement of the base strength of base 10 i.e. the ten digits 0-9 from left to right in the panel as shown in Charts 3. Step 2 transfers the counting digits 1-9 only into the corridor, descending serially from 1 to 9. Step 3 requires the membership of the base strength in the panel to descend nine places in their respective columns according to the membership in the topmost segment of the corridor. Step 4 requires each digit in the corridor to move to the left side of each digit in the row under the panel (Table 1).
Results
Keys:
SFN 1: Sudit Family, No 1
SFL 1: Sudit Family Lineage 1
SFL 3, 6, 9: Sudit Family Lineages 3, 6, 9
Discussion
The scope of the discussion is determined by the extent of the hesitancy of the tracking venture as portrayed in the question opening the title, to wit: Tracking Tumours into Number Community? And the retort of assurance conveyed by Yes, How and Why concluding the title. The idea of tracking tumours into number community itself might have been extemporaneous upon seeing both tumours and isodigitals as manifestations of quantity in form of swellings. Hesitancy portrayed in the topic might have crept in upon some reflection on the classification of tumours and diagnosis of certain categories of them that are familiar lethal diseases. In effect the hesitancy is about whether the flight of the venture of tracking tumours into number community could have a soft landing on the runway littered with issues of classification, diagnosis, exploits and impact of tumours as outlined in Table 4. Fortunately, the topic starting with hesitancy ends with a retort of assurance in the three words thus: Yes, How and Why.
In classification, Tumours divide into two categories namely Benign and Malignant, so do Isodigitals divide into two, namely Pre-emptives and Non-pre-emptives as shown in subdivisions of classification in Table 4. Subdivisions of classification abound in both Tumours and Isodigitals as per Table 4, where according to Medicine for Nurses, 12th Edn (1975) R26 by W. Gordon Sears and R.S. Winwood there are as many as seven subdivisions of Benign Tumours (Table 4).
Isodigitation varieties and growth patterns with facilitators
a. Peaked palindromic pre-emptive isodigitals, ref. Chart 1 and Table 3. They are products of Isodigital Square Multiplication (ISM) of digit 1 in increasing DLA indexes evident from DLA 2. The incumbent DLA index (4) of the ISM is the peak(n). The upward slope is worked in serial steps from 1 at the base to peak (n) ie 4 by kenization process of adding 1 successively while the downward slope from peak(n) dekenization process of subtracting 1 successively to 1 at the base again as shown in Figure 1. The serial products of kenization are christened kenites, while those of dekenization are dekenites, as depicted in Figure 1. Kenization (adding 1) and dekenization (subtracting 1) working in concert produce duplicate serial isodigitation in ISM of digit 1 rather ironically in view of their opposing drives (Figure 1).
b. Non-palindromic bifocal pre-emptive isodigitals ref. Chart 1 and Table 3. They are products of Isodigital Square Multiplication (ISM) of digits 3,6,9 all in Sudit Family 3 in increasing DLA indexes and the isodigitation appears first in DLA 3 in each case. The digital engagements in the bifocal isodigitation are phenomenal and fall into generations of development, to wit: first generation, second generation, third etc in terms of DLA index progression as depicted in Figure 2 (Tables 5 & 6).
In Figure 2, Part A, at DLA 1 the Isodigital Square Multiplication (ISM) primary digit is 3 and the product 09 is called gamete, where the leading digit 0 is denoted L and the trailing digit 9, T. At DLA 2 the ISM 33 x 33 product 1089 is derived thus: the leading digit 0 of the gamete 09 becomes a kenizer and kenizes itself (adds 1 to itself) to form a kenizite, 1, as depicted in Table 5 and place it in its front, while the trailing digit 9 of the gamete also becomes a dekenizer and dekenizes itself (subtracts 1 from itself) as shown in Table 5 to form a dekenizite, 8, and places it in its front to give altogether 1089 as shown in the ISM 33x33 DLA 2 product. At DLA 3, ISM 333x333 product grows to 110889 from 1089 due to insertion of one additional kenizite 1 in front of 0 and insertion of another additional dekenizite 8 in front of 9 to bring about the isodigitations evident at two sites for the first time. The isodigitations at the two sites continue to grow by one kenizite and one dekenizite with the progression of the DLA index of ISM as shown in the succeeding cases of Part A.
In Part B at DLA 1 the ISM 6x6 uses primary digit 6 to obtain the product 36 where 3 is the leading digit of the gamete 36 and 6 is the trailing digit. At DLA 2, the ISM 66 x 66 gives 4356. This is because 3 the leading digit of the gamete 36 at DLA 1 has become a kenizer in DLA 2 ISM and raised 4 as a kenizite for placement in its front, and 6 the trailing digit of the gamete 36 at DLA 1 has also become a dekenizer in DLA 2 ISM and raised 5 for placement in its front to give altogether 4356. At DLA3, The ISM 666x666 yields 443556 as the product where isodigitation is evident at two sites for the first time because of the insertion of another kenizite 4 in from of 3 and another dekenizite 5 in front of 6. The progression of the isodigitation at the two sites of ISM product with increasing DLA index is as explained before in Part A. Whence the isodigitation phenomenon in ISM 9x9 in Part C has the same explanation as those of 3 in Part A and 6 in Part B in Figure 2.
c. Plateaued palindromic pre-emptive Isodigitals
The growth pattern of the isodigitation in this case is based on potentiation index of base 11, whereby the incumbent potentiation power (n) is replicated (n-1) times and sandwiched in 11 to make the product of potentiation multiplication of base 11 at various powers of potentiation. Hence given 14441, the digits I in front and I behind put together laterally give 11, which is known to be the potentiation base 11, and the digit 4 indicates the potentiation power 4 while the isodigitation digitality of 3 for 444 is derived from the power 4 by dekenization ie. subtraction of 1 from 4. In effect the population of the isodigitation consists of the power index (n) replicated (n-1) times and sandwiched in 11 to give the palindromic plateaued isodigital product always as depicted in Figure 2.
d. Non- Pre-emptive Isodigitals in three Subdivisions of Total, partial and Twin
Table 3.
Diagnosis
They are commonplace in base 10 digibreed, the mega community of all integral members established by successive collateral position as depicted in Chart 3. Each of them, no matter the type, has a unique and specific location in the base 10 mega community of numbers given by its own ROCI/RODI where RODI is the last digit of the number, and ROCI is the rest of the digits to the left of the RODI. The RODI, always single digit is domiciled in the base- strength of the digibreed displayed in the panel, while ROCI can be single or multidigital, depending on the DLA level of the number concerned and it is in a sequence domiciled in the corridor to the left of the digibreed field.
The two components come together during successive collateral posting in the serial formation of numbers: the ROD1 advancing geotropically (downward) in its column to the row of the ROCI, while the ROCI in the corridor advances amatropically (toward the right) in its row for konostatic placement (to the left) beside the RODI in its column, and form the number given ROCI/RODI in a unique and specific position in the mega number community. However, all integral numbers including the preemptive and non-per-emptive isodigitals share in the mode of formation and location in the base 10 digibreed, the mega community of numbers.
Findings
There are specific techniques for forming is digitations in numbers e.g. isodigital square multiplication (ISM) and Base 11 potentiation multiplication and Base 10 digibreed construction. There are digits favorable and digits unfavorable in ISM with respect of formation of isodigitations. For example, digits 3,6,9 of sudit family 3 and digit 1 of sudit family 1 alone are favorable for formation of isodigitation in numbers by ISM technique, while the rest of the five digits 2,5,8 in sudit family 2, and 4 and 7 in sudit family 2, are unfavorable. There are digits making up the DLA 1 product of ISM of digits 3, 6, 9 i.e. 09 for ISM 3;36 for ISM 6 and 81 for ISM 9 that initiate processes for creation of the isodigitation growth elements in the case of bifocal nonpalindromic isodigitals. So, there are growth promoters in terms of digits and processes owed to agents of isodigitation in numbers. The foregoing aspects of isodigitals in numbers may well be found of tumours in humans.
Conclusion and Significance
Tumours as swellings of tissues in humans and isodigitals also of swellings in numbers are both manifestations of quantity. There is massive evidence of resemblance between tumours in humans and isodigitals in numbers in justification of tracking tumours into number community, initially attended by hesitancy. The issues of isodigitation growth pattern and growth promoters as well as selective engagement of four digits out of the nine counting digits revealed so far show the effort of probing the intricacies of isodigitation in number communities is worthwhile at least academically. The significance of tracking tumours into number community is that with the encouraging correspondence of the features of both tumours and isodigitals as manifestations of quantity, scientists can be challenged to take them as clues for further research on tumours, whether malignant or not in the interest of health care and well-being of humanity.
Recommendations
The striking resemblance between tumours in humans and isodigitals in numbers should be a food for thought amongst scientists in medicine and numeration science.
References
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- Brown Watson (2003) The Amazing Universe English (Edn).
- Sherman K. Stein (1976) Mathematics the Man-Made Universe an Introduction to the Spirit of Mathematics W.H. Freeman and Company, San Francisco, California, USA.
- George K Stone (1964) Science in Action Prentice-Hall, Inc. Englewood Cliffs, New Jersey, USA.
- Alma E. Guinness (Ed) (1987) ABC’s of the Human Body.