Jadhav Division Axiom

Jadhav Division Axiom, gives a way to correctly predict the number of digits before decimal point in an incomplete or improper, division process left with remainder zero and a Quotient with decimal part, given by Jyotiraditya Jadhav

Statement[edit]

In an incomplete division process if the dividend is lesser then Divisor into product of 10 raise to a power "k", and bigger then divisor into product of 10 with power "k-1" then there will be k number of terms before decimal point in an divisional process.

$d\times 10^{k}-1<n<d\times 10^{k}$ [edit]

Number of digits before decimal point is k (here d represents divisor and n represents dividend)

Practical Observations[edit]

22/7 = 3.14

here { 7 X 10 ^(1-1) < 22 < 7 X 10^1 } , so number of digits before decimal point is 1

100/ 6 = 16.6

here {6 X 10^(2-1)<100<6 X 10^2 }, so number of digits before decimal point is 2

Uses[edit]

All type of division processes
Can be used to correctly predict the nature of the answer for long division processes.
Can be used to determine the sin and cosine functions of extreme angles^[1]

Other Discoveries by Jyotiraditya Jadhav[edit]

Sources[edit]

↑ https://artofproblemsolving.com/wiki/index.php/Jadhav_Division_Axiom

[1] ttps://artofproblemsolving.com/wiki/index.php/Jadhav_Division_Axiom

[1]

Jadhav Division Axiom

Contents

Statement[edit]

$d\times 10^{k}-1<n<d\times 10^{k}$ [edit]

Practical Observations[edit]

Uses[edit]

Other Discoveries by Jyotiraditya Jadhav[edit]

Sources[edit]

📰 Article(s) of the same category(ies)[edit]

Jadhav Division Axiom

Statement[edit]

d × 10 k − 1 < n < d × 10 k {\displaystyle d\times 10^{k}-1<n<d\times 10^{k}} [edit]

Practical Observations[edit]

Uses[edit]

Other Discoveries by Jyotiraditya Jadhav[edit]

Sources[edit]

📰 Article(s) of the same category(ies)[edit]

$d\times 10^{k}-1<n<d\times 10^{k}$ [edit]