Modular Arithmetic
Modular Arithmetic

Floating point numbers in Scilab
Floating point numbers in Scilab

Fermat`s Little Theorem and Chinese Remainder Theorem Solutions
Fermat`s Little Theorem and Chinese Remainder Theorem Solutions

MTH 05 Lecture Notes
MTH 05 Lecture Notes

College Algebra Week 2
College Algebra Week 2

Practice Workbook, Grade 3 (PE) - Teachers` Resources for cycle 1
Practice Workbook, Grade 3 (PE) - Teachers` Resources for cycle 1

Here - Math-Boise State
Here - Math-Boise State

Unavoidable Errors in Computing
Unavoidable Errors in Computing

Rational Numbers
Rational Numbers

leibniz, bernoulli and the logarithms of negative numbers
leibniz, bernoulli and the logarithms of negative numbers

Recursive call to factorial(1)
Recursive call to factorial(1)

Floating-point Arithmetic
Floating-point Arithmetic

ECO 153 Introduction to Quantitative Method I
ECO 153 Introduction to Quantitative Method I

Awk is a powerful command language that allows the user to
Awk is a powerful command language that allows the user to

Baby steps through Basic Algebra book
Baby steps through Basic Algebra book

109_lecture4_fall05
109_lecture4_fall05

Representing Numbers Using Fibonacci Variants
Representing Numbers Using Fibonacci Variants

... Continued Fractions A simple continued fraction for a (positive) fraction is ...
Manassas City Public Schools (4-19-07)
Manassas City Public Schools (4-19-07)

Number Theory II: Worksheet —Solutions
Number Theory II: Worksheet —Solutions

Numerical Mathematical Analysis
Numerical Mathematical Analysis

Bridge to Higher Mathematics
Bridge to Higher Mathematics

the existence of fibonacci numbers in the algorithmic generator for
the existence of fibonacci numbers in the algorithmic generator for

ID : in-8-Cubes-and-Cube
ID : in-8-Cubes-and-Cube

Lecture 12
Lecture 12

6.1. The Set of Fractions Problem (Page 216). A child has a set of 10
6.1. The Set of Fractions Problem (Page 216). A child has a set of 10

Location arithmetic

Location arithmetic (Latin arithmeticæ localis) is the additive (non-positional) binary numeral systems, which John Napier explored as a computation technique in his treatise Rabdology (1617), both symbolically and on a chessboard-like grid.Napier's terminology, derived from using the positions of counters on the board to represent numbers, is potentially misleading in current vocabulary because the numbering system is non-positional.During Napier's time, most of the computations were made on boards with tally-marks or jetons. So, unlike it may be seen by modern reader, his goal was not to use moves of counters on a board to multiply, divide and find square roots, but rather to find a way to compute symbolically.However, when reproduced on the board, this new technique did not require mental trial-and-error computations nor complex carry memorization (unlike base 10 computations). He was so pleased by his discovery that he said in his preface ... it might be well described as more of a lark than a labor, for it carries out addition, subtraction, multiplication, division and the extraction of square roots purely by moving counters from place to place.