1.1 ARITHMETIC AND LOGIC UNIT
The arithmetic/logic unit (ALU)
contains circuitry that executes the arithmetic and logical operations. The
unit can perform four arithmetic operations: addition, subtraction,
multiplication, and division. Its logical operations usually involve making
comparisons that test for three conditions: the equal-to condition, the
less-than condition, and the greater-than condition. The computer can test for
more than one condition at once, so it can discern three other conditions as
well: less-than-or-equal-to, greater-than-or-equal-to, and
less-than-or-greater-than (not-equal-to). All of the other elements of the
computer system—control unit, registers, memory, I/O—are there mainly to bring
data into the ALU for it to process and then to take the results back out. We
have, in a sense, reached the core or essence of a computer when we consider
the ALU. In Figure 1.1 showing the ALU is interconnected with the rest of the
processor. Data are presented to the ALU in registers, and the results of an
operation are stored in registers. These registers are temporary storage
locations within the processor that are connected by signal paths to the ALU.
Figure1.1 ALU Input and Output
1.2 INTEGER REPRESENTATION
The fact that computers are
finite has important design implications. It means that computers can never
faithfully represent the sets of integers or real numbers, both of which are
infinite. Since these are generally what we work with in physics and mathematics,
it’s important to understand how we approximately represent integers and reals
on a computer.
1.2.1 SIGN-MAGNITUDE
REPRESENTATION
The sign-magnitude binary
format is the simplest conceptual format. To represent a number in
sign-magnitude, we simply use the leftmost bit to represent the sign, where 0
means positive, and the remaining bits to represent the magnitude (absolute
value).
1.2.2 TWO’S COMPLIMENT
Two's complement number
representation is used for signed numbers on most modern computers. This
notation allows a computer to add and subtract numbers using the same
operations (thus we do not need to implement adders and subtractors). We can
characterize two's complement notation as:
A fixed number of bits are used
to represent numbers
The most significant bit is
called the sign bit
This same notation is used to
represent both positive and negative numbers.
1.3 INTEGER ARITHMETIC
This
section examines common arithmetic functions on integer representations.
1.3.1 ADDITION AND SUBTRACTION OF
INTEGER
Rule
of ADDING and SUBTRACTING INTEGERS.
1.3.2 MULTIPLICATION AND
DIVISIONOF INTEGER
Rule
of MULTIPLYING and DIVIDING INTEGERS.
1.4 FLOATING POINT
With a fixed-point notation (e.g., twos complement) it is possible to represent a range of positive and negative integers centered on 0. By assuming a fixed binary or radix point, this format allows the representation of numbers with a fractional component as well.
1.5 FLOATING POINT ARITHMETIC
1.5.1 FLOATING POINT ADDITION
AND SUBTRACTION
For addition and subtraction,
it is necessary to ensure that both operands have the same exponent value.
There are four basic phases of the algorithm for addition and subtraction:
1.
Check for zeros.
2.
Align the significands.
3.
Add or subtract the significands.
4.
Normalize the result.
1.5.2 FLOATING POINT
MULTIPLICATION AND DIVISION
Check
for zeros
Add/subtract
exponents
Multiply/divide
significands (watch sign)
Normalize
Rounding
CONCLUSION
Computer
arithmetic is a very old field that is now blossoming with recent discoveries.
These ideas have come from education and changes in the technology and number
systems. Education plays a key part in this advancement; understanding through
proofs is key to insuring correctness in implementations. It is also vital that
these descriptions express the underlying meaning of the concepts. The field of
computer arithmetic is forever expanding around these discoveries and elegant
proofs of basic concepts.
BOOK
BOOK
1.College
Algebra 4th Edition William Hart 1943
2.Data
Communications Principle Richard D. Giltin "Calculations of performance -
Binary Signals"
3.Digital
Electronics and Logic Design B. SOMANATHAN NAIR "Bolean
Algebra and Logic Simplification"
EBOOK
1.Computer
Organization and Architecture Willian Stallings 7th Edition.
WEBSITE
1.Addition
and Subtraction of Integer http://mypages.iit.edu/~smart/dvorber/lesson4.htm
2.Multiplication
and Division of Integers
http://www.mathplanet.com/education/pre-algebra/explore-and-understand-integers/multiplying-and-dividing-with-integers