Hand in this assignment on paper in class on Monday.
For each of the following positive binary integers, what is
the decimal equivalent?
1101
1110111
1
Add 11010 to 1011. Show your work (in particular, show where
you get carries, and where you don't). You can check your work
by translating the numbers into decimal, but I want to see
you do the usual gradeschool addition algorithm in base 2 instead
of base ten.
When you look at an integer expressed in the decimal
system, it's easy to tell whether the number is divisible
by 2, or 5, or 10, or 100, or 1000, or.... For example, a
number is divisible by 5 if its decimal expression ends with
a 5 or a 0, and a number is divisible by 100 if its decimal
expression ends in two zeros.
What sorts of divisibility are easy to see when a number is
expressed in binary, and how can you see them?
The number 1.398 is equal to 1 + 3/10 + 9/100 + 8/1000. If we
move to binary, and use a "binary point" instead of a decimal point,
what will the following numbers equal? That is, what are the
base ten equivalents of the following binary numbers?
0.11
1.011
When you multiply a decimal number by 10, you shift the decimal point
to the right one place. How can you shift a binary point to the right?
Rewrite the following base-ten numbers as 16-bit two's complement
integers: -1, 31, -31, and 1729.
What does the bit pattern 01101001 represent if you interpret
it as an 8-bit two's complement integer? What if you interpret
it as a character using ASCII?