I need to convert the binary number 0000 0110 1101 1001 1111 1110 1101 0011 to IEEE floating-point. The answer is 1.10110011111111011010011 x 2^−114, but how is the exponent derived?
Take the first 9 digits
The first one is the sign (0 == positive)
The next 8 are the exponent, converted to decimal == 13. The sign in IEEE 32 binary float are offsetted by 127, so 13 - 127 = -114.
(and the missing 1 for the fraction part, it's implicit)
Let's break the representation of your number up into the component parts of an IEEE-754 floating-point value:
The exponent field is
The exponent of an IEEE-754 number is stored in a biased representation, which means that a fixed value is added to the true exponent to get the value stored in the encoding. For single (32-bit) precision, the bias is 127. To get the exponent from the encoding, we need to subtract off this bias:
the units bit of the significand is not stored (it is implicitly 1 unless the exponent field is zero), so we insert that bit into the significand, and get the value you listed: