# Fixed Point Numbers Vs Floating Point Numbers

What are the various advantages/disadvantages from a computer architecture of fixed and floating point numbers? I can understand that both lead to inaccuracy of sorts.

My other questions are

1. How do these inaccuracies arise?

2. Is one form better than the other?

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You have not specified which programming language you are using, however, most programming languages do not have a built-in fixed point type.

Main stream languages like C and C++ have integer types and floating-point types. If you intend to use something like a fixed-point type with, say, four decimals, you would have to implement this on top of the existing integer types. Alternatively, use an existing library.

When it comes to the question which is better, the answer is "it depends". Things that you would have to consider are:

• What kind of hardware do you intend to use? Most modern host machines (PC:s) have dedicated floating-point hardware, likewise high-end embedded systems. However, when using a low-end embedded system it does not, so it must implement floating-point operations in terms of the existing assembler instructions.

• What is the nature of your application? Does it work naturally with, say, four decimals. What will happen if you get a rounding error on the least significant bit etc.

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Why floating-point numbers are needed

Since computer memory is limited, you cannot store numbers with infinite precision, no matter whether you use binary fractions or decimal ones: at some point you have to cut off. But how much accuracy is needed? And where is it needed? How many integer digits and how many fraction digits?

• To an engineer building a highway, it does not matter whether it’s 10 meters or 10.0001 meters wide - his measurements are probably not that accurate in the first place.
• To someone designing a microchip, 0.0001 meters (a tenth of a millimeter) is a huge difference - But he’ll never have to deal with a distance larger than 0.1 meters.
• A physicist needs to use the speed of light (about 300000000) and Newton’s gravitational constant (about 0.0000000000667) together in the same calculation.

To satisfy the engineer and the chip designer, a number format has to provide accuracy for numbers at very different magnitudes. However, only relative accuracy is needed. To satisfy the physicist, it must be possible to do calculations that involve numbers with different magnitudes.

Basically, having a fixed number of integer and fractional digits is not useful - and the solution is a format with a floating point.