This example shows how to perform binary point scaling in `FI`

.

`a = fi(v,s,w,f)`

returns a `fi`

with value `v`

, signedness `s`

, word length `w`

, and fraction length `f`

.

If `s`

is true (signed) the leading or most significant bit (MSB) in the resulting fi is always the sign bit.

Fraction length `f`

is the scaling `2^(-f)`

.

For example, create a signed 8-bit long `fi`

with a value of 0.5 and a scaling of 2^(-7):

a = fi(0.5,true,8,7)

a = 0.5000 DataTypeMode: Fixed-point: binary point scaling Signedness: Signed WordLength: 8 FractionLength: 7

The fraction length or the scaling determines the position of the binary point in the `fi`

object.

When the fraction length `f`

is positive and less than the word length, the binary point lies `f`

places to the left of the least significant bit (LSB) and within the word.

For example, in a signed 3-bit `fi`

with fraction length of 1 and value -0.5, the binary point lies 1 place to the left of the LSB. In this case each bit is set to `1`

and the binary equivalent of the `fi`

with its binary point is `11.1`

.

The real world value of -0.5 is obtained by multiplying each bit by its scaling factor, starting with the LSB and working up to the signed MSB.

`(1*2^-1) + (1*2^0) +(-1*2^1) = -0.5`

`storedInteger(a)`

returns the stored signed, unscaled integer value `-1`

.

`(1*2^0) + (1*2^1) +(-1*2^2) = -1`

a = fi(-0.5,true,3,1) bin(a) storedInteger(a)

a = -0.5000 DataTypeMode: Fixed-point: binary point scaling Signedness: Signed WordLength: 3 FractionLength: 1 ans = '111' ans = int8 -1

When the fraction length `f`

is positive and greater than the word length, the binary point lies `f`

places to the left of the LSB and outside the word.

For example the binary equivalent of a signed 3-bit word with fraction length of 4 and value of -0.0625 is `._111`

Here `_`

in the `._111`

denotes an unused bit that is not a part of the 3-bit word. The first `1`

after the `_`

is the MSB or the sign bit.

The real world value of -0.0625 is computed as follows (LSB to MSB).

`(1*2^-4) + (1*2^-3) + (-1*2^-2) = -0.0625`

bin(b) will return `111`

at the MATLAB® prompt and `storedInteger(b) = -1`

b = fi(-0.0625,true,3,4) bin(b) storedInteger(b)

b = -0.0625 DataTypeMode: Fixed-point: binary point scaling Signedness: Signed WordLength: 3 FractionLength: 4 ans = '111' ans = int8 -1

When the fraction length `f`

is negative the binary point lies `f`

places to the right of LSB and is outside the physical word.

For instance in `c = fi(-4,true,3,-2)`

the binary point lies 2 places to the right of the LSB `111__.`

. Here the two right most spaces are unused bits that are not part of the 3-bit word. The right most `1`

is the LSB and the leading `1`

is the sign bit.

The real world value of -4 is obtained by multiplying each bit by its scaling factor `2^(-f)`

, i.e. `2(-(-2)) = 2^(2)`

for the LSB, and then adding the products together.

`(1*2^2) + (1*2^3) +(-1*2^4) = -4`

`bin(c)`

and `storedInteger(c)`

will still give `111`

and `-1`

as in the previous two examples.

c = fi(-4,true,3,-2) bin(c) storedInteger(c)

c = -4 DataTypeMode: Fixed-point: binary point scaling Signedness: Signed WordLength: 3 FractionLength: -2 ans = '111' ans = int8 -1

In this example we create a signed 3-bit `fi`

where the fraction length is set automatically depending on the value that the `fi`

is supposed to contain. The resulting `fi`

has a value of 6, with a wordlength of 3 bits and a fraction length of -1. Here the binary point is 1 place to the right of the LSB: `011_.`

. The `_`

is again an unused bit and the first `1`

before the `_`

is the LSB. The leading `1`

is the sign bit.

The real world value (6) is obtained as follows:

`(1*2^1) + (1*2^2) + (-0*2^3) = 6`

`bin(d)`

and `storedInteger(d)`

will give `011`

and `3`

respectively.

d = fi(5,true,3) bin(d) storedInteger(d)

d = 6 DataTypeMode: Fixed-point: binary point scaling Signedness: Signed WordLength: 3 FractionLength: -1 ans = '011' ans = int8 3

This is an interactive example that allows the user to change the fraction length of a 3-bit fixed-point number by moving the binary point using a slider. The fraction length can be varied from -3 to 5 and the user can change the value of the 3 bits to '0' or '1' for either signed or unsigned numbers.

The "Scaling factors" above the 3 bits display the scaling or weight that each bit is given for the specified signedness and fraction length. The `fi`

code, the double precision real-world value and the fixed-point attributes are also displayed.

Type fibinscaling at the MATLAB prompt to run this example.

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