# Statistical Functions Part Two

## F.DIST.RT

Returns the inverse of the t-distribution.

### Syntax

FDIST(Number; degrees_freedom_1; degrees_freedom_2)

Number is the value for which the F distribution is to be calculated.

degrees_freedom_1 is the degrees of freedom in the numerator in the F distribution.

degrees_freedom_2 is the degrees of freedom in the denominator in the F distribution.

### Examples

=F.DIST.RT(0.8;8;12) yields 0.6143396437.

## F.INV.RT

Returns the inverse of the t-distribution.

### Syntax

FINV(Number; degrees_freedom_1; degrees_freedom_2)

Number is probability value for which the inverse F distribution is to be calculated.

degrees_freedom_1 is the number of degrees of freedom in the numerator of the F distribution.

degrees_freedom_2 is the number of degrees of freedom in the denominator of the F distribution.

### Examples

=F.INV.RT(0.5;5;10) yields 0.9319331609.

## FDIST

Calculates the values of an F distribution.

### Syntax

FDIST(Number; degrees_freedom_1; degrees_freedom_2)

Number is the value for which the F distribution is to be calculated.

degrees_freedom_1 is the degrees of freedom in the numerator in the F distribution.

degrees_freedom_2 is the degrees of freedom in the denominator in the F distribution.

### Examples

=FDIST(0.8;8;12) yields 0.61.

## FDIST

Returns the inverse of the t-distribution.

### Syntax

FDIST(Number; degrees_freedom_1; degrees_freedom_2)

Number is the value for which the F distribution is to be calculated.

degrees_freedom_1 is the degrees of freedom in the numerator in the F distribution.

degrees_freedom_2 is the degrees of freedom in the denominator in the F distribution.

C = 0 calculates the density function C = 1 the distribution.

### Examples

=F.DIST(0.8;8;12;0) yields 0.7095282499.

=F.DIST(0.8;8;12;1) yields 0.3856603563.

## FINV

Returns the inverse of the F probability distribution. The F distribution is used for F tests in order to set the relation between two differing data sets.

### Syntax

FINV(Number; degrees_freedom_1; degrees_freedom_2)

Number is probability value for which the inverse F distribution is to be calculated.

degrees_freedom_1 is the number of degrees of freedom in the numerator of the F distribution.

degrees_freedom_2 is the number of degrees of freedom in the denominator of the F distribution.

### Examples

=FINV(0.5;5;10) yields 0.93.

## FINV

Returns the inverse of the F probability distribution. The F distribution is used for F tests in order to set the relation between two differing data sets.

### Syntax

FINV(Number; degrees_freedom_1; degrees_freedom_2)

Number is probability value for which the inverse F distribution is to be calculated.

degrees_freedom_1 is the number of degrees of freedom in the numerator of the F distribution.

degrees_freedom_2 is the number of degrees of freedom in the denominator of the F distribution.

### Examples

=F.INV(0.5;5;10) yields 0.9319331609.

## FISHER

Returns the Fisher transformation for x and creates a function close to a normal distribution.

### Syntax

FISHER(Number)

Number is the value to be transformed.

### Examples

=FISHER(0.5) yields 0.55.

## FISHERINV

Returns the inverse of the Fisher transformation for x and creates a function close to a normal distribution.

### Syntax

FISHERINV(Number)

Number is the value that is to undergo reverse-transformation.

### Examples

=FISHERINV(0.5) yields 0.46.

## FTEST

Returns the result of an F test.

### Syntax

FTEST(Data_1; Data_2)

Data_1 is the first record array.

Data_2 is the second record array.

### Examples

=FTEST(A1:A30; B1:B12) calculates whether the two data sets are different in their variance and returns the probability that both sets could have come from the same total population.

## FTEST

Returns the result of an F test.

### Syntax

FTEST(Data_1; Data_2)

Data_1 is the first record array.

Data_2 is the second record array.

### Examples

=FTEST(A1:A30; B1:B12) calculates whether the two data sets are different in their variance and returns the probability that both sets could have come from the same total population.

## GAMMA

Returns the Gamma function value. Note that GAMMAINV is not the inverse of GAMMA, but of GAMMADIST.

### Syntax

Number is the value for which the Gamma distribution is to be calculated.

## GAMMADIST

Returns the values of a Gamma distribution.

The inverse function is GAMMAINV.

### Syntax

GAMMADIST(Number; Alpha; Beta; C)

Number is the value for which the Gamma distribution is to be calculated.

Beta is the parameter Beta of the Gamma distribution.

Beta is the parameter Beta of the Gamma distribution.

C = 0 calculates the density function C = 1 the distribution.

### Examples

=GAMMADIST(2;1;1;1) yields 0.86.

## GAMMADIST

Returns the values of a Gamma distribution.

The inverse function is GAMMAINV or GAMMA.INV.

This function is identical to GAMMADIST and was introduced for interoperability with other office suites.

### Syntax

GAMMADIST(Number; Alpha; Beta; C)

Number is the value for which the Gamma distribution is to be calculated.

Beta is the parameter Beta of the Gamma distribution.

Beta is the parameter Beta of the Gamma distribution.

C = 0 calculates the density function C = 1 the distribution.

### Examples

=GAMMA.DIST(2;1;1;1) yields 0.86.

## GAMMAINV

Returns the inverse of the Gamma cumulative distribution. This function allows you to search for variables with different distribution.

### Syntax

GAMMAINV(Number; Alpha; Beta)

Number is the probability value for which the inverse Gamma distribution is to be calculated.

Beta is the parameter Beta of the Gamma distribution.

Beta is the parameter Beta of the Gamma distribution.

### Examples

=GAMMAINV(0.8;1;1) yields 1.61.

## GAMMAINV

Returns the inverse of the Gamma cumulative distribution. This function allows you to search for variables with different distribution.

This function is identical to GAMMAINV and was introduced for interoperability with other office suites.

### Syntax

GAMMAINV(Number; Alpha; Beta)

Number is the probability value for which the inverse Gamma distribution is to be calculated.

Beta is the parameter Beta of the Gamma distribution.

Beta is the parameter Beta of the Gamma distribution.

### Examples

=GAMMA.INV(0.8;1;1) yields 1.61.

## GAMMALN

Returns the natural logarithm of the Gamma function: G(x).

### Syntax

GAMMALN(Number)

Number is the value for which the natural logarithm of the Gamma function is to be calculated.

### Examples

=GAMMALN(2) yields 0.

## GAMMALN.PRECISE

Returns the natural logarithm of the Gamma function: G(x).

### Syntax

GAMMALN.PRECISE(Number)

Number is the value for which the natural logarithm of the Gamma function is to be calculated.

### Examples

=GAMMALN.PRECISE(2) yields 0.

## GAUSS

Returns the standard normal cumulative distribution.

It is GAUSS(x)=NORMSDIST(x)-0.5

### Syntax

GAUSS(number)

Number is the value for which the Gamma distribution is to be calculated.

### Examples

=GAUSS(0.19) = 0.08

=GAUSS(0.0375) = 0.01

## GEOMEAN

Returns the geometric mean of a sample.

### Syntax

GEOMEAN(Number1; Number2; ...; Number30)

Number1, Number2, ..., Number30 are numeric arguments or ranges that represent a random sample.

### Examples

GEOMEAN(23; 46; 69) = 41.79. The geometric mean value of this random sample is therefore 41.79.

## HARMEAN

Returns the harmonic mean of a data set.

### Syntax

HARMEAN(Number1; Number2; ...; Number30)

Number1, Number2, ..., Number30 are up to 30 values or ranges, that can be used to calculate the harmonic mean.

### Examples

GEOMEAN(23; 46; 69) = 41.79. The geometric mean value of this random sample is therefore 41.79.

## HYPGEOMDIST

Returns the hypergeometric distribution.

### Syntax

HYPGEOMDIST(X; N_sample; Successes; N_population)

X is the number of results achieved in the random sample.

N_sample is the size of the random sample.

Successes is the number of possible results in the total population.

N_population is the size of the total population.

### Examples

=HYPGEOMDIST(2; 2; 90; 100) yields 0.81. If 90 out of 100 pieces of buttered toast fall from the table and hit the floor with the buttered side first, then if 2 pieces of buttered toast are dropped from the table, the probability is 81%, that both will strike buttered side first.

## HYPGEOMDIST

Returns the hypergeometric distribution.

### Syntax

HYPGEOMDIST(X; N_sample; Successes; N_population)

X is the number of results achieved in the random sample.

N_sample is the size of the random sample.

Successes is the number of possible results in the total population.

N_population is the size of the total population.

Cumulative : 0 or False calculates the probability density function. Other values or True calculates the cumulative distribution function.

### Examples

=HYPGEOMDIST(2; 2; 90; 100) yields 0.81. If 90 out of 100 pieces of buttered toast fall from the table and hit the floor with the buttered side first, then if 2 pieces of buttered toast are dropped from the table, the probability is 81%, that both will strike buttered side first.

=HYPGEOM.DIST(2;2;90;100;1) yields 1.

## TRIMMEAN

Returns the mean of a data set without the Alpha percent of data at the margins.

### Syntax

TRIMMEAN(Data; Alpha)

Data is the array of data in the sample.

Alpha is the percentage of the marginal data that will not be taken into consideration.

### Examples

=TRIMMEAN(A1:A50; 0.1) calculates the mean value of numbers in A1:A50, without taking into consideration the 5 percent of the values representing the highest values and the 5 percent of the values representing the lowest ones. The percentage numbers refer to the amount of the untrimmed mean value, not to the number of summands.

## ZTEST

Calculates the probability of observing a z-statistic greater than the one computed based on a sample.

### Syntax

ZTEST(Data; Number; Sigma)

Data is the given sample, drawn from a normally distributed population.

mu is the known mean of the population.

Sigma (optional) is the known standard deviation of the population. If omitted, the standard deviation of the given sample is used.

See also the Wiki page.

## ZTEST

Calculates the probability of observing a z-statistic greater than the one computed based on a sample.

### Syntax

ZTEST(Data; Number; Sigma)

Data is the given sample, drawn from a normally distributed population.

mu is the known mean of the population.

Sigma (optional) is the known standard deviation of the population. If omitted, the standard deviation of the given sample is used.

### Examples

=Z.TEST(A2:A20; 9; 2) returns the result of a z-test on a sample A2:A20 drawn from a population with known mean 9 and known standard deviation 2.