Difference between revisions of "TI-BASIC:Tcdf"

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(Initial automated import)
 
 
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Alternatively, you can exploit the identity
 
Alternatively, you can exploit the identity
  
[[TI-BASIC:Math|Math]]
+
<math>
 
\operatorname{tcdf}(-\infty,0,\nu)=\frac1{2}
 
\operatorname{tcdf}(-\infty,0,\nu)=\frac1{2}
[[TI-BASIC:/math|/math]]
+
</math>
  
 
(similarly for the interval from 0 to ∞)
 
(similarly for the interval from 0 to ∞)
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and thus
 
and thus
  
[[TI-BASIC:Math|Math]]
+
<math>
 
\operatorname{tcdf}(-\infty,x,\nu)=\frac1{2}+\operatorname{tcdf}(0,x,\nu)
 
\operatorname{tcdf}(-\infty,x,\nu)=\frac1{2}+\operatorname{tcdf}(0,x,\nu)
[[TI-BASIC:/math|/math]]
+
</math>
  
 
For the form used in two-tailed tests, the following identity may be useful:
 
For the form used in two-tailed tests, the following identity may be useful:
  
[[TI-BASIC:Math|Math]]
+
<math>
 
\operatorname{tcdf}(-x,x,\nu)=2\operatorname{tcdf}(0,x,\nu)
 
\operatorname{tcdf}(-x,x,\nu)=2\operatorname{tcdf}(0,x,\nu)
[[TI-BASIC:/math|/math]]
+
</math>
  
 
= Formulas =
 
= Formulas =
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As with any other continuous distribution, tcdf( can be defined in terms of the probability density function, [[TI-BASIC:Tpdf|Tpdf(]]:
 
As with any other continuous distribution, tcdf( can be defined in terms of the probability density function, [[TI-BASIC:Tpdf|Tpdf(]]:
  
[[TI-BASIC:Math|Math]]
+
<math>
 
\operatorname{tcdf}(a,b,\nu)=\int_a^b \operatorname{tpdf}(t,\nu)\mathrm{d}t
 
\operatorname{tcdf}(a,b,\nu)=\int_a^b \operatorname{tpdf}(t,\nu)\mathrm{d}t
[[TI-BASIC:/math|/math]]
+
</math>
  
 
The function can also be expressed in terms of an [http://mathworld.wolfram.com/IncompleteBetaFunction.html incomplete beta function].
 
The function can also be expressed in terms of an [http://mathworld.wolfram.com/IncompleteBetaFunction.html incomplete beta function].
Line 51: Line 51:
 
For one degree of freedom (ν=1), tcdf( is expressible in terms of simpler functions:
 
For one degree of freedom (ν=1), tcdf( is expressible in terms of simpler functions:
  
[[TI-BASIC:Math|Math]]
+
<math>
 
\operatorname{tcdf}(a,b,1)=\frac1{\pi}\left(\tan^{-1}\left(b\right)-\tan^{-1}\left(a\right)\right)
 
\operatorname{tcdf}(a,b,1)=\frac1{\pi}\left(\tan^{-1}\left(b\right)-\tan^{-1}\left(a\right)\right)
[[TI-BASIC:/math|/math]]
+
</math>
  
 
This is the so-called Cauchy distribution.
 
This is the so-called Cauchy distribution.

Latest revision as of 19:24, 24 February 2016

TCDF.GIF

Command Summary

Calculates the Student's t probability betwen lower and upper for degrees of freedom ν.

Command Syntax

tcdf(lower, upper, ν)

Menu Location

Press:

  1. 2ND DISTR to access the distribution menu
  2. 5 to select tcdf(, or use arrows.

Press 6 instead of 5 on a TI-84+/SE with OS 2.30 or higher.

Calculator Compatibility

TI-83/84/+/SE

Token Size

2 bytes

tcdf( is the Student's t cumulative density function. If some random variable follows this distribution, you can use this command to find the probability that this variable will fall in the interval you supply.

Unlike Normalcdf(, this command only works for the standardized distribution with mean 0 and standard deviation 1. To use it for non-standardized values you will have to standardize them by calculating (X-μ)/σ (where μ is the mean and σ the standard deviation). Do this for both lower and upper.

Advanced

Often, you want to find a "tail probability" - a special case for which the interval has no lower or no upper bound (the form frequently used in one-tailed tests). For example, "what is the probability x is greater than 2?". The TI-83+ has no special symbol for infinity, but you can use E99 to get a very large number that will work equally well in this case (E is the decimal exponent obtained by pressing [2nd] [EE]). Use E99 for +∞, and -E99 for -∞.

Alternatively, you can exploit the identity

<math> \operatorname{tcdf}(-\infty,0,\nu)=\frac1{2} </math>

(similarly for the interval from 0 to ∞)

and thus

<math> \operatorname{tcdf}(-\infty,x,\nu)=\frac1{2}+\operatorname{tcdf}(0,x,\nu) </math>

For the form used in two-tailed tests, the following identity may be useful:

<math> \operatorname{tcdf}(-x,x,\nu)=2\operatorname{tcdf}(0,x,\nu) </math>

Formulas

As with any other continuous distribution, tcdf( can be defined in terms of the probability density function, Tpdf(:

<math> \operatorname{tcdf}(a,b,\nu)=\int_a^b \operatorname{tpdf}(t,\nu)\mathrm{d}t </math>

The function can also be expressed in terms of an incomplete beta function.

For one degree of freedom (ν=1), tcdf( is expressible in terms of simpler functions:

<math> \operatorname{tcdf}(a,b,1)=\frac1{\pi}\left(\tan^{-1}\left(b\right)-\tan^{-1}\left(a\right)\right) </math>

This is the so-called Cauchy distribution.

Related Commands