HP 50g Graphing Calculator User Manual

Page 18-53

Θ Confidence limits for regression coefficients:

For the slope (

Β): b − (t

n-2,

α/2

)

⋅s

e

/

√S

xx

<

Β < b + (t

n-2,

α/2

)

⋅s

e

/

√S

xx

,

For the intercept (

Α):

a

− (t

n-2,

α/2

)

⋅s

e

⋅[(1/n)+⎯x

2

/S

xx

]

1/2

<

Α < a + (t

n-2,

α/2

)

⋅s

e

⋅[(1/n)+⎯x

2

/

S

xx

]

1/2

, where t follows the Student’s t distribution with

ν = n – 2, degrees

of freedom, and n represents the number of points in the sample.

Θ Hypothesis testing on the slope, Β:

Null hypothesis, H

0

:

Β = Β

0

, tested against the alternative hypothesis, H

1

:

Β ≠ Β

0

. The test statistic is t

0

= (b -

Β

0

)/(s

e

/

√S

xx

), where t follows the

Student’s t distribution with

ν = n – 2, degrees of freedom, and n represents

the number of points in the sample. The test is carried out as that of a
mean value hypothesis testing, i.e., given the level of significance,

α,

determine the critical value of t, t

α/2

, then, reject H

0

if t

0

> t

α/2

or if t

0

< -

t

α/2

.

If you test for the value

Β

0

= 0, and it turns out that the test suggests that you

do not reject the null hypothesis, H

0

:

Β = 0, then, the validity of a linear

regression is in doubt. In other words, the sample data does not support
the assertion that

Β ≠ 0. Therefore, this is a test of the significance of the

regression model.

Θ Hypothesis testing on the intercept , Α:

Null hypothesis, H

0

:

Α = Α

0

, tested against the alternative hypothesis, H

1

:

Α ≠ Α

0

. The test statistic is t

0

= (a-

Α

0

)/[(1/n)+

⎯x

2

/S

xx

]

1/2

, where t follows

the Student’s t distribution with

ν = n – 2, degrees of freedom, and n

represents the number of points in the sample. The test is carried out as
that of a mean value hypothesis testing, i.e., given the level of significance,

α, determine the critical value of t, t

α/2

, then, reject H

0

if t

0

> t

α/2

or if t

0

<

- t

α/2

.

Θ Confidence interval for the mean value of Y at x = x

0

, i.e.,

α+βx

0

:

a+b

⋅x−(t

n-2,

α/2

)

⋅s

e

⋅[(1/n)+(x

0

-

⎯x)

2

/S

xx

]

1/2

<

α+βx

0

<

a+b

⋅x+(t

n-2,

α /2

)

⋅s

e

⋅[(1/n)+(x

0

-

⎯x)

2

/S

xx

]

1/2

.

Θ Limits of prediction: confidence interval for the predicted value Y

0

=Y(x

0

):

a+b

⋅x−(t

n-2,

α/2

)

⋅s

e

⋅[1+(1/n)+(x

0

-

⎯x)

2

/S

xx

]

1/2

< Y

0

<