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R Software Module

rwasp_multipleregression.wasp

Title produced by software

Multiple Regression

Date of computation

Fri, 15 Dec 2017 13:34:21 +0100

Cite this page as follows

Statistical Computations at FreeStatistics.org, Office for Research Development and Education, URL https://freestatistics.org/blog/index.php?v=date/2017/Dec/15/t1513341272i0yt0tyv76tw4bs.htm/, Retrieved Wed, 15 May 2024 12:42:18 +0200

Statistical Computations at FreeStatistics.org, Office for Research Development and Education, URL https://freestatistics.org/blog/index.php?pk=, Retrieved Wed, 15 May 2024 12:42:18 +0200

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Estimated Impact

Dataseries X:

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Histogram

Boxplots

28.4	31.8	18160868.57
33.6	40.1	11237274
21.4	33.6	7202198
21.0	23.4	10538275
31.7	42.6	5659715
30.8	24.4	81197537
28.4	47.5	1314870
38.9	46.5	4628949
28.0	30.1	10858018
32.7	37.5	46449565
31.5	36.5	66488186
20.1	25.4	4225316
15.3	19.8	60795612
37.3	43.4	847008
22.3	40.1	1986096
31.5	45.3	2921262
41.1	41.1	562958
21.0	27.3	9855571
18.9	20.2	429344
35.7	35.0	16900726
32.0	29.1	8576261
22.8	32.6	38005614
18.4	26.9	10374822
16.4	17.9	19870647
24.0	36.7	2062874
18.4	23.9	5421349
36.0	49.6	5471753
33.0	46.7	9747355
40.1	43.1	64875165
31.7	46.5	329100
39.1	47.5	5166493
44.2	35.3	8237666

Summary of computational transaction
Raw Input	view raw input (R code)
Raw Output	view raw output of R engine
Computing time	8 seconds
R Server	Big Analytics Cloud Computing Center

\begin{tabular}{lllllllll}
\hline
Summary of computational transaction \tabularnewline
Raw Input view raw input (R code)  \tabularnewline
Raw Outputview raw output of R engine  \tabularnewline
Computing time8 seconds \tabularnewline
R ServerBig Analytics Cloud Computing Center \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=0

[TABLE]
[ROW]

Summary of computational transaction[/C][/ROW] [ROW]

Raw Input[/C]

view raw input (R code) [/C][/ROW] [ROW]

Raw Output[/C]

view raw output of R engine [/C][/ROW] [ROW]

Computing time[/C]

8 seconds[/C][/ROW] [ROW]

R Server[/C]

Big Analytics Cloud Computing Center[/C][/ROW] [/TABLE] Source: https://freestatistics.org/blog/index.php?pk=&T=0

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=0

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Summary of computational transaction
Raw Input	view raw input (R code)
Raw Output	view raw output of R engine
Computing time	8 seconds
R Server	Big Analytics Cloud Computing Center

Multiple Linear Regression - Estimated Regression Equation
Tertiary_educationM[t] = + 4.24142 + 0.666725Tertiary_education_F[t] + 7.08903e-08POPULATION[t] + e[t]
Warning: you did not specify the column number of the endogenous series! The first column was selected by default.

\begin{tabular}{lllllllll}
\hline
Multiple Linear Regression - Estimated Regression Equation \tabularnewline
Tertiary_educationM[t] =  +  4.24142 +  0.666725Tertiary_education_F[t] +  7.08903e-08POPULATION[t]  + e[t] \tabularnewline
Warning: you did not specify the column number of the endogenous series! The first column was selected by default. \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=1

[TABLE]
[ROW][C]Multiple Linear Regression - Estimated Regression Equation[/C][/ROW]
[ROW][C]Tertiary_educationM[t] =  +  4.24142 +  0.666725Tertiary_education_F[t] +  7.08903e-08POPULATION[t]  + e[t][/C][/ROW]
[ROW][C]Warning: you did not specify the column number of the endogenous series! The first column was selected by default.[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=1

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=1

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Multiple Linear Regression - Estimated Regression Equation
Tertiary_educationM[t] = + 4.24142 + 0.666725Tertiary_education_F[t] + 7.08903e-08POPULATION[t] + e[t]
Warning: you did not specify the column number of the endogenous series! The first column was selected by default.

Multiple Linear Regression - Ordinary Least Squares
Variable	Parameter	S.D.	T-STATH0: parameter = 0	2-tail p-value	1-tail p-value
(Intercept)	+4.241	4.194	+1.0110e+00	0.3202	0.1601
Tertiary_education_F	+0.6667	0.1083	+6.1580e+00	1.035e-06	5.173e-07
POPULATION	+7.089e-08	4.556e-08	+1.5560e+00	0.1306	0.0653

\begin{tabular}{lllllllll}
\hline
Multiple Linear Regression - Ordinary Least Squares \tabularnewline
Variable & Parameter & S.D. & T-STATH0: parameter = 0 & 2-tail p-value & 1-tail p-value \tabularnewline
(Intercept) & +4.241 &  4.194 & +1.0110e+00 &  0.3202 &  0.1601 \tabularnewline
Tertiary_education_F & +0.6667 &  0.1083 & +6.1580e+00 &  1.035e-06 &  5.173e-07 \tabularnewline
POPULATION & +7.089e-08 &  4.556e-08 & +1.5560e+00 &  0.1306 &  0.0653 \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=2

[TABLE]
[ROW][C]Multiple Linear Regression - Ordinary Least Squares[/C][/ROW]
[ROW][C]Variable[/C][C]Parameter[/C][C]S.D.[/C][C]T-STATH0: parameter = 0[/C][C]2-tail p-value[/C][C]1-tail p-value[/C][/ROW]
[ROW][C](Intercept)[/C][C]+4.241[/C][C] 4.194[/C][C]+1.0110e+00[/C][C] 0.3202[/C][C] 0.1601[/C][/ROW]
[ROW][C]Tertiary_education_F[/C][C]+0.6667[/C][C] 0.1083[/C][C]+6.1580e+00[/C][C] 1.035e-06[/C][C] 5.173e-07[/C][/ROW]
[ROW][C]POPULATION[/C][C]+7.089e-08[/C][C] 4.556e-08[/C][C]+1.5560e+00[/C][C] 0.1306[/C][C] 0.0653[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=2

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=2

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Multiple Linear Regression - Ordinary Least Squares
Variable	Parameter	S.D.	T-STATH0: parameter = 0	2-tail p-value	1-tail p-value
(Intercept)	+4.241	4.194	+1.0110e+00	0.3202	0.1601
Tertiary_education_F	+0.6667	0.1083	+6.1580e+00	1.035e-06	5.173e-07
POPULATION	+7.089e-08	4.556e-08	+1.5560e+00	0.1306	0.0653

Multiple Linear Regression - Regression Statistics
Multiple R	0.7527
R-squared	0.5666
Adjusted R-squared	0.5367
F-TEST (value)	18.96
F-TEST (DF numerator)	2
F-TEST (DF denominator)	29
p-value	5.426e-06
Multiple Linear Regression - Residual Statistics
Residual Standard Deviation	5.469
Sum Squared Residuals	867.5

\begin{tabular}{lllllllll}
\hline
Multiple Linear Regression - Regression Statistics \tabularnewline
Multiple R &  0.7527 \tabularnewline
R-squared &  0.5666 \tabularnewline
Adjusted R-squared &  0.5367 \tabularnewline
F-TEST (value) &  18.96 \tabularnewline
F-TEST (DF numerator) & 2 \tabularnewline
F-TEST (DF denominator) & 29 \tabularnewline
p-value &  5.426e-06 \tabularnewline
Multiple Linear Regression - Residual Statistics \tabularnewline
Residual Standard Deviation &  5.469 \tabularnewline
Sum Squared Residuals &  867.5 \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=3

[TABLE]
[ROW][C]Multiple Linear Regression - Regression Statistics[/C][/ROW]
[ROW][C]Multiple R[/C][C] 0.7527[/C][/ROW]
[ROW][C]R-squared[/C][C] 0.5666[/C][/ROW]
[ROW][C]Adjusted R-squared[/C][C] 0.5367[/C][/ROW]
[ROW][C]F-TEST (value)[/C][C] 18.96[/C][/ROW]
[ROW][C]F-TEST (DF numerator)[/C][C]2[/C][/ROW]
[ROW][C]F-TEST (DF denominator)[/C][C]29[/C][/ROW]
[ROW][C]p-value[/C][C] 5.426e-06[/C][/ROW]
[ROW][C]Multiple Linear Regression - Residual Statistics[/C][/ROW]
[ROW][C]Residual Standard Deviation[/C][C] 5.469[/C][/ROW]
[ROW][C]Sum Squared Residuals[/C][C] 867.5[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=3

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=3

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Multiple Linear Regression - Regression Statistics
Multiple R	0.7527
R-squared	0.5666
Adjusted R-squared	0.5367
F-TEST (value)	18.96
F-TEST (DF numerator)	2
F-TEST (DF denominator)	29
p-value	5.426e-06
Multiple Linear Regression - Residual Statistics
Residual Standard Deviation	5.469
Sum Squared Residuals	867.5

Menu of Residual Diagnostics
Description	Link
Histogram	Compute
Central Tendency	Compute
QQ Plot	Compute
Kernel Density Plot	Compute
Skewness/Kurtosis Test	Compute
Skewness-Kurtosis Plot	Compute
Harrell-Davis Plot	Compute
Bootstrap Plot -- Central Tendency	Compute
Blocked Bootstrap Plot -- Central Tendency	Compute
(Partial) Autocorrelation Plot	Compute
Spectral Analysis	Compute
Tukey lambda PPCC Plot	Compute
Box-Cox Normality Plot	Compute
Summary Statistics	Compute

\begin{tabular}{lllllllll}
\hline
Menu of Residual Diagnostics \tabularnewline
Description & Link \tabularnewline
Histogram & Compute \tabularnewline
Central Tendency & Compute \tabularnewline
QQ Plot & Compute \tabularnewline
Kernel Density Plot & Compute \tabularnewline
Skewness/Kurtosis Test & Compute \tabularnewline
Skewness-Kurtosis Plot & Compute \tabularnewline
Harrell-Davis Plot & Compute \tabularnewline
Bootstrap Plot -- Central Tendency & Compute \tabularnewline
Blocked Bootstrap Plot -- Central Tendency & Compute \tabularnewline
(Partial) Autocorrelation Plot & Compute \tabularnewline
Spectral Analysis & Compute \tabularnewline
Tukey lambda PPCC Plot & Compute \tabularnewline
Box-Cox Normality Plot & Compute \tabularnewline
Summary Statistics & Compute \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=4

[TABLE]
[ROW][C]Menu of Residual Diagnostics[/C][/ROW]
[ROW][C]Description[/C][C]Link[/C][/ROW]
[ROW][C]Histogram[/C][C]Compute[/C][/ROW]
[ROW][C]Central Tendency[/C][C]Compute[/C][/ROW]
[ROW][C]QQ Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Kernel Density Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Skewness/Kurtosis Test[/C][C]Compute[/C][/ROW]
[ROW][C]Skewness-Kurtosis Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Harrell-Davis Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Bootstrap Plot -- Central Tendency[/C][C]Compute[/C][/ROW]
[ROW][C]Blocked Bootstrap Plot -- Central Tendency[/C][C]Compute[/C][/ROW]
[ROW][C](Partial) Autocorrelation Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Spectral Analysis[/C][C]Compute[/C][/ROW]
[ROW][C]Tukey lambda PPCC Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Box-Cox Normality Plot[/C][C]Compute[/C][/ROW]
[ROW][C]Summary Statistics[/C][C]Compute[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=4

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=4

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Menu of Residual Diagnostics
Description	Link
Histogram	Compute
Central Tendency	Compute
QQ Plot	Compute
Kernel Density Plot	Compute
Skewness/Kurtosis Test	Compute
Skewness-Kurtosis Plot	Compute
Harrell-Davis Plot	Compute
Bootstrap Plot -- Central Tendency	Compute
Blocked Bootstrap Plot -- Central Tendency	Compute
(Partial) Autocorrelation Plot	Compute
Spectral Analysis	Compute
Tukey lambda PPCC Plot	Compute
Box-Cox Normality Plot	Compute
Summary Statistics	Compute

Multiple Linear Regression - Actuals, Interpolation, and Residuals
Time or Index	Actuals	InterpolationForecast	ResidualsPrediction Error
1	28.4	26.73	1.669
2	33.6	31.77	1.826
3	21.4	27.15	-5.754
4	21	20.59	0.4102
5	31.7	33.05	-1.345
6	30.8	26.27	4.534
7	28.4	36	-7.604
8	38.9	35.57	3.328
9	28	25.08	2.92
10	32.7	32.54	0.1636
11	31.5	33.29	-1.79
12	20.1	21.48	-1.376
13	15.3	21.75	-6.452
14	37.3	33.24	4.063
15	22.3	31.12	-8.818
16	31.5	34.65	-3.151
17	41.1	31.68	9.416
18	21	23.14	-2.142
19	18.9	17.74	1.16
20	35.7	28.77	6.925
21	32	24.25	7.749
22	22.8	28.67	-5.871
23	18.4	22.91	-4.512
24	16.4	17.58	-1.184
25	24	28.86	-4.856
26	18.4	20.56	-2.16
27	36	37.7	-1.699
28	33	36.07	-3.068
29	40.1	37.58	2.524
30	31.7	35.27	-3.567
31	39.1	36.28	2.823
32	44.2	28.36	15.84

\begin{tabular}{lllllllll}
\hline
Multiple Linear Regression - Actuals, Interpolation, and Residuals \tabularnewline
Time or Index & Actuals & InterpolationForecast & ResidualsPrediction Error \tabularnewline
1 &  28.4 &  26.73 &  1.669 \tabularnewline
2 &  33.6 &  31.77 &  1.826 \tabularnewline
3 &  21.4 &  27.15 & -5.754 \tabularnewline
4 &  21 &  20.59 &  0.4102 \tabularnewline
5 &  31.7 &  33.05 & -1.345 \tabularnewline
6 &  30.8 &  26.27 &  4.534 \tabularnewline
7 &  28.4 &  36 & -7.604 \tabularnewline
8 &  38.9 &  35.57 &  3.328 \tabularnewline
9 &  28 &  25.08 &  2.92 \tabularnewline
10 &  32.7 &  32.54 &  0.1636 \tabularnewline
11 &  31.5 &  33.29 & -1.79 \tabularnewline
12 &  20.1 &  21.48 & -1.376 \tabularnewline
13 &  15.3 &  21.75 & -6.452 \tabularnewline
14 &  37.3 &  33.24 &  4.063 \tabularnewline
15 &  22.3 &  31.12 & -8.818 \tabularnewline
16 &  31.5 &  34.65 & -3.151 \tabularnewline
17 &  41.1 &  31.68 &  9.416 \tabularnewline
18 &  21 &  23.14 & -2.142 \tabularnewline
19 &  18.9 &  17.74 &  1.16 \tabularnewline
20 &  35.7 &  28.77 &  6.925 \tabularnewline
21 &  32 &  24.25 &  7.749 \tabularnewline
22 &  22.8 &  28.67 & -5.871 \tabularnewline
23 &  18.4 &  22.91 & -4.512 \tabularnewline
24 &  16.4 &  17.58 & -1.184 \tabularnewline
25 &  24 &  28.86 & -4.856 \tabularnewline
26 &  18.4 &  20.56 & -2.16 \tabularnewline
27 &  36 &  37.7 & -1.699 \tabularnewline
28 &  33 &  36.07 & -3.068 \tabularnewline
29 &  40.1 &  37.58 &  2.524 \tabularnewline
30 &  31.7 &  35.27 & -3.567 \tabularnewline
31 &  39.1 &  36.28 &  2.823 \tabularnewline
32 &  44.2 &  28.36 &  15.84 \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=5

[TABLE]
[ROW][C]Multiple Linear Regression - Actuals, Interpolation, and Residuals[/C][/ROW]
[ROW][C]Time or Index[/C][C]Actuals[/C][C]InterpolationForecast[/C][C]ResidualsPrediction Error[/C][/ROW]
[ROW][C]1[/C][C] 28.4[/C][C] 26.73[/C][C] 1.669[/C][/ROW]
[ROW][C]2[/C][C] 33.6[/C][C] 31.77[/C][C] 1.826[/C][/ROW]
[ROW][C]3[/C][C] 21.4[/C][C] 27.15[/C][C]-5.754[/C][/ROW]
[ROW][C]4[/C][C] 21[/C][C] 20.59[/C][C] 0.4102[/C][/ROW]
[ROW][C]5[/C][C] 31.7[/C][C] 33.05[/C][C]-1.345[/C][/ROW]
[ROW][C]6[/C][C] 30.8[/C][C] 26.27[/C][C] 4.534[/C][/ROW]
[ROW][C]7[/C][C] 28.4[/C][C] 36[/C][C]-7.604[/C][/ROW]
[ROW][C]8[/C][C] 38.9[/C][C] 35.57[/C][C] 3.328[/C][/ROW]
[ROW][C]9[/C][C] 28[/C][C] 25.08[/C][C] 2.92[/C][/ROW]
[ROW][C]10[/C][C] 32.7[/C][C] 32.54[/C][C] 0.1636[/C][/ROW]
[ROW][C]11[/C][C] 31.5[/C][C] 33.29[/C][C]-1.79[/C][/ROW]
[ROW][C]12[/C][C] 20.1[/C][C] 21.48[/C][C]-1.376[/C][/ROW]
[ROW][C]13[/C][C] 15.3[/C][C] 21.75[/C][C]-6.452[/C][/ROW]
[ROW][C]14[/C][C] 37.3[/C][C] 33.24[/C][C] 4.063[/C][/ROW]
[ROW][C]15[/C][C] 22.3[/C][C] 31.12[/C][C]-8.818[/C][/ROW]
[ROW][C]16[/C][C] 31.5[/C][C] 34.65[/C][C]-3.151[/C][/ROW]
[ROW][C]17[/C][C] 41.1[/C][C] 31.68[/C][C] 9.416[/C][/ROW]
[ROW][C]18[/C][C] 21[/C][C] 23.14[/C][C]-2.142[/C][/ROW]
[ROW][C]19[/C][C] 18.9[/C][C] 17.74[/C][C] 1.16[/C][/ROW]
[ROW][C]20[/C][C] 35.7[/C][C] 28.77[/C][C] 6.925[/C][/ROW]
[ROW][C]21[/C][C] 32[/C][C] 24.25[/C][C] 7.749[/C][/ROW]
[ROW][C]22[/C][C] 22.8[/C][C] 28.67[/C][C]-5.871[/C][/ROW]
[ROW][C]23[/C][C] 18.4[/C][C] 22.91[/C][C]-4.512[/C][/ROW]
[ROW][C]24[/C][C] 16.4[/C][C] 17.58[/C][C]-1.184[/C][/ROW]
[ROW][C]25[/C][C] 24[/C][C] 28.86[/C][C]-4.856[/C][/ROW]
[ROW][C]26[/C][C] 18.4[/C][C] 20.56[/C][C]-2.16[/C][/ROW]
[ROW][C]27[/C][C] 36[/C][C] 37.7[/C][C]-1.699[/C][/ROW]
[ROW][C]28[/C][C] 33[/C][C] 36.07[/C][C]-3.068[/C][/ROW]
[ROW][C]29[/C][C] 40.1[/C][C] 37.58[/C][C] 2.524[/C][/ROW]
[ROW][C]30[/C][C] 31.7[/C][C] 35.27[/C][C]-3.567[/C][/ROW]
[ROW][C]31[/C][C] 39.1[/C][C] 36.28[/C][C] 2.823[/C][/ROW]
[ROW][C]32[/C][C] 44.2[/C][C] 28.36[/C][C] 15.84[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=5

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=5

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Multiple Linear Regression - Actuals, Interpolation, and Residuals
Time or Index	Actuals	InterpolationForecast	ResidualsPrediction Error
1	28.4	26.73	1.669
2	33.6	31.77	1.826
3	21.4	27.15	-5.754
4	21	20.59	0.4102
5	31.7	33.05	-1.345
6	30.8	26.27	4.534
7	28.4	36	-7.604
8	38.9	35.57	3.328
9	28	25.08	2.92
10	32.7	32.54	0.1636
11	31.5	33.29	-1.79
12	20.1	21.48	-1.376
13	15.3	21.75	-6.452
14	37.3	33.24	4.063
15	22.3	31.12	-8.818
16	31.5	34.65	-3.151
17	41.1	31.68	9.416
18	21	23.14	-2.142
19	18.9	17.74	1.16
20	35.7	28.77	6.925
21	32	24.25	7.749
22	22.8	28.67	-5.871
23	18.4	22.91	-4.512
24	16.4	17.58	-1.184
25	24	28.86	-4.856
26	18.4	20.56	-2.16
27	36	37.7	-1.699
28	33	36.07	-3.068
29	40.1	37.58	2.524
30	31.7	35.27	-3.567
31	39.1	36.28	2.823
32	44.2	28.36	15.84

Goldfeld-Quandt test for Heteroskedasticity
p-values	Alternative Hypothesis
breakpoint index	greater	2-sided	less
6	0.1918	0.3836	0.8082
7	0.2046	0.4092	0.7954
8	0.2509	0.5017	0.7491
9	0.183	0.366	0.817
10	0.1078	0.2155	0.8922
11	0.07477	0.1495	0.9252
12	0.04222	0.08444	0.9578
13	0.08252	0.165	0.9175
14	0.07083	0.1417	0.9292
15	0.1411	0.2822	0.8589
16	0.09952	0.199	0.9005
17	0.2295	0.4591	0.7705
18	0.161	0.3221	0.839
19	0.1038	0.2076	0.8962
20	0.1221	0.2443	0.8779
21	0.1679	0.3357	0.8321
22	0.1654	0.3308	0.8346
23	0.1322	0.2644	0.8678
24	0.08384	0.1677	0.9162
25	0.07181	0.1436	0.9282
26	0.6194	0.7611	0.3806

\begin{tabular}{lllllllll}
\hline
Goldfeld-Quandt test for Heteroskedasticity \tabularnewline
p-values & Alternative Hypothesis \tabularnewline
breakpoint index & greater & 2-sided & less \tabularnewline
6 &  0.1918 &  0.3836 &  0.8082 \tabularnewline
7 &  0.2046 &  0.4092 &  0.7954 \tabularnewline
8 &  0.2509 &  0.5017 &  0.7491 \tabularnewline
9 &  0.183 &  0.366 &  0.817 \tabularnewline
10 &  0.1078 &  0.2155 &  0.8922 \tabularnewline
11 &  0.07477 &  0.1495 &  0.9252 \tabularnewline
12 &  0.04222 &  0.08444 &  0.9578 \tabularnewline
13 &  0.08252 &  0.165 &  0.9175 \tabularnewline
14 &  0.07083 &  0.1417 &  0.9292 \tabularnewline
15 &  0.1411 &  0.2822 &  0.8589 \tabularnewline
16 &  0.09952 &  0.199 &  0.9005 \tabularnewline
17 &  0.2295 &  0.4591 &  0.7705 \tabularnewline
18 &  0.161 &  0.3221 &  0.839 \tabularnewline
19 &  0.1038 &  0.2076 &  0.8962 \tabularnewline
20 &  0.1221 &  0.2443 &  0.8779 \tabularnewline
21 &  0.1679 &  0.3357 &  0.8321 \tabularnewline
22 &  0.1654 &  0.3308 &  0.8346 \tabularnewline
23 &  0.1322 &  0.2644 &  0.8678 \tabularnewline
24 &  0.08384 &  0.1677 &  0.9162 \tabularnewline
25 &  0.07181 &  0.1436 &  0.9282 \tabularnewline
26 &  0.6194 &  0.7611 &  0.3806 \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=6

[TABLE]
[ROW][C]Goldfeld-Quandt test for Heteroskedasticity[/C][/ROW]
[ROW][C]p-values[/C][C]Alternative Hypothesis[/C][/ROW]
[ROW][C]breakpoint index[/C][C]greater[/C][C]2-sided[/C][C]less[/C][/ROW]
[ROW][C]6[/C][C] 0.1918[/C][C] 0.3836[/C][C] 0.8082[/C][/ROW]
[ROW][C]7[/C][C] 0.2046[/C][C] 0.4092[/C][C] 0.7954[/C][/ROW]
[ROW][C]8[/C][C] 0.2509[/C][C] 0.5017[/C][C] 0.7491[/C][/ROW]
[ROW][C]9[/C][C] 0.183[/C][C] 0.366[/C][C] 0.817[/C][/ROW]
[ROW][C]10[/C][C] 0.1078[/C][C] 0.2155[/C][C] 0.8922[/C][/ROW]
[ROW][C]11[/C][C] 0.07477[/C][C] 0.1495[/C][C] 0.9252[/C][/ROW]
[ROW][C]12[/C][C] 0.04222[/C][C] 0.08444[/C][C] 0.9578[/C][/ROW]
[ROW][C]13[/C][C] 0.08252[/C][C] 0.165[/C][C] 0.9175[/C][/ROW]
[ROW][C]14[/C][C] 0.07083[/C][C] 0.1417[/C][C] 0.9292[/C][/ROW]
[ROW][C]15[/C][C] 0.1411[/C][C] 0.2822[/C][C] 0.8589[/C][/ROW]
[ROW][C]16[/C][C] 0.09952[/C][C] 0.199[/C][C] 0.9005[/C][/ROW]
[ROW][C]17[/C][C] 0.2295[/C][C] 0.4591[/C][C] 0.7705[/C][/ROW]
[ROW][C]18[/C][C] 0.161[/C][C] 0.3221[/C][C] 0.839[/C][/ROW]
[ROW][C]19[/C][C] 0.1038[/C][C] 0.2076[/C][C] 0.8962[/C][/ROW]
[ROW][C]20[/C][C] 0.1221[/C][C] 0.2443[/C][C] 0.8779[/C][/ROW]
[ROW][C]21[/C][C] 0.1679[/C][C] 0.3357[/C][C] 0.8321[/C][/ROW]
[ROW][C]22[/C][C] 0.1654[/C][C] 0.3308[/C][C] 0.8346[/C][/ROW]
[ROW][C]23[/C][C] 0.1322[/C][C] 0.2644[/C][C] 0.8678[/C][/ROW]
[ROW][C]24[/C][C] 0.08384[/C][C] 0.1677[/C][C] 0.9162[/C][/ROW]
[ROW][C]25[/C][C] 0.07181[/C][C] 0.1436[/C][C] 0.9282[/C][/ROW]
[ROW][C]26[/C][C] 0.6194[/C][C] 0.7611[/C][C] 0.3806[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=6

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=6

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Goldfeld-Quandt test for Heteroskedasticity
p-values	Alternative Hypothesis
breakpoint index	greater	2-sided	less
6	0.1918	0.3836	0.8082
7	0.2046	0.4092	0.7954
8	0.2509	0.5017	0.7491
9	0.183	0.366	0.817
10	0.1078	0.2155	0.8922
11	0.07477	0.1495	0.9252
12	0.04222	0.08444	0.9578
13	0.08252	0.165	0.9175
14	0.07083	0.1417	0.9292
15	0.1411	0.2822	0.8589
16	0.09952	0.199	0.9005
17	0.2295	0.4591	0.7705
18	0.161	0.3221	0.839
19	0.1038	0.2076	0.8962
20	0.1221	0.2443	0.8779
21	0.1679	0.3357	0.8321
22	0.1654	0.3308	0.8346
23	0.1322	0.2644	0.8678
24	0.08384	0.1677	0.9162
25	0.07181	0.1436	0.9282
26	0.6194	0.7611	0.3806

Meta Analysis of Goldfeld-Quandt test for Heteroskedasticity
Description	# significant tests	% significant tests	OK/NOK
1% type I error level	0	0	OK
5% type I error level	0	0	OK
10% type I error level	1	0.047619	OK

\begin{tabular}{lllllllll}
\hline
Meta Analysis of Goldfeld-Quandt test for Heteroskedasticity \tabularnewline
Description & # significant tests & % significant tests & OK/NOK \tabularnewline
1% type I error level & 0 &  0 & OK \tabularnewline
5% type I error level & 0 & 0 & OK \tabularnewline
10% type I error level & 1 & 0.047619 & OK \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=7

[TABLE]
[ROW][C]Meta Analysis of Goldfeld-Quandt test for Heteroskedasticity[/C][/ROW]
[ROW][C]Description[/C][C]# significant tests[/C][C]% significant tests[/C][C]OK/NOK[/C][/ROW]
[ROW][C]1% type I error level[/C][C]0[/C][C] 0[/C][C]OK[/C][/ROW]
[ROW][C]5% type I error level[/C][C]0[/C][C]0[/C][C]OK[/C][/ROW]
[ROW][C]10% type I error level[/C][C]1[/C][C]0.047619[/C][C]OK[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=7

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=7

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Meta Analysis of Goldfeld-Quandt test for Heteroskedasticity
Description	# significant tests	% significant tests	OK/NOK
1% type I error level	0	0	OK
5% type I error level	0	0	OK
10% type I error level	1	0.047619	OK

Ramsey RESET F-Test for powers (2 and 3) of fitted values
> reset_test_fitted RESET test data: mylm RESET = 0.41259, df1 = 2, df2 = 27, p-value = 0.666
Ramsey RESET F-Test for powers (2 and 3) of regressors
> reset_test_regressors RESET test data: mylm RESET = 1.2117, df1 = 4, df2 = 25, p-value = 0.3307
Ramsey RESET F-Test for powers (2 and 3) of principal components
> reset_test_principal_components RESET test data: mylm RESET = 1.3371, df1 = 2, df2 = 27, p-value = 0.2795

\begin{tabular}{lllllllll}
\hline
Ramsey RESET F-Test for powers (2 and 3) of fitted values \tabularnewline
> reset_test_fitted
	RESET test
data:  mylm
RESET = 0.41259, df1 = 2, df2 = 27, p-value = 0.666
 \tabularnewline
Ramsey RESET F-Test for powers (2 and 3) of regressors \tabularnewline
> reset_test_regressors
	RESET test
data:  mylm
RESET = 1.2117, df1 = 4, df2 = 25, p-value = 0.3307
 \tabularnewline
Ramsey RESET F-Test for powers (2 and 3) of principal components \tabularnewline
> reset_test_principal_components
	RESET test
data:  mylm
RESET = 1.3371, df1 = 2, df2 = 27, p-value = 0.2795
 \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=8

[TABLE]
[ROW][C]Ramsey RESET F-Test for powers (2 and 3) of fitted values[/C][/ROW]
[ROW][C]> reset_test_fitted
	RESET test
data:  mylm
RESET = 0.41259, df1 = 2, df2 = 27, p-value = 0.666
[/C][/ROW]
[ROW][C]Ramsey RESET F-Test for powers (2 and 3) of regressors[/C][/ROW]
[ROW][C]> reset_test_regressors
	RESET test
data:  mylm
RESET = 1.2117, df1 = 4, df2 = 25, p-value = 0.3307
[/C][/ROW]
[ROW][C]Ramsey RESET F-Test for powers (2 and 3) of principal components[/C][/ROW]
[ROW][C]> reset_test_principal_components
	RESET test
data:  mylm
RESET = 1.3371, df1 = 2, df2 = 27, p-value = 0.2795
[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=8

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=8

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Ramsey RESET F-Test for powers (2 and 3) of fitted values
> reset_test_fitted RESET test data: mylm RESET = 0.41259, df1 = 2, df2 = 27, p-value = 0.666
Ramsey RESET F-Test for powers (2 and 3) of regressors
> reset_test_regressors RESET test data: mylm RESET = 1.2117, df1 = 4, df2 = 25, p-value = 0.3307
Ramsey RESET F-Test for powers (2 and 3) of principal components
> reset_test_principal_components RESET test data: mylm RESET = 1.3371, df1 = 2, df2 = 27, p-value = 0.2795

Variance Inflation Factors (Multicollinearity)
> vif Tertiary_education_F POPULATION 1.070978 1.070978

\begin{tabular}{lllllllll}
\hline
Variance Inflation Factors (Multicollinearity) \tabularnewline
> vif
Tertiary_education_F           POPULATION 
            1.070978             1.070978 
 \tabularnewline
\hline
\end{tabular}
%Source: https://freestatistics.org/blog/index.php?pk=&T=9

[TABLE]
[ROW][C]Variance Inflation Factors (Multicollinearity)[/C][/ROW]
[ROW][C]> vif
Tertiary_education_F           POPULATION 
            1.070978             1.070978 
[/C][/ROW]
[/TABLE]
Source: https://freestatistics.org/blog/index.php?pk=&T=9

Globally Unique Identifier (entire table): ba.freestatistics.org/blog/index.php?pk=&T=9

As an alternative you can also use a QR Code:

The GUIDs for individual cells are displayed in the table below:

Variance Inflation Factors (Multicollinearity)
> vif Tertiary_education_F POPULATION 1.070978 1.070978

Figure 1

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Figure 2

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Figure 3

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Figure 4

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Figure 5

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Figure 6

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Figure 7

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Figure 8

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Figure 9

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Figure 10

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Parameters (Session):

par1 = TRUE1pearsonpearson08888TRUEgreypearson11greygrey1pearsonpearsongrey11greygrey ; par2 = 2no0000noDo not include Seasonal DummiesDo not include Seasonal Dummiesnono80noDo not include Seasonal DummiesDo not include Seasonal Dummiesnono ; par3 = TRUE512No Linear TrendNo Linear TrendNo Linear TrendNo Linear Trend1e-08No Linear TrendNo Linear TrendNo Linear TrendNo Linear Trend ; par4 = 0000 ; par5 = 0000 ; par6 = 1212121212121212 ;

Parameters (R input):

par1 = grey ; par2 = no ; par3 = No Linear Trend ; par4 = ; par5 = ; par6 = 12 ;

R code (references can be found in the software module):

library(lattice)
library(lmtest)
library(car)
library(MASS)
n25 <- 25 #minimum number of obs. for Goldfeld-Quandt test
mywarning <- ''
par6 <- as.numeric(par6)
if(is.na(par6)) {
par6 <- 12
mywarning = 'Warning: you did not specify the seasonality. The seasonal period was set to s = 12.'
}
par1 <- as.numeric(par1)
if(is.na(par1)) {
par1 <- 1
mywarning = 'Warning: you did not specify the column number of the endogenous series! The first column was selected by default.'
}
if (par4=='') par4 <- 0
par4 <- as.numeric(par4)
if (!is.numeric(par4)) par4 <- 0
if (par5=='') par5 <- 0
par5 <- as.numeric(par5)
if (!is.numeric(par5)) par5 <- 0
x <- na.omit(t(y))
k <- length(x[1,])
n <- length(x[,1])
x1 <- cbind(x[,par1], x[,1:k!=par1])
mycolnames <- c(colnames(x)[par1], colnames(x)[1:k!=par1])
colnames(x1) <- mycolnames #colnames(x)[par1]
x <- x1
if (par3 == 'First Differences'){
(n <- n -1)
x2 <- array(0, dim=c(n,k), dimnames=list(1:n, paste('(1-B)',colnames(x),sep='')))
for (i in 1:n) {
for (j in 1:k) {
x2[i,j] <- x[i+1,j] - x[i,j]
}
}
x <- x2
}
if (par3 == 'Seasonal Differences (s)'){
(n <- n - par6)
x2 <- array(0, dim=c(n,k), dimnames=list(1:n, paste('(1-Bs)',colnames(x),sep='')))
for (i in 1:n) {
for (j in 1:k) {
x2[i,j] <- x[i+par6,j] - x[i,j]
}
}
x <- x2
}
if (par3 == 'First and Seasonal Differences (s)'){
(n <- n -1)
x2 <- array(0, dim=c(n,k), dimnames=list(1:n, paste('(1-B)',colnames(x),sep='')))
for (i in 1:n) {
for (j in 1:k) {
x2[i,j] <- x[i+1,j] - x[i,j]
}
}
x <- x2
(n <- n - par6)
x2 <- array(0, dim=c(n,k), dimnames=list(1:n, paste('(1-Bs)',colnames(x),sep='')))
for (i in 1:n) {
for (j in 1:k) {
x2[i,j] <- x[i+par6,j] - x[i,j]
}
}
x <- x2
}
if(par4 > 0) {
x2 <- array(0, dim=c(n-par4,par4), dimnames=list(1:(n-par4), paste(colnames(x)[par1],'(t-',1:par4,')',sep='')))
for (i in 1:(n-par4)) {
for (j in 1:par4) {
x2[i,j] <- x[i+par4-j,par1]
}
}
x <- cbind(x[(par4+1):n,], x2)
n <- n - par4
}
if(par5 > 0) {
x2 <- array(0, dim=c(n-par5*par6,par5), dimnames=list(1:(n-par5*par6), paste(colnames(x)[par1],'(t-',1:par5,'s)',sep='')))
for (i in 1:(n-par5*par6)) {
for (j in 1:par5) {
x2[i,j] <- x[i+par5*par6-j*par6,par1]
}
}
x <- cbind(x[(par5*par6+1):n,], x2)
n <- n - par5*par6
}
if (par2 == 'Include Seasonal Dummies'){
x2 <- array(0, dim=c(n,par6-1), dimnames=list(1:n, paste('M', seq(1:(par6-1)), sep ='')))
for (i in 1:(par6-1)){
x2[seq(i,n,par6),i] <- 1
}
x <- cbind(x, x2)
}
if (par2 == 'Include Monthly Dummies'){
x2 <- array(0, dim=c(n,11), dimnames=list(1:n, paste('M', seq(1:11), sep ='')))
for (i in 1:11){
x2[seq(i,n,12),i] <- 1
}
x <- cbind(x, x2)
}
if (par2 == 'Include Quarterly Dummies'){
x2 <- array(0, dim=c(n,3), dimnames=list(1:n, paste('Q', seq(1:3), sep ='')))
for (i in 1:3){
x2[seq(i,n,4),i] <- 1
}
x <- cbind(x, x2)
}
(k <- length(x[n,]))
if (par3 == 'Linear Trend'){
x <- cbind(x, c(1:n))
colnames(x)[k+1] <- 't'
}
print(x)
(k <- length(x[n,]))
head(x)
df <- as.data.frame(x)
(mylm <- lm(df))
(mysum <- summary(mylm))
if (n > n25) {
kp3 <- k + 3
nmkm3 <- n - k - 3
gqarr <- array(NA, dim=c(nmkm3-kp3+1,3))
numgqtests <- 0
numsignificant1 <- 0
numsignificant5 <- 0
numsignificant10 <- 0
for (mypoint in kp3:nmkm3) {
j <- 0
numgqtests <- numgqtests + 1
for (myalt in c('greater', 'two.sided', 'less')) {
j <- j + 1
gqarr[mypoint-kp3+1,j] <- gqtest(mylm, point=mypoint, alternative=myalt)$p.value
}
if (gqarr[mypoint-kp3+1,2] < 0.01) numsignificant1 <- numsignificant1 + 1
if (gqarr[mypoint-kp3+1,2] < 0.05) numsignificant5 <- numsignificant5 + 1
if (gqarr[mypoint-kp3+1,2] < 0.10) numsignificant10 <- numsignificant10 + 1
}
gqarr
}
bitmap(file='test0.png')
plot(x[,1], type='l', main='Actuals and Interpolation', ylab='value of Actuals and Interpolation (dots)', xlab='time or index')
points(x[,1]-mysum$resid)
grid()
dev.off()
bitmap(file='test1.png')
plot(mysum$resid, type='b', pch=19, main='Residuals', ylab='value of Residuals', xlab='time or index')
grid()
dev.off()
bitmap(file='test2.png')
sresid <- studres(mylm)
hist(sresid, freq=FALSE, main='Distribution of Studentized Residuals')
xfit<-seq(min(sresid),max(sresid),length=40)
yfit<-dnorm(xfit)
lines(xfit, yfit)
grid()
dev.off()
bitmap(file='test3.png')
densityplot(~mysum$resid,col='black',main='Residual Density Plot', xlab='values of Residuals')
dev.off()
bitmap(file='test4.png')
qqPlot(mylm, main='QQ Plot')
grid()
dev.off()
(myerror <- as.ts(mysum$resid))
bitmap(file='test5.png')
dum <- cbind(lag(myerror,k=1),myerror)
dum
dum1 <- dum[2:length(myerror),]
dum1
z <- as.data.frame(dum1)
print(z)
plot(z,main=paste('Residual Lag plot, lowess, and regression line'), ylab='values of Residuals', xlab='lagged values of Residuals')
lines(lowess(z))
abline(lm(z))
grid()
dev.off()
bitmap(file='test6.png')
acf(mysum$resid, lag.max=length(mysum$resid)/2, main='Residual Autocorrelation Function')
grid()
dev.off()
bitmap(file='test7.png')
pacf(mysum$resid, lag.max=length(mysum$resid)/2, main='Residual Partial Autocorrelation Function')
grid()
dev.off()
bitmap(file='test8.png')
opar <- par(mfrow = c(2,2), oma = c(0, 0, 1.1, 0))
plot(mylm, las = 1, sub='Residual Diagnostics')
par(opar)
dev.off()
if (n > n25) {
bitmap(file='test9.png')
plot(kp3:nmkm3,gqarr[,2], main='Goldfeld-Quandt test',ylab='2-sided p-value',xlab='breakpoint')
grid()
dev.off()
}
load(file='createtable')
a<-table.start()
a<-table.row.start(a)
a<-table.element(a, 'Multiple Linear Regression - Estimated Regression Equation', 1, TRUE)
a<-table.row.end(a)
myeq <- colnames(x)[1]
myeq <- paste(myeq, '[t] = ', sep='')
for (i in 1:k){
if (mysum$coefficients[i,1] > 0) myeq <- paste(myeq, '+', '')
myeq <- paste(myeq, signif(mysum$coefficients[i,1],6), sep=' ')
if (rownames(mysum$coefficients)[i] != '(Intercept)') {
myeq <- paste(myeq, rownames(mysum$coefficients)[i], sep='')
if (rownames(mysum$coefficients)[i] != 't') myeq <- paste(myeq, '[t]', sep='')
}
}
myeq <- paste(myeq, ' + e[t]')
a<-table.row.start(a)
a<-table.element(a, myeq)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, mywarning)
a<-table.row.end(a)
a<-table.end(a)
table.save(a,file='mytable1.tab')
a<-table.start()
a<-table.row.start(a)
a<-table.element(a,'Multiple Linear Regression - Ordinary Least Squares', 6, TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'Variable',header=TRUE)
a<-table.element(a,'Parameter',header=TRUE)
a<-table.element(a,'S.D.',header=TRUE)
a<-table.element(a,'T-STAT
H0: parameter = 0',header=TRUE)
a<-table.element(a,'2-tail p-value',header=TRUE)
a<-table.element(a,'1-tail p-value',header=TRUE)
a<-table.row.end(a)
for (i in 1:k){
a<-table.row.start(a)
a<-table.element(a,rownames(mysum$coefficients)[i],header=TRUE)
a<-table.element(a,formatC(signif(mysum$coefficients[i,1],5),format='g',flag='+'))
a<-table.element(a,formatC(signif(mysum$coefficients[i,2],5),format='g',flag=' '))
a<-table.element(a,formatC(signif(mysum$coefficients[i,3],4),format='e',flag='+'))
a<-table.element(a,formatC(signif(mysum$coefficients[i,4],4),format='g',flag=' '))
a<-table.element(a,formatC(signif(mysum$coefficients[i,4]/2,4),format='g',flag=' '))
a<-table.row.end(a)
}
a<-table.end(a)
table.save(a,file='mytable2.tab')
a<-table.start()
a<-table.row.start(a)
a<-table.element(a, 'Multiple Linear Regression - Regression Statistics', 2, TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'Multiple R',1,TRUE)
a<-table.element(a,formatC(signif(sqrt(mysum$r.squared),6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'R-squared',1,TRUE)
a<-table.element(a,formatC(signif(mysum$r.squared,6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'Adjusted R-squared',1,TRUE)
a<-table.element(a,formatC(signif(mysum$adj.r.squared,6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'F-TEST (value)',1,TRUE)
a<-table.element(a,formatC(signif(mysum$fstatistic[1],6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'F-TEST (DF numerator)',1,TRUE)
a<-table.element(a, signif(mysum$fstatistic[2],6))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'F-TEST (DF denominator)',1,TRUE)
a<-table.element(a, signif(mysum$fstatistic[3],6))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'p-value',1,TRUE)
a<-table.element(a,formatC(signif(1-pf(mysum$fstatistic[1],mysum$fstatistic[2],mysum$fstatistic[3]),6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'Multiple Linear Regression - Residual Statistics', 2, TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'Residual Standard Deviation',1,TRUE)
a<-table.element(a,formatC(signif(mysum$sigma,6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'Sum Squared Residuals',1,TRUE)
a<-table.element(a,formatC(signif(sum(myerror*myerror),6),format='g',flag=' '))
a<-table.row.end(a)
a<-table.end(a)
table.save(a,file='mytable3.tab')
myr <- as.numeric(mysum$resid)
myr
a <-table.start()
a <- table.row.start(a)
a <- table.element(a,'Menu of Residual Diagnostics',2,TRUE)
a <- table.row.end(a)
a <- table.row.start(a)
a <- table.element(a,'Description',1,TRUE)
a <- table.element(a,'Link',1,TRUE)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Histogram',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_histogram.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Central Tendency',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_centraltendency.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'QQ Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_fitdistrnorm.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Kernel Density Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_density.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Skewness/Kurtosis Test',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_skewness_kurtosis.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Skewness-Kurtosis Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_skewness_kurtosis_plot.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Harrell-Davis Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_harrell_davis.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Bootstrap Plot -- Central Tendency',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_bootstrapplot1.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Blocked Bootstrap Plot -- Central Tendency',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_bootstrapplot.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'(Partial) Autocorrelation Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_autocorrelation.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Spectral Analysis',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_spectrum.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Tukey lambda PPCC Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_tukeylambda.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <-table.element(a,'Box-Cox Normality Plot',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_boxcoxnorm.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a <- table.row.start(a)
a <- table.element(a,'Summary Statistics',1,header=TRUE)
a <- table.element(a,hyperlink( paste('https://supernova.wessa.net/rwasp_summary1.wasp?convertgetintopost=1&data=',paste(as.character(mysum$resid),sep='',collapse=' '),sep='') ,'Compute','Click here to examine the Residuals.'),1)
a <- table.row.end(a)
a<-table.end(a)
table.save(a,file='mytable7.tab')
if(n < 200) {
a<-table.start()
a<-table.row.start(a)
a<-table.element(a, 'Multiple Linear Regression - Actuals, Interpolation, and Residuals', 4, TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a, 'Time or Index', 1, TRUE)
a<-table.element(a, 'Actuals', 1, TRUE)
a<-table.element(a, 'Interpolation
Forecast', 1, TRUE)
a<-table.element(a, 'Residuals
Prediction Error', 1, TRUE)
a<-table.row.end(a)
for (i in 1:n) {
a<-table.row.start(a)
a<-table.element(a,i, 1, TRUE)
a<-table.element(a,formatC(signif(x[i],6),format='g',flag=' '))
a<-table.element(a,formatC(signif(x[i]-mysum$resid[i],6),format='g',flag=' '))
a<-table.element(a,formatC(signif(mysum$resid[i],6),format='g',flag=' '))
a<-table.row.end(a)
}
a<-table.end(a)
table.save(a,file='mytable4.tab')
if (n > n25) {
a<-table.start()
a<-table.row.start(a)
a<-table.element(a,'Goldfeld-Quandt test for Heteroskedasticity',4,TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'p-values',header=TRUE)
a<-table.element(a,'Alternative Hypothesis',3,header=TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'breakpoint index',header=TRUE)
a<-table.element(a,'greater',header=TRUE)
a<-table.element(a,'2-sided',header=TRUE)
a<-table.element(a,'less',header=TRUE)
a<-table.row.end(a)
for (mypoint in kp3:nmkm3) {
a<-table.row.start(a)
a<-table.element(a,mypoint,header=TRUE)
a<-table.element(a,formatC(signif(gqarr[mypoint-kp3+1,1],6),format='g',flag=' '))
a<-table.element(a,formatC(signif(gqarr[mypoint-kp3+1,2],6),format='g',flag=' '))
a<-table.element(a,formatC(signif(gqarr[mypoint-kp3+1,3],6),format='g',flag=' '))
a<-table.row.end(a)
}
a<-table.end(a)
table.save(a,file='mytable5.tab')
a<-table.start()
a<-table.row.start(a)
a<-table.element(a,'Meta Analysis of Goldfeld-Quandt test for Heteroskedasticity',4,TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'Description',header=TRUE)
a<-table.element(a,'# significant tests',header=TRUE)
a<-table.element(a,'% significant tests',header=TRUE)
a<-table.element(a,'OK/NOK',header=TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'1% type I error level',header=TRUE)
a<-table.element(a,signif(numsignificant1,6))
a<-table.element(a,formatC(signif(numsignificant1/numgqtests,6),format='g',flag=' '))
if (numsignificant1/numgqtests < 0.01) dum <- 'OK' else dum <- 'NOK'
a<-table.element(a,dum)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'5% type I error level',header=TRUE)
a<-table.element(a,signif(numsignificant5,6))
a<-table.element(a,signif(numsignificant5/numgqtests,6))
if (numsignificant5/numgqtests < 0.05) dum <- 'OK' else dum <- 'NOK'
a<-table.element(a,dum)
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'10% type I error level',header=TRUE)
a<-table.element(a,signif(numsignificant10,6))
a<-table.element(a,signif(numsignificant10/numgqtests,6))
if (numsignificant10/numgqtests < 0.1) dum <- 'OK' else dum <- 'NOK'
a<-table.element(a,dum)
a<-table.row.end(a)
a<-table.end(a)
table.save(a,file='mytable6.tab')
}
}
a<-table.start()
a<-table.row.start(a)
a<-table.element(a,'Ramsey RESET F-Test for powers (2 and 3) of fitted values',1,TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
reset_test_fitted <- resettest(mylm,power=2:3,type='fitted')
a<-table.element(a,paste('',RC.texteval('reset_test_fitted'),'
',sep=''))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'Ramsey RESET F-Test for powers (2 and 3) of regressors',1,TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
reset_test_regressors <- resettest(mylm,power=2:3,type='regressor')
a<-table.element(a,paste('',RC.texteval('reset_test_regressors'),'
',sep=''))
a<-table.row.end(a)
a<-table.row.start(a)
a<-table.element(a,'Ramsey RESET F-Test for powers (2 and 3) of principal components',1,TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
reset_test_principal_components <- resettest(mylm,power=2:3,type='princomp')
a<-table.element(a,paste('',RC.texteval('reset_test_principal_components'),'
',sep=''))
a<-table.row.end(a)
a<-table.end(a)
table.save(a,file='mytable8.tab')
a<-table.start()
a<-table.row.start(a)
a<-table.element(a,'Variance Inflation Factors (Multicollinearity)',1,TRUE)
a<-table.row.end(a)
a<-table.row.start(a)
vif <- vif(mylm)
a<-table.element(a,paste('',RC.texteval('vif'),'
',sep=''))
a<-table.row.end(a)
a<-table.end(a)
table.save(a,file='mytable9.tab')

Free Statistics

Description of Statistical Computation

Tree of Dependent Computations

Dataset

Tables (Output of Computation)

Figures (Output of Computation)

Input Parameters & R Code