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I've been struggling with converting scaled and centered model coefficients from a glmer model back to uncentered and unscaled values.

I analysed a dataset using GLMM in the lme4 (v1.1.7) package. It involves the calculation of maximum detection range of acoustic receivers and effect of environmental variables.

Sample data:

dd <-   structure(list(SUR.ID = c(10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 10186L, 
10186L, 10186L, 10186L, 10249L, 10249L, 10249L, 10249L, 10249L, 
10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 
10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 
10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 
10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 10249L, 
10249L, 10249L, 10249L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 10250L, 
10250L, 10250L, 10250L), Valid.detections = c(1L, 4L, 0L, 1L, 
6L, 7L, 0L, 1L, 0L, 0L, 6L, 5L, 3L, 5L, 0L, 0L, 1L, 0L, 0L, 0L, 
2L, 3L, 0L, 1L, 5L, 1L, 0L, 0L, 1L, 1L, 0L, 0L, 5L, 3L, 1L, 1L, 
0L, 0L, 5L, 8L, 0L, 1L, 0L, 0L, 3L, 7L, 1L, 2L, 7L, 0L, 7L, 6L, 
0L, 3L, 0L, 1L, 0L, 1L, 2L, 5L, 0L, 3L, 0L, 2L, 1L, 5L, 3L, 0L, 
0L, 2L, 0L, 0L, 0L, 0L, 0L, 3L, 4L, 0L, 2L, 2L, 0L, 3L, 0L, 0L, 
9L, 8L, 0L, 2L, 9L, 0L, 7L, 4L, 0L, 5L, 0L, 2L, 0L, 1L, 2L, 4L, 
3L, 2L, 1L, 1L, 3L, 4L, 1L, 2L, 1L, 3L, 0L, 0L, 0L, 6L, 0L, 5L, 
6L, 1L, 3L, 1L, 1L, 0L, 2L, 1L, 6L, 5L, 2L, 1L, 2L, 0L, 1L, 7L, 
5L, 4L, 1L, 0L, 0L, 1L, 0L, 0L, 1L, 1L, 0L, 4L, 2L, 6L, 0L, 0L, 
0L, 1L, 0L, 0L, 3L, 9L, 0L, 7L, 0L, 2L, 7L, 3L, 0L, 5L, 0L, 1L, 
1L, 9L, 2L, 9L, 1L, 0L, 6L, 1L, 0L, 1L, 0L, 0L, 0L, 0L, 3L, 13L, 
0L, 4L, 1L, 1L, 1L, 2L, 1L, 6L, 0L, 2L, 0L, 0L, 0L, 1L, 1L, 11L, 
5L, 0L, 6L, 5L), distance = c(200L, 200L, 200L, 200L, 100L, 100L, 
300L, 300L, 400L, 400L, 50L, 50L, 50L, 50L, 300L, 300L, 200L, 
200L, 400L, 400L, 200L, 200L, 100L, 100L, 100L, 100L, 300L, 300L, 
300L, 300L, 400L, 400L, 50L, 50L, 50L, 50L, 400L, 400L, 100L, 
100L, 200L, 200L, 200L, 200L, 100L, 100L, 100L, 100L, 50L, 300L, 
50L, 300L, 300L, 300L, 400L, 400L, 400L, 400L, 50L, 50L, 200L, 
200L, 200L, 100L, 200L, 100L, 100L, 100L, 300L, 300L, 400L, 400L, 
400L, 50L, 400L, 50L, 50L, 300L, 50L, 300L, 200L, 200L, 200L, 
200L, 100L, 100L, 100L, 100L, 50L, 300L, 50L, 300L, 300L, 300L, 
400L, 400L, 400L, 400L, 50L, 50L, 200L, 200L, 200L, 100L, 200L, 
100L, 100L, 100L, 300L, 300L, 400L, 400L, 400L, 50L, 400L, 50L, 
50L, 300L, 50L, 300L, 200L, 200L, 200L, 200L, 100L, 100L, 300L, 
300L, 400L, 400L, 50L, 50L, 50L, 50L, 300L, 300L, 200L, 200L, 
400L, 400L, 200L, 200L, 100L, 100L, 100L, 100L, 300L, 300L, 300L, 
300L, 400L, 400L, 50L, 50L, 50L, 50L, 400L, 400L, 100L, 100L, 
200L, 200L, 200L, 200L, 100L, 100L, 100L, 100L, 50L, 300L, 50L, 
300L, 300L, 300L, 400L, 400L, 400L, 400L, 50L, 50L, 200L, 200L, 
200L, 100L, 200L, 100L, 100L, 100L, 300L, 300L, 400L, 400L, 400L, 
50L, 400L, 50L, 50L, 300L, 50L, 300L), wind.speed = c(8.9939016, 
8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 
8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 
8.9939016, 8.9939016, 8.9939016, 10.8187512, 10.8187512, 8.9939016, 
8.9939016, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 
10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 
10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 
10.8187512, 8.9939016, 8.9939016, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 
8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 
8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 8.9939016, 
10.8187512, 10.8187512, 8.9939016, 8.9939016, 10.8187512, 10.8187512, 
10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 
10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 10.8187512, 
10.8187512, 10.8187512, 10.8187512, 10.8187512, 8.9939016, 8.9939016, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
2.389683519, 2.389683519, 2.389683519, 2.389683519, 2.389683519, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038, 
4.779367038, 4.779367038, 4.779367038, 4.779367038, 4.779367038
), receiver.depth = c(0.65, 0.65, 0.69, 0.69, 0.685, 0.685, 0.645, 
0.645, 0.645, 0.645, 0.67, 0.67, 0.665, 0.665, 0.705, 0.705, 
1.12, 1.12, 0.73, 0.73, 1.155, 1.155, 1.13, 1.13, 1.155, 1.155, 
1.105, 1.105, 1.155, 1.155, 1.095, 1.095, 1.145, 1.145, 1.14, 
1.14, 1.15, 1.15, 0.65, 0.65, 0.41, 0.41, 0.455, 0.455, 0.405, 
0.405, 0.49, 0.49, 0.415, 0.42, 0.415, 0.42, 0.45, 0.45, 0.43, 
0.43, 0.45, 0.45, 0.51, 0.51, 1.01, 1.01, 1.095, 1.045, 1.095, 
1.045, 1.09, 1.09, 1, 1, 0.975, 0.975, 1.08, 1.055, 1.08, 1.055, 
1.085, 1.095, 1.085, 1.095, 0.41, 0.41, 0.455, 0.455, 0.405, 
0.405, 0.49, 0.49, 0.415, 0.42, 0.415, 0.42, 0.45, 0.45, 0.43, 
0.43, 0.45, 0.45, 0.51, 0.51, 1.01, 1.01, 1.095, 1.045, 1.095, 
1.045, 1.09, 1.09, 1, 1, 0.975, 0.975, 1.08, 1.055, 1.08, 1.055, 
1.085, 1.095, 1.085, 1.095, 0.65, 0.65, 0.69, 0.69, 0.685, 0.685, 
0.645, 0.645, 0.645, 0.645, 0.67, 0.67, 0.665, 0.665, 0.705, 
0.705, 1.12, 1.12, 0.73, 0.73, 1.155, 1.155, 1.13, 1.13, 1.155, 
1.155, 1.105, 1.105, 1.155, 1.155, 1.095, 1.095, 1.145, 1.145, 
1.14, 1.14, 1.15, 1.15, 0.65, 0.65, 0.41, 0.41, 0.455, 0.455, 
0.405, 0.405, 0.49, 0.49, 0.415, 0.42, 0.415, 0.42, 0.45, 0.45, 
0.43, 0.43, 0.45, 0.45, 0.51, 0.51, 1.01, 1.01, 1.095, 1.045, 
1.095, 1.045, 1.09, 1.09, 1, 1, 0.975, 0.975, 1.08, 1.055, 1.08, 
1.055, 1.085, 1.095, 1.085, 1.095), water.temperature = c(20.33, 
20.33, 20.9, 20.9, 20.72, 20.72, 20.365, 20.365, 20.505, 20.505, 
20.445, 20.445, 20.62, 20.62, 20.88, 20.88, 22.775, 22.775, 20.92, 
20.92, 22.86, 22.86, 22.755, 22.755, 22.835, 22.835, 22.765, 
22.765, 22.86, 22.86, 22.78, 22.78, 22.835, 22.835, 22.78, 22.78, 
22.835, 22.835, 20.32, 20.32, 27.925, 27.925, 27.62, 27.62, 27.82, 
27.82, 27.58, 27.58, 27.67, 27.98, 27.67, 27.98, 27.63, 27.63, 
27.64, 27.64, 27.96, 27.96, 27.52, 27.52, 26.21, 26.21, 25.725, 
26.14, 25.725, 26.14, 25.605, 25.605, 26.205, 26.205, 26.255, 
26.255, 25.92, 26.07, 25.92, 26.07, 25.525, 25.795, 25.525, 25.795, 
27.925, 27.925, 27.62, 27.62, 27.82, 27.82, 27.58, 27.58, 27.67, 
27.98, 27.67, 27.98, 27.63, 27.63, 27.64, 27.64, 27.96, 27.96, 
27.52, 27.52, 26.21, 26.21, 25.725, 26.14, 25.725, 26.14, 25.605, 
25.605, 26.205, 26.205, 26.255, 26.255, 25.92, 26.07, 25.92, 
26.07, 25.525, 25.795, 25.525, 25.795, 20.33, 20.33, 20.9, 20.9, 
20.72, 20.72, 20.365, 20.365, 20.505, 20.505, 20.445, 20.445, 
20.62, 20.62, 20.88, 20.88, 22.775, 22.775, 20.92, 20.92, 22.86, 
22.86, 22.755, 22.755, 22.835, 22.835, 22.765, 22.765, 22.86, 
22.86, 22.78, 22.78, 22.835, 22.835, 22.78, 22.78, 22.835, 22.835, 
20.32, 20.32, 27.925, 27.925, 27.62, 27.62, 27.82, 27.82, 27.58, 
27.58, 27.67, 27.98, 27.67, 27.98, 27.63, 27.63, 27.64, 27.64, 
27.96, 27.96, 27.52, 27.52, 26.21, 26.21, 25.725, 26.14, 25.725, 
26.14, 25.605, 25.605, 26.205, 26.205, 26.255, 26.255, 25.92, 
26.07, 25.92, 26.07, 25.525, 25.795, 25.525, 25.795), Habitat = structure(c(1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 1L, 
1L, 1L, 1L, 1L, 1L, 1L, 1L), .Label = "Drug Channel", class = "factor"), 
    Distance = c(-0.078078746, -0.078078746, -0.078078746, -0.078078746, 
    -0.858866211, -0.858866211, 0.702708718, 0.702708718, 1.483496183, 
    1.483496183, -1.249259944, -1.249259944, -1.249259944, -1.249259944, 
    0.702708718, 0.702708718, -0.078078746, -0.078078746, 1.483496183, 
    1.483496183, -0.078078746, -0.078078746, -0.858866211, -0.858866211, 
    -0.858866211, -0.858866211, 0.702708718, 0.702708718, 0.702708718, 
    0.702708718, 1.483496183, 1.483496183, -1.249259944, -1.249259944, 
    -1.249259944, -1.249259944, 1.483496183, 1.483496183, -0.858866211, 
    -0.858866211, -0.078078746, -0.078078746, -0.078078746, -0.078078746, 
    -0.858866211, -0.858866211, -0.858866211, -0.858866211, -1.249259944, 
    0.702708718, -1.249259944, 0.702708718, 0.702708718, 0.702708718, 
    1.483496183, 1.483496183, 1.483496183, 1.483496183, -1.249259944, 
    -1.249259944, -0.078078746, -0.078078746, -0.078078746, -0.858866211, 
    -0.078078746, -0.858866211, -0.858866211, -0.858866211, 0.702708718, 
    0.702708718, 1.483496183, 1.483496183, 1.483496183, -1.249259944, 
    1.483496183, -1.249259944, -1.249259944, 0.702708718, -1.249259944, 
    0.702708718, -0.078078746, -0.078078746, -0.078078746, -0.078078746, 
    -0.858866211, -0.858866211, -0.858866211, -0.858866211, -1.249259944, 
    0.702708718, -1.249259944, 0.702708718, 0.702708718, 0.702708718, 
    1.483496183, 1.483496183, 1.483496183, 1.483496183, -1.249259944, 
    -1.249259944, -0.078078746, -0.078078746, -0.078078746, -0.858866211, 
    -0.078078746, -0.858866211, -0.858866211, -0.858866211, 0.702708718, 
    0.702708718, 1.483496183, 1.483496183, 1.483496183, -1.249259944, 
    1.483496183, -1.249259944, -1.249259944, 0.702708718, -1.249259944, 
    0.702708718, -0.078078746, -0.078078746, -0.078078746, -0.078078746, 
    -0.858866211, -0.858866211, 0.702708718, 0.702708718, 1.483496183, 
    1.483496183, -1.249259944, -1.249259944, -1.249259944, -1.249259944, 
    0.702708718, 0.702708718, -0.078078746, -0.078078746, 1.483496183, 
    1.483496183, -0.078078746, -0.078078746, -0.858866211, -0.858866211, 
    -0.858866211, -0.858866211, 0.702708718, 0.702708718, 0.702708718, 
    0.702708718, 1.483496183, 1.483496183, -1.249259944, -1.249259944, 
    -1.249259944, -1.249259944, 1.483496183, 1.483496183, -0.858866211, 
    -0.858866211, -0.078078746, -0.078078746, -0.078078746, -0.078078746, 
    -0.858866211, -0.858866211, -0.858866211, -0.858866211, -1.249259944, 
    0.702708718, -1.249259944, 0.702708718, 0.702708718, 0.702708718, 
    1.483496183, 1.483496183, 1.483496183, 1.483496183, -1.249259944, 
    -1.249259944, -0.078078746, -0.078078746, -0.078078746, -0.858866211, 
    -0.078078746, -0.858866211, -0.858866211, -0.858866211, 0.702708718, 
    0.702708718, 1.483496183, 1.483496183, 1.483496183, -1.249259944, 
    1.483496183, -1.249259944, -1.249259944, 0.702708718, -1.249259944, 
    0.702708718), Receiver.depth = c(-0.744681049, -0.744681049, 
    -0.612233214, -0.612233214, -0.628789194, -0.628789194, -0.761237028, 
    -0.761237028, -0.761237028, -0.761237028, -0.678457132, -0.678457132, 
    -0.695013111, -0.695013111, -0.562565277, -0.562565277, 0.811581001, 
    0.811581001, -0.47978538, -0.47978538, 0.927472856, 0.927472856, 
    0.84469296, 0.84469296, 0.927472856, 0.927472856, 0.761913064, 
    0.761913064, 0.927472856, 0.927472856, 0.728801105, 0.728801105, 
    0.894360898, 0.894360898, 0.877804918, 0.877804918, 0.910916877, 
    0.910916877, -0.744681049, -0.744681049, -1.539368053, -1.539368053, 
    -1.390364239, -1.390364239, -1.555924032, -1.555924032, -1.274472385, 
    -1.274472385, -1.522812073, -1.506256094, -1.522812073, -1.506256094, 
    -1.406920219, -1.406920219, -1.473144136, -1.473144136, -1.406920219, 
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    -0.854229153, -0.854229153, -0.854229153, -0.854229153)), .Names = c("SUR.ID", 
"Valid.detections", "distance", "wind.speed", "receiver.depth", 
"water.temperature", "Habitat", "Distance", "Receiver.depth", 
"Transmitter.depth", "Water.temperature", "Wind.speed"), class = "data.frame", row.names = c(NA, 
-200L))

Prior to data analysis, I needed to scale and center my predictors. I did this using:

scale(... , center=T, scale=T)

The scaled variables in df start with a capital, the unscaled don't.

The model that I obtained looks like this

m1 <- glmer(Valid.detections ~ Transmitter.depth + Receiver.depth + Water.temperature + 
                Wind.speed + Distance + (Distance | SUR.ID), data=df, family = poisson)

Now that I have all the coefficients of the predictors, I wish to calculate the distance at which the number of detections = y = 0, given certain environmental values (calculation not shown here).

x <- seq(from=1, to=1000)
X <- as.data.frame(x)     
 y <- exp(fixef(m2gg)["(Intercept)"] + fixef(m2gg)["Distance"]*X + fixef(m2gg)["Transmitter.depth"]*0.6067926 + 
      fixef(m2gg)["Receiver.depth"]*-0.1610828 + fixef(m2gg)["Water.temperature"]*-0.1128282 + 
      fixef(m2gg)["Wind.speed"]*-0.2959290)

However, since I scaled and centered all predictors, there's a need to "unscale" and "uncenter" the value of distance to make sense out of the calculated value for distance.

UPDATE:: While the parameter values above are fixed numbers, actually they are the values of only one receiver. Ultimately, I would like to calculate the maximum range of multiple receivers given random intercepts and random slopes for distance for each receiver, taken from the mini sample data below

sample2 <- structure(list(X.Intercept. = c(-0.101691254, -0.184443307), 
        distance = c(0.002089427, -0.00065884), SUR.ID = 10185:10186, 
        water.temperature = c(24.272, 24.272), transmitter.depth = c(1.54925, 
        1.54925), receiver.depth = c(0.82625, 0.82625), wind.speed = c(6.745425839, 
        6.745425839), Water.temperature = c(-0.112828232, -0.112828232
        ), Transmitter.depth = c(0.606792556, 0.606792556), Receiver.depth = c(-0.16108278, 
        -0.16108278), Wind.speed = c(-0.295928998, -0.295928998)), .Names = c("X.Intercept.", 
    "distance", "SUR.ID", "water.temperature", "transmitter.depth", 
    "receiver.depth", "wind.speed", "Water.temperature", "Transmitter.depth", 
    "Receiver.depth", "Wind.speed"), class = "data.frame", row.names = c(NA, 
    -2L))

I don't seem to be able to wrap your last 3 commands in a loop function that runs through the 3 commands as many times as there are receivers

L <- length(sample2$SUR.ID)
for (i in 1:L){
vals[i] <- '(Intercept)'=sample2[i,1],Transmitter.depth=sample2[i,11],
              Receiver.depth=sample2[i,8],Water.temperature=sample2[i,10],
              Wind.speed=sample2[i,13],distance=dist)
pred.obs[i] <- exp(cc %*% t(vals[i]))
max(dist[pred.obs>1])[i]
}
share|improve this question
    
does stackoverflow.com/questions/23642111/… answer your question? – Ben Bolker Jun 17 '14 at 17:24
    
@Ben: I should've included this information in my OP. I'm aware of this thread, since it's the only one that discusses unscaling. However, I do not understand your solution. By copy pasting your proposed solution to see how scaling and rescaling (unscaling?) works, I tried to understand it step by step. However, it doesn't seem to undo the scaling, as it doesn't produce the starting values of the predictors. – MvZB Jun 17 '14 at 19:10
    
Can you give a reproducible example ? Same data as stackoverflow.com/questions/23478792/… ? – Ben Bolker Jun 17 '14 at 20:30
    
@Ben: I updated my OP, and provided a reproducible example. It's similar to the data in my other post, but slightly more lean, and have scaled and centered predictors included. Thanks. – MvZB Jun 18 '14 at 7:47
up vote 3 down vote accepted

Read in data:

source("SO_unscale.txt")

Separate unscaled and scaled variables (Transmitter.depth doesn't appear to have a scaled variant)

unsc.vars <- subset(dd,select=c(Transmitter.depth,
                       receiver.depth,water.temperature,
                       wind.speed,distance))
sc.vars <- subset(dd,select=c(Transmitter.depth,
                     Receiver.depth,Water.temperature,
                     Wind.speed,Distance))

I noticed that the means and standard deviations of the scaled variables were not exactly 0/1, perhaps because what's here is a subset of the data. In any case, we will need the means and standard deviations of the original data in order to unscale.

colMeans(sc.vars)
apply(sc.vars,2,sd)
cm <- colMeans(unsc.vars)
csd <- apply(unsc.vars,2,sd)

It is possible to 'unscale' even if the new variables are not exactly centered/scaled (one would just need to enter the actual amount of the shift/scaling done), but it's marginally more complicated, so I'm just going to go ahead and fit with precisely centered/scaled variables.

## changed data name to dd
library(lme4)
cs. <- function(x) scale(x,center=TRUE,scale=TRUE)
m1 <- glmer(Valid.detections ~ Transmitter.depth +
            receiver.depth + water.temperature + 
            wind.speed + distance + (distance | SUR.ID),
            data=dd, family = poisson,
            control=glmerControl(optimizer=c("bobyqa","Nelder_Mead")))
## FAILS with bobyqa alone
m1.sc <- glmer(Valid.detections ~ cs.(Transmitter.depth) +
               cs.(receiver.depth) + cs.(water.temperature) + 
               cs.(wind.speed) + cs.(distance) + (cs.(distance) | SUR.ID),
               data=dd, family = poisson,
               control=glmerControl(optimizer=c("bobyqa","Nelder_Mead")))

An important point is that in this case the very different scaling doesn't seem to do any harm; the scaled and unscaled model get essentially the same goodness of fit (if it were important, we would expect the scaled fit to do better)

logLik(m1)-logLik(m1.sc)  ## 1e-7

Here is the rescaling function given in a previous answer:

rescale.coefs <- function(beta,mu,sigma) {
    beta2 <- beta ## inherit names etc.
    beta2[-1] <- sigma[1]*beta[-1]/sigma[-1]
    beta2[1]  <- sigma[1]*beta[1]+mu[1]-sum(beta2[-1]*mu[-1])
    beta2
}     

The parameters do indeed match very closely. (The shifting/scaling vectors include possible scaling/shifting of the response variable, so we start with 0/1 since the response is not scaled [it would rarely make sense to scale a response variable for a GLMM, but this function can be useful for LMMs too].)

(cc <- rescale.coefs(fixef(m1.sc),mu=c(0,cm),sigma=c(1,csd)))
##            (Intercept) cs.(Transmitter.depth)    cs.(receiver.depth) 
##            3.865879406            0.011158402           -0.554392645 
## cs.(water.temperature)        cs.(wind.speed)          cs.(distance) 
##           -0.050833325           -0.042188495           -0.007231021 

fixef(m1)
##  (Intercept) Transmitter.depth    receiver.depth water.temperature 
##  3.865816422       0.011180213      -0.554498582      -0.050830611 
##   wind.speed          distance 
## -0.042179333      -0.007231004 

Since they're the same (since the unscaled model does fit OK), we could use either set for this calculation.

ddist <- 1:1000
vals <- cbind(`(Intercept)`=1,Transmitter.depth=0.6067926,
          Receiver.depth=-0.1610828,Water.temperature=-0.1128282,
          Wind.speed=-0.2959290,distance=ddist)
pred.obs <- exp(cc %*% t(vals))
max(ddist[pred.obs>1])

Now suppose you want to do similar scaling/unscaling for a model with interactions or other complexities (i.e. the predictor variables, the columns of the fixed-effect model matrix, are not the same as the input variables, which are the variables that appear in the formula)

m2 <- update(m1,. ~ . + wind.speed:distance)
m2.sc <- update(m1.sc,. ~ . + I(cs.(wind.speed*distance)))
logLik(m2)-logLik(m2.sc)

Calculate mean/sd of model matrix, dropping the first (intercept) value:

X <- getME(m2,"X")                                        
cm2 <- colMeans(X)[-1]
csd2 <- apply(X,2,sd)[-1]                                            
(cc2 <- rescale.coefs(fixef(m2.sc),mu=c(0,cm2),sigma=c(1,csd2)))
all.equal(unname(cc2),unname(fixef(m2)),tol=1e-3)  ## TRUE

You don't actually have to fit the full unscaled model just to get the scaling parameters: you could use model.matrix([formula],data) to derive the model matrix. That is, if you haven't already fitted m2 and you want to get X to get the column means and standard deviations, i.e.

X <- model.matrix(Valid.detections ~ Transmitter.depth + receiver.depth +
                      water.temperature + 
                      wind.speed + distance + 
                      wind.speed:distance,
                  data=dd)

If you have a LMM/have scaled the response variable, you should also multiply all of the standard deviations (including the residual error, sigma(fitted_model)) by the original SD of the response variable.

share|improve this answer
    
Thank you, this is awesome! Once again you save the day. Exactly what I wanted. You are right, the unscaled transmitter depth is missing, but I get the point. – MvZB Jun 18 '14 at 14:11
    
I reran your script on my full dataset, fitting the unscaled and scaled model. I ran "(cc <- rescale.coefs(fixef(m1.sc),mu=c(0,cm),sigma=c(1,csd)))" to rescale 15 parameters. Unfortunately, I get returned a warning messageWarning messages: {1: In sigma[1] * beta[-1]/sigma[-1] : longer object length is not a multiple of shorter object length 2: In beta2[-1] * mu[-1] : longer object length is not a multiple of shorter object length} Do you perhaps know why this happens? Consequently, the rescaled parameter values look nowhere near the unscaled parameter values. – MvZB Jun 18 '14 at 15:09
    
hmm. have you compared length(fixef(m1.sc)), length(cm), length(csd)? I believe the latter should be one shorter than the former (the fixed effects include an intercept term; by design the mu and sigma arguments are the same length as beta, they contain one term for the scaling of the response plus terms for the scaling of each fixed-effect parameter). Perhaps you have a categorical variable or some other kind of 'derived' predictor variable in your model? – Ben Bolker Jun 18 '14 at 17:07
    
Yes, i have 3 categorical predictors and 6 interactions between categorical predictors and variables: length(fixef) = 15, length(cm) = 5, length(csd) = 5. And how do I take into account random intercept and slope? (please see the update in my OP) – MvZB Jun 19 '14 at 11:17
    
(1) you have to unscale based on the columns of the model matrix (i.e. technically speaking the predictor variables rather than the input variables; (2) taking account of the random effects is a bit of a can of worms, it might warrant another question (r-sig-mixed-models might be more appropriate), (3) if your scaled and unscaled models converge to the same likelihood then you can ignore the warning and don't have to fuss with all of this scaling stuff anyway. – Ben Bolker Jun 19 '14 at 12:08

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