dpoly: Polynomial dose-response function
In MBNMAdose: Dose-Response MBNMA Models
View source: R/dose.functions.R
dpoly R Documentation
Polynomial dose-response function
Description
Polynomial dose-response function
Usage
dpoly(
degree = 1,
beta.1 = "rel",
beta.2 = "rel",
beta.3 = "rel",
beta.4 = "rel"
)
Arguments
degree
The degree of the polynomial - e.g. degree=1 for linear, degree=2 for quadratic, degree=3 for cubic.
beta.1
Pooling for the 1st polynomial coefficient. Can take "rel", "common", "random" or be
assigned a numeric value (see details).
beta.2
Pooling for the 2nd polynomial coefficient. Can take "rel", "common", "random" or be
assigned a numeric value (see details).
beta.3
Pooling for the 3rd polynomial coefficient. Can take "rel", "common", "random" or be
assigned a numeric value (see details).
beta.4
Pooling for the 4th polynomial coefficient. Can take "rel", "common", "random" or be
assigned a numeric value (see details).
Details
-
\beta_1 represents the 1st coefficient.
-
\beta_2 represents the 2nd coefficient.
-
\beta_3 represents the 3rd coefficient.
-
\beta_4 represents the 4th coefficient.
Linear model:
\beta_1{x}
Quadratic model:
\beta_1{x} + \beta_2{x^2}
Cubic model:
\beta_1{x} + \beta_2{x^2} + \beta_3{x^3}
Quartic model:
\beta_1{x} + \beta_2{x^2} + \beta_3{x^3} + \beta_4{x^4}
Value
An object of class("dosefun")
Dose-response parameters
Argument Model specification
"rel" Implies that relative effects should be pooled for this dose-response parameter separately for each agent in the network.
"common" Implies that all agents share the same common effect for this dose-response parameter.
"random" Implies that all agents share a similar (exchangeable) effect for this dose-response parameter. This approach allows for modelling of variability between agents.
numeric() Assigned a numeric value, indicating that this dose-response parameter should not be estimated from the data but should be assigned the numeric value determined by the user. This can be useful for fixing specific dose-response parameters (e.g. Hill parameters in Emax functions) to a single value.
When relative effects are modelled on more than one dose-response parameter,
correlation between them is automatically estimated using a vague inverse-Wishart prior.
This prior can be made slightly more informative by specifying the scale matrix omega
and by changing the degrees of freedom of the inverse-Wishart prior
using the priors argument in mbnma.run().
References
\insertAllCited
Examples
# Linear model with random effects
dpoly(beta.1="rel")
# Quadratic model dose-response function
# with an exchangeable (random) absolute parameter estimated for the 2nd coefficient
dpoly(beta.1="rel", beta.2="random")
MBNMAdose documentation built on Aug. 8, 2023, 5:11 p.m.
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View source: R/dose.functions.R
| dpoly | R Documentation |
Polynomial dose-response function
Description
Polynomial dose-response function
Usage
dpoly(
degree = 1,
beta.1 = "rel",
beta.2 = "rel",
beta.3 = "rel",
beta.4 = "rel"
)
Arguments
degree |
The degree of the polynomial - e.g. |
beta.1 |
Pooling for the 1st polynomial coefficient. Can take |
beta.2 |
Pooling for the 2nd polynomial coefficient. Can take |
beta.3 |
Pooling for the 3rd polynomial coefficient. Can take |
beta.4 |
Pooling for the 4th polynomial coefficient. Can take |
Details
-
\beta_1represents the 1st coefficient. -
\beta_2represents the 2nd coefficient. -
\beta_3represents the 3rd coefficient. -
\beta_4represents the 4th coefficient.
Linear model:
\beta_1{x}
Quadratic model:
\beta_1{x} + \beta_2{x^2}
Cubic model:
\beta_1{x} + \beta_2{x^2} + \beta_3{x^3}
Quartic model:
\beta_1{x} + \beta_2{x^2} + \beta_3{x^3} + \beta_4{x^4}
Value
An object of class("dosefun")
Dose-response parameters
| Argument | Model specification |
"rel" | Implies that relative effects should be pooled for this dose-response parameter separately for each agent in the network. |
"common" | Implies that all agents share the same common effect for this dose-response parameter. |
"random" | Implies that all agents share a similar (exchangeable) effect for this dose-response parameter. This approach allows for modelling of variability between agents. |
numeric() | Assigned a numeric value, indicating that this dose-response parameter should not be estimated from the data but should be assigned the numeric value determined by the user. This can be useful for fixing specific dose-response parameters (e.g. Hill parameters in Emax functions) to a single value. |
When relative effects are modelled on more than one dose-response parameter,
correlation between them is automatically estimated using a vague inverse-Wishart prior.
This prior can be made slightly more informative by specifying the scale matrix omega
and by changing the degrees of freedom of the inverse-Wishart prior
using the priors argument in mbnma.run().
References
\insertAllCitedExamples
# Linear model with random effects
dpoly(beta.1="rel")
# Quadratic model dose-response function
# with an exchangeable (random) absolute parameter estimated for the 2nd coefficient
dpoly(beta.1="rel", beta.2="random")
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