sim_evans: Simulation of an Evans (1991) bubble process
In kvasilopoulos/exuber: Econometric Analysis of Explosive Time Series
sim_evans R Documentation
Simulation of an Evans (1991) bubble process
Description
Simulation of an Evans (1991) rational periodically collapsing bubble process.
Usage
sim_evans(
n,
alpha = 1,
delta = 0.5,
tau = 0.05,
pi = 0.7,
r = 0.05,
b1 = delta,
seed = NULL
)
Arguments
n
A positive integer specifying the length of the simulated output series.
alpha
A positive scalar, with restrictions (see details).
delta
A positive scalar, with restrictions (see details).
tau
The standard deviation of the innovations.
pi
A positive value in (0, 1) which governs the probability of the bubble continuing to grow.
r
A positive scalar that determines the growth rate of the bubble process.
b1
A positive scalar, the initial value of the series. Defaults to delta.
seed
An object specifying if and how the random number generator (rng)
should be initialized. Either NULL or an integer will be used in a call to
set.seed before simulation. If set, the value is saved as "seed" attribute
of the returned value. The default, NULL, will not change rng state, and
return .Random.seed as the "seed" attribute. Results are different between
the parallel and non-parallel option, even if they have the same seed.
Details
delta and alpha are positive parameters which satisfy 0 < \delta < (1+r)\alpha.
delta represents the size of the bubble after collapse.
The default value of r is 0.05.
The function checks whether alpha and delta satisfy this condition and will return an error if not.
The Evans bubble has two regimes. If B_t \leq \alpha the bubble grows at an average rate of 1 + r:
B_{t+1} = (1+r) B_t u_{t+1},
When B_t > \alpha the bubble expands at the increased rate of (1+r)\pi^{-1}:
B_{t+1} = [\delta + (1+r)\pi^{-1} \theta_{t+1}(B_t - (1+r)^{-1}\delta B_t )]u_{t+1},
where \theta theta is a binary variable that takes the value 0 with probability 1-\pi and 1 with probability \pi.
In the second phase, there is a (1-\pi) probability of the bubble process collapsing to delta.
By modifying the values of delta, alpha and pi the user can change the frequency at which bubbles appear, the mean duration of a bubble before collapse and the scale of the bubble.
Value
A numeric vector of length n.
References
Evans, G. W. (1991). Pitfalls in testing for explosive
bubbles in asset prices. The American Economic Review, 81(4), 922-930.
See Also
sim_psy1, sim_psy2, sim_blan
Examples
sim_evans(100, seed = 123) %>%
autoplot()
kvasilopoulos/exuber documentation built on March 18, 2024, 8:49 a.m.
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| sim_evans | R Documentation |
Simulation of an Evans (1991) bubble process
Description
Simulation of an Evans (1991) rational periodically collapsing bubble process.
Usage
sim_evans(
n,
alpha = 1,
delta = 0.5,
tau = 0.05,
pi = 0.7,
r = 0.05,
b1 = delta,
seed = NULL
)
Arguments
n |
A positive integer specifying the length of the simulated output series. |
alpha |
A positive scalar, with restrictions (see details). |
delta |
A positive scalar, with restrictions (see details). |
tau |
The standard deviation of the innovations. |
pi |
A positive value in (0, 1) which governs the probability of the bubble continuing to grow. |
r |
A positive scalar that determines the growth rate of the bubble process. |
b1 |
A positive scalar, the initial value of the series. Defaults to |
seed |
An object specifying if and how the random number generator (rng)
should be initialized. Either NULL or an integer will be used in a call to
|
Details
delta and alpha are positive parameters which satisfy 0 < \delta < (1+r)\alpha.
delta represents the size of the bubble after collapse.
The default value of r is 0.05.
The function checks whether alpha and delta satisfy this condition and will return an error if not.
The Evans bubble has two regimes. If B_t \leq \alpha the bubble grows at an average rate of 1 + r:
B_{t+1} = (1+r) B_t u_{t+1},
When B_t > \alpha the bubble expands at the increased rate of (1+r)\pi^{-1}:
B_{t+1} = [\delta + (1+r)\pi^{-1} \theta_{t+1}(B_t - (1+r)^{-1}\delta B_t )]u_{t+1},
where \theta theta is a binary variable that takes the value 0 with probability 1-\pi and 1 with probability \pi.
In the second phase, there is a (1-\pi) probability of the bubble process collapsing to delta.
By modifying the values of delta, alpha and pi the user can change the frequency at which bubbles appear, the mean duration of a bubble before collapse and the scale of the bubble.
Value
A numeric vector of length n.
References
Evans, G. W. (1991). Pitfalls in testing for explosive bubbles in asset prices. The American Economic Review, 81(4), 922-930.
See Also
sim_psy1, sim_psy2, sim_blan
Examples
sim_evans(100, seed = 123) %>%
autoplot()
R Package Documentation
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