UPDATE in V1.1.0: missing input data files added; relative paths to input data files changed to “../data/FILENAME”
A model that allows for representing key theories of Roman amphora reuse, to explore the differences in the distribution of amphorae, re-used amphorae and their contents.
This model generates simulated distributions of prime-use amphorae, primeuse contents (e.g. olive oil) and reused amphorae. These simulated distributions will differ between experiments depending on the experiment’s variable settings representing the tested theory: variations in the probability of reuse, the supply volume, the probability of reuse at ports. What we are interested in teasing out is what the effect is of each theory on the simulated amphora distributions.
The results presented in the related publication (Brughmans and Pecci in press) for all experiments were obtained after running the simulation for 1000 time steps, at which point the simulated distribution patterns have stabilized.
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
Release Notes
A model that allows for representing key theories of Roman amphora reuse, to explore the differences in the distribution of amphorae, re-used amphorae and their contents.
This model generates simulated distributions of prime-use amphorae, primeuse contents (e.g. olive oil) and reused amphorae. These simulated distributions will differ between experiments depending on the experiment’s variable settings representing the tested theory: variations in the probability of reuse, the supply volume, the probability of reuse at ports. What we are interested in teasing out is what the effect is of each theory on the simulated amphora distributions.
The results presented in the related publication (Brughmans and Pecci in press) for all experiments were obtained after running the simulation for 1000 time steps, at which point the simulated distribution patterns have stabilized.
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
Associated Publications
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
This release is out-of-date. The latest version is
1.1.0
Roman Amphora reuse 1.0.0
Submitted byTom BrughmansPublished Aug 07, 2019
Last modified Mar 15, 2023
UPDATE in V1.1.0: missing input data files added; relative paths to input data files changed to “../data/FILENAME”
A model that allows for representing key theories of Roman amphora reuse, to explore the differences in the distribution of amphorae, re-used amphorae and their contents.
This model generates simulated distributions of prime-use amphorae, primeuse contents (e.g. olive oil) and reused amphorae. These simulated distributions will differ between experiments depending on the experiment’s variable settings representing the tested theory: variations in the probability of reuse, the supply volume, the probability of reuse at ports. What we are interested in teasing out is what the effect is of each theory on the simulated amphora distributions.
The results presented in the related publication (Brughmans and Pecci in press) for all experiments were obtained after running the simulation for 1000 time steps, at which point the simulated distribution patterns have stabilized.
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
Release Notes
A model that allows for representing key theories of Roman amphora reuse, to explore the differences in the distribution of amphorae, re-used amphorae and their contents.
This model generates simulated distributions of prime-use amphorae, primeuse contents (e.g. olive oil) and reused amphorae. These simulated distributions will differ between experiments depending on the experiment’s variable settings representing the tested theory: variations in the probability of reuse, the supply volume, the probability of reuse at ports. What we are interested in teasing out is what the effect is of each theory on the simulated amphora distributions.
The results presented in the related publication (Brughmans and Pecci in press) for all experiments were obtained after running the simulation for 1000 time steps, at which point the simulated distribution patterns have stabilized.
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
References
Brughmans, T., & Pecci, A. (in press). An inconvenient truth. Evaluating the impact of amphora reuse through computational simulation modelling. In C. Duckworth & A. Wilson (Eds.), Recycling and the Ancient economy. Oxford studies on the Roman economy. Oxford: Oxford University Press.
Create an Open Code Badge that links to this model more info
This model has not been reviewed by CoMSES Net and should be independently reviewed to
meet the Open Code Badge guidelines.
You can use the following HTML or Markdown code to create an Open Code Badge that links to
version 1.0.0
of this computational model.
This website uses cookies and Google Analytics to help us track user engagement and improve our site. If
you'd like to know more information about what data we collect and why, please see
our data privacy policy. If you continue to use this site, you consent to
our use of cookies.
