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clam
1 is an age-depth modelling tool which
calibrates any radiocarbon dates, and then repeatedly chooses random age
estimates from the (radiocarbon or other) dates and draws curves through
them in order to estimate ages and their uncertainties.
clam
works through R (or Rstudio). The first time you
are using clam
on your computer, you will have to install
its R package, by typing within the terminal of R:
To use clam
, first the package has to be loaded (this
will also load its companion packages rice
and
rintcal
which deal with radiocarbon calibration):
## Loading required package: rice
The package comes with a pre-loaded dataset, called
Example
. Let’s start by running this default core, using
all default settings. Note R’s comments about where the files are going
to be placed, as we will need this information later. Press
y
and/or Enter
to accept any suggestions about
where it will place files, or alternatively provide a folder location
using the option coredir
.
## The run's files will be put in this folder: /private/var/folders/w_/ktch6mh953z13lmhs4_9bj_80000gn/T/RtmpYSswlI/Rbuild89495c1c21e/clam/vignettes/clam_runs/Example
##
## Warning, some dates lie partly outside the calibration curve!
## Calibrating dates...
## Interpolating, sampling.....
##
## Example's 95% confidence ranges span from 20 to 522 yr (average 226 yr)
## Fit (-log, lower is better): 6.36
clam
will calibrate any C-14 dates, sample the age
estimates, draw curves, calculate age ranges, produce graphs and provide
information about the confidence ranges. The output graph, above,
contains: the calibrated distributions in blue (and a green/blue cal BP
for the core’s surface), the age-depth model’s 95% ranges (grey
envelope) and its mean (black curve). Besides the graph, clam also
produces files containing age estimates (95% ranges and the mean) for
each depth (by default every cm from the top to the bottom core depth).
This file can be found in the core’s folder, together with files giving
the calibrated ranges for the dated depths.
Please don’t over-interpret the Fit value, which is also reported.
Sometimes age-depth models with low fit values, so with a good match of
the dates to the model, will still be unrealistic, e.g. with very abrupt
changes or even age reversals. Note also that the uncertainty estimates
provided by classical modelling are likely to be underestimates of the
true uncertainties2, and that Bayesian age-models such as
OxCal’s P Sequence
or R packages rbacon
or
BChron
are more robust alternatives which provide more
realistic error estimates.
There are many options to produce different types of age-depth
models. The default, type=1
, is linear interpolation
between the dated depths. Alternatives are linear or higher polynomial
regression (type=2
, the degree is set with the
smooth
parameter), cubic spline (type=3
),
smooth spline (type=4
) or locally weighted spline
(type=5
). Hiatuses can be set at specific depths using
hiatus
, and bits where sedimentation was abrupt can also be
modelled (slump
, e.g., tephra layers). If some dates appear
outlying they can be labelled such and excluded from the age-model
(e.g. if the sixth and ninth dates counting from the top one appear
outlying, type outliers=c(6,9)
). If you prefer your ages as
BC/AD, use BCAD=TRUE
. Note that such decisions can have
large impacts on the resulting age-depth model - please be critical
about your assumptions.
By default, ages are calculated for every cm from the top to the
bottom dated depth. This can be adapted by specifying dmin
,
dmax
, and every
(default 1). A file with
depths can also be provided. This must be in the core’s folder (see
later), start with the core’s name, and end in _depths.txt
.
Then use depths.file=TRUE
as option.
Here is an example using some of the above options:
## The run's files will be put in this folder: /private/var/folders/w_/ktch6mh953z13lmhs4_9bj_80000gn/T/RtmpYSswlI/Rbuild89495c1c21e/clam/vignettes/clam_runs/Example
##
## Warning, some dates lie partly outside the calibration curve!
## Calibrating dates...
##
## section 1,
## Using smoothing spline (smoothing 0.3), sampling
## .....
##
## section 2,
## extrapolating beyond dated levels, dangerous!
##
## Using smoothing spline (smoothing 0.3), sampling
## .....
##
## Warning, some dates lie partly outside the calibration curve!
##
## Example's 95% confidence ranges span from 29 to 1201 yr (average 374 yr)
## Fit (-log, lower is better): 7.43
When clam runs it will tell you where the files will be stored. The
default is to use an ‘umbrella’ folder called clam_runs
or
Cores
, and store the runs as folders within it. After
running the default core, a folder ‘Example’ will appear in the umbrella
folder, and this will contain the input and output files of the clam
run.
To run your own cores, make a new folder within the umbrella folder,
and save it under a name, e.g., MyCore
. Then place a file
called MyCore.csv
in that folder. This file will contain
the dates and should have the same formatting as the
Example.csv
file in the Example
folder. It has
headers and six fields (or seven if you want to include a variable
thickness
which will draw a rectangle showing the thickness
of the dated depth):
Lab ID | C14 age | cal age | error | offset | depth |
---|---|---|---|---|---|
surface | -50 | 5 | 0 | ||
GR0001 | 95 | 37 | 31 | ||
GR0002 | 410 | 45 | 135 | ||
GR0003 | 1502 | 37 | 298 | ||
GR0004 | 2167 | 42 | 365 |
Note that depths with radiocarbon dates should have the dates in the second/radiocarbon column, and no entry in the cal age column. Dates already on the calendar scale should be empty in the second column and have their entry in the third/cal age column. Leave the offset column empty if no offset is assumed. All dates must have an error estimate - this cannot be left empty. If you produce your file in a spreadsheet program such as MS-Excel or LibreOffice, please also check its formatting in a plain-text editor to see if all looks OK (e.g., no orphan quotation marks, no empty lines, not too many commas).
Then run clam("MyCore")
.
For more information and options, run ?clam
. If you have
any questions or ideas for improvements, please contact me at maarten.blaauw@qub.ac.uk.
If you use clam
in your publications, please cite Blaauw
20103,
the version used (e.g., 2.6.1), any non-default settings applied, and
for radiocarbon dates their calibration curves (e.g., IntCal204).
Blaauw, M., 2010. Methods and code for ‘classical’ age-modelling of radiocarbon sequences. Quaternary Geochronology 5, 512-518↩︎
Blaauw, M., Christen, J.A., Bennett, K.D., Reimer, P.J., 2018. Double the dates and go for Bayes – impacts of model choice, dating density and quality on chronologies. Quaternary Science Reviews 188, 58-66↩︎
Blaauw, M., 2010. Methods and code for ‘classical’ age-modelling of radiocarbon sequences. Quaternary Geochronology 5, 512-518↩︎
Reimer, P.J. et al., 2020. The IntCal20 Northern Hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon 62, 725-757↩︎
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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