vegperiod: Determine vegetation period
In vegperiod: Determine Thermal Vegetation Periods
vegperiod R Documentation
Determine vegetation period
Description
Calculate start and end date of vegetation periods based on daily average
air temperature and the day of the year (DOY).
The sum of day degrees within the vegetation period is included for convenience.
Usage
vegperiod(
dates,
Tavg,
start.method,
end.method,
Tsum.out = FALSE,
Tsum.crit = 0,
species = NULL,
est.prev = 0,
check.data = TRUE
)
Arguments
dates
vector of calendar dates (objects of class Date or something
understood by as.Date()). Must contain entire years if est.prev > 0
else the first year may comprise only November and December.
Tavg
vector of daily average air temperatures in degree Celsius.
Same length as dates.
start.method
name of method to use for vegetation start. One of
"Menzel" (needs additional argument species, see below), "StdMeteo"
resp. "ETCCDI", "Ribes uva-crispa". Can be abbreviated (partial
matching). For further discussion see Details.
end.method
name of method to use for vegetation end. One of
"vonWilpert", "LWF-BROOK90", "NuskeAlbert" and "StdMeteo" resp.
"ETCCDI". Can be abbreviated (partial matching). For further discussion
see Details.
Tsum.out
boolean. Return the sum of daily mean temperatures above
Tsum.crit within vegetation period, also known as growing day degrees.
Tsum.crit
threshold for sum of day degrees. Only daily mean temperatures
> Tsum.crit will be tallied. The default of 0 prevents negative
daily temperatures from reducing the sum. Climate change studies often use
a threshold of 5.
species
name of tree species (required if start.method="Menzel"
ignored otherwise).
Must be one of "Larix decidua", "Picea abies (frueh)",
"Picea abies (spaet)", "Picea abies (noerdl.)", "Picea omorika",
"Pinus sylvestris", "Betula pubescens", "Quercus robur",
"Quercus petraea", "Fagus sylvatica".
est.prev
number of years to estimate previous year's chill
days for the first year (required if start.method="Menzel" ignored
otherwise).
Menzel requires the number of chill days of previous November and
December. If est.prev = 0 the first year is used to get the previous
year's chill days and dropped afterwards. Thus, a year from the time
series is lost. To avoid losing a year, est.prev = n estimates the
previous year's chill days for the first year from the average of n
first years of the time series.
check.data
Performs plausibility checks on the temperature data to
ensure that the temperatures have not been multiplied by ten.
Plausible range is -35 to +40°C.
Details
Common methods for determining the onset and end of thermal vegetation
periods are provided, for details see next sections. Popular choices with
regard to forest trees in Germany are Menzel and vonWilpert. Climate
change impact studies at NW-FVA are frequently conducted using Menzel with
"Picea abies (frueh)" and NuskeAlbert for all tree species; with tree
species specifics accounted for in subsequent statistical models.
Start methods:
The method Menzel implements the algorithm described in
Menzel (1997). The method is parameterized for 10 common tree species. It
needs previous year's chill days. ETCCDI resp.
StdMeteo is a simple threshold based procedure as defined by the
Expert Team on Climate Change Detection and Indices (cf. ETCCDI 2009, Frich
et al. 2002, Zhang et al. 2011) leading to quite early vegetation starts.
This method is widely used in climate change studies. The method
Ribes uva-crispa is based on leaf-out of gooseberry (Janssen
2009). It was developed by the Germany's National Meteorological Service
(Deutscher Wetterdienst, DWD) and is more robust against early starts than
common simple meteorological procedures.
End methods:
The end method vonWilpert is based on von Wilpert (1990). It
was originally developed for Picea abies in the Black Forest but is
commonly used for all tree species throughout Germany. As usual, the rules
regarding the soilmatrix are neglected in this implementation.
LWF-BROOK90 is -for the sake of convenience- a
reimplementation of the LWF-BROOK90 VBA (version 3.4) variant of "vonWilpert"
(Hammel and Kennel 2001). Their interpretation of von Wilpert (1990) and the
somewhat lower precision of VBA was mimicked. NuskeAlbert
provide a very simple method which is inspired by standard climatological
procedures but employs a 7 day moving average and a 5 °C threshold (cf.
Walther and Linderholm 2006). ETCCDI resp. StdMeteo
is a simple threshold based procedure as defined by the Expert Team on
Climate Change Detection and Indices (cf. ETCCDI 2009, Frich et al. 2002,
Zhang et al. 2011) leading to quite late vegetation ends.
Value
A data.frame with year and DOY of start and end day of
vegetation period. If Tsum.out=TRUE, the data.frame contains an
additional column with the sum of day degrees within vegetation periods.
References
ETCCDI (2009)
Climate Change Indices: Definitions of the 27 core indices.
http://etccdi.pacificclimate.org/list_27_indices.shtml
Frich, P., Alexander, L., Della-Marta, P., Gleason, B., Haylock, M.,
Klein Tank, A. and Peterson, T. (2002)
Observed coherent changes in climatic extremes during the second half of
the twentieth century.
Climate Research, 19, 193–212.
doi: 10.3354/cr019193.
Hammel, K. and Kennel, M. (2001)
Charakterisierung und Analyse der Wasserverfügbarkeit und des
Wasserhaushalts von Waldstandorten in Bayern mit dem Simulationsmodell
BROOK90.
Forstliche Forschungsberichte München.
Janssen, W. (2009)
Definition des Vegetationsanfanges.
Internal Report, Deutscher Wetterdienst, Abteilung Agrarmeteorologie.
Menzel, A. (1997)
Phänologie von Waldbäumen unter sich ändernden Klimabedingungen -
Auswertung der Beobachtungen in den Internationalen Phänologischen Gärten
und Möglichkeiten der Modellierung von Phänodaten.
Forstliche Forschungsberichte München.
von Wilpert, K. (1990)
Die Jahrringstruktur von Fichten in Abhängigkeit vom Bodenwasserhaushalt
auf Pseudogley und Parabraunerde: Ein Methodenkonzept zur Erfassung
standortsspezifischer Wasserstreßdispostion.
Freiburger Bodenkundliche Abhandlungen.
Walther, A. and Linderholm, H. W. (2006)
A comparison of growing season indices for the Greater Baltic Area.
International Journal of Biometeorology, 51(2), 107–118.
doi: 10.1007/s00484-006-0048-5.
Zhang, X., Alexander, L., Hegerl, G. C., Jones, P., Tank, A. K.,
Peterson, T. C., Trewin, B. and Zwiers, F. W. (2011)
Indices for monitoring changes in extremes based on daily temperature and
precipitation data.
Wiley Interdisciplinary Reviews: Climate Change, 2(6), 851–870.
doi: 10.1002/wcc.147.
Examples
data(goe)
vegperiod(dates=goe$date, Tavg=goe$t,
start.method="Menzel", end.method="vonWilpert",
species="Picea abies (frueh)", est.prev=5)
# take chill days from first year, which is then dropped
vegperiod(dates=goe$date, Tavg=goe$t, start="Menzel", end="vonWilpert",
species="Picea abies (frueh)", est.prev=0)
# add column with sum of day degrees in vegetation periods
vegperiod(dates=goe$date, Tavg=goe$t, Tsum.out=TRUE,
start="StdMeteo", end="StdMeteo")
vegperiod documentation built on Nov. 1, 2022, 5:07 p.m.
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| vegperiod | R Documentation |
Determine vegetation period
Description
Calculate start and end date of vegetation periods based on daily average air temperature and the day of the year (DOY). The sum of day degrees within the vegetation period is included for convenience.
Usage
vegperiod( dates, Tavg, start.method, end.method, Tsum.out = FALSE, Tsum.crit = 0, species = NULL, est.prev = 0, check.data = TRUE )
Arguments
dates |
vector of calendar dates (objects of class |
Tavg |
vector of daily average air temperatures in degree Celsius.
Same length as |
start.method |
name of method to use for vegetation start. One of
|
end.method |
name of method to use for vegetation end. One of
|
Tsum.out |
boolean. Return the sum of daily mean temperatures above
|
Tsum.crit |
threshold for sum of day degrees. Only daily mean temperatures
|
species |
name of tree species (required if Must be one of |
est.prev |
number of years to estimate previous year's chill
days for the first year (required if
|
check.data |
Performs plausibility checks on the temperature data to ensure that the temperatures have not been multiplied by ten. Plausible range is -35 to +40°C. |
Details
Common methods for determining the onset and end of thermal vegetation
periods are provided, for details see next sections. Popular choices with
regard to forest trees in Germany are Menzel and vonWilpert. Climate
change impact studies at NW-FVA are frequently conducted using Menzel with
"Picea abies (frueh)" and NuskeAlbert for all tree species; with tree
species specifics accounted for in subsequent statistical models.
Start methods:
The method Menzel implements the algorithm described in
Menzel (1997). The method is parameterized for 10 common tree species. It
needs previous year's chill days. ETCCDI resp.
StdMeteo is a simple threshold based procedure as defined by the
Expert Team on Climate Change Detection and Indices (cf. ETCCDI 2009, Frich
et al. 2002, Zhang et al. 2011) leading to quite early vegetation starts.
This method is widely used in climate change studies. The method
Ribes uva-crispa is based on leaf-out of gooseberry (Janssen
2009). It was developed by the Germany's National Meteorological Service
(Deutscher Wetterdienst, DWD) and is more robust against early starts than
common simple meteorological procedures.
End methods:
The end method vonWilpert is based on von Wilpert (1990). It
was originally developed for Picea abies in the Black Forest but is
commonly used for all tree species throughout Germany. As usual, the rules
regarding the soilmatrix are neglected in this implementation.
LWF-BROOK90 is -for the sake of convenience- a
reimplementation of the LWF-BROOK90 VBA (version 3.4) variant of "vonWilpert"
(Hammel and Kennel 2001). Their interpretation of von Wilpert (1990) and the
somewhat lower precision of VBA was mimicked. NuskeAlbert
provide a very simple method which is inspired by standard climatological
procedures but employs a 7 day moving average and a 5 °C threshold (cf.
Walther and Linderholm 2006). ETCCDI resp. StdMeteo
is a simple threshold based procedure as defined by the Expert Team on
Climate Change Detection and Indices (cf. ETCCDI 2009, Frich et al. 2002,
Zhang et al. 2011) leading to quite late vegetation ends.
Value
A data.frame with year and DOY of start and end day of
vegetation period. If Tsum.out=TRUE, the data.frame contains an
additional column with the sum of day degrees within vegetation periods.
References
ETCCDI (2009) Climate Change Indices: Definitions of the 27 core indices. http://etccdi.pacificclimate.org/list_27_indices.shtml
Frich, P., Alexander, L., Della-Marta, P., Gleason, B., Haylock, M., Klein Tank, A. and Peterson, T. (2002) Observed coherent changes in climatic extremes during the second half of the twentieth century. Climate Research, 19, 193–212. doi: 10.3354/cr019193.
Hammel, K. and Kennel, M. (2001) Charakterisierung und Analyse der Wasserverfügbarkeit und des Wasserhaushalts von Waldstandorten in Bayern mit dem Simulationsmodell BROOK90. Forstliche Forschungsberichte München.
Janssen, W. (2009) Definition des Vegetationsanfanges. Internal Report, Deutscher Wetterdienst, Abteilung Agrarmeteorologie.
Menzel, A. (1997) Phänologie von Waldbäumen unter sich ändernden Klimabedingungen - Auswertung der Beobachtungen in den Internationalen Phänologischen Gärten und Möglichkeiten der Modellierung von Phänodaten. Forstliche Forschungsberichte München.
von Wilpert, K. (1990) Die Jahrringstruktur von Fichten in Abhängigkeit vom Bodenwasserhaushalt auf Pseudogley und Parabraunerde: Ein Methodenkonzept zur Erfassung standortsspezifischer Wasserstreßdispostion. Freiburger Bodenkundliche Abhandlungen.
Walther, A. and Linderholm, H. W. (2006) A comparison of growing season indices for the Greater Baltic Area. International Journal of Biometeorology, 51(2), 107–118. doi: 10.1007/s00484-006-0048-5.
Zhang, X., Alexander, L., Hegerl, G. C., Jones, P., Tank, A. K., Peterson, T. C., Trewin, B. and Zwiers, F. W. (2011) Indices for monitoring changes in extremes based on daily temperature and precipitation data. Wiley Interdisciplinary Reviews: Climate Change, 2(6), 851–870. doi: 10.1002/wcc.147.
Examples
data(goe)
vegperiod(dates=goe$date, Tavg=goe$t,
start.method="Menzel", end.method="vonWilpert",
species="Picea abies (frueh)", est.prev=5)
# take chill days from first year, which is then dropped
vegperiod(dates=goe$date, Tavg=goe$t, start="Menzel", end="vonWilpert",
species="Picea abies (frueh)", est.prev=0)
# add column with sum of day degrees in vegetation periods
vegperiod(dates=goe$date, Tavg=goe$t, Tsum.out=TRUE,
start="StdMeteo", end="StdMeteo")
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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