photobiologyLamps

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Package ‘photobiologyLamps’ complements other packages in the R for photobiology suite. It contains spectral emission data for LED, fluorescent, incandescent and other lamps (lamps.mspct) in several collections of spectra.

Spectra in the package are contained in several collections, listed in the table below.

Collection Description n
lamps.mspct Spectra from imdividual lamps at full power and ambient temperature 67
amaran_m9.mspct Aputure Amaran M9 LED video lamp dimming 6
andoer_ir49.mspct Andoer IR LED photo/video lamp dimming 2
elgato_klm_cct.mspct ElGato Key Light Mini LED video lamp colour temperature 12
elgato_klm_dim.mspct ElGato Key Light Mini LED video lamp dimming 6
ledsavers.mspct LedSavers 4 channel LED bulb channel mixing 16
Nichia_LED_RECOM_dim.mspct Custom LED light source in Aralab plant-growth chamber, dimming 8
Osram_L_18W_840_temp.mspct White fluorescent tubes in Aralab plant-growth chamber at temperatures 5 C to 35 C 8
Percival_LED_dim.mspct White LEDs in Percival plant-growth chamber, dimming 11
qp_uvb313_temp.mspct and qp_uvb313_temp.spct Q-Panel UVB-313 UV-B fluorescent tubes at temperatures -5 C to 35 C 7
sunwayfoto_fl96.mspct Sunwayfoto FL96 LED fill light dimming and colour temperature 7

Collections of spectra in package ‘photobiologyLamps’. n gives the number of spectra. Collection lamps.mspct contains spectra for different lamps, one spectrum for each lamp. Each of the other collections contains multiple spectra measured under different conditions or settings from one lamp or luminaire.

The data are for the most part original but also include some spectra digitized from plots in manufacturers’ specifications. Data have been acquired over many years, although when possible lamps have been measured again after we acquired a spectrometer with improved wavelength resolution. It is important for users to be aware that depending on the optical wavelength resolution of the instruments used, spectra can look quite different because of the broadening of peaks. This is most obvious in lamps with narrow emission peaks like mercury vapours lamps. If you make use of the data, please inspect the metadata and read the documentation. The metadata is in most cases fairly complete, although the distance from lamps to the entrance optics is frequently unknown. For this reason some spectra have been normalized. The multiplier used for normalization is part of the metadata, making it possible to recover the original spectrum. The metadata includes, when available, a descriptor of the spectrometer and the settings used for acquiring the spectral data.

This package contains only data. Data are stored as collections of spectra of class source_mspct from package ‘photobiology’, which is the core of the R for photobiology suite. Spectra can be easily plotted with functions and methods from package ‘ggspectra’. The spectra can be used seamlesly with functions from package ‘photobiology’. However, class source_mspct is derived from list and class source_spct is derived from data.frame making the data also usable as is with base R functions.

Spectra for light emitting diodes (LEDs) and LED arrays (leds.mspct) available as electronic components are included in the companion package ‘photobioloyLEDs’.

Examples

library(ggspectra)
library(photobiologyLamps)
theme_set(theme_bw())

The package includes spectral data for several lamps.

length(lamps.mspct)
#> [1] 67

The members of the collections are named, and several vectors of names are available indexing lamps.mspct, such as by manufacturer,

Philips_lamps
#>  [1] "Philips.CF.PLS.11W.927"       "Philips.FT.TL.40W.01.uv"     
#>  [3] "Philips.FT.TL.40W.12"         "Philips.FT.TL.40W.12.uv"     
#>  [5] "Philips.FT.TL5.35W.830.HE"    "Philips.FT.TLD.36W.15"       
#>  [7] "Philips.FT.TLD.36W.18"        "Philips.FT.TLD.36W.18.lores" 
#>  [9] "Philips.FT.TLD.36W.83"        "Philips.FT.TLD.36W.89"       
#> [11] "Philips.FT.TLD.36W.92"        "Philips.FT.TLD.36W.965"      
#> [13] "Philips.FT.TLD.36W.BLB.108"   "Philips.FT.TLL.36W.950"      
#> [15] "Philips.Inc.50W.spot.halogen" "Philips.LED.T8.10W.840"

or type of lamp.

incandescent_lamps
#> [1] "Generic.Inc.bulb.60W"         "Osram.Inc.20W"               
#> [3] "Philips.Inc.50W.spot.halogen"

Response to temperature of UV-B fluorescent tubes.

what_measured(qp_uvb313_temp.mspct)
#> # A tibble: 7 × 2
#>   spct.idx what.measured                              
#>   <fct>    <chr>                                      
#> 1 minus05C Fluorescent tube: Q-Panel UVB313 40W at -5C
#> 2 plus00C  Fluorescent tube: Q-Panel UVB313 40W at 0C 
#> 3 plus05C  Fluorescent tube: Q-Panel UVB313 40W at 5C 
#> 4 plus10C  Fluorescent tube: Q-Panel UVB313 40W at 10C
#> 5 plus20C  Fluorescent tube: Q-Panel UVB313 40W at 20C
#> 6 plus30C  Fluorescent tube: Q-Panel UVB313 40W at 30C
#> 7 plus35C  Fluorescent tube: Q-Panel UVB313 40W at 35C

Different settings of a four-channel LED bulb, with its own indexing vectors of member names.

what_measured(ledsavers.mspct)
#> # A tibble: 16 × 2
#>    spct.idx      what.measured                                 
#>    <fct>         <chr>                                         
#>  1 B             LED lamp: LedSavers 7.5W four channels (WRGB).
#>  2 blue.green    LED lamp: LedSavers 7.5W four channels (WRGB).
#>  3 bluish.green  LED lamp: LedSavers 7.5W four channels (WRGB).
#>  4 cool.green    LED lamp: LedSavers 7.5W four channels (WRGB).
#>  5 dark.orange   LED lamp: LedSavers 7.5W four channels (WRGB).
#>  6 fuchsia       LED lamp: LedSavers 7.5W four channels (WRGB).
#>  7 G             LED lamp: LedSavers 7.5W four channels (WRGB).
#>  8 greenish.blue LED lamp: LedSavers 7.5W four channels (WRGB).
#>  9 orange        LED lamp: LedSavers 7.5W four channels (WRGB).
#> 10 pink          LED lamp: LedSavers 7.5W four channels (WRGB).
#> 11 purple        LED lamp: LedSavers 7.5W four channels (WRGB).
#> 12 R             LED lamp: LedSavers 7.5W four channels (WRGB).
#> 13 sand          LED lamp: LedSavers 7.5W four channels (WRGB).
#> 14 W             LED lamp: LedSavers 7.5W four channels (WRGB).
#> 15 warm.blue     LED lamp: LedSavers 7.5W four channels (WRGB).
#> 16 yellow        LED lamp: LedSavers 7.5W four channels (WRGB).

Different small video/photography LED lamps: sunwayfoto_fl96.mspct, elgato_klm_cct.mspct, elgato_klm_dim.mspct, amaran_m9.mspct and andoer_ir49.mspct. Each of these collections of spectra contains data for one lamp with different dimming and/or colour temperature settings.

The first example below shows you how to plot the emission spectrum of one of the lamps.

autoplot(lamps.mspct$Airam.CF.Spiraali.14W.3000K, geom = "spct",
         annotations = c("+", "title:what"))

The second example shows how to access metadata.

what_measured(lamps.mspct$Airam.CF.Spiraali.14W.3000K)
#> [1] "Compact fluorescent lamp: Airam CF Spiraali 14W 3000K"

Installation

Installation of the most recent stable version from CRAN:

install.packages("photobiologyLamps")

Installation of the current under development version from R-Universe CRAN-like repository (source and binaries available):

install.packages('photobiologyLamps', 
                 repos = c('https://aphalo.r-universe.dev', 
                           'https://cloud.r-project.org'))

Documentation

HTML documentation is available at (https://docs.r4photobiology.info/photobiologyLamps/), including a User Guide.

News on updates to the different packages of the ‘r4photobiology’ suite are regularly posted at (https://www.r4photobiology.info/).

Two articles introduce the basic ideas behind the design of the suite and describe its use: Aphalo P. J. (2015) (https://doi.org/10.19232/uv4pb.2015.1.14) and Aphalo P. J. (2016) (https://doi.org/10.19232/uv4pb.2016.1.15).

A book is under preparation, and the draft is currently available at (https://leanpub.com/r4photobiology/).

A handbook written before the suite was developed contains useful information on the quantification and manipulation of ultraviolet and visible radiation: Aphalo, P. J., Albert, A., Björn, L. O., McLeod, A. R., Robson, T. M., & Rosenqvist, E. (Eds.) (2012) Beyond the Visible: A handbook of best practice in plant UV photobiology (1st ed., p. xxx + 174). Helsinki: University of Helsinki, Department of Biosciences, Division of Plant Biology. ISBN 978-952-10-8363-1 (PDF), 978-952-10-8362-4 (paperback). PDF file available from (https://hdl.handle.net/10138/37558).

Contributing

Pull requests, bug reports, and feature requests are welcome at (https://github.com/aphalo/photobiologyLamps).

Citation

If you use this package to produce scientific or commercial publications, please cite according to:

citation("photobiologyLamps")
#> To cite package ‘photobiologyLamps’ in publications use:
#> 
#>   Aphalo, Pedro J. (2015) The r4photobiology suite. UV4Plants Bulletin,
#>   2015:1, 21-29. DOI:10.19232/uv4pb.2015.1.14
#> 
#> A BibTeX entry for LaTeX users is
#> 
#>   @Article{,
#>     author = {Pedro J. Aphalo},
#>     title = {The r4photobiology suite},
#>     journal = {UV4Plants Bulletin},
#>     volume = {2015},
#>     number = {1},
#>     pages = {21-29},
#>     year = {2015},
#>     doi = {10.19232/uv4pb.2015.1.14},
#>   }

License

© 2013-2025 Pedro J. Aphalo (pedro.aphalo@helsinki.fi). Released under the GPL, version 2 or greater. This software carries no warranty of any kind.