Fowler–Yang equations: Difference between revisions

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'''Relative growth rate''' ('''RGR''') is the growth rate relative to the size of the population. It is also called the [[exponential growth]] rate, or the continuous growth rate. In terms of differential equations, if <math>P</math> is the population, and <math>\frac{dP}{dt}</math> its growth rate, then its relative growth rate is <math>\frac{1}{P}\frac{dP}{dt}</math>. If the relative growth rate is constant, i.e., <math>\frac{1}{P}\frac{dP}{dt} = k</math>, it is not difficult to verify that the solution to this equation is <math>P(t) = exp(kt)</math>. When calculating or discussing relative growth rate, it is important to pay attention to the units of time being considered.<ref name="BriggsCochran2011">{{cite book|author1=William L. Briggs|author2=Lyle Cochran|author3=Bernard Gillett|title=Calculus: Early Transcendentals|url=http://books.google.com/books/about/Single_Variable_Calculus.html?id=_cMLQgAACAAJ|accessdate=24 September 2012|year=2011|publisher=Pearson Education, Limited|page= 441|isbn=978-0-321-57056-7}}</ref>
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For example, if an initial population of <math>P_0</math> bacteria doubles every twenty minutes, then at time <math>t</math> it is given by the equation <math>P(t) = P_0 2^t = P_0 exp(ln(2)t)</math> where <math>t</math> is the number of twenty-minute intervals that have passed. However, we usually prefer to measure time in hours or minutes, and it is not difficult to change the units of time.  For example, since 1 hour is 3, twenty-minute intervals, the population in one hour is <math>P(3)=P_0 2^3</math>.  The hourly growth factor is 8, which means that for every 1 at the beginning of the hour, there are 8 by the end.  Indeed <math>P(T) = P_0 8^T = P_0 exp(ln(8)T)</math> where <math>T</math> is measured in hours, and the relative growth rate may be expressed as <math>ln(2)</math> or approximately 69% per twenty minutes, and as <math>ln(8)</math> or approximately 208% per hour.<ref name="BriggsCochran2011"/>
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In [[plant physiology]], RGR is a measure used to quantify the speed of plant growth. It is measured as the mass increase per aboveground biomass per day, for example as g g<sup>−1</sup> d<sup>−1</sup>. It is considered to be the most widely used way of estimating plant growth, but has been criticised as calculations typically involve the destructive harvest of plants.<ref name=hoffman>{{cite doi|10.1093/aob/mcf140}}</ref> Another problem is that RGR nearly always decreases over time as the biomass of a plant increases, but traditionally this has been ignored when modelling plant growth. The RGR decreases for several reasons - non-photosynthetic biomass (roots and stems) increases, the top leaves of a plant begin to shade lower leaves and soil nutrients can become limiting. Overall, respiration scales with total biomass, but photosynthesis only scales with photosynthetic biomass and as a result biomass accumulates more slowly as total biomass increases.<ref>{{cite doi|10.1111/j.2041-210X.2011.00155.x}}</ref> The RGR of trees in particular slow with increasing size due in part to the large allocation to structural material of the trunk required to hold photosynthetic material up in the canopy. A novel approach to separate size effects from intrinsic growth differences is implemented and described in detail in Philipson ''et al.'' (2012).<ref>Christopher D. Philipson, Philippe Saner, Toby R. Marthews, Reuben Nilus, Glen Reynolds, Lindsay A. Turnbull, Andy Hector (2012) Light-based regeneration niches: evidence from 21 dipterocarp species using size-specific RGRs. Biotropica. doi:10.1111/j.1744-7429.2011.00833.x
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http://onlinelibrary.wiley.com/doi/10.1111/j.1744-7429.2011.00833.x/abstract;jsessionid=49E8727AE3DD4F0E2A0BD887E972B84F.d03t03</ref>
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RGR is calculated using the following equation:<ref name=hoffman/>
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RGR = (ln W2 - ln W1)/(t2-t1)
 
Where:
 
ln = [[natural logarithm]]
 
t1 = time one (in days)
 
t2 = time two (in days)
 
W1 = Dry weight of plant at time one (in grams)
 
W2 = Dry weight of plant at time two (in grams)
 
==References==
{{reflist}}
 
[[Category:Plant physiology]]

Latest revision as of 13:32, 20 August 2013

Relative growth rate (RGR) is the growth rate relative to the size of the population. It is also called the exponential growth rate, or the continuous growth rate. In terms of differential equations, if P is the population, and dPdt its growth rate, then its relative growth rate is 1PdPdt. If the relative growth rate is constant, i.e., 1PdPdt=k, it is not difficult to verify that the solution to this equation is P(t)=exp(kt). When calculating or discussing relative growth rate, it is important to pay attention to the units of time being considered.[1]

For example, if an initial population of P0 bacteria doubles every twenty minutes, then at time t it is given by the equation P(t)=P02t=P0exp(ln(2)t) where t is the number of twenty-minute intervals that have passed. However, we usually prefer to measure time in hours or minutes, and it is not difficult to change the units of time. For example, since 1 hour is 3, twenty-minute intervals, the population in one hour is P(3)=P023. The hourly growth factor is 8, which means that for every 1 at the beginning of the hour, there are 8 by the end. Indeed P(T)=P08T=P0exp(ln(8)T) where T is measured in hours, and the relative growth rate may be expressed as ln(2) or approximately 69% per twenty minutes, and as ln(8) or approximately 208% per hour.[1]

In plant physiology, RGR is a measure used to quantify the speed of plant growth. It is measured as the mass increase per aboveground biomass per day, for example as g g−1 d−1. It is considered to be the most widely used way of estimating plant growth, but has been criticised as calculations typically involve the destructive harvest of plants.[2] Another problem is that RGR nearly always decreases over time as the biomass of a plant increases, but traditionally this has been ignored when modelling plant growth. The RGR decreases for several reasons - non-photosynthetic biomass (roots and stems) increases, the top leaves of a plant begin to shade lower leaves and soil nutrients can become limiting. Overall, respiration scales with total biomass, but photosynthesis only scales with photosynthetic biomass and as a result biomass accumulates more slowly as total biomass increases.[3] The RGR of trees in particular slow with increasing size due in part to the large allocation to structural material of the trunk required to hold photosynthetic material up in the canopy. A novel approach to separate size effects from intrinsic growth differences is implemented and described in detail in Philipson et al. (2012).[4]

RGR is calculated using the following equation:[2]

RGR = (ln W2 - ln W1)/(t2-t1)

Where:

ln = natural logarithm

t1 = time one (in days)

t2 = time two (in days)

W1 = Dry weight of plant at time one (in grams)

W2 = Dry weight of plant at time two (in grams)

References

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  4. Christopher D. Philipson, Philippe Saner, Toby R. Marthews, Reuben Nilus, Glen Reynolds, Lindsay A. Turnbull, Andy Hector (2012) Light-based regeneration niches: evidence from 21 dipterocarp species using size-specific RGRs. Biotropica. doi:10.1111/j.1744-7429.2011.00833.x http://onlinelibrary.wiley.com/doi/10.1111/j.1744-7429.2011.00833.x/abstract;jsessionid=49E8727AE3DD4F0E2A0BD887E972B84F.d03t03