Exponential growth explained

Exponential growth is a process that increases quantity over time at an ever-increasing rate. It occurs when the instantaneous rate of change (that is, the derivative) of a quantity with respect to time is proportional to the quantity itself. Described as a function, a quantity undergoing exponential growth is an exponential function of time, that is, the variable representing time is the exponent (in contrast to other types of growth, such as quadratic growth). Exponential growth is the inverse of logarithmic growth.

If the constant of proportionality is negative, then the quantity decreases over time, and is said to be undergoing exponential decay instead. In the case of a discrete domain of definition with equal intervals, it is also called geometric growth or geometric decay since the function values form a geometric progression.

The formula for exponential growth of a variable at the growth rate, as time goes on in discrete intervals (that is, at integer times 0, 1, 2, 3, ...), is

x_t = x_0(1+r)^t

where is the value of at time 0. The growth of a bacterial colony is often used to illustrate it. One bacterium splits itself into two, each of which splits itself resulting in four, then eight, 16, 32, and so on. The amount of increase keeps increasing because it is proportional to the ever-increasing number of bacteria. Growth like this is observed in real-life activity or phenomena, such as the spread of virus infection, the growth of debt due to compound interest, and the spread of viral videos. In real cases, initial exponential growth often does not last forever, instead slowing down eventually due to upper limits caused by external factors and turning into logistic growth.

Terms like "exponential growth" are sometimes incorrectly interpreted as "rapid growth". Indeed, something that grows exponentially can in fact be growing slowly at first.[1] [2]

Examples

Biology

Physics

Economics

Finance

Computer science

Internet phenomena

Basic formula

A quantity depends exponentially on time ifx(t)=a\cdot b^where the constant is the initial value of, x(0) = a \,, the constant is a positive growth factor, and is the time constant—the time required for to increase by one factor of :x(t+\tau) = a \cdot b^ = a \cdot b^ \cdot b^ = x(t) \cdot b\, .

If and, then has exponential growth. If and, or and, then has exponential decay.

Example: If a species of bacteria doubles every ten minutes, starting out with only one bacterium, how many bacteria would be present after one hour? The question implies, and .

x(t)=a\cdot b^ = 1 \cdot 2^x(1\text) = 1\cdot 2^ = 1 \cdot 2^6 =64.

After one hour, or six ten-minute intervals, there would be sixty-four bacteria.

Many pairs of a dimensionless non-negative number and an amount of time (a physical quantity which can be expressed as the product of a number of units and a unit of time) represent the same growth rate, with proportional to . For any fixed not equal to 1 (e.g. e or 2), the growth rate is given by the non-zero time . For any non-zero time the growth rate is given by the dimensionless positive number .

Thus the law of exponential growth can be written in different but mathematically equivalent forms, by using a different base. The most common forms are the following:x(t) = x_0\cdot e^ = x_0\cdot e^ = x_0 \cdot 2^= x_0\cdot \left(1 + \frac \right)^,where expresses the initial quantity .

Parameters (negative in the case of exponential decay):

The quantities,, and, and for a given also, have a one-to-one connection given by the following equation (which can be derived by taking the natural logarithm of the above):k = \frac = \frac = \fracwhere corresponds to and to and being infinite.

If is the unit of time the quotient is simply the number of units of time. Using the notation for the (dimensionless) number of units of time rather than the time itself, can be replaced by, but for uniformity this has been avoided here. In this case the division by in the last formula is not a numerical division either, but converts a dimensionless number to the correct quantity including unit.

A popular approximated method for calculating the doubling time from the growth rate is the rule of 70,that is,

T\simeq70/r

.

Reformulation as log-linear growth

If a variable exhibits exponential growth according to

x(t)=x0(1+r)t

, then the log (to any base) of grows linearly over time, as can be seen by taking logarithms of both sides of the exponential growth equation:\log x(t) = \log x_0 + t \cdot \log (1+r).

This allows an exponentially growing variable to be modeled with a log-linear model. For example, if one wishes to empirically estimate the growth rate from intertemporal data on, one can linearly regress on .

Differential equation

x(t)=x0ekt

satisfies the linear differential equation:\frac = kxsaying that the change per instant of time of at time is proportional to the value of, and has the initial value

x(0)=x0

.

The differential equation is solved by direct integration:\begin\frac & = kx \\[5pt]\frac x & = k\, dt \\[5pt]\int_^ \frac & = k \int_0^t \, dt \\[5pt]\ln \frac & = kt.\endso that x(t) = x_0 e^.

In the above differential equation, if, then the quantity experiences exponential decay.

For a nonlinear variation of this growth model see logistic function.

Other growth rates

In the long run, exponential growth of any kind will overtake linear growth of any kind (that is the basis of the Malthusian catastrophe) as well as any polynomial growth, that is, for all :\lim_ \frac = 0.

There is a whole hierarchy of conceivable growth rates that are slower than exponential and faster than linear (in the long run). See .

Growth rates may also be faster than exponential. In the most extreme case, when growth increases without bound in finite time, it is called hyperbolic growth. In between exponential and hyperbolic growth lie more classes of growth behavior, like the hyperoperations beginning at tetration, and

A(n,n)

, the diagonal of the Ackermann function.

Logistic growth

See main article: Logistic curve. In reality, initial exponential growth is often not sustained forever. After some period, it will be slowed by external or environmental factors. For example, population growth may reach an upper limit due to resource limitations.[8] In 1845, the Belgian mathematician Pierre François Verhulst first proposed a mathematical model of growth like this, called the "logistic growth".[9]

Limitations of models

Exponential growth models of physical phenomena only apply within limited regions, as unbounded growth is not physically realistic. Although growth may initially be exponential, the modelled phenomena will eventually enter a region in which previously ignored negative feedback factors become significant (leading to a logistic growth model) or other underlying assumptions of the exponential growth model, such as continuity or instantaneous feedback, break down.

Exponential growth bias

Studies show that human beings have difficulty understanding exponential growth. Exponential growth bias is the tendency to underestimate compound growth processes. This bias can have financial implications as well.[10]

Rice on a chessboard

See also: Wheat and chessboard problem. According to legend, vizier Sissa Ben Dahir presented an Indian King Sharim with a beautiful handmade chessboard. The king asked what he would like in return for his gift and the courtier surprised the king by asking for one grain of rice on the first square, two grains on the second, four grains on the third, and so on. The king readily agreed and asked for the rice to be brought. All went well at first, but the requirement for grains on the th square demanded over a million grains on the 21st square, more than a million million (trillion) on the 41st and there simply was not enough rice in the whole world for the final squares. (From Swirski, 2006)[11]

The "second half of the chessboard" refers to the time when an exponentially growing influence is having a significant economic impact on an organization's overall business strategy.

Water lily

French children are offered a riddle, which appears to be an aspect of exponential growth: "the apparent suddenness with which an exponentially growing quantity approaches a fixed limit". The riddle imagines a water lily plant growing in a pond. The plant doubles in size every day and, if left alone, it would smother the pond in 30 days killing all the other living things in the water. Day after day, the plant's growth is small, so it is decided that it won't be a concern until it covers half of the pond. Which day will that be? The 29th day, leaving only one day to save the pond.[12] [11]

See also

Sources

External links

Notes and References

  1. News: Opinion | Stop Saying 'Exponential.' Sincerely, a Math Nerd.. Manil. Suri. The New York Times . 4 March 2019.
  2. Web site: 10 Scientific Words You're Probably Using Wrong. 11 July 2014. HowStuffWorks.
  3. Slavov. Nikolai. Budnik. Bogdan A.. Schwab. David. Airoldi. Edoardo Airoldi. Edoardo M.. van Oudenaarden. Alexander. Constant Growth Rate Can Be Supported by Decreasing Energy Flux and Increasing Aerobic Glycolysis . Cell Reports. 7. 3. 2014. 705–714. 2211-1247. 10.1016/j.celrep.2014.03.057. 24767987. 4049626.
  4. Web site: Introduction to Nuclear Weapon Physics and Design. Nuclear Weapons Archive. Sublette. Carey. 26 May 2009.
  5. To Go Viral. Ariel Cintrón-Arias. 2014. physics.soc-ph. 1402.3499.
  6. Book: Karine Nahon. Jeff Hemsley. Going Viral. 2013. Polity. 978-0-7456-7129-1. 16.
  7. Web site: Gangnam Style vs Call Me Maybe: A Popularity Comparison. YouTube Trends. YouTube. 2012.
  8. Book: Crauder. Bruce. Evans. Benny. Noell. Alan. Functions and Change: A Modeling Approach to College Algebra. 2008. Houghton Mifflin Harcourt. 978-1-111-78502-4. 398.
  9. Book: Bernstein, Ruth . Population Ecology: An Introduction to Computer Simulations. 2003. John Wiley & Sons. 978-0-470-85148-7. 37.
  10. 10.1111/j.1540-6261.2009.01518.x. Exponential Growth Bias and Household Finance. 2009. Stango. Victor . Zinman. Jonathan. The Journal of Finance. 64. 6. 2807–2849.
  11. Book: Porritt, Jonathan. Capitalism: as if the world matters. 2005. Earthscan. London. 1-84407-192-8. 49.
  12. Book: Meadows, Donella. The Limits to Growth: The 30-Year Update. 2004. Chelsea Green Publishing. 9781603581554. 21.