Examples of exponential growth in the following topics:
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- Exponential decay occurs in the same way, providing the growth rate is negative.
- In the long run, exponential growth of any kind will overtake linear growth of any kind as well as any polynomial growth.
- If $\tau > 0$ and $b > 1$, then $x$ has exponential growth.
- This graph illustrates how exponential growth (green) surpasses both linear (red) and cubic (blue) growth.
- Apply the exponential growth and decay formulas to real world examples
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- For example, a simple model of population growth is the Malthusian growth model.
- This is essentially exponential growth based on a constant rate of compound interest: $P(t)=P_0e^{rt}$ where $P_0=P(0)=\text{initial population}$, $r$ is the growth rate, and $t$ is the time.
- A slightly more realistic and largely used population growth model is the logistic function that may be defined by the formula: $P(t) = \frac{1}{1 + e^{-t}}$.
- The graph illustrates how exponential growth (green) surpasses both linear (red) and cubic (blue) growth.
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- A logistic equation is a differential equation which can be used to model population growth.
- More quantitatively, as can be seen from the analytical solution, the logistic curve shows early exponential growth for negative $t$, which slows to linear growth of slope $\frac{1}{4}$ near $t = 0$, then approaches $y = 1$ with an exponentially decaying gap.
- The equation describes the self-limiting growth of a biological population.
- where the constant $r$ defines the growth rate and $K$ is the carrying capacity.
- It can be used to model population growth because of the limiting effect scarcity has on the growth rate.
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- The prey are assumed to have an unlimited food supply, and to reproduce exponentially unless subject to predation; this exponential growth is represented in the equation above by the term $\alpha x$.
- With these two terms, the equation above can be interpreted as follows: the change in the prey's number is given by its own growth minus the rate at which it is preyed upon.
- In the predator equation, $\delta xy$ represents the growth of the predator population.
- $\gamma y$ represents the loss rate of the predators due to either natural death or emigration; it leads to an exponential decay in the absence of prey.
- Hence, the equation expresses the change in the predator population as growth fueled by the food supply, minus natural death.
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- The derivative of the exponential function is equal to the value of the function.
- The importance of the exponential function in mathematics and the sciences stems mainly from properties of its derivative.
- If a variable's growth or decay rate is proportional to its size—as is the case in unlimited population growth, continuously compounded interest, or radioactive decay—then the variable can be written as a constant times an exponential function of time.
- Graph of the exponential function illustrating that its derivative is equal to the value of the function.
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- Now that we have derived a specific case, let us extend things to the general case of exponential function.
- Here we consider integration of natural exponential function.
- Note that the exponential function $y = e^{x}$ is defined as the inverse of $\ln(x)$.
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- Both exponential and logarithmic functions are widely used in scientific and engineering applications.
- The exponential function is widely used in physics, chemistry, engineering, mathematical biology, economics and mathematics.
- The exponential function arises whenever a quantity grows or decays at a rate proportional to its current value.
- The exponential function $e^x$ can be characterized in a variety of equivalent ways.
- The derivative (or slope of a tangential line) of the exponential function is equal to the value of the function.
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- The exponential function (in blue) and the sum of the first 9 terms of its Taylor series at 0 (in red).
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- The exponential function (in blue) and the sum of the first $n+1$ terms of its Taylor series at $0$ (in red) up to $n=8$.
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- The exponential function (in blue), and the sum of the first $n+1$ terms of its Maclaurin power series (in red).