In this article, we will learn how to do exponential and logarithmic curve fitting in Python. Firstly the question comes to our mind What is curve fitting?

**Curve fitting **is the process of constructing a curve or mathematical function, that has the best fit to a series of data points, possibly subject to constraints.

**Logarithmic curve fitting:**The logarithmic curve is the plot of the logarithmic function.**Exponential****curve fitting:**The exponential curve is the plot of the exponential function.

Let us consider two equations

y = alog(x) + bwherea ,bare coefficients of that logarithmic equation.

y = ewhere^{(ax)*e(b) }a ,bare coefficients of that exponential equation.

We will be fitting both curves on the above equation and find the best fit curve for it. For curve fitting in Python, we will be using some library functions

We would also use numpy.polyfit() method for fitting the curve. This function takes on three parameters x, y and the polynomial degree(n) returns coefficients of nth degree polynomial.

Syntax:numpy.polyfit(x, y, deg)

Parameters:

x->x-coordinatesy->y-coordinatesdeg-> Degree of the fitting polynomial. So, if deg is given one we get coefficients of linear polynomial or if it is 2 we get coefficients of a quadratic polynomial.

### Logarithmic curve fitting

To do Logarithmic curve fitting, we have to follow some steps which are explained below with the implementation.

#### Importing Libraries

## Python

`import` `numpy as np ` ` ` `# It is for ploting the curve ` `import` `matplotlib.pyplot as plt ` |

#### Creating/Loading Data

As we have imported the required libraries we have to create two arrays named x and y. And after creating those two arrays we have to take the log of the values in x and y with the help of numpy.log() method.

## Python3

`# Points on X-axis ` `x_data ` `=` `np.array([` `11` `, ` `23` `, ` `31` `, ` `43` `, ` `51` `]) ` ` ` `# Points on Y-axis ` `y_data ` `=` `np.array([` `2` `, ` `4` `, ` `6` `, ` `8` `, ` `10` `]) ` ` ` `print` `(x_data) ` `print` `(y_data) ` ` ` `# Taking log of x values ` `xlog_data ` `=` `np.log(x_data) ` ` ` `print` `(xlog_data)` |

**Output:**

#### Fitting of Data

After, getting the log values of x and y arrays, With the help of numpy.polyfit() we find the coefficient for our equation. As we took a linear equation hence in polyfit method we will pass 1 in degree parameter.

## Python3

`# Given log values of x , y as input ` `curve ` `=` `np.polyfit(log_x_data, y_data, ` `1` `) ` ` ` `print` `(curve)` |

**Output:**

#### Getting Output

So we get the coefficients as [5.04, -10.79] with that we can get the equation of the curve which would be (y= a*log(x)+y, where a,b are coefficient)

y = 5.04*log(x) - 10.79

## Python3

`y ` `=` `5.04` `*` `log_x_data ` `-` `10.79` ` ` `print` `(y)` |

**Output:**

#### Plotting Results

Now, let’s plot the graphs one with xlog_data, ylog_data, and another with xlog_data and y equation which we have obtained. For plotting graphs in python, we will take the help of Matplotlib.pyplot.plot() function.

Syntax:matplotlib.pyplot.plot(x-coordinates, y-coordinates)

Parameters:

x:horizontal coordinates of the data pointsy:vertical coordinates of the data points

## Python3

`# Blue color ` `plt.plot(log_x_data, y_data) ` ` ` `# Best fit in orange ` `plt.plot(log_x_data, y)` |

**Output:**

In the above graph yellow line represents the graph of original x and y coordinates and the blue line is the graph of coordinates that we have obtained through our calculations, and it is the best fit.

### Exponential curve fitting

We will be repeating the same process as above, but the only difference is the logarithmic function is replaced by the exponential function.

First, let us create the data points

## Python3

`x_data ` `=` `np.array([` `11` `, ` `19` `, ` `31` `, ` `39` `, ` `51` `]) ` `print` `(x_data) ` ` ` `y_data ` `=` `np.array([` `5` `, ` `8` `, ` `32` `, ` `84` `, ` `110` `]) ` `print` `(y_data) ` |

**Output:**

Equation: y = e(ax)*e(b)

In this equation we will plot the graph and the a, b are coefficients which we can be obtained with numpy.polyfit() method. Now lets us find the coefficients of exponential function with degree .

## Python3

`ylog_data ` `=` `np.log(y_data) ` `print` `(ylog_data) ` ` ` `curve_fit ` `=` `np.polyfit(x_data, log_y_data, ` `1` `) ` `print` `(curve_fit)` |

**Output:**

So, a = 0.69 and b = 0.085 these are the coefficients we can get the equation of the curve which would be (y = e^{(ax)}*e^{(b),} where a, b are coefficient)

y = e^{(0.69x)*e(0.085) }final equation.^{ }^{ }

## Python3

`y ` `=` `np.exp(` `0.69` `) ` `*` `np.exp(` `0.085` `*` `x_data) ` ` ` `print` `(y) ` |

**Output:**

Now, let us plot the graphs with the help of Matplotlib.pyplot.plot() function.

## Python3

`# Blue ` `plt.plot(x_data, y_data) ` ` ` `# best fit in orange ` `plt.plot(x_data, y)` |

**Output:**

In the above graph blue line represents the graph of original x and y coordinates and the orange line is the graph of coordinates that we have obtained through our calculations, and it is the best fit.

Hence, this is the process of fitting exponential and logarithmic curves in Python with the help of NumPy and matplotlib.

Attention geek! Strengthen your foundations with the **Python Programming Foundation** Course and learn the basics.

To begin with, your interview preparations Enhance your Data Structures concepts with the **Python DS** Course. And to begin with your Machine Learning Journey, join the **Machine Learning – Basic Level Course **