# Plancks Formula for Blackbody spectrum

I am trying to write a simple python code for a plot of intensity vs wavelength for a given temperature, T=200K. So far I have this...

import scipy as sp
import math
import matplotlib.pyplot as plt
import numpy as np
pi = np.pi
h = 6.626e-34
c = 3.0e+8
k = 1.38e-23

def planck(wav, T):
a = 2.0*h*pi*c**2
b = h*c/(wav*k*T)
intensity = a/ ( (wav**5)*(math.e**b - 1.0) )
return intensity


I don't know how to define wavelength(wav) and thus produce the plot of Plancks Formula. Any help would be appreciated.

• Presumably you want a range of wavelengths. Do you know what range? Look into range. Mar 14, 2014 at 23:22
• Usually the wavelength is just even spaced vector, you can use np.arange or np.linspace. Remember the indent in your planck function. Mar 14, 2014 at 23:24

Here's a basic plot. To plot using plt.plot(x, y, fmt) you need two arrays x and y of the same size, where x is the x coordinate of each point to plot and y is the y coordinate, and fmt is a string describing how to plot the numbers.

So all you need to do is create an evenly spaced array of wavelengths (an np.array which I named wavelengths). This can be done with arange(start, end, spacing) which will create an array from start to end (not inclusive) spaced at spacing apart.

Then compute the intensity using your function at each of those points in the array (which will be stored in another np.array), and then call plt.plot to plot them. Note numpy let's you do mathematical operations on arrays quickly in a vectorized form which will be computationally efficient.

import matplotlib.pyplot as plt
import numpy as np

h = 6.626e-34
c = 3.0e+8
k = 1.38e-23

def planck(wav, T):
a = 2.0*h*c**2
b = h*c/(wav*k*T)
intensity = a/ ( (wav**5) * (np.exp(b) - 1.0) )
return intensity

# generate x-axis in increments from 1nm to 3 micrometer in 1 nm increments
# starting at 1 nm to avoid wav = 0, which would result in division by zero.
wavelengths = np.arange(1e-9, 3e-6, 1e-9)

# intensity at 4000K, 5000K, 6000K, 7000K
intensity4000 = planck(wavelengths, 4000.)
intensity5000 = planck(wavelengths, 5000.)
intensity6000 = planck(wavelengths, 6000.)
intensity7000 = planck(wavelengths, 7000.)

plt.plot(wavelengths*1e9, intensity4000, 'r-')
# plot intensity4000 versus wavelength in nm as a red line
plt.plot(wavelengths*1e9, intensity5000, 'g-') # 5000K green line
plt.plot(wavelengths*1e9, intensity6000, 'b-') # 6000K blue line
plt.plot(wavelengths*1e9, intensity7000, 'k-') # 7000K black line

# show the plot
plt.show()


And you see:

You probably will want to clean up the axes labels, add a legend, plot the intensity at multiple temperatures on the same plot, among other things. Consult the relevant matplotlib documentation.

• why math.e**b instead of just np.exp(b) Mar 14, 2014 at 23:54
• Because I took the function from user3421850's question and they used math.e**b. Mar 15, 2014 at 4:04
• @Zhenya - Also now that I look at it, their formula was incorrect, since they have an extra pi in the formula for a. (Note h is Planck's constant, not h-bar (Planck's reduced constant ħ = h/2pi).) Mar 15, 2014 at 4:27
• Re units: it's anyway better to always use dimensionless units rather than (arbitrary) SI units. Write the formula on a piece of paper, use substitutions (here, x = \hbar * \omega / k T), express both rhs and lhs in terms of dimensionless functions of dimensionless variables, plot those (and use axis labels for stating the exact variables). Mar 15, 2014 at 10:52
• @DevonDahon - Matplotlib 2.1 with the deprecation was from October 2017. This comment predates that by three years. Will edit though. I believe just need to remove call to hold() as it's the default behavior. Oct 6, 2020 at 14:04

You may also want to use the RADIS library, which allows you to plot the Planck function against wavelengths, or against frequency / wavenumber, if needed !

from radis import sPlanck

sPlanck(wavelength_min=135, wavelength_max=3000, T=4000).plot()
sPlanck(wavelength_min=135, wavelength_max=3000, T=5000).plot(nfig='same')
sPlanck(wavelength_min=135, wavelength_max=3000, T=6000).plot(nfig='same')
sPlanck(wavelength_min=135, wavelength_max=3000, T=7000).plot(nfig='same')


Just want to point out that there seems to be an equivalent of what OP wants to do in astropy:

https://docs.astropy.org/en/stable/api/astropy.modeling.physical_models.BlackBody.html

Unfortunately, it is not very clear to me yet how to get wavelength vs frequency based expression.