Runge Kutta Methods
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"Runga Kutta methods are used to approximate the value to simultaneous non-linear differential equations. <br>\n",
"More about Runga Kutta Methods [here](https://en.wikipedia.org/wiki/Runge%E2%80%93Kutta_methods).\n",
"\n",
"Here we will try to solve the following three equations with unknown variables S, I and R.\n",
"\n",
"\\begin{equation}\n",
"\\frac{d S(t)}{d t}=A-\\mu S(t)-\\frac{r I}{N_0} S(t)\n",
"\\end{equation}\n",
"<br>\n",
"$$\n",
"\\frac{d I(t)}{d t}=\\frac{r I(t)}{N_0} S(t)-(\\mu+a) I(t)\n",
"$$\n",
"<br>\n",
"$$\n",
"\\frac{d R(t)}{d t}=a I(t)-\\mu R(t)\n",
"$$\n",
"<br>\n",
"         \n",
"where, $\\mathrm{S}(\\mathrm{t})+\\mathrm{I}(\\mathrm{t})+\\mathrm{R}(\\mathrm{t})=\\mathrm{N}(\\mathrm{t})$\n",
"<br><br>\n",
"$$\n",
"=>\\frac{N(t)}{d t}=A-\\mu N\n",
"$$\n",
"\n",
"These equations have a physical significance also, they represent the SIR model for the transmission of tuberclosis as documented [here](https://drive.google.com/file/d/1t2Rgh1jdEmT_aJ7RKAkDf0ZH_lhFM2sp/view?usp=sharing). \n",
"\n",
"S, I and R represent the following three kinds of people:\n",
"\n",
"\n",
"1. S: The first category is individuals who have not been infected with the TB virus, sometimes known as the suspicion group. \n",
"2. I: The second category consists of people who have been infected with the TB virus.\n",
"3. R: The last category consists of people who recovered or died\n",
"after being infected with the TB virus.\n",
"\n",
"\n",
"\n",
"\n",
"Other than S, I and R, all other terms are constants, and the equations can be represented as follows:"
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"source": [
"def dS_dt(S, I, R, t):\n",
" return (1449401 - 0.001167*S - (0.5/1449401)*I*S)"
],
"metadata": {
"id": "NqEw5s-KgR1g"
},
"execution_count": 18,
"outputs": []
},
{
"cell_type": "code",
"source": [
"def dI_dt(S, I, R, t):\n",
" return ((0.5/1449401)*I*S - (0.001167 + 0.111111)*I)"
],
"metadata": {
"id": "TH77cRchhc6-"
},
"execution_count": 19,
"outputs": []
},
{
"cell_type": "code",
"source": [
"def dR_dt(S, I, R, t):\n",
" return (0.111111*I - 0.001167*R)"
],
"metadata": {
"id": "GxXtTA92kJRB"
},
"execution_count": 20,
"outputs": []
},
{
"cell_type": "code",
"source": [
"t = int(input()) # Enter a required value of time where you want the value of S, I and R."
],
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"outputId": "855bae9e-af27-48ad-b2e3-327277207cf8"
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"execution_count": 22,
"outputs": [
{
"name": "stdout",
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"text": [
"10\n"
]
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"cell_type": "code",
"source": [
"S_data = []\n",
"I_data = []\n",
"R_data = []\n",
"SIR_data = []\n",
"N_data = []\n",
"Time = []"
],
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"execution_count": 23,
"outputs": []
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{
"cell_type": "markdown",
"source": [
"**Runge-Kutta method implementation with S,I,R as dependent variables and t as independent variable**"
],
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"cell_type": "code",
"source": [
"def rungeKutta(S0, I0, R0, t, h):\n",
"\n",
" # No of iterations = n\n",
" # Step size = h\n",
" n = (int)((t)/h)\n",
" \n",
" # setting initial values\n",
" S = S0\n",
" I = I0\n",
" R = R0\n",
"\n",
" # implementation of runge-kutta\n",
" for i in range(1, n + 1):\n",
" kS1 = dS_dt(S, I, R, t)\n",
" kI1 = dI_dt(S, I, R, t)\n",
" kR1 = dR_dt(S, I, R, t)\n",
" \n",
" kS2 = dS_dt(S + 0.5 * h * kS1, I + 0.5 * h * kI1, R + 0.5 * h * kR1, t + 0.5*h)\n",
" kI2 = dI_dt(S + 0.5 * h * kS1, I + 0.5 * h * kI1, R + 0.5 * h * kR1, t + 0.5*h)\n",
" kR2 = dR_dt(S + 0.5 * h * kS1, I + 0.5 * h * kI1, R + 0.5 * h * kR1, t + 0.5*h)\n",
"\n",
" kS3 = dS_dt(S + 0.5 * h * kS2, I + 0.5 * h * kI2, R + 0.5 * h * kR2, t + 0.5*h)\n",
" kI3 = dI_dt(S + 0.5 * h * kS2, I + 0.5 * h * kI2, R + 0.5 * h * kR2, t + 0.5*h)\n",
" kR3 = dR_dt(S + 0.5 * h * kS2, I + 0.5 * h * kI2, R + 0.5 * h * kR2, t + 0.5*h)\n",
"\n",
" kS4 = dS_dt(S + kS3 * h, I + kI3 * h, R + kR3 * h, t + h)\n",
" kI4 = dI_dt(S + kS3 * h, I + kI3 * h, R + kR3 * h, t + h)\n",
" kR4 = dR_dt(S + kS3 * h, I + kI3 * h, R + kR3 * h, t + h)\n",
" \n",
" # Updating S, I, R\n",
" S = S + (1.0 / 6.0)*(kS1 + 2 * kS2 + 2 * kS3 + kS4)*h\n",
" I = I + (1.0 / 6.0)*(kI1 + 2 * kI2 + 2 * kI3 + kI4)*h\n",
" R = R + (1.0 / 6.0)*(kR1 + 2 * kR2 + 2 * kR3 + kR4)*h\n",
"\n",
" S_data.append(S)\n",
" I_data.append(I)\n",
" R_data.append(R)\n",
" SIR_data.append(S+I+R)\n",
" Time.append(t)\n",
"\n",
" # Updating value of t\n",
" t += h\n",
" \n",
" # printing N(t) at desired t (N(t)=S(t)+I(t)+R(t))\n",
" print(\"N(t) = \" ,S+I+R)\n",
" return [S,I,R]"
],
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"execution_count": 24,
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"cell_type": "code",
"source": [
"# Driver Code\n",
"S0 = 1446093\n",
"I0 = 1885\n",
"R0 = 1423\n",
"h = 0.01\n",
"print ('The value of S(t), I(t) and R(t) is:', rungeKutta(S0, I0, R0, t, h)) "
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"text": [
"N(t) = 15842350.284962129\n",
"The value of S(t), I(t) and R(t) is: [410394.8072337986, 10323985.625711355, 5107969.852016973]\n"
]
}
]
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{
"cell_type": "markdown",
"source": [
"**Runge-Kutta method implementation with N as dependent variable and t as independent variable**"
],
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{
"cell_type": "markdown",
"source": [
"We implemented it just to prove that the equation N(t) = S(t)+I(t)+R(t) is consistent with the values of S,I,R we got above for the same value of t."
],
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"cell_type": "code",
"source": [
"def dN_dt(t, N):\n",
"\treturn (1449401-0.001167*N)\n",
"\n",
"# implementing runge kutta method for ODE: dN/dt = A - m*N where m is death rate\n",
"def rungeKutta(t0, A, t, h):\n",
"\n",
"\t# no. of iterations = n\n",
"\t# step size = h\n",
"\tn = (int)((t - t0)/h)\n",
"\t\n",
"\tN = A\n",
"\tfor i in range(1, n + 1):\n",
"\t\tk1 = dN_dt(t0, N)\n",
"\t\tk2 = dN_dt(t0 + 0.5 * h, N + 0.5 * h * k1)\n",
"\t\tk3 = dN_dt(t0 + 0.5 * h, N + 0.5 * h * k2)\n",
"\t\tk4 = dN_dt(t0 + h, N + h * k3)\n",
"\n",
"\t\t# Update value of y\n",
"\t\tN = N + (1.0 / 6.0)*(k1 + 2 * k2 + 2 * k3 + k4)*h\n",
"\t\tN_data.append(N)\n",
"\n",
"\t\t# Update next value of t0\n",
"\t\tt0 += h\n",
"\treturn N\n",
"\n",
"# Driver Code\n",
"t0 = 0\n",
"A = 1449401\n",
"h = 0.01\n",
"print ('The value of N(t) at required t is:', rungeKutta(t0, A, t, h))"
],
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"text": [
"The value of N(t) at required t is: 15842350.284962097\n"
]
}
]
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{
"cell_type": "code",
"source": [
"# print(S_data)"
],
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"execution_count": 27,
"outputs": []
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{
"cell_type": "code",
"source": [
"# print(I_data)"
],
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"execution_count": 28,
"outputs": []
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{
"cell_type": "code",
"source": [
"# print(R_data)"
],
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"execution_count": 29,
"outputs": []
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{
"cell_type": "code",
"source": [
"# print(Time)"
],
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"execution_count": 30,
"outputs": []
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{
"cell_type": "code",
"source": [
"# print(N_data)"
],
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"execution_count": 31,
"outputs": []
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{
"cell_type": "markdown",
"source": [
"**Variation of S, I, R and N with time.**"
],
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{
"cell_type": "code",
"source": [
"import math\n",
"import numpy as np\n",
"import matplotlib.pyplot as plt\n",
"t = np.linspace(20,38, 1000)\n",
"plt.scatter(Time, S_data)"
],
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"output_type": "execute_result",
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"text/plain": [
"<Figure size 432x288 with 1 Axes>"
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"image/png": 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\n"
},
"metadata": {
"needs_background": "light"
}
}
]
},
{
"cell_type": "code",
"source": [
"plt.scatter(Time, I_data)"
],
"metadata": {
"colab": {
"base_uri": "https://localhost:8080/",
"height": 293
},
"id": "nR549ji3ljC-",
"outputId": "eef6d6cc-9fb1-4521-ba58-e250a72de7b4"
},
"execution_count": 33,
"outputs": [
{
"output_type": "execute_result",
"data": {
"text/plain": [
"<matplotlib.collections.PathCollection at 0x7ff40cbf3e10>"
]
},
"metadata": {},
"execution_count": 33
},
{
"output_type": "display_data",
"data": {
"text/plain": [
"<Figure size 432x288 with 1 Axes>"
],
"image/png": "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\n"
},
"metadata": {
"needs_background": "light"
}
}
]
},
{
"cell_type": "code",
"source": [
"plt.scatter(Time, R_data)"
],
"metadata": {
"colab": {
"base_uri": "https://localhost:8080/",
"height": 293
},
"id": "EmJtZ1aLljYH",
"outputId": "e12b863b-2f6a-43fe-abdd-c858ee83d008"
},
"execution_count": 34,
"outputs": [
{
"output_type": "execute_result",
"data": {
"text/plain": [
"<matplotlib.collections.PathCollection at 0x7ff40c9e3710>"
]
},
"metadata": {},
"execution_count": 34
},
{
"output_type": "display_data",
"data": {
"text/plain": [
"<Figure size 432x288 with 1 Axes>"
],
"image/png": "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\n"
},
"metadata": {
"needs_background": "light"
}
}
]
},
{
"cell_type": "code",
"source": [
"plt.scatter(Time, N_data)"
],
"metadata": {
"colab": {
"base_uri": "https://localhost:8080/",
"height": 293
},
"id": "uN90E-c4ljkh",
"outputId": "7d10ea76-834d-425f-d9ca-fff71cd1ff02"
},
"execution_count": 35,
"outputs": [
{
"output_type": "execute_result",
"data": {
"text/plain": [
"<matplotlib.collections.PathCollection at 0x7ff40c9c4dd0>"
]
},
"metadata": {},
"execution_count": 35
},
{
"output_type": "display_data",
"data": {
"text/plain": [
"<Figure size 432x288 with 1 Axes>"
],
"image/png": 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}
About this Algorithm
Runga Kutta methods are used to approximate the value to simultaneous non-linear differential equations.
More about Runga Kutta Methods here.
Here we will try to solve the following three equations with unknown variables S, I and R.
\begin{equation}
\frac{d S(t)}{d t}=A-\mu S(t)-\frac{r I}{N_0} S(t)
\end{equation}
$$
\frac{d I(t)}{d t}=\frac{r I(t)}{N_0} S(t)-(\mu+a) I(t)
$$
$$
\frac{d R(t)}{d t}=a I(t)-\mu R(t)
$$
         
where, $\mathrm{S}(\mathrm{t})+\mathrm{I}(\mathrm{t})+\mathrm{R}(\mathrm{t})=\mathrm{N}(\mathrm{t})$
$$
=>\frac{N(t)}{d t}=A-\mu N
$$
These equations have a physical significance also, they represent the SIR model for the transmission of tuberclosis as documented here.
S, I and R represent the following three kinds of people:
- S: The first category is individuals who have not been infected with the TB virus, sometimes known as the suspicion group.
- I: The second category consists of people who have been infected with the TB virus.
- R: The last category consists of people who recovered or died after being infected with the TB virus.
Other than S, I and R, all other terms are constants, and the equations can be represented as follows:
def dS_dt(S, I, R, t):
return (1449401 - 0.001167*S - (0.5/1449401)*I*S)def dI_dt(S, I, R, t):
return ((0.5/1449401)*I*S - (0.001167 + 0.111111)*I)def dR_dt(S, I, R, t):
return (0.111111*I - 0.001167*R)t = int(input()) # Enter a required value of time where you want the value of S, I and R.10
S_data = []
I_data = []
R_data = []
SIR_data = []
N_data = []
Time = []Runge-Kutta method implementation with S,I,R as dependent variables and t as independent variable
def rungeKutta(S0, I0, R0, t, h):
# No of iterations = n
# Step size = h
n = (int)((t)/h)
# setting initial values
S = S0
I = I0
R = R0
# implementation of runge-kutta
for i in range(1, n + 1):
kS1 = dS_dt(S, I, R, t)
kI1 = dI_dt(S, I, R, t)
kR1 = dR_dt(S, I, R, t)
kS2 = dS_dt(S + 0.5 * h * kS1, I + 0.5 * h * kI1, R + 0.5 * h * kR1, t + 0.5*h)
kI2 = dI_dt(S + 0.5 * h * kS1, I + 0.5 * h * kI1, R + 0.5 * h * kR1, t + 0.5*h)
kR2 = dR_dt(S + 0.5 * h * kS1, I + 0.5 * h * kI1, R + 0.5 * h * kR1, t + 0.5*h)
kS3 = dS_dt(S + 0.5 * h * kS2, I + 0.5 * h * kI2, R + 0.5 * h * kR2, t + 0.5*h)
kI3 = dI_dt(S + 0.5 * h * kS2, I + 0.5 * h * kI2, R + 0.5 * h * kR2, t + 0.5*h)
kR3 = dR_dt(S + 0.5 * h * kS2, I + 0.5 * h * kI2, R + 0.5 * h * kR2, t + 0.5*h)
kS4 = dS_dt(S + kS3 * h, I + kI3 * h, R + kR3 * h, t + h)
kI4 = dI_dt(S + kS3 * h, I + kI3 * h, R + kR3 * h, t + h)
kR4 = dR_dt(S + kS3 * h, I + kI3 * h, R + kR3 * h, t + h)
# Updating S, I, R
S = S + (1.0 / 6.0)*(kS1 + 2 * kS2 + 2 * kS3 + kS4)*h
I = I + (1.0 / 6.0)*(kI1 + 2 * kI2 + 2 * kI3 + kI4)*h
R = R + (1.0 / 6.0)*(kR1 + 2 * kR2 + 2 * kR3 + kR4)*h
S_data.append(S)
I_data.append(I)
R_data.append(R)
SIR_data.append(S+I+R)
Time.append(t)
# Updating value of t
t += h
# printing N(t) at desired t (N(t)=S(t)+I(t)+R(t))
print("N(t) = " ,S+I+R)
return [S,I,R]# Driver Code
S0 = 1446093
I0 = 1885
R0 = 1423
h = 0.01
print ('The value of S(t), I(t) and R(t) is:', rungeKutta(S0, I0, R0, t, h)) N(t) = 15842350.284962129
The value of S(t), I(t) and R(t) is: [410394.8072337986, 10323985.625711355, 5107969.852016973]
Runge-Kutta method implementation with N as dependent variable and t as independent variable
We implemented it just to prove that the equation N(t) = S(t)+I(t)+R(t) is consistent with the values of S,I,R we got above for the same value of t.
def dN_dt(t, N):
return (1449401-0.001167*N)
# implementing runge kutta method for ODE: dN/dt = A - m*N where m is death rate
def rungeKutta(t0, A, t, h):
# no. of iterations = n
# step size = h
n = (int)((t - t0)/h)
N = A
for i in range(1, n + 1):
k1 = dN_dt(t0, N)
k2 = dN_dt(t0 + 0.5 * h, N + 0.5 * h * k1)
k3 = dN_dt(t0 + 0.5 * h, N + 0.5 * h * k2)
k4 = dN_dt(t0 + h, N + h * k3)
# Update value of y
N = N + (1.0 / 6.0)*(k1 + 2 * k2 + 2 * k3 + k4)*h
N_data.append(N)
# Update next value of t0
t0 += h
return N
# Driver Code
t0 = 0
A = 1449401
h = 0.01
print ('The value of N(t) at required t is:', rungeKutta(t0, A, t, h))The value of N(t) at required t is: 15842350.284962097
# print(S_data)# print(I_data)# print(R_data)# print(Time)# print(N_data)Variation of S, I, R and N with time.
import math
import numpy as np
import matplotlib.pyplot as plt
t = np.linspace(20,38, 1000)
plt.scatter(Time, S_data)<matplotlib.collections.PathCollection at 0x7ff40cbf3590>
plt.scatter(Time, I_data)<matplotlib.collections.PathCollection at 0x7ff40cbf3e10>
plt.scatter(Time, R_data)<matplotlib.collections.PathCollection at 0x7ff40c9e3710>
plt.scatter(Time, N_data)<matplotlib.collections.PathCollection at 0x7ff40c9c4dd0>
