Added constant birth rate to create stable population sizes

HeLab · Oct 21, 2021 · a4d4fca · a4d4fca
1 parent ca34adb
commit a4d4fca
Showing 1 changed file with 51 additions and 18 deletions.
diff --git a/ODEsImmunity.R b/ODEsImmunity.R
@@ -17,29 +17,33 @@ SEAI<-function(t,y,p){
     N = y[5]+y[6]+y[7]+y[8]+y[9]+y[10]
     m = (PSU+PSD+PRU+PRD)/N
     I = 1-exp(-m)
+    rat = 0.8
     eps = (((PSD+PSU+((PRD+PRU)*(wr))))/(PSD+PSU+PRD+PRU))
     dPSU.dt = -(b*(PSU/N)*ws*(NU+SU+AU)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (b*(PSD/N)*ws*(NU+SU+AU)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (muSU)*(PSU)
     dPSD.dt = -(b*(PSD/N)*ws*(ND+SD+AD)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (b*(PSU/N)*ws*(ND+SD+AD)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (muSD)*(PSD)
     dPRU.dt = -(b*(PRU/N)*wr*(NU+SU+AU)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (b*(PRD/N)*(NU+SU+AU)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (muRU)*(PRU)
     dPRD.dt = -(b*(PRD/N)*wr*(ND+SD+AD)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (b*(PRU/N)*(ND+SD+AD)*(1/K)*(((PSU+PSD+PRU+PRD)/N)-K)) - (muRD)*(PRD)
-    dNU.dt = (del*N)+ (ND/Tau)-(b*I*eps*NU*(d+rho1))-(muNU*NU) - (del*att*NU)
+    #dNU.dt = (del*(AU+AD))+(ND/Tau)-(b*I*eps*NU*(d+rho1))-(muNU*NU) - (del*att*NU)
+    dNU.dt = del+(ND/Tau)-(b*I*eps*NU*(d+rho1))-(muNU*NU) - (del*att*NU)
     dND.dt = (b*I*eps*NU*d)-(ND/Tau)-(b*I*eps*ND*rho2)-(muND*ND) - (del*att*ND)
     dSU.dt = (b*I*eps*NU*rho1)+(SD/Tau)-(b*I*eps*SU*(d+rho3)) - (del*att*SU)
     dSD.dt = (b*I*eps*ND*rho2)+(b*I*eps*SU*d)-(SD/Tau)-(b*I*eps*SD*rho4) - (del*att*SD)
+    #dAU.dt = rat*(AU+AD)*(1-((AU+AD)/L))+(AD/Tau)+(b*I*eps*SU*rho3)-(b*I*eps*omega1*AU*d) - (del*att*AU)
     dAU.dt = (AD/Tau)+(b*I*eps*SU*rho3)-(b*I*eps*omega1*AU*d) - (del*att*AU)
+    #dAD.dt = rat*(AU+AD)*(1-((AU+AD)/L))+(b*I*eps*SD*rho4)+(b*I*eps*omega1*AU*d)-(AD/Tau) - (del*att*AD)
     dAD.dt = (b*I*eps*SD*rho4)+(b*I*eps*omega1*AU*d)-(AD/Tau) - (del*att*AD)
     return(list(c(dPSU.dt,dPSD.dt,dPRU.dt,dPRD.dt,dNU.dt,dND.dt,dSU.dt,dSD.dt,dAU.dt,dAD.dt)))
   })
 }
 
-b = 20000
+b = 9
 
 nstrains = 20
 
-att = 0
-del = 0
-muND = 0
-muNU = 0
+att = 0.001#.000000000001
+del = 50
+muND = 0.1
+muNU = 0.1
 rho1 = 0.5 #prob of immunity gain from NU to SU
 rho2 = 0.5 #prob of immunity gain from ND to SD
 rho3 = 1/nstrains #prob of immunity gain from SU to AU
@@ -50,8 +54,10 @@ omega2 = 1/100 #prob of appearance of new antigen only in resistant strains
 
 L = 10000
 
+
+
 ws = 1
-wr = 1-0.6
+wr = 1-0.6#-0.6
 #muSU = 1
 muSU=0.05
 #muSD = 20
@@ -61,7 +67,7 @@ muRD = 0.05
 #muRU = 1
 muRU = 0.05
 Tau = 20#/365
-d = 0.9
+d = 0.3
 #m = 3
 K=10
 p2 = list(b=b,ws=ws,wr=wr,muSU=muSU,muSD=muSD,muRD=muRD,muRU=muRU,Tau=Tau,d=d,del=del,muND=muND,muNU=muNU,rho1=rho1,rho2=rho2,rho3=rho3,rho4=rho4,omega1=omega1,omega2=omega2,L=L,att=att)
@@ -83,36 +89,63 @@ plot(out2[,1],(out2[,4]),type="l", xlab = "Time", ylab="Population", main = "b=0
 lines(out2[,1],(out2[,5]),col="RED")
 legend(x=40,y=6,legend=c("PRU","PRD"),bty="n",lwd = c(2,1),col=c("BLACK","RED"))
 
-plot(out2[,1],(out2[,6]),type="l", xlab="Time", ylab="Population", main = "b=0.2239*365,d=0.30")
+plot(out2[,1],(out2[,6]),ylim=c(0,max(out2[,7])),type="l", xlab="Time", ylab="Population", main = "b=0.2239*365,d=0.30")
 lines(out2[,1],(out2[,7]),col="RED")
 legend(x=40,y=1000,legend=c("NU","ND"),bty="n",lwd=c(2,1),col=c("BLACK","RED"))
 
-plot(out2[,1],(out2[,8]),type="l", xlab="Time",ylab="Population", main = "b=0.2239*365,d=0.30")
+plot(out2[,1],(out2[,8]),ylim=c(0,max(out2[,9])),type="l", xlab="Time",ylab="Population", main = "b=0.2239*365,d=0.30")
 lines(out2[,1],(out2[,9]),col="RED")
 legend(x=40,y=1000,legend=c("SU","SD"),bty="n",lwd=c(2,1),col=c("BLACK","RED"))
 
-plot(out2[,1],out2[,10],type="l",xlab="Time",ylab="Asymptomatic Population (A)", main="b=0.2239*365,d=0.30")
+plot(out2[,1],out2[,10],ylim=c(0,max(out2[,10])),type="l",xlab="Time",ylab="Asymptomatic Population (A)", main="b=0.2239*365,d=0.30")
 lines(out2[,1],out2[,11],col="RED")
 
+plot(out2[,1],(out2[,8]+out2[,9])/(out2[,10]+out2[,11]))
+
 
 out3eq = vector(mode = "numeric", length = 22)
 out3eq2 = vector(mode = "numeric", length = 22)
+out3eq3 = vector(mode = "numeric", length = 22)
 bvalues = c(0,0.0001,0.0005,0.05,0.10,0.15,0.20,0.25,0.27,0.30,0.32,0.35,0.37,0.40,0.45,0.50,0.55,0.60,0.70,0.80,0.90,1)
 #bvalues = c(0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24)
-wrvalues = c(0,0.10,0.15,0.20,0.25,0.27,0.30,0.32,0.35,0.37,0.40,0.45,0.50,0.55,0.60,0.65,0.70,0.75,0.80,0.85,0.90)
-dvalues = c(0,0.10,0.15,0.20,0.25,0.27,0.30,0.32,0.35,0.37,0.40,0.45,0.50,0.55,0.60,0.65,0.70,0.75,0.80,0.85,0.90)
+wrvalues = c(0,0.10,0.15,0.20,0.25,0.27,0.30,0.32,0.35,0.37,0.40,0.45,0.50,0.55,0.60,0.65,0.70,0.75,0.80,0.85,0.90,1)
+dvalues = c(0,0.10,0.15,0.20,0.25,0.27,0.30,0.32,0.35,0.37,0.40,0.45,0.50,0.55,0.60,0.65,0.70,0.75,0.80,0.85,0.90,1)
 for (i in 1:22){
-  b=bvalues[i]*10
+  b=bvalues[i]*1
   #wr=wrvalues[i]
   #d=dvalues[i]
-  p3 = list(b=b,ws=ws,wr=wr,muSU=muSU,muSD=muSD,muRD=muRD,muRU=muRU,Tau=Tau,d=d,del=del,muND=muND,muNU=muNU,rho1=rho1,rho2=rho2,rho3=rho3,rho4=rho4,omega1=omega1,omega2=omega2,L=L,att=att)
-  out3 = ode(y=N0,times=t2,func=SEAI,parms=p3)
-  #out3eq[i] = out3[3999,2] + out3[3999,3]+out3[3999,4] + out3[3999,5]
+  p2 = list(b=b,ws=ws,wr=wr,muSU=muSU,muSD=muSD,muRD=muRD,muRU=muRU,Tau=Tau,d=d,del=del,muND=muND,muNU=muNU,rho1=rho1,rho2=rho2,rho3=rho3,rho4=rho4,omega1=omega1,omega2=omega2,L=L,att=att)
+  out3 = ode(y=N0,times=t2,func=SEAI,parms=p2)
+  out3eq[i] = out3[3999,2] + out3[3999,3]+out3[3999,4] + out3[3999,5]
   out3eq2[i] = (out3[3999,4]+out3[3999,5])/(out3[3999,2] + out3[3999,3] + out3[3999,4] + out3[3999,5])
+  out3eq3[i] = out3[3999,10]+out3[3999,11]
 }
 
-plot(bvalues,out3eq2,xlab="b/10")
+plot(bvalues,out3eq2,xlab="b/10",ylab="Proportion resistant")
+#plot(bvalues,out3eq3)
 print(out3eq2)
+#print(out3eq3)
+
+mat6 = matrix(data=0,nrow=22,ncol=22)
+for (i in 1:22){
+  for (j in 1:22){
+    #d = dvalues[i]
+    #    A = Avalues[j]
+    wr = wrvalues[i]
+    b = bvalues[j]*10
+    p2 = list(b=b,ws=ws,wr=wr,muSU=muSU,muSD=muSD,muRD=muRD,muRU=muRU,Tau=Tau,d=d,m=m)
+    out5 = ode(y=N0,times=t2,func=SEAI,parms=p2)
+    #    PTotal = out5[3999,2] + out5[3999,3] + out5[3999,4] + out5[3999,5]
+    #    mat[i,j] = (out5[3999,4] + out5[3999,5])/PTotal
+    #mat2[i,j] = (out5[3999,2] + out5[3999,3] + out5[3999,4] + out5[3999,5])/6000
+    #mat3[i,j] = out5[3999,6]/out5[3999,7]
+    mat6[i,j] = (out5[3999,4]+out5[3999,5])/(out5[3999,2] + out5[3999,3] + out5[3999,4] + out5[3999,5])
+
+  }
+}
+print(mat6)
+
+