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New answer posted

a year ago

0 Follower 10 Views

V
Vishal Baghel

Contributor-Level 10

(x+1)dydx=2ey1dy2ey1=dxx+1eydy2ey=dxx+1

Integrating both sides, we get:

eydy2ey=log|x+1|+logC..........(1)Let2ey=tddy(2ey)=dtdyey=dtdyeydy=dt

Substituting this value in equation (1), we get:

dtt=logog|x+1|+logClog|t|=log|C(x+1)|log|2ey|=log|C(x+1)|12ey=C(x+1)2ey=1C(x+1)..........(2)

Now, at x=0& y=0, equation (2) becomes:

21=1CC=1

Substituting C=1 in equation (2), we get:

2ey=1x+1ey=21x+1ey=2x+21x+1ey=2x+1x+1y=log|2x+1x+1|,(x1)

This is the required particular solution of the given differential equation.

New question posted

a year ago

0 Follower 1 View

New answer posted

a year ago

0 Follower 2 Views

V
Vishal Baghel

Contributor-Level 10

The given differential equation is:

dydx+ycotx=4xcosecx

This equation is a linear equation of the form

dydx+Py=Q,where,p=cotx&Q=4xcosecxNow,I.F=ePdx=ecotxdx=elog|sinx|=sinx

The general solution of the given differential equation is given by,

y(I.F)=(Q*I.F.)dx+C

ysinx=(4xcosecx.sinx)dx+Cysinx=4xdx+Cysinx=4.x22+Cysinx=2x2+C..........(1)Now,y=0at,x=π2

Therefore, equation (1) becomes:

0=2*π2+CC=π22

Substituting C=π22 in equation (1), we get:

ysinx=2x2π22

This is the required particular solution of the given differential equation.

New answer posted

a year ago

0 Follower 1 View

V
Vishal Baghel

Contributor-Level 10

Kindly go through the solution

New answer posted

a year ago

0 Follower 3 Views

A
alok kumar singh

Contributor-Level 10

1. Ans:

(a). According to Ellingham diagram, the reaction of CO2 is more feasible at temperatures lower than 710 K and thus it is a better reducing agent below 710 K.

While the reaction of CO is more feasible at temperatures higher than 710 K and thus it is a better reducing agent at above 710 K.

 

(b). According to the Ellingham diagram, the more negative the Gibbs free energy of a particular reaction the more feasible it is to carry out. Since the oxides are easier to reduce, sulfide ores are converted into oxides before reduction.

 

(c). To extract copper,

...more

New answer posted

a year ago

0 Follower 29 Views

V
Vishal Baghel

Contributor-Level 10

(xy)(dx+dy)=dxdy(xy+1)dy=(1x+y)dxdydx=1x+yxy+1dydx=1(xy)1+(xy)..........(1)Let,xy=tddx(xy)=dtdx1dydx=dtdx1dtdx=dydx

Substituting the values of xy and dydx in equation (1), we get:

1dtdx=1t1+tdtdx=1(1t1+t)dtdx=(1+t)(1t)1+tdtdx=2t1+t

(1+ttdt)=2dx(1+1t)dt=2dx..........(2)

Integrating both sides, we get:

t+log|t|=2x+C(xy)+log|xy|=2x+Clog|xy|=x+y+C..........(3)

Now,y=1,at,x=0

Therefore, equation (3) becomes:

log1=01+C

C=1

Substituting C=1 in equation (3), we get:

og|xy|=x+y+1

This is the required particular solution of the given differential equation .

New answer posted

a year ago

0 Follower 13 Views

V
Vishal Baghel

Contributor-Level 10

yexydx=(xexy+y2)dyyexydxdy=xexy+y2exy[y.dxdyx]=y2exy.[y.dxdyx]y2=1..........(1)

Let,exy=z

Differentiating it with respect to y, we get:

(exy)=dzdyexy.ddy(xy)=dzdyexy.[y.dxdyxy2]=dzdy..........(2)

From equation (1) and equation (2), we get:

dzdy=1dz=dy

Integration both sides, we get:

z=y+Cexyy+C

New answer posted

a year ago

0 Follower 15 Views

V
Vishal Baghel

Contributor-Level 10

(1+e2x)dy+(1+y2)exdx=0dy1+y2+exdx1+e2x=0

Integrating both sides, we get:

tan1y+exdx1+e2x=C..........(1)Let,ex=te2x=t2ddx(ex)=dtdxex=dtdxexdx=dt

Substituting these values in equation (1), we get:

tan1y+dt1+t2=Ctan1y+tan1t=Ctan1y+tan1(ex)=C..........(2)Now,y=1,at,x=0

Therefore, equation (2) becomes:

tan11+tan11=Cπ4+π4=CC=π2

Substituting C=π2 in equation (2), we get:

tan1y+tan1(ex)=π2

This is the required solution of the given differential equation.

New answer posted

a year ago

0 Follower 4 Views

V
Vishal Baghel

Contributor-Level 10

The differential equation of the given curve is:

sinxcosydx+cosxsinydy=0sinxcosydx+cosxsinydycosxcosy=0tanxdx+tanydy=0

Integrating both sides, we get:

log(secx)+log(secy)=logClog(secx.secy)=logCsecx.secy=C..........(1)

The curve passes through point (0,π4)

1*√2=CC=√2

On subtracting C=√2 in equation (10, we get:

secx.secy=√2secx.1cosy=√2cosy=secx/√2

New answer posted

a year ago

0 Follower 3 Views

V
Vishal Baghel

Contributor-Level 10

Given: Differential equation dydx+y2+y+1x2+x+1=0

dydx+y2+y+1x2+x+1=0dydx= (y2+y+1)x2+x+1dyy2+y+1=dxx2+x+1dyy2+y+1+dxx2+x+1=0

Integrating both sides,

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