After i do what you explain Prof output in ejs console give this
cHotEqn V 4.02 cHotEqn
cHotEqn V 4.02 cHotEqn
Setting eq to
cHotEqn V 4.02 cHotEqn
Setting eq to
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
cHotEqn V 4.02 cHotEqn
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
cHotEqn V 4.02 cHotEqn
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c
Setting eq to m\frac{d^2y}{dt^2}+b\frac{dy}{dt}+ky=mg
Setting eq to L\frac{d^2Q}{dt^2}+R\frac{dQ}{dt}+\frac{Q}{C}=V_c