Solve the following equation for v0 and again for t: v=v0+ at

Calculate the rms currents (in A) for an AC source given by  v(t) = V0 sin(?t), where...

Calculate the rms currents (in A) for an AC source given by  v(t) = V0 sin(?t), where V0 = 100 V and ? = 200? rad/s, when connected across the following. (a) a 22 µF capacitor A (b) a 40 mH inductor A (c) a 46 ? resistor A

4) The output voltage from function generator can be described by the following equation V(t) =...

4) The output voltage from function generator can be described by the following equation V(t) = V0 ? f(t) + C Where V(t) is the actual output, f(t) is determined by the type of output shape, , . What is the effect of turning the frequency knob up?

Solve for the mass density of the string using the equation ? = sqrt T /...

Solve for the mass density of the string using the equation ? = sqrt T / µ. Use the experimental slope = (1/µ) = 1270.826 kg/m to find the actual value of µ. If needed: v = 26.4 m/s T = 0.4905 (kg)(m/s^2) Please explain how you found µ by providing each equation/step taking in order to solve for µ. Include algebra as well and thank you!

Y'''+Y'=0 Let v(t)=y'(t), write the differential equation satisfied by v.

Y'''+Y'=0 Let v(t)=y'(t), write the differential equation satisfied by v.

Solve the differential equation x''(t)+5x'(t)+4x(t)=2

Solve the differential equation x''(t)+5x'(t)+4x(t)=2

solve diff equation: y'' - 2y' + y = (e^t)/t

solve diff equation: y'' - 2y' + y = (e^t)/t

Use the Laplace Transform method to solve the following differential equation problem: y 00(t) − y(t)...

Use the Laplace Transform method to solve the following differential equation problem: y 00(t) − y(t) = t + sin(t), y(0) = 0, y0 (0) = 1 Please show partial fraction steps to calculate coeffiecients.

) Solve the differential equation dydt= cos⁡(t)y+sin(t) using either the method of variation of parameters or...

) Solve the differential equation dydt= cos⁡(t)y+sin(t) using either the method of variation of parameters or the method of integration factor. Clearly identify the integration factor or parameter v(t) used (depending on which method you use). Also identify the solution to the homogeneous equation, and the particular solution. The use your solution to find the solution to the IVP obtained by adding the initial condition y(0) = 1.

Solve for x(t) the following equation using Laplace transform: x ̈ - 3x ̇ + 2x...

Solve for x(t) the following equation using Laplace transform: x ̈ - 3x ̇ + 2x = 4 With (x ) ̇(0)=3 ; x (0)=2

Solve heat equation for the following conditions ut = kuxx t > 0, 0 < x...

Solve heat equation for the following conditions ut = kuxx t > 0, 0 < x < ∞ u|t=0 = g(x) ux|x=0 = h(t) 2. g(x) = 1 if x < 1 and 0 if x ≥ 1 h(t) = 0; for k = 1/2