please answer 2.2-3 parts a,b, and c
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please answer 2.2-3 parts a,b, and c Simplity your ansel. 2.23 A real LTIC system with...
An LTIC system is specified by the equation(D2+9)y(t)=(3D+2)x(t)y0(0^-)=6a. Find the characteristic polynomial, characteristic equation, characteristic roots, and characteristic modes of this system.b. Find y0(t) the zero-input component of the response y(t) for t ≥ 0, if the initial conditions are y0(0−) = 2 and y0(0^-)=-1
3. An LTIC system is specified by the equation (D2 9)y(t) (3D 2)x(t) Assume y(0)3,y(0) 6 d) What is the characteristic equation of this system? e) What are the characteristic roots of this system? f Determine the zero-input response yo(t). Simplify your answer
3. An LTIC system is specified by the equation (D2 9)y(t) (3D 2)x(t) Assume y(0)3,y(0) 6 d) What is the characteristic equation of this system? e) What are the characteristic roots of this system? f Determine the...
2. (Chapter 2). A linear, time-invariant, continuous-time (LTIC) system with input f(t) and output y(t) is specified by the differential equation D2(D +1)y(t) (D - 3)f(t) Find the characteristic polynomial, characteristic equation, characteristic root(s), and characteristic mode(s) of this system. a. b. Is this system asymptotically stable, marginally stable, or unstable? Justify your answer.
2. (Chapter 2). A linear, time-invariant, continuous-time (LTIC) system with input f(t) and output y(t) is specified by the differential equation D2(D +1)y(t) (D - 3)f(t)...
2. (Chapter 2). A linear, time-invariant, continuous-time (LTIC) system with input 1(1) and output y(t) is specified by the differential equation D(D? + 1)y(t) = Df(t). a. Find the characteristic polynomial, characteristic equation, characteristic root(s), and characteristic mode(s) of this system. b. Is this system asymptotically stable, marginally stable, or unstable? Justify your answer.
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Find yol(t), the zero-input component of the response for an LTIC system described by the following differential equation: (D2 + 6D +9)y(t) (3D+5)r(t) where the initial conditions are yo(0)-3)0(0) -7
Find yol(t), the zero-input component of the response for an LTIC system described by the following differential equation: (D2 + 6D +9)y(t) (3D+5)r(t) where the initial conditions are yo(0)-3)0(0) -7
(b) Given a LTIC system described by (D2 + 3D + 2)y(t) = Dx(t) with initial conditions y(0) = 0, y(0) = 5. X(t) = e . Find the zero input response. [10 points)
Questions 4-5: An LTIC system can be described by an equation: dy(t) dr 2 + 2x(t) dt? 4. What will be the zero-input response y(i), if the initial conditions are yo (0) = 0, and Y. (O) = 12 A). y.(t) = e" + B). y(t)=en-ex C). y.(t)=e-2 -2% D). y(t) = -2-2 +e-3 The transfer function of the LTIC system can be calcu . If the input signal of the system is x(t) = 8(6), what will as H(m)...
3. Consider a linear time invariant system described by the differential equation dy(t) dt RCww + y(t)-x(t) where yt) is the system's output, x(t) ?s the system's input, and R and C are both positive real constants. a) Determine both the magnitude and phase of the system's frequency response. b) Determine the frequency spectrum of c) Determine the spectrum of the system's output, y(r), when d) Determine the system's steady state output response x()-1+cos(t) xu)+cost)
Not yet graded /30 pts Question 3 A system is described by the following second-order linear differential equation dy + +5 6y(t)-4f(t )-3f(t) dt dt2 where y(0)-1. y (0) 5, and the input f(t) e'u(t) Solve the differential equation using the Laplace Transform method. Note that f(0) - 0 Your Answer: no option to upload answers so i emailed them to you Quiz Score: 0 out of 100 hp 12 144 5 6
Not yet graded /30 pts Question 3...
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1. Answer the following questions for the system below. (60 pts) (a) Derive the equation of motion in a matrix form: [m]{x}+[k]{x}={F(t)} (b) Write the characteristic equation. (c) Find the natural frequencies and natural modes. (d) Prove the orthogonality of the natural modes. (e) Determine the amplitude of x, at t=1 sec when it starts to vibrate from rest at t=0 sec. X2 4k 2k 4m m cos 100