MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Electrical Engineering and Computer Science 6.003: Signals and Systems--Fall 2003 PROBLEM SET 2 SOLUTIONS (E1)O&W1.38(a) (a) From Figure 1. 34 in O&W, we have the following 6△(t) Figure 2.o1.1 Narrow Pulse Now, consider SA(2t)which is a time compressed version of Figure 1. 34 in Oppenheim and willsky Figure 2.O1.2: Time Compressed Narrow Pulse The area under this new pulse is of course 1. If we take the limit as 4-0,we end up with
� � � � MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Electrical Engineering and Computer Science 6.003: Signals and Systems—Fall 2003 Problem Set 2 Solutions (E1) O&W 1.38(a) (a) From Figure 1.34 in O&W, we have the following ��(t) 1 � t Figure 2.O1.1: Narrow Pulse Now, consider ��(2t) which is a time compressed version of Figure 1.34 in Oppenheim and Willsky. ��(2t) 1 2 1 � t Figure 2.O1.2: Time Compressed Narrow Pulse 1 The area under this new pulse is of course 2 . If we take the limit as � � 0, we end up with: 1
6(2t)=limb△(2t) The area under which remains 3. From the result in Section 1.4.2 of the text we 6(2)=亓6(t) We can also show this using the relationship between the unit step function and the unit impulse (i.e. the unit impulse is the time derivative of the unit step function). For a given A, the approximation of both unit steps t) and uA(2t)are shown to the right. Note that u,△(2t) reaches unity at t=会 Making a change of variable s= 2t where ds 6△(2)6△(t) 2dt and using Eqn(1. 73)in O& w, gives 2dt 1du△(2)12 2 dt 2△△ The area enclosed by a(2t) is half of that of Sa(t) as shown to the right. Since &(t)is defined by it's area, we get d(2t)=38(t). In general 6(a)=一0(t) holds for any nonzero real number a. The above is a proof of the time scaling property, which tells us that we've simply squeezed da(t) by a
� � �(2t) = lim ��(2t) ��0 The area under which remains 1 . From the result in Section 1.4.2 of the text we 2 have: 1 �(2t) = �(t) 2 u�(2t) We can also show this using the relationship 1 between the unit step function and the unit �� u�(t) impulse (i.e. the unit impulse is the time � derivative of the unit step function). For a given �, t the approximation of both unit steps � 0 � u�(t) and u�(2t) are shown to the right. Note 2 � that u�(2t) reaches unity at t = �. 2 Making a change of variable s = 2t where ds = ��(2t) ��(t) 1 2dt and using Eqn(1.73) in O&W, gives � du�(s) du�(2t) ��(s) = = ds 2dt 1 du�(2t) 1 2 1 = = = . 2 dt 2 � � t 0 � The area enclosed by ��(2t) is half of that of 2 � ��(t) as shown to the right. Since �(t) is defined by it’s area, we get �(2t) = 1 �(t). In general 2 1 �(at) = �(t) |a| holds for any nonzero real number a. The above is a proof of the time scaling property, which tells us that we’ve simply squeezed ��(t) by a factor of two. 2
(E2)O&W2.33(a-(i) (a)()We need to find the homogeneous and particular solutions with the final solution being the sum of the two. Let's start with the particular solution which we will denote yp(t). Let the particular solution take the form of the input for t> 0, (t)=Aet. Substituting into(P2 33-1)for t>0 we ha 3.Aet +2Ae Which a g noting the homogeneous solution as yn(t), we have yn(t)= Best where B and s are constants to be determined. Substituting into(P2 33-1)with the input set to o we have Bse+ 2Be 0 Thus the homogeneous solution takes the form Be-2t. The output is then given y(t)= yn(t)+ yp(t) We know that the system is initially at rest, so at t=0, the output has to be zero B Thus, the output, y(t) + Note that we had to solve for B with the additional information(in addition to the differential equation) that the system was at initial rest. This is because LCCDES are Not complete characterizations of systems. In general, we need more information to compute the output when given and input signal
