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Transient Analysis - Applications, Switches, and SPICE Voltage-Controlled Switches, and Designing Responses Kevin D. Donohue, University of Kentucky 1 Recall Example Determine the pulse response for io(t) the circuit below with input vs(t) = 40v(t), where pulse duration T is 2 ms: io(t) 10 vs(t) 0.1 mF 40 Show: i0pulse(t ) 0.8 0.8 exp(1250t )u(t ) 0.8 0.8 exp(1250(t 2m))u(t 2m)amps iopulse(t ) 0.8u(t ) u(t 2m) 0.8 exp(1250t )u(t ) 12.1825u(t 2m)amps Pulse Response 0.8 0.7 0.6 ma 0.5 0.4 0.3 0.2 0.1 0 0 1 2 3 4 ms 5 6 7 8 Kevin D. Donohue, University of Kentucky 2 Recall SPICE Simulation Do a SPICE Simulation to determine the pulse response for io(t) the previous circuit with input vs(t) = 40v(t), where pulse duration T is 2 ms: To solve you must do a transient analysis, define the voltage source as piecewise linear, and describe its transient properties. R 10 (Amp) +0.000e+000 +2.000m +4.000m R0 40 tranex-Transient-14 C 0.0001 +8.000m V 0 tranex-Transient-14-Table TIME I(VAM) (s) (Amp) +0.000e+000 +0.000e+000 +10.000n +99.999n +10.840n +109.104n : : : : : : +7.285m +972.534u +7.445m +795.710u +7.605m +651.035u +7.765m +532.665u +7.925m +435.817u VAm Time (s) +6.000m +8.000m +500.000m +396.630u +0.000e+000 I(VAM) Kevin D. Donohue, University of Kentucky 3 SPICE Simulation With Switches Use voltage controlled switches in SPICE to determine the pulse response for io(t) in the previous circuit with input vs(t) = 40v(t), where pulse duration T is 2 ms: To solve you must set up separate circuits for the controlling voltages defined as piece-wise linear voltage to achieve switching action. V0 0 R 10 SwitchV0 VAm R0 40 V1 0 C 0.0001 SwitchV1 V 40 V1 for SwitchV1 Time Voltage 0 1 .00001 -1 .00199 -1 .00201 1 .008 1 IVm 0 V0 for SwitchV0 Time Voltage 0 -1 .00001 1 .00199 1 .00201 -1 .008 -1 IVm For switch settings, you should give each a unique name and indicate the controlling source (V1 or V0) or a voltmeter name. You can also modify the closed and open resistances of the switch, which are default 1 ohm and 1G ohm, respectively. When control voltage is less than 0, switch is closed. When control voltage is greater than 0, switch is open. Kevin D. Donohue, University of Kentucky 4 SPICE Plots Compare the results from response using a pulsed voltage source to that of the result using switches (Closed resistance = 1 Ohm, Open resistance = 1G Ohm: tranexsw-Transient-17 (Amp) +0.000e+000 706mA Switch Example +2.000m +4.000m Time (s) +6.000m +8.000m +600.000m +400.000m +200.000m +0.000e+000 I(VAM) tranex-Transient-14 (Amp) +0.000e+000 735mA Pulse Source Example +2.000m +4.000m Time (s) +6.000m +8.000m +500.000m +0.000e+000 Kevin D. Donohue, University of Kentucky 5 Design Transmitting Terminal for Digital Communications Link The circuit below represents a channel for sending digital data in the form of unit pulses transmitted from vp. A pulse with amplitude -1 V is a binary 0 and a 1 V pulse is a binary 1. The receiver has an infinite input impedance and is connected at vr. Find R0 to make the system critically damped. For the critically damped case using a detector that requires the voltage to be greater than 0.95 volts for a binary 1 (below -0.95 volts for binary 0) for at least 50% of the pulse duration, what is the smallest pulse duration that should be transmitted over this channel? R0 vp R=2 L=10H C=.1F + vr - Kevin D. Donohue, University of Kentucky 6 Obtain Design Equations: Characteristic Equation for System: 1 R R0 s 0 s LC L 2 Roots: 2 s1,2 4 R R0 R R0 LC L L 2 R0 18,22 While a negative resistance can be achieve with electronics and a power supply, it will be more expensive than a simple positive resistance so choose R0 18 Kevin D. Donohue, University of Kentucky 7 Analysis to Determine Bit Rate For R0 = 18, solution becomes: 1 A1 exp( 106 t ) A2t exp( 106 t ) For Binary 1 Interval vr 1 B1 exp( 106 t ) B2t exp( 106 t ) For Binary 0 Interval Assume a worse case transition of -1 V to 1 V, where steady-state had effectively been reached before the transition. Therefore initial conditions become vc(0+) = -1 and iL(0+) = 0: vr 1 2 exp( 106 t ) 2(106 )t exp( 106 t ) Kevin D. Donohue, University of Kentucky 8 Find Result Numerically Can write a Matlab program to plot result and numerically find pulse width: Plot of vr in -1 to 1 transition 1 0.8 0.6 0.4 0.2 volts Since waveform must be above .95 volts for 50% of the pulse duration, the smallest pulse that should be used is 11.14 s. This would correspond to a bit rate of 8.97 kbits/sec. This could carry 0.064 channels of stereo CD quality audio, or 1.4 telephone quality voice signals. vr exceeds .95 V at t=5.57 microseconds 0 -0.2 -0.4 -0.6 -0.8 -1 0 1 2 3 4 5 6 microseconds Kevin D. Donohue, University of Kentucky 7 8 9 10 9 Matlab Program A Matlab program is referred to as a script (type “help script” at the Matlab prompt for more information). This is a text file that ends with a *.m extension (also called an mfile). Program comments are preceded by the percent symbol %. % This program will find the time point where the waveform vr = .95 % Since time constant is 1/1e6 = 1 microsecond, create a time axis for about 10 time constants: t = 10*(1/1e6)*[0:9999]/10000; % Create 10000 points over 10 time constants vr = 1 - 2*exp(-1e6*t) - 2e6*t.*exp(-1e6*t); % Create function points Kevin D. Donohue, University of Kentucky 10 Matlab Program Continued ... % Plot waveform, divide axis by 1e-6 to put units in microseconds plot(t/1e-6,vr) xlabel('microseconds') % Label x-axis ylabel('volts') % Label y-axis % Plot and plot a dashed line at .95 volts hold on % Keep current plot in figure box and plot over it with … plot(t/1e-6,.95*ones(size(t)), 'k--') % in above, k means black, and -– means broken line (see help plot) % Loop to find points where vr exceed .95: k = 1; % Initialize array index kend = length(t); % Find total number of points in array % While loop, increment k until vr equals or exceeds .95 while (vr(k)<.95) k=k+1; end Kevin D. Donohue, University of Kentucky 11 Matlab Program Continued … tint = t(k) % Find time point from index plot([tint, tint]/1e-6, [-1 1], 'k--') % hold off Plot vertical line Kevin D. Donohue, University of Kentucky 12