Access denied under U.S. Export Administration Regulations.
- Evaluation Boards & Kits
- FPGA Reference Designs
- Quick Start Guides
- Linux Software Drivers
- Microcontroller Software Drivers
- ACE Software
- Technical Guides
- University Program Overview
- ADALM1000 (M1k) Active Learning Module
- ADALM2000 (M2k) Active Learning Module
- ADALP2000 Parts kit for Circuits
- ADALM-PLUTO SDR Active Learning Module
- Teaching and Lab Materials
- Wiki Site Map
- Recent Changes
- Media Manager
- Analog Devices Wiki
Table of Contents
Activity: transient response of rc circuit, for adalm1000.
The objective of this Lab activity is to study the transient response of a series RC circuit and understand the time constant concept using pulse waveforms.
As in all the ALM labs we use the following terminology when referring to the connections to the M1000 connector and configuring the hardware. The green shaded rectangles indicate connections to the M1000 analog I/O connector. The analog I/O channel pins are referred to as CA and CB. When configured to force voltage / measure current - V is added as in CA- V or when configured to force current / measure voltage -I is added as in CA-I. When a channel is configured in the high impedance mode to only measure voltage -H is added as CA-H.
Scope traces are similarly referred to by channel and voltage / current. Such as CA- V , CB- V for the voltage waveforms and CA-I , CB-I for the current waveforms.
Background:
In this lab activity you will apply a pulse waveform to the RC circuit to analyses the transient response of the circuit. The pulse-width relative to a circuit's time constant determines how it is affected by an RC circuit.
Time Constant (τ): Denoted by the Greek letter tau, τ, it represents a measure of time required for certain changes in voltages and currents in RC and RL circuits. Generally, when the elapsed time exceeds five time constants (5τ) after switching has occurred, the currents and voltages have reached their final value, which is also called steady-state response.
The time constant of an RC circuit is the product of equivalent capacitance and the Thévenin resistance as viewed from the terminals of the equivalent capacitor.
A Pulse is a voltage or current that changes from one level to another and back again. If a waveform's high time equals its low time it is called a square wave. The length of each cycle of a pulse is its period (T).
The pulse width (tp) of an ideal square wave is equal to half the time period.
The relation between pulse width and frequency is then given by,
Figure 1: Series RC circuit.
From Kirchhoff's laws, it can be shown that the charging voltage V C (t) across the capacitor is given by:
where, V is the applied source voltage to the circuit at time t = 0. The product RC is the time constant. The response curve is increasing and is shown in figure 2.
Figure 2: Capacitor charging for Series RC circuit to a step input with time axis normalized by t
The discharge voltage for the capacitor is given by:
Where Vo is the initial voltage stored in capacitor at t = 0. The product RC is often referred to the so called time constant, τ. The response curve is a decaying exponential as shown in figure 3.
Figure 3: Capacitor Discharging for Series RC circuit
ADALM1000 hardware module Resistors ( 2.2 KΩ, 10 KΩ) Capacitors (1 µF, 0.01 µF)
1. Set up the circuit shown in figure 4 on your solderless breadboard with the component values R 1 = 2.2 KΩ and C 1 = 1 µF. Open the ALICE Oscilloscope software.
Figure 4. Breadboard diagram of RC circuit R 1 = 2.2 KΩ and C 1 = 1 µF.
Figure 5. Breadboard diagram of RC circuit R 1 = 2.2 KΩ and C 1 = 1 µF.
2. Set the channel A AWG Min value to 0.5 and Max value to 4.5V to apply a 4Vp-p square wave centered on 2.5 V as the input voltage to the circuit. From the AWG A Mode drop down menu select the SVMI mode. From the AWG A Shape drop down menus select Square. From the AWG B Mode drop down menu select the Hi-Z mode.
3. From the ALICE Curves drop down Menu select CA- V , and CB- V for display. From the Trigger drop down menu select CA- V and Auto Level. Adjust the time base until you have at approximately two cycles of the square wave on the display grid.
Figure 6: Oscilloscope Configuration.
This configuration uses the oscilloscope to look at the input of the circuit on channel A and the output of the circuit on channel B. Make sure you have checked the Sync AWG selector.
4. Observe the response of the circuit for the following three cases and record the results.
a. Pulse width » 5t : Set the frequency of AWG A output such that the capacitor has enough time to fully charge and discharge during each cycle of the square wave. So let the pulse width be 15t and set the frequency according to equation (2). The value you have found should be approximately 15 Hz. Determine the time constant from the waveforms obtained on the screen if you can. If you cannot obtain the time constant easily, explain possible reasons.
b. Pulse width = 5t : Set the frequency such that the pulse width = 5t (this should be approximately 45 Hz). Since the pulse width is 5t, the capacitor should just be able to fully charge and discharge during each pulse cycle. From the figure determine t (see figure 2 and figure 7 below.)
Figure 7: Measuring the time constant t approximately by counting the number of squares.
c. Pulse width « 5t : In this case the capacitor does not have time to charge significantly before it is switched to discharge, and vice versa. Let the pulse width be only 1.0t in this case and set the frequency accordingly.
5. Repeat the procedure using R 1 = 10 KΩ and C 1 = 0.01 µF and record the measurements.
1. Calculate the time constant using equation (1) and compare it to the measured value from 4b. Repeat this for other set of R and C values.
2. Discuss the effects of changing component values.
- Fritzing files: rc_filt_bb
- LTSpice files: rc_filt_ltspice
For Further Reading:
ALICE Oscilloscope User's Guide Oscilloscope Terminology
Return to Introduction to Electrical Engineering Lab Activity Table of Contents Return to Circuits Lab Activity Table of Contents
- View Source
- Fold/unfold all
- [ Back to top ]
Transient response of RC circuit
After the introduction of the SMU ADALM1000 let’s continue with the fourth part of our series with some small, basic measurements.
By Doug Mercer and Antoniu Miclaus, Analog Devices
Now let’s get started with the next experiment.
The objective of this lab activity is to study the transient response of a series RC circuit and understand the time constant concept using pulse waveforms.
Background:
In this lab activity, you will apply a pulse waveform to the RC circuit to analyze the transient response of the RC circuit. The pulse width relative to a circuit’s time constant determines how it is affected by an RC circuit.
Time Constant ( τ ): A measure of time required for certain changes in voltages and currents in RC and RL circuits. Generally, after four time constants ( 4 τ ), the capacitor in the RC circuit is virtually fully charged and the voltage across the capacitor is now approximatively at 98% of its maximum value. This interval is considered to be the transient response of the RC circuit. When the elapsed time exceeds five time constants ( 5 τ ) after switching has occurred, the currents and voltages have reached their final value, which is also called steady-state response.
Table 1 shows the voltage and current percentage values for the capacitor in the RC charging circuit at a given time constant while charging.
Table 1. Voltage and Current Percentage Values for Given Time Constant
| Time Constant (τ) | Percentage of Maximum | |
| Voltage | Current | |
| 0.5 τ | 39.3% | 60.7% |
| 0.7 τ | 50.3% | 49.7% |
| τ | 63.2% | 36.8% |
| 2 τ | 86.5% | 13.5% |
| 3 τ | 95.0% | 5.0% |
| 4 τ | 98.2% | 1.8% |
| 5 τ | 99.3% | 0.7% |
Note that the capacitor will never become 100% charged in reality. Therefore, five time constants are used to consider a capacitor fully charged for all practical purposes.
The time constant of an RC circuit is the product of equivalent capacitance and the Thévenin resistance as viewed from the terminals of the equivalent capacitor.
A pulse is a voltage or current that changes from one level to another and back again. If a waveform’s high time equals its low time it is called a square wave. The length of each cycle of a pulse is its period ( T ).
The pulse width ( t p ) of an ideal square wave is equal to half the time period.
The relation between pulse width and frequency is then given by,
From Kirchhoff’s laws, it can be shown that the charging voltage V c ( t ) across the capacitor is given by:
where V is the applied source voltage to the circuit for t = 0 , and R C = τ is the time constant.
The transient response curve of RC circuit increases and is shown in Figure 3.
The discharge voltage for the capacitor is given by:
Where V 0 is the initial voltage stored in capacitor at t = 0 , and R C = τ is time constant. The response curve is a decaying exponential as shown in Figure 4.
- ADALM1000 hardware module
- Resistors ( 2 . 2 k Ω , 10 k Ω )
- Capacitors ( 1 μ F , 0 . 01 μ F )
1. Set up the circuit shown in Figure 5 on your solderless breadboard with the component values R 1 = 2 . 2 k Ω and C 1 = 1 μ F . Open the ALICE Oscilloscope software.
2. Set the Channel A arbitrary waveform generator (AWG) Min value to 0.5 V and the Max value to 4.5 V to apply a 4 V p-p square wave centered on 2.5 V as the input voltage to the circuit. From the AWG A Mode drop down menu, select the SVMI mode. From the AWG A Shape drop down menus select Square . From the AWG B Mode drop down menu, select the Hi-Z mode.
3. From the ALICE Curves drop down menu, select CA-V and CB-V for display. From the Trigger drop down menu, select CA-V and Auto Level . Adjust the time base until you have at approximately two cycles of the square wave on the display grid.
This configuration uses the oscilloscope to look at the input of the circuit on Channel A and the output of the circuit on Channel B. Make sure you have checked the Sync AWG selector.
4. Observe the response of the circuit for the following three cases and record the
- Pulse width ≫ 5 τ : Set the frequency of AWG A output such that the capacitor has enough time to fully charge and discharge during each cycle of the square Let the pulse width be 15 τ and set the frequency according to Equation 2. The value you have found should be approximately 15 Hz. Determine the time constant from the waveforms obtained on the screen if you can. If you cannot obtain the time constant easily, explain possible reasons.
- Pulse width = 5 τ : Set the frequency such that the pulse width = 5 τ (this should be approximately 45 Hz). Since the pulse width is 5 τ , the capacitor should just be able to fully charge and discharge during each pulse cycle (see Figure 3 and Figure 4).
- Pulse width ≪ 5 τ : In this case the capacitor does not have time to charge significantly before it is switched to discharge, and vice versa. Let the pulse width be only 1 . 0 τ in this case and set the frequency.
5. Repeat the procedure using R 1 = 10 k Ω and C 1 = 0 . 01 μ F and record the measurements.
- Calculate the time constant ( τ ) using Equation 1 and compare it to the measured value from 4b ( R = 2 k Ω and C = 0 . 01 μ F ).
- Repeat this for another set of values, R = 10 k Ω and C = 0 . 01 μ F . You can find the answers at the StudentZone blog .
As in all the ALM labs, we use the following terminology when referring to the connections to the ALM1000 connector and configuring the hardware. The green shaded rectangles indicate connections to the ADALM1000 analog I/O connector. The analog I/O channel pins are referred to as CA and CB. When configured to force voltage/measure current, –V is added (as in CA-V) or when configured to force current/measure voltage, –I is added (as in CA-I). When a channel is configured in the high impedance mode to only measure voltage, –H is added (as in CA-H).
Scope traces are similarly referred to by channel and voltage/current, such as CA-V and CB-V for the voltage waveforms, and CA-I and CB-I for the current waveforms.
We are using the ALICE Rev 1.1 software for those examples here. File: alice-desktop-1.1-setup.zip. Please download here .
The ALICE desktop software provides the following functions:
- A 2-channel oscilloscope for time domain display and analysis of voltage and current
- The 2-channel arbitrary waveform generator (AWG) controls.
- The X and Y display for plotting captured voltage and current voltage and current data, as well as voltage waveform histograms.
- The 2-channel spectrum analyzer for frequency domain display and analysis of voltage
- The Bode plotter and network analyzer with built-in sweep generator.
- An impedance analyzer for analyzing complex RLC networks and as an RLC meter and vector
- A dc ohmmeter measures unknown resistance with respect to known external resistor or known internal 50 Ω.
- Board self-calibration using the AD584 precision 2.5 V reference from the ADALP2000 analog parts kit.
- ALICE M1K voltmeter.
- ALICE M1K meter source.
- ALICE M1K desktop tool.
For more information, please look here .
Note: You need to have the ADALM1000 connected to your PC to use the software.
Doug Mercer [[email protected]] received his B.S.E.E. degree from Rensselaer Polytechnic Institute (RPI) in 1977. Since joining Analog Devices in 1977, he has contributed directly or indirectly to more than 30 data converter products and he holds 13 patents. He was appointed to the position of ADI Fellow in 1995. In 2009, he transitioned from full-time work and has continued consulting at ADI as a Fellow Emeritus contributing to the Active Learning Program. In 2016 he was named Engineer in Residence within the ECSE department at RPI.
Antoniu Miclaus [[email protected]] is a system applications engineer at Analog Devices, where he works on ADI academic programs, as well as embedded software for Circuits from the Lab® and QA process management. He started working at Analog Devices in February 2017 in Cluj-Napoca, Romania. He is currently an M.Sc. student in the software engineering master’s program at Babes-Bolyai University and he has a B.Eng. in electronics and telecommunications from Technical University of Cluj-Napoca.
Band-stop filters
29th March 2022 12th April 2022
Thévenin equivalent circuit and maximum power transfer
31st January 2020 3rd March 2022
Transient response of RL circuit
14th February 2020 3rd March 2022
COMMENTS
In this experiment, we apply a pulse waveform to the RC circuit to analyze the transient response of the circuit. The pulse-width relative to a circuit's time constant determines how it is affected by an RC circuit. Time Constant (τ): A measure of time required for certain changes in voltages and currents in RC and RL circuits.
The capacitor's voltage and current during the discharge phase follow the solid blue curve of Figure 8.4.2 . The elapsed time for discharge is 90 milliseconds minus 50 milliseconds, or 40 milliseconds net. We can use a slight variation on Equation 8.4.5 to find the capacitor voltage at this time. VC(t) = Eϵ − t τ.
steady state. We call the response of a circuit immediately after a sudden change the transient response, in contrast to the steady state. A rst example Consider the following circuit, whose voltage source provides v in(t) = 0 for t<0, and v in(t) = 10V for t 0. in + v (t) R C + v out A few observations, using steady state analysis. Just before ...
Forced Response of RC Circuits. For the circuit shown on Figure 15 the switch is closed at t=0. This corresponds to a step function for the source voltage Vs as shown on Figure 16.We would like to obtain the capacitor voltage vc as a function of time. The voltage across the capacitor at t=0 (the initial voltage) is Vo.
In this experiment, we apply a pulse waveform to the RC circuit to analyse the transient response of the circuit. The pulse-width relative to a circuit's time constant determines how it is affected by an RC circuit. Time Constant (t): A measure of time required for certain changes in voltages and currents in RC and RL circuits.
operation. This experiment is designed to familiarize the student with the simple transient response of two-element RC circuits, and the various methods for measuring and displaying these responses. Case 1: Capacitor is Charging In normal operation, a capacitor charges part of the time and discharges at other times. Consider first
Exercise 1: Procedure. (1) Analytically determine the time constants of the circuits in Figures 2 & 3. (remember that the oscilloscope acts as 1MΩ resistor) Connect the power supply, 1μf capacitor, 1MΩ resistor, and channel 1 of the oscilloscope as shown in Figure 2. Set the trigger mode to Single and the trigger slope to detect a falling slope.
Background: In this lab activity you will apply a pulse waveform to the RC circuit to analyse the transient response of the circuit. The pulse-width relative to a circuit's time constant determines how it is affected by an RC circuit. Time Constant (τ): Denoted by the Greek letter tau, τ, it represents a measure of time required for certain ...
Experiment 8 Pre-Reading Transient Response in RC Circuits ©2008 by Professor Mohamad H. Hassoun In this experiment, the student will examine the types and properties of capacitors and the transient behavior of simple RC circuits. The student will also explore a voltage integrator that utilizes a capacitor in an op-amp circuit. Learning Objectives
Now let's get started with the next experiment. Objective: The objective of this lab activity is to study the transient response of a series RC circuit and understand the time constant concept using pulse waveforms. Background: In this lab activity, you will apply a pulse waveform to the RC circuit to analyze the transient response of the ...
Experiment 2: RC Circuit Transient Behavior Goal: To learn how to use an oscilloscope and use it to study the transient response of an RC circuit subjected to a square wave EMF applied by a function generator. Circuit: The function generator applies an alternating square wave EMF with amplitude V o at frequency f as indicated in the diagram.
Breadboard diagram of RC circuit R 1 = 2.2 KΩ and C 1 = 1 µF. 2. Set the channel A AWG Min value to 0.5 and Max value to 4.5V to apply a 4Vp-p square wave centered on 2.5 V as the input voltage to the circuit. From the AWG A Mode drop down menu select the SVMI mode. From the AWG A Shape drop down menus select Square.
V1. 1k. TF = 0 PW = 1E-3 PER = 2E-3. 0. V. C1. 0.1E-6. Build the RC circuit shown in the top figures (They are the same circuit but the PSpice circuit on the right shows probe position). On the Discovery Board, set your signal to a 1V amplitude (2V peak-to-peak) square wave with a DC offset of 1 Volts.
RL Circuits First-order circuits with inductors can be analyzed in much the same way. Consider the \charging" and \dis- charging" RL circuits below. ISR L iL(t) IS L iL(t) R t =0 t =0. Figure 3: The \charging" and \discharging" RL circuits. While the notion of charging an inductor doesn't really make sense, one can think of this in terms of ...
This exercise is similar to the "Transient Response of an RC Circuit" exercise, except that the capacitor is replaced by an inductor. In this experiment, you will apply a square waveform to the RL circuit to analyze the transient response of the circuit. The pulse width relative to the circuit's time constant determines how it is affected ...
Series RC circuit. From Kirchhoff's laws, it can be shown that the charging voltage V c (t) across the capacitor is given by: V c (t) = V (1 - e - t R C), t ≥ 0. where V is the applied source voltage to the circuit for t = 0, and R C = τ is the time constant. The transient response curve of RC circuit increases and is shown in Figure 3 ...
Second-Order Transient Response In ENGR 201 we looked at the transient response of first-order RC and RL circuits Applied KVL Governing differential equation Solved the ODE Expression for the step response For second-order circuits, process is the same: Apply KVL Second-order ODE Solve the ODE Second-order step response
explained below (this is the same method we used in Experiment 8 to visualize the transient response of an RC circuit). Figure 8 depicts a DC voltage source in series with a switch. The switch can have two positions: "up" and "down". When the switch is in the "up" position, the voltage V S is applied to the series RL components ...
Figure 2 shows the response of the series RLC circuit with L=47mH, C=47nF and for three different values of R corresponding to the under damped, critically damped and over damped case. We will construct this circuit in the laboratory and examine its behavior in more detail. Under Damped. R=500Ω. Critically Damped. R=2000 Ω. Over Damped. R ...
The Transient Response of RC Circuits The Transient Response (also known as the Natural Response) is the way the circuit responds to energies stored in storage elements, such as capacitors and inductors. If a capacitor has energy stored within it, then that energy can be dissipated/absorbed by a resistor. How that energy is dissipated is the ...
The transient response of RL circuits is nearly the mirror image of that for RC circuits. To appreciate this, consider the circuit of Figure 9.5.1 . Figure 9.5.1 : RL circuit for transient response analysis. Again, the key to this analysis is to remember that inductor current cannot change instantaneously.
In this experiment, we apply a square waveform to the RL circuit to analyse the transient response of the circuit. The pulse-width relative to the circuit's time constant determines how it is affected by the RL circuit. Time Constant (t): It is a measure of time required for certain changes in voltages and currents in RC and RL circuits.