Experiment 21 Design a Traffic Arrow.

Slides:

Advertisements

Similar presentations

Experiment 17 A Differentiator Circuit

Advertisements

555 Timer ©Paul Godin Updated February Oscillators ◊We have looked at simple oscillator designs using an inverter, and had a brief look at crystal.

Design a Logic Probe Experiment 20. Design Specifications Design a logic probe as shown in the block diagram of Figure 1 of Experiment 20 with a signal.

Diode Clamper Circuit. By:Engr.Irshad Rahim Memon

Introduction to electronics lab ENGRI 1810 Using: Solderless prototype board (white board) Digital multimeter (DMM) Power Supply Signal Generator Oscilloscope.

Using a 555 Timer.  Emits regular sounds, usually a single frequency tone, beat, or click, which instrument players and singers use to count the meter.

Relaxation Oscillators

Automatic Holiday Light Display. Goal of Experiment Design an automatic light display in which a set of blinking lights (LEDs) turns on as the amount.

Experiment 11: An Inverting Amplifier

Experiments 8 and 9. Same Circuit: Experiment 8 and 9 You should use the +5 V and +9 V supplies on the ANDY board. You should use red wire to bring the.

Announcements Troubles with Assignments… –Assignments are 20% of the final grade –Exam questions very similar (30%) Deadline extended to 5pm Fridays, if.

Section 24.4 The 555 Timer. 2 Rectangular Waves - Reminder: Duty Cycle – ratio of pulse width to cycle time where PW = the pulse width of the circuit.

Part A: Controlling Oscillation Frequency with Capacitors and Resistors Part B: Diodes and Light Experiment Timer.

1 Lab Equipment. 2 TopicSlides DC Power Supply3-4 Digital Multimeter5-8 Function Generator9-12 Scope – basic controls13-20 Scope – cursors21-24 Scope.

Announcements Assignment 1 due now. Assignment 2 posted, due on Thursday.

Project 3 Build an Astable Multivibrator

MEASUREMENT DEVICES OUTLINE Multimeters Analog Multimeters

Electronic Instrumentation Experiment 6: Diodes * Part A: Diode I-V Characteristics * Part B: Rectifiers Part C: PN Junction Voltage Limitation Part D:

Design a Voltmeter Experiment 19. Goal Design a circuit that displays the value of unknown voltage between certain voltage ranges. – The unknown voltage.

M.S.P.V.L. Polytechnic College, Pavoorchatram

Series RC Circuit. Shunt resistor It is good practice to short the unused pin on the trimpot when using it as a variable resistor Velleman function generator.

Pulse Width Modulation (PWM) LED Dimmer Circuit

Week 9: Design a Night Light

As an Astable Multivibrator.  An integrated chip that is used in a wide variety of circuits to generate square wave and triangular shaped single and.

Electronic Metronome Using a 555 Timer.

Pulse Width Modulation (PWM) LED Dimmer Circuit

Series RC Circuit. Shunt resistor It is good practice to short the unused pin on the trimpot when using it as a variable resistor Velleman function generator.

An Inverting Amplifier. Op Amp Equivalent Circuit The differential voltage v d = v 2 – v 1 A is the open-loop voltage gain v2v2 v1v1 An op amp can be.

Chapter 6 Voltage Regulators - Part 2-.

Integrator Op Amp Amplifier

Week 7: Design a Night Light New Experiment It is not in the lab manual.

A Differentiator Circuit.  All of the diagrams use a uA741 op amp. ◦ You are to construct your circuits using an LM 356 op amp.  There is a statement.

Experiment 17 A Differentiator Circuit

09/16/2010© 2010 NTUST Today Course overview and information.

Week 11 Design a Photoflash Charging Circuit. New Experiment Not in the lab manual. It is posted on the course Scholar site.

Electronic Circuits Laboratory EE462G Lab #4 DC Power Supply Circuits Using Diodes.

Automatic Holiday Light Display. Goal of Experiment Design an automatic light display in which a set of blinking lights (LEDs) turns on as the amount.

Single Time Constant Measurement Dr. Len Trombetta 1 ECE 2100.

Analog Discovery Arbitrary Function Generator for Windows 7 by Mr

Diode: Application Half-Wave Rectifier

Lab 10 Experiment 21 Design a Traffic Arrow. Just so it is clear This is it. – Last official experiment for the semester. It is your option as to whether.

Introduction to Phasors Week 2: Experiment 22. Experimental Procedures Do not do the steps labeled “Extra Credit” in the Procedure. No extra credit will.

Chapter 6 Voltage Regulators - Part 2-.

Week 5 Experiments 8 and 9. Lecture Schedule Next week (9/29/2011) – Topics of lectures are: Design a Voltmeter – You have two weeks to perform this lab.

Design a Logic Probe Experiment 20.

Design a Photoflash Charging Circuit.  Not in the lab manual. It is posted on the course Scholar site.

1.0 LINEAR DC POWER SUPPLY The importance of DC Power Supply Circuit For electronic circuits made up of transistors and/or ICs, this power source.

Experiment 4 Kirchhoff’s Laws. Changes from circuit in lab manual. 1. The DC voltage supply to use is +5V, not +9V as is shown in the lab manual. 2. A.

1 13. Pulsed waveforms and Timing Circuit Design 13.1Op. Amp. Pulse GeneratorsOp. Amp. Pulse Generators timer IC Oscillator555 timer IC Oscillator.

1 Surge Current in the Capacitor filter Initially the filter capacitor is uncharged. At the instant the switch is closed, voltage is connected to the bridge.

Diode Rectifier Circuits Section 4.5. In this Lecture, we will:  Determine the operation and characteristics of diode rectifier circuits, which is the.

Week 3: Experiment 4 Kirchhoff’s Laws.

Week 4: Experiment 24 Using Nodal or Mesh Analysis to Solve AC Circuits with an addition of Equivalent Impedance.

Lab 7 Hints. Activity 1C, 1B Activity 1A Battery or power supply (in previous picture)

PEAK INVERSE VOLTAGE Using the ideal diode model, the PIV of each diode in the bridge rectifier is equal to V2.This is the same voltage that was applied.

Chapter 9 CAPACITOR.

CSE251 Diode Applications – Rectifier Circuits. 2 Block diagram of a DC power supply. One of the most important applications of diodes is in the design.

SINGLE PHASE INDUCTION MOTOR SOFT START BY STEPPED DELAY OF REDUCING FIRING ANGLE Submitted by:

Single Phase Induction Motor Speed Control

555 Timer EEE DEPARTMENT KUMPAVAT HARPAL( )

SOFT START OF SINGLE PHASE PUMP MOTOR

Week 9: Series RC Circuit

Project 3 Build an Astable Multivibrator

Project 3 Build an Astable Multivibrator

Week 4: Experiment 24 Using Nodal or Mesh Analysis to Solve AC Circuits with an addition of Equivalent Impedance.

Prepared by: Engr. Qurban Ali Memon Incharge of Final project Lab.

Lecture No# 8 Prepared by: Engr. Qurban Ali Memon

2019 Investing Now Summer Program

Presentation transcript:

Experiment 21 Design a Traffic Arrow

There is NO final in this course! Just so it is clear There is NO final in this course!

10% Portion of Final Grade There was a statement about online lecture quizzes and other activities that is worth 10% of your final grade. This will be a short writing exercise where you will provide input to the ECE department on your experience in the online lab course. This will be posted on the Assignments section of the course Scholar site and will be due on August 14.

Design a Traffic Arrow 3 1 2 6 4 You should place the LEDs on your ANDY board in a similar configuration.

Sequence 1. All LEDs are off 2. 20-40 ms later, Section 1 LEDs turn on Section 1 LEDs remain on 4. 20-40 ms later, Section 3 LEDs turn on Section 1 and 2 LEDs remain on 3. 20-40 ms later, Section 4 LEDs turn on Section 1-3 LEDs remain on

All LEDs are off

Section 1 LEDs are on

Section 2 LEDs are on

Section 3 LEDs are on

All LEDs are on

All LEDs are off

To obtain desired clock frequency for pulse generator Use digital clock (CLCK) on the ANDY board be used. The minium clock frequency is ~ 70 Hz—a frequency well above the maximum suggested in lab manual. To slow down the clock, connect two 100 μF electrolytic capacitors (in series) to the EXT CAP socket header on the ANDY board. Note: it is critical to wire electrolytic capacitors with the correct polarity as discussed in Section 3.1 of this text. Or, use the square wave pulse on the Velleman or Analog Discovery arbitrary function generator.

Electrolytic Capacitor with the ANDY Board The positive lead of capacitor C1 should be plugged into either the top-left or bottom-left pin of the EXT CAP socket header (J17). The negative lead of capacitor C2 must be connected to ground. There is a negative sign on this side of the capacitor. Also, the negative lead is shorter than the positive lead.

Block Diagram of Circuit Charging of C3 is determined by R4C3 time constant.

Discharging of C3 is accomplished using LED 6 when the clock pulse from the ANDY board is at 0V.

Diodes (even LEDs) act like switches When the voltage on the positive side of the diode is greater than the voltage on the negative side plus the turn-on voltage (~2V), the diode conducts current. When the voltage on the positive side is less than the voltage on the negative side plus the turn-on voltage (~2V), the diode acts like an open circuit.

Operation of LED 6 VLED6 < 2V 5 – VC3 > -2V VLED6 > 2V LED6 will be inserted into the circuit ‘backwards’ compared to the other LEDs.

Series of Voltage Comparators Voltage dividers are used to determine the reference voltage at which the op amp output voltage changes from (roughly) V- to V+. You need to calculate what the reference voltages should be to obtain the correct timing of the lights based upon an exponential shape to the voltage across the capacitor,. [Review Experiments 6 and 15]

Resistor Values R0, R1, R2, and R3 are used to limit the current that flows through the LEDs. This should be ~ 10mA. R4 in combination with C3 determines the rate at which the voltage increases on the input of the voltage comparators. Note that C3 will not fully discharge through LED6.

Oscilloscope Measurements You can measure about 4-6 seconds worth of data using your oscilloscope. The measurement must be performed as DC coupled as the rate of change of the voltage across C3 is slow. AC coupling will filter out what appears to be a dc voltage across C3. AC and DC coupling is selectable on the Velleman scope. It is the default condition on the Discovery Analog scope. You can use the square wave signal from the input as the trigger when measuring the other voltages to show the time delay as the sets of LEDS turn on. You should use the oscilloscope when debugging your circuit.

Pre-Lab Submit in a .docx file: PSpice schematic of your full circuit with all resistor and capacitor values included. PSpice simulation of the voltage across C3 as a function of time and the voltage of the pulse generator voltage for the subcircuit shown to the right. Please read the material on LEDs to learn how to use DBREAK and a battery to model the LED.

Circuit Validation Demonstrate that the LEDs light in the prescribed sequence and at the prescribed time (approximately one-half to one second apart).

Post-Validation Report The design report, which may be written in a format of your choosing, should be self-contained. At a minimum, the report must include the following: 1. A statement of the objectives of the project 2. A description of the design principles used and the feature set included 3. A schematic diagram of the circuit 4. A PSpice analysis showing the bias voltages and the locations of any PSpice voltage and/or current probes. A screen snapshot of the PSpice waveforms showing the pulse generator voltage versus the voltage at the junction of R4 and C3 should be included. The waveforms must also show the output voltages from the op amps. Be sure to answer the question in Procedure Part A, step 6. 5. Test results that demonstrate the performance of the design.