proteus homework help
Boost your journey with 24/7 access to skilled experts, offering unmatched proteus homework help
Trusted by 1.1 M+ Happy Students
Recently Asked proteus Questions
Expert help when you need it- Q1:Part 1 | Create Primitive Blocks 1. Create the 1-bit adder block defined in the 4-bit carry lookahead adder circuit. (see lecture handout) 2. Create a half adder circuit. 3. Create a full adder circuit. 4. Create the lookahead carry unit block defined in the 4-bit carry lookahead adder circuit. (see lecture handout) 5. Create a 4-input odd function circuit. (see lecture handout)See Answer
- Q2:Part III | Create Larger Circuits 1. Create a 4-digit BCD adder circuit. (see lecture handout) 2. Create a 32-bit carry lookahead adder using four 8-bit carry lookahead adders. (see lecture handout)See Answer
- Q3: Note : Assessment Pack Contents 1. INTRODUCTION This is a project for each individual to complete. During the laboratory sessions you should create a simple pulse sensor based on photoplethysmography. This must be completed using a photodiode sensor input, an appropriate signal conditioning electronics based on passive high pass and active low pass filters with amplification and an output from the pulse sensor which should be demonstrated by an oscilloscope. A LED may be added to the output. 2. SPECIFICATIONS Specified Assignment Content Design and make a circuit to that measures the pulse in your finger demonstrating the output on an oscilloscope, using Proteus software. PCB Design • The device shall be constructed on a single-sided printed-circuit board (PCB.) The PCB must include your name, student number, and UCLan email. If additional connections are required these shall be provided by 002 links/wires. The dimensions of the PCB should be no greater than 70 mm × 70 mm. Circuit Design Create a simple pulse sensor using photoplethysmography, it starts with a very low voltage signal so needs to be amplified and high frequencies and noise needs to be removed. Components 。 TCRT1000 o Op amp LM358 o Resistors and Capacitors of various sizes 。 Voltage regulator LM7805 (if required) Power supply voltage range Regulate the power source so a safe DC value of 5 Volts is provided to the op amp circuit. • Task 1. Research circuits and complete calculations. • Task 2. Design a circuit to meet the specification using Proteus. | • Task 3. Design a PCB layout for your circuit using ECAD Proteus. Provide evidence, statements, photographs, pictures of all your work in a formal Technical Presentation.See Answer
- Q4:Lab Project: Structural Design of Sequential Circuits Problem Statement Design a circuit that increments a digit (0 - F) shown on the seven-segment display device once each second. The circuit has four pushbutton inputs: one button starts the counter, a second button stops the counter, a third button increments the counter, and the fourth button asynchronously resets all memory devices in the design. The system has the block diagram shown Fig. 1 below. You must create the 4-bit counter, a clock divider, a seven-segment display decoder, and a controller circuit. You may use any design tools or methods you wish. You must also create and submit a state diagram for the controller, together with K-maps showing the next-state and output circuits in your final report. Controller 4-bit counter 7-seg decoder BTN1 Start Run Cen B0 A BTN2 Stop B BTN3 Inc C B1 Clk divider B2 D Clk pin Clk Clk B3 E RST F RST G BTN4 Figure 1. Clock divider with a counter and a comparator Clock Divider A clock signal is needed in order for sequential circuits to function. Usually, the clock signal comes from a crystal oscillator on-board. The oscillator used on Intel FPGA boards usually ranges from 50MHz. However, some peripheral controllers do not need such a high frequency to operate. We can use a counter with a comparator to condition a flip-flop with an inverter to implement a clock divider that can control the output frequency of the on-board clock, slowing it to 1Hz. The block diagram of such a clock divider is shown in Fig. 2. Counter Comparator Q A ->clk EQ rst Constant En D Q clk > Clk clk div Rst rst Figure 2. Clock divider with a counter and a comparator. In the block diagram, the counter increases by 1 whenever the rising edge of clk arrives. It also resets its output to '0' when it reaches the constant number defined in the constant block. The comparator compares the output of the counter with the pre-defined constant and asserts EQ if the output of counter is equal to the pre-defined constant. When EQ is asserted, the output of the clock divider flips. Let's assume that the pre-defined number is 3, and the output of clock divider (clk_div) is initialized to 0. It takes three clock cycles before the output of the counter equals the pre-defined constant, 3. 2 pages Lab Project #10: Structural design of Sequential Circuits When it reaches 3, the output of clock divider (clk_div) turns to 1, and the counter resets itself. It takes another three cycles before the output of the counter equals the pre-defined constant, 3. When it reaches 3 again, clk_div turns back to 0. So, it takes 6 clock cycles before clk_div goes to 1 and returns to 0 again. As a result, the frequency of clk_div is one sixth of the frequency of original clk. In this example, we are going to use this clock divider to implement a signal of exactly 1 Hz frequency. First, we will need to calculate the constant. As an example, suppose the input clock frequency of the board is 100 MHz. We want our clk_div to be 1 Hz. So, it should take 100000000 clock cycles before clk_div goes to '1' and returns to '0'. In another words, it takes 50000000 clock cycles for clk_div to flip its value. So, the constant we need to choose here is 50000000.See Answer
- Q5:SPECIFICATIONS Specified Assignment Content Design and make a circuit to that measures the pulse in your finger demonstrating the output on an oscilloscope, using Proteus software. PCB Design · The device shall be constructed on a single-sided printed-circuit board (PCB.) · The PCB must include your name, student number, and UCLan email. · If additional connections are required these shall be provided by 0Q links/wires. · The dimensions of the PCB should be no greater than 70 mm x 70 mm. Circuit Design Create a simple pulse sensor using photoplethysmography, it starts with a very low voltage signal so needs to be amplified and high frequencies and noise needs to be removed. Components o TCRT1000 Op amp LM358 Resistors and Capacitors of various sizes Voltage regulator LM7805 (if required) Power supply voltage range Regulate the power source so a safe DC value of 5 Volts is provided to the op amp circuit. Practical Work Construction Manufacture your given PCB, you will need to compare the design to your own circuit to calculate the correct format of the components. INSTRUCTIONS Tasks (keep a record in a log book though out, this is for your benefit is not required for marking) · Task 1. Research circuits and complete calculations. · Task 2. Design a circuit to meet the specification using Proteus · Task 3. Design a PCB layout for your circuit using ECAD Proteus, · Task 4. Interim Review at deadline. · Task 5. Manufacture your given PCB · Task 6 Test circuit in the laboratory, making appropriate measurements on an oscilloscope and then compare to the schematic simulation. · Task 7 Fault find circuit Power supply voltage range Regulate the power source so a safe DC value of 5 Volts is provided to the op amp circuit. Practical Work Construction Manufacture your given PCB, you will need to compare the design to your own circuit to calculate the correct format of the components. INSTRUCTIONS Tasks (keep a record in a log book though out, this is for your benefit is not required for marking) · Task 1. Research circuits and complete calculations. · Task 2. Design a circuit to meet the specification using Proteus · Task 3. Design a PCB layout for your circuit using ECAD Proteus, · Task 4. Interim Review at deadline. con PCR · Task 6 Test circuit in the laboratory, making appropriate measurements on an oscilloscope and then compare to the schematic simulation. · Task 7 Fault find circuit · Task 8 Analyse circuit, compare your results to the specifications, simulations, explain and include improvements. Provide evidence, statements, photographs, pictures of all your work in a formal Technical Presentation. Please refer to the Marking Scheme Breakdown for more details regarding assessment and tasks. Marking Scheme Breakdown Interim Review Marks 10% Demonstration of own Proteus Documents Show and explain + Schematic Diagram + Simulation + PCB Design /10 Marking Scheme Breakdown Presentation Marks 90% rks 90% 11:07 € 4G 53 ‹ Back ASS 2 Pulse Sensor intro ... Proteus. Task 3. Design a PCB layout for your circuit using ECAD Proteus. Task 4. Interim Review at deadline. Task 5. Manufacture your given PCB. Task 6. Test circuit in the laboratory, making appropriate measurements on an oscilloscope and then compare to the schematic simulation. Task 7. Fault find circuit. Task 8. Analyse circuit, compare your results to the specifications, simulations, explain and include improvements. Please refer to the Marking Scheme Breakdown for more details regarding assessment and tasks ._ Pulse Sensor Heart Rate Monitor TASK 1 Research TCRT1000 Note the TRCT1000 does not exist on Proteus so we will be using a low voltage AC signal to simulate the circuit. Passive high pass filter Op Amp LM358 Non inverting amplifier Active low pass filter Buffer Voltage Regulator LM7805 to control the supply voltage. Pulse Sensor Heart Rate Monitor Task 2. Design and simulate a circuit to meet the specification using Proteus. Refer to the block diagram provided in this presentation. Task 3. Design a PCB layout for your circuit using ECAD Proteus. ( You'll get some extra help with this so it shouldn't take so long) -See Answer
TutorBin Testimonials
I found TutorBin Proteus homework help when I was struggling with complex concepts. Experts provided step-wise explanations and examples to help me understand concepts clearly.
Rick Jordon
5
TutorBin experts resolve your doubts without making you wait for long. Their experts are responsive & available 24/7 whenever you need Proteus subject guidance.
Andrea Jacobs
5
I trust TutorBin for assisting me in completing Proteus assignments with quality and 100% accuracy. Experts are polite, listen to my problems, and have extensive experience in their domain.
Lilian King
5
I got my Proteus homework done on time. My assignment is proofread and edited by professionals. Got zero plagiarism as experts developed my assignment from scratch. Feel relieved and super excited.
Joey Dip
5
Popular Subjects for proteus
You can get the best rated step-by-step problem explanations from 65000+ expert tutors by ordering TutorBin proteus homework help.- Matlab And Simulation
- Analog Electronics
- Antenna Theory
- Embedded System
- Microprocessor and Microcontroller
- Proteus
- Arduino
- Basic Electronics
- CodeWarrior
- Communications
- CPUIator
- Electronics Devices
- Image Processing
- Instrumentation
- Logic Circuits/Vlsi
- Microwave Devices
- Network Analysis And Synthesis
- OrCAD
- Photonics
- Signal Processing
- Signals And Systems
- Symica
- TinkerCAD
- Verilog
- Virtuoso
- Xilinx
- Soft Computing
TutorBin helping students around the globe
TutorBin believes that distance should never be a barrier to learning. Over 500000+ orders and 100000+ happy customers explain TutorBin has become the name that keeps learning fun in the UK, USA, Canada, Australia, Singapore, and UAE.
