EXPERIMENT 1.

Slides:

Advertisements

Similar presentations

How We Load Power Supplies. All sources have an EMF. EMF is the open terminal voltage of the battery. All sources have a certain amount of internal resistance.

Advertisements

Electricity & Magnetism

Physics Review #1 LCHS Dr.E. A positive test charge is placed between an electron, e, and a proton, p, as shown in the diagram below. When the test charge.

Current Current is defined as the flow of positive charge. I = Q/t I: current in Amperes or Amps (A) Q: charge in Coulombs (C) t: time in seconds.

Lecture 5 Current/Voltage Measurement Resistance Measurement.

Thursday November 29, 2007SNC1D | Miss. Manaktola 1 Simple Circuits Quiz SNC1D: Thursday November 29, 2007.

Circuits Series and Parallel. Series Circuits Example: A 6.00 Ω resistor and a 3.00 Ω resistor are connected in series with a 12.0 V battery. Determine.

Chapter 5 Series Circuits.

Verification of OHM’s law By: Engr.Irshad Rahim Memon.

Use Ohm’s Law to solve the following equations.

Current and Resistance

Current. Current Current is defined as the flow of positive charge. Current is defined as the flow of positive charge. I = Q/t I = Q/t I: current in Amperes.

4.2.3A Ohm’s Law & Circuit Basics Why Make Electrons Flow Anyway?

Welcome to Physics Jeopardy Chapter 18 Final Jeopardy Question Equivalent Resistance 100 Complex circuits Misc Parallel.

Friday, February 4 th, 2011 Introducing Current and Direct Current Circuits.

Series and Parallel Circuits Making Electricity Work for Us.

Physics Review #1 LCHS Dr.E. What is the voltage? 12Ω 36V 6Ω 2Ω 2Ω.

Section 2: Series and Parallel Circuits. Series Circuits Picture of Series Circuit:Properties: 1)Current: 2) Voltage: 3) Equivalent Resistance:

Introduction to Circuit Theory. Image Source: Wikipedia.

Electrical circuits. Intensity (I): Number of charges that flow past a given point every second. Measured in Amperes (A). Wires that carry the electrical.

Electrical Resistance Electrical resistance is a measure of how difficult it is for electricity (electrons) to flow through a material. The units of resistance.

Electric Circuits. Potential Electric Potential is just like gravitational potential It depends on –The distance from the source –The amount of charge.

Regents Physics Chapters 17/18 Circuits  Series Circuits.

Chapter 2-3 Principles of Electric Circuits, Conventional Flow, 9 th ed., Floyd T. Elsarnagawy, mde207,

J. Gabrielse Ohm’s law V I R. J. Gabrielse Voltage (V) Definition: what pushes charges Unit: volt (V) Measured by putting voltmeter in parallel. -+

1 Chapter 3 Resistive Circuits. 2 Figure The circuit being designed provides an adjustable voltage, v, to the load circuit. Figure (a) A proposed.

Regents Physics Parallel Circuits –Ohm’s Law in Parallel Circuits.

Ohm’s Law Resistance in Series Circuits

Resistance Electricity Lesson 3. Learning Objectives To define resistance. To know what causes resistance. To know how to measure resistance.

Building Circuits. Why are some Christmas lights more expensive than others?

Physics A First Course Electricity Chapter 13.

What we will do today Define the term ‘potential difference’. Look at the ratio V/I for a resistor. Define an equation relating resistance, voltage and.

Ohm’s Law PSSA Requirement Unit 9 Honors Physics.

Circuit Basics & Series Circuits Aim: How are circuits designed and connected?

ELECTRICAL CIRCUITS All you need to be an inventor is a good imagination and a pile of junk. -Thomas Edison.

Base your answers to the question on the information below. A copper wire at 20°C has a length of 10.0 meters and a cross-sectional area of 1.00 × 10-3.

The Series Circuit Summary 1. The sum of the _____________or voltage equals the potential rise of the source. 2. The current is ______________ everywhere.

Operating a Amp – Volt – Ohm Meter Created for CVCA Physics By Dick Heckathorn 3 March 2K + 14.

ELECTRICAL CIRCUITS All you need to be an inventor is a good imagination and a pile of junk. -Thomas Edison.

THEVENIN’S & NORTON’S THEOREM AND MAXIMUM POWER TRANSFER THEOREM

How do we measure current and potential difference (voltage) in a circuit? HW:

Operating a Amp – Volt – Ohm Meter

ELECTRICAL QUANTITIES IN CIRCUITS

8.3 Resistance and Ohm’s Law

Why Make Electrons Flow Anyway?

Last day to vote!!! New maximum is extended to 30 points

FIGURE 5-1 A series circuit with three bulbs

Electrical Circuits.

ELECTRICAL CIRCUITS All you need to be an inventor is a good imagination and a pile of junk. -Thomas Edison Lesson Objectives: To explain the difference.

Electrical Circuits.

Topic H: Electrical circuits

Ohm’s Law The relationship between voltage, current and resistance is known as Ohm’s Law: V = IR Voltage (V) = Current (I) x Resistance (R) Volts.

SUPERPOSITION THEOREM

THE RESISTOR Forward characteristic Reverse characteristic Circuit.

Series Circuits: Other examples:.

One Thing at a Time Series Circuits.

Experiment No. 1 Ohm’s Law

Multimeter Purpose Used to measure Voltage and Current around a circuit. Multimeter is the generic name given to the universal, Volt, Amp, and Ohmmeter.

Series Circuits: Other examples:.

Ohm’s Law – The relationship between Current, Voltage and Resistance.

Ohm’s Law and Circuit Basics

Resistance in Series and Parallel

Series and Parallel Circuits

Current and Simple Circuits Voltage Resistance Safety

Equivalent Resistance

Current We can measure the amount of current using an Ammeter. A

FIGURE 5-1 A series circuit with three bulbs

Presentation transcript:

EXPERIMENT 1

PART A Beginning at 0 V, increase the voltage across R3 in 1-Volt steps until 6 V. Measure and record the resulting current in Table 1.1 for each increment of voltage.

PART A Measure the actual value of each resistor and record in Table 1.1 Nominal Resistance R=6.8kΩ Measured Resistance R = Voltage Source (Vs) (V) 1 2 3 4 5 6 Current (Measured values) (mA) (Theoretical values) 0.11 0.32 0.43 0.65 0.75 0.86 Nominal Resistance, R=1kΩ Measured Resistance, R = Nominal Resistance, R=1.5kΩ Measured Resistance, R =

Plot the graphs of I verses V for results in Table 1. 1 Plot the graphs of I verses V for results in Table 1.1. (Assign I to the vertical axis and V to the horizontal axis).

Slope (G) R (1/G) Measured Values Theoretical Values 0.1471 mS 6.8 k

PART B Remove the voltmeter and ammeter connections Adjust the supply voltage (Vs) to 15V. (Note the value must be kept constant throughout the test by connecting voltmeter across the voltage supply in the circuit to observe the voltage.) Switch off the supply. Connect the ammeter in position A. Switch on the supply. Read the current through resistor R1. Current through R1 Connect the voltmeter across R1 and measure the voltage drop across it. Voltage across R1 Repeat 3 until 5 for the ammeter positions B, C, and D and the voltmeter positions across resistors R2 and R3. Record the voltage for close and open loop. Fill up the measured values in Table 1.3

Supply voltage (volt) V1 (volts) V2 V3 Σ Voltage 1.6129 2.4194 10.968 15 Supply current (mA) I1 I2 I3 I Total 1.613 1.613 1.613 mA Total resistance (Ohms) R1 R2 R3 Σ R R1+R2+R3 1000  1500  6800  9300 

PART C A B C D Adjust the supply voltage 15V. (Note the value of the supply voltage and keep it constant throughout the test.) Switch off the supply. Connect the ammeter in position A, the total current, ITotal. Switch on the supply. Measure voltage across resistor R1 Place the ammeter at positions B, C, and D and the voltmeter positions across resistors R2 and R3. Be careful not to touch R3 during measurement as it might be hot. Fill up the measured values in Table 1.4.

A B C D w x y z

Equivalent resistance Supply current (ampere) I1 (amperes) I2 I3 Σ Current 15 mA 10 mA 2.206 mA 27.21 mA Supply voltage (volt) V1 (volts) V2 V3 15 15 15V Equivalent resistance R1 (Ohms) R2 R3 1000  1500  6800  0.551 k Total conductance G1 (Siemens) G2 (siemens) G3 Σ G 1 mS 0.667 mS 0.147 mS 1.8149 mS