* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Ohm`s Law
Nanofluidic circuitry wikipedia , lookup
Integrating ADC wikipedia , lookup
Galvanometer wikipedia , lookup
Transistor–transistor logic wikipedia , lookup
Josephson voltage standard wikipedia , lookup
Valve RF amplifier wikipedia , lookup
RLC circuit wikipedia , lookup
Schmitt trigger wikipedia , lookup
Operational amplifier wikipedia , lookup
Power electronics wikipedia , lookup
Voltage regulator wikipedia , lookup
Power MOSFET wikipedia , lookup
Switched-mode power supply wikipedia , lookup
Electrical ballast wikipedia , lookup
Resistive opto-isolator wikipedia , lookup
Opto-isolator wikipedia , lookup
Current source wikipedia , lookup
Surge protector wikipedia , lookup
Rectiverter wikipedia , lookup
Network analysis (electrical circuits) wikipedia , lookup
Current Electricity, Ohm’s Law & Circuits Current (I) • The rate of flow of charges through a conductor • Needs a complete closed conducting path to flow • Must have a potential difference (voltage) • Measured with an “ammeter” in amps (A) named for Ampere – French scientist • I = current, A Q = charge, C Coulomb t = time, s So: 1 Amp = 1 sec ond Q I t Voltage (V) • Electric potential difference between 2 points on a conductor. Equal to the electric potential energy per charge. PE V q • Sometimes described as “electric pressure” that makes current flow • Supplies the energy of the circuit • Measured in Volts (V) using a voltmeter • 1 Volt = 1 Joule / Coulomb Resistance (R) • The “electrical friction” encountered by the charges moving through a material. • Depends on material, length, and crosssectional area of conductor • Measured in Ohms (Ω) R A Where: R = resistance, = length of conductor, A = cross-sectional area of conductor, ρ = resistivity of conducting material Resistivity (ρ) • Property of material that resists the flow of charges (resistivity, ρ, in Ωm) • The inverse property of conductivity • Resistivity is temperature dependent…as temperature increases, then resistivity increases, and so resistance increases. Ohm’s Law • A relationship between voltage, current, and resistance in an electric circuit • used to make calculations in all circuit problems • V = potential difference (voltage) in volts • I = electric current in amperes (amps , A) • R = resistance in ohms ( ) V IR Electric Power (Watts) Energy Power time 2 V P IV I R • Used for thermal energy R 2 Electric Energy • Electric energy can be measured in Joules (J) or Kilowatt hours ( kWh ) • for Joules use Power in watts and time in seconds • for kWh use Power in kilowatts and time in hours E Pt Series Circuits • Current can only travel through one path • Current is the same through all parts of the circuit. • The sum of the voltages of each component of the circuit must equal the battery. • The equivalent resistance of a series circuit is the sum of the individual resistances. Req R1 R2 R3 ... VBattery V1 V2 V3 ... IT I1 I 2 I 3 ... R1 V I R3 R2 Solving a Series Circuit R1=1 Ω IT 6V R2=1 Ω Step 1: Find the equivalent (total) resistance of the circuit RT R1 R2 RT 1 1 2 Step 2: Find the total current supplied by the battery Step 3: Find Voltage Drop across each resistor. VBatt 6V IT 3amps RT 2 V1 I R 3A 1 3V Note: Since both resistors are the same, they use the same voltage. Voltage adds in series and voltage drops should add to the battery voltage, 3V+3V=6V Parallel Circuits • Current splits into “branches” so there is more than one path that current can take • Voltage is the same across each branch • Currents in each branch add to equal the total current through the battery 1 1 1 1 ... Req R1 R2 R3 I T I1 I 2 I 3 ... V VBattery V1 V2 V3 ... R1 R2 R3 Solving a Parallel Circuit Step 1: Find the total resistance of the circuit. 1 RT 1 R1 1 R2 1 RT 1 1 1 2 1 R3 so... R 1 3 11 6 6 T 11 Step 2: Find the total current from the battery. IT VT RT 12V 6 11 22 A Step 3: Find the current through each resistor. Remember, voltage is the same on each branch. I1 V1 R1 121V 12 A I2 V2 R2 122 V 6 A I3 V3 R3 123V 4 A Step 4: Check currents to see if the answers follow the pattern for current. I T I1 I 2 I 3 R2=2Ω 12V R1=1Ω R3=3Ω I T 12 A 6 A 4 A 22 A The total of the branches should be equal to the sum of the individual branches. Combo Circuits with Ohm’s Law What’s in series and what is in parallel? A 3Ω B 5Ω 15V 1Ω 6Ω 4Ω 7Ω D 2Ω C 6Ω 4Ω B 1Ω 3Ω It is often easier to answer this question if we redraw the circuit. Let’s label the junctions (where current splits or comes together) as reference points. A 5Ω 15V C 2Ω D 7Ω Combo Circuits with Ohm’s Law Now…again…what’s in series and what’s in parallel? 6Ω 4Ω B 3Ω 1Ω A C 2Ω D 7Ω 5Ω 15V The 6Ω and the 4Ω resistors are in series with each other, the branch they are on is parallel to the 1Ω resistor. The parallel branches between B & C are in series with the 2Ω resistor. The 5Ω resistor is on a branch that is parallel with the BC parallel group and its series 2Ω buddy. The total resistance between A & D is in series with the 3Ω and the 7Ω resistors. Combo Circuits with Ohm’s Law Finding total (equivalent) resistance 6Ω 4Ω B 3Ω C 2Ω 1Ω A D 7Ω 5Ω 15V To find RT work from the inside out. Start with the 6+4 = 10Ω series branch. So, 10Ω is in parallel with 1Ω between B&C… 1 RBC 11 101 11 10 so... RBC 10 11 0.91 Then, RBC + 2Ω=2.91Ω and this value is in parallel with the 5Ω branch, so… 1 1 1 R AD 2.91 5 so... RAD 1.84 Finally RT = RAD +3 + 7 = 1.84 + 3 + 7 RT = 11.84Ω Combo Circuits with Ohm’s Law Solving for current and voltage drops in each resistor RT = 11.84Ω 6Ω 4Ω I T VRTT 1115.84V 1.27 A C 2Ω B 1Ω 3Ω D A 7Ω 5Ω IT=1.27A IT=1.27A 15V The total current IT goes through the 3Ω and the 7Ω and since those are in series, they must get their chunk of the 15V input before we can know how much is left for the parallel. So… IT I 3 I 7 1.27 A Then… V3 I 3 R 1.27 A 3 3.81V V7 I 7 R 1.27 A 7 8.89V So… VP 15V 3.81V 8.89V 2.3V AD Since parallel branches have the same current, that means the voltage across the 5Ω resistor V5Ω=4.84V and the voltage across the parallel section between B&C plus the 2Ω is also 4.84V Combo Circuits with Ohm’s Law Solving for current and voltage drops in each resistor (continued) 6Ω 4Ω B 1Ω 3Ω A C 2Ω I2Ω=0.81A D 7Ω 5Ω IT=1.27A Known values from previous slide. RT 11.84 I T 1.27 A V3 3.81V V5 8.89V VPAD 2.3V 15V To calculate the current through the 5Ω resistor… I 5 VR5 25.3V 0.46 A IT=1.27A To calculate the top branch of the parallel circuit between points A & D we need to find the current and voltage for the series 2 Ω resistor. Since the current through the resistor plus the 0.92A for the bottom branch must equal 1.3A. So… I 2 1.27 A 0.46 A 0.81A V2 I 2 R 0.81A 2 1.62V Combo Circuits with Ohm’s Law Solving for current and voltage drops in each resistor (continued) I6Ω=I4Ω =0.068A C B 6Ω I1Ω=0.68A A 2Ω 4Ω 1Ω 3Ω Known values from previous slide. I2Ω=0.81A D RT 11.84 7Ω V3 3.81V 5Ω IT=1.27A IT=1.27A 15V Next we need to calculate quantities for the parallel bunch between points B&C. The voltage that is left to operate this parallel bunch is the voltage for the 5Ω minus what is used by the series 2Ω resistor. The 1Ω resistor gets all of this voltage. I T 1.27 A Finally we need to calculate the current through the 6Ω and 4Ω resistors and the voltage used by each. I 6 I 4 0.68V ( 6 4) 0.068 A All we need now is the voltage drop across the 6Ω and 4Ω resistors. So… V7 8.89V VPAD V5 2.3V I 5 0.46 A I 2 0.81A V2 1.62V VPBC V1 0.68V I1 0.68 A VPBC V1 2.3V 1.62V 0.68V V6 I 6 R 0.068 A 6 0.41V I1 V1 R 0.68V 1 0.68 A V4 I 4 R 0.068 A 4 0.27V THE END! Voltmeter and Ammeter • Ammeter – Measures current in amps – Placed in series where current is to be measured • Voltmeter – Measures voltage in Volts – Placed in parallel across whatever is being measured