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Electrical Circuit Analysis Ch 01 basic concepts

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The document discusses the analysis and design of basic linear electric circuits, emphasizing the development of mathematical models to predict circuit behavior. It covers fundamental concepts such as charge, current, voltage, and power, as well as the principles of circuit analysis, including the notion of nodes and the identification of circuit elements. The materials also include problem-solving techniques, unit measurements, and the passive sign convention for power transfer in electrical components.

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CIRCUITS 1 DEVELOP TOOLS FOR THE ANALYSIS AND DESIGN OF BASIC LINEAR ELECTRIC CIRCUITS
A FEW WORDS ABOUT ANALYSIS USING MATHEMATICAL MODELS
BASIC STRATEGY USED IN ANALYSIS
MATHEMATICAL ANALYSIS DEVELOP A SET OF MATHEMATICAL EQUATIONS THAT REPRESENT THE CIRCUIT - A MATEMATICAL MODEL - LEARN HOW TO SOLVE THE MODEL TO DETERMINE HOW THE CIRCUIT WILL BEHAVE IN A GIVEN SITUATION THIS COURSE TEACHES THE BASIC TECHNIQUES TO DEVELOP MATHEMATICAL MODELS FOR ELECTRIC CIRCUITS THE MATHEMATICS CLASSES - LINEAR ALGEBRA, DIFFERENTIAL EQUATIONS- PROVIDE THE TOOLS TO SOLVE THE MATHEMATICAL MODELS FOR THE FIRST PART WE WILL BE EXPECTED TO SOLVE SYSTEMS OF ALGEBRAIC EQUATIONS 20642 0164 84912 321 321 321 =+−− =++− =−− VVV VVV VVV LATER THE MODELS WILL BE DIFFERENTIAL EQUATIONS OF THE FORM f dt df y dt dy dt yd fy dt dy 4384 3 2 2 +=++ =+ THE MODELS THAT WILL BE DEVELOPED HAVE NICE MATHEMATICAL PROPERTIES. IN PARTICULAR THEY WILL BE LINEAR WHICH MEANS THAT THEY SATISFY THE PRINCIPLE OF SUPERPOSITION 1 1 2 2 1 1 2 2 Model Principle of Superposition ( ) ( ) ( ) y Tu T u u T u T uα α α α = + = +
a b 2 T E R M I N A L S C O M P O N E N T c h a r a c t e r i z e d b y t h e c u r r e n t t h r o u g h i t a n d t h e v o l t a g e d i f f e r e n c e b e t w e e n t e r m i n a l s N O D E N O D E ELECTRIC CIRCUIT IS AN INTERCONNECTION OF ELECTRICAL COMPONENTS LOW DISTORTION POWER AMPLIFIER + - L C 1R 2R Sv − + Ov TYPICAL LINEAR CIRCUIT The concept of node is extremely important. We must learn to identify a node in any shape or form
BASIC CONCEPTS LEARNING GOALS •System of Units: The SI standard system; prefixes •Basic Quantities: Charge, current, voltage, power and energy •Circuit Elements: Active and Passive
http://physics.nist.gov/cuu/index.html
Electrical Circuit Analysis Ch 01 basic concepts
Information at the foundation of modern science and technology from thePhysics Laboratoryof NIST Detailed contents Values of the constantsand related information Searchable bibliographyon the constants In-depth information on the SI, the modern metric system Guidelinesfor the expression of uncertainty in measurement About this reference. Feedback. Privacy Statement / Security Notice - NIST Disclaimer
SI DERIVED BASIC ELECTRICAL UNITS
ONE AMPERE OF CURRENT CARRIES ONE COULOMB OF CHARGE EVERY SECOND. ELECTRONONEOFCHARGETHEIS(e) (e)106.28COULOMB1 18 ×= sCA ×= VOLT IS A MEASURE OF ENERGY PER CHARGE. TWO POINTS HAVE A VOLTAGE DIFFERENCE OF ONE VOLT IF ONE COULOMB OF CHARGE GAINS ONE JOULE OF CHARGE WHEN IT IS MOVED FROM ONE POINT TO THE OTHER. C J V = OHM IS A MEASURE OF THE RESISTANCE TO THE FLOW OF CHARGE. THERE IS ONE OHM OF RESISTENCE IF IT IS REQUIRED ONE VOLT OF ELECTROMOTIVE FORCE TO DRIVE THROUGH ONE AMPERE OF CURRENT A V =Ω IT IS REQUIRED ONE WATT OF POWER TO DRIVE ONE AMPER OF CURRENT AGAINST AN ELECTROMOTIVE DIFFERENCE OF ONE VOLTS AVW ×=
CURRENT AND VOLTAGE RANGES
Strictly speaking current is a basic quantity and charge is derived. However, physically the electric current is created by a movement of charged particles. + + + )(tq + What is the meaning of a negative value for q(t)? PROBLEM SOLVING TIPPROBLEM SOLVING TIP IF THE CHARGE IS GIVEN DETERMINE THE CURRENT BY DIFFERENTIATION IF THE CURRENT IS KNOWN DETERMINE THE CHARGE BY INTEGRATION A PHYSICAL ANALOGY THAT HELPS VISUALIZE ELECTRIC CURRENTS IS THAT OF WATER FLOW. CHARGES ARE VISUALIZED AS WATER PARTICLES
+ + + )(tq + EXAMPLE ])[120sin(104)( 3 Cttq π− ×= =)(ti )120cos(120104 3 tππ×× − ][A ][)120cos(480.0)( mAtti ππ= EXAMPLE    ≥ < = − 0 00 )( 2 tmAe t ti t FIND THE CHARGE THAT PASSES DURING IN THE INTERVAL 0<t<1 == ∫ − 1 0 2 dxeq x ) 2 1 ( 2 1 2 1 02 1 0 2 eee x −−−=− −− FIND THE CHARGE AS A FUNCTION OF TIME ∫ ∫ ∞− ∞− − == t t x dxedxxitq 2 )()( 0)(0 =⇒≤ tqt ∫ −− −==⇒> t tx edxetqt 0 22 )1( 2 1 )(0 And the units for the charge?... )1( 2 1 2− −= eq Units?
1 2 3 4 5 610− 10 20 30 Charge(pC) Time(ms) Here we are given the charge flow as function of time. )/(1010 0102 10101010 9 3 1212 sC s C m − − −− ×−= −× ×−×− = 1 2 3 4 5 610− 10 20 30 Time(ms) )Current(nA 40 20− DETERMINE THE CURRENT To determine current we must take derivatives. PAY ATTENTION TO UNITS
CONVENTION FOR CURRENTS IT IS ABSOLUTELY NECESSARY TO INDICATE THE DIRECTION OF MOVEMENT OF CHARGED PARTICLES. THE UNIVERSALLY ACCEPTED CONVENTION IN ELECTRICAL ENGINEERING IS THAT CURRENT IS FLOW OF POSITIVE CHARGES. AND WE INDICATE THE DIRECTION OF FLOW FOR POSITIVE CHARGES -THE REFERENCE DIRECTION- a b a a ab b b A3 A3− A3 A3− THE DOUBLE INDEX NOTATION IF THE INITIAL AND TERMINAL NODE ARE LABELED ONE CAN INDICATE THEM AS SUBINDICES FOR THE CURRENT NAME a bA5 AIab 5= AIab 3= AIba 3−= AIab 3−= AIba 3= POSITIVE CHARGES FLOW LEFT-RIGHT POSITIVE CHARGES FLOW RIGHT-LEFT baab II −= A POSITIVE VALUE FOR THE CURRENT INDICATES FLOW IN THE DIRECTION OF THE ARROW (THE REFERENCE DIRECTION) A NEGATIVE VALUE FOR THE CURRENT INDICATES FLOW IN THE OPPOSITE DIRECTION THAN THE REFERENCE DIRECTION
This example illustrates the various ways in which the current notation can be used b a I A3 = = −= ab cb I AI AI 4 2 A2 c
CONVENTIONS FOR VOLTAGES ONE DEFINITION FOR VOLT TWO POINTS HAVE A VOLTAGE DIFFERENTIAL OF ONE VOLT IF ONE COULOMB OF CHARGE GAINS (OR LOSES) ONE JOULE OF ENERGY WHEN IT MOVES FROM ONE POINT TO THE OTHER + a b C1 IF THE CHARGE GAINS ENERGY MOVING FROM a TO b THEN b HAS HIGHER VOLTAGE THAN a. IF IT LOSES ENERGY THEN b HAS LOWER VOLTAGE THAN a DIMENSIONALLY VOLT IS A DERIVED UNIT sA mN • • == COULOMB JOULE VOLT VOLTAGE IS ALWAYS MEASURED IN A RELATIVE FORM AS THE VOLTAGE DIFFERENCE BETWEEN TWO POINTS IT IS ESSENTIAL THAT OUR NOTATION ALLOWS US TO DETERMINE WHICH POINT HAS THE HIGHER VOLTAGE
THE + AND - SIGNS DEFINE THE REFERENCE POLARITY V IF THE NUMBER V IS POSITIVE POINT A HAS V VOLTS MORE THAN POINT B. IF THE NUMBER V IS NEGATIVE POINT A HAS |V| LESS THAN POINT B POINT A HAS 2V MORE THAN POINT B POINT A HAS 5V LESS THAN POINT B
THE TWO-INDEX NOTATION FOR VOLTAGES INSTEAD OF SHOWING THE REFERENCE POLARITY WE AGREE THAT THE FIRST SUBINDEX DENOTES THE POINT WITH POSITIVE REFERENCE POLARITY VVAB 2= VVAB 5−= VVBA 5= BAAB VV −=
ENERGY VOLTAGE IS A MEASURE OF ENERGY PER UNIT CHARGE… CHARGES MOVING BETWEEN POINTS WITH DIFFERENT VOLTAGE ABSORB OR RELEASE ENERGY – THEY MAY TRANSFER ENERGY FROM ONE POINT TO ANOTHER BASIC FLASHLIGHT Converts energy stored in battery to thermal energy in lamp filament which turns incandescent and glows The battery supplies energy to charges. Lamp absorbs energy from charges. The net effect is an energy transfer EQUIVALENT CIRCUIT Charges gain energy here Charges supply Energy here
WHAT ENERGY IS REQUIRED TO MOVE 120[C] FROM POINT B TO POINT A IN THE CIRCUIT? VVAB 2= JVQW Q W V 240==⇒= THE CHARGES MOVE TO A POINT WITH HIGHER VOLTAGE -THEY GAINED (OR ABSORBED) ENERGY THE CIRCUIT SUPPLIED ENERGY TO THE CHARGES ENERGY VOLTAGE IS A MEASURE OF ENERGY PER UNIT CHARGE… CHARGES MOVING BETWEEN POINTS WITH DIFFERENT VOLTAGE ABSORB OR RELEASE ENERGY
VVAB 5= − + V5 WHICH POINT HAS THE HIGHER VOLTAGE? THE VOLTAGE DIFFERENCE IS 5V
EXAMPLE A CAMCODER BATTERY PLATE CLAIMS THAT THE UNIT STORES 2700mAHr AT 7.2V. WHAT IS THE TOTAL CHARGE AND ENERGY STORED? CHARGE THE NOTATION 2700mAHr INDICATES THAT THE UNIT CAN DELIVER 2700mA FOR ONE FULL HOUR ][1072.9 13600102700 3 3 C Hr Hr s S C Q ×= ××    ×= − TOTAL ENERGY STORED THE CHARGES ARE MOVED THROUGH A 7.2V VOLTAGE DIFFERENTIAL ][10998.6 ][2.71072.9][ 4 3 J J C J VCQW ×= ××=    ×= ENERGY AND POWER 2[C/s] PASS THROUGH THE ELEMENT EACH COULOMB OF CHARGE LOSES 3[J] OR SUPPLIES 3[J] OF ENERGY TO THE ELEMENT THE ELEMENT RECEIVES ENERGY AT A RATE OF 6[J/s] THE ELECTRIC POWER RECEIVED BY THE ELEMENT IS 6[W] HOW DO WE RECOGNIZE IF AN ELEMENT SUPPLIES OR RECEIVES POWER? VIP = IN GENERAL ∫= 2 1 )(),( 12 t t dxxpttw
PASSIVE SIGN CONVENTION POWER RECEIVED IS POSITIVE WHILE POWER SUPPLIED IS CONSIDERED NEGATIVE A CONSEQUENCE OF THIS CONVENTION IS THAT THE REFERENCE DIRECTIONS FOR CURRENT AND VOLTAGE ARE NOT INDEPENDENT -- IF WE ASSUME PASSIVE ELEMENTS a b −+ abV abI ababIVP = IF VOLTAGE AND CURRENT ARE BOTH POSITIVE THE CHARGES MOVE FROM HIGH TO LOW VOLTAGE AND THE COMPONENT RECEIVES ENERGY --IT IS A PASSIVE ELEMENT a b −+ abV GIVEN THE REFERENCE POLARITY a b abI IF THE REFERENCE DIRECTION FOR CURRENT IS GIVEN −+ THIS IS THE REFERENCE FOR POLARITY REFERENCE DIRECTION FOR CURRENT a b −+ abV VVab 10−= EXAMPLE THE ELEMENT RECEIVES 20W OF POWER. WHAT IS THE CURRENT? abI SELECT REFERENCE DIRECTION BASED ON PASSIVE SIGN CONVENTION ababab IVIVW )10(][20 −== ][2 AIab −= A2
Voltage(V) Current A - A' S1 S2 positive positive supplies receives positive negative receives supplies negative positive receives supplies negative negative supplies receives S2S1 We must examine the voltage across the component and the current through it 0,0 <> ABAB IV 1SON 0,0 '''' >> BABA IV 2SON A A’ B B’ ''''2 1 BABAS ABABS IVP IVP = = UNDERSTANDING PASSIVE SIGN CONVENTION 0,0 '''' >< BABA IV S2ON − + V I
CHARGES RECEIVE ENERGY. THIS BATTERY SUPPLIES ENERGY CHARGES LOSE ENERGY. THIS BATTERY RECEIVES THE ENERGY WHAT WOULD HAPPEN IF THE CONNECTIONS ARE REVERSED IN ONE OF THE BATTERIES?
DETERMINE WHETHER THE ELEMENTS ARE SUPPLYING OR RECEIVING POWER AND HOW MUCH a b a b WHEN IN DOUBT LABEL THE TERMINALS OF THE COMPONENT AIab 4= VVab 2−= WP 8−= SUPPLIES POWER VVab 2= 2A− 2abI A= − 4P W= − ABSORBS POWER
1 2 1 2 AIVV 4,12 1212 −== AIVV 2,4 1212 == WHEN IN DOUBT LABEL THE TERMINALS OF THE COMPONENT
SELECT VOLTAGE REFERENCE POLARITY BASED ON CURRENT REFERENCE DIRECTION − + )5(][20 AVW AB ×=− ][4 VVAB −= − + IVW ×−= )5(][40 ][8 AI −=
SELECT HERE THE CURRENT REFERENCE DIRECTION BASED ON VOLTAGE REFERENCE POLARITY A2− )2(][40 1 AVW −×= ][201 VV −= IVW ×=− ])[10(][50 ][5 AI −= WHICH TERMINAL HAS HIGHER VOLTAGE AND WHICH IS THE CURRENT FLOW DIRECTION
+ - − + V24 −+ V6 − + V18 A2 A2 1 23 P1 = 12W P2 = 36W P3 = -48W )2)(6(1 AVP = )2)(18(2 AVP = )2)(24()2)(24(3 AVAVP −=−= IMPORTANT: NOTICE THE POWER BALANCE IN THE CIRCUIT COMPUTE POWER ABDORBED OR SUPPLIED BY EACH ELEMENT
CIRCUIT ELEMENTS PASSIVE ELEMENTS INDEPENDENT SOURCES VOLTAGE DEPENDENT SOURCES CURRENT DEPENDENT SOURCES ?,,, βµ rgFORUNITS
EXERCISES WITH DEPENDENT SOURCES OVFIND ][40 VVO = OIFIND mAIO 50=
DETERMINE THE POWER SUPPLIED BY THE DEPENDENT SOURCES ][40 V ][80])[2])([40( WAVP −=−= TAKE VOLTAGE POLARITY REFERENCE TAKE CURRENT REFERENCE DIRECTION ][160])[44])([10( WAVP −=×−=
POWER ABSORBED OR SUPPLIED BY EACH ELEMENT ][48)4)(12(1 WAVP == ][48)2)(24(2 WAVP == ][56)2)(28(3 WAVP == ][8)2)(4()2)(1( WAVAIP xDS −=−=−= ][144)4)(36(36 WAVP V −=−= NOTICE THE POWER BALANCE
USE POWER BALANCE TO COMPUTE Io W12− ))(6( OI )9)(12( − )3)(10( − )8)(4( − )11)(28( × ][1 AIO = POWER BALANCE

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Electrical Circuit Analysis Ch 01 basic concepts

  • 1. CIRCUITS 1 DEVELOP TOOLS FOR THE ANALYSIS AND DESIGN OF BASIC LINEAR ELECTRIC CIRCUITS
  • 2. A FEW WORDS ABOUT ANALYSIS USING MATHEMATICAL MODELS
  • 3. BASIC STRATEGY USED IN ANALYSIS
  • 4. MATHEMATICAL ANALYSIS DEVELOP A SET OF MATHEMATICAL EQUATIONS THAT REPRESENT THE CIRCUIT - A MATEMATICAL MODEL - LEARN HOW TO SOLVE THE MODEL TO DETERMINE HOW THE CIRCUIT WILL BEHAVE IN A GIVEN SITUATION THIS COURSE TEACHES THE BASIC TECHNIQUES TO DEVELOP MATHEMATICAL MODELS FOR ELECTRIC CIRCUITS THE MATHEMATICS CLASSES - LINEAR ALGEBRA, DIFFERENTIAL EQUATIONS- PROVIDE THE TOOLS TO SOLVE THE MATHEMATICAL MODELS FOR THE FIRST PART WE WILL BE EXPECTED TO SOLVE SYSTEMS OF ALGEBRAIC EQUATIONS 20642 0164 84912 321 321 321 =+−− =++− =−− VVV VVV VVV LATER THE MODELS WILL BE DIFFERENTIAL EQUATIONS OF THE FORM f dt df y dt dy dt yd fy dt dy 4384 3 2 2 +=++ =+ THE MODELS THAT WILL BE DEVELOPED HAVE NICE MATHEMATICAL PROPERTIES. IN PARTICULAR THEY WILL BE LINEAR WHICH MEANS THAT THEY SATISFY THE PRINCIPLE OF SUPERPOSITION 1 1 2 2 1 1 2 2 Model Principle of Superposition ( ) ( ) ( ) y Tu T u u T u T uα α α α = + = +
  • 5. a b 2 T E R M I N A L S C O M P O N E N T c h a r a c t e r i z e d b y t h e c u r r e n t t h r o u g h i t a n d t h e v o l t a g e d i f f e r e n c e b e t w e e n t e r m i n a l s N O D E N O D E ELECTRIC CIRCUIT IS AN INTERCONNECTION OF ELECTRICAL COMPONENTS LOW DISTORTION POWER AMPLIFIER + - L C 1R 2R Sv − + Ov TYPICAL LINEAR CIRCUIT The concept of node is extremely important. We must learn to identify a node in any shape or form
  • 6. BASIC CONCEPTS LEARNING GOALS •System of Units: The SI standard system; prefixes •Basic Quantities: Charge, current, voltage, power and energy •Circuit Elements: Active and Passive
  • 9. Information at the foundation of modern science and technology from thePhysics Laboratoryof NIST Detailed contents Values of the constantsand related information Searchable bibliographyon the constants In-depth information on the SI, the modern metric system Guidelinesfor the expression of uncertainty in measurement About this reference. Feedback. Privacy Statement / Security Notice - NIST Disclaimer
  • 10. SI DERIVED BASIC ELECTRICAL UNITS
  • 11. ONE AMPERE OF CURRENT CARRIES ONE COULOMB OF CHARGE EVERY SECOND. ELECTRONONEOFCHARGETHEIS(e) (e)106.28COULOMB1 18 ×= sCA ×= VOLT IS A MEASURE OF ENERGY PER CHARGE. TWO POINTS HAVE A VOLTAGE DIFFERENCE OF ONE VOLT IF ONE COULOMB OF CHARGE GAINS ONE JOULE OF CHARGE WHEN IT IS MOVED FROM ONE POINT TO THE OTHER. C J V = OHM IS A MEASURE OF THE RESISTANCE TO THE FLOW OF CHARGE. THERE IS ONE OHM OF RESISTENCE IF IT IS REQUIRED ONE VOLT OF ELECTROMOTIVE FORCE TO DRIVE THROUGH ONE AMPERE OF CURRENT A V =Ω IT IS REQUIRED ONE WATT OF POWER TO DRIVE ONE AMPER OF CURRENT AGAINST AN ELECTROMOTIVE DIFFERENCE OF ONE VOLTS AVW ×=
  • 13. Strictly speaking current is a basic quantity and charge is derived. However, physically the electric current is created by a movement of charged particles. + + + )(tq + What is the meaning of a negative value for q(t)? PROBLEM SOLVING TIPPROBLEM SOLVING TIP IF THE CHARGE IS GIVEN DETERMINE THE CURRENT BY DIFFERENTIATION IF THE CURRENT IS KNOWN DETERMINE THE CHARGE BY INTEGRATION A PHYSICAL ANALOGY THAT HELPS VISUALIZE ELECTRIC CURRENTS IS THAT OF WATER FLOW. CHARGES ARE VISUALIZED AS WATER PARTICLES
  • 14. + + + )(tq + EXAMPLE ])[120sin(104)( 3 Cttq π− ×= =)(ti )120cos(120104 3 tππ×× − ][A ][)120cos(480.0)( mAtti ππ= EXAMPLE    ≥ < = − 0 00 )( 2 tmAe t ti t FIND THE CHARGE THAT PASSES DURING IN THE INTERVAL 0<t<1 == ∫ − 1 0 2 dxeq x ) 2 1 ( 2 1 2 1 02 1 0 2 eee x −−−=− −− FIND THE CHARGE AS A FUNCTION OF TIME ∫ ∫ ∞− ∞− − == t t x dxedxxitq 2 )()( 0)(0 =⇒≤ tqt ∫ −− −==⇒> t tx edxetqt 0 22 )1( 2 1 )(0 And the units for the charge?... )1( 2 1 2− −= eq Units?
  • 15. 1 2 3 4 5 610− 10 20 30 Charge(pC) Time(ms) Here we are given the charge flow as function of time. )/(1010 0102 10101010 9 3 1212 sC s C m − − −− ×−= −× ×−×− = 1 2 3 4 5 610− 10 20 30 Time(ms) )Current(nA 40 20− DETERMINE THE CURRENT To determine current we must take derivatives. PAY ATTENTION TO UNITS
  • 16. CONVENTION FOR CURRENTS IT IS ABSOLUTELY NECESSARY TO INDICATE THE DIRECTION OF MOVEMENT OF CHARGED PARTICLES. THE UNIVERSALLY ACCEPTED CONVENTION IN ELECTRICAL ENGINEERING IS THAT CURRENT IS FLOW OF POSITIVE CHARGES. AND WE INDICATE THE DIRECTION OF FLOW FOR POSITIVE CHARGES -THE REFERENCE DIRECTION- a b a a ab b b A3 A3− A3 A3− THE DOUBLE INDEX NOTATION IF THE INITIAL AND TERMINAL NODE ARE LABELED ONE CAN INDICATE THEM AS SUBINDICES FOR THE CURRENT NAME a bA5 AIab 5= AIab 3= AIba 3−= AIab 3−= AIba 3= POSITIVE CHARGES FLOW LEFT-RIGHT POSITIVE CHARGES FLOW RIGHT-LEFT baab II −= A POSITIVE VALUE FOR THE CURRENT INDICATES FLOW IN THE DIRECTION OF THE ARROW (THE REFERENCE DIRECTION) A NEGATIVE VALUE FOR THE CURRENT INDICATES FLOW IN THE OPPOSITE DIRECTION THAN THE REFERENCE DIRECTION
  • 17. This example illustrates the various ways in which the current notation can be used b a I A3 = = −= ab cb I AI AI 4 2 A2 c
  • 18. CONVENTIONS FOR VOLTAGES ONE DEFINITION FOR VOLT TWO POINTS HAVE A VOLTAGE DIFFERENTIAL OF ONE VOLT IF ONE COULOMB OF CHARGE GAINS (OR LOSES) ONE JOULE OF ENERGY WHEN IT MOVES FROM ONE POINT TO THE OTHER + a b C1 IF THE CHARGE GAINS ENERGY MOVING FROM a TO b THEN b HAS HIGHER VOLTAGE THAN a. IF IT LOSES ENERGY THEN b HAS LOWER VOLTAGE THAN a DIMENSIONALLY VOLT IS A DERIVED UNIT sA mN • • == COULOMB JOULE VOLT VOLTAGE IS ALWAYS MEASURED IN A RELATIVE FORM AS THE VOLTAGE DIFFERENCE BETWEEN TWO POINTS IT IS ESSENTIAL THAT OUR NOTATION ALLOWS US TO DETERMINE WHICH POINT HAS THE HIGHER VOLTAGE
  • 19. THE + AND - SIGNS DEFINE THE REFERENCE POLARITY V IF THE NUMBER V IS POSITIVE POINT A HAS V VOLTS MORE THAN POINT B. IF THE NUMBER V IS NEGATIVE POINT A HAS |V| LESS THAN POINT B POINT A HAS 2V MORE THAN POINT B POINT A HAS 5V LESS THAN POINT B
  • 20. THE TWO-INDEX NOTATION FOR VOLTAGES INSTEAD OF SHOWING THE REFERENCE POLARITY WE AGREE THAT THE FIRST SUBINDEX DENOTES THE POINT WITH POSITIVE REFERENCE POLARITY VVAB 2= VVAB 5−= VVBA 5= BAAB VV −=
  • 21. ENERGY VOLTAGE IS A MEASURE OF ENERGY PER UNIT CHARGE… CHARGES MOVING BETWEEN POINTS WITH DIFFERENT VOLTAGE ABSORB OR RELEASE ENERGY – THEY MAY TRANSFER ENERGY FROM ONE POINT TO ANOTHER BASIC FLASHLIGHT Converts energy stored in battery to thermal energy in lamp filament which turns incandescent and glows The battery supplies energy to charges. Lamp absorbs energy from charges. The net effect is an energy transfer EQUIVALENT CIRCUIT Charges gain energy here Charges supply Energy here
  • 22. WHAT ENERGY IS REQUIRED TO MOVE 120[C] FROM POINT B TO POINT A IN THE CIRCUIT? VVAB 2= JVQW Q W V 240==⇒= THE CHARGES MOVE TO A POINT WITH HIGHER VOLTAGE -THEY GAINED (OR ABSORBED) ENERGY THE CIRCUIT SUPPLIED ENERGY TO THE CHARGES ENERGY VOLTAGE IS A MEASURE OF ENERGY PER UNIT CHARGE… CHARGES MOVING BETWEEN POINTS WITH DIFFERENT VOLTAGE ABSORB OR RELEASE ENERGY
  • 23. VVAB 5= − + V5 WHICH POINT HAS THE HIGHER VOLTAGE? THE VOLTAGE DIFFERENCE IS 5V
  • 24. EXAMPLE A CAMCODER BATTERY PLATE CLAIMS THAT THE UNIT STORES 2700mAHr AT 7.2V. WHAT IS THE TOTAL CHARGE AND ENERGY STORED? CHARGE THE NOTATION 2700mAHr INDICATES THAT THE UNIT CAN DELIVER 2700mA FOR ONE FULL HOUR ][1072.9 13600102700 3 3 C Hr Hr s S C Q ×= ××    ×= − TOTAL ENERGY STORED THE CHARGES ARE MOVED THROUGH A 7.2V VOLTAGE DIFFERENTIAL ][10998.6 ][2.71072.9][ 4 3 J J C J VCQW ×= ××=    ×= ENERGY AND POWER 2[C/s] PASS THROUGH THE ELEMENT EACH COULOMB OF CHARGE LOSES 3[J] OR SUPPLIES 3[J] OF ENERGY TO THE ELEMENT THE ELEMENT RECEIVES ENERGY AT A RATE OF 6[J/s] THE ELECTRIC POWER RECEIVED BY THE ELEMENT IS 6[W] HOW DO WE RECOGNIZE IF AN ELEMENT SUPPLIES OR RECEIVES POWER? VIP = IN GENERAL ∫= 2 1 )(),( 12 t t dxxpttw
  • 25. PASSIVE SIGN CONVENTION POWER RECEIVED IS POSITIVE WHILE POWER SUPPLIED IS CONSIDERED NEGATIVE A CONSEQUENCE OF THIS CONVENTION IS THAT THE REFERENCE DIRECTIONS FOR CURRENT AND VOLTAGE ARE NOT INDEPENDENT -- IF WE ASSUME PASSIVE ELEMENTS a b −+ abV abI ababIVP = IF VOLTAGE AND CURRENT ARE BOTH POSITIVE THE CHARGES MOVE FROM HIGH TO LOW VOLTAGE AND THE COMPONENT RECEIVES ENERGY --IT IS A PASSIVE ELEMENT a b −+ abV GIVEN THE REFERENCE POLARITY a b abI IF THE REFERENCE DIRECTION FOR CURRENT IS GIVEN −+ THIS IS THE REFERENCE FOR POLARITY REFERENCE DIRECTION FOR CURRENT a b −+ abV VVab 10−= EXAMPLE THE ELEMENT RECEIVES 20W OF POWER. WHAT IS THE CURRENT? abI SELECT REFERENCE DIRECTION BASED ON PASSIVE SIGN CONVENTION ababab IVIVW )10(][20 −== ][2 AIab −= A2
  • 26. Voltage(V) Current A - A' S1 S2 positive positive supplies receives positive negative receives supplies negative positive receives supplies negative negative supplies receives S2S1 We must examine the voltage across the component and the current through it 0,0 <> ABAB IV 1SON 0,0 '''' >> BABA IV 2SON A A’ B B’ ''''2 1 BABAS ABABS IVP IVP = = UNDERSTANDING PASSIVE SIGN CONVENTION 0,0 '''' >< BABA IV S2ON − + V I
  • 27. CHARGES RECEIVE ENERGY. THIS BATTERY SUPPLIES ENERGY CHARGES LOSE ENERGY. THIS BATTERY RECEIVES THE ENERGY WHAT WOULD HAPPEN IF THE CONNECTIONS ARE REVERSED IN ONE OF THE BATTERIES?
  • 28. DETERMINE WHETHER THE ELEMENTS ARE SUPPLYING OR RECEIVING POWER AND HOW MUCH a b a b WHEN IN DOUBT LABEL THE TERMINALS OF THE COMPONENT AIab 4= VVab 2−= WP 8−= SUPPLIES POWER VVab 2= 2A− 2abI A= − 4P W= − ABSORBS POWER
  • 29. 1 2 1 2 AIVV 4,12 1212 −== AIVV 2,4 1212 == WHEN IN DOUBT LABEL THE TERMINALS OF THE COMPONENT
  • 30. SELECT VOLTAGE REFERENCE POLARITY BASED ON CURRENT REFERENCE DIRECTION − + )5(][20 AVW AB ×=− ][4 VVAB −= − + IVW ×−= )5(][40 ][8 AI −=
  • 31. SELECT HERE THE CURRENT REFERENCE DIRECTION BASED ON VOLTAGE REFERENCE POLARITY A2− )2(][40 1 AVW −×= ][201 VV −= IVW ×=− ])[10(][50 ][5 AI −= WHICH TERMINAL HAS HIGHER VOLTAGE AND WHICH IS THE CURRENT FLOW DIRECTION
  • 32. + - − + V24 −+ V6 − + V18 A2 A2 1 23 P1 = 12W P2 = 36W P3 = -48W )2)(6(1 AVP = )2)(18(2 AVP = )2)(24()2)(24(3 AVAVP −=−= IMPORTANT: NOTICE THE POWER BALANCE IN THE CIRCUIT COMPUTE POWER ABDORBED OR SUPPLIED BY EACH ELEMENT
  • 33. CIRCUIT ELEMENTS PASSIVE ELEMENTS INDEPENDENT SOURCES VOLTAGE DEPENDENT SOURCES CURRENT DEPENDENT SOURCES ?,,, βµ rgFORUNITS
  • 34. EXERCISES WITH DEPENDENT SOURCES OVFIND ][40 VVO = OIFIND mAIO 50=
  • 35. DETERMINE THE POWER SUPPLIED BY THE DEPENDENT SOURCES ][40 V ][80])[2])([40( WAVP −=−= TAKE VOLTAGE POLARITY REFERENCE TAKE CURRENT REFERENCE DIRECTION ][160])[44])([10( WAVP −=×−=
  • 36. POWER ABSORBED OR SUPPLIED BY EACH ELEMENT ][48)4)(12(1 WAVP == ][48)2)(24(2 WAVP == ][56)2)(28(3 WAVP == ][8)2)(4()2)(1( WAVAIP xDS −=−=−= ][144)4)(36(36 WAVP V −=−= NOTICE THE POWER BALANCE
  • 37. USE POWER BALANCE TO COMPUTE Io W12− ))(6( OI )9)(12( − )3)(10( − )8)(4( − )11)(28( × ][1 AIO = POWER BALANCE