SINUSOIDAL STEADY-STATE ANALYSIS

1. SINUSOIDAL STEADY-STATE ANALYSIS Prepared by Ertuğrul Eriş Reference Book: Electric Circuits Nilsson, Riedel Güncelleme: 1 : October 2011 Ertuğrul Eriş

2. SINUSOIDAL STEADY-STATE ANALYSIS(SİNÜSOİDAL SÜREKLİ HAL) • The Sinusoidal Source/Signal • The Sinusoidal Response • The Phasor (Fazör) • The Passive Circuit Elements in The Frequency Domain • Kirchhoff ‘s Law in The Frequency Domain • Series/parellel, Delta-to-Wye simplifications • Source transformations, Thevenin-Norton equivalent circuits • The Node-voltage Method • The Mesh-current Method • The Transformer (Transformatör (M elemanı)) • The Ideal Transformer Ertuğrul Eriş

3. ELECTRONIC/ELECTRICAL ENNGINEERING • Information transfer • Audio (Ses), text, Image, video (görüntü hareketsiz, hareketli) • Why electrical (Electronic engineering): • Information process, storage, transmit/recieve • Signal transfors required (microphone, speakers;...) • Other fields (Electrical engineering) • Energy source (alternatives) • Heat • Light Ertuğrul Eriş

4. POWER/SIGNAL SOURCES • Upto now DC power sources included circuits • System/circuit inputs • Power inputs • DC (batteries, transistor included circuits) • AC sources, power sources • Sıgnal inputs • Electrical signals «audio, image, video» representing voice, still and moving pictures • Sum of sinusoidal signals (fourier sseries) • System/circuit outputs • Sinusoidal signals Ertuğrul Eriş

5. WHY SINUSOIDAL SIGNALS • Analog Electricals signals • v(t), i(t) • Mathematical • continious • Periodical • Fourier transforms • Sum of iferent frequeny and amplitıde sinusoidal signals • Linear circuits Ertuğrul Eriş

6. NON SINUSOIDAL SIGNALS • Digital Electrical signals • V(t), i(t) • Advantages:Noise elimination,Strorage, accuracy • Disadvantages • Analog-Digital-Analog converters • Digital sistemler • Boolean Algebra/ Logic design • Digital control, digital communicatin Ertuğrul Eriş

7. LINEAR CIRCUITS/ORDINARY DIFFERENTIAL EQUATIONS • Linear Circuit • Homogenity: sources multiplied by k→solutions multiplied by k • Super position: all sources included soluion → sum of each sources alone solutions • Inputs • DC Power, first semestr RC,RL,RLC • AC power or signal (Circuit Analysis, this course) • Linear circuit analysis/ Ordinary differeential equation solution • Homogenous solution= transient response (Geçici çözüm ): (zamanla kaybolan çözüm) • Particular solution=steady-state response (Sürekli çözüm) (devamlı gözlenen) Ertuğrul Eriş

8. SINUSOIDAL STEADY-STATE SOLUTION / PARTICULAR SOLUTION OF A ORDINARY DIFFERENTIAL EQUATION • General solutıon • Homogenous solutıon(transient): • Depending on the chracteristic roots «under, over, critically damped» exponentially decreasing funtion in a few mınutes it becomes zero. • Particular solutıon: • The same type (DC, sınusoidal) as source functions • Şimdiye kadar kaynaklar DC idi, şimdiden sonra AC • General solutıon= Homogenous+ Particular Since homogenous solution disapears in a few seconds then general solution becomes particular solution which is called: SINUSOIDAL STEADY-STATE SOLUTION (Yani Sinüsoidal Sürekli Hal Çözümü) Ertuğrul Eriş

9. SINUSOIDAL STEADY-STATE SOLUTION / PARTICULAR SOLUTION OF A ORDINARY DIFFERENTIAL EQUATION • Particular solution • Independent Source type • Sınusoidal sources, • Elements’ current and voltages are also sinusoidal • Frequency: same as source frequency • But «Phase and amplitude»will change Ertuğrul Eriş

10. LINEAR CIRCUIT ANALYSIS SUMMARY

11. SINUSOIDAL SIGNAL • Parameters • Periodic: Frequency/period • Amplitute(genlik) • Phase(Faz) Ertuğrul Eriş

12. PHASE OF SINUSOIDAL SIGNAL (Faz) Degree= (180/ π )radian VmCos(ωt+Φ) ile VmCos(ωt) phase difference: Vm Cos(ωt+Φ) → Vm ; ωt+Φ = 0 → t = (- Φ/ ω) Vm Cos(ωt) (time) Vm Cos(ωt+Φ) Phase chage→shift : Φ positve→shift left; Φ negative →shift right Ertuğrul Eriş

13. MEASUREMENT RMS=Root of the Mean value of the Squared function Why rms? edaquate? How to measure frequency, phase? Ertuğrul Eriş

14. GENERAL SOLUTION IN t-DOMAIN Transient solution (geçici hal) Sinusoidal steady-state solution (sürekli sinüsoidal hal) θ=arctg ωL/R • OBSERVATION: • Independent source: sinusoidal. • Homogenous solution becomes zero. • Particular solution: • source type, sınusoidal • Frequency same as source frequency • Phase and amplitude change, not the same as source Proteusta simulation available on course web-site. Ertuğrul Eriş

15. EXAMPLE • R=1KΩ, L=10mH, • V=sin(ω t), Vm=1V, f=100khz, Φ=0 • Θ=arctg(ωL/R)=810 • τ=(L/R)=10μs • (Vm/√(R2+ω2))=157 μA • i(t)=-157 μA sin(810)e(-t/10 μs) +157 μA sin(ωt-810) • t=0→i(0)=0 • t= L/R=time costant=10 μs • 10μs→ i(10 μs)=97,61 μA • «proteus» solution is available on course web-side Ertuğrul Eriş

16. PHASOR (FAZÖR) :FREQUENCY DOMAIN ω-domain t-domain vs ω-domain Ertuğrul Eriş

17. KOMPLEX NUMBERS: POLAR/RECTANGULAR TRANSFORM • Polar form • De jθ = D(cos θ+ j sin θ) • Rectangular form • A+jB • A= Dcos θ B= Dsin θ Ertuğrul Eriş

18. KOMPLEX NUMBERS: RECTANGULAR/POLARTRANSFORM • A+jB 1. kadran • D= √A2+B2 θ= arctn (B/A) • -A-jB 3. kadran • D= √A2+B2 ,θ= arctn (B/A)+180 • -A+jB 2. kadran • D= √A2+B2 ,θ= 180-arctn (B/A) • A-jB 4. kadran • D= √A2+B2 ,θ= -arctn (B/A) Nilsson Appendix B Ertuğrul Eriş

19. FREQUENCY DOMAIN: RESISTANCE V=R I Phasor «bold» Ertuğrul Eriş

20. FREQUENCY DOMAIN: INDUCTANCE V = jωL I Voltage leading current π / 2 Current lagging voltage - π / 2 j = e jπ/2 = cos(π/2) + j sin(π/2) Ertuğrul Eriş

21. FREQUENCY DOMAIN: CONDUCTANCE V = (1/jωc) I Voltage lagging current -π/ 2 Current leading voltage +π/ 2 j = e jπ/2 = cos(π/2) + j sin(π/2) Ertuğrul Eriş

22. IMPEDANCE: REACTANCE ADMITTANCE: CONDUCTANCE SUSCEPTANCE (empedans,reakyans,admitans,iletkenlik,süseptans) • IMPEDANCE (Empedans): V=Z I • ADMITTANCE (Admitance) : I=Y V • Current and voltage phasors are complex numbers • IMPEDANCE and ADMITTANCE complex numbers, not phasor, • Reactance: Imaginary part of ımpedance • Conductance: Real part of admittance • suseptance: Imaginary part of admittance Ertuğrul Eriş

23. KIRCHOFF’S LAWS IN FREQUENCY DOMAIN • Element voltages and currents become Element voltage phasors and current phasors, • Advantages of frequency domain? • Disadvantages of frequency domain? Σvi = 0; Σii = 0 Ertuğrul Eriş

24. COMPARISON t-DOAIN AND ω-DOMAIN SOLUTIONS transient Stady-state solution θ=arctg ωL/R Which solution has not been calculated? What are the results? Compare source and output signals? Ertuğrul Eriş

25. A SINUSOIDAL RELATION • Sum of two sinusoidal signals with the same frequency equals to a single sinusoidal signal with the same frequency Cos(ωtŦΦ)=cos ωt cos Φ±sin ωt sin Φ • sin(ωt±Φ)=cos ωt sin Φ ± sin ωt cos Φ Y1=20cos(ωt-30), Y2=40cos(ωt+60) Y1+Y2= 44.72 cos(ωt+33.430) Y1=20e-j30Y2=40ej60 Y1+Y2=44.72 ej33,43 Ertuğrul Eriş

26. COMBINING IMPEDANCES IN SERIAL Zab= Z1+Z2+…….+Zn Ertuğrul Eriş

27. EXAMPLE Which solution in t-domain? benefits? Ertuğrul Eriş

28. COMBINING IMPEDANCES IN PARALLEL Yab= Y1+Y2+…….+Yn Ertuğrul Eriş

29. EXAMPLE Ertuğrul Eriş

30. NODE VOLTAGE METHOD IN ω-DOMAIN What about C and L values? t-domain solutions? How? C=10μF, L=(2/5)mH, ω=104 r/s unique? Ertuğrul Eriş

31. MESH-CURRENTMETHOD IN ω-DOMAIN I1 = -58e j63.4 =58e j244 =58e -j116 I2 = -64.2e j67.5 Ix = 6.32e j(180-71,5) ω=1000r/s L1=2mH L2=3mH C=62,5μF t- domain solutions? Ertuğrul Eriş

32. DELTA-WYE TRANSFORMS (YILDIZ-ÜÇGEN DÖNÜŞÜMLERİ) Ertuğrul Eriş

33. EXAMPLE Ertuğrul Eriş

34. SOURCE TRANSFORMS IN ω-DOMAIN Other interpratation: Thévenin Norton equvalance circuits transforms Ertuğrul Eriş

35. EXAMPLE Ertuğrul Eriş

36. THÉVENIN EQUIVALANCE IN ω-DOMAIN Thévenin equivalent circuit with respect to a-b terminals Is it possible to fınd Thévenin equivalent circuit of a circuit which include ınductors and capacitors?Why? Ertuğrul Eriş

37. NORTON EQUIVALANCE IN ω-DOMAIN Norton equivalent circuit with respect to a-b terminals Norton /Thevenin equivalance transform: IN= V0 / Zth ; ZN=Zth Ertuğrul Eriş

38. EXAMPLE a b Norton current=I0=(430/51)+j(20/51) Ertuğrul Eriş

39. MUTUAL INDUCTANCE(Linear Transformer) Ertuğrul Eriş

40. MUTUAL INDUCTANCE EXAMPLE c d (cd) Terminal Thevenin Equivalent: Vth = Vcdopen circuit voltage Zth = ımpedance seen looking into the terminals (cd) Ertuğrul Eriş

41. IDEAL TRANSFORMER + I2 I1 + V2 V1 M2=L1L2 Ertuğrul Eriş

42. IMPEDANCE MATCH BY USING IDEAL TRAFO n=(n1/n2) Z1=V1/I1=n2*ZL Speaker and amplifier impedance match!, Impedance seen looking into the right of V1 Ertuğrul Eriş

43. SSS SUMMARY • CONSTRAINTS • Linear circuits • Independent sources are sinusoidal (AC) • Particular solution only! • BENEFITS • No differential equations but • Linear algebraic equations • LOSTS/ADDITIONALS • Transient solution • time→Phasor →time transforms • Stability cannot be observed Ertuğrul Eriş

44. SSS: AN EVALUATION • Sinusoidal independent sources • Asin(ωt+φ) • Sinusoidal elements’ current and voltages • B(ω) sin[ωt+θ(ω)] • No changes: sinusoidal functions, frequency • Chages: Amplitude and Phase depending on the elements’ values and the frequency Ertuğrul Eriş

45. PROGRAM DESIGN DEPT, PROGRAM G R A D U A T E S T U D E N T STUDENT P R OG R A M O U T C O M E S PROGRAM OUTCOMES P R OG R A M O U T C O M E S STATE, ENTREPRENEUR FIELD QALIFICATIONS EU/NATIONAL QUALIFICATIONS KNOWLEDGE SKILLS COMPETENCES NEWCOMERSTUDENT ORIENTIATION GOVERNANCE Std. questionnaire ALUMNI, PARENTS ORIENTIATION STUDENT PROFILE Std. questionnaire FACULTY NGO STUDENT, ??? CIRCICULUM ??? INTRERNAL CONSTITUENT Std. questionnaire EXTRERNAL CONSTITUENT EXTRERNAL CONSTITUENT REQUIREMENTS EU/NATIONAL FIELD QUALIFICATIONS PROGRAM OUTCOMES QUESTIONNAIRES QUALITY IMP. TOOLS GOAL: NATIONAL/INTERNATIONAL ACCREDITION

46. BLOOM’S TAXONOMYANDERSON AND KRATHWOHL (2001) !!Listening !! Doesn’t exits in the original!!! http://www.learningandteaching.info/learning/bloomtax.htm Ertuğrul Eriş

47. ULUSAL LİSANS YETERLİLİKLER ÇERÇEVESİ BLOOMS TAXONOMY Ertuğrul Eriş

48. COURSE ASSESMENT MATRIX LEARNING OUTCOMES Devre Analizi İlk Ders

49. ‘ABET’ ENGINEERING OUTCOMES Ertuğrul Eriş