2. F1 x F2 Sum and Mixing of Frequencies

4. f USB = fc + fm and f LSB = fc − fm eam=EcSin(Wct)+mEc/2Cos(Wc-Wm)t-mEc/2Cos(Wc+Wm)t Carrier LSB USB

5. Sidebands and the Frequency Domain Figure 3-8: The relationship between the time and frequency domains.

8. Ea = E max − E min 2 m = Ea / Ec Ec = Emax - Ea Calculatiom of modulation index by envelope

9. BW = fUSB−fLSB=2fm Ec mEc/2 Fc Fc+Fm Fc-Fm FcFc+Fm-Fc -Fc+Fm-Fc-Fm Fc-Fm Two sided spectrum mEc/4 Ec/2

10. Property of Active Device

11. Block Diagram of a Simple AM Transmitter

12. P T = (I T ) 2 Rwhere I T is measured RF current and R is antenna impedance P T =P C +P USB +P LSB Power relations in AM

13. P T = (I T ) 2 R P T =P C +P USB +P LSB Power relations in AM in terms of current P c = (I c ) 2 R But

14. Transmission Efficiency Percent efficiency Useful Power /Total power

15. Modulation by several sinewaves Two modulating signals are given by X 1 (t)=E m1 CosW m1 t X 2 (t)=E m2 CosW m2 t ec=Ec CosWct Carrier wave e am =A CosWct where A=Ec+X 1 (t)+X 2 (t) e am = (Ec+E m1 CosW m1 t + E m2 CosW m2 t) CosWct e am = Ec(1+E m1 /Ec CosWm1t + E m2 / Ec CosW m2 t) CosWct e am = Ec(1+m1 CosW m1 t + m2 CosW m2 t) CosWct e am = Ec CosWct+m1Ec/2 Cos(Wc+W m1 )t + m1Ec/2 Cos(Wc-W m1 )t+m2Ec/2 Cos(Wc+Wm2)t+m2Ec/2 Cos(Wc-Wm2)t Fc Fc+fm1 Fc+fm2 Fc-fm1 Fc-fm2 Ec m1Ec/2 m2Ec/2 m1Ec/2 m2Ec/2 BW=2fm2

16. Total power in AM Wave= Pt=P USB1 +P USB2 +P LSB1 +P LSB2 Modulation Index

17. P T = (I T ) 2 Rwhere I T is measured RF current and R is antenna impedance P T =P C +P USB +P LSB Power relations in AM

18. P T = (I T ) 2 R P T =P C +P USB +P LSB Power relations in AM in terms of current P c = (I c ) 2 R But

19. Transmission Efficiency Percent efficiency Useful Power /Total power

20. Modulation by several sinewaves Two modulating signals are given by X 1 (t)=E m1 CosW m1 t X 2 (t)=E m2 CosW m2 t ec=Ec CosWct Carrier wave e am =A CosWct where A=Ec+X 1 (t)+X 2 (t) e am = (Ec+E m1 CosW m1 t + E m2 CosW m2 t) CosWct e am = Ec(1+E m1 /Ec CosWm1t + E m2 / Ec CosW m2 t) CosWct e am = Ec(1+m1 CosW m1 t + m2 CosW m2 t) CosWct e am = Ec CosWct+m1Ec/2 Cos(Wc+W m1 )t + m1Ec/2 Cos(Wc-W m1 )t+m2Ec/2 Cos(Wc+Wm2)t+m2Ec/2 Cos(Wc-Wm2)t Fc Fc+fm1 Fc+fm2 Fc-fm1 Fc-fm2 Ec m1Ec/2 m2Ec/2 m1Ec/2 m2Ec/2 BW=2fm2

21. Total power in AM Wave= Pt=P USB1 +P USB2 +P LSB1 +P LSB2 Modulation Index

22. Amplitude Modulators There are two types of amplitude modulators. They are low-level and high-level modulators. Low-level modulators generate AM with small signals and must be amplified before transmission. High-level modulators produce AM at high power levels, usually in the final amplifier stage of a transmitter. Modulators are class C amplifiers and at output tank circuit.

23. Low level AM Transmitter 540KHz to 1640KHz

24. modula tor 540KHz to 1640KHz

25. Amplifier Classes Class A - bias point is set so that the amplifier conducts through a complete cycle (360 deg) of the input waveform. This class has low efficiency (~35%) but high linearity. Class AB - bias point is set so that the amplifier conducts through at least 180 deg but less than 360deg of the input waveform. This class has better efficiency (~55%) but lower linearity. Class B - bias point is set so that the amplifier conducts through a half cycle (180 deg) of the input waveform. This class has higher efficiency (~60%),but poor linearity. Class C - bias point is set so that the amplifier conducts through less than 180 deg of the input waveform. This class has higher efficiency (~70%), but even poorer linearity

26. Use of Tank circuit

27. Low level Class C Grid Modulator

28. High level Plate Modulator

29. Low level Transistor Modulator

30. Low level and High level AM Transmitter modulat or 540KHz to 1640KHz

31. Advantages of DSBFC = 1.Transmitters are less complex 2.Receivers are simple, detection is easy. 3.Cost efficient. Disadvantages = 1.Power wastage - carrier doesn’t carry any information and USB & LSB contains same information. 2. Needs larger Bandwidth 3. Gets affected by noise.

32. Types of AM= 1.DSBFC 2.DSBSC 3.SSB 4.ISB 5.VSB Balanced Modulator Modulatin g signal carrier DSBSC 180 phase shift

33. DSB-SC Generation Methods 1.Ring Balanced Modulator 2.Lattice Balanced Modulator 3.Push pull Balanced modulator eam=mEc/2Cos(Wc-Wm)t-mEc/2Cos(Wc+Wm)t 180 phase shift Ec mEc/2 Fc Fc+Fm Fc-Fm BW=2fm

34. Balanced Modulator 1.Ring modulator 2.Lattice-type balanced modulator.

35. Lattice Modulator + -- +

36. Push Pull Balanced Modulator i net = ae m + 2be c e m Drain Current Modulating signal Two side bands

38. AM Waveforms

40. SSB Generation Methods 1.Filter Method 2.Phase shift method 3.Third method (Weaver method) mEc/2 Fc Fc+Fm Fc-Fm mEc/2 Fc Fc+Fm Fc-Fm BW=fm

41. SSB Circuits Figure 4-31 An SSB transmitter using the filter method.

43. This technique can be used at relatively low carrier frequencies. At high frequencies, the Q of the filter becomes unacceptably high. The required Q necessary to filter off one of the sidebands can be approximated by:

44. SSB Circuits Figure 4-33 An SSB generator using the phasing method.

45. SSB phase shift

46. Important points= 1.Sharp cutoff Filters are not required 2.Freq Up conversion is not required 3.Easy to switch between sidebands. Simply change the oscillator position. 4.Designing a phase shift network for AF range is dificult.

47. Weaver Method or Third method LSB

50. Independent side band transmitter 10MHz to 30MHz

51. VESTIGIAL SIDEBAND MODULATION VSB is used in TV transmission to transmit Video signal. In VSB full USB is transmitted with some part of LSB. As filter response is not sharp at the edges it may attenuate part of transmitted sideband if only SSB is used to transmit. Part of the LSB is called as Vestige. BW required is less than the DSBFC and DSBSC. No of channels can be increased.

53. VSB AM Technique- USB LSB 0 5 MHz 5.75MHz1.25 MHz 0.5 Picture career Sound career

55. AM Receivers 1.Tuned Radio Frequency (TRF) 2.Superheterodyne Receiver fo - fs = f IF + - + -

56. Receiver Characteristics Sensitivity- it must provide amplification to recover the original modulating signal from a very weak received signal. Sensitivity refers to the weakest signal that can be received and still produce an acceptable out. Sensitivity can be specified as a minimum voltage (microV) or as a power level (dBm). Gain of RF and IF amp. decides sensitivity.

58. Selectivity =it must be able to select the desired signal from the thousands of other signals in the spectrum. It is the ability to select the desired signal and reject all other.

60. Fidelity = Is A Measure Of The Ability Of A Communications System To Produce At The Output Of The Receiver, An Exact Replica Of The Original Source Information

61. 540KHz to 1640KHz Ganged tuning

62. Problems of Tuned Radio Frequency (TRF) Receiver 1.Instability- Overall gain of RF amplifiers is very very high so a very small f/b from o/p to i/p with correct phase can initiate oscillations. Due to stray capacitance at high freq. 2.Variation in BW- For 535KHz – 1640KHz Range BW=10KHz for fc=535 Q=fr/BW=535/10=53.5 for fc=1640 Q=164 But max value of Q is 120 so BW=fr/Q=1640/120=13.7K So receiver picks adjacent channels. 3. Insufficient Selectivity- Due to variable BW selectivity of TRF receiver is poor.

63. Superheterodyne Receivers Superheterodyne receivers convert all incoming signals to a lower frequency, known as the intermediate frequency (IF), at which a single set of amplifiers is used to provide a fixed level of sensitivity and selectivity. Gain and selectivity are obtained in the IF amplifiers. The key circuit is the mixer, which acts like a simple amplitude modulator to produce sum and difference frequencies. The incoming signal is mixed with a local oscillator signal.