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PSpice for analog communications engineering

In PSpice for Analog Communications Engineering we simulate the difficult principles of analog modulation using the superb free simulation software Cadence Orcad PSpice V10.5. While use is made of analog behavioral model parts (ABM), we use actual circuitry in most of the simulation circuits. For ex...

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Bibliographic Details
Main Author: Tobin, Paul, 1948-
Format: Electronic
Language:English
Published: San Rafael, Calif. (1537 Fourth Street, San Rafael, CA 94901 USA) : Morgan & Claypool Publishers, c2007.
Edition:1st ed.
Series:Synthesis lectures on digital circuits and systems (Online) ; #9.
Subjects:
PSpice.
Telecommunication systems > Computer simulation.
Analog electronic systems > Computer simulation.
Online Access:Abstract with links to full text
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020 # # |a 1598291610 (electronic bk.) 
020 # # |a 9781598291612 (electronic bk.) 
020 # # |a 1598291602 (pbk.) 
020 # # |a 9781598291605 (pbk.) 
024 7 # |a 10.2200/S00071ED1V01Y200612DCS009  |2 doi 
035 # # |a 99755650 (OCLC) 
035 # # |a (CaBNvSL)gtp00531454 
040 # # |a CaBNvSL  |c CaBNvSL  |d CaBNvSL 
050 # 4 |a TK5102.5  |b .T636 2007 
082 0 4 |a 621.3822  |2 22 
100 1 # |a Tobin, Paul,  |d 1948- 
245 1 0 |a PSpice for analog communications engineering  |c Paul Tobin.  |h [electronic resource] / 
250 # # |a 1st ed. 
260 # # |a San Rafael, Calif. (1537 Fourth Street, San Rafael, CA 94901 USA) :  |b Morgan & Claypool Publishers,  |c c2007. 
300 # # |a 1 electronic text (xiii, 139 p. : ill.) :  |b digital file. 
490 1 # |a Synthesis lectures on digital circuits and systems,  |v #9  |x 1932-3174 ; 
500 # # |a Part of: Synthesis digital library of engineering and computer science. 
500 # # |a Title from PDF t.p. (viewed on October 13, 2008). 
500 # # |a Series from website. 
504 # # |a Includes bibliographical references (p. 133) and index. 
505 0 # |a Amplitude modulation techniques -- Baseband to passband -- The communications channel -- Amplitude modulation -- AM generation: Method 1 -- AM using analog behavioral models: Method 2 -- AM generation: Method 3 -- Power in an AM signal -- Transmission efficiency -- Trapezoidal method: Speech-modulated DSBFC AM signal -- Spectrum of speech-modulated AM signal -- The four-quadrant AD633 multiplier IC -- Linear amplitude modulator -- Multiplying, squaring, and frequency doubling -- Exercises -- AM diode detection and four-quadrant multipliers -- AM detection -- Precision rectifier -- Diagonal clipping distortion -- Choice of time constant -- Automatic gain control -- Probe log command -- Double-sideband suppressed carrier -- Double-balanced modulator -- Coherent detection -- DSBSC production using four-quadrant multipliers -- DSBSC demodulation -- Exercises -- System stability, Nyquist criterion -- Nyquist criterion -- JFET Colpitts oscillator -- The feedback network -- Closed-loop testing -- The output file -- The oscillator output -- Hartley oscillator -- Quartz crystal and equivalent circuits -- Quartz crystal response -- CMOS Colpitts crystal oscillator -- Phase-shift oscillator -- Gain and phase margins -- Nyquist plot -- Nyquist diagram and oscillators -- Exercises -- Superhetrodyne amplitude modulation receivers -- Nonlinear mixing -- JFET nonlinear mixer circuit -- Mixer output -- Superhetrodyning -- Image frequency -- Superhetrodyning and image frequencies -- AM Superhetrodyne receiver -- The input/mixer stage -- The local oscillator: Arithmetic selectivity -- JFET-tuned radio frequency amplifier -- RF-tuned amplifier measurements -- Measuring the output impedance of an RF amplifier -- AC equivalent circuit -- BJT bandpass amplifier -- Tuning capacitance -- Diode detection and automatic gain control -- Power amplifier stage -- Audio output signals -- RF signals -- Speech scrambling -- Exercises -- Frequency modulation principles -- Modulation index -- FM spectrum -- FM production using the VSFFM generator part -- Power in an FM signal -- Varactor diode -- FM oscilloscope display -- FM preemphasis and deemphasis -- FM stereo generation -- FM baseband stereo signals -- Replacing ABM parts with circuitry -- FM stereo reception -- Exercises -- Superhetrodyne frequency modulation receivers -- FM Superhetrodyne receiver -- Mixer stage -- Coupled-tuned RF amplifiers -- Double-tuned intermediate RF amplifier -- Automatic gain control -- The phase-lock loop detector -- PLL compensation -- The lock and capture range -- ABM phase-locked loop -- Frequency demodulation -- Receiver waveforms -- Exercises -- Noise -- Sources of noise -- Noise factor and noise figure -- Defriis' formula -- Common emitter amplifier -- The output file -- Probe expression commands -- The "(if, then, else)" command -- Importing noise -- Adding noise to the input signal -- Exercises -- Appendix A -- References. 
506 # # |a Abstract freely available; full-text restricted to subscribers or individual document purchasers. 
510 0 # |a Compendex 
510 0 # |a INSPEC 
510 0 # |a Google scholar 
510 0 # |a Google book search 
520 # # |a In PSpice for Analog Communications Engineering we simulate the difficult principles of analog modulation using the superb free simulation software Cadence Orcad PSpice V10.5. While use is made of analog behavioral model parts (ABM), we use actual circuitry in most of the simulation circuits. For example, we use the 4-quadrant multiplier IC AD633 as a modulator and import real speech as the modulating source and look at the trapezoidal method for measuring the modulation index. Modulation is the process of relocating signals to different parts of the radio frequency spectrum by modifying certain parameters of the carrier in accordance with the modulating/information signals. In amplitude modulation, the modulating source changes the carrier amplitude, but in frequency modulation it causes the carrier frequency to change (and in phase modulation it's the carrier phase). The digital equivalent of these modulation techniques are examined in PSpice for Digital Communications Engineering, where we look at QAM, FSK, PSK and variants. We examine a range of oscillators and plot Nyquist diagrams showing the marginal stability of these systems. The superhetrodyne principle, the backbone of modern receivers is simulated using discrete components followed by simulating complete AM and FM receivers. In this exercise we examine the problems of matching individual stages. 
530 # # |a Also available in print. 
538 # # |a Mode of access: World Wide Web. 
538 # # |a System requirements: Adobe Acrobat Reader. 
630 0 0 |a PSpice. 
650 # 0 |a Telecommunication systems  |x Computer simulation. 
650 # 0 |a Analog electronic systems  |x Computer simulation. 
690 # # |a Amplitude modulation. 
690 # # |a Frequency modulation. 
690 # # |a Phase modulation. 
690 # # |a Radio-frequency amplifiers. 
690 # # |a Superhetrodyne receivers. 
690 # # |a Phase lock loops. 
690 # # |a Nyquist plot. 
690 # # |a Gain and phase margins. 
730 0 # |a Synthesis digital library of engineering and computer science. 
830 # 0 |a Synthesis lectures on digital circuits and systems (Online) ;  |v #9. 
856 4 2 |u https://ezaccess.library.uitm.edu.my/login?url=http://dx.doi.org/10.2200/S00071ED1V01Y200612DCS009  |3 Abstract with links to full text 

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