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Transcript
S-72.245 Transmission Methods in Telecommunication Systems (4 cr) Carrier Wave Modulation Systems Analog Carrier Wave Systems 2 Carrier wave techniques form a bases for telecommunication systems Topics today in CW-applications: – Single conversion radio receiver • FM radio (analog) stereo multiplexing – Measurement equipment • Spectrum analyzer – Multiplexing techniques • Frequency Division Multiplexing (FDM) • Quadrature-carrier multiplexing – Phase-locked loop (PLL) • FM-demodulator • frequency synthesis • Costas loop Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Single -conversion receiver* Assume reception of a bandpass signal Multiplication at the receiver with the local oscillator signal having frequency of fLO yields signals at two CW-bands xc (t ) A(t )cos ct (t ) xIF (t ) xLO (t ) xc (t ) A(t )cos( LOt )cos ct (t ) A(t )cos LO c t (t ) / 2 A(t )cos LO c t (t ) / 2 Therefore, IF can be selected as f IF f LO f c or LO can be selected as f LO f c f IF *also called as heterodyne-receiver 3 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Mirror frequency Select for IF for instance Am (t )cos LO c t (t ) / 2 For the reason that cos is even function there are two frequency bands that convert to intermediate frequency namely ' ' , IF LO c c LO LO IF c c c LO LO IF This means that both bandpass signals at the received frequencies LO IF are converted to the intermediate frequency. Example: Assume we set f LO 110MHz, f IF 10MHz therefore receiver picks signals at the bands of f c f LO f IF 110 MHz 10 MHz = 120 MHz 100 MHz 4 However, this is usually not wanted, and the other band must be filtered away by the first bandpass filter at the receiver Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Filtering mirror frequencies (image rejection filtering) 2 f IF BT BRF 2 f IF f IF f LO f C f C f LO f IF (selected) f C ' f C 2 f IF (see the figure) * *Should pass the message but not the mirror image 5 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen SC basic characteristics SC can be used with all CW methods The RF stage provides image rejection The IF stage provides gain and interference rejection – note that the fractional BW= BT/fIF is selected by adjusting fIF Remember from the second lecture that system design is easier if the fractional bandwidth is kept relatively small: For analog FM broadcasting: BIF / f IF 200kHz /10.6MHz 0.02 6 when it was required 0.01 B / f0 0.1 Tuning of the receiver to a desired band is easy by adjusting the local oscillator. (Often BRF is selected to be so wide and fLO so high that the first bandpass filter (amplifier) center frequency requires no tuning, as usually in FM radios) Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Scanning spectrum analyzer 7 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen BRF 8 BIF VCO, BRF and BIF filters form together a scanning bandpass filter (SBF) Ramp generator takes care of sweeping SBF After the IF filter the envelope detector yields signal whose power is comparable to the power that has passed the SBF Sweep rate and BIF determine system resolution. High resolution->small BIF and sweep rate as discussed soon When larger sensitivity is desired sweep rate must be decreased Spectrum analyzer includes often integrator (or averaging function) to improve SNR via inclusion of multiple sweep data Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Example: averaging improves SNR Assume white Gaussian noise with variance s2 (random part) is added into a sinusoidal signal (deterministic part) and thus the signal SNR is PS (V / 2) 2 V 2 SNR1 2 2 PN sN 2s N How much SNR can be expected to improve by n-fold averaging? Ans: or in dB: (nV / 2) 2 nV 2 SNRn 2 nSNR1 2 ns N 2s N SNR 10log10 ( SNRn ) 10log10 ( SNR1 ) 10log10 ( SNRn / SNR1 ) 10log10 (n) 9 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Frequency-division multiplexing (FDM) 10 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen FDM receiver First the FDM wave is demodulated. Then each subcarrier is detected by using separate bandpass filters and detectors. 11 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen AT & T FDM hierarchy in PSTN voice channel Note: nowadays respective combining realized by PCM 12 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Advanced FDM: xDSL with OFDM Conventional FDM: – Each channel occupies accurately certain frequency band – Bandwidth efficiency increased by using SSB modulation – Usage of guard bands wastes resources – A lot of filtering functions (complex circuitry) Modern FDM: OFDM (orthogonal frequency division multiplexing) and DMT (discrete multitone modulation) yield increased spectral adaptation. Applied in xDSL (digital subscriber line techniques). DMT with cable attenuation only rejected sub-band DMT with cable attenuation, interference and cross-talk 13 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen FM stereo multiplexing (MPX-system) 14 The MPX encoder utilizes various linear modulation methods L+R and L-R signals are transmitted on different channels SCA (Subsidiary Communication Authorization) is used to transmit background music for selected subscribers Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen FM stereo decoder System is based on detecting both L+R and L-R signals from which the R and L can be calculated Compatibility to mono-phonic transmission is granted by using the unmodulated L+R and DSB modulated L-R signal at 23-53 kHz that is automatically filtered out in mono-phonic reception 15 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Quadrature-carrier multiplexing Two signals x1 and x2 are transmitted via same channel xC (t ) AC x1 (t )cos( C t ) x2 (t )sin( C t ) Signals can be analog or digital CW or baseband signals (QPSK, DSB, SSB ...) xC (t ) Task: show that the signals x1 and x2 can be detected independently at the receiver! 16 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Quadrature-carrier reception In order to detect the x1 component multiply by the cos-wave: cos( C t ) x1 (t )cos( C t ) x2 (t )sin( C t ) x1 (t ) 1 cos(2 C t ) / 2 x2 (t )sin(2 C t ) / 2 In order to detect the x2 component multiply by sin-wave: sin( C t ) x1 (t )cos( C t ) x2 (t )sin( C t ) x2 (t ) 1 cos(2 C t ) / 2 x1 (t )sin(2 C t ) / 2 17 Note – Second-order frequency must be filtered away – The local oscillator must be precisely in-phase to the received signal, otherwise cross-talk will follows Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Phase-locked loops (PLLs) 18 Phase-locked loop is a feedback arrangement capable to synchronize itself to a noisy external reference The output signals of the loop can be used to produce for instance multitude of locked frequencies PLL application areas include... – modulators – demodulators – frequency synthesis – multiplexers – signal processors Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen The PLL principle The PLL circuit consists of – phase comparator (in the figure below the multiplier) – lowpass filter – feedback amplifier – VCO (voltage controlled oscillator), whose output frequency is linearly proportional to input amplitude Principle: phase difference of Xc(t) and v(t) adjusts VCO Phase comparator output is comparable to phase difference of input signals 19 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen PLL phase comparator realizations Circuits: (a) analog and (b) digital phase comparator circuit Note that for (a) output is proportional to – input signal phase difference – input signal amplitudes (unintended AM thus harmful) In (b) AM effects are compensated and response is more linear pulse ratio: 50/50 ideal XOR-circuit sin(a cos( ) 1 sin( ) 1 sin( ) 2 2 20 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen FM detection by PLL time domain sin (t ) (t ) (t ) v (t ) (t ) 2 K y(t )dt phase domain v t v dv (t ) (t ) dt t v (t ) ( ) d 21 frequency domain t v ( ) d Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen 1 V ( f ) 1 V (0) ( f ) 2 j 2 f PLL FM-demodulator: the feedback analysis Solve transfer function with feedback: Y( f ) Y ( f ) X ( f ) H 2 ( f )Y ( f ) H1 ( f ) Y ( f ) H1 ( f ) H 2 ( f )Y ( f ) X ( f ) H1 ( f ) Y( f ) H1 ( f ) X(f ) 1 H1 ( f ) H 2 ( f ) This is applied to the linearized PLL yielding relationship between the input phase and output voltage: Ka H ( f ) Y( f ) ( f ) 1 K a H ( f ) K v / jf 1 jfKH ( f ) ( f ) K v jf KH ( f ) (K Ka Kv ) 22 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Applying the FM signal to the linearized PLL model Remember the FM wave: d (t ) / dt 2 f x(t ) where the modulating signal is denoted by x(t). The input FM phase to the system is thus (t ) 2 f x( )d t This is in frequency domain: ( f ) 2 f X ( f ) /( j f ) assuming no DC component or V(0) = 0, or v ( ) d t 1 V ( f ) 1 V (0) ( f ) 2 j 2 f 0 23 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Applying FM signal to the detector... (cont.) Thus the input is ( f ) f X ( f ) /( jf ) and the output is 1 jfKH ( f ) f X ( f ) Y( f ) ( f ) HL ( f ) K v jf KH ( f ) Kv where the loop equivalent transfer function is Y(f) HL ( f ) H( f ) H ( f ) j( f / K ) K Ka Kv Assume that the first order LP function is used or f f X(f ) W 1 Y( f ) X ( f ), 1 Kv 1 j( f / K ) Kv K 1 j( f / K ) f y (t ) x(t ) Kv Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen HL ( f ) 24 PLL based frequency synthesizer Reference signal fin is locked for instance to the fundamental frequency of a crystal oscillator f in Phase detector Divide by 10 By adjusting the divider different frequencies can be produced whose phase is locked into fin 25 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen Filt. VCO f out 10 fin Detecting DSB using PLL-principle An important application for PLLs is in synchronization of receiver local oscillator in synchronous detection In the Costas PLL (below) two phase discriminators are used to: – cancel out DSB modulation x(t) in the driving signal – synchronize the output frequency to the center frequency of the DSB spectra (the suppressed carrier) – to detect the DSB signal Costas PLL detector for DSB PD: phase detector (=multiply+LPF) Loop drives phase error to zero 26 LPF yields constant (zero) output when loop is locked to carrier sin ss cos ss 1 sin 2 ss sin 0 ss 2 Helsinki University of Technology,Communications Laboratory, Timo O. Korhonen