EE345S Real-Time Digital Signal Processing Laboratory


Analog Sinusoidal Modulation

Many ways exist to modulate a message signal $m(t)$ to produce a modulated (transmitted) signal $x(t)$. For amplitude, frequency, and phase modulation, modulated signals can be expressed in the same form as

\begin{displaymath} x(t) = A(t) \cos( 2 \pi f_c t + \Theta(t) ) \end{displaymath}

where $A(t)$ is a real-valued amplitude function (a.k.a. the envelope), $f_c$ is the carrier frequency, and $\Theta(t)$ is the real-valued phase function. Using this framework, several common modulation schemes are described below:
Modulation $A(t)$ $\Theta(t)$ Carrier Type Use
DSB-LC $A_c \left[ 1 + k_a m(t) \right]$ $\Theta_0$ Yes Amplitude AM radio
DSB-SC $A_c m(t)$ $\Theta_0$ No Amplitude  
DSB-VC $A_c m(t) + \epsilon$ $\Theta_0$ Yes Amplitude TV images
SSB $A_c \sqrt{m^2(t) + \left[ m(t) \star h(t) \right]^2}$ $\arctan( - { {m(t) \star h(t)} \over {m(t)} } )$ No Amplitude $\dagger$ Marine radios
QAM $A_c \sqrt{m_1^2(t) + m_2^2(t)}$ $\arctan( - { {m_2(t)} \over {m_1(t)} } )$ No Hybrid Satellite
Phase $A_c$ $\Theta_0 + k_p m(t)$ No Angle  
Frequency $A_c$ $2 \pi k_f \int_0^t m(t) dt$ No Angle FM radio
$\dagger$ $h(t)$ is the impulse response of a bandpass filter or phase shifter to effect a cancellation of one pair of redundant sidebands. For ideal filters and phase shifters, the modulation is amplitude modulation because the phase would not carry any information about $m(t)$. Note that there is one more variant of amplitude modulation known as vestigal sideband modulation in which the upper sideband is kept and a fraction of the lower sideband is kept or vice-versa.

Each TV channel is allocated a bandwidth of 6 MHz. The picture intensity and color information are transmitted using vestigal sideband modulation. The audio portion is frequency modulated.

The quantity

\begin{displaymath} \tilde{x}(t) = A(t) \; e^{ j \Theta(t) } = x_{I}(t) + j x_{Q}(t) \end{displaymath}

is known as the complex envelope, where $x_{I}(t)$ is called the in-phase component and $x_{Q}(t)$ is called the quadrature component. Both $x_{I}(t)$ and $x_{Q}(t)$ are lowpass signals, and hence, the complex envelope $\tilde{x}(t)$ is a lowpass signal. An alterative representation for the modulated signal $x(t)$ is

\begin{displaymath} x(t) = \Re{e} \{ \tilde{x}(t) e^{j 2 \pi f_c t} \} \end{displaymath}



Brian L. Evans