Question 29.16: Using a general first-order ΣΔ modulator, assume that the in......
Using a general first-order ΣΔ modulator, assume that the input to the modulator, v_{x}(kT) is a positive DC voltage of 0.4 V. Show the values of each variable around the ΣΔ modulator loop and prove that the overall average output of the DAC approaches 0.4 V after 10 cycles. Assume that the DAC output is ±1 V, and that the integrator output has a unity gain with an initial output voltage of 0.1 V, and that the comparator output is either ±1 V.
The present integrator output will be equal to the sum of the previous integrator output and the previous integrator input. Therefore, Eq. (29.95) becomes
u(k T)=x(k T-T)-q(k T-T)+u(k T-T) (29.95)
v_{u}(k T)=\,v_{u}(k T-T\,)\,+\,v_{a}(k T-T) (29.102)
where
v_{a}(k T)=v_{x}(k T)-v_{q}(k T) (29.103)
and the quantizing error, Q_{e}(k T), is defined by Eqs. (29.96) and (29.98) as
Q_{e}(k T)=y(k T)-u(k T) (29.96)
y(k T)=q(k T) (29.98)
{Q}_{e}(k T)=v_{q}(k T)-v_{u}(k T) (29.104)
The initial conditions define the values of the variable for k = 0. The output of the integrator is given to be 0.1 V. Thus, the ADC output is low, the DAC output is V_{{{R E F}}}, and the output of the summer, v_{a}(0), is 0.4 – V_{{{R E F}}} = – 0.6 V.
The output for k = 1 begins again with the integrator output. Using Eq. (29.102), v_{ u}(k T) becomes
v_{ u}(T)=0.1 + (– 0.6) = – 0.5\ VSince the output of the integrator is negative, the output of the comparator is positive and – V_{{{R E F}}} is subtracted from 0.4 to arrive at the value for v_{a}(T).
Continuing in the same manner and using the previous equations, we can write the voltages for each cycle as seen in Fig. 29.48. After 10 cycles through the modulator, the average value of v_{ q}(k T) becomes,
\overline{{{v_{q}(k T)}}}=\frac{7-3}{10}=0.4\;VNotice that the behavior of \overline{{v_{q}(k T)}} swings around the desired value 0.4 V. If we were to continue computing values, as k increases, the amount that differs \overline{{v_{q}(k T)}} from 0.4 V would decrease. Ideally, we could make the deviation of as \overline{{v_{q}(k T)}} small as desired by allowing the modulator to take as many samples as necessary to meet that accuracy.
